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ANNALS OF BOTANY

VOL. XXXIII

■%

Annals of Botany

EDITED BY

DUKINFIELD HENRY SCOTT, M.A., LL.D., D.Sc., F.R.S.

LATELY HONORARY KEEPER OF THE JODRELL LABORATORY, ROYAL BOTANIC GARDENS, KEW

JOHN BRETLAND FARMER, D.Sc., M.A., F.R.S.

PROFESSOR OF BOTANY, ROYAL COLLEGE OF SCIENCE, LONDON

FRANCIS WALL OLIVER, M.A., D.Sc., F.R.S.

QUAIN PROFESSOR OF BOTANY, UNIVERSITY COLLEGE, LONDON
AND

ROLAND THAXTER, M.A., Ph.D.

PROFESSOR OF CRYPTOGAMIC BOTANY IN HARVARD UNIVERSITY, CAMBRIDGE, MASS., U.S.A.

ASSISTED BY OTHER BOTANISTS

VOLUME XXXIII

With Twenty-eight Plates and One Hundred and Eighty-eight Figures in the Text

LONDON

HUMPHREY MILFORD, OXFORD UNIVERSITY PRESS
AMEN CORNER, E.C.

Edinburgh, Glasgow, New York, Toronto, Melbourne, and Bombay

PRINTED IN ENGLAND

AT THE OXFORD UNIVERSITY PRESS

CONTENTS

-M |

PAGE

William Gibson Farlow • xv-xvi

No. CXXIX, January, 1919.

Scott, D. H. — On the Fertile Shoots of Mesoxylon and an Allied Genus. With Plates I— III

and three Figures in the Text ........... 1

Willis, J. C. — The Flora of Stewart Island (New Zealand) : a Study in Taxonomic Distri-
bution. With two Maps and fourteen Tables in the Text 23

Salisbury, E. J. — Variation in Eranthis hyemalis, Ficaria verna, and other Members of the
Ranunculaceae, with Special Reference to Trimery and the Origin of the Perianth.

With twenty Figures in the Text and Tables I-X 47

Sahni, B.— On an Australian Specimen of Clepsydropsis. With Plate IV and two Figures in

the Text 81

Bracher, Rose. — Observations on Euglena deses. With nine Figures in the Text . . 93

Steil, W. N. — A Study of Apogamy in Nephrodium hirtipes, Hk. With Plates V-VII . 103

NOTE.

Groom, Percy. — The Wood of Tetracentron, Trochodendron, Drimys, and. other Types . 133

No. CXXX, April, 1919.

Digby, L.— On the Archesporial and Meiotic Mitoses of Osmunda. With Plates VIII-XII and

thirty-five Figures in the Text . . . 135

Arber, the late E. A. Newell. — Remarks on the Organization of the Cones of Williamsonia

gigas (L. and H.). With five Figures in the Text 1 73

Haines, F. M. — A New Auxanometer. With two Figures in the Text 181

Spratt, Ethel R. — A Comparative Account of the Root-nodules of the Leguminosae. With

Plate XIII and five Figures in the Text 189

Tuttle, Gwynethe M. — Induced Changes in Reserve Materials in Evergreen Herbaceous

Leaves. With seven Figures in the Text 201

Arber, Agnes. — On the Law of Age and Area, in Relation to the Extinction of Species . 21 1

Carter, Nellie. — Studies on the Chloroplasts of Desmids. I. With Plates XIV-XVIII . 215

Holmes, M. G.— Observations on the Anatomy of Ash-wood with Reference to Water-

conductivity. With seven Figures in the Text 255

NOTE.

Phillips, R. W. — Note on the Duration of the Prothallia of Lastraea Filix-mas, Presl. . . 265

No. CXXXI, July, 1919.

Willis, J. C. — The Floras of the Outlying Islands of New Zealand and their Distribution.

With two Maps and twenty-one Tables in the Text ....... 267

Carter, N. — Studies on the Chloroplasts of Desmids. II. With Plates XIX and XX and

one Figure in the Text 295

Dey, P. K. — Studies in the Physiology of Parasitism. V. Infection by Colletotrichum Linde-

muthianum. With Plate XXI 3°5

Whitby, Stafford. — Variation in Hevea brasiliensis. With one Diagram in the Text . 313

Cleland, Ralph E. — The Cytology and Life-history of Nemalion multifidum, Ag. With

Plates XXII-XXIV and three Figures in the Text 3 23

Blackman, V. H. — The Compound Interest Law and Plant Growth 353

Wormald, H. — The ‘Brown Rot’ Diseases of Fruit Trees, with Special Reference to two

Biologic Forms of Monilia cinerea, Bon. I. With Plates XXV and XXVI . .361

VI

Contents.

PAGE

No. CXXXII, October, 1919.

Petch, T. — Mocharas and the Genus Haeraatomyces. With two Figures in the Text . . 405

Worsdell, W. C. — The Origin and Meaning of Medullary (Intraxylary) Phloem in the

Stems of Dicotyledons. II. Compositae. With twenty-seven Figures in the Text . 421

Arber, Agnes. — Studies on Intrafascicular Cambium in Monocotyledons (III and IV). With

seven Figures in the Text ............ 459

Carter, Nellie. — The Cytology of the Cladophoraceae. With Plate XXVII and two Figures

in the Text . . 467

Willis, J. C. — On the Floras of Certain Islets outlying from Stewart Island (New Zealand).

With one Map in the Text 479

Osborn, T. G. B.— Some Observations on the Tuber of Phylloglossum. With Plate XXVIII

and forty-three Figures in the Text .... ...... 485

Smith, A. Malins. — The Temperature-coefficient of Photosynthesis : a Reply to Criticism.

With two Figures in the Text . • ® <■ 517

INDEX

A. ORIGINAL PAPERS AND NOTES.

PAGE

Arber, Agnes. — On the Law of Age and Area, in Relation to the Extinction of Species . 21 1

Studies on Intrafascicular Cambium in Monocotyledons (III and IV). With

seven Figures in the Text -459

Arber, the late E. A. Newell.— Remarks on the Organization of the Cones of Williamsonia

gigas (L. and H.). With five Figures in the Text 173

Blackman, V. H. — The Compound Interest Law and Plant Growth 353

Bracher, Rose. — Observations on Euglena deses. With nine Figures in the Text . . 93

Carter, Nellie. — Studies on the Chloroplasts of Desmids. I. With Plates XIV-XVIII . 215

Studies on the Chloroplasts of Desmids. II. With Plates XIX and XX

and one Figure in the Text 295

The Cytology of the Ciadophoraceae. With Plate XXVII and two

Figures in the Text 467

Cleland, Ralph E. — The Cytology and Life-history of Nemalion multifidum, Ag. With

Plates XXII-XXIV and three Figures in the Text ....... 323

Dey, P. K. — Studies in the Physiology of Parasitism. V. Infection by Colletotrichum Linde-

muthianum. With Plate XXI 305

Digby, L. — On the Archesporial and Meiotic Mitoses of Osmunda. With Plates VIII-XII

and thirty-five Figures in the Text • 1 35

Groom, Percy. — The Wood of Tetracentron, Trochodendron, Drimys, and other Types . 133

Haines, F. M. — A New Auxanometer. With two Figures in the Text . . . . .181

Holmes, M. G. — Observations on the Anatomy of Ash- wood with Reference to Water-conduc-
tivity. With seven Figures in the Text 255

Obituary :

William Gibson Farlow xv-xvi

Osborn, T. G. B. — Some Observations on the Tuber of Phylloglossum. With Plate XXVIII

and forty-three Figures in the Text 485

Petch, T. — Mocharas and the Genus Haematomyces. With two Figures in the Text . . 405

Phillips, R„ W. — Note on the Duration of the Prothallia of Lastraea Filix-mas, Presl. . . 265

Sahni, B. — On an Australian Specimen of Clepsidropsis. With Plate IV and two Figures in

the Text 81

Salisbury, E. J. — Variation in Eranthis hyemalis, Ficaria verna, and other Members of the
Ranunculaceae, with Special Reference to Trimery and the Origin of the Perianth.

WTith twenty Figures in the Text and Tables 1-X 47

Scott, D. H. — On the Fertile Shoots of Mesoxylon and an Allied Genus. With Plates I— III

and three Figures in the Text 1

Smith, A. Malins. — The Temperature-coefficient of Photosynthesis: a Reply to Criticism.

With two Figures in the Text . . . . . . . . . . . 5 1 7

Spratt, Ethel R.- — A Comparative Account of the Root-nodules of the Leguminosae: With

Plate XIII and five Figures in the Text 189

Steil, W. N. — A Study of Apogamy in Nephrodium hirtipes, Hk. With Plates V-VII . 109

Tuttle, Gwynethe M. — Induced Changes in Reserve Materials in Evergreen Herbaceous

Leaves. With seven Figures in the Text . . . . . . . . .201

Whitby, Stafford, — Variation in Hevea brasiliensis. With one Diagram in the Text . 313

Willis, J. C. — The Flora of Stewart Island (New Zealand) : a Study in Taxonomic Distri-
bution. With two Maps and fourteen Tables in the Text .

23

Vlll

Index.

PAGE

Willis, J. C. — The Floras of the Outlying Islands of New Zealand and their Distribution.

With two Maps and twenty-one Tables in the Text 267

On the Floras of Certain Islets outlying from Stewart Island (New Zealand).

With one Map in the Text 479

Wormald, H. — The ‘Brown Rot’ Diseases of Fruit Trees, with Special Reference to two

Biologic Forms of Monilia cinerea, Bon. I. With Plates XXV and XXVI . . 361

Worsdell, W. C. — The Origin and Meaning of Medullary (Intraxylary) Phloem in the Stems

of Dicotyledons. II. Compositae. With twenty-seven Figures in the Text . . 421

Bu LIST OF ILLUSTRATIONS.

a. Plates. I. Mesoxylon and Mesoxylopsis (Scott).

II. Mesoxylopsis and Mitrospermum (Scott).

III. Mesoxylon (Scott).

IV. Clepsydropsis (Sahni).

V-V1I. Nephrodium hirtipes (Steil).

VIII-XII. Mitoses in Osmunda (Digby).

XIII. Leguminous Root-nodules (Spratt).
XIV-XVIII. Chloroplasts of Desmids (Carter).

XIX, XX. Micrasterias (Carter).

XXI. Colletotrichum (Dey).

XXII-XXIV. Nemalion (Cleland).

XXV, XXVI. Monilia (Wormald).

XXVII. Cladophoraceae (Carter).

XXVIII. Phylloglossum (Osborn).

. Figures. i. Transverse section of fertile shoot, a, and its branch, b (Scott) . . 2

2. Transverse section of fertile shoot, a, and bracts, B. At B, two bracts,

belonging to a branch of the shoot (Scott) 5

3. Part of a branch of Cordaites laevis (restored). It bears several leaves

and two inflorescences, the upper ?, the lower <5, with distichous floral
buds. From Grand’Eury (Scott) . . . .. ( . 9

Map of New Zealand and outlying islands (Willis) . . . . 25

26

» » 1? j) ?;••••

1. Flower of Eranthis hyemalis. The roman numerals indicate the order

of dehiscence (Salisbury) 48

2. Eranthis hyemalis. A and B, flowers with the androecium dissected

away, showing the paired character of the supernumerary honey-
leaves (/) ; c, floral diagram of typical cyclic flower; d, partially
bifurcated honey-leaf ; E and F, petaloid honey-leaves ; g and H,
honey-leaves bearing anthers (a) ; 1 and j, branched stamens ; K, seal
of outer perianth segment ; L, of inner perianth segment ; M, scar of
nectary; n, scar of stamen ; v.b. vascular strand (Salisbury) . 49

3. Ditto. Empirical diagrams showing arrangement of honey-leaves and

stamens (Salisbury) 51

4. Variation ‘curves’ for perianth, honey-leaves, and gynaeceum of E.

hyemalis (Salisbury) 52

5. Eranthis hyemalis. A and B, lobed perianth segments; c, trilobed

bract replacing a perianth member ; d, partially virescent perianth
segment ; e-g, lobed perianth segments ; H, partially coloured bract ;

1, supernumerary perianth segment (Salisbury) . . . .53

Index .

IX

Figures.

PAGE

6. Ditto. Empirical diagrams showing arrangement of bracts and perianth

segments in abnormal flowers (Salisbury) 54

7. Ditto. Meristic variation in androecium (Salisbury) . . . 55

8. Fused carpel and stamen of Eranthis hyemalis (a) and branched carpel

of Helleborus niger (b) (Salisbury) . .... 56

9. Eranthis hyemalis. Variation in bracts (Salisbury) ... 58

10. Ficaria verna. Empirical diagrams showing arrangement of the

perianth segments and stamens (Salisbury) 62

11. a and B, branched stamens of Ficaria verna; C, petaloid stamen;

D, partially coloured sepal ; e3 sepal with lobed lamina ; F, Anemone
nemorosa, branched stamen ; G, bilobed petal of Ficaria verna ;
h-j, variation in the sepals of F. verna (Salisbury) ... 63

12. Ficaria verna. Variation * curve ’ for androecium (Salisbury) . . 64

13. Ditto. Variation ‘ curve * for gynaeceum (Salisbury) ... 65

14. Anemone nemorosa. Variation ‘ curve ’ for androecium (Salisbury) 68

15. Ditto. Variation £ curve ’ for gynaeceum (Salisbury) ... 68

16. A, diagram of perianth of A. nemorosa ; B, floral diagram of Aconitum

napellus ; c, branched stamen of Aquilegia sp. ; d and E, branched
stamens of Delphinium sp. ; F, diagram of perianth of Ranunculus
bulbosus (Salisbury) 69

17. Anemone napellus. Variation ‘ curve ’ for androecium (Salisbury) . 70

18. Variation ‘curve’ for the androecium of Aconitum Lycoctonum

(Salisbury) 70

19. Variation ‘ curve ’ for the gynaeceum of Aquilegia sp. (Salisbury) . 72

20. Stamens of Ranunculus auricomus, var. depauperata, developed in place

of the petals (Salisbury) 73

1. Diagram to show the fossil in plan and elevation (Sahni) ... 85

2. Ditto illustrating the extent to which the intruded roots distort the

normal clepsydroid shape of the leaf-traces (Sahni) ... 87

1. Euglena deseSj showing changes in shape occurring in one individual

during several minutes’ observation (Bracher) .... 95

2. E. deses. Diurnal differences in appearance. (1) Early morning

(actively moving) ; (2) midday (lying still on mud surface) ; (3) night
(rounded off) (Bracher) 96

3. Apparatus for producing tidal effect over area of Avon mud (Bracher) 97

4. Graph representing the intensity of greenness on the mud under normal

conditions with reference to the periods of high water and of dark-
ness (Bracher) 98

5. A graph drawn to illustrate the behaviour of E. deses when removed

from the influence of the tide (Bracher) 100

6. (1) Position of Euglenae at commencement of experiment : a, stiff mud ;

b, wet mud ; c, mud covered by water ; u, water only. ( 2_) Posi-
tion of Euglenae after five days’ illumination from one side
(Bracher) 102

7. E. deses. 1-5, changes in shape of one individual when warmed from

1-5° C. to 160 C. (Bracher) 103

8. Graph showing the time taken for Euglena deses to respond to the

stimulus of light at different temperatures (Bracher) . . .104

9. Showing position taken up by Euglenae on the mud during rain

(Bracher) . 105

1-8. Archesporial divisions. 9-12. Last archesporial division from meta-
phase. 13. Rest between last archesporial division and heterotype
prophase. 14. Intermediate stage between the telophase of the last
archesporial division and the heterotype prophase. 15-27. Hetero-
type division. 28-34. Homotype division. 35. Resting stage of
tetrad (Digby) ........ facing 138

X

Index .

Figures.

page

i. Restoration of female cone of Williamsonia gigas with the front bracts

removed. 2. The same in section (E. A. N. Arber) . . . 1 75

3. Restoration of male cone of Williamsonia gigas. 4. The same in section

(E. A. N. Arber) 176

5. Outline of the ‘ pyriform axis’ (androphore) of a male cone of William-
sonia gigas (after W. C. Williamson) (E. A. N. Arber) . . 177

1. A New Auxanometer (Haines) 182

2. „ ,, (Haines) 184

1. a. Longitudinal section of root and young nodule of Alnus. b. Trans-

verse section of nodule of Alnus. c. Longitudinal section of part of
old branched nodule of Alnus (Spratt) 190

2. a. Longitudinal section of nodule and root of Lupin, b. Longitudinal

section of an older nodule (Spratt) 192

3. Longitudinal section of nodule and root of Spartium (Spratt) . .193

4. a. Longitudinal section of nodule and root of Phaseolus. b. Longitudinal

section of old nodule and root of Lotus corniculatus (Spratt) . 193

5. Longitudinal section of nodule and root of Sophora (Spratt) . *195

1 . Cross-section of Linnaea leaf, showing starch in material exposed to

higher temperature for one week. Section treated with chloral
hydrate and iodine (Tuttle) 204

2. Horizontal section of Linnaea leaf, showing starch in epidermal cells.

The material had been exposed to higher temperature for one week.
Section treated with chloral hydrate and iodine (Tuttle) . .204

3. Horizontal section of Linnaea leaf, showing oils and fat in epidermal

cells. Material fresh from outside before exposure to higher tempera-
ture. Section treated with 1 per cent, osmic acid (Tuttle) . . 205

4. Linnaea material exposed to higher temperature for four days, sections

of which were treated with chloral hydrate and iodine (Tuttle) . 203

5. Cross-section of Linnaea leaf, showing fats and oils before exposure to

higher temperature. Section treated with 1 per cent, osmic acid
(Tuttle) 206

6. Cross-section of Linnaea leaf, showing decreased fat and oil content.

Material exposed to higher temperature for one week. Section
treated with 1 per cent, osmic acid (Tuttle) .... 206

7. Cross-section of Linnaea leaf. Material outside for reconversion during

extremely low temperature. Section treated with iodine solution

(Tuttle) 207

Observations on the Anatcmy of Ash- wood with reference to Water-
conductivity (Holmes) —

1. Specimens A 8, A 8 a, A 8 b, A 8 e (Holmes) . . . *256

2. Specimens A 3, A 4, A 6, A 8 a, A 8 b, A 8 e (Holmes) . . . 257

3. Specimens A 3, A 4, A 6 (Holmes) 257

4. Specimen A 3 (Holmes) . 258

5. Specimen A 4 (Holmes) . . . . . . . . . 259

6. Specimen A 6 (Holmes) ......... 260

7. Specimens A 8, A 8 a, A 8 b} A 8 e (Holmes) 261

Map of New Zealand and outlying islands (Willis) .... 267

Map of New Zealand and islands to show imaginary distribution from

Auckland and Dunedin (Willis) 268

Micrasterias apiculata, (Ehrenb.) Menegh (Carter) .... 300

Diagram showing frequency curve and yield in grammes per day of

1,011 seven-year-old Hevea brasiliensis (Whitby) . . . 317

1. The growing apex of the thallus. a. Apical cell of a young assimilative

branch, b. Lateral budding to form a new branch, c. Terminal cell
of a central strand filament (Cleland) 325

2. Method of growth in a vegetative tuft. a. Lateral budding to form

Index .

xi

Figures.

page

a side-branch. b. Terminal budding to form a trichome. c. False
appearance of dichotomy, d. Trichome developed on the median
line. e. Trichome developed to one side of the mjdian line.
f. Looped central strand filament (Cleland) . . . .32')

3. A cystocarp developing its first carpospores, showing, the withering
trichogyne, condition of the chromatophore, the fusion of the stalk-
cells, and food particles in the stalk (Cleland) .... 340

1. Inner surface of the cortex of Bombax malabaricum, when producing

Mocharas (Petch) 412

2. Longitudinal section of the cortex of Bombax malabaricum, when pro-

ducing Mocharas. A, wood ; B, abnormal cortex ; c, normal cortex
with lignified fibres ; d, galleries of Mocharas ; E, browned tissue ,

showing extension of Mocharas formation; f, lignified vessels

(Petch) . 413

r. Tragopogon orientalis. Transverse sections of the extreme base of the
central cylinder of the stem, numbered from below upwards
(Worsdell) 426

2. Tragopogon. Longitudinal section of the lower part of the central

cylinder of the stem, showing the typical origin and course of the
medullary strands in the genus (Worsdell) 426

3. Tragopogon orientalis. Segment of vascular ring, showing internal-

phloem strands imps) (Worsdell) 426

4. Tolpis barbata. Vascular ring, showing transitions between some of its

constituents and the medullary bundles (mb). Rudimentary medullar
strands (bundles and phloem-strands) are shown at ms (Worsdell) 126

5. Lactuca virosa. Segment of vascular ring from lower part of stem ; in

the pith are scattered bundles and phloem-strands (Worsdell) . 431

6. L. virosa. Ditto from upper part of stem, showing arc-shaped internal -

phloem-strands (Worsdell) 431

7. L. Plumieri. Petiole, showing vascular ring ( vr ) and medullary strands

(ms) (Worsdell) 431

8. L. alpina. Petiole, showing vascular ring and medullary strands (ms)

(Worsdell) . . . 431

9, 10. Crepis biennis. Segments of vascular ring of stem, showing medullary
strands (ms) in the bay formed by the outgoing median leaf-bundle
(mlb). One of the lateral leaf- bundles at lib (Worsdell) ®. . 434

11. C. biennis. Petiole, showing the vestigial character of the adaxial

portion of the vascular ring (avr), the central medullary strands
(cms), and the peripheral medullary strands (pms)>( Worsdell) . 435

12. Picris hieracioides. Vascular ring of stem, showing its vestigial outer-

most constituents (vvr) and two peripheral medullary bundles (mb)
(Worsdell) 437

13. P. strigosa. Vascular ring and medullary bundles (mb) (Worsdell) 438

14. Helminthia echioides. Segment of cylinder of stem, showing vascular

ring and the scattered medullary phloem-strands (mps) (Worsdell) 438

15. Cynara Scolymus. Segment of vascular cylinder and cortex (c) of

uppermost portion of peduncle, showing the scattered disposition of
the bundles (Worsdell) . 440

16. C. Cardunculus. Petiole, showing scattered disposition of the bundles

(Worsdell) 440

1 7. Gundelia Tournefortii. Segment of cylinder of stem, showing scattered

medullary phloem-strands (mps) (Worsdell) .... 442

18. Senecio clivorum. Petiole, showing extreme scattered disposition of

the bundles (Worsdell) 442

19. Petasites officinalis. Peduncle of male plant, showing scattered disposi-

tion of bundles (Worsdell) 443 .

Index .

xii

Figures.

page

20. P. officinalis. Petiole, showing well-developed medullary system of

bundles. Bundles of adaxial portion of vascular ring at avr
(Worsdell) - 445

21. Rudbeckia laciniata. Vascular cylinder of stem, showing absence ot

medullary strands (Worsdell) 445

22. R. maxima. Ditto, showing presence of medullary bundles ( mb )

(Worsdell) 445

23. R. maxima. Leaf, showing complete absence of medullary bundles

(Worsdell) 445

24. Echinacea (Rudbeckia) purpurea. Vascular cylinder of stem, showing

rudimentary central medullary bundles ( mb ) (Worsdell) . . 445

25. E. (Rudbeckia) purpurea. Petiole, showing medullary bundles (mb).

The most peripheral of these (pmb) are recent lateral derivatives
from the arc-bundles to which they are opposed (Worsdell) . 446

26. Inula Helenium. Segment of vascular ring of stem, showing medullary

phloem-strands (nips). Leaf-bundles at lb (Worsdell) . . 448

27. I. Helenium. Petiole, showing well-marked scattered disposition of

the bundles, and the small inverted bundles ( pms ) on the ventral
side of the median bundle of the arc (Worsdell) .... 448

1-5. Transverse sections of leaf-bundles (Agnes Arber) .... 461

6. Carludovica rotundifolius H. Wendl. Transverse section of bundle

from near growing point of axis (Agnes Arber) .... 463

7. Sciaphila purpurea Benth. Transverse section of a bundle from an

axis less than 1 mm. in diameter (Agnes Arber) . . . 463

1. Rhizoclonium hieroglyphicum, (Klitz.) Stockm. a, transverse section

of a filament in the autumn condition ; B, external view of part of
a similar filament ; C and D, transverse sections of a very narrow
form ; e and F, transverse sections of a much larger form ; g, part
of a longitudinal section of a similar filament (Carter) . , 470

2. Chaetomorpha, Kiitz. A and B, Ch. gracilis, Kiitz. Transverse sections.

C, Ch. Linum, (Muell.) Kiitz. Longitudinal section (Carter) . 471

Map of New Zealand and outlying islands (Willis) .... 479

1. Four-leaved sterile plant showing current tuber buried about 18 mm.

New tuber formed on short stalk at shallower depth (Oct. 1917)
(Osborn) 486

2. Two-leaved sterile plant with current tuber 4 mm. below ground-level.

Newr tuber formed on long stalk. Sunken about 11 mm. (Oct. 1917)
(Osborn) '486

3. Single-leaved plant with current tuber partially exposed. New tuber

as yet scarcely swollen, but sunken to 7 mm. (Sept. 14,1918) (Osborn) 486

4. Graph showing variation in depth of current and new tubers on 186

plants collected from (approx.) 300 sq. cm. soil (Oct. 1917)
(Osborn) 488

5. Single-leaved plant with current tuber C.T. and two old season’s coats,

o.T.j and o.t.2. This plant is entering on the fourth season of
growth. At this date the root is short and no new tuber visible
(June 13, 1918) (Osborn) 490

6. Two-leaved plant with current tuber c.T. at 1 1 mm. depth, new tuber

N.T. just forming. Coats of three previous seasons’ tubers (o.t.j,
o.t.2s 0.t.3) are just below ground-level, showing depth adjustment
in 1917 (July 11, 1918) (Osborn) 490

7. Three-leaved plant with current tuber C.T. at 9 mm. depth. Old

tuber coats (o.T., &c.) of four previous seasons at shallower depth

(July li, 1918) (Osborn) 490

8-14. Regenerating leaves collected in field (Oct. 1917)* 8* Detached leai

lying horizontally on soil showing regeneration. A stalk’s minute

Index .

xm

Figures.

page

tuber has formed from the cell mass developed at proximal end. The
scar (sc.) is almost obliterated. 9 A. Leaf as collected. 9 b. Same
after seven weeks on moist soil, n A. Leaf as collected. 11 b. Same
after seven weeks on moist soil. 12 A. Leaf with unusually large
cell mass formed at ground-level, also stalk with growing-point
beginning to elongate. 12 b and c. Same viewed from proximal end.

13. Single-leaved plant forming adventitious cell mass on leaf above
injury, also new tuber; current tuber not shown. Fig. 14. Three-
leaved plant with cell mass forming from proximal end of broken
leaf (Osborn) 492

1 5. Three-leaved plant grown in laboratory. One leaf, injured July 17, 1918,

has developed an adventitious tuber (Osborn) .... 494

16-22. Leaves of Series B, detached and put on soil July 11, 1918. The dates
below in brackets are those on which the figures were drawn. 16 A.

Cell mass forming (Sept. 16). 16 b. Same with adventitious tuber

(Nov. 16). 17 a. Growing-point just visible on cell mass (Sept. 16).

17 b. Same, showing elongation of stalk (Sept. 24). 18 a. Cell

mass with rhizoids and short stalk bearing growing-point (Sept. 16).

1 8 b. Same developing two growing- points from cell mass, also
‘leaflet’ (Sept. 26). 18 c. ‘Leaflet’ enlarged, two tubers forming

(Oct. 8). 18 D. Same : tubers are smaller and less regular than those

formed singly by other leaves of the same series. Rhizoids absent
(Nov. 16). 19 A. Small cell mass, stalk, and growing-point

(Sept. 16). 19 b. Same (Nov. 16). 20 A. Portion of leaf showing

cell mass. Leaflet stalk and tubers beginning to swell. No rhizoids
at this date (Oct. 8). 20 B. Same original leaf beginning to rot

(Nov. 16). 21 and 22. Two remaining leaves of series (Nov. 16)

(Osborn) 496

23-29. Leaves of various series. The dates below in brackets are those on
which the various figures were drawn. 23. Leaf of Series C. The
cell mass is nodulose ; a transverse section of this leaf is seen Fig. 38
(Sept. 24). 24 a and b. Leaf of Series C. This leaf curved on

soil in horizontal plane. Adventitious growth from convex side
(Nov. 16). 25. Leaf of Series D. Note absence of definite growing-

point and formation of many starchy cell masses (Oct. 21). 26-29.

Leaves of Series E (Nov. 25) (Osborn) 499

30-35. Leaves of Series A, detached and put on soil June 13, 1918. The dates
below in brackets are those on which the figures were drawn. 30.
Adventitious tuber arising from side (Nov. 16). 31. Extreme case

of leaf curvature in vertical plane. Cell mass nodular (Sept. 16).

32 A. Leaf showing vertical curvature. This leaf appears to be an
exception to rule that adventitious growth occurs from convex surface
(Sept. 16). 32 B. Same, viewed from above ; note nodular develop-

ment of cell mass. This leaf was laid flat on soil Sept. 16 (Oct. 21).

32 c. Same ; note many short-stalked, white, swollen bodies
(Nov. 27). 33 A. Leaf viewed from above, and B, viewed from side,

showing geotropic curvature of the many minute, stalked tubers
(Nov. 27). 34 A. Leaf viewed from above, and B, viewed from below
(Nov. 26). 35. Portion of leaf, viewed from side, with several

scattered centres of adventitious growth. Two have developed leaf-
lets and small tubers (Nov. 17) (Osborn) 502

36. Portion of transverse section of leaf showing adventitious growth from

single epidermal cell. Stomate seen to left (Osborn) . . . 503

37. Transverse section of leaf showing considerable cell mass of epider-

mal origin, interrupted by stomate at St. Growth is becoming
localized by development of growing-point seen at right (Osborn) . 503

XIV

Index .

PAGE

Figures. 38. Transverse section of leaf (see Fig. 23). Two growing-points are
developing ; the anticlinal walls separating the groups of epidermal
cells involved are plainly seen (Osborn) 503

39. Portion of longitudinal section showing junction of leaf tissue and cell

mass showing epideimal origin of latter. Cell mass developed
stalk in which a ‘tracheide’ is seen (Osborn) .... 503

40. Transverse section of leaf ; epidermis indicated by faint line. An

irregular cell mass has formed, and the growing-point has begun to
invaginate (Osborn) ....... . 505

41. Portion of longitudinal section through cell mass, stalk (wdiich was

accidentally bent), and tuber. ‘Vascular supply’ seen from its
expansion in cell mass to cup of ‘ tracheides ’ around growing apex
(x). Apex projecting into the chamber and seated on spherical mass
of starchy tissue. The whole length of channel shown (Osborn) . 505

42. Longitudinal section of adventitious growth on leaf in Fig. 20 B. Apex

( x ) seen projecting into chamber ; extent of starchy tissue shown by
faint line. Greater part of ‘ vascular supply ’ seen extending towards
‘ leaflet’ (/) (which passes out of plane of section), but no ‘ leaflet’
bundle differentiated (Osborn) 505

43. Detail of apex of tuber seen Fig. 41. Starchy tissue indicated by heavier

outline to cells (Osborn) 506

1. This figure is redrawn from Matlhaei’s Fig. 3, rectifying a mistake and

adding, from her tables, two omissions (Smith) .... 522

2. Reinke’s results. Curve A. Average of all results in Tables I to VIII.

B. Average of all results except those obtained after the plant had
been once exposed to 16 units of light (Smith) .... 533

William Gilson Farlow.

HE news of Professor Farlow’s death on June 3 has been received with

X. sincere regret by British botanists, more especially by those who are
connected with the ‘ Annals of Botany \ All who have had the pleasure of
working with him mourn the loss of a loyal and able colleague and a genial

friend.

It is only fitting that some notice of him should appear in this periodical,
of which he was formerly one of the editors : but nothing like an exhaustive
account of his life or a critical estimate of his writings need be attempted.
It will suffice to give, in this short sketch, some general appreciation of his
significance as a botanist.

William Gilson Farlow was born in Boston on December 17, 1844.
He studied at Harvard, and concluded his University career by taking the
degree of M.D. in 1870. Although he graduated in Medicine, his intention
was to devote himself to Botany, no doubt inspired by Asa Gray. How he
proceeded to carry out this intention is told in a pamphlet, e Cryptogamic
Botany at Harvard University, 1874-96 \ published when his life-work was
about half done. He narrates how he was invited by Asa Gray in 1870 to
give instruction in Cryptogamic Botany, and how impossible he found it to
acquire in America even a passable knowledge of the subject that he had
to teach. Consequently he came to Europe for instruction, and spent two
years studying in Germany and France.

It may be remarked incidentally that a considerable portion of this
time was spent in the laboratory of de Bary at Strasburg. Whilst working
there, he made the interesting discovery, which has made his name familiar
to all botanists, that the prothallus of certain Ferns gives rise vegetatively
to young Fern-plants (Bot. Zeitg., 1874). This remarkable substitution of
vegetative propagation for sexual reproduction was subsequently further
investigated by de Bary and termed 4 apogamy ’ (Bot. Zeitg., 1878).
Farlow’s attention was, however, mainly directed to Algae and Fungi,
a study in which at that time de Bary was pre-eminent.

On his return, fully equipped, to America, Farlow was appointed
Assistant Professor of Botany at Harvard (1874). In the pamphlet he tells
by what slow and painful degrees he established a laboratory and accumu-
lated a herbarium for the proper teaching and study of his subject. His
efforts were crowned with such success that they were soon recognized by
his promotion to full professorial rank as Professor of Cryptogamic Botany

[Annals of Botany, Vol. XXXIII. No. CXXXII. October, 1919.]

xvi Obituary . — William Gilson Far low.

(1879), a title which he bore until his death although he had not been
engaged in active teaching for some years previously.

The pamphlet contains striking evidence of the activity that prevailed
in the cryptogamic department during the first twenty years of its existence,
in the form of a list of the numerous papers, all relating to Algae or Fungi,
published as the outcome of work accomplished within it. Among the
authors, besides Farlow himself, are many whose names have since become
well known, such as Thaxter, Humphrey, Davis, Richards, Burt, Peirce,
Galloway. Were there a similar record of the doings of the department
during the succeeding twenty years, it would be at least as brilliant as that
of the earlier period.

Farlow goes on to contrast the position of his study at the beginning
and at the end of the period under review. He points out that whereas in
1872 he had ‘found it impossible to obtain instruction in Cryptogamic
Botany anywhere in the United States, there are in 1896 many institutions
scattered over the country where a student can in a few weeks acquire the
knowledge which it took the writer several years to gather together in
different European countries ’. It is for us to say, what Farlow himself could
not say, that this great change was, directly or indirectly, due to his own
efforts. When it is remembered that these ‘ institutions scattered over the
country ’ taught not only Cryptogamic Botany but all the other branches of
the science as well, some idea can be formed of the revolution that had been
brought about, affecting the national attitude towards Botany so profoundly
that in no country in the world has botanical organization, both academic
and practical, become more extensive and efficient than in the United States.
Farlow had brought back with him from Europe not only the information
necessary for his work, but also, what was far more important, the inspira-
tion of the modern spirit, of which, as he points out, Sachs’s ‘ Lehrbuch ’ was
to him the embodiment. Without at all under-estimating the value of his
published work, it may be truly said that Farlow’s real significance is that
of a pioneer or missionary.

He readily associated himself with those who had been working on
similar lines in this country, when they founded a modern and adequate
periodical for the publication of the results of botanical research. He at
once accepted the position of American Editor, and his name appears on
the title-page of vols. i-xx of the ‘Annals of Botany’ (1887-1906). His
co-operation was invaluable, and contributed largely to establish the friendly
relations existing between English-speaking botanists on opposite sides of
the Atlantic.

S. H. V.

Vol. XXXIII. No. CXXIX. January, 1919. Price 14s.

Annals of Botany

EDITED BY

DUKINFIELD HENRY SCOTT, M.A., LL.D., D.Sc., F.R.S.

LATELY HONORARY KEEPER OF THE JODRELL LABORATORY, ROYAL BOTANIC GARDENS, KEW

JOHN BRETLAND FARMER, D.Sc., M.A., F.R.S.

PROFESSOR OF BOTANY, ROYAL COLLEGE OF SCIENCE, LONDON

FRANCIS WALL OLIVER, M.A., D.Sc., F.R.S.

QUAIN PROFESSOR OF BOTANY, UNIVERSITY COLLEGE, LONDON

AND

ROLAND THAXTER, M.A., Ph.D.

PROFESSOR OF CRYPTOGAMIC BOTANY IN HARVARD UNIVERSITY, CAMBRIDGE, MASS., U.S.A.

ASSISTED BY OTHER

LONDON

HUMPHREY MILFORD, OXFORD UNIVERSITY PRESS
AMEN CORNER, E.C.

Edinburgh, Glasgow, New York, Toronto,
Melbourne, Cape Town, and Bombay

1919

Priuted in England at the Oxford University Press.

CONTENTS.

PAGE

SCOTT, D. H. — On the Fertile Shoots of Mesoxylon and an Allied Genus. With Plates

I— III and three Figures in the Text i

Willis, J. C. — The Flora of Stewart Island (New Zealand): a Study in Taxonomic

Distribution. With two Maps and fourteen Tables in the Text ..... 23

Salisbury, E. J. — Variation in E,ranthis hyemalis, Ficaria verna, and other Members of
the Ranunculaceae, with Special Reference to Trimery and the Origin of the Perianth.

With twenty Figures in the Text and Tables I-X 47

Sahni, B. — On an Australian Specimen of Clepsydropsis. With Plate IV and two Figures

in the Text . . . . . . .81

Bracher, Rose. — Observations on Euglena deses. With nine Figures in the Text . 93

Steil,‘W. N. — Apogamy in Nephrodium hirtipes, Hk. With Plates V- VI I . ’r~ ,: . 109

NOTE.

Groom, Percy.— The Wood of Tetracentron, Trochodendron, Drimys, and other

Types 133

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On the Fertile Shoots of Mesoxylon and an
Allied Genus.

BY

D. H. SCOTT, F.R.S.

With Plates I-III and three Figures in the Text.

{* FEB 25 1919

\ /?/

Contents,

PAGE

PAGE

The Fertile Shoots of Mesoxylon

MULTIRAME .

Stems of the Mesoxylon Type with
i a Single Leaf-trace — a New

Description of the Specimens
Nature of the ‘ Appendage ’
Anatomical Details .
Discussion ....

i Genus .

7 Discussion

^ Conclusion .

15

16

*7

*9

Other Shoots associated with Seeds
Discussion

I2 References .

14 Explanation of the Plates

20

The Fertile Shoots of Mesoxylon multirame,

IN a recent paper on the structure of this species of Mesoxylon (Scott,
1918, p. 453) it was pointed out that the axillary shoots are branch-
systems of a special kind, entirely different from the relatively main axis
which bears them. They are characterized by the bilaterally symmetrical
organization of the shoot, with a much flattened stele, and by the distichous
branches, which bear reduced leaves or bracts, as well as other appendages
which may be either prophylls or secondary branchlets. The shoots are
closely associated with seeds (Mitrospermum compression, A. Arber) and
may have been the organs which bore them. They are termed ‘ fertile
shoots as there is little doubt that they were connected with reproduction.
In the present communication it is proposed to describe these organs fully,
and to discuss the evidence available as to their function.

Description of the Specimens .

In some ways the most important specimen is one shown in immediate
association with a stem of M. multirame 1 bearing axillary shoots, for here
we have direct evidence for the fertile shoot belonging to the plant. This

1 Sections Scott Collection 2564-70.

[Annals of Botany, Vol. XXXIII. No. CXXIX. January, 1919.]

B

2

Scott. — On the Fertile Shoots of

specimen will be considered later, but in the first instance it will be most
satisfactory to describe a much better preserved example from another
series ; 1 though not actually associated with a stem, many leaves of the
Mesoxylon type are present, and the structure of the shoot itself leaves
no doubt as to its nature.

The first section of this series is an important one and is fully illustrated
(Text-fig. i ; PL III, Figs. 17-19). The main part of the specimen is
a much flattened, apparently naked axis, in approximately transverse
section, measuring about 6-5 x 1-5 mm. (Text-fig. 1). It has an extremely
long and narrow stele, just as in the well-known axillary shoots of M. multi-
rame (Scott, 1918, PI. XIII, Fig. 22). The secondary wood is 3-5 elements
thick ; where the stele is least collapsed, groups of irregularly arranged
elements with somewhat thick walls are seen at the inner edge of the

A

Text-FIG. i. Transverse section of fertile shoot, A, and its branch, B. For details see Plate III,
Figs. 17-19. x 12. S. 2781. From a drawing by Mr. G. T. Gwilliam.

secondary zone, and may possibly represent the centripetal xylem of the
stele, though the other sections lend little support to this interpretation
(PI. Ill, Fig. 18). The stele is branching ; at one end a small round stele
with little or no pith is passing out, and immediately beyond it a small distal
bundle is seen (PL III, Fig. 19). These features are very constant wherever
this phase of branching is observed.

At the opposite end of the section (B) there is a large branch detached,
but obviously broken off from the main shoot (Text-fig. 1 ; PL III, Fig. 17).
It bears bracts, seen both in connexion with the branch and just free ; each
bract has a single vascular bundle. The branch itself has a rounded stele,
with its bundles somewhat widely spaced, and a considerable pith.

The branch is also giving off a distal appendage (cut obliquely), clearly
subtended by one of the bracts, which ensheathes it (Pl. III, Fig. 17). This
appendage therefore seems to be a secondary branchlet. The presence of

Sections S. 2781-95. Ail the specimens described in this paper are from Shore, Littleborough.

Mesoxylon and an Allied Genus. 3

an appendage has been observed in several cases, but its nature is open to
question (see p. 7).

The main shoot has a certain amount of hypodermal sclerenchyma
which extends into the branch, and is especially well developed on the
abaxial side of the bracts.

The next section (2782) is not so complete, but at the end (a) where the
little round stele was given off in 2781, we now see the base of a branch
attached, with a round medullate stele just like that of the former branch.
It thus appears that the relatively large stele of the branch, with its pith and
distinct bundles, is an expansion of the little pithless stele first given off from
the main stele of the shoot. The relative dimensions are — for the branch-
stele when first given off, about 0-25 mm. ; for the stele when it has passed
into the branch, about 0*7 mm. ; measuring to the outside of the wood only
in each case. The branch seen in the previous section (at the end marked B)
is in this case (2782) only represented by bracts.

In the third section (2783) (PI. I, Fig. 1) the branch of which we saw
the base before (at the A end) is here quite free. The bracts and their bases
are well shown, but the stele has perished. At the opposite end of the sec-
tion (b) another little stele is being given off ; it is cut obliquely enough to
show that tracheides extend to the centre. There are some irregularities in
the wood of the main stele here which may be pathological. Off this end
a branch or bud is present in oblique section — perhaps the upper part of the
first branch.

In the fourth section (2784) a little branch-stele is again detached
(at the A end). It shows the small distal bundle, which here seems to have
just separated from the branch-stele.

In the fifth section (2785) the branch-stele (at the A end) has moved
farther out ; it has expanded slightly and acquired a pith. The little distal
bundle has moved far out into the cortex. Beyond the opposite end
there are some bracts, cut longitudinally, and at a greater distance are two
buds in transverse section, each showing both the bracts and a stout appen-
dage lying outside the bract-cycles (PI. I, Fig. 2). The presence of these
buds is explained by the next sections, which show that the axillary shoot
curved, so as to be cut in a more longitudinal direction in the later sections ;
the buds evidently belong to the part of the shoot which runs almost longi-
tudinally. It is not necessary to follow the series farther in detail ; enough
has been said to show that the axillary shoot gives off distichous leafy
branches alternately, the plane of branching being that of the flattened stele
of the shoot. The branch, besides the small leaves or bracts, bears a further
appendage, the nature of which is discussed below (p. 7).

Anatomically each branch receives a stele from the main shoot ; it is
small when first given off, but rapidly expands and becomes medullated.
Each bract contains a single vascular bundle, while the appendage has

4

Scott. — On the Fertile Shoots of

a minute stele or mesarch bundle. In the later sections of the series
another axillary shoot (in 2793) and two or three more branches or buds are
met with. In two of these (in slide 2789) there is an appendage in addition
to the bracts, like that shown in PI. I, Fig. 2. In one case it is possible that
a second appendage is present in the same bud.

The fertile shoot is associated, though not very closely in this case, with
a number of seeds. In the series of fifteen sections twelve distinct specimens
of Mitrospermum compressum , A. Arber, occur. They present all the
characters of the species, and there is no doubt as to their identification (see
p. 18). None of them, however, show any special relation to the fertile
shoots, so the evidence is simply that of association, and such force as it has
depends on the high number of the associated seeds. One of the Mitro-
spermum seeds (shown in sections 2792-4) appears to be young, judging
from the comparative thinness of the cell-walls of the sclerotesta, but though
this seed is in the neighbourhood of the second axillary shoot there is
no indication of any connexion.

Some of the sections of the Mitrospermum are interesting in themselves ;
in one (section 2781) the prothallus is preserved ; another (2787) shows four
pollen-grains in the pollen-chamber, and a third (2791) passes through the
chalaza. Though these details are irrelevant to our immediate question, it
has been thought worth while to figure the two former (PI. II, Figs. 15, 16).

It is fair to mention that other seeds, Physostoma elegans and Conostoma
oblongum , occur in the series, but only a couple of specimens of the former
and one of the latter.

We have next to consider the specimen of a fertile shoot associated with
a vegetative stem of M. multirame} The stem is of the ordinary type,
about 2 cm. in diameter, with a pith varying from about 7 to 9 mm. in
diameter in different parts of the specimen, and wood from 2 to 2*5 mm. in
thickness. It is thus a rather small and young stem (PI. I, Fig. 4).

All the distinctive characters of the species, especially the very gradual
convergence of the twin-bundles of the leaf-trace at the margin of the pith,
are shown, though the preservation is not specially good. The stem,
particularly in its lower part, bears a number of axillary shoots, of which the
characteristic steles are conspicuous (PI. I, Fig. 4); they have the usual
tangentially elongated or flattened form, and their secondary wood is thicker
on the inner than on the outer face.

The fertile shoot lies quite close to the stem (PI. I, Fig. 4) ; it is not
much flattened, though the outline is irregular and distorted. The transverse
dimensions are roughly 2-9 x 2 mm. In the section in which the shoot first
appears (2564) the main stele is badly preserved, but at one end (A) a small,
round, pithless stele has been given off, and there are traces of a minute distal

1 The vegetative stem runs through the series 2563 to 2574, from below upwards; slides 2984
and 2985 appear to be of the same stem, as are also the longitudinal sections 2575-8.

Mesoxylon and an Allied Genus, 5

strand. The hypodermal sclerenchyma of the shoot is strongly developed.
At the opposite end (b) the shoot bears a large hastate branch, not much
smaller than itself, measuring, in the oblique section, about 2*4 X 2 mm.
in diameter (PL I, Fig. 4, b). The three projections appear to be the
bases of bracts ; no other appendage is distinguishable. The middle is
occupied by a large medullate stele, with bundles well separated, just as in
the former specimen. The pith has

almost perished. The distal arc of A

the vascular ring projects outwards,
but this may be due to accidental
causes.

In the next section (2565) the
little round stele (at the A end) has
enlarged and acquired a small pith ;
at the opposite end the branch is de-
tached, but the preservation is bad.

The third section (2566) (Text-
fig. 2) is favourable for the axillary
shoot, in which the very narrow stele
is fairly preserved ; at one end (b)
the usual round branch-stele, with
its distal bundle, is passing out.

Branches at either end are repre-
sented by bracts (shown at b).

The next section (2567) shows
little change; the same round branch-
stele and distal bundle are present, as
before.

In the fifth section (2568) the
shoot has diminished somewhat in
size (to about 2-5 x 1*75 mm.) ; it is
badly preserved, but bears a large
hastate branch, much like that in
the first section, but so cut as to
appear attached by a narrower base
(PL I, Fig. 5). At a distance of
only o-8 mm. from the shoot, at the opposite end to the branch, is a seed
of Mitrospermum compression , in transverse section. There is, however,
no indication of any connexion with the fertile shoot.

In the following section (2569) little remains of the shoot. A second
seed is present, close to the former ; it is a rather young Mitrospermum t
judging from the comparatively thin- walled sclerotesta ; again there is
no evidence of connexion with the shoot or its branches.

Text-fig. 2. Transverse section of fertile
shoot, A, and bracts, B. si., main stele of shoot;
b.st., stele of a branch; v.b., distal bundle. At B,
two bracts, belonging to a branch of the shoot,
x 40. S. 2566. From a drawing by Mr. G. T.
G william.

6

Scott. — On the Fertile Shoots of

Nothing more of interest is shown in the series. In another section,
apparently from the same specimen (2985), a detached axillary shoot
is present close to the stem, but it does not show branching, for it is
no doubt cut near the base.

I have found no other specimens of Mitrospermum in this series
besides the two mentioned above. In this case, therefore, their significance
depends, not on their number, but on their close association with the fertile
shoot. Whether the two seeds were originally attached to the shoot cannot
be determined, but it is not improbable that this was the case.

The specimen is inferior to that in the previous series ; in particular the
organ which we have called the appendage of the branch is nowhere clearly
shown, though it was almost certainly present, as the other characters agree
so closely with those of the former specimen. The special interest of the
shoot just described Ires in its close association, on the one hand, with
Mitrospermum compression^ and on the other with a stem of Mesoxylon
multirame bearing axillary shoots. From the structure of the fertile shoot,
especially its narrow, flattened stele, there can be no doubt that it is of the
same nature as the axillary shoots borne on the stem ; it evidently consti-
tutes the upper part of a shoot, of which the base may have been still
attached to the main stem..

There is another example of a fertile branch shown in a single section
(3040) ; the specimen is associated with leaves of the Mesoxylon type,
but not with a stem or with seeds. It is the best specimen for the general
habit, as it is so little distorted. The shoot is seen in somewhat oblique
transverse section, and measures about 5x2 mm. (PL I, Fig. 6). The
Identity with the axillary shoots of Mesoxylon multirame is manifest (cf.
Scott, 1918, PI. XIII, Fig. 22). The constriction near one end of the section
seems to be accidental. The stele is about 2 mm. long by only 0-37 mm.
broad, and is thus a good deal flattened, though the whole shoot is not.
As pointed out in a previous paper (Scott, 1918, p. 443), the narrow form of
the stele in these shoots is no doubt in the main the natural one. The
secondary wood is three or four elements thick ; no centripetal xylem
is preserved. The Dictyoxylon outer cortex is well developed ; dark
elements (secretory sacs ?) are, as usual, present in the inner cortex.

At one end of the section the shoot bears a large branch or bud, nearly
3 mm. in diameter (PI. I, Fig. 6, b). It consists of an axis, continuous
with that of the shoot, and a number of bracts, several of which are in con-
nexion with the axis, while one is free. The large medullate stele of the
branch (o-8 mm. in diameter) is cut obliquely. On its distal side several
leaf-trace bundles are seen on their way out to bracts. The dorsal bands of
fibres in the bracts are well shown.

The specimen thus exhibits the general characters of the fertile shoot
clearly, but affords no new data. No distal appendage is shown, but the
plane of section would probably have missed it.

Mesoxylon and an Allied Genus .

7

Nature of the 1 Appendage ’.

The nature of the appendage of the branch seen in several sections of
the first series described (from 2781 onwards) remains doubtful. From the
evidence of the sectiofi represented in Text-fig. 1 and PL III, Fig. 17, it
would appear that the appendage is a secondary branchlet, for it is clearly
subtended by a bract. The other four cases observed (a typical example is
shown in PJ. I, Fig. 2) are all from detached buds or branches. In all of
these the appendage lies outside the regular cycles of bracts, and is of
relatively large size ; in the case figured, for example, it measures quite
1 mm. in diameter, while all the rest of the bud is only about 1*7 x 1-3 mm.
The appendage is not subtended by a bract in any of these examples, though
in that figured there appear to be one or two on one side of it. The struc-
ture of the appendage does not suggest a branchlet ; it rather resembles
a somewhat large bract cut through its basal part ; it is flattened or
grooved towards the axis of the branch. The slender vascular strand in the
case figured has a square xylem-group with the smallest elements almost
central (PI. I, Fig. 3) ; it thus appears to be mesarch, and does not differ
essentially from the bundle of a bract. The distribution of the fibrous
tissue is also similar in the appendage and the bracts ; in both, at a little
distance above the base, it is chiefly concentrated on the abaxial surface,
where it forms three or more bands, one being median.

On the whole, therefore, the evidence, apart from the case of the section
2781 (Text-fig. t), appears to be in favour of the appendage being itself of
the nature of a bract. It is possible that the appearance of a branchlet sub-
tended by a bract in the case cited may be deceptive, for here also one might
interpret the appendage as a bract, cut very obliquely and still in connexion
with the branch, the apparently subtending bract being merely one of
an overlapping series.

In the other cases, where the appendage lies to the exterior of the
bract-cycles, one might interpret it as the prophyll of the branch, probably
supplied by the little bundle given off from the branch-stele near its base
(see PL III, Fig. 19 and Text-fig. 2). In any case it cannot be said that
there is any sufficient evidence for the appendage representing the pedicel of
a seed, as at first seemed probable.

A natomical Details.

A few points in the anatomical structure of the fertile shoot and
its branches remain to be considered.

The wood generally has been found to consist of spiral and scalariform
elements, thus resembling the inner zone of the wood in the vegetative stem.
Considering the thinness of the wood in the shoot and branch, this is
not surprising.

8

Scott. — On the Fertile Shoots of

As already mentioned, there is in one case (PI. Ill, Fig. 18) some
evidence for the presence of centripetal xylem in the stele of the main shoot.
There is, however, no indication of the protoxylem between the centrifugal
and the apparently centripetal elements ; neither do the other sections con-
firm the presence of the latter. Most probably such appearances are
merely due to displacement and compression of portions of the centrifugal
wood. One would not, in fact, expect centripetal xylem to be represented
in the main shoot ; in the vegetative stem it is always associated with the
leaf-traces, and, as the axillary shoot is leafless, there are no leaf-traces
here.

In the branch the case is different, for here the stele receives the traces
of the numerous bracts, so that we may expect to find centripetal xylem.
But, unfortunately, the preservation is never good enough to show the struc-
ture clearly. In the best section for the branch-stele (2781) (PI. Ill,
Fig. 17) one can see that the greater part of the xylem of the bundles is
centrifugal and in radial series ; a few irregularly arranged elements on the
inner margin may probably represent the centripetal part of the xylem.
This applies to the branch-stele after it has expanded and acquired a pith ;
where it is first given off from the main stele it has a purely centric struc-
ture, with neither centripetal xylem nor pith (PI. Ill, Fig. 19 and Text-
fig. 2).

There is no doubt that the bundles of the bracts themselves are
mesarch, with a fair amount of centripetal xylem. The case figured with
the protoxylem nearly central (PI. I, Fig. 3). is from an ‘ appendage ’, but,
as explained above (p. 7), the structure does not differ from that of an
ordinary bract.

The distribution of the sclerenchyma in the axillary shoot is in the
usual form of a Dictyoxylon hypoderma, sometimes nearly continuous
(Text-figs. 1 and 2; PI. I, Figs. 1, 5, and 6). The branch has little free
surface, but on the bracts themselves the fibrous tissue is often well developed,
occurring on both surfaces but chiefly on the distal side, where it forms
several often more or less confluent bands (Text-fig. 2, PI. I ; Figs. 2 and
6 ; PI. Ill, Fig. 17). The parenchyma of the cortex contains sacs with
dark contents, similar to those occurring in the vegetative stem (Scott,
1918, p. 452).

Discussion .

The very peculiar characters of the shoots under consideration, and
in particular their bilateral symmetry and distichous branching, at once
distinguish them from the vegetative axis and indicate a special function.
As Grand’Eury said, in speaking of one of his species of Cordaianthus :

‘ La disposition distique des bourgeons est le signe dune nouvelle destina-
tion ’ (Grand’Eury, 1877, p. 329). On general grounds there could be no

Mesoxylon and an Allied Genus.

reasonable doubt that the function of such highly modified shoots was
connected with reproduction ; as a matter of fact there are the closest
analogies with various well-known Cordaitean fructifications, and Mesoxylon ,
as we know, was a near ally of Cordaites. Grand’Eury says of Cordaianthus ,

‘ Les bourgeons floraux plus ou moins nombreux ont une disposition
generalement distique’ (1. c., p. 237). Our axillary shoot of course corre-
sponds to the main axis of the inflorescence, which Grand’Eury describes
as ‘ fleshy and the distichously arranged branches to the floral buds.
Some of Grand’Eury’s figures of Cordaianthus agree remarkably well
with our Specimens, and might almost serve as restorations of them.
Attention may be especially directed to Cordaianthus baccifer (l.c.,
PI. XXVI, Figs. 10, 12, 13) and
to the illustrations in PI. XXV,
which show the inflorescences as
borne on the stem ; one of them
is reproduced in our Text-fig. 3.

The ‘ naked peduncle ’ (e. g. C.
glomeratus, l.c., p. 230; cf. C.
gemmifer , PI. XXVI, Fig. 5) is
clearly comparable to the leafless
main axis of our axillary shoot.

Grand’Eury lays stress on the
absence of bracts, flowers, and
leaves on the peduncle (1. c.,
p. 228).

The dimensions of the
smaller specimens of Cordaian-
thus are quite comparable to
those of our specimens. It may
be further pointed out that in
Grand’Eury’s figures showing the
inflorescences in situ (l.c., PI. XXV)

their insertion lies some little distance above the subtending leaf. This agrees
with the position of our axillary shoots (Scott, 1918, p. 448). In position,
form, size, and general morphology our fertile shoots thus agree with the
inflorescences known as Cordaianthus. One point of difference may be
mentioned. Grand’Eury (l.c., p. 228) describes the floral buds as borne in
the axils of bracts, which are shown in many of his figures.though they are
sometimes abortive. There appears to be no subtending bract to the bud
or branch in our specimens, for the distal bundle, which might have been
interpreted as the trace of such a bract, springs from the branch-stele, and
not from the stele of the main shoot (see PI. Ill, Fig. 19, and Text-fig. 2).
It would thus seem to have supplied a prophyll of the branch, rather than

Text- fig. 3. Part of a branch of Cordaites
laevis (restored). It bears several leaves and two
inflorescences, the upper ?, the lower S, with distichous
floral buds. From Grand’Eury. About natural size.

io Scott . — On the Fertile Shoots of

a subtending bract. The distinction between the two would, however, be
scarcely recognizable in specimens preserved as impressions, and the
difference is of little significance.

We now come to the comparison of the actual floral buds or branches
with those of Cordaianthus , and here there is more opportunity for detailed
correlation, for fairly full data are supplied by the work of Renault and.
especially by the later investigations of Bertrand, while, so far as I know,
no previous observer has described the structure of the main axis of the
inflorescence. Renault (1879, PL XVII, Fig. i) shows a transverse section of
the axis of Cordaianthus subglomeratus , with some indication of the vascular
ring, but here there is little analogy with our specimens, as the floral buds
are not distichously arranged.

Renault (1879) has little to say about the structure of the axis and
bracts of the floral buds ; his attention was concentrated on the stamens
and ovules. His figures, however, show the bracts arranged spirally in
numerous cycles, each bract having a single vascular strand (1. c., PL XVI,
Figs.|i2-i5 ; PL XVII, Figs. 1-3, 11, 13, 14). The bracts of the female catkin
are described as thicker and more coriaceous than those of the male
(l.c., p. 313).

Much fuller details are given by the late Professor C. E. Bertrand in his
paper on the Female Bud of Cordaites (Bertrand, 1911). His observations
are confined to the detached floral bud or catkin (which he sometimes calls
the ‘ inflorescence ’), and there is no reference to the main axis, which appears
not to be represented among Renault’s preparations on which the account
is based.

The axis of the young bud, he says, has no free surface ; it is covered
by the bases of the bracts (1. c., p. 25). The vascular ring consists of about
ten isolated strands surrounding a pith. Each strand includes on the
inner side an irregular group of spiral elements, with 2-4 groups of radially
arranged secondary elements on the exterior. The illustration (1. c., PL V,
Fig. 37) shows that the structure of the stele of the bud essentially agree.'
with that in our specimens (cf. PL III, Fig. 17). A detailed comparison o
the other tissues is superfluous, as the preservation is poor both in his
material and ours.

The bracts in Renault’s specimens are remarkably like ours. Those
figured by Bertrand (1. c., PL V, Fig. 43) are almost identical with the
bracts of the bud shown in PL I, Fig. 2 (see also Text-fig. 2) ; the form
of those cut near the base is the same, and that of the more distal bracts
very nearly so. The bracts, however, are much less numerous in our
specimens, perhaps because some are lost. The structure of the bracts in
the French specimens is described by Bertrand in great detail (l.c., pp. 30-7).
Here it may suffice to mention that in the free, middle part, the bract has
two bands of fibres on the distal face, and a less developed fibrous layer

Mesoxylon and an Allied Genus. 1 1

on the inner side. In ours the distal bands, where they are distinct, are
more numerous. The parenchyma is large-celled, especially towards the
middle, just as in ours. The vascular bundle is described as identical with
a single nerve of the vegetative leaf of Cordaites (1. c., p. 34); in our
specimens it is mesarch, which comes to the same thing. Bertrands Fig. 41
shows a bundle exactly like that of an imperfectly preserved bract in one
of our specimens. In the basal part of the bract the fibrous bands disappear
just as in ours. Bertrand speaks of hairs on the bracts, which have not
been detected in our specimens.

Considering that there is no question of specific identity, the agree-
ment between the branches in our specimens and the floral buds of the
F rench fructifications is remarkably close. Taking both general morphology
and detailed structure into consideration, we may conclude with confidence
that our fertile shoots with their branches are of the same nature as the
inflorescences of Cordaites ; they constitute, in fact, the Cordaianthus of
Mesoxylon multirame.

The question remains, Of what sex was this Cordaianthus} The detailed
comparison has been with a female fructification, but there was little
difference in general morphology and structure between the two sexes.
Male catkins, however, are short-lived organs, and it is hardly likely that
we should find the accessory parts mature and fairly preserved without
some trace of the stamens themselves. Also any force that association
may have tells in favour of the fertile shoots having been seed-bearing
organs. Supposing that this was their nature, it is probable that some
of the Mitrospermums which we find in the neighbourhood of the fertile
shoots, especially the younger seeds, may have been borne on them and
become detached. In the best known female specimens of Cordaianthus
the seeds are borne laterally on the catkin, each terminating a short
pedicel, probably in the axil of a bract (Bertrand, 1911, p. 37). The ovules
are surrounded by the bracts of the catkin, from among which the ripening
seed may emerge. We have found no satisfactory evidence of the presence
of seed-pedicels, for the ‘ appendage ’ appears to have been of the nature of
a bract, except perhaps in the one case shown in Text-fig. 1 and PI. Ill,
Fig. 17, and even here, as we have seen, the interpretation of the appendage
as a branchlet or pedicel is open to some doubt. Unfortunately, then, we
are at present unable to explain how the seeds were borne, and the solution
of the question must await the discovery of more perfect specimens.
Possibly the seed may have been terminal on the branch.

In any case the nature of the fertile shoot of Mesoxylon midtiranie as
a Cordaianthus has been sufficiently demonstrated.

12

Scott. — On the Fertile Shoots of

Other Shoots associated with Seeds.

We have now to consider two examples of shoots which show in their
structure no relation to Cordaianthus , and indeed resemble vegetative buds
rather than inflorescences, but are more or less closely associated with seeds
of the Mitrospermum type. As^we shall see, they show an unmistakable
relation to Mesoxylon , though there are reasons for doubting whether they
can properly be included in that genus.

The specimen to be first described is represented by seven transverse
sections, the series running from below upwards.1 The axis, with the
leaf-bases, has a diameter of about 8 mm. The whole surface is clothed
with the massive leaf-bases, the true cortex being comparatively narrow
(PL I, Figs. 7, 8). At some places the leaf-base is seen expanding into
the lamina, and imperfectly preserved laminae of other leaves surround the
specimen.

There is a somewhat narrow zone of wood, about 10-20 elements in
thickness ; in places the centripetal xylem of the leaf-traces can be
recognized, most clearly in the second section (2599). The most interesting
point is that the leaf-traces are single where they pass through the wood.
They run out horizontally, so that they can be traced far out into the leaf-
base, forking once or twice after reaching the cortex. Farther out in their
course they become more vertical, and undergo repeated divisions, for in
the outer part of a leaf-base as many as nine little bundles, cut very
obliquely, have been observed (PI. I, Fig. 7, l.b.). The structure of
the wood and also the Dictyoxylon cortex are like those of a Mesoxylon ,
and the pith, so far as can be judged from transverse sections, appears to
have been discoid, for the displaced diaphragms are shown (PI. I, Figs. 7, 8).
Periderm was formed, cutting off the leaf-bases.

The leaves in connexion with or surrounding the axis have many
bundles, and are of the ordinary Cordaites or Mesoxylon type. The xylem
of the foliar bundles appears to be mainly centripetal. In the upper
sections (e. g. 2603) periderm had formed in the leaves, usually on both
surfaces — an interesting point, which strongly suggests a resting, vegeta-
tive bud. In the upper part of the specimen the wood diminishes in
thickness.

There is nothing in the structure of this specimen to indicate that
it was a fertile shoot. It is, however, associated with seeds, apparently of
Mitrospermum compression, of which five specimens occur in the series,
two of them lying near the bud. One of the seeds shows signs of
youth.

1 The numbers of the sections in my collection are 2598 to 2604. They were received in
August, 1910, from Mr. Lomax, who described the specimen as ‘a small apical shoot’, and called
attention to the association with the seeds of Cardiocarpon (now Mitrospermum ) compressum .

Mesoxylon and an Allied Genus . 13

The other specimen, represented by six sections, is more remarkable,
for the axis increases rapidly in diameter from below upwards, and appears
to approach the growing point at the upper end.1 At the base (section
3017) the shoot measures altogether about 4*5 mm. in diameter; the stele
is about i«7 mm., with a minute pith, only about 0*4 mm. in diameter; the
wood is of unequal thickness, from 0*37 to 0*9 mm. (PI. I, Fig. 9). Two
single leaf-traces are passing out. The cortex and leaf-bases are obscure
in this section, but the axis is surrounded by broad, ill-preserved leaves.
In the next section (3018) the diameter of the shoot has increased to
7-8 mm. The stele is incomplete, but evidently larger than before, with
the wood 0-53 mm. thick in the part preserved ; numerous bundles are seen
entering a leaf-base, as in the previous specimen. The third section (3019)
(PI. II, Fig. 10) is a much better one and shows a marked change. The
diameter of the whole shoot is here about 8x10 mm. The stele measures
3x2-5 mm. and the pith, which is pentagonal in form with gaps at the
angles, about 1-5 mm. The wood reaches 0-57 mm. (24-30 elements) in
thickness. A large single leaf-trace is passing out. The pith here, as in
all the sections which show it, seems continuous; there is nowhere any
indication of a discoid structure. Centripetal xylem is distinctly shown at
certain points around the pith.

In the fourth section (3020) the dimensions have further increased,
the whole diameter being about iox 15 mm. The stele has a diameter of
3x2-8 mm. and the pentagonal pith of i-8 mm.; the wood has a fairly
uniform thickness of 0-4 mm. There is a forking leaf-trace in the cortex,
opposite one of the gaps in the ring of wood.

In the two sections last mentioned the large leaf-bases and the
encircling leaves are better preserved, though still imperfect ; they seem
to agree essentially with those of the former specimen ; certainly the leaf-
bases are relatively more strongly developed than on the vegetative stems
of Mesoxylon , and the leaves themselves are polydesmic and probably of
the Cordaitean type.

In the next section of the series (3021) the axis is destroyed, but the
uppermost section (3022) is interesting, for it shows the stele in a very
young condition. The preservation is bad on the whole, but a ring of
quite isolated, vascular bundles is shown. There appear to be nine of these
bundles, though some are obscure, surrounding a large pith and separated
by broad principal rays. The secondary wood of each bundle is only four
or five cells thick ; in some cases a few centripetal elements can be
recognized. At one place a leaf-trace is passing out, almost horizontally.

1 The series is 3017-22, from below upwards. The sections were received from Mr. Lomax in
October, 1910. He rightly regarded this specimen also as an apical shoot (possibly, as he then
thought, of Mesoxylon multirame) and attached great importance to its intimate association with
the seeds.

H

Scott. — On the Fertile Shoots of

The diameter of the vascular ring is about 2-5 mm. ; allowing for the small
development of the wood, this is about the full size of the stele in the
preceding sections. Evidently we are here approaching the apical region
of the bud ; it is interesting to find that the vascular bundles are at first
widely separated, and that it is only at a later stage that they become
united into a more or less continuous vascular zone.

About nine seeds of Mitrospermum occur in the series, some of which
are evidently young. In section 3019 three of the seeds closely surround
the shoot and all appear young, the cell-walls of the sclerotesta being but
little thickened. In one of them the indications of youth are especially
marked ; all the cell-walls are remarkably thin, the megaspore is relatively
small, and there appears to be a thick layer of nucellar tissue persisting
between the megaspore and the integument.

Discussion .

There can, I think, be no doubt that the two specimens just described
are of the same kind. Both are of the nature of buds or apical shoots,
as is proved by the leaves wrapped closely round the axis. They agree
in the structure of the wood, in the single leaf-traces dividing in the cortex,
and in the massive leaf-bases. The chief differences are, first, in the
structure of the pith, which seems to have been discoid in the first specimen
and continuous in the second. There is a slight difference also in the form
of the pith, which is markedly pentagonal, at least where it attains its full
size, in the second specimen, and only faintly angular in the first. This,
however, is a small point.

Another conspicuous difference is the striking contraction of the whole
shoot and its stele towards the base in the second specimen, while the
diameter is fairly uniform throughout in the first. This distinction suggests
that the second specimen may have been, a lateral bud, and the first a
terminal one. This suggestion might perhaps also throw some light on the
difference in the structure of the pith.

The anatomical habit of both shoots is distinctly that of a Mesoxylon ;
the presence of centripetal wood and the polydesmic structure of the
encircling leaves show that the affinity is a real one. But in the important
character of the single leaf-trace there is a marked distinction from
Mesoxylon , for in all the species referred to this genus the trace is double
where it passes through the wood. This, in fact, has been made a character
of the genus (Scott and Maslen, 1910, p. 2 37). It is true that in the buds
of the fertile shoot of M. multirame the leaf-trace is single, but here the
reason is obvious, for it supplies a monodesmic bract. In the shoots now
under consideration the leaf-base and leaf have many bundles, and yet the
trace is single at its origin, only dividing as it passes through the cortex.
This peculiar feature might no doubt be due to the shoots being of a special

1 5

Mesoxylon and an Allied Genus.

morphological nature, differing from vegetative branches. They might
then belong to some species of Mesoxylon. But specimens of ordinary
vegetative stems of the Mesoxylon type have now come to light which
agree with these shoots in having single leaf-traces, and it is suggested that
the shoots belonged to a plant of this kind. The stems in question will be
described immediately; in the meantime the attribution of the bud-like
shoots must be left an open question (see p. 17).

There is nothing to show that these shoots were connected with
reproduction ; they have all the character of vegetative buds, and bear no
resemblance to any form of Cor daian thus. If they bore branches of the
nature of fructifications, no trace of any such organs is to be found in
the specimens. Yet the association with Mitrospermum seeds, and espe-
cially with young seeds, is striking. Probably it is accidental, for if all
the seeds are of the same species they could not have been borne both
on these shoots and on the Cordaianthus of Mesoxylon multirame.

I shall return to the subject of association at the conclusion of
the paper.

Stems of the Mesoxylon Type with a Single Leaf-trace —
r a New Genus.

The stems in question are represented only by two isolated transverse
sections in my collection.1 The smaller of the two specimens (2983) is
about 11 mm. in diameter in its present condition, but the cortex is incom-
plete (PI. II, Fig. 11), The stele (to the outer edge of the wood) measures
about 9x8 mm. and the pith about 5 x 3*5 mm. The pith is almost
destroyed by Stigmarian rootlets, and it is impossible to determine whether
it was discoid or not. The small-celled wood is from 1-3 to 2*5 mm. thick.
The medullary rays are narrow and uniseriate, and the general structure of
the wood, so far as can be judged from a transverse section, is similar to that
of a Mesoxylon , such as M. multirame or M. poroxyloides. It also agrees
essentially with that of the bud-like shoots described in the preceding
paragraphs.

Three leaf-traces, each manifestly a single bundle, are seen on their
course through the wood ; they pass out obliquely but not horizontally.
In two of them the centripetal xylem can be clearly seen, and in one, at
any rate, the intermediate position of the protoxylem is evident (PI. II,
Fig. 12). A fourth bundle is just leaving the pith, and this also sltbws the
same mesarch structure. The inner edge of the wood is not well preserved,
and though there are indications of centripetal wood at some points, it
is nowhere very clear, apart from the outgoing traces. The phloem and

1 The numbers are 2983 and 2993, both received from Mr. Lomax early in 1916; they were
found at Shore, Littleborough.

1 6 Scott. — On the Fertile Shoots of

pericycle are poorly preserved, and the inner cortex, which alone is present,
shows a not very distinctive parenchymatous structure.

On the data available it appears that this specimen is a stem allied to
Mesoxylon ; the size, and especially the considerable development of the
wood, indicate that it was an ordinary vegetative shoot.

The second specimen (section 2993) is of a much larger stem (PI. II,
Fig. 13). Only the pith and wood are preserved, and the latter is incom-
plete. The maximum radius, to the outer edge of the wood, is almost
2 cm. The pith is about 6 mm. in diameter ; it is nearly complete, but
it is quite likely that the plane of section may happen to coincide with
a diaphragm. Its contour is obscurely angular. The structure is very
uniform, the cells merely becoming smaller towards the outside ; many
of them have dark contents. The appearance is very similar to that of
a diaphragm of Mesoxyton multirame when seen in horizontal section.

The structure of the wood is the same as in the former specimen,
except that the rays sometimes appear to be biseriate, a feature often met
with in species of Mesoxylon . It shows a more definite appearance of
4 annual rings ’ than is usual in carboniferous woods ; examined with a lens
the rings look quite like concentric bands of autumn wood (PI. II, Fig. 13).
But they prove, on closer investigation, not to be really continuous, and
though some of the cells are flattened this is not at all generally the case.
The distinction appears to depend mainly on a somewhat greater thickness
of the cell-walls in these bands.

Two single leaf-traces are seen passing out obliquely through the inner
part of the wood (PL II, Fig. 13).

At several points of the inner edge of the wood a prominent group of
primary xylem is seen, which is evidently centripetal in development, and
comparable to the primary xylem of a Mesoxylon (PI. II, Fig. 14). In all
cases such groups occur singly, never in pairs ; they clearly represent the
downward continuation of single leaf-traces which have passed in at a higher
level.

Discussion .

These two specimens differ practically in nothing except size, and may
safely be referred to the same species. The characters open to investigation
are somewhat meagre ; in the general structure of the wood and pith
(when shown) and in the presence of centripetal xylem, both in the outgoing
leaf-traces and in strands at the inner edge of the wood, the stems agree with
Mesoxylon. They differ from that genus in the important point that the
leaf-trace, as it traverses the wood, is single and not double. At the same
time it is evident that the specimens are ordinary vegetative stems, and thus
directly comparable with those on which the genus Mesoxylon was founded.
It will be noticed that the pith is smaller than is usual in Mesoxylon .

7

Mesoxylon and an Allied Genus. i

Without altering the generic characters of Mesoxylon it is impossible
to include the stems in question in that genus, for the generic diagnosis con-
tains the statement : ‘ Leaf-traces double where they leave the pith, the two
strands uniting at a lower level ’ (Scott and Maslen, 1910, p. 237). There is
no question of dropping this character, on which great stress has been laid
in all descriptions of the species of Mesoxylon. It must, however, be under-
stood that it applies essentially to the vegetative stems only.

It thus becomes necessary to establish a new genus for the specimens
just described, and the name I propose to adopt is Mesoxylopsis. I think
we are logically compelled to include in the new genus the two bud-like
shoots (of the 2598 and 3017 series) previously described. They too have
single leaf-traces, and the evidence goes to show that, the shoots were vege-
tative organs. The fact that they bore polydesmic leaves shows that the
singleness of the leaf-trace was not simply an adaptation to a reduced foliar
structure. The case for separation from Mesoxylon is in fact just about as
strong for these buds as it is for the larger stems just described. Although,
therefore, we cannot absolutely prove that the bud-like shoots may not have
been peculiar specialized branches of a Mesoxylon, the presumption on present
evidence is that they belonged to Mesoxylopsis , and I have taken account of
their characters in drawing up the following diagnosis of the new genus :
Mesoxylopsis, gen. nov.

Pith probably discoid in the mature stem.

Wood dense, with narrow, usually uniseriate medullary rays.

Leaf- traces single where they leave the pith and pass through the
wood, forking repeatedly in the cortex and leaf- base.

Centripetal xylem present in the leaf-traces at the margin of the pith
and throughout their outward course into the leaves.

Leaf-bases massive, crowded.

Leaves polydesmic, of the type of Cordaites and Mesoxylon .

All the specimens may be referred to a single species which I have
pleasure in naming Mesoxylopsis Arberae , sp. nov., after Dr. Agnes Arber,
F.L.S., who has so kindly aided in the determination of seeds associated
with the shoots described in the present paper.1 The characters of the
species are those of the genus. In the specimens observed the pith is
relatively small, not exceeding 6 mm. in diameter.

Conclusion.

In the first part of the paper the structure of the fertile shoots of
Mesoxylon midtirame is described. They are found to be identical with the
axillary shoots, which have been known since the first discovery of the
species.

1 See below, p. 18.
C

i8

Scott —On the Fertile Shoots of

The fertile shoot is bilaterally symmetrical ; it consists of a naked main
axis, containing a flattened stele, and bearing distichously arranged bud-like
branches, lying in the plane of the major axis of the main shoot. Each
branch has a cylindrical, medullated stele, and bears numerous spirally
arranged bracts, with a single vascular bundle of mesarch structure.
A large bract, lying outside the others, may probably be the prophyll
of the branch. In one case an appendage, apparently of a different kind,
was observed, which might possibly be the pedicel of a seed.

In general morphology, and in the detailed organization of the lateral
buds, the fertile shoots show a close agreement with the distichous forms of
Cordaicinthas , described by Grand’ Eury, Renault, and Bertrand, and are
clearly of the same nature. The sex of the inflorescence has not been
determined, as no reproductive organs are attached, but the probability
is in favour of its having been a seed-bearing organ. It is associated with
the seeds named Mitrospermum compression by Dr. Agnes Arber.

Two shoots of a different kind are then described, which appear to
have been of the nature of vegetative buds, for their structure is that
of a stem, and they bear closely packed polydesmic leaves, of a Cordaitean
type. The leaf-traces of these shoots are single where they traverse the
wood, only dividing in the cortex. These shoots also are associated with
seeds of Mitrospermum compressum .

Lastly, two larger stems of the Mesoxylon type are recorded, in which
the leaf-traces are likewise single in passing through the wood. These
stems and the bud-like shoots are placed together in a new genus,
Mesoxylopsisy differing essentially from Mesoxylon in the leaf-trace being
single and not double. The one known species is named Mesoxylopsis
Arber ae.

The equally intimate association of Mitrospermum compressum with
the Cordaianthus of Mesoxylon multirame on the one hand, and with the
bud-like shoots of Mesoxylopsis Arberae on the other, raises grave doubts as
to the value of the evidence from association, always so uncertain in palaeo-
botany, and doubly treacherous among the crowded and intermixed frag-
ments of the coal-ball petrifactions. It was, however, clearly desirable
to ascertain whether the seeds of the two categories were in fact specifically
identical. Dr. Agnes Arber, F.L.S., to whom I have submitted sections
showing the seeds associated with both kinds of shoots, kindly allows me to
quote her opinion, as follows : ‘ The sections of the seeds all seem to me to
be typical Mitrospermum compressunty and I see no reason for separating
those in the three slides in which they are associated with Mesoxylon multi-
ramel At the same time Dr. A. Arber calls attention to a remark in her
preliminary note on this seed (A. Arber, 1910, p. 393) : ‘ There is sufficient
variation among the specimens, both in dimensions and structure, to
suggest that Cardiocarpon [now Mitrospermum ] compressuniy instead of

Mesoxylon and an Allied Gams. 19

being a single species, may possibly represent an assemblage of seeds
belonging to closely allied plants.’

It is therefore not impossible that seeds of the Mitrospermum com -
pressum type, at present indistinguishable from one another, may have
been borne both by Mesoxylon multirame and Mesoxylopsis Arherae . But,
in the existing state of our knowledge, we are not justified in making any
such assumption, and the significance of the evidence from association
in the two cases is at present quite doubtful. Considering, however, that
the fertile shoots of Mesoxylon midtirame have now been shown to agree in
morphology and structure v/ith a Cordaianthusy it is highly probable that
the platyspermic seeds associated with them may have really belonged
to the plant.

The genus Diplotesta, to which Bertrand referred the ovules of his
Cordaiantkus (Bertrand, 1911), appears to be closely allied to Mitrospermum
(Brongniart, 1881, Pis. XIII and XIV ; Bertrand, 1907), and the latter
genus is in every respect a seed of the type which there is good reason for
attributing to the Cordaitales (see Seward, 1917, pp. 332-56).

The main result of the present investigation is, however, the proof that
Mesoxylon multirame bore a Cordaianthus in all respects comparable to the
inflorescence of Cordaites. The close affinity of the two genera and the
definite location of Mesoxylon in the family Cordaiteae are thus securely
established. There is little doubt that the new genus Mesoxylopsis is
of like affinities, but further evidence is needed before its exact position
can be determined.

While the evidence from association with seeds has proved too
uncertain to be relied on, great credit is due to Mr, James Lomax for
calling attention to the shoots described in the present paper. In the
case of the fertile branches of Mesoxylon multirame his conviction of their
‘ fructiferous ’ nature has been fully confirmed.

The photographic illustrations to the present communication are the
work of Mr. W. Tams of Cambridge. The drawings, both the text-,
figures and those in the plate, are from the pencil of Mr. G. T. G william,
F.R.A.S. To both these gentlemen I desire to return my thanks for their
skilful aid.

References.

Arber, Agnes (1910) : A Note on Cardiocarpon compression, 'WiM. Proc. Cambridge Philosophical
Soc., vol. xv, pt. v, p. 303.

(1912) : On the Structure of the Palaeozoic Seed Mitrospermum compression (Will.),

Ann. Bot., vol. xxiv, p. 491.

Bertrand, C. E. (1907) : Les caracteristiques du genre Diplotesta de Brongniart. Bull, de la Soc*
Bot. de France, 4® serie, tome vii, p. 389.

20

Scott. — On the Fertile Shoots of

Bertrand, C. E. (1911) : Le Bourgeon femelle des Cordaites d’apres les preparations de Bernard
Renault. Bull, de la Soc. des Sciences de Nancy, p. x.

Brongniart, A. (1881) : Recherches sur les Graines fossiles silicifiees. Paris.

Grand’Eury, C. (1877) : Flore carbonif&re du Departement de la Loire et du Centre de la France.
Paris.

Maslen, A. J. (1911) : The Structure of Mesoxylon Stitcliffii (Scott). Ann. Bot., vol. xxv, p. 381.
Renault, B. (1879) : Structure comparee de quelques tiges de la Flore Carbonifere. Nouvelles
Archives du Museum, tome ii, 2e serie, p. 215.

Scott, D. H. (1912): The Structure of Mesoxylon Lomaxii and M. poroxyloides. Ann. Bot.,
vol. xxvi, p. ion.

(1918) : The Structure of Mesoxylon multirame. Ann. Bot., vol. xxxii, p. 437.

Scott, D. II., and Maslen, A. J. (1910) : On Mesoxylon , a New Genus of Cordaitales. Preliminary
Note. Ann. Bot., vol. xxiv, p. 236.

Seward, A. C. (1917) : Fossil Plants, vol. iii. Cambridge University Press.

EXPLANATION OF PLATES I-III.

Illustrating Dr. Scott’s paper on tjxe Fertile Shoots of Mesoxylon and an Allied Genus.
The photographic figures require to be examined with a lens.

PLATE I.

Photographs by Mr. W. Tams.

Figs. 1-6. Fertile shoots of Mesoxylon multirame.

Fig. 1. Transverse section of the fertile shoot shown in Text-fig. 1 ; at A is a detached branch
with bracts, and at B the bracts of another branch, x about 7. S. 2783.

Fig. 2. Another detached bud, transverse, with numerous bracts, br ., and a large appendage, ap.
x 22. S. 2785.

Fig* 3* Vascular bundle of the appendage in Fig. 2, showing the central protoxylem, px.
x about 200. S. 2785.

. Fig. 4. Part of transverse section of a stem of M. multirame , accompanied by a fertile shoot.
x1., secondary wood of the stem; ax., an axillary stele of the same; F.S., main fertile shoot; b.,
branch attached to it. x about 8. S. 2564.

Fig. 5. Another transverse section of the same fertile shoot ; F.S., main shoot ; b., large hastate
branch attached to it. x 17. S. 2568.

Fig. 6. Another fertile shoot in obliquely transverse section. F.S. , main shoot, with narrow
stele ; b., large branch attached to it, with bracts, x about 10. S. 3040.

Figs. 7-9. Shoots of Mesoxylopsis Arberae.

Fig. 7. Shoot in transverse section. /., pith, apparently discoid. U.1, single leaf-trace passing
through wood; l.t.2, leaf-trace forking in cortex; l.b., leaf-base with numerous bundles; /., leaves
surrounding shoot, x about 8. S. 2598.

Fig. 8. Next section of the same shoot, p., pith, as before ; lit., leaf-trace beginning to fork ;
l.b., leaf-base expanding into lamina on either side; /., leaves surrounding shoot, x about 8.
S. 2599.

Fig. 9. Lower part of another shoot in transverse section, st., centre of stele, with small solid
pith and very unequal wood in which two single leaf-traces are seen ; l.b., one of the leaf-bases.
X 17. S. 3017.

Mesoxylon and an Allied Genus .

21

PLATE II.

Photographs by Mr. W. Tams.

Fig. io. From a higher section of the same shoot as Fig. 9, showing the enlarged stele and
surrounding tissues. /., the large, solid pith ; l.t., a single leaf-trace passing through the wood,
x about 15. S. 3019.

Figs. n-14. Stem of Mesoxylopsis Arberae.

Fig. 1 r. General transverse section. UP, single leaf-trace starting from the pith; UP, another
leaf-trace ; c., remains of cortex, x about 7. S. 2983.

Fig. 1 2. The leaf-trace, UP, from Fig. 1 1 and neighbouring tissues, more magnified. xP, centri-
petal xylem of leaf-trace, x about 50. S. 2983.

Fig. 13. General transverse section of another stem, showing rings of growth. p., more or less
solid pith ; UP, l.t ?, single leaf-traces passing through wood, x about 4. S. 2993.

Fig. 14. The leaf-trace, LtP , from Fig. 13 and neighbouring tissues more magnified ; xP, centri-
petal xylem of leaf-trace, x *about 50. S. 2993.

Figs. 15, 16. Mitrospermunt compressum.

Fig. 15. Transverse section of seed, sa., sarcotesta ; sc., sclerotesta ; pr., prothallus, a delicate,
imperfectly preserved tissue, filling the megaspore, x about 16. S. 2781.

Fig. 16. Part of obliquely transverse section through upper part of a seed, sc., sclerotesta ;
p.c ., the pollen-chamber, in which four large pollen-grains, p.g., are contained, x 125. S. 2787.

PLATE III.

Mesoxylon muliirame.

From drawings by Mr. G. T. Gwilliam. All are from the section shown, as a whole, in Text- fig. 1.

Fig. 17. The branch b of the fertile shoot, in approximately transverse section, st., stele of
branch; br., a free bract; ap., appendage; br.s ., bract, apparently subtending the appendage,
x about 30. S. 2781.

Fig. 18. Part of stele of fertile shoot, transverse. xP, apparent primary wood; xP, secondary
wood, x about 170. S. 2781.

Fig. 19. Part of fertile shoot, at A end, transverse, si., portion of main stele; st.b., stele of
a branch; v.b., distal bundle, x about 60. S. 2781.

< 'Arcnals of Botany

Tams.^hot.

SCOTT

MESOXYLON AND MESOXYLOPSIS

Vol. XXXWPL.I.

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SCOTT — MESOXYLON AND M ESO XYLO P S I S.

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SCOTT- MESOXYLOPSIS AND MITROSPERMUM

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VolJXXmfl.H.

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SCOTT- MESOXYLOPSIS AND MITROSPERMUM.

a/lnnals of Botany,

Vol. HMIJFI.H1.

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SCOTT — MESOXYLON.

The Flora of Stewart Island (New Zealand) : a Study
in Taxonomic Distribution.

BY

J. C. WILLIS, M.A., Sc.D.,

European Correspondent , Botanic Gardens , Rio de Janeiro.

With two Maps and fourteen Tables in the Text.

IN this paper I shall put together a few notes upon the flora of Stewart
Island, the southernmost of the main chain of the New Zealand islands
proper. I have carried on this study by the aid of my hypothesis of age
and area, which indicates many new directions in which to search for facts
that have hitherto passed unnoticed. My former predictions as to composi-
tion and distribution made by its aid have been so successful, that in this
paper I have adopted entirely the method of prediction and subsequent
verification, giving fourteen different predictions about the plants of Stewart
Island. The composition of the flora is first dealt with, and its geographical
and other relationships. The subject of the probable invasions of New
Zealand by plants, commenced in my last paper, is then followed up, in so
far as the relationship of Stewart Island to these invasions is concerned, and
it will be continued in papers on the floras of the more outlying islands.

In publishing this series of papers on the geographical distribution of
the New Zealand flora I am sometimes accused by botanists in Europe of
trespassing upon a line of work which various New Zealand botanists have
made peculiarly their own. These investigators have a real knowledge of
the local conditions, whereas I possess none, and are turning out work
of great value and importance, upon which I should not dream of trespass-
ing. But I may be permitted to point out that their work is concerned
with ecological, not with taxonomic, distribution, and it is to the latter that
age and area refers. The two lines of work are really very distinct, and
have comparatively little overlap. What is beginning to come out with
great clearness from the study of age and area is that, given fairly uniform
conditions, such as one finds in New Zealand, the distribution of the flora
about the country, so far as the area occupied by the different species is
concerned, is governed almost entirely by the law of age and area. The

[Annals of Botany, Vol. XXXIII. No. CXXIX. January, 1919

2\ Willis. — The Flora of Stewart Island [New Zealand) :

mere fact that one can make so many predictions about any of the floras of
the New Zealand region, and find, on verification of the facts, that they are
justified, is alone sufficient to show this. The principal cause that interferes
with the uniformity of the action of age and area is the presence of actual'
barriers, such as Cook’s Strait, Foveaux Strait, the central mountain chain,
the sea dividing New Zealand from the outlying islands, and so on, but
within New Zealand the actual ecological barriers, which might easily alter
very largely the distribution of species if they were of sufficient breadth and
width, do not seem to affect the question of area occupied, save in quite
a minor degree. The plants are locally distributed, within the area which
is assigned to them by the passage of time, in accordance with their
reactions to the various ecological factors which are operative there. But
ecology seems little concerned, so far as we can see, and so far as the
figures of distribution give any guide, with the actual composition of the
flora. Unfavourable ecological conditions may determine that a certain
species shall not survive in a given place, so that it may reach what, in
a list of modifying causes we have given in a previous paper (6, p. 206), we
have termed the climatic boundary, but which might better perhaps be
termed in a more general way the ecological boundary. But otherwise
ecology simply seems to make what it can, so to speak, of the floras
with which it is provided by the mere action of phylogenetic descent and
of time.

That the composition of the flora of Stewart is what it is, is largely due
to the simple fact that certain species were at a certain distance from
Stewart early enough to arrive there before the formation of Foveaux
Strait, which cut it off from New Zealand proper. The figures of distribu-
tion give little evidence to show that many species have arrived since the
formation of the strait, though there are a few, for example Ur tic a australis ^
which seem to be such cases. In general the distribution follows age and
area with such closeness that one may make predictions on this basis alone,
and find them often within perhaps five per cent, of accuracy.

It is worth while pointing out that by using the hypothesis of age and
area one finds great numbers of new facts ready to be picked up, or explana-
tions of what have hitherto been regarded as facts to be simply accepted
as such. As one has as yet no guide as to their relative immediate impor-
tance, one must be content to collect them all, and no doubt they will in
time prove their comparative values.

Stewart Island is a small island of 664 square miles, separated from
South Island by Foveaux Strait, which at its narrowest has a breadth of
sixteen miles, and at its shallowest (centre) a depth of fifteen fathoms (thirty
metres). It would therefore seem not unreasonable to suppose that the
separation from South Island was at a very remote period. This is con-
firmed by the fact that Stewart possesses local endemic species, confined

a Study in Taxonomic Distribution . 25

to itself alone. In its relations to South Island it occupies a position like
that of Ceylon in relation to South India.

It has the same indented rocky coast as South Island, and is similarly
mountainous, Mt. Anglem reaching 3,200 feet. Geologically it is chiefly
composed of archaean rocks, like those in the extreme south-west of South
Island. It is clear from the soundings (see map) that it must have received
its flora by way of New Zealand proper, and, being closer to the main
islands, and probably not divided from New Zealand at an earlier period
than the Chathams and Aucklands,
it has received many more plants
than they, and has double the flora
of either of them.

Stewart Island being thus away
from the general centres of distri-
bution of the New Zealand flora,
which in the previous paper we
have seen to have been, one prob-
ably in the North Island, the other
somewhere about the middle of the
southern half of the South Island,
a brief consideration of its relation-
ships from the standpoint of age
and area enables us to say that its
flora will be composed of species
which in comparison to those of New
Zealand proper will be old.1 We shall work upon this as a fundamental fact
and go on to study the flora by the method of prediction and verification.

Composition of the Flora of Stewart Island,

As showing that age and area lends itself to prediction, we shall begin
by endeavouring to predict as far as may be the actual composition of the
flora, assuming that we know nothing about Stewart other than its position,
but that we know the floras of New Zealand and the other outlying islands
to the extent described by Cheeseman (1, 2).

To commence with the actual size of the flora : we have seen that the
falling off in number of species from their zones of greatest concentration is
fairly regular (8, p. 343 2), and we should expect, if Stewart were in land
connexion, that the flora would be about 550, but as the formation of the
strait must have been early enough to prevent many species from crossing
which have since reached the strait from the north, we shall not expect so

1 The same conclusion follows almost as clearly from the usual interpretation of the hypothesis
of Natural Selection.

2 Species endemic to New Zealand and islands are not given in this list.

New Zealand and outlying islands. The dotted
line is the 1,000 fathom limit.

26 Willis . — The Flora of Stewart Island (New Zealand) :

many, but perhaps 400 or less. In actual fact the flora is 31 1, to which
must be added 57 ferns. (Cf. Appendix, p. 42.)

In my last paper we saw that New Zealand probably received the
bulk of its flora by two great invasions, one northern, within 400 miles
from the north end of North Island, and the other southern, with its centre
somewhere a little south of the middle of South Island. If we assume, for
the sake of simplicity, that Auckland and Dunedin were the actual centres
of these invasions,1 and draw circles round them, as done in the adjoining
map, then it is clear that the older plants will be near the boundaries of the
outer circles, in so far as actual barriers of sea have not interfered with
their distribution, and the younger successively nearer to the centres. It

therefore follows (this thesis
will be more fully developed in
a later paper on the outlying
islands) that the Chatham Is-
lands should have a good deal
in common with the Kermadecs
of the older families, genera, and
species, which can have reached
both, and similarly much in
common with the Aucklands,
while of families, genera, and
species that are sufficiently old
in New Zealand all three groups
of islands should possess repre-
sentatives. The circle for the
northern invasion that covers
the Kermadecs and Chathams
does not include Stewart, while
that for the southern invasion
which covers the Chathams and
Aucklands, or the Chathams and Campbell, does.

The general result of this prediction, then, so far as concerns Stewart,
is that one will expect to find there all families, genera, and species that
occur in the Kermadecs, Chathams, and Aucklands, or in the last two only.
But as Stewart is nearer to the centres, one may expect to find there also
a good many that have not reached the Kermadecs and Aucklands, or the
Chathams and Aucklands, or even any of the outlying islands.

The Chathams, in their intermediate position, will probably contain
a good many plants which do not reach the Aucklands. A straight line
drawn from them to New Zealand reaches it at a point which is much

1 Examination of the map will show that displacement of the centres of the circles by 100 miles
or so makes no difference to the arguments in this paper.

New Zealand and outlying islands. The dotted
line is the 1,000 fathom limit.

a Study in Taxonomic Distribution.

2 7

farther from Stewart than from the Chathams. But if we draw a line direct
from Stewart to the Chathams, and use it as the diameter of a circle, this
circle cuts New Zealand near Lake Taupo in the North Island, and near
Foveaux Strait. One will therefore expect to find, to a large extent, that
those species which occur in the Chathams, and reach Lake Taupo as well
as Foveaux Strait, will occur in Stewart, unless that island was cut off too
early, a point as to which we have no information.

The southern invasion, as we shall see in the next paper, probably
passed not very far from the Aucklands, and a circle with its centre iri
Dunedin and passing through Stewart also passes through the north end of
South Island. One will therefore expect to find most Auckland species
that reach the north end of South Island also occurring in Stewart, again of
course in so far as an early cutting off of Stewart may not have interfered.

A family will very rarely arrive in a country as a group of genera
simultaneously ; some will arrive sooner than others. On the whole , there-
fore, a family with several genera will be older in the country than one with
one, and the same will be true of genera, those with many species being on
the whole the older. Now as the Stewart flora is mainly composed of older
forms, we shall not go far wrong if we predict that it will contain most of
those families that contain more than the average number of genera (in
New Zealand proper), and those genera that contain more than the average
number of species. This then may be added to the previous predictions.
As, however, there are not so many families and genera with numbers above
the average, this will not, probably, add very many.

We shall now give a complete list of the flora of Stewart, marking
against each species and family the result of applying to it these different
predictions. Everything that is actually predicted is printed in italics. As
a rule when a genus or family is predicted some of the actual species are
also predicted, but in the few cases where this does not happen, the genus
or family is printed in italics, the species in roman type.

Table I (and cf. p. 42).

A occurring in the Kermadecs, Chathams, and Aucklands, or the two latter.

B occurring in the Chathams, and reaching Lake Taupo and Foveaux Strait,

C occurring in the Aucklands, and reaching the north end of South Island.

Families with five or more genera, and genera with five or more spp., are marked with f»

ABC

ABC

RANUNCULACEAE
Clematis + indivisa
Ranunculus + Lyallii

xxx

MAGNOLIACEAE
Drimys colorala

CR UCTFERA E +
Cardamine f hinsuta
Lepidium f oleraceum
tenuicaule

VIOLACEAE
Viola filicaulis

xxx

xxx

xxx

gracilipes

liirtus

Kirkii (endemic St )
lappaceus
rivularis
acaulis

x

xxx

x

X

2 8 Iv Mis— The Flora of Stewart Island ( New Zealand!)

A B

Viola Cunninghamii x

Melicytus ramiflorus
lanceolatus

Hymenanlhera\ crassifolia
PITTOSPORACEAE
Pittosporum^ Colensoi

CARYOPHYLLACEAE x x

Stellaria + parvifiora x

Colobanthus f Muelleri x

Spergularia media

PORTULACACEAE
Claytonia australasica
Montia fontana x

ELATINACEAE
Elatine americana

MALVACEAE x

Plagianthus betulinus x

TILIACEAE
Aristotelia racemosa
fruticosa

Elaeocarpus Hookerianus

LINACEAE x

Linu77i 7nonogynu7U x

GERANIACEAE x x

Geraniiun f mici'ophylhim
sessiliflorum

molle x

Pelargoniu77i au sir ale x

COR I ARIA CEAE x

Coriaria ruscifolia x

ROSA CEAE x x

Rubus australis
cissoides
schmidelioides
Geu77i f leiospermum

Acae7ia\ sanguisoi'bae x x

SAXIFRAGACEAE f
Donatia novaezealandiae
Carpodetus serratus
Weinmannia racemosa

CRASSULACEAE x x

Tillaea f moschata x

diffusa

DROSERACEAE
Drosera f stenopetala
Arcturi
spathulata
binata

II H ALORRHA G I ACE A E x x

oragis f alata

tetragyna

depressa

micrantfia

Myriophylliwi elatinoides
intermedium
pedunculatum

Gumiera f 7)ioiioica x

Hamiltoni

Callitriche Muelle7-i x

MYRTACEAE x x

Leptospe7')7iu7n scopariu77i x

Metrosidei'os f lucida

hypeiicifolia
Myrtus pedunculata

C A

ONAGRACEAE x

Epilobiimi f Billa7'dieranu>u
pubens
alsinoides
rotundifolium
linnaeoides

mi77imula7'ifoliu77i x

Fuchsia excorticata
Colensoi
FICOIDEAE
Tetragonia expansa
trigyna

* UM BELLI FERAE f x

Hyd7'ocotyle'\ tripartita
americana
novaezealandiae
microphylla
asiatica

Actinotus novaezealandiae
Apium prostratum
Craittzia lineata
Aciphylla f Traillii
Ligusticu7?i f intermedium

flabellatum (endemic)

x ARALIA CEAE f x

x Aralia Lyallii
Paiiax f shfiplex
Edgerleyi
Colensoi
Schefflera digitata
Pseudopanax i* crassifolius
CORNACEAE
x Griselinia littoralis

RUBIACEAE x

Copros77ia + lucida

rhamnoides

x pa7"vijiora

acerosa
pi'opinqua

foetidisswia x

Colensoi
cimeata
repens

x Neidefa depressa

dichondraefolia
x setulosa

x Asperula perpusilla

COMPOSITAE f x

Lagenophora + Forsteri x

petiolata

x Brctchyconie f pinnata

Thomson i

0lea7*ia f angustifolia

Traillii (endemic)
x Colensoi

nitida
ilicifolia
avicenniaefolia
Celmisia f Sinclairii
petiolata
longifolia

x linearis

sessili flora

X argentea

Gnaphaliu77i f luteo-album x

japotiicuTH

a Study in Taxonomic Distribution.

29

Gnaphalium f collinum

A B

X

Raoulia \ Goyeni (endemic)
Helichrysum f bellidioides

X X

filicaule

X

Cassinia f Vauvilliersii
fulvida
Craspedia uniflora

Cotula f coronopifolia x

australis x

Traillii (endemic)
dioica

A brotanella f muscosa (endemic)

Erechtites f prenanthoides x x

arguta

scaberula x

diversifolia
glabrescens
Senecio f bellidioides
Lyallii

lauius x

Stewartii (endemic)
elaeagnifolius
rotundifolius
Microseris Forsteri

So nc hus as per x x

oleraceus x

STYLIDIACEAE
Phyllachne Colensoi
Oreostylidium subulatum
Forstera sedifolia

GOODENIACEAE
Selliera radicans

CAMPANULACEAEf x x

Pratia angulata x x

Wahlenbergia saxicola
ERICACEAE
Gatiltheria f antipoda
perplexa

EPA CRIDA CEAE f x x

Pentachondra pumila
Cyathodes f acerosa

empetrifolia
Leucopogon Fraseri
Archeria Traversii
Dracophyllum f Menziesii

longifolium
Urvilleanum
Pearsoni (endemic)
rosmarinifolium

PRIMULA CEAE X

Samolus repens . x

MYR SIMA CEAE x

Myrsinef Urvillei

divaricata
nummularia
LOGANIACEAE
Mitrasacme novaezealandiae

GENTIANACE4E x

Gentiana + lineata

Grisebadhii
saxosa

Liparophyllum Gunnii

BORAGINACEAE x

Myosotis f antarctica
capitata

A B C

CONVOLVULACEAE f x

Calystegia Soldanella x

Dichondra brevifolia

SCROPHULARIACEAE\ x x

Glossostigma elatinoides
Veronica f salicifolia x

amabilis

elliptica x

buxifolia

Ourisia + macrophylla
sessilifolia
caespitosa
Euphrasia f Dyeri

LENTIBULARIACEAE

Utricularia + monanthos

PLANTAGINACEAE x

Plantago f Raoulii

Brownii x

triandra

CHENOPODIA CEA E + x

Chenopoditun + glaucum
Atriplex Billai'dieri x

POLYGONACEAE x x x

Rnmex negledus x

Muehlenbeckia australis x

CHLOR ANTHAC EAE
Ascarina lucida

TH YMELAEA CEAE x

Pimelea f Lyallii
Drapetes Dieffenbachii
Lyallii

UR TIC A CEAE f x

Urtica australis x

ORCHIDACEAE f x x x

Dendrobium Cunninghamii
Earina mucronata x

suaveolens

Sarcochilus adversus x

Thelymitra + longifolia x x x

uniflora x

Microtis porrifolia x

Prasophyllum Colensoi
Pterodylis f Banksii x

australis
graminea

Lyperanthus antarcticus
Caladenia Lyallii

bifolia

X

X

X

X

X

Chiloglottis cornuta

X

X

X

X

X

Corysanthes f oblonga

X

X

X

rivularis

X

rotundifolia

X

X

triloba

X

macrantha

X

X

X

Gastrodia Cunninghamii

X

I RID AC EAE

X

X

Libertia ixioides

X

pulchella

LI LI AC EAE f

X

X

X

Rhipogonum scandens

X

Enargea marginata

X

Cordyline f australis

Aste/ia f linearis

X

nervosa

X

x x

30 Willis . — The Flora of Slewart Island ( New Zealand) :

Phormium tenax
Bulbinella Hookeri
Arthropodium candidum
Herpolirion novaezealandiae

JUNCACEAE
Juncus f pallidus
effusus
bufonius
planifolius
antarcticus
novaezealandiae
Luzula f campestris

NAIAD ACE AE\
Triglochin striatum
Potamogeton f polygonifolius
Cheesemanii

Zostera nana

CENTROLEPIDACEAE
Centrolepis viridis
Gaiinardia setacea

RESTIONA CEAE
Leptocarpus simplex
Hypolaena lateriflora

C YPERA CEAE +
Eleocharis t sphacelata
Sciipus f aucklandicus
cernuus
antarcticus
inundatus-
nodosus
Carpha alpina
Schoenus f pauciflorus
axillaris
nitens

Cladium f glomeratnm
Gunnii
Vauthiera
Gahnia f procera
Oreobolus pumilio
strictus

Uncinia f caespitosa
australis
leptostachya
riparia
rupestris
filiformis
Carex f appressa
echinata
ternaria
testacea
lucida
uncifolia
comans
litorosa
dissita
Solandri

Deyeuxia f Forsteri
setifolia
avenoides
quadriseta
Dichelachne crinita
Deschampsia + caespitosa
Trisetum antarcticum
Danthonia f Cunninghamii
Raoulii
Crassiuscula
pungens (endemic)
pilosa

semiannularis
Arundo conspicua
Poa f foliosa

novaezealandiae

Astoni

seticularis

pusilla

caespitosa

Colensoi

imbe cilia

Atropis novaezealandiae
Festuca f littoralis
rubra

FILTCES

Hymenophyllum f rarum

polyanthos
villosum
australe
pulcherrimum
, dilatatum

demissum
flabellatum
rufescens
subtilissimum
Cheesemanii
minimum
tunbridgejise
unilaterale
multifidum
bivalve

Trichomanes + reniforme
Lyallii
venosum
strictum

Cyathea medullaris
Hemitelia Sinithii
Alsophila Colensoi
Dicksonia squarrosa
Linds ay a linearis
Adiantum + ajflne
Hypolepis tenuifolia
Pteris f aquilina
scaberula
incisa

Lomaria + ( Blechmwi ) Patersoni
discolor

triflda

X

vuicamca

lanceolata

X

GRA MINE A E f

XXX

dura

X

Ehrharta Thomsoni

Banksii

Microlaena stipoides

alpina

X

avenacea

X

capensis

XXX

Hierochloe redolens

XXX

fluviatilis

X X

Fraseri

Asplenium + adiantoides

X

a Study in Taxonomic Distribution.

3i

Asplenium ohtusatum
lucidum
bulbiferum
flaccidum

Polystichum + aculeatum
capense

Dryopteris f hispida

Polypodium f punctatum
Billardieri

ABC ABC

X

X

X

Polypodium f grammitidis

XXX

X

X

X

Cyclophorus serpens

X

X

Gleichenia f circinata

X,

X

X

dicarpa

X

X

X

X

Cunninghamii

X

Schizaea Jisiulosa

XXX

X

Todea hymenophylloides

X

X

X

X

X

X

superba

X

A glance at the table will show that the species predicted form
a very representative well-distributed assortment. There are 70 out of 200
Dicotyledons, or 35 per cent., 53 out of 1 1 1 Monocotyledons, or 47 per cent,
and 43 out of 57 ferns, or 75 per cent. We may draw attention to
Onagraceae, and especially Epilobiuni (all 6 species predicted), Coprosma
(6 of 9), Orchidaceae, Juncaceae, and the ferns, including Pteris (all 3 species),
L omaria (7 out of g), and Asplenium (all 5).

There remain unpredicted 188 Angiosperms and 14 ferns. Ten of the
former are local endemics which are dealt with below, and it might be
possible to maintain that there is still room for relicts among the remaining
178. It is therefore of interest to trace their distribution in New Zealand.
None have discontinuous areas, which is a feature that one might expect
sometimes to show among relicts. Classifying them according to their
range (two do not occur in New Zealand proper) we get :

Table II.

No. of Species. Including

Class 1. 1

,001-1,080 m.

75

2.

881-1,000

16

3-

761-880

26

4.

641-760

14

5*

521-640

15

6.

401-520

14

7-

281-400

4

8.

161-280

7

9*

41-160

5

10.

1-40

—

Mean rarity

Mean rarity for New Zealand

176

3*o

5*5

33 wides 42 endemics 1
3 13

146 10 16

3 11

1 14

2 12

— 4

30 — 7

— 5

52 124

i-8 3-4

3*7 6*i

It is fairly evident that one can hardly consider as relicts the 146
species of classes x to 5, which also reach the North Island, and that include
50 wides, some of which, like Spergularia media, , are almost world-ranging.
Thus there remain at most only 30 to choose from, or less than 10 per cent,
of the flora of Stewart. It would be stretching too far an unproved
hypothesis (that of the supposition that most species of very limited range
are dying out) to include the 14 in class 6, which are mostly held up at

1 Endemic to New Zealand or New Zealand and islands.

32 Willis. — The Flora of Stewart Island (New Zealand):

Cook’s Strait, and which include two wides, so that there really only remain
1 6, in classes 7 to 9. Of the 5 in class 9, 4,1 Gunner a Hamiltoni , Olearia
angustifolia , Veronica amabilis , and especially Atropis novae zealandiae , are
more or less closely confined to the coast, and I must leave it to the
ecologists to settle whether they can be in any way regarded as relicts, or
whether they are really coast species which arrived (or evolved) late, and by
water carriage.

In any case, however, these last 16 species belong all of them to fairly
large (old) genera (i. e. large in number of species in New Zealand). The
genera of the 5 in class 9 contain in New Zealand 147 species, an average of
almost 30 ; those of the 7 in class 8 contain 140 species, or an average of
20 ; those of class 7 are 4 with 38 species, or an average of 9. All are
much above the average size of genera in New Zealand (4*2 species). It
is obvious that these species belong to the same class of genera (the larger
and older) as do the actual endemics of Stewart itself, which are dealt with
below (10 genera, 249 species). As one approaches the centre of New
Zealand one finds endemics in increasing numbers belonging to smaller and
smaller genera, which, as we have seen above, are on the whole younger and
younger genera. If these are relicts, then it is clear that the younger
and smaller (in the country) a genus is, the greater its chance of giving rise
to relicts ; but the very awkward problem at once crops up, to explain why
the relicts are crowded together in the centre of the main country of New
Zealand, where there are also the most wides, as we have already shown
(6, p. 201). There is not, it seems to me, any evidence about these species
to give any ground for supposing them relicts.

A comparison of the figures of rarity given at the bottom of Table II
will also prove of little encouragement to the upholders of the hypothesis
of dying out. All these species are on the average far more wide-ranging
in New Zealand than the averages of the groups to which they belong.
Even the endemics show a greater average range in New Zealand than the
average of the wides of that country (7, p. 331).

Examination of the 14 unpredicted ferns (where if anywhere one might
expect relicts) gives even less cause to believe in extinction. Six belong
to class 1, ranging New Zealand from end to end, 3 to class 2, 5 to class 3,
and none to any more localized class.

There yet remains one objection which may be brought up against the
whole prediction and discussion given above. It may be said that I have
drawn my predictions so wide that I have included the whole flora, and have
simply picked out from this list the species belonging to Stewart. As the
bulk of the predictions are based upon the actual floras of the other islands,
this can hardly be the case, but it will be well in conclusion to give a list of

1 The fifth is Gentiana lineata , occurring in LongWood Range and Blue Mountains, Otago, and
an unknown locality in Stewart.

33

a Study in Taxonomic Distribution .

the species predicted for Stewart that are not recorded. Under prediction
A everything was exact. Under B (species reaching the Chathams, Lake
Taupo, and Fovea ux Strait) the following have not been found in Stewart,
though predicted as likely :

Plagianthus divaricatus (cf. p. 42)
Geranium dissectum
Sophora tetraptera
Potentilla anserina (cf. p. 42)

Epilobium pallidiflorum (cf. p. 42)

„ chionanthum
„ insulare (cf. p. 42)
Mesembryanthemum australe (cf. p. 42)
Hydrocotyle moschata
Oreomyrrhis andicola (cf. p. 42)

Daucus brachiatus
Coprosma robusta

„ Cunninghamii
Erechtites quadridentata (cf. p. 42)
Lobelia anceps

Wahlenbergia gracilis (cf. p. 42)
Myosotis spathulata (cf. p. 42)
Calystegia tugoriorum (cf. p. 42)
Dichondra repens
Solanum nigrum
„ aviculare

Myoporum laetum
Mentha Cunninghamii (cf. p. 42)
Salicornia australis
Polygonum serrulatum
Pimelea arenaria

Scirpus frondosus (cf. p. 42)

„ americanus

Deyeuxia Billardieri (cf. p. 42)

These are twenty-nine in all, of which sixteen are wides, and there is no
reason to suppose that their absence from Stewart is due to anything other
than the fact that Foveaux Strait was formed before they reached so far
south in their wanderings. It is noteworthy that the list contains only
three Monocotyledons, though this group forms so large a proportion of the
flora of Stewart (111 of 31 1).1

Finally, under prediction C (Auckland species reaching to Foveaux
Strait and the north end of South Island) there were wrongly predicted :

Colobanthus Billardieri (cf. p. 42) Rostkovia gracilis

Epilobium confertifolium

to which the same explanation may apply.

General Features and Relationships of the Flora.

We shall now go on to apply the method of prediction in greater detail,
with the view of bringing out the general features and relationships of the
flora of Stewart.

(1) As the family is older than the genus, the genus than the species,
one will expect that in comparison with the flora of New Zealand proper
a greater proportion of families will be represented than of genera, of
genera than of species. Verification of this gives :

1 In a later paper I hope to deal with the distribution of the Monocotyledons, which shows
many interesting points, e. g. a regularly diminishing percentage from one end of New Zealand to the
other, and twice as great a percentage in the Aucklands as in the Kermadecs, with an intermediate
figure in the Chathams, and so on.

D

34 Willis . — The Flora of Stewart Island (New Zealand):

Table III.

Families.

Genera.

Species.

New Zealand

9i

329

L392

Stewart

£4 or 59 %

1 54 or 46 %

31 1 or 22 %

(2) A family will

rarely arrive

as a group of genera

simultaneously ;

some will arrive sooner

than others.

Therefore, on the whole, families with

more than one genus in a given country will be older there than those with

only one in that country, and may be expected to be better represented.

Testing this, we get :

Table IV.

Family represented , „ ~ 7 ,

Represented in

Not represented

in ATeiv Zealand by

Stewart by

there.

1 genus

36 families

13 families, 36%

23 families

2

15

6 40

9

3

*5

12 80

3

4-5

10

9 90

1

6-10

9

8 90

1

over 10

6

6 100

-

91

54 59 %

37

In other words, the most ‘successful’ families in New Zealand are the
best represented in Stewart, and the proportion of families shows a steady
increase with the increasing number of genera contained in them.

One may even push this into greater detail, and take the thirty-six
families with one genus, dividing them according to the number of species
in the genus, when one finds :

Table V.

Genera .

7

5

24

No. of Species contained.
6 or more ; 50 in all

3> 4) or 5 5 1 7
1 or 2 ; 30

Represented in Stewart by
14 species, or 28 %

4 23

3 10

(3) One may extend the idea indicated in this last table, and make the
same prediction about the genera as about the families, and say that those
with most species in New Zealand will be the best represented in Stewart.

Table VI.

Genus represented in

In ATew Zealand.

Represented in

Not representea

New Zealand by

Stewart by

there.

1 species

155 genera

32 genera, or 20 %

123 genera

2

£4

22

40

32

3

29

20

68

?

4~5

29

23

79

6

6-10

36

32

88

4

11-20

16

15

93

1

over 20

10

10

100

““

329

154

46%

*75

Thus, just as with the families, the proportion of genera represented in
Stewart shows a steady increase with the increasing number of species in
the genus, from 20 per cent, of those with one up to 100 per cent, of those
with more than 20 species.

35

a Study in Taxonomic Distribution.

Of the 31 1 species of the flora of Stewart, 206, or 66 per cent., belong
to the comparatively few genera that possess in New Zealand 5 or more
species in the genus, the average number in a genus in New Zealand
being 4-2.

On the hypothesis of Natural Selection, as usually interpreted, one
would expect to find Stewart Island — an outlying island, small in area,
simple in geological structure, with small flora and peopled by old species —
occupied largely by plants unsuited to life in the crowded South Island, in
fact a kind of refuge for the destitute. This expectation is vehemently con-
tradicted by what we have just indicated. The genera of Stewart, as
a glance at the list of the flora will show, are in reality what it has been the
custom to call the ‘ successful ’ genera of the neighbouring island, from which
it must have received its flora. These genera are in reality simply those
which were the first to arrive of their various affinity groups. The first 10
genera of the Stewart flora are represented in New Zealand by 103 species,
or an average of 10-3 species per genus, against an average for New Zealand
of 4-2. The last 10 have 70 species in New Zealand, or an average of 7-0.
The 154 genera of Stewart contain in New Zealand 1,067 species, against
325 for the 175 unrepresented genera.

(4) The Stewart Island plants being old, we shall expect to find
‘wides’, which are the oldest forms, best represented among them.

Table VII.

r ir i . Endemic to Neiv Zealand

/! or Arew Zealand and Islands.

New Zealand as a whole 301 1,000

Stewart Island 1 1 1, or 36 % 187 \ or 18 %

(5) One will expect to find the Stewart Island plants, as very old, very
widespread in New Zealand :

Table VIII.

Endemic to

Endemic to

Class.

Range in Neiv Zealand,

Wides.

New Zealand

ATew Zealand

and Islands.

only.

1

1,001-1,080 miles
641-1,000

81

37

48

2-4

23

18

40

5-10

1-640

7

8

36

hi

63

124

Thus 166 plants, or 55 per cent., belong to the first class, which ranges
New Zealand from end to end. Even the species endemic to New Zealand
alone show more in the first class than in classes 2, 3, and 4 put together,
though in New Zealand as a whole the numbers in the first four classes are,
52, 60, 59, and 61.

If we calculate out the rarity in the usual manner, we find that while in

1 The remaining thirteen include the ten local endemics, and Aralia Lyallii, Urtica australis ,
and Poa foliosa , not found in New Zealand proper, and perhaps, or probably, water-borne.

36 Willis. — The Flora of Stewart Island ( New Zealand ) :

New Zealand as a whole the wides show a rarity of 3-7, those that occur in
Stewart show 1-7. As each unit of rarity represents 120 miles, this means
that they range (in New Zealand) on the average 240 miles farther.
Similarly the species endemic to New Zealand and the islands show 2-2 for
Stewart against 2*9 1 for New Zealand as a whole, and the species endemic
to New Zealand only show 3*2 against 6*5. In other words, they range on
an average 796 miles against 400, and even exceed in their range the
average wide of New Zealand as a whole, which ranges only 736 miles.
This is a feature which is quite impossible of explanation by aid of the
doctrine of Natural Selection.

(6) As the ferns are probably older, Stewart should have proportion-
ately more of them than New Zealand proper, but one must remember that
the question of the ferns is complicated by the probability — amounting to
practical certainty — that new wides may continue to arrive long after the
barrier interposed by the sea has become practically impassable to more
than a very few Angiosperms (8, p. 340).

Table IX,

Endemic to New Zealand Ende7nic to New
and Islands. Zealand only.

Ferns. Angiosperms . Ferns. Angiosperms. Ferns . Angiosperms.

New Zealand 92 301 12 98 24 902

Stewart 39,0142% in, or 36% 8, or 66 % 63, or 64 % 10,0141% 124, or 13%

All the figures for ferns are higher than for Angiosperms, though there
is considerable difference among them. The difference, however, is most
marked in the New Zealand endemics, as would be expected.

(7) Stewart Island possesses 10 species endemic to itself alone, and
found nowhere else. As on the whole, as we have already pointed out, the
largest families in New Zealand will be the oldest, we shall expect these
endemics to belong to them (and cf. Appendix, p. 42).

Table X.

Family (in order of size

Species in

Species in

Endemics.

f Olearia Traillii

Raoulia Goyeni

in New Zealand ).^

New Zealand.

Stewart.

j

1. Compositae

203

44 1

1 Cotula Traillii
Abrotanella muscosa
^ Senecio Stewartii

2. Cyperaceae

117

34

Carex longiculmis

3. Scrophulariaeeae

109

9

JJ

4. Gramineae

97

30

Danthonia pungens

5. Orchidaceae

57

21

Ligusticum flabellatum

6. Umbelliferae

54

11

})

7. Ranunculaceae

45

8

Ranunculus Kirkii

8. Rubiaceae

43

13

y>

9. Onagraceae

3i

8

y y

10. Epacridaceae

28

10

Dracophyllum Pearsoni

Total 10 families

784 species

188 species

10 species

1 For the reason why these species are more common than the average of the wides, see 7,
P- 33i.

37

a Study in Taxonomic Distribution.

Thus all the endemics are to be found in the to largest families in New
Zealand, and as a matter of fact in 6 of them, which contain in New Zea-
land 544 species (total for New Zealand, 91 families and 1,301 species), and
in Stewart 137 species (total for Stewart, 54 families and 311 species). They
belong, that is, to the most ‘successful’ families in New Zealand. The
great proportion belonging to Compositae is noticeable, and goes to indicate,
with other parallel evidence that could be produced, that species are some-
what readily formed in this family.

(8) In the same way, one will expect the Stewart endemics to belong
on the whole to the larger genera of New Zealand, and testing this, we find
that Olearia has 35 species, Raoidia 17, Cotida 19, Abrotanella 7 (the
nearest approach to the average of 4*2), Senecio 30, Carex 54, Danthonia 13,
Ligusticum 18, Ranunctdus 38, and Dracophyllum 18, a total of 249 species
for 10 genera, or practically 25 each, almost six times the average for
a genus in New Zealand.

Relationships of the Flora to those of the Outlying Islands.

We shall now go on to deal with the relationship of the flora of
Stewart to those of the Kermadecs, Chathams, and Aucklands, which (see
maps) are islands outlying much farther from New Zealand proper, but at
the same time islands that must have received the bulk of their flora either
by way of New Zealand, as in the case of the Chathams more especially, or
at any rate from the same invasions, as in the case of the Kermadecs (to
some extent) and the Aucklands. As authority for these floras I shall
continue to use Cheeseman’s Flora (1), supplemented by his later lists in
Chilton’s ‘ Subantarctic Islands of New Zealand ’ (2).

Stewart Island lies in lat. 470 S., the Aucklands in 5 1°, the Chathams
in 440, and the Kermadecs in 30°. The distance in a straight line from
Stewart to the Aucklands is about 200 miles, to the Chathams about 700
miles, and to the Kermadecs about 1,200 miles, including nearly the whole
of New Zealand, which lies between. Stewart is chiefly archaean rocks, the
Aucklands all of igneous origin (some parts granites and gabbros, but
mostly volcanic), the Chathams schists, volcanic rocks, or tertiary sediments,
and the Kermadecs entirely volcanic (4).

(9) It is clear from the maps, especially the second map on p. 26, that
while the plants of Stewart Island are old in New Zealand, those of the
other more outlying islands will be older, in general, whether they were
derived from New Zealand, or whether they reached these islands on the
way to New Zealand. One will therefore expect to find that Stewart has
a large proportion of species in common with these different islands, and
that they have a larger proportion of species in common with Stewart than
they have with New Zealand as a whole, though in general they are nearer
to New Zealand. Testing this, we find :

38 Willis. — The Flora of Stewart Island ( New Zealand) :

Table XI.

Common to Stewart and Aucklands

7i

species, or

22 ^

' of flora of Stewart

*5

New Zealand and A.

83

6

New Zealand

Stewart and Chathams

84

27

Stewart

* J

New Zealand and C.

118

9

New Zealand

Stewart and Kermadecs

22

7

Stewart

New Zealand and K.

52

3

New Zealand

That Stewart Island should have a great deal in common with the
Aucklands might be expected, but that it should have proportionately so
much more in common with the Chathams and the Kermadecs than has
New Zealand, though the latter divides it from the Kermadecs, and is nearer
to the Chathams, would never be expected on the older views as to distribu-
tion of species. This subject will be followed up in a subsequent paper on
the outlying islands.

(10) On examination of the map, it will be noticed that no circle can
be drawn to include the Chathams and Aucklands without including
Stewart, unless it be placed with its centre in an impossible depth of sound-
ings. Unless, therefore, the times of separation from New Zealand of
Stewart and these islands were very different, we shall expect to find that
all species common to the Chathams and Aucklands also occur in Stewart :

Dicotyledons
Monocotyledons
Ferns

(11) If one draw a straight line from Stewart to the Chathams, bisect
it, and use the point of bisection as the centre of a circle whose circum-
ference passes through the islands mentioned, then it is evident that if at
the time of dispersal of most species there was continuous land where the
1,000 fathom line now runs, the species common to Stewart and the
Chathams should in general have covered this circle, or so much of it as was
above water. The circle cuts the North Island near Lake Taupo, at about
350 miles from the North Cape, so that, except in so far as barriers caused
by submergence of parts of the land, or in other ways, have interfered, we
should expect these species to range in New Zealand up to or beyond
Lake Taupo.

Examination soon shows that, of the 84 species common to Stewart
and the Chathams, no less than 74 range New Zealand from end to end,
while six more range from Stewart up to from 100 to 200 miles beyond
Lake Taupo. This leaves only four, or less than 5 per cent, which do
not reach the lake. These are Tillaea moschata and Veronica elliptica ,

Table XII.

Common to Chathams
and Aucklands.

J9

13

l9

51

Occur in Stewart.

19

13

19

5i

39

a Sltidy in Taxonomic Distribution.

both coast species which may have arrived later than the rest, by water
transport ; Carex appressa , which is given by Kukenthal (3) as occurring
throughout New Zealand, and which consequently will not be an exception,
either here or in the previous paper in which it was given as such (7, p. 329) ;
and finally Pterostylis australis , which is regarded by Hooker as a variety
of P. Banksii , whose range is the entire length of New Zealand.

Of the ferns found in the Chathams, and reaching to Lake Taupo one
way and Foveaux Strait the other, 36 reach Stewart and 7 reach only to
the strait, whilst Lomaria dtira , which reaches only about half-way along the
South Island, though it occurs in Stewart, the Snares, the Aucklands, Camp-
bell, and the Antipodes, as well as the Chathams, is given by Cheeseman as
‘a purely littoral plant, never found far from the influence of sea-spray’.

(12) It is clear that of the many species which Stewart has in common
with the other islands, those in common with the Kermadecs, which are the
farthest away, will on the whole be the oldest, those in common with the
Chathams probably next, and those in common with the Aucklands youngest.
In other words, the first named should be the most widespread in New

Zealand

•

Table XIII.

Class.

Range.

Stewart and

Stewart and

Stewart and

Kermadecs.

Chathams.

A ticklands.

i

1,001-1,080 m.

22, or 100 %

74, or 87 %

40, or 56 %

2

881-1,000

- —

3

5

3

761-880

—

3

8

4

641-760

—

—

8 ,

5

521-640

—

2

4

6

40T-520

—

1

3

7

281-400

—

—

—

8

161-280

—

1

3

9

41-160

—

—

• —

10

1-40

—

—

—

22

84

71

Rarity (Classes 1-10)

1*0

I°3

2‘3-

Thus the Kermadec species have the maximum commonness (distribu-
tion area) possible, ranging New Zealand from end to end. The Chatham
species are almost as common, and the Auckland species a good deal
less so.

(13) As the Kermadec species are the oldest, they should include the
greatest proportion of wides, while the species endemic to New Zealand and
the islands, which are younger, should show more in the other islands :

Common to

Table XIV.

Wides.

Endemic to New
Zealand and Islands .

3, or 14 %
34 4i
45 6.3

Stewart and Kermadecs
,, Chathams

„ Aucklands

1 9, or 86 %
60 59

26 37

40 Willis. — The Flora of Stewart Island ( New Zealand ) ;

The Relationship of Stewart Island to Invasions

of Plants.

We have now to go on to consider the relationship of Stewart Island
to the great invasions of plants into New Zealand which were considered in
my last paper (9, p. 355). And first let us deal with the northern invasion,
which probably entered, we saw, at some point (or more likely space) in the
North Island not more than 400 miles south of North Cape (the island is
320 miles long).

It is at once evident that the northern invasion was very early, or that
it found New Zealand at the time of its entry comparatively unobstructed
with vegetation, for although it had to travel the whole length to Foveaux
Strait, 1,000 miles south of North Cape, none the less a very fair proportion
of its species arrived there in time to cross to Stewart before it was too late.
There reach the strait, of the plants of this invasion, 5 wides and 32
endemics, and of these 3 wides and 14 endemics cross the strait. Those
which cross belong, as one would expect from predictions 2, 3, to the largest
genera and families of the invasion. As a matter of fact they belong to
Pittosporaceae (1 genus, 19 species), Saxifragaceae (6/8), Myrtaceae (4/18),
Araliaceae (5/15), Cornaceae (2/5), Lentibulariaceae (1/6), and Urticaceae
(5/10), a total of 7 families, 24 genera, and 81 species, i. e. an average per
family of 3-4 genera, and per genus of 3-3 species. The remainder of the
invasion consists of 2 6 families, with 38 genera and 52 species, averages of
1*4 genera per family and 1-3 species per genus.

To go on to the southern invasion, it is at once evident that this was
either much later in New Zealand or found the ground more troublesome
to traverse, as although it was mainly herbaceous, and we have some
reason to suppose that herbs may travel faster than trees, of which the
northern invasion was chiefly composed, and although it had its centre
about 400 to 600 miles south of the other invasion, and was therefore so
much the nearer to Stewart, none the less it is not so well represented there
as the northern invasion. Only 51 wides out of 91 (at Foveaux Strait)
occur in Stewart, or 56 per cent., against 3 out of 5, or 60 per cent., of the
northern wides ; and of the total of plants of the invasion, and its result in
endemics, only 115 out of 286 cross Foveaux Strait, or 40 per cent., against
17 out of 37, or 45 per cent.

Had the southern invasion entered New Zealand by way of Stewart
Island, one would not expect such a result, but would expect to find more
species in Stewart than on the northern side of the strait. One may without
any further discussion, it seems to me, come to the conclusion that the
southern invasion of plants entered Stewart from the north side of Foveaux
Strait, and consequently that Stewart did not lie in the direct track of that
invasion.

a Study in Taxonomic Distribution. 41

Again it happens that (as predicted for the northern invasion) Stewart
contains chiefly representatives of the larger genera — all the families of the
southern invasion are to be found. It contains 56 genera of this invasion,
represented in New Zealand by 451 species, against 5a unrepresented
genera with 9 1 species.

We have thus made quite a number of predictions, based solely upon
the hypothesis of age and area, about the flora of Stewart Island, and every
one of them has proved to be correct, with a large margin. It is clear that
it is fairly safe to make predictions from age and area ; in other words, the
operation of this law is by far the principal factor in determining the actual
geographical distribution of species about the globe prior to the advent of
man. Physical barriers of course have a much greater influence in deter-
mining the actual areas occupied, but their influence is of purely negative
kind, while age is positive. Local distribution, in a given district, on the
other hand, is determined by the ecological conditions of that district, but
unless the ecological boundary (beyond which a species cannot grow) is
fairly broad and wide, it does not seem to affect seriously the total area
occupied within the outer limits.

It must again be made clear, for this is a point on which many of my
critics fail to understand my position, that the law must not be applied to
individual species, but only to groups of allied forms. It is a law which
applies to taxonomic distribution, and its operations can only be clearly
made out, and disentangled from the many other causes that aid in deter-
mining geographical distribution, by taking a group of allied species.
After a lapse of x years a group of 20 herbaceous Compositae will occupy
an area z ; after a lapse of y years a group of arboreous Dipterocarpaceae
will occupy the same area z in the same country, but we have no means
of comparing x and y at present. Each, however, is governed by age
and area.

Another point whose misunderstanding seems to cause difficulty for
some in accepting the law, is the enormous differences between one species
and another in the area occupied. They seem unable to conceive how this
can come about without the operation of Natural Selection in reducing the
area occupied by one of the species. In thinking over the subject they are
apt to forget that the area occupied per unit time increases as the age of the
species increases. So long as one only takes the diameter of the area
occupied, as I have done in New Zealand, a plant when it reaches a diameter
of, say, 1,000 miles is perhaps twice the age that it was when it reached 500.
But if the species were spreading every way in untouched continental areas
of uniform conditions, then, while the diameter increased

1234567

2

42 IV 1 1 /is. — The Flora of Stewart Island (New Zealand):

the area would increase

i 4 9 I(5 25 36 49

or, in other words, in equal times the increase in area occupied would be

3 5 7 9 n 13

so that it becomes quite easily possible for a species to spread over an

enormous area once that its area occupied is large. Biologists who are not

accustomed to working with figures are apt to forget that the area of

a circle increases with the square of its diameter.

Appendix.

Since the above was in type, I have received from Dr. L. Cockayne,
F.R.S., a most valuable letter of suggestion and criticism, and my one
regret is that there is not time to think it over and incorporate the results
in this paper, though I hope that further papers on New Zealand, which
I have in preparation, will show its effects.

I had originally intended to base my statements in this paper solely
on the work of Cheeseman (1, 2), but Dr. Cockayne has called my attention
to the fact that his report on Stewart Island (ic) contains many additions
to the flora. There are so many that it would be unpardonable to ignore
it, though its incorporation really makes no difference to my final results,
and does not affect in any way the correctness of the predictions here made.
The additions to the flora made in the paper referred to are : —

A B

R A NUNC ULACEAR
Ranunculus f Crosbyi (endemic)

Caltlia novaezealandiae
VIOLACEAE
Plymenanthera + dentata

CAR YOPHYLLAC.EAE
Colobanthus f Billardieri?

HYPERICACEAE
Hypericum japonicum
MALVACEAE
■ Plagianthus divaricatus
TILIACEAE
Aristotelia Colensoi

COR I A RI A CEAE
Coriaria thymifolia
ROSA CEAE
Potentilla anserina
Acaena + novaezealandiae

HA L OR HA GIA CEA E
Myriophylliwi Votschii
Gzmnera^ prorepens
arenaria ?

ONAGRACEAE
Epilobium f pallidiflorutn
junceum
pictum
insulare
novaezealandiae

C

F1COIDEAE
Mesejnbryanthemum azistrale
UMBELLIFERAE +
Azorella f Cockaynei (endemic)
Oreomyrrhis andicola
Ligusticzim f aromaticum
x ARALIACEAE\

Panax\ anomalum
RUBIACEAE _

Coprosma f rotundifolia
areolata
ramulosa
retusa

COMPOSITAE +

Olearia f divaricata (endemic) ]
virgata

Celmisia f rigida (endemic)
x Gnaphalium f trinerve

x Raoulia f australis

glabra

Helichrysum f Loganii ?

• grand iceps
Abrotanella f linearis
Erechtites f quadridentata
x Taraxacum glabralmn

S TYLIDIA CEA E
Phyllachne clavigera
x CAMPANULA CEA E +

Wahlenbergia gracilis

ABC

x

x

X

X

X

a Study in Taxonomic Distribution .

43

ABC

MYRSINACEAE
Myrsine + chathamica (prob. introd.)

APOCYNACEAE
Parsonsia heterophylla
B0RAG1NACEAE

Myosotis f spathulata x

CONVOLVULACEAE +

Calystegia tugoriorum x

SCR 0 PH U LA R/A CEA E +

Veronica f Laingii (endemic)

Ourisia f prorepens ?

modesta (endemic)

Euphrasia f repens
LABIA TAE

Mentha Cunninghamii x

ILLECEBRACEAE
Scleranthus biflorus

POLYGONACEAE
Muehlenbeckia complexa
LORANTHACEAE
Loranthus f micranthus
EUPHORBIA CEAE
Euphorbia glauca
LILIA CEAE t
Astelia + subulata

Phormium Cookianum
Bulbinella Gibbsii (endemic)
JUNCACEAE
Juncus f lamprocarpus
C YPERA CEA E +
Eleocharis f acuta

Cunninghamii
Scirpus f sulcatns
frondosus
Uncinia \ compacta

pedicellata (endemic)
rubra

Carex f secta
pumila
Oederi

GRAMINEAE f
Agrostis + Dyeri
Deyeuxia + Billardieri
Deschampsia f Chapmanni
Agropyrum scabrum
Asprella gracilis
FI LIC ES t
Hypolepis millefolium
Lomaria + nigra
Asplenium f Lyallii
Polystichum f cystotegia

adianiiforme

ABC

x

X

X

X

X

Of these species, 21 are predicted, and 56 not, a proportion considerably
smaller (largely owing to the presence of so many endemics of Stewart
Island) than that given at the end of the principal table above (28 against
45 per cent.). No fewer than 14 of the 32 species given as wrongly predicted
on p. 33 are included in this list, so that there only remain 18 species
predicted that have not been found.

The predictions given in the paragraphs numbered 1, 2, 3, 4, 5, and 6
remain as before, with slight numerical alterations.

In prediction 7 (Stewart Island endemics) we must add nine new
endemics to the ten there mentioned, as follows :

Family {in Order of Size

No. of Species in

No. of Species in

Endemics.

in New Zealand).

New Zealand A

Stewart.

1. Compositae

203

44

( Olearia divaricata
\ Celmisia rigida

2. Cyperaceae

117

34

Uncinia pedicellata

3. Scrophulariaceae

109

9

l Veronica Laingii
( Ourisia modesta

4. Gramineae

97

30

—

5. .Orchidaceae

57

21

j Azorella Cockaynei
{ Aciphylla Trailin'*

6. Umbelliferae

54

11

__

7. Ranunculaceae

45

8

Ranunculus Crosbyi

8. Rubiaceae

43

13

—

9. Onagraceae

31

8

—

10. Epacridaceae

28

10

—

11. Leguminosae

25

—

—

12. Boraginaceae

24

2

—

13. Juncaceae

24

7

—

14. Cruciferae

22

3

—

15 Liliaceae

20

9

Bulbinella Gibbsii

1 The new endemics must be added to these totals.

2 Regarded above as occurring in New Zealand.

44 Willis.— The Flora of Stewart Island ( New Zealand ) ;

This result again emphasizes the fact that the endemics occur almost
only in the very largest families (the average size of a family in New
Zealand is 15 species), i. e., as we have explained, the families which are
on the whole the oldest in New Zealand. If we add together the two
lists of endemics, we find that 17 occur in the first seven families, and
only 2 in the second eight, while the 76 smaller families contain none
whatever.

The addition of these nine to the list of endemics of Stewart also
confirms prediction 8, for the genera to which they belong, 9 in all, contain
249 species, or an average of 27 each, a slightly higher figure than that
given for the genera containing the first ten endemics.

The other predictions given also remain as stated, with slight numerical
corrections.

Nothing, therefore, in this great addition to the species found on
Stewart Island compels any modification or real revision of the general
thesis of this paper, and in this respect it may be compared with the
revision of the figures for Ceylon which I have elsewhere published (11),
and which also showed no differences in the final results.

Summary.

The flora of Stewart Island is dealt with in the light of age and area as
regards its taxonomic distribution. Numerous predictions are made as to
what should be expected under that hypothesis, and verification is made
upon the facts, all the predictions proving to be correct.

An attempt is made to predict the actual composition of the flora
from what is known of the floras of the Kermadecs (1,200 miles away, at
the other end of New Zealand), Chathams, and*Aucklands, and 139 species
of Angiosperms out of 383 are correctly predicted, and no less than 46 out
of 62 ferns (74 per cent.), while only 18 species are predicted that have not
been found.

Verification of the other predictions shows that—

Stewart has a greater proportionate representation of families than
of genera, and of genera than of species, as compared with New
Zealand.

Families are represented in proportion to the number of genera
contained in them (in New Zealand).

Genera are represented in proportion to the number of species in
them (in New Zealand).

Wides (the oldest forms) are best represented in the flora of
Stewart.

The plants of Stewart are very widely spread in New Zealand,
about twice as widely as the average.

The proportional representation of ferns is greater.

a Study in Taxonomic Distribution . 45

The endemics of Stewart are in the largest (in general, oldest)
families of New Zealand.

The endemics of Stewart are in the larger (older) genera of New
Zealand.

The Kermadec, Chatham, and Auckland Islands have proportion-
ately more in common with Stewart than they have with New Zealand
itself, although they are nearer to New Zealand than to Stewart.

All species that occur both in the Chathams and the Aucklands
are also found in Stewart.

Species common to Stewart and the Chathams (84) range in New
Zealand, with 4 (really 3) exceptions, up to Lake Taupo or beyond (in
the North Island), i.e. to the circumference of the circle passing through
Stewart and the Chathams.

The species common to Stewart and the Kermadecs (22) are most
widespread in New Zealand (rarity i-o, the minimum), those common
to Stewart and the Chathams next, and those to Stewart and the
Aucklands least so.

The plants common to Stewart and the Kermadecs, being the
oldest, show the greatest proportion of wides, while endemic forms
show in increasing proportion in the plants common to Stewart and the
Chathams, or Stewart and the Aucklands.

The relationship of Stewart to the two great invasions of plants into
New Zealand is then considered, and it is shown that the northern invasion
was perhaps the earlier, and that Stewart did not lie in the track of the
southern invasion, but received the plants thereof from the north side of
Foveaux Strait. In each invasion the plants which occur in Stewart are
selected from the largest families and genera.

Finally, it is pointed out that as so many predictions may be success-
fully based upon age and area alone, the operation of this factor must be the
principal positive determining cause in geographical distribution, while the
operation of barriers is the principal negative cause. Some difficulties
which various workers have experienced in thinking of the hypothesis are
also pointed out, notably that the area occupied, in the absence of barriers
or other causes of limitation, increases with the square of the diameter, the
latter probably increasing uniformly with the passage of time.

46 Wiliis. — The Flora of Stewart Island ( New Zealand ).

Bibliography.

1. Cheeseman : Manual of the New Zealand Flora.. Wellington, 1906.

2. — : On the Systematic Botany of the Islands to the South of New Zealand, in Chilton's

‘ Subantarctic Islands of New Zealand', vol. ii, p. 389. Wellington, 1909.

3. Kukenthal: Cyperaceae-Caricoideae, in ‘ Das Pflanzenreich \ Leipzig, 1909.

4. Marshall: Geology of New Zealand. Wellington, 1912.

5. Petrie : Gramina of the Subantarctic Islands of New Zealand, in Chilton. 1. c., p. 472.

6. Willis : Relative Age of Endemic Species. Ann. Bot., vol. xxxi, 1917, p. 189.

7. : Distribution of the Plants of the Outlying Islands of New Zealand. 1. c., p. 327.

8. : Further Evidence for Age and Area. 1. c., p. 335.

9. : The Sources and Distribution of the New Zealand Flora, l.c., vol. xxxii, 1918, p. 339.

10. Cockayne : Report on a Botanical Survey of Stewart Island (N.Z. Dept, of Lands). Welling-

ton, 1909.

11. Willis : The Endemic Flora of Ceylon (correction). Proc. Roy. Soc , B., vol. lxxxix, 1916.

Variation in Eranthis hyemalis, Ficaria verna, and
other Members of the Ranunculaceae, with Special
Reference to Trimery and the Origin of the Perianth.

BY

E. J. SALISBURY, D.Sc., F.L.S.,

Lecturer in Botany , East London College , University of London.

With twenty Figures in the Text and Tables I-X.

THE observations embodied in the present paper were made with a view
to obtaining more detailed information than was available regarding
the structure of 5 indefinite ’ flowers. The results seemed sufficiently inter-
esting to warrant their publication, since they appear to justify certain con-
clusions regarding the character of the perianth in the Ranunculaceae.

The material employed has been derived from several widely separated
localities, in order, as., far as possible, to ensure the inclusion of extremes.
Reliance has, however, been chiefly placed on a detailed examination of
numerous specimens from one or two habitats.

L Eranthis' hyemalis, Salisbury.

(a) The structure of the normal flower .

Examination of nearly four hundred specimens of Eranthis hyemalis
shows that by far the greater number exhibit a coloured perianth of six
members disposed in two whorls of three members each, thus corresponding
to the one-third phyllotaxy of the foliage and scale-leaves (cf. Irmisch, 1860).
As the flower emerges from the soil (Salisbury, 1916 a) it is protected by an
involucre of three bracts. These are connate at the base and form a whorl
immediately below the flower. A close examination will show that of the
three bracts one is completely external, the adjacent member has one margin
underlapping and the other overlapping, whilst the third is completely
internal. The bracts are thus arranged in a spiral which may pass either in
the clockwise or anticlockwise (Fig. 2, c) direction.

Each bract exhibits three principal lobes, which are usually deeply
divided, and the whole is supplied by three vascular strands that anastomose

[Annals of Botany, Vol. XXXIII. No. CXXXX January, 1919.]

48 Salisbury. — Variation in Eranthis hy emails,

almost immediately on entering the leaf and again diverge, other smaller
veins branching off at the same time (cf. Fig. io, A-c).

The members of the outer whorl of the perianth are broad and, on
removal, show a scar with from five to three vascular bundles (cf. Fig. 2, K),
of which the three median bundles are large and the two lateral bundles
(not always present) small. The three inner perianth members are narrower
than the outer and usually supplied by only three vascular strands (Fig. 2, L),
or less commonly by two or even one vascular bundle. In all cases there
appears to be but a single strand which leaves the receptacular stele, but
this sooner or later gives off two main lateral branches in succession. The
variation in the number of bundles, as seen on the scar when a perianth

segment is removed, is due
to differences in the level
at which this trifurcation
takes place. Payer (1857)
was therefore incorrect in
writing, ‘Si Ton arrache ces
six petales, on remarque
dans chaque cicatrice des
trois petales externes l’em-
preinte de trois faisceaux
fibro-vasculaires, et dans
chaque cicatrice des trois
petales internes l’em-
preinte d’un seul faisceau
fibro-vasculaire \ No dis-
tinction with regard to the
vascular supply can be
drawn between the mem-
bers of the outer and inner
whorl beyond the fact that the broader outer perianth segments usually
exhibit more main strands than do the narrower segments of the inner
whorl. As we shall see later, supernumerary perianth segments are by
no means infrequent, and these usually are narrower even than the inner
perianth segments, and, like the latter when they too are narrow, fre-
quently exhibit a scar with only one vascular bundle. Sometimes these
supernumerary perianth segments are, however, broader when the bundle
branches into three almost at the level of its insertion. The vascular
organization of all perianth segments is consequently essentially similar,
the minor distinctions being related to their breadth.

Within the perianth there are most commonly found six nectaries, or
honey-leaves, which arise in pairs opposite each of the outer perianth seg-
ments. The nectary on removal exhibits a scar with a single vascular

Fig. i. Flower of Eranthis hyeynalis. The roman
numerals indicate the order of dehiscence.

Ficaria verna , and other Members of the Ranuncutaceae. 49

bundle (Fig. 2, m) ; this passes up the stalk, but on reaching the body of the
nectary branches into three strands which traverse the bilobed dorsal lip.

The androecium consists of numerous stamens, the number of which, as
shown in the sequel, is very variable — most commonly thirty or some other
multiple of three. The stamens are generally found to form a series of
radial files, the number of files being commonly double that of the nectaries.
There are thus usually twelve radial series, of which six terminate peripher-
ally in a nectary, whilst the remaining six alternate with them ; the former

^5 Fig. 2. Eranthis hyemalis. a and B, flowers with the androecium dissected away, showing
the paired character of the supernumerary honey-leaves (/) ; c, floral diagram of typical cyclic
flower ; d, partially bifurcated honey-leaf ; e and F, petaloid honey-leaves ; G and H, honey-
leaves bearing anthers (a) ; I and j, branched stamens ; K, scar of outer perianth segment ; L, of
inner perianth segment ; M, scar of nectary ; N, scar of stamen ; v.b. vascular strand.

each consists typically of two stamens and one nectary and the latter of
three stamens. To this arrangement (Fig. 2, c) there are, however, numerous
exceptions (Fig. 3), the number of orthostichies being sometimes as many
as twenty and not infrequently eleven, thirteen, or fourteen.

By removing a flower, before any of the stamens have dehisced, and
placing it in a warm room under a low-power dissecting microscope, the
whole sequence of dehiscence can be readily followed. We have confirmed
the observation of Irmisch (loc. cit.), that the first stamens to mature are the
three situated opposite the inner perianth segments. These are followed by

E

50 Salisbury. — Variation in Er ant his hyemalis ,

the three stamens opposite the outer perianth segments (Fig. i). The
three members of each whorl dehisce in rapid succession, followed after
a shorter or longer interval by those of the next whorl within. The number
of stamens, then, and their order of dehiscence, indicates that the androecium
is quite commonly whorled, but a pseudo-spiral appearance is brought
about by mutual pressure which results in a lateral displacement comparable
to that seen in the floating rosettes of Callitriche vernalis or the leaves sur-
rounding the inflorescence of Cyperus alter nifolius. In other cases, however, .
the androecium is obviously spiral, frequently with a divergence of T2T or T2^,
the eleven or thirteen parastichies being clearly recognizable. As was
pointed out by Irmisch (loc. cit.), the flower of Eranthis is then either cyclic or
hemicyclic, or when, as happens but rarely, the perianth is spiral the flower
may be completely acyclic.

Eichler (1878, p. 169) describes the androecium of Eranthis as most
frequently consisting of rows of three stamens each, opposite the petals,
alternating with which are six rows of four members, a total of forty-two
stamens. Not only, however, have we failed to confirm this arrangement,
but the number of stamens in the specimens examined seldom reached this
figure.

The gynaeceum consists of a varying number of carpels, usually either
five or six. In the latter case two whorls of three members each are clearly
recognizable.

A drawing of a typical flower is shown in Fig. 1, the roman numerals
indicating the order of dehiscence of the stamens. In Fig. 3, C, is shown by
means of a diagram a typical cyclic flower.

(b) Meristic variation T

(1) The perianth. The ‘curve’ given in Fig. 4 shows the numerical
variation exhibited by the perianth. As will be seen, the lowest number of
members observed was five, but in such cases, with few exceptions, the place
of the sixth member was taken in the outer whorl by a bract. The actual
variation, apart from transformation, is then almost entirely in the direction
of increase, the maximum number observed being nine. This unilateral
character of the variation ‘ curve 5 for perianth members is frequent, and de
Vries (1908, p. 740) in Ranunculus bulbosiLs has isolated a concealed secondary
summit to which this asymmetry is to be attributed.

If a large number of flowers be examined one is struck by the repeated
occurrence of perianth members showing all degrees of lobing, examples of
which are shown in Fig. 5, E-G, and Fig. 6, C. Nearly every condition, from
a mere notch to two almost completely separated halves, has been observed.
Most commonly the two lobes lie in the same tangential plane, but less
frequently the lobes are large and overlap to a considerable extent. When

Ficaria verna , and other Members of the Ranunculaceae . 5 1

more than six perianth segments are present the increased number of
primordia may be regarded as due to a tendency to produce a polymerous
perianth of which the bifurcated members are an incomplete expression.

The two antagonistic tendencies, towards trimery and multiplication of
parts, have resulted on the one hand in the production of the numerous
instances of supernumerary perianth segments, and on the other in the more
or less complete fusions exhibited as notched and bilobed structures. That
these latter are to be so interpreted seems indicated by the occasional
presence of slightly notched perianth segments in which the two halves do

Fig. 3. Eranthis hyevialis. Empirical diagrams showing arrangement of honey-leaves

and stamens.

not stand in the same tangential plane. As a result there is a longitudinal
kink where the two halves join that seems best interpreted as due to fusion
between two primordia not situated precisely side by side. The rarity of the
latter phenomenon is, however, strong presumptive evidence that the fusing-
pairs of primordia were themselves the product of the congenital fission of
a single primordium, and that subsequent fusion has taken place along the
original plane of separation ; a view supported by the fact that the super-
numerary perianth segments are generally much narrower than those
normally present (Fig. 5, I). The position which they occupy in the flower
is also in agreement with this hypothesis (cf. Fig. 6, A and C). Evidence
based on numerical relations will, moreover, be adduced to show that there
is no ground for the assumption that the supernumerary members are the
result of transformation either of honey-leaves or of stamens. Further, the

52 Salisbury. — Variation in Eranthis hy emails,

supernumerary perianth segments often He on the same orthostichy as the
honey-leaf, hence to explain the structure of such flowers on this view
a double metamorphosis must be assumed, viz. the transformation of the
honey-leaf into a petal and of the next stamen within, on the same ortho-
stichy, into a honey-leaf. Again, very rarely a supernumerary perianth
segment is present and at the same time the honey-leaves are only five in

Fig. 4. Variation ‘ curves 1 for perianth, honey-leaves, and gynaeceum of E. hy emails.

number, that on the same orthostichy as the extra perianth segment being
absent. This might appear to indicate that, as a rare occurrence, a honey-
leaf does become completely transformed, but in the case illustrated in
Fig. 3, D, this explanation is not admissible, since it would involve the
assumption of one more stamen on this orthostichy than are present on any
one of the other§. Evidently in such cases the reversion of the nectary to
the staminal condition is in some way related to the space- conditions con-
sequent upon the presence of the supernumerary perianth segment.

Ficaria verna , and other Members of the Ranunculaceae . 53

In any consideration of the Ranunculaceous perianth the construction
which it primitively exhibited is necessarily important, and Erantkis sheds
some light on this question. Two conditions are found in Ranunculaceae,
viz. the pentamerous and the trimerous, and both are met with in the present
species, though the former condition but rarely. As already stated, in most
cases where there are only five coloured perianth segments this is due to
the transformation of one ; but rarely a true pentamerous perianth is found,
and where such is the case the five members exhibit a quincuncial arrange-
ment as in typical pentamerous species. It is clear that this condition can
easily have been derived from two alternating whorls of three members
each if we assume that the member which is half external, half internal, was
formed by the fusion of the anterior member of the outer perianth with one

Fig. 5. Eranthis hyemolis. a and b, lobed perianth segments; c, trilobed bract replacing
a perianth member; d, partially virescent perianth segment; e-g, lobed perianth segments;
H, partially coloured bract ; I, supernumerary perianth segment. Green parts indicated by shading.

or other of the lateral members of the inner perianth, according as the flower
exhibits a right-handed or left-handed spiral. This would produce the typical
quincuncial imbrication. That the perianth member in question has been so
derived would seem to be indicated by the fact that in some cases it exhibits
six principal veins in place of the usual three. The anterior perianth segment
in a quincuncial flower may, moreover, be bilobed, and its attachment is
broader than that of the other segments. In Eranthis there can be no
question that the pentamerous condition has been derived from the trimer-
ous, and in view of the widespread character of the latter type in related
families it may well have been the primitive condition in the Ranales as
a whole. Thus we find that in the Nymphaeaceae the genera with the
least specialized type of ovary, viz. Cabomba and Brasenia , are trimerous

54

Salisbury. — Variation in Eranthis hy emails,

throughout, whilst the more specialized ovaries are associated with a multi-
plication of parts. Moreover, Cabomba and Brasenia exhibit a simpler
anatomical structure than the other genera (Gwynne-Vaughan, 1897). A
trimerous perianth is also characteristic of the families Anonaceae, Berberi-
daceae, Lactoridaceae, Lardizabalaceae, Menispermaceae, Magnoliaceae, and
Myristicaceae, although several of these orders exhibit the usual derivative of
trimery, namely, dimery. Trimery is thus associated with the arboreal
habit as well as being of widespread occurrence in
the Cohort.

In the Ranunculaceae both pentamerous and
trimerous flowers occur in the same genus or even
in the same species, though pentamery is always
associated with the highly specialized zygomorphic
flowers. For example, in many Paeonies there is
a quincuncial calyx followed by a pentamerous
coloured perianth, but in Paeonia whitmanniana
the calyx consists of three members and the coloured
perianth of two trimerous whorls (Baillon, 1862). In
Ficaria verna , when the calyx consists ot six members
they occur in two alternating whorls of three members
each ; when the calyx consists of five members the
arrangement is quincuncial (Clos, 1852). Similarly
in various species of Anemone and Helleborus the
perianth may consist of two trimerous, or one quin-
cuncial whorl. In Anemone nemorosa both conditions
occur (Yule, 1902). In A. pulsatilla the trimerous
condition is the normal one, in A. ranunculoides the
pentamerous. This variation is, moreover, not re-
stricted to the Ranunculaceae, but occurs also in the
Berberidaceae (cf. Eichler, 1875, Bd. I, p. 1 6) and
is even found amongst the stereotyped Mono-
cotyledons. Paris qnadrifolia and some members
of the Araceae, for example, not infrequently exhibit
a single quincuncial whorl (cf. Smith, 1893).

(d) The honey-leaves or nectaries. The honey-leaves vary in number
from four to twelve (cf. Figs. 3 and 6). Only one example with four
nectaries was encountered, and it is worthy of note that here, as in nine out
of the fifteen specimens with only five nectaries, there was no accompanying
increase in the number of perianth segments. The reduced number must
therefore be attributed to an actual diminution, and is probably due to
replacement of one of the pairs of honey-leaves by a single member, and the
orientation in such cases fully warrants this suggestion. The increase, up
to as many as twelve, is doubtless the outcome of bifurcation of one or more

malis. Empirical diagrams
showing arrangement of
bracts and perianth seg-
ments in abnormal flowers.
Green parts black, coloured
parts shaded. Constrictions
indicate lobing.

Ficaria verna , and other Members of the Rammculaceae. 55

of the six honey-leaves usually present. In Fig. 2, A, is shown the arrange-
ment of the honey-leaves in a flower where their number was eight, the
gynaeceum and androecium having been dissected away. It will be noticed
that four of the honey-leaves are grouped in pairs. The members of each
pair here arise in such close proximity, as to render their origin from a single
rudiment highly probable. The same feature is illustrated from a specimen
with seven honey-leaves in Fig. 2, B, the contiguous members being situated
at the point marked p. In addition specimens of partially bifurcated honey-
leaves are occasionally present (Fig. 2, D), the example illustrated being
taken from a specimen in which there were also six normal honey-leaves.
Cases such as this doubtless indicate a bifurcation of the original rudiment
and the subsequent fusion of the two halves. Rarely an additional honey-

Fig. 7. Eranthis liyemalis. Meristic variation in androecium.

leaf is exhibited that, from its position, is to be regarded as a transformed
stamen, since it is situated on the same orthostichy as one of those normally
present.

(3) The androecium. The number of stamens ranges from 18 to 44
(cf. Fig. 7), and it is very significant that the lowest number observed should
be a multiple of three. Church (1908, pp. 14-16) found that, in the speci-
mens examined by him, the range was from 24 to 39, with 30 as the usual
number. In our specimens the mode was also 30, whilst a large proportion
of flowers had 24 or 27 stamens. It will be noticed that, though the
general trend of the ‘ curve 5 is of the normal type, there are several maxima
associated with numbers which are some multiple of three. Several
instances of flowers with forked stamens have been observed (Fig. 2, 1 and j),
and it is of importance to note that in most cases, if the forking be disre-

56

Salisbury. — - Variation in Eranthis hy emalis,

garded, the number of stamens is again a multiple of three. Thus in three
separate flowers, in each of which one forked stamen was present, the total
numbers (inclusive of the forked stamens) were 30, 33, and 36.

Having regard to the method of development of stamens and that the
anther is the first part formed, it is evident that these bifurcated examples
must have originated as separate papillae, though probably derived by the
fission of a single primordiurn, the two halves of which subsequently fused.
Here too, then, as in the perianth, we appear to have the two antagonistic
tendencies of multiplication and maintenance of the trimerous condition.
The large proportion of individual flowers with 24, 27, and 30 stamens is
the outcome of the one, whilst the occurrence of numbers which are not
a multiple of three is probably often the outcome of the other. Besides the
examples, figured stamens have been found which were branched from the

extreme base and consequently only a stage
removed from two separate structures.

Eranthis hyemalis is by no means alone
amongst the Helleboreae in exhibiting a trimer-
ous tendency, for, apart from the examples
given later, Church (loc. cit.) states that the
gynaeceum of Helleborus foetidus usually con-
sists of three carpels, whilst the stamens vary
in number from 30 to 54, with 45 as the normal
condition. Both extremes and mean, be it
noted, multiples of three.

(4) The gynaeceum. The carpels in the
specimens examined varied from 3 to io, though
Church (loc. cit.) gives the range as from 3 to
11, and here again importance is probably to

FlG* 8- Fused carpel and be attached to the fact that the minimum
stamen of Eranthis hyemalis (a)

and branched carpel of Helleborus number is three. Although six carpels very
niger (b). frequently occur, rather more individuals were

found to possess five carpels, though Church
(loc. cit.) gives six as the prevailing number. The gynaeceum would thus
appear to be more specialized in the direction of reduction than the androe-
cium, a condition that is by no means uncommon in the group. Where six
carpels are present, they occur in two whorls of three members each, but
where the number is five they appear to be grouped in a single whorl. No
case of branching or fusion of carpels has been observed here, but in the
closely allied genus Helleborus joined carpels do occur (cf. Fig. 8, B, showing
two of the carpels in H. niger joined together), which suggests the possibility
that departures from the strictly trimerous condition may be the result of
congenital fusion of carpel-rudiments. The number of ovules in each carpel
ranges from six to ten, but is most commonly eight or seven (cf. Table IV)-

Ficaria verna, and other Members of the Ranunculaceae. 57
(c) Numerical relations }

A study of the numerical relations between the different floral regions
in the same flower set forth in Tables I-IV establishes the proposition
that all the parts of the flower tend to vary at the same time and in the same
direction . Thus we find that the larger number of nectaries are associated
with more numerous perianth segments, and out of a total of forty-eight
flowers with more than six perianth members only five had less than the
normal number of nectaries, whilst twenty-nine showed an increase. Such
evidence, then, gives no support to the assumption that supernumerary
perianth segments represent modified nectaries.

Still more striking is the numerical relation between carpels and
stamens, or nectaries and stamens. From Tables II and III it is evident
that when the number of stamens is in excess of the mean (viz. 30) the
carpels and nectaries usually also exhibit an increase in number over the
normal. The converse is, moreover, also true. A similar correlation is seen
between the number of carpels and the number of ovules (cf. Table IV),
though the number of cases examined (viz. 1 28) is too small to bring out
this relation clearly. Hence, whatever the cause of increase or decrease,
whether nutrition or some more subtle factor, it evidently tends to operate
in a similar way upon the production of all the organs of the flower. The
facile explanation sometimes resorted to, that increase of one type of organ
takes place at the expense of another, is not borne out by the facts. On
the contrary, it is clear that each type of structure is capable of exhibit-
ing independent numerical increase or decrease without metamorphosis.
Where metamorphosis does occur it is the exception rather than the rule.
It is in conformity with this that the total number of parts in the flower
as a whole exhibits a wide range of variation, viz. from thirty to
seventy-one.

It will also be seen from the data given that in general there is
a marked tendency for all the whorls of the flower to exhibit trimery at the
same time.

(d) Transition.

We have already noted the variability in form of the bracts, and that,
though usually deeply divided, they always exhibit three main lobes which
may be quite entire (cf. Fig. 9). Rarely, as noted by Irmisch (loc. cit.), an
additional bract may be present accompanying a normal perianth of six
coloured members — doubtless the result of bifurcation. In nearly all cases,
however, where there is an additional bract it is found to consist of three
entire lobes and to occupy the position of one of the outer perianth segments.
An instructive example is represented in the diagram (Fig. 6, b). In this

1 The author has been unable to obtain a copy of the paper by Mori (Firenze, 1910) on the
correlative variation in this species.

58 Salisbury. — Variation in Er ant his hy emails ,

instance one member of the outer whorl had become transformed into
a trilobed bract (Fig. 5, C) and the other two members of the whorl were
undivided but exhibited a yellow central region and a green margin
(Fig. 5, d). One or more members of the perianth may be trilobed and
only partially virescent (Fig. 5, a). More rarely the trilobed structures are
uniformly yellow (Fig. 5, B). Very rarely, too, one or more members of the
involucre of bracts may exhibit partial petaloidy (Fig. 5, H). Such variations
are too frequent to be regarded as mere abnormalities, for not only have
they been observed in every locality from which material was obtained by
the present writer, but they were recorded by Irmisch in i860 as of frequent
occurrence in the following passage: ‘Nicht selten wird ein Hiillblatt
mehr oder weniger vollstandig in ein gelbes Kelchblatt verwandelt, oder es
ist ein Kelchblatt zur Halfte grim, zur anderen Halfte gelb, oder einzelne
Kelchblatter erscheinen, ohne die gelbe Farbe aufzugeben, nach Art der

Hiillblatter mit tiefen Einschnitten,
lauter Beweise fur die innige Be-
ziehung dieser Blattkreise zu ein-
ander’ (1880, p. 225).

There have thus been observed
almost every possible transition
between the involucral bracts and
the perianth members. Moreover
the latter may be replaced by the
former. That such phenomena
repeatedly exhibited by healthy
plants have some significance can
scarcely be denied, and one can
therefore only conclude that either
the perianth members are petaloid bracts and that both had their origin in
foliar structures, or that the bracts are derivatives of the perianth members
and that both had their origin from sporophylls.

That the former view is the correct one is indicated on general grounds
that will be considered later, but in this particular species we may note that
the replacement of perianth members by bracts is not infrequent, whilst
petaloid bracts are rare, and, as is well known, atavistic variations are usually
much commoner than those of a progressive character.

Moreover, the vascular supply of the perianth member corresponds
closely with that of the bract, whilst even petaloid nectaries when well
developed do not show the same vascular organization. It is, however, true
that the supernumerary petals do help to bridge this gap.

The most important argument is undoubtedly that in no case have we
found a perianth member replaced by a nectary or showing any signs of
transition to one. Thus if we were to accept the other alternative we

Ficaria verna, and other Members of the Ramtnctilaceae. 59

should have the unique condition of a whorl which exhibited variations
exclusively in the direction of progression.

In a few flowers nectaries have been observed one side of which bore
an anther containing apparently fertile pollen (Fig. 2, G and H, a). These
and the rare instances of two nectaries on the same staminal orthostichy
show that here, as is probably the case for all the Helleboreae, the nectaries
are staminodal structures. That is to say, the honey- leaves bearing anthers
are to be regarded as reversions.

Not infrequently nectaries showing an enlarged petaloid anterior lobe
are encountered (Fig. 2, F), thus emphasizing the potentialities of the
androecium in this direction. Such petaloid nectaries are always situated
on the staminal orthostichies and in this respect differ from the super-
numerary perianth segments. Moreover they usually exhibit only one
vascular bundle at the base and, in all the cases seen, show some indication
of a nectary. An interesting example is illustrated in Fig. 3, E, where the
resemblance to the staminodal petal of Ranunculus is striking. But this
condition, whilst indicating how the adaxial scale of that genus may have
arisen, is too rare to be regarded as an indication of any tendency here.

Table I.

Er an this hy emails.

Number of
Nectaries ,

Number of Perianth Segments.

Totals .

5

6

7

8

9

4 Number of specimens

—

1

__

—

—

1

100 %

5

55 55

1

9

4

1

—

15

6*6%

59*9 %

26.6%

6.6%

6

55 55

—

163

12

2

—

177

92 %

6.7%

i-i %

7

55 55

1

50

6

7

1

65

8

i-5%

76-5 %

9-2 %

lc*7 %

i-5 %

55 55

1

16

5

2

—

24

4-r %

66-6 %

20.8 %

8-3 %

9

5 5 5 5

—

4

3

2

—

9

44-4 %

33-3 %

22.2 %

10

55 5 5

—

4

1

1

—

6

1 1

66-6 %

16.6 %

2

16.6%

12

5 5 5?

100 %

5 ? : >

100 %

Totals

3

248

33

15

!

3°°

1 %

82.6 %

11 %

5%

o-3%

60 Salisbury. — Variation in Eranthis hyemalis ,

Table II.

Eranthis hyenialis.

Number of
Stamens.

Number of Nectaries.

Totals ,

18

Number of specimens

4

5

1

6

2

7

8

9

10

1 1

12

3

»9

53

33

—

—

3

1

—

—

—

—

—

4

20

33

3?

—

—

2

—

— • ■

—

—

—

—

2

21

33

33

fpl|s|

—

3

1

—

—

—

—

—

4

22

5?

33

1

—

3

3

—

—

—

—

—

7

23

5?

33

—

1

5

3

—

—

■ —

—

—

9

24

33

?,

—

2

25

2

1

—

—

—

1

3i

25

„

• — -

2

9

1

1

—

—

—

—

13

26

33

33

—

1

13

1

1

—

—

—

—

16

27

„

„

—

2

18

5

1

—

—

—

—

26

28

33

33

—

2

10

5

—

—

—

—

—

17

29

33

33

—

—

13

7

1

—

—

—

—

21

30

33

33

—

2

27

9

1

3

—

—

—

42

31

33

„

—

1

9

3

—

—

1

—

—

H

32

33

33

—

—

11

3

2

—

1

—

—

17

33

33

33

—

—

9

3

3

—

—

— '

—

15

34

„

33

—

—

2

4

1

—

—

—

—

7

35

33

33

—

—

—

3

2

2

—

1

■ —

8

36

33

33

—

—

6

4

2

—

1

—

—

13

37

3 3

3 3

—

1

4

1

2

—

—

—

—

8

38

33

33

—

—

1

2

2

—

—

— "

—

5

39

33

33

—

ISplaa

1

2

1

—

—

—

—

4

40

33

—

—

—

1

—

—

1

—

—

2

41

33

—

—

1

1

1

3

—

—

—

6

42

33

„

—

—

—

—

1

—

1

1

—

3

43

33

33

—

—

—

—

—

—

1

—

—

1

44

33

33

—

—

—

—

1

1

—

—

—

2

Totals

•

1

*5

!77

65

24

9

6

2

1

300

Table III.

Eranthis hyemalis.

Number of
Stamens.

Number of Carpels.

Totals.

18

Number of specimens

3

3

4

5

1

6

7

8

9

10

3

19

33

yy

1

2

—

1

—

—

—

—

4

20

5?

yy

—

i

1

—

—

—

—

—

2

21

y y

—

2

2

—

—

—

—

A Hlflf

4

22

33

yy

—

6

1

—

—

—

—

—

7

23

yy .

yy

—

3

4

2

—

—

—

—

9

24

yy

yy

2

12

11

5

—

—

1

—

3i

25

yy

,,

1

3

8

1

—

—

—

—

13

26

y 3

yy

—

4

8

4

—

—

—

—

16

27

yy

yy

—

5

15

5

1

—

—

—

26

28

yy

yy

—

2

8

7

—

—

—

—

17

29

yy

„

—

1

1 1

8

1

—

—

—

21

30

y y

yy

—

2

13

24

3

—

—

—

42

3i

yy

yy

—

—

3

11

—

—

—

—

' 14

32

yy

—

—

6

6

4

—

1

—

17

33

yy

yy

—

—

5

6

3

1

—

—

15

34

yy

yy

—

—

—

4

3

—

—

—

7

35

yy

yy

■ —

—

2

3

2

1

—

—

8

36

yy

yy

—

— .

—

4

8

—

1

—

13

37

yy

y y

—

—

1

3

2

2

—

—

8

38

yy

yy

—

—

. —

—

3

—

2

—

5

39

yy

yy

—

—

—

—

2

—

1

1

4

40

y)

yy

—

—

—

—

2

—

—

—

2

4T

y y

yy

—

—

—

—

4

2

—

—

6

42

yy

yy

—

—

—

1

1

1

—

—

3

43

yy

yy

—

—

—

—

—

—

1

—

1

44

yy

yy

—

—

—

—

—

—

—

2

2

Totals

6

43

100

95

39

7

7

3

3°°

Ficaria verna , and other Members of the Ranunctilaceae. 61

Table IV.

Eranthis hy emails.

Number of

Carpels in Number of Ovules.

Flower.

6

7

8

9

10

4

Number of specimens

—

8

4

—

—

66.6%

33*3 %

5

5

8

6

—

1

25%

40 %

3o %

5%

6

5

1 1

18

5

3

11 *9 %

26.1 %

42.8 %

n-9%

7-2%

7

>> >>

—

6

11

2

1

30 %

55 %

5%

8

))

2

4

4

6

—

p

12.5%

25 %

25 %

36.5 %

9

1

6

8

2

1

5*5 %

33-3 %

44-4 %

11 %

5-5 %

Totals

r3

43

51

15

6

128

II. Ficaria verna, L.

The flower of this species (cf. Clos, 1852 ; Baillon, 1863, p. 4 ; Payer,
1857, p. 254) usually consists of a calyx of three members, exhibiting
a one-third spiral, followed by eight or seven coloured perianth segments
bearing nectaries. The androecium is most commonly composed of from
eighteen to twenty-five stamens which show an obvious tendency to dehisce
in whorls of three, though the successive whorls exhibit lateral displace-
ment (cf. Fig. 10, G-H). The gynaeceum generally consists of from nine to
twenty-four carpels, the lower numbers being often clearly arranged in
trimerous whorls.

(a) M eristic variation.

(1) The calyx . The number of sepals ranges from three to seven, more
than 400 of the 514 examples examined possessing the former number.
The arrangement of the extra sepals as shown in Fig. 10, a-h, negatives
any suggestion that these are transformed petals. It is true that the sepals
are sometimes coloured, but in no instance do such bear any indication of
a nectary, which is always present on virescent petals. On the other hand,
the position of the supernumerary sepals (Ki'-K^') does harmonize with
the view that they represent fission products of one or more of the three
members normally present (K1-K3). We thus have exhibited in the calyx
a phenomenon commonly met with in other members of the group and also
in the other whorls of this flower. Celakovsky’s dogmatic statement that
these extra sepals here, and in Anemone hepatica , are modified members of
the coloured perianth within cannot therefore be upheld. Having regard
to the correlation generally exhibited between the number of parts in the
different whorls, it might be regarded as strong evidence against the view

62

Salisbury. — Variation in E rant his hyemalis ,

here expressed that high calyx numbers are frequently associated with alow,
perianth number. But the examples given (cf. Fig. 10, G and H) show that the
absent petal in each case is a member of the inner whorl and not of the outer.

Hence one cannot be dealing with

an

underlying cause is doubtless nutrition.

instance of transformation. The
The sepals being large in number
and the first parts of the flower
to develop, have entailed a drain
upon the nutrition which is met
by an absence of fission in the
corolla, or even, as in these cases,
a suppression of one member.

(2) The corolla. The num-
ber of petals ranges from four
to eleven, although eight is much
the most* frequent. A study of
the diagrams (Fig. 10) of several
of the more conspicuous variants,
as also of quite normal flowers,
shows that the multifarious types
presented are all explicable on
the assumption that the corolla
is typically trimerous, but that
two members of the inner whorl,
and sometimes all three, exhibit
fission into two separate seg-
ments. The numbering of the
petals in the diagrams is based
on this assumption. More rarely
the outer corolla whorl also ex-
hibits fission (cf. Pi, P2, Fig. 10, e).
Eichler regarded these supernu-
merary members in both Ficaria
verna. and Anemone hepatica as
independent additional members,
but in the latter species admits the
occurrence of more or less fused
members (Eichler, 1875, Bd. I,
p. 158). Such cases of partial
fission (cf. Fig. ii,g) have been observed by the writer in several specimens,
and their position fully warrants the assumption that they represent two
members which in the more common condition are distinct. Very rarely
additional nectary-bearing petals are present which must, from their
position with regard to the staminal orthostichies and the other perianth

Fig. 10. Ficaria verna. Empirical diagrams
showing arrangement of the perianth segments and
stamens. The numbers indicate the order of de-
hiscence. ki'-kT indicate fission products of the
calyx-segments normally present (KI-K3).

Ficaria verna , and other Members of the Ranunculaceae. 63

members, be interpreted as transformed stamens. It is important to recog-
nize this fact that even here, where the corolla segments have obviously
originated from stamens (as have the honey-leaves in other Ranunculaceae),
increase in number is far more frequently an outcome of the fission of the
rudiments already present than of further transformation of stamens.
Hence we find a correlated increase in the androecium and corolla. In the
example instanced, however, in which the position of the supernumerary
petals indicated transformation, the correlated increase of the androecium
was much less pronounced than the normal.

(3) The androecium . The variation ‘ curve ’ for this region of the flower
exhibits the same salient features as in E rant his hyemalis. Out of a total

Fig. 11. A and b, branched stamens of Ficaria verna ; c, petaloid stamen; D, partially
coloured sepal; E, sepal with lobed lamina; F, Anemone nemo7'osa, branched stamen; g, bilobed
petal of Ficaria verna ; h-j, variation in the sepals of F. verna.

of over 500 flowers completely dissected the minimum number of stamens
exhibited by any flower was a multiple of three. This minimal condition
should, if the variation ‘ curve ’ were of the normal type, be only presented by
a very small percentage of individuals. In actual fact there were no less
than fifteen examples, a number so high as not merely to emphasize the
reality of this secondary maximum, but also the abrupt character of the
lower limit.

It is also very significant that the three highest numbers observed were
also multiples of the three and occur as isolated points on the variation
‘ curve ’, since the largest number, foot a multiple of three, was forty-nine (cf.
Fig. 12).

Most frequently the androecium consists of either twenty-one or
twenty-four stamens, but secondary maxima also occur at most other

64 Salisbury. — Variation in Er an this hyemalis ,

multiples of three, the only notable exception being the number twenty-
seven, of which there were only eleven examples ; but this is doubtless corre-
lated with the large number of flowers exhibiting twenty-eight stamens
(viz. twenty-one), many of which are probably the outcome of complete
fission of one of the staminal rudiments. Hence we get an increase of the
higher category at the expense of the lower.

We thus have again a ‘ curve ’ which may be regarded as consisting of
a number of secondary variation * curves each having some multiple of three
as its mode. Departure from the mode is to be interpreted as an outcome

Fig, 12. Ficaria verna , variation ‘curve’ for androecium.

of fission or of fusion. Here, as in E rant his , branched stamens are not in-
frequent, and examples are figured in which two or even three anthers occur
on the same filament (Fig. n, A and B). Rarely small abortive stamens
have been observed, so that complete suppression may sometimes have
taken place.

(4) The gynaeceum . Here again, although the feature is less marked
(cf. Fig. 13), the maxima on the variation ‘curve’ are chiefly situated at
multiples of three, the most frequent number being 1 5. The general trend
exhibits the same markedly asymmetrical form so frequently characterizing
that of the perianth.

(b) Correlation.

Tables V and VI bring out the fact that there is a marked correlation
between the different whorls as regards either increase or decrease, so that
we cannot attribute an augmented corolla to staminal transformation,

Ficaria verna , and other Members of the Ranunculaceae . 65

except in special cases, as that instanced above. In illustration we find that
of the seven examples with eleven petals only one has twenty-four stamens,
whilst the remaining six have from thirty-eight to sixty-three. Table V
shows that twenty per cent, of the flowers have stamens and carpels which
at the same time number some multiple of three.

(c) Transition .

Partially transformed stamens have been sometimes encountered, and
one instance is here figured (Fig. 11, c). These emphasize the staminodal
character of the petals.

By far the commonest substantive variation is that found in the calyx,

Fig. 13. Ficaria verna , variation ‘ curve’ for gynaeceum.

where one or more members become more or less leafy (Fig. 11, H-j) and
develop a blade that is often lobed (Fig. 1 1, E). There seems little doubt,
from a study of all the transition stages, that the sepals really represent the
basal region of modified bracts. It is also significant that where complete
reversion takes place it is to the lobed, probably primitive, type of leaf, and
not to the specialized simpler form of the foliage proper. Examples such
as these afford the strongest evidence that the sepals had their immediate
origin from foliar structures and not from sporophylls, as on the latter
assumption the lobed form is inexplicable.

A partially coloured sepal is shown in Fig. 11, D, but, as has already
been pointed out, such cases can invariably be distinguished from true
petals. The fact that the sepals can become coloured is well exemplified in
many Ranunculaceae, and merely illustrates the possibility of an attractive
whorl being developed from either source of origin.

F

TABLE V. Ficaria verna . 507 flowers.

Number of Carpels in Gynaeceum .

66

On

Cl

OO

Cl

X>.

Cl

vo

Cl

\C.

Cl

C!

cO

O

Cl

ON

00

VO

»o

^ M

Salisbury . — Variation in E rant his hy emalis ,

| ro ro o

1 1 | «5 I I co ci

Cl Cl N VO I M I Cl Cl

t I 00 N N I Cl

r I Cl t^VO VC CO Cl
COM CO Tf- Cl VO Cl M CO Cl

mcOcoI O W On« h I I

M CO Cl >0 CO M d m vo
2s M M I I K5+N H Tt-vO. I
2 M I. I 00 ^ Tt-VC CO Tf- M M M |

^ t> ci vo m cl I m vo co m m ci |

®MM|Jt^.J>ilN'5'^-C^|M| I I
CN t'tn N H | I | | |m|

00 l I I -I M M I I I I | | I

M Cl
Cl I
M Cl

I I

M d

CO ci
I 1
<M L
I I
I I
I -cf

I I

Cl w

I, I

I

i''.

CO

VC

CO

CO

ON

'■cf'

O

CO

CO

CO

o

Cl

00

vr.VO i^CO O' O M Cl CO vfl VC J^oo ON o M Cl CO Tt- VO VC t-^00 ON O M d CO rf- 10VC X'^OO ON O m tJ- O cO

M M M 1-1 r-i Cl Cl Cl Cl Cl Cl Cl Cl Cl d CC CC M CO CO to to W3 ro cf! Tf ■+ t(- Tf- ^ Tf ^j- 1}- If, Ifi VfjVO VO

'lumodOApuy in suptuv^ fo .izqiunjsp

ON

VO

CO

(One 52)
(One 55)

Ficaria verna , and other Members of the Ranunculaceae . 67

Table VI. Variation of Corolla and Androecium in
Ficaria verna. 514 flowers.

Number of
Stamens .

Number of Corolla Segments.

Totals.

15 Number of specimens

4

5

6

2

7

5

8

8

9

10

11

12

15

16

77

77

—

— *

3

1

5

—

—

—

—

9

17

— -

2

4

6

—

— •

—

— «•

12

18

7 7

77

—

1

9

2

18

— *

—

—

—

30

T9

V

3>

— *

4

16

J4

—

—

—

—

34

20

77

77

—

1

3

8

H

—

—

—

26

21

77

77

1

1

H

17

23

—

—

—

—

56

22

79

77

—

3

2

9

19

5

—

—

38

23

77

„

— •

1

7

1 1

17

■ —

1

—

37

24

77

77

i

—

4

16

24

3

—

1

—

49

25

77

„

—

—

6

4'

16

1

— -

—

27

26

77

77

—

— -

—

4

7

1

—

1 2

27

77

77

— .

—

1

—

9

1

—

—

—

U

28

77

77

— ■

• 2

5

14

—

—

—

—

21

29

77

77

—

—

— a-

—

2

• —

— .

—

—

2

30

77

77

—

—

2

8

3

—

-*■

—

I3

3i

77

77

—

—

—

-«■

*7

4

3

—

—

10

32

77

77

— -

7

—

—

— =

—

7

33

77

77

—

—

—

10

1

—

— •

—7

1 1

34

77

77

—

■

—

10

2

—

—

— *

1 2

35

77

—

—

—

—

2

1

—

—

—

3

36

7%

,,

—

—

7

2

1

— *

—

10

37

77

77

—

—

—

1

2

3

—

—

6

38

77

77

—

—

—

—

2

4

I

1

—

8

39

77

79

—

—

—

6

2

2

3

L3

40

77

7 7

—

— ■

—

—

4

1

2

7

41

>7

77

—

—

—

2

3

2

•

7

42

77

77

—

— ~ '

—

— *

3

3

—

0

43

77

77

—

—

—

4

1

1

—

—

6

44

77

77

—

— "

—

—

— -

2

—

1

—

3

45

77

77

—

—

—

—

2

—

—

—

2

46

77

77

—

—

—

— 7-

2

— =•

— -

—

—

2

47

77

9 7

—

—

—

I

1

—

1

—

—

3

48

,,

77

— ■

—

—

: — i

—

2

—

—

2 •

49

7. 7

„

—

—

— r

—

— •

•—

—

—

50

7 7

»

54

77

77

—

—

“

—

1

—

1

60

77

77

-TT

—

—

—

—

. —

I

■ — ■’

—

t

63

9 7

X7

—

—

—

—

—

1

1

—

2

Totals

•

2

9

6.1

107

265

45

l8

7

O

514

Ill, Anemone nemorosa, L.

Of this species only 154 flowers were dissected, which in view of the
large number of parts involved is too few to give good variation ‘ curves \
These, however, show clearly the tendency for maxima to occur at multiples
of three (cf. Figs. 14 and 15), a feature that, owing to the small number of
examples, is somewhat obscured by the overlap of the variations around the
trimerous maxima. As is well known, the perianth here frequently consists
of two whorls of three members each ; when, however, a greater number are
present the orientation of the supernumerary segments warrants the assump *
tion that here again increase is the outcome of fission (Fig. 16, a). Where,
however, the number is fewer (e.g. five) the insertion suggests fusion of one

68

Salisbury. — Variation in Eranthis hy emails,

member of the outer whorl with one of the inner, in consequence of which
a quincuncial arrangement results. The involucre in one case has been
observed to exhibit increase, four bracts being present in place of the usual
three, so that here too we have fission exemplified.

16-
11-
I*-
11-
. Ji-
ll ;
la -

V

5 -
7 '

6 -
' 4* -

4 -
3 -
1 -

'f

s

As shown in Fig. 1 1, F, branched stamens occur, so that it would appear
as if increase in the number of parts may take place in any whorl of the
flower as a result of fission of rudiments already present. It will be noticed
(Table VII) that, if we ignore the branching, four out of the six examples
have androecia which are multiples of three.

Here too there is obvious correlation, for we find the coefficient
between stamens and carpels is 0-66, whilst the probable error is 0*03.

Ficaria verna, and other Members of the Ranuneulaceae . 69

Between perianth segments and stamens the correlation coefficient is c-x 6
and the probable error 0-055. Complete or partial abortion of the male
or female organs, accompanied by increase of those of the other sex, may
occur in this and other species (cf. Elmore, 1915).

Table VII.

A nemone nemorosa.

Number of

Number of

Number of

Stamens .

Branched Stamens.

Anthers.

54

1

55

5t

1

55

54

1

55

42

2

44

59

1

60

59

2

61

Transitions are rare, but the sepals sometimes
develop laminae, in which case the apical region is
lobed and green, suggesting that here, as in Ficaria ,
the sepal merely represents the basal region of the
bract or foliage leaf of which it is the derivative
(cf. Baillon, 1863, p. 2, and Salisbury, 1916, p. 526,
Fig. 1).

In eleven flowers, or about 6-5 per cent, of
the total, all the floral whorls consisted of some
multiple of three, the details of which are given
below (Table VIII).

Table VIII.

Anemone nemorosa .

Perianth

Segments.

Stamens .

Carpels.

Number of
Specimens.

6

42

15

1

6

42

18

1

6

45

15

1

6

54

15

2

6

54

1 8

1

6

54

21

1

6

60

2 7

* 1

6

63

27

2

6

93

33

1

As there were fifty-eight flowers with stamens
numbering some multiple of three, the calculated
probability is that about nineteen of these should
possess carpels numbering some multiple of three ;
in actual fact there were no less than twenty-five
such cases.

Fig. 16. a, diagram
of perianth of A. nemorosa ;
B, floral diagram of Aconi~
turn napellus ; c, branched
stamen of Aquilegia sp. ;
D and E, branched stamens
of Delphinium sp. ; F, dia-
gram of perianth of Ranun-
culus bulbosus.

70

Salisbury. — Variation in Eranthis hy emails.

IV. Aconitum napellus, L., and A. Lycoctonum, L.

(a) Aconitum napellus. The fact that the gynaeceum of this species
normally exhibits three carpels suggested that even here, despite the obvious
specialization of the flower, the trimerous tendency might extend to the
androecium.

Eighty specimens of this flower were dissected and in every case the
outer perianth was composed of five members. The inner whorl, inclusive
of the two nectaries, consisted of eight, or more rarely seven, six, or three
members. Seventy-three flowers possessed a gynaeceum of three carpels,
whilst the remaining seven had two perfect carpels. In two of these lattei
the third carpel was represented by a dwarfed rudiment devoid of ovules.
Clearly, then, we can attribute the bicarpellary condition to the abortion of

Fig. 17. Aconitum napellus , variation ‘curve’
for androecium.

J\ conltum Lycoctonum

Fig. 18. Variation ‘curve’ for the an-
droecium of Aconitum Lycoctonum.

one member, and we may note that all conditions from three to one carpel
are normally encountered in the genus Delphinium. A study of the order
of dehiscence of the stamens shows that the first to mature constitute
a trimerous whorl (cf. Fig. 16, B, I, I, 1), of which one member is situated
opposite the hood and the two others opposite the gaps between the lateral
and ventral sepals.

The variation ‘ curve’ for the total number of stamens (Fig. 17) shows
a range from thirty-nine to fifty-two, with prominent maxima at forty-two,
forty-five, and fifty-one and an indication of a maximum at forty-eight.
Here too, then, the minimum number is a multiple of three and the primary
and secondary maxima indicate quite clearly variations around primary and
secondary modes corresponding to multiples of that number. As in other
Ranunculaceous flowers the actual phyllotaxis of the androecium is doubtless

Ficaria verna , and other Members of the Ranunculaceae . 7 1

but an expression of the various mechanical forces in the developing bud,
and can give us no clue to the primitive construction of the flower ; but the
order of dehiscence and the arbitrary recurrence of certain numbers cannot
be explained on purely mechanical grounds and must be construed as of
phylogenetic import.

(b) Aconitum Lycoctonum. The androecium of this species was exam-
ined in forty unopened flower-buds obtained from wild plants in Switzerland
by Prof. F. E. PTitsch. From the variation ‘curve’ given in Fig. 18 it will
be seen that the range is narrow and that in the majority of cases the number
of stamens was thirty. The lower limit observed was twenty-nine, but
Eichler (1875, p. 164, Fig. 67) figures a specimen with only twenty- seven
stamens. The large proportion of examples with thirty-three stamens is
strongly suggestive of a second maximum. In all the flowers examined the
gynaeceum consists of three carpels, so that the trimerous tendency is here
even more marked than in its congener, a fact that may not be without
significance in view of the greater specialization of A. napellus.

V. Aquilegia vulgaris, L.

We have assumed that where a frequency • curve ’ shows maxima at
multiples of three the explanation lies in an innate trimerous tendency, as
a consequence of which the variation ‘ curve’ is to be regarded as composed
of a series of subsidiary variation ‘curves’ around the different multiples of
three, each, however, of diminished prominence in proportion as it departs
from the primary mode.

It is well known that the flower of Aquilegia is whorled throughout and
is typically pentamerous in structure, and it was thought that the variation
in the number of the carpels might afford corroboration of the above assump-
tion by the presence of maxima at multiples of five. For this purpose
300 flowers were examined, and it was found that two maxima were present,
namely, at five and ten (cf. Table IX). Even here, however, the lower limit
was three carpels.

Table IX.

Aquilegia vulgaris .

Number of Carpels. Number of Specimens.

3

3

4

3

5

202

6

30

7

22

8

13

9

6

10

20

11

0

12

0

13

1

As in the essentially trimerous flowers we have been considering the
stamens are often not a multiple of three, so too here the number of stamens

7 2 Salisbury .— Variation in Eranthis hyemalis ,

is often not a multiple of five. Moreover, the same explanation can be
advanced since partially branched stamens (cf. Fig. 16, c) are sometimes
encountered and indicate the tendency towards fission of primordia.

VI. Various other Ranunculaceae.

(a) Delphinium sp. Fifty flowers of a species of Delphinium belonging
to the section Staphisagria with three, or rarely two, carpels were dissected,
and in two examples branched stamens were observed. In the one case
three anthers were present on the same filament and in the second instance
two (cf. Fig. 1 6, D and e).

The number of stamens was most frequently thirty-two, this being the
case in thirteen specimens. Seven flowers had thirty stamens and eight

had thirty-three. If one may judge
by this small number, the mode is
here not a multiple of three, but it is
significant that the minimum number
of stamens was twenty-seven and the
number of carpels almost invariably
three.

In one specimen six inner peri-
anth segments were present, in
place of the normal four, but since
the androecium consisted of thirty-
three stamens the increase cannot be
attributed to transformation. The
facts, then, seem to warrant the as-
sumption that, here too, fission of
both perianth and ^staminal rudi-
ments takes place as in other members of this family.

(b) Ranunculus bulbosus. Out of several hundred flowers of this species
forty-one exhibited supernumerary members in one or other whorl of the
perianth. The details of these specimens are given in Table X. It will be
noted that in only one instance was the increased number of petals asso-
ciated with a diminished number of sepals, and, further, that an increase in
the number of sepals was, in every case, accompanied by an increase in the
number of petals. The additional sepals may therefore be regarded as the
result of fission of the original sepal rudiments. The same explanation can
be applied to the corolla, for we find that large numbers of petals are almost
invariably associated with an increased number of stamens, as indicated by
the following floral formulae of some conspicuous examples :

K 5, C 6, A 6i, G 36
K 5, C8, A 54, G 37
K 6, C7, A 71, G 37
K 6., C 5, A 60, G 41

Fig. 19. Variation ‘curve’ for the gynaeceum
of A quilegia sp.

Ficaria verna , and other Members of the Ranunculaceae. 73

In addition the orientation of the supernumerary petals is quite con-
sistent with their origin by fission (cf. Fig. 16, F, P4 and P5).

Number of Sepals.

4

5

6

7

8

9

10

Total number of specimens

Table X.

Ranunculus bidbosus.

Number of Petals.

5 6 7 8 9 10

10 7 3 4

621 —

1 — 1 —

11

1

=

A very significant feature, which emphasizes not only the distinction
between calyx and corolla but also the essentially foliar character of the
former, is the fact that in three out of the fourteen flowers with extra
sepals, the number of peduncular ridges cor-
responded to the number of calyx segments.

But in no case were additional ridges present
when the sepals numbered five whatever the
increase might be in the number of corolla
segments. Coloured sepals are occasionally
met with (cf. Leavitt, 1909).

(c) Ranunculus acris . Seventy flowers
of this species were dissected and showed
a wide range of variability as regards the
number of parts present. The minimum
observed was seventy-nine and the maximum
275. The sepals varied in number from five
to twelve, the petals from five to thirteen,
the stamens from forty-four to 167, and the
from fourteen to eighty-three. Such
extraordinary fluctuation would necessitate
the examination of a far larger number of
specimens before any conclusions could be drawn regarding the existence
of any trimerous or pentamerous tendency. But the data are sufficient
to show that each region tends to vary meristically in the same sense. In
the extreme example referred to above the floral formula was K 12, C 13,
A 167, G 83. In no instance was an increase in the number of sepals accom-
panied by a decrease in the number of petals. Evidence for the origin of
supernumerary petals by fission is afforded by the occurrence of cleft or
trilobed corolla segments. Petaloid stamens were observed in a few

Fig. 20. Stamens of Ranunculus
auricomus ,var. depauperata , developed
in place of the petals.

74 Salisbury . — Variation in Eranthis ky emalis ,

specimens, and coloured sepals, though rare, were also noted. The latter
however, never show any indication of a nectary and can be readily
distinguished from virescent petals. In one example a sepal was present
which bore at the apex a small trilobed lamina.

(d) Ranunculus auricomus. This species is interesting as it affords
frequent examples of reversion of petals to stamens. This condition is
normally found in the so-called var. depauperata. In this form the position
of the petals is in some specimens occupied by normal stamens, but in others
by stamens which are much larger than usual or even subpetaloid in character
(see Fig. 20, A-C). The instructive feature, however, is the fact that, accom-
panying the reversion of the corolla segments, the sepals usually become
coloured yellow, whilst in the perfect-flowered form the sepals are quite
green.

VII. The Origin of the Perianth.

There can be little doubt that the solitary inflorescence of Anemone has
been derived by reduction from a, many-flowered inflorescence. Thus, in
Anemone narcissiflora two to six flowers arise together in an umbel from
the involucre of bracts. In A. ranunculoides the number of flowers varies
from three to one. In A. palmata the flower is normally solitary, but two
flowers quite frequently occur, whilst in A. nemorosa the single-flowered
condition has become fixed. In all these cases the flowers arise from an
involucre of three or rarely four leaves which is obviously homologous in the
different species. Now whilst in the case of the single-flowered members we
might a priori imagine these bracts to represent descended perianth leaves
which had become foliaceous, as Worsdell maintains (1916), such a concep-
tion is hardly applicable where we find the involucre surrounding a group
of several flowers. On the other hand, the assumption that the involucre
consists of foliage leaves is in complete harmony with all the facts and
equally applicable to the many- or few-flowered inflorescence. Again, if we
study the numerous species of Anemone we find almost every transition
from involucral leaves in all respects resembling the foliage leaves (e. g.
A. nemorosa ), to those in which the involucral leaves are essentially calyx-
like and closely approximated to the flower (e. g. A. hepatica ). It is, more-
over, significant that in general where the involucre is situated close to
a flower its members depart farther from the foliaceous type than where it
is more remote.

Now this transition can of course be viewed from either direction, but
if the bracts forming the involucre are only modified stamens it is scarcely
conceivable that their ultimate development should present all the indica-
tions of homology with, rather than analogy to, the foliage leaves. If such
a striking parallel evolution had actually taken place, it could only indicate
an identity of function. Yet if we examine species of Anemone with
a simple type of leaf but in which the involucre is not in close proximity to

Ficaria verna , arid other Members of the Ranunculaceae. 75

the flower (e.g. A. palmata ), we find that the involucral leaves partake of
the dissected, probably ancestral, foliar type and do not resemble the simple
foliage of the species — a fact that cannot be explained on any other
hypothesis than the common origin, and therefore phylogeny, of both bracts
and foliage.

In Ranunculus acris Goebel (1905, p. 393) was struck by the unusual
condition that the hypsophylls were more divided than the foliage leaves,
and we have already noted the same feature exhibited by Ficaria verna.

Again, on the foliar theory we should naturally expect to find the
involucre of upwardly displaced leaves more closely approximated to the
flower the more specialized the floral structure. In the genus Nigella the
different species show various degrees of fusion between the carpels ; in
N. arvensis the carpels are only slightly joined, whilst in N. damascena the
fusion is complete. In the former the involucre is remote from the flower,
in the latter closely approximated to it.

If we accept the view that this involucre is directly derived from
sporophylls then we have the anomaly of the least specialized involucre
associated with the most specialized gynaeceum and vice versa.

There can be little doubt that the involucres of Anemone , Eranthis ,
and Nigella are homologous structures, and there are no adequate grounds
for regardingthe involucre of A. hepatica as distinct in origin from the calyx
of Ranunculus ficaria.

Various writers have pointed out that the Ranunculaceae present us
with almost all stages in the development of petaloid stamens, from the
nectariferous staminodes of Anemoiie pulsatilla to the petal of Ranunculus .

If we hold that the perianth is entirely staminodal (cf. de Candolle,
1823 ; Drude, 1887 ; Celakovsky, 1896 and 1900 ; Worsdell, 1903) then we
must assume that two totally uncorrelated lines of evolution from the same
type of structure are presented to us. For in Ranunculus or any of the
Helleboreae we must assume that, first, the non-nectariferous perianth was
developed from the sporophylls and that subsequently from the same origin
a completely distinct type, the nectariferous petal, became elaborated.
Moreover, there is no relation between the specialization of the non-nectari-
ferous perianth and the development of the honey-leaves. In Anemone
pulsatilla we find a highly specialized coloured perianth, together with the
simplest type of nectar-secreting staminode, and in the Helleboreae the
more advanced type of flower of Helleborus has a less specialized honey-
leaf than Eranthis.

If we now turn to the mode of arrangement of the perianth segments
we find that in the Clematideae the calyx usually consists of four members
(arising as two pairs, cf. Payer, 1857, p. 252) corresponding to the four
orthostichies of the decussately arranged leaves of the adult plant. In the
other tribes, where the leaves are alternate and generally exhibit a one-third

76 Salisbury . — Variation in Eranthis hy emalis ,

or two-fifths phyllotaxis, the calyx commonly consists of from three to five
members. Such correspondence between the orthostichies of the vegetative
leaves and calyx-segments has no significance unless the latter be derived
from the former, since the staminal orthostichies are usually much more
numerous. The case of Clematis alpina might be regarded as an exception,
since here there are four staminodal petals alternating with the four sepals.
But the spacial relations here determine the position of the inner whorl just
as they determine that of the corolla in Ranunculus or of the stamens in
Rosaceae. Such an explanation cannot, however, be applied to the outer-
most whorl.

It is, therefore, obvious that to regard the perianth as an homologous
structure derived from the stamens involves us in several assumptions for
which there appears no warrant. On the other hand, these very difficulties
fall into place if we accept the view that the perianth is in some cases
(e. g. Anemone) entirely foliar in origin (cf. Prantl, 1887) and in others (e. g.
Ficaria) derived partly by modification of leaves (the calyx) and partly from
sporophylls (the corolla) (cf. Grant Allen, 1882).

Great stress has been laid by some writers on the existence in this
group of polymerous perianths (Worsdell, 1916, p. 129), the argument
being briefly that the supernumerary perianth segments could not have
arisen de novo and must therefore be regarded as transformed stamens.
That fission is a common phenomenon in the calyx of the Ranunculaceae, as
also in the other floral whorls, has been amply demonstrated in the foregoing
pages. As pointed out by de Vries (1893), the unilateral character of the
Galtonian half-curves, as exhibited in the perianth variation of Caltha
palustris or Ranunculus bulbosus , can be explained if we assume increase to
be due to dldoublement. The same feature is also encountered in allied
families; for example, Marchand (1863, p. 127) recorded the occurrence of
dedoublement in the androecium of Epimedium musschianum , extreme
examples exhibiting eight stamens in place of the usual four. The structure
of the normal flower of Podophyllum peltaium illustrates fission both in the
androecium and perianth.

Polymerous perianths can therefore be best explained as due to fission
(cf. also Rendle, 1903), and the fact that increase in their members is usually
accompanied by an increase rather than a decrease in the androecium
renders the transformation theory in the highest degree improbable.

It has been shown that there is a fairly widespread tendency for the
androecium and gynaeceum in this group to consist of parts which number
some multiple of three, and examination of the variation * curve , renders it
very probable that this feature is the result of a trimerous tendency (cf.
p. 64). It seems most likely, then, that an arrangement of parts on six or
three orthostichies was primitive for the group, but owing to increase in the
number of members through fission this arrangement has become obscured.

Fie aria verna, and other Members of the Ranunculaceae . 77

Such increase has resulted in mechanical pressure, which in turn has pro-
duced displacement, so that a high phyllotaxy has resulted. Perhaps, too,
shortening of the torus has contributed to this effect. As already pointed
out, this interpretation harmonizes with the fact that trimerous flowers are
frequent amongst the Ranales as a whole and particularly associated with
the less specialized and arboreal forms.

The view here put forward is, then, that the primitive Ranunculaceous
flower exhibited an androecium and gynaeceum of members either arranged
in alternating whorls of three members each or on six orthostichies and
probably borne on an elongated axis. The essential organs were surrounded
by a perianth of foliar origin also consisting of trimerous whorls. From this
condition both the pentamerous calyx of Ranunculus and tetramerous calyx
of Clematis have been derived, whilst the more primitive perianth of two
trimerous whorls is seen in Eranthis and Anemone spp. What was perhaps
the early Ranunculaceous type is seen in some species of Magnolia in which
the whole floral structure is composed of alternating trimerous whorls.

As a subsequent specialization the outermost stamens have in some
cases developed as an attractive whorl (e. g. Ranunculus , &c.), but in others
foliar perianth members are alone present and perform both functions of
protection and attraction (e. g. Anemone pulsatilla ).

The occurrence of trimery and androecial fission as a feature of the
Ranunculaceae is all the more interesting as both are found in the Alisma-
ceae, to which Monocotyledonous family the Ranunculaceae exhibit so
many resemblances*

VIII. Summary.

The variations, both meristic and substantive, in the flowers of Eranthis
hy emails , Ficaria verna , and other members of the Ranunculaceae, are
described and the following facts established :

(1) Meristic variation is exhibited in all the floral regions, involving a
corresponding variation in the total number of parts present.

(2) There is usually an obvious correlation between the variation in
the different parts of the flower, and, in general, increase or decrease is
exhibited simultaneously by the perianth, androecium, and gynaeceum.

(3) Branched: stamens are not infrequently present, and bifurcated
petals have been observed in several members of the group. Branched
carpels are recorded for Helleborus .

(4) The position of the supernumerary perianth segments is consistent
with their origin by fission.

(5) The two-whorled trimerous perianth of Eranthis , Anemone , &c., is
sometimes replaced by a pentamerous whorl exhibiting the quincuncial
arrangement, a change that can be attributed to fusion between one member
of the outer whorl with one of the inner.

78 Salisbury. — Variation in E rant his hy emails ,

(6) Increase in any one region is usually accompanied by increase in
the adjacent regions, so that transformation cannot be assumed.

(7) In several members of the Ranunculaceae belonging to different
tribes and genera the 4 carve ’ of meristic variation for the androecium and
gynaeceum exhibits several maxima which correspond to numbers that are
some imdtiple of three. The minimum number of parts present is often also
a multiple of the same number.

(8) Substantive variations of the nature of transitions are not infrequent
and emphasize the foliar nature of the calyx, as in Ficaria and Ranunculus ,
and of the entire perianth in Eranthis , Anemone, &c. Still others occur
which emphasize the staminodal character of the honey-leaves.

The facts adduced appear to warrant the following theoretical conclu-
sions :

(a) Meristic variation is mainly the outcome of two tendencies, viz.
fission and fusion.

(b) The supernumerary perianth members are usually the result of
fission, and only very rarely, in the case of staminodal corollas, do we find
any evidence of increase as a result of transformation.

(e) Decrease in number is usually the result of fusion (e. g. Anemone ,
Paeonia), more rarely of suppression (e. g. gynaeceum of Aconittim).

( d ) The perianth is either derived entirely from modified foliage
leaves (e.g. Anemone , Eranthis , &c.) or in part from bracts and in part
from stamens (e.g. Ranunculus , Clematis alpina , &c.).

(e) The flower, of the Ranunculaceae is probably derived from a trimer-
ous type, which has, however, in many cases become obscured by multipli-
cation of parts and consequent changes in phyllotaxy, or by fusion and
abortion.

Bibliography.

Allen, Grant (1882) : The Colours of Flowers.

Baillon, H. (1862) : Sur la fleur des Pivoines. Adansonia , vol. iii, pp. 45-9.

(1868) : Memoire sur la famille des Renonculacees. Ibid., vol. iv, pp. 1—57*

de Candolle, A. P. (1823) : Theorie elementaire de la botanique. Paris.

Celakovsky, L. (1896 and 1900) : Ueber den phylogenetischen Entwickelungsgang der BKithe und
liber den Ursprung der Blumenkrone. Sitzungsber. d. k. bohmischen Ges. d. Wiss.
Church, A. H. (1908) : Types of Floral Mechanism. Oxford.

Clos, D. (1852) : Etude organographique de la Ficaire. Ann. des Sci. Nat., Bot., 3e ser., vol. xvii,
pp. 129-42.

Drude, O. (1887) : Die systematische und geographische Anordnung der Phanerogamen. Schenk’s
Handbuch, vol. iii, pt. 2.

Eichler, A. W. (1875-8) : Bliithendiagramme. Leipzig.

FTmore, C. J. (1915) : Staminate Flowers in Anemone . Bot. Gaz.

Ficaria verna , and other Members of the Ranunculaceae . 79

Goebel, K. (1905) : Organography. Vol. ii, Eng. ed., Oxford.

Gwynne-Vaughan, D. T. (1897) : On some Points in the Morphology and Anatomy of the
Nymphaeaceae. Trans. Linn. Soc. 13ot., vol. v, pp. 287-99.

Irmisch, T. (1860) : Ueber einige Ranunculaceen. III. E rant his hyemalis. Bot. Zeit., pp. 221-6.
Leavitt, R. G. (1909) : Homoeosis in Plants. Bot. Gaz.,ep. 41, Fig. 7.

Marchand, L. (1863) : Sur les fleurs monstrueuses d ' Epimedium. Adansonia , vol. iv, p. 127.
Payer, J. B. (1857) : Traite d’Organogenie comparee de la fleur. Paris.

Prantl, K. (1887) : Beitrage zur Morphologie und Systematik der Ranunculaceae. Eng. Bot.
Jahrb., vol. ix.

Rendle, A. B. (1903) : The Origin of the Perianth in Seed Plants. New Phytologist, vol. ii,
pp. 66-72.

Salisbury, E. J. (1916) : Variations in Anemone nemorosa. Ann. of Botany, vol. xxx, pp. 525-8.

■ (1916 a) : The Emergence of the Aerial Organs in Woodland Plants. Journal of

Ecology, p. 125.

Smith, T. C. (1893) : Yorkshire Naturalist, p. 246.

l)E Vries, H. (1893) : Les Demi-courbes Galtoniennes. Arch. Neerlandaises, t. xxviii, pp. 442-57.

(1906) : Species and Varieties, their Origin by Mutation. 2nd Eng. ed., Chicago.

Worsdell, W. C. (1903): The Origin of the Perianth of Flowers. New Phytologist, vol. ii,
pp. 43-8.

(1906) : Principles of Teratology. Vol. ii, Ray Society.

Yule, G. U. (1902) : Variation in the Number of Sepals in Anemone nemorosa. Biometrika.

On an Australian Specimen of Clepsydropsis.

BY

B. SAHNI, M.A. (Cantab.), M.Sc. (Lond.).

With Plate IV and two Figures in the Text.

I. Introduction.

HE specimen forming the subject of this paper is from the private

X collection of Mr. A. B. Walkom, of the University of Brisbane. It
was collected near Mt. Tangorin, New South Wales (long. 1510 22' E., lat.
32°36' S.), and, although not discovered in situ , is, according to the owner,
probably of Carboniferous age. More definite information regarding the
horizon is unfortunately lacking.

A cursory examination of the sections showed that the fossil should be
referred to the Zygopterideae, and that on account of the shape of the petiolar
trace (as seen in transverse section) it would have to be placed near
Clepsydropsis antiqua , Unger. This fact had an additional interest at the
time, for I was then under the impression that this was the first specimen of
a Zygopterid to be recorded from Australia — in fact from any other part of
the world except Europe and one locality in Western Siberia. The work
was therefore carried on with increased interest : the greater part of it was
completed early in the year 1917, and a preliminary account was read before
the Cambridge Philosophical Society on February 19, 1917. Only a few days
before that date, however, I received from Professor W. H. Lang a letter
for which I am much indebted to him. In that letter he informed me that
Mrs. E. M. Osborn, of Adelaide, Australia, was also investigating a Zygo-
pterid from Australia, and referred me to her preliminary account of it in the
Annual Report of the last Manchester meeting of the British Association
(1915), 1 of which I was unfortunately not aware. Mrs. Osborn’s fossil also
comes from New South Wales, but from a locality ne§r Barraba, about T50
miles north-west of Mt. Tangorin, and was discovered in situ in rocks
probably of Upper Devonian age. From the short sketch just referred to
it was obvious that the two plants belonged to the same genus, but it was
impossible to say whether the Barraba fossil was specifically distinct from

1 pp- 727-8.

[Annals of Botany, Vol. XXXIII. No. CXXIX. January, 1919.]

82 Safari . — On an Australian Specimen of Clepsydropsis.

the Mt. Tangorin fossil. On the advice of Professor Seward a brief descrip-
tion of the Mt. Tangorin specimen, accompanied by a few rough figures,
was sent to Mrs. Osborn for comparison ; in her answer (received in
September 1917) she states that there is no doubt as to the specific
identity of the two, and proposes the name Ankyropteris australis (see,
however, pp. 83-4, below). Two valuable features about the Barraba fossil
are, firstly, that the stem is preserved, and, secondly, that the origin of the
leaf-trace is visible. The Mt. Tangorin specimen, on the other hand, which
does not include the stem, and is on the whole not well preserved, contains
portions of the petioles slightly more distal than those in the Barraba fossil,
and in the further branching of the petiolar trace to a very small extent
appears to supplement the structures preserved in the latter.

I am very grateful to Mrs. Osborn for the great kindness she has shown
me in comparing my description and in so willingly supplying me with un-
published details about her own fossil, which have been of much help and
interest. It is also my pleasant duty to express my heart-felt thanks to
Professor Seward, who was kind enough to entrust the work to me, and who
has been a constant source of help and encouragement. The work was
carried out during the tenure of a Research Studentship at Emmanuel
College, Cambridge, and latterly also of a Grant from the Dixon Fund
of the University of London.

II. Review of Previous Literature.

The name Clepsydropsis , which has reference to the cross-section of the
petiolar trace, was first used by Unger in 1854,1 but it was not until two
years later 2 that he published a diagnosis of the genus, placing it in Corda’s 3
family Rachiopterideae, and described (provisionally as three distinct
species, C. antiqua , robusta , composita) some fern-petioles from the Cyprid
Schists in the Upper Devonian (Lower Culm) of Saalfeld in Thuringia.
Unger’s originals have since been several times re-examined, and from
Solms-Laubach’s 4 work (1896), as well as from a more recent paper5 by
Dr. Paul Bertrand, it appears that the two last-named species were founded
upon deformed specimens of C . antiqua , Ung. In 1889 Stenzel 6 described
another species, Asterochlaena ( Clepsydropsis ) kirgisica , Stenz., from the
vicinity of Pawlodar, north of Semipalatinsk in Western Siberia, about the
horizon of which we have no certain data. The fossil was discovered as
a pebble in an alluvium overlying coal-bearing strata, and was considered to
be of Lower Permian (Rothliegende) age,7 but this is by no means free
from doubt.8 The original of Stenzel’s Fig. 38, PI. IV, collected by Aberg

1 Unger (1854), p. 599. 2 Unger (1856), p. 165.

3 Corda (1845). 4 Solms (1896), pp. 25-7.

5 Bertrand (1911 a), p. 4. 6 Stenzel (1889).

7 Stenzel (1889), p. 20.

8 Solms (1910), p. 542. See also Goeppert u. Stenzel (1881), p. 16.

Sahni . — On an Australian Specimen of Clepsydropsis. 83

and conveyed to Germany by Ludwig, was at Dresden, but Stenzel also
examined a slice in the possession of Goeppert.1

Hitherto two species, namely, C. antiqua , Ung., from the Upper
Devonian of Thuringia, and C. kirgisica, Stenz., doubtfully from the Lower
Permian of West Siberia, have been recognized. The published descriptions
do not reveal any differences that are clearly of specific value, but, pending
a more detailed examination of Stenzel’s fossil, it is prudent to keep the two
species apart.

The most recent paper directly bearing upon the subject is Mrs.
Osborn’s ‘ Preliminary Observations on an Australian Zygopteris \2 which is
of great interest as being the first record of the Zygopterideae from outside
of Europe and Siberia. In this paper two important points, on which there
has been a good deal of speculation in the past,3 have been definitely
settled. Firstly it has been shown that the cauline xylem cylinder is of the
A nkyropteris Grayi type, and secondly that the leaf-trace is nipped off as
a closed ring of xylem enclosing a portion of the ‘ mixed pith * of the
stellate axial cylinder, and that this ring subsequently becomes flattened,
with a slight curve convex on the adaxial side (as is often the case in
A nkyropteris). The curve finally disappears, and a slight median constric-
tion imparts to the trace the form well known for the genus Clepsydropsis
(see Text-fig. 2, j). There are no axillary branches.

III. Nomenclature.

As already mentioned, Mrs. Osborn has proposed to place the fossil
in the genus A nkyropteris^ a perfectly natural course, considering the
stem structure and the mode of origin of the leaf-trace. On the other
hand, the shape finally assumed by the leaf-trace would by itself lead to
a reference of the plant to the genus Clepsydropsis . In fact the latter course
was at first actually adopted in the case of the Mt. Tangorin specimen,
described below, in which the stem and the leaf-trace origin are not preserved.
However, the combination, in the Barraba specimen, of the structural

1 In the same year Schenk (1889, pp. 553-4; see also Schenk, 1890, pp. 46, 156) figured and
briefly described a fossil ( Rachiopteris Ludwigii , Leuckart u. Schenk) mainly agreeing with Stenzel’s
description of C. kirgisica. The original of Schenk’s outline drawings (PI. Ill, Figs. 50, 51) was in
the Botanical Collection at Leipzig and was named by him after Ludwig, who collected it in the
Ural steppes between Akolinsk and Semipalatinsk, and Leuckart, through whose agency it reached
Leipzig. The ultimate sources of the two originals are so nearly identical as to leave little doubt
that they were portions of the same specimen, yet neither Stenzel nor Schenk refers to the other’s
paper ; on the contrary, both the authors seem to imply that their respective fossils were till then
undescribed. There is on this point a regrettable confusion in the literature, which, in spite of
Solms-Laubach’s (1910, p. 543) attempt to explain it, appears not yet to have been removed. Only
C. kirgisica , Stenz., has been recognized by subsequent writers, although it is possible that
C. {RachioptS) Ludwigii, Leuck. u. Schenk, may be distinct, for Schenk’s figures of the transverse
sections show the petiolar trace in this fossil at least half as long as the petiolar diameter.

2 Osborn (1915), pp. 727-8.

3 Bertrand (1908, 1911 b, 1911 c, 1912, 1914); Solms (1910), pp. 540-1.

G 2

84 Salmi. — On an Australian Specimen of Clepsy dr apsis .

features of both Clepsydropsis and Ankyropteris strongly suggests that
these two genera should be united. This step was proposed in a recent
paper,1 and in the following pages the genus Clepsydropsis will be under-
stood to include Ankyropteris.

It is of some interest to find that this conclusion is fully corroborated
by some photographs of C. antiqua , Ung., published by Dr. P. Bertrand in
1911 (1911 a, PL II, Fig. 16 ; PL I, Pigs. 1, 2 + 3 and 4 + 5 ; also Bertrand,
1912, Fig. 21, p. 228). These figures show beyond doubt that the mode of
leaf-trace origin in that species was essentially the same as that in the
Barraba fossil, and that known for C. (Ank.) Grayi , Will., if we disregard
the complications due to the presence of the axillary branch. (See Fig. 35,
p. 244, in Progressus , 1912.)

The figures in question are based upon a single specimen, discovered
by Dr. Bertrand among Unger’s originals. The unusually small dimensions
of the petiolar strand led him to conclude that it was probably either an
abnormally thin petiole or a normal petiole sectioned in its distal region.
Dr. Bertrand, however, evidently overlooked one rather important point in
the figure, which shows that it undoubtedly represents a section across the
basal region of a petiole. This is the presence, in the tangential plane, of
a plate of narrow tracheides forming a bridge between the two peripheral
loops and similar to the tracheides lining the loops themselves. The signifi-
cance of this feature at once becomes apparent when we consider that the
clepsydroid shape of the strand in the Barraba fossil is the result of the
tangential flattening, followed by a median constriction, of a closed xylem
ring lined internally by a zone of specially narrow tracheides. An exactly
similar condition was observed in one of the petiolar strands in the
Mt. Tangorin specimen, and is described below (p. 88; see Fig. 6, PL IV).
Subsequently I learned from Mrs. Osborn that the same feature is visible in
her specimen, and that it persists for a short distance from the leaf-base
upwards.

A diagnosis of the genus Clepsydropsis as extended in accordance with
the above suggestion is given in my paper above referred to, along with
other theoretical considerations.

IV. Description.

Gross features. When received the fossil was an almost semicircular
slab about 3*5 cm. thick, with the diameter of the semicircle about 1 1 cm.
long. The more or less flat upper and lower faces showed the cut ends of
about a dozen cylindrical petioles varying in diameter from about 15 to
17 mm., a few of which were evidently compressed into unnatural shapes.
The spaces between the petioles were packed with numerous occasionally
branched roots running in all directions. These were possibly mixed with

1 Sahni (1918).

Sahni . — On an Australian Specimen of Clepsydropsis . 85

pinnae and aphlebiae, though these could not definitely be made out. On
the polished faces the characteristic petiolar strands could be observed in
several of the leaves, and when the surface was covered with a thin layer of
oil, with the help of a lens the course of the roots and petiolar strands could
be traced for some distance into the transparent siliceous matrix.

Text-fig. 1 is a diagram to show the fossil in plan and elevation; the
outlines of the plan were drawn from the lower end of the fossil. The
block was first cut into two pieces along XX, ancf from the left-hand piece

the two transverse sections T 1, T 2, and the three longitudinal sections L 1,
L 2, L 3 were prepared. Subsequently two transverse sections ti^ti were
prepared from the right-hand piece. The original specimen is therefore
now in four pieces, A, B, C, D, besides a fragment left over after levelling one
of the ends. In the figure the petioles are marked with numbers to corre-
spond with those in Text-fig. 2.

The orientation of the petiolar strands (indicated by short straight lines
in Text-fig. 1) shows that the leaves are arranged in their natural positions
round a stem which is, however, missing. The longitudinal sections show
the petioles sloping inwards towards the stem side, but from the low angle

86 Sahni. — On an Australian Specimen of Clepsydropsis .

at which they stand to the vertical it maybe concluded that the leaves were
probably almost erect in their basal region. These facts make it very
probable that the plant was a fair-sized tree-fern resembling the fossil
Osmundaceae.

Anatomy . The preservation on the whole cannot be described as
good, although some portions show well-preserved details of structure.
Many of the roots have penetrated deep into the cortex of the leaf-stalks,
and have even distorted the shapes of most of the petiolar strands.

The roots probably all belong to the Clepsydropsis itself, although none
of them is seen actually connected with the leaves— they may be arising
from the more proximal regions of the latter and in part even directly from
the stem, as appears to be the case in the Barra ba specimen, and as Stenzel
(1889) describes in C. kirgisica (p. 22, PI. IV, Fig. 38, w). They have
a diarch xylem strand (PI. IV, Fig. 1) and the pitting of the metaxylem
tracheides was finely scalariform as in the leaf-strand. The cortex of the
petiole consists of a broad inner zone of large thin-walled cells with inter-
spaces, succeeded on the outside by a narrower zone of cells gradually
decreasing in diameter towards the epidermis (PI. IV, Fig. 2). In longitu-
dinal section the cells of the inner cortex are nearly isodiametric, those of
the outer cortex more elongated, with transverse or oblique end-walls
(PI. IV, Fig. 3). The epidermis is not preserved, consequently the ‘ external
glands or hairs’ mentioned by Mrs. Osborn are not seen. A few of the
outermost layers of the cortex appear to be specialized as a thickened
hypodermis , as described by Schenk in Rachiopteris L udwigii (1889, p. 554) >
but it is difficult to be clear on this point. The total radial thickness of the
preserved cortex varies from 3 to 4 mm. ; between it and the petiolar strand
the leaf tissues are nowhere preserved. In Schenk’s fossil just referred to
this space was in part at least (loc. cit ., p. 553) occupied by a sclerotic sheath.

The adjoining figures, from camera-lucida sketches of the petiolar
strands, illustrate the extent to which the intruded roots (shown in rough
outline only to indicate their positions) distort the normal clepsydroid
shape of the leaf-traces. Only one of these happens to be completely
undisturbed (Text-fig. 2, 1, 1). It was seen cut at two different levels (T 1,
T 2) and its dimensions are given below :

Total length, 6*4 mm.

Thickness at the ‘ waist ’, 3 mm.

Length of each peripheral loop, 1*7 mm.

Distance between the inner ends of the two loops, 2*1 mm.

The variations in size could be judged from the remaining figures, but
the amount of distortion makes it unsafe to base any measurements upon
them. The limits of the xylem could not in all cases be accurately
observed, owing to imperfect preservation. In many places only rows of
dirt-granules are seen, which, however, unmistakably marked the contours

Salmi. — On an Australian Specimen of Clepsydropsis. 87

Text-fig. 2. The petiolar strands, which are all shown with their adaxial faces in the direction
of the arrow, are marked with numbers to correspond with those in Text-fig. 1. The Roman
numerals refer to the petioles as seen in the transverse sections T 2, t 2 ; the corresponding Arabic
numerals to the respective petioles, as seen in the transverse sections T 1, / 1. hor further
explanation, see text, p, 86,

88 Sakni. — On an Australian Specimen of Clepsydropsis.

of the tracheides. Only those parts are shown in solid black where outlines
of tracheides were recognized with tolerable certainty. The dotted areas
refer to parts where the existence of xylem was only inferred.

The shape of the trace at once decides the specific distinctness of the
plant from either C. antiqua , Ung., or C. kirgisica , Stenz. It is proportion-
ately thinner, has pointed instead of truncated ends, and the internal
contour of the peripheral loops is fusiform instead of elliptical.

The tissue filling the peripheral loops, which in the Barraba fossil
consists of parenchyma intermixed with small tracheides, is not preserved
at all. The loops are instead filled up by a deposit of mineral granules in
the form of peculiar branched tubular structures, the appearance of which '
suggests that they were probably formed in the same manner as a continu-
ally growing semi-permeable membrane round a crystal of copper sulphate
in a solution of potassium ferrocyanide. A similar process was probably
responsible for a pseudo-cellular structure replacing the cortical cells in
some of the leaves, each pseudo-cell having been formed round an inde-
pendent centre.

The tracheides are practically all scalariform (PI. IV, Fig. 4), with
occasional anastomoses between the bars of thickening, as an approach to
the reticulate type. The peripheral loops are lined with tracheides
distinctly narrower than those immediately outside them. As we pass still
farther away from the loops the tracheides again diminish in size (PL IV,
Fig- 5)- Only one spiral element was observed ; of the others some on
account of their small diameter gave the impression of being annular. In
a few scalariform tracheides the pits, which were rather farther apart than
usual, showed in surface view what may be called 4 false borders ’, because in
sectional views they could not be seen at all. It may be that the free edges
of the thickening bars, instead of hanging over the pit so as to narrow the
entrance to it, sloped in the opposite direction, so that the entrance to the
pit became wider than the bottom. The effect in surface view would in
either case be almost the same. The tracheides average about 100 /x in
diameter ; the largest seen was 180 /x, the smallest 20 /x across.

In one of the leaf- traces the inner ends of the two peripheral loops
were connected by a series of narrower tracheides similar in size and form
of pitting to those lining the loops themselves (PI. IV, Figs. 6, 7). The
significance of this feature has already been explained on p. 84.

Dr. Bertrand (1911 c, p. 509) records the presence in the leaf-strand
of C. antiqua of a number of tracheides of secondary origin. No trace of
secondary xylem was present in any of the leaf-strands of the Mt. Tangorin
fossil.

The origin of the pinna-trace is exactly as in C. antiqua , that is, the
trace is constricted off as a closed ring from the end of the peripheral loop.
Unfortunately the large number of intrusions have greatly disturbed the

Sahni . — On an Australian Specimen of Clepsydropsis . 89

relative positions and shapes of the different parts of the xylem, and in
a few cases (Text-fig. 2) they have even broken the latter into two or more
pieces.

One of the leaves shows further branching of the vascular supply
(Text-fig. 2, 2 ). In this case a small elliptical ring of xylem is seen lying
just off the pinna-trace, adaxially to it, at an angle of 450. Owing to
bad preservation, in the only other section that passes through this leaf
there is no sign of this strand, so that it is at present impossible to ascertain
its point of origin, whether from the pinna-trace or directly from the
primary leaf-strand ; but from the direction of the long axis of the ellipse
(due to oblique section of a circular tube) it seems highly probable that it
arose from the pinna-trace. In view of the proximity of intruded roots,
however, it is quite likely that the strand in question has been shifted slightly
out of its natural position. The obliquely-cut tracheides show a finely
scalariform pitting ; no spiral or annular elements are seen. The thickness
of the ring is about three tracheides ; the tissue in the centre of the ring is.
not preserved.

V. Theoretical.

Aphlebiae . In C. antiqua Dr. Bertrand (1911 a, pp. 15-17) has
figured a small ring-like strand occupying a rather similar position. This
strand evidently has the same morphological value in both cases. Dr.
Bertrand regards it as the trace of a pinnule (tertiary rachis). It is probable,
as Professor Seward suggested, that the organs supplied by these tertiary
strands were of the nature of aphlebiae. This supposition is confirmed by
a comparison with the corresponding structures in Diplolabis Roemeri ,
Metaclepsydropsis duplex (Gordon, 1911 a , b), Stauropteris oldhamia
(Bertrand, 1909, p. 29, Fig. 4). The strands referred to by Stenzel (1889,
p. 45) as arising from the base of the leaf-trace are also probably of the
same nature.

Better preserved material is necessary to decide the question as to the
normal number and position of the aphlebia-strands on each side of the
pinna in Clepsydropsis (Unger, 1856, p. 167 ; Solms, 1896, pp. 25-7 ; Stenzel,
1889, pp. 21, 23) ; a re-examination of Stenzel’s original specimens of
C. kirgisica would be useful.

Habit. — The known genera of Zygopterideae may be classified into two
groups, the Clepsydroideae (including the genera Asterochlaena and Clepsy-
dropsis) and the Dineuroideae (including Dineuron , Diplolabis , Metaclepsy-
dropsis , Etapteris , Stauropteris , Zygopteris , and provisionally Gyropteris
sinuosa , which may ultimately have to be placed as a species of either
Diplolabis or Metaclepsydropsis ). Except for Gyropteris , these two groups
are co-extensive with those proposed by Kidston and Gwynne-Vaughan
(1910, p, 470) on the basis of the number of (free) branch-axes on each side

90 Salmi.— On an Australian Specimen of Clepsydropsis.

of the primary rachis. It is interesting to find that, so far as our present
knowledge goes, the symmetry of the stem in the two groups is quite
distinct. Thus in the only genera of the Dineuroideae in which the stem is
known, viz. Diplolabis and M etaclepsydropsis (Gordon, 1911 a, b), it had the
form of a creeping rhizome with the leaves confined to the dorsal side and
rising perpendicularly from it. On the other hand, in the Clepsvdroideae,
in which our knowledge of the stem is more complete, the leaves arose
radially on all sides of the stem, which was either an upright stock (Astero-
chlaena (Bertrand, 1911 b ), C. kirgisica (Stenzel, 1889, Fig. 38, PL IV), and
the Australian Clepsydropsis) or, as in C. (Ank.) scandens (Stenzel, 1889;
Scott, 1909), it scrambled among the roots on the upright stem of a
Psaroniits.

It appears as if the precocious bifurcation of the pinna-trace in the
Dineuroideae (except Gyropteris ), and the consequent peculiar habit of the
petiole in that sub-family, had something to do with the manner in which
the basal portion of the leaf was held. One is tempted to expect that the
stem of the remaining Dineuroideae will also be a horizontally creeping
rhizome.

VI. Summary.

A description is here given of a Clepsydropsis , collected near Mt.
Tangorin, New South Wales, in rocks possibly of Carboniferous age. It is
specifically identical with the fossil briefly described by Mrs. Osborn in the
Report of the British Association (Manchester meeting, 1915, p. 727).

It is shown that in C. antiqua , Unger, also, the leaf-trace arose as
a closed ring of xylem which became tangentially flattened, and then
became clepsydroid as the result of a median constriction. This fact
strongly supports the suggestion put forward in an earlier paper that the
genera Clepsydropsis and Ankyropteris should be united, the leaf-trace
origin in the latter genus being known to be essentially the same.

The two groups of the Zygopterideae (Clepsydroideae and Dineu-
roideae) were also sharply distinct in the symmetry of their stem, which, so
far as we know, was radial in the formal group and dorsiventral in the
latter. It is suggested that this distinction will be maintained as our know-
ledge of the stem becomes more complete. The apparently radial symmetry
of the basal region of the leaf in the Dineuroideae (due, as previously shown,
to an early bifurcation of the pinna-trace) may also be related to its probably
strictly upright position in that sub-family. The opinion has already been
expressed in an earlier paper that this apparently radial symmetry was not
continued into the probably more or less horizontal laminated distal portion
of the leaf.

Botany School, Cambridge,

April 1, 1918.

Sahni . — On an Australian Specimen of Clepsydropsis . 91

Bibliography.

Bertrand, Paul (1908) : Sur les stipes des Clepsydropsis . Comptes Rendus, cxlvii, pp. 945-7.

(1909) : Etudes sur la fronde d^s Zygopteridees. Lille.

(1911 d): Nouvelles remarques snr la fronde des Zygopteridees. Bull. Soc. Hist.

Nat. Autun, xxv.

(1911 b) : Structure des stipes d ' Aster ochlaena laxa . Mem. Soc. Geol. du Nord,

t. vii, mem. No. 1.

(1911 e) : Observations sur les Cladoxyl^es. Assoc. Fran9« pour I’Avancement

des Sciences, 40® session, Dijon, p. 509.

(1912) : L’etude anatomique des fougeres, etc. Progressus rei botanicae, iv.

(1914) : Etat actuel de nos connaissances sur les genres Cladoxylon et Steloxylon.

Assoc. Franf. pour l’Avancement des Sciences, 430 session, Le Havre, p. 446.

Corda (1845) : Beitrage zur Flora der Vorwelt. Prag.

Goeppert, H. R., und Stenzel, G. (1881) : Die Medulloseae, eine neue Gruppe der fossilen
Cycadeae. Palaeontographica, 28 (3. Folge, 4. Lief., iii), p. 16.

Gordon, W. T. (1911a:): On Diplolabis Roemeri Solms. Trans. Roy. Soc. Edin., xlvii, Part IV,
No. 24.

(1911 b ) : On Metaclepsydropsis duplex Will. Ibid., xlviii, Part I, No. 8.

Kidston, R., and Gwynne-Vaughan, D. T. (1910) : On the Fossil Osmundaceae. Part IV, ibid.

Osborn, E. M., Mrs. (1915): Preliminary Observations on an Australian Zygopteris . Report
British Assoc., pp. 727-8.

Saiini, B. (1918) : On the Branching of the Zygopteridean Leaf and its Relation to the Probable
4 Pinna’ Nature of Gyropteris sinuosa Goeppert. Annals of Botany, xxxii.

Schenk, A. (1889) : Ueber Medullosa, Cotta, und Tubicaulis , Cotta. Abh. d. kgl. sachs. Ges. d.
Wiss., xxvi, Math.-Phys. Kl., xv.

(1890) : Die fossilen Pflanzenreste. Handbuch der Botanik, iv. Breslau.

Scott, D. H. (1909) : Studies in Fossil Botany.

(1912) : On a Palaeozoic Fern, the Zygopteris Grayi of Williamson. Annals of

Botany, xxvi (i), p. 39.

Solms-Laubach, H., Graf zu (1896) : Ueber die seinerzeit von Unger beschriebenen . . . Pflanzen-
reste . . . von Saalfeld. . . . Abh. d. k. preuss. geol. Landesanstalt, Neue Folge, Heft 23,
Berlin.

(1910) : Ueber die in den Kalksteinen des Kulm von Glaetzisch-

Falkenberg in Schlesien erhaltenen struktmbietenden Pflanzenreste, IV. Zeitschrift fur
Botanik.

Stenzel, G. (1889) : Die Gattung Tubicaulis , Cotta. Bibliotheca Botanica, Heft 12, Cassel.

Unger, F. (1854): Zur Flora des Cypridinenschiefers. Sitzungsber. d. k.-k. Akad. Wiss. Wien,
Bd. xii, p.. 599.

(1856): Beitrag zur Palaontologie des Thiiringer Waldes (Richter u. Unger). Denkschr.

d. k.-k. Akad. zu Wien, Math.-Naturwiss. Kl., xi, p. 165.

EXPLANATION OF PLATE IV.

Illustrating Mr. Sahni’s paper on an Australian Specimen of Clepsydropsis.

(The figures are all from untouched photographs, with the exception of Fig. 3, in which some
of the fainter lines on the print were intensified with a lead pencil.)

Fig. 1. Transverse section of a diarch root-strand; the two poles lie at the right and left ends
of the strand, x c. 35*5.

Fig. 2. Transverse section of peripheral region of a petiole, o.c., outer cortex ; i.c., inner cortex.
X c. 38.

9 2 Sakni.- — On an Australian Specimen of Clepsydropsis .

Fig. 3. Longitudinal section of the same, x c. 43.

Fig. 4. Longitudinal section of a portion of a petiolar strand, to show the finely scalariform
pitting 01 the tracheides. x c. 133.

Fig. 5. Transverse section of a portion of the petiolar strand, also shown in Text-fig. 2, j.
Owing to a fracture in the xylem, the peripheral loop appears considerably wider than is normally
the case ( compare with the undisturbed strand shown in Text-fig. 2). The loop is lined internally
as well as externally by specially narrow tracheides. x c. 40.

Fig. 6. Transverse section of the petiolar strand, also shown in Text-fig. 2, 9. a., a., antennae;

peripheral loops; s.t., small tracheides, forming a more or less complete bridge between the two
loops, x c. 29.

Fig. 7. Longitudinal section of the same strand, passing radially across its median plate, to
show the small tracheides, s.t., flanked by the larger tracheides. x c. 33.

cfhwals of Botany,

vouxrm,PiJV.

B. Salmi phot;.

SAH N I— CLEPSYDROPSl S.

Hutih. coll.

Observations on Euglena deses.

BY

ROSE BRACHER.
With nine Figures in the Text.

Contents.

PAGE

Section I. Introduction 93

„ II. Daily Movements of E. deses dependent on External Factors , 95

„ III. Behaviour of E. deses when removed from the Influence of the

Tide 99

,, IV. Further Investigations of the Influence of Light and Temperature

on the Behaviour of E. deses 100

,, V. Depth to which E. deses burrows in Mud 104

„ VI. Climatic Conditions 105

„ VII. The Need for Oxygen 106

„ VIII. Summary 106

„ IX. Conclusion 107

Bibliography 108

Introduction.

THE organism with which this paper has to deal occurs along the banks
of the river Avon within its tidal portion, which extends for about
seven and a half miles inland. The actual point at which the present work
was for the most part carried out is about a quarter of a mile lower down
the river than the Clifton Suspension Bridge. At low tide the river in this
part of its course is reduced to a very narrow stream, leaving exposed on
either side wide stretches of mud.

On examining the surface of the mud, one can see that parts are
coloured bright green, while in other places the mud appears yellowish
brown in hue. Closer examination reveals the fact that the green colour is
restricted to small patches varying from a quarter of an inch to one inch in
diameter, and often so close together as to form an almost continuous
carpet.

[Annals of Botany, Vol. XXXIII. No. CXXIX. January, 1919.]

94 Br acker . — Observations on Euglena deses.

By examining small quantities of the mud under the microscope, one
can see that the green colour is due to the presence of a vast number
of small green organisms, identified by the aid of Dangeard (3) and
'Wager (7) to be Euglena deses. The yellow and brown colour is due
to the presence of a large number of diatoms, and it is a noteworthy
fact that while the Euglenae occupy, for the most part, the higher positions
on the ridges of mud, the diatoms are usually to be found in the damper
mud of the holiows.

According to Dangeard (4) Euglena requires a certain amount of
organic matter for its nutrition, and the occurrence of the organism in so
great abundance here is probably due to the quantity of sewage brought
down to the Avon from the neighbouring towns. An analysis of the mud
at this spot shows that the organic content is 6 per cent, (approx.).

By continuing observations on the banks of the Avon, one may see
that the green colour mentioned above is not permanently on the mud, but
disappears and reappears apparently according to the times of sunrise,
sunset, and high tide. One may well compare the behaviour of this
organism with that of Convoluta roscoffensis described by Gamble and
Keeble (5) and Georges Bohn (1). This animal is found on the shores
of Brittany, where it colours patches of the sand bright green. It
comes to the surface during certain times of the day, but burrows into the
sand during darkness and for the periods of high tide. Laurie (6) describes
similar diurnal movements in the Peridinian, Amphidinium opercidatum ,
which is brown in colour and occurs on the sea-shore at Port Erin.
Bohn (2) further shows that certain Gasteropods, such as Littorina
rudis , exhibit diurnal migrations, taking shelter under pebbles and rocks
during darkness and high-tide periods.

Although such comparisons are of great interest, one should remember
that in all the organisms mentioned above, with the exception of the Peri-
dinian, there is a much more highly developed structure than in the unicellular
Euglena , and therefore it is not wise to lay too great a stress on their
similarities and differences.

This paper was, therefore, undertaken with a view to investigating the
possible influence of such external factors as light, tidal flow, and tempera-
ture changes upon the movements of E. deses and the part which they play
in the life of the organisms.

E. deses is very contractile and constantly changing its shape. By
a series of changes, consisting chiefly of contraction into a ball, expansion
to full length, and bending round upon itself, the organism is able to creep
about over the surface of the mud. Up to the present time no cilia have
been observed, and in the experiments performed the organism appears to
be unable to swim freely in water. One would expect, therefore, that any
response to stimuli which the organism makes would of necessity be much

95

Br acker. — Observations on Euglena closes.

slower than that made by the free-swimming forms such as E. viridis.
Fig. I shows the changes in shape occurring in one specimen of E. deses
during several minutes’ observation under the microscope.

Fig. i. 1-5. Euglena deses , showing changes in shape occurring in one individual during several
minutes’ observation. (Mag. 400 times.)

Daily Movements of E. deses dependent on External

Factors.

A series of observations were made on the Avon banks between dawn
and sunset with a view to investigating the times of the daily movements
of Euglena.

At dawn no Euglenae are Visible on the surface of the mud, but from
readings taken in October, December, April, and May the green colour
begins to appear about one to two hours after sunrise.

Average

Time of

Month.

Week.

lime of

Appearance

Sunrise.

of Euglenae.

October

8 th- 1 5 th

6.12

7-30

December

3rd-9th

7-45

9.0

April

23rd-29th

4-37

6.30

May

1 4th- 20th

4-3

6.0

As the light becomes brighter and the temperature increases the mud
becomes correspondingly greener, until about midday the surface is very
green indeed. The organisms remain thus exposed until the light begins to
fade in the evening, when they once more disappear from view and burrow
down into the mud. Readings were taken in the same months for the time
of disappearance of the organism, which is shown to be less than half an
hour before sunset.

Month.

Week.

Average
Time of
Stmset.

Time of
Disappearance .

October

8th- 1 5th

5-*5

5.0

December

3rd~9th

3-49

3.30

April

2 3rd- 2 9th

7.18

7-°

May

14 th- 20th

7.40

7-30

96

Brae her. — Observations on Euglena deses.

The diurnal movements would cause one to expect corresponding
changes in the appearance of the organism during the day, and accordingly
drawings were made at various times to investigate the nature of these.

Early in the morning they appear extended and active as they rise to
the surface and are moving with continual amoeboid movements. Later in
the day they appear rounded off, and at night the eyespot is completely
hidden from view.

If light were the only determining factor the above results would
include all the daily movements of Euglena deses ; but its behaviour, as has
already been stated, is considerably modified by the response of the organism
to the action of the tide.

If a patch of mud is watched immediately after the tide has receded
from it, no Euglenae are visible. From about a half to one hour later the
first make their appearance in small isolated groups, about a quarter of an

Fig. 2. E. deses. Diurnal differences in appearance. (Mag. ioo times.) (i) Early morning
(actively moving) ; (2) midday (lying still on mud surface); (3) night (rounded off).

inch in diameter. With regard to the incoming tide, the Euglenae do not
disappear into the mud before they are covered by the tide, but when a few
ripples of the rising water have passed over the spot they burrow down, and
the green colour quickly fades and does not reappear until after the water
has gone back.

It may be seen, therefore, that the intervention of the action of the
tide alters to a considerable extent the simple diurnal movements dependent
solely upon light, and one would expect to find much variation in the
behaviour of the organism according as the two factors, light and tidal
action, are reacting simultaneously or at different times.

In order to keep the Euglenae under closer observation and yet under
natural conditions, an apparatus was devised for producing a periodic tidal
flow over a given area of mud. In main essentials this apparatus consisted
of a tank which was filled and emptied automatically by means of siphons
which had been so arranged as to produce a tide at the proper time. In
Fig. 3 a drawing of the apparatus is shown.

97

Brae her. — Observations on Euglena deses.

Mud (M.) is placed in the glass tank T in the position shown in
diagram. Cement dams (cq and c2) serve to keep the mud in position.
Water is stored in two vessels (ax and A2) which are connected by the
siphon Sr By means of a tap at the base of the siphon S2 water is run
drop by drop into the bottle B. By keeping this always overflowing, the
pressure of water in the bottle remains approximately constant. By means
of the tap water from the bottle is then run into the inverted bell-jar J.
The indicator I enables the stop-cock to be kept at a definite angle, and

T Tank.

Fig. 3.

by adjusting this the time taken to fill the bell-jar may be regulated.
By trial it was possible to fill the bell-jar to the required level in twelve
hours. In reaching the level of the siphon s3 the water all passes over
into the tank by means of the tube X, and high tide is effected. The
outgoing tide is arranged thus : As the water rises in the tank T it also
rises in the glass cylinder K, the two being connected by the siphon S4.
This cylinder is too narrow to allow any appreciable fall of water to take
place in the tank. On reaching the level of the siphon S5 the water in
the cylinder is gradually passed off by means of slow dripping from the tap
at the end of the siphon, and accordingly the water is gradually emptied
from the tank until it reaches the level of the upper end of siphon S5
within the cylinder, when air enters and the flow of water is stopped. By

H

98 Brae her. — Observations on Euglena deses.

regulating the tap the duration of high tide may be altered to suit the
experiment.

As the greenness of the mud varied from hour to hour, readings were
taken, and for this purpose a colour scale was made consisting of four colours
to which the numbers o, 5, 10, and 15 were given respectively.

Shade 15 = Brightest green colour on mud.

Shade 10 = Green colour shown when Euglenae are beginning to go
down.

Shade 5 = Very pale green when nearly all Euglenae have dis-
appeared.

Shade o = Pure grey colour of mud.

By practice it was possible to read which shade the mud most closely
resembled at the time when the readings were taken. These readings were

Fig. 4. Ihe graph represents the intensity of greenness on the mud under normal conditions
with reference to the periods of high water (depicted black) and of darkness (depicted shaded). The
intensity of greenness is measured according to the following scale: 15 (bright green), 10 (green),
5 (pale green), and o (pure grey colour of mud). The observation extends over eleven days, the
divisions of which are marked at noon (N.) and midnight (Mid.).

plotted on a graph and a curve obtained, while the periods of high tide,
and also those of day and night, are shown in order to compare the
appearance of the mud with these (Fig. 4).

Starting on Monday it may be seen that the organisms make their
appearance about two hours after sunrise and attain their maximum number
on the surface between the hours of 8 a.m. and 1 1.30 a.m. About half an hour
before the tide comes in they begin to go down and completely disappear

Br acker. — Observations on Euglena deses. 99

as the water rises over them. About half an hour after the tide has receded
they reappear, regain their maximum number between the hours of three
and five, and disappear again completely just before sunset. On Tuesday
the process was repeated, but owing to a decrease in time (about five hours)
between the ebb of the tide and the sunset, the Euglenae do not reappear to
their fullest extent and the mud does not become very green. On Wednesday
this period of time is reduced to four hours, and the Euglenae make no
reappearance after high tide during that day. On Thursday and Friday
the same phenomenon occurs as the time is still further reduced. On
Saturday and Sunday the appearance of the organisms is retarded, since
the period of high tide extends over the usual time when they rise to the
surface. On Monday and Tuesday of the second week the periods of time
between sunrise and high-water are two and three hours respectively, but
the organisms do not rise to the surface until after the tide has receded.
On Wednesday the period is increased to four hours, and on this day the
Euglenae appear on the surface in small numbers for a short time before
high tide. On Thursday the period between sunrise and high water is still
further prolonged, and the Euglenae appear for a longer time and in greater
numbers, but it is not until the tide once more approaches the region of
midday that the green colour on the mud attains its maximum degree of
intensity twice in one day.

Thus it may be seen :

1. That, other conditions being equal, the Euglenae rise to the surface
about two hours after sunrise and go down shortly before sunset, burrowing
into the mud during the day for the period of high tide.

2. That if the period between the ebb of the tide and sunset is not
longer than about four hours, the organisms do not reappear during this
interval.

3. That if the period between sunrise and high water is not longer than
three hours, the organism does not appear on the surface until the tide has
receded.

Behaviour of E. deses when removed from the
Influence of the Tide.

It may easily be seen that those Euglenae which live close to the outer
edge of the river bank are only covered by the tide for comparatively short
periods, while those lower down may remain covered with water for several
hours. Moreover, owing to the fortnightly variations in the tide, it happens
that during neap tides this outer zone may be exposed for several days
without being covered by the tide. Material was taken from this region
and kept in dishes, and it was noticed that the organisms responded only to
the stimulus of light. In other material, however, which was taken from

H 2

IOO

Br acker. — Observations on Euglena deses.

a zone always under tidal influence, it was noticed that, although removed
from the Avon and placed in a dish in the laboratory, the organisms still
continued to burrow into the mud at the time of high tide.

In order to ascertain exactly how long this phenomenon persisted,
accurate readings were taken at every hour by means of the colour scale
used in the previous experiment, and curves drawn in order to show the
behaviour of the organisms when removed from the influence of the tide

(Fig- 5)-

Fig. 5. A graph drawn to illustrate the behaviour of E. deses when removed from the influence
of the tide. The lettering and shading are as in Fig. 4.

The material was obtained at 9 a.m. on Wednesday morning, when the
mud was well covered with Euglenae. It was placed in the laboratory and
left without any tidal influence.

Result.

On Wednesday afternoon the organisms went down during the period
of high tide.

On Thursday afternoon the organisms again went down at about the
same time as the period of high tide on Wednesday.

On Friday the organisms again went down for the same period, though
they commenced to do so about an hour later, the disappearance being
more rapid.

On Saturday and Sunday, however, the Euglenae did not disappear at
all during the day until just before sunset.

Therefore, although removed from tidal influence, E . deses continues
to show tidal periodicity for about three days. Gamble and Keeble (5)
describe a similar periodicity in Convoluta , which they maintain only lasts
for one day. Bohn (1), however, states that he has watched the phenomenon
during fourteen consecutive tides.

Further Investigations of the Influence of Light and
Temperature on the Behaviour of E. deses .

The influence of light. It has been shown that E. deses is sensitive to
light, since it comes to the surface of the mud as soon as the daylight has
reached a sufficient degree of intensity. Small variations in the light during

Br acker, — Observations on Euglena deses. ioi

the day appear to make no difference to the number of Euglenae on the
surface, as in bright sunlight or good daylight without sun the greenness of
the mud remains the same. If, however, the day is extremely dull and the
intensity of the light does not reach a certain point required by the Euglenae,
only a very few organisms appear, and from December 13 to December 15,
when a very heavy fog enveloped the city, no individuals could be seen on
any of the mud under observation. The Euglenae disappear into the mud at
nightfall, but the same phenomenon can be brought about by placing them
at any time in the dark. It was found that the time taken for complete
disappearance varied with the temperature, as will be shown later, but
averaged about thirty minutes. On replacing in the light the Euglenae took
about the same time to rise to the surface again.

If kept in the dark for one or two days the Euglenae do not appear on
the surface until replaced in daylight. If kept for longer periods a few may
be visible on the surface of the mud, and eventually most of them return to
the surface, probably to obtain more oxygen. The chief difference in the
appearance of these Euglenae kept in the dark is the disappearance of the
paramylon grains which are used as reserve food, and when all has been
used up the organism dies. On being replaced in light, however, before all
the paramylon has disappeared, the Euglena is able to manufacture fresh
grains in a very short period of time.

Another experiment was performed in which the Euglenae were placed
in dishes and illuminated only from one side in order to see if they would
move towards the light.

Four dishes were used which contained respectively :

(1) A quantity of stiff mud containing Euglenae.

(2) A quantity of wet mud containing Euglenae.

(3) A quantity of mud with Euglenae, over which a layer of water
half an inch deep was placed.

(4) A number of Euglenae in water only.

In (1) and (2) the Euglenae gradually moved towards the source of
light, and about the end of five days were all massed at the lighter end of
the dish, many heaped upon the glass.

In (3) the Euglenae moved somewhat towards the source of light, but
not so pronouncedly as in (1) and (2).

In (4) the organisms kept their original position, and at the end of the
day appeared completely dead, owing to a lack of oxygen and food material,
as they are not able to swim in water.

In the diagram given below (Fig. 6) the positions of the Euglenae at
the beginning and end of the experiment are shown.

From these experiments it may be concluded that Euglena deses is
sensitive to light and moves towards the source of light, and is not repulsed
by bright sunshine.

102

Brae her, — Observations on Englena deses.

Its movements in response to the stimulus are very slow as compared
with results obtained by Wager (8) on Englena viridis. He mentions
that if a cloud passes over the sun these organisms immediately leave
the position which they occupy on the surface of a pond and swim down
into the water, to reappear as soon as the cloud has passed. Also a number

Fig. 6. (i) Position of Euglenae at commencement of experiment: A, stiff mud; B, wet

mud; c, mud covered by water; d, water only. (2) Position of Euglenae after five days’
illumination from one side.

of Euglenae in a saucer illuminated from one side will pass towards the
source of light in a few minutes.

Influence of temperature. Cultures of Englena were kept at tem-
peratures ranging from 30 C. to 2o°C.,and in these the organisms appeared
to flourish equally well. By changing the temperature, however, one is
able to observe a marked difference in the rate at which the organism
responds to stimuli.

At low temperatures, i. e. below 40 C., it was found that the Euglenae
became rounded off, very sluggish, and slow in response to stimuli, but as
the mud was gradually warmed up, they became more active and expanded
to their fullest length.

During the winter of 1916-17 the periods of frost were very severe.
From December 6 to December 17 the average minimum temperature
was -30 C. The mud in the vessels was frozen each night, but during the
warmest part of the day, when the mud thawed and rose to a temperature
of 30 C., Euglenae were visible in small numbers for a few hours.

From January 20 onwards the mud was completely frozen for
a period of twenty-nine days. The temperature frequently fell as low as
- io°C., and the mud did not thaw at all during the day-time. When the
thaw did set in, however, the mud was closely watched for any traces of
Euglenae either in the vegetative or encysted form. Five days later, a faint
green colour on the mud showed, on examination, that some of the Euglenae
had withstood the severe frost.

103

Br acker. — Observations on Euglena deses.

Experiments were then performed in order to see at what temperature
the Euglenae become active again after freezing. Four dishes containing
mud and Euglenae were placed out of doors at nightfall so that the next
morning the mud in all the dishes was frozen. They were placed in a good
light and kept at different temperatures as follows :

(i) Kept all day at o° C.

(*) „ i°C.

(3) „ *°C.

(4) Warmed slowly from o° C. to 40 C.

These experiments were repeated several times and the following
results obtained :

In (1), (2), and (3) no Euglenae appeared during the day.

In (4) the first traces of Euglenae appeared on the surface of the mud
when the temperature was approximately 2*5° C.

If the mud is frozen while the organisms are visible and then placed in

Fig. 7. E. deses.

1-5, changes in shape of one individual when warmed from 1.50 C. to i6°C.

the dark, the Euglenae will not burrow into the mud until the temperature
is as high as 2*5° C. At low temperature the Euglenae appear rounded
off, and Fig. 7 shows the changes in appearance when the organism is
warmed.

In order to see at what temperature the organism is most active the
cultures were kept at different temperatures and covered with a black cloth,
and the time taken for complete disappearance was recorded. From a large
number of experiments performed, the following results were obtained :

Temperature.

Time to disappear.

3°C.

60 minutes (approx.

6°C.

4° „

9° C.

30 „

I 2° C.

25 „

I5°C. ,

20 „

20° C.

30 »

#5

25° C.

i| hours

104

B r acker. — Observations on Englena deses .

A graph showing these results is given in Fig. 8.

E, deses is therefore capable of withstanding extremes of temperature
for short periods, but is less able to withstand long periods of adverse con-
ditions. The organisms become very .sluggish if subjected to temperatures
above 250 C. or below 50 C., and below 2-5° C. no response to stimuli has
been observed. The rate at which the organism responds to stimuli is

Fig. 8. Graph showing the time taken for Euglena deses to respond to the stimulus
of light at different temperatures.

dependent on the temperature. It is increased as the temperature is raised,
but above 150 C. its activities grow less.

Depth to which E. deses burrows in Mud.

Experiments were performed with a view to finding the depth the
Euglenae burrow in the mud in response to stimuli. By means of a Gillette
razor-blade the surface mud was scraped off in several dishes to a depth of
J in.. Jin., and Jin. respectively. The time chosen was after the cultures
had been placed in the dark, i. e. when the Euglenae had burrowed into the
mud.

As a result it was found that in the § inch experiment a large number
of Euglenae reappeared when placed in the light, in the J inch a few, and in
the Jinch none at all.

Therefore one would conclude that the majority of Euglenae do not
burrow deeper than J inch. The experiment was repeated by inserting a
strip of Bolton silk, mounted on a frame at an angle of 450, in the mud.
The organisms burrowing down became entangled in the meshes, and by

Brae her. — Observations on Euglena deses. 105

measuring the distance down the slope over which the organisms are to be
found one is able to calculate the greatest distance to which they burrow.

As a result it was found that the greatest depth was about \ inch, while
the majority were found at about | inch. This agrees with the results
obtained in the previous experiment, and also with that obtained by Laurie
for Amphidinium , which he says burrows to a depth of about Jinch (6).

Climatic Conditions.

(1) Rain. Several visits paid to the Avon during wet weather show
that E. deses does not appear on the actual surface of the mud during rain.
If, however, one examines the sides of the small drainage channels which

Fig. 9. Showing position taken up by Euglenae on the mud during rain.

run through the mud at right angles to the river, one can see a large number
of Euglenae clustered here to obtain shelter from the rain, and it is a note-
worthy fact that they occur in far greater numbers on the side from which
the rain is driving and so are almost in complete shelter. A section draw-
ing is shown in Fig. 9.

(4) Drought. The mud at the outer edges of the river bank often
becomes very dry when the tide does not cover it for some days, and in
order to see the effect of drying on the organism, mud was kept in dishes
and left until quite dry and hard.

On examination it was found that all the Euglenae were dead and
disorganized.

Other mud was kept until it became very stiff but was still soft enough
to receive an impression. With this the Euglenae ceased to respond to the
stimulus of light and remained on the surface of the mud. They appeared
rounded off and dark green in colour. On subsequent wetting the organisms

yviiD-

□

ram

mud

Position of
Euglena

106 Brae her. — Observations on Euglena deses.

regained their activity and were capable of responding to the light stimulus.
In none of the experiments was found any sign of encysted forms.

E . deses is therefore able to withstand drying up to a certain point,
but as soon as the mud becomes hard and crumbles, the organism is
apparently killed.

The Need for Oxygen.

It has been shown that E. deses will not live in stagnant water. This
is probably owing to the lack of suitable food and partly to the lack of
oxygen.

In order to investigate the second factor separately, a dish containing
mud and Euglenae was placed under a bell-jar with pyrogallic acid and
potash. The bell-jar was sealed to the glass plate on which it stood by
means of wax.

It was noticed that after three days the organisms ceased to come up
and down in response to the stimulus of light, and on examination were
seen to be contracted into very irregular shapes. After a few minutes’
exposure to the air they regained their normal appearance.

A second experiment was carried out in which the organisms were left
without oxygen for a week, when the organisms were contracted but dead,
and did not revive on exposure to air.

Thus when oxygen becomes scarce Euglena is able to resist this
adverse condition for a time by contraction, but if completely deprived of
oxygen for some days life is impossible.

Summary.

The behaviour of E. deses living on the banks of the Avon is dependent
on certain external factors, namely, light, tidal flow, and temperature
changes.

The influence of light . This influence is a direct one and therefore ot
great importance. The Euglenae are visible on the mud during day-time,
but burrow under the surface during the night, which phenomenon can be
brought about by placing the organisms at any time in darkness.

The influence of tidal flow. The tidal influence shows itself inasmuch
as the organism burrows into the mud during the period that it is covered
by the tide. If the time of high water is not more than three hours after
sunrise the appearance of the organism is delayed, and correspondingly, if
the time of high water is not more than four hours before sunset, the re-
appearance of the Eiglena does not take place that day. Further, E. deses
possesses a tidal periodicity which causes it to respond to the stimulus for
about three days after being removed from the actual tidal influence.

The influence of temperature changes is not so important as those

Br acker .—Observations on Euglena deses. 107

mentioned above, as E. deses is active at any temperature between 2*5° C.
and 25° C. Outside these limits its movements are arrested. By raising
the temperature the movements of the organism are accelerated within
certain limits, the optimum temperature being about 15° C.

Conclusion.

One would conclude from the foregoing experiments that the life of
Euglena deses is dependent on a series of movements which the organism
performs each day. With regard to the physiological reasons for such
movements very little can be said, but it is worthy of note that the two
series of movements, namely, those in response to light and those in response
to the tide, are different in nature. The influence of light is a direct one,
for Euglenae placed in the dark at any time disappear, to reappear when
replaced in the light. There is no evidence of any periodic effect, for in
cultures placed in the dark overnight and left there during the next day
the Euglenae do not reappear at the accustomed time in the morning. As
soon, however, as the culture is replaced in the light the organisms come to
the surface. From this one would think that the periodic tidal movement
is not dependent on light conditions, but is rather due to the shock of
the waves, as is thought by Bohn (2) to be the case in Convoluta roscof-
fensis.

Finally, it is very interesting to observe how the requirements of such
an organism as E. deses are so well suited to the conditions under which it
lives. Being unable to swim freely in water, it cannot live at the bottom of
ponds or stagnant pools, or it would be unable to obtain sufficient oxygen to
carry on its life processes, and on the other hand it is unable to withstand
drought and could not live in mud which is liable to become completely
dried in the summer. The periodic tidal flow is therefore an ideal condition,
since the organism is kept moist and has also long periods of exposure
when it is able to carry on respiration to a greater extent than when covered
by water. The tide tends to keep the mud at fairly equable temperatures,
and this is of distinct advantage, since the organism is unable to withstand
extremes of temperature.

Being thus so well adapted to its mode of life, the organism is able to
exist in the vegetative state all the year round, and this may account for the
fact that no encysted forms, so common in E. viridis during dry seasons,
have as yet been observed here.

In the struggle for existence the organism has evolved a structure
which enables it to live in an habitat where few other organisms occur, and
so the seasonal dying out of the species, which occurs in ponds when one
form of organism supplants another, plays no part here, and the organism is
present in immense numbers all the year round.

io8 Br acker. — Observations on Euglena deses.

I take this opportunity of offering my best thanks to Dr. 0. V. Darbi-
shire, under whose direction the work was carried out, and also to Professor
Gamble, F.R.S., and Miss E. M. Lee, M.Sc., for valuable help and advice.

Department of Botany,

University of Bristol.

Bibliography.

1. Bohn : Sur les mouvements oscillatoires de Convoluta roscoffensis . Comptes rendus des Seances

de l’Academie des Sciences, vol. cxxxvii, 1903, pp. 576-8.

2. : Periodicite vitale des animaux soumis aux oscillations du niveau des hautes mers.

Comptes rendus des Seances de l’Academie des Sciences, vol. cxxxix, 1904, pp. 610-11.

3. Dangeard : Recherches sur les Eugleniens, pp. 92-9.

4. — : Ibid, p. 197.

5. Gamble and Keeble : The Bionomics of Convoluta roscoffensis . Quarterly Journal of Micro-

scopical Science, vol. xlvii, 1903.

6. Laurie : On the Bionomics of Amphidinium operculatum. Report of British Association, 1913.

7. Wager : On the Effect of Gravity upon the Movements of Euglena viridis and other Micro-
organisms. Phil. Trans. Royal Society, London, vol. cci, pp. 333-90.

— : Movements of Aquatic Micro-organisms in Response to External Forces. The
Naturalist, June and July, 1914.

8.

A Study of Apogamy in Nephrodiutn hirtipes, Hk.

BY

W. N. STEIL,

University of Wisconsin, Madison, Wisconsin , U.S.A.

With Plates V-VII.

Introduction.

THE first reported observation of a sporophyte tissue element in the cells
of a fern gametophyte was made by Leszcyc-Suminski (1848), who
found tracheides near the apical notch of the prothallium of Pteris sul-
cata, L.

Wigand (1849) described a cylindrical or conical process produced
as an outgrowth from the apical notch of the fern prothallium, instances of
this sort being found in several cultures. According to his description, the
embryo begins its development on the ventral side of the prothallium and
at the posterior portion of the process. Since there can be no certainty
regarding the purity of his cultures, the peculiar developments described
cannot be referred to any particular species. There can be no doubt, how-
ever, from his descriptions (l.c., pp. 106, 107) and figures (Figs. 25-9) that
he studied embryos of apogamous origin.

Mercklin (1850) found cells in the prothallium of Pteris sulcata like
those observed by Leszczyc-Suminski. Mercklin also figured (l.c., PI. VII,
Fig. 6) a prothallium and a young embryo of Nothochlaena Eckloniana.
Mercklin’s figure, although somewhat diagrammatic, suggests that the
embryo had been apogamously produced. Over a half-century later
Woronin (1907) found apogamy in the same species.

Farlow (1874) discovered apogamy in Pteris cretica albo-lineata , and
was first to recognize clearly the nature of an apogamous embryo as
distinguished from one resulting from fertilization. He described the
origin of the embryo as an asexual outgrowth from the prothallium. When
the embryo is about to begin its development, the portion of the prothallium
posterior to the apical notch becomes pale, and tracheides appear in the
nearly colourless region. A process, similar to that described by Wigand,
develops from the apical notch. The embryo is now produced on the
ventral surface of the prothallium posterior to the apical region. The leaf

[Annals of Botany, Vol. XXXIII. No. CXXIX. January, 1919.]

IIO

Steil. — Apogamy in Nephr odium hirtipes, Hk.

appears first, then the root, and later the stem. A foot is never formed.
Between the cells of the gametophyte and those of the apogamous embryo
there is no sharp line of distinction. The vascular system of the embryo is
intimately connected with vessels in the prothallium. These characters
described by Farlow for Pteris cretica have been found by other investigators
in a number of apogamous ferns. In the same year Abbot (1874) reported
apogamy in an unidentified fern.

De Bary (1878) extended Farlow’s observations on Pteris cretica and
also tested a large number of other species to determine the extent of
apogamy in ferns. He found it to occur in Aspidium falcatum and
A. Filix-mas var. cristata. The development of the embryo in both these
species is similar to that described by Farlow for Pteris cretica.

Sadebeck (1879) reported apogamy in Todea africana. Leitgeb
(1885) reported it as occurring occasionally in Osmunda regalis and Cerato-
pteris thalictroides. His observations on the two latter species have,
however, never been confirmed. Stange (1887) discovered apogamy in
Doodya caudata , Todea pellucid a, and T. rivularis. Berggren (-1888) de-
scribed it in Nothochlaena distans.

The development of the apogamously produced embryos of Doodya
caudata was investigated by Heim (1896). Since archegonia and antheridia
appear to develop to maturity in this species, Heim believed that fertilization
may also occur. Archegonial and antheridial ‘projections’ are developed
on the prothallia, and these projections produce the apogamous embryos.
As many as thirty projections may be formed on a single prothallium,
but only a few embryos produced will survive.

Bower (1888) discovered apogamy in Trichomanes alatum. Although
spores are ordinarily formed in this species, apospory commonly occurs.
The prothallia thus developed give rise to the apogamous embryos.

Lang (1898) induced apogamy in the following species of ferns, the
prothallia of which were grown under special cultural conditions for a period
of two and a half years : S colop endr him vulgare , Sw., vars. ramulossi-
simum , Woll., and marginale , Nephrodium dilatatum , Desv., var. cristatum
gracile , A! ephrodium Or copter is, Desv., var. coronans , Barnes, Aspidium
aculeatum , Sw., var. midtijidum , Woll., A. angulare , Willd., vars. folio sum
midtifiduni and acutifolium multifidum , A. frondosum , Lowe, A. thyrium ,
Mett., var. nipponicum and var. cristatum, A. Filix-foemiua , Bernh., vars.
percristatum , Cousens, cruciato-cristatum and coronatum, Lowe, and Poly-
podium vtdgare , L., var. grandiceps , Fox. By watering the cultures from
below and keeping them in strong light, Lang believed that apogamy was
induced. He was inclined to think that the high temperature under which
the prothallia were grown may have been a factor in inducing the appear-
ance of the sporophytic structures, although he believed that the prevention
of fertilization was the most important condition.

Steil. — Apogamy in Nefi hr odium hirtipes , Hk, 1 1 1

In all the ferns which Lang placed under these cultural conditions,
excepting Aspidium angular e , Willd., var. acutifolium multifidum^og^my
was induced. He believed that if the prothallia of this variety had been
maintained under the cultural conditions for a longer period of time,
apogamy might have resulted. In all species excepting \ Pcly podium
vulgar e, archegonial projections were produced. From processes that
appeared on the prothallia of Scolopendium vulgar e, S w. , var. ramidossisimum,
Woll., and Nephr odium dilatatum , Desv., sporangia were formed. The
apogamous formation of sporangia in these cases is analogous to the
development of antheridia directly on the fern leaf. A case of apospory
of this nature was later described by Woronin (1907) in Trichomanes
Kraussii. The cultural conditions which Lang maintained were evidently
not uniform, since in every culture some embryos were produced as a re-
sult of fertilization. No control cultures were used by Lang, and, although
he exercised great care in his cultural work, no positive conclusion can
be drawn from his results regarding the actual conditions which induced
apogamy.

In a preliminary note, Farmer. Moore, and Digby (1903) reported
nuclear migrations and fusions in the vegetative cells of the prothallium
of Lastraea pseudo-mas. A diploid nucleus was thus established in some
of the cells by a fusion in pairs of the nuclei of adjacent cells. The
apogamous embryo, according to their description, begins its develop-
ment from cells whose nuclei have the double number of chromosomes,
the latter being acquired as a result of the ‘ irregular ’ fertilization or
4 substitution ’ fusions. Such fusions, as described by these investigators,
are the first to be reported in ferns.

Miss Digby (1905) found no reduction in chromosome number in
the life-history of the apogamous Nephr odium pseudo-mas, Rich., var.
ads tat a , fifty chromosomes being counted in the cells of both genera-
tions. Nuclear migrations were found in 73 per cent, of the prothallia
of the apogamous Nephr odium pseudo-mas, Rich., var. polydactyla , Wills.

Farmer and Digby (1907) later published a more extensive account of
their cytological investigations of apospory and apogamy in ferns. Of the
seven forms studied by them, the following were parthenogenetic and
aposporous : Athyrium Filix-foemiha var. clarissima , Bolton, A. Filix-
foemina var. unco-glomeratum , Stansfield, and Scolopendrium vulgar e, var.
crispum Drummondae. The prothallia of Athyrium Filix-foemina var.
clarissima , Jones, and Lastraea pseudo-mas var. crista ta apospora were
produced aposporously. In the former archegonia were produced, but the
embryo, as also in the latter species, always originated as a vegetative out-
growth of the gametophyte. In Lastraea [Nephr odium) pseudo -mas var.
polydactyla, Wills, and L. pseudo-mas var. polydactyla , Dadds, the prothallia
were produced from spores. Archegonia were never formed, and the embryo

1 1 2 Steil. — Apogamy in Nephr odium hirti'pes , Hk,

in these, as in the two previously mentioned forms, originated as a vegetative
outgrowth.

So far as the nuclear history of apogamous ferns is concerned, that
of the polydactyla varieties is of great interest. Nuclear migrations and
fusions were observed by Farmer and Digby to occur between adjoining
cells posterior to the apical region of the prothallium. From such a fusion
or ‘ irregular fertilization ’ the apogamous embryo originated. In all the
cases of induced apogamy, Farmer and Digby assume that similar migra-
tions and fusions occur previous to the formation of the embryo. This con-
clusion is based not alone on their investigations, but on the observations of
Lang (1898), who found binucleate cells in the prothallia of some of the
ferns in which he believed that he had induced apogamy (his Fig. 2,
PI. VIII). Heim (1896) also figured such cells in the prothallia of Doodya
caudata (p. 338, Fig. 7). Stephens and Sykes (1910) found binucleate cells
in the prothallia of Pteris droogmantiana , which, however, resulted from
a nuclear division not followed by cell division. Although Stephens and
Sykes assumed the occurrence of apogamy in Pteris droogmantiana in
their preliminary report, so far as I am aware no further contribution has
yet appeared dealing with apogamy in this fern.

Farmer and Digby (1907) made a detailed study of the chromosome
number in the apogamous and parthenogenetic species. In Athyrium
Filix-foemina var. clarissima , Bolton, eighty-four chromosomes were counted
in both generations. Ninety chromosomes were found to be present
throughout the life-history of A . Filix-foemina var. clarissima , Jones,
and one hundred were counted in both generations of A. Filix-foemina var.
unco-glomeratum , Stansfield. In each of these cases the number of chromo-
somes present is, they conclude, presumably the sporophytic number. The
nuclei of the prothallial cells of Scolopendrmm vulgare var. crispum Drum-
mondae contain eighty chromosomes, but one hundred were found in the
cells of the embryo. Between sixty and seventy-eight chromosomes —
probably the gametophytic number — were observed in the nuclei of the
aposporous Lastraea pseudo-mas var. cristata apospora. From sixty-four to
sixty-six chromosomes were found in nuclei of the gametophyte of Lastrea
pseudo-mas vars. polydactyla^ Wills and Dadds, and from one hundred and
twenty-eight to one hundred and thirty-two in the sporophytic nuclei. The
double number was, according to their description, established by the
fusions of the nuclei' in the prothallial cells.

Goebel (1905) found apogamy to occur in Trichomanes Kraussii
and Peilaea nivea.

Woronin (1907, 1908) discovered apogamy in Peilaea tenerayP . flavens,
N othochlaena Eckloniana , and N. sinuata. Woronin investigated these cases
and also the apogamy of the species reported by Goebel. Archegonia were
never produced on the prothallia of any of these species, although normal

Steil. — Apogamy in Ncphrodium hirlipes , Hk. 113

antheridia were produced in all cases except Trichomancs Kraussii , in
which they aborted before reaching maturity. Woronin holds that the
Pellaea and Nothochlaena species have become apogamous on account of
the xerophytic conditions under which they live. It is assumed that
such an environment, being unfavourable for fertilization, may have led to
the development of apogamy.

Yamanouchi (1908 c) reported the occurrence of apogamy in Nephro-
dinm molle , Desv., the prothallia of which had been watered from below
and kept in direct sunlight. He had shown that fertilization and sporo-
genesis normally occur in this fern, and hence was certain that the apo-
gamy which he observed had been induced by the cultural conditions.
The apogamous sporophyte is described as having the gametophytic
number of chromosomes, namely from sixty-four to sixty-six. It is to
be regretted that none of the sporophytes thus produced were grown to
maturity. A study of sporogenesis, if spores were formed at all, would
be of especial interest. According to Yamanouchi, the apogamous sporo-
phyte began its development in a comparatively short period after the
prothallium assumed the heart-shaped form and when the archegonia are
ordinarily produced. Hence a long period of time does not appear to
be necessary to induce apogamy, as seemed to be the case in Lang’s
experiments.

Miss Black (1909) has duplicated so far as possible with the same
species the cultural conditions used by Yamanouchi for inducing apogamy
in N ephrodium molle. She also grew the prothallia of Dryopteris stipularis
under the same conditions. Although the prothallia of both species were
watered from below and kept in strong light, they developed to a large size
and produced sex-organs. At no time were sporophytes produced in any
of the cultures so treated.

Mottier (1915) also attempted to show the effect of dry cultural
conditions and strong light on the development of apogamous embryos.
He grew the prothallia of both the species which Miss Black had used,
as well as those of Onoclea Struthiopteris. Mottier also was unable
to induce the appearance of a single apogamous sporophyte. On the basis
of this work and of a study of the normally produced embryo of Nephro-
dium molle , Mottier questions whether Yamanouchi was actually dealing
with an apogamously produced embryo.

Heilbronn (1910) found among the prothallia of a culture of Asplenium
Ruta-muraria prothallia which he identified as those of Cystopteris fragilis .
The latter were isolated, and their further development was studied.
It was observed that in the stronger illumination of summer, embryos were
produced apogamously as outgrowths both of the vegetative cells of the
prothallium and of the sex-organs. Later in the season, when the illumina-
tion was weaker, the projections like those which during the summer formed

I

1 14 Steil. — Apogamy in Nephr odium hirtipes , Hk.

embryos now produced antheridia and archegonia, and sporophytes de-
veloped only as a result of fertilization. The following summer the new
projections again formed apogamous embryos. Heilbronn attributed the
occurrence of apogamy to intense illumination, although he failed to obtain
similar results in some other species placed under the same conditions.
Some differences were observed between the two types of embryos of
Cystopteris fragilis , but it was not determined whether the spores produced
by the apogamously formed sporophytes would produce prothallia of the
normal Cystopteris form, or those of the apogamous form which Heilbronn
distinguished as Cystopteris forma polyapogama. Heilbronn also found
apogamy in Aspidium aculeatum var. cruciato-polydactylum , Jones, and
A. angular e forma grandidens, Moore.

In several instances Miss Pace (1913) found on prothallia, probably of
a species of Osmunda , sporangia similar to those described by Lang (1898).
The prothallia had been grown for a long period, but were not subjected
either to dryness or to strong illumination. She considered the prevention
of fertilization by watering from below to be the cause of the formation
of the apogamous embryos.

Nagai (1914) obtained apogamous embryos of Asplenium nidus avis
when the cultures were lacking in moisture, but he believed that high
temperature and strong light may also be factors in inducing apogamy.

Miss Allen (1911) studied the cytology of Aspidium falcatum , in which
de Bary had discovered apogamy in 1878. According to her description
there is a fusion in pairs of the sixteen cells which ordinarily in the Poly-
podiaceae function as the spore mother-cells. The eight cells produced by
this fusion function as the spore mother-cells. By the nuclear fusion the
double chromosome number is established, but the reduction division
follows the fusion, so that the thirty-two spores which are finally formed
contain the haploid number of chromosomes.

In a preliminary note (Steil, 1915 b) I have reported a course in
Nephr odium hirtipes similar to that described by Miss Allen. P'urther
studies, as will be indicated in what follows, have led me to modify in
certain respects the conclusions which I first formed regarding the cyto-
logical basis of apogamy in this species.

For the past six years I have grown the prothallia of a number of
species of ferns for the purpose of determining the occurrence of apogamy
and of investigating, so far as possible, the cytology of the apogamous
forms. I have reported apogamy in Pellaea atropurpurea , L. (Steil, 1910),
and later (Steil, 1915 a) in P. adiantoidisl J. Sm, Aspidium chrysoloba , A.
tsussimense , and N ephrodium hirtipes , Hk. I have also found it to occur in
Pellaea atropurpurea var. cristata, Trek, P. hast at a, L., Aspidium falcatum
Rockford ian u m , A. falcatum Fortunei , A. falcatum caryotidium , Ptems
sulcata , L., Pteris argyrea , Moore, P ter is Parkeri , and in a number of

Steil. — Apogamy in N ephrodium hirtipes , Hk. 1 1 5

varieties of Ptcris ere tic a (Steil, 1918). Anthcridia are produced on the
prothallia of all the species in which I have observed the development of
apogamous embryos. Archegonia are, however, developed in only a few of
these species. Cytological studies of the apogamous ferns have already
been begun, and in several species the history of the sporogenous cells
appears to be similar to that herein described for N ephrodium hirtipes.

In all the apogamous ferns which have so far been investigated,
antheridia appear to be developed except in Trichomanes alatum and
T. Kraussii . In these two species antheridia never develop to maturity.
In numerous cultures of the prothallia of Pellaea atropurpurea, L., anther-
idia were found by the writer, but under certain cultural conditions they
frequently appear in large numbers. I11 a number of species archegonia are
never produced, in a few they abort, and in still others they are apparently
developed to maturity. Whether fertilization occurs in the latter cases, as
reported by Heim (1896) and Heilbronn (1910) for some of the apogamous
species, is a question that must be left for further investigation.

Materials and Methods.

The reader is referred to my preliminary note on N ephrodium hirtipes
(1915 b) for a brief description of the cultural conditions under which the
prothallia were grown. In the many cultures which have been made since
the discovery of apogamy in this species, no important differences have been
observed in the development of the prothallia or in that of the apogamously
produced embryos.

The spores of N ephrodium hirtipes from which the prothallia were
grown were collected from plants grown in the university greenhouse. Five
of these plants were obtained from the first culture of the prothallia made
December 14, 1913. The others were obtained from different sources.

The rate of growth and the size of the prothallia were affected by the
strength of the nutrient solution, the temperature, the moisture, and the
illumination. Too intense illumination was avoided by shading. The
moisture supply was sufficient to allow fertilization to occur in all of the
numerous non-apogamous species which have been grown under the same
conditions as TV ephrodium hirtipes. The temperature of the Wardian case
in which the prothallia were grown varied from 70° F. in winter to about
1 io° F. in the hottest days of summer. While a o-x per cent. Knop’s
solution was generally used for the prothallia grown on sphagnum, various
strengths of this solution were used and the spores were sown also on the
surface of the liquid medium. Beyerinck’s solution as modified by Moore
(1903) also proved very satisfactory. By tilting the bell-jar^ which were
placed over the uncovered Stender dishes with the growing prothallia, an
abundant supply of oxygen and carbon dioxide was provided.

1 1 6 Steil. — Apogamy in Nephr odium hirtipes , Hk.

So far as possible an attempt was made to check the influence of the
cultural conditions on the development of archegonia and the formation of
embryos of apogamous origin. When spores were sown on soil in different
parts of the greenhouse the prothallia of Nephr odium hirtipes always pro-
duced embryos apogamously. Variations in the illumination, the strength
of the nutrient solution, or the temperature, resulted neither in the produc-
tion of archegonia nor in any essential difference in the manner of formation
of the embryos. A number of species of ferns in which fertilization is
known to occur were also grown in the Wardian case, but they never pro-
duced embryos apogamously under these conditions.

Spores of Asplenium nidus avis and N ephr odium molle obtained
through the kindness of Dr. George T. Moore, Director of the Missouri
Botanical Garden, were sown, and the resulting prothallia were also subjected
to the same cultural conditions under which the prothallia of N ephr odium
hirtipes were grown. In both species antheridia and archegonia were pro-
duced in large numbers and embryos appeared only as a result of fertiliza-
tion. Therefore, my cultural conditions were not such as to induce apogamy
in Asplenium nidus avis , in which it was observed by Nagai (1914), or in
N ephr odium molle \ in which induced apogamy was reported by Yama-
nouchi (1908 c).

In preparing material for cytological study, various fixing agents were
used. By far the best preparations were obtained with the Flemming
fluids. Flemming’s weaker solution gave the best results for the prothallia
and the young embryos ; the Flemming medium solution proved most
•satisfactory for work on the sporogenous cells. Sections were cut usually
five or six microns in thickness. For some of the studies of the sporogenous
cells, sections were made eight or ten microns in thickness. Although a
number of stains were used, Flemming’s triple stain (safranin, gentian violet,
and orange G) gave the best results.

Observations.

The Gametophyte of Nephr odium hirtipes.

The spores of N ephr odium hirtipes usually remain capable of germina-
tion for about a month after they mature, although some of them retain
their germinating power for a much longer period.

The spores germinate within a few days after they are sown. Nothing
unusual was observed in the germination of the spores or in the early stages
of development of the prothallia. The prothallia become typically heart-
shaped (Figs. 1-3, PI. V). Glandular hairs are produced on both surfaces,
especially on the anterior portion and along the margins of the prothallium.
Archegonia are never produced, and antheridia are not formed, as a rule,
under ordinary cultural conditions. Spermatogenesis has not been studied

Steil. — Apogamy in N ep hr odium hirtipes , Hk. 1 1 7

in detail, but, so far as I have observed, it seems normal in every respect.
The antherozoids are actively motile.

Secondary prothallia were readily induced, and these resembled in all
essential respects the primary prothallia, producing, like them, apogamous
sporophytes. I have also found that in some other apogamous species,
including Pellaea atropurpurea , Pteris cretica albo-lineata , and Pteris sulcata ,
secondary prothallia produce apogamously sporophytes.

Numerous attempts were made to induce apospory in Nephr odium
hirtipes by methods which have been described by different investigators to
bring about aposporous development of the gametophyte in other ferns, such
as placing the leaves of young sporophytes in contact with the soil, attach-
ing to the soil leaves and fronds of older plants, placing portions of leaves
on moist soil or sphagnum, and growing prothallia-bearing young embryos
in weak light. So far, only the last method has been successful to a very
limited degree. Occasionally when prothallia with very young embryos
were placed in subdued light, the apical region of the prothallium, frequently
almost colourless grew forward into a long cylindrical or conical process, and
on the new portion it was observed that after the primary leaf had begun
its development as a direct outgrowth of the prothallium, its proximal
portion, instead of forming a lamina typical in form and structure, became
branched and gradually prothalloid. A root, so far as I could determine,
was usually absent in such cases. Fig. 22, Plate V, represents a good
specimen of this kind observed in the cultures. The petiole (p) was cylin-
drical and contained a well-developed vascular bundle (v), shown only in
part in the photograph. No stomata were found on any portion of the
sporophytic growth. The cells (c) in the flattened portion of the structure
next to the terminal part of the petiole were columnar and presented
a regular arrangement. There was a gradual change in the form of these
cells towards the apical region (a) which was already differentiated. A
filamentous portion (/), consisting of a single row of cells, had been produced
from the prothalloid part of the outgrowth. Later an embryo was observed
to begin its development directly behind the apical region (a). Whether or
not such a development of a gametophyte from a sporophyte of this nature
is to be called apospory is a question of definition.

The Sporophyte of N ephrodium hirtipes.

Development of the Embryo. The embryo originates from cells posterior
to the apical notch of the prothallium and on its ventral side. A light-
coloured region frequently appears either in the notch or at some distance
behind it (Figs. 4, 5, 6, 10, n, Pl. V). It is in this light-coloured region that
the embryo is usually formed. The cells of this region usually contain
numerous colourless plastids, but few chloroplasts as compared with the

1 1 8 Steil. — Apogamy in Nephrodium hirtipcs , Hk.

neighbouring prothallial cells (Figs. 7 and 8, PI. V). When prothallia are
grown in weak light a larger proportion develop this light region. An early
stage in the development of the embryo is shown in Fig. 3, PI. V. In this
case only a few small superficial cells of the embryo are visible on the
ventral side of the prothallium. The paler portion, so conspicuous in
the prothallia represented by Figs. 4, 10, and 11, PI. V, is absent in
this instance. Sometimes tracheides appear in the portion of the pro-
thallium just described («, Fig. 10, PI. V), but these are not always
present at so early a stage in the development of the embryo. The pale
region is generally differentiated before the prothalliutn has reached its
maximum size. The growth of the prothallium continues for some time
even after the apical cell of the primary leaf and that of the primary root
have been differentiated.

From numerous sections made of prothallia showing early stages in the
development of embryos, it has not yet been determined whether a single
superficial cell only is concerned in the formation of the embryo as described
by Yamanouchi (1908 c) in N ephrodium molle. The embryo certainly begins
its development very early and even before the cushion of the prothallium
has been formed. The details of this development are reserved for future
investigation.

The apical cell of the leaf of the embryo is differentiated first, then that
of the root, and finally that of the stem. The stem rudiment appears between
the base of the leaf and the prothallium. The root is endogenous. Afoot,
so far as I have been able to determine, is never produced.

As the embryo grows it involves a considerable portion of both the
upper and lower parts of the prothallium. This is shown in Figs. 6 [b and c)
and 11, PI. V. Fig. 12 of the same plate is a dorsal view of the prothalliutn
that is represented in ventral view in Fig. 11. The extent of the tissue
belonging to the embryo can be readily determined from the appearance of
the cells in a stained section. The cells of the embryo are smaller than the
prothalloid cells, and their cytoplasmic contents are much denser. The
nuclei of the embryo are large in proportion to the size of the cells, although
many appear to be no larger absolutely than the nuclei of the gametophyte.
The vascular system which develops in the young embryo grows anteriorly
into the leaf and posteriorly towards the root apex. A vascular strand
also extends into the anterior portion of the prothallium and in the direction
of the apex of the stem.

Multicellular glandular hairs are produced on the young embryo.
Sometimes similar hairs are borne also on the light region in the neighbour-
hood of the notch (Fig. 9, PI. V).

While the leaf usually appears first in the development of the embryo
(Figs. 13, 14, 15), in some cases the root develops before the leaf (Fig. 16.
PI. V). In still other cases the leaf and the root appear simultaneously (Figs.

Steil. — Apogamy in Nephr odium hirtipes , Hk. 119

17-21, PI. V). Sometimes the leaf is developed from the surface of the pro-
thallium (Fig. 19, PI. V), and in a few instances it has been found that leaves
are developed from both surfaces. Occasionally roots were observed to
make their appearance on both surfaces of the prothallium. Secondary
prothallia produce embryos in all essential respects similar to tho^se formed
by the primary prothallia. Large irregular prothallia whose form results
from changes in the intensity of illumination may produce more than one
embryo each (Fig. 24, PI. V, a and b ), and these embryos may develop into
normal sporophytes. Fig. 23, PL V, represents a portion of a prothallium
of irregular form with two embryos, each with a leaf and a root. On another
portion of the same prothallium a third embryo had been produced.

A careful study was made to determine whether nuclear migrations and
fusions similar to those described by Farmer and Digby (1907) occur among
the vegetative cells of the prothallium previous to the development of the
embryo. For this purpose both stained prothallia mounted whole and
stained sections were studied. In not a single instance were nuclear
migrations, nuclear fusions, or binucleate cells observed.

Sporogenesis. After it was discovered that in the sporangium of
N ephr odium hirtipes the chromosome number is doubled in consequence of
incomplete nuclear divisions in the manner described below, it appeared
desirable to make as thorough a study as possible of the whole subject of
sporogenesis. The observations on the sporogenous cells are based on
prepared slides of thousands of sporangia in different stages of development.
Most of the work was checked by a microscopical examination of living
material. The presence of numerous nuclear division figures in the sporo-
genous cells belonging to the generations previous to the spore mother-cells,
in tapetal cells, and in the wall cells of the sporangium, facilitated the counting
of the chromosomes. In the dividing nuclei of cells of all these classes
between sixty and sixty-five chromosomes were counted. The same
approximate number of chromosomes was counted in dividing nuclei of the
gametophyte and the young sporophyte.

The nuclear and cell divisions in the sporangium, preceding the stage
at which eight sporogenous cells are present, are normal in every respect.
At this stage the sporogenous cells are nearly isodiametric, although there
are frequent exceptions, some of them being at times much elongated. The
resting nucleus is large, although not so large as the new diploid nucleus
formed at a later period. The resting nucleus passes through the normal
prophase stages. At this time the tapetum is composed of two layers of
cells. Normal division figures are not uncommon in the tapetal cells and
the sporangial wall cells even, at a later stage.

The metaphases following these prophases are at first normal in
appearance, when observed either from the side or in polar view (Fig. 24,
PL VI). Instead, however, of the metaphases being followed by the

I 20

Steil. — Apogamy in Nephr odium hirtipes , Ilk.

anaphases and telophases in the usual order, a peculiar incomplete nuclear
and cell division now occurs.

In the large majority of cases only a number of the daughter chromo-
somes in the equatorial plate pass to the respective poles of the broad-poled
spindle. In other instances the chromosomes appear to pass but a short
distance towards the poles. The resting nucleus in the former instance will
be either kidney-shaped or dumb-bell-shaped (Figs. 30, 31, PI. VI), and in
the latter spherical (Fig. 26, PI. VI). It is evident from the foregoing that
the new nuclear membrane encloses all the nuclear material which in an
ordinary division is distributed to two daughter nuclei. The new nucleus
so established thus contains the diploid number of chromosomes.

Fig. 25, PI. VI, was made from a longitudinal section of a sporangium.
F'ive of the eight sporogenous cells are shown in the section, and in each
case some of the chromosomes have passed to the poles of the spindle. In
cell a all the chromosomes appear to have passed to the poles, but the next
section of the same nucleus shows many chromosomes between the two
apparently separate groups shown in this figure. Fig. 27 of PL VI shows
a similar but later stage. Only four of the sporogenous cells are shown in
this case. The outlines of the cells are already becoming rounded, which
fact indicates that they are to function as spore mother-cells. The chromo-
somes are beginning to anastomose preparatory to the passing of the
nucleus into a resting condition. The nuclear membrane has already been
formed and encloses therefore the diploid number of chromosomes. Later
stages are represented by Figs. 28, 29, 30, 31, 32, 33, and 34, PI. VI. In
some of the nuclei shown in these figures the nuclear material is beginning
to pass into the resting condition. It appears that occasionally the nucleus
passes into this condition before the nuclear membrane has been formed.
It was impossible, however, to obtain any positive evidence on this point.
It is not difficult to find in a sporangium of N ephr odium hirtipes nuclei of
the different forms described in various stages of synapsis and in the
heterotypic and homotypic divisions. It is certain that the cells with
these nuclei function as spore mother-cells.

During synapsis a large number of the nuclei of the spore mother-cells
are spherical in form. The number of nuclei of the kidney-shaped and the
dumb-bell-shaped types becomes progressively smaller as the spore mother-
cells grow older. Unless the incomplete cell divisions to be described later
progress too far, there is no reason to doubt that many nuclei, at first
irregular in form, later become spherical.

Frequently in the same sporangium spherical nuclei and nuclei of the
irregular forms described are present. Often chromatin material in the
different nuclei of the sporogenous cells in a sporangium is in the same
stage. It appears, from an examination of numerous preparations, that in
some instances the chromosomes in the equatorial plate of the eight-celled

12 I

Steil. — Apogamy in Nep hr odium hirtipes , II k.

stage retain their position in the plate or pass only a short distance towards
the poles of the spindle. Fig. 26, PI. VI, represents a dividing nucleus in
which the chromosomes have passed only a short distance towards the poles.
The distribution of the chromosomes in this case may suggest a polar view
of an equatorial plate stage, but in such a view and at an early stage the
chromosomes present a more compact arrangement. Spindle fibres were
demonstrated to be present in some cases at this time. From an examination
of other sections of the same nucleus, it is probable that neither a kidney-
shaped nor a dumb-bell-shaped nucleus will be formed from such a nucleus.
Frequently a nearly spherical resting nucleus was found in a sporangium,
while adjacent to it was a nucleus of the kidney-shaped type. The
spherical nucleus in this case may have resulted from an incomplete nuclear
division in which the chromosomes of the equatorial plate passed only a
short distance towards the poles.

A number of nuclei in a sporangium become spherical at an early stage,
and some sporangia were found in which the nuclei of all eight of the
sporogenous cells were spherical, and in this case each nucleus was in the
resting condition. Two assumptions can be made in regard to the origin of
such nuclei. The resting nuclei of the first eight-celled stage may npt divide
and function as the nuclei of the spore mother-cells, or they may begin to
divide, but the chromosomes may not pass to the poles. From what has
been stated in regard to the history of the chromosomes in the equatorial
plate, it is very probable that the latter assumption is true. In some
sporangia, as previously stated, all the nuclei are either kidney-shaped or
dumb-bell-shaped, while in other sporangia the nuclei vary from the
spherical to the kidney or dumb-bell forms. It would not, therefore, be
surprising to find a sporangium all of whose nuclei were spherical in form,
even though an incomplete division had occurred in each.

Spindle fibres were in some instances stained with difficulty, and at first
were overlooked. These fibres are shown in Figs. 24, 2.5, 27, 28, 29, of
PL VI. In the cell shown in Fig. 28 a cell plate was already formed
although no nuclear membrane was present. Sometimes the fibres are well
developed, but there is no indication of a cell plate (Figs. 25 and 27, PI. VI).
As the different longitudinal sections of nuclei indicate, spindle fibres are
never present on the convex side of the nucleus. In a number of instances
spindle fibres appeared to be absent even on the concave side of the nucleus.
In some cases, on account of the distribution of the fibres, the plate formed
on the spindle did not extend to the nuclear membrane ( c , Fig. 27, PI. VI).
In the majority of cases, however, the plate extends from the wall of the cell
to the nuclear membrane (Figs. 29-33, VI). In some instances the fibres
are poorly developed or quite absent. This seems to be frequently the case
when the nuclei- are somewhat irregular in form. When spindle fibres are
present a cell plate is often produced and a distinct cell wall is formed later,

122 Steil. — A p agamy in Nephr odium hirtipes, Hk.

extending part way across the cell. Hence when a new wall is produced it
extends frorp. the wall of the cell to the concavity of the nucleus (Figs. 30,
3T 32> and 33, PL VI).

Fig. 32, PL VI. presents some evidence that if spindle fibres are formed
during the division of the nucleus they may sometimes wholly or partially
disappear before cell-wall formation. On the left-hand side of the figure
the new walls are present, but on the other side no indication of such walls
is observed. Fig. 33 was drawn from the same sporangium. Such figures
are very infrequent and suggest that complete nuclear and cell divisions may
occur in rare instances. It would be difficult to conceive how Fig. 33 could
represent the result of a fusion of two sporogenous cells and their nuclei.
The whole figure represents clearly a single cell, and the portions of it have
been produced by an incomplete cell division just described. Such a cell
could be formed from one similar to a , Fig. 25, PL VI.

It appears, therefore, that the eight sporogenous cells undergo not only
an incomplete nuclear division but also in some instances an incomplete cell
division. That nuclear and cell divisions are not completed, except possibly
in very rare instances, was determined by counting the sporogenous cells at
various stages of development. Many spore mother-cells during the resting
stage of the nucleus, synapsis, the heterotypic and the homotypic divisions,
and spores showed evidences of incomplete division (Figs. 33, 34, PL VI, and
Figs. 39, 43, 49, 50, 51, and 52, PL VII). Hence there can be no question
that cell and nuclear divisions rarely, if ever, occur during the first eight-
celled stage of the sporogenous cells.

Except in the sEape of the cell or its nucleus, nothing unusual was
observed in the structure or behaviour of the sporogenous cells after the
incomplete division just described. The nucleus and the cell increase con-
siderably in size, and unless there is a well-developed spindle produced, and
a partial division of the cell occurs, the majority of the cells and their nuclei
finally become approximately spherical. A comparison of the sizes of the
resting nuclei before and after the incomplete divisions shows that they are
considerably larger at the latter stage. While the nuclear material is still in
the form of a reticulum, it recedes gradually from one side of the nuclear
membrane. A continuous spireme appears to be formed as the nucleus
passes into synapsis. Fig. 35, PL VI, represents an early stage in this con-
tinuous spireme thread. The compact synaptic mass that finally appears
pressed against the membrane on one side of the nucleus includes the
nucleolus, which seems to persist during the contraction stage (Fig. 36, PI. VI).
When the spireme emerges from synapsis, radiating portions of the thread
extend to the nuclear membrane on the side opposite that at which the con-
traction took place. During the synaptic period the cytoplasmic portion of
the mother-cell, where the synaptic mass is present, is very thin. After
synapsis the cytoplasm of the mother-cell gradually grows to a nearly

i23

Steil. — Apogamy in Nep hr odium hirtipes , Hk.

uniform thickness. The mother-cells grow considerably while the foregoing
changes are taking place, although they vary much in size at any particular
stage. Fig. 39, PI. VII, is drawn from a flattened spore mother-cell and
hence appears unusually large. The details of chromosome formation were
not followed. In diakinesis (Figs. 37 and 38, PI. VI, and Fig. 39. PI. VII) the
chromosomes were counted, and there were found to be present at this time
between sixty and sixty-five bivalent chromosomes. A multipolar spindle
is formed which becomes bipolar (Figs. 40 and 41, PI. VII). The various
stages in the division of the nuclei of the spore mother-cells were studied, and
in the vast majority of cases the divisions are in every way normal (Figs. 42,
43, 44, 45, 46, PI. VII). Sometimes anaphase figures were found in both the
heterotypic and homotypic divisions with lagging chromosomes (Fig. 42,
PI. VII). During the metaphase of the heterotypic division a few of the
chromosomes pass to the poles while the remainder are still in the equatorial
plate. Between the heterotypic and the homotypic divisions the individual
chromosomes can be readily distinguished (Fig. 43, PI. VII).

During the heterotypic division a granular zone appears in a broad
equatorial plate midway between the daughter nuclei. This zone stains
heavily and is composed of numerous small granules of cytoplasmic material
(Figs. 43, 44, 45, and 46, PI. VII). In the homotypic division the axis of
the spindles may be parallel (Fig. 45, PL VII), oblique (Fig. 46, PI. VII), or
perpendicular to one another, or the axes of the two may lie in the same
line.

As a result of the division of the spore mother-cells thirty-two spores
are produced, each having the reduced number of chromosomes, namely
between sixty and sixty -five. Frequently the chromatin material in each
member of the young tetrad is aggregated at one side of the nucleus and
a clear region appears on the opposite side (Fig. 47, PI. VII). The cells in
the preparation from which the figure was drawn showed no signs of
plasmolysis, and since the same appearance was observed when different
fixing fluids were used, this condition of the nucleus is not likely to have
resulted from the technique employed. There is considerable growth in the
size of the spores before the thick wall is formed about each one (Fig. 48,
PI. VII). Sometimes chromatic material is found in the cytoplasm of the
young spore (Fig. 54, PL VII). The origin of the nuclear material may be
traced to chromosomes left in the cytoplasm during the division of the spore
mother-cell nucleus.

Since a number of sporogenous cells during the eight-celled stage were
found in which the divisions were almost completed, it seemed probable, as
I have already suggested, that at least in some cases such divisions may
occur. A large number of preparations were examined, but no instance of
such a division was found. The cells at different stages were also counted,
and in only two cases observed did it appear that more than eight mother-

124 SteiL — Apogamy in Nephr odium hirtipes , Hk .

cells had been formed in a sporangium. In one sporangium three
undivided mother-cells and six tetrads were found. There must have been
at an early stage, therefore, nine spore mother-cells. One of the eight
sporogenous cells which ordinarily undergo the incomplete division already
described presumably completed its division in this case, and thus the
additional spore mother-cell may have resulted. In one other instance more
than the usual number of tetrads was found in a sporangium. In this case
there were eleven tetrads, six showing evidences of incomplete divisions,
and five of complete divisions. Fig. 53, PI. VII, represents one of the tetrads
with incompletely divided cells. In the plane of the section only one of the
cells and its nucleus indicated that the divisions never had been completed.
However, the other cell and its nucleus showed similarly that incomplete
divisions had occurred. If three of the eight sporogenous cells which as a rule
undergo the incomplete divisions described divided, three additional cells
would be produced. The other five cells would undergo the usual divisions
in the formation of the tetrads ; but six of the cells, it may be supposed,
would show abnormalities in the divisions. From such a single instance it
is, of course, unsafe to draw any positive conclusions. The two sporangia
here described were the only ones which afforded evidence that a complete
division of one or more of the eight original sporogenous cells may
occasionally occur.

Sometimes, on account of the shape of the spore mother-cell and its
nucleus, the chromatin material may be divided during synapsis into two
nearly equal masses. In one instance two nearly distinct chromosome
groups were observed during diakinesis in a dumb-bell-shaped nucleus. As
a result of the usual divisions eight nuclei may be produced. When the
spore mother-cells are kidney-shaped or dumb-bell-shaped, the chromosomes
during the anaphase of the heterotypic division at one or both of the poles
may occasionally be separated into two groups (Fig. 49, PI. VII). The
separation of the chromosomes in this instance is clearly brought about by
the indentation of the mother-cell resulting from the original incomplete
division. Each of the three nuclei represented in this figure may divide
(Fig. 50, PI. VII) and six spores may be formed. Fig. 52, PI. VII, shows
five of the six nuclei which result in such a case. Several metaphase figures
were found in the preparations similar to that shown in Fig. 50, but only
one spore mother-cell containing three anaphase figures was observed
(Fig. 51, PI. VII). That the two smaller division figures represented in the
figure resulted from a division of one of two groups of chromosomes pro-
duced during the anaphase of the heterotypic division cannot be stated with
certainty. When there are two indentations in the spore mother-cell there
might conceivably be produced during the anaphase of the heterotypic
division four chromosome groups, and in consequence of the following-
division eight spores might be formed from a single spore mother-cell. No

I25

Steil. — A p agamy in Nephrodium hirtipes, Hk.

such instances were observed in any of my preparations. Whether such
spores whose nuclei do not possess the normal number of chromosomes have
the power to germinate has not been determined.

The formation of more than four spores from a single spore mother-cell
has been reported in Angiosperms by various investigators. Wille (1886)
gives a summary of the early literature of the subject and reports also his
own discoveries. Strasburger (1892) and Juel (1897) found that the super-
numerary pollen grains of Hemerocallis fidva are produced by the forma-
tion of cells whose nuclei originate from chromosomes which fail to pass to
either pole during the division of the spore mother-cell. Fullmer (1899)
observed in the same species that occasionally some of the nuclei of the
spore-tetrads divide, and that as a result of these divisions additional micro-
spores are produced. Miss Lyon (1898) reported that in Euphorbia corollata
sometimes five or six microspores are produced in place of the usual four
spores of a tetrad. No explanation is given for the presence of the super-
numerary spores in this plant. So far as I know, the formation of more
than four spores from a spore mother-cell has not previously been described
in any of the Bryophytes or Pteridophytes.

Discussion.

In my preliminary note (1915 b) I described cell and nuclear fusions in
the sporangia of Nephrodium hirtipes similar to those described by Miss
Allen (1911) in Aspidium falcatum . Since sporangia of Nephrodium
hirtipes were found containing eight sporogenous cells whose nuclei in some
cases were in prophases and in other cases in metaphases, it seemed that the
completion of the divisions must result in the formation of sixteen sporo-
genous cells in each sporangium. In older sporangia figures were found
which seemed to show that these sixteen cells were fusing in pairs. The
presence of thirty-two spores in each sporangium, evidently produced by the
division of eight spore mother-cells, apparently confirmed this conclusion.
However, a later and more extended study of additional preparations, which
contained an abundance of division figures, has shown that the divisions
first initiated at the stage of the eight sporogenous cells arc never or very
rarely completed ; that these incomplete divisions result in irregular cell
and nuclear forms, as well as in the partial division of the cells by cell-plates
or walls, which were first interpreted as evidences of cell fusion ; and that
the result of these incomplete divisions, as indicated in what precedes, is
a doubling of the number of chromosomes in each of the eight cells which
then proceed to function as spore mother- cells. A later examination of my
older preparations shows, as a matter of fact, that they contain very few
earlier stages in incomplete nuclear and cell division, and hence the most
important evidence on the history of the sporogenous cells was not at first
obtained.

126 Sfeil. — Apogamy in Nephr odium hirtipes , Hk.

Miss Allen’s figures of the sporogenous cells of Aspidium falcatum are
so similar to many of those which I have obtained in Nephr odium hirtipes as
to make it seem probable that a further study of the former species may
show that in it also the divisions first initiated at the stage of the eight sporo-
genous cells are, except in very rare cases, never completed. Her Fig. 44,
PL III, representing an early stage in fusion, may be interpreted as showing
a completed nuclear division and a nearly completed cell division, and if
this be a correct interpretation the division shown in this case has progressed
farther than any I have observed in N ephrodium. However, in some instances,
as in Fig. 33, PL VI, my preparations show a near approach to a complete
division of the cell and its nucleus.

In three cases Miss Allen found more than eight spore mother-cells in
a sporangium of Aspidium falcatum. The larger number of spores was
accounted for by the failure of some of the sporogenous cells to fuse in pairs.
In two instances I found that more than eight sporogenous cells must have
been produced in a sporangium of N ephrodium hirtipes . If in these
instances any of the sporogenous cells complete their divisions, more than
eight spore mother-cells will be formed. No evidence has been presented
by either Miss Allen or myself to indicate that the spore mother-cells which
do not possess the diploid number of chromosomes have the power to
divide. Six of the eleven tetrads found in a single sporangium of Nephro-
dium (Fig. 53, PL VII) showed that abnormalities had occurred in the
division of the mother-cells, which, as has been previously suggested, may
have been produced from sporogenous cells that completed their divisions
and hence did not have the diploid number of chromosomes. Since more
than four spores are sometimes produced from a single spore mother-cell of
N ephrodium hirtipes , no conclusion can be drawn from the number of spores
in a sporangium in regard to the possibility of the division of the super-
numerary spore mother-cells. It is evident, however, that spores may be
formed with nuclei which have not received the haploid number of chromo-
somes (Figs. 50, 51, and 52, PL VII).

The formation in many instances of a spindle, and not seldom of
a cell plate extending part way across the cell, and the distribution of the
chromosomes from the equatorial plate exclude the possibility that the
irregular nuclear figures which I have found in the eight sporogenous cells of
Nephrodium hirtipes can in any case represent amitotic division. Amitosis,
also, cannot occur at any later stage, since in such a case more than thirty-
two spores would then be produced.

In apogamous ferns three cases have been reported in which ‘ substitu-
tion fusions ’ are thought to occur — that is, fusions of cells (or nuclei) other
than those which are morphologically gametes, by means of which the
diploid number of chromosomes is established. In the two Lastraea varieties
studied by Farmer and Digby (1907), in which the fusion is between nuclei

Steil. — Apogamy in Nephrodium hirtipes , Hk. \ 2 7

of two vegetative cells of the prothallium, the haploid number of chromo-
somes characterizes the gametophyte, the diploid number the sporophyte.
In Aspidium falcatum , in which according to Miss Allen (1911) the fusion
is between sporogenous cells, chromosome reduction immediately following,
the haploid number of chromosomes is characteristic of both generations.
So far as the chromosome number is concerned the same condition prevails
in Nephrodium hirtipes as in Aspidium falcatum.

The chromosome number in other apogamous ferns, so far investigated,
is of interest. As a result of induced apogamy in Nephrodium molle ,
according to Yamanouchi (1908 a, b, and c) the haploid number is found in
both the gametophyte and the sporophyte. Farmer and Digby (1907)
think that in Lastraea pseudo-mas var. cristata apospora both generations
possess the haploid number of chromosomes. On the other hand, the same
investigators found that in Athyrium Filix-foemina var. clarissima, Jones, the
diploid number of chromosomes persists throughout both generations. Thus
it appears from the studies so far made of apogamous ferns, as well as by
evidence from other groups of plants, that the characteristic differences
between gametophyte and sporophyte are not determined alone by differ-
ences in the chromosome number, but that the sharply contrasted develop-
mental possibilities of spore and zygote are governed by other factors
which are as yet entirely unknown.

Apogamy in ferns developed in all probability at a late period in the
evolution of the homosporous ferns. So far no certain case of apogamy has
been discovered in the Eusporangiatae. Jeffrey (1896), however, believed
that he found in one instance evidence of apogamy in Botrychium virgini-
anum. A large number have been found among the Polypodiaceae, the
most highly specialized, and probably the most recent, homosporous lepto-
sporangiate family.

In regard to the origin of apogamy in Nephrodium hirtipes three
possibilities are presented. If at one time in the life-history of the fern
fertilization was by some means suppressed, the archegonia may have
disappeared and fertilization have thus been rendered impossible. The
embryo may then have arisen as a vegetative outgrowth. As a substitution
for fertilization the incomplete divisions described in this paper may have
occurred. Why a doubling of the number of chromosomes should still
be necessary for the maintenance of the life-cycle is difficult to explain,
since, as has just been stated, in Lastraea pseudo-mas var. cristata apospora
the haploid number of chromosomes remains unchanged throughout both
generations, and although Yamanouchi (1908) did not investigate sporo-
genesis in the apogamously produced sporophytes of Nephrodium molle , it is
probable that the gametophyte number is maintained in both generations of
the fern.

On the other hand, the occurrence of incomplete nuclear divisions

128 Steil. — Apogamy in Nep hr odium hirtipes , Hk.

in the sporangium of N ephr odium hirtipes may have preceded the appear-
ance of apogamy. If the number of chromosomes was not at first reduced,
the act of fertilization was rendered unnecessary, and hence the embryo may
have arisen at first parthenogenetically and later apogamously. If the
latter view is held, the double number of chromosomes would be present
throughout the life-history. However, on the basis of other investigations
of different apogamous species, it is probable that the chromosome number
now characteristic of both generations of Nephrodium hirtipes is the original
haploid number, and hence it seems likely that apogamy may have arisen
before the incomplete nuclear divisions were established. These views
regarding the origin of apogamy are similar to those expressed by Miss
Allen (1911) with reference to Aspidium falcatum .

Although so far no cytological evidence has been presented to confirm
the occurrence of hybridization in ferns, it is possible that N ephr odium
hirtipes and perhaps some other apogamous ferns may be of hybrid origin,
and that the abnormalities which I have described have resulted from
fertilization between two more or less closely related species.

Summary.

1. The prothallium of Nephrodium hirtipes is produced by the
germination of a spore.

2. The gametophyte never produces archegonia, but antheridia are
formed which develop apparently normal antherozoids.

3. The development of secondary prothallia is readily induced by
cultural conditions.

4. Attempts to induce an aposporous gametophyte development in
this species have been successful only in rare instances.

5. The embryo originates at an early stage in the development of
the gametophyte as a vegetative outgrowth of the prothallium. The apical
cell of the leaf is first formed, and then that of the root, and later that of the
stem. A foot is never produced. The later stages in the development of
the embryo resemble those of the ordinary fern embryo produced as
a result of fertilization.

6. At no time have nuclear migrations and fusions been observed
to occur in the prothallium when the embryo begins its development.

7. At the stage when the sporangium contains eight sporogenous
cells, an incomplete nuclear and cell division occurs in each of these
eight cells. As a result of the incomplete divisions, each nucleus con-
tains the diploid number of chromosomes — between 120 and 130. The
eight sporogenous cells, now diploid, function as spore mother-cells. The
spores formed from these cells have the haploid number of chromosomes —
between 60 and 65 — and this number is retained in the cells of both the
gametophyte and of the apogamously developed sporophyte.

129

Steil. — Apogamy in Nephrodium hirtipes , Hk.

8. Thirty-two spores are ordinarily produced in a sporangium of
Nephrodium hirtipes . The smaller number of spores which sometimes
occur is to be accounted for by abnormalities in the nuclear condition of the
spore mother- cell.

9. A larger number than thirty-two spores is sometimes produced
by the formation of more than four spores from a single spore mother-
cell. In rare instances more than eight spore mother-cells appear to be
produced in a sporangium. Whether in such a case all the spore
mother-cells can form normal tetrads and spores has not been deter-
mined.

To Professor C. E. Allen I wish to express my thanks for helpful
suggestions and criticisms received during the progress of the foregoing
investigation.

Bibliography.

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401-2.

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K

1 3°

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(1915 b) : Apogamy in Nephrodium hirtipes. Bot. Gaz., lix. 254-5.

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— - 7 : — (1908 c): Apogamy in Nephrodium. Ibid., 289-319.

EXPLANATION OF PLATES V-VII.

Illustrating Dr. W. N. Steil’s paper on Apogamy in Nephrodium hirtipes.

The photo-micrographs on Plate V represent different magnifications. The young sporophytes
from which photographs 13-21 and 23 were made are magnified about 2J diameters. The figures on
Plates VI and VII, excepting 29, 30, and 31, were drawn with a Zeiss compensating ocular No. 12,
and apochromatic objective, 2 mm. N. A. 1.30, at table level with the aid of a camera lmrda. With
a tube elongation of 142 mm. a magnification of about 2,150 diameters was obtained. Figs. 29, 30,
and 31 represent a magnification of about 1,250.

PLATE V.

Fig. 1. A dorsal view of a young prothallium.

Fig. 2. A dorsal view of a young prothallium just before the embryo becomes visible.

Fig. 3. An older prothallium, viewed from the ventral side. The small dark region posterior
to the apical notch represents the outer cells belonging to the young embryo.

Fig. 4. A dorsal view of a highly magnified portion of a prothallium. The embryo is visible as
a compact area in the paler portion.

Fig. 5. A dorsal view of an older embryo.

Steil. — Apogamy in Nephr odium hirtipes , Hk. 131

Fig. 6. Dorsal views of three prothallia at different stages of development. Paler portion ot
the prothallium produced before the embryo appears shown in a. In both b and c light areas and
young embryos shown.

Fig. 7. A highly magnified view of a small portion of a ‘ light f region.

Fig. 8. A highly magnified view of a small portion in the neighbourhood of the light region.

Fig. 9. A highly magnified portion of the apical region of a prothallium after the embryo has
begun its development, h, multicellular hair.

Fig. 10. A portion of a prothallium showing the apical region and tracheides, t , in paler
portion.

Fig. 1 1. A highly magnified view of a prothallium, dorsal view. multicellular hair produced
on young embryo.

Fig. 12. Ventral view of the same prothallium.

Figs. 13, 14, 15. Young embryos with leaves developed in advance of the roots.

Fig. 16. An embryo with a root produced in advance of the leaf.

Fig. 17. Embryo with leaf developed on the dorsal side of the prothallium.

Fig. 18. An embryo whose root and leaf have grown to about the same length.

Figs. 19, 20. Young embryos. Leaves in advance of the roots.

Fig. 21. An embryo with three leaves.

Fig. 22. A prothallium obtained from a young embryo when a culture was placed in weak
illumination. petiole-like portion of a leaf; c, flattened outgrowth with elongated cells ;

a, apical region of gametophytic portion ; f filament.

Fig. 23. A prothallium on which three apogamously produced embryos were formed. Two of
these are shown in the photograph.

PLATE VI.

Fig. 24. Equatorial plate of the eight-celled stage of the sporogenous cells.

Fig. 25. Five of the eight sporogenous cells drawn from a longitudinal section of a sporangium.
In the dividing nuclei some of the chromosomes have passed to the poles. Spindle fibres present.

Fig. 26. A dividing nucleus of one of the eight cells. The chromosomes have not passed to
the poles.

Fig. 27. Four of the eight sporogenous cells drawn from a longitudinal section. The chromo-
somes are beginning to lose their identity c, clear region where no spindle fibres are present ;
a, nuclear membrane encloses in each cell the diploid number of chromosomes.

Fig. 28. Some of the chromosomes have passed to the poles. Spindle fibres and cell-plate
present.

Fig. 29. A later stage. Spindle fibres and cell-plate shown on the concave side of the nucleus.

Fig. 30. A kidney-shaped nucleus. A wall has been produced on the concave side of the
nucleus.

Fig. 31. A dumb-bell-shaped nucleus. Wall shown extending to the concavity of the nucleus.

Fig. 32. A dumb-bell-shaped nucleus. Cell division has progressed still farther than in the
preceding stage. Cytoplasm on one side of the nucleus divided into two distinct portions, and
a partial separation of the latter has resulted.

Fig 33. A dumb-bell-shaped nucleus. There was produced in this case a nearly complete
nuclear and cell division.

Fig. 34. A kidney-shaped nucleus. The cell is beginning to round up. The indentation on the
left-hand side of the figure is the result of incomplete cell division.

Fig. 35. A spore mother-cell whose nucleus is preparing for synapsis.

Fig. 36. The nucleus of the spore mother-cell just emerging from synapsis.

Figs. 37 and 38. The chromosomes during diakinesis. Fig. 37 represents an early stage.

PLATE VII.

Fig. 39. A much flattened spore mother-cell at the same stage as represented in Fig. 15.
Indentation shown on one side as a result of incomplete cell division.

Fig. 40. The heterotypic division. Spindle, multipolar.

Fig. 41. Equatorial plate stage of the heterotypic division. Spindle bipolar.

Fig. 42. An anaphase of the heterotypic division. Some lagging chromosomes shown.

132 Steil. — Apogamy in Nephr odium hirtipes , Ilk.

Fig. 43. A telophase stage of the heterotypic division. Granular zone present.

Fig. 44. Metaphases of the homotypic division. Spindle multipolar.

Figs. 45 and 46. Anaphase stages of the homotypic division.

Fig. 47. A young tetrad. A clear region on one side of the nucleus.

Fig. 48. An older tetrad.

Fig. 49. An anaphase stage of the heterotypic division, showing how one of the two sets of
chromosomes may be divided into two groups.

Fig- 5°- A metaphase stage following tho stage represented by Fig. 26.

Fig. 51. An anaphase stage.

Fig. 52. A spore mother-cell from which six spores have been produced, five of which are
shown in the figure.

Fig. 53. A tetrad, the members of which have been incompletely divided.

Fig. 54. Two young spores of the same tetrad. Chromatin material in the cytoplasm.

Jlrmals of Botany,

W.N. STEIL— NEPHRODIUM HIRTIPES.

voi. xxxm,. vi.v.

Huth colL

W.N.STEIL — IMEPHRODIUM HIRTIPES

VolJXm.PL.Vl r

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NOTE

THE WOOD OF TETRACENTRON, TROCHODENDRON, DRIMYS, AND
OTHER TYPES. — Messrs. Bailey and Thompson in their paper published in the
Annals of Botany, October, 1918, erroneously attribute to me an expression of the
view that Tetracentron is descended from a form that possessed wood-vessels which
have been lost in subsequent evolution. In my paper (Annals of Botany, xxiv, 1910)
to which they refer, I merely ventured to suggest and supply evidence in favour of
the possibility that the tracheidal structure of the wood of this and certain other
genera might represent cases of degeneration from a previous tracheal condition.
I then thought, as I still think, that the information available in regard to these
anomalous Angiosperms is not sufficient to render possible a decision in favour of
either of the two phylogenetic explanations of their wood-structure.

PERCY GROOM.

[Annals of Botany, Vol. XXXITI. No. CXXIX. January, 1919.]

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CONTENTS.

PAGE

DlGBY, L. — On the Archesporial and Meiotic Mitoses of Osmunda. With Plates VIII-XII

and one Figure in the Text 135

Arber, the late E. A. Newell. — Remarks on the Organization of the Cones of

Williamsonia gigas (L. and H.). With five Figures in the Text .... 173

Haines, F. M. — A New Auxanometer. With two Figures in the Text . . . .181
Spratt, Ethel R. — A Comparative Account of the Root-nodules of the Leguminosae.

With Plate XIII and five Figures in the Text . 189

Tuttle, Gwynethe M.— Induced Changes in Reserve Materials in Evergreen Herbaceous

Leaves. With seven Figures in the Text 201

Arber, Agnes. — On the Law of Age and Area, in Relation to the Extinction of Species . 21 1
Carter, Nellie. — Studies on the Chloroplasts of Desmids. I. With Plates XIV-

XVIII 215

Holmes, M. G. — Observations on the Anatomy of Ash-wood with Reference to Water-

conductivity. With seven Figures in the Text . . . _ .— . . *255

NOTE.

Phillips, R. W. — Note on the Duration of the Prothallia of Lastraea Filix-mas, Presl. 265

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On the Archesporial and Meiotic Mitoses of Osmunda.

BY

L. DIGBY.

With Plates VIII-XII and one Figure in the Text.

Introduction.

/<0

V

^soman

JUN

!f,'onal

THE sporogenous tissue of Osmunda has been a favourite object for
cytological study ; not only is it often used for class demonstra-
tion, but many cytologists have chosen it for critical examination, and the
resulting literature is conflicting in its conclusions. The large size of the
nuclei and the remarkably clear and well-defined character of the division
figures suggest, on a superficial survey, an easy solution to some of the
more complex problems connected with karyokinesis, but, on closer inspec-
tion, it will be found that, although the general landmarks of nuclear
division are certainly strikingly portrayed, yet factors £xist which make
the elucidation of the deeper controversial questions exceedingly difficult.

In the first place, the arrangement of the sporangia affords no clue as
to the stages of nuclear division in their contained archesporial or spore
mother-cells, whereas in many tissues the position of the nuclei is a useful
guide in identifying the sequence of the individual phases. For instance,
longitudinal sections of anthers generally show the nuclei near the base to be
slightly less advanced than those near the apex, and those more centrally
placed to be in an intermediate stage ; whilst in transverse sections the two
outer loculi may be seen to be in advance of the two inner ones, and of each
respective pair one loculus may be slightly ahead of the other in the pro-
gress of nuclear division. Osmunda , on the other hand, gives no such lead,
for contiguous sporangia may present widely separated stages. Matters
are further complicated owing to the exceeding rapidity with which some of
the most critical stages are passed through. Probably others have had a
similar experience to that of the writer, and have been baffled year after year
in the attempt to elucidate the origin of the heterotype chromosomes owing
to the elimination of certain particular phases in the available material which
have ultimately proved to be the key to the problem. And lastly, Osmunda
is difficult to fix satisfactorily. It is simple to achieve a somewhat flashy
hard fixation which displays familiar stages well, but it is unsatisfactory for
those of crucial importance such as post-synapsis and pre-second con-
traction.

[Annals of Botany, Vol. XXXIII. No. CXXX. April, 19x9.]

Digby . — On the Archesporial and

136

Methods.

After several seasons of repeated failures, Professor Farmer suggested
the simple expedient of immersing the material in warm, weak spirit before
placing it in the fixing fluid. This method proved to be a brilliant success,
and the ensuing fixation was beautiful, with no apparent contraction or
distortion.

Fixing was done exclusively on warm ‘ growing * days at about noon.
Small portions of the sporangiferous apex of the frond were plunged for
a few seconds in warm (about 30° C.) 30 per cent, spirit. They were
then speedily transferred to fixing fluid at the same temperature. A
vacuum pump was attached to the bottle, but the material generally sank
immediately without pumping. Rapid infiltration of the fixing fluid is
apparently the secret of this almost perfect fixation. Wilson Smith (18) also
tried moistening young sporangia in alcohol before placing them in the
‘ killing’ fluid, but, although they sank at once, he reports that the fixation
was so poor that they were useless for purposes of study. He does not
mention the strength of the alcohol, nor whether it was warmed.

The fixing reagents used in this investigation were strong Flemming,
weak Flemming, strong Merkel, Hermann, strong chromic, and acetic
alcohol. With acetic alcohol rapid penetration of the fixative occurs with-
out the preliminary alcohol bath, but it is not a sufficiently fine fixative
for critical examination. The tissue was left 15 minutes in acetic alcohol
and then washed well with methylated spirit, or preferably with absolute
alcohol. In the case of the other fixatives, the material was kept in the
fluid until the following morning and then washed for four hours in running
water. It is most important that the sporangia should not be submitted to
any sudden change throughout the subsequent processes to the final
embedding in paraffin wax. The material was therefore either put into
10 per cent, glycerine and evaporated slowly to pure, or it was run up by
a continuous dropping method devised by Mr. Tabor into absolute alcohol.
Cedar-wood oil was found to be the most satisfactory clarifying reagent.
After several changes of absolute alcohol, the oil was pipetted into the
bottom of the bottle, and the material from floating in a layer of absolute
alcohol became gradually impregnated by the oil and sank. After a change
into fresh cedar-wood oil the bottle was placed in the embedding oven and
shavings of paraffin wax gradually added. In an hour the material was
transferred to pure paraffin. Four hours in melted paraffin, with three
changes gave excellent results. Most of the sections were cut at 3 [x , as it
was found that the thinnest sections were the most useful for critical
phases.

A variety of stains have been used, but of these Breinl, Flemming’s triple,
Heidenhain, gentian violet and orange, proved to be the most useful.

Meiotic Mitoses of Osmunda. 137

This investigation includes several species of Osmunda which have been
severally minutely examined. The greater number of the drawings have
been made from the nuclei of 0. palustris var. aurea , but nuclei of other
species have been intercalated when they showed any one particular phase
more clearly. The plates therefore comprise figures of O. palustris , O. palus-
tris var. aurea , 0. palustris var. undulata , and 0. regalis.

The plants have been most successfully grown in greenhouses at the
Chelsea Physic Garden under the personal care of Mr. Hales, the Curator,
to whom I am greatly obliged.

The following nomenclature will be adopted throughout the paper :

The term ‘ thread ’ will be used to specify the longitudinal half of an
entire univalent spireme or chromosome which first appears during telo-
phase. The two £ threads ’ or halves separate during telophase, and reasso-
ciate during the ensuing prophase, forming an entire univalent spireme or
‘ filament’ which eventually becomes an entire univalent chromosome. The
term ‘ filament ’ will be used to specify the entire univalent spireme, the
product of the close lateral association of two threads (i.e. of two longitu-
dinal halves of univalent spireme). The term c strands * will be used to
describe the very fine strands of linin that connect the several chromosome
segments of early telophase, also those which serve as fine transverse
Connexions between the individuals of a pair of associating and dissociating
threads, and between the individuals of a pair of conjoining and disjoining
filaments.

The terms ‘ association ’ or f approximation • will be confined exclusively
to the coming together, laterally, in pairs of the ‘ threads ’ (i.e. of the two
longitudinal halves of the univalent spireme) to form the entire univalent
spireme, which becomes the entire univalent chromosome ; the terms ‘ con *
junction ’ or ‘ conjoining ’ to the coming together in pairs of the ‘ filaments’
(i. e. of the two entire univalent spiremes) to form the bivalent spireme which
becomes the bivalent chromosome.

The terms ‘ fission * or ‘ dissociation ’ will be restricted to the longitudinal
splitting of the ‘ filament ’ (he. of the entire univalent spireme) into ‘ threads ’
(i.e. into half univalent spiremes) and to the splitting of the entire univalent
chromosome into daughter chromosomes ; the term 5 disjunction ’ or ‘ disjoin -
ing ’ to the separation of the two conjoined ‘ filaments ’ (i. e. to the separation
of the bivalent spireme into two entire univalent spiremes) and to the
separation of the bivalent chromosome into the two entire univalent
chromosomes.

Archesporial Divisions.

Probably all cytologists are agreed that the constitution of each indi-
vidual chromosome is one of duality, and that this dominating feature usually
persists throughout the cycles of chromosome construction and dissolution

M 3

138

Digby. — On the Archesporial and

which constitute nuclear mitosis. This double character is apparent more
or less continuously, except during the ‘ rest ’ which may intervene between
successive nuclear divisions, when it may become temporarily obscured. It
is represented by paired threads, by paired beads, and by paired segments
of spireme. In order that this duality may be clearly appreciated, it is pro-
posed to trace its course briefly before commencing the detailed description
of a somatic division (see Text-fig., Nos. 1-8).

If a nuclear division be examined at late anaphase or telophase it will
be seen that the individual daughter chromosomes, which have recently
separated on the equatorial plate, show fission in varying degrees, thus
tending to divide their substance into longitudinal halves (threads). As the
newly-formed nuclei prepare to pass into rest the sides or halves (threads) of
the chromosomes become beaded, with lengths of linin between the beads.
The sides gradually separate from one another and the beads become
resolved into ever finer granules, until in complete rest a state of more or
less even reticulum is reached. In some plants there is no such thorough
chromosome dissolution, and portions of split chromosomes may persist and
thus establish visible continuity between anaphase and prophase. During
prophase the series of events is reversed, and the chromosome halves
(threads) which separated during the preceding telophase approach one
another, forming parallel groupings of granules and parallel threads. The
space between each pair of associating parallels becomes the future line of
fission. When association is consummated in the realization of the com-
pleted chromosome, each chromosome opens out and splits into longitu-
dinal halves on the equatorial plate of the spindle, and each half becomes
a daughter chromosome. The daughter chromosomes proceed to the poles,
and thus the cycle is completed.

Such is the scheme of a typical somatic mitosis, and it will be shown
later how this simple procedure is elaborated in the heterotype division.
Occasionally, as in Primula (4), a modification occurs, owing to the longi-
tudinal halves (threads) of the chromosomes tending to hold together,
instead of to separate. Accordingly, the entire chromosome in telophase
inclines to break up transversely into beads or segments, instead of to split
into two parallel threads. When the nucleus enters upon prophase, the
chromosomes are reorganized by the entire univalent segments co'ming
together again end to end like a string of beads.

The archesporium has been selected for the study of vegetative divi-
sions, and the description of the cycle of phases passed through by a nucleus
will commence with the anaphase. This is a clearly defined stage with the
daughter chromosomes newly arrived at the poles, and thus affords a good
starting-point whence to trace the dissolution and subsequent reconstruc-
tion of the chromosomes.

The daughter chromosomes, having arrived at the spindle poles, at first

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139

Meiotic Mitoses of Osmund a.

show little or no sign of fission (PL VIII, Fig. i) ; but before the nuclear limit-
ing membrane makes its appearance, and whilst the chromosomes, as seen
from a polar view, are still arranged in a rosette, they show marked fission
throughout their substance (Fig. 2). Sometimes the sides (threads) are
homogeneous, sometimes they are beaded. By the time that the nucleus is
bounded by a membrane some of the chromosomes have begun to lose their
visible identity ; the split widens, and the chromatin tends to separate out
along the fine connecting strands that join the several chromosome segments
(Fig. 3). When the chromosome halves (threads) are practically resolved
into small beads, the skeleton of each quondam chromosome is presented as
a cloudy area which, in spite of its haziness, still reveals traces of its double
character (Fig. 4). This appearance is difficult to reproduce faithfully in
a drawing, but it is very characteristic of late telophasic stages. The hazi-
ness gradually diffuses throughout the nucleus, owing to the spreading of
the beads or granules (Fig. 5), until there results a faint reticulum with the
chromatin almost entirely concentrated in the nucleoli, of which there may
be three or more (Fig. 6). This is the so-called ‘ rest 1 which probably
intervenes between each successive vegetative division.

It may be difficult to discriminate between the phases of nuclei going
into, from those coming out of, rest and entering upon prophase. They can,
however, usually be distinguished by (1) the gradual blurring of the nuclear
contents as the nucleus passes into rest, owing to the fragmentation of the
chromatin into finer and finer granules as compared to the sharper definition
and generally more active appearance exhibited by nuclei in the onset of
prophase ; (2) the position of the recently laid down cell-wall between the
daughter nuclei. In telophase the nuclei are more or less apposed to the
cell-wall, and in a microscopical field of this stage the several pairs of nuclei
can as a rule be recognized, whereas in prophase the daughter nuclei move
away from the dividing wall towards the centre of the cell.

The earliest indication of the inception of prophase is to be seen in the
more active appearance of the nuclei and in the presence of a few large
chromatic granules in the reticulum (Fig. 7). The reticulum is very distinct,
particularly when stained with Heidenhain (Fig. 8), it having chromatic
granules scattered throughout the meshwork, with here and there larger
chromatic aggregations. The granules are at first distributed throughout
the nucleus, and they then incline to cluster (Fig. 9) and are of varied sizes
(Fig. 10). Simultaneously the reticulum gradually passes into a spireme
thread.*

At this stage the linin threads, containing the beads of chromatin
situated at intervals along their lengths, tend to run in parallel pairs ; this is
the inception of chromosome formation. The parallelisms represent the
reassociation of the longitudinal chromosome halves (threads) which had
separated during the preceding telophase. As prophase advances, the two

140

Digby. — On the Arckespoj'ial and

threads associate more and more closely and concentrate, and thus gradually
constitute the entire univalent spireme (filament) which eventually segments
transversely into the univalent chromosomes. The approaching threads are
precisely similar, even to the correspondence of their beading. Later it will
be seen that this same phenomenon is exhibited by the threads or asso-
ciating halves of univalent spireme in the presynaptic and synaptic phases
(PI. IX, Figs. 41 and 46) and by the filaments or conjoining entire univalent
spiremes in the stages preparatory to second contraction (PL X, Fig. 69).

The linin threads become increasingly distinct, and the chromatic beads
more definitely arranged, often forming groups of four (PL VIII, Figs. 12
and 13). Gradually the chromatin infiltrates the linin threads, causing them
to stain chromatically (Figs. 14 and 15). Lengths of threads become
closely apposed in pairs (Fig. 16), and the several paired portions (fila-
ments) incline to segregate in a form suggestive of the future individual
chromosome segments. In some of these paired segments (filaments) the
two sides (threads) may be still beaded and separate for a distance, then
becoming closely associated to form a thickened rod — the future chromo-
some (Figs. 17 and 18). Fine strands still connect the various segments.
In the next stage there is an almost complete approximation of the parallel
sides (threads) (Fig. 19); the space between them, when visible, is to be
distinguished as the line of fission which will separate the daughter chromo-
somes on the approaching spindle. The spireme filaments, i.e. the entire
univalent spiremes formed by the association of threads in pairs, are some-
what slight and curve and twist, and the chromatin is evenly diffused
throughout their lengths. In some of the nuclei the fission is more evident
than in others (Fig. 20).

As the nuclei approach the spindle stage, the filaments become
increasingly individualized as chromosomes ; one or two nucleoli may still
persist. Spindle fibres appear in the cytoplasm and converge towards the
nucleus from four points (Fig. 21). These phases are evidently exceedingly
quickly passed through, and even in two adjacent nuclei one of them may
be in a stage such as shown in Fig. 19, while the other maybe in metaphase.
With the disappearance of the nuclear membrane, and the invasion of the
spindle fibres, the chromosomes concentrate and consequently thicken, and
vestiges only of fission can be discerned (Fig. 22). In the process of arrang-
ing themselves on the spindle (not figured) the chromosomes are still
elongated, but when adjusted they speedily thicken and stain deeply
(Fig. 23). The line of fission then opens out and separates each chromo^
some into its daughter halves, and these recede to their respective poles
(Fig. 24). In anaphase (Fig. 1) there is little visible indication of the
separation of the halves (threads), preparatory for the next division, inasmuch
as fission does not appear until late anaphase or early telophase (Fig. 2).
This feature contrasts with the spindle figures of the homotype, where fission

Meiotic Mitoses of Osmundct . 141

in the daughter chromosomes is very strongly pronounced directly they have
separated on the equatorial plate (PI. XI, Fig. 95). The chromosomes group
themselves at the poles (PI. VIII, Fig. ]), and thus the cycle is completed.

Humphrey (12) describes ‘ Centrospharen’ in connexion with the division
figures of O. regalis , but they have not been seen in this investigation.

Telophase of the Last Archesporial Division.

In order to interpret the critical and debated phenomena of the hetero-
type prophases the investigation must be started from the telophase of the
preceding archesporial division. It is, however, remarkably difficult to
decide whether the archesporial nuclei of any one particular sporangium are
in telophase of actually the last division before the onset of the heterotype
prophase. The growth of the tapetum is not a reliable guide, consequently no
correlation can be established between the number of thetapetal layers and
the development of the archesporial tissue, or of the subsequently formed
spore mother-cells. Matters are further complicated by the rapidity with
which the telophase is apparently passed through, because exceedingly few
cases can be found which, after critical examination and weighing of all
available evidence, can be duly considered to be in this stage. Such
sporangia have been exclusively selected for this investigation ; the sur-
rounding sporangia having their nuclei, as a rule, in ‘rest’ or in early
heterotype prophase.

Nuclei in late telophase of the last archesporial division are, as would
be expected, indistinguishable in character from those of the preceding arche-
sporial mitoses which have already been described (see Text-fig., Nos. 9-12).
There is the same splitting of chromosomes into two longitudinal halves
(threads), which may be more or less homogeneous or beaded (Figs. 25 and
26). As fragmentation of the chromatin proceeds, the halves (threads)
separate widely, and the chromatic contents become distributed throughout
the nucleus, and consequently visible chromosome individuality is lost.
Fine strands join the chromatic portions together (Fig. 27). The nuclei at
this stage are small and have a definite limiting membrane which causes
them to stand out sharply from the surrounding cytoplasm. Fig. 28 shows
a late stage fixed in strong chromic, which accounts for the chromatin of
the now dispersed chromosomes being in relatively more aggregated portions,
and staining more deeply— characteristics of this fixative.

From this stage, and onwards to that of the definite heterotype pro-
phase, there is considerable difficulty in unravelling the course of events, as
apparently some of the nuclei pass directly from the telophase of the last
archesporial division (PI. VIII, Fig. 29) into the heterotype prophase (PI. IX,
Fig. 35), whilst others pass through an intermediate resting stage (Fig. 34),
with the characteristic pre- and post-rest phases (see Text-fig., Nos. 13 and 14).
Consequently it is sometimes impossible to decide whether a nucleus is in

142

Dig by . — On the A rchesporial and

telophase or prophase. It might be expected that, as in the earlier arche-
sporial divisions, the position of the recently laid down cell-wall, separating
the daughter nuclei, would be a guide to the solution of this problem ;
but, owing to rapid growth, nuclei undoubtedly in heterotype prophase
may be closely apposed to the wall. The following observations have been
found to be of some assistance in distinguishing the phases :

(1) The size and shape of the nucleus maybe useful, but not infallible,
guides. During late telophase and early rest, the nuclei are, as a rule, more
or less spherical, and of relatively small dimensions ; as prophase proceeds
they increase proportionately in volume, and tend to become ovoid in form.
(2) A nucleus in telophase has a somewhat definite limiting membrane, but
its contour fades away during rest, thus causing the nuclear outline to blend
with the surrounding cytoplasm. During prophase the limiting membrane
is still indefinite, but the brightly staining contents of the nuclei cause them
to stand out in sharp relief. (3) There may be three or more nucleoli in the
telophasic stages, but in definite prophase there are seldom more than two.
(4) In telophase a clear space, traversed only by isolated threads, is con-
stantly present round each nucleolus, whilst in prophase the nucleoli are
more or less entangled in the reticulum.

In the light of these remarks it will be seen that it is not practicable to
come to a conclusion with regard to the definition of the stages represented in
PI. VIII, Fig. 30, and PI. IX, Figs. 31, 32, and 33. The paired beaded threads
(PI. VIII, Fig. 30) are typically telophasic as compared to the pairing of more
or less homogeneous threads in prophase. This pairing is very evident in
the superficial section (PI. IX, Fig. 31) taken from the same sporangium as
Fig. 30. The three nucleoli and the more or less clear spaces surrounding
them are also suggestive of telophase. On the other hand, the large size of
the nucleus and its active appearance indicate prophase. A somewhat
similar stage is shown in Fig. 32, but in this case little evidence remains of
paired beaded threads, though the groupings of the beads in twos or fours
and the disposition of the fine linin threads indicate parallel arrangements.

These figures have been intercalated to show the impossibility of
identifying certain phases, but, on the other hand, it is feasible to follow out
a definite sequence in the passing of telophase into prophase as shown by
Figs. 29, 33, and 36. Fig. 29 is a more or less typical late telophase,
the chromosome halves (threads) having fragmented into chromatic beads,
leaving spaces round the two nucleoli. It is believed that such a nucleus
may either proceed directly through an intermediate stage (Fig. 33) into the
heterotype prophase (Fig. 36) or may pass through an intermediate rest
(Fig. 34). In this particular instance the former is probably its course, for
Fig. 33, a nucleus unquestionably in a stage transitional between telophase
and prop-hase, is taken from the same sporangium and even from the same
microscopic field as Fig. 29.

Meiotic Mitoses of Osmunda . 143

The material of this investigation suggests that the resting phase is
eliminated more frequently than not, and consequently that the majority of
the nuclei pass directly from the telophase of the last archesporial division
into the heterotype prophase. This may be accounted for by the fixing of
the material having been done solely on warm, growing days at about noon,
presumably under conditions of most rapid growth ; possibly if they had
been fixed under less congenial circumstances there might have been a pre-
ponderance of resting phases.

It is proposed to trace the course (1) of those nuclei that pass directly
from telophase into prophase, (2) of those that pass through an interkinetal
rest before entering upon prophase.

(1) In those nuclei that pass directly from telophase into prophase no
complete separation of the chromosome halves (threads) occurs, but traces of
paired threads persist. . These, therefore, establish the identity between the
parallel threads of the telophase of the last archesporial division (derived
from the longitudinal splitting of the chromosomes) and the parallel threads
of the heterotype prophase, and accordingly testify to the nature of each
thread of a pair as representing that of half a univalent chromosome (see
Text-fig., Nos. 12, 14, and 15).

Fig. 33 is a nucleus in the transition between the telophase of the last
archesporial division (PI. VIII, Fig. 29) and the heterotype prophase (PI. IX,
Fig. 36). Some of the linin threads run in pairs, and some of the chromatic
beads are arranged in groups of two and four. Three nucleoli persist. In
the next stage (Fig. 36) the clijmps of beads have dispersed, leaving a more
even reticulum and the general aspect of the nucleus is that of prophase.

(2) Following on the late telophase as shown in Fig. 29, the nucleus
may enter the resting stage. Complete rest (PI. IX, Fig. 34) is characterized
by an even distribution of granules and fine threads throughout the nucleus,
forming a close, colourless, foam-like reticulum with the chromatic staining
contents almost entirely relegated to the nucleoli. The passing of rest into
very early prophase (Fig. 35) is recognized by the somewhat more sharply-
staining reticulum, by the appearance of chromatic staining granules, and by
the generally more active character of the nucleus, thus causing it to be
sharply defined from the surrounding cytoplasm as compared to its indistinct
contour when in rest. This stage leads on to that of Fig. 36, in which
a decided increase in the size of the nucleus has taken place, and the meshes
of the reticulum have become extended, showing beads and fine threads
joining the beads together.

Heterotype or First Meiotic Division.

In order that the phenomena concerning chromosome formation in the
two divisions constituting the meiotic phase may be clearly understood, it

144

Dig by.— On the A rchesporial and

is proposed to give a brief introductory outline of the scheme of events
before proceeding with the detailed description (see Text-fig., Nos. 15-35).

It has been shown how, in the archesporial divisions, each pair of parallel
threads in the prophase are the reassociating longitudinal halves of a chromo-
some which had separated during the preceding telophase. The parallel
threads concentrate, become closely associated side by side, and thus re-
organize a chromosome. They again separate on the spindle and each longi-
tudinal half becomes a daughter chromosome, which will, in its turn, split
longitudinally in telophase. Parallel threads, homologous to those of the
archesporial prophases, are found in early heterotype prophase, but their com-
plete separation as daughter chromosomes is postponed, and is only finally
achieved on the homotype spindle. The paired lengths of threads of the
heterotype prophases are balled up in synapsis, and whilst in synapsis the
lateral association of the halves (threads) is completed and the entire univa-
lent spireme filament emerges as an apparently continuous thick double
thread. This post-synaptic spireme corresponds to the univalent spireme of
the somatic prophases before it has segmented transversely into univalent or
somatic chromosomes. The univalent spireme of the heterotype division
also segments transversely ; but before and during second contraction these
entire univalent segments (filaments) join in pairs to organize a bivalent
combination, the heterotype chromosome. On the heterotype spindle the
whole univalent chromosome of each bivalent pair parts from its fellow, and
one passes to either pole. This is therefore a reduction division, for each
daughter nucleus will contain half the number of chromosomes typical of
the somatic divisions. On the homotype spindle the entire univalent
chromosome splits into the two daughter chromosomes. This is the
division prepared for by the association in pairs of the half univalent
spiremes (threads) met with in the presynaptic and synaptic phases.

Heterotype Prophase to Synapsis.

The earliest definite prophase of the first meiotic division (Fig. 36)
shows a more or less coarsely beaded linin reticulum. Some of the fine
threads of the reticulum may run in pairs and some of the granules may be
arranged in groups of four. These are the first indications of the re-
association of the chromosome halves (threads) which separated during the
preceding telophase. From this stage onwards, there is a progressive and
decided enlargement of the nucleus, entailing an extension of the clear
areas devoid of chromatic contents. Simultaneously the reticulum loses its
reticulate character, it becomes drawn out into beaded threads (Fig. 37), and
gradually the chromatin of the beads infiltrates the linin, thus causing it to
stain evenly and to assume more definitely the spireme character (Fig. 38).
This spireme thread shows a gradual but conspicuous parallel arrangement
of portions of its lengths (Fig. 39). The pairing becomes more accentuated

145

Meiotic Mitoses of Osmunda.

(Fig. 40) until, as in Fig. 41, long lengths may run parallel to one another,
and these may be connected by paired beads at intervals At this stage
the withdrawal of the nuclear contents preparatory to synapsis is first indi-
cated ; in Fig. 41 the spireme (thread) has retreated from a small area of
the periphery in the NW. region and in other parts has become slightly
drawn together. As the spireme (thread) withdraws from the nuclear
periphery it becomes increasingly thrown into loops, suggesting a continuous
thread (Fig. 42) ; but it is not possible to prove this supposition. At this
stage the spireme (thread) resembles a loosely tangled skein of wool with
threads running very closely parallel (Fig. 44), sometimes actually in contact
(Fig. 42), whilst others twist and loop over one another (Figs. 42 and 43).

When the nucleus has passed into the early synaptic stage (Fig. 45)
the knot, in favourable preparations, is seen to consist of fine threads, the
cut ends of which appear as small beads of chromatin. The association of
the sides of the loops (i. e. of two threads) can be recognized towards the
thinner margins of the knot ; the associations are obscured towards the
centre by the close tangle of threads. The similarity of the approximating
sides (threads) is striking (Fig. 46) ; so alike are they that they would be
regarded as splitting instead of associating had not their origin been traced.
They also appear exceedingly taut and strained. Both these features will
again be found to be characteristic of the univalent segments (filaments) of
spireme when they conjoin in pairs.

Synapsis.

The synaptic stage of Osmunda is, as a rule, far more instructive than
in the majority of plants, where it often happens that its densely staining
intricate mass makes its structure impossible to resolve. Such is also the
case in Osmunda when fixed with strong chromic, but with strong Flemming
and Hermann the individual threads can be clearly seen. Merkel fixative
has a variable effect ; sometimes it yields a clear, and sometimes a dense,
appearance during synapsis.

During synapsis, the association of threads in pairs, prepared for during
the presynaptic stages , is consummated. The complete sorting out and
association in pairs, side by side, of the threads of the whole skein of half
univalent spireme (thread) is achieved, and hence the spireme filament which
issues from synapsis is, throughout its length, of an entire univalent nature.
If an early synapsis before association (Fig. 45) be compared with a late
synapsis after association (Fig. 49), when the spireme (filament) is beginning
to unravel and to invade the nuclear cavity, it will be observed that the
difference in thickness of the spiremes is most striking, and that there is no
difficulty in distinguishing the two phases. The spireme thread, therefore,
in the early synaptic stages, before association, is not only half the thickness,
but is also of necessity double the length of the spireme filament of the
later synaptic stages when association is accomplished.

146

Dig by. — On the Arckesporial and

It is only very rarely that association of a long length of spireme
thread is to be seen proceeding in a nucleus, but such cases, when present,
are most striking. The half univalent spireme (thread) is thrown into loops
which are orientated towards one portion of the nuclear periphery, and there
the sides of the loops (i. e. threads) are seen to be associating in pairs (Figs.
47 and 48). This investigation has necessitated the examination of a very
large amount of material, and only these two diagrammatic examples have
been found. If the spireme loops are orientated solely towards the nuclear
poles, then the chance of cutting the nucleus at the precise angle to demon-
strate the phenomenon would be remote. In the majority of nuclei at this
stage, association can be detected as taking place between lengths of spireme
thread in the synaptic knot, but these cases are naturally not nearly so con-
vincing as in the nuclei figured. Gregoire (10) has published a beautiful
drawing (Planche I, Fig. 24) of this polarization showing the association
in a most graphic manner. He writes: ‘ C’est surtout dans YOsmunda
regalis que nous avons rencontre les plus beaux cas de dualites d’accole-
ment. . . . Dans la Fig. 24 on voit des filaments 1 minces nettement orientes
vers un pole du noyau, chose assez rare dans les sporocytes — nos figures en
apportent le premier cas aussi clair, a notre connaissance * (p. 378). He
interprets the association of threads in synapsis as the association of two
lengths of entire univalent spiremes, each associating thread representing an
entire somatic chromosome ; whereas the conclusion arrived at during the
present investigation is that each length of associating spireme represents
the longitudinal half of a univalent spireme or univalent chromosome.

The association of threads in pairs to form the spireme filament is
completed before the spireme begins to come out of synapsis ; the emerging
spireme filament, therefore, is double throughout its length — no single unasso-
ciated threads remain (Fig. 49). Accordingly from late synapsis onwards the
nature of the spireme is that of an entire univalent filament, i. e. the product
of the lateral association of the two longitudinal halves (threads) of univalent
spireme, but separation between the halves (threads) may still remain more
or less evident. This spireme filament is homologous with the continuous
spireme filament of a somatic prophase, before it segments transversely into
the somatic chromosomes.

The nucleolus occasionally buds during synapsis. No typical formation
of chromatic bodies has been observed, but von Derschau (2) has figured and
described them in O. regalis.

Early Hollow Spireme Stage.

As the univalent spireme filament comes out of synapsis (Fig. 49)
fission is, as a rule, conspicuous. Sometimes the separation of the two
associated threads is considerable, sometimes it is shown merely by the

1 ‘ Threads according to the nomenclature adopted in this paper (see foot-note, p. 159).

147

Meiotic Mitoses of Osmuncia.

shading in the beading, whilst at still other times the sides (threads) are so
closely appressed as to form a single row of beads. P'ig. 50 shows a Her-
mann fixed superficial section of the loosening of synapsis. In this nucleus
every portion of the spireme filament exhibits fission (i. e. separation) and
that of a very beaded kind characteristic of Hermann preparations, whilst
in strong Flemming preparations the sides (threads) are more homogeneous
(Fig. 51). The spireme filament distributes itself throughout the nucleus
(Fig. 51), the -so-called ‘ hollow spireme ’ stage, and as it invades the nuclear
cavity it becomes thrown into loops (Fig. 52), and these are often orientated
round the nucleolus (Fig. 53). It is exceedingly difficult to decide whether
free ends are present, but the evidence points to an affirmative, and at
a slightly later stage they are certainly to be found. From this stage
onwards the spireme filament becomes more uniformly homogeneous, and
fission rapidly closes. Figs. 53 and 54 have been taken from sporangia in
which the nuclei of half of the sporangium show fission, whilst in those
of the other half fission has already closed (PI. X, Fig. 59).

Perhaps it may not be out of place here to make a slight digression
and allude to the widely separated stages in the progress of nuclear division
that may be found in a single sporangium, testifying to the rapidity with
which many of these phases are passed through. In a single sporangium
some nuclei may be in the pre-second contraction phase, whilst others are
in diakinesis (PI. XII, Fig. 101) ; or half of the nuclei may be in second con-
traction and the other half in metaphase. These rapid transitions increase
the difficulty in interpreting the complicated stages leading to second con-
traction. Wilson Smith (18) has given some interesting data on this subject,
and it is evident that in his plants growth was not so rapid as in the material
collected for the present research. His material of O. regalis was fixed in
northern Indiana, and he calculates that the resting and early spireme
stages last for about two weeks, synapsis for three or four days, whilst the
two meiotic divisions are effected in quick succession, within a period of
two or three days.

Later Hollow Spireme to Second Contraction.

To describe clearly the series of nuclear phases between hollow spireme
and second contraction is a difficult task, for not only do the spireme fila-
ments show great diversity according to the fixative used (with strong
chromic the swelling is considerable), but even adjacent nuclei in a sporan-
gium reveal strikingly different characters.

The principle to be borne in mind is, that as the nuclei pass into
second contraction an arrangement for the conjunction in pairs of entire
univalent spireme segments (i.e. of filaments) is evolved. This conjunction
may be in all stages of completion before second contraction supervenes,
but it is finally consummated in the massing of second contraction, during

148

Dig by. — On the Archesporial and

which the course of events becomes obscured. Whereas during synapsis
the association of the halves of univalent chromosomes is completed, so
during second contraction the conjunction in pairs of entire univalent
chromosomes is achieved.

It is not possible to find a nucleus which shows diagrammatically the
conjunction of all its spireme filaments, but by working through every
nucleus of a sporangium at this stage, isolated instances may be observed.
In a single nucleus several pairs of filaments may show conjunction, or per-
haps only one pair may be conjoining, or there may be no trace of conjunc-
tion whatsoever. It is only by comparing numbers of nuclei, and by
checking them with those of pre- and post-stages, that it is possible to arrive
at a conclusion on the matter.

When the nucleus is in the late hollow spireme stage, the first indication
of conjunction may be observed in well-fixed preparations. These early
stages, so unmistakable in the particular material on which this investiga-
tion is based, had never been observed in the fixations of former years.
Moreover, the phases subsequent to second contraction, which seemed
hitherto to defy interpretation, are here intelligible and clear, and there are
many graduated transitional phases to be seen. The advantages which
have made the elucidation of these difficult and crucial stages possible are
due to the successful fixation carried out in the manner already described
(P. 136).

The first sign of conjunction is recognized by the tendency of the sides
of the loops (i. e. of spireme filaments) to incline towards one another, and
at the points where they are bent in closely together they become joined by
very fine connecting strands (PI. IX, Figs. 54 and 55). The surface of the
spireme is slightly drawn out at the place of attachment of these strands.
This is the first step in the combination of entire univalent spiremes (fila-
ments) or chromosomes in pairs to form the bivalent spiremes which will
become the heterotype chromosomes. In Fig. 55 the sides of the loops are
connected at one point suggestive of a future U-shaped chromosome;
Fig. 56 typifies the future X -shaped chromosome; whilst Figs. 57 and 58
show a looping over of the spireme filament characteristic of other hetero-
type chromosome figures.

These studies of early conjunction of univalents (filaments) show degrees
of fission (i.e. traces of the two original separate threads of which the
univalent spireme is composed) in each univalent spireme, but from this
stage onwards to the coming out of second contraction fission is usually
closed. Fission is never visible in the substance of the filaments when they
are closely conjoined (PI. X, Figs. 60 and 63), though it may be evident in
the filaments which are still independent (Figs. 65 and 66).

Fig. 59 is taken from the same sporangium as Fig. 53, but is in
a decidedly later stage. In this univalent spireme (Fig. 59) complete

149

Meiotic Mitoses of Osmunda.

coalescence of the approximated threads has occurred, and there is consider-
able thickening of the spireme filament. The nucleus has been cut some-
what superficially, but the preparation for conjunction is manifested both in
the looping over and drawing together of the sides of the loops, and in the
fine connecting transverse strands.

The stage when the univalent spireme (filament) is uniformly spread
throughout the nuclear cavity appears to be of short duration, for almost
immediately it tends to aggregate preparatory for second contraction
(Fig. 60), and at the same time becomes stretched and smoother in outline.
It now shows various degrees in the process of conjunction in pairs; some
lengths may be merely running parallel, whilst others, though still separate,
are joined at intervals by fine strands (Fig. 59) ; others form a closed ring
(Fig. 61) ; others are twisted over one another (Fig. 61) ; whilst others are
closely conjoined side by side for some distance (Fig. 60) and then diverge.
If each nucleus in a sporangium at this stage be examined, it will be found
that the spiremes in the majority show some signs of conjunction. Fission
is still occasionally visible as in the loop of Fig. 62. Moreover, there may
be a straightening out of the loops and also beautiful anastomosis, but as
these figures are somewhat aberrant they have not been published.

The massing of the spireme filaments preparatory for second contrac-
tion increases (Fig. 62), and at the same time they withdraw from the
periphery of the nucleus and definitely become transversely segmented
(Figs. 62 and 63). Conjunction meanwhile proceeds (Fig. 63). Nuclei cut
superficially show segments of conjoining spireme filaments (PL X, Figs.
6 4, 65, and 66) which bear a striking resemblance to the future completely
organized heterotype chromosomes (PI. XI, Figs. 80 and 81) except for
their slightness as compared to the concentrated mature segments.

It may here be emphasized that the breadth of the spireme filament
affords no criterion whatsoever on which to build any calculation as to the
stage reached, except in the extreme case mentioned above, and also in the
pre- and post-synaptic spiremes before and after association. Thin spireme
is so often due solely to tension, as in associating half univalent spiremes
(threads) and conjoining univalent segments (filaments), and directly the
strain is relaxed the spiremes shorten and thicken.

Fission is apparent in the free portions of univalent sides (filaments) of
several of these chromosome-like combinations (Figs. 64, 65, and 66). Con-
junction of the univalents (filaments) becomes increasingly close. Figs. 67,
68, and 69 have all been taken from the same sporangium, and Figs. 67 and
69 from the same microscopic field. In Fig. 67 comparatively little conjunc-
tion has taken place, whilst in Figs. 68 and 69 conjunction is advanced.
Lawson (14) has published two identical stages in Smilacina( PL I, Figs. 15
and 16). He states that the large number of threads1 present in his Fig. 15

1 ‘ Filaments according to the nomenclature adopted in this paper.

150 Digby. — On the Archesporial and

makes it quite clear that ‘ the reduction in the number of chromosomes has
not yet taken place ’, whilst in his Fig. 16 the spireme threads 1 ‘ are segre-
gating in pairs preparatory to a lateral union ’ (p. 625).

When the majority of the spireme filaments have conjoined in pairs
(Figs. 68 and 69), they necessarily occupy a more restricted area than when
they were independent of one another (cf. Figs. 60, 62, 63, and 67 with
Figs. 68 and 69). The nucleus at the same time decreases considerably in
size. The conjoining spireme filaments stain uniformly and have a taut
and strained appearance pricS to close conjunction (cf. Figs. 59, 63, and 67
with Fig. 69). Close conjunction bears a striking resemblance to fission,
the two approaching univalent spiremes (filaments) being identical even to
their beading (Fig. 69). It is only by following every stage, and by con-
stant comparison, that these pre-second contraction phases can be inter-
preted and the fact substantiated that one is here dealing with conjunction
and not with separation. It will be remembered that the associating halves
of univalent spireme (threads) in presynaptic prophases exhibit precisely
similar characters.

The conjoining stages appear to have been missed by many cyto-
logists, who have therefore concluded that these paired filaments going into
second contraction are ^k-joining and not co7i-]oinmg, and hence that this
separation is the opening out of the fission seen in the post-synaptic spireme.
Gregoire (10) and Yamanouchi (19) have both come to this conclusion with
regard to Osmunda. Farmer and Moore (8), on the other hand, described
the coming together of the sides of the loops in the stages leading to second
contraction, and they note that they approximate closely ‘and thus simulate
an appearance of a longitudinal fission 5 (p. 520). It is proposed to refer to
this point again in the ‘ General Considerations

Gradually (Figs. 70 and 71) the greater part of the spireme filaments
become collected together and lose their visible identity in the massing of
second contraction, but isolated portions may remain independent and free
(Fig. 71). In this nucleus (Fig. 71) the two outlying spireme filaments
show a twisted conjunction, but in Fig. 72 some of the filaments, not involved
in the aggregation of contents, are widely separated, whilst others are
closely conjoined. It is suggested that close conjunction of two filaments
(i. e. of two univalent spiremes) may, in some instances, never take place at
all, for it is not unusual to find bivalent chromosome-like entities lying out-
side the mass of second contraction ; these apparently concentrate and
thicken, and thus take a short cut to becoming heterotype chromosomes.

The main and final process of conjunction, involving the sorting out
and conjoining in pairs of all the univalent segments (filaments), takes place
during second contraction, whereas the association of the pair of threads which
together make up the univalent spireme is consummated during synapsis.

1 ‘Filaments according to the nomenclature adopted in this paper.

Mcioiic Mitoses of Osmunda .

151

Coming out of Second Contraction and Diakinesis.

From the stage of second contraction, and onwards up to the close of
the homotype division, the nuclear phases are comparatively straight-
forward, are simple of interpretation, and afford little ground for debate.

There is no difficulty in distinguishing between the nuclei issuing from
second contraction, and those about to enter that phase ; for in working
through the post-second contraction events, bivalent chromosomes in vary-
ing stages of evolution will be seen. Further, the univalent chromosome
segments often issue from second contraction in detached portions, and
these speedily join end to end (Fig. 73). Moreover, the spore mother-cells
now begin to separate. It has been found in these preparations, in which
the method of fixation has largely eliminated artificial contraction, that the
rounding-off of the spore mother-cells occurs at a considerably later phase
than would appear to be the case when studying material which had not
been so well fixed.

As second contraction loosens, the bivalent segments begin to sort
themselves out (Fig. 73). Some of the univalents (filaments) are still closely
conjoined, whilst others are more or less separated, and it may be possible
in isolated instances to distinguish the separate bivalent combinations, i. e.
the future heterotype chromosomes. Some second contraction figures
loosen directly into more or less organized thick, concentrated chromosomes
(Fig. 74), whilst in others the univalents are more slender, and are in process
of disjoining (Fig. 75).

As the univalent chromosomes of each bivalent combination separate,
they thicken (Fig. 7 6) and stain as more or less homogeneous bodies. The
nuclear surface then increases considerably and the chromosome segments
are dispersed at its periphery. Some of the bivalent chromosomes are
clearly individualized, whilst others are not completely organized. Fission
can only rarely be detected at this stage (Fig. 77). This is the reappearance
of the fission which was evident in the univalent post-synaptic spireme,
parting the threads which had associated during synapsis, and it will
eventually result in the separation of the daughter univalent chromosomes
on the homotype spindle.

The chromosomes concentrate rapidly (Fig. 78) ; the small granules
and globules which are often seen scattered in the nucleus and even
attached to the chromosomes are probably fragments of dissolving
nucleolus.

In fortunate preparations spindle fibres are seen to radiate towards the
nucleus from four poles which appear as cones in the cytoplasm (Fig. 79), as
in Polypodium vulgar e (7) and other ferns. Strasburger (17) has figured
a multipolar spindle origin (PI. IV, Fig. 178). Wilson Smith (18) occa-

N

*52

Digby . — (9/2 the Archesporial and

sionally found tripolar spindles, but he considers them to be abnormal
stages in spindle development.

The chromosomes retreat before the encroaching fibres towards the
centre of the nucleus, and fission is sometimes evident in the univalent
segments (PL XI, Fig. 80). The nuclear limiting membrane disappears,
the fibres invade the nucleus (Fig. 81), and the chromosomes collect towards
the centre of the nucleus.

Heterotype Metaphase, Anaphase, and Telophase.

The chromosomes then arrange themselves on the spindle (Fig. 82),
which has now become bipolar. The number of chromosomes as seen in
polar view of an equatorial plate of O. palustris, var. aurea , is apparently
20 (Fig. 83) ; the reduced number both in O. regalis (17, 11, 13) and in
O. cinnamomea (19, 13) is 22.

Disjunction of the entire univalent chromosomes of each bivalent pair
takes place on the equatorial plate, and it is immediately succeeded by
a cleavage in the substance of each entire chromosome, widely separating it
into diverging halves. This is the first sign of dissociation of the threads of
spireme which associated in pairs during the presynaptic and synaptic
stages, and is therefore the opening out of the fission so clearly seen in the
entire univalent post-synaptic spireme (filament).

Fission in the univalent chromosomes as they proceed to the hetero-
type spindle poles is so extensive as to split each chromosome into a V, the
apex of the V pointing to the pole (Fig. 84) (see Text-fig., No. 25). This pre-
cocious cleavage may be attributable to the fact that entire univalent chromo-
somes are passing to the poles, a phenomenon peculiar to the heterotype
mitosis. These daughter chromosomes will finally separate on the homotype
spindle. The cleavage continues to be very marked when the chromosomes
are looked at in polar view of early anaphase (Fig. 85), and it causes each
chromosome to be double, thus making it difficult to obtain an accurate count.

The chromosomes draw together and a further and new fission appears
in the substance of each daughter chromosome, giving it a fenestrated or
vacuolated appearance (Fig. 86) (see Text-fig., No. 26). This new fission in
the daughter chromosomes of the heterotype telophase is homologous with the
fission in the daughter chromosomes, of a somatic telophase. It is prophetic
of the post-ho7notypic division, and reappears in the early anaphase and telo-
phases of the homotype mitosis, thereby splitting the daughter chromosomes
(Fig. 98) into longitudinal halves (threads) (see Text-fig., Nos. 31, 33, 34,
and 35).

This double fission becomes intelligible when it is remembered that
entire univalent premeiotic chromosomes are distributed to the poles of the
heterotype spindle, instead of half or daughter univalent chromosomes, as
in somatic divisions. Consequently, not only does the whole univalent

1 53

Meiotic Mitoses of Osminda.

chromosome split into its daughter halves, but the daughter halves them-
selves conform to their normal procedure in somatic telophases, and split
into longitudinal halves (threads). This fact once more illustrates the dual
nature of each chromosome.

The splitting of the daughter chromosome halves initiated by the
fenestration proceeds (Fig. 87) and the identity of the chromosomes is lost
to view in paired beads and parallel threads (Fig. 88). Simultaneously
a nuclear limiting membrane makes its appearance.

In tracing the series of stages between the heterotype telophase and
the onset of the homotype prophase, the presence or absence of the nuclear
limiting membrane and the evolution of the cell- plate separating the
daughter nuclei are found to be useful guides in the reconstruction of the
sequences. The phases between the two divisions are apparently quickly
passed through, for it is not uncommon to find heterotype anaphases inter-
spersed with homotype metaphases in the same sporangium.

Following the dissolution of the chromosomes comes their reconstruc-
tion, and this may be regarded as the beginning of the homotype division.

Homotype or Second Meiotic Division.

The homotype may justly be regarded as a continuation of the last pre-
meiotic division , and consequently the heterotype represents an interpolated
phase in which the numerical reduction of the chromosomes is accomplished.

The univalent spireme filament of the homotypic prophases is homo-
logous with the univalent spireme filament of the heterotypic prophases,
and this in turn is derived from the reassociation of the longitudinal halves
of univalent chromosomes (threads) that had split apart during the pre-
ceding telophase of the last premeiotic division. These halves (or threads)
do not dissociate during the heterotype division, but their separation takes
place on the homotype spindle (see Text-fig., No. 30).

The points of difference between a homotypic and a somatic division
are : (1) the homotype possesses half the somatic number of chromosomes ;
(2) the homotype is endowed with entire univalent chromosomes from the
preceding heterotype spindle, instead of with half univalent or daughter
chromosomes ; (3) the homotype prophases show a very precocious splitting
of the univalent spireme as compared to somatic prophases, or, in other
words, the daughter chromosomes, which will separate on the homotypic
spindle, are dissociated at a very early stage.

The onset of the homotype prophase is recognized by the chromatic
contents becoming concentrated into rounded masses in excess of the
x number of chromosomes (Fig. 89). This is not remarkable, as double the
reduced number of chromosomes split into longitudinal halves (threads)
during the preceding heterotype telophase owing to the splitting of each
entire univalent chromosome into daughter chromosomes (Figs. 84 and 85),

154

Digby.—Ou the Archesporial and

followed by a further longitudinal splitting of each daughter chromosome into
halves (threads) (Figs. 86 and 87). Consequently, as the longitudinal halves
(threads) severally associate in pairs, they bring about the reorganization
of the double number of chromosome segments (see Text-fig., Nos. 25-28).

It has not been possible to find stages in the building up of the
chromatic masses, so quickly do the longitudinal halves (threads) appear to
reassociate upon their partial separation, but it is assumed that each of
these masses is a filament, derived from the reassociation of the split halves
(threads) of a daughter chromosome of the heterotype telophase. This view is
confirmed by the fact that throughout the homotype prophases, the daughter
univalent chromosomes, instead of being closely associated as in somatic
prophases, are organized as more or less independent individuals, and they
even take up their position as such on the equatorial plate.

These chromatic masses are arranged round that portion of the peri-
phery of the nucleus which is remote from the cell-plate, leaving a central
clear space. Accordingly, they emphasize that particular area of the nuclear
limiting membrane, whereas the boundary of the nucleus towards the cell-
plate is undefined and gives access to cytoplasmic strands. Wilson Smith
(18) also remarks on the bunching together of the chromatin on the side of
the cell remote from the greater mass of ‘ kinoplasm \

The nuclear membrane gradually disappears, the chromatic contents
collect closely together (Fig. 90), and the further events are involved in
some obscurity. Spindle fibres radiate into this mass, and the chromatic
segments become more and more indeterminate (Fig. 91). The segments
loosen out along the fibres, and the nucleus elongates at right angles to the
cell-plate of the heterotype division (Fig. 92). The evolution of the spindle
fibres proceeds (Fig. 93), and the chromosome-like segments are greatly
elongated. They become almost completely divided by fission into longi-
tudinal halves (Fig. 93) ; in fact, the daughter chromosomes take up their
position as independent individuals on the equatorial plate (Fig. 94) instead
of dividing in the ordinary manner only when arranged on the spindle.

As the daughter chromosomes move away from one another and
proceed towards the spindle poles (Fig. 95) fission once more immediately
appears in them, often resulting in a separation of each of them into com-
plete halves (threads). This is the fission prepared for by the alveolization
of the daughter chromosomes in the heterotype anaphase. Arrived at the
poles (Fig. 96) the tension slackens, and the chromosomes draw together in
the figure of a rosette, as seen from a polar view. They thicken considerably
and for a time appear homogeneous, fission being temporarily obliterated.
As anaphase passes into telophase (Fig. 97) the chromosome^ separate from
one another and fission once more reappears ; each chromosome divides
into two halves (threads) which are at first homogeneous, but rapidly
become beaded (Fig. 98). In Fig. 97 one chromosome, in advance of the

Meiotic Mitoses of Osmunda . 155

others, has already split into two parallel rows of beads. A nuclear limiting
membrane makes its appearance (Fig. 99), the skeletons of the quondam
chromosomes become less and less recognizable as their beaded sides
separate, and thus inaugurate a reticulum (Fig. 99). The beads gradually
become distributed throughout the nucleus (Fig. 100), which thus passes
into the fine reticulate, or resting, stage found in the cells of the spore
tetrad.

The predominating feature of the homotype division lies in the pre-
cocious separation of the daughter chromosomes, suggesting weak cohesion
between them. Possibly some physical conditions associated with the
reception into the nucleus of entire premeiotic chromosomes during the
previous telophase of the heterotype division may be responsible for this
phenomenon.

Synangia.

Five cases of synangia have been found, three in O. palustris , var.
aurea , and two in O. palustris , var. undulata. Of these one is in arche-
sporial division (PI. XII, Fig. 102) the others in the first meiotic division
(Figs. 103, 104, 105, 106). One side of the synangium may have its spore
mother-nuclei in a considerably more advanced stage than the others
(Figs. 105 and 106).

It is interesting to note that Bower (1) has described synangia as
occurring not unfrequently in O. regalis (PI. Ill, Fig. 51) 5 he has also
found them in Gleichenia (PL I, Fig. 31), and mentions that they may be
observed occasionally in Todea barbara .

General Considerations.

No attempt will be made to touch even the fringe of the vast literature
which has grown up round the hotly debated question concerning the mode of
origin of heterotype chromosomes. It is merely proposed (1) briefly to
recall the main differences in the views held by telosynaptists and para-
synaptists, (2) to suggest a possible explanation for these different views by
showing how variously the details of mitosis may be modified, (3) to con-
sider in particular the evidence afforded by the mitoses of Osmunda.

I. The Main Differences between the Telosynaptic and Para-
synaptic Views .

Farmer (6) has drawn attention to the confusion which has arisen
round the terms * telosynapsis J and 4 parasynapsis ’, and sums up the posi-
tion in a few cogent sentences. He shows that by emphasizing a point of
comparative unimportance, these terms ‘ have led to a misconception on the
part of many people, as to the really fundamental differences which still
divide the two schools of investigators \ There is no essential difference
between a lateral approximation achieved by the twisting together of the
sides of a loop, ‘ and an approximation produced by the coming together

156 Digby. — On the Archesporial and

in pairs of chromosomes hitherto disunited, nor is it a matter of any
importance whether the approximation occurs at a somewhat earlier or
later period in mitosis. The really vital question at issue between the two
schools does not, as a matter of fact, consist in Telosynapsis v. Parasynapsis
as etymologically understood, but upon the interpretation to be placed on the
much earlier stages of prophase in the heterotype mitosis.’

Telosynaptists and parasynaptists 1 are agreed as to the evolution of
the somatic chromosomes.2 They acknowledge the splitting into longi-
tudinal halves (threads) of each daughter somatic chromosome during
telophase ; the separation of the halves (threads) during interkinesis, their
reassociation during the ensuing prophase, and their final separation as two
daughter chromosomes during metaphase, each preparing to split again
during telophase and thus completing the cycle.

Those who advocate the telosynaptic theory for the origin of the
heterotype chromosomes regard the parallel threads of the heterotype pro-
phase as homologous with those of the somatic prophases, namely that
each parallel thread of a pair represents half a somatic chromosome which
separated from the other half in the preceding telophase. On the other
hand, parasynaptists regard the parallel threads of the heterotype prophase
as the pairing of entire somatic chromosomes. This is the fundamental and
vital difference in the two views, and governs the interpretation of subse-
quent stages. Telosynaptists accordingly regard the spireme that issues
from synapsis as univalent , and claim a subsequent secondary conjunction
of paired portions of univalent spireme, during the second contraction stages,
to form the typical bivalent or heterotype chromosome. Parasynaptists,
on the other hand, regard the spireme that issues from synapsis as already
bivalent , and consequently believe that this spireme itself splits to form the
typical univalent segments of the heterotype chromosome. Lastly, as
a final corollary, telosynaptists hold that the paired threads, which asso-
ciated during synapsis, separate on the homotype spindle, whereas para-
synaptists maintain that they separate on the heterotype spindle.

2. Modifications in the Details of Mitosis.

It is evident that the root of the difficulty lies in the fact that as yet no
single type has been found, whether animal or plant, which shows clearly
and straightforwardly, with no elimination or disguising of phases, the
whole series of events passed through during the heterotype mitosis. Each
form has its distinctive cytological characters, and its nuclei may show one
particular phase with exceeding clearness, whilst the pre- or post-stages

1 These terms are employed here because they have become so widely used, and not because
they are regarded as correct or even appropriate.

2 It has been noted (p. 138) that a modification of the characteristic type of somatic division may
be found (as in Primula) in which fission tends to remain closed until it splits the chromosomes
apart on the equatorial plate.

J57

Meiotic Mitoses of Osmunda.

may be confused. A well-defined phase, taken without its context, may be
misleading and give rise to an error of judgement. For example, the parallel
threads of the heterotype prophases may be exceedingly striking and
definite, but it is impossible to offer a fully reasoned statement as to their
homology, if an interkinetal rest exists between the last premeiotic division
and the heterotype prophase during which all visible continuity is lost. Or
again, fission in the post-synaptic spireme may be very evident, but this
stage may be succeeded by most confused hollow spireme and second con-
traction phases, thus obscuring the conjunction of univalents. This has led
to the very commonly expressed inference that the disjunction of univalents
after second contraction is the opening out of the fission observed in
the substance of the post-synaptic spireme.

It is believed that no conclusion can be drawn from the study of
a series of nuclear phases of any one particular animal or plant. In order
to expand this suggestion, it is proposed to compare the critical stages of
the heterotype division in four plants, Galtonia (3), Primula (4), Crepis (5),
and Osmunda . Each exhibits not only individually distinctive characters
which dominate its mitoses, but shows considerable variation in the details.

The most instructive point in Galtonia is the direct passing of the
telophase of the last premeiotic division into the meiotic prophase with no
intermediate rest ; consequently the origin of the parallel threads of the
heterotype prophases can be traced directly to the longitudinally split
chromosomes of the preceding telophase. This fact substantiates the nature
of each thread of the parallel pair as representing the longitudinal half of
a somatic chromosome. None of the other three plants show this all-
important character so clearly. In Osmunda the homology can occasionally
be traced, but not in so indubitable a manner, and a rest may intervene
between the two divisions. In Crepis and Primula there is invariably
a complete rest during which all visible chromosome continuity is lost.

To proceed to synapsis. This stage is only really clear in Osmunda ,
on account of the distinct individuality maintained as between the threads.
Under favourable conditions, many of the parallel threads of presynapsis
can be seen, in a single nucleus, to be simultaneously in the act of closely
associating in pairs. The contrast between the fine associating threads
going into synapsis and the resultant thick emerging spireme filament is
exceedingly striking. In Galtonia , Primida , and Crepis , the density of the
synaptic knot obscures the course of events there taking place.

To pass on to the complex stages between hollow spireme and early
diakinesis. Primula shows the conjunction of filaments in pairs, i. e. of
portions of univalent spireme, most clearly and diagrammatically. The
figures are exceedingly sharply defined, and the univalent spireme filament
is homogeneous, showing no fission, which simplifies the following out of
the process. Moreover, in two species, P. floribunda and P. kewensis

158 Digby. — On the Archesporial and

(seedling), second contraction is omitted, so that the sequence of phases
extending from the first indication of the conjunction of univalents (fila-
ments) to the realization of the mature bivalent chromosomes can be traced
without intermittence. In Osmund a the conjunction of filaments in late
hollow spireme is conspicuous in well-fixed preparations, but the fact that
fission may persist nearly to second contraction adds a perplexing feature.
In Galtonia there is no convincing evidence for conjunction, but as the
nucleus approaches second contraction the univalents (filaments) tend to
conjoin in pairs to form bivalent segments. In Crepis virens, notwithstand-
ing that the haploid number of chromosomes is but 3, it is impossible to
trace their evolution, owing to the viscous character of the nuclear contents,
and also to the fact that the hollow spireme stage is usually omitted, the
nucleus passing almost directly from synapsis into second contraction.

From the foregoing remarks it will be realized that no one of these
four plants is completely satisfactory throughout its phases, but if the
telophases of the last premeiotic division and the early heterotype prophases
of Galtonia could be combined with the later presynaptic and synaptic
phases of Osmunda , and the hollow spireme to diakinesis stages of Primula ,
a completely coherent and intelligible series of nuclear phases would be
established.

3. The Evidence afforded by Osmunda.

The conclusions of several investigators with regard to the origin of
the heterotype chromosomes in Osmunda are somewhat at variance.

In 1900 Strasburger (17) incorporated a short account of the hetero-
type division of O. regalis in a paper dealing with a variety of subjects.
He does not inquire into the manner in which the chromosomes are reduced,
as he assumes the heterotype prophase to be predestined to evolve the
x number. The fission which appears in the spireme, soon after it has
emerged from synapsis, he regards as the premature splitting apart of the
two univalent chromosomes which will separate on the equatorial plate of the
heterotype spindle. Great emphasis is laid on the fact that this separation
is immediately followed by a second longitudinal fission for the homotype
division.

Farmer and Moore (8) in 1905 showed that a similarity in the process
of reduction occurs in animals and plants, and O. regalis was one of the
plants selected. They describe the close conjoining of the sides of the
loops at the onset of second contraction, each side eventually forming
a univalent segment of the heterotype or bivalent chromosome. Further,
that * the homotype mitosis is associated with the completion of the longi-
tudinal, division of the chromosomes already incepted during the prophase of
the heterotype division ' (p. 505).

In 1907 Gregoire (10) cited Osmunda as strongly supporting the para-
synaptic theory, and in this paper appears his historical figure of a nucleus

159

Meiotic Miloses of Osmunda .

in synapsis showing the ‘ filaments minces ’ 1 orientated towards one pole of
the nucleus and associating in pairs. He regards this stage as the pairing
of entire univalent chromosomes. With Strasburger, he considers the
fission in the post-synaptic spireme as the separation of these same entire
univalent chromosomes which had come together during synapsis and which
will separate at the heterotype metaphase.

In 1910 Yamanouchi (19) published a paper on O. cinnamomea , and
his views coincide with those of Gregoire. He traces the duality of the
threads,2 from early prophase to their separation as daughter chromosomes
on the heterotype spindle. He shows that ‘ the threads come out of the
network as two independent threads from the start ’ (p. 5) ; that they come
to lie parallel to one another, and that these ‘ double threads ’ shorten and
thicken, and a pair of such shortened and thickened ‘ threads ’ become
a bivalent chromosome (p. 6).

It is evident that neither Strasburger, Gregoire, nor Yamanouchi
noticed the conjunction of segments of entire univalent spireme (i.e. of
filaments) in the post-synaptic stages, and consequently were unaware of the
complications thus introduced, and Gregoire and Yamanouchi consequently
assumed that the striking pairing of threads in presynapsis and synapsis was
the pairing of entire univalent chromosomes.

After years of hesitation the writer has come to the firm conclusion
that Osmunda affords a striking piece of evidence in favour of the ‘ telo-
synaptic ’ 3 theory of the origin of the heterotype chromosomes. It is
possible to identify all the important stages illustrated by the previously
mentioned workers, namely the parallel filaments (of Gregoire) in the pre-
synaptic prophases, the association of these filaments in pairs during
synapsis resulting in the emerging thick spireme, and the separation of the
univalent segments as they come out of second contraction to organize the
typical heterotype chromosomes. If this really represents the complete
sequence of events, and if the fission in the post-synaptic spireme is that
which eventually parts the univalent chromosomes on the heterotype
spindle, how has the numerical reduction of the chromosomes come about ?
The only possible answer is that the paired filaments (of Gregoire) of the

1 Gregoire (1910, Les Cineses de maturation dans les deux regnes. La Cellule, xxvi) calls the
‘ threads ’ (term used in the sense adopted in this paper) of heterotype prophases 1 filaments minces ’,
and considers each ‘ filament mince ’ to be an entire somatic chromosome. He thus describes
synapsis: ‘ C’est le stade de noyau leptotene (Winiwarter, 1900) ou leptonema (Gregoire, 1907), ou
noyau a filaments minces . . . l’association deux a deux des filaments minces des noyaux leptotenes
et un rapprochement graduel des deux filaments associes, donnant origine aux anses epaisses des
noyaux pachytenes. . . . Nous avons (1907) propose, pour ce stade, le nom de noyaux zygotenes ’
( = noyaux amphitencs of Janssens) (p. 237%

2 Yamanouchi (19) retains the term ‘ threads ’ throughout the heterotype division. He considers
the pairing of ‘ threads ’ in synapsis to be the coming together of two entire homologous somatic
chromosomes which separate on the heterotype spindle.

3 See foot-note on p. 156.

160 Digby . — On the A rchesporial and

presynaptic prophases must represent the pairing of entire somatic
chromosomes. This brings one to the bed-rock of the problem, and it will
be discussed in detail.

From evidence supplied by both schools of cytologists, it is clear that,
as a general rule,1 the somatic chromosomes in telophase apparently dis-
organize by first dividing into longitudinal halves (threads), which gradually
become dissipated throughout the nucleus. Prophase, therefore, entails a re-
association of these halves for the reorganization of each individual chromo-
some. If this dual nature of the chromosomes be borne in mind, it will be
realized that in all prophases, whether somatic or meiotic, there must be a
coming together of the halves (threads) dispersed during the preceding telo-
phase involving a pairing of threads. Consequently, that parallel threads
should be present in all nuclei, including those of parthenogenetic eggs (15)
and gametophytes (9), is only a normal event, and it bears no relation
whatsoever to the pairing of entire homologous chromosomes.

Gr^goire (10) and his followers promote this view with regard to somatic
prophases, but, on the other hand, they regard the paired threads of the
heterotype prophases as the pairing of filaments representing entire homo-
logous chromosomes. Such a theory postulates the complete rearrange-
ment of the elements of the last premeiotic telophase, for which, however,
there appears to be no supporting evidence, for its visible microscopical
detail is in every respect identical to that of preceding telophases. On the
contrary, when there is no interkinetal rest it is possible to trace the origin
of the paired threads of the heterotype prophases back to the longitudinally
split chromosomes of the preceding archesporial telophase. This is irre-
futable evidence on behalf of the view that th ft paired threads of the hetero-
type prophases are homologous to those of the somatic prophases ; that is to say,
that each thread represents half a univalent chromosome of the preceding
telophase. Having established this fact, the subsequent phases form
a logical story.

During synapsis the lateral association in pairs of the threads is con-
summated. Whereas in somatic prophases the threads come together to
form the univalent spireme filament which segments directly into univalent
chromosomes, in the heterotype prophases this univalent spireme filament
as it issues from synapsis is continuous, the univalent segments (filaments)
being joined end to end, and their separation is postponed until a con-
siderably later stage.

It was not until the success in fixing was attained that all stages in the
conjunction in pairs of entire univalent lengths of spireme (i.e. of filaments)
were observed throughout the phases between post-synapsis and second
contraction. In Osmunda these stages are not only difficult to fix suffi-
ciently well to show this phenomenon, but they are also quickly passed

1 See foot-note, p. 156.

Meiotic Mitoses of Osmunda. 1 6 1

through, and consequently may be easily missed. Evidently neither
Strasburger (17), Gregoire (10), nor Yamanouchi (19), were aware of them.
The first indication of conjunction is to be seen in the drawing together of
portions of the univalent loops (filaments) or univalent lengths of spireme
filament in the hollow spireme stage. This is also coupled with the con-
necting together of the approaching spireme filaments by fine transverse
strands. The spore mother-cell nuclei of some sporangia may show no
signs whatever of this early conjunction, whilst in others it is exceedingly
evident. At the approach of second contraction the conjoining becomes
more intimate. This phenomenon, again, may be easily overlooked. It is
not a case of all the portions of spireme filament in a nucleus conjoining
simultaneously, but of isolated examples of conjunction of lengths and
segments. During second contraction, the side-to-side conjunction becomes
so close that, as the bivalent segments come out of the chromatic aggrega-
tion, they appear to split apart. This disjunction of the bivalents bears so
close a resemblance to fission, that, if the intermediate conjoining stages had
been missed, it would naturally be inferred that this is the opening out of
the fission present in the post-synaptic spireme. Apparently, in some
instances, univalent segments may achieve the necessary conjunction with-
out entering second contraction, for it is not uncommon to find fully organ-
ized bivalent chromosomes lying outside, and independent of, second
contraction. Moreover, in some species of Primula (4) and Smilacina (14),
in which the conjunction of univalents (i.e. of filaments) in the post-synaptic
stages is extraordinarily clear, second contraction is omitted, and close con-
junction in pairs of the univalent segments (filaments) proceeds freely with-
in the nucleus ; and when this is accomplished, the univalents separate to
form the typical bivalent chromosome.

Although, as a general rule, complete conjunction of univalents (i. e. of
filaments) appears to require close lateral conjoining of the filament seg-
ments, yet it seems certain that bivalency may be achieved by a less
intimate combination, such as a looping over of univalents (filaments), or an
end-to-end connexion.

There are no controversial phases from the heterotype diakinesis
onwards to the end of the homotype division.

Of recent years Lawson (14) and Nothnagel (16) have both published
valuable evidence in favour of the telosynaptic theory. Lawson has found
a very clear type of conjunction of univalent segments of spireme in
Smilacina (14, FI. I, Fig. 16), and, as in Primula , second contraction
is omitted. He writes that f up to the time of this lateral pairing of the
spiremes ... I have been unable to recognise any fundamental difference
from the series of changes which occur in the early stages of an ordinary
somatic mitosis * (p. 611).

Nothnagel (16) very lucidly describes a telosynaptic series of events in

162

Digby . — On the Archesporial and

the pollen mother-cells of Allium tricoccum. She traces the parallel threads
of the heterotype prophases, which she calls daughter halves of single
somatic chromosomes, as originating from the vacuolization of the chromo-
somes in the preceding telophase of the last division of the sporogenous
tissue. The continuity can be followed during the interkinetal rest when
the remains of the chromosomes of the telophase are visible as ladder-like
structures. During synapsis the parallel spiremes approximate, resulting in
a single thick spireme. Apparently she did not see the stages of conjunc-
tion. She is of opinion that the radiating loops of second contraction
represent somatic chromosomes joined end to end, and that they separate
at the outer end. Thereupon an arm of a loop pairs with, and twists
round, an arm of a neighbouring loop ; thus a bivalent is formed by A + B.
No such proceeding has been seen in Osmunda .

Summary.

t. For the convenience of readers a glossary of terms consistently used
throughout this paper is here given.

c Thread ’ — the longitudinal half of an entire univalent spireme or
chromosome.

* Filament ’ — an entire univalent spireme, i.e. the spireme resulting
from the parallel association of two half univalent spiremes or threads.

‘ Strands’ — very fine strands of linin (i) connecting the several chromo-
some segments of early telophase ; (2) transversely connecting [a) the indi-
viduals of a pair of associating and dissociating threads, (b) the individuals
of a pair of conjoining and disjoining filaments.

‘ Association’ = the coming together in pairs, side by side, of two
threads or half univalent spiremes to form the entire univalent spireme or
filament, which becomes the univalent chromosome.

‘ Fission’ —(f) the longitudinal separation of the entire univalent spireme
into two threads or half univalent spiremes ; (2) the longitudinal separation
of a univalent chromosome into two daughter chromosomes.

‘ Conjunction ’ — the coming together in pairs of two entire univalent
spiremes or filaments to form the bivalent spireme which becomes the
bivalent or heterotype chromosome.

‘ Disjunction ’ = (1) the separation of the bivalent spireme into two
entire univalent spiremes, or (2) the separation of the bivalent or hetero-
type chromosome into two entire univalent chromosomes.

2. Archesporial Divisions.

The archesporial divisions of Osmunda are straightforward, and con-
form to the scheme generally described for the somatic mitosis of plants.

Meiotic Mitoses of Osmunda. 163

These phases clearly demonstrate the dual nature of each univalent chromo-
some, which presumably persists throughout the cycle of chromosome disso-
lution and reconstitution (see Text-fig., Nos. 1-8).

In late anaphase the substance of each chromosome is seen to be
divided already into longitudinal halves — the ‘threads’ (PI. VIII, Fig.. 2). As
the newly formed nucleus proceeds towards rest, the chromosome halves or
threads become beaded (Fig. 4). The threads gradually separate widely,
and the beads become resolved into finer and finer granules until a fine
reticulate state is reached— the so-called resting stage (Fig. 6).

During prophase the series of events is reversed, and the chromosome
halves, or threads, reassociate to build up the univalent chromosome. The
first indication of the coming together of the halves consists in the drawing
together, in parallel pairs, of the fine beaded threads (Fig. 11). Each
beaded thread gradually concentrates into spireme (Fig. 16), and the asso-
ciation of the two halves (i. e. the two threads) becomes increasingly intimate
until it results in the organization of the completed univalent chromosome
(Fig. 21). The space between the associating halves (threads) forms the
future line of fission which splits the chromosome into its daughter halves
on the equatorial plate.

The daughter chromosomes proceed to their respective poles (Fig. 24),
and in late anaphase (Fig. 2) each divides again by fission into longitudinal
halves (threads), thus completing the cycle.

3. Interkinesis betzveen the Telophase of the Last Archesporial
Division and the Heterotype Prophase.

The telophase of the last archesporial division (PI. VIII, Fig. 25) is in-
distinguishable from that of the preceding archesporial telophases, and
shows the longitudinal splitting of the chromosomes into threads (see Text-
fig., Nos. 9-12). The late telophase (Fig. 29) may pass through an inter-
kinetal rest (PI. IX, Fig. 34), or it may proceed directly into the heterotype
prophase (Fig. 36) (see Text-fig., Nos. 13 and 14).

Those nuclei which pass through an interkinetal rest show the same
gradual formation of a reticulum by the spreading out of the threads and
the fragmentation of the chromatic granules, as in the archesporial divisions.
Those nuclei that proceed directly from telophase into the heterotype pro-
phase show transitional stages in which both telophase and prophase
characters are present (Figs. 30, 32, and 33). There is no complete separa-
tion of the threads or chromosome halves, but traces of paired spireme and
paired beads persist from the one phase to the other. These, therefore,
substantiate the identity or homology existing between the parallel threads
of the telophase (PL VIII, Fig. 25) derived from the longitudinally split
chromosomes, and the parallel threads of the heterotype prophase

164

Digby . — On the Archesporial and

(Fig. 37, &c.), and accordingly establish the nature of each thread of a pair
to be that of a half univalent chromosome.

4. First Meiotic Division .

Osmunda conforms to the telosynaptic view of the origin of the hetero-
type chromosomes (see Text-fig., Nos. 15-27).

The paired spireme threads of the heterotype presynaptic prophases
are homologous with those of the somatic prophases ; that is to say, each
thread of a pair is derived from the longitudinal half chromosome of the
preceding telophase. During the phases leading to synapsis, these halved
univalent spiremes (threads) become arranged in closely parallel pairs
(Figs. 40, 41, &c.), and the individual halves of each pair are identical.
Close association of the two individual halves (threads) of each pair is
achieved during synapsis. All stages in the preparation for, and in the
realization of, association are to be found. Those cases are particularly strik-
ing in which the loops of spireme threads are polarized towards one side
of the nucleus in synapsis, and association in pairs of the sides of several loops
(i.e. of threads) is seen to be taking place simultaneously (Figs. 47 and 48).

The entire filament as it emerges from synapsis is wholly of univalent
nature ; no unassociated threads or halved filaments remain (Fig. 49). There
may be a space in the substance of the univalent spireme between the two
recently associated threads ; this space marks the future line of that delayed
fission which will take effect on the homotype spindle when the daughter
univalent chromosomes separate from each other during the homotype
mitosis.

After the spireme filament has become unravelled, and is distri-
buted throughout the nuclear cavity, segments of the entire (i.e. made
up of the joined halves) univalent spireme filament proceed to conjoin in
pairs. The first indication of this conjunction is to be seen in the drawing
together of the sides of loops or lengths of spireme filament, the two being
joined by a fine transverse strand (Fig. 54, &c.). This conjunction in pairs
of univalent spiremes (i.e. of filaments) is prepared for, and more or less
achieved, during the stages leading to second contraction (PI. X, Figs. 68,
69, &c.), but it is finally consummated during second contraction itself
(Figs. 71 and 72). In the early conjoining stages, the conjoining filament
segments describe figures closely resembling the future heterotype chromo-
somes (Fig. 65). The two individual filament segments of each conjoining
pair are precisely similar (Fig. 69).

As the bivalent segments come out of second contraction they proceed
to disjoin and give rise to the typical heterotype chromosome figures
(Fig. 74, &c.).

The two entire univalent chromosomes of each bivalent combination
separate on the heterotype spindle (PI. XI, Fig. 82). As the univalent

Meiotic Mitoses of Osmunda. 165

chromosomes proceed to the poles, fission almost completely separates
them into the daughter chromosomes which will separate on the homotype
spindle (Fig. 84).

In anaphase (Fig. 85) these daughter univalent chromosomes persist (see
Text-fig., Nos. 25 and 26), and as telophase advances each daughter chromo-
some further splits into two threads (Fig. 86). This apparently additional
secondary fission may be accounted for by the fact that entire univalent
chromosomes, instead of half univalent chromosomes, have passed to the
spindle poles, as in all other spindle figures.

The daughter chromosomes become resolved into paired beads and
parallel threads (Figs. 87 and 88), and the identity of the chromosomes is
lost to view.

5. Second Meiotic Division.

The homotype prophase follows speedily on the heterotype telophase,
and with no intervening rest. The threads derived from the splitting of the
daughter halves of the univalent chromosomes of the heterotype anaphase
come together in pairs, and concentrate into chromatic masses (Fig. 89).
These are in excess of the reduced number of chromosomes, and this is only
to be expected, since double the reduced number of chromosomes split
apart in anaphase, owing to the splitting of the daughter univalents (see
Text-fig., Nos. 25-28).

Throughout the homotype prophase the daughter chromosomes are
more or less separate, and they pass on to the spindle as individual entities
(Fig. 94) (see Text-fig., Nos. 29-35). As the daughter univalent chromo-
somes proceed to the spindle poles, each one becomes almost completely
divided into longitudinal halves (threads) (Fig. 95). This is the reappearance
of that fission seen in the daughter chromosomes of the heterotype telophase
(Fig. 86). The fission closes up temporarily during the homotype anaphase
(Fig. 96), and then reappears during telophase, thus splitting the chromo-
somes into halves (threads) (Fig. 98). These threads are at first homo-
geneous and then become beaded. The parallel threads gradually diverge
from one another (Fig. 99) and form a reticulum, thus giving rise to the
resting stage of the several tetrad nuclei (Fig. 100).

6. The exact correspondence of the two spiremes as they come
together in pairs is exceedingly striking. This phenomenon is character-
istic, not only of the associating pairs of threads or half univalent spiremes
of the somatic and presynaptic prophases (PI. VIII, Figs. J 1, 14, 16 ; PI. IX,
Figs. 41, 46, &c.), which combine to form the entire univalent spireme
filament, but also of the conjoining pairs of filaments or entire univalent
spiremes of the post-synaptic stages which unite to form the bivalent
spireme (PI. X, Fig. 69). In both cases the paired spiremes are taut and
strained, and the spireme of each pair is precisely similar to its fellow, even
to the beading. If their previous history had not been traced, the spiremes

1 66

Digby . — On the Archesporial and

in both instances would be considered to be splitting asunder instead of
approaching each other.

7. In the same sporangium nuclei in widely separated stages may occur
(PI. XII, Fig. 101), testifying to the rapidity with which the nuclear phases
are passed through. Sporangia have been found in which some of the spore
mother-nuclei are in pre-second contraction, whilst others are in diakinesis
(Fig. 101) ; again, some of the nuclei may be in second contraction, while
others are in metaphase.

8. Several cases of synangia have been found, one in archesporial
division (Fig. 102) ; the others have their spore mother-cells in the first
meiotic division (Figs. 103, 104, 105, and 106). The nuclei of one side of
the synangium may be in a considerably more advanced stage than those of
the other (Figs. 105 and 10 6).

Chief Results of the Foregoing Investigation.

1. It is shown that telophasic events have an important bearing on the
interpretation of the succeeding prophase.

2. That the sequence of events in prophase can only be interpreted in
the light of the preceding telophase.

3. The above-mentioned facts have been found to be of fundamental
importance in elucidating the early stages of the heterotype division.

4. In the heterotype division the prophasic stages, ordinarily included
under ‘ synapsis do not consist in the lateral conjunction of two entire
somatic chromosomes, but in the lateral reassociation of the threads in
pairs which together make a single entire somatic chromosome.

5. Conjunction in pairs of entire somatic chromosomes occurs in the
stages leading up to, and is finally consummated during, second contraction.

In conclusion I wish to express my great indebtedness to Professor
Bretland Farmer, F.R.S., for his most valuable advice and criticism, and also
for his kindness in affording me facilities which have rendered the comple-
tion of this investigation possible.

The Botanical Laboratory,

Imperial College of Science and Technology.

Bibliography.

1. Bower, F. O. (1900) : II. Studies in the Morphology of Spore-producing .Members. No. IV.

The Leptosporangiate Ferns. Phil. Trans. Roy. Soc., B., cxcii, pp. 29-138,

2. Derschau, M. von (1909) : Beitrage zur pflanzlichen Mitose : Centren, Blepharoplasttn.

Pringsh. Jahr. wiss. Bot., Leipzig, xlvi, Heft I, pp. 103-18.

3. Digby, L. (1910) : The Somatic, Premeiotic, and Meiotic Nuclear Divisions of Galtonia
candicans. Ann. of Bot., xxiv, No. 96, Oct., pp. 727-57.

(1912): The Cytology of Primula kewensis and of other related Primula Hybrids.

Ann. of Bot., xxvi, No. 102, April, pp. 358-88.

4.

Meiotic Miloses of Osmunda . 167

5. Digby, L. (1914) : A Critical Study of the Cytology of Crepis virens. Archiv f. Zellforschung,

Leipzig, xii, i. Heft, pp. 97-146.

6. Farmer, J. B. (1912): Telosynapsis and Parasynapsis. Ann. of Bot., xxvi, No. 102, April,

pp. 623-4.

7. and Digby, L. (1910) : On the Cytological Features exhibited by certain

Varietal and Plybrid Ferns. Ann. of Bot., xxiv, No. 93, Jan., pp. 191-212.

8. and Moore, J. E. S. (1905) : On the Meiotic Phase (Reduction Divisions) in

Animals and Plants. Quart. Journ. Micr. Sc., xlviii, Part 4, Feb., pp. 489-557.

9. Fraser, H. C. I., and Snell, J. (1911): The Vegetative Divisions in Vicia Faba. Ann. of
Bot., xxv, No. 100, Oct., pp. 845-55.

10. Gr£goire, V. (1907) : La Formation des Gemini h^terotyp'iques dans les vegetaux. La

Cellule, Louvain, xxfv, 2e fasc., pp. 369-420.

11. Guignard, L. (1898) : Le Developpement du Pollen et la reduction chromatique dans le

Naias major. Archiv. d’Anat. Micros., Paris, ii, pp. 455-509.

12. Humphrey, J. E. (1894) : Nucleolen und Centrosomen. Ber. deut. bot. Gesellsch. Berlin, xii,

pp. 108-17.

13. Ishikawa, M. (1916): A List of the Number of Chromosomes. Bot. Mag., Tokyo, xxx,

. No. 360, pp. 404-48.

14. Lawson, A. A. (1912): A Study in Chromosome Reduction. Trans. Roy. Soc., Edinburgh,

xlviii, Part iii, No. 25, pp. 601-27.

15. Meves, F. (1907) : Die Spermatocytenteilungen bei der Honigbiene ( Apis mellifica , L.), nebst

Bemerkungen iiber Chromatinreduktion. Archiv f. mikr. Anat., Bonn, lxx, 3. Heft, Juli,
pp. 414-91.

16. Nothnagel, M. (1916) : Reduction Divisions in the Pollen Mother-cells of Allium tricoccum .

Bot. Gaz., Chicago, lxi. No. 6, pp. 453-76.

17. Strasburger, E. (1900) : Ueber Reduktionstheilung, Spindelbildung, Centrosomen und Cilien-

bildner im Pflanzenreich. Hist. Beitrage, Jena, iv-vi, pp. 1-224.

18. Wilson Smith, R. (1900): The Achromatic Spindle in the Spore Mother-cells of Osmunda

regalis. Bot. Gaz., Chicago, xxx, No. 6, pp. 361-77.

19. Yamanouchi, S. (1910): Chromosomes in Osmunda. Bot. Gaz., Chicago, xlix, No. 1,

pp. 1-12.

EXPLANATION OF PLATES VIII-XII.

Illustrating Miss Digby’s paper on the Archesporial and Meiotic Mitoses of Osmunda.

All the figures were drawn with a camera lucida under a 2 mm. apochr. Horn. imm. Zeiss N.A. 1-40

with comp. oc. 18 x about 2250.

For the photomicrographs on Plate XII I am indebted to Mr. W. B. Randles, B.Sc.

Figs. 1-24. Archesporial Divisions.

Figs. 25-34. Interkinetal Stages.

Figs. 35-88. First Meiotic Division.

Figs. 89-100. Second Meiotic Division.

Fig. 1 01. Sporangium containing nuclei in widely separated stages (photomicrograph).

Figs. 102-6. Synangia (photomicrographs).

Osmunda palustris. Figs. 4, 16, 19, 25, 26, 27, 28, 62, 63, 64, 65, 79.

O, palustris var. undulata. Figs. 22, 60, 61, 67, 68, 69, 71, 72, 73, 74, 102, 103.

O. regalis. Figs. 32, 48, 82.

0. palustris var. aurea. All the remaining figures.

ABBREVIATIONS.

1. Fixatives. A.A. = Acetic Alcohol ; H. = Hermann ; S.C. = Strong Chromic ; S.F. = Strong
Flemming ; S.M. = Strong Merkel ; W.F. = Weak Flemming.

2. Areas of Nucleus. E. = East ; N. = North ; N W. = North-West ; S. = South ; SE. = South-
East; SW. = South-West; W. = West.

O

Digby. — On the Archesporial and

1 68

PLATE VIII.

Fig. i. 0. palustris var. aurea. Polar view of anaphase of archesporial mitosis. Fission not
visible in the chromosomes (S.F.).

Fig. 2. Early telophase showing the splitting of the chromosomes into longitudinal halves or
threads (S.F.).

Fig. 3. The nucleus is bounded by a limiting membrane. Some of the individual split chro-
mosome segments are still recognizable, while others have lost their visible identity owing to the
separation of their beaded halves (threads) (S.F.).

Fig. 4. 0. palustris. The hreads become resolved into fine beads producing a cloudy effect
(W.F.).

Fig. 5. O. palustris var. aurea. The beaded threads tend to separate from one another, thus
inaugurating a reticulum. In some of the chromosome segments the halves (threads) are still closely
parallel (S.F.).

Fig. 6. The beaded threads have completely separated, and the nucleus shows a faint reticulum,
the chromatin being mostly concentrated in the nucleoli. This is the so-called 1 resting ’ stage (S.F.).

Fig. 7. Very early prophase. The nucleus has a generally more active appearance, and a few
large chromatic granules are present in the reticulum (S F.).

Fig. 8. The granules of the reticulum become more distinctly chromatic (S.F.).

Fig. 9. The chromatic granules incline to cluster and are of very varied sizes ; the meshes of
the reticulum become wider (S F.).

Fig. 10. Some of the threads of the reticulum break down, and the meshes open out, and thus,
very gradually, the reticulum becomes converted into a spireme thread. At this stage there are
indications of the fine spireme threads tending to arrange themselves in parallel pairs. This is the
first sign of the reassociation of the threads, i. e. the longitudinal halves of the chromosomes which
Separated during the preceding telophase (Fig. 4, &c.). Therefore each thread is of a half univalent
nature. As prophase advances the reassociation becomes closer until the mature univalent chromo-
some is organized (S.F.).

Fig. 11. The beaded linin threads form striking parallelisms, as shown in the pair lying
horizontally in the E. of the nucleus. Cf. this reassociation of the chromosome halves with the
separation of the chromosome halves, as shown in Figs. 4 and 5. Note that the two approaching
threads are precisely similar even to the correspondence of the beads (S.F.).

Fig. 12. The linin threads become increasingly distinct and the chromatic beads show more
definitely a parallel arrangement, and are often disposed in groups of four (S.F.).

Fig. 13. A slightly later stage ; the chromatic beads are somewhat larger (S.F.).

Fig. 14. The chromatin from the beads gradually infiltrates the linin threads, causing them to
stain chromatically (S.F.).

Fig. 15. A superficial section of a nucleus from the same sporangium as Fig. 14, showing some
of the lengths of associating spiremes as fine parallel threads, whilst others are chromatic (S.F.).

Fig. 16. 0. palustris. This nucleus shows the close association in pairs of the threads, and the
segregation of these paired individual segments suggestive of the future univalent chromosomes.
Note the exact similarity of the approaching sides (H.).

Fig. 17* 0. palustris var. aurea. Note the marked association of the threads (S.F.).

Fig. 18. Superficial section of a portion of a nucleus from the same sporangium as Fig. 17,
showing that on the close association of two threads the resulting filament becomes considerably
thickened (S.F.).

Fig. 19. 0. palustris. A later stage in which there is an almost complete approximation of the
two parallel threads, and the space between them may now be distinguished as the line of fission.
The spireme filaments curve and undulate, and many of the fine connecting transverse strands have
disappeared (A. A.).

Fig. 20. 0. palustris var. aurea. The spireme filaments lengthen out, but are still undulating.
In this particular nucleus fission is evident (S.F.).

Fig. 21. Spindle fibres appear and converge towards the nucleus from four points (S.F.).

Fig. 22. 0. palustris var. undulata. The nuclear limiting membrane disappears, the chromo-
somes concentrate, and vestiges only of fission are to be seen (S.M.).

Fig. 23. 0. palustris var. aurea. Oblique view of a metaphase. The chromosomes are thick
and concentrated and show no fission (S.F.).

Meiotic Mitoses of Osmunda. 169

Fig. 24. The daughter chromosomes show no fission as they proceed to their respective poles
(S.F.).

Fig. 25. 0. palustris. Telophase of the last archesporial division before the heterotype pro-
phase. The chromosome segments are splitting apart into halves (threads) ; each thread may be
more or less homogeneous, or beaded (S.M.).

Fig. 26. The separation of the chromosome halves or threads has proceeded slightly farther ;
note the clear spaces round the nucleoli (S.M.).

Fig. 27. Superficial view of a portion of a nucleus at this stage; fine strands join the severally
paired segments, the skeletons of the former chromosomes (S.M.).

Fig. 28. Very late telophase. The chromosomes are now no longer recognizable owing to the
dispersal of their halves, although parallel fine threads are still to be seen. The more aggregated
appearance of the chromatin is due to the fixative used (S.C.).

Fig. 29. 0. palustris var. aurea. Typical late telophase showing the spaces round the two
nucleoli, the threads having completely separated and fragmented into beads (S.F.).

Fig. 30 A nucleus showing both telophase and prophase characters, evidently passing directly
from the telophase of the last archesporial division into the heterotype prophase (see also Figs. 31
and 32). The beaded parallel threads and the presence of three nucleoli are suggestive of telophase,
whilst the large size and generally active appearance of the nucleus denote prophase (S.F.),

PLATE IX.

Fig. 31. Superficial section of a nucleus in the same stage as Fig. 30 showing strikingly paired
threads (S.F.).

Fig. 32. 0. regalis. Another nucleus which cannot be definitely described as either in telophase
or in prophase. Although actually only one pair of parallel beaded threads is to be seen (in the S.
of the nucleus), yet there are indications of parallel arrangements in the groupings of the beads and
in the disposition of the fine linin threads (A. A.).

Fig. 33. 0 . palustris var. aurea. A transitional nucleus passing directly from telophase of the
last archesporial division into the heterotype prophase without an intermediate rest. The nucleus
is larger than in rest (Fig. 34) and is active in appearance and stains sharply. Three nucleoli are
present ; the chromatic beads are larger than those of early prophase (Fig. 36) ; parallel arrange-
ments of beads and threads are to be seen. It is impossible to designate such a nucleus as being
either in telophase or in prophase (S.F.).

Fig. 34. The resting stage between the last archesporial division and the heterotype prophase.
The nucleus shows a colourless reticulum with the chromatin concentrated in the nucleoli (S.F.).

Fig. 35- Very early prophase ; note the somewhat more sharply staining reticulum and the few
chromatic granules (S.F.).

Fig. 36. A nucleus definitely in prophase. The reticulum is more defined, consisting of fine
threads with chromatic beads at the junction of the meshes. A few of the linin threads tend to run
parallel to one another, and the granules to group themselves in pairs and fours (cf. Fig. 10). This
is the first indication of the reassociaiion of the chromosome halves (threads) which separated in the
preceding telophase (Figs. 25, 26, and 27) (S.F.).

Fig- 37. The nucleus has enlarged considerably. The reticulum gradually opens out to form
beaded threads, and these threads tend to run in pairs, each thread representing half a univalent
chromosome of the preceding telophase. As the nuclei proceed towards synapsis the pairing of these
half univalent spiremes (threads) preparatory to their close association to form the entire univalent
spireme (filament) becomes increasingly conspicuous (S.F.).

Fig. 38. The linin threads become chromatic and hence definitely spireme in character (S.F.).

Fig. 39. The spireme shows a very striking pairing of its lengths (S F.).

Fig. 40. The pairing becomes more accentuated, and in some parts has resulted in the close
association of the two threads to form the entire univalent spireme or filament (S.F.).

Fig. 41. Note the lengths of paired threads connected at intervals by paired beads. There is
a slight withdrawal of the nuclear contents in the NW. portion of the periphery preparatory for
synapsis (S.F.).

Fig. 42. The spireme thread retreats from the nuclear periphery and is thrown into loops which
lie free in the nuclear cavity ; towards the margins parallel arrangements are visible (S.F.).

Fig* 43* A superficial section of a nucleus in the same stage as Fig. 42, showing two associating
lengths of spireme thread twisting over one another (S.F.).

O 2

170 Digby. — On the Archesporial and

Fig. 44. Another superficial section of the same stage showing threads running closely
parallel (S.F.).

Fig. 45. Early synapsis. Association of the sides of the loops (i. e. of two threads) can be seen
towards the margins of the knot, especially in the S. It will be seen that the two threads are
separate for a length and then closely associated (S.F.).

Fig. 46. Superficial section of a portion of a nucleus in early synapsis, showing striking
similarity of the approaching threads (H.).

Fig. 47. Synapsis showing the polarization of the threads as loops towards one side of the
nucleus, and the association of the threads, i. e. the sides of the loops, in pairs actually taking place.
This is the consummation of the association of the half univalent spiremes (threads) in pairs to form
the entire univalent spireme (filament) (S.F.).

Fig. 48. 0. regalis. This nucleus in synapsis is at a slightly later stage to that of Fig. 47.
The association of the threads has become closer, leaving only a vestige of ‘ fission ’ between
them (A.A.).

Fig. 49. 0. palustris var. aurea. The spireme filament is beginning to come out of synapsis.
The association is completed ; the emerging spireme filament is thick, being the product of the
coming together of the two halves of univalent spireme, i. e. of two threads. From henceforth the
spireme filament is of an entire univalent nature. Fission is visible in parts (H.).

Fig. 50. Superficial section of a nucleus coming out of synapsis. Every portion of the spireme
filament shows fission and that of a very beaded character, characteristic of Hermann fixation (H.).

Fig. 51. Early hollow spireme. The spireme filament has come out of synapsis and is dis-
tributed throughout the nucleus. Fission separates more thread-like sides characteristic of Strong
Flemming fixation (S.F.).

Fig. 52. Superficial section of a nucleus in the same stage as Fig. 51, showing the looping of
the spireme (S.F.).

Fig- 53- The spireme loops incline to arrange themselves round the nucleolus. In this nucleus
fission is still evident, whilst in some nuclei in the same sporangium (cf. Fig. 59) it is closed (H.).

Fig. 54. Figs. 54-8 are studies of the conjunction in pairs of lengths of filament, i. e. of entire
univalent spiremes, the first indication of the evolution of the heterotype chromosomes. Note in the
loops pointing S. in Fig. 54 the sides are drawn in towards one another and connected by a fine
transverse strand. Also the two filaments pointing NW. are connected by fine cross strands (H.).

Fig- 55* Note the conjunction of the univalent sides of the loop suggestive of a future U-shaped
chromosome. Fission in the univalent sides, separating the threads, is evident (H.).

Fig. 56. Shows the conjunction of univalents (i. e. of filaments) prophetic of a future X-shaped
chromosome (S.F.).

Figs. 57 and 58 show a looping over and conjunction of univalents forming figures typical or
heterotype chromosomes. In Fig. 57 only vestiges of fission are to be seen (S.F.).

PLATE X.

Fig. 59. This nucleus is from the same sporangium as Fig. 53, but is in a slightly later stage.
Fission has closed, and there is a marked conjunction of filaments, as seen in the looping over of the
spireme, and in the S. of the nucleus fine transverse strands join the univalent sides (H.).

Fig. 60. 0. palustris var. undulata. The spireme in the N. portion of the nucleus is beginning
to aggregate preparatory for second contraction. Note the conjoining pair of filaments in the SE.
attached to the nucleolus. They are separate for a distance except for a fine transverse connexion,
and then closely conjoined and then again separate. No fission is visible (H.).

Fig. 61. Note the conjunction of filaments end to end to form a closed ring in the N. of the
nucleus, and the twisting over of two filaments in the centre of the nucleus (H.).

Fig. 62. 0. palustris . The filaments are withdrawing from the nuclear periphery and collecting
towards the centre in preparation for second contraction. Note the loop to the S. of the nucleus
showing fission. At this stage the spireme filament has definitely segmented and free ends are to be
seen (H.).

Fig. 63. Nucleus preparing to go into second contraction. Note the striking example of con-
junction in the SW. portion of the nucleus. The filaments are closely conjoined for a length and
then diverge to form a closed loop. No fission is visible. The apparently thickened spireme of the
nucleus is due to the strong chromic fixative. Towards the SE. striae are visible in the cytoplasm,
the first sign of the origin of the spindle fibres (S.C.).

Meiotic Mitoses of Osmunda . iji

Fig. 64. Superficial section of a nucleus showing the conjunction of filaments. The resulting
figures are extraordinarily like those of fully organized heterotype chromosomes (cf. Fig. 78) except
for the slightness of the filaments. Fission is visible in the substance of some of the filaments, in
others it is closed (H.).

Fig. 65. Another superficial section of the same stage as Fig. 64. Note the bivalent segment
on the SE. side showing fission in the independent filaments or segments of univalent spireme, and.
then their conjunction to form a closed ring showing no fission (H.).

Fig. 66. 0. palustris var. aurea. A study of two conjoining filaments twisting over one
another, showing fission in their free ends (H.).

Fig. 67. 0. palustris v ar. uudulata . A nucleus going into second contraction, showing little
sign of conjunction. This nucleus is taken from the same sporangium as Figs. 68,69, and 71, and
even from the same microscopic field as Figs. 69 and 71. In Fig. 69 conjunction is advanced, in
Fig. 71 the nucleus has entered second contraction (H.).

Fig. 68. As the filaments go into second contraction they show close conjunction in pairs. The
nucleus has decreased considerably in size (H.).

Fig. 69. This nucleus is taken from the same sporangium and even from the same microscopic
field as Fig. 67. Whereas in Fig. 67 the filaments are relatively thick and show little sign of con-
junction, in Fig. 69 close conjunction in pairs has taken place between most of the segments. Note
the taut and strained appearance of the conjoining filaments and their precise similarity even to the
beading (cf. the same phenomenon in the associating threads, Figs. 16, 41, and 46) (H,).

Fig. 70. 0. palustris var. aurea. A nucleus going into second contraction. In the centre the
filaments have collected to form a dense mass. Note the variety in shape, size, and degree of con-
centration in the filaments not involved in the central mass ; some have conjoined and some are in
the act of conjoining (H.).

Fig. 71. 0. palustris var. undulata. This nucleus is taken from the same sporangium and from
the same microscopic field as Figs. 67 and 69. The greater part of the nuclear contents are in
second contraction, the two outlying filaments show a twisted conjunction (H.).

Fig. 72. Another figure of second contraction. Some of the outstanding bivalent segments
show a wide separation of their filaments and others close conjunction (H.).

Fig. 73. A nucleus coming out of second contraction. As the bivalent segments emerge some
show close conjunction of their univalents, whilst others show stages in the process of disjunction.
Above the nucleolus on the E. side is an instance of a univalent spireme emerging in detached
portions which speedily join up end to end r(H.).

Fig. 74. This nucleus is an example of the second contraction apparently loosening directly into
fully organized bivalent chromosomes. The two bivalent segments on the W. side of the nucleus
are disjoining (H.).

Fig. 75. 0. palustris var. aurea. In this type of nucleus the bivalent segments come out of
second contraction as two closely conjoined univalents, and their disjunction closely resembles fission.
The univalent sides as they disjoin are slight, but speedily concentrate (S.F.).

Fig. 76. As the univalent chromosomes disjoin they concentrate and stain homogeneously.
Note the thick bivalent segment running N. and S. which has not yet disjoined into its univalent
segments (S.F.).

Fig. 77. On coming out of second contraction, the chromosome segments pass to the periphery
of the nucleus. Some of the bivalent or heterotype chromosomes are clearly individualized. Fission,
which is rarely visible at this stage, can be seen in the univalent segment of the chromosome lying
against the S. boundary of the nucleus (H.).

Fig. 78. The chromosomes concentrate rapidly. Note the univalents twisting over one another
in the E. of the nucleus, recalling the twisting over of univalent spiremes (i. e. of filaments) in the
early conjunction stages (cf. Fig. 64, the segment in the S. of the nucleus) (S.F.).

Fig. 79. 0. palustris. Spindle fibres make their appearance from four points in the cytoplasm,
and the nuclear limiting membrane disappears (S.C.).

PLATE XI.

Fig. 80. 0. palustris var. aurea. The chromosome^ return towards the centre of the nucleus.
Fission is sometimes visible in the substance of the univalent chromosomes (H.).

Fig. 81. The spindle fibres invade the nucleus, and the chromosomes concentrate considerably
and fission closes (H.).

172 Eigby. — Archesporial and Meiotic Mitoses of Osmiinda.

Fig. 82. 0. regalis. Metaphase of the first meiotic division. The quadripolar spindle has
become bipolar (S.F.).

Fig. 83. 0. palustris v ar. aurea. Polar view of an equatorial plate showing twenty bivalent
chromosomes (H.).

Fig. 84. As the entire univalent chromosomes proceed to the poles fission widely separates each
chromosome into daughter chromosomes (H.).

Fig. 85. Polar view of anaphase ; each univalent chromosome appears double owing to fission
still widely separating the daughter chromosomes (H.).

Fig. 86. A second and new fission appears in each daughter univalent chromosome, splitting it
into two threads and giving it a fenestrated or vacuolated appearance (H.).

Fig. 87. The nucleus becomes bounded by a limiting membrane ; the splitting apart of the
sides (threads) of the daughter chromosomes proceeds, and fine transverse strands join the various
threads to one another (H.).

Fig. 88. Telophase of the first meiotic division. The identity of the chromosomes is lost to
view and the sides are resolved into paired beads and parallel threads (S.F.).

Fig. 89. The onset of the prophase of the second meiotic division. The chromatic nuclear
contents become concen' rated in rounded masses lying in the portion of the nucleus remote from the
cell-plate separating the daughter nuclei (S!F.).

Fig. 90. The nuclear contents mass together (S.F.).

Fig. 91. Spindle fibres invade the chromatic mass (S.F.).

Fig. 92. The chromatic segments which are still somewhat indeterminate loosen out along the
fibres (S.F.).

Fig* 93* The chromosome segments become greatly elongated and each appears double, having
already split into daughter chromosomes (S.F.).

Fig. 94. Metaphase of the second meiotic division. The daughter chromosomes are completely
separated before taking up their position on the spindle (H.).

Fig. 95* As the daughter chromosomes proceed to the poles fission almost completely separates
them into threads. This is the opening out of the fission prepared for in the alveolization of the
daughter univalent chromcsomes in the anaphase of the heterotype division (Fig. 86) (H.).

Fig. 96. Polar view of the anaphase of the second meiotic division. The chromosomes draw
together and fission closes (H.).

Fig. 97. The chromosomes separate from one another, and fission once more divides them into
longitudinal halves or threads which are at first homogeneous (H.).

Fig. 98. The threads become beaded (H.).

Fig. 99. A nuclear limiting membrane appears. The beaded threads separate, but the beaded
skeleton of a few of the chromosomes can still be recognized (H.).

Fig. 100. The resting stage of the tetrad. The beads become distributed throughout the nucleus
and thus a fine reticulum is formed (S.F.).

** ...

PLATE XII.

(Photomicrographs by Mr. W. B. Randles.)

Fig. 1 01. 0. palustris var. aurea. Spore mother-nuclei in pre-second contraction and in
diakinesis in the same sporangium, x 400.

Fig. 102. 0. palustris var. undulata. Synangium in archesporial division, x 350.

Fig. 103. Synangium. The spore mother-nuclei of one side are in synapsis and coming out of
synapsis, the nuclei of the other side are coming out of synapsis, x 200.

Fig. 104. 0. palustris \ ar. aurea. Synangium. The spore mother-nuclei of the one side are
in hollow spireme stage, but as the sporangium lies obliquely the section does not pass through
them on the other side, x 200.

Fig. 105. Synangium. The spore mother-nuclei of the one side are in synapsis, and of the
other side in diakinesis. x 225.

Fig. 106. Synangium. The spore mother-nuclei of the one side are in synapsis, and of the
other side in metaphase, x 200.

n I n R Y - Mi T OSES IN GSM fj N D A

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DIGBY— MITOSES IN OSMUNDA.

.

Remarks on the Organization of the Cones of
Williamsonia gigas (L. & H.).

BY

THE LATE E. A. NEWELL ARBER, M.A., Sc.D., F.L.S.,

Trinity College , Cambridge , University Demonstrator in Palaeobotany ,1

With five Figures in the Text.

AS is well known, the organization of the cones of Williamsonia gigas
il (L. and H.) has remained a palaeobotanical puzzle since the days
when Williamson 2 and Yates 3 first attempted that restoration independently
in 1849. The memoirs which bear on this matter and have been published
since that date must now approach, if they do not exceed, a hundred in
number. A detailed account of these researches, with a full and up-to-date
bibliography, has recently been given by Professor Seward,4 so they need
not be enumerated here.

At the present time there is much which is still admittedly obscure in
regard to the morphology of the cones of this plant. They have not yet
been found with all their organs in continuity, and there seems unfortunately
to be little likelihood of such incrustations being obtained in the near
future. From analogy with Bennettites, we should expect that the micro-
sporophylls in particular were fleeting, caducous organs, and thus the chance
of obtaining specimens fossilized while these structures were mature and
before they had been shed appears to be very small indeed. We must look
forward rather to the happy discovery of petrified male cones of this or some
similar species in the future, a discovery of which we need not despair,
seeing that a female petrified cone of Williamsonia is now known. Con-
siderable progress has, however, been made in the recognition of what is
either the complete or the incomplete female cone, firstly by Lignier,5 and
more convincingly by Seward 6 quite recently. It may be well therefore to

1 Owing to the author’s death before this paper was finally revised, the responsibility for any
errors which it may contain rests with me. I have to acknowledge a grant from the Royal Society
in aid of the preparation of this and other memoirs left by the author in various stages of comple-
tion.— Agnes Arber.

2 Williamson (1849). 3 Yates (1849).

4 Seward (1917), vol. iii, chapter 37.

6 Lignier (1903). 6 Seward (1917), vol. iii, pp. 429, &c.

[Annals of Botany, Vol. XXX11I. No. CXXX. April, 1919.]

1 74 A rber .— Remarks on the Organization of the

sum lip the difficulties which remain in order to see how the position stands
at present. This I propose to do briefly here.

The chief uncertainties are as follows :

(1) Were the cones monosporangiate (unisexual) or amphisporangiate
(bisexual) ?

(2) Where were the male sporophylls attached ?

(3) What structure, if any, was borne on the axis of the cone above the
female organs (interseminal scales and seeds) ?

(4) Was there an infundibular expansion, somewhat similar in form to
the united whorl of male sporophylls, but of a sterile nature, and where was
it attached ?

Were the Cones monosporangiate or amphisporangiate?

On the question as to whether the cones were monosporangiate or
amphisporangiate there will always be differences of opinion until the perfect
male cone has been discovered. It is, at present, a case merely of the
balance of probability. On the amphisporangiate side, the older view, we
find ranged the opinions of Lignier,1 Wieland,2 and quite recently Seward,3
who says (1917) ‘ they may have been bisporangiate — a view that seems to
me the more probable — but this has not been demonstrated \

That the cone of Williamsonia was monosporangiate, and that there
were separate male and female cones, was first advocated by Nathorst,4 and
more recently has been supported by Thomas.5 The present writer
supports the Monosporangiate theory on the following grounds.

He believes that all the parts of the two cones, male and female, were
figured by Williamson6 as far back as 1870, and that it is merely a matter
of piecing the parts together correctly. The illustrations in question are
Figs. 1, 2, 4, and 5 of Williamson’s PL 52, and Figs. 6-8 of the same author’s
Plate 53. The latter set of specimens are now known to represent the apex
of the axis still bearing interseminal scales, probably sterile. More com-
plete specimens of the lower parts of the same cones were figured by
Saporta7 from British specimens in 1891. The only doubt then as regards
the female cone is whether any organ was borne at the tip of the axis of
that cone at the region of the terminal mamilla, termed by Williamson the
corona, a point to be further discussed presently.

As particularly pertinent to this inquiry, emphasis may be laid on
a fact, which appears to have been overlooked in recent years. The cones
of Williamsonia had two quite different axes, exactly as Williamson first
figured them, and despite Lignier’s 8 opinion that the staminal whorl

1 Lignier (1907). 2 Wieland (1911), p. 462.

3 Seward (1917), vol. iii, pp. 423-4. 4 Nathorst, (1909) p. 30, (1911) p. 26.

5 Thomas (1915), p. 137. 6 Williamson (1870).

7 Saporta (1891), vol. iv, PI. iS, Fig. 2 : PI. 19, Fig. 2 ; PL 20, Fig. 2.

8 Lignier (1907).

i75

Cones of Williamsonia gigas (L. & Hi).

occurred on the same axis as the female organs. The cones which we now
know to have been partly or wholly female had a long conical axis, the best
illustrations of which are those of Saporta already referred to above. The
shape of these axes is also shown in the restoration of the female cone given
here in Figs, i and 2. Other cones, however, possessed a flask-shaped
or urn-shaped axis as figured on Williamson’s PI. 52, Fig. 4 (refigured in
outline here as Fig. 5, p. 177). The writer has also seen more than one
other example of the same structures among the specimens of Williamsonia
at Cambridge. The shape of this axis is entirely different from that of the
female flower, and thus there are certainly grounds for very strong suspicion

Fig. 1. Restoration of female cone of Williamsonia gigas with the front bracts (per.)
removed (half natural size). Fig. 2. The same in section; 9 organs = interseminal scales
or seeds.

that this plant possessed two cones. None of the urn-shaped axes, regarded
by the writer as male, ever show any trace of interseminal scales such as are
almost always persistent at the base or apex or both regions of the female
flower. Any organs which they bore were clearly attached apically, and it
is difficult to imagine that they could have been other than the microsporo-
phylls.

Where were the Male Sporophylls attached?

Perhaps the greatest difficulty in regard to the Williamsonian cone is
to decide where the male sporophylls were attached. These organs are of
course now exceedingly well known as detached objects. It should be
remembered in this connexion that Nathorst,1 to whom we owe our know-
ledge of these organs in particular, has shown that they were borne terminally
on something. The axis bearing them was not produced beyond the cup
of united sporophylls. That fact is incontestable. The male sporophylls

1 Nathorst, (1909) pp. 11, 12, (1911) p. 20.

176 Arber— Remarks on the Organization of the

were thus certainly not attached below the interseminal scales. It follows
therefore that they were borne either at the apex (corona) of the female
conical axes, or on the urn-shaped axis distinguished above. My own view
is that the latter possibility is almost certainly correct. If the urn-shaped
axes did not bear the microsporophylls, what did they bear ? They must
have borne some organ beyond doubt. They certainly did not bear inter-
seminal scales, unless in some other more distal region, now missing, and
even in that case one would have to admit that the cones of W illiamsonia
were dimorphic.

My view is that Williamson’s Plate 52, Fig. 1, was seated on the apex
of the axes seen in Figs. 4 and 5 of the same plate, and that his Fig. 2 is

Fig. 3. Restoration of male cone of W illiamsonia gigas (half natural size). Fig. 4. The same
in section, st. whorl of microsporophylls ; per. — bracts ; and. = androphore.

simply the lower surface of the cup of united microsporophylls. I
therefore restore provisionally the male cone of W illiamsonia as shown in
Figs. 3 and 4.

If this is correct the male strobilus in this species had a distinct
gonophore, or more strictly speaking androphore (and. in Figs. 3 and 4),
whereas the female cone had none. That is to say, there was a considerable
elongation of the internode or internodes between the perianth bearing
nodes at the base of the cone, and the node bearing the whorl of micro-
sporophylls. Such a gonophore occurs in the case of several Angio-
spermous amphisporangiate flowers, though somewhat rarely. The genus
Gynandropsis (family Capparidaceae), of South America and elsewhere,
furnishes a well-known example. In W illiamsonia, the object of the
gonophore no doubt was to elevate the microsporophylls when mature out

Cones of Williamsonia gigas (L. & //.). 177

of the circumscribed space enclosed by the perianth members when the
cone was immature.

The male cone of Williamsonia is probably not the only strobilus of
this group possessing a gonophore. In W illiamsoniella coronata , recently
instituted by Thomas,1 we find both the male and female organs of this
amphisporangiate cone borne on a long stalk. It is true that perianth
segments (so-called bracts) are not known to occur at the base of this stalk,

Fig. 5. Outline of the * pyriform axis’ (androphore) of a male cone of Williamsonia gigas (after
Williamson, W. C„, 1870, PL 52, Fig. 4), natural size.

but at the same time this organ may be at least provisionally interpreted as
being of the nature of a gonophore.

Were any Structures borne at the Apex of the
Female Cone?

The question as to whether any structure was borne at the ‘ corona ’ of
the female axis must be left open. In W illiamsoniella coronata , mentioned
above, the axis is also prolonged somewhat beyond the region of the inter-
seminal scales, though to a much less degree than in the female William-
sonia cone. There is no evidence, however, that it bore any other structure
above the female organs.

In the case of Williamsonia , I think it is very unlikely that anything
was attached in that region. Certainly the male sporophylls were not borne
here, and if anything was attached in this region it must have been some
other organ. It should also be recalled that many other examples of
< 1 Thomas (1915), Text-fig. 1.

178 Ar her. — Remarks on the Organization of the

female cones of other species of W illiamsonia are known as impressions, and
in one case as a petrifaction. In none of these is there any evidence that
the axis projected beyond the zone of the interseminal scales. The female
cone of W illiamsonia gigas appears to be quite exceptional in this respect.
It is therefore extremely improbable that any organ at all was attached at
the corona.

Was there a Sterile Infundibulum?

The question whether there was a sterile infundibulum may, I think, be
almost dismissed. It is an idea which persists as a relic of the times when
the nature of the whorl of male sporophylls was misunderstood, and probably
the idea arose originally from Williamson’s Fig. 2 on his Plate 52. There is
very little doubt that the organs in question represent simply the lower
surface of the microsporophyll whorl. In this view I agree with Seward,1
as opposed to Nathorst2 and Lignier.3 Williamson himself regarded the
specimen mentioned above as simply the other surface of the organ which
he illustrated on Fig. 1 of the same plate. If any such organ did exist it is
unknown to me, and it could only have been attached at the corona at the
apex of the female flower, at which point indeed it has been restored by
Lignier.4

Conclusions.

While in the absence of continuity between the male organs of the
cone of W illiamsonia gigas (L. and H.) and its axis it is impossible to prove
the exact morphology of the fructifications of this plant, I conclude that the
balance of probability points as follows in regard to the chief uncertainties
which exist as to the organization of the fructifications of this fossil.

(1) The cones were probably monosporangiate.

(2) The female cone possessed a conical axis, sheathed in perianth
segments below, and bearing seeds and interseminal scales above. The tip
of the axis projected for about 2 cm. beyond the highest interseminal scales,
as is also the case, but to a less extent, in W illiamsoniella coronata. In all
probability no other organ was borne on this axis, either at the tip or else-
where.

(3) The male cone possessed an urn-shaped axis sheathed in perianth
segments below. This axis was of the nature of a gonophore. On it was
seated apically the whorl of partly united male sporophylls. It did not
bear interseminal scales.

(4) There is no evidence of any sterile infundibular organ attached to
or terminating either cone. All the organs of these cones have been known
since 1870 in continuity, except the male sporophyll whorl and its gono-
phore.

1 Seward (1917), vol. iii, p. 428. 2 Nathorst (1909), pp. 12-13. 3 Lignier (1907).

4 Lignier (1903), Text-fig. 8, p. 35 ; see also Seward (1917), vol. iii, Fig. 548 on p. 432.

Cones of Williamsonia gigas (L. & Hi).

179

Bibliography.

Lignier, O. (1903): Le Fruit du Williamsonia gigas Carr. &c. Mem. Soc. Linn. Normandie,
vol. xxi, p. 19, 1903.

(1907) : Sur un moule litigieux de Williamsonia gigas (L. and H.) Carr. Bull. Soc.

Linn. Normandie, s6t. 6, vol. i, p. 3, 1909 for 1907.

Nathorst, A. G. (1909) : Palaeobotanische Mitteilungen. 8 : Uber Williamsonia , Wielandia ,
Cycadocephalus und Weltrichia. K. Svenska Vetenskap. Handl., vol. xlv, No. 4, 1909.

• (1911): Palaeobotanische Mitteilungen. 9: Neue Beitrage zur Kenntnis der

Williamsonia-Blnten. K. Svenska Vetenskap. Handl., vol. xlvi, No. 4, 1911.

Saporta, Le Marquis de (1891) : Plantes Jurassiques, tome iv : Types proangiospermiques et
Supplement Final. Pal. Francs., ser. 2, Vdgetaux, Paris, 1891.

Seward, A. C. (1917) : Fossil Plants, vol. iii. Cambridge, 1917.

Thomas, H. H. (1915): On Williamsoniella , a New Type of Bennettitalean Flower. Phil. Trans.
Roy. Soc , Ser. B, vol. ccvii, p. 113, 1915.

Wieland, G. R. (1911) : On the Williamsonian Tribe. Amer. Journ. of Science, vol. xxxii, p. 433,
191 1.

(1916) : American Fossil Cycads, vol. ii. Washington, 1916.

Williamson, W. C. (1849): On the scaly vegetable heads or collars from Runswick Bay, sup-
posed to belong to Z ami a gigas. Proc. Yorkshire Phil. Soc., vol. i, pt. 1, p. 45, 1849.

(1870) : Contributions towards the History of Zamia gigas, Lindl. and Hutt.

Trans. Linn. Soc , vol. xxvi, p. 663, 1870.

Yates, J. (1849) : Notice of Zamia gigas. Proc. Yorkshire Phil. Soc., vol. i, pt. 1, p. 37, 1849.

A New Auxanometer.1

BY

F. M. HAINES,

Demonstrator , Botanical Department , East London College,

With two Figures in the Text.

HAVING regard to the slow rate of growth usually obtained under
laboratory conditions, and the small magnifications effected by
existing auxanometers, an endeavour has been made to design an instru-
ment which will record the growth of the plant on a much larger scale, that
is with a much higher ‘ magnification 5 than has, as far as the author is
aware, ever been attempted hitherto, and which will at the same time allow
of the observation extending, if necessary, over a period of at least three or
four days. Although the form of apparatus to be described can claim no
advantage over its predecessors in the matter of simplicity, the manipulation
should present no difficulty after the first setting up, and the care necessary
will not seem disproportionate when the fact is taken into consideration
that the instrument is capable of magnifying the growth to such an extent
that its representative length on the recording graph may be varied at will
from 20 to ioo times the actual increase in length of the plant.

An experimental instrument fitted with everything except the com-
pensating gear for the stretching of the fibres has shown itself capable of
giving smooth curves on the recording sheet for periods of two days with
a magnification of fifty, and has been checked by a Ganong auxanometer
working on the same plant ; but as, owing to the present conditions, only
a rough working model has so far been constructed, the present account
must be looked upon as merely preliminary.

The chief features in the new instrument are as follows :
i. The magnification is not produced by concentric pulleys of different
radii arranged as in Ganong’s instrument, nor by a lever as in Farmer's, but
by employing a differential pulley, the plant being (indirectly) connected by

1 From the Botanical Department, East London College.

[Annals of Botany, Vol. XXXIII. No. CXXX. April, 1919.]

182

Haines . — ^4 New A nxanomete?

a fibre to the hook which usually carries the load, while the inking pen is
attached to the thread on which the ‘ work ’ is done.

2. The inking mechanism, to avoid friction, does not travel on
a vertical wire as in Ganong’s instrument, but runs horizontally on a mono-
rail, two-wheeled trolley.

3. The pen on the trolley travels over a rotating drum which is
actuated by a large falling weight and made to revolve once in twelve
hours by a clock mechanism ; and

4. The particular arrangement of pulleys over which the fibres pass
forms a complete compensating mechanism for general expansions and
contractions in the fibres, so that no error is introduced by variations in the
relative humidity of the surrounding atmosphere.

3 A

Fig. 1 is a diagrammatic representation of the instrument, showing
only the essential features without the compensating gear for changes in
length of the fibres. A fibre attached to the tip of the plant round a cotton-
wool pad passes over the two pulleys A and B, and down to the hook which
carries the pulley C. The pulley C is in the loop of a thread Q R, of which
the end R passes round one of the grooves of larger radius of the
differential pulley E, while the end Q passes round a groove of smaller
radius in the opposite direction. Each end passes about one turn round its
own groove and is then affixed to the rim of the pulley. Round that groove
on E which has the largest radius passes a fibre U, one end of which is
affixed to the pulley, while the other is attached to the trolley F. The

Haines. — A New A uxanometer.

183

latter runs on two grooved wheels on the single rail K, and carries a glass
pen L (see inset, Fig. 1), the point of which rests on the drum G.
G revolves once in 12 hours and possesses clips, which are not shown in the
figure, for affixing graph paper. As the plant grows the pulley C drops by
the same amount as the plant apex rises. Suppose the plant apex rises
and the pulley C falls a distance d, then if the thread R passes round
a groove on E of radius rv Q round a groove of radius r2, and U round
a groove of radius R, it can be easily shown that the trolley F and pen L

2 d R

move along the drum a distance -. For, if the pulley E turn through

ri~r2

one complete revolution, F moves a distance 2 n R (to the left, say), the
thread R descends a distance 2 ir rv and the thread Q ascends a distance 2 n r2.
C descends a distance equal to half the difference between the distances
moved by the threads Q and R, = f {2 tt rx — 2 tt r2} = it {r1 — r2). The magnifi-
distance moved by F 2 tt R 2 R

cation or ratio

distance moved by c T\ri~r^

plant grow a distance d the pen moves a distance

2 dR

so that if the

When the plant

grows it allows the differential pulley to turn so that the trolley F carrying
the pen may move over the drum. The movement is produced by a small
hanging weight N, and communicated to the trolley by means of the fibre
‘S which passes over the pulley M. In order that there may be no undue
strain on the plant, the weight N is such that it only just exceeds the
value of the limiting friction of the trolley and pulleys. With the same
object the weight D is provided to counterbalance the weight of C.

As the pen moves along and the drum G revolves, a spiral line is
traced out, the pitch of the spiral representing the twelve hours’ growth
2 R

multiplied by . The pulley E is made with five separate grooves

ri ~ r2

of radii 5 cm., 4-9 cm., 4*8 cm., 4 >6 cm., and 4-0 cm. (see inset to Fig. 1), so
that any desired magnification may be obtained by using appropriate pairs
or threes of the grooves. Any of the fibres may be affixed to any of the
grooves on E, the end of each fibre being provided with a little hook which
fits into a notch on the circumference and so facilitates the operation of
altering the magnification. At T is a clock-work mechanism for rotating
the drum. It is actuated by a heavy weight (not shown) hanging on the
end of a flexible brass wire which passes round a drum at H. The weight
is wound up by the handle P. The pulleys throughout are mounted on
needle or ‘ frictionless ’ bearings.

In the apparatus in its simplest form as described above, it will be
noted that any stretching of the fibres due to changes in humidity in the
atmosphere all acts in the same direction, namely to make the growth
appear too much , and as the magnification is large, and there is great length

i 84 Haines. — A New A uxanometer.

of fibre, the error introduced would be serious in accurate work. In order
to compensate for the variability in the lengths of the fibres the arrange-
ment employed is that seen in Fig. 2. In this figure it will be observed
there is no longer a single continuous fibre from the plant apex to the pulley
C as in Fig. 1, but there are three distinct fibres X2X2, Y, and z. The fibres
x2 and Y when they reach the pulley A pass round it a few turns and then
become attached to its rim. Similarly the fibres Z and pass round the
pulley B a few turns and are then also attached. In each case the two
fibres run round the pulley in the same groove and in the same direction,
but the pulleys A and B, instead of being simple, as in Fig. 1, are now
double, each possessing two distinct grooves of the same radius and side by

side (see inset, Fig. 2). In the
second groove of each pulley there
is attached a fibre running in the
opposite direction to the other two,
which when it leaves the pulley
hangs down and carries a small
weight. The weights V, v' carried
on these fibres are exactly equal,
and their function, which will be
more fully understood later, is to
maintain a tension in XxX2. The
reason that v and v run in separate
grooves on the pulleys A and B is
to avoid friction with the other
fibres, and to prevent the possi-
bility of those which are being
wound on to the pulleys becoming
superposed on those which are
leaving. The grooves are figured,
for the sake of clearness (in Fig. 2),
as if they were of different radii,
but this is not actually so, their
radii being, as already stated, exactly equal. As in Fig. 1, the pulley
C is counterbalanced by the weight D, and, when the plant grows, is
allowed to fall by the same distance as the stem apex rises. Now that the
nature of the pulleys and connexions is understood it will be readily seen
from the figure that stretching in the fibres Y and Z will tend to make the
reading too large , while stretching in the fibre xtx2 will tend to make the
reading too small. Also stretching in Q R, which in this respect acts like
a single fibre of length x (see Fig. 2), tends to make the reading too
large. For compensation, therefore, the length of XxX2 must be made equal
to the sum of the lengths x} Y, and z. As the growth of the plant and fall

Fig. 2.

Haines . — A New A uxanometer . 185

of C are small compared with the length of this relation holds sensibly
true throughout the experiment.

If the only possible source of error were that introduced by stretching
of the threads consequent upon changes in the relative humidity of the
atmosphere, this condition would be sufficient in itself to ensure compensa-
tion ; but as the fibres are also liable to stretch as a result of the tensions to
which they are subjected, complete compensation will only be obtained if
the average of the tensions in the fibres Z, Y, and (q + r) taken together be
made equal to the tension in the fibre XjX2. This condition is secured by
giving appropriate values to the weights V, v' and W (Fig. 2), and these
values are determined. as follows:

Suppose the tension maintained in the fibre u by the weight N = t.

2 / R

Then the tension in z will be equal to the wreight of C + ■> and the

t R

l K.

tension in Q = tension in R=

/i“^2

As V = v', the tension in X is only due to the weights V, v', and we

have

ty

TX

TZ

= w
= vr

= c +

2 t R

r, —r*

T(Q + r) =

2 tR

where c represents the mass of the pulley c, and
Tx, tYj&c., represent the respective tensions in the
fibres X, Y, &c. For equilibrium a weight zv3 is

2 / R

provided, equal to

ri~r2

For compensation (see above),
Ty + tz + t(Q+R)

3

TX =

, ( 2/R , 2/R

1. e. V' = W + C+ +

i r,-r2

m

= jw + ~ t R +c| / 3, or collecting the constant quantities,
( r\ ^2 ' ‘

R> r2, t, and C to one side of the equation, we get

/ 4 £R

3V'-w = — +C.

r,—r0

With the exception of the value of t, which can be found by prelimi-
nary experiment in a manner to be described later, all the quantities on the
right-hand side of this equation can be easily found by direct measurement
or weighing, so' that for perfect compensation a weight W is placed in the
scale-pan, which satisfies the above equation using the given values of
V and v'. If the tension produced in Y be found insufficient, or great
enough to harm the growing point, the weights V and v' may be altered
and the corresponding value for W again found from the equation and
placed in the scale-pan. The value of V is of the order five to ten grammes,

Haines. — A New A uxanometer.

1 86

and W may be anything from about 1-5 grm. down to 0*5 grm. or less,
according to the nature of the plant on which the experiment is conducted.

All stretching of the fibres is now compensated for except that of the
fibre U, which connects the trolley and differential pulley. Stretching here
is far less serious than elsewhere as it is not magnified by the instrument.
It will be seen that, supposing the instrument be magnifying the growth
a hundred times, even if the fibre stretch as much as the plant grows (which
it is very unlikely to do) the error will only be one per cent., and is
therefore scarcely worth correcting for. With lower magnifications and any
very accurate work, however, the error may be completely eliminated by
using a control fibre. A fibre 10 cm. long attached to a trolley of its own
running on a rail by the side of the first may be fixed to a special hook on
the stand carrying the differential pulley and be subjected by similar means
to the same tension as the first fibre. The expansions and contractions of
the control fibre are recorded at one end of the drum, and if they amount
to anything appreciable, the correction for the particular length of the fibre
U which has run out from E at any moment may be calculated and added
or subtracted from the recorded reading as the case may be. In order to
facilitate the determination of the length of U a scale of centimetres is
provided beside the rail K, the zero-mark being perpendicularly below the
bearings of E. When only a twelve hours’ observation is taken and the
travel of the trolley is large, the paper on the drum, when unfolded, will
reveal two graphs which may be added together algebraically to give the
correct curve.

Before an experiment, when no plant is connected with Y and the
scale-pan W is empty, small weights are gradually added to a light scale-
pan hanging at N, until the weight is found which will just set the experi-
mental trolley and differential pulley, &c., in motion. Let the weight
found = wv Next the weight is found which sets the trolley in motion
when disconnected from the differential pulley. Let this weight = w2.
Then, when the whole apparatus is fitted up for an experiment, and the
weight in the scale-pan at N is wv the tension in the fibre U is given by
the equation t — (ww + w1)-(wJl + ^2), where Wn is the weight of the scale-
pan at N.

i. e. t = w1 — wr

This is the value of t which should be substituted in the expression

, 4 ^ R

<$v — w = — +C,

Tl~~r2

when finding the correct value of w which ensures compensation in the
fibres Q, R, X2X2, Y, and Z (Fig. a). With a given value for the weights
V and v', therefore, the complete working equation for W is as follows :

'4R (Wj-W2)
r, — r0

W

= 3V'-{-

+ c

}•

Haines. — A New Auxanometer.

1 87

This, and the equation for the magnification, namely

are the only equations needed in the practical work.

A brief outline will now be given of the method of manipulation of the
instrument. The chief points in the preparation for an experiment may be
enumerated as follows :

1. Weigh the pulley C.

2. Connect the fibres Q, R, and U with grooves on E which give the
desired magnification.

3. Place the plant in position and measure the distance Y from its
apex to the pulley A.

4. Find the sum of the lengths x and Z by measuring from the centre
of E to the centre of B, and subtracting the length of the mounting of C.

5. Calculate ^ + Y + z, and move the pulley O until X1 + x2 = x + Y + z.
(During these operations, pulleys which have loose threads on them maybe
clamped, if necessary, by special provisions to prevent them being turned by
unbalanced weights.)

6. Attach the weights V and v'.

7. Find the weight w1 with the trolley detached.

8. Find the weight w2 which turns all the pulleys when the trolley is
attached to E. The value of w2 may be incorrect for two reasons : (a) the
friction of the pulleys A and B will be less than during the experiment, as
the weights w and wz are not yet in place, and (h) because the friction of
the pen L on the drum will be greater than during the experiment as the
drum is at rest instead of in motion. As the weights W and wz are very
small compared with the other weights producing friction in A and B, namely,
V, v', c, and D, the difference in friction values due to their absence will be
practically negligible, and the speed of revolution of the drum being also
very small, the two errors may be taken as counterbalancing one another.
If they do not counterbalance, the calculated value of W will be too small
(assuming the errors due to friction in A and B to be the most serious), and
W may be increased by a few milligrammes at the beginning of the experi-
ment. This will overcome the friction of A and O, and so restore the slight
tension in the thread Y.

9. Calculate the value of t and the tension in z due to t alone

(i.e. — - * R V Counterbalance this tension by a suitable weight placed in

the scale-pan at wv Also use the equation to find W. If the value found
be suitable, place the weight in the scale-pan ; if unsuitable, repeat the
operation with a different value for V and v'.

10. Attach Y to the growing point.

11. Adjust O very slightly until F is at the correct end of the drum.

i88

Haines . — ^4 New Auxanometer .

12. Set the drum in motion.

At this point the whole system is in equilibrium, for in the cases of A
and B the moments are equal in the two directions and the tension in z has
been arranged to counterbalance exactly the tension in U. When the plant
grows the tension in the fibre Y is released so that the moments of the
forces tending to turn A to the right become greater than those tending to
turn it to the left. A therefore turns to the right and increases the tension
in X2. This increases the tension in Xx and turns the pulley B to the right,
allowing C to fall. The tension in Q R falls so that E revolves to the right
as a result of the tension in U. The length of U is therefore increased so
that the trolley F moves over the drum. When the trolley reaches the end
of its travel it automatically stops the clockwork so that further rotation
causes no unnecessary lines on the graph, and the record may be removed
at the operator’s convenience.

In conclusion, the author wishes to tender his heartiest thanks to
Dr. Fritsch and Dr. Salisbury, who have given him every help and facility
for the prosecution of this work.

A Comparative Account of the Root-nodules of
the Leguminosae.

BY

ETHEL R. SPRATT, D.Sc., A.K.C.,

University of London, King s College , and Battersea Polytechnic.

With PJate XIII and five Figures in the Text.

In the Text-figures m. — meristematic zone ; B. = bacteroidal tissue ; c. = outer protective cells ;

v.b. — vascular strand ; r. = root.

PLANTS which are capable of producing root-nodules when Bacillus
radicicola penetrates into the root-hairs and subsequently the cortical
cells of the root may be placed in two classes — those which belong to the
Natural Order Leguminosae and those which do not. All these structures
have been shown by several investigators to be actively concerned with
assimilation of nitrogen. The bacteria utilize the free nitrogen of the
atmosphere, and since the plants associated with them can live in very poor
soil they produce nitrogenous material which can be assimilated by the
plant.

This symbiotic association is characteristic of the two gymnospermous
families Cycadaceae and Podocarpaceae, the dicotyledonous families
Elaeagnaceae and Myricaceae, and the genera Alnus and Ceanothus .
Although these plants are widely separated in any other classificatory
scheme, they are all non-legumes producing root-nodules containing Bacillus
radicicola *. Each of these nodules has individual characteristics, but in
every case the bacteria penetrate the root-hair and enter the cortex of the
root without causing any morphological change, until a young lateral root
during its passage through the cortex of the parent root becomes infected,
when its development is so altered that it becomes a nodule. The plerome
was already differentiated when the bacteria entered, therefore they
attacked the cortical cells only, the stele retaining its central position and
the growing point remaining apical (see Text-fig. i).

The nodules which are characteristic of the Leguminosae are produced
by infection of the root-hairs and cortex by the same organism, which here
stimulates the cortical cells to increase in size, thus producing a local swell-
ing which very soon becomes visible (see PL XIII, Fig. 6). A basal meristem

[Annals of Botany, Vol. XXXIII. No. CXXX. April, 1919.]

190 Spratt. — A Comparative Account of the

is differentiated from the pericycle, and in this area one or more vascular
strands appear and become continuous with the vascular tissue of the root.
By subsequent growth it breaks through the parenchyma of the root and
may become quite a large structure, consisting of a mass of central cells
containing bacteria, surrounded by a zone of parenchyma in which there
are a number of vascular strands, which are either collateral, with the xylem
towards the outside and exarch, or concentric, with the xylem central.
Both types may occur in the same nodule. The xylem consists of tracheides,
usually spirally marked, and parenchyma. The phloem is simply narrow,
very elongated cells. Each strand is surrounded by a few very definite
layers of cells which form a kind of bundle-sheath.

Text-fig. i. a . Longitudinal section of root and young nodule of Abuts, b. Transverse section
of nodule of Alnus. c. Longitudinal section of part of old branched nodule of Alnus. x 10.

The nodule is protected by a varying number of layers of cells developed
from a meristematic layer continuous with the phellogen of the root, which
may become dead and empty, or in some cases thickened (see PI. XIII,
Figs. 7, 8, 9).

Whatever its ultimate form and however much it may resemble any
particular non-leguminous nodule, e.g. Vicia Faba and Alnus , the nodules
in these two classes are fundamentally different. In the non-legume it is
a modified root, whilst in the legume it is an exogenous growth arising in
the cortex, which develops a peripheral vascular system and has not a
growing point which is primarily differentiated in an apical position.

The leguminous nodules have received a good deal of attention from
a large number of investigators. In 1867 Woronin described and figured
them, showing the central mass of bacteroidal cells surrounded by an outer
layer in which were several vascular bundles. Peirce in 1902 says they are
modified lateral roots, but subsequently described their origin from the
layer immediately outside the endodermis. They have, however, been very

Root-nodules of the Leguminosae . 191

largely accepted as modified lateral roots, and the organism responsible for
their formation has been the main subject of research. It has been variously
described as a fungus by Frank in 1879, Marshall Ward in 1887, and others,
also as simply proteid matter by Brunchorst, but in 1888 Beijerinck called
the organism Bacillus radicicola , and showed it to be a true Schizophyte.
The formation of infection threads led many to regard the organism as
a fungus, but in 1900 Dawson demonstrated that these are not fungal hyphae
but masses of little rod -like bacteria, which have divided very rapidly and
remained associated together, forming zoogleal threads in which they pass
from cell to cell (PI. XIII, Fig. 7).

It had long been thought that the nodules on leguminous roots were
connected with nitrogen assimilation ; this was definitely established to be so
by Hellriegel and Wilfarth in 1888. A few years later Nobbe and Hiltner
and also Maze demonstrated that it was the bacteria in the nodule which
were capable of utilizing the atmospheric nitrogen, and much has since
been done in Germany, America, and also in this country in an endeavour
to make a wide practical application of this power which the bacteria
possess. That the bacteria have a source of nitrogen supply apart from
that of the host plant is supported by the statement made by Moore, that
the percentage of nitrogen present in the nodule is greater than in any other
part of the plant.

The organism is polymorphic, and different forms occur, not only in
connexion with different plants but also in different cells of the same nodule.
Nobbe thought each tribe of the Papilionaceae had its own specific organism.
This, however, cannot be, because although the organism adapts itself to
a particular host and will therefore more readily infect another host of the
same kind, in 1901 the American Board of Agriculture found it possible to
cross-inoculate any legume from any other except Lupin, and Bottomley
has since cross-inoculated Tares with the organisms from Acacia , Alnus ,
and Elaeagnus , i. e. the two sub-orders of the Leguminosae, Papilionaceae,
and Mimosoideae with one another, and a legume with the two non-legumes
Alnus and Elaeagnus . Beijerinck in 1888 said there were two kinds of
Bacillus radicicola , distinguished by the medium in which they flourished,
which was either acid or alkaline. Most legumes do not incline towards an
acid soil, but Lupin and the particular race of Bacillus radicicola which
inhabits the nodules on its roots do, and since in an alkaline soil, or a plant
which normally lived in one, the environment would be so very different, it
is probable that the adaptation required is too great to be easily obtained.
This possibly has a further bearing on the structure of the nodules produced
by plants living under very different conditions.

The Natural Order Leguminosae is the second largest family of
Phanerogams, having about 440 genera and 7,000 species, living in every
kind of soil and climate and showing a variety in habit which includes trees,

192

Spratt. — A Comparative Account of the

shrubs, herbs, and climbers. Amongst so much diversity one naturally
looks for differences in the root-nodules of these plants, and they exhibit
great variation in form and size, and some also in their anatomy.

From the investigation of a large number of genera it seems possible
to place them in four groups, thus :

I. The Genisteae type, in which the nodule is primarily spherical, with
a spherical meristem outside the bacteroidal tissue, which later becomes
localized at certain parts, and thus the nodule acquires a very uneven surface
and shape see (PI. XIII, Fig. 1). The vascular supply forms one broad zone
across the base of the nodule, which subsequently branches and produces
a varying number of strands. The bacteroidal tissue becomes separated
into a number of distinct areas with a varying amount of sterile tissue
between them (see Text-fig. 2). The nodule is protected by a relatively large
development from a well-defined phellogen of regular layers of cells, of which
large areas are repeatedly split off and renewed as the nodule grows (see

Text-fig. 2. a. Longitudinal section of nodule and root of Lupin, b. Longitudinal section

of an older nodule, x 20.

PI. XIII, Fig. 8). Infection threads are rarely produced ; in fact, Beijerinck
says none are formed at all in Lupin. The nuclei with prominent nucleoli
remain conspicuous for a long time in the bacteroidal cells.

Plants with this type of nodule are further linked together by being
woody and having a copious development of periderm ; many are shrubs,
e. g. Genista , Ulex , Amorpha , and Laburnum is a tree. They can all live
on poor dry sandy soil, and some where there is little or no calcium
carbonate, e. g. Lupin. They are further characterized anatomically by
the presence of schizogenous secretory cavities with tanniniferous contents
which are colourless in the living plant, but become brown by the action of
oxidizing agents and drying. Curious four-sided prismatic structures also
occur in the parenchymatous tissue, which are crystals of calcium oxalate
and hatfe been called styloids. The medullary rays traverse the secondary
xylem obliquely, forming a kind of net-like pattern and producing knot-
like swelling in the neighbourhood of the xylem parenchyma. Tannin
sacs and styloids also occur in the nodules, and the parenchyma is more

Root-nodules of the Leguminosae. 193

active than in nodules of other genera, since its development causes the
separation of the bacteroidal tissue into several zones.

This group may be subdivided thus :

{a) In Lupinus , Ornithopus , Cytisus , and Desmodium the primary
vascular strand is tetrarch and divides into four, correlated with which
four growing points are differentiated. The bacteroidal zones become
separated by a broad band of parenchyma, in the centre of which a vascular
strand appears (see Text-fig. 2).

(b) In Genista , Ulex , Spartium , and. Amorpha the primary vascular
strand at the base is diarch and
divides into two strands which
traverse the nodule some distance
before branching again. The
bacteroidal zones are separated
by a narrow band of parenchy-
matous cells. In the old nodule
of Ulex an apical meristem is
differentiated, but more usually
there is one to each bacteroidal
zone (see Text-fig. 3).

II. The Phaseoleae and Tri-
foleaetype ofnodule are very simi-
lar to those above (PI. XIII, Fig. 2), but the bacteroidal tissue always remains
an undivided central zone. The growing point at an early stage frequently
becomes localized apically ; consequently they elongate, although usually

Text-fig. 3. Longitudinal section of nodule and
root of Spartium . x 20.

Text-fig. 4. a. Longitudinal section of nodule and root of Phaseolus. x 10. b . Longitudinal
section of old nodule and root of Lotus corniculatus . x 15.

remaining very narrow, e. g. Trifolium , and frequently the apical meristem
branches so that a repeatedly branched nodule may result, e. g. Lotus
corniculatus (see Text-fig. 4 and PI. XIII, Fig. 3).

There is greater development of infection threads than in the previous
groups. Dawson described them as being present only in the young

194 Spratt . — A Comparative Account of the

nodules of Phaseolus and Coronilla ; Peirce has described them in Trifolium ;
the writer has frequently observed them in young nodules. The nucleus
in the young bacteroidal cells is well defined, with a prominent nucleolus,
but as the cell increases in size it becomes associated with a large central
vacuole. In Lotus corniculatus frequently two nucleoli are present, and in
Coronilla the nucleus becomes amoeboid and subsequently divides so that
many cells are multinucleate.

Many of these plants have a very wide distribution and show an
immense adaptation to their environment, e. g. Trifolium and Lotus . They
live principally on poor dry sandy soil like the plants of the Genisteae type,
and like them produce characteristic tannin sacs, styloids, and oblique
medullary rays. Styloids are especially prominent in the outer tissue of the
nodule of Phaseolus (see PL XIII, Fig. 9). These nodules all have one
vascular strand at the base and may be grouped thus :

(a) Phaseolus , Coronilla , and others where the vascular strand divides
at the base below the bacteroidal tissue into four strands, which supply the
nodule for some time before any further branching occurs.

(b) Ononis , Anthyllis , and others in which the vascular strand divides
at the base into two.

(e) Trifolium , Lotus , and others where the single strand passes from
the base obliquely to one side of the nodule and remains undivided for
some time ; later it branches, but at some distance from the base.

III. In the Viceae type the nodules have an elongated form with
a well-defined apical meristem and a basal intercalary zone which produces
a small amount of tissue. The nodule frequently branches and may form
very large clusters, e. g. Vida Faba and Stizolobium ; but there is one
continuous bacteroidal zone, the apical portions of which are traversed
by innumerable infection threads. In young nodules these threads are
distributed throughout the whole tissue, but later they are confined to
the areas where new cells are continually being formed and infected with
Bacillus radicicola . The nuclei, which are at first large and prominent,
lose their spherical outline, become elongated and irregular, and eventually
separate into two or more irregular granular bodies associated with a large
vacuole, and later become further dispersed (see PI. XIII, Fig. 10). Two
vascular strands are produced at a very early stage of the development of
the nodule on opposite sides, each of which has a separate attachment to
the root-stele (see PI. XIII, Fig. 7).

In this group are a large number of plants of considerable agricultural
value which require a moderately good soil with sufficient clay to keep
it moist and calcium carbonate to prevent acidity. The genera Viciai
Pisurn, Lathy ms , Galega , Stizolobium , and Colutea have been examined
and found to have nodules of this type.

IV. The nodules of the above groups all occur on annual plants or are

195

Root-nodules of the Leguminosae .

produced each spring on the new roots and develop through the growing
season until the autumn, when they decay in the soil. Beijerinck drew atten-
tion to the perennial nature of the nodules of Robinia. The author has
examined nodules of Robinia Pse2idacacia> Sophora , and some species of
Acacia , all of which last for more than one growing period. These plants
are trees or woody undershrubs which are indigenous in the west temperate
and sub-tropical regions. The climatic conditions in these parts would
naturally enable the bacteria to retain their activity for a much longer
period than in colder regions, and in the nodules of these plants there
is a copious development of protective tissue from the phellogen, consisting
of thick-walled cells which are very dark in colour owing to the formation
of tannin in Robinia and Acacia , but in Sophora they remain much paler,
no tannin being present.

These three genera represent three quite different types of Legumi-
nosae, Acacia being a very large genus in the Mimosoideae, while

Text-fig. 5. Longitudinal section of nodule and root of Sophora. x 15. x is the first
bacteroidal zone produced ; z, that produced during the second growing period ; y , the area between
them, in which the vascular strands anastomose.

Sophora and Robmia are both members of the Papilionaceae ; but Sophora
represents the unusual type in which the stamens are free, and Robinia is
one of the largest trees in the order. They all have characteristic pinnate
leaves with a large number of pinnules adapted to a greater or less degree
for movement in response to external stimuli.

The nodules all develop two vascular strands which have a separate
attachment to the root-stele, and a well-developed bundle sheath is present.
In Acacia the meristem extends all round the bacteroidal tissue and its
activity is renewed from time to time. But the greatest growth always
takes place so that the nodule becomes bean-shaped (see PI. XIII, Fig. 4).
In Sophora and Robinia the growing point is apical and the nodule becomes
elongated and transversely indented. The indentations occur between two
periods of growth, and consist of cortical cells which in Sophora are trans-
versed by the vascular strands which anastomose in this area (see Text-fig. 5).

Infection threads have been observed in connexion with the migration
of the bacteria into the newer bacteroidal cells. These cells elongate in the

196 Spratt. — A Comparative Account of the

direction of the length of the nodule, become multinucleate, and later the
nuclei disappear. Many empty nodules were also found on the roots, in-
dicating that they only last for a limited period which does not correspond
with the life of the root as in non-leguminous nodules. This type may be
called the Mimosoideae type.

The amount of nitrogen which is fixed by Bacillus I'adicicola has been
thought to be connected with the quantity of slime which is produced
under the given circumstances. When the development of slime is large
the bacteria are held in it and form what is called a zoogleal thread. It is
in this form that they are very active in entering the root-hairs and passing
from cell to cell of the nodule. In the Viceae type the zooglea persists
much longer than in the other groups in the cell of the nodule itself.
Eventually the slime is absorbed and the bacteria live freely in the cell,
then in many cases they no longer remain rod-shaped but assume a
characteristic form, e. g. in Vida Fab a they become V and Y shape, in Lotus
corniculatus spherical. These have been called bacteroids. Buchanan has
described a large number of these forms both in nodules and artificial
cultures and ascertained that their production and formation depend very
largely on their nutrition. Many have believed them to be absorbed
by the plant, but inside them are small denser spherical bodies, the presence
of which renders the organism much more resistant to its environment than
it was before, consequently they are more and more abundant as the nodule
grows older and the season advances.

The nuclear changes which have been observed above are associated
with the presence of the zooglea. It is in those cells in which the zooglea
persists and envelops the nuclei that the latter become amoeboid and
divide amitotically before the cell becomes a permanent cell with very little
protoplasmic content at all. This has also been recorded in non-legumin-
ous nodules ; e. g. in the Podocarpineae and Elaeagnaceae the nuclei behave
as , described above for the Viceae type, but have not been observed to do
so in Alnus , although it is so much like Elaeagnus in other respects.
The presence of the zooglea apparently has a stimulating effect upon the
nucleus.

In artificial cultivation it has been observed that the amount of slime
produced is largely influenced by the medium used, e. g. the kind of carbo-
hydrate supplied. Bacteria obtained from nodules of different plants also
behave rather differently towards the carbohydrate supplied, some respond-
ing more readily to maltose, others to sucrose, and so on. They all can
utilize a very large number of carbohydrates, but become particularly
adapted to one form, probably by growing in the root of a plant which
contains that one. Buchanan found the production of gum or slime in
some cases was favoured by the presence of sodium succinate, ammonium
citrate, glycerine, glucosides, and inhibited by asparagin, whilst in other cases

197

Root-nodules of the Leguminosae.

it is entirely the reverse. It has, however, been demonstrated generally
that the addition of a trace of nitrogenous material behaves as a stimulant
for the rapid production of slime, and Mockeridge found the presence of an
organic substance, e. g. a humate, had a very marked effect. The acidity
or alkalinity of the medium also plays a prominent part. Moore found that
the presence of from 0-33 to 1 per cent, of potassium and sodium salts was
often sufficient to inhibit the formation of nodules, whilst the same amount
of calcium and magnesium salts favoured their production.

It therefore seems probable that the nature of the cell-sap of the root
will determine not only whether the bacteria shall enter and multiply, but
also the production of infection threads, which can only be produced in the
presence and absence of certain definite substances in the medium. This in
the plant is the cell, and the particular nature of the cell-sap it contains will
be influenced by that of the soil in which the plant is growing. It is
consequently of interest that they are absent from the Genisteae type and
only slightly developed in the Phaseoleae and Trifoleae type, which flourish
in poor sandy soil, but play an important part in the Viceae and Mimosoideae
types, which normally inhabit a richer damper soil. In the Genisteae type
also, where they are absent, the plants grow where there is a deficiency of
calcium carbonate. There thus seems to be a variation in the morphology
of the nodule resulting from infection produced primarily by the possible
response of the bacteria to the cell-sap of the host, and the presence of the
bacteria induces growth on the part of the host which will naturally be
influenced by the anatomical peculiarities of that plant.

Summary.

1. Plants which produce root-tubercles when infected with the
nitrogen-fixing organism Bacillus radicicola are of two kinds — legumes
and non-legumes.

2. The root-tubercles of non-legumes are modified lateral roots, but
those of legumes are exogenous in origin.

3. In the leguminous nodule the bacteroidal tissue is central and the
vascular system consists of a number of peripheral strands.

4. Bacillus radicicola is connected with the assimilation of nitrogen
from the atmosphere, and although it is polymorphic, cross-inoculation
occurs.

5. The leguminous nodules can be placed in four groups :

I. The Genisteae type, in which the meristem is spherical, the
vascular supply forms one broad zone across the base, and
the bacteroidal tissue becomes divided into several parts.

(a) In Lupinus the primary vascular strand is tetrarch and
the bacteroidal zones are separated by vascular as
well as parenchymatous tissue.

1 98

Sprcitt . — A Comparative Account of the

(b) In Genista the primary vascular strand is diarch and
the tissue between the bacteroidal zones is all paren-
chyma.

II. The Phaseoleae and Trifoleae type, in which the bacteroidal
tissue always remains an undivided central zone, the growing
point becomes localized apically, and zoogleal threads are
prominent in the young nodules.

(a) In Phaseolus the basal vascular strand divides into
four.

(b) In Ononis the basal vascular strand divides into two.

(c) In Trifolium the single strand remains undivided for
some time.

III. The Viceae type, in which there is a well-defined apical meri-
stem with a basal intercalary zone. Zoogleal infection threads
are very prominent. Two vascular strands have a separate
attachment to the root-stele.

IV. The Mimosoideae type, in which the nodules persist for more
than one year.

6. When the zooglea persists and envelops the nuclei, the latter
become vacuolate, then amoeboid, and later divide amitotically.

7. After the disappearance of the infection threads the bacteria assume
a variety of forms known as bacteroids.

8. The production of slime is connected with the amount of nitrogen
fixed, and is influenced by the medium in which the bacteria are living.

9. The nature of the cell-sap has a marked influence on the capabilities
of the bacteria.

10. The form of the nodule depends primarily on the nature of the
environment of the host, which influences the cell-sap and consequently
the behaviour of the bacteria after they have entered, and secondarily
on the anatomical peculiarities of the particular plant.

Bibliography.

BeijeRINCK, M. W. : Die Bakterien der Papilionaceenknollchen. Bot. Zeit, vol. xlvi, 1888.
Bottomley, W. B. : The Cross-inoculation of the Nodule-forming Bacteria from Leguminous and
Non-leguminous Plants. Report Brit. Assoc., 1907.

— : The Root-nodules o i My rica Gale. Ann. Bot., vol. xxvi, 1912.

Brunchorst, J. : Ueber die Knollchen an den Leguminosenwurzeln. Ber. d. Deutsch. Bot. Ges.,
vol. iii, 1885.

Buchanan, R. E. : The Gum produced by Bacillus radicicola. Centralbl. f. Bakt., Abt. ii,
Bd. xxii, 1909.

199

Root-nodules of the Leguminosae .

Dawson, M. : Nitragin and the Nodules of Leguminous Plants. Phil. Trans., B., vol. cxcii, 1900.

Frank, A. B. : Die Pilzsymbiose der Leguminosen. Landwirthschaft. Jahrb. xxi, Berlin, 1892.

Hellriegel, H., and Wilfarth, H. : Untersuchungen iiber die Stickstoffnahrung der Gramineen
und Leguminosen. Zeit. des Vereins fiir Riibenzucker-Industrie, 1888.

Maz£ : Les microbes des nodosites des Legumineuses. Ann. Inst. Pasteur, xii, 1898.

Mockeridge, F. A. : Some Effects of Organic Growth-promoting Substances (Auximones) on the
Soil Organisms concerned in the Nitrogen Cycle. Proc. Roy. Soc., B., vol. lxxxix, 1917.

Moore, G. F. : Bulletin 71 of Bureau of Plant Industry, Washington, Jan., 1905.

Nobbe and Hiltner : Ueber die Anpassungsfahigkeit der Knollchenbakterien ungleichen Ursprungs
an verschiedene Leguminosengattungen. Landwirtschaftliche Versuchsstationen, vol. xlvii,
1896.

Peirce, J. G. : The Root-tubercles of Bur Clover and of some other Leguminous Plants. Proc. of
the California Acad, of Sciences, 1902.

Prazmowski, A. : Die Wurzelknollchen der Erbse. Landw. Versuchsstationen, 1890 and 1891.

Solereder : Systematic Anatomy of Dicotyledons, 1908.

Spratt, E. R. : The Morphology of the Root-tubercles of Alnus and Elaeagnus and the Poly-
morphism of the Organism causing their Formation. Ann. Bot., vol. xxvi, 1912.

: The Formation and Physiological Significance of the Root-nodules in the Podo-

carpaceae. Ann. Bot., vol. xxvi, 1912.

: The Root-nodules of the Cycadaceae. Ann. Bot., vol. xxix, 1915.

Ward, H. M. : On the Tubercular Swellings on the Roots of Vida Faba. Phil. Trans. Roy. Soc.,
Lond., 1887, vol. clxxviii.

Willis : Flowering Plants and Ferns, 1908.

Winogradsky : Sur l’assimilation de l’azote gazeux de Tatmosphere par les microbes. Compt.
rendus, Paris, 1893.

DESCRIPTION OF PLATE XIII.

Illustrating Dr. Ethel R. Spratt’s paper on Root-nodules of the Leguminosae.

P. = root; v.s. = vascular strand; b.t. = bacteroidal tissue; i.t. — infection thread; m. = meristem ;
S.t. = root-stele; c. = outer protective layers; n. == nucleus; 0. = nucleolus; N. = nodule.

Fig. 1. Roots of Lupinus with nodules. Nat. size.

Fig. 2. Roots of Phaseolus with nodules. Nat. size.

Fig. 3. Roots of Lotus corniculatus with nodules. Nat. size.

Fig. 4. Roots of Acacia with nodules. Nat. size.

Fig. 5. Roots of Vicia Faba with nodules. Nat. size.

Fig. 6. Part of longitudinal section of a root of Vicia Faba , showing the cortical cells (c.cl),
some of which, i.c., have become infected with Bacillus radicicola. x 325.

Fig. 7. Longitudinal section of nodule of Vicia Faba . x 325.

Fig. 8. Transverse section of nodule of Lupinus, showing three zones of bacteroidal tissue.
p. = phellogen ; s. = thick-walled cells, x 70.

Fig. 9. Transverse section of nodule of Phaseolus. p. = phellogen ; y. = styloids. x 70.

Fig. 10. Bacteroidal cells of Lathy rus odoratus, showing nuclear changes, v. = vacuole, x 325.

Q

E.R.SPRATT— LEGUMINOUS

ROOT- NODULES.

Voi. xxxw,pi,xm.

Huth,Litlif L on don.

Jlmujls oP Butujiy,

VoL. XXXIII PI xm

leguminous root-

nod u l e s

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mrry%

Induced Changes in Reserve Materials in Evergreen
Herbaceous Leaves.

BY

GWYNETHE M. TUTTLE, M.Sc.,

Botanical Department, University of Alberta.

With seven Figures in the Text.

EVERGREEN trees are generally divided into two classes: (a) ‘starch *
trees, whose reserve food is stored in the form of starch, and (b) ‘ fat ’
trees, in which the starch is converted into oil during the autumn. According
to Warming (1), the presence of oils and fats in the latter may enable the
plant to withstand lower temperatures, ‘ in that fatty oil in the form of an
emulsion prevents the sub-cooling of the plant tissue and increases the
power of resistance to frost ’. Hence we find this class of trees largely
distributed throughout the colder regions, while the ‘starch’ trees are found
in localities of higher winter temperature.

Much attention has been given to this phenomenon in trees, but no infor-
mation is available in connexion with herbaceous plants. Since many
evergreen herbaceous plants grow in the shade of the ‘ fat ’ trees subjected
to the same extremes of cold, it would seem possible that they should
exhibit similar features. It was with a view to ascertaining a few facts in
this connexion that the present work was undertaken. My attention was
called to the need for investigation in this direction by Dr. F. J. Lewis, to
whom I am greatly indebted for helpful criticism and suggestions given
throughout the progress of the work.

The only recent investigation bearing on this subject is that of Kiichi
Miyake (2) at Tokyo. He confined his attention solely to the calculation
of the winter starch content of a number of trees and herbaceous plants
from different parts of Japan. The conclusion is reached that the starch
content of trees in winter is very small compared with that during the
summer, but that the content varied with trees of different species and also
with the region from which the material came — that from Northern Japan,

[Annals of Botany, Vol. XXXIII. No. CXXX. April, 1919.]

Q %

202 Tuttle. — Induced Changes in Reserve

where lower winter temperatures occurred, showed less starch than that
from the southern districts. Kiichi Miyake simply recorded the starch
content as he found it. He did not try to account for its variation. It
would have been interesting to know whether part of this decrease in
starch was due to the formation of fats and oils at the beginning of winter,
but no mention is made of investigation in this direction.

The present investigation was undertaken, therefore, not so much with
a view to ascertaining the food reserve in a large number of plants as that
of a single one, Linnaea borealis , L. var. Americana , Forbes, and to investigate
the changes which these reserves undergo when subjected to different
temperature conditions. *

In view of the fact that temperature is vitally connected with the
problem, a brief statement may be given of the meteorological conditions
of the district. Early frosts are characteristic of Western Canada, occurring
usually from the 6th to the ioth of September — frequently followed by
warmer periods. The precipitation during September and October is usually
high, but varies considerably with the different years. The winter seasons
are quite variable, but the extreme temperatures remain the same from year
to year, ranging from about — 40° F. ( — 40° C.) to an occasional 50° F. ( 1 o° C.).
The humidity of the air is moderately low and high winds are rare. The
depth of snow averages from one to two feet on the level.

The winter 1916-17, however, has been unusual. Cold periods of five
to ten days in which the thermometer ranged from o° F. (— 170 C.) to
— 40° F. ( — 40° C.) have alternated quite regularly with slightly longer
periods of rising temperature, reaching on one occasion 47°F. (8° C.). As
will be mentioned later, these fluctuations have been useful during the
progress of the investigation, especially in connexion with reconversion.

I. Preliminary Tests of Reserves.

The work was commenced late in October, just about the time of leaf-
fail of deciduous trees. A number of leaves were examined then for their
starch and oil content. A solution of iodine and another of chloral hydrate
and iodine were used in the tests for starch, the former in the preliminary
tests and the latter in the material during conversion, as the chloral hydrate
swelled the starch grains and also decolorized the sections, thus making
the reaction much clearer. For fats and oils, sections of the material were
tested with a 1 per cent, solution of osmic acid and also with neutral red
solution, both tests yielding similar results.

Table I shows the starch and oil content of the majority of local plants
which still retained their leaves.

Materials in Evergreen Herbaceous Leaves .

203

Table I.

Fall Starch and Oil Content of Leaves.

Date.

Material.

Starch.

Oils and Fats.

Oct. 23

Picea canadensis , Mill (B. S. P.)

Very little

Large amount

„ 23

Pyrola rotundifolia , L.

None

>> >»

„ 23

Linnaea borealis , L. var. Americana
(Forbes), Redner

Very little

3 3 33

„ 24

Cornus canadensis , L.

None

33 3?

„ 26

Hypnum (sp.)

Good reaction

None

„ 26

Marchantia (sp.)

Very little

Large amount

„ 26

Mitella nuda, L.

None

33 33

„ 28

Pinus Banksiana (Lamb)

Very little

3 3 33

It will be seen from the table that all the evergreens were practically
destarchified, and on the other hand they contained a large amount of oil.

II. Conversion of Oils and Fats to Starch.

A series of experiments was then started to induce the formation of
starch in the destarched plants. The following plants were brought indoors
and subjected to higher temperatures : Linnaea , Pyrola , and Pice a. The
first two plants were potted, but in the case of Pice a shoots were kept in
water. The experiments were kept in a dark room at a temperature of
68° F. (20° C.), and in each case a control was placed outside in the dark at
the lower temperature.

The material of Linnaea showed starch appearing as early as the
second day, while Pyrola and Picea showed no increase, although allowed to
remain at the higher temperature for five weeks. This points to the fact
that different species vary in their response to the change in temperature.

As Linnaea responded most readily to experiment, the following
observations were all made from that plant. They are based on material
collected and potted at intervals of five or six days during November and
December, 1916, and January, 1917. In each case the result was based on
a test from six to twelve leaves.

Table II.

Starch in Material exposed to Higher Temperature.

Condition

Dale.

when

isl day.

2nd day.

jrd day.

4th day.

1 week.

potted.

Nov.

8 1

experiment

No starch

No test

No test

No test

No test

Good reaction

control

>>

>>

33

33

No starch

m j

1 experiment

}>

n

>>

Good reaction

33

Strong reaction

>»

[ control

n

No starch

33

No starch

.6 j

1 experiment

t>

5>

No test

Good reaction

Strong reaction

| control

if

n

>5

33

No starch

No starch

23 j

1 experiment

}>

»

V

33

Good reaction

Strong reaction

»

| control

>>

5>

Slight reaction

33

No starch

No starch

Dec.

( experiment

}}

No starch

33

Good reaction

Strong reaction

4 ,

( control

>>

No reaction

33

No starch

No starch

18 !

1 experiment

>5

>>

Slight reaction

33

Good reaction

Strong reaction

»

j control

>>

y>

No reaction

33

No starch

No starch

3° ;

1 experiment

No test

Slight reaction

33

Good reaction

Strong reaction

V

j control

>>

>»

No reaction

33

No reaction

No reaction

204

Tuttle . — Induced Changes in Reserve

Material which has been inside for two days shows a starch reaction in
all parts of the leaf. At the end of four days the cells are quite crowded
with starch, but the amount increases until the seventh or eighth day (Fig. i),
after which time the starch content seems to remain constant.

The starch in all cells is present in a very finely divided state and the
individual grains exhibit Brownian movement to a marked degree.

* IG. I. Cross-section of Linnaea leaf, showing starch in material exposed to higher temperature
for one week. Section treated with chloral hydrate and iodine.

Fig. 2. Horizontal section of Linnaea leaf, showing starch in epidermal cells. The material
had been exposed to higher temperature for one week. Section treated with chloral hydrate and
iodine.

It is interesting to note the large amount of starch present in the
epidermal cells of material undergoing conversion (Fig. 2), as none is found
there during the summer when the starch is being formed as a product of
photosynthesis — this apparently suggesting that the starch has arisen by
conversion of oils and fats which are abundant in the epidermis during the

Materials in Evergreen Herbaceous Leaves . 205

winter (Fig. 3). It has been observed that the starch grains are grouped as
though each group had arisen from a single oil globule.

No regular variation in the conversion has been determined. Entire
plants have been tested, and it has been shown that they do not possess 6 fat *
leaves and ‘ starch 1 leaves — all leaves tend to form starch when exposed to
higher temperature. Fig. 4 shows the test of three plants from material
which had been exposed to higher temperature for four days.

In this test, plants I and III gave a strong reaction in all of the
leaves, but very little reaction was obtained in any leaves from plant II.

Fig. 3. Horizontal section of Linnaea leaf, showing oils and fats in epidermal cells. Material fresh
from outside before exposure to higher temperature. Section treated with i per cent, osmic acid.

Fig. 4. Linnaea material exposed to higher temperature for four days, sections of which were
treated with chloral hydrate and iodine.

Strong starch reaction in sections from ax-ar-bx-b2-c2 , gx -g-2-hx-h2-ix-i2.

Slight starch reaction in sections from ex-fT
No „ ,, „ ,, ,, e2-dx-d2.

This may be due to the fact that its leaves were not so vigorous as those . of
plants 1 and in. Hence any variation seems to be due to some plants being
more vigorous than others, and also to the age of the leaves, as it has been
observed that younger leaves carry on the conversion much more rapidly
than do the older ones.

20 6

Tuttle . — Induced Changes in Reserve

The increase in the starch content of these leaves is much more evident
than the decrease in the oils and fats which one would suppose must be
taking place, as that seems the only source from which the starch can be
derived, for the factor of photosynthesis has been eliminated by placing the
material in darkness. All the leaves showing a large amount of starch
gave a strong reaction with the test for oils and fats. In horizontal sections
passing through the epidermis there seems to be quite as much oil as starch
present. The palisade tissue shows no appreciable decrease. It is only in the
cells of the mesophyll that an actual difference has been recognized. Here
the decrease is quite evident, as will be seen by comparing Figs. 5 and 6.

Fig. 5 . Cross-section of Linnaea leaf, showing Fig. 6. Cross-section of Linnaea leaf, show-
fats and oils before exposure to higher temperature. ing decreased fat and oil content. Material ex-
Section treated with i per cent, osmic acid. posed to higher temperature for one week. Sec-

tion treated with i per cent, osmic acid.

III. Reconversion of Starch into Fats and Oils.

Having shown that starch appears in those leaves subjected to a higher
temperature, it was then attempted to cause a reconversion of the starch to
oils and fats by lowering the temperature. Material of Linnaea which had
been kept at 68° F. (20° C.) for a week, and which showed as a result a high
starch content, was placed outside in darkness on two different dates —
November 25 and December 13. As will be seen from Tables III and IV,
the temperature conditions were very different during the two experiments.

Table III.

Material containing Starch exposed to moderately low Temperature .

Date .

Av.

Temperature.

Experiment.

Control.

Nov. 25

25° F. (— 30 C.)

Strong starch reaction

Strong starch reaction

„ 30

36 F. (20 C.)

Decreased starch content, four

00 07

leaves out of six destarchified

Dec. 4

28° F. (- 2°C.)

All material destarchified

09 01

Materials in Evergreen Herbaceous Leaves. 207

Table IV.

Material containing Starch exposed to extremely low Temperature.

Dale • Temperature. Experiment. Control.

Dec. 13 4°F. (— i5°C.') Strong starch reaction Strong starch reaction

,, 20 — i6°F. (— 26° C/) No decrease in starch, cells ,, ,,

strongly

„ 23 - I9°F. (- 28cC.)

From Tables III and IV it is
amount of starch undergoes re-
conversion, in which the starch
is changed back into oils and fats
if subjected to moderately low
temperature. If, however, the
material, full of starch and hence
in a summer condition, is subjected
to extremely low temperatures no
reconversion takes place and the
material is killed. The strong
plasmolysis of the cell contents
exhibited in this material is shown
in Fig. 7.

plasmolysed

?> >> >>

seen that material containing a large

Fig. 7. Cross-section of Linnaea leaf. Material
outside for reconversion during extremely low tem-
perature. Section treated with iodine solution.
Starch grains visible in epidermic cells. Owing to
the high starch content, the plasmolysed cell con-
tents were stained deep blue.

IV. Cause of Conversion.

The conversion of fats to starch is quite impossible as an unaided
chemical change, and hence the action of an enzyme is suggested. Tests
were made for the presence of an enzyme both in material fresh from out-
side and in that which had been exposed to higher temperature for some time.

The test in this case was an alcoholic solution of guaiacum resin, which,
with the addition of hydrogen peroxide, gives a blue reaction in the pre-
sence of any enzyme. In enzyme tests made December 7 and 18 in fresh
material no reaction was obtained. Material, however, which had been
exposed to higher temperature for several days gave a strong reaction when
tested.

About a month later (Jan. 11-id) material in the same condition was
tested which yielded rather different results. In the interval, however, the
weather had moderated and some very high temperatures had been recorded.
All Linnaea leaves, both from outside and inside, then responded very
strongly to the enzyme test. There was an inclination at first to doubt the
test, but when leaves of Begonia and Geranium from a greenhouse gave
negative results it was concluded that the change in temperature must have
affected the outside material. Still the change had not been great enough to

2o8 Tuttle . — Induced Changes in Reserve

cause the formation of starch, for the outside material gave no reaction to
the iodine test. The effect of changing temperature was watched, and it
was found that the enzyme response diminished after a fortnight of lower
temperature, although at that time a slight reaction was given despite the
fact that the material was gathered when the temperature was lower than
o° F. (— 1 70 C.).

The important point, however, was that the material undergoing con-
version gave a strong enzyme reaction. The next step was to determine
whether or not this was due to the fat-splitting enzyme lipase. The test
applied was that used by G. J. Fowler (3) and Reynolds Green (4) in work
with germinating Ricinus seeds. Here the solution which is to be tested
for the presence of the enzyme is allowed to act on an oil emulsion caus-
ing (if lipase be present) the hydrolysis of the oil and the formation of a
fatty acid.

An extract of the leaves was made by grinding them in a mortar with
a solution containing 5 per cent, sodium chloride and 0-2 per cent, thymol
as an antiseptic. This was allowed to stand for twenty-four hours and then
filtered. The filtrate was treated as follows : an emulsion of olive oil with
a little gum arabic was made, and to this was added a small amount of the
extract, phenolphthalein being used as an indicator. As the leaf extract and
oil emulsion were both slightly acid, they were carefully neutralized with
a few drops of very dilute caustic potash. From two to five experiment
tubes were made up in this manner. A control was made up in a similar
manner, except that the extract was boiled for two or three minutes before
it was added to the emulsion. Both experiments and control were placed
in an oven at 950 F. (350 C.). Table V gives the results of several tests for
lipase in extracts from material of different conditions. The test made on
January 9 shows that fresh material from outside without exposure to
higher temperature does not respond to the test for lipase.

Table V.

Date .
Dec. 4

„* §
Jan. 2

>> 9

L 16

Feb. 8

A ction of L ipase .

Exposure to Higher
Temperature .

4 days

4 »

2 „

None (material tested
when brought in)

2 days

2

11

Experiment.

Acid reaction after
4 hours

Acid reaction after
4 hours

Acid reaction after
2 hours
No reaction

Acid reaction after
2 hours

Acid reaction after
4 hours

Boiled

Control.

No reaction

Slightly acid 1
No reaction

Indicator.

Litmus

Phenolphthalein

1 Due to insufficient boiling.

Materials in Evergreen Herbaceous Leaves . 209

It has been recorded earlier in the paper that material fresh from out-
side responded to the general enzyme test. Experiment of January 9 in
Table V shows that the enzyme in fresh material is not lipase — hence the
presence of another enzyme is suggested. Owing to the browning of the
leaf extract on standing, oxidases were suggested.

It was determined (3) that guaiacum resin without the hydrogen peroxide
was a test for oxidase alone, and so the material was subjected to this test.
Sections of the leaves, both fresh and converting, gave only slight reactions
with the guiacum resin, but the extract gave a good response. This is due
to the fact that, on standing, a substance is formed in the extract which
increases the oxidation (5).

In the tests for lipase given above it will be noticed that phenolphthalein
was used as an indicator instead of the litmus solution used by Reynolds
Green in his experiments with extract from endosperms of Ricinus. Litmus
was used in the early experiments in this work, but it was found that the
plant extract decolorized the litmus directly it was added. This fact was
a further proof of the presence of oxidases, as they cause an immediate
decolorization of litmus solution. Hence litmus was of no use as an
indicator in the presence of oxidases, and so phenolphthalein was substituted,
with whose action they do not seem to interfere.

The results of this investigation may be briefly summarized as follows :

1. Most evergreen plants are destarch ified in NVV. Canada as early as
October, and then contain a large amount of oil.

2. Exposure to higher temperature in the case of Linnaea induces the
formation of starch in darkness.

3. Starch is present in the material after two days and increases in
amount until about the eighth day.

4. The starch is in a very finely divided state and the individual grains
exhibit Brownian movement.

5. All healthy leaves are capable of carrying on conversion. The plant
does not possess ‘ starch 1 leaves and ‘ fat ’ leaves.

6. The starch disappears when again exposed to moderately low
temperature for about eight days, but the leaves are killed if exposed to
extremely low temperatures when filled with starch.

7. A decrease in the oil content is evident in leaves which have formed
starch by conversion.

8. Enzymes are present in material undergoing conversion.

9. Lipase has been demonstrated in material undergoing conversion.

10. Oxidases are present in the leaf of Linnaea even at quite low
temperature.

210 Tuttle . — Induced Changes in Evergreen Herbaceous Leaves.

Bibliography.

1. Warming, Eug. : Ecology of Plants. 1909.

2. Kuchi Miyake : On the Starch of Evergreen Leaves and its Relation to Photosynthesis during

the Winter. Bot. Gaz., xxxiii.

S. Fowler, G. J. : Bacteriological and Enzyme Chemistry. 1911.

4. Reynolds Green, J. : Fermentation. 1901.

5. Wheldale, Muriel : Direct Guaiacum Reaction given by Plant Extracts. Proc. Royal Society,

Series B, 84.

On the Law of Age and Area, in Relation to the
Extinction of Species.

BY

AGNES ARBER.

DR. J. C. WILLIS, in the well-known series of papers in this and other
journals in which he has elaborated his theory of ‘ Age and Area
has brought forward evidence for its validity which appears to me to be
completely convincing. I am, however, unable to accept one subsidiary
hypothesis, which Dr. Willis seems to regard as an integral factor in his
scheme — the idea that, at least in the case of the Angiosperms, no extinc-
tion of species is now proceeding. This opinion he has repeatedly expressed.
He wrote, for instance, in 1916 1 that ‘There is no evidence whatever that
any of the angiospermous species of the Ceylon flora are dying out, and
from analogy we may imagine this to be generally true ’. He does indeed
qualify this in 1918 2 as far as to admit that ‘ there is a certain amount of
geological evidence of former greater spread ’, but he seems to regard this
as an exception of no real importance. Berry,3 on palaeobotanical
grounds, and also Sinnott 4 and Ridley,5 for more general reasons, have
controverted Willis’s view that no extinction is taking place among the
Flowering Plants, and have expressed the opinion that certain members of
this group are dying out at the present day.

When we look at the matter broadly, and consider living things as
a whole, it becomes abundantly clear that extinction both of plant and
animal species has occurred on a vast scale in the course of bygone
geological epochs. I fancy that those palaeontologists who have paid the
closest attention to these questions would be the least likely to accept
Willis’s contention that extinction in the past has been due almost entirely to
catastrophes of some kind, or to great climatic changes.6 Even if we follow
Willis in narrowing the issue down to Angiosperms, we must admit that
there is no apparent reason for supposing them privileged to escape the
universal fate. It might possibly be maintained that at the present day
the Angiosperms are a dominant group entirely on the up-grade, in which
extinction has not yet begun. But this position is refuted by certain

1 Willis, J. C. (1916). 2 Willis, J. C. (1918). 2 Berry, E> w> (1917

4 Sinnott, E. W. (1917). 5 Ridley, H. N. (1916). « Willis, J. C. (1918).

[Annals of Botany, Vol. XXXIII. No. CXXX. April, 1919.]

2 l 2

Agnes A r her. — On the Lctiv of Age and A rea, in

palaeobotanical evidence which can scarcely be gainsaid. For the sake of
brevity I will cite one instance only. Professor Berry,1 by bringing together
the evidence of Cretaceous and Tertiary fossils, has established that the
genus Nelumbo, which is now represented by two species only, occurring
respectively in Asia and America, had formerly a cosmopolitan range,
including Greenland, Europe, and Africa. A number of the species which
have been identified in the fossil state are now wholly extinct. A map
showing the present and past distribution, which is included in Professor
Berry’s paper, brings vividly home to the reader the losses which this genus
has suffered.

Having become convinced that Willis’s position, in regard to the extinc-
tion of Angiospermic plants, was untenable, I sought to discover whether
the validity of the Law of Age and Area must, in reality, stand or fall with
the question of the dying out of species ; the conclusion I have reached is
that Willis’s deductions regarding extinction depend upon a false assumption,
and that they may be discarded without in any way affecting the truth of
the law.

It will be remembered that Willis bases his hypothesis in the first
instance upon a consideration of the degree of rarity of the various species
constituting the flora of Ceylon.2 Following Trimen, he classifies the plants
into a series of classes grading from ‘ Very Common ’ to ‘ Very Rare ’, and
he uses the ingenious idea of awarding to each species ‘ marks ’ for rarity on
a numerical scale. He writes, regarding the statistics based upon these
classes, ‘ In what way the figures we have given are to be reconciled with
any theory of the dying out of species I fail to understand ’.3 When we
scrutinize Willis’s degrees- of rarity more closely, we see that he uses the
words ‘ common ’ and ‘ rare ’ in a slightly peculiar,4 5 though legitimate, .sense,
which he is careful expressly to define ; he lays special stress on the fact
that ‘ my figures . . . refer to area occupied, not to commonness on the
ground ’.6 This being the case, it seems to me quite impossible to draw any
conclusions for or against extinction from the figures in question ; the whole
matter hinges upon a confusion of thought between ‘ common ’ in the sense of
widespread, and i common ’ in the sense of numerically abundant. Willis
apparently expects that those who differ from him on the question of
extinction ought to be able to ‘ define a size of area above which species are
to be regarded as growing, or below which as dying out’.6 But what Tight
have we to assume that the mechanism of extinction of a species is simply

1 Berry, E. W. (1917 2). 2 Willis, J. C. (1915). 8 Willis, J. C. (1916).

4 The contention that Willis uses the word ‘ common ’ in a sense unusual among naturalists, is

supported by the fact that Darwin (Origin of Species, 6th ed., 1894, p. 40) defines the most common

species as those that ‘ abound most in individuals ’, and also draws a distinction between ‘ wide
range ’ and ‘ commonness

5 Willis, J. C. (1917) (the italics are mine).

Willis, J. C. (1918).

213

Relation to the Extinction of Species.

the converse of its mechanism of development, and hence consists in
a progressive reduction of the area occupied ? If we follow this assumption
to its logical conclusion, we must suppose that each species in dying out
steadily reduces its area, until it finally expires at its birthplace ! This
seems to be a fallacy comparable with the prevalent idea that structural
degeneration is c an actual retracing of steps until the point of departure is
reached \1 There are, it is true, certain instances in which the area occupied
by a dying species shrinks from the margin inwards ; the Oxlip in East
Anglia is an example,2 but such cases are probably wholly exceptional.
This plant [Primula elafior , Jacq.) occupies a restricted region and is
surrounded on all sides by Primroses ( Primula vulgaris , Huds.), which do not
penetrate into its area. Year by year the Oxlip and Primrose hybridize on
the margin of the Oxlip’s demesne ; it seems that the Oxlip will ultimately
be hybridized out of existence, and its place taken by the Primrose, which
is present in such hordes that the loss which it suffers by hybridization is
negligible. It appears to me, however, that, apart from such rare cases as
this, the tangible evidence of the dying out of a species would more pro-
bably be a progressive decrease in ‘ commonness on the ground while the
total area over which the species spreads might remain unchanged almost to
the last. This gradual decrease in abundance would be a subtle matter to
gauge and to define, but it ought to come within the scope of ecological
observations, when the progress of that branch of Botany has enabled
connected records to be kept over a long series of years. Willis’s methods,
on the other hand — valuable as they are for their own purpose — are not
adapted for giving any indication of the progress of extinction, if it takes
place in such a way that the total area from which the species is known
remains unaltered.

For the reasons which I have attempted to outline, I consider that —
although Willis’s. statistics undoubtedly substantiate the truth of his main
hypothesis regarding Age and Area— they have no necessary bearing upon
the question of the extinction of species.

Balfour Laboratory,

Cambridge.

1 There is a useful discussion of this and related questions in Demoor, J., Massart, J7, and
Vandervelde, E. (1899).

2 Christy, M. (1897).

214

Agnes Arber . — On the Law of Age and Area .

Literature cited.

Berry, E. W. (1917 *) : A Note on the ‘ Age and Area’ Hypothesis. Science, vol. xlvi, 1917,
pp. 539-40.

■ (1917 2) : Geologic History indicated by the Fossiliferous Deposits of the Wilcox

Group (Eocene) at Meridian, Mississippi. U.S. Geol. Surv., Prof. Paper 108 E, Shorter
Contributions to General Geology, 1917, pp. 61-72, 3 pis., 1 text-fig., 1 map.

Christy, M. (1897) : Primula elatior in Britain : Its Distribution, Peculiarities, Hybrids, and
Allies. Journ. Linn. Soc. Bot., vol. xxxiii, 1897-8, pp. 172-201, 1 map.

Demoor, J., Massart, J., and Vandervelde, E. (1899) : Evolution by Atrophy. Trans, by
Mrs. Chalmers Mitchell. Intern. Sci. Ser., vol. lxxxvii, 1899.

Ridley, H. N. (1916) : On Endemism and the Mutation Theory. Ann. Bot., vol. xxx, 1916,
PP- 551-74-

Sinnott, E. W. (1917) : The ‘ Age and Area ’ Hypothesis and the Problem of Endemism. Ann.
Bot., vol. xxxi, 1917, pp. 209-16.

Willis, J. C. (1915) : The Endemic Flora of Ceylon, with Reference to Geographical Distribution
and Evolution in General. Phil. Trans. Roy. Soc., Lond., Ser. B, vol. ccvi, 191 5, pp. 307-42,
4 text-figs.

(1916) : The Evolution of Species in Ceylon, with reference to the Dying Out of

Species. Ann. Bot., vol. xxx, 1916, pp. 1-23, 2 text-figs.

(1917) : The Relative Age of Endemic Species and other Controversial Points. Ibid.,

vol. xxxi, 1917, pp. 189-208.

(1918) : The Sources and Distribution of the New Zealand Flora, with a Reply to

Criticism. Ibid., vol. xxxii, 1918, pp. 339-67.

Studies on the Chloroplasts of Desmids. I.

BY

NELLIE CARTER, M.Sc.

With Plates XIV-XVIII.

Contents.

PAGE

I. Introduction . . . .215

II. General Characters of the

Chloroplasts . . . .219

III. The Chloroplasts of Netrium . 227

IV. The Chloroplasts of Closterium . 228

I. Introduction.

Historical.

THE first figures of Desmids which give one any clear idea of the nature
of the cell-contents were those of Ralfs (1848). Although Ralfs did
not attempt to indicate the form of the chloroplast in the larger species of
Euastrum and Cosmarium, yet from his figures of such genera as Desmidium,
Closterium , and Staurastrum, a fairly good idea of the structure of the
chloroplasts in these forms can be obtained.

Nageli (1849) also figured typical chloroplasts of the genera Pleurotae-
nium, Closterium , Netrium, Staurastrum, and Cosmarium.

De Bary (1858) described in general the chloroplasts of the group, and
made a statement to the effect that all Desmids, with the exception of species
of Pleurotaenium and Spirotaenia, have axile chloroplasts. This is by no
means true, however, since parietal chloroplasts are known to occur in many
other genera besides these two. De Bary also described in more detail
some of the simplest types of chloroplast found in each genus, and gave an
account of the behaviour of the chloroplasts in a few genera during cell-
division.

Lundell (1877) attempted to subdivide the genera Cosmarium and
Staurastrum according to the disposition of the chloroplasts, and instituted

[Annals of Botany, Vol. XXXIII. No. CXXX. April, 1919.]

R

PAGE

V. The Chloroplasts of Tetmemorus 236

VI. The Chloroplasts of Euastrum 237
VII. The Chloroplasts of Xanthi-

dium ...... 245

VIII. Summary ..... 248

216 Carter. — Studies on the Chloroplasts of Desmids. I.

two new sub-genera, Pleurotaeniopsis and Pleurenterium , to include those
species of Cosmarium and Staurastrum respectively which have parietal
chloroplasts. Cosmarium and Staurastrum , in the restricted sense of
Lundell, contained only those species with axile clPoroplasts.

The figures given by Delponte (1873) for such genera as Desmidium
and other filamentous Desmids give one quite a good idea of the structure
of the chloroplasts, whilst in many species of Closterium , Penium , Netrium ,
Staurastrum , and several species of Cosmarium , the form of the chloroplast
is also indicated.

Klebs (1879) illustrated the ridged nature of the chloroplasts and the
position of the pyrenoids in many species of Clostermm and Penium , and
also gave a figure of Cosmarium de Baryi , Arch., which is quite comparable
with that given some years later by Liitkemuller (1893).

Schmitz (1882), in his work Die Chromatophoren der Algeria only
just mentions Desmids as having chloroplasts of very diverse forms, which
usually consist of a central axile portion provided with radiating plates of
various kinds.

Gay (1884) figured the chloroplasts in a few species of Closterium ,
Penium , and Micrasterias , and also in species of several other genera.

An attempt to subdivide the genus Xanthidium , similar to that of
Lundell (1871) in connexion with Cosmarium and Staurastrum , was made
by Boldt (1888), who included in a new sub-genus ,Euxanthidium, all species
of the genus having parietal chloroplasts, and in Centrenterium all species in
which the chloroplasts are axile. Boldt described a new species of Xanthi-
dium, X. groenlandicum, Boldt, which he placed in the sub-genus Centren-
terium, evidently believing it to have axile chloroplasts. The same species
has been figured again by Larsen (1907), and although these figures are not
particularly good for the chloroplasts, they do indicate, together with his
description, that the chromatophores in this species are really very similar
to those of other species of the genus which have parietal chloroplasts.

Lagerheim (1888) raised the sub-genera Pleurotaeniopsis and Pleuren-
terium of Lundell to the rank of genera.

Liitkemuller, who did some careful work on Desmids, published in
1893 a detailed account of the chloroplasts in certain species of Cosmarium ,
and also in a few other species formerly placed in Lagerheim’s genus
Pleurotaeniopsis . This was followed in 1895 and 1903 by a complete review
of the genus Spirotaenia, and in this work the obscure structure of the
chloroplast in those species belonging to the Polytaeniae was for the first
time elucidated, and it was definitely shown that in these species of Spiro-
taenia the chloroplasts are really axile, in spite of the fact that the genus
was originally supposed to be characterized by the fact that its chloroplasts
are in the form of spirally twisted parietal bands.

These investigations of Dr. Liitkemuller may be regarded as the only

Carter . — Studies on the Chlorop lasts of Desmids. /. 217

thorough work that has ever been done on the chloroplasts of Desmids,
with the single exception of the more recent work of Lutman (1910, 1911) on
Closterium. Liitkemuller was one of the few investigators who attempted
to discover the real nature of the more complicated chloroplasts of the
group. He worked for a considerable time on Desmids, and made many
excellent preparations of the chloroplasts, but his untimely death in 1912
prevented this work from being published.

In their Monograph of the British Desmidiaceae, W. and G. S. West
(1904-11) indicated the nature of the chloroplasts and the position of the
pyrenoids in many members of the order, as far as this could be ascertained
by superficial observation, noting in particular the variability of the chloro-
plast in Cosmarium Subcucumis , Schmidle, and other species. The same
authors (1896, 1897, 1902, 1903, 1907) and G. S. West (1914) have figured
the chloroplasts in Roy a, W. and G. S. West, and also in some new species
of Cylindrocystis , C. Americana^ W. and G. S. West,1 C. ohesa, W. and G. S.
West, and C. pyramidata , W. and G. S. West,1 besides indicating the nature
of the chloroplasts in several other species.

Seeing that there is no exact information concerning the nature of the
chromatophores in the great majority of Desmids, it was suggested by
Professor G. S. West that the investigation of the chloroplasts of this group
would be a useful and interesting study.

Methods.

With most Desmids, careful staining is essential for the investigation of
the chloroplasts ; only in a very few species of Staurastrum , Cosmarium ,
and Closterium can the nature of the cell-contents be successfully determined
in the living condition, and even in these staining is desirable in order to
ascertain the number and position of the pyrenoids. In all others the con-
tents are uniformly green in the living condition, or merely show a few
darker bands, their real nature being quite obscure. With some of the
thicker species, even in stained specimens it is quite impossible to make out
with any certainty the structure of the chloroplasts, because of the extremely
dense nature of the cell-contents, and sections are essential, as for example
in the larger species of EiLastrum and Cosmarium . In the investigation of
the chloroplasts of the large species of Euastrum particularly, sections
revealed the most unexpected structure, and it is quite probable that their
complicated construction would never have been understood by mere super-
ficial observation. The same is most certainly true in the case of many
other large Desmids, and with these also sectioning is the only means of
obtaining accurate information.

In the case of Cosmarium hire turn , Brdb., the cell- wall appeared to
have a peculiar affinity for the stain used, iron-haematoxylin staining quite

1 It is most probable that these two species really belong to the genus Cosmarium.

218 Carter, — Studies on the Chloroplasts of Desmids. /.

black, and entirely obscuring the cell-contents in whole mounts. Naturally
it was quite impossible to get any idea of the structure of the chloroplast
from such preparations, and consequently it was absolutely necessary to cut
sections. The same phenomenon has been noticed, though not to the same
extent, in a few other species of Cosmarium , and also in certain species of
Closterium and Peniurn. On the whole, however, it is quite unusual for the
cell-wall to absorb the stain in this way.

In the case of those species of Closterium and Penium whose cell-walls
seem to have such a marked affinity for haematoxylin, this is probably to be
attributed to the presence of iron salts in the composition of the wall,
which help to fix the stain. The same explanation, however, is not true in
the case of Cosmarium biretum , since a test for iron in its cell-wall gave
only negative results. In the latter species it is possibly the presence of
considerable quantities of some other mineral salt, probably lime, which
accounts for the deeply staining properties of the cell-wall.

When the cell-wall in Closterium becomes very old and brown, the
power of attracting the haematoxylin seems to be lost, and the cell-wall
scarcely stains at all. This is possibly due to the fact that the iron probably
becomes united with a large organic radical, in which complex form it is
incapable of acting as a mordant.

A large part of the work was done from fresh material collected chiefly
in Sutton Park, Warwickshire, and in Devonshire, but a considerable
number of species were investigated from material furnished by Professor
G. S. West, which had been preserved for some time in formalin or potassium
copper acetate. After well washing such material in water, the structure of
the chloroplast was usually quite clear on staining.

The investigation of a few species was carried out from some prepara-
tions made by Dr. Liitkemuller, and very kindly lent by Professor G. S.
West. The specimens had been stained in Delafield’s haematoxylin and
were mounted in Venetian turpentine.

The living material was always fixed as soon as possible after the
collections had been made, because most species do not live long when
removed from their natural habitat. The most satisfactory fixing reagent
was found to be a hot solution of corrosive sublimate. Bouin’s picric-
formol-acetic fixing solution always produces considerable shrinkage of the
cell-contents, even when very much diluted, and with Flemming’s weaker
solution the staining is rarely so satisfactory. The solution used consisted
of corrosive sublimate, 3 grm. ; glacial acetic acid, 3 c.c. ; 50 per cent,
alcohol, 1 00 c.c.

The hot sublimate was removed from the material as soon as possible
and replaced by clean 50 per cent, alcohol. After washing in several
changes of alcohol the remaining sublimate was removed by the addition of
a dilute alcoholic solution of iodine. The material was then taken either

Carter. — Studies on the Chlor op lasts of Desmids . /. 219

down into water for staining, or up through absolute alcohol and xylol, and
finally into paraffin for sectioning, the transference to the various liquids
being made as gradual as possible. A centrifuge was always used for
facilitating the removal of solutions, and thus it was possible to transfer the
material without loss, and in a comparatively short time, through the
numerous different strengths of solutions which were absolutely necessary in
order to prevent the shrinkage of the cell-contents. In transferring from
water to absolute alcohol and xylol, the material could be taken without
shrinkage through solutions of strengths increasing successively by 10 per
cent., being kept about 10 minutes in each one. It would have been quite
impossible to get through so much material if it had been necessary to wait
for the Desmids to settle by gravity each time the solution was changed.

The most satisfactory stain was found to be Heidenhain’s iron-haema-
toxylin. This always gives a perfect differentiation of the chloroplasts, the
general cytoplasm staining very faintly or not at all. Material was trans-
ferred from water to a 2J per cent, solution of iron alum, and allowed to
remain in this for 10 to 20 minutes. After rinsing in water it was stained
for about 40 minutes in per cent, aqueous solution of haematoxylin. The
proper differentiation of the cell- contents was obtained by washing out part
of the stain in diluted mordant, the operation being controlled by watching
a drop of the material under the microscope. After well washing in water
the material was transferred gradually to absolute alcohol and xylol, and
finally placed in very dilute Canada balsam, which was allowed to concen-
trate slowly until it was of a consistency suitable for mounting.

Venetian turpentine was also used instead of Canada balsam with
equally good results. The material was transferred from 95 per cent,
alcohol to the diluted turpentine, and allowed to concentrate in an atmo-
sphere kept dry by means of fused calcium chloride.

II. General Characters of the Chloroplasts.

In the lower group of the Desmidiaceae the form of the chloroplasts is
usually very much simpler than in the Placodermae, the only genera in
which very complicated structure occurs being Netrium and Spirotaenia .
Consequently the chloroplasts of these rather more primitive Desmids are
very much better known. Thus the simple axile chloroplasts of Gonato-
zygon and Mesotaenium , and the spirally-twisted bands of Genicular ia^ were
figured by such early investigators as Nageli (1849) and de Bary (1858).
The chloroplasts in two species of Spirotaenia were figured by Ralfs (1848),
and the whole genus has since been thoroughly investigated by Liitkemuller
(1895), whilst in the case of Roya the chloroplast has been figured by
W. and G. S. West (1896). In all these genera the chloroplasts usually
stretch from end to end of the cell, and the nucleus often occupies in con-

220 Carter . — Studies on the Chlor op lasts of Desmids. I.

sequence a more or less lateral position, but in some individuals the
chloroplast may be interrupted in this region, so that two chloroplasts are
present instead of one. In the spirally twisted bands of Genicidaria and
the parietal chloroplasts of some species of Spirotaenia the pyrenoids are
scattered in the chloroplast near the cell-wall, but in all others they lie in
a single row in the middle of the cell, and in Mesoiaenium there may be
only one pyrenoid in the central position.

Cylindrocystis and Netrium differ from all the other Saccodermae in
the somewhat complicated form of their chloroplasts (Figs. 13-19). In both
genera there are invariably two chloroplasts in each cell, each one consisting
of a central axile mass containing typically one pyrenoid and a number of
strands or plates which radiate towards the periphery. The chloroplasts of
these two genera have been figured by de Bary (1858) and West (1902;
1904-11, vol. i). Netrium interruptum , (Breb.) Liitkem., is unique
amongst the Saccodermae in the possession of four axile chloroplasts in
each cell, one above the other in a longitudinal series.

Amongst the Placodermae there is much greater variety in the form
of the chloroplasts, and, with the exception of some filamentous species,
most of them have hitherto never been figured. There is almost invariably
in the higher Desmids at least one chloroplast in each semi-cell, although in
a few very small species, e.g. Cosmarium subtile p (West) Liitkem., C. tinc-
tump Ralfs, C. subtilissimu m ,1 2 3 4 5 G. S. West, Cosmocladium constrictump
Arch., and Staurastrum inconspicuump Nordst., there is only one simple
chloroplast in each cell, typically with a single pyrenoid in the central
position. In the larger species of the group the chloroplasts may be axile
or parietal. When axile there may be either one chloroplast in the centre
of each semi-cell, or else two placed side by side. In Closterium Libellida ,
Focke, var. interruptump W. and G. S. West, there are two axile chloroplasts
in each half-cell, one on top of the other, just as in Netrium interruptum .
When parietal there may be four or more chloroplasts in each semi-cell, and
here there is far more variation in the actual number of chloroplasts present
than is the case with axile ones. In species which normally have two axile
chloroplasts in each semi-cell, more or less than two are rarely observed, and
although in the case of species normally having one axile chloroplast in
each semi-cell one sometimes encounters individuals which have two, this is
quite unusual. In the case of parietal chloroplasts, however, the number of
plates or bands present may vary from two to eight or even more.

1 Vide W. and G. S. West (1904-11, vol. i). This species was figured under the name of
Penhim subtile .

2 Vide Liitkemiiller (1902), p. 356.

3 Vide G. S. West (1914).

4 Vide G. S. West (1904).

5 Vide W. and G. S. West (1904-11, vol. i). This species was figured under the name of
Penium Libellulai var. interruptum .

Carter . — Studies on the Chloroplasts of Desmids . /. 221

The most striking thing about the chloroplasts of the higher members
of the Desmidiaceae is their complexity of form. It is very rarely that one
finds straight outlines, or simple ridges ; on the other hand, the chloroplasts
are usually most complicated structures, the margins of the plates of which
they are composed being divided and subdivided, and the ridges often
branched repeatedly; cf. Figs. 65 and 77.

In many species which have greater or smaller parietal expanses of
chloroplast, the main body of the chloroplast is often removed a short
distance away from the cell-wall, and numerous short outgrowths of chloro-
plast extend from it towards the periphery. Such outgrowths were first
noticed by Lutkemuller (1903), being described by him for Cosmarium
tessellatum } C. turgidum , and C. de Baryi. It is most probable, however,
that the phenomenon is not confined to these species, but is quite general,
occurring in most genera where parietal or partly parietal chloroplasts are
to be found. It has been observed during the present investigation in other
species of Cosmarium , in various species of Euastrum and Xanthidium (see
Figs. 62, 72, 89, 100, and 113), and also in Pleurotaenium elephantinum , Cohn.

On the other hand, these projections do not seem to be an absolutely
constant feature of any species in which they may be observed, but probably
depend to a considerable extent on the condition of the cell. They are often
very conspicuous in individuals with massive chromatophores, being in such
cases both numerous and of large size. In cells with feebly developed
chloroplasts they are often altogether absent, and the parietal part of the
chloroplast closely envelops the cell-walk In general it is in cells with
much available chlorophyll-bearing material that the most elaborate chloro-
plasts are to be found, not only with regard to these projections from the
external surface of the parietal parts, but also in the branching of the ridges
and the elegance of the lobing and toothing of the edges of the various
plates. But even in specimens with well-developed chloroplasts, the delicate
form of the chromatophore may be secondarily interfered with by the
presence of large quantities of starch, as will be explained later.

Usually in cells with feebly developed choroplasts the same general
structure can be recognized as in the better developed specimen of the
same species, except that all superfluous ornamentation is wanting. Some-
times, however, a considerable difference in appearance may be presented
by two specimens of the same species, one with well-developed chloroplasts,
the other with very little photosynthetic material. This is very marked
in Cosmarium Brebissonii , Menegh., where some individuals have such
large chloroplasts that these penetrate every part of the cell, which is almost
full of pyrenoids and chloroplasts, whilst other specimens contain so little
chlorophyll-bearing material that the chloroplasts form merely a thin layer
lining the cell-wall, the interior of the cell being quite free from them.

1 Liitkemiiller described these three species under the generic name of Pleurotaeniopsis.

222 Carter . — Studies on the Chloroplasts of Desmids . /.

Thus it is possible for considerable variation to occur in the form of the
chloroplast within the limits of a single species, according to the relative
amount of chlorophyll-bearing material present.

The general appearance of the chloroplast seems to be also greatly
influenced by the amount of starch contained in it as free stroma-starch
apart from that occurring in immediate connexion with the pyrenoids.
This difference can sometimes be distinguished in the living condition, but
it is much more evident after staining.

Some individuals stain much more deeply than others, whilst at the
same time the form of their chloroplasts is much more definite, the various
plates of which they are composed being very distinct and sharply defined,
their pyrenoids are conspicuous as dark globules with very definite starch-
sheaths, and on examining the more minute structure of the chloroplast its
protoplasmic reticulum is seen to be very fine and close in texture, its whole
substance appearing homogeneous, except for the pyrenoids.

On the other hand, certain individuals present a very different appear-
ance. Their chloroplasts do not stain nearly so deeply and are much more
bulky, not having the fine definition of the first type, whilst the distinction
between chromatophores and general cytoplasm is not nearly so marked as
before. Although there is a paler region round each deeply staining
pyrenoid, a really definite starch-sheath cannot be distinguished, since there
is a gradual transition to the general substance of the chromatophore, which,
when closely examined, is seen to have a very granular appearance, instead
of being practically homogeneous as before.

On testing with iodine it is found that the first type of individual con-
tains practically no starch except that which forms the starch-sheaths of its
pyrenoids, whilst in the second type the chloroplasts are absolutely packed
throughout with starch, and it is the presence of innumerable starch-grains
which causes the granular appearance of the chromatophore described
above. It seems that under certain conditions starch-grains are thrown off
from the pyrenoids in large numbers, and spread into every part of the
chromatophore, stretching apart the meshes of its fine protoplasmic reticulum
and causing the chloroplast to swell to three or four times its former bulk.
During the process of becoming swollen with stroma-starch the chloroplast
often naturally loses its delicate form and becomes a comparatively shape-
less mass. As a direct result of this, the more delicate parts of its structure,
e.g. the numerous finger-like projections sometimes found on the external
surface of many parietal chloroplasts, may be partly or entirely obliterated.
The distending of the chloroplast begins in the region of the pyrenoids and
gradually extends to the more remote parts. This phenomenon sometimes
causes remarkable variations in the form of the chloroplast, -particularly in
certain species of Closterium , in which the relative size of the central axis
and radiating ridges is largely dependent on the amount of starch present.

Carter . — Studies on the Chloroplasts of Desmids. /. 223

In some species the form of the chloroplast varies very little amongst
individuals, and a typical form can be described which is true in all
essentials for practically all specimens, the only differences being minor
ones, such as those due to external conditions, as mentioned above. This
is the case with many species of Staurastrum and Cosmarimn . In other
species there is a marked tendency to vary, and a considerable proportion
of individuals do not conform to the type. This is very noticeable in the
larger species o iEuastrum, where, although the typical form of the chloroplast
is axile, all stages to the parietal condition are to be found ; cf. Figs. 72-5
and 100-5. Liitkemuller (1893) noticed the existence of such variations
in Cosmarium docidioides 1 and Xanthidium Brebissonii ,1 2 and possibly it
also occurs in other species. The chloroplasts of the thicker-celled species
of Micrasterias are also variable, but in quite a different way.

The very intimate connexion between the nucleus and chloroplasts was
noticed in many species. This is seen best where there are two axile
chloroplasts in each semi-cell, as in certain species of Cosmarium. In such
cases the basal part of each chloroplast is drawn out into a string-like
portion, which is apparently attached directly to a corner of the nucleus, this
being usually more or less rectangular in shape. Very often as a result of
the frequent use of the centrifuge in the preparation of the material, the
nucleus becomes displaced from its normal position in the isthmus, and is to
be seen a little distance away in one of the semi-cells, dragging behind it the
chloroplasts by means of their string-like attachments, the connexion
between them still unbroken. Thus there must be a very vital connexion
between the nucleus and chloroplasts, either directly or through the medium
of the layers of protoplasm which surround them. In any case it must be
very strong to withstand the treatment described above.

Sometimes similar thread-like attachments are noticed between the
edges of the chloroplast plates and the layers of cytoplasm lining the cell-
wall. This seems to be very common with chloroplasts which are not
sufficiently massive to extend right up to the cell-wall at all points, espe-
cially in the case of young semi-cells.

The number and position of the pyrenoids vary considerably amongst
different individuals of the group, depending to a great extent on the shape
of the chloroplast, their number being also bound up with the general
condition of the cell. In most species which have large parietal chloroplasts
the pyrenoids are indefinite and are scattered indiscriminately (Figs. 102
and 129). Some species, e.g. small species of Xanthidium , have smaller
parietal plates, each of which has typically one pyrenoid (Figs. 106, 109,
113, and 1 15).

1 Liitkemuller described the chloroplasts of this Desmid under the name of Docidium baculum .

2 That Liitkemuller also noticed the variation of the chloroplasts in this species is indicated in
some of his unpublished drawings.

224 Carter . — Studies on the Chloroplasts of Desmids. /.

In the case of species having axile chloroplasts, the pyrenoids are
usually found in those parts of the cell where the chloroplast is most
massive. This is frequently the axis of the chloroplast itself, but in some
cases, e.g. the larger species of Euastrum , the actual axis of the chloro-
plast is very slender, and the pyrenoids are practically confined to the
more massive peripheral parts of the chloroplast (Fig. 73). The number of
pyrenoids embedded in the axis of axile chloroplasts depends on its size.
Thus where there is a long narrow axis, e.g. Closterium , the pyrenoids
occur in a line, and may be quite numerous (Figs. 6, 10, 23, 35, 38, and 47).
Where the axis is larger and broader, e.g. some species of Micrasterias ,
the number of pyrenoids present may be more than 100, and they are
scattered throughout. In many species where the axis is much more
limited in its extent, there is typically only one pyrenoid in the axis of each
chloroplast.

The general condition of the cell, however, probably greatly influences
the amount of food-reserves stored in the form of pyrenoids, and at any
time two or more pyrenoids may occur in such positions wfiere only one
would have been expected. This is true both in the case of axile and
parietal chloroplasts, which were formerly supposed to have only one
pyrenoid.

When division of a pyrenoid occurs, usually by budding, or the gradual
constriction of one to form two, the newly formed pyrenoids separate from
each other almost immediately, where this is possible, e.g. the extensive
chloroplast-plates of Xanthidium armatum , (Breb.) Rabenh. (Figs. 129 and
130), or Micrasterias denticidata , Breb. Where the space is more limited,
however, the migration of the pyrenoids is impossible. For example, some
species of Cosmarium have two axile chloroplasts in each semi-cell, each
chloroplast containing originally a single pyrenoid. If either of these
pyrenoids divides, the products of its division could not possibly separate,
because the chloroplast only forms a minute film round it, and the two
pyrenoids remain in the position of the original one. Further division may
result in the formation of a group of three or even more pyrenoids in the
axis of one or more of the chloroplasts in some individuals. In the living
condition such a group of pyrenoids would be apparent simply as one
refractive mass, and it would be almost impossible to distinguish it from
a single pyrenoid. This is probably why the number of pyrenoids has
been thought to be definite in so many Desmids. The examination of
stained material, however, has shown that this is not so, although the
relative position of the pyrenoid groups is really quite constant in such
cases.

Lutkemuller (1893) noted such variations in the number of pyrenoids
in several species of Cosmarium , and also in species of Arthr ode smus,
Staurastrum , and Euastrum , whilst W. and G. S. West (1898) have also

Carter. —Studies on the Chlor op lasts of Desmids. /. 225

reported unusually large numbers of pyrenoids in Hyalotheca neglecta ,
Racib., and Cosmarium sphagnicola , W. and G. S. West.

The observations of these investigators are supported byDucellier (1917),
who noted some irregularities in the number of the pyrenoids in various
species of the genus Cosmarium, and gave some evidence that the number
of pyrenoids in this genus is not always one or two, as was formerly
stated. The present investigation also supports this, not only with regard to
the genus Cosmarium , but also to species of other genera which have
chloroplasts containing typically one pyrenoid. The single pyrenoid may,
under favourable conditions, give rise to a group of two or more pyrenoids,
and so long as the group of pyrenoids occupies the same relative position as
the original one, the specimen can be regarded as being quite ordinary ;
cf. Fig. 59. Of course one occasionally meets with individuals which have
an abnormal number of pyrenoids in unusual positions. Thus specimens of
Euastrum pectinalum , Breb., Eu. bidentatum , Nag., Cosmarium subtumidum,
Nordst., &c., have been encountered having two chloroplasts in each semi-
cell, each containing one pyrenoid, whereas normally there should be only
one chloroplast, containing one pyrenoid ; cf. Figs. 51 and 54, 66 and 70.
If the two pyrenoids had simply occupied the same position as if there had
been only one, the specimens would have been regarded as normal, but
since each pyrenoid was contained in a distinct and separate chloroplast,
they were regarded as being unusual — and were omitted as such. Different
anomalies were met with in other species.

Ducellier also raises the question whether the number of pyrenoids
contained in any cell belonging to the genus Cosmarium is not dependent
to some extent on the size of the individual. This does not seem to be the
case, either in Cosmarium or in any other genus of Desmids. Ducellier
does not show the chloroplast in any of his figures, and it would appear
that this is a factor which he has entirely neglected. The actual mass of
chlorophyll-bearing material contained in the cell undoubtedly does have
a direct effect on the amount of food-reserves stored as pyrenoids, but the
amount of chloroplast present in individuals of one species varies consider-
ably, irrespective of their size. Thus in some large cells the chloroplast
may be particularly scanty, whilst in smaller individuals of the same species
it may be quite massive ; in such cases the large cell probably contains less
reserve food than the smaller one. Again, the conditions which control the
division of the pyrenoid are very obscure, and cannot be determined. For
in the same collection one individual may contain a few large pyrenoids,
whilst another of the same species may contain many smaller ones.
Furthermore, the conditions governing pyrenoid division may vary in
different parts of the same semi-cell. For example, in one specimen of
Xanthidium Brebissonii containing two axile chloroplasts in a semi-cell,
one chloroplast was provided with a single extremely large pyrenoid, whilst

2 2 6 Carter. — Studies on the Chtor op lasts of Desmids . /.

the other had a group of small ones (see Fig. i ii). In view of these facts
it seems very unlikely that there is any definite relation between the number
of pyrenoids contained in a cell and its size.

The method of division observed in the pyrenoids was nearly always
by constriction or pulling apart of one individual to form two. More rarely
the pyrenoids divide by a clean cut into two parts, or the pyreno-crystal
fragments to form many. In many cases when actively dividing the pyreno-
crystal was observed in the process of budding off two or more new
pyrenoids at the same time (Figs. 59, 60, and 80).

Whilst examining the chloroplasts of Cosmarium ochthodes , Nordst.,
numerous darkly staining globules were noticed, sometimes in the peripheral
parts of the radiating plates, but more often in the reticulated films of
chloroplast stretching from these over the interior of the cell-wall. In
stained preparations they have the general appearance of small naked
pyrenoids, staining in exactly the same way as the pyreno-crystal of the
larger pyrenoids of the cell. They do not appear to have a definite starch-
sheath, but are always surrounded by a lighter space. In sections stained
with iodine the globules become distinctly brown, and when tested with
other reagents they always give the same reaction as the pyreno-crystals of
the ordinary pyrenoids. They stain brilliantly with acid fuchsin and are
undoubtedly of a proteid nature.

Similar globules have been observed in several other species of Cos-
marium and Closterimn (Fig. 44), in one species of Cylindrocystis , and they
have also been found scattered amongst the larger pyrenoids in the chloro-
plasts of Micrasterias denticidcita and Xanthidinm armatum . When tested
in several of these other species they were found to behave in exactly the
same way as before.

Their position in those parts of the chloroplast nearest the cell-wall is
a constant feature, and is very marked in every case in which they were
observed with the exception of Micrasterias denticidata , in which species
this distinction is scarcely possible. They vary considerably in number and
are not found in every individual of such species in which they have been
observed.

They seem to have no relations with the ordinary large pyrenoids of
the cell, and are probably not derived from them in any way, being most
likely formed de novo when the conditions in the cell are favourable for
the storage of large quantities of reserve food. In all the species of
Cosmarium in which these small globules were observed, the points at which
the ordinary pyrenoids occur are definite and fixed, usually in the interior
of the cell, and even if these do divide the products of their division remain
in the position of the original ones, whilst these small globules are only to
be found near the cell-wall. Thus the possibility of their origin from the
division of the ordinary large pyrenoids can be neglected.

Carter. — Studies on the Chloroplasts of Desmids. /. 227

The only record of similar pyrenoids occurring in the Chlorophyceae is
provided by Schmitz1 (1882), who reports that in some of the thicker-celled
species of Zygnema , very small pyrenoids are sometimes apparent in the
peripheral ends of the rays of the star-shaped chloroplasts. Schmitz does
not definitely say that these pyrenoids were destitute of starch, but their
position near the cell-wall and their supposed origin de novo is very
suggestive of the small proteid granules observed in certain Desmids.

It is proposed to give, as far as is possible from the limited number of
species examined, a comparative account of the chloroplasts found in each
genus, excluding those genera in which the form of these bodies is already
well known, and in this part of the work the genera dealt with will be
Netrium, Closterinm , Tetmemorus , Eucistrmn , and Xanthidium.

III. The Chloroplasts of the Genus Netrium.

This genus belongs to the Saccodermae, and the species examined were
N. Digitus , (Ehrenb.) Itzigs. and Rothe, N. oblongum , (de Bary) Liitkem.,
N. oblongum , var. cylindricum , West and G. S. West, and N. interruptum ,
(Breb.) Liitkem. The chloroplasts of these species are generally well known,
and consist of a central axis from which a number of plates are given off.
In N. Digitus these are nearly always eight in number (Fig. 15), in
N. oblongum there are eight or nine, in N. oblongum , var. cylindriaim , about
seven (Fig. 18), and in N. interruptum about eleven or twelve (Fig. 19), but
except in the case of N. Digitus the counting of the plates had to be
done from whole specimens, and so these numbers may not be exact.

The peripheral edges of the plates in N . Digitus are more or less deeply
cut into teeth which project alternately on either side of the plate towards
the cell-wall (Figs. 13 and 15). The actual size and shape of the projec-
tions vary considerably; in some cases they consist of long fine strands
which stretch in various directions towards the cell-wall, whilst in other
individuals they are quite fiat and angular.

In N. oblongum the plates are similarly notched but are not quite so
complicated (Figs. 16 and 17), and in N. interruptum the edges of the
plates are entire (Fig. 19). .The latter species also differs from the others in
having two chloroplasts in each half-cell.

The pyrenoids found in these species of the genus are peculiar in several
ways. They occur only in the central axis of the chloroplast and are
usually of extraordinary length, there being as a rule one pyrenoid only in
each chloroplast, which is apparent as a conspicuous darkly staining rod in
the middle of each half-cell (Fig. 14). The amount of starch round each
pyrenoid naturally varies very much according to the condition of the cell,
but the starch grains are always very small in comparison with the size of

p. 74.

1

228 Carter . — Studies on the Chloroplasts of Desmids. I.

the pyreno-crystal, and it is only very rarely that there is only one layer of
starch grains round each pyrenoid. In most cases the starch layer is of
some thickness, and consists of very numerous starch grains closely packed
together, either in a compact even layer or projecting irregularly in all
directions into the reticulum of the chromatophore (Figs. 14, 16, 17, 18,
and 19).

In some cases the pyreno-crystal is observed to fragment, forming
several shorter, or very many small spherical or irregularly shaped globules
in a longitudinal series embedded in the central cylinder of starch-grains
(Fig. 17). The size of the small pieces of pyreno-crystal varies very much ;
they are often very irregular in shape and are not necessarily arranged in
a single series in the middle of the chloroplast, two or more often occurring
side by side.

Such complex pyrenoids have only been observed, outside the genus
Netrium , in the chloroplasts of Ciosteriam Libellula, Focke, Penium spiro-
striolatum , Barker (Fig. 20), P. polymorphum , Perty, P. mar gar i taceum ,
(Ehrenb.) Breb., and Cylindrocystis Brebissonii , Menegh.

In Netrium interruptum one specimen was observed to have only one
chloroplast in each half-cell, with a single pyrenoid stretching throughout
its whole length (Fig. 19). There were, however, signs of the constriction
of the chloroplast about half-way between the nucleus and the apex of the
cell. This suggests that for a time after cell-division each individual has
only one chloroplast with one pyrenoid, and that the division of this to
produce the two usually present does not occur until some time afterwards.

IV. The Chloroplasts of the Genus Closterium.

In 1910 Lutman published a paper describing the chloroplasts of
CL Ehrenbergii and Cl. moniliferum , figuring transverse sections of both
species, and pointing out how the structure of the chloroplast in the genus
Closterium , as he found it in these two species, differs from that figured by
Nageli (1849) for Cl. parvidum and CL moniliferum . According to Lutman,
the chloroplast of Closterium in transverse section is like a coarsely cogged
wheel, whereas according to Nageli’s figures it is like a hub with radiating
spokes. Lutman asserted that Nageli’s optical sections give quite an
erroneous conception of the true state of affairs, the chloroplast in Closterium
consisting of a curved cone-shaped structure with relatively low ridges on
its surface, and not of a series of radiating plates arranged round a slender
central core.

With the object of ascertaining whether the examination of other
species of Closterium would support Lutman’s statement, the chloroplasts
of the following species have been investigated, both by means of whole
mounts and of sections: — Cl. Lunula, (Mull.) Nitzsch., Cl. lanceolatum , Kiitz.,

Carter . — Shi dies on the Chloroplasts of Desmids. /. 229

CL Siliqua , West and G. S. West, CL costatum , Corda, CL striolatum ,
Ehrenb., CL regulare , Br^b., CL angustatum , Kutz., Cl. attenuation ,
Ehrenb., Cl. Libellula , Focke, Cl. Dianae , Ehrenb., Cl. rostratum, Ehrenb.,
and Cl. juncidum , Ralfs. This has led to the conclusion that the broad
axis figured by Lutman for CL Ehrenbergii and CL moniliferum is not
common to all species of the genus, and furthermore that even within the
limits of a single species the relative size of the axis and ridges cannot be
considered as a fixed character, but is, on the other hand, liable to consider-
able individual variation, according to the condition of the cell, this being,
however, more pronounced in certain species than in others.

In a few of the species examined, e.g. Cl. Lunula , Cl. lanceolatum , and
Cl. Siliqua , the structure of the chloroplast as seen in transverse section is
often quite similar to that figured by Lutman, but even here the axis is
sometimes much more slender in proportion than his figures show it (Figs.
2-5). Cl. attenuation and CL Libellula seem almost invariably to have
chloroplasts, which in transverse section are rather more like Nageli’s
figures than those of Lutman, in having fairly large radiating plates and
a comparatively slender axis (Figs. 9 and 12).

In Cl. costation , Cl. striolatum , and Cl. regulare , however, the most
conspicuous variations in the size of the central axis occur, transverse
sections of some individuals of these species being quite similar to those
figured by Lutman (Figs. 30 and 34), whilst sections of other specimens
may present the most unexpected appearance (Figs. 26-9 and 40-2).
The axis in these peculiar chloroplasts may quite lose its definite shape as
a more or less cone-shaped structure, the whole chloroplast in transverse
section being irregularly branched, so that the axis appears merely as
a strand of tissue connecting up the irregularly arranged ridges (Fig. 41).
This strand of material, which constitutes the axis, may be very much
swollen at intervals for the accommodation of the pyrenoids, but it is usually
very drawn out in between.

In all the species examined, with the exception of CL Lunula
(Figs. 1-5), the pyrenoids occur in a single row in the middle of the central
axis, but when photosynthesis has been going on very rapidly, and the
pyrenoids have become very numerous, they occasionally spread in certain
places towards the periphery ; cf. Fig. 34. In Cl. Lunula the relative
position of the pyrenoids depends on the size of the axis of the chloroplast.
They are usually embedded in the peripheral parts of the axis ; thus in
cells having a broad axis and low ridges they are quite near the cell-wall, and
in such cases are never found very far in the interior of the cell (Figs. 1 and
2), whilst in other individuals having a very slender axis and large ridges,
the pyrenoids are crowded together in the comparatively small axis of the
chloroplast, which in such cases may be an almost solid mass of pyrenoids
and starch (Figs. 3 and 4). This variation in the size of the axis and the

230 Carter.— -Studies on the Chloroplasts of Desmids. I.

relative position of the pyrenoids has also been noticed in Cl. Elirenbergii ,
although it is not mentioned by Lutman (1910).

The number of ridges arranged round the central axis is fairly constant
for each species, Cl. striolatum having twelve or thirteen, Cl. angustahim
nine or ten, and so on.

The edges of the ridges are only ornamented to any great extent in
Cl. Lunula. In this species they are hollowed out at intervals, or regularly
lobed throughout their whole length, and these lobes or projections stretch
out towards the cell-wall (Figs. 1 and 3). The edges of the ridges in
Cl. Libelhda are usually conspicuously sharp and straight.

The size of the ridges, as has already been stated, is a very variable
character, and in certain species this variability may greatly influence the
external appearance of the individual. In many cases the ridges when
examined from the exterior are apparent as nearly parallel dark lines
stretching from the region of the nucleus to the apices of the cell. This is
usually the case in Cl. Libelhda (Fig. 8). In certain individuals, however,
particularly of the species CL costatum , Cl. striolatum , Cl. regtdare , and
Cl. angustatum , the ridges seem to travel in tortuous paths from end to end
of the cell, and sometimes appear to lose their individuality by apparently
fusing for a short distance one with another (Figs. 31 and 38). Although
this is a very common occurrence in all the four above-mentioned species, it
is by no means a constant feature of any one of them, individuals having
ordinary straight ridges being also sometimes met with. Thus in some
individuals of these species the ridges may appear to undulate very gently,
and in extreme cases each individual ridge may bend alternately to the
left and to the right in such a way as to produce a reticulation something
like adioneycomb, or more irregular anastomosis against the interior of the
cell-wall.

This irregular arrangement of the ridges has been figured by Delponte
(1873) in CL didymotocum } and also in two other species described by him
as CL hirndo 2 and Cl. crassnm .3 In the case of the first species at any rate
he described the chloroplast as consisting of tortuous strings and tubules
immersed in the protoplasm, and seemed very uncertain about the existence
in this species of a chloroplast consisting of lamellae radiating from the
centre to the periphery. Although Cl. didymotocum was not examined
during this investigation, there seems to be no doubt that the appearance
figured by Delponte was due to the same anastomosing of the ridges as has
been observed in CL costatum , &c., in which species it has been definitely
proved that the superficial tortuous ribbons such as were described by him
for Cl. didymotocum are really joined up to the axis of the chloroplast in the
interior of the cell, and are not merely isolated strings, as he seemed to think.

1 Delp , 1.6., Tav. XVII, Figs. 32-4. 2 Delp., l.c., Tav. XVIII, Fig. 7.

3 Delp., l.c., Tav. XVIII, Fig. 23.

Carter . — Studies on the Chlor op lasts of Desmids . I. 231

In the case of specimens having nearly parallel or very slightly undu-
lating ridges, these are seen in transverse section radiating from the central
axis at practically equal distances from each other all the way round, and as
a rule the ridges in such cases are very small in comparison with the size of
the axis (Figs. 30 and 34). But where the undulation of the ridges becomes
very pronounced, and their paths are very tortuous, transverse sections
reveal a remarkable difference of structure. The axis here is usually very
slender, and the ridges, instead of originating quite independently of each
other from the axis, as in cases where they are nearly parallel, are seen in
transverse section to show a certain amount of branching. Thus in the
case of an individual of CL costatum , which would have had fourteen ridges
visible from the exterior, a transverse section showed that the central axis
gives off five ridges only, and that the fourteen ridges lying against the cell-
wall are the ultimate products of the branching of these original five
(Fig. 3a). Another specimen of the same species had thirteen ridges
resulting from the subdivision of four primary ridges, and so on, the
arrangement of the ridges round the axis varying with individuals.

Again, the combination of the ridges at various points in the same cell
differs continually, as the examination of consecutive sections shows. Thus
Figs. 41-3 represent consecutive sections of a specimen of CL striolatum
having thirteen ridges, and from a comparison of these the rapidly changing
position and arrangement of the individual ridges in a short length of the
cell is quite evident. The ridges, where they overlap the nucleus (Fig. 43),
are quite free and distinct from each other, whilst in the remaining two
sections the ridges are joined together in quite different combinations in
each case. Thus it is clear that any particular ridge partially fuses for
a greater or shorter distance with one or more neighbouring ridges, and, at
various points in the length of the cell, any individual ridge is united with
ever-varying groups of other ridges, being restricted of course to its own
immediate neighbours.

As seen in transverse section, however, the fusion of any two ridges
rarely extends all the distance from the central axis to the, periphery, the
ridges being quite free from each other as they lie against the cell-wall, but
fusing in various combinations in the interior of the cell (Figs. 29, 32, and 41 ).
Where, in the external view of an individual, two ridges come so close
together as apparently to fuse, a careful examination will usually show that
they are quite distinct from each other on the surface (Fig. 38), although
they are probably united just beneath, as seen in the tangential section,
Fig. 39. Sometimes, however, complete fusion of two ridges may occur
near the apex of an individual, or one ridge may end abruptly, so that
there may not be so many ridges round the axis near the apex of the cell
as lower down.

Thus, throughout the whole length of the cell the arrangement of the

s

232 Carter . — Studies on the Chloroplasts of Desmids. I.

ridges round the central axis in these complicated chloroplasts is continually
changing, the position of any particular ridge in relation to the other vary-
ing from time to time, and it is this which probably accounts for the
repeated bringing together and separation of neighbouring ridges which
causes the reticulate appearance seen in the external view.

In species like Cl. costatum , Cl. striolatum , Cl. regulare , and Cl.
angustatum , therefore, transverse sections of different individuals may
present striking differences of structure, according to the relative size of the
ridges and axis. If the ridges of the individual in the external view are
nearly parallel, then in section the axis will probably be very broad,
occupying most of the interior of the cell, whilst the ridges will be compara-
tively low, but quite distinct from each other. If, on the other hand, the
ridges are anastomosing to any great extent, in such cases the axis in
transverse section will be much smaller, the ridges will be more extensive
and also more or less branched, the chloroplast as a whole being much more
irregular in outline.

As regards the finer structure of the chloroplast, it was noticed that in
sections of Closteriinn showing branched ridges the protoplasmic network of
the chloroplast is much closer and more compact than that of sections
showing a broad axis and low ridges. This is particularly noticeable in
those species in which there is the possibility of very great variation in the
relative size of the axis and ridges, those specimens with large or branched
ridges showing an extremely fine reticulation of the chloroplast, and more-
over the ridges in such cases are usually very thin, but the protoplasmic
network of the whole chloroplast is very dense and very sharply defined
from the rest of the protoplast (Figs. 26-9, 32, and 41-2). In specimens of
these species which have low ridges and a very massive central axis, the
chloroplast is seen in transverse section to have a very coarsely reticulate
appearance, which on careful examination is found to be due to the presence
of numerous granules which do not take the stain (Figs. 30 and 34). Test-
ing with iodine shows that the chloroplast is full of tiny starch-grains
which are packed within the meshes of the reticulum of the chloroplast,
either in the axis only, or in the ridges as well.

If sections of individuals having branched ridges be stained with iodine,
it is seen that no starch is present, with the exception of that forming the
starch-sheaths of the pyrenoids. This tends to prove that in these species
the size of the axis depends largely on the condition of the cell. If little
starch is present, then the axis will probably be slender, but if photosyn-
thesis has been going on very rapidly, starch-grains begin to accumulate in
such large numbers that they stretch apart the meshes of the reticulum and
cause the axis to become very swollen. Later, the ridges also may be
similarly distended.

Apparently the presence of large quantities of starch in the low-ridged

Carter .■ — Studies on the Chloroplasts of Desmids. /. 233

type gives a certain amount of rigidity to the chromatophore, and when
the starch disappears the reticulum of the chloroplast collapses and the
ridges become thinner but more plate-like as the axis decreases in size. In
this condition they are unable to preserve their original straight paths from
end to end of the chloroplast, but from lack of internal support bend
irregularly all down the cell.

The distending of the chloroplast with starch-grains may occur in any
species of Closterium , or indeed in any other Desmid, and although, so far,
it has only been observed to influence the form of the chloroplast to any
great extent in Cl. costatmn , Cl. striolatum , Cl. regulare) and Cl. angustatum ,
it is quite probable that the examination of other species of the genus at
various seasons of the year will show that the phenomenon is quite general
with this type of chloroplast.

Slight undulation of the ridges is also sometimes observed in some of
the smaller species in which the ridges are scarcely large enough to allow of
real anastomosis. Thus in some individuals of Cl. Dianae and CL rostratum
the ridges undulate in this way, whilst in others they do not. Probably this
difference is also due to the same variation in the starch-content of the
chromatophore.

Although the variation in the size of the axis is usually to be correlated
with the amount of stroma-starch contained in it, yet in the two large
species Cl. Lunula and Cl. Ehrenbergii this is not so. For in these species
there is also great variation in the size of the axis of the chloroplast, the
protoplasmic network of the chloroplasts of individuals having broad
radiating plates and a comparatively slender axis being usually in the form
of a very fine, compact reticulum, but where the axis is much broader the
protoplasmic network is very coarse; cf. Figs. 2 and 4. In the latter case
the appearance is not due to the presence of stroma-starch, but simply to
the extreme vacuolation of the protoplasm.

In material containing a quantity of Cl. Ehre7ibergii and a little
CL moniliferum , which had been stained in the usual way, it was noticed
that practically every individual of the former species contained countless
numbers of small darkly staining granules, similar to those previously
observed in species of Cpsmarium. They are usually found in large
numbers in the narrow ridges of the chloroplast quite near the cell-wall
(Fig. 44), and never occur very far in the interior of the cell. In some
individuals they are not so numerous as in others, and possibly vary in
number and size according to the state of nutrition of the cell. In Cl.
moniliferum there are sometimes similar rather smaller globules in exactly
the same position in the peripheral region of the ridges. Occasionally
such darkly staining globules have been observed in CL Lunida , but they
were not so common in this species as in CL Ehrenbergii .

234 Carter. — Studies on the Chloroplasts of Desmids. I.

Cl. Lunula .

The ridges in this species are about fourteen to seventeen in number,
and the axis in transverse section is usually broad, but the relative size of
the axis and ridges is liable to considerable variation; cf. Figs. 1-4.
Sometimes the ridges are so low that they scarcely exist at all in the broader
part of the cell ; towards the apices they are always more evident (Figs. 1
and 3). When the axis is very broad the pyrenoids are scattered in a single
layer in its peripheral parts (Figs. 1 and 2). Other specimens may have
very distinct ridges, which in transverse section are seen to be quite thin
and plate-like, and consequently the axis in these cases is much more
slender than before, the pyrenoids being necessarily crowded together in the
more central region of the ceil (Figs. 3 and 4). This variation in structure
is quite evident even in the living condition. I11 certain individuals the
cell-contents are much more densely green than in others. Such specimens
have very distinct ridges, and the pyrenoids are crowded together in the
middle of the cell, forming a large refractive mass. Other specimens are
much paler in colour, and the cytoplasm is very coarsely reticulated, the
reticulation being sometimes visible even with the low power. Here the
pyrenoids are scattered in a more or less superficial layer, and the ridges are
very low and often scarcely perceptible. Both these types of structure and
various intermediate stages are to be found in a single collection. The dense
green colour of the first type is probably due to the much closer reticulation
of the protoplasmic foundation of the chloroplast.

In individuals having rather extensive plate-like ridges these may
undulate very strongly (Fig. 3). Sometimes undulation only occurs in the
apical end of the chloroplast when the ridges in the middle of the cell are
too low to allow of such undulation. In transverse section, however, no
branching of the ridges is to be observed, except occasionally in sections
taken from the apical end of the cell, which may show just a suggestion of
branching (Fig. 5). On the whole, however, the undulation in this case is
merely the result of the ridges travelling in slightly waving paths, and not
due to actual anastomosis, or fusion of the tissue of one ridge with that of
other ridges.

The degree to which the edges of the ridges are lobed naturally depends
to some extent qn the size of the ridges themselves. In cells having very
low ridges, the lobing of the edges may be practically absent except at the
apices of the cell, where the ridges are always larger (Fig. 1). In individuals
having more definite plate-like ridges the edges are usually distinctly lobed
throughout their whole length, though the depth to which they are hollowed
out varies (Fig. 3). Occasionally in specimens having a very slender axis
with crowded pyrenoids it may be said that ridges scarcely exist, since they
are represented merely by innumerable long finger-like outgrowths radiating

Carter . — Studies on the Chlor op lasts of Desmids . I. 235

from the axis to the cell-wall in rather obscure longitudinal rows. Very
often such a structure of the chloroplast is visible at the apices of the cell
only, whilst in the broader part the ridges are more obvious.

Cl. lanceolatum and Cl. Siliqua .

These two species also have chloroplasts, consisting of a rather broad
central axis, from the surface of which the ridges do not project very far
(Figs. 6-7 and 45-6). In the external view the ridges are seen to travel in
nearly parallel straight lines (Figs. 6 and 45), and although in Cl. lanceo-
latum they may undulate very slightly, they never anastomose. In the
latter species the ridges are about twelve in number, whilst in CL Siliqua
there are about ten or eleven. The pyrenoids lie in a single line in the
middle of the cell in both cases, and in Cl. lanceolatum they are often
provided with a very thick starch-sheath, so that when they occur in
a transverse section they occupy the whole of the broad axis (Fig. 7).

CL costatum , CL striolatum , Cl. regiriare , and Cl. angustaturn.

In these species there is great variation in the relative size of the axis
and ridges ; in the external view, anastomosis of the ridges is consequently
often seen (Figs. 31 and 38), whilst in other individuals they are nearly
parallel and straight. Similarly this variation in structure is also evident
when various transverse sections are examined, some sections showing
a structure similar to that figured by Lutman, whilst in others the ridges
may be very irregularly branched, according as they are straight or
anastomose respectively (Figs. 26—30, 32-4, and 40-3). In extreme
cases the axis may not have a definite rod- or cone-like form, but may
merely consist of an irregular strand very much distended at the points
where pyrenoids occur. Cl. costatum has usually thirteen or fourteen ridges,
CL striolatum about thirteen, Cl. regidare twelve, and Cl. angustaturn about
ten. The pyrenoids occur in a single row in the middle of the cell, occa-
sionally spreading when very numerous towards the periphery (Fig. 34).
In these species the difference in appearance of the .protoplasmic network
of the chloroplast, and the difference in the relative size of the axis and
ridges, according as much or little stroma-starch is present, is particularly
noticeable.

Cl. attenuatum .

In the case of CL attenuatum the ridges are about ten in number and
are seen in transverse section to be fairly large and plate-like (Figs. 11 and
1 2). They were never observed to anastomose, but it is quite possible that
in certain circumstances they would do so. The pyrenoids are in a single
line in the middle of the cell (Fig. 10).

236 Car ter .—Studies on the Chtoroplasts of Desmids. 1 \

CL Libellula.

This species always seems to have fairly large ridges, even when quite
a considerable amount of stroma-starch is present (Fig. 9). They are about
twelve in number, and are occasionally seen to anastomose, although being
as a rule quite straight (Fig. 8). The pyrenoids are in a single line in the
middle of the cell, and are peculiar in being usually of very great length,
a single pyrenoid sometimes stretching through more than half the entire
length of the chloroplast (Fig. 8). Consequently they are very few in
number, about two or three in each half-cell. Excepting that a single
pyrenoid rarely stretches through the whole length of the chloroplast, these
pyrenoids agree in every particular with those found in the genus Netrium
(Figs. 13-19), being provided with several layers of starch-grains. This is
the only species of Closterium in which such pyrenoids have been observed.

In the three smaller species, Cl. Dianae , Cl. rostratum, and Cl.jnncidum ,
the ridges seem to be fairly large considering the small size of the cell
(Figs. 21-5, 35-7, 47, and 48). Cl. Dianae and Cl. rostratum have about five
or six ridges which sometimes undulate gently (Fig. 21), whilst in the case
of Cl. juncidum they are about seven in number.

Note : — The chloroplasts of Pleurotaenimn Trabecida , (Ehrenb.) Nag.,
var. rectum , (Delp.) W. and G. S. West.

The chloroplasts in the genus Pleurotaenium are generally supposed to
be in the form of parietal bands, with numerous pyrenoids embedded in
them. In the case of PI. Trabecida, var. rectum , it was found, however, after
the examination of a large quantity of material, that the chloroplast is
invariably axile, with a single row of pyrenoids in the middle of the cell
(Fig. 49). A few low longitudinal ridges, which are sometimes twisted
slightly in a spiral round the axis, project from its surface. There was no
suggestion in any individual of the chloroplasts being even partly parietal.

V. The Chloroplasts of the Genus Tetmemorus.

It has long been known that the chloroplasts in Tetmemorus are axile,
with a central row of pyrenoids. This latter character was indicated in the
figures of Ralfs (1848) for the three largest species of the genus, whilst
de Bary (1858) also illustrated the ridged nature of the chloroplast in
T. Brebissonii , but since these early times no work has been done on
the chloroplasts of the genus.

Three species were examined during this investigation, T. Brebissonii ,
(Menegh.) Ralfs, T. granulatus, (Breb.) Ralfs, and T. laevis , (Kutz.) Ralfs.
All these species have axile chloroplasts, but whilst those of the two smaller
ones resemble each other, the chloroplast of T. Brebissonii is rather
different.

Carter . — Studies on the Chloroplasts of Desmids. I. 237

The latter species has a central axis occupying the centre of the
semi-cell, and from this about eight plates radiate towards the periphery.
As these approach the cell-wall, they begin to thicken rapidly, forking
slightly so as to embrace a larger proportion of the cell-wall (Fig. 81),
From the exterior the edges of these plates are seen as parietal bands
running longitudinally (Fig. 79). The edges of the parietal bands are often
quite straight, but they may sometimes be fringed with tiny projections or
else undulate gently.

The pyrenoids are confined to the central axis of the chloroplast, and
are very variable in size and number. Sometimes there are only two or
three long narrow pyrenoids occupying the whole length of a single chloro-
plast, but more often there are about four to nine smaller spherical
pyrenoids, either in a single median series, or when very numerous they
may occur crowded together, two or more side by side in the distended axis
of the chloroplasts ; cf. Fig. 80. The pyrenoids are often seen in an active
state of division, the pyreno-crystal budding in various directions and
being consequently very irregular in shape.

In T. granulatus and T. laevis the axile chloroplasts are also provided
with a central row of pyrenoids, which number about three to five in each
chloroplast of the larger species, and one or two in T. laevis. In both cases
the axis is provided with a number of radiating plates, but in neither species
is there any attempt at the formation of definite thick parietal strands as in
T. Brebissonii. T. granulatus has about eight to ten radiating plates, and
in T. laevis there are about eight, but, in the former species particularly,
these are often so complicated that it is scarcely possible to count them even
in sections ; cf. Fig. 77.

The edges of the plates are usually deeply cut, forming long attenuated
outgrowths which stretch towards the periphery, some projecting on one
side of the ridge, some on the other, and when this happens the individual
identity of each ridge becomes very obscure (Fig. 76). In other specimens
the toothing of the edges is not so deep, and the plates are much more dis-
tinct (Fig. 78). The extent to which the ridges are toothed greatly influences
the appearance of the individual. Where definite plates occur these are
sometimes seen in the front view of the specimen to undulate in a manner
similar to that occurring in certain species of Closterium , adjacent ridges
alternately touching and becoming distant.

VI. The Chloroplasts of the Genus Euastrum.

The larger species of this genus are so very densely green in the living
condition that it is impossible to get any idea of the form of their chloro-
plasts, even after very careful study. For this reason they have never been
accurately described or figured.

The earliest investigators did not usually attempt to illustrate the

238 Carter . — Studies on the Chloroplasts of Desmids. I.

structure of the chloroplasts, and the figures of Delponte (1873) were the first
to show any differentiation at all of the cell-contents. Delponte indicated
the presence of ridges on the surface of the chloroplasts in Eu. ansatum and
Eu . oblongum , but, on the whole, his figures do not give a very good idea
of the form of the chloroplast in the genus.

Gay (1884) gives a more distinct figure of the chloroplast in Eu.
Didelta, var. sinuatum , but it is incorrect, since he represents in a single
semi-cell two separate chloroplasts, each with a central pyrenoid. During
this work the typical chloroplast of this species was found to be quite
different.

In practically all cases, careful staining is essential for the successful
investigation of the chloroplasts of this genus, and with the largest species
it is even necessary to cut sections in order to understand their complicated
structure. After the general plan of the chloroplast has been made out by
means of sections, it is then possible to interpret the extraordinary appear-
ance presented by the whole specimen.

The species examined were Eu. dubium , Nag., Eu. elegans , (Breb.)
Kiitz., Eu. binale , (Turp.) Ehrenb., Eu. pectinatum , Breb., Eu. ansatum ,
Ralfs, Eu. bidentatum , Nag., Eu. eras sum, (Breb.) Kiitz., Eu. oblongum ,
(Grev.) Ralfs, Eu. Didelta, (Turp.) Ralfs, Eu. ampullaceum , Ralfs, Eu.
affine , Ralfs, Eu. insigne , Hass., Eu. ventricosum , Lund., Eu. sinuosum ,
Lenorm., Eu. cuneatum , Jenner, and Eu. verrucosum , Ehrenb. It was
found that in every case the chloroplasts are typically axile, and in all these
species, with the single exception of Eu. verrucosum , there is only one
chloroplast in each semi-cell. It is possible that this species, which differs
from all the others examined, not only in its chloroplast, but also in the
general form of its cells, should be placed in a special section of the genus
j E nostrum.

Excluding Eu. verrucosum, the species examined fall into two distinct
groups according to the structure of their chloroplasts. In the first the
chloroplast is quite simple, and contains typically a single pyrenoid in the
central position. The larger species form the second group. Their
chloroplasts are much more complicated, and although being nominally
axile, have by far their greater mass disposed in a parietal layer against the
interior of the cell-wall. The pyrenoids are numerous, and are practically
confined to the more peripheral parts of the chromatophore.

Although presenting very diverse appearances when examined from
the exterior, the chloroplasts of the various species of the genus are really
all built up on the same plan, and a comparison of transverse sections shows
that the differences even between the two main groups are very slight. In
fact all can be considered as elaborations of the simple type found in
Eu. dubium, and in general the chloroplast becomes more complicated
with the increase in size of the cell.

Carter. — Studies on the Chtoroptasts of Desmids. /. 239

Group I.

This group comprises in general the smallest species of the genus.
The chloroplast consists of a fairly massive central portion containing
one or more pyrenoids, and from this radiate towards the periphery various
plates which are always destitute of pyrenoids.1 The most important part
of the chloroplast in these smaller species is the central axile mass, the
peripheral parts being relatively small and insignificant.

Eu. dubium , Eu. elegans , and Eu. binale.

These small species, and probably all the smallest species of the genus,
have a very simple type of chloroplast. Here there is a rather massive
chloroplast which occupies practically the whole of the tiny semi-cell, and
consists simply of an axile mass containing typically one pyrenoid, from
which four lobes are given off, two of these enveloping each front wall
of the semi-cell (Figs. 56- 8). Sometimes in the front view two ridges are
visible in the median region, owing to the slight branching of the four
primary lobes, but this is seen much better in the end view ; cf. Fig. 58.

Eu. bident atum .

Eu. bidentatum has a chloroplast which is rather different from that of
any of the above-mentioned species. It sometimes has a more or less
definite parietal layer of chloroplast, comparable to some extent with the
parietal plates found in the larger species of the genus. The parietal
portion, however, usually takes the form of irregular bands lying against the
cell-wall (Fig. 51) ; it is only very rarely that definite parietal plates are
present (Fig. 50). These bands are seen in the end view to be connected
up to a central axile mass containing a single pyrenoid. They are, in fact,
merely the flattened edges of the various lobes arising from the central axis
(Fig. 53). There are usually four such lobes, but occasionally extra ones
are present.

Eu. pectinatum and Eu. ansatum .

These two species, in spite of their fairly large size, have typically one
pyrenoid in each semi-cell, but their chloroplasts, although being exactly of
the same type as that found in the smallest species of the genus, are rather
more elaborate.

There is, in these two species, a single pyrenoid embedded in a central
mass of chloroplast, which occupies comparatively less space than the
corresponding axis of the smaller species, whilst the ridges are in conse-

1 In one specimen of Eu. pectinatum a number of small naked pyrenoids or proteid granules
were observed in the peripheral parts of the chloroplasts, but in this group ordinary pyrenoids
never occur except in axile part of the chromatophore.

240 Carter. — Studies on the Chloroplasts of Desmids. /.

quence much larger and more important. Four main ridges are given off
from the central axis (Fig. 68), and as a rule each of these soon forks into
two, sending one branch to the front wall and the other to the side wall
(Fig. 61). Thus there are usually eight ridges in all, two running towards
each front wall, and two towards each side wall. In the front view the
chloroplast often looks more complicated owing to the extraordinary bending
or further branching of these eight ridges, or the presence of extra ridges
arising from the central axis (Figs. 59 and 66). The subsidiary ridges
arising by the further division of the eight main ridges are seen in the front
view as short dark lines. It is usually only the main ones which extend all
the way from the nucleus to the apex of the semi-cell. In these two species
also the edges of the ridges lying against the cell-wall are frequently lobed.

The single pyrenoid in the centre of the cell may be replaced in
well-nourished specimens by a group of two to four, usually in a line,
one above the other, or more rarely side by side in the central axis
(Figs. 59 and 60).

The general form of the chloroplast in all these smaller species having
a central pyrenoid is very similar, the chromatophore simply becoming more
elaborate with the increase in size of the cell. There is very little variation
amongst the individuals of each particular species, and the only deviation
from the type was observed in one or two specimens of Eu. bidentatum , the
same condition being also noticed on other occasions in Eu. pectinatum and
Eu. binale . These peculiar specimens contained two pyrenoids in each
semi-cell, side by side, but widely separated from each other. Moreover
each pyrenoid was embedded in the centre of a separate mass of chloro-
plast. The semi-cell therefore contained two axile chloroplasts, each con-
sisting of an axis containing a pyrenoid and several radiating plates
stretching towards the cell- wall ; cf. Figs. 54, 55, 70, and 71. It was
interesting to notice this variation in the structure of the chloroplast,
because in Eu. verrucosum (Figs. 90, 91, and 92) the chloroplast is normally
of this particular type. It would be unwise, however, to attach too much
importance to the coincidence, since the variation only concerned a few
isolated specimens, and moreover the same kind of structure has also
occasionally been observed in certain species of other genera, e. g. Cos-
mar iumy which normally have a single chloroplast with one pyrenoid.

Group II.

The chloroplasts of species belonging to this group are characterized
by the fact that the axile part is very thin and delicate, and contains few or
no pyrenoids, whilst the cell-wall is covered with a thick parietal layer
of chloroplast which is much more important and usually contains numbers
of pyrenoids.

Carter. — Studies on the Chloroplasts of Desmids. I. 241

Most of the largest species examined have chloroplasts of this type,
including Eu. eras sum , Eu . oblongitm , Eu. Didelta , Eu . ampidlaceum ,
Eu. affine, Eu. insigne , Eu. ventricosum , Eu. sinuosum , and Eu. cuneatmn.
There is remarkable uniformity in the structure of the chloroplasts in
typical specimens of all the above species, that of the last-mentioned being
the only one which differs even slightly from the general type.

Although the form of the chloroplast is so very constant throughout
the whole group, in each individual species there is considerable variation,
the same kind of variation being met with in every case. Specimens whose
chloroplasts are transitional between the axile and parietal conditions are
frequently found in most of the species mentioned above.

Putting aside such exceptions, and taking the ordinary axile form
of chloroplast found in Eu. crassum as a type, it is seen that the massive
chloroplast has a central axis running through the interior of the semi-cell
from nucleus to apex ; cf. Fig. 100 (lower semi-cell). This gives off four
radiating plates, two going towards each front face of the semi-cell (Fig. 101).
On reaching the cell-wall each of these radiating plates spreads itself
out against the surface of the wall, forming an extensive parietal plate, two
of which can be seen in the front view of the semi-cell ; cf. Fig. 100 (upper
semi-cell). This parietal portion, consisting of four plates, forms by far the
more massive part of the chloroplast, the central axis and radiating plates
being very thin and difficult to distinguish in whole specimens.

The central axis usually has the form of a long narrow flattened plate
or slender rod which is in close connexion with the nucleus near the
isthmus, and often extends nearly to the median incision of the apical
lobe. When more or less plate-like, it varies in its disposition, sometimes
presenting its surface to the observer in the front view and sometimes
its edge. Very often it is twisted at some particular point through an
angle of 90°, so that for part of the way one sees its surface, and for the rest
of the way its edge; cf. Figs. 63, 72, and 100. It is very common for two
such twists to occur, one a little way from the nucleus and the other
a similar distance from the apex.

Occasionally, especially in Eu. Didelta , the central axis is much
broader than usual, and forms an extensive plate in the middle of the cell.
In transverse sections such an axis is seen as a thin line parallel to the front
walls of the cell, giving off at each end two extremely short radiating plates
which spread out almost immediately to form the parietal part of the
chloroplast (Fig. 65). Thus there is a concentration of chloroplast substance
towards the sides of the cell, and this fact is also apparent from an examina-
tion of the whole specimen in the front view, because two dark lines are to
be seen stretching from the nucleus to the apex, one on each side of the
median line. In such cases it is very difficult to demonstrate the presence
of the central axis of the chloroplast. It cannot as a rule be seen at all in

242 Carter . — Studies on the Chloroplasts of Desmids. I.

the front view, and it would be very easy to confuse such a chloroplast with
the really parietal form which is occasionally met with in this genus.
In order to determine whether the chloroplast is axile or not, it is necessary
to examine it from the side or end. The central axile plate will then
be viewed along its edge, and will appear as a sharp line if it be present.
Such broad central axes occur occasionally in other species of the genus
(cf. Figs. 82, 93, and 94), but it is the rule rather than the exception
in Eu. Didelta .

In most specimens, pyrenoids are rarely found in the central axis,
but there may be one or two small ones, especially when this part of
the chloroplast is more massive than usual. If there is a twist in the axis,
a tiny pyrenoid is also commonly found at the point of twisting.. Eu.
sinuosum , Eit. ampidlaceum , and Eu. affine , however, often have pyrenoids
even of the ordinary size in their central axis, especially in well-nourished
specimens with large chloroplasts.

In transverse sections the radiating plates are seen connecting up the
parietal plates with the central axis, and their length naturally depends on
the shape and disposition of the latter. They may be long and distinct
(Figs. 73, 99, and ioi), or in rare cases they may appear to be entirely
absent, the parietal part of the chloroplast apparently arising directly from
the central axis; cf. Eu. Didelta (Fig. 65). Towards the cell-wall these
radiating plates thicken out, and finally spread out over the wall to form the
parietal plates (Figs. 83, 99, and 101).

The latter form a thick layer lining nearly the whole of the cell-wall,
and there are four of them in each semi-cell, two side by side on each front
face (Figs. 62, 63, 72, 82, 93, 94, &c.). The general shape of the parietal
plate necessarily depends on the outline of the cell. Its one edge approxi-
mately follows the lateral margin of the semi-cell, and the opposite edge
closely approaches the median line. The plates are sometimes coarsely
lobed, and these lobes are further subdivided, forming a fringe of pro-
jections, the shape of which varies according to the species. In Eu.
oblongum they are rounded or finger-like (Fig. 72) ; in Eu. crassum they are
more jagged (Fig. 100). The lobing, particularly of those edges near the
median line, is frequently very deep, and as a consequence the plates are
sometimes nearly cut horizontally into two or three separate parts (Figs. 72.
and 100).

The external surface of the parietal plates is rare1 / quite smooth, but is
usually covered with tiny outgrowths extending towards the cell-wall. The
size and shape of these projections vary with the species, but they are
usually very similar to the teeth or outgrowths round the edges of the
parietal plates of the same species. In Eu. crasstim they are frequently
very large and can be seen quite easily in living specimens (Fig. ico). In
the smaller species they are not so evident, but they can usually be

Carter.— Studies on the Chloroplasts of Desmids. I. 243

distinguished in stained material, and can be recognized in transverse
sections (Figs. 65, 73, 83, 97, 99, and 10 1). It is only occasionally, when the
chloroplast is feebly developed or when the chloroplast is very distended
with stroma-starch, that the parietal plates are quite smooth.

Most of the pyrenoids contained in the cell are embedded in the
substance of the parietal plates. The number and size of the pyrenoids
present vary considerably according to the condition of the individual cell.
Eu . crassum and Eu. ventricosum seem to have the greatest number, seven
or eight being scattered throughout each parietal plate, or in all about
thirty to forty in each semi-cell (Figs. 82 and 100). In Eu. Didelta , Eu.
oblongum , and Eu. ampullaceum there are about three in each parietal
plate, most of them embedded in the thickest part of the chloroplast, where
the radiating plates spread out to form the parietal plates (Figs. 65 and 97).
Eu. affine has very few pyrenoids, only five to eight in each semi-cell, but
these are very large (Fig. 93). Eu. sinuosum has about as many smaller
ones (Fig. 62).

Eu. cun eat uni.

Eu. amentum , although agreeing essentially with Eu. crassum in the
form of its chloroplast, differs from the general type in one or two respects.
The central axis is usually in the form of a broad triangular plate, its surface
parallel to the front faces of the semi-cell, as is frequently the case in
Eu. Didelta. The two lateral edges of the plate are seen in transverse
section to thicken abruptly and fork into two. Thus there are four masses
of chloroplast, each extending towards the cell-wall, either as a parietal plate
with projections on its external surface (Figs. 84 and 87) or as a more or
less brush-like mass (Fig. 89 and 85). In the latter case the whole chloro-
plast with the exception of the central axis is deeply cut into numerous long
finger-like projections stretching towards the cell-wall, and definite parietal
plates are not evident in the front view. Various stages between the
comparatively smooth parietal plate and the brush-like form are to be
found.

Eu. cuneatum also differs from all other members of the group in the
arrangement of its pyrenoids, of which there are three to twelve in each
semi-cell. When there are comparatively few pyrenoids, these are embedded
in the thickened edges of the central axis, all in one plane (cf. Fig. 85), but
when there are more than can be accommodated in this position they spread
outwards into the parietal masses (Fig. 87). They are, however, always
found in the interior of the cell rather than in the parietal parts of the
chloroplast.

Occasionally Eu. cuneatum is found with a distinct parietal layer of
chloroplast containing scattered pyrenoids, very similar to that of Eu. cras-
sum, but more often it shows the structure described above.

244 Carter . — Shiclies on the Chloroplasts of Desmids. /.

Although the chloroplast described above is typical for all the species
mentioned, it is not uncommon to find odd specimens which have a slightly
different structure. The variations usually concern the axial part of the
chloroplast ; the parietal plates vary very little amongst individuals of the
same species, the chief differences occurring in the lobing of the edges of
the plate and the number and size of the outgrowths from its surface. It
is quite a common thing, however, to find in many species specimens in
which the central axis is much shorter than usual, leaving a space either at
the apex or base of the semi-cell, or both (Figs. 104 and 105). The shape
of the radiating plates is necessarily interfered with when this happens, and
they accordingly curve outwards from the shortened axis towards the apex
and base of the cell, so that the parietal plates are usually quite normal. In
other cases both the central axis and the radiating plates may be missing,
and the parietal plates are then the only remaining part of the chloro-
plast (Fig. 102). Sometimes the parietal plates, in such cases, are not
entirely separate and free from each other, but are variously connected by
one or two extremely thin strands of chloroplast running across the cell
from one plate to another (Figs. 74, 75, 96, and 103).

Occasionally very irregular chloroplasts are found, in which the central
axis may be perforated (Fig. 94) or displaced, together with the radiating
plates, from its usual position. Another variation is seen in Figs. 86
and 88.

In typical specimens of the group, the axial part of the chloroplast,
composed of such extremely thin plates, cannot play a very important part
in the photosynthetic processes of the cell. This is proved to some extent
by the usual absence of pyrenoids from the central axis in the largest
species of the genus. The majority are always to be found in the parietal
plates. Considering this fact, and also that parietal chloroplasts have been
evolved in a few advanced species of other genera of Desmidiaceae, it might
be expected that in these large species of Euastrum there would be
a tendency for the useless part of the chloroplast in the interior of the cell
to disappear, leaving just the parietal plates. This is possibly the reason
why so many individuals seem to show transitional stages between the axile
and parietal condition.

A less important variation was observed in two isolated specimens, one
of Eu . eras sum, and the other of Eu. oblongum . Here all the pyrenoids
were aggregated in a compact irregular mass in the interior of the cell.
The central axis was considerably swollen to accommodate them, and from
it a number of short strands of chloroplast ran out towards the cell-wall,
ending, in the first-mentioned species, in irregular parietal bands. In the
specimen of Eu. oblongum there was a more or less complete reticulated
layer of chloroplast lining the cell-wall. These two specimens were interest-
ing because they appear to form a link between Groups I and II, and this

Carter . — Studies on the Chloroplasts of Desmids. /. 245

was all the more striking because an unusual specimen of Eu. ansatum
(Group I) was also encountered which was almost identical with the
abnormal specimen of Ett. eras sum described above.

The Chloroplasts of Eu . verrucosum.

This species differs from all the other species examined in having two
chloroplasts in each semi-cell. In each chloroplast there is typically one
large pyrenoid, and the general appearance of the cell is very suggestive of
certain large species of Cosmarium. Each chloroplast is provided with an
axis, which, beginning at the isthmus, stretches diagonally towards the
incision between the apical and lateral lobes; cf. Fig. 91. This axis con-
tains a single large pyrenoid, and around it are arranged about four or five
irregular ridges which radiate towards the front and side walls of the cell
(Figs. 90 and 92). The peripheral edges of the ridges are usually very
little ornamented.

Thus the chloroplast of Eu. verrucosum is very unlike that of any other
species examined, and it is therefore very difficult to explain its relationships.
It is possible, however, that the examination of other more closely allied
species would help to make clear its affinities.

VII. The Chloroplasts of the Genus Xanthidium.

In a few species of the genus, the form of the chloroplast can be made
out from living material, and the chloroplasts of one or two species were
figured by Delponte (1873). The structure of the chloroplast and the
position of the pyrenoids were also indicated in several species by W. and
G. S. West (1904-11).

Boldt (1888) attempted to subdivide the genus according to the dis-
position of the chloroplasts, and instituted the sub-genera Euxanthidium
and Centrenterium to include those species having parietal and axile
chloroplasts respectively.

Larsen (1907) described and figured X ’. groenlandicwn , Boldt, indi-
cating that in its chloroplasts this species agrees fairly well with certain
species of the genus having a distinctly parietal chloroplast, whereas Boldt
placed it in Centrenterium.

During this investigation the following species were examined :■ —
X. aculeatum , Ehrenb., X. acanthophorum , Nordst., X. hastiferum , W. B.
Turn., X. Brebissonii> Ralfs, X. antilopaeum , (Breb.) Kiitz., X. cristatum ,
Breb., X . subhastiferum, var. Murrayi , W. and G. S. West, X. fasciculatum,
Ehrenb., and X. armatum , (Breb.) Rabenh. The chloroplasts of these
species were found to be of two distinct types, either axile or parietal, but in
at least one species the form of the chloroplast is variable, and transitions
from the axile to the parietal condition were observed.

246 Carter . — Studies on the Chi or op lasts of Desmids . /.

X. acideatum , X. acanthophorum , and X. hastiferum.

These three species were found to have axile chloroplasts. In all cases
there are two chloroplasts in each half-cell (Figs. 117, 118, and 127). Each
chloroplast is provided with an axis which arises on one side of the isthmus
near the nucleus and extends obliquely towards the corresponding lateral
region of the semi-cell, increasing in size and containing typically one large
pyrenoid ; cf. Fig. 127 (lower semi-cell).

Around this axis are arranged a varying number of plates which radiate
towards the cell-wall in various directions. Four of these plates are usually
more prominent than the others, one extending to each front face of the
semi-cell, and two to the corresponding lateral face (Fig. 128). Other
plates or ridges, if present, are often much more irregular, and do not
extend from end to end of the semi-cell in the same way as the four larger
ones (Figs. 317 and 118). The margins of the plates may be quite smooth,
irregular, or lobed.

X Brebissonii.

In this species the chloroplasts in typical specimens are exactly
similar to those of X. acideatum , X. hastiferum , and X. acanthophorum ,
there being in each semi-cell two axile chloroplasts each with a single
pyrenoid (Figs. 119, 120, and 121). In many cases, however, the pyrenoids
are much more numerous, as many as nine being present in one semi-cell,
and the form of the chloroplasts may be considerably changed. Very often
there are two or three pyrenoids in the axis of each chloroplast where
typically there should be but one (Figs. 122 and 123), or again there may
be two or three very small pyrenoids in the peripheral edges of one or more
of the plates radiating from the axis (Fig. 123). The actual form of the
chloroplast in such cases is often not seriously interfered with, and there
are as before two axile chloroplasts in each semi-cell. In other individuals
the numerous pyrenoids are not confined to the centre of the chloroplast,
but, on the other hand, pyrenoids of considerable size may also occur in the
more peripheral parts of the cell, showing the increased importance of the
parietal parts of the chloroplast even although as a whole it may still be
axile (Fig. 124). In other specimens the pyrenoids are quite absent from
the positions in the interior of the cell in which they should typically occur,
and the form of the chloroplast is quite different, being practically parietal,
often very irregular in shape, consisting of a variable number of masses, each
of which contains several scattered pyrenoids (Fig. 125). Occasionally there
are four definite parietal plates each with a pyrenoid, regularly arranged, as
in those species of the genus which typically have parietal chloroplasts
(Fig. 126).

The axile condition of the chloroplast seems to be far more common
than the parietal, and of sixteen specimens examined only five exhibited

Cartel'. — Studies on the Chloroplasts of Desmids. /. 247

any marked tendency to the parietal condition, and even in these one semi-
cell in every case had distinctly axile chloroplasts. Sometimes in the same
semi-cell one chloroplast was distinctly axile, whilst in the other half of the
semi-cell there were signs of the tendency to the parietal condition.

X. antilopaeum , X. cristatum , X. subhastiferum , var. Mrirrayip
X . fascicidcitum :, and X. armatum .

These remaining five species all have parietal chloroplasts, of which
there are typically four in each semi-cell, two side by side on each front face
(Figs. 106, 108, 113, 1 15, and 129). The parietal plates are usually very
thin, and adhere closely to the cell-wall, corresponding fairly accurately with
it in shape. In X. armatum the chloroplast plates are often prolonged at
the angles of the cell to form projections which fill up the hollow bases of
the branched spines (Figs. 129, 131, and 132). Very often there is an extra
chloroplast on one or both front faces of the cell, either a small one, wedged
in between the others, or one equal to them in size (Fig. 109). Rarely
there is a fairly large number of small rounded plates, seven such chloro-
plasts having been observed on one front face of a semi-cell of X. subhasti-
ferum , var. Murrayi. Occasionally in X. armatum the chloroplast is in the
form of a number of rather narrow parietal ribbons, running longitudinally,
about six to eight in each semi-cell.

The edges and external surface of the chloroplast plates in X. subhasti-
ferurn , var. Murrayi , and X. cristatum , appear to be quite smooth and
without projections of any kind ; cf. Figs. ]o8, 109, and 115. The same is
usually the case in X. antilopaeum (Fig. 106), although it was occasionally
noticed that in this species the surface of the chloroplasts was more irregular.
In X . fasciculatum, however, the edges and surface of the plates were almost
invariably covered with numerous short outgrowths (Fig. 113), and it was
in this species that the maximum development of the chloroplast in this
direction was noticed. In X. armatum the presence of such projections is
a very variable character, being dependent on the amount of stroma-starch
contained in the chloroplast. When little starch is present in the chloro-
plast plates are very thin, their protoplasmic foundation is dense in
texture, and in such cases a few slight prominent ridges (Fig. 130) or
more numerous delicate projections usually stretch from their external
surface towards the periphery. When more starch is present, the chloro-
plasts become distended to three or more times their former thickness, and
here the external surface is usually quite smooth, the delicate ridges having
been quite obliterated in the process (Figs. 129 and 131).

1 This Desmid was erroneously figured by W. and G. S. West (1904-11, vol. iv) as having an
axile chloroplast with a single pyrenoid in each semi-cell.

T

248 Carter . — Studies on the Chloroplasts of Desmids. /.

In practically all cases each parietal chloroplast is in close connexion
with the nucleus at the base of the semi-cell ; cf. Fig. 106.

With the exception of the large species X. armatum , there is typically
one pyrenoid in the centre of each parietal chloroplast (Figs. 106, 109, 113,
and t 1 5), although very often two or three may be seen close together in
one or more of the plates (Fig. 108). The pyrenoids are often very large,
and the thin chloroplasts are in consequence thickened considerably where
they occur, the corresponding chloroplasts of the two front faces of the
semi-cell sometimes projecting so far into the interior of the cell that they
nearly touch at these points; cf. Figs, no and 111. In X. armatum the
pyrenoids are more numerous, numbering about five to twelve in each
chloroplast (Figs. 129-32). They vary considerably in size, some of them
being extremely small, and comparable to the small globules found in the
parietal parts of the chloroplast in Cosmarium ochthodes and other species.

VIII. Summary of the General Characters of
the Chloroplasts.

The chloroplasts in the Saccodermae are, with a few exceptions, usually
very simple in form, and are nearly all well known.

In the higher Desmids the chloroplasts are, in general, very compli-
cated and beautiful structures, and many of them have not hitherto been
investigated. The delicacy of their form is dependent upon —

(a) the relative amount of chlorophyll-bearing substance present in the
individual, and

(b) the general physiological condition of the cell, particularly as regards
the quantity of free stroma-starch present in the chromatophore.

The chloroplasts may be axile or parietal, and their general form is
usually constant, but in a few cases there is marked variation in the disposi-
tion of the chloroplasts amongst individuals of one species.

The number and position of the pyrenoids present depend on the
size and shape of the chromatophore. In the more extensive chloroplast
plates of both axile and parietal forms they are often very numerous and
scattered.

In all cases the amount of foo.d stored in the form of pyrenoids is
dependent on the condition of the cell, and at any time two or more
pyrenoids may be formed by the division of an original one.

In many forms the number of pyrenoids present in each semi-cell is
generally supposed to be constant. This is not true, since the actual
number of pyrenoids present is dependent on various changing factors, but
in such cases the points of pyrenoid formation are usually quite definite and
fixed.

In addition to the ordinary large pyrenoids which are usually provided

Carter. — Studies on the Chloroplasts of Desmids . /. 249

with a starch-sheath, in several species numbers of small naked pyrenoids
or granules of protein were observed in the superficial layers of the chroma-
tophore.

A. Summary of the Special Characters of Netrium
and CLOSTERIUM.

The chloroplast of Netrium consists of seven to twelve plates radiating
from a central axis.

The central axis of each chloroplast is occupied by a single long
pyrenoid stretching throughout its whole length and surrounded by a thick
sheath of starch which is almost invariably more than one layer of grains in
thickness.

Under certain conditions the pyreno-crystal of this long pyrenoid
breaks up into numerous spherical or irregularly shaped portions which
remain embedded in the central mass of starch grains.

The only other genus in which these peculiar pyrenoids have been
observed to occur extensively is Penium , although they are also general in
the two species Cylindrocystis Brebissonii and Closterium Libellida.

Lutman’s statement that the chloroplast in Closterium consists of
a curved cone-shaped structure with relatively low ridges on its surface is
not true for all species of this genus.

The relative size of the axis and ridges varies with the species, and also
to some extent within each individual species, according to the physiological
condition of the cell.

The pronounced undulation or anastomosis of the ridges frequently
seen in certain species of the genus only occurs in individuals having fairly
large ridges. Such individuals show a very irregularly branched structure
in transverse section and are nearly always destitute of stroma-starch.

Other individuals of these particular species containing much stroma-
starch usually have a much broader axis and comparatively low ridges,
which are seen in the front view to be practically parallel.

Even in species swell as CL Lunula and Cl. Ehrenbergii , where the
pyrenoids are arranged in the peripheral parts of the axis, there is consider-
able variation in the relative size of the axis and ridges, often to be corre-
lated with the variation in texture of the protoplasmic reticulum of the
chloroplast, and therefore the relative position of the pyrenoids is also
subject to a certain amount of variation.

In spite of the fact that all species of Pleurotaenium are supposed to
have parietal chloroplasts, it was observed that in PL Trabecida , var. rectum ,
the chloroplast consists of an axile rod, containing pyrenoids, with several
low ridges projecting from its surface.

250 Carter . Studies on the Chloroplasts of Desmids. /,

B. Summary of the Special Characters of T ETMEMORUS.

The chloroplast in Tetmemorus is essentially similar to that of Closterium
in consisting of a central axis containing pyrenoids and a number of
radiating ridges.

In T. Brebissonii the ridges thicken abruptly towards the periphery,
forming longitudinal parietal bands of considerable width.

T, granulatus and T. laevis have simple ridges which do not form such
extensive parietal masses, but end with toothed edges, or are provided with
attenuated projections which stretch towards the cell-wall. When little or
no stroma-starch is present in the chloroplasts of these two species, the
ridges often undulate in a manner similar to that occurring in certain
species of Closterium.

C. Summary of the Special Characters of Eua strum.

With the exception of Eu. verrucosum the chloroplasts of all the
species examined can be considered as variations of one type. At the
same time they naturally form two distinct groups.

The smallest species examined form Group I. They have a relatively
large axile mass of chloroplast containing typically one pyrenoid, and from
this four, main lobes project towards the periphery. These lobes are in the
very smallest species quite small and insignificant, but in the larger species
of the group they are somewhat larger and may be branched.

Group II contains most of the largest species examined. Here the
structure of the chloroplast is essentially similar to that of the first group,
but the real axis of the chloroplast is very thin, and the peripheral lobes
spread out to form a thick layer lining the cell-wall, so that the greater
mass of the chloroplast is in the parietal position. The pyrenoids, instead
of occurring in the centre of the semi-cell as in the first group, are to be
found in the more massive part of the chloroplast forming the parietal
plates, the interior of the cell being often quite free from them. Following
on the decrease in importance of the axile part of the chloroplast in Group II
is a decided tendency for it to disappear altogether, leaving only the parietal
mass of chloroplast with its pyrenoids lining the cell-wall. Transitions
from the axile to the parietal condition of the chloroplast were observed in
most of the larger species examined.

In the case of Eu. verrucosum there are two distinct axile chloroplasts
in each semi-cell, each with a large central pyrenoid, as in many species of
Cosmarium. The structure of its chloroplast suggests that it has no very
close affinities with any of the other species of the genus examined, but if
other related species could be investigated, its extraordinary structure would
possibly be explained.

Carter. — Studies on the Chloroptasts of Desmids. /. 251

D. Summary of the Special Characters of Xanthidium.

In those species of Xanthidium examined, two distinct types of chloro-
plast were observed.

A few species were found to have axile chloroplasts. These invariably
had two chloroplasts in each semi-cell, there being typicallyone pyrenoid in
the centre of each.

The remaining species examined had parietal chloroplasts, and here
there were usually four in each semi-cell. In all these species, with the
exception of X. armatum , there was typically one pyrenoid in the centre of
each chloroplast, but in this very large species the pyrenoids were both
numerous and scattered.

X. Brebissonii seems usually to have chloroplasts of the first type, but
the pyrenoids frequently become very numerous, and the chloroplasts often
tend to become partly parietal.

In conclusion, I wish to express my sincerest thanks to Professor
G. S. West for much valuable help and advice during the course of the
work, and also for supplying much of the material. I am also deeply
indebted to the Birmingham Natural History and Philosophical Society for
a grant from their Endowment of Research Fund, to help in the cost of
reproducing the plates, and also to the Royal Society for a further grant
for the same purpose.

The Botanical Laboratory,

University of Birmingham.

Bibliography.

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Band xiii, No. 5, 1888.

DeLPONTE, J. B. (1873): Specimen Desmidiacearum subalpinum. Augustae Taurinorum, 1873,
Mem. d. R. Accad. d. Scienze di Torino, ser. 2, xxviii.

Ducellier, F. (1917) : Notes sur le pyrenoide dans le genre Costnarium Corda. Bull, de la Soc.
Bot. de Geneve, 2me serie, vol. ix, 1917.

Gay, F. (1884) : Essai d’une Monographic locale des Conjuguees. Montpellier, 1884.

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d. Physik. Oek. Gesellsch. zu Konigsberg, 1879.

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Handlingar, Band xiii, No. 9, 1888.

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Lundell, P. M. (1871) : De Desmidiacies quae in Suecia inventae sunt, observationes criticae.
Nova Acta R. S. S. Upsala, ser. 3, xiii, 1871.

252 Carter. — Studies on the Chlor op lasts of Desmids. I.

Lutkemuller, J. (1893) : Beobachtungen iiber die Chlorophyllkorper einiger Desmidiaceen.
Oesterr. bot. Zeitschrift, 1893, Nr. 1 u. 2.

: (1895) : Ueber die Galtung Spirotaenia , Breb. Ibid., 1895, Nr. 1 u. ff.

(1902) : Die Zellmembran der Desmidiaceen. Beitrage zur Biologie der Pflanzen,

Band viii, 1902.

(1903) : Ueber die Gattung Spirotaenia, Breb. Oesterr. bot. Zeitschrift, 1903.

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Bot. Gazette, xlix, 1910.

(1911) : Cell and Nuclear Division in Closterium. Bot. Gazette, li, 1911.

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Ralfs, J. (1848): The British Desmidiaceae. London, 1848.

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West, G. S. (1904) : The British Freshwater Algae. Cambridge, 1904.

(1914) : A Contribution to our Knowledge of the Freshwater Algae of Columbia.

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West, W. and G. S. (1896) : On some New and Interesting Freshwater Algae. Journ. Roy. Micro.
Soc., 1896.

(1897) : Desmids from the United States. Journ. Linn. Soc., vol. xxxiii, 1897.

(1898) : Observations on the-Conjugatae. Ann. Bot., vol. xii, 1898.

(1902) : A Contribution to the Freshwater Algae of the North of Ireland.

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(1904-11): Monograph of the British Desmidiaceae. Ray Soc., vqI. i, 1904;

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DESCRIPTION OF PLATES XIV-XVIII.

Illustrating Miss Nellie Carter’s paper on the Chloroplasts of Desmids.

The specific characters of Desmids are sometimes obliterated during the prolonged processes
of preparation, but all the species were identified in either the living or carefully fixed condition
by Professor G. S. West.

PLATE XIV.

Figs. 1-5. Closterium Lunula, (Miill.) Nitzsch. Fig. 1 x 350 ; Fig. 2, transverse section of
a similar specimen, x 810; Fig. 3, another individual, the ridges of whose chloroplast are much
broader, x 350; Fig. 4, transverse section of a similar specimen, x 810; Fig. 5, transverse section
near apex of cell, x 810.

Figs. 6, 7. Cl. laticeolatum, Kiitz. Fig. 6 x 510; Fig. 7, transverse section (intervening
cytoplasm more deeply stained than the chloroplast itself), x 810.

Figs. 8, 9. Cl. Libellula , Focke. Fig. 8 x 510; Fig. 9, transverse section (axis distended with
starch), x 810.

Figs. 10-12. Cl. attenuatum , Ehrenb. Fig. 10 x 510; Fig. 11, transverse section near apex
of cell, x 810; Fig. 12, transverse section from thicker part, x 810.

Figs. 13-15. Netrium Digitus, (Ehrenb.) Itzigs. and Rothe. Fig. 13, whole specimen, x 510;
Fig. 14, longitudinal median section, x 510; Fig. 15, transverse section, x 510.

Figs. 16-18. N. oblongum , (de Bary) Liitkem., var. cylindricum, W. and G. S. West. Fig. 16,
specimen having one long pyrenoid in each chloroplast, x 510; Fig. 17, specimen having many
small pyrenoids, x 510; Fig. 18, optical section, x 510.

Carter . — Studies on the Chloroplasts of Desmids . /. 253

Fig. 19. N. interrupt urn, (Breb.) Liitkem. Individual having one pyrenoid and one chloroplast
which is just beginning to constrict, probably a recently divided specimen, x 510.

Fig. 20. Penittm spirostriolatum, Barker. Transverse section, x 510.

PLATE XV.

Fig. 21-5. Closterium 'ro stratum , Ehrenb. Fig. 21, specimen whose ridges undulate slightly,
x 510; Fig. 22, another specimen with straight ridges, x 510 ; Fig. 23, longitudinal section, x 510 ;
Fig. .24, transverse section, x 810; Fig. 25, transverse section near apical end of chloroplast, x 810.

Figs. 26, 27. Cl. angustatum , Kiitz. Successive transverse sections, x 810.

Figs. 28-30. Cl. regulare , Breb. Transverse sections of different individuals, x 810.

Figs. 31-4. CL costatum , Corda. Fig. 3r x 510; Figs. 32-4, transverse sections of different
individuals, x 810.

Figs- 35-7* Cl. Dianae, Ehrenb. Fig. 33 x 510; Figs. 36 and 37, transverse sections, x 810.

Figs. 38-43. Cl. striolatu?Hy Ehrenb. Fig. 38 x 510 ; Fig. 39, part of a longitudinal tangential
section showing anastomosis of the ridges, x 810 ; Fig. 40, transverse section showing the distending
of the chloroplast with stroma-starch; Figs. 41-3, serial transverse sections of another individual
containing little or no stroma-starch, and showing the varying combinations of the ridges, x 810.

Fig. 44. Cl. Ehrenbergii, Menegh. Surface view showing proteid granules, x 810.

Figs. 45, 46. Cl. -Siliqua, W. and G. S. West. Fig. 45 x 510; Fig. 46, transverse section,
x 810.

Figs. 47, 48. Cl. juncidum, Ralfs. Fig. 47 x 510; Fig. 48, transverse section, x 810.

Fig. 49. Pleurotaeninm Trabecula , (Ehrenb.) Nag., var. rectum , (Delp.) W. and G. S. West
x 510.

PLATE XVI.

(All x 510 with the exception of Figs. 77 and 81).

Figs. 50-5. Euastrum bidentatum , Nag. Figs. 50 and 51, front view; Fig. 52, side view;
Fig. 53, end view ; Fig. 54, an unusual specimen having two chloroplasts and two pyrenoids in each
semi-cell ; Fig. 55, end view of same specimen.

Figs. 56-8. Eu. dubium, Nag. Fig. 56, front view; Fig. 57, side view; Fig. 58, end view.

Figs. 59-61. Eu. ansatum , Ralfs. Fig. 59, front view ; Fig. 60, side view; Fig. 61, transverse
section.

Fig. 62. Eu. sinuosum , Lenorm. Front view.

Figs. 63-5. Eu. Didelta , (Turp.) Ralfs. Fig. 63, front view, lower semi-cell in optical section ;
Fig. 64, longitudinal median section, showing the central axis of each semi-cell and the radiating
plates cut irregularly ; Fig. 65, transverse section.

Figs. 66-71. Eu. pectinatum , Breb. Fig. 66, front view ; Figs. 67 and 68, transverse sections ;
Fig. 69, side view; Fig. 70, an unusual specimen ; Fig. 71, upper semi-cell of the same individual in
optical transverse section.

Figs. 72-5. Eu. oblongum , (Grev.) Ralfs. Fig. 72, front view, lower semi-cell in optical section ;
Fig. 73, typical transverse section ; Figs. 74 and 75, transverse sections of unusual specimens.

Figs. 76, 77. Tetmemorus granulatus , (Breb.) Ralfs. Fig. 76, slightly oblique front view ;
Fig. 77, transverse section, x 810.

Fig. 78. Tet. laevis, (Kiitz.) Ralfs. Front view.

Figs. 79-81. Tet. Brtbissonii, (Menegh.) Ralfs. Fig. 79, oblique front view; Fig. 80, longi-
tudinal median section, passing through the entire ridge on the right, and through the parietal
expansion only on the left ; Fig. 81, transverse section, x 810.

PLATE XVII.

(All x 510.)

Figs. 82, 83. Eu. ventricosunif Lund. Fig. 82, front view; Fig. 83, transverse section.

Figs. 84-9. Eu. cuneatum , Jenner. Figs. 84 and 89, front view; Figs. 85 and 87, transverse
sections ; Fig. 88, unusual specimen with part of one of its parietal plates free from the rest of the
chloroplast; Fig. 86, optical transverse section of the same individual in the upper region of
the semi-cell.

254 Carter. — Studies on the Chloroplasts of Desmids. I.

Figs. 9CH2. Eu. verrucosum, Ehrenb. Fig. 90, front view; Fig. 91, longitudinal section;
Fig. 92, transverse section (upper chloroplast rather torn).

Fig. 93. Eu. affine, Ralfs. Front view.

Figs. 94-7. Eu. ampullaceum , Ralfs. Fig. 94, front view of an individual with imperfectly
developed chloroplast, possibly after rapid cell-division; Fig. 95, typical front view; Fig. 96,
transverse section of specimen with entirely parietal chloroplasts ; Fig. 97, transverse section of
typical specimen.

Figs. 98, 99. Eu. insigne , Hass. Fig. 98, front view; Fig. 99, transverse section.

Figs. 100-5. Eu. crassum , (Breb.) Kiitz. Fig. 100, front view, lower semi-cell in optical
section; Fig. 101, transverse section; Fig. 102, specimen having an entirely parietal chloroplast;
Fig. 103, optical longitudinal section of specimen having a chloroplast which is practically parietal,
but has two strands passing through the interior of the cell; Figs. 104 and 105, optical longitudinal
sections showing the shortening of the central axis.

PLATE XVIII.

Figs. 106, 107. Xanthidium antilopaeum> (Breb.) Kiitz. x 510. Fig. 106, front view ; Fig. 107,
side view.

Figs. 108-12. X. subhastiferum , West, var. Murrayi , W. and G. S. West, x 510. Figs. 108
and 109, front view; Fig. no, longitudinal section passing through pyrenoids in the lateral region
of the cell (contents of lower semi-cell not shown) ; Fig. in, longitudinal section nearer the middle
line; Fig. 112, transverse section.

Figs. 113, 114. X. fasciculatum, Ehrenb. x 510. Fig. 113, front view; Fig. 114, end view.

Figs. 115, 116. X. cristatum , Breb. x 510. Fig. 115, front view; Fig. 116, end view.

Figs. 117, 118. X. aculeatum , Ehrenb. x 510. Fig. 117, front view; Fig. 118, optical
transverse section.

Figs. 119-26. X. Brebissonii , Ralfs. x 510. Figs. 119, 120, and 121, front view, side view
and optical transverse section of a typical specimen; Figs. 122-6, optical transverse sections of
various individuals, showing the variation in number and size of the pyrenoids, and transitions from
the axile to the parietal disposition of the chloroplasts.

Figs. 127, 128. X. acanthophorum , Nordst. x 810. Fig. 127, front view, lower semi-cell in
optical section ; Fig. 128, side view.

Figs. 129-32. X. armatum, (Br^b.) Rabenh. x 510. Fig. 129, front view of individual whose
chloroplast is packed with stroma-starch; Fig. 130, front view of specimen containing little starch
except that round the pyrenoids; Fig. 131, longitudinal section; Fig. 132, transverse section.

t/hubals of Botany,

C A RT E R . N C H L O R O P L A 3 T S OF DESMIDS

Voi.ixxih,pijw:

Ku/bTi, L on don.

SrnuiLs of Botany.

CARTER. N. CHLOROPLASTS OF D E S M I D S .

voi.xmi, pi.iv

Huth., London.

Jlnnals of Botany,

71. 70.

58.

CARTER. N. CHLOROPLASTS OF DESMIDS.

VoLZMUITl.Xl7!.

Huth/Lon.don.

Annals of Botany,

CARTER. N. — CHLOROPLASTS OF DESMIDS.

Voiixm,n.xvii.

.

Hutih, L on don.

cftruncds of Botany,

CARTER. N.-CHLOROPLASTS OF DESMIDS.

Voimm,pi.jvu.

c^rmals of Botany,

CARTER. N.— CHLOROPLASTS OF DESMIDS.

voi.miii,pi.xvin.

Rutin,, London.

Jjnnals of Botany,

CARTE R.N.- C H LOROPLASTS OF DESMIDS.

voi.xxxm,pi.xvui

HuthjLondon.

Observations on the Anatomy of Ash-wood with
Reference to Water-conductivity.

BY

M. G. HOLMES, B.Sc.

With seven Figures in the Text.

J investigation into the anatomy of Ash-wood has been carried out on

ii the lines of that described for Hazel-wood in a previous paper.1
Attention was directed chiefly to the proportion of the water-conducting
elements present in the wood. The results are presented graphically, and
are intended to make possible a comparison between different parts of the
same shoot as regards this character, as well as between shoots which differ

in size and vigour.

Material.

As in the case of the Hazel, the Ash-wood here investigated was all
wood of the first year. Three of the specimens, A3, A 4, and A 6, were
typical stool shoots, long, thick, and unbranched, with long internodes and
the scars of large leaves ; they were cut on March 10, 1918, from separate
Ash stools which had had one season’s growth after coppicing. Specimen
A 8 was cut on May t8, 1918, from an Ash stool of four years’ growth,
being the upper part of one of the shoots, bearing several laterals of the
previous season ; three of these were chosen for comparison with the first-
year stool shoots. They are much shorter than the latter, and lack some of
the vigour characteristic of the juvenile form. At the season when A 8 was
cut, the buds had opened and the leaves were beginning to expand ; the
external appearance of the shoot is shown in Fig. 1.

In the Ash the opposite leaves of a pair are often not placed exactly
level ; sometimes in the stool shoots they are several centimetres apart. In
these circumstances the position of the node was taken for convenience of
comparison as the middle transverse plane between the upper limits of the
two leaf scars, and the internodes were measured accordingly. The lengths
of the whole shoots and of their internodes are compared in Fig. 2. The

1 Holmes, M. G. : A Study in the Anatomy of Hazel-wood with Reference to Conductivity of
Water. Ann. of Bot., vol. xxxii, 1918.

[Annals of Botany, Vol. XXXIII. No. CXXX. April, i9ig.]

256

Holmes . — Observations on the Anatomy of

large axillary buds are placed well above the insertion of the leaf, and often
below the large bud there is a much smaller supernumerary one. In the
Ash shoot the terminal bud is generally present, but frequently it does not
develop farther, and in the next season the strongest shoots grow out from

the lateral buds near the apex. The
apices of specimens A 3, A 4, and
A 6 are compared in Fig. 3 ; it was
found that the apical buds of A 3
and A 4, the shorter shoots, were
strong, while that of A 6, the longer
shoot, was weaker. In specimen
A 8 is seen the result of the abortion
of the terminal bud. That formed
in 1916 failed to develop, and in
1917 six shoots grew out from
lateral buds, getting less vigorous
from the top downwards ; a similar
condition is repeated in the develop-
ment of the buds of A 8 a, the
strongest of these shoots, at the
opening of the season of 1918. In
the Ash a number of the shoots
which do develop are not perma-
nent ; such weak shoots as A 8 e are
likely to be suppressed very soon.
In A8£ the apex was dying back
by the failure of the apical and also
the lateral buds at the end.

Anatomy.

Fig. 1. The numbers refer to the internodes,
reckoned from the base of each shoot re-
spectively. The statistics of shoots A 8 a, A 8 b,
A 8 e, are given in Fig. 7.

There is a complete cylinder of wood
these shoots, widest in A 3, internode

In the young and vigorous stool
shoots there is a wide pith, especially
in the middle part of the shoot. At
the base, the wood cylinder is par-
ticularly wide between the cambium
and the pith, and it decreases in width
towards the apex relatively more than
does either the pith or the cortex,
in the terminal internode of each of
11, in the sense indicated above, and

very narrow in A 6, internode 15. In A 8 the cambial activity had been
resumed at the time that the specimen was cut, so that some new wood of
the 3918 season was present ; but this new spring wood was not taken into

257

Ash-wood with Reference to Water-conductivity.

account in the investigation, and the figures from which the graphs were
drawn refer to the wood developed in the first season only, so that these
graphs can be compared fairly with those given for A 3, A4, and A 6, and
also with those for the Hazel shoots,1 H 7 to H 10. The wood cylinder for the
first year is completely closed in all the sections cut from A 8, and is
particularly wide between the cambium and the pith in internode 6 at the
end of A 8 a.

Fig. 2. The numbers refer to the internodes on each
shoot respectively.

Fig. 3. The numbers refer to inter-
nodes, reckoned from the base of the
shoot.

The water-conducting elements in Ash-wood are all vessels ; there are
no tracheides. The vessels are scattered among wood fibres, and are
especially associated with wood parenchyma in vertical strands, the latter
being most abundant near the autumnal limit of the cylinder.

The wood is crossed by numerous medullary rays, one or two cells
wide, and often many cells deep. The vessels are mostly round or elliptical
in transverse section, and have numerous bordered pits in their walls ; they

1 Holmes, M. G. : loc. cit.

258 Holmes.— Observations on the Anatomy of

are easily distinguished by their size and shape from the wood fibres, and by
their walls, which are thicker, pitted, and more completely lignified than
those of the latter. The small vessels near the cambium are very thick-
walled, with a quite circular lumen. Spirally thickened vessels occur in the
protoxylem next to the pith. In longitudinal section the vessels are seen
to consist of short segments communicating by round holes, chiefly in radial
oblique walls ; the segments of the wide vessels may be four or five times

Fig. 4.

as long as they are wide, but are often shorter. The wood is richest in
vessels immediately round the pith, especially in the four groups of primary
xylem corresponding with the opposite and decussate phyllotaxy. In all
except the smallest sections, where the widest vessels occur in these
primary groups, there are wider vessels in the region of the wood just out-
side this part, and they get smaller again towards the periphery, and more
scattered. Apart from the primary bundles, the distribution of the vessels
is very uniform in most of the sections, especially at the lower levels.

Ash-wood with Reference to Water -conductivity.

259

Method.

The data as to the size, proportion, and distribution of the water-con-
ducting elements were obtained in substantially the same manner as that
described for the Hazel.1 In many of the smaller sections it was found
practicable to obtain the total number of the vessels by actual counting in
the whole or a large part of the section.

Fig. 5.

Results.

The figures are presented in graphical form, a set of six curves being
given for each shoot. These lines are lettered to correspond with those given
for the Hazel shoots, and the vertical scales are the same. It has been
found convenient, however, to double the horizontal scale, in which an equal
interval was taken for each internode regardless of its length ; for in the

1 Holmes, M. G. : loe. cit.

260 Holmes . — Observations on the Anatomy of

stool shoots of the Ash the internodes are longer and fewer than in the
Hazel stool shoots, and also each bears two leaves.

The total or absolute conductivity for water is represented, for purposes
of comparison in this inquiry, by the area in square millimetres of all
the vessels in each transverse section of the wood, taken at the middle
points of the selected internodes. This is shown in curve B,and is obtained

Fig. 6.

by calculation from curves F and E ; it depends upon the total area of the
wood, given in curve A, as well as upon its specific quality.

Curve A , giving the variation in area of the wood along each shoot,
shows in general a very regular descent, rather steeper at the base ; this is
especially the case in the larger shoots, in which considerable support is
necessary.

Curve F gives the total number of vessels present in the transverse
section at the different levels in each shoot. It shows a fairly steady decline
from base to apex ; in A 8 b the decline is particularly steep.

o m

26i

Ash-wood with Reference to Water-conductivity .

Curve E gives the average diameter of the vessel cavities in the trans-
verse section of the wood, measured in ju. The figure obtained for each
section depends of course on the proportion of wide to narrow vessels, as
well as on their actual widths. The curve keeps fairly level or may rise
slightly from the base upwards for the greater part of the length of the
shoot, and then falls again towards the apex. Only the fall is seen
in the very small shoot A 8 e. Curve E reaches its highest point in

Fig. 7.

A 6 at internode 10 (the highest calculated figure being 27*85 \i at A 6, 8),
but this of course is only an average value. In all sections narrow as well
as wide vessels are present, but on the whole they are narrower in the
smaller sections, and the rapid decline of the curve towards the apex is due
to the absence of the larger vessels. The highest diameters recorded in
each shoot for a single vessel were as follows :

Shoot No. A 6 A3 A4 A 8 a A8h A8*

Diameter of widest vessels in /x . 80 76 72 46 32 28

262 Holmes. — Observations on the Anatomy of

The vessels formed in the beginning of the second annual ring in A 8 are
much wider than any present in the first ring, as is usual.

Curve B shows the total area of all the vessel cavities in each section,
and represents the absolute water-conductivity. It is obtained by combin-
ing the data from curves F and E, and shows in general a corresponding
decline from the base to the apex of the shoot. It is to be noticed that
both the curves A and B reach a lower point in the terminal internode of
A 6, in which the apical bud is weak, than in that of A 4, in which the bud
is stronger. The higher figures for A3, internode 11, are to be connected
with the presence of two pairs of leaves above this point, instead of one
pair as in A4 and A 6 ; see Fig. 3. The same applies in the case of A8#,
internode 6, as seen in Fig. 1. The values for curves A and B in the smaller
shoots A 8 b and A 8 e are very much lower.

The specific conductivity for water is represented for comparative
purposes by the percentage of the area of the wood occupied by the
cavities of the vessels which it contains, in transverse section. This is
shown in curve C. It depends upon the number of vessels present in a unit
area of the wood as given in curve D, as well as upon their average width
as discussed above for curve E. The figures for curve C are obtained most
easily by combining the data from curves A and B.

Curve D gives the number of vessels per square millimetre of wood for
each section. The numbers vary between 32 and 633 in the four larger
shoots, with a higher range in the others. It will be seen that the curve
rises from the base upwards for each shoot, indicating that the wood is
richer in vessels near the apex, and richer in fibres near the base, where
mechanical support is necessary. The ascent of the curve is especially
rapid near the apex, because of the smaller size of the vessels in this part as
well as their close packing. In this connexion the high values for curve D
in A 8 b and A 8 e are due both to the much smaller proportion of mechanical
elements in these weak shoots, and to the small diameter of the vessels.

Curve C serves as a measure of the specific water-conductivity of the
wood, as explained above, in so far as it can be determined in transverse
section. In general, the curve rises and then falls, the maximum occurring
nearer the apex of the shoot than the base. In other words, up to a certain
point the increase in the number of vessels, ,per unit area, makes the wood
more efficient for water-conduction, its merely strengthening function being
gradually reduced, but when the vessels get very small, the wood becomes
less efficient again, their walls occupying a relatively larger area in propor-
tion to their cavities. The rise and fall are shown in a general way by
a comparison as a whole of the three curves for A 8 ; the figures are low for
A 8 where there is a fairly high proportion of fibres, and fairly low again
for A 8 e, where the vessels are very narrow. The sharp drop in curve C for
the final internode in A 8 b is interesting in view of the failure on the part

Ash-wood with Reference to Water -conductivity . 263

of the buds at the apex of this shoot to develop. It was observed that this
part of the shoot was alive at the resumption of cambial activity in the
spring, for the section showed some development of new elements, though
very slight as compared with that in the lower internodes. The highest
value recorded for curve C was 9-5 per cent, at internode 11 in A 6, while
the maximum for A8 h at internode 4 reached 6*9 per cent. The lowest
value was i*68 per cent, at internode 2 in A3. The percentage of ‘ conduct-
ing area ’, curve C, is lower at the base of A 3 than at the base of A 4, while
the total ‘ conducting area ’, curve B, is about the same ; this is because the
larger area of wood in A3, internode 2, contains a higher proportion of fibres.

Comparison with the re suits obtained for Hazel. There is a general
resemblance between Ash and Hazel in the figures obtained for their stool
shoots. The forms of the curves are similar, showing on the whole a decline
in absolute conductivity with a rise in specific conductivity from the base
of the shoot towards its apex, the latter falling again near the end.

The actual values for specific conductivity, curve C, however, are much
lower for Ash than for Hazel, taken as a whole, the limits of variation for
the shoots examined being as follows :

Plant. Ash. ' Hazel.

Range of values for curve C i*68 to 9-5 per cent. 3*21 to 20*26 per cent.

This is in agreement with the results obtained by Professor Farmer,1
for the two kinds of wood in question, by his experimental method of
determining specific conductivity. His figures are quoted below :

Stool Shoots of Ash. Hazel.

Normal range of specific conductivity 14+10 31+9

Thus in both cases the figures obtained for Hazel-wood are about
double those obtained for Ash-wood. In order to account anatomically for
this difference we may compare the diameters of the water-conducting
elements and their distribution, as shown in the present investigation. For
the shoots examined the ranges of variation for the average and the actual
diameters are as follows :

Stool Shoots of Ash. Hazel .

Range of values for curve E in p 27-85 to 10*14 23*27 to 4-9

Rang~ of actual diameters in /x 80 to 3 48 to 2

It is evident that, on the whole, the water-conducting elements are
wider in Ash than in Hazel, so that the reason for the lower specific con-
ductivity in Ash does not find its explanation in this feature. Turning to
the distribution of these elements, the ranges of variation for the shoots
examined are as follows :

Stool Shoots of Ash. Hazel.

Range of values for curve D 32 to 633 115 to 4,000

1 Farmer, J. B. : On the Quantitative Differences in the Water-conductivity of the Wood in
Trees and Shrubs, Parts I and II. Proc. Roy. Soc., B., vol. xc, 1918.

U

264 Holmes. — Observations on the Anatomy of Ash-wood.

Thus on the whole Hazel-wood has a greater number of water-conducting
elements per square millimetre than Ash-wood, which more than compen-
sates for the smaller diameter of these elements and their greater resistance
to the flow of water on this account. The relatively low specific con-
ductivity of Ash-wood must be attributed to its relative poverty in vessels.
It is to be understood that these observations apply to wood of the first
year only, and that a still greater range of variation might, and probably
would, be found for some of the characters — for instance, in those forming
the basis of curve E — by examining a larger number of examples ; but I am
inclined to think that the general range for specific conductivity would not
be altered materially, and that the relation between Ash- and Hazel-wood
in this respect would remain as indicated above.

Summary.

The results obtained from a quantitative investigation of the constitu-
tion of Ash-wood in young shoots, with special reference to vessel content,
have been discussed, and compared with similar data previously obtained
for Hazel-wood. It is shown that on the whole there is a fall in absolute
water-conductivity and a rise in specific conductivity from the base of
a shoot to its apex, in both kinds of wood examined, and that, in general,
the figures for specific conductivity are lower in Ash than in Hazel. In the
latter the water-conducting elements are more numerous than in the former,
though on the whole they are not so wide.

My thanks are due to Professor Parmer, of the Imperial College,
South Kensington, for his suggestion of this work and his help in carrying
it out, and to Professor Potter, of Armstrong College, Newcastle-on-Tyne,
where part of the work was undertaken.

NOTE,

NOTE ON THE DURATION OF THE PROTHALLIA OF LASTRAEA
FILIX-MAS, PRESL. — I venture to record here some observations on prothallia of
Lastraea Filix-mas , which seem to indicate a greater vitality and more prolonged
duration than have been generally attributed to prothallia.

In August, 1912, 1 desired to obtain some early stages of fern prothallia for class
purposes. To this end, I used a tank with a glass front, and covered the bottom with
pieces of coke partly immersed in water. On these were laid some mature fronds of
Lastraea , and the top covered over with slate slabs. The conditions for germination seem
to have been successfully met, and by early October the pieces of coke were covered by
myriads of prothallia in all the early stages of development.

These were in due course used for demonstration purposes, and the tank
dismantled. I retained, however, two or three pieces of the coke, and placed them in
a glass basin with water, and covered the top with a glass plate. The basin was then
placed on a shelf in the laboratory and for some time forgotten.

It was not until March, 1914, after an interval of about twenty months from the
sowing of the spores, that I remembered about these prothallia, and re-examined them.
Fortunately the water had not dried up, thanks to the circumstance that the edge of the
basin was ground, and the covering plate fitted fairly closely.

The appearance then presented by the contents of the basin was so remarkable,
that at the first glance I supposed that the crop of prothallia had been succeeded by
a crop of moss. For in the feeble illumination of the shelf, each prothallium had
grown vertically upwards, covering the flanks of the coke lumps as thickly as they
could stand, and resembling miniature forests on the sloping surfaces. The average
height was about 15 millimetres, and the breadth from 1 millimetre to i-|. From the
surface turned away from the light (invariably the morphologically under surface) in-
numerable rhizoids attached the vertical prothallia like guy-ropes to the surface of the
coke, and the edges bristled with the characteristic mucilage cells. While the prothallia
were light green through the greater part of their length, the bases were brown through
the death of the cells. I could find no fungi, however, on the decadent portion.

On microscopic examination, I could find no trace of archegonia on any of these
depauperated prothallia, but the whole of the under surface was studded over with
antheridia, to the number of many hundreds on each. Near the apex were immature
antheridia, then farther back antheridia which released the antherozoids on access
of water, and in the older parts antheridia which had dehisced. I calculated that upon
the one prothallium on which I attempted a count, there must have been from 700 to
1,000 antheridia from base to apex.

I now transplanted some of these prothallia, laying them flat with the under surface
downwards, on suitable soil in an earthenware saucer, and placed them under a bell-

[Annals of Botany, Vol. XXXIII. No. CXXX. April, 1919.]

266

Note.

jar on a window ledge. They gradually established themselves, growing forward
quite normally, broadening, and deepening the colour as they grew. By July, young
plants began to appear, which showed their second leaf in August. I then made
a second transplantation with a similar result.

The original stock in the glass basin was replaced in its old situation on the shelf
in order to discover how long the prothallia could retain their vitality under these
conditions.

I am now able to state that some of these prothallia have remained alive through
the years 1915-16-17 into the current year, that is, for nearly six years from the sowing
of the spores. They have gradually languished, however, and many have died off
altogether, but even last spring I found young antheridia immediately behind the
apices of the surviving prothallia. I was not able to make a successful transplantation
from the stock this year, and at the time of writing. all the green apices have
disappeared.

The points which seem to me from these observations worth record are (1) the
narrowing of the prothallus and the assumption of the vertical habit in the feeble
illumination, (2) the rigid maintenance of the morphological dorsiventrality in this
condition, (3) the recovery of the capacity to produce archegonia on transplantation
to more suitable conditions, (4) the great tenacity of life under unfavourable conditions,
and (5) the comparative immunity from fungal attack.

R. W. PHILLIPS.

University College of North Wales, Bangor.
September , 1918.

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CONTENTS.

PAGE

WILLIS, J. C. — The Floras of the Outlying Islands of New Zealand and their Distribution.

With two Maps and twenty-one Tables in the Text 267

Carter, N. — Studies on the Chloroplasts of Desmids. II. With Plates XIX and XX

and one Figure in the Text . ■ , . • • . 295

Dey, P. K. — Studies in the Physiology of Parasitism. V. Infection by Colletotrichum

Lindemuthianum. With Plate XXI 305

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Cleland, Ralph E.— The Cytology and Life-history of Nemalion multifidum, A g. With

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WORMALD, H.— The ‘Brown Rot’ Diseases of Fruit Trees, with Special Reference to two

Biologic Forms of Monilia cinerea, Bon. I. With Plates XXV and XXVI . . 361

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The Floras of the Outlying Islands of New Zealand
and their Distribution.

/Jr1"1811

BY

AUC:

J. C. WILLIS, M.A., Sc.D., F.R.S.,

European Correspondent of the Botanic Garden , Rio de Janeiro.

With two Maps and twenty-one Tables in the Text.

IN this paper I shall deal chiefly with the smaller islands that lie at some
distance from New Zealand, but on the same submarine plateau,
especially with the Kermadecs, Chathams, and Aucklands, following up
the work on the taxonomic distribution of the New Zealand flora given in
a series of preceding papers (6 to 11). In one of these (8) I have already shown
that one may prophesy, with the
aid of age and area, that the plants
that reach these islands will on the
whole be the oldest, and therefore
the most widespread, in New Zea-
land, and find, on examination of
the facts, that the prophecy is com-
pletely borne out.

My authority for the floras
continues to be in the main Cheese-
man’s New Zealand Flora (2), sup-
plemented by his later lists in
Chilton’s * Subantarctic Islands ’ (3),
and by Cockayne’s lists (4). As
I have already pointed out, the
detailed completion of a flora
makes but slight differences in the
final result. This was very strikingly shown in the additions to the
Ceylon flora made in a short paper subsequently published (13), and in
those to the flora of Stewart Island given in the appendix to my last
paper (11). In neither instance was any serious difference made by the
addition in the one case of no, in the other of 71, further species. By

[Annals of Botany, Vol. XXXIII. No. CXXXI. July, 1919.]

X

New Zealand and outlying islands. The dotted
line is the 1,000 fathom limit.

268

Willis. — The Floras of the Outlying Islands of

keeping to the larger floras and papers it must not be forgotten that I gain
the very considerable advantage of dealing with a flora worked up by one
or by a few persons, and consequently one which is fairly uniformly treated
in its conception of specific forms, &c.

The second map-diagram of my last paper, reproduced here, represents
an imaginary distribution of the plants of the northern and southern invasions
of New Zealand already dealt with, and supposed, for the sake of simplicity,
to centre in Auckland (city) and Dunedin. A very brief consideration of
it shows that while on the whole the plants of Stewart Island will be older
in New Zealand itself than the general average of the plants of New
Zealand, those of the outlying islands will be on the whole at least as old,

and in most cases probably
older, as they would have to
start very early from New Zea-
land to reach the islands be-
fore they were cut off. The
Kermadecs and Aucklands,
however, having been to some
extent in the track of invasions,
may of course contain species
which arrived there too late to
reach New Zealand at all, or
only just reached it at the last
minute before it was cut off.
The Chathams, on the other
hand, must clearly have re-
ceived all, or nearly all, their
flora by way of New Zealand ;
no invasion can have passed

New Zealand and inlands to show imaginary distribu- . xr , c

tion from Auckland and Dunedin. that way. We shall start from

this conception of the great
relative age of the floras of the outlying islands as a fundamental fact,
and study the floras of these islands by the method of prediction and
verification, just as was done in the case of Stewart.

One will expect to find that there is what one may perhaps term
a selection list (the Scottish term ‘ short leet ’ exactly expresses it) of the
(in New Zealand) older families, from which Stewart as the nearest island
will select practically all, while the more outlying islands will have fewer
of them. But the families of these islands should be all included in the
Stewart list, unless they be the later arrivals of the northern or southern
invasions, or families which have their maximum development in the centre
of New Zealand, from which it is less distance to the Chathams than to
Stewart.

New Zealand and their Distribution.

269

Now if Natural Selection were the determinant, one would hardly expect,
when one considers the extremely different climatic, geological, and other
conditions of these widely separated islands, that they would, so to speak,
choose their floras from just the same families. One would anticipate
finding considerable differences between them, and that more of the
other important families of New Zealand would occur, or that the islands
would contain relicts belonging to some of the less important families in
New Zealand.

(1) We shall therefore expect to find that the islands have proportionately
more in common with Stewart in the matter of families than with New
Zealand proper.

Table I.

Occurring in Aucklands. C hat ha ms. Kermadecs.

32

35%

53%

4S

4i

>2 %
68%

40%

46% \

of 91 New Zeal. fams.
of 60 Stewart fams.

Thus all the islands, even the Kermadecs, contain a considerably
higher percentage of Stewart families than they do of New Zealand families.
All the Auckland families occur in Stewart, 41 out of 48. or 85 per cent.,
of the Chatham families, and even 28 out of 37, or 75 per cent., of the
Kermadec families.

(2) We shall expect to find that a large part of the families in the different
islands are the same, and that most of them are selected from the Stewart
list. The following table gives, in ordinary type, the 60 Stewart families,
with the islands in which they occur. Those not occurring in Stewart are
printed in capitals.

Table II.

Fam.

Spp. in Stewart
Island.

Fam.

Spp. in Stewar ,
Island.

Ranunculaceae

10

A C

Droseraceae

4

A

Magnoliaceae

1

—

Haloragidaceae

13

A

C K

Cruciferae

3

A C K

Myrtaceae

4

A

C K

Violaceae

6

C K

Onagraceae

L3

A

C

Pittosporaceae

1

Iv

Cucurbitaceae

—

K

Caryophyllaceae

4

A C

Ficoideae

3

C K

Portulacaceae

2

A

Um belli ferae

T4

A

C-K

Elatinacene

1

—

Araliaceae

7

A

C K

Ilypericaceae

1

—

Cornaceae

1

C

Malvaceae

2

C

Rubiaceae

J7

A

C K

Linaceae

1

c

Compositae

54

A

C K

Tiliaceae

4

—

Stylidiaceae

4

A

Geraniaceae

4

A C K

Goodeniaceae

1

K

Rutaceae

K

Campanulaceae

3

A

C 1C

Rhamnaceae

—

C

Ericaceae

2

—

Anacardiaceae

— -

C K

Epacridaceae

10

A

c

Coriariaceae

2

C K

Primulaceae

1

A

C K

Leguminosae

—

C IC

Myrsinaceae

4

A

C K

Rosaceae

7

A C K

<» Apocynaceae

1

—

Saxifragaceae

g

—

Loganiaceae

1

—

Crassulaceae

2

A C

Gentianaceae

X 2

4

A

c

270

Willis. — The Floras of the Outlying Islands of

Table II ( continued ).

Fain.

Spp. in Stewart

Fam.

Spp. in Stewart

Island.

Island.

Boraginaceae

3

A C

Loranthaceae

\

Convolvulaceae

3

C K

Euphorbiaceae

1

C IC

Solanaceae

C K

Urticaceae

1

A C K

Scrophulariaceae

13

A C IC

Orchidaceae

21

A C IC

Myoporaceae

C IC

Iridaceae

2

C

Lentibulariaceae

1

—

Liliaceae

12

A C K

Labiatae

1

c

Juncaceae

8

A C

Plantaginaceae

3

A

Palmae

—

C K

Ulecebraceae

1

—

Typhaceae

—

IC

Chenopodiaceae

2

C K

Naiadaceae

4

C

Polygon aceae

3

A C IC

Centrolepidaceae 2

A

Piperaceae

C K

Restionaceae

2

C

Chloranthaceae

1

K

Cyperaceae

44

A C K

Thymelaeaceae

3

C

Gramineae

35

A C IC

Thus of the

60 Stewart families, 49 (or 81 per

cent.) occur in

other islands, while of the 31 families that occur in New Zealand and
do not occur in Stewart, only 10 (or 32 per cent.) occur in the islands.
Of these 10, Rutaceae, Rhamnaceae, Anacardiaceae, Cucurbitaceae, Myo-
poraceae, Piperaceae, Palmae, and Typhaceae, are enumerated in the
list of the northern invasion given on p. 356 of 10, and Solanaceae is
given as probably belonging to that invasion, so that only Leguminosae
remains. This is represented in the Kermadecs by Canavalia , a genus
that does not occur in New Zealand, and in the Chathams by Sophora
tetraptera , a species which should in all probability be found on Stewart.

It is thus clear that the prophecy made above is borne out by the
facts. A mere glance at the table suffices to show how many of the families
occur in two or more groups of islands, and we have seen that most of them
also occur in Stewart.

(3) As we have already seen, in dealing with Stewart Island, the
largest families (in a given country) will on the whole be the oldest (in
that country). We may therefore predict that the families that reach all
three groups of islands will on the whole be the largest, both in New
Zealand as a whole, and in Stewart. Those reaching two groups will be
next in size, and then will follow those reaching only one, and those reaching
none. An examination of the facts gives us

Table III.

Reaching ' The families contain (in New Zealand as a whole),

3 islands. 221, 119, 113, 113, 6r, 57, 47, 22, 22, 20, 19, 17, 17, || 11, 11, 9, 8, 8, 1.

3 » 5°j 3L 31, 26, 25, 25, 20, 17, || 15, 12, 10, 10, 5, 4, 3, 3, 2, 2, 1 , 1.

1 island. 19, || 15, 13, 7, 7, 7, 6, 6, 5, 5, 3, 3, 3, 3, 2,. 2, 2, 2, r, 1.

No islands. || 10, 8, 6, 6, 6, 6, 4, 4, 4, 4. 3, 3, 2, 2, 2, 2, 2, 2, 2, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1.

The mark || is placed at the position of the average size of family in New Zealand (15-2 species).

A similar comparison for Stewart Island shows that the size of the
families in that island, according to the number of groups they reach, is :

New Zealand and their Distribution . 271

Table IV.

Reaching She of Families in Stewart Island.1

3 islands. 54, 38, 30, 21, 17, 14, 13, 13, 13, 10, 7, 7, || 4, 4, 3, 3, 3, 1, 1.

2 „ 12, 10, 10, 8, || 6, 4, 4, 3, 3, 3, 2, 2, 2, 1.

1 island. |) 4, 4, 4, 3, 3, 2, 2, 2, 2, 2, 1, 1, 1, 1, 1, 1.

No islands. || 4, 3, 2, 1, r, 1, 1, 1, 1, 1, 1.

A mere glance at these figures is enough to show that the prophecy
is borne out by the facts ; but we may put it in tabular form thus :

Table V.

New Zealand Families. Stewart Families .l

Reaching

Fams.

spp.

Average size ,

Fams.

spp.

Average size.

3 islands

*9

896

47.1

19

256

I3’4

2 ,,

20

293

14.6

14

70

5-°

1 island

20

112

5.6

16

34

2.1

No island

32

91

2.8

11

l7

i-5

(4) Just as we predicted in the case of Stewart that the New Zealand
families omitted would be on the whole the smallest, so here we may
predict that the missing Stewart families will on the whole be the smallest,
a prophecy which is clearly borne out by the facts in Tables IV and V.

(5) One will expect the Aucklands to contain many of the families
of the southern invasion — they contain all but Naiadaceae. One will
expect the Chathams also to contain many.’ and on the whole to lack the
smaller ones. The smallest, those with less than 1 1 species, are Portula-
caceae, Droseraceae, Stylidiaceae, Plantaginaceae, and Centrolepidaceae,
and it is exactly these which are missing in the Chathams. The bulk of
the invasion, if not all of it, is missing in the Kermadecs.

(6) One will expect the Chathams to contain many of the families of
the northern invasion, and perhaps the Kermadecs also, but, as we have
already seen (10, p. 358), they do not seem to have lain in the track of
the main invasion. Examination of the facts shows that the Chathams
contain only 9 of the 33 families, and the Kermadecs 11, while Stewart
itself only contains 8 and the Aucklands 3. It is thus evident that old
though it was, the northern invasion did not in general get very far south.
This may have been due to the species reaching their climatic boundary,
in some cases at any rate, though my experience of the surprising degree
of cold which many ‘ tropical * species bear in southern Brazil, and the fact
that so many tropical species go very far south in New Zealand, makes
me hesitate to say that a species has reached its climatic limit. Given
slow enough progress, a species may travel into climates to which it would
seem quite unsuitable.

1 Note the much greater proportion of the Stewart families reaching islands, even three islands.
The Stewart families are on the whole older.

272 Willis . — The Floras of the Outlying Islands of

(7) One may also predict that the outlying islands will have pro-
portionately many more families in common with one another than they
have with New Zealand.

Table VI.

Ke>

•madecs.

Chathams.

Aucklands .

Aew

Zealand.

Kermadecs in common with

—

3i

64%

19

59 %

37

40%

Chathams ,, ,, ,,

3i

83%

27

84%

48

52%

Aucklands ,, ,, ,,

19

5i%

27

56%

32

35%

Even the Aucklands have a greater proportion in common with the
Kermadecs than any of the islands but the Chathams have with New
Zealand.

(8) We may now go on to deal in the same way with the genera, and
may begin by predicting that they will be chiefly selected from the list of
genera found in Stewart Island. The result of testing this prediction is
given in the following table, which gives the Stewart list, with the number
of species in Stewart, and the islands in which the genera are found. The
genera that occur in the islands and New Zealand and have not been found
in Stewart are printed in capitals.

Table VII.

Clematis

1

—

Tillaea

2 A C

Ranunculus

8

A

C

Drosera

4 A

Caltha

1

—

Ilaloragis

4 A K

Drimys

1

—

40

Myriophyllum

4 —

Cardaminc

1

A

C Iv

Gunnera

4 C

Lepidium

2

A

C

Callitriche

1 A C K

Viola

2

C

Leptospermum

1 C

Melicytus

2

K

Metrosideros

2 A K

Hymenanthera

2

Myrtus

1 —

Pittosporum

1

K

Epilobium

11 A C

Stellaria

1

A

C

Fuchsia

1 A

Colobanthus

2

A

c

Sicyos

— K

Spergularia

1

—

Mesembryanthemum

1 C K

Claytonia

1

—

5°

Tetragon i a

2 C K

Montia

1

A

Iiydrocotyle

5 C K

Elatine

1

—

Azorella

1 A

Hypericum

1

—

Actinotus

1

Plagianthus

2

c

Apium

1 A K

Aristotelia

3

—

Oreomyrrhis

1 C

Elaeocarpus

1

—

Crantzia

1 C

Linum

1

c

Aciphylla

1 C

Geranium

3

A

C K

Ligusticum

3 A

Pelargonium

1

C

Daucus

— C

Oxalis

—

K

60

Aralia

1 —

Melicope

—

K

Panax

4 A K

POMADERRIS

—

C

Schefflera

1 —

CORYNOCARPUS

—

C K

Pseudopanax

1 C

Coriaria

2

C K

COROKIA

C

SOPHORA

—

C

Griselinia

x

Rubus

* 3

—

Coprosma

13 A C K

Geum

1

A

Nertera

3 A

Potentilla

1

C

Asperula

1 —

Acaena

2

A

C IC

Lagenophora

2 A C K

Donatia

1

—

70

Brachycome

2 —

Carpodetus

1

—

Olearia

SAC

Weinmannia

1

—

Celmisia

7 A

New Zealand and their Distribution . 273

Table VII [continued).

Gnaphalium

4

A C K

Pari et aria

—

1C

Raoulia

3

—

Dendrobium

1

—

Helichrysum

4

A C

Earina

2

c

Cassinia

2

A

Sarcochilus

1

c

Clasped ia

1

—

Thelymitra

2

A C

SlEGESBECKIA

—

K

140 Microtis

1

C IC

Bidens

—

IC

Prasophyllum

1

A

80

Cotula

4

A C IC

Pterostylis

3

C

Abrotanella

2

A

Acianthus

C IC

Erechtites

6

A C

Lyperanthus

1

A

Senecio

6

C K

Caladenia

.2

A C

Microseris

1

—

Chiloglottis

1

A C

Taraxacum

1

—

Corysanthes

5

A C

Sonchus

2

A C K

Gastrodia

1

C

Phyllachne

2

A

Libertia

2

C

Oreostylidium

1

—

150 Rhipogonum

1

c

Forstera

1

•' ■ — •

Enargea

1

—

90

Selliera

1

—

Cordyline

1

1C

Pratia

1

A C

Astelia

3

a e

Lobelia

d ~

C IC

Phormium

2

c

Wahlenbergia

2

C IC

Bulbinella

2

A

Gaultheria

2

—

Arthropodium

1

—

Pentachondra

1

—

Herpolirion

1

— '

Cyathodes

2

A C

Rostkovia

—

A

Leucopogon

1

C

J uncus

7

A C

Archeria

1

—

160 Ltizula

1

A C

Dracophyllum

5

A C

Rhopalostylis

—

C IC

IOO

Samolus

1

A C IC

Typha

—

K

Myrsine

4

A C IC

Triglochin

r

C

Parsonsia

1

—

Potamogeton

2

—

Mitrasacme

1

—

Zostera

i

—

Gentiana

3

A C

Centrolepis

1

—

Liparophyllum

1

—

Gaimardia

1

A

Myosotis

3

AC

Lepyrodia

—

e

Ipomoea

—

1C

Leptocarpus

1

—

Calystegia

2

C IC

170 Hypolaena

1

Dichondra

1

C

Eleocharis

3

C

I 10

SOLANUM

C IC

Scirpus

7

A C IC

Glossostigma

1

—

Carpha

1

A

Veronica

5

A C IC

Schoenus

3

C

Ourisia

5

—

Cladium

3

C

Euphrasia

2

—

Gahnia

1

—

Utricularia

1

—

Oreobolus

2

A

Myoporum

—

C IC

Uncinia

9

A C

Mentha

1

c

Carex

15

A C IC

Plantago

3

A

1 80 Ehrharta

Scleranthus

1

—

Microlaena

2

A

120

Rhagodia

—

1C

Agrostis

1

A

Chenopodium

1

—

Hierochloe

2

A C

Atriplex

1

c

Oplismenus

—

IC

Salicornia

—

c

Deyeuxia

5

A C IC

Polygonum

—

c

Dichelachne

1

C

Rumex

1

A C IC

Deschampsia

2

A C

Muehlenbeckia

2

C

Trisetum

1

A C

Piper

—

C K

Danthonia

6

A C

Peperomia

—

K

1 90 Arundo

1

C

Ascarina

1

IC

Agropyrum

1

K

130

Pimelea

1

C

Poa

8

A C 1C

Drapetes

2

Atropis

1

A

Loranthus

1

—

Asprella

1

■ 44

Euphorbia

1

c

Festuca

2

C

Urtica

1

A C

Thus we find, on summing up, that while New Zealand as a whole
has 329 genera, of which 169 occur in Stewart and 160 do not, 114 of the

274 Willis. — The Floras of the Chet lying Islands of

former, or 67 per cent., occur in the islands, while of the latter only 26
(the genera in capitals) occur, or 17 per cent., an enormous difference. The
prophecy made above is thus fully borne out by the facts.

Further, of the 26, it occur only in New Zealand and the Kermadecs,
7 in the Chathams, 7 in both Kermadecs and Chathams, and one only
(Rostkovia) in the Aucklands and the South Island of New Zealand.
This was probably a late arrival of the southern invasion. 15 of the
26 genera belong to families enumerated in the northern invasion (10,
p. 35b), and all but Rostkovia are distinctly northern types, most of which
probably took part in the northern invasions.

(9) Just as with the families, we may predict that those genera will
on the whole be the largest in number of species, whether in New Zealand
as a whole, or in Stewart Island, which reach three of the outlying groups
of islands. Then will follow those reaching two islands, one island, and
no islands at all. Testing this we find :

Table VIII.

Reaching

Gen.

Spp. in Stewart.

Average.

Spp. in N.Z.

Average.

Stewart and 3 groups

17

78

4*5

293

17.2

>> 2 >j

39

132

3*3

396

IO-I

„ „ 1 group

58

99

i-7

294

5.0

)> » no „

55

74

i-3

162

2.9

Neither Stewart nor other

islands

J33

204

i*5

Other islands, but not

Stewart

27

43

i*5

(10) Just as with the families, one may predict that the islands will
have proportionately more genera in common with one another than they
have with New Zealand.

Table IX.

Kermadecs.

Chatha?ns.

Aucklands.

New Zealand.

Kermadecs in common with

—

32

21

62 )

*

32%

30%

*9% i

Chathams „ ,, „

32

—

44

98 \

5i%

64%

29% 1

Aucklands ,, ,, ,,

21

44

■ —

68 J

33%

44%

20%

Again the facts bear out the prophecy.

(11) One may predict that the genera which occur in Stewart and do
not occur in the islands will on the whole be the smaller genera of Stewart.
The average number of species in a genus in Stewart is 2*2, and of the
55 genera that do not occur in the islands 44 have one species in Stewart
Island, six have 2, and the others 3, 3, 3, 4, and 5, or an average of 1-3
species per genus.

(12) We may now go on to the actual species, and predict that these
will also be largely selected from the Stewart list. It would occupy too

New Zealand and their Distribution . 275

much space to give the whole list over again (cf. 11, p. 27), but of the 382
species so far recorded from Stewart, no fewer than 153, or 40 per cent., are
found in the islands, whereas of the 1,301 species found in New Zealand as
a whole, only 199 occur on the islands, or 15 per cent. Thus there are only
46 species bn the islands, other than local endemics or species which do not
occur at all in New Zealand, which do not occur in Stewart, against 153
which do.

(13) We may predict that the families which occur in Stewart but
have no species on the islands will on the whole be small (in Stewart).
The average size of a family in Stewart is 6*3 species, and those families
that contain no species on the islands contain in Stewart 4, 3, 2, 1, 1, 1, i, 1,
1, 1, 1 species, or all below the average size in Stewart.

(14) We may also predict in this connexion that the islands will have
very many species in common between themselves, and this also proves to
be the case. The Kermadecs have a total flora of 71, of which 19 occur
nowhere else, leaving 52, of which 30 occur in the Chathams and 5 in the
Aucklands. The Chathams have a total flora of 152, of which 27 occur
nowhere else, leaving 125, of which 30 occur in the Kermadecs, and 32 in
the Aucklands. The Aucklands have a total flora of 119, of which 44 do
not occur in New Zealand, leaving 75, of which 32 occur in the Chathams
and 5 in the Kermadecs.

(15) We may predict that the species in common between the islands,
or between the islands and Stewart, will show a greater proportion of wides
(which on the whole are older than endemics), the more the islands on which
the species occur.

Table X.

Wides.

Proportion.

Endemics.

Proportion.

3 islands and Stewart

4

80%

1

20 /

2 >> »

27

64%

55

36%

1 >5 J5 >>

43

4i %

61

59%

No „ but „

57

24 %

174

76%

Not even reaching Stewart

170

18%

749

82 %

The proportions decrease and increase, respectively, with regularity.

(16) We may now go on to some slightly more general predictions,
and say that as on the whole the islands were probably cut off earlier than
Stewart, their plants will on the whole be older, and should therefore show
a greater proportion of families to genera and genera to species.

Table

XI.

Families.

Genera.

Gen. per fam.

Species.

Spp. per gen.

Islands

55

130

2-3

199

i*5

Stewart

60

169

2.8

382

2.2

New Zealand

9i

329

3-6

1392

4.2

(17) We may make the same prediction with regard to the islands as
the second made with respect to Stewart on p. 34 of 11, that on the whole

276 Willis. — The Floras of the Outlying Islands of

the more genera in a family the older the family will be, and therefore the

better represented.

Table XII.

Fam. repres. in N.Z. by

In N.Z.

In Stewart.

In islands.

Not there.

1 genus

36

16

15

4i %

21

2 genera

15

7

10

66%

5

3 > >

L5

13

10

66%

5

4-5 33

10

10

10

100%

—

6-10 „

9

8

8

90%

1

over 10 „

6

6

6

100 %

—

(18) Similarly we

may repeat the prediction

(3)

on the

same page, and

say that the same thing will be true with regard to the genera. This also
proves to be the case, the proportions of genera that occur being 21, 35, 583
55, 66, 68, and 80 per cent., a progressive table, save for the one slight drop
from 58 to 55 in the middle.

(19) We may go on to predict that the plants reaching 3 groups of
islands, New Zealand, and Stewart, 2 groups, 1 group, Stewart only, and
the main islands of New Zealand only, should show a progressive decrease
in the average size of families and genera.

Table XIII.

Reaching Aver, size of fain. Aver, size of genus.

3 islands

88

6 1

2 33

42

13

1 3,

29

7.8

Stewart only

18.5

6-8

N.Z. as a whole

15

4.2

N.Z. only

2.9

i*5

(20) All the predictions we have made with regard to the flowering
plants should also hold in the case of the ferns, and a very cursory exami-
nation shows that they do, so that it would be a work of supererogation to
go into details ; but we may predict that as the ferns are on the whole an
older group than the flowering plants, those of the flora of Stewart will be

* on the whole better represented. Examination shows that no less than
64 per cent, of the ferns of Stewart are represented on the islands, against
only 40 per cent, of the species of flowering plants.

There are other predictions that might be made with regard to
families, genera, and species, but we must go on to other more general
features, and may begin with the species endemic to the islands only, which
are fairly numerous.

(21) Upon the hypothesis of Natural Selection one might expect that
some of these endemics at any rate would be relicts. If this were so, one
might surely expect to find some of them occurring upon two of the groups
of islands and not in New Zealand ; they might have spread to these

1 Only 5 genera with 30 species, too small a number for a reliable result.

New Zealand and their Distribution.

2 77

islands in early times, and have since been killed out in the more crowded
main islands of New Zealand. But in actual fact we find that there arc
none with such a distribution ; all that occur in the Kermadecs and
Chathams, or Chathams and Aucklands, occur also in New Zealand, as
would be expected on the hypothesis of age and area. There are a good
many which occur in the Aucklands and some of the other islands in the
same stretch of sea (Campbells, Antipodes, and Macquarie), but none that
occur in two of the main groups of islands and not also in New Zealand.

(22) One will expect the endemics to belong on the whole to the
oldest, i.e. in general to the largest, families and genera in New Zealand.
They belong in fact to Ranunculaceae, Caryophyllaceae, Geraniaceae,
Rosaceae, Umbelliferae, Cornaceae, Rubiaceae, Compositae, Epacridaceae,
Myrsinaceae, Gentianaceae, Boraginaceae, Scrophulariaceae, Plantaginaceae,
Chloranthaceae, Urticaceae, Liliaceae, Juncaceae, Palmae, Cyperaceae, and
Gramineae, 21 families, which contain in New Zealand and the islands as
a whole 939 species, or 44 species per family, whilst no endemics occur
in the other 70 families of the New Zealand flora, with 453 species (average
6*4 per family), except in the genera Scaevola , Homalanthus , and BoeJi-
meria , which occur in the Kermadecs, but not in New Zealand.

Grouping all the families of New Zealand in order of size, we find that
52 endemics occur in 8 of the first 10 families, 10 in 5 of the second 10, and
3 in the other 2 families which are above the average size, or 65 endemics
in all in families which are above the average in size, whilst 8 only occur in
all the 68 other families which are below the average in point of size.

In the same way, 6o#endemics belong to 25 genera which are above the
average, and 13 to 11 genera which are below it.

(23) Being, on our supposition, very old genera, all the genera which
contain endemics confined to the islands, unless possibly some of the later
ones of the invasions, should occur in Stewart. Three genera occur in the
Kermadecs only, and are not found in New Zealand, so that they may be
looked upon as genera which arrived in those islands from the north too
late to reach New Zealand, and three are endemic genera of the islands.
All the remaining genera, except Corokia and Rostkovia , that contain
island endemics, occur in Stewart. Corokia is a distinctly northern type,
and the endemic occurs in the Chathams ; Rostkovia probably a late
arriving southern type, whose endemic occurs in Campbell.

It is thus clear that, just as in Stewart Island, the endemics of the
islands belong chiefly to the ‘ successful ’ families and genera of New Zealand.
The families are given above, and the actual genera are Ranunculus
(4 endemics), Stellaria. Colobanthus, Geranium , Geum , Azorella , Aciphylla
(2), Ligusticum (3), STILBOCARPA, Pseudopauax, Corokia , Coprosma (4),
Olearia (4), PLE UROPHYLL UM (3), Celmisia (2), Cotida (3), Abrotanella
(2), Senecio (2), Sonchus , Cyathodes, Dracophyllum, My r sine (3), Gentiana (5;,

278 Willis . — The Floras of the Outlying Islands of

MYOSOTIDIUM , Veronica (4), Plantago , A scar in a, Urtica , Bulbinella ,
Rostkovia , Carex (2), Imperata , Hierochloe , Deschampsia (2), Poa (7), Festuca
(2). Those which have no number against them are represented by one
species only, and those in capitals are endemic genera of the islands only.
No one can look over this list of genera, and honestly suggest that it
represents a set of relicts. Many are genera of world-wide distribution,
and all are common, except the three endemic genera, with 5 species, which
represent most of the species which might perhaps be looked upon as
relicts.

(24) We have seen (10, pp. 358, 361) that the northern invasion of New •
Zealand was nearly all tree-like, the southern herbaceous. We shall there-
fore expect the proportion of trees to be greatest in the endemics of the
northern islands, of herbs greatest in the southern. In actual fact, the
Kermadecs have 7 endemic shrubs and trees and 2 herbs (both Mono-
cotyledons), the Chathams have 13 shrubs and trees and 12 herbs (4 Mono-
cotyledons), and the Aucklands 3 shrubs and trees only against 27 herbs
(7 Monocotyledons), whilst in the Campbells there are 3 shrubs, in the
Antipodes 1, and in Macquarie none. This bears out the prophecy com-
pletely, and it may also be pointed out that the three endemic genera of the
islands are composed entirely of herbs ( Stilbocarpa , Pleurophyllum , Myo-
sotidiu7fi)} a fact which does not harmonize well with Prof. Sinnott’s suggestion
that endemics are relicts and herbs the youngest forms.

It is clear, from the success of the 24 predictions above given, that, just
as in the case of Stewart Island, it is hardly conceivable that the out-
lying islands should have received their floras by casual transport across
the intervening seas. There must have been connexion by land at some
time. When one works out their species one by one, it is fairly clear that
a few — at most hardly exceeding, if they even equal, 10 per cent. — may
have been carried by water or by birds, but the great bulk must undoubtedly
have arrived by land. In no other way could the great similarities between
the islands, or between the islands and Stewart, have come about. No
casual transport could give results like those above, nor would it occur that
the island endemics belonged almost solely to the larger families.

The Kermadec Islands.

We must now go on to consider in brief some of the relations of the
islands to one another, and to New Zealand and its probable invasions of
plants (10, p. 355). Let us begin with the Kermadecs. They have
altogether, according to Cheeseman, a flora of 71 species, made up thus:

Table XIV.

Dicotyledons 31 families 47 genera 56 species

Monocotyledons 6 „ 15 ,, 15 ,,

New Zealand and their Distribution . 279

Of these 62 genera and 71 species, there do not occur in New Zealand
at all, in addition to the local endemics of the islands (belonging to genera
of New Zealand), no less than 8 genera and 8 species, viz. Canavalia obtu-
sifolia (cosmotropical), Ageratum conyzoides (cosmotropical), Scaevola
gracilis (Kermadecs only), Aleurites moluccana (trop. Asia), Homalanthus
polyandrus (Kermadecs only), Boehmeria dealbata (ditto), Panicum san-
guinale (cosmotropical), Cenchmis calyculatus (Polynesia). Besides these
there occur in these islands Metrosideros villosa (Polynesia), Coprosma
petiolata and acutifolia (endemic), Myrsine kermadecensis (ditto), Ipomoea
biloba (cosmotropical), Ascarina lanceolata (endemic), Cor dy line terminalis
(Polynesia, Indomalaya), Rhopalostylis Baueri (Norfolk I.), Imperata
Cheesemanii (endemic), Eleusine indica (trop. Asia), and Poa polyphylla
(endemic), 10 genera in all with 11 species, the genera, but not the species,
occurring in New Zealand.

Now as these species, which do not occur in New Zealand proper, are
either endemic to the Kermadecs, or common to the Kermadecs and Poly-
nesia, it would seem probable that the Kermadec Islands received part of
their flora not by way of New Zealand, but by way of the ridge which runs
north from these islands to Tonga and Fiji, or at any rate from some part
of Polynesia.

Subtracting these from the total of the Kermadec flora leaves only 52
species found there which actually occur in New Zealand, and it is of
interest to trace out their distribution there. Twenty-five belong to Class 1
in order of rarity, ranging New Zealand (including Stewart) from end to end,
and of these no less than 20 reach the Chathams also, and 5 the Aucklands
as well. It may be noted that the 5 which have not been recorded from
the Chathams are Melicytus ramiflorus (tree), Haloragis alata> Tetragonia
expansa , Apium prostratum , and Agropyrum scabrum (herbs). A further
13 belong to Class 2, ranging from North Cape to Foveaux Strait, and of
these only 6 reach the Chathams, a much smaller proportion, corresponding
to the generally lesser age. With regard to these species, 38 in all, it
seems to me almost impossible at present to make any safe deductions as to
whether they reached New Zealand by way of the Kermadecs, or vice versa.

There remain 14 species with less range, all of which range north-
wards to North Cape. Several of these belong to genera which are other-
wise unrepresented in New Zealand, e. g. Piper excelsum (Polynesia, Class 3)
Corynocarpus laevigata (K. and N. Z. only, Class 4), Oplismenus imdulati-
folius (K. and N.Z. only, Class 4), Sicyos angulata (Polynesia, Class 5).
Acianthns Sinclairii (K. and N. Z. only, genus New Caled., Class 5),
Rhagodia nutans (Australia, Class 6), Siegesbeckia orientalis and Bidens
pilosa (palaeotropical, Class 7), Peperomia Endlicheri (Lord Howe Island,
Norfolk Island, Class 7). These species it would seem justifiable to regard as
having entered New Zealand by way of the Kermadecs.

28o

Willis .- — The Floras of the Outlying Islands of

There remains one species in Class 9, Ipomoea palmata , which ranges
about 80 miles from North Cape. The only other species of Ipomoea in
this region, /. biloba , occurs only in the Kermadecs. It is fairly clear from
the very short range that I. palmata probably did not reach New Zealand
from the Kermadecs by land. It is more probable that it has only com-
paratively lately, so to speak, arrived, and by water carriage. There are
hundreds of miles of the northern coast on which it would in all probability
be equally at home.

It is thus fairly evident that while a large part of the flora of the
Kermadecs was in all probability derived from New Zealand, it is at least
extremely probable that some of it was derived directly from some part of
Polynesia, probably by way of the Tonga-Fiji ridge. This supposition is
confirmed by the behaviour of the ferns, already pointed out (9. p. 341). A
number of Polynesian ferns appear to have entered New Zealand by way of
the Kermadecs, and in New Zealand only range part of the length of the
islands.

When we come to compare the Kermadec flora with that comprised in
the northern invasion (10, p. 356), and find that 22 of the 33 families are
missing, it seems hardly possible, in view of what we now know about the
rarity of dying out among flowering plants at any rate, that the northern
invasion passed by way of the Kermadecs. On the other hand, we have
seen that the only members of Anacardiaceae, Cucurbitaceae, and Pipera-
ceae, three of the 33 families enumerated in it, probably passed to New
Zealand by way of the Kermadecs. It would seem therefore probable that
these three families should be excluded from the list of the northern
invasion proper, and should be classed, together with the other plants
mentioned above {Siege sbeckia, &c.), as a second northern (Kermadec)
invasion.

From the extreme regularity of the distribution of the Kermadec
plants in New Zealand (except the conspicuously different Ipomoea palmata) ,
one is obliged, it seems to me, to conclude that there was at one time a land
bridge connecting the two.

We also know (10, p. 358) that the northern invasion was mainly
(84 per cent.) trees and shrubs. Examination of the Kermadec flora,
however, shows that it contains 45 herbs and only 26 shrubs and trees.
The latter thus form only 36 per cent, of the flora, a very different propor-
tion from that in the northern invasion proper.

Of the 2 6 shrubs and trees, 12 are confined to the Kermadecs, or at
least do not reach New Zealand, and 5 of the other 14 range from end to
end of New Zealand, the mean range of the whole 14 being represented by
the figure 3*0. Of the 45 herbs, 7 only are not found in New Zealand,
20 range New Zealand from end to end, and the mean range is represented
by the figure 2-2. These facts are inclined to suggest, though they offer no

New Zealand and their Distribution .

281*

proof, that herbs may range more rapidly than trees and shrubs, as indeed
one is inclined to think must necessarily be the case. Eight of the 14 shrubs
and trees reach the Chathams also, and only 17 of the 38 herbs, a fact
which also points in the same direction, as it gives one to suppose that the
former were opposite to the Chatham connexion at an earlier period than
the latter.

(25) Finally, many Kermadec species also reach the Chathams, as we
have seen. Now if age be the chief determinant in distribution, we shall
expect (cf. map-diagram 2) that those of these forms which belong to the chief
northern invasion, supposed to centre in Auckland, will also reach Dunedin
to the south, while those which do not may cease at a less distance from
the North Cape. Examining the facts, we find that of the 29 species which
the Kermadecs have in common with the Chathams, 26 range to Dunedin
or farther south, whilst Piper excelsum reaches only to Banks Peninsula and
Okarito, Corynocarpus laevigatus to Banks Peninsula and Westland, and
Aciant hus Sinclair ii to Dun Mountain and Westport. All of these, we have
seen above, may very probably be regarded as having entered New
Zealand in the Kermadec invasion ; and it is also noteworthy that Coryno-
carpus is a tree, which might have been early enough to reach the Chathams
without perhaps travelling sufficiently fast to have reached so far south as
some of the other forms also common to the Kermadecs and Chathams.
There are 16 other Kermadec species which reach as far south as Coryno-
carpus and do not reach the Chathams ; 13 of these are herbs, Melicytus
ramijlorus and Panax arboreum are trees, and Coprosma Baueri is a shrub.

The Auckland Islands.

Turning now to the southern end of New Zealand for a while, let us
look at the flora of the Aucklands and their surrounding inlands (the
Antipodes, Campbell, and Macquarie). The first thing that strikes one is
that though the Aucklands are subantarctic and the Kermadecs subtropical,
the former have a much larger flora recorded, 1 19 species against 71. Of
these 44 do not occur in New Zealand proper.

As regards constitutional habit, the Aucklands contain only one tree
(. Metrosideros lucid a), 11 shrubs, and 107 herbs. The last named thus
form 90 per cent, of the total, against only 64 per cent, in the Kermadecs.

Another feature of interest is the great proportion of Monocotyledons.
To deal properly with this feature, we must briefly consider the distribution
of Monocotyledons in New Zealand itself, though complete details must be
left for subsequent papers. If we divide the main islands of New Zealand
from north to south into zones of 100 miles, as has already been done upon
several occasions (cf. 6, p. 444), and tabulate the species that occur in them,
we get for the Monocotyledons :

282 Willis. — The Floras of ihe Outlying Islands of

Table XV.

100 m.

-200

-300

-400

-5°°

-600

-700

-800

-900

-1000

-1080

Wides reaching islands

21

21

23

23

24

26

26

26

26

29

26

Wides (N.Z. only)
Endemic N.Z. and

7i

68

85

84

83

80

76

69

62

56

27

islands

22

22

23

25

27

3i

3i

30

3i

3i

30

Endemic N.Z. only

56

63

71

81

80

100

98

98

I04

86

39

170

174

202

213

214

237

231

223

223

202

122

It is clear that the centre of the Monocotyledons as a whole is in the
South Island. But the numbers do not run with perfect regularity to
a maximum at one zone, and this leads one to suspect, what indeed seems
probable when one realizes (10, p. 355 seq.) that there have been at least
two invasions of New Zealand, that the group really entered partly in one,
partly in the other, invasion. The southern invasion of Monocotyledons
was, as we shall see, so much the larger that its figures all but swamp those
of the northern.

If we how examine the Monocotyledons genus by genus, we soon find
that they divide into two main groups, one commencing at the north end of
New Zealand and ranging to a greater or less distance south, the other com-
mencing at the south end and ranging to a greater or less distance north.
It is very striking how few species there are which have intermediate
ranges, among the wides — the endemics of course haver every possible
range. The only wides that do not reach one or the other end of the two
main islands of New Zealand are given in the table below (I have counted
those wides that only reach the southern end of the narrow peninsula at the
extreme north as reaching the north end of New Zealand, this peninsula
being so entirely different from the rest of the country, and so small
in area).

Table XVI.

Prasophyllum rufum
Pterostylis mutica
Hypoxis pusilla
Juncus scheuchzerioides
Triglochin palustre
Potamogeton palustre
Zannichellia palustris
Lepilaena Preissii
Centrolepis strigosa
Lepyrodia Traversii
Eleocharis acicularis

A mere glance at this list, for any one who is familiar with Cheeseman’s
Flora, is sufficient to show that it includes, as is usual in lists of species that
behave irregularly (as regarded from the point of view of age and area), the
bulk of the doubtful determinations, species of possible recent introduction,
&c. The three orchids might possibly have been brought by the aid of the
wind in comparatively recent times. There are only perhaps 8 of the 21

Uncinia Sinclairii
tenella
Carex acicularis
lagopina
leporina
Brownii

Imperata arundinacea
Stipa setacea
Alopecurus geniculatus
Agrostis parviflora

New Zealand and their Distribution . 283

which can be regarded as probably in reality ranging short of either end of
New Zealand, and which are not either wrongly named or probably intro-
duced, whilst it is obvious that any further discoveries of these species in
new localities will go to make the original contention, that the wides in
general range to one or the other end of New Zealand, nearer and nearer to
the exact truth. In any case, as there are 179 Monocotyledon wides, it is
clear that an ‘error’ of 8 is nothing very marked.

Beginning with the orchids, we may probably regard as northern
genera (inasmuch as their wides, where they do not range completely along
New Zealand, usually begin at the north end) Dendrobium , Biilbophyllum ,
Earina , Sarcockilus , Spiranthes , Thelymitra , Orthoceras , Microtis , Cate ana,
Acianthus , Cyrtostylis , Calochilus , and Gastrodia . Similarly we may regard
Cordyline and Astelia in Liliaceae, Rhopalostylis in Palmae, Freycinetia in
Pandanaceae, Kyllinga , Cyperus , Mariscus , Fimbristylis , Scirpus , Schoenus ,
Cladium , Lepidosperma , and Gahnia in Cyperaceae, and Imperata , Zoysia ,
P asp alum, Isachne , Oplismenus , Spinifex , Sporobolus , Dichelachne , Amphi -
bromus , Bromus , and Agropyrum in Gramineae, as northern types. If now
we take the zonal distribution of the species of these genera, and add them
up, we get :

Table XVII.

■loom.

-200

-300

-400

-5°o

-600

-700

-800

-900

-1000

-1080

Wides reaching islands

14

14

T4

T4

15

21

•15

13

T3

13

10

Wides (N.Z. only)
Endemic N.Z. and

36

32

32

30

25

1 7

1 1

5

3

3

islands

13

13

13

14

14

T4

14

12

12

12

11

Endemic N.Z. only

28

27

29

3i

24

23

19

16

H

10

6

9i

86

88

89

77

73

65

52

44

38

30

tapering markedly from north, to south. If now we subtract this table from
Table XV, we get :

Table XVIII.

-100 m.

-200

-300

-400

-500

-600

-700

-800

-goo

-1000

-1080

Wides reaching islands

7

7

9

9

10

11

11

13

13

16

16

Wides (N.Z. only)

35

36

53

54

58

59

59

58

57

53

24

Endemic N.Z. and

islands

9

9

10

11

13

17

17

18

J9

19

19

Endemic N.Z. only

28

36

42

50

5*5

77

79

82

90

76

33

79

88

114

124

i37

164

166

171

!79

164

92

These figures clearly show that the supposition of two chief invasions
of Monocotyledons is supported by the facts ; and it is probable that when
our detailed knowledge of distribution in New Zealand reaches comparative
perfection, we may be able to go into even greater detail. As it is, one or two
genera, e. g. Scirpus or Schoenus , have wides beginning at both the north and
the south ends of New Zealand, and ranging part way along the islands to the
south or to the north. If these genera were regarded as having entered by

Y

284 Willi Sr — The Floras of the Outlying Islands of

both invasions, and their species divided between them, the slight irregu-
larities shown in the tables above would be removed.

(26) The southern invasion of Monocotyledons being thus much larger
than the northern, we shall expect the Aucklands to show a larger percent-
age of this group in their flora than do the Kermadecs, and we shall
expect the Chathams to show an intermediate percentage.

Table XIX.

A ucklands. Chathams. Kermadecs.

Monocotyledons 54 45 % 49 31 % 15 21 %

Dicotyledons 65 55 % 106 69 % 56 79 %

(27) It follows incidentally from what has been said that Stewart
Island should show a greater proportion of Monocotyledons in its flora than

New Zealand as a whole. This comes out in

\ .

Table XX.

New Zealand as a whole
( including islands') .

Monocotyledons 348 27 %

Dicotyledons 954 73 %

or, to put it in another way, 37 per cent of the New Zealand Mono-
cotyledon flora occur in Stewart, and only 26 per cent, of the Dicotyledon
flora (neglecting in each case the few Stewart endemics). The whole makes
a very awkward problem for the supporter of Natural Selection ; why are
Monocotyledons so much better suited to Stewart and the Aucklands than
to the Kermadecs, and why are the Chathams intermediate in the propor-
tion they bear? But if we simply recognize that the proportions are merely
due to the size and time of the invasions of New Zealand by plants, we get
a perfectly simple and straightforward explanation.

(28) Examination of map-diagram 2 will show that if we draw a circle
with its centre in the Auckland Islands, passing through the Chathams, it will
also pass through Auckland City. We shall therefore expect that in
general (unless of course there was not direct land communication in either
of these directions), species which reach both the Aucklands and the
Chathams will also reach Auckland City. Examination of the facts shows
that of the 32 species that these groups of islands have in common, 2 6 are
found at least as far north in New Zealand as Auckland City. Of the
other 6, 2 are wides, both South American species, Tillaea moschata and
Veronica elliptica , reaching, the one to the northern side of Cook’s Strait,
the other to West Wanganui and Cape Foulwind, in South Island.
Coprosma foetidissima reaches to the Thames goldfields, and Deschampsia
caespitosa to the lower Waikato, so that these two reach within a very
short distance of Auckland. Tillaea moschata and Rumex neglectus are

Stewart.

I3° 34%
252 66%

New Zealand and their Distribution . 285

coast species, which may have reached the Chathams by water, and Urtica
australis finally, which only reaches the small islands in Foveaux Strait, is
also probably a water-carried species. The prediction is thus borne out by
the facts as well as can be expected. Even if all the six species be con-
sidered as exceptional, the prediction is within 20 per cent, of accuracy.

Both the southern invasion, and the floras of the Aucklands, Camp-
bell, &c., contain a large number of South American forms, and the
question has been much discussed as to how they have reached New
Zealand, or whether indeed they did not reach South America from New
Zealand. Guppy (5, p. 294) discusses the possibilities of water carriage,
and shows that seeds drifted from South America could only reach the
extreme north of New Zealand. But an examination of the New Zealand
forms with South American affinities shows that those which do not range
the entire length *of the islands are mainly concentrated in the south. The
only ones with northern location are Sicyos angulata (range 0-540),
Mesembryanthemum aequilaterale (360-500), Gratiola peruviana (0-940),
Cyperus vegetus (60-500), and Scirpus sulcatus (80-700, Tristan da Cunha,
not South America proper). Of these we have seen that the first probably
entered from the Kermadecs, it also occurring in Polynesia and Australia,
and the last may have been drifted by water from Tristan. Mesembryan-
themum and Gratiola also occur in Australia, so that there remains only
Cyperiis vegetus , and it is permissible to suppose that this may have arrived by
water carriage, perhaps when the Lord Howe I. bank was dry land.

Water carriage, however, will hardly explain how the others reached
New Zealand from South America, and there remains the possibility that
the transport was the other way, and that these species reached South
America from New Zealand. Guppy shows that transport is possible from
the south of New Zealand to Chili. The genera involved are mostly so
cosmopolitan that one cannot argue from the generic distribution, and
must take other matters into consideration. The great argument against
this supposition, to my mind, is based upon age and area. These species,
in South America, mostly reach not only Chili, but also Fuegia, the
Falkland Islands, South Georgia, &c., and in some cases also Kerguelen
and other islands of the Antarctic Ocean. It is, therefore, clear that they
must be enormously old in South America, and if they had gone there
from New Zealand they must be yet older in that island, and should
therefore be very widely distributed there, which is exactly what does not
occur. Their distribution shows clearly that they must be older in South
America, and must therefore have gone to , not from, New Zealand.

Or again, we may take single examples. It would seem very strange
if Ranuncirius biternatus spread from Macquarie to South America (it does
not occur in New Zealand), or Cardamine glacialis , found only in the
Aucklands, Campbell. Macquarie, and South America, or other species

286 Willis. — The Floras of the Outlying Islands of

found only in limited areas in the South Island. The South American
wides are no commoner, in fact slightly rarer (less distribution area) in New
Zealand than the Australian wides, and it may also be noticed that those
South American wides that also reach Australia are very widespread indeed
in New Zealand.

There seems therefore some reason to suppose that the affinity between
New Zealand and South America is really due to the fact that at one time
there was land connexion, complete or nearly complete, between them,
though a few species, especially those with northern range in New Zealand,
may owe their presence to water carriage. The equatorial current from
the west coast of South America passes by way of the Kermadec and
Chatham Islands.

As to the position and direction of the land bridge, it is very difficult
to come to any definite conclusion in the present state of our knowledge.
In general we may perhaps imagine that it went by way of the Antarctic
continent, perhaps all the way to South Georgia, or perhaps by way of
Juan Fernandez to Chili, though this seems unlikely. But a land connexion
seems to me to be indicated by the facts of distribution.

As so many Australian and Tasmanian forms are included in the plants
of the southern invasion, it would seem probable that this land connexion
extended also to Australia and Tasmania.

Whether the South American and the Australian plants arrived by the
same route from the south it is difficult to say. The general facts seem to
me to indicate — it is impossible to put it into words without a vast amount
of detail — that it is quite possible, if not probable, that the land joining
New Zealand to the Antarctic continent was more or less broken up by
water areas. It is, for example, noticeable that a number of species which
occur in Kerguelen, the Crozets, Marion Island, &c., are found only in
Macquarie, though of course this is quite possibly due to water carriage.

The next question is, Did this connexion with Antarctica pass through
any of the groups of islands that we are now considering? As even the
Aucklands only possess 39 out of 127 wides of the southern invasion, and
Campbell, the Antipodes, and Macquarie progressively less, it may be
inferred that it did not pass directly through any of them, and that it was
probably nearest to the Aucklands.

The average rarity in New Zealand of the Auckland wides as a whole
is 2*7, while that of the wides of the southern invasion is 3-1. This is little
to go upon, but at least it tends to show that on the whole the arrivals of
wides in the Aucklands were fairly early.

There are a considerable number of South American genera which
occur in New Zealand but not in the Aucklands, another fact which goes to
show that the southern invasion, or some of the invasions, if there were
more than one, did not pass directly through these islands.

New Zealand and their Distribution.

287

In Campbell, the Antipodes, and Macquarie we find in general the
Auckland flora, in less and less proportion, so that on the whole these
islands must probably have received their floras by the same invasion. It
would lead too far to go into greater detail.

The Chatham Islands.

To turn lastly to the Chathams, it is obvious that they could never
have formed part of a bridge from New Zealand to anywhere else, the .water
on their eastern side being almost the deepest in the world, so that their
flora, except in so far as it may have been brought by currents, must have
come through New Zealand. Even if the whole area shown in the map as
above the depth of 1,000 fathoms were dry land, a species beginning
between the Chathams and Antipodes would as a rule have also reached
New Zealand by the time that it had reached both groups of islands.

The Chathams are fairly opposite to the middle of New Zealand, and
connected by shallower water with the South than with the North Island, so
that one will expect their flora to be fairly rich, unless they were cut off
very early indeed, a matter as to which we have no information. As
a matter of fact they have the richest flora of the outlying island groups,
composed of 106 species of Dicotyledons and 49 of Monocotyledons, the
proportion of the latter being, as we have seen, intermediate between that
in the Kermadecs and that in the Aucklands.

(29) We shall expect that on the whole the families missing in the
Chathams from the Stewart list, which is likewise old, will be the smaller
families of that island, i. e. on the whole those which have been the latest in
arriving there. If we omit all those with one species, we omit Magnoliaceae,
Pittosporaceae, Elatinaceae, Hypericaceae, Linaceae, Cornaceae, Goodenia-
ceae, Primulaceae, Apocynaceae, Loganiaceae, Labiatae, Illecebraceae,
Lentibulariaceae, Chloranthaceae, Loranthaceae, and Euphorbiaceae.
Primulaceae must certainly occur in the Chathams, as the only species in
the family occurs in both Kermadecs and Aucklands. Leaving this out,
the only other families in this list which are recorded from the Chathams
are Linaceae, Cornaceae, Labiatae, and Euphorbiaceae. The other Stewart
families not recorded from the Chathams are Portulacaceae (2 species),
Tiliaceae (4), Saxifragaceae (3), Droseraceae (4), Stylidiaceae (4), Erica-
ceae (2), Plantaginaceae (3), and Centrolepidaceae (2), but we have already
seen that (prediction 5) we must expect the Chathams not to contain the very
small families of the southern invasion. This excludes from this list Portu-
lacaceae, Droseraceae, Stylidiaceae, Plantaginaceae, and Centrolepidaceae,
leaving only three families of the Stewart flora that might be expected and
have not been'recorded, and four recorded that would hardly be expected,
as being families with only one species in Stewart. The seven families that
occur in the Chathams and do not as yet appear to have been recorded

288 Willis. — The Floras of the Outlying Islands of

from Stewart, Rhamnaceae, Anacardiaceae, Leguminosae, Solanaceae, Myo-
poraceae, Piperaceae,and Palmaceae,are all northern except perhaps Legumi-
nosae, which is the largest New Zealand family not yet recorded from
Stewart.

(30) In the same way. we shall expect the smaller genera of the
Stewart flora to be those that are chiefly missing, and on examination we
find that of those represented in Stewart by one species 57 are not found in
the Chathams, and 31 have been found, while of those represented by two
or three species 19 have not been found, and 26 are present, in the
Chathams.

(31) One may, by the aid of age and area, go a good way towards
a prediction of the whole flora of the Chathams (cf. that of the flora of
Stewart in 11, p. 27). If one first predict that they will contain the
Kermadec species that reach Dunedin, this gives 38 species of which 26
reach the Chathams ; then adding that they will contain the Auckland
species that reach Auckland city gives about as many more. If now one
add to this that the bulk of the rest of the flora will likely be made up from
the species which range the whole length of New Zealand (for those that
ranged less distance would as a rule be too young to reach the Chathams at
all, unless they ranged beyond New Zealand to the Kermadecs or Auck-
lands), one obtains almost all the remaining flora, except the local endemics,
which we have already seen may be to some extent predicted as likely to
belong to the oldest families in the Chathams, that is to say, to the families
represented by the most species in New Zealand (see above, p. 270). Of
course this prediction that the Chatham ' flora will be selected almost
entirely from Classes 1 and 2 (6, p.449) of the New Zealand flora brings in
also a great many other species belonging to those classes, but which do not
occur in the Chathams. We have as yet no means of deciding which are
the oldest species in a given class, and it will only be the oldest, in general,
which will reach the Chathams. The fact remains, however, that by this
prediction we cover all of the Chatham flora but 14 species and the local
endemics, and we have seen that we can more or less closely predict the
families and genera to which these belong. These unpredicted species are :

Pomaderris apetala : a special case, see 8, p. 332.

Corynocarpas laevigatas : see above, p. 279.

Tillaea moschata\ a coast species.

Epilohium insulate : lowland swamps.

Coprosma foetidissima\ see above, p. 284.

I~I e lie hr y sum flic aide : dry grassy places.

Veronica elliptica : a coast species.

Piper excelsum : usually near the coast.

Urtica australis.

Pterostylis australis : cf. 11, p. 39.

New Zealand and their Distribution .

289

A cian thus S inclairii.

Rhopalostylis sapida.

Lepyrodia Traversii\ doubtful determination, see Cheeseman.

Deschampsia caespitosa : see above, p. 284.

Thus several are doubtful determinations, or coast forms, which may
have been brought by the currents. But it is only among these few species
that one can look for exceptions to age and area ; all the remainder of the
flora of the Chathams — 155 species in all — is easily explained by the
simple operation of this law, and no other assistance is needed to explain it.

(32) We may predict that the Chathams should have proportionately
more species in the higher classes of width of distribution than the

Kermadecs or Aucklands, where more recent arrivals may occur, as these
islands have been nearer to the tracks of the invasions.

Table XXI.

The Chathams have 155 species, of which 77 are Class 1, 30 Class 2

,, Kermadecs „ 71 ,, ,, 22 ,, ,, 16 ,,

„ Aucklands „ 119 „ „ 35 „ ,, 6

The proportion (and the totals) in the Chathams is by far the greatest.

One might give other predictions about the floras of these islands, but
these will suffice to show that in a well-defined area like New Zealand and
its surrounding islands one can without hesitation draw upon the hypothesis
of age and area to make predictions about the taxonomic distribution of
the flora, and find that the predictions are justified by the facts. I have
now used the hypothesis to make no fewer than 67 predictions (32 in this
paper), every one of which has proved to be correct. In several cases the
exactness with which the prediction has been borne out by the facts has
been positively astonishing, and in all cases the result has been as near to
accuracy as can reasonably be expected in a biological subject, and espe-
cially in one so complex as geographical distribution, where changes in the
configuration of the land and sea may be continually going on, and in a very
complicated way. It seems to me, therefore, that the hypothesis of age and
area, having been successfully used to make so many predictions, may now
perhaps be regarded as being fairly well established as one of the chief (if
not the chief) positive factors in geographical distribution, while the action
of barriers, which may be of many kinds — seas, rivers, mountains, ecological
barriers, changes of climate, &c. — may be regarded as the chief negative
factor, and other things, such as the action of man, are also of very great
importance indeed.

If this position be regarded as reasonable, it is evident that we must
now state the hypothesis in rather more clear and definite terms than
those in which it vyas first formulated, e. g. in 6, p, 438. After careful

290 Willis . — The Floras of the Outlying Islands of

consideration of the various papers that have been written on the subject,
and after devoting much time to further work upon it, I am inclined to word
the hypothesis thus :

The area occupied at any given time, in any given country, by any
group of allied species at least ten in number, depends chiefly, so long as
conditions remain reasonably constant, upon the ages of the species of that
group in that country, but may be enormously modified by the presence of
barriers such as seas, rivers, mountains, changes of climate from one region
to the next or other ecological boundaries, and the like, also by the action
of man, and by other causes.

In other words, age and area is the chief positive, the action of barriers
the chief negative, factor in plant distribution, while in recent times the
action of man has become of greater importance than either.

It is clear that in general this law also covers the case of a genus of
more than a very few species, for a genus is in general a group of allied
species, though it is becoming every year more clear (cf. 1 and 12, p. 446)
that many genera are based upon too few characters, and are in reality
polyphyletic.

The acceptance of this hypothesis will involve various changes in our
methods of handling problems of geographical distribution, and in further
papers I shall go on to indicate some of these.

Summary.

In this paper the chief attention is devoted to the islands outlying
around New Zealand, especially the Kermadecs, Chathams, and Aucklands,
and the following points are indicated, chiefly by the method of prediction
and subsequent verification, which is here used successfully no fewer than
32 times.' It is first shown that the floras of these islands must be very
old, from their far outlying position, and is then indicated that —

i.1 The islands have proportionately more families in common with
Stewart, whose flora is also old, than with New Zealand proper (Table I).

2. The great proportion of the families in the different islands are the
same, and most are selected from the Stewart list (Table II).

3. The families reaching three groups of islands are on the whole the
largest (oldest), those reaching two next, and then those reaching one or
none (Table III). The same is true for the Stewart families (Table IV),
and the total result is summed up in Table V.

4. The Stewart families that are missing in the islands are on the whole
the smallest.

5. The Aucklands and the Chathams contain most of the families of
the southern invasion, and those that are missing in the Chathams are the
smallest, numerically, of that invasion.

1 Predictions numbered as in text above.

New Zealand and their Distribution .

291

6. The Chathams contain many families of the northern invasion.

7. The outlying islands have proportionately more families in common
with one another than they have with New Zealand (Table VI).

8. The genera of the floras of the outlying islands are chiefly selected
from the Stewart list (Table VII) ; only 26 out of 140 do not occur there,
and are mostly northern genera.

9. The genera that occur in the islands are on the whole the largest in
number of species, both in Stewart and New Zealand (Table VIII).

10. The islands have proportionately more genera in common with one
another than they have with New Zealand (Table IX).

1 1 . The Stewart genera which are missing are on the whole the smallest.

12. The species in the islands are also to a very large extent indeed
selected from the Stewart list.

13. The Stewart families that have no species in the islands are on the
whole very small in Stewart.

14. The islands have very many species in common among themselves.

1 5. The species in common between three islands (the oldest) show the
largest proportion of wides (the oldest forms), then those of two islands, one
island, and those reaching none (Table X).

16. The plants of the islands show a greater proportion of families to
genera and genera to species than those of Stewart and New Zealand
(Table XI).

17. The. more genera in a family in New Zealand, the older on the
whole is the family in New Zealand, and the better represented in the
islands (Table XII).

18. The same thing shows in regard to the genera.

19. The plants reaching 3 groups of islands, New Zealand and Stewart,
2, 1, Stewart and New Zealand only, and New Zealand only, show a progres-
sive decrease in the average size of families and genera (Table XIII).

20. All these predictions are also true of the ferns, and the fern flora
of Stewart, as on the whole older, is better represented in the islands than
the flowering plants.

21. The species endemic to the islands only do not occur on two of the
chief groups without occurring in New Zealand, as one might expect were
they relicts.

22. The endemics of the islands belong on the whole to the largest
(i.e. on the whole the oldest) families of New Zealand.

23. Practically all the genera of the island endemics, being old, occur
in Stewart.

Just as in Stewart, the island endemics belong mainly to the { success-
ful ’ families and genera of New Zealand.

24. The proportion of trees is greatest in the northern islands, least in
the southern, intermediate in the Chathams.

292 Willis . — The Floras of the Outlying Islands of

The islands must have had connexion by land with New Zealand.

The Kermadecs contain a number of species which do not occur in
New Zealand, but occur in Polynesia ; it therefore seems probable that
they received part of their flora direct from Polynesia.

The distribution of the Kermadec species in New Zealand is considered,
and it is shown that it does not agree with any hypothesis but that of a land
bridge between the two.

The Kermadecs probably were not in the track of the main northern
invasion of New Zealand, but were upon the route of a minor invasion from
Polynesia.

25. The Kermadec species which reach the Chathams also reach in
general as far south in New Zealand as Dunedin.

The Aucklands show a great proportion of Monocotyledons, and the
distribution of this group in New Zealand is briefly considered* it being
shown that it probably took part in both invasions.

The wides of New Zealand nearly all range to one or the other end of
the islands, if not to both. Those which do not (Table XVI) include the
doubtful determinations, species of probable recent introduction, &c.

26. The proportion of Monocotyledons is greatest in the Aucklands,
least in the Kermadecs, and intermediate in the Chathams.

27. Stewart Island shows a greater proportion of Monocotyledons
than New Zealand.

28. Species reaching both Aucklands and Chathams reach also in
general to Auckland city.

The evidence is against the probability of carriage by water of South
American forms to New Zealand, or of New Zealand forms to South
America, though there are a few that may have been so carried, and favours
the former existence of a land bridge, which probably passed to New
Zealand nearer to the Aucklands than to the other southern islands.

29. The families missing in the Chathams are the smaller families of
the Stewart list, in general ; (30) similarly the smaller genera.

31. A great part of the Chathams’ flora can be predicted by aid of age
and area.

32. The Chathams have more species in the highest classes (widest
distribution in New Zealand) than the Kermadecs and Aucklands.

The hypothesis has now been successfully used to make no fewer than
67 predictions, which have proved to be correct on examination of the facts,
and increase of area with age may thus perhaps be considered as being the
chief positive factor in determining the distribution of plants about the globe,
the chief negative factor being the presence of barriers.

Finally, a restatement of the hypothesis is made.

New Zealand and their Distribution.

293

Literature quoted.

1. Bower: Natural Classification of Plants (Hooker Lecture), esp. p. 119. Journ. Linn. Soc.

(Bot.), xliv, 1918, p. 107.

2. Cheeseman : Manual of the Flora of New Zealand, Wellington, 1906.

3. : Islands to the S. of New Zealand, in Chilton’s Subantarctic Islands of New

Zealand, ii. 389, Wellington, 1909.

4. Cockayne : Botanical Survey of Stewart Island, Wellington, 1909.

5. Guppy : Plants, Seeds, and Currents in the West Indies and Azores, 1917.

6. Willis : Distribution of Species in New Zealand. Ann. Bot., xxx, p. 437, 1916.

7. : Relative Age of Endemic Species. 1. c., xxxi, p. 189.

8. : Distribution of Plants of the Outlying Islands. 1. c., xxxi, p. 327.

9. — : Further Evidence for Age and Area. 1. c., xxxi, p. 335.

10. — 7 — : Sources and Distribution of the New Zealand Flora. 1. c., xxxii, p. 339.

11. : The Flora of Stewart Island. 1. c., xxxiii, p. 23.

12. Studies in the Morphology of the Podostemaceae. Ann. R. B. Gardens, Peradeniya,

i, p. 267, 1902.

13. : The Endemic Flora of Ceylon : A Correction. Proc. -Roy. Soc., B., lxxxix, p. 257.

Studies on the Chloroplasts of Desmids. II.

BY

N. CARTER, M.Sc.

With Plates XIX and XX and one Figure in the Text.

Contents.

IX. The Chloroplasts of Micrasterias.

IN this genus the general form of the chloroplast in some species has
long been recognized. Thus an extensive chloroplast plate containing
numbers of scattered pyrenoids was figured by Ralfs (1848) in several species,
and later Delponte (1873) and W. and G. S. West (1904-11) also indicated
the presence of ridges on the surface of the chloroplast in some other
species.

But although it has long been observed that in those species of the
genus having very flattened cells the chloroplasts are correspondingly
flattened and plate-like, in the case of those species in which the cells are
comparatively thicker very little is known concerning the chloroplasts.

The species whose chloroplasts have been examined during this
investigation are M. confer ta, Lund., M. denticulately Breb., M. Tkomasiana,
Arch., M. rotata, (Grev.) Ralfs, M. papillifera, Breb., M. radiata, Hass.,
M . Crux-Melitensis, (Ehrenb.) Hass., M. pinnatifida, (Kiitz.) Ralfs,
M. apiculata, (Ehrenb.) Menegh., M. Americana, (Ehrenb.) Ralfs, M. oscitans,
Ralfs, var. mucronata, (Dixon) Wille, and M. tr nne at a, (Corda) Breb. In
spite of the fact that the chloroplasts of these species present very diverse
appearances when examined in the front view, it has been found that they
are all built up on the same plan. On comparing, for instance, the chloro-
plasts of a species having very flattened cells, e.g. M. denticulata, with those
of a species whose cells are in proportion very much thicker, e.g. M. truncata,
considerable differences are at once apparent ; cf. PI. XIX and XX, Figs, i and
25 ; nevertheless both can be considered as variations of one simple type.

There is in every case one chloroplast in each semi-cell, and this consists
primarily of an extensive flattened plate, having approximately the same
outline as the cell-wall, and occupying a central position, its surfaces
parallel to the front faces of the semi-cell. As a rule from both sides of
this axile plate various ridges are given off, stretching towards the cell-wall.
The size, number, and disposition of these ridges vary considerably according
to the species, and even to some extent amongst individuals of the same

[Annals of Botany, Vol. XXXIII No. CXXXI. July, 1919.]

296 Carter . — Studies on the Chloroplasts of Desmids. II.

species, according to the physiological condition of the cell. This is
particularly the case with some of the flat-celled species, where frequently
in some individuals no trace of ridges is to be found at all, whereas in
others they are quite distinct. In other thicker celled species, e. g.
M. truncata , they are often so large, numerous, and profusely branched,
that the axile plate is frequently quite hidden by them. The size and
prominence of the ridges depends largely on the thickness of the cell,
because they stretch out towards the cell-wall, chiefly at right angles to the
axile plate.

In the flat-celled species of Micrasterias the axile plate does not
usually occupy more than one-third the entire space between the two front
walls of the semi-cell (Figs. 3-8 and 10), but the thickness of the chloroplast
always varies considerably according to the amount of stroma starch
contained in it. The axile plate extends into all the peripheral lobes and
projections of the cell-wall, and is slightly hollowed out at the base of the
semi-cell for the accommodation of the nucleus (Figs. 2 , 9, and 24). In
outline it may be very similar to the cell-wall, or it may be even more
intricately incised and lobed. Sometimes it seems to be drawn out at
intervals into threadlike strands vvhich apparently connect up the chloro-
plast to the peripheral layer of cytoplasm lining the cell-walk This
happens when the chloroplast is not sufficiently massive to extend right up
to the cell-wall at all points.

In those species with very thick cells the axile plate is not so evident
in the front view as in the case of those species having flattened cells
(Figs. 13, 19, and 25). It is seen, however, in the end view or in transverse
sections as an extremely thin plate lying in the middle of the cell, half-
way between the front walls (Fig. 27). Towards the sides of the cell it
usually loses its identity in the profusion of branching ridges (Figs. 14, 20,
21, and 27). Very often in such cases it has no definite plate-like form, but
consists of a more or less irregularly shaped mass connecting up the huge
ridges one with another, these forming by far the more important part of
the chloroplast (Fig. 21).

In nearly all the species examined a more or less extensive hollowing
away of the central axile plate was noticed in the upper region of the polar
lobe. This is often seen as a semicircular or more elongated space free
from chloroplast in the extreme apex of the cell. In the flat-celled species
this apical hollowing rarely extends for more than one-fourth the distance
from apex to nucleus, and is frequently less (Figs. 2 and 24). In the thick-
celled species, however, the axile plate is sometimes shortened from the
apex by as much as two-thirds its greatest length, so that the chloroplast
is distinctly bilobed (Figs. 15, 19, and 25). When this happens the ridges
often spread round over the internal surface of the wall so that the absence
of the axis in the apical region may not at first sight be noticed, but in

Carter .—Studies on the Chloroplasts of Desmids. II. 297

other cases the colourless gap may be quite obvious. In such individuals
there are often apparently two chloroplasts in each semi-cell, separated from
each other by a colourless space in the median region. On careful examina-
tion, however, it is usually possible to locate the remains, at any rate, of the
axile plate just beyond the nucleus connecting up the two apparently
separate chloroplasts (Fig. 25). In the genus Micrasterias the formation
of two separate chloroplasts in a single semi-cell by means of this extensive
hollowing away in the apical region was not very frequently observed, but
in Cosmarium Ralfsii,1 which has a chloroplast exactly similar to that of
the thick-celled species of Micrasterias , the same phenomenon also occurs,
and here all stages in the progressive shortening of the axis in the median
region have been observed, including the final stage in which two distinct
chloroplasts were present. It is quite possible that this also happens
occasionally in those species of Micrasterias having very thick cells.

The ridges, if present, project from both surfaces of the axile plate,
extending to the cell-wall. If the distance from the central axis to the
cell-wall be considerable, i.e. in the thick-celled species, the ridges frequently
fork and branch (Figs. 20-22 and 27) ; in most cases, however, they are
simple and unbranched (Figs. 14 and 18). Their free edges are rarely
quite straight, but either undulate (Figs. 2, 15, and 17), or, as is more
often the case, they are much more elaborately ornamented (Figs. 13 and
24). Sometimes their edges may be drawn out to form short thread-like
outgrowths attached to the peripheral layer of cytoplasm lining the cell-
wall, as in the case of the edges of the axile plate (Fig. 19).

In many of the flat-celled species the ridges project only very slightly
from the surface of the plate, and in some individuals may be scarcely
perceptible. When this is the case they are usually to be found following
the outlines of the more important incisions of the plate, just a little distance
from .its edge (Figs. 2 and 24).

Very often there are two very prominent ridges on both surfaces of
the axile plate in the median region. These usually extend right from
the nucleus at the base of the semi-cell up into the polar lobe, one on each
side of the apical gap in the axis (Text-fig.; Figs. 9, 15, and 17). They
usually stretch for a little way over the surface of the nucleus itself, which
is therefore embraced by eight claw-like projections, the outgrowths of the
four ridges on each chloroplast of the cell. In species having such
prominent median ridges other smaller ones may or may not be present.
If present they are sometimes irregularly scattered (Figs. 13 and 15), or
may be in definite positions round the more important incisions as before
(Text-fig.).

1 This species was for some time believed to have chloroplasts in the form of parietal bands ;
its axile form was first discovered by Dr. Liitkemuller, who figured it and published a short note on
it in his paper, Zur Kenntnis der Destnidjaceen Bohmens, 1910.

298 C aider .—Studies on the Chlor op lasts of Desmids. II.

In those species of the genus having the thickest ceils the ridges are
comparatively speaking very large and profusely branched. Their arrange-
ment is usually very irregular, and they extend in all directions towards
the cell-wall (Figs. 19 and 25). Here the axial part of the chloroplast is
quite insignificant, and it is not surprising that in the apical and median
regions of the cell the axis is often wanting.

It is probable that this absence of chlorophyll from the apical region
of so many individuals is a manifestation of the attempt on the part of the
organism to fill the more peripheral parts of the semi-cell with photosyn-
thetic material as soon as possible, at the risk of robbing the interior of its
normal share, since the parts of the chloroplast underlying the cell-wall
are obviously more important in the process of photosynthesis than the
more internal parts. This theory is supported by observations of the
behaviour of the chloroplasts during cell-division. When the young semi-
cell is newly formed it contains at first no chlorophyll, but soon the
chloroplast of the older semi-cell begins to bud, sending two lobes through
the isthmus, one on each side of the nucleus into the young semi-cell. In
the very flattened cells of some species this bilobed form is not retained
in a very conspicuous manner as the chloroplast streams more and more
into the new semi-cell, and very soon the median part between them also
begins to bud, so that the ingrowing chloroplast becomes practically semi-
circular in outline, excepting for a small gap often found in its extreme
apex. This is because all parts of the cell are equally good for photosyn-
thesis, and it is just as important that the median part of the cell should
be provided with chlorophyll as the more lateral parts. But in the thicker
celled species the two small lobes first projected into the new semi-cell
quickly expend their substance in an attempt to mantle the cell-wall by
the formation of numerous large ridges which spread out in all directions
as more and more chloroplast enters from the older semi-cell. Whilst this
is happening the axis has very little chance of developing in the median
part of the cell, as indeed there is little need for it to do so, since the
median part of the front walls is probably already sufficiently mantled by
ridges extending from the left and right lobes of the chloroplast. Thus it
often happens that when the division of the chloroplast occurs at the
isthmus, the chloroplast in the new semi-cell is still distinctly bilobed, or,
if the growth of the two chloroplast lobes has been so rapid that the axis
in the median part has not been able to develop at all, then these two
lobes become completely isolated when separated from the original
chloroplast by the division at the isthmus, and consequently the new semi-
cell contains two distinct chloroplasts instead of one.

The pyrenoids in the chloroplasts of this genus are often extremely
numerous (Figs. 2, 9, and 17), but at the same time they are very variable
both in size and number. In individuals of the same species, for instance,

Carter . — Studies on the Chloroplasts of Desmids . II. 299

there may be thirty fairly large pyrenoids, or as many as eighty to a
hundred rather smaller ones.

It is in those species having compressed cells and a simple axile
chloroplast plate that the pyrenoids are most numerous, and here they are
scattered indiscriminately. In the thick-celled species, where the ridges
of the, chloroplast have become relatively more important, the pyrenoids
are reduced in number, and are more or less confined to those parts of the
axis which give rise to the ridges (Fig. 27), whilst in those species having
branched ridges they may be found also in the more peripheral parts of the
ridges at the points of branching (Figs. 21 and 22).

M. conferta .

This species has a rather simpler chloroplast than any other species
examined. Only one specimen was available for examination, and this had
in each semi-cell a simple axile plate of very irregular shape. Ridges were
only very slightly developed, and were found only along a few, not all, of
the larger incisions. The pyrenoids were eight or nine in, number; they
were variable in size and scattered irregularly (Fig. 1).

M. dentictdata and M. Thomasiana .

The chloroplasts of these two species greatly resemble each other.
There is a large axile plate which is usually provided with a series of more
or less distinct, though comparatively small, ridges following the outlines
of the more important incisions between the lobes (Figs. 2-8). The
prominence of the ridges, however, varies considerably with different
individuals. This variation is again to be correlated with the amount of
stroma starch present in the individual. If little starch be present, then
the ridges along the incisions of the cell will usually be very distinct,
whereas, if the chloroplast becomes very distended with stroma starch, the
axile plate is often swollen to three or four times its former thickness and
the ridges are lost.

In M. Thomasiana the ridges parallel to the sinus project for some
distance into the two outgrowths of the cell-wall at the base of the semi-
cell ; the third or median lobule was not strongly developed in the material
examined.

In both species the pyrenoids are very numerous, there being usually
about sixteen to seventy in M. Thomasiana , and twenty to forty in the case
of M. dentictdata (Fig. 2). . Occasionally in the latter species there may
be more than a hundred pyrenoids in a single chloroplast.

M. papillifera.

In this species there is a series of very distinct ridges arranged all
round the incisions of the axile plate (Fig. 24). They are fairly large, very

Z

300 Carter.— Sht dies on the Chloroplasts of Desmids. II.

sharply defined, and have their free edges produced to form outgrowths of
various shapes. The two median ridges continue for some distance beyond
the incisions on each side of the polar lobe, but never extend quite as far
as the nucleus. The pyrenoids are large and number from twelve to
fifteen.

M. apiculata , (Ehrenb.) Menegh. x 510.

M. rotata and M. apicidata.

The most striking feature of the chloroplasts of these two species is
that there are two very prominent ridges on each side of the axis stretching
right from the nucleus to the apex of the chloroplast. These are rather
larger in M. apicidata than in M. rotata because of the relatively greater
thickness of the cell; cf. Text-fig. with Figs. 9 and 10. In the former
species there is in addition a series of ridges, almost equally striking,
following the outlines of the principal incisions of the axile plate. In
M. rotata ridges are usually wanting in the lateral lobes of the cell, and
even if present they are only very slightly developed. The pyrenoids in
M. apicidata usually number about thirty ; in M. rotata they are often
much more numerous, and may be more than eighty.

M. radiata and M. Crux- M elite nsis.

The chloroplasts of these two species are quite similar to each other
(Figs. 15, 17, and S3). The axile plate extends for quite a considerable
distance into the peripheral outgrowths of the cell-wall, and has two rather
definite median ridges projecting from both its surfaces. There are various
other ridges (Fig. 18), very irregularly arranged, perhaps more so in the
case of M. radiata than in M. Crux-Melitensis . In the only specimen of
the latter species examined there were about thirteen pyrenoids in each
semi-cell, whilst in M. radiata they vary from eight to thirty.

Carter . — Studies on the Chloroplasts of Desmids. II. 301

M. pinnatifidat.

In this tiny species two very prominent median ridges are to be seen
in the front view, and towards the lateral edges of the cell the plate thickens
abruptly, at the same time splitting into two lamellae. This is best seen
in the end view (Fig. 12). It was only possible to examine one individual,
and this had three pyrenoids in each semi-cell, one in the polar lobe and one
in each lateral lobe of the cell (Fig. 11).

M. Americana.

This species has ridges which are very large and conspicuous, but
probably unbranched. There are two very distinct median ridges visible
in the front view, but these usually seem to be displaced either to one side
or the other (Fig. 13). This is due to the fact that the front faces of the
cell are not flat, and the cell is much thicker in the middle than at the
edges (Fig. 14). Consequently the cell always tilts over to one side when
resting on a flat surface. The peg-like outgrowths of the cell-wall on the
polar lobe are usually the cause of this tilting to one side of the cell, but in
the variety examined these were not strongly developed.

Besides the median ridges of the chloroplast there are various others
radiating from the region of the nucleus towards the periphery. In spite
of the thickness of the cell, the central axis, as in all the other species
dealt with so far, retains its definite plate-like form. In Fig. 14 the axis
is seen to be very distended with stroma starch, which has not yet, however,
spread as far as the ridges. The pyrenoids number about twelve to fifteen
and are scattered throughout the axis of the chloroplast.

M. oscitans) var. mucronata , and M. truncata .

These two species have relatively thicker cells than any of the others
which were examined. In both the ridges are variable in number, but they
are always large and very much branched, quite superseding the central
axis in their much greater development (Figs. 21 and 27). The delicacy
of the branching of the chloroplast is largely dependent on the amount of
stroma starch present in it. The formation of much starch causes the
chloroplast to become very distended, and thus the elegance of the stroma
starch-free chloroplast is lost ; cf. Figs. 20 and 21.

The shortening of the axile plate in the median region of the cell is
frequently considerable, and the chloroplast is in consequence often distinctly
bilobed (Figs. 19 and 25). In such cases a transverse section near the top
of the semi-cell is quite different from one near the nucleus. The former
naturally cuts through the two separate lobes of the chloroplast, and two
distinct masses are to be seen (Fig. 22), whilst towards the base of the
semi-cell a continuous central axis is seen with various plates or branched

Z 2

302 Carter. — Studies on the Chloroplasts of Desmids. II.

ridges stretching towards the cell-wall in all directions (Fig. 21). In the
front view two median ridges are usually quite conspicuous in comparison
with the others, and that part of the central axis lying between them, even
where it is present, is often very delicate and only found after careful
focusing (Fig. 25). Occasionally specimens of M. truncata have been
observed in which two distinct chloroplasts were present in each semi-cell,
the axis in the median region of the cell being altogether absent, but as
a rule the remains of the axile plate can be seen just above the nucleus.

When there is a very extensive hollowing away of the axis in the
upper part of the semi-cell, the ridges in the apical region often spread
themselves closely over the inner surface of the cell-wall, forming a more or
less definite parietal layer (Figs. 25 and 26).

The pyrenoids in both species vary very much in size, and usually
number about five to ten in each semi-cell, although there may be as many
as twenty. They are usually to be found embedded in the thicker parts
of the chloroplast, where the ridges arise from the central axis, or even in
the more peripheral parts of the ridges themselves. Occasionally pyrenoids
occur in the parietal part of the chloroplast in the apical lobe where the
axis in this region is wanting (Fig. 26), but the majority of the pyrenoids
are always to be found in the interior of the cell. They are very often seen
to be in a state of active division, two or more small ones being constricted
off from a single large one.

Summary of the Special Characters of Micrasterias .

In all the species examined there is normally one chloroplast in each
semi-cell, and all the different forms encountered can be considered as
variations of one simple type.

There is always a more or less distinct axile plate parallel to the front
faces of the semi-cell in the central position, and from this there usually
arise numbers of ridges or plates which project towards the cell-wall in
various directions. The relative size of the axis and ridges varies with
different species.

The prominence of the ridges seems to depend on the thickness of the
cell ; in the more flattened cells of some species they are insignificant and
may under certain physiological conditions be altogether absent, but in the
thicker celled species they are very large and may sometimes even be
branched. The ridges in the latter case constitute by far the more
important part of the chloroplast, the axis often becoming very thin and
indefinite in form.

With the increase in size and importance of the ridges, the pyrenoids
become more restricted in number and disposition, occurring only in the
more massive parts of the chloroplast.

Carter . — Studies on the Chloroplasts of Desmids . //. 303

In most species a tendency was noticed for the axis of the chloroplast
to become shortened in the apical lobe of the cell. This is more pronounced
in the thicker celled species, in which the chloroplast may even tend to
become parietal in this region by reason of the absence of the axis. Some-
times the shortening of the axis in the median region extends through
the whole length of the semi-cell, in which case two chloroplasts are present
instead of one.

(r»

In conclusion, I wish to express my gratitude to the Birmingham
Natural History and Philosophical Society and also to the Royal Society
for grants to help in the cost of reproducing the plates illustrating this
work. My thanks are also due to Professor G. S. West for much valuable
help and advice throughout the investigation.

The Botanical Laboratory,

University of Birmingham.

Bibliography.

Delponte, J. B. (1873) : Specimen Desmidiacearum subalpinum , Augustae Taurinorum. Memor.

d. R. Accad. d. Scienze di Torino, Ser. 2, vol. xxviii, 1873.

Lutkemuller, J. (1910) : Zur Kenntnis der Desmidiaceen Bohmens. Verhandl. der k. k. zool.-bot,
Gesell., lx, 1910.

Ralfs, J. (1848) : The British Desmidiaceae. London, 1848.

West, W. and G. S. (1904-11) : Monograph of the British Desmidiaceae. Ray Society, vol. i,
1904; vol. ii, 1905; vol. iii,. 1 908 ; vol. iv, 1911.

DESCRIPTION OF PLATES XIX AND XX.

Illustrating Miss N. Carter’s paper on Chloroplasts of Desmids. II.

During the prolonged processes of preparation the specific characters of Desmids often become
obliterated, but all the species were identified, either in the living or carefully fixed condition, by
Professor G. S. West.

PLATE XIX. (All x 510).

Fig. 1. Micrasterias conferta, Lund.

Figs. 2-8. AI. denticulata , Breb. Fig. 2, front view ; Fig. 3, longitudinal median section ;
Figs. 4-8, transverse sections taken at intervals from the sinus to the apex of the semi-cell, showing
the large axile plate, and the comparatively small ridges cut in various directions.

Figs. 9 and 10. M. rotata , (Grev.) Ralfs. Fig. 9, front view of semi-cell ; Fig. 10, slightly
oblique transverse section, showing the median ridges cut transversely.

Figs. 11 and 12. M. pinnatifida, (Kiitz.) Ralfs. Fig. 11, front view; Fig. 12, optical transverse
section.

PLATE XX. (All x 510).

Figs. 13 and 14. M. Americana , (Ehrenb.) Ralfs, var. Lewisiana, West. Fig. 13, front view ;
Fig. 14, optical transverse section, showing the axis of the chloroplast greatly distended with starch.

304 Carter. — Studies on the Chloroplasts of Desmids. II.

Figs. 15-18. MPradiata, Hass. Fig. 15, front view of semi-cell showing the bilobed form of
the chloroplast owing to the shortening of the axis in the median region ; Fig. 17, front view of
another individual which does not show this phenomenon ; Fig. 16, longitudinal oblique section,
the ridges cut irregularly in surface section ; Fig. 18, transverse section.

Figs. 19-22. M. oscitans, Ralfs, var. inucronata, (Dixon) Wille. Fig. 19, front view of individual
having a distinctly bilobed chloroplast in each semi-cell ; Fig. 20, transverse section showing the
whole chloroplast distended with stroma starch; Fig. 21, transverse section of an individual whose
chloroplast contains little starch excepting in the immediate neighbourhood of the pyrenoids ; Fig. 22,
transverse section of a specimen whose chloroplast is deeply cleft owing to the shortening of the
axis in the median region.

Fig. 23. M. Crux-Melitensis, (Ehrenb.) Hass., front view.

Fig. 24. M. papillifera , Breb., front view.

Figs. 25-27. M. truncata , (Corda) Breb. Fig. 25, front view of an individual, the axis of whose
chloroplast is much shortened and very delicate in the median region ; Fig. 26, surface view of the
polar lobe of J:he same individual seen from the end, showing how the cell-wall is mantled with
parietal films of chloroplast when the axis is wanting in this region of the cell ; Fig. 27, optical
transverse section of the basal part of the semi-cell.

Annals of Botany,

N. CARTE R-MICRASTERIAS

Vol.XXW,Pl. XIX.

London.

,

■ V'' 'A- . '

'

cAmwls of Botany,

voi.mm, pi. xx.

17.

Huth (London

Annals of Botany,

N. CARTER — MIC RASTERIAS,

Vo i. mm, pi. ix.

17.

Huth, London.

.

faiSM

i

Studies in the Physiology of Parasitism.

V. Infection by Colletotrichum Linde muthianum.

BY

P. K. DEY, B.Sc.

From the Department of Plant Physiology and Pathology , Imperial College of Science and

Technology, London.

With Plate XXI.

IN all previous works on bean anthracnose caused by the well-known
parasite Colletotrichum Lindeniuthianum , no observations of the actual
mode of infection have been made. Whetzel (14) gives a diagram of
penetration of the germ-tube through the outer surface of the bean-pod but
he does not appear to have made any study of the details of penetration.
Frank (6) observed that the germ-tubes of C. Lindeniuthianum produced on
the surface of the host dark-brown appressoria from which infection took
place, but he neither described nor gave any figures of the process of
infection.

In the case of infection by Botrytis cinerea , workers like Biisgen (4)
and Marshall Ward (12), believed that the germ-tube effected its entrance by
softening and dissolving the cuticularized epidermal wall of the host ;
Voges (11) also speaks of the slime formed by the germ-tube of Fusicladium
softening the cuticle. But, as pointed out by Blackman and Welsford (1),
no critical observations were in any case made. It was Brown (2) who,
working with B. cinerea , first showed that the cuticle of the host is quite
unaffected by the powerful extract which he obtained from young hyphae.
When such an extract is placed on a delicate, uninjured rose petal, the
cuticle and the underlying tissue remain unchanged ; when placed on
wounded petals, however, disorganization of the tissue takes place in a very
short time. He thus indicated that the germ-tubes of B. cinerea have no
power of causing a softening of the cuticle, and that the latter is im-
permeable to the enzymes which dissolve the non-cuticularized walls. It
thus seemed probable that penetration of the cuticle by the germ-tube takes
place by mechanical means. Blackman and Welsford (1) made careful
microscopic study of this question, and showed that the passage of the germ-

[ Annals of Botany, Vol. XXXIII. No. CXXXI. July, igig.]

306 Dey. — Studies in the Physiology of Parasitism. V.

tube of B. cinerea into the bean-leaf was effected by a rupture of the cuticle,
due to the mechanical pressure exerted by the germ-tube.

The object of the present work was to make a careful microscopic
examination of the stages of infection of the bean by Colletotrichum
Lindemuthianum , and to discover if this fungus, belonging to a quite
different group, acts in the same way as Botrytis cinerea.

Methods . The cultures were made mostly in a medium of maize-
meal agar, also on French bean-pods, autoclaved in test-tubes. The maize-
meal agar medium was made in the following way — 30 grm. of maize-meal
were cooked in 1,000 c.c. water at ioo° C. for half an hour. To this
15 grm. of agar were added, and the mixture heated to no° C., to dissolve
the agar. The medium thus prepared was ‘ tubed ’ and autoclaved at
1200 C. for 20 minutes.

Spores were sown on slopes and Petri dishes. In three to four days
small white patches appear. Examination of the young growth shows
a felted mass of fine hyphae, with indications here and there of formation
of acervuli. The hyphae frequently swell up into vesicles, as described
by Stoneman (9), and branch copiously, giving a knotted appearance to the
mycelium. After six days these spreading patches were dotted over with
very small black areas, which even with a hand lens were seen to consist of
very dark spines enclosing a pinkish spore mass. The spores are borne on
short erect hyphae, which arise from swollen vesicles, and are abjointed from
the tips of the hyphae, two or three in a series. At the same time mucilage
is formed which surrounds the spores. After a few more days of growth
acervuli become still more numerous, and gradually turn the white back-
ground of mycelium into a black mass. The spore masses are now visible
to the naked eye as round pinkish globules. The hyphae of the fungus
are colourless, but the dark appearance of an old colony is due to the black
stiff spines of the numerous acervuli. In cultures a month old or more, the
spore masses, instead of remaining as moist pink globules, seem to dry up
and shrink, becoming at the same time rather creamy in colour. They also
become set with dark-coloured spines, so that old cultures become almost
uniformly black and rugged in appearance.

Germination of Spores. Spores from cultures about two weeks old
were sown in thin films of sterile tap-water on a clean and flamed slide
kept in a Petri dish containing sterile, moist blotting-paper. Under these
conditions spores germinate quite readily in 18-24 hours at 20°-25° C. —
the optimum temperature for the growth of the fungus, according to
Edgerton (5), lying somewhere between 2i°-23° C. It was observed that
if the drop of water containing the spores had a sharp convex surface,
spores lying in the middle of the drop hardly germinated, while most of
those lying near the border did ; this difference of behaviour is probably
due to difference in oxygen supply. During the early stages of germina-

Dey.— Studies in the Physiology of Parasitism. V. 307

tion the spores swell up and become rather constricted in the middle, and
thus have a more or less dumb-bell shaped appearance, as observed by
former workers ; they sometimes become septate. A germ-tube comes out
generally from one end of the spore, but the rare, septate ones produce
a germ-tube at each end. In a very few cases more than two germ-tubes
were found to develop from a spore. The germ-tube, as it grows, comes
in contact with the hard surface of the glass, and as soon as this occurs its
tip swells out into a dark-brown, thick-walled, spore-like body, the
appressorium (of Frank) or adhesion organ. Muncie (10) holds that the
appressorium is not formed until the germ-tube has reached a certain
length. Observation shows, however, that it is formed whenever the
germ-tube touches a hard foreign substance; thus it may be produced
soon after the germ-tube comes out of the spore, so that it lies almost in
contact with the spore (PI. XXI, Fig. 3 A) ; on the other hand, the germ-tube
may grow to a considerable length before it is produced (Fig. 3). As to the
stimulus necessary for its formation, there is no doubt it is the result of
contact, as Hasselbring (7) has shown in the case of Gloeosporium fructi-
genum. In this species Hasselbring observed a distinct germ-pore in the
appressorium, through which a hypha later grows out. In C. Linde -
muthianum , however, no such germ-pore is to be found, the hypha
always arising at the point of contact of the appressorium with the glass,
whatever orientation the appressorium may possess. The young appres-
sorium is sheathed in a mucilaginous coat (Figs. 4, 4 a). This can clearly
be demonstrated by staining with very dilute watery gentian violet for
30 seconds, or by mounting the germinated spores in ‘ collargol ’ (1). By
means of this sheath the appressorium becomes attached to the surface, so
that even a fairly strong jet of water does not remove it. In fixed and
stained preparations this mucilage appears to be reduced by the dehydrating
agents to irregular granules and threads, analogous to the similar structures
observed in the germ -tube of Botrytis cinerea by Blackman and Welsford (1).

Penetration of the Germ-tube into the Host. In following the details
of penetration by the young ‘ infection hypha ’, freshly picked, young,
juicy pods of French bean ( Phaseolus vulgaris , vars. Canadian Wonder and
Brown Dutch) were used. These two varieties were found to be very
susceptible to the disease. The size of the bean-pods varied from 5 to
8 cm. long by about § cm. wide. In such young pods the cuticle is thin,
and so they were likely to prove suitable for infection studies. Young
leaves were first tried, but as their cuticle and the outer walls of their
epidermal cells are exceedingly thin, such leaves were found unsuitable for
observation of the changes occurring in the cuticle and subcuticular layers
during penetration. Spores were taken from a culture on maize-meal agar
which had been at 250 C. for about a month ; these were stirred thoroughly
in 1 c.c. of sterile tap-water till the mucilage holding them together in

3o8 Dey.— Studies in the Physiology of Parasitism . V.

masses was removed and a uniform suspension was obtained. Ordinary
tap-water was used instead of a nutrient solution, as used by Blackman and
Welsford in similar experiments with B.’cinerea , as infection readily occurs
in this, the normal medium, under natural conditions. The density of the
suspension was estimated with the naked eye, till a faintly milky appearance
was arrived at.

Small drops of this suspension were placed on bean-pods, pre-
viously washed thoroughly with sterile water to remove dust and foreign
spores, and kept in a moist chamber. Care was taken that the drops
spread out in thin films, so that nearly all the spores might be under
similar condition of oxygen supply. The pods were then incubated at
250 C. On the second day, that is twenty-four hours after sowing, small
bits of the pod under the ‘ infection drops 1 (3) were cut out every four
hours, and fixed, generally in Carnoy’s fluid (absolute alcohol, 6 parts ;
chloroform, 3 parts; glacial acetic acid, 1 part), but sometimes in
Flemming’s stronger solution of half strength. The tissue underneath the
c infection drop’ does not show any sign of infection during early stages, so
that it is not possible to gauge by the eye the stage of infection reached.
Now and then small brown spots were visible with the microscope below
the ‘ infection drop ’ ; Frank noticed those spots about twenty-four hours
after sowing the spores, and held that they were due to infection. These
spots, however, appear even when tap-water is substituted for the ‘infection
drops Thus they are not the result of infection, but may be due to
osmotic disturbances.

The fixed material was embedded in paraffin, and in every case
sections 4 ^ in thickness were cut. Heidenhain’s iron-alum haematoxylin
and erythrosin were first used for staining, but as erythrosin does not bring
out the cuticle, a counterstain, Sudan III, was employed instead. In
making up this stain o-oi grm. of Sudan III (Griibler’s) is first made into a
paste with absolute alcohol, and then made up to 5 c.c. with 95 % alcohol. It
is allowed to stand for a few days, and then 5 c.c. of pure glycerine are
added to it. Sections thus stained were mounted in glycerine jelly (10).

Observations. The germ-tube produced by the spore soon forms
a brown, thick- walled, more or less spherical appressorium on the surface
of the pod (6). The appressorium is pressed closely against the surface,
the part in actual contact with the pod becoming somewhat flattened. The
appressorium appears to be held on the surface by means of its mucila-
ginous sheath. The spore is also fixed in some way to the surface, though
no mucilaginous envelope has been observed around it ; further growth of
the germ-tube thus causes the tube to curve up, since it is fixed at both ends
(Fig. 5). Some pressure is thus exerted on the surface, and, no doubt as
a result of this, a slight indentation of the wall of the epidermal cell is to
be observed. This is the first preliminary to penetration.

Dey. — Studies in the Physiology of Parasitism. V. 309

In material on which spores have been growing for 24-40 hours,
nothing beyond this preliminary stage is to be observed. The activities
of the young germ-tube during this period are confined to the production
of the appressorium, for the development of the infection hypha is never
observed earlier than forty-eight hours after sowing, while the appressoria
may be formed within twenty-four hours. Muncie held that the incuba-
tion period (between sowing and penetration) varied from 3^ to 6 days,
according to the amount of moisture present and the temperature.
Edgerton was not able to obtain definite signs of infection earlier than four
and a half days after sowing (8). These workers, of course, did not observe
the very earliest stages of infection investigated here.

The next stage in infection is the development of a slight protuberance
on that part of the appressorium in contact with the cuticular surface.
This protuberance pushes in the cuticle still farther, so that a distinct
hollow is formed on the surface (Fig. 5 a). From this protuberance there
now develops a very fine peg-like outgrowth, the ‘ infection hypha ’, which
stains homogeneously, and in which the distinction of wall and cavity
could not be observed.1 As the result of the development of the ‘ infection
hypha 5 a rupture is caused in the relatively inelastic cuticle (Fig. 6).
A very careful and searching study was made for evidence of disorganiza-
tion or swelling or any other change in the cuticle at this stage or later,
but no such evidence was obtainable. C. Lindemuthianum forms then no
special substance which is capable of producing softening or chemical
change in the cuticle. These facts prove that, as in the case of B . cinerea ,
the f infection hypha ’ obtains entrance by breaking or rupturing the cuticle
of the host as the result of the pressure exerted by the development of
the ‘ infection hypha ’ arising from the appressorium. In sections this
rupture is indicated by a break in the continuity of the cuticle near the
peg (Figs. 7, 8, 10, 14, 15). The perforation to be observed is considerably
wider than the ‘ infection hypha’ itself. This may be explained by the fact
that the epidermis of the bean-pod is no doubt in a state of tension, owing
to the turgescence of the inner tissue.2 When the ‘ infection hypha ’ enters
through the cuticle and brings about softening and disorganization of the
subcuticular layers, the cuticle is free to contract at that particular spot,
and consequently the aperture is widened.

Once the cuticle is ruptured, the pressure due to growth in length of
the germ-tube forces the appressorium a little farther into the surface of
the pod ; this is well seen in Fig. 15. In the same figure it is to be noted
that the penetrating peg, which is at first exceedingly fine, swells into
a hypha of normal size soon after it reaches the softer cellulose layers.

1 The relation of the ‘ infection hypha ’ to the inner and outer layers of the appressorium could
not be determined.

2 That the outer tissues of the fruit are so stretched can be well demonstrated in the cucumber.

310 Dey. — Studies in the Physiology of Parasitism. V.

The passage of the fungus through the cell-wall is associated with
a swelling and dissolution of the cellulose layers. The first sign of this
action on the wall is the disappearance of the uniform stratification of the
cell-wall, and the appearance of a clearer area round the ‘ infection hypha ’.
No such change in the subcuticular layers is to be noticed, however, before
the break in the cuticle is effected. The cuticle apparently bars completely
the passage into these layers of any enzyme secreted by the £ infection
hypha’. The behaviour of C. Lindemuthianum is in this respect quite
analogous with that of B. cinerea.

The ‘ infection hypha after growing a short distance into the host,
produces at its end a small vesicle (Figs. 9, 10, 11, 12, 13, 14) from which one
or more branches emerge and spread through the host tissue. This vesicle
may be developed in the swollen subcuticular layers of the wall, or its
formation may be delayed till the ‘ infection hypha ’ has penetrated far into
the cell. This vesicle appears to be similar to that described by Marshall
Ward (13) for the infection process in Uredo dispersa ; the nature of this
vesicle is obscure.

The effect of the entrance of the hypha into the host-cell is to be
observed in Figs. 14, 15, 16. From these figures it is evident that the
collapse of the cell immediately beneath the place of entry takes place
only after a hypha is well established in its cavity ; the invading hypha
may be the original ‘infection hypha’ (Fig. 15) or a branch from the
‘ vesicle ’ (Fig. 16). When the ‘ infection hypha 5 enters the cavity of the
cell, the protoplasmic contents of the latter apparently flow towards the
hypha and collect round it (Figs. 13, 14, 15). Movement of nuclei, similar
to that found by Blackman and Welsford in the bean-cell invaded by
B. cinerca , has never been observed in this case.

The stomata of the host do not seem to afford an easier channel of
infection than that through the epidermal cell. Only one instance of the
passage of an ‘infection hypha’ through the stoma was found in all the material
examined. Even there infection has taken place from an appressorium in
the usual manner, and not directly by the germ-tube (Fig. 17).

In conclusion, the author wishes to express his gratitude to Professor
V. H. Blackman, at whose instigation the work was undertaken, and from
whom he has throughout received most helpful criticism and advice.

Summary.

The spore of Colletotrichum Lindemuthianum , when germinating on
the host plant, produces a germ-tube, which directly it comes in contact
with the host surface develops at its end a thick- walled, dark-coloured
appressorium. The appressorium becomes attached closely to the surface
by the help of its mucilaginous envelope.

Dey— Studies in the Physiology of Parasitism. V. 31 1

From the surface of the appressorium in contact with the host, a peg-
like £ infection hypha * grows out, which ruptures mechanically the cuticular
layer, and then brings about swelling of the subcuticular layers, no doubt
by enzymic action.

There is no evidence that the ‘infection hypha’ can exert any swelling,
disorganizing, or other chemical action upon the cuticle.

The mechanism by which the ‘ infection hypha ’ of C. Lindemuthianum
penetrates the host surface is thus in all respects similar to the mechanism
employed by the germ-tube of Botrytis cinerea .

References.

1. Blackman, V. H., and Welsford, E. J. : Studies in the Physiology of Parasitism. II. Infection

by Botrytis cinerea. Ann. Bot., vol. xxx, p. 389, 1916.

2. Brown, W. : Studies in the Physiology of Parasitism. I. The Action of Botrytis cinerea. Ann.

Bot., vol. xxix, p. 313, 1915.

3. : Studies in the Physiology of Parasitism. III. On the Relation between the

‘ Infection Drop’ and the Underlying Host Tissue. Ann. Bot., vol. xxx, p. 439, 1916.

4. Busgen, M. : Ueber einige Eigenschaften der Keimlinge parasitischer Pilze. Bot. Zeit., vol. i,

P- 53, 1893.

5. Edgerton, C. W. : Effect of Temperature on Glomerella. Phytopath., vol. v, p. 247, 1915.

6. Frank, B. : Ueber einige neue, weniger bekannte Pflanzenlcrankheiten. Land. Jahrb., vol. xii,

p. 511,1883..

7. Hasselbring, H. : The Appressoria of the Anthracnoses. Bot. Gaz., vol. xlii, p. 135, 1906.

8. Muncie, J. H. : Experiments on the Control of Bean Blight. Michigan Agri. Coll. Expt. Sta.

Technical Bull., 38, 1917.

9. Stoneman, B. : A Comparative Study of the Development of some Anthracnoses. Bot. Gaz.,

vol. xxvi, p. 69, 1898.

10. Strasburger und Koernicke : Botanisches Praktikum, 5th ed., p. 809, 1913.

11. Voges, E. : Die Bekampfung des Fusicladium. Zeit. f. Pflanzenkrank., vol. xx, p. 385, 1910.

12. Ward, H. M. : A Lily Disease. Ann. Bot., vol. ii, p. 319, 1888.

13. : On the Histology of Uredo dispersa , Erikss., and the ‘ Mycoplasm ’ Hypothesis.

Phil. Trans., B., vol. cxcvi, p. 26.

14. Whetzel, H. PI. : Some Diseases of Beans. Cornell Univ. Agri. Expt. Sta. Bull., 239, 1906.

15; - — : Bean Anthracnose. Ibid., 255, 1908.

EXPLANATION OF FIGURES IN PLATE XXI.

Illustrating Mr. Dey’s paper on Physiology of Parasitism.

All figures except 1-4 a were drawn with the camera lucida, under Koristka in semi-apochro- '
matic, oil-immersion objective, and No. 8 eyepiece. Figs. 1-4 A were drawn under Leitz j1^ in. oil-
immersion objective, and No. 4 eyepiece.

The host tissue figured is that of the pod of Phaseolus vulgaris.

Fig. 1. Germinating spore, x 1050.

Figs. 2-3 a. Germinating spore, showing the appressorium : drawn from material fixed in
picro-nigrosin after twenty-four hours of growth, x 1050,

3i 2 Dey. — Studies in the Physiology of Parasitism. V.

Figs. 4, 4 A. Germinating spore, showing mucilaginous sheath round the appressorium : drawn
from fresh material stained with dilute gentian violet, x 1050.

Fig. 5. Germinating spore attached to the epidermis. The germ-tube is curved and is fixed at
both ends, x 1500.

Fig. 5 A. A slight protuberance on the appressorium causing an indentation of the wall of the
host. The mucilage round the appressorium appears to be reduced to thread-like structures, x 1500.

Fig. 6. The ‘ infection hypha’ has grown out from the appressorium and penetrated the cuticle,
x 1500.

Figs. 7, 8. The ‘ infection hypha ’ is growing in the subcuticular layers after effecting its entrance
by perforating the cuticle. The hole produced in the cuticle is somewhat wider than the ‘ infection
hypha’. x 1500.

Fig. 9. A somewhat later stage than Fig. 8. Swelling and disorganization of the cell-wall is
clearly seen, x 1500.

Figs. 10, 11. The ‘infection hypha’ is swollen into a vesicle in the disorganized cellulose
layers, x 1500.

Fig. 12. A somewhat later stage than Fig. 11. The vesicle has given origin to a branch,
x 1500.

Fig. 13. The vesicle and its outgrowth are visible. Swelling and disorganization of the sub-
cuticular layers have taken place. The protoplasm of the epidermal cell appears to have accumulated
in the upper part of the cell, probably as the result of the action of the invading hypha. x 1500.

Fig. 14. The ‘infection hypha ’ has formed the vesicle after passing into the cavity of the cell.
Disorganization of the wall and the protoplasm has occurred, x 1500.

Fig. 15. The ‘ infection hypha ’ has passed into the cavity of the epidermal cell. Disorganization
of the protoplasmic contents is well advanced. The break in the cuticle is now much enlarged and
the appressorium is pressed slightly into it. The ‘ infection hypha ’, which is very narrow at its base,
has swollen into a hypha of normal size in the layers of the cell-wall below the cuticle. The
protoplasm of the cell appears to have accumulated round the ‘infection hypha’. x 1500.

Fig. 16. The ‘infection hypha’ passing into the cavity of a guard cell has swollen out into
a vesicle, and has caused shrinkage and death of the cell, x 1500.

Fig. 17. The appressorium has formed over a stoma. The ‘injection hypha’ is growing down
through the pore of the stoma, x 1500.

c/frzriaZs of Botany,

P.K.D. del.

DEY — COLLETOTRICHUM

voi^xmun.xxi.

Hath lith. et imp.

Variation in Hevea brasiliensis.

BY

, STAFFORD WHITBY, M.Sc., A.R.C.S.,

McGill University , Canada.

With one Diagram in the Text.

IT was desired to secure data as to the extent to which variation occurs
in the amount of rubber yielded by individual trees of Hevea brasiliensis ,
of the same age and growing under the same conditions, and as to the
possible correlation between the yield of rubber and the girth of the trunk.

In addition to data directly relative to the matter just mentioned, the
observations which have been made afford information concerning the
extent of variation in the rubber content of the latex from individual trees
and concerning a number of other points noticed in what follows.

The observations were made in the Federated Malay States. A normal
area of plantation rubber trees, 7 years old, was selected. The area was
approximately 13 acres in extent and contained 1,338 trees, planted 20 feet
square. Of these trees 1,137 were in tapping. The trees comprising the
balance of 201, not in tapping, were mostly ‘ supplies i. e. trees which had
been put in since the area was first planted up in order to fill vacancies
caused by disease, pests, wind, &c. These trees were of course younger
than the other trees on the area and, owing to overshadowing, had not had
a good chance to grow. They were, in fact, all removed in the ordinary
course of thinning-out operations on the plantation in question soon after
the close of the observations recorded here. Of the 1,137 trees in tapping,
106 were one year behind the remainder in their tapping history ; having
attained a trunk-girth up to the standard fixed for the commencement of
tapping operations about one year later than the rest of the trees. Some
of them doubtless represented the original plantings, but others no doubt
represented ‘ supplies ’. As no means were available for distinguishing
original plantings in this group from c supplies \ and as these trees were
being tapped at a lower point on the trunk than the rest, they are not
included in the present survey. Of the remainder of 1,03 1 trees, 20 are not
included because of incompleteness of the record or failure of the tappers to
cut deep enough. The data refer, therefore, to a population of 1,01 1 trees,
in their third year of tapping, on a normal plantation area of seven-year-
old Para rubber. They serve sufficiently well to indicate the extent of

[Annals of Botany, Vol. XXXHI. No. CXXXI. July, 1919.] >

3T4

Whitby. — - Variation in Hevea brasiliensis.

variation between individual trees, in regard particularly to rubber yield, on
an area planted, as all the Eastern plantations have been, from non-selected
seed, and to suggest the extent of possible improvement in the yields of
plantations which seed selection might bring about.

Variation in the Rubber Content of Samples of Latex.

In order to decide as to whether the rubber content of the latex (the
‘ strength ’ of the latex) was sufficiently constant to make it feasible to
lighten the burden of collecting yield data from individual trees by
measuring volumes of latex instead of taking weights of rubber, the
strength of the latex from a number of individual trees in the population
was determined. These determinations revealed unexpectedly great
variations in the strength of the latex from different trees. A frequency
table for the samples of latex from the 245 trees examined is given in
Table I. In each case the latex was diluted with an equal volume of water,
and coagulated with acetic acid ; the coagulum was converted into crepe,
and the crepe, after being allowed to dry in the air, was weighed.

It was found that the strength of the latex from a given tree was
approximately constant on different days,1 and appeared to be characteristic
for the individual tree. Several trees were kept under observation for more
than a year ; and it was found in these cases that, although, as was
expected, the strength of the latex from a given tree changed to a certain
extent with the weather, yet a tree yielding at one time latex with a rubber-
content clearly higher than the average could be relied upon to yield
strong latex at all times (and vice versa),2 and that, by taking samples of
latex from a number of trees over a short period such that weather
conditions would not be likely to affect the trees to seriously unequal
extents, a very fair comparison of the trees in respect of this characteristic
could be made.

Table I.

Rubber Content of Latex from 245 Trees of Hevea brasiliensis , Seven

Years Old.

Grm. rubber per
100 c.c.

us On *-< cc 10 j>. o\ t-t co 10 w c\ m ro in

<N «M d CO CO COCOCO

CO | | 1 I I 1 i I I I I I I 1 I I

<N -rt-vooo O <N Tt-vooo o <M ^t-vooo O <N t*-
ci <m o cococococo^-',^-ri-Tj-Thif5ir5io

Frequency

4 2 7 n 16 27 44 35 23 32 17 12 5 1 4 3

Mean = 36*58 + 0.25 per cent.3 <r = 5*86 + 0*17 per cent. CV. = 16*02+0*49 per cent.

2

1 The trees were tapped once a day only — in the early morning. It was found that when trees
were tapped in the afternoon as well as in the morning the strength of the latex obtained on the
second occasion was usually markedly lower than of that obtained on the first.

2 Cf. Bulletin No. 13, Dept. Agric. Ceylon, 1914.

3 This figure, it should be noted, refers to seven-year-old trees. The age of a tree is a factor
in determining the strength of its latex. The author concluded from a limited number of observations,
concerning areas from four to eighteen years old, that, as a tree grows older, the rubber content of
the latex yielded by it increases 1-2 per cent, per annum.

3i5

Whitby. — Variation in Hevea brasiliensis .

The samples of latex included in the table were taken mostly from
the larger yielding trees (mean yield n*8 grm. per diem). The figures did
not, however, indicate that there was any correlation between yield and
latex strength. The figures may thus be considered as fairly indicative of
the whole population in regard to the strength of the latex.

Variation in Yictd.

The exact magnitude of the yield of rubber given by any one tree
varied at different times, but was found to be, in general, sufficiently
constant to allow of a fair comparison of the yielding capacities of the trees
on a given area under similar tapping conditions being made by taking the
mean of the yields on a number (in these observations, mostly six, but in
some cases ten to twelve) of separate days.

It seemed clear that, although the actual magnitude of the yield from
a given tree varied to a certain extent at different times, owing to variations
in fortuitous circumstances, such as the rainfall, the prevailing humidity,
the depth of tapping, the hour at which tapping is performed, yet trees
presented characteristic differences in their capacity for yielding rubber,
and, at all events in a first investigation, might reasonably b® compared in
respect of this capacity by taking measurements under conditions such that
variations in the fortuitous factors which influence the yield were as far as
possible avoided, or affected all trees equally, and by, in addition, basing
conclusions for any given tree on the mean of several determinations.

In addition to the evidence as to the comparative constancy of the
yield from individual trees, which the considerable body of data summarized
below afforded when examined in detail, further evidence in support of this
conclusion was secured by keeping a limited number of trees under obser-
vation for a longer period than that covered by the main series of measure-
ments. In the case of some of these trees the yield was determined at
intervals over a period of two years. It was clear that, although seasonal
variations in the yield took place, the yield for a given tree was in most
cases approximately constant over such a period. Speaking generally,
a tree which was seen to be a high yielder at one time could be relied upon
to give a high yield at all times.1

Concerning the factors which, apart from the characteristic yielding
capacity, affect the yield, the following points are noted :

(a) All trees were under the same tapping system (a single V-cut on

1 This conclusion may be considered as being in agreement with general plantation experience.
Trees are sometimes noted as falling off seriously in their yield or even as * going dry \ (It is pos-
sible that such behaviour may be due to disease or other abnormal conditions.) But, in general, it is
recognized that high yielding trees (which naturally come under notice more frequently than other
trees) can be expected, if not over-tapped, to give high yields during the whole of their tapping history.

Also cf. the records for the original generation of trees raised from the seeds first introduced into
the East from Brazil : Bulletins Nos. 4 and 13, Dept. Agric. Ceylon.

A a

3 1 6 Whitby . — Variation in Hevea brasiliensis .

half the circumference, reopened every morning) and had had the same
tapping history. They had been tapped for two successive years on the
two halves of the ‘basal’ section of the trunk, i.e. the portion extending
vertically from, say, 20 in. to 4 in. from the ground. In the succeeding year
of tapping, when the observations were made, they were tapped on the
section of the trunk immediately above the ‘basal ’ section, i.e. the section
from, say, 36 in. to 20 in. from the ground. On all trees the tapping cut
had advanced roughly the same distance down the section, viz. 6-8 in., at
the beginning of the survey.

Thus the height of the tapping cut on the trunk did not enter, as
a disturbing factor, into the observations.

(b) The trees were tapped by an experienced gang of tappers 1 by
means of the simple gouge. The depth of the tapping on each tree was
tested by a probe on each occasion that latex was collected from it. In
the case of trees where the tapping was clearly not deep enough, the latex
was not collected, and an instruction was issued to the tapper to go deeper
in the future. The percentage which had thus to be dealt with was not
very large. Finally, the records showed a small number of trees on which
the tappers had not succeeded in going sufficiently deep, and, as already
mentioned, these were excluded from the population surveyed.

It may be considered that the depth of tapping on the trees surveyed
represented the greatest accuracy in this direction which is practically
attainable.2

(c) In order to avoid as far as possible the disturbing effect on the
comparison of variation in weather conditions, not only was the figure for
the yield from each tree based on several measurements, but the times at
which the measurements for each tree were taken were distributed at
different points over the period of the observations. The period of the
year at which the trees lose their leaves was avoided for the observations,
as trees are very unequally affected by this ‘ wintering ’. The observations
were made over what may be regarded as four typical months in the

1 It may fairly be mentioned that the native tappers show a degree of skill with the tapping
gouge and an accuracy in excising thin strips of bark greater than any to which the author,
personally, could lay claim.

2 An attempt was made to classify the trees according to the degree of exactness with which
the fullest possible depth of tapping consistent with avoidance of injury to the cambium had been
attained, by estimating the extent to which further latex, if any, issued forth on probing at the
tapping level ; but it did not prove to offer any particular advantage in regard to the main object of
the investigation. It appeared that, excluding the cases already mentioned in which the tapping
was palpably not deep enough, the trees, on the one . hand, which would, on the ground that
deepening of the incision entirely failed to give more latex, be classed as being tapped fully deep
enough were in general those giving small yields, and the trees, on the other hand, which would, on
the ground that deepening of the incision gave somewhat more latex, be classed as not being tapped
quite deep enough were in general those giving large yields. Thus, it may be remarked, a still
more exact adjustment of the-tapping depth than that actually attained Avould merely have had the
general effect of increasing the contributions from the large yielders, and hence of making still more
clearly marked the characteristic features of the variation noted later.

W.hitby. — Variation in Hevea brasiliensis.

l7

Malay States, viz. August-November. The element in the weather which
most markedly influences the yield is the rainfall, the trees yielding better
in wet than in dry weather. The daily rainfall on the area during the
course of the observations was recorded. The monthly totals were :
Aug., 473 in. (rain on 13 days) ; Sept., 12*83 in. (18 days) ; Oct., 6-7 2 in.
(17 days); Nov. 9-46 in. (17 days).

The results obtained for the rubber yield from the trees surveyed are
summarized in the following frequency table :

Table II.

Rubber Yield from Population of 1,011 Seven-year-old Hevea brasiliensis .

Grm. per diem 0-1.5 2 3 4 5 6 7 S 9 10 n 12 13 14

Frequency 55 84 101 140 95 104 76 78 42 41 37 34 26 13

Grm. per diem 15 16 17 iS 19 20 21 22 23 24 25 26 27 and over1

Frequency 15 7 11 14 5 4 3 4 4 3 4 2 9

Mean yield = 7.12 ±0.115 grm.2 a = 5.425 + 0.08. Mode (by inspection) = 4.0 grm.
CV. - 76.19 + 1.14 per cent. Coefficient of skewness (on a) - +0.575.

The results are represented graphically in the following diagram :

The outstanding feature of the variation in rubber yield among the
population examined is sufficiently indicated by the high coefficient of
variability, and the marked positive skewness of the frequency curve, viz.
the presence of an important number of trees which are yielding amounts
of rubber several times larger than the modal value.

1 Mean of this group, 35.74 grm.

2 Equivalent to 5.49 lb. per tree per annum. Making due allowance for the effect of wintering,
for the time occupied by the establishment of wound response, &c., this figure accords fairly with the
vield of 360 lb. per acre per annum which the section of the plantation in question was giving over all.

Lump rubber, i. e. natural coagulum which forms in the collecting cups, is included in the
yields recorded, but 1 tree scrap i. e. rubber obtained from the latex which is left on the cuts after
the trees have ceased to drip, is neglected. The average amount of tree scrap which each tapping
gives is indicated by the following figures: (a) 195 trees gave 134 grm. tree scrap; (.6) 190 trees
gave 1I5 grm. tree scrap.

A a 2

3 1 8 Whitby. — Variation in Hevea brasiliensis.

It may be remarked, for example, that 9 *6 per cent, of the trees (trees
giving twice the mean quantity or more) was on the average yielding 3-6
times as much rubber per tree as the remainder of the trees. On the one
hand, 9-6 per cent, of the trees on the area was contributing 28 per cent, of
the total yield. On the other hand, 137 per cent, of the trees (Groups
0-2 gms.) was contributing only 2*9 per cent, of the crop, and certainly did
not repay the cost of tapping. The highest yielders in the population
were four trees giving the following yields per diem: 41*45, 41*56,. 4172,
42-77 1 grm.

The great possibilities of seed selection in improving rubber yields are
indicated by the above figures.

The data obtained have a certain bearing on the conduct of tapping
experiments. They show that the extent of variation on what is pre-
sumably a normal area may be such that it is quite impermissible to
assume, as is often done in tapping experiments, that small groups of trees
(say 50 or 100 trees) chosen at random from an area of uniform age,
situation, and appearance, will have the same yielding capacity, and hence
that differences in yield which the groups may display when different
tapping systems are applied to them are due to differences in the tapping
systems, and afford a true comparison of the yielding capabilities of the
systems in question. Thus, taking a point at random on the area with
which the present investigation deals, counting off from it 36 rows, and
arranging these rows in their order of succession, into groups of 3, 6,
and 12 rows, representing respectively groups of 45, 90, and 100 trees
we find the yields per group, under the same tapping system, to be as
follows : 2

Table III.

Yields from Adjoining Groups of frees, under the same Tapping System t
on an apparently Uniform Area .

Grm. rubber per diem.

Group of 45 trees. 284, 285, 204, 259, 260, 334, 392, 439, 328, 390, 325, 276.

„ „ 90 „ 569, 463, 594, 831, 718, 601.

„ „ 180 „ 1032, 1425, 1319.

1 Equivalent to a yield (calculated without making allowance for the reduction which
£ wintering &c. involves) of 33 lb. for a tapping year of 350 days.

It may be remarked that at an earlier point in its history one of these four trees had, according
to the estate records, been treated against an attack by white ants. It would seem certain, however,
that the high yield which it displayed during the period of the present observations was not due to
white ants, because ( a ) careful examination failed to reveal the presence of white ants and the tree
was certainly alive two years after the observations had been concluded, ( b ) the greatly increased
flow of latex which white ants are recognized as inducing is transient, whereas the present tree was
found to give large yields over a period of two years during which it was kept under observation.

2 The most frequent number of trees in a row was fifteen. In cases where the number was other
than this, the yield for the row has, for the sake of simplicity, been adjusted proportionately.

Whitby. — Variation in Hevea brasiliensis . 319

A number of observations were made on the problem of collecting
seeds from selected trees.

Owing to the circumstance that the seeds are often projected to
considerable distances from a tree when the ripe capsules burst, the seeds
lying on the ground under a given tree are not usually all derived from the
tree in question. In order to secure seeds whose origin was definitely
known, the author at first placed conical bags of wire-netting round the
capsules on the selected trees ; but it was later found sufficient to secure
one true sample of the seeds from a given tree, as it was observed that the
seeds from any one tree were exactly similar in appearance.1 The
differences which the seeds from different trees exhibit in regard to tint,
mottling, and size,2 are very marked, but perhaps even more noteworthy
than such differences is the accuracy with which the tint, the mottle-
pattern, and the shape, down to such peculiarities as slight striations on
one side, are repeated in all the seeds from a given tree. With a little
experience it was found possible, once a true sample had been secured to
act as a pattern, readily to pick out the seeds from a given tree from those
lying on the ground in its neighbourhood. It was often possible to avoid
the trouble of placing a number of wire-netting bags on the tree for the
purpose of securing a true sample by keeping the tree under watch for
a short time on a hot afternoon at the period when the capsules were
bursting in numbers.

Variation in Girth .

The girth of the trees was measured at two points: 22 in. and 36 in.
from the ground. The girths recorded in the following frequency table are
the mean of the girths at these two points.3 4

Table IV.

Girths of Population of 1,011 Seven-year -old Hevea brasiliensis.

. ,. NO

Girth in cm.

1

ON

CO

Frequency 2 12 29 49 70 106 114 146 127 114 91 60 49 20 8 14'

Mean girth = 80-30 + 0-25 cm. a = 11-91+0-18. C V. = 14-85+0-22 percent.

1 For a similar observation made in Brazil, cf. Cramer: Rubber Rectieil, Amsterdam, 1914, 12.

2 For data on the variation in weight and size, see Sprecher : Bull. Jardin Botanique de
Buitenzorg, No. 19, 1915, p. 112.

8 22 in. from the ground represents the lower level and 36 in. from the ground the upper level
of the section of the trunk which was being tapped during the year in which the observations were
made. 2 2 in. from the ground is also the level frequently fixed for measuring the girth of trees in
order to decide whether they are large enough for tapping ; and it may therefore be stated that the
mean girth given in the table was on the average 5.75 per cent, less than the girth measured
at 22 in.

4 Mean of this group, 1 1 3 cm.

320 Whitby. — Variation in Hevea brasiliensis.

The girth data, like the data for latex strengths, appear to present
a normal distribution.

Correlation between Yield and Girth .

The question of the extent to which the girth of the trunk is indicative
of the rubber yield of a tree has considerable practical significance. If the
correlation results showed that it is justifiable to assume that there is a high
degree of probability that a tree with a small trunk will give a poor yield,
and a tree with a large trunk a good yield, the work of selecting trees, in
regard to their yielding capacity, for thinning-out operations would be
greatly facilitated.

The figures given below indicate that, although there is a definite
positive correlation between yield and girth, the extent of the correlation is
not sufficient to justify very much emphasis being placed on girth when
selecting trees for thinning out.

Table V.

Correlation between Yield and Girth in a Popidation of ion Seven-year-

old Hevea brasiliensis .

Yields , grm, per diem .

VO

n

<N

VO

00

0

vO

<N

n

m-

£>0

|

7

7

7

7

V

T

7

S-<

I

1

1

CO

m

1-

o\

WH

ro

10

>

O

ro

10

i>.

ON

M

1-1

M

N

IN

O

50-52

I

I

2

53-56

5

3

2

I

I

12

57-60

8

11

3

5

I

I

29

61-64

>4

15

8

6

O

2

I

49

65-68

13

24

16

6

3

4

2

I

I

70

69-72

16

30

25

l1

7

5

2

2

I

I

106

73-76

li

28

19

*7

11

H

2

2

I

2

I

114

•77-80

* 7

36

32

2 r

14

11

8

4

I

I

I

146

81-84

16

27

29

23

8

6

5

6

2

I

2

I

127

85-88

13

28

21

16

8

9

5

2

5

3

I

3

114

89-92

8 '

17

3 8

19

9

6

3

1

6

1

2

1

91

93-96

■5

9

10

1 2

S

4

1

3

1

3

I

2

1

60

97-100

3

8

9

4

5

6

5

3

3

1

I

r

49

IOI-X04

2

2

5

2

2

3

1

1

1

1

20

105-108

3

3

1

I

8

109-124

1

2

2

2

1

2

2

1

1

139

241

J99

T54

83

7i

39

22

25

9

7

7

6

9

IOI I

r = + 0.260 + 0.020.

In addition to the characters which have been mentioned as showing,
for a given tree, approximate constancy, certain peculiarities were observed
in the cases of particular trees, which were also constant over considerable
periods of observations, and which may probably be regarded as charac-
teristic of the trees displaying them. Such were the following :

(a) Rapid discoloration of the latex. Rapid oxidative discoloration of
the latex may be associated merely with insufficiently deep tapping. Thus

Whitby. — Variation in Hevea Brasili 'crisis. 321

it may not infrequently be observed that the latex left on the tapping cut,
after a tree has ceased to drip, darkens rapidly at the upper end of the cut,
where there is a strong tendency for the tapping to fall short of the proper
depth. But, quite apart from cases of rapid discoloration which could be
avoided by deeper tapping, it was observed that in some cases rapid
discoloration appeared to be characteristic of the tree. One tree, which
showed this feature very strikingly, was kept under notice for five years,
and was always seen to produce rapidly-discolouring latex, which gave an
exceptionally strong reaction for peroxidase.1

(/;) Tendency to rapid coagulation. In the case of two trees in the
population with which this communication more particularly deals, a
tendency to exceptionally rapid natural coagulation was observed in the
latex, and persisted over a considerable period.

(c) A marked cream-straw colour appeared to be characteristic of the
latex from a small percentage of trees. (This colour is to be distinguished
from the transient yellow colour which latex from a new cut often has
before wound response has established itself.) The latex in question has
a noticeably ‘ rich ’ appearance. It was not, however, found in general to
have a higher rubber content than the average.

Postscript. — Since the above was in print, A. A. L. Rutgers 2 has
given some interesting data which are in full accord with the observations
(made in 1913), recorded in the present paper, as to the practical constancy
of the yield from individual trees and as to the character of the distribution
of the total yield over a group of rubber trees of equal age. Data for three
areas are recorded by Rutgers.3 As a result of comparing the classifica-
tion of the trees made at the outset with that made ten to twenty months
later, he concludes that * good trees remain good, poor trees remain poor \
From his data for a group of 1,467 trees (mean daily yield per tree, 9-1 g.)
it may be calculated that, at one extreme, 9-0 per cent, of the trees (trees
giving 17 g. or more) produced 23*9 per cent, of the total yield, and, at the
other extreme, 27-3 per. cent, of the trees (trees giving 0-5 g.) produced
only 7*2 per cent, of the total yield.

1 Cf. Whitby : Roll. Zeit, 1913, vol. xii, p. 147.

2 Selectie en Uitdunning. Archief voor de Rubbercultuiir, 1919, 3, 105-123.

3 It may be remarked that in the case of two of these areas the volume of latex, not the weight
of rubber, per tree was the quantity measured. Also, in the instructions with regard to the
collection of yield data for the purpose of selecting trees for thinning-out operations, it is directed
only that the volume of latex shall be determined. It would seem, however, from the results
recorded in the present paper on the ‘ V ariation in Rubber Content of Samples of Latex ’, that this
simpler procedure does not give exact results, and that it is necessary to weigh the rubber.

The Cytology and Life-history of Nemalion
multifidum, Ag.1

BY

RALPH E. CLELAND.

With Plates XXII— XXIV and three Figures in the Text.

Introduction.

HE cytological situation in those red algae which develop tetraspores

JL has become in the past few years fairly clear. The seat of chromosome
reduction has been accurately determined as being in the tetraspore mother-
cell, and the life-histories of several of the representative forms have been
worked out. The conclusions from cytological investigations have received
striking support from experimental cultures (Lewis, 1912 £,1914), which
have shown that sexual plants come from tetraspores and tetrasporic plants
from carpospores ; these two phases alternating in the life-history. The
situation, however, in those forms which do not produce tetraspores, has not
been thoroughly ascertained. The results obtained by Wolfe (1904) on
Nemalion multifidnm , and Svedelius (1915) on Scinaia furcellata , are con-
tradictory and the group as a whole needs thorough investigation.

In the hope that I might be able to throw some light upon this situation,
work was begun on Nemalion during the summer of 1916. The investiga-
tion has been carried on at the University of Pennsylvania, and at the
Marine Biological Laboratory, Wood’s Hole, Mass., under the direction of
Prof. Bradley M. Davis. I wish to take this opportunity of thanking
Dr. Davis for material, and for the constant help and criticism that he has
so willingly given. I am also indebted to Professors George T. Moore and
Ivey F. Lewis for much sympathetic assistance extended to me at Wood’s
Hole. Since the work was undertaken, a short paper on Nemalion by
Kylin (1916 c) has appeared. A number of his results I have been able to

verify.

Methods and Material.

Some of the material used in this investigation was collected by
Dr. Davis in the summer of 1908 off Gay Head, Mass., and fixed by him
in weak Flemming. This proved to be very well fixed. The rest of the

1 Contribution from the Botanical Laboratory of the University of Pennsylvania.

[Annals of Botany, Vol. XXXIII. No. CXXXI. July, 1919-]

324 C lei and. — The Cytology and Life-history of

material was collected by the writer during the summer of 1917, at Wood’s
Hole, Mass., and vicinity. Three fixing reagents were employed— weak
Flemming, weak chromacetic, and Merkel’s fluid. The two latter were
tried primarily as aids in the study of chromatophore structure, and for
nuclear studies proved to be decidedly inferior. Fixations were made at
all hours of the day and night, both in the field and in the laboratory.
Some of the material was fixed at ordinary temperatures, some at close
to o° C. The latter material showed no improvement over the former.

Stages in the germination of carpospores were obtained by placing
fruiting plants in shallow vessels in sea-water where the spores were shed
for a number of hours. By scraping the bottoms of such dishes, a wide
range of stages was obtained. Spores were also collected on slides laid in
the bottom of dishes under fruiting plants.

Most of the material was embedded in paraffin and sectioned at 3 \x.
Some was mounted whole, either in glycerine jelly, or fixed to the slide
with Meyer’s albumin, then stained and mounted in balsam. HeidenhaiiVs
hacmatoxylin was the stain chiefly used. Experiment proved the following
procedure to be the most satisfactory for sectioned material : 4 per cent,
iron alum, 8 hours ; running water, 5 minutes ; Heidenhain’s haematoxylin,
| per cent, water solution, 3d to 48 hours ; running water, 5 minutes ; 2 per
cent, iron alum until sufficiently destained. With weaker treatment the
chromatic structures failed to take the stain strongly enough to give proper
differentiation.

Vegetative Structure.

Although the vegetative structure of N emotion is well known, a short
account of certain details of anatomy and development should be given.
The thallus consists of a central core of closely intertwining and branching
threads from which radiate out in continuous series tufts of branching
assimilative filaments.

The strands of the central core are largely made up of long, attenuate
cells, in which I could find neither chromatophore nor nucleus, and which
apparently serve to support and hold together the tufts of assimilative
filaments. The tips of these strands, however, are actively growing and are
found scattered throughout the region of the core, but especially in the
younger parts of the plant. From these tips new assimilative filaments
and new cells of the central core threads are developed in rapid succession
(Text-fig. 1). The cells of these actively growing tips are short, thin-
walled, and have a nucleus, but no chromatophore (Fig. 7). The strands
lengthen by division of the apical cell and the branches which develop from
them arise as lateral buds from cells near the apex (Text-fig. 1, b). As the
cells become removed from the growing tips, the nuclei are less evident

Nemalion multifidum , Ag, 325

and finally cannot be distinguished, the cells becoming typical mature
strand cells of the central core.

At the tip of the thallus the central strands are very active, the
terminal cells cutting off segments rapidly, from many of \vhich new apical
cells arise as lateral outgrowths. Some of the branches thus formed become
new central strands, but most of them develop into assimilative branches
(Text-fig. i, b} c). So quickly does this development take place that the
assimilative filaments completely surround and hide the central portion, and
it is not unusual to find mature procarps within a distance of their own length
of the tip. The nuclei of the apical strand cells are very large and present
a strongly reticulate. appearance. In the cells of filaments destined to con-
tinue as central strands no chromatophore can be found (Fig. 7), but these
appear very quickly in the cells
of developing assimilative fila-
ments.

While most of the assimi-
lative tufts arise at the tip of
the thallus, new tufts are con-
stantly being interpolated be-
tween old ones farther back.

In the development of the
tufts two methods of growth
are present. First, growth
may take place by apical cell
division. This is the method
by which all branches already
formed increase in length.

The apical cell lengthens until
it is three or four times as
long as broad. The nucleus usually divides before the chromatophore
(Figs. 4-6), although in germinating carpospores the reverse is more often
the case (Figs. 81, 90). Second, growth may be by budding. Buds may
be of two kinds, those leading to the development of side-branches
(Text-fig. 2, a ), and those which give rise to trichomes (Text- fig. 2, b), The
latter always grow out from a terminal cell, the former from a subterminal
one. The bud which is to develop into a side-branch is put out as a papilla
at the upper end of the cell. The chromatophore moves to the opening
into the papilla and there divides, one-half passing into the bud. The
nucleus divides, and one daughter nucleus passes into the new cell, which
is then cut off. The new branch, thus begun, develops by apical growth,
and, as it matures, gradually takes on an appearance of equality with the
main branch, giving rise to a condition of false dichotomy. True dichotomy
is not present in Nemalion,

Text-fig. i. The growing apex of the thallus.
a. Apical cell of a young assimilative branch, b. Lateral
budding to .form a new branch, c. Terminal cell of a
central strand filament, x 700.

326

Cleland.—The Cytology and Life-history of

Trichomes may continue the axis of the parent filament (Text-fig. 2,^),
but more usually they are developed at one side of the median line of the
terminal cell (Text-fig. 2,e). Each trichome is equipped with a nucleus,
but has no chromatophore. After the trichome cell is cut off, it grows
very rapidly and soon becomes fifty or more times as long as broad. At
its distal end there is a quantity of cytoplasm in which lies the nucleus.
The rest of the hair appears to be empty. After it has reached maturity,
the base of the hair begins to gelatinize and a new trichome is developed
to take its place.

It is important to notice, in relation to the development of the

Text-fig. 2. Method of growth in a vegetative tuft. a. Lateral budding to form a side-branch.
b. Terminal budding to form a trichome. c. False appearance of dichotomy, d. Trichome developed
on the median line. e. Trichome developed to one side of the median line. f. Looped central
strand filament, x 700.

chromatophore, to be described later, that the growth of the assimilative
tuft is limited and that this limit is reached very close to the growing apex
of the plant. Cells, therefore, which but a short way behind the apex are
terminal cells of filaments, will contiuue to be terminal all through the
history of the plant. The growth in thickness of the thallus, as it becomes
older, is due to increase in the number of central strands ; and the increase
in assimilative structure which goes with this enlargement is due entirely to
the development of new or secondary filaments, either from old tufts or
from active strands of the central region.

Nemalion multifidum , ^4^. 327

Cell Structure.

The cell-wall is lamellate, as is easily demonstrated by the use of
swelling reagents. The interior of a vegetative cell is very largely taken up
by the chromatophore, which rests towards the upper end and occupies
about one-half to two-thirds of the cell space. At the lower end, especially
in old cells, there is usually a large vacuolar area. Below the chromato-
phore and between it and the vacuole lies the nucleus. It is very small,
measuring usually about in diameter. Within the nuclear mem-

brane lies a conspicuous nucleolus. The remaining space within the nucleus
is occupied by a faintly staining, but unmistakable reticulum (PI. XXIII,
Fig. 1). The nuclear cavity is never entirely empty of a reticular structure
except in newly organized nuclei immediately following mitosis. At this
stage, the small cavity is traversed only by a few radiating fibrillae which
appear to suspend the nucleolus in the centre, the entire chromatin content
being contained within this nucleolus. The details of mitosis in vegetative
cells are very difficult to study, since the nuclei are small, and since, also,
stages are not very often found, due to the fact that Nemalion is a slow-
growing plant, only making eight to ten inches of growth in a season. The
main details, however, have been made out satisfactorily, and it is certain
that the chromosome number is about 8 as reported by Wolfe. Except
for the absence of the nucleolus at metaphase, the details of nuclear
behaviour (Figs. 1-3) are in entire correspondence with those seen in the
cystocarp, where they are more easily studied. No detailed account,
therefore, will be given at this time.

The cells are joined by protoplasmic connexions. These stain an
intense black with Heidenhain’s haematoxylin, so that they stand out very
clearly. They appear as a pair of fused lens-shaped bodies, one to each
cell, the edges of which are continuous with the inner surfaces of the cell-
walls (P'igs. 23, 40, 43). Owing to their small size and deeply staining
nature, it has been impossible to demonstrate protoplasmic connexions as
clearly as has been done by Lewis (1909) for Griffithsia Bornetiana. That
intimate connexions exist, however, can hardly be doubted.

The Chromatophore.

The most striking object in the cell is the chromatophore. It consists
typically (Figs. 9-12) of a central region containing a pyrenoid-like body,
surrounded by a dense enveloping layer, from which strands radiate out-
ward to the periphery of the cell, where they flatten out to some extent
against the plasma membrane. These strands may be long, like spokes of
a wagon wheel, or short, like cogs, according as the central region of the
chromatophore occupies a larger or smaller portion of the cell. In either
case, they flatten out in the same way at the periphery. Usually they do

328 Cleland. — The Cytology and Life-history of

not approximate one to another closely enough at the periphery to form
a membrane.

It is the central region of the chromatophore, however, which is of
greatest interest The appearance of this region varies according to the
position of the cell of which it is a part. If the cell lies at the periphery of
the thallus, where it is in the best position for assimilation, the central
region consists of a spherical or ellipsoidal dark-staining area (Fig. 9), either
minutely granular or quite homogeneous and amorphous-looking, in the
centre of which is an intensely staining pyrenoid body, of homogeneous
appearance. In a cell which lies towards the interior of the thallus, how-
ever, we find quite a different condition (Fig. 11). Here the pyrenoid body
is smaller and occasionally even altogether wanting. The homogeneous
area surrounding it is replaced by a series of more or less granular threads
radiating outward from the pyrenoid to the periphery of the central region.
When the pyrenoid is entirely absent the threads occupy the entire central
area. If we examine cells intermediate in position between the innermost
and outermost (Fig. 10) we find all gradations between the two conditions
just described.

We must not conclude, however, that the conditions shown in Fig. 9
will be gradually attained by the chromatophore in Fig. 11 as it grows
older. It must be remembered that the growth of each assimilative fila-
ment is limited, and this growth limit is reached a very short distance behind
the growing apex. The result of this is that the cell shown in Fig. 9, which
is the terminal cell of a mature filament, will remain the terminal cell of that
filament (except in so far as it may cut off one or more trichomes) throughout
the life of the plant. Furthermore, the cell shown in Fig. 11, which is
situated somewhat below the periphery of the thallus, although it was at
one time the terminal cell of the filament, has, at all times, held its present
position with reference to the interior of the thallus — that is, close to the
central core. In other words, this cell has not had the same assimilatory
advantages that the cell in Fig. 9 has had throughout its whole life. There
is, therefore, no direct transition from the condition in F'ig. 3 1 to that in
Fig. 9. This is a natural result of the absence of intercalary growth.

The method of development of these two conditions in the chromato-
phore is illustrated in Fig. 8. Ch 10m atoph ores make their appearance
wherever one of the active strands of the core region gives rise to a new
assimilative tuft. If we follow the development of a single tuft through
from the apex, we observe that a cell is cut off laterally from a central
strand. At first this cell shows no signs of chromatophore, but very soon
a structure looking like a small area of very dense cytoplasm is seen
(F'ig. 8, a). This rapidly becomes denser and more distinct (Fig. 8, b). An
aggregation of material then takes place towards the centre of the structure
(F'ig. 8, c), where it becomes arranged into threads, the peripheral part

Nemalion miiltifidum , Ag. 329

meanwhile losing in density. Cell division occurs while the chromatophore
is in condition b or c.

After'the first cell division, the chromatophore left in the segment will
follow the line of development shown in Fig. 8, e, since this cell is always
to remain buried within the thallus. While the outer region of the
chromatophore is growing in size and developing projections which reach to
the periphery of the cell, the central region becomes larger and the threads
become more open and loose. The pyrenoid then begins to appear, at first
small, then increasing in size, until at maturity it occupies about one-half
of the area.

The apical cell meanwhile continues to divide and re-divide until the
limit of growth is reached. Division then ceases. The chromatophore of
the apical cell is in stage b or / of Fig. 8. Stage / differs from stage c in
that the central region is very densely granular and shows no tendency
towards a thread-like arrangement. This chromatophore now takes the line
of development^*, h. As it enlarges, the outer zone puts forth projections
in exactly the same manner as shown in d. The central region, however,
becomes less granular and more homogeneous (Fig. 8, g). The pyrenoid
then makes its appearance (Fig. 8, Zi) as a small, round, dark body, which
rapidly increases in size until, in the mature cell, it has the appearance
shown in Fig. 9. We see, therefore, that the chromatophore may develop
in* different ways depending upon its position in the thallus. If we were to
trace the development of a chromatophore in one of the middle cells of the
filament, we should find it taking a course midway between the two
described. Every degree of difference can be found.

Division of the chromatophore is by simple elongation and constriction.
If it is in the condition shown in Fig. 8, c or / the granular portion con-
stricts first, then the outer portion. Chromatophores which are older than
this commonly do not divide, the only exception being where a mature cell
gives rise to a side-bud which develops into a new filament. Everywhere
else, however, including cystocarp and carpospore, the general rule holds.

The difference between the conditions which I have just described and
the results which Wolfe obtained are striking. Wolfe found no pyrenoid
structures of any kind. Instead, he reported the central region of the
chromatophore as occupied by a vacuole, entirely empty of solid contents.
He, therefore, concluded that Nemalion has no pyrenoid or pyrenoid-like
structure. The difference between his results and mine are due entirely to
methods of fixation. Wolfe used only chromacetic fluids as killing reagents,
the effect of which seems to be to destroy more or less completely the
material of the central region. I also employed weak chromacetic to some
extent, as well as Merkel’s fluid. With Merkel’s fluid, an appearance
almost identical with that shown in Wolfe’s figures was obtained (Fig. 13),
the central region nearly always being an empty hollow, the bounding wall

330 Cleland. — The Cytology and Life-history of

of which was covered with small granules. With weak chromacetic I
obtained similar results. In no cell was the central region intact, and in
many cases it seemed entirely empty (Fig. 14), as figured by Wolfe, although
more usually a part or all of the pyrenoid or central body remained in an
ill-preserved or shrunken condition (Fig. 1 5), with occasionally a few other
granules scattered about in the surrounding vacuole. Perfectly preserved
chromatophores were only found in Flemming-fixed material. It is clear,
therefore, that a pyrenoid-like structure exists in the centre of the chroma-
tophore. In this connexion, it is interesting to note Schmitz’s (1882) state-
ment with regard to the sensitivity of the pyrenoid of the Nemalionaceae
and Bangiaceae : ‘ Bei diesen Algen namlich quellen die Pyrenoide bei
Einwirkung von siissem Wasser, Spiritus, verdLinnete Essigsauer, u. s. w.
auf, und vertheilen sich schliesslich vollstandig im dem umgebenden
Losungsmittel.’ The material in the central region is probably only pre-
served by the best fixing fluids.

One should notice in this connexion that Kurssanow (1909) described
material of N. lubricum both with and without the pyrenoid. He believed
the absence of the pyrenoid to be a sign of degeneration and approaching
death of the cell, which can be artificially produced by fixing in the labora-
tory. He stated that material fixed in the field shows the pyrenoid, while
material fixed in the laboratory shows none. He described a line of
development from presence to absence of the pyrenoid which does not con-
form in the least with the mode of development in my material and seems
to me very doubtful. Kurssanow used as fixing fluids iodine in sea-water
and von Rath’s fluid diluted ten times in sea-water. I obtained no difference
in chromatophore structure between material fixed in the field and material
fixed in the laboratory. Neither did I obtain any difference between the
material fixed during the day and that fixed during the night. The nature
of the fixing fluid used determined the only observed differences in the
appearance of the chromatophore and pyrenoid.

There has been much diversity of opinion as to the nature of the
pyrenoid and the methods by which it works. Schmitz (1882) described
the pyrenoid as a rather homogeneous mass which in structure is closely
allied to nuclein. Although actively concerned in the manufacture of
starch, it takes no actual morphological part in this process. The starch is
deposited in the clear zone surrounding the pyrenoid.

Meyer (1895) believed the pyrenoid to be crystalloidal in nature,
serving merely as reserve food and taking no part in metabolism.

Schimper (1885) considered the pyrenoid to be of the nature of a
protein crystal, but believed that it took part in the manufacture of starch
in essentially the same manner as described by Schmitz.

Boubier (1899) likened the pyrenoid to a leucoplast and considered
that not only the central body, but also the surrounding clear area, which

Nemalion multi fidum, Ag . 331

he described as penetrated by radiating granular strands, should be con-
sidered as the pyrenoid.

Timberlake (1901), working on Hydrodictyon , described its pyrenoid,
which is protein in nature, as cutting off segments from itself in the form of
concentric discs, which, by the deposition of starch, become transformed
into starch grains.

Lutman (1910) has not been able to confirm Timberlake’s results for
Closterium . He found that the pyrenoid is not homogeneous, but is cut
into by radiating clefts of lighter staining capacity. He considered it more
probable that the cleavage resulting therefrom gives rise to new pyrenoids
rather than to starch grains. All the starch grains, however, are formed
around the pyrenoid.

McAllister (1914) described the chloroplast of Anthoceros as contain-
ing a large number of very small, distinct, proteid pyrenoid bodies, which
probably increase in number by fission, the ones near the periphery of the
chloroplast being transformed directly into starch grains.

Miss Bourquin (1917) has recently contradicted the earlier workers on
Zygnema , by describing the formation of starch grains as taking place
entirely independently of the pyrenoid, the latter apparently exerting no
influence upon the process.

It will be seen, therefore, that there has been a wide difference in
opinion with respect to the method by which the pyrenoid acts. Almost
all workers are agreed, however, that it exerts some kind of an influence
upon the development of starch, or, in other words, that it represents
a photosynthetic centre.

There is no reason for believing that the pyrenoid of Nemalion is
merely a mass of reserve food. We invariably find that wherever photo-
synthesis is most likely to occur, as at the periphery of the thallus, it is
there that the pyrenoid is of largest size and of greatest prominence. On
the other hand, all cells which are buried in the thallus, away from the
more direct light, have a pyrenoid which is much reduced, or sometimes
entirely wanting. If the central body were a mass of reserve food, it would
be reasonable to suppose that it would be at least as plentiful in the inner
as in the outer cells, for the food elaborated in the outer cells must be
passed inward to all the living cells of the plant. The relative prominence
of the pyrenoid seems rather to be correlated with photosynthetic activity.
Besides this, tests show that the seat of reserve food is not in the chroma-
tophore but in the surrounding cytoplasm of the cell.

The pyrenoid of Nemalion resembles those ol Hydrodictyon and
Anthoceros in being protein in nature, staining yellow with the xantho-
proteic test, and, with the safranin and gentian-violet stain, standing out as
a clear refractive brilliant-red structure in the centre of the surrounding
area, which stains a rather neutral blue with gentian-violet. There seems,

B b

332 Cleland . — The Cytology and Life-history of

however, to be no resemblance between the methods of action of the
pyrenoid of Hydrodictyon and Anthoceros, and that o.f Nemalion . What-
ever may be true with reference to the action of the central body in
Nemalion , this much is certain, there is no segmentation or cleavage of the
body to form starch grains. Having once attained its mature state it
remains constant in size and appearance and never gives rise to any bodies.
In other words, as Schmitz stated, it takes no actual morphological part in
the process of starch formation. The fact, however, that we do not have in
Nemalion a pyrenoid of the nature described by Timberlake and McAllister
does not mean that it takes no part in photosynthesis. Starch grains are
never formed in this plant through any agency, although reserve food is
actively elaborated.

I have made some tests, both on living and fixed material, for the
purpose of ascertaining the position and nature of the reserve food sub-
stances. Tests were made with a saturated aqueous solution of iodine by
allowing it to filter slowly under a cover-slip, the material being mounted
in water and under observation with the immersion lens. Diffused through
the cytoplasm of those cells which were actively elaborating, there appeared
a pale pink colour, which deepened to a brilliant wine-red, and then to an
almost violet tone. The outer portion of the chromatophore became
a brilliant saffron-yellow and the pyrenoid a dark blue-green. As the
iodine became stronger, the whole contents of the cell stained a deep brown,
completely disguising the colours first obtained. In certain cells this
pinkish colour did not appear, namely, in the trichomes, many terminal
cells of filaments, carpogonia, and the stalk-cells of developing cystocarps.
In all of these cells chromatophores are either rudimentary or absent. The
cells of the gonimoblastic filaments showed a small quantity of this material
diffused through the cytoplasm, the amount increasing with the develop-
ment of the chromatophore. Ungerminated carpospores gave quite
a strong reaction which gradually diminished as germination progressed.
Young germ-tubes failed to show the reaction.

Other material was treated with chloral hydrate-iodine solution in the
same way. This in a more striking manner than before showed the
brilliant red to violet coloration, and strengthening the solution did not
bring on the undesirable brown staining with the iodine to so marked
a degree. With this substance it was possible to see more clearly the
small granules surrounding the pyrenoid, owing to the swelling action of
the reagent. In all cases they took on a hue exactly like that of the
pyrenoid. This colour was extremely difficult to classify, even in sectioned
material, when unmodified by the surrounding yellow-staining portion of
the chromatophore, because the granules are extremely small, and both they
and the pyrenoid so refractive as to make a correct interpretation of the
colour impossible. Since they appear to give exactly the same reaction as

333

Nemalion multifidum , Ag.

the pyrenoid itself, I would consider that they bear no relation to starch
grains. It appears from these tests that reserve food is not stored in the
chromatophore, but is diffused through the cytoplasm of the cell.

This wine-red or violet-coloured reserve food material is the substance
that has been termed ‘Floridean starch’. Bruns (1894), Kolkvitz (1899),
Biitschli (1903), and others have studied its presence in the red algae, and
it appears to be an intermediate product between the starches found in most
higher plants and the simpler di- and mqno-saccharides. Biitschli describes
it as intermediate between amyloerythrin and amyloporphyrin, giving
violets, purples, reds, and red-browns with various reagents. He describes
the colour obtained with iodine as wine-red to red-violet and with chloral
hydrate-iodine as between violet and livid. In Nemalion , therefore, as in
many other Florideae, we have as the main product of photosynthesis, not
the complex starches of the higher plants, but a simpler starch, more soluble
and giving different colour reactions with the various reagents. In view of
the fact, therefore, that in Nemalion the reserve food substance is not built
up into grains but is diffused throughout the cell, and that this substance is
of a lower order than ordinary starch, we may conclude that, although the
pyrenoid takes no morphological part in metabolism, as do pyrenoids in
other groups, this fact does not disprove its metabolic function, and that it is
actively concerned with the elaboration of Floridean starch.

Spermatogenesis.

•

The account which Wolfe has given of the development of the anther-
idial branch is in all points correct and needs not to be repeated. The
cells are very small, averaging 3*5 /ot in diameter, and have well-marked
chromatophores, with a distinct darkly-staining central region at a stage
corresponding to Fig. 8, f. The nucleus divides in the manner typical for
all vegetative cells. The spindle is exceedingly small (Fig. 16), and usually
each pole shows quite distinctly a minute black body at its tip. These
figures are very plentiful, but are too small, 1-4 x 3- 1 /x, to be favourable for
a chromosome count.

Antheridia are budded off laterally from the cells of the antheridial
branches. This process is accompanied by chromatophore as well as
nuclear division (Figs. 16, 17), so that the young antheridium possesses
a chromatophore, as described by Wolfe. Kylin (1916^) did not observe
the presence of a chromatophore, although admitting the possibility of such
being present. After the antheridium is cut off, the chromatophore, which
is of the most rudimentary nature, disappears from view. Whether it is
still present and hid by the dense cytoplasm of the cell or whether it
actually loses its identity could not be determined.

The process which Wolfe described as taking place during the matura-
tion of the antheridium, by which the chromatophore is broken up and the

B b 2

334 Clelcind . — The Cytology and Life-history of

contents distributed in the nucleus, I have not been able to confirm.
Appearances which might lead to such an interpretation I have only found
in poorly fixed material. In such material the main part of the cell
contents, usually including the nucleus, is massed at the distal end of the
cell. If destaining is not carried quite far enough, some of the haemato-
xylin will remain in this dense area while in the remainder of the cell it
has become completely extracted. This corresponds to the condition
interpreted by Wolfe as a broken-down chromatophore, the material from
which becomes aggregated at the distal end of the cell, where at least part
of it, he believed, passes into the nucleus. In perfectly-fixed material
there is no indication of such a structure at any stage, the cytoplasm remain-
ing perfectly smooth and even throughout.

According to Wolfe, the food material thus brought into the nucleus
rests for a time as a number of distinct granules in the nuclear cavity, but
finally all passes into the nucleolus. When the sperm atium escapes, the
granules are still to be seen, although the nucleus itself is in a resting con-
dition. Kylin considers that the granules are in reality eight to ten
chromosomes, and that after a short resting period a true prophase is entered
upon, the nucleus being in this condition at the time when the spermatium
is set free. With the exception of chromosome count, the observations of
Kylin are correct. The nucleus is at first at rest, but usually by the time
when the spermatium escapes it has entered a prophase condition showing
six to eight lightly staining chromosomes (Fig. 18). »

In most of the red algae so far studied the spermatium nucleus is in
prophase at the time of its escape. This is true of P olysiphonia violacea
(Yamanouchi, 1906), Rhodomela virgata (Kylin, 1914), Delesseria sanguinea
(Svedelius, 1914), Scinaia furcellata (Svedelius, 1915), Griffithsia corallina
(Kylin, 1916 a), and Bonnemaisonia asparagoides (Kylin, 1916 b).

Several antheridial cells may be developed in succession from the
same point on the antheridial branch, and it is not uncommon to see several
empty antheridial walls one inside another with a new antheridium
developing within.

One to several spermatia may fuse with a trichogyne (Figs. 30-24).
At time of union the spermatium contains but one nucleus. Soon after
fusion, however, the nucleus divides (Fig. 19), two male gamete nuclei being
thus formed, both of which may pass into the trichogyne (Fig. 31). Wolfe
and Kylin have both described and figured this division, but Kurssanow
(1909) failed to find it. Division of the spermatium nucleus has been
considered doubtful for Griffithsia Bornetiana by Lewis (1909), and is
reported not to take place in P olysiphonia , Scinaia , or Griffithsia corallina .
The presence of this division clearly shows, as Wolfe has pointed out, that
the spermatium is, strictly speaking, the homologue of an antheridium.

Only one male nucleus succeeds in entering the carpogonium, although

335

Nemalion multifidum , Ag.

others may get part way down the trichogyne (Fig. 22). At the time of
passage through the trichogyne the male nucleus contains a large homo-
geneous nucleole, and is therefore in a resting condition (Figs. 30-23). In
those forms in which the male nucleus is in prophase at the time of escape
of the spermatium, and in which no division takes place, the male nucleus
is reported to pass down the trichogyne in prophase, as a group of small
bodies, each a chromosome. This is the condition described for Polysiphonia ,
Griffithsia corallina , and Scinaia.

After the male nucleus has passed into the carpogonium, the trichogyne
is cut off from the carpogonium by a cleavage plane (Fig. 32), and later by
a cell-wall (Figs. 21, 22, 24, 31). The supernumerary male nuclei therefore
are left behind in the trichogyne (Figs. 21, 22), which remains for sometime
after fertilization, but finally withers and disappears (Text-fig. 3).

Oogenesis.

The procarp arises laterally from near the base of a vegetative tuft.
It is easily recognized even in the one-celled condition by its form, being
broader and shorter than the vegetative branches. The mature branch
most frequently consists of four cells, but five and three are not uncommon,
and two- or six-celled pro carps are occasionally seen. The cells of the
procarp have nuclei of the usual type. Each cell also possesses a chromato-
phore. In the basal cell this generally has a form more or less typical
for any interior vegetative cell. The chromatophore becomes less and less
well developed, however, in the cells above, until in the carpogonium and
sub-carpogonial cell all sign of its pyrenoid structure is gone and the
chromatophore consists merely of a dense mass of material very often
surrounded by a narrow ring (Fig. 29). The cells before the fertilization of
the carpogonium are entirely free from the darkly-staining bodies which are
so characteristic at a later stage;

After the procarp has attained its full length, the terminal cell or
carpogonium gives rise at its tip to a swelling which elongates and develops
into the trichogyne (Figs. 26-29). At the base of the carpogonium is
found the nucleus, which is quite large and possesses a prominent nucleolus
and a distinct light-staining reticulum. Above the nucleus lies the chro-
matophore. Occasionally the position of the nucleus and chromatophore
is reversed (Figs. 26, 27).

I have given special attention to the question of the presence of
a trichogyne nucleus. I have examined many hundreds of unfertilized
carpogonia with their trichogynes in every stage of development, and in
only a few instances have I found indications of such a body. In two of
these cases an extra nucleus was very clearly shown (Figs. 27, 28), which of
course would constitute the so-called trichogyne nucleus. It should be
noted, however, that in both of these cases the extra nucleus is not in the

336 Cleland. — The Cytology and Life-history of

trichogyne, but in the carpogonium. These extra nuclei are extremely
small, insignificant structures, and they very quickly break down (Fig. 29).
I have not found a single case where a nucleus was even doubtfully present
in the trichogyne itself. The fact that in many hundreds of carpogonia
and trichogynes, in all stages of growth, only a few possible examples of
an extra nucleus have been found, convinces me that the formation of
a trichogyne nucleus in Nemalion is not an invariable occurrence. When it
is present, this extra nucleus is diminutive and lives only a short time, not
even long enough, in most cases at least, to reach the trichogyne. We
probably have here a reduction from the condition where a trichogyne
nucleus was regularly present, to a state where it is only occasionally found.
It will be seen from the figures that the position of the carpogonial nucleus
in the cell bears no relation to the formation of a trichogyne nucleus. In
Fig. 28 the division seems to have taken place below the chromatophore ;
in Fig. 27, above it. The carpogonial nucleus seems often to rest in the
upper part of the carpogonium, even when no mitosis occurs.

There has been some dispute as to the presence of the trichogyne
nucleus in Nemalion and related forms. Wolfe was positive in his assertion
of its presence, describing it as well marked and unmistakable. Kylin,
while describing and figuring it, stated that it is very small and visible only
with difficulty in very young trichogynes. Kurssanow denied its presence
entirely in Nemalion lubricant and Helminthora divaricata. Davis (1896),
working on Batrachospermum , was the first to describe a trichogyne nucleus,
but Osterhout (1900) and Schmidle (1899) did not find it in this form.
Svedelius (1915) reported it in Scinaia furcellata and Kylin (1916$) in
Bonnemaisonia asparagoides. In the tetraspore-bearing red algae the
evidence for its presence seems to be very clear. It has been described in
Polysiphonia as a large body which does not disintegrate until after the
fertilization of the egg ; in Rhodomela virgata , Griffithsia corallina , and
Delesseria sanguinea as a structure which quickly disintegrates and
disappears. Lewis has not determined the situation for Griffithsia Bornet-
iana) but the probabilities are that it conforms to the condition found in
G . corallina.

More than one theory has been advanced concerning the origin and
nature of the trichogyne and its nucleus. Davis (1896) regarded the
trichogyne of Batrachospermum with its nucleus and reduced chromato-
phore as having a certain degree of independence as a separate cell.
Yamanouchi (1906) admitted that the trichogyne has a certain degree of
independence, due to its possession of a nucleus, and believed that the
multicellular trichogynes found in the Laboulbeniales illustrate a further
development of this independence. However, he considered the trichogyne
to have been originally an outgrowth of the carpogonium, and the trichogyne
nucleus to represent a second female gamete nucleus now functionless.

337

Nemalion multifidum , Ag.

Wolfe concluded that the trichogyne ‘ instead of being a mere hair-like
outgrowth from a cell is at first a cell in the strictest sense of the word,
which only later is specially modified in connexion with the reproductive
processes ’.

One of the striking features of Nemalion is the similarity in appearance
and method of development between the trichomes and the trichogyne.
It might not seem unreasonable to suppose that the carpogonium originally,
like any other terminal cell, possessed the capacity of budding off trichomes,
and that, after the male gametes lost their power of motility, this hair was
modified into a receptive organ, and the formation of a wall between it
and the carpogonium suppressed. The trichogyne would then represent
a separate cell which has in some measure lost its independence. Such an
explanation, however, looks no farther than the species under consideration.
When we consider Nemalion and other red algae in the light of evolutionary
relationships and study resemblances to other forms, and especially to
Coleochaete , another interpretation presents itself which is essentially that of
Yamanouchi. The striking resemblance between Coleochaete and the red
algae, in vegetative structure, reproductive organs, and the development of
the fertilized egg, lends weight to the possibility that the trichogyne-like
outgrowth of the oogonium of Coleochaete is homologous to the trichogyne
of the red algae. By this interpretation, the trichogyne of Nemalion would
not represent a separate cell, and the trichogyne nucleus is probably the
vestige of a second female gamete.

Fertilization.

At the time the male nucleus enters the carpogonium, the female
nucleus may lie at any position in that cell, being perhaps more often found
in the upper part than in the lower. Both gamete nuclei at time of fusion
are in the resting condition. As the nuclei come together, it may be seen
that they are somewhat unequal in size (Figs. 31, 32), the female being
about half as large again as the male. The process of fusion of the nuclei
is a slow one, and stages are, therefore, often found. The nuclear membranes
melt away at the point where they come together, and the contents of the
male nucleus pass into the cavity of the female. The chromatic nucleoles
then fuse (Fig. 24). If nuclear union has occurred in the upper part of the
cell, the zygote nucleus may remain in that position until after the first
mitosis, or it may migrate back to the lower part of the cell.

Reduction and Development of the Cystocarp.

The zygote nucleus increases in size and remains for some time in
a resting condition, while an additional thickness of wall is laid down com-
pletely around the protoplast. In the resting state (Fig. 33) the zygote
nucleus possesses a reticulum of exceedingly delicate, closely interwoven

338 Cleland.— The Cytology and Life-history of

threads. After a time, however (Fig. 34), the individual threads begin here
and there to show signs of thickening, and it is soon evident that with this
gradual thickening there is a corresponding decrease in the length of the
reticulum, the meshes becoming larger in size and the threads fewer in
number. This process is often attended by a knotting at the points where
two strands cross (Fig. 35). As the threads thicken they become quite
granular, with definite bodies scattered all along them. At this point the
threads show parallel arrangements (Fig. 36), and it is probable that an
association of the threads, in pairs takes place. I have noted no. marked
contraction of the thread system comparable to the stage of synapsis or
synizesis in higher plants. From now on, the threads of the spireme
present a much more even, smooth, and striking appearance, becoming
thicker, while the total length markedly decreases. The spireme is double
its former thickness and possibly represents a fusion of the male and female
chromatic elements in the nucleus (Fig. 37). At the intersections of the
threads, thickenings begin to form as knot-like structures. These knots
grow larger, and at the same time the portions of the thread system
connecting them become more and more attenuate until finally it can be
seen that they are breaking here and there as they become too thin to hold.
The process is one of condensation of chromatic material to form individual
chromosomes, accompanied of course by their separation. The final result
of this process is a set of eight bodies which are rather oblong in shape and
quite large, and almost entirely separated from one another (Fig. 38).
These are bivalent chromosomes, the paired members of which are to be
segregated by the first mitosis in the carpogonium. The two portions of
these bivalent chromosomes then separate (Fig. 39), and the result is a set
of eight pairs of single chromosomes standing apart in the nucleus and
forming a very clear stage of diakinesis (Fig. 40). My observations are
thus in accord with the account of Kylin for Nemalion and of Svedelius for
Scinaia in placing chromosome reduction at the first division of the zygote
nucleus.

Diakinesis seems to be of rather short duration. The paired chromo-
somes soon become arranged in the equatorial plate and a spindle is formed.
Polar structures are developed during the later prophase stages prior to
diakinesis, but are not easily seen since they appear merely as slightly
denser areas in the cytoplasm. That they are distinct bodies, however, is
shown by such conditions as are pictured in Fig. 41, in which a slight
amount of shrinkage has occurred, leaving the polar structures separated
from the surrounding cytoplasm. The details of spindle formation were
not observed.

The metaphase of the first mitosis is intranuclear (Fig. 42), although
the nuclear membrane breaks down very soon after the equatorial plate is
formed. The nucleolus is present during metaphase as an empty-looking

339

Nemalion multifidum , Ag.

body inside the nuclear membrane and appears to be in process of disin-
tegration. The polar structures are broad, lightly staining, and show no
signs of an aster. At anaphase, the members of the eight pairs of chromo-
somes separate and pass as univalent chromosomes towards the poles of the
spindle, where they become organized into the daughter nuclei. The
w individual chromosomes fuse into a large irregular body which rounds up
and becomes a chromatin nucleolus. The nuclear membrane is formed and
the nucleolus becomes suspended in the nuclear cavity by radiating
fibrillae.

The two daughter nuclei thus formed lie one above the other in the
now somewhat elongated carpogonium (Fig. 44). The chromatophore
divides, one half passing upward, the other downward. A cell-wall is then
cut in horizontally across the carpogonium, dividing it into an upper
sporogenous and a lower hypogynous cell (Fig. 45). The hypogynous cell
does not divide again, but the sporogenous cell gives rise to the gonimo-
blastic filaments of the cystocarp. We generally expect, in connexion with
reduction phenomena, to find that both of the nuclei formed as a result of
the first or ‘ heterotypic * division divide again by what is known as the
homotypic division, the end-product being a group of four reduced nuclei.
In Nemalion , however, we find that the nucleus of the hypogynous cell as
a rule remains undivided until disintegration finally takes place. Very
exceptionally this nucleus does divide, and in one instance I have been able
to confirm Wolfe’s observation of a vertical division of the hypogynous cell,
suggesting that originally the full tetrad of reduced nuclei was formed.
Such a tetrad is formed in Scinaia , as reported by Svedelius, although only
one nucleus of the four remains functional.

The nucleus of the sporogenous cell soon passes through a mitosis
(Fig. 46), and a cell-wall is laid down vertically; cutting off a lateral
segment. This process is repeated several times, with the result that a
number of cells are cut off laterally around the central sporogenous cell
(Figs. 47, 48). Each of these lateral cells gives rise to a gonimoblastic
filament which becomes branched in the manner typical of vegetative
growth. When mature, each filament consists of a series of three or four
cells, the terminal one of which develops into a carpospore (Text-fig. 3).
When the carpospore is ready to be shed, the wall ruptures at the distal
end and the protoplast escapes, leaving the empty wall attached to the
filament. The growth of a filament does not stop with the shedding of the
first spore, but a new cell is budded off within the empty shell (Fig. 49),
which matures into a spore and escapes, leaving a second empty shell.
Proliferation, as described by Wolfe, may in this manner continue through-
out the growing season. The spore when first shed is elliptical, but it soon
rounds up.

All through the development of the gonimoblastic filament, the

340 Cleland. — Lhe Cytology and Life-history of

chromatophore may be seen. At first it is nothing more than a body of
somewhat denser consistency than the surrounding cytoplasm, and, in well-
fixed material, is in contact with the cytoplasm. As growth proceeds it
becomes more distinct, following the same line of development as described

escaping spore possesses a very
distinct chromatophore, which is
in the condition corresponding
to Fig. 8,/.

Immediately after fertiliza-
tion, the chromatophores of the
upper stalk-cells of the carpo-
genic branch begin to show signs
of disintegration, and here and
there in the cytoplasm of these
cells appear a number of densely-
staining granules of varying size,
which have probably been cor-
rectly interpreted by Wolfe as
masses of reserve food material
(Fig. 4 6). As the cystocarp
develops, this process spreads to
the lower cells of the stalk and
the amount of material appears
greatly to increase in the upper
cells. The cells of the stalk
then begin to fuse together by
a widening of the connexion
between them. The process begins at the top and progresses downward,
resulting in one large fused cell, containing much reserve food material and
in which the nuclei and chromatophores gradually disintegrate (Text-fig. 3).

Mitoses in the Cystocarp.

It is in the developing gonimoblasts that the details of mitosis can best
be studied in Nemalion. This is due to the relatively large size of the
nuclei and to the rapid growth and consequent abundance of figures.
Every mitosis from first to last can clearly be followed.

The first indication of prophase is an increasing prominence of the
linin network of the nucleus and the development, where the threads join,
of numerous small aggregations of material, giving to the thread system
a knotted appearance (Fig. 51). These bodies gradually grow larger and
more prominent (Figs. 52, 61), but the threads themselves never become
very distinct. As the bodies increase in size, it is evident that they also
become fewer in number (Figs. 53, 54, 62). The threads connecting

for vegetative filaments (Fig. 8). The

Text-fig. 3. A cystocarp developing its first
carpospores, showing the withering trichogyne, con-
dition of the chromatophore, the fusion of the stalk-
cells, and food particles in the stalk, x 1056.

34i

Nemalion multi fidum, Ag.

certain of the bodies seem to contract, bringing them together so that they
fuse, and in this way the number is brought down to eight, each of which is
a chromosome (Figs. 54, 6 2). The thread system appears to be gradually
absorbed into the chromosomes and they finally lie free in the nucleoplasm.
Each of the chromosomes can be assumed to have retained its autonomy
throughout the resting period, and the history of prophase is merely one of
condensation and separation.

The chromosomes then become arranged to form the equatorial plate
(Figs. 55, 56, 63, 64, 65). The spindle is intranuclear, and the nuclear
membrane remains intact until the beginning of anaphase, when it quickly
breaks down. At metaphase large, broad polar structures are conspicuously
present at the tips of the spindles. The most striking feature of the meta-
phase in the cystocarp is the retention of the nucleolus. Presenting a rather
empty and disorganized appearance, it takes a position on the edge of the
equatorial plate, outside of the spindle, and does not disappear until the
breaking down of the nuclear membrane. Wolfe observed this condition,
but interpreted it as an extrusion of chromatin material representing part
of the nucleolus. The presence of the nucleolus at this stage seems to be
a fairly constant feature in the cystocarp, but has not been observed in
vegetative divisions, this constituting the only difference that I have noted
between the cystocarpic and vegetative mitoses.

The chromosomes split at the plate, and the daughter chromosomes,
eight in number, pass to the poles (Figs. 57, 58). The whole of the
chromatin content passing to each pole is organized into a chromatin
nucleolus, around which a nuclear membrane is formed (Figs. 59, 60).

The nucleus thus organized increases in size, and the nucleolus becomes
suspended by several radiating fibrillae (Fig. 60). It can then be seen that
material passes out of the nucleolus, and that this material becomes distri-
buted in a definite reticulum characteristic of the typical resting nucleus.
We note, therefore, that at first the nucleolus is truly a karyosome, con-
taining the whole of the chromatin material of the nucleus. Later on, this
chromatic material becomes gradually distributed as a network throughout
the nucleus. Occasionally, during the resting period, the nucleolus divides
into two daughter nucleoli, a condition which has been seen nowhere but in
the cystocarp (Fig. 50).

The chromosome number in all of the divisions of the cystocarp is
clearly eight. Since Wolfe, however, concluded that the reduction .takes
place with the development of the first-formed carpospore from each fila-
ment, I have given particular attention to the condition at that stage. As
may be seen from Figs. 61-66, however, the prophase and metaphase of
this division differ in no way from those of previous mitoses in the cystocarp
and the chromosome number is the same. The cystocarp of Nemalion , there-
fore, is haploid throughout its history in agreement with that of Scinaia .

342

C lei and. — The Cytology and Life- history of

Germination of the Carpospore.

The germination of the carpospore has been briefly described by
Lewis (1912#), but as he did not consider details of cytological structure, I
have taken up the matter from that standpoint. The following account is
based entirely upon sectioned material.

The rounded carpospore possesses a chromatophore, in the condition
corresponding to Fig. 8,f and a nucleus which is in the resting state show-
ing a closely woven reticulum (Fig. 66). Previous to germination, the
chromatophore may divide (Fig. 67), although as a general rule it remains
undivided. Germination is by means of a tube which is put forth as
a papilla and attains varying lengths. Into this the contents of the spore
pass, the chromatophore in advance of the nucleus. If the chromatophore
has previously divided, one of the two remains behind in the cyst (Figs. 80,
82). During the growth of the germ tube, and the passage into it of the
spore contents, the nucleus completes the early stages of prophase (Fig. 70).
These correspond exactly to those described for the cystocarp, but are even
more striking in appearance, due to the large size and clearness of the
nucleus. By the time that the nucleus is in mid-prophase, it has taken up
a position near, or at the entrance to, the tube (Figs. 71, 72). There it
completes the stages preliminary to mitosis and there it divides. Late
prophase consists in the condensation and amalgamation of the numerous
chromatic bodies untilseight chromosomes are formed (Figs. 71-73). During
late prophase, the polar structures may often be seen, at first minute, then
becoming larger and more prominent (Figs. 70, 72, 74). At this time the
nucleoplasm becomes very dense and stains heavily, so that it is almost
impossible to make out the stages just preliminary to metaphase. When
first formed, the equatorial plate is almost obscured by this state of affairs.
A little later, however, the figure comes out clearly and it is possible to see
that there are approximately eight chromosomes (Figs. 77, 78). The spindle
is intranuclear (Figs. 75, 78), and no trace of the nucleolus has been seen at
metaphase. The figure may lie in a perpendicular or in a horizontal position
with respect to the axis of the germ tube (Figs. 75-77)* The daughter
chromosomes separate (Figs. 78, 79), pass to the poles, and are organized
in the usual way to form daughter nuclei. One of the daughter nuclei
passes into the tube, the other remains behind in the cyst, and a wall is laid
down, cutting the germ tube off from the cyst (Figs. 80, 81).

The subsequent history of the cyst is interesting. If the chromato-
phore has divided previous to germination, one of the daughter chromato-
phores remains in the cyst and soon begins to break down. The nucleus
also in many cases disintegrates, but it may undergo a mitotic division.
The figure is occasionally seen (Figs. 83, 84), and even prophase stages
have been observed (Fig. 82) Following the mitosis, however, the daughter

343

Nemalion multifidum , Ag.

nuclei do not become completely organized. The chromatic material is
gathered together into nucleoli, but no nuclear membranes are formed and
the two bodies lie side by side for some time before they finally disinte-
grate (Figs. 85-7). The appearance of these two bodies side by side is
a very common one, and it is probable that this division takes place
frequently. There is a considerable variation as to the time at which it
occurs. It may take place very soon after the cyst has been cut off
(Figs. 85, 86), or it may not occur until the filament is two-celled (Fig. 83).
The presence of this division is very interesting since it recalls the second
division of reduction mitoses, as reported in the germination of certain algal
spores (e. g. Spirogyrd) ; but the evidence is clear that this is not the point
of reduction in Nemalion , and the mitosis may simply refer to a time when
the basal cell of the sporeling retained vegetative activity, perhaps giving
rise to additional filaments.

Meanwhile the germ tube has grown greatly in length and the tube
nucleus has come to occupy a position lateral to the now quite long
chromatophore (Fig. 89). Usually the chromatophore divides first
(Figs. 8 1, 90), followed by the nucleus, but the reverse may be the case
(Figs. 89, 92). The second mitosis varies in no particular from the first.
After nuclear division a cross-wall is laid down, resulting in a two-celled
filament. In the same manner the third mitosis takes place and the third
cell is formed (Fig. 94). Miss Chester (1898) has followed the development
of the sporeling through subsequent phases, until it assumes the appearance
and method of growth of the typical Nemalion plant.

The events recorded in this paper seem clearly to indicate that there is
no phase in the life-history of Nemalioyi corresponding to the sporophyte
of other groups. The cystocarp is shown not to be fundamentally sporo-
phytic in nature, but to correspond closely to the tissue development
leading to zoospore formation in the fertilized oogonium of Coleochaete ,
where Allen (1905) has placed for this plant the point of chromosome
reduction in the first mitosis of the fertilized egg.

Discussion.

The problem of alternation of generations in the red algae is a per-
plexing one, and would demand more space for a complete discussion than
can here be given. It will, therefore, be but briefly considered.

We find in the Florideae two distinct divisions. The first group,
termed £ haplobiontic ’ by Svedelius (1915) and represented by Nemalion
and Scinaia , presents a life-history without a change of chromosome
number in the cystocarp and without a tetrasporic phase. The second group,
termed ‘ diplobiontic ’, carries a diploid number of chromosomes through
the gonimoblasts of the cystocarp, through the carpospore, and through

344 Cleland. — T he Cytology and Life-history of

a tetrasporic generation. A striking feature of the tetrasporic plant, in
almost every case, is the fact that morphologically it is almost identical
with the sexual plant. Galaxaura excepted (Howe, 1917), there have been
reported no morphological differences between these two generations that
cannot be correlated with the peculiarities of their reproductive organs ; and
even in Galaxaura the differences between sexual and tetrasporic plants are
small and not phylogenetically fundamental. There are no forms in which
the tetrasporic generation appears to be in process of development from
something simpler to something more complex. In other words, there is
no evidence in the red algae pointing to a separate origin and gradual
development in complexity of the tetrasporic generation comparable to the
increasing complexity of the alternating sporophytic generation in the
Bryophytes and Pteridophytes.

Evolution in the red algae has probably been somewhat as follows.
All of the red algae at one time were without tetraspores or cytological
alternation of generations. They were all in agreement in the fact that
reduction occurred at the first division of the zygote. Although none
possessed tetraspores, some of them bore monospores, just as some of
the non-tetrasporic plants to-day possess monospores. The present-day
tetrasporic plants came about through a postponement of the time of
reduction, at first perhaps to the germination of the carpospore and finally
to the following generation. The failure of reduction to occur at carpo-
spore germination meant that the next generation was diploid instead of
haploid, as it otherwise would have been. Original monospores then
probably became the seat of chromosome reduction, developing four tetra-
spores by the cutting in of walls following the reduction divisions. The
occasional appearance of abnormal or partly developed tetraspores on
sexual plants indicates a close relationship between the monosporangium
and the tetrasporangium, suggesting strongly a homology. All of the
evidence so far seems to point toward this as the course of evolution in the
Florideae. The morphological similarity of the sexual and tetrasporic
plants, the sharp break between haplobiontic and diplobiontic types, the
presence of incomplete tetraspores on sexual plants and possibly apogamous
sexual organs on tetrasporic plants, all seem to favour this view. Cyto-
logical investigation is much to be desired on other forms of the haplo-
biontic group. It is possible that types may be found in which reduction
takes place with the germination of the carpospore. Such forms would
constitute an important link, clearly indicating the above as the probable
course of evolution.

We have, therefore, a method of evolution in the Florideae very
different from that found in the Archegoniates. The situation in the
Archegoniates . is simple. The sporophyte has been developed as an
entirely new structure to bear the diploid phase. The sporophyte and the

345

Nemalion multifidum , Ag.

diploid condition have arisen simultaneously, and both have become
extended and amplified through the same cause— a progressive sterilization
of sporogenous tissue. The' sporophyte structure is antithetic with the
gametophyte structure, as is the diploid with the haploid condition.

The situation in the Florideae, however, is more complex. In those
forms which possess a sporophytic phase, the diploid condition is not borne
by one sporophyte structure but by two structures — the cystocarp and the
tetrasporic plant — neither of which in its origin is wholly analogous with
the sporophyte of the Archegoniates. The cystocarp has arisen as a
structure antithetic to the sexual plant, and has done so in the same way
that the sporophyte of the Archegoniates has arisen, namely, by a steriliza-
tion of sporogenous tissue, having possibly come from a condition similar
to that found in Coleochaete, where a number of cells (eight) are formed by
division of the zygote, each of which, however, gives rise to a zoospore.
By progressive sterilization in the cystocarp, a certain amount of tissue
formation has come to precede spore formation. We have, therefore, in the
cystocarp of a form like Nemalion , a structure which we may look upon as
a spore-bearing epiphytic plant, alternating with the sexual plant and
bearing an antithetic relation to it. The cystocarp, however, differs in one
very fundamental respect from the sporophyte of the Archegoniates in that
it has originated independently of the appearance of a diploid condition.
In Nemalion and Scinaia the cystocarp is already well developed, although
the diploid condition has as yet not appeared. The cystocarp, therefore,
unlike the sporophyte of the Archegoniates in its origin, was not funda-
mentally sporophytic in nature.

The only structure in the red algae which is always diploid in
character is the tetrasporic plant. This, as we have already pointed out,
is morphologically identical with a sexual plant, but is modified by the
possession of a diploid number of chromosomes. It resembles the sporophyte
of the Archegoniates in that it carries the double number of chromosomes,
but in origin is entirely different from this, since it is not an entirely new
structure, but only an old one made over.

We have, therefore, two markedly different situations. On the one
hand, in the Archegoniates we find a sporophyte appearing simultaneously
with the diploid condition and representing something as new, morphologi-
cally, as is the diploid condition cytologically— a structure without a
phylogenetic ancestry. On the other hand, in certain red algae we have
a sporophytic phase composed of two separate generations, one of which
(the cystocarp) is antithetic to the sexual plant, but was in existence before
the diploid condition made its appearance ; the other of which (the tetra-
sporic plant) is the morphological homologue of the sexual plant. In the
Archegoniates two antithetically alternating plants correspond to two
antithetically alternating cytological phases. In the red algae these

346 Cleland. — The Cytology and Life-history of

cytological phases are borne by three distinct generations, two of which are
morphologically homologous, while the third is morphologically antithetic
to the other two.

Two terms have been widely applied in treating of the subject of
alternation of generation. These terms are 1 antithetic 5 and ‘ homologous \
As far as cytological alternation is concerned, it may be stated as axiomatic
that the haploid and diploid phases in all plants bear an antithetic relation
the one to the other. The diploid condition is new, and in no way homo-
logous to the haploid condition.

Since the term 4 alternation of generations \ however, includes not only
cytological but also morphological alternation, the application of either
term to Floridean alternation of generations is unsatisfactory, since neither
expresses the whole truth with reference to the situation in the red algae.
The great confusion which has arisen over the subject has been largely
a result of attempting to apply terms coined to express the relatively
simple conditions in the Archegoniates to the more complex situation in
the red algae.

It is not my purpose to offer a new terminology applying to this
situation, but to point out the great need of such. While we may continue
for the present to use the term { antithetic ’ as expressing a larger percent-
age of the whole truth than does the term ‘ homologous yet we should
bear in mind that the situation in the red algae is not strictly comparable
to that in the Archegoniates. It is to be hoped that in the near future
a term will be proposed which will be expressive of the whole truth with
reference to the morphological and cytological nature of the alternation of
generations in the red algae.

Summary.

1. Nemalion possesses a true pyrenoid, which appears as a densely-
staining body in the centre of a radiating chromatophore, its prominence
being directly proportional to its opportunities for photosynthetic activity.
This pyrenoid is actively concerned in the elaboration of soluble ‘ Floridean
starch ’, which stains wine-red to violet with iodine, and lies diffused
throughout the cytoplasm of the cell.

2. The nucleus of the spermatium is in prophase of mitosis at the time
of the escape of the spermatium and divides after the latter has become
attached to the trichogyne. Hence the spermatium is the homologue of an
antheridium.

3. Several male nuclei may pass into the trichogyne, but only one
enters the carpogonium.

4. A trichogyne nucleus is only occasionally formed, and, when
present, breaks down very quickly.

Nemalion multi fidum, Ag. 347

5. The fusion of gamete nuclei involves a fusion of the chromatic
nucleoles.

6. Chromosome reduction occurs with the first division of the zygote
nucleus. The threads of the delicate reticulum thicken and shorten and
finally take on a parallel arrangement. A fusion of threads then apparently
takes place, followed by condensation of material to form eight bivalent
chromosomes. These then become differentiated as eight pairs of chromo-
somes distributed about the nuclear cavity in a clear stage of diakinesis.
The sixteen chromosomes of these eight pairs are segregated by the first
mitosis, which is therefore a reduction division.

7. The chromosome number is eight throughout all nuclear divisions
in the history of the plant, except the first mitosis of the zygote nucleus.

8. Vegetative mitoses are best studied in the cells of the developing
cystocarp. The resting nucleus contains a large nucleole and a reticulum
of delicate threads. Approaching mitosis is indicated by the appearance
where the threads cross of numerous granules which, increasing in size, are
brought together by the contraction of the threads, fusing successively until
the eight chromosomes are differentiated. The spindle is intranuclear, and
conspicuous polar structures are present. The nucleolus, presenting an
empty appearance, takes a position during metaphase on the edge of the
equatorial plate, outside of the spindle, and apparently disappears with the
breaking down of the nuclear membrane. The two sets of daughter
chromosomes during telophase severally organize a chromatin nucleole from
which material is later distributed as a network throughout the resting
nucleus.

9. The nucleus left in the carpospore cyst after the first division of the
carpospore nucleus may again divide, but the resulting nuclei do not become
completely organized and soon break down.

10. Since reduction, as in Scinaia and Coleochaete , takes place with the
first mitosis of the zygote nucleus, the cystocarp of Nemalion is not sporo-
phytic in character, and there is no cytological alternation of generations
in this plant.

University of Pennsylvania,

July , 1918.

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Yamanouchi, S. (1906) : The Life-history of Polysiphonia. Bot. Gaz., xlii. 401-49.

EXPLANATION of plates xxii-xxiv.

Illustrating Mr. Cleland’s paper on Nemalion multifidum , Ag.

All figures were drawn with the aid of a camera lucida at the level of the table, under a Spencer
1.8 mm. objective. The following were the oculars used, with the magnifications obtained: Zeiss
compensating No. 12, approximately 2,200 diameters; Zeiss compensating No. 18, approximately
3,300 diameters; Spencer 10 x, 1,530 diameters; Spencer 18 x, 2,140 diameters.

Nemalion multifidwn, Ag.

349

PLATE XXII.

Vegetative Structure.

Fig. i. Terminal cell at the apex of the thallus, nucleus in prophase, x 2,200.

Fig. 2. Same, nucleus in later stage of prophase, x 2,200.

Fig. 3. A cell at the apex of the thallus putting forth a bud which will develop into a side-
branch. Metaphase of a vegetative mitosis, showing eight chromosomes, x 2,200.

Figs. 4-6. Stages in the division of a terminal cell, showing division of the chromatophore.
x 1,520.

Fig. 7. Terminal cells of a central strand filament, with no sign of a chromatophore. x 2,200.

Fig. 8. Development of the chromatophore. <2, earliest stage; b, a little later; c, d, e, develop-
ment in an interior cell ; /, g, h , development in a terminal cell.

Fig. 9. Mature chromatophore in a terminal cell, x 2,200.

Fig. 10. Mature chromatophore in a cell midway between the base and the apex of a filament,
x 2,200.

Fig. 11. Mature chromatophore in a cell at the base of a filament, x 2,200.

Fig. 12. Mature chromatophore in a terminal cell, the pyrenoid divided, a frequent occurrence,
x 1,520.

Fig. 13. Mature chromatophore in a terminal cell, showing the effect of Merkel’s fluid, the
pyrenoid broken down, x 2,200.

Figs. 14, 15. Mature chromatophore in a terminal cell, showing the effect of chromacetic acid,
the pyrenoid partially or wholly destroyed, x 2,200.

Spermatogenesis.

Fig. 16. Metaphase at the cutting off of an antheridium. x 2,200.

Fig. 17. Telophase and chromatophore division at the cutting off of an antheridium. x 2,200.

Fig. 18. Prophase in the antheridium. x 3,300.

Fig. 19. Metaphase in a spermatium which is attached to a trichogyne. x 3,300.

Fig. 20. Male nucleus in the trichogyne. x 1,520.

Fig. 21. A fertilized carpogonium. Two spermatia are seen. A nucleus from the lower one
has fertilized the egg, the other nucleus is disintegrating in the lower portion of the trichogyne.
Both nuclei belonging to the upper spermatium are visible, one still within the spermatium, the -
other in the trichogyne. x 1,520.

Fig. 22. Male nuclei in the trichogyne. One has broken down, x 1,520.

Fig. 23. Male nucleus entering the carpogonium. x 1,520.

Fig. 24. Several spermatia on one trichogyne. Male and female chromatic nucleoles fusing in
the zygote nucleus. The carpogonium already cut off from the trichogyne. x 1,520

PLATE XXIII.

Oogenesis and Fertilization.

Fig. 25. A developing procarp, x 200.

Fig. 26. A young carpogonium and trichogyne. No trichogyne nucleus is present. It is rather
unusual to find the nucleus above the chromatophore at this stage, x 2,200.

Figs. 27, 28. Trichogyne nuclei. Fig. 28 shows that the trichogyne nucleus can be cut off in
the lower portion as well as in the upper part of the carpogonium. x 1,520.

Fig. 29. Entire procarp with immature trichogyne. A trichogyne nucleus is present in process
of disintegration, x 1,520.

Fig. 30. The female nucleus above the chromatophore, as the male nucleus descends in the
trichogyne. The more usual position, x 1,520.

Fig3* 31, 32. Fertilization. It more usually occurs at the upper end of the carpogonium than
in the lower portion, x 2,200.

The Reduction Division.

Fig- 33* Resting zygote nucleus with delicate chromatic reticulum, x 2,200.

Fig. 34. Early prophase. The thread system beginning to thicken and shorten, x 2,300,

Fig. 35. Here and there knots of chromatic material have appeared, x 2,200.

C C 2

350 Cleland. — The Cytology and Life-history of

Fig. 36. The threads present a granular appearance and show parallelism, suggesting fusion,
x 2,200.

Fig. 37. Thick spireme. Eight chromatic knots are beginning to form in the angles of the
spireme, and will develop into the eight bivalent chromosomes, x 2,200.

Fig. 38. Eight bivalent chromosomes, almost free from one another, x 2,200.

Fig. 39. Bivalent chromosomes free, and now split, forming pairs of single chromosomes, x 2,200.

Fig. 40. Diakinesis. Seven pairs of univalent chromosomes shown, x 2,200.

Fig. 41. A zygote nucleus approaching mitosis with the polar structures made conspicuous
through shrinkage of the surrounding cytoplasm, x 2,200.

Fig. 42. Metaphase of the first mitosis which is the reduction division. The nucleolus is still
present. The spindle is intranuclear, x 2,200.

Fig. 43. Metaphase of the first mitosis, x 2,200.

Fig. 44. After the first mitosis and before the cross-wall is formed, x 2,200.

Fig. 45. Carpogonium divided into the sporogenous and hypogvnous cells, x 2,200.

The Developing Cystocarp.

Fig. 46. Sporogenous cell above with metaphase of the second mitosis. Food particles in
a stalk-cell, x 2,200.

Fig. 47. Metaphase in a gonimoblast initial, x 2,200.

Fig. 48. Y oung cystocarp. x 1,520.

Fig. 49. The proliferation of carpospore initials. New spores being developed in old cysts.
X 1,520.

Mitosis in the Cystocarp.

Fig. 50. Resting nucleus with two nucleoli. Often seen in the cystocarp, but nowhere else,
x 2,200.

Fig. 51. Beginning prophase, x 2,200.

Fig. 52. Later prophase. Many chromatic bodies, x 2,200.

Fig* 53* Still later prophase. The bodies become fewer by fusion, x 2,200.

Fig. 54. Late prophase, showing chromosomes, x 2,200.

Figs. 55, 56. Metaphases. Spindle intranuclear, with polar structures and nucleolus at the side
of the equatorial plate, x 2,200.

Figs. 57, 58. Anaphases, x 2,200.

Fig. 59. Telophase. Spindle remnants still show, x 2,200.

Fig. 60. Newly organized nuclei. Chromatin nucleoles suspended by fibrillae. All of the
chromatin is contained still within these nucleoles. x 2,200.

Figs. 61-5. Prophases and metaphase of the division which results in the cutting off of the
first carpospore from a filament. Behaviour as in previous mitoses in the cystocarp (Figs. 51-6).
x 2,200.

PLATE XXIV.

The Germination of the Carpospore.

Fig. 66. A carpospore, the chromatophore with well-developed pyrenoid. x 2,200.

Fig. 67. A carpospore in which the chromatophore has divided, x 2,200.

Fig. 68. The effect of weak chromacetic acid on the pyrenoid. x 2,200.

Fig. 69. Protrusion of the germ tube. Early prophase in the nucleus, x 2,140.

Fig. 70. Early prophase. Polar structures have appeared, x 2,200.

Figs. 71, 72. Mid-prophase. Many chromatic bodies. Polar structures shown in Fig. 72.
X 2,200.

Fig. 73. Late prophase. The chromatic bodies have condensed in number to eight chromo-
somes. x 2,200.

Fig* 74* Just previous to metaphase. Chromacetic fixed. Note effect on pyrenoid. x 2,200.
Figs. 75, 76. Metaphases. Spindles lying at different angles, intranuclear, x 2,200.

Fig* 77* Metaphase. Chromacetic fixed, x 2,200.

Fig. 78. Anaphase. Chromacetic fixed. Note effect on pyrenoid, x 2,200.

Fig. 79. Anaphase, x 2,140.

Nemalion multifidum , Ag. 351

Fig. 80. The tube is cut off, leaving a nucleus and chromatophore in the cyst. The division
of the chromatophore took place previous to germination, x 2,140.

Fig. 81. Nucleus undivided in the cyst. Chromatophore in the tube divides before the nucleus,
x 2,200.

Fig. 82. Prophase in the cyst nucleus. This section is cut obliquely so that only a small
portion of the tube is shown. Such a striking prophase is not often seen in the cyst, and is probably
due to the unusual amount of cytoplasm left behind, x 2,200.

Fig. 83. Metaphase in the cyst, x 2,200.

Fig. 84. Anaphase in the cyst, x 2,200.

Fig. 85. The nucleus in the cyst has divided, but the daughter nuclei have not become com-
pletely organized, x 2,200.

Fig. 86. The two unorganized daughter nuclei in the cyst. A very usual condition, x 2,200.

Fig. 87. Two unorganized nuclei and a chromatophore in the cyst, x 2,200.

Fig. 88. Prophase for mitosis in the first tube cell, x 2,200.

Fig. 89. Metaphase taking place in the tube before chromatophore division, polar structures,
x 2,200.

Fig. 90. Metaphase after chromatophore division. The more usual condition, x 2,200.

Fig. 91. Anaphase in the tube cell, polar structures. Transverse section of the tube, x 2,200.

Fig. 92. Telophase in the tube cell, x 2,200.

Fig. 93. Previous to wall formation, x 2,200.

Fig. 94. Two-celled stage of the tube. Third metaphase, x 2,200.

CLELAND — NEMALION.

Huth lit'h.e'L ira p.

Annals of Botany,

Cleland. del.

CLELAND — NEMALION

Voi.JKxiii'Pi.xxni.

Iinth Irth. et imp.

,4nnals of Botany,

7

Voi.xKxm,pL.xxm.

3 7.

62

65 .

Huth lath et imp.

38.

59.

i/huxals of Bo teeny

Cleland de] .

91.

Vol. XXXIII, PL. XXIV.

92

Huth lith. eti imp.

Voi.xxxiiiPi.xxrv.

1 9 .

c/Jrtnals of Botany ,

66.

75.

68.

70.

74.

67.

80.

Clela.nd del .

CLELAND — NEMALI ON

Huth lith. e« imp.

The Compound Interest Law and Plant Growth.

BY

V. H. BLACKMAN.

IN many phenomena of nature we find processes in which the rate of
change of some quantity is proportional to the quantity itself. Since
money put out at compound interest increases in this way — the rate of
increase being clearly proportional to the amount of capital at any time —
Lord Kelvin called the law which such processes follow ‘ the compound
interest law The rate at which a body cools follows the compound
interest law, for the hotter the body relative to its surroundings the more
rapidly it loses heat. Again, the variation of atmospheric pressure with
height above sea-level follows this law, as does also the velocity of a chemical
reaction. Wilhelmy’s law, discovered as long ago as 1850, that ‘ the amount
of chemical change in a given time is directly proportional to the quantity
of reacting substance present in the system ’, is simply a restatement of the
compound interest law.

The importance of this law for the proper appreciation of the growth of
.a plant was brought home to the writer in 1917 in connexion with the
results of some experiments on the growth of cucumbers carried out in
association with Mr. F. Gregory at the Cheshunt Experimental Station.

It is clear that in the case of an ordinary plant the leaf area will increase
as growth proceeds, and with increasing leaf area the rate of production of
material by assimilation will also increase ; this again will lead to a still
more rapid growth, and thus to a greater leaf area and a greater production
of assimilating material, and so on. If the rate of assimilation per unit area
of leaf surface and the rate of respiration remain constant, and the size of
the leaf system bears a constant relation to the dry weight of the whole
plant, then the rate of production of new material, as measured by the dry
weight, will be proportional to the size of the plant, i. e. the plant in its
increase of dry weight will follow the compound interest law.

The fact that the increase in number of unicellular organisms, when
not limited by external conditions, follows a regular geometric series has
long been recognized. The resemblance also of the growth processes of
animals and plants to an autocatalysis has been pointed out by a number
of workers, as J. Loeb, W. Ostwald, Robertson, F. F. Blackman, Chodat

[Annals of Botany, Vol. XXXIII. No. CXXXI. July, 1919.]

354 Blackman. — The Compound Interest Law and Plant Growth.

and his pupils.1 The application of the compound interest law to the
growth of the higher plants, though of fundamental importance to a right
understanding of the plant’s rate of increase, has, however, been over-
looked by most botanists,2 and its recognition is sadly lacking in the text-
books both of plant physiology and general botany. Chodat in his
‘ Principes de Botanique ’ (2nd edit., p. 133) appears to be the only text-book
writer who even refers to the relation of growth to a geometric series, and
his treatment of the subject appears under the section of the book which
deals with the growth of the cell, and it is confined to pointing out the
similarity of the growth of the cell to a process resembling autocatalysis.

Apart from any question of autocatalysis it is obvious that the increase
in size of the assimilating surface of the young plant must constantly
accelerate the rate of growth, and that the consideration of this acceleration
is essential for the proper comparison of the final weight of different plants
and of the same plants grown for different periods.

When money accumulates at compound interest, the final amount
reached depends on (1) the capital originally employed, (2) the rate of
interest, (3) the time during which the money accumulates. In the case of
an annual plant the ultimate dry weight attained will depend on (1) the weight
of the seed, since that determines the size of the seedling at the time that
accumulation of new material begins ; (2) on the rate at which the material
present is employed to produce new material, i. e. the percentage increase
of dry weight per day or week or other period ; (3) the time during which
the plant is increasing in weight.

It is clear then that some simple equation is required to relate these
three factors to the final, weight attained ; such an equation does not appear
to have been hitherto put forward by those few workers who have considered
the growth relations of the whole plant from this aspect. Before dealing,
however, with this attention may be drawn to the work of Noll and his pupils,
who have provided the data of the growth relations of a number of plants
during various stages.

Noll seems to have been the first to formulate the view that in the case
of an annual plant the successive dry weights taken at regular periods
follow a geometric series. In 1906 Noll read before the Niederrheinische
Gesellschaft fiir Natur- und Heilkunde zu Bonn a paper (which appears only

1 There can be no doubt that the development of an increasing number of rapidly enlarging
cells which occurs in the development of most plant organs will cause a rapid acceleration of growth,
producing a curve of growth which is very similar to that of an autocatalysed reaction. A process
of autocatalytic nature does not, however, explain the rapid fall in the rate of growth in the later
stages of development of the human body, or the fall in the rate of growth of a plant organ which
has passed its ‘ grand period ’ of growth. The growth of an annual body of a plant organ of limited
size is clearly dominated by factors other than those that play their part in a simple autocatalytic
process.

2 Since the above was written I have seen the proof of a paper (to appear in the Annals of
Applied Biology) by Dr. F. Kidd and Dr. W. West in which they point out the importance of the
compound interest law.

Blackman . — The Compound Interest Law and Plant Growth. 355

in title in the Proceedings of the society) entitled ‘ Uber die Substanz-
quotienten pflanzlicher Entwickelungsstadien In the next two years three
of his pupils, Gressler,1 Hackenberg,2 and Kiltz,3 published inaugural disser-
tations dealing with the determination of the ‘ Substanzquotienten ’ of
various plants.

From these papers it becomes clear that the c Substanzquotient ’ is the
factor which relates the dry weight at the end of any period of growth with
the dry weight at the beginning of that period. Taking Gressler’s results
with Helianthus uniflorus giganteus we find that in five successive weeks the
average dry weight in grammes of a number of plants was 0-0454, 0*147,
0-508, 1*653, 17*33, 30*35, 46-2, 66-1, 88*9. Dividing the second by the

first, the third by the second, and so on, we find that the successive weekly
‘substance-quotients’ were 3-25, 3*45, 3'24> 3\56> 3*°» I*75, 1#4» 1'3-

The successive, weekly dry weights clearly exhibit at first a progression
which is approximately geometrical ; later, however, the rate of increase falls
off, the series becoming an arithmetical one.

The ‘ substance-quotient ’ per week is obviously a clumsy and in-
accurate method of expressing these results. What is required is some
simple method of relating the plant’s activity in the production of new
material to time and to the initial weight of the seedling. Hackenberg and
Kiltz merely state their results as ‘ substance-quotients ’ per week, but in
calculating the average £ substance-quotient ’ over a period of many weeks
Gressler treats his results as a discontinuous geometric series. The formula
which would then apply is W1~ W0 (1 +r)t, where W1 = the final weight,
W0 = the initial weight, r = the rate of interest, and t — time. Gressler’s
results for Helianthus calculated in this way per week and per day are
shown in columns 5 and 6 of the accompanying table.

Seedling Final Time tRate of Interest Rate of Interest
weight . weight, jjavs (- Discontinuous ). ( Continuous ).

Grm. Grm. ' per week, per day. per week, per day.

II. uniflorus giganteus

0.0327

17*33

37

227.6%

i8*5%

ii9*°%

17.00

%

It. nanus

0.0348

14.805

37

214*3 %

i7*7%

ii4*5 %

16.36

%

It. cucumer if olius nanus

0.00106

0.401

56

no*o %

H*2%

74*i %

10.59

%

H. macrophyllus giganteus

0-0241

6.772

32

243*3 %

J9*3 %

123*4%

17.63

%

H. arboreus giganteus

0.0192

14.680

40

219.6%

i8-i%

116.1%

16.59

%

Treatment of the results in this way would, however, only be satisfac-
tory if the additional material were added discontinuously at the end of
each day or week. It is obvious, however, that during the daylight period the
plant is adding new material continuously, and during rapid growth the plant

1 P. Gressler: Ueber die Substanzquotienten von Helianthus Annuus. Inaug. Diss., Bonn,
1-29, Tables I-V, 1907.

2 H. Hackenberg: Ueber die Substanzquotienten von Cannabis sat iva xmd Cannabis gigantea.
Inaug. Diss., Bonn, 1-27, 1908. Also Beihefte zum Bot. Centralbl., xxiv, pp. 45-64, 1908.

8 H. Kiltz : Versuche uber den Substanzquotienten beim Tabak und den Einfluss von Lithium auf
dessen Wachsthum. Inaug. Diss., Bonn, 1908 (seen only in abstract, Bot. Centralbl., cx, p. 455,
1909).

356 Blackman. — The Compound Interest Lazv and Plant Growth.

is continuously, or nearly continuously, unfolding its leaves and increasing
its assimilating area. The plant’s increase is thus comparable rather to
money accumulating at compound interest, in which the interest is added to
the principal not daily or weekly, but continuously. The simple equation
which best applies to the growth of active annual plants is thus :

Wx = W0ert,

where, as before, W1 = the final weight, W0 — the initial weight, r = the
rate of interest, and t — time, and e is the base of natural logarithms.1
Some of Gressler’s results have been calculated on this basis of continuous
addition at compound interest, and are given in the last two columns of the
table. The rate of interest required to give the same final dry weight is
naturally less when it is added continuously than when it is assumed to be
added discontinuously, and far less than the rate of interest per week
calculated from the weekly ‘ substance-quotients ’.

As has already been stated, it is obvious from general considerations,
and also from the equation, that the final weight attained will depend on the
initial weight, the rate of interest (r), and the time. The differences in the
dry weight attained by two plants may thus depend on simply the initial dry
weights of the seedlings ; if the rate of interest is the same the final weights
will then vary directly as the initial weights. This shows the marked
effect which large seeds as compared with small seeds may have on the
final weight attained. Again, if the initial weights are the same a small
difference in the rate of interest ( r ) will soon make a marked difference in
the total yield, and the difference will increase with the lengthening of the
period of growth. A difference of 1 per cent, in the rate of interest will in
a period of 69 days double the final weight attained.

Oats in water culture may, according to Wolff, attain a dry weight
2,359 times that of the seed. If the growing period be taken as 100 days,
the rate of interest on the basis of continuous addition is 776 per cent, per
day. If the rate of assimilation per unit area should rise by 5*8 per cent,
then, allowing 10 per cent, for loss of respiration, the final weight at the end
of 100 days would go up 50 per cent. Plants of Helianthus macrophyllus
giganteus (investigated by Gressler) with a seed weight of 0*0241 grm. may
in 32 days reach a dry weight of 6-77 grm., i.e. a weight 251 times that of
the seed. This on calculation by the equation given above requires that r
shall be 0-1763 (i. e. an average rate of 17-63 per cent.) per day. An increase

w.

In fising the formula it is only necessary to

find the number which expresses the relation between the final and initial dry weights of the plant ;
and then to find the napierian logarithm (loge) of that number, or to find the common logarithm
and multiply by 2.3026. The logarithm so found when divided by the time gives the rate of
interest required. Suppose a plant has doubled itself in ten days. We find that the loge 2 is 0.69315 ;
therefore the plant has been producing new material at the rate of 0*0693 (i. e. 6.93 per cent.) per day.
If the period were 5 days the rate would be 13.8 per cent, per day ; if 100 days, then 0-69 per cent,
per day.

Blackman. — The Compound Interest Law and Plant Growth . 357

of assimilation of 2 per cent, would in this case increase the weight at the
end of 32 days by about 20 per cent.

A marked difference in the rate of interest (r) is exhibited by different
plants. The table given shows that in some species of Helianthus it may
reach 17*6 per cent, per day, while in H. cucumerifolius nanus it is only
10*42 per cent, per day. In some results obtained by Stefanowska 1 with
Maize in water culture the plants increased their fresh weight 27-5 times
in 45 days ; the rate of interest was therefore only 7-45 per cent, per day.
Obviously some plants can work with far greater economy than others.
Thus for every 100 grm. of dry material already present H. macrophyllus
giganteus can produce new material at the average rate of 10-4 grm. per
day ; calculating from Hackenberg’s results, we find that Cannabis gigantea
may work at a rate of 13-1 per cent, per day for a short time, and (from
Kiltz) that Nicotiana Tabacum may work at the rate of 20*5 per cent, per
day. Zea Mais , on the other hand, as stated above, under some conditions
works at the average rate of only 7-45 per cent, per day.

The rate of interest (r of the equation) is clearly a very important
physiological constant. It represents the efficiency of the plant as a producer
of new material , and gives a measure of the plant’s economy in working.
The rate of interest, r, may be termed the efficiency index of dry weight
production, since not only does it indicate the plant’s growth efficiency as
measured byincrease of dry material, but it also appears as an exponential
term in the equation which expresses the relation between the initial dry
weight, the final dry weight, and the period of growth. It may also be
termed the 'economy constant’ of the plant ; it is of course comparable
to the velocity constant of a chemical reaction.

It is suggested that in all water cultures, pot experiments, and similar
experiments where dry weights are determined after a period of growth, the
efficiency index should be calculated from the seed weight and the final weight
attained, so that a measure of the plant’s average economy of working may be
obtained.2 Such a calculation will show how far a large final weight is
determined by a large initial weight or by a high efficiency index.

A glance at the table given above shows that the ‘ dwarfness ’ of
Helianthus cucumerifolius nanus is due not only to the very small seed
weight but also to the comparatively low efficiency of the plant, the efficiency
index being only 0*1042 (or 10-42 per cent.) per day. This form of
Helianthus is handicapped by a seed i/300th of the weight of that of
H. uniflorus giganteus , so that even if it had the same efficiency it could
only attain 1/300 of the final weight of the latter. Other things being equal,
a small seed is a permanent handicap to a plant in the production of
material. H. cucumerifolius nanus , in order to attain after 37 days the same

1 Comptes rendus de l’Acad. des Sciences, cxxxviii, 304-6, 1904.

2 Where root parts are not available, the efficiency index can be given for the aerial parts only.
The seeds should, where possible, be weighed without the testa.

358 Blackman.- — The Compound Interest Law and Plant Growth .

weight as H. uniflorns , would have to work at an efficiency of 0*2621
(i. e. 26-21 per cent.) per day ; with this high economy of working the plant
would double its weight in less than three days. For the highest production
of vegetative material by the single plant two factors are necessary — large
seeds, and a high economy in working represented by a large efficiency index.

The importance of these two factors in breeding cereal crop plants
should be borne in mind ; it may be possible to breed for a high efficiency
index. In many crop plants the matter is of course complicated by the
effect of crowding on the efficiency of the individual plant, a question which
requires further analyses.

The growth is naturally affected by external conditions, being higher
when conditions are favourable, but even under the same conditions there
are large variations in the economy of working of different plants, so the
efficiency index is certainly to a large extent a characteristic of different
species and varieties. It would be of great interest to determine to what
these differences in efficiency are due. They maybe the result of differences
in the rate of assimilation per unit area of leaf surface, of differences in the
rate of respiration, of differences in the thickness of the leaves, or of
differences in the distribution of material to leaves on the one hand and to
the axis on the other. The larger the proportion of new material that the
plant can utilize in leaf production the greater, other things being equal,
should be its efficiency.

It is clear, from Gressler’s and Hackenberg’s results with Helianthus
and Cannabis , that the efficiency of the plant is greatest at first and then
falls somewhat, but the fall is only slight until the formation of the inflor-
escence, when there is a marked diminution in the efficency index. For
Helianthus arboreus giganteus , for example, the £ substance- quotients ’ for
successive weeks are 3-11, 3-49, 3-71, 3-06, 2-59, 3-03, 2-0, 1-5, 1-4, i-i, 1*3,
1-3. The sudden fall from 3-03 to 2-0 is associated with the appearance
of the inflorescence.

The observations of Gressler, Hackenberg,&c., require repetition, for they
worked with only a small number of plants and they give no idea of the
experimental errors involved, though the differences in dry weight of the
individual plants must have been considerable. It would be very valuable
to have data for various agricultural and horticultural plants, showing the
average efficiency index under various conditions. If the dry weight measure-
ments were combined with a measurement of leaf area and leaf weight some
insight could be obtained into the nature of the differences which exhibit
themselves as differences in the efficiency index of different plants and as
differences in the efficiency index of the same plant at different stages.1

1 If such observations were combined with an estimation of the carbon content of the root, stem,
and leaf, together with some measure of the rate of respiration, the analysis could be carried still
further. It is hoped to undertake this work with some agricultural plants.

Blackman. — The Compound Interest Law and Plant Growth. 359

The fall in efficiency after the first few weeks of growth may perhaps
be correlated with the mechanical relations connected with larger size. A
doubling of the leaf area would require a stem of more than twice the
weight to attain equal strength. Gregory 1 found that with larger leaf areas
the ratio of stem weight to leaf weight went up.

As the efficiency of the plant is highest in its early stages favourable
conditions at that time should have a marked effect on growth. If a plant,
owing to such conditions, should double its size as compared with another
plant, then there is no reason why that advantage should not be retained to
the end of the growing season. A ; good start ’ means, among other things,
a larger capital to work with throughout the growing season.

Gericke,2 investigating the effect of various injuries on the growth of
Helianthus animus , showed that the removal of the cotyledons not only
affected the total weight — -as was to be expected, since a large portion of
the plant’s capital was thereby lost — but also markedly reduced the
efficiency of the plant. Calculations from his weekly data of dry weights
show that the efficiency index never rose above 14-24 per cent, per day as
compared with the 18-46 per cent, of normal plants. It is not at all clear
why the loss of the cotyledons should reduce the economy of working of
the plant developed from the remaining portion, especially as the removal
of one cotyledon and one of the first leaves had no such effect. It suggests
that the cotyledons may contain a supply of some special material necessary
for the proper development and efficiency of the plant ; a possible analogy
with the growth substances of animals occurs to one. The subject certainly
requires further investigation.

Kiltz (loc. cit .) observed in Nicotiana a marked decrease in dry weight
at the time when the seed was matured, reaching 2-98 per cent, in the case
of N. gigantea. This might be explained by assimilation being brought to
a standstill while respiration continued. The amount to be explained in
this way is, however, very large, and Chodat, Monnier and Deleano 3 have
described a restoration to the soil of mineral matter up to 40 per cent, of the
dry weight of the mature plant. Whatever its cause, the phenomenon is of
importance in all experiments where the dry weight of annual plants which
have reached the fruiting stage is in question.

Summary.

Attention is drawn to the fact that the growth of an annual plant,
at least in its early stages, follows approximately the ‘ compound interest
law ’. The dry weight attained by such a plant at the end of any period
will depend on (1) the weight of the seed (or the seedling at its start),

1 Experimental and Research Station, Cheshunt, Herts., Report III, p. 24, 1917.

2 F. Gericke : Experimented Beitrage zur Wachstumsgeschichte von Helianthzts cmnuus.
Inaug. Diss., Halle, 1-43, 1909.

3 Bull, de l’Herbier Boissier, vii. 350 and 948, 1907.

360 Blackman.— T he Compound Interest Law and Plant Growth.

representing the initial capital with which the plant starts ; (%) the average
rate at which the plant makes use of the material already present to build
up new material : this represents the rate of interest on the capital (material)
employed ; (3) the period of growth.

The plant is continually unfolding its leaves and increasing its assimi-
lating power. Successive increases in the weight of the plant cannot there-
fore be treated as a discontinuous geometric series, as if the new material
(interest) were added at the end of daily or weekly periods. New material
is added continuously during daylight, and during rapid growth the plant is
continuously, or nearly continuously, unfolding its leaves and increasing its
assimilating rate. The growth of the plant more nearly approximates to
money accumulating at compound interest where the interest is added
continuously. The simple equation which best expresses the growth rela-
tions of active, annual plants is W1 = W0ert, where W1 = the final weight,
W0 — the initial weight, r — rate at which the material already present is
used to produce new material, and t = time.

The term r is an important physiological constant, for it is a measure
of the efficiency of the plant in the production of new material ; the greater
r is, the higher the return which the plant obtains for its outlay of material.

The rate of interest, r. may thus be termed the * efficiency index ’ of dry
weight production, for not only is it a measure of the plant’s efficiency but
it is also an exponential term in the equation expressing the growth of the
plant. In some forms of Helianthus the average efficiency index for the
period up to the formation of the inflorescence may reach 0-1763 (i e. 17-63
per cent.) per day.

It is suggested that in all experiments (such as water cultures, pot
experiments) dealing with the production of vegetative material the efficiency
index be calculated. The relative efficiency of different plants and of the
same plant at different stages can thus be determined ; also the effect on
the efficiency index of various external conditions.

A small difference in the ‘ efficiency indices ’ of two plants (resulting, for
example, from a slightly greater rate of assimilation or a more economical
distribution of material between leaves and axis) may lead to a large
difference in final weight. In oats, for example, an increase of 6 per cent,
in assimilation might lead to an increase of 50 per cent, in dry weight at the
end of joo days.

The data of earlier workers show that the ; efficiency index ’ is highest in
the early stages of growth, and then falls slightly. In Helianthus , Cannabis ,
and Nicotiana it falls sharply at the beginning of the reproductive period
when the inflorescence first appears.

There is evidence that annual plants at the end of their period of
growth may lose considerably in dry weight.

Imperial College of Science and Technology,

London.

The ‘Brown Rot’ Diseases of Fruit Trees, with Special
Reference to Two Biologic Forms of Monilia cinerea.
Bon. I.

BY

H. WORMALD, M.Sc. (Lond.), A.R.C.Sc.

Mycological Department , South-Eastern Agricultural College , Wye , Kent.

With Plates XXV and XXVI.

Contents.

PAGE

I. Introduction .361

II. Historical 363

III. General Observations . 367

(ci) The Occurrence of Monilia fructigena and M. cinerea on Primus spp. . . 367

(d) The ‘Wither Tip’ Disease of Pium Trees in 1918 ...... 368

(c) Sources of Infection on Plum Trees ......... 369

( d ) An Epidemic Outbreak of a ‘ Blossom Wilt’ of Plum and Cherry Trees in 1918 369

(e) M. cinerea and M. fructigena on Pyrus spp . . 370

IV. Methods adopted in isolating Pure Strains 371

V. Inoculation Experiments with M. cinerea and M. fructigena :

(a) Apples inoculated with Strains of the Two Species 373

(P) Plums ,, „ „ „ „ 381

(V) Plum Flowers inoculated with Strains of M. cinerea . . . . *387

(a) Apple „ „ „ „ „ „ 389

VI. Conclusions 397

I. Introduction.

IT has long been common knowledge among horticulturists and plant
pathologists that the fruits of the cultivated species of the genera Pyrus
and Primus are frequently attacked by fungi which, gaining access to the
nutritious parenchymatous cells of the fruit through wounds or abrasions of
the skin, rapidly develop within the tissues. The progress of the disease is
indicated by a discoloration of the affected cells, the resulting brown colour
often showing a striking contrast with the healthy tissues, particularly in
the case of immature fruit with pale green skins (see Fig. 4).

[Annals of Botany, Vol. XXXIII, No. CXXXI, July, 1919.]

362 Wormald. — ‘ Brown Rot ' Diseases of Fruit Trees.

The most important of the fungi producing these symptoms are to be
referred to that genus of the ‘Fungi Imperfecti ’ known as Monilia.
Although these Monilias are able to continue from year to year without
the interpolation of an ascigerous stage, such a stage has been observed,
and it is now customary to allocate the species to the ascomycetous genus
Sclerotinia .

The effect produced on the fruit by these species of Monilia is
commonly known as ‘ Brown Rot ’ in this country, and this term is also
now generally applied to the various diseases of fruit trees caused by
these fungi. On the Continent the same diseases are referred to as ‘ Rot
brun ‘ Faulniss der Friichte’, ‘ Grind oder Schimmel des Obstes ’, ‘ Schwarz-
faule ’, ‘ Bluten- und Zweigdiirre ’, ‘ Muffa o marciume dei frutti ’, &c. The
result of the development of the Monilias within the tissues is not usually,
however, a ‘ rot ’ in the sense of putrefaction, since the organs attacked
become so permeated with the mycelium that the whole forms a stromatic
mass which generally tends to become more or less indurated rather than
rotten. Thus the fruit, when so infected, instead of decaying and disin-
tegrating, often becomes desiccated, and may remain on the tree in a
‘ mummified ’ condition for some months.

Towards the end of the nineteenth century serious losses to the cherry
crops on the Continent, the flowers, fruit, and often branches being killed,
led to an investigation of the cause of the outbreaks. The disease, at first
attributed to the action of frost, was soon found to be due to epidemic
attacks of a Monilia. It is now generally recognized that although the
Brown Rot fungi are usually associated with fruit-rots they also cause
blossom-wilts, destroy young twigs, and often kill branches by producing
cankers which, girdling them and penetrating to the xylem elements,
obstruct the course of the transpiration current and so cause the desiccation
and death of those parts distal to the cankers.

The fruit is also liable to infection after it is picked, and apples in the
store often suffer severely, for, since the disease under certain conditions is
contagious, one affected apple may transmit the rot to those around it.
Under storage conditions apples attacked by M. fructigena sometimes
become quite black, a fact recorded in this country as early as 1885 by
Worthington G. Smith.

That the Brown Rot fungi are recognized by mycologists and phyto-
pathologists as of paramount importance is shown by the numerous papers
and articles which have been published on the subject.1 Many of these
articles are merely records of the occurrence of the? diseases, and relatively
few supply scientific evidence for the conclusions arrived at. Of the
experimental work, particularly that carried out on the Continent, very few
investigators employed ‘ pure culture’ methods in carrying out inoculations,

1 See Bibliography on pp. 398-403.

W or maid, — ‘ Brown Rot ’ Diseases of Fruit Trees. 363

and this, together with the fact that many workers still refuse to recognize
that there are at least two distinct species of Monilia causing Brown Rot
diseases, renders much of the work valueless as scientific records.

II. Historical.

In previous papers where the present writer (1917-18) described two
specific diseases, on apple trees and plum trees respectively, literature was
cited which related more particularly to the two diseases or to results obtained
during the course of experiments connected with them, and no attempt was
made to obtain a complete review of the papers dealing with those diseases
of fruit trees caused by species of Monilia. Since the object of the present
article is to show the relation which the two diseases bear to one another
and to other Brown Rot diseases, a more general historical survey of our
knowledge of the subject is desirable.

The earliest record of the occurrence of a Monilia on fruit appears to
have been one by Persoon, who, finding a fungus producing tufts of
moniliform chains of conidia on the decaying fruits of Pyrus communis ,
Primus domestica , and Amygdalus persica in the year 1796, named it
Torula fructigena. Five years later he changed the name to Monilia
fructigena , and this is the name which is still usually applied to the conidial
stage of the fungus. The former name was, however, frequently used for
some time by certain workers, e.g. Albertini and Schweinitz (1805), Fuckel
(1869), Saccardo (1873), Rabenhorst (1844-1853).

In 1817 Kunze and Schmidt named the fungus Oidium fructigenum ,
and this name was retained by Ehrenberg (1818), Fries (1829), Duby
(1830), Cooke (1871), and Worthington Smith (1885). Other names by
which it has been known are Acrosporium fructigenum , used in 1822 by
Persoon himself, but not adopted by other botanists, Oospora fructigena and
O. Candida , as used by Wallroth (1833), and Oidium W allrothii, by von
Thiimen (1875), who, however, in 1879 changed it to O. fructigenum.

Schroter, in 1893, from analogy with other species of Monilia producing
an ascigerous stage, concluded that M. fructigena was the conidial stage of
an ascomycete, and transferred it therefore to the genus Sclerotinia ; in
this connexion Prillieux (1897) wrote, ‘ ce n’est que par analogie que Ton
peut regarder ce parasite comme une Pezize reduite a sa forme imparfaite
de fructification5. In 1903 Ritzema Bos proposed that the fungus should
be referred to the genus Stromatinia ; this name has not been generally
accepted, though adopted by Delacroix and Maublanc in their ‘ Maladies
des Plantes cultivees \1

The apothecial stage of Monilia fructigena was discovered on the
Continent by Aderhold in 1904, thus confirming Schroter’ s conclusion
regarding the ascomycetous nature of the fungus. Norton (1902) had two

1 Loc. cit., vol. ii, p. 255. (Paris, 1909).

364 W or maid. — ‘ Brown Rot ’ Diseases of Fruit Trees.

years previously found apothecia which had developed from mummied
peaches; this form Norton himself referred to Sclerotinia fructigena , but
Aderhold and Ruhland (1905) concluded that it was A. cinerea.

Westerdijk, in 19x2, discovered a Sclerotinia on mummied cherries
which, from the dimensions of its asci and ascospores, appeared to be
different from S. fructigena, S. laxa , or 5. cinerea ; the direct connexion
between the ascospores and a conidial stage was not traced however.

That Monilia was a genus which was to be considered as of economic
importance was recognized by von Thumen in 1875, and in the following
year by Hallier. Soon epidemic outbreaks of diseases caused by Monilias
of fruit trees on the Continent resulted in the publication of many papers
on the subject, particularly during the last decade of the nineteenth
century, when articles appeared under such well-known names as Schroter
(1893), Wortmann (1895), Wehmer (1895-6), Frank (1898), Frank and
Kruger (1897-9), Aderhold (1897), Woronin (1897-9), Goethe (1898),
Behrens (1898), Muller-Thurgau (1900), Sorauer (1899), and others,1 the
years 1897-1900 being prolific in references to epidemic outbreaks of Monilia
diseases. In Germany the first serious complaint of such an epidemic
appears to have been in 1894 ; thus Frank and Kruger write in 1899, £ Die
erste Klage iiber das epidemische Auftreten der Monilia-Krankheit . . . wurde
in Deutschland im Fruhling 1894 laut, wo die landwirtschaftliche Hochschule
in Berlin uber das allgemeine Absterben der Kirschenbliiten in der
Ortschaft Blankenfelde bei Berlin um Rat befragt wurde’.

Since 1900, Aderhold, Muller-Thurgau, and Sorauer have continued
their observations, and others have taken up the work or recorded the
damage caused, e.g. Ritzema Bos (1903), Molz (1907), Kock (1910), Muth
(1910), Ewert (1912), Voges (1912), Westerdijk (1912), Broz (1913), and
Eriksson (1913).

In 1818 Ehrenberg discovered a form on apricots which he named
Oidium laxmn ; as with O. fructigenum, this fungus has also been referred
to other genera, its synonomy being as follows :

Oidium laxum , Ehrenb. Sylv. (1818), p. 10,-22.

Acrosporium laxum , Pers. Myc. I (1822), p. 25.

Oospora laxa , Walk. Plor. Crypt. (1833), n. 1 574.

Monilia laxa , Sacc. et Vogl. Sacc. Syll. Fung. IV (1866), 35.

Sclerotinia laxa (Ehrenb.), Aderh. et Ruhl. (1905).

Aderhold and Ruhland (1905) found the apothecial stage of this fungus
in 1904 developing from mummied apricots which had been placed in soil
in pots and kept under observation; they cultivated the ascospores on
artificial media and reproduced the conidial stage. Since that date the
name Sclerotinia laxa has been generally reserved for the form producing

1 See Bibliography.

W or maid. — ‘ Brown Rot ' Diseases of Fruit Trees . 365

the brown rot of apricots, e.g. Faes (1914), Chifflot and Massonnat (1915),
Peglion (1917).

Bonorden in 1851 introduced the name Monilia cinerea for a form
which he found ‘ auf faulenden Friichten ’ ; as in the case of M. fructigena ,
Schroter, in 1893, referred it to the ascomycetous genus Sclerotinia.

In spite of Woronin’s well-known papers of 1898-9, in which he
submits convincing proof that Sclerotinia fructigena and S. cinerea can
be readily distinguished even in the Monilia stage, other investigators
refuse to accept his conclusions, and consider that ‘ Brown Rot ’ diseases
of our cultivated fruit trees are caused by one species only, i.e. S . fructigena.
Thus Frank and Kruger (1899) 1 say, ‘ Auch der von Woronin fest-
gehaltenen Unterscheidung von Monilia fructigena Pers. und M. cinerea
Bon. konnen wir wegen der Ubergange ihrer Merkmale nicht beistimmen,
ein Standpunkt, auf dem auch Behrens und Wehmer zu stehen scheinen
Eriksson (1913) also writes,2 ‘ Ich mache hier keinen Unterschied zwischen
Monilia cinerea und M. fructigena , da eine Speciesbestimmung nur nach
der Farbe der Conidienpolster immer misslich ist \

Although ‘ Brown Rot 9 has caused serious damage to the fruit crops
in our own country for many years, no scientific investigations of the
outbreaks have, until quite recently, been attempted, and references to the
diseases have been practically confined to notifications of their occurrence
and to the recommendation of methods of control adopted abroad. No
attempt was made to compare the forms occurring here with those
investigated by Woronin and others on the Continent, and generally it has
been assumed that all outbreaks of ‘ Brown Rot ’ were caused by Monilia
fructigena .3 *

In 1864 an article appeared in the ‘Gardeners5 Chronicle ’ over the
initials M. J. B., describing a serious outbreak of a rot of apricots, the
disease being caused by ‘ a little greyish mould, Oidium fructigenum 5 ;
a similar disease of apples and pears was assumed to be caused by the
same fungus. Worthington G. Smith writes, in 1885, that ‘The fungus
(referred to Oidium fructigenum ) is often extremely destructive to stored
Apples when kept in damp or unventilated store rooms ; the same pest
destroys Pears, Plums, and other fruits.

‘ The warts are generally grey in colour, varying, however, in tint from
cream to fawn colour, or different shades of grey.’ It would seem from this
description of the pustules that both Monilia fructigena and M. cinerea
had been observed but not recognized as different species. The same
writer had also noticed that ‘ The fungus has, in some instances, the power
of changing the skin of the Apple to a jet-black colour \

1 Loc. cit. , p. 203. 2 Loc. cit., p. 65.

3 An article in the Gardeners’ Chronicle of December 30, 1915, refers to M. cinerea and

M. laxa , but only in relation to work done on the Continent.

D d a

366 Worm aid. — ‘ Brown Rot ’ Diseases of Frtiit Trees .

Massee again recognized one species only, referring to it as Monilia
fructigena in his ‘ British Fungus-Flora’ (1893), and in ‘A Text-Book of
Plant Diseases ’ (1903) ; later (1910) he describes it as Sclerotinia fructigena .
Cooke (1906) also attributed attacks of Brown Rot on apples, pears,
cherries, and apricots to one species, Monilia fructigena.

Spinks (1915-16) has recently investigated ‘ A Black Rot of Apples ’,
particularly with regard to its occurrence on cider apples, and finds that it
is caused by Sclerotinia fructigena , in the restricted use of this name as
defined by Woronin ; this disease is probably identical with the one
observed by Worthington Smith (1885).

In 1907 Salmon recorded outbreaks of Brown Rot on acid cherries, and
in 1910-14 called attention to a serious ‘Brown Rot 5 disease which destroys
the blossom of apple trees and may invade the branches and produce
cankers. The present writer (1917) undertook the further investigation of
epidemic attacks of this ‘ Blossom Wilt and Canker Disease ’ of apple trees,
which was particularly prevalent on the variety Lord Derby in the Weald
of Kent, and found that the fungus responsible was not Monilia fructigena ,
which had been assumed to be the species causing the disease, but a grey
Monilia conforming to descriptions of M. cinerea , Bon. Later a ‘ Wither
Tip of Plum Trees ’ (1918) was found to be caused by a fungus morpho-
logically similar to that occurring on ‘ Brown Rot Cankers ’ of apple trees,
but was different from that form biologically, in that it was unable to
establish itself in the flowering spurs of the apple, and so was incapable of
inducing the typical ‘ Blossom Wilt ’ condition or of forming cankers on
apple trees.

Meanwhile phytopathologists in the United States had been attracted
to the investigation of outbreaks of £ Brown Rot ’ in America, where fruit-
growers were subjected to great losses annually, caused by a species of
Monilia , peach trees proving particularly susceptible to the disease. Peck
(1881) found that Oidium fructigenum attacked the fruit through wounds,
for he was unable to produce infection by placing conidia on the uninjured
skin. In 1886 Arthur recorded a blossom infection of cherries in New
York as having occurred during the previous summer, and three years later
Erwin F. Smith (1889) described a blossom blight of peaches as caused by
Monilia fructigena , another paper on the same subject by the same author
appearing in 1891. In that year Humphrey also wrote on ‘ The Brown Rot
of Stone Fruits ’, and he too referred the fungus to M. fructigena , which
he believed to have a conidial stage only. During the nine years following,
further papers by Humphrey appeared, and other investigators took up
the work, e.g. Chester (1892), Taft (1894), Bailey (1894), Goff (1897),
Quaintance (1900), Waugh (1900).

In 1902 Norton made an important discovery when he found the
ascigerous stage of the Brown Rot fungus occurring on peaches in Maryland ;

Wormald. — ‘ Brown Rot ’ Diseases of Fruit Trees . 367

the apothecia were developing from mummied fruit which had been lying
on the ground for some time in an old peach orchard. Many bulletins on
Brown Rot appeared during the succeeding ten years, dealing chiefly with
the therapeutics of the disease, which was still generally attributed to
Monilia frtictigena. Then a series of papers appeared, written by Jehle
(1913), Matheny (1913), Cooley (1914), Conel (1914), Valleau (1915), Brooks
and Fisher (1916), and Bartram (1916), in which the writers conclude that the
Brown Rot organism occurring in America is identical with Monilia cinerea.
Bon., of Europe. ‘ Peach Canker,’ attributed by Jehle to Sclerotinia cinerea
(1913) or A. fructigena (1914), is found by McCubbin (1918), working in
Ontario, to be due' mainly to Valsa leucostoma , though the initial lesions
in many instances are caused by the ‘ Brown Rot fungus ’.

The Brown Rot diseases are also common in Australia,1 and in New
Zealand, as shown by Mansfield (1916), Cockayne (1918), and Cunningham
(1918).

Articles recording experiments bearing on the physiological activities
of fungi frequently give some attention to the Sclerotinias of fruit trees,
e.g. Behrens (1898), Schellenberg (1908), Bruschi (1912), Cooley (1914),
and Brooks and Cooley (1916).

III. General Observations.

In addition to observations already recorded in reference to a ‘ Blossom
Wilt and Canker of Apple Trees’ (1917), and a ‘Wither Tip of Plum
Trees’ (1918), examination of diseased fruit trees in various districts of
Kent, and of specimens received from other sources, has yielded further
interesting information relative to the occurrence and mode of parasitism of
Monilia cinerea and M. fructigena, and the following notes supplement
those records of observations in the open which have already been
published.

(a) The Occurrence of Monilia fructigena and M. cinerea on Prunus spp .

It has been generally assumed that M. cinerea is wholly, or almost,
restricted to the stone-fruit trees ( Prunus spp.), and M . fructigena to species
of Pyrus. This assumption has arisen from the observations recorded by
continental workers, and does not necessarily obtain in this country ; in
fact, M. fructigena is often found on cherries and plums, while a form of
M. cinerea is responsible for a serious Blossom Wilt of apple trees. The
records of the occurrence of M. cinerea on stone-fruit trees on the Continent
have been chiefly in reference to the disease on the ‘ Sauerkirsche ’. The
acid cherry trees grown in England are also very susceptible to attack from
M. cinerea , the blossom, fruit, and branches being killed ; in no instance
have I foufid M . fructigena on the acid cherry. In Kent the sweet cherries

1 Vide McAlpine’s ‘ Fungus Diseases of Stone Fruit in Australia’, p. 53. Melbourne, 1902.-

368 Wormald . — 4 Brown Rot ’ Diseases of Fruit Trees.

are cultivated on a much greater scale than the acid cherries, and on these
M. fructigena is frequently found on the ripening fruit, while M. cinerea not
only occurs on the fruit, but may sometimes cause a serious Blossom Wilt,
as in the spring of 1918.

Both species are found on ripening and mature plums ; sometimes
M. cinerea is the predominant species present, on other occasions M. fruc-
tigena. In 1916 two growers, one in Sussex, the other in the Maidstone
district of Kent, complained of serious losses by Brown Rot at the time of
picking ; samples sent to Wye College were found in each case to be
affected by M. fnictigena only. On the other hand, an orchard of Czar
and Bush plums, near Maidstone, visited by the writer at the time the fruit
was being gathered in 1917, was found to be infected by M. cinerea almost
exclusively, a few examples only being found with M. fructigena. In
another orchard, plums (varieties Monarch and Victoria) were attacked by
the two species almost equally ; in some instances the same cluster of plums
bore both species, and occasionally the two were found on one and the same .
plum (see Figs. 1 and 2).

Both species occur on damsons, M. cinerea , as far as my own experience
goes, being the more frequent. On peaches I have found M . fructigena on
the ripening fruit and M. cinerea on dead twigs, but have not yet met with
apricots affected with Brown Rot.1

{b) The ‘ Wither Tip ’ Disease of Plum Trees in 1918.

This disease, which was prevalent in Kent in 1916, was practically
absent in the following year, but reappeared with its former intensity in
1918, when it was again (as in 1916) associated with an attack of aphides
( Aphis pruni). Specimens of the ‘Wither Tip’ disease, received from
Worcestershire and Norfolk, also bore traces of aphides on the leaves.
The simultaneous occurrence on plum trees of the attack by the aphis and
the outbreak of the Monilia disease of the vegetative shoots lends support
to the theory that the insect renders the trees more susceptible to ‘ Wither
Tip ’, either by aiding the dispersal of the conidia, by carrying them from one
shoot to another, or by so injuring and weakening the leaves by punctures
that the fungus is able to invade the tissues of the leaves and then the
shoots ; probably both these factors are operative during a severe infection.

Observations in 1916-17 proved that on diseased shoots infected in
1916 pustules of Monilia cinerea appeared during the following winter and
spring. An examination of the same twigs (which had been labelled on
the trees) in 1918 showed that pustules with viable conidia were again to
be found on some of them, though many bore no fertile pustules at that
time. Such twigs, therefore, may serve as sources of infection for two years.

1 While this paper was in the press apricot twigs, bearing a fungus morphologically identical
with M. cinerea , have been received at Wye from Norfolk.

Wormald. — ‘ Brown Rot ’ Diseases of Fruit Trees . 369

(c) Sources of Infection on Plum Trees.

It is only during years of abnormal weather conditions, such as
obtained in the spring of 1918, that heavy losses are produced on sweet
cherries by the Brown Rot fungi. The plum tree, however, proves generally
to be more susceptible, and each year extensive damage to the crop is
reported. Monilia fructigena appears to be confined to the fruit, and
persists from year to year, so far as is at present known, only on the
mummied fruit, in this country. M. cinerea , on the other hand, not only
attacks the fruit, but also the flowers, leaves, young shoots, and branches,
thus not only directly reducing the cropping powers of the tree, but
providing numerous sources of infection for the developing fruit.

From observations made at Wye it was found that at the time the
fruit is about half grown, pustules of M. cinerea may be found on

(1) mummied fruit, the result of infection during the previous year ;

(2) flowers killed in the spring of the current year ;

(3) newly-attacked leaves on the vegetative shoots of the current

year ;

(4) vegetative shoots killed during the previous year ;

(5) cankers formed the previous year on the branches.

The ‘ Wither Tip ’ condition may occur also on the ‘suckers’ at the
base of the trees, and on those shoots growing out from the stumps of
trees cut down ; these serve as sources of infection which may easily escape
observation.

(d) An Epidemic Outbreak of a ‘ Blossom Wilt ’ of Plum and
Cherry Trees in 1918.

In 1918 the yields of the plum and cherry crops were far below the
average. From investigations made in Kent it appeared that the failure
was largely due to Monilia cinerea aided by weather conditions particularly
favourable for the dissemination and development of the fungus during the
period when the trees were in bloom, the atmosphere being almost con-
tinually saturated with moisture for about a week. The following factors
contributed in inducing the epidemic outbreak of the disease :

(1) The low temperature retarded the development of the flowers,
which on opening remained receptive and liable to infection for a relatively
long period ; this was partly owing to the fact that the cold wet weather
decreased the activities of pollinating insects.

(2) The successive expanding of the flowers extended over a period
long enough for those primarily infected to produce pustules of conidia
during the time that later flowers were in progress of opening ; these
flowers which expanded towards the end of the flowering period were

370 Wormald '. — ‘ Brown Rot ’ Diseases of Fruit Trees.

therefore liable to infection from two sources, viz. mummied fruit and
infected flowers.

(3) The pustules borne by the mummied fruit became extremely
pulverulent with conidia (the saturated atmosphere being particularly
favourable for their development) during the period when the flowers
were open.

Another important factor was the great fertility of the trees during
the previous season, in consequence of which many plums and cherries had
remained unpicked and had become infected with Monilia , with the result
that they persisted on the trees as ‘ mummies ’ and served as the primary
source of infection during the spring of 1918.

{e) Monilia cinerea and M. fructigena on Pyrus spp .

The assumption that Monilia cinerea rarely occurs on the c cored fruit ’
has been negatived during recent years, the fact that this species may
frequently cause the destruction of 50 per cent, to 75 per cent, of the
inflorescences of certain varieties of apple trees and that it is generally
distributed throughout the fruit-growing counties in the south of England
being sufficient evidence that on those varieties of apple trees it is far
more dangerous than M. fructigena. The latter species occurs almost
exclusively on the fruit, but occasionally extends from the infected apple
into the fruiting spur (Fig. 3) or even into the branch to form a canker
(Fig. 14). M. cinerea , on the other hand, infects the flowers and, rapidly
advancing into the spurs, kills them, and cankers, girdling the branches,
are often produced (see Figs. 10-13). The statement made in 1917 that
I had never found M. cinerea on maturing or ripe apples still holds good.

With reference to the Brown Rot Canker disease, earlier observations
appeared to show that the fungus produces fructifications on spurs and
cankers during the winter and spring following their infection, and that
subsequently the fungus produces no more pustules, but dies away,
and the cankers become covered by the development of callus (see
Fig. 16). More recent observations have shown that, although this is true
as a general rule, in some instances infected spurs have developed pustules
during the second year after infection. Thus in the summer of 1917 it
was found that a few of the spurs labelled as being infected in 1915, and
which had produced pustules in 1916, also bore pustules in 1917 ; in one
instance a spur which had been infected from artificial inoculation of the
inflorescence from a pure culture in 1916, and had borne fructifications in
1917, produced still other pustules with viable conidia in 1918, though the
canker which had been formed at the base of the spur was by this time
almost healed over by callus (see Fig. 13, which shows the spur and canker
here referred to, photographed in March, 1918). In every case observed
where a canker has been produced that has not completely girdled the

Wormald.-- Brown Rot ’ Diseases of Fruit Trees. 371

branch the lesion tends to become healed quite early (Fig. 16), and no
more pustules develop on the cankered surface of the branch itself subse-
quent to the year following infection. When, however, the canker girdles
and kills the branch the lesion cannot be healed and the fungus may
persist in the tissues of the canker for several years. In the spring of 1917
large cankers bearing numerous pustules were removed from affected trees ;
some of these were placed in a pot on the ground, others were suspended
at about 3 feet above the ground level. In January, 1919, those cankers
which had been suspended still bore numerous powdery pustules (see
Fig. 12) ; of those on the ground most had lost their bark and no pustules
were present, while the rest bore a few pustules at the upper end. Such
cankers, therefore, may serve as sources of infection for at least three
years.

Another feature, not previously recorded, in connexion with this
disease is the fact that when a leading branch is girdled by a canker,
which, as already shown,1 occurs about the end of June when the tree is
growing vigorously, the upward flow of sap is suddenly checked and
diverted into the buds immediately below the canker, with the result that
these buds are stimulated to grow out into weak vegetative shoots instead
of developing into fruiting spurs (Fig. 15). A similar result has been
described and figured as occurring on plum trees affected with the ‘ Wither
Tip ’ disease.2 On pear trees I have met with Monilia cinerea on one
occasion only, when it was found on a young pear about 1 cm. in length,
while M.fructigena often occurs, causing a brown rot, on the ripening fruit.

Pyrus japonica is subject to a Blossom Wilt similar in general appear-
ance to that of the apple tree. I have isolated the fungus in one case, and
it proved to be similar physiologically and biologically to the form of
M . cinerea obtained from plums and cherries.

IV. Methods adopted in isolating Pure Strains.

The strains of Monilia used in the experiments recorded in this paper
were all c pure ’, each being derived from a single conidium ; the conidia
were obtained for this purpose either directly, from naturally infected
specimens bearing fructifications, or indirectly from cultures prepared with
the object of inducing the development of conidia in those cases where
mycelium only was present in infected material.

A method of isolating pure strains of Monilia from infected tissues
containing mycelium has been described in previous papers (1917-18), and
brief references have there been made to a method of obtaining strains
from single conidia. The latter given in detail is as follows : Two watch-

1 Vide Ann. Appl. Biol., vol. iii, p. 167.

2 Vide ibid., vol. v, Plate VIII, 'Fig. 3.

372 Wormald. — ‘ Broivn Rot ’ Diseases of Fruit Trees.

glasses, held in forceps, are passed several times through a Bunsen flame;
one is then inverted over the other and both allowed to cool, when into the
lower is poured about i c.c. of sterilized distilled water. Particles of
pulverulent pustules are brought in contact with the water, and the conidia,
becoming detached, float on the surface. By means of a flamed platinum
wire loop (i mm. diam.) drops are transferred from the watch-glass to the
surface of sterilized nutrient agar in a Petri dish. As this operation is
carried out in a room set apart for culture work it was found possible to
examine these drops directly, the cover of the dish being removed, under
a low power of the microscope with but little risk of contamination. Since
the conidia float on water the surface of the drop is brought into focus and
examined for the presence of floating conidia. Generally with one loopful
three drops of water can be deposited on the agar without recharging the
loop, and this is a convenient number to examine before evaporation causes
their obliteration. When a drop is found to contain a single conidium the
cover of the dish is replaced and a ring of ink is made on the bottom of
the dish to mark its position. Several such marked drops having been
obtained, the dish is placed in a drawer at room temperature until the
following day. After twenty-four hours the inverted plate is examined under
the microscope with a i-inch objective. One of the rings of ink is brought
into the field and the microscope tube is gradually lowered until the agar is
in focus as indicated by the appearance of numerous small granules; the
layer of granules last seen before they disappear from view indicates the
surface of the agar, and this is then examined at that level for the germi-
nating conidium within the ring of ink, the blurred outline of which is still
discernible.

It will, in general, be seen at this stage whether the conidium is truly
isolated or whether contamination has taken place. In most instances the
length of the germ tube and its mode of growth were also noted, and it was
generally found that the germ tube of M . fructigena could be distinguished
from that of M. cinerea }

On the second day after isolation they are again examined and two
or three of those which are found to be uncontaminated, and quite isolated
from other germinating conidia, are transferred to another agar plate.
Usually this transference is made after forty-eight hours, but occasionally,
when the temperature of the room was low and growth had not been
vigorous, the sporelings were removed on the third day after the isolation
of the conidia. When the resulting mycelial discs are 2-3 cm. in diameter
(representing about eight days’ growth) small portions of the mycelium are
removed from the periphery of the disc and placed on agar slants in test-
tubes for future use, and when conidia are required sub-inoculations are
also made on sterilized potato.

1 Further details will be given in Part II of this papqr.

W or maid. — ‘ Brown Rot ’ Diseases of Fruit Trees. 373

In this way purity of culture is ensured, for should contamination
arise from fungus spores, or by bacteria capable of growing on the culture
medium employed, it would be detected during the forty-eight hours suc-
ceeding isolation, and should the sporeling be contaminated by bacteria
which do not develop under those conditions and would therefore escape
detection, they are eliminated by taking mycelium from the peripheral
region of the mycelial disc after growth has proceeded for a few days.
This method was the one adopted for obtaining the ‘ single spore strains ’
of Monilia frnctigena and M. cinerea (used in the experiments described
in this paper) when viable oonidia were available, i. e. when the fungi were
developing pulverulent pustules.

When the parasites occur as barren mycelium in the tissues of the
host they are induced to produce conidia on sterilized potato as already
described in the papers on ‘ A Blossom Wilt and Canker of Apple Trees’1
(1917) and ‘ A Wither Tip of Plum Trees’2 (1918). The conidia are then
isolated and single spore strains obtained as described above.

Single spore strains of Monilia fructigena were prepared directly from
the conidia of fertile pustules on apples or apple spurs, or indirectly from
barren pustules (winter condition) by placing particles of the pustules on
the nutrient agar, thus inducing vegetative growth for sub-inoculation on
potato for conidia production. ‘ Black Rot ’ strains of M. fructigena were
also obtained indirectly by first stimulating vegetative development from
particles of the diseased apple flesh (permeated with mycelium) placed on
the agar.3

V. Inoculation Experiments with Monilia cinerea and

M. FRUCTIGENA.

(a) Apples inoculated with Strains of the Two Species.

Experiments carried out on apples in 1916 with the object of comparing
the action of that form of Monilia cinerea which causes the Blossom Wilt
disease of apple trees with that of a strain of M. cinerea isolated from a plum
affected with Brown Rot, and with that of a strain of M. fructigena also
obtained from a plum, have already been described in a previous paper (1917).
It was there shown that the mode of development of the Blossom Wilt
form of Monilia under those conditions (growing on immature apples in
the laboratory) was different from that of either of the other two forms
in that the brown coloration of the affected areas rapidly became dark
brown and finally black in the case of the Blossom Wilt strain, while the

1 Loc. cit., p. 174. 2 Loc. cit., p. 33.

3 The writer has found the method here described (slightly modified in the case of spores or
. conidia which do not float in water) of obtaining ‘ single spore strains ’ suitable for other fungi with
reproductive bodies large enough to be easily seen under a low power of the microscope.

374 Wormald. — ‘ Brown Rot ’ Diseases of Fruit Trees .

other two strains failed to induce this nigrescence except on fully matured
apples inoculated some time after they had been picked and stored ; it was
also to be distinguished from the fact that on the apples so infected it
produced very few pustules, or in some instances none at all, while the
strains of M. cinerea and M. fmctigena from plums readily developed
pustules.

During 1917 another series of experiments was carried out using the
same strain of the Blossom Wilt fungus (which, however, had been re-isolated
from an apple spur infected from a pure culture) and other strains of Monilia
cinerea and M . fmctigena. In this series, Experiments Nos. 4 and 5 were
made on apples growing on a tree in the open, Nos. 1, 2, 3, 6, and 7 on
apples which were inoculated and kept under laboratory conditions. In
the latter case, the fruit after inoculation was placed in a glass vessel which
had been sterilized on the inside by a thorough cleansing with cotton-wool
soaked in 95 per cent, alcohol. The actual inoculation consisted in making
a small V-shaped cut through the skin, removing a particle of the tissues
underneath, and inserting mycelium from an agar culture of the fungus, the
skin being then turned back into position. When the resulting ‘ Brown Rot ’
had developed for about seven days, by which time the fungi had become
well established in the tissues, the apples were placed under bell-jars on
a slate slab (which had also been cleansed with alcohol), the jars being
raised above the surface of the slab on glass supports 1 cm. in height, thus
allowing for a circulation of the air. This method, though not excluding
the possibility of infection by other organisms during the latter stages of
the experiment, provided conditions less abnormal than would have been
the case had the apples been kept in an enclosed space throughout the
experiment, and as no other organisms appeared it is to be concluded that
the results obtained were produced by the fungi inserted in the wounds.

In 1917 inoculation experiments on apple flowers showed that the
strain of Monilia cinerea obtained from a c withered tip ’ of a plum tree was
unable to induce the Blossom Wilt condition on the flowering spurs of the
apple ; other experiments carried out in 1918 (described in detail in the
present paper) with other strains from plum and cherry also failed to
produce the Blossom Wilt on apple trees. The ‘ Blossom Wilt and Canker’
form of Monilia cinerea is therefore distinct biologically from that occurring
generally on the species of Prunus , and it is proposed, for convenience, to
refer to it in describing the following experiments as Monilia cinerea forma
mali and the form on plum and cherry as M. cinerea forma pruni. Strains
of Monilia obtained from America have also been used, and, as these have
certain characters in common which distinguish them from M. cinerea as
found in Europe,1 they will be referred to as M. cinerea forma americana.

1 Vide Ann. Appl. Biol., vol. iii, No. 4, p. 180.

Wormctld. — ‘ Brown Rot ’ Diseases of Fruit Trees. 375

Experiment i.

Strains used

f. Monilia cinerea forma mail.

[M. fructigena , strain from apple spur.

Two apples (var. Bramley’s Seedling) were each inoculated on one side
with a strain of the apple Blossom Wilt form of Monilia cinerea , and on the
opposite side with a strain of M. fructigena obtained from an apple spur
which had become infected through the fruit. The inoculations were made
on September 14, 1917, with the following results :

September 21. In both apples on the side inoculated with Monilia
cinerea the rot had extended 2 -5-4- 5 cm. from the point of inoculation ; no
pustules were present, but conidiophores had developed along the cut at
the place where the inoculation was made ; the discoloration was a deep
brown, with darker, more or less concentric zones ; many of the lenticels
were marked with dark circles.

On the side inoculated with M. fructigena the rot had extended
3-3*5 cm. ; a few yellow pustules, to 2 mm. in diameter, were present, and
conidiophores had also developed along the wound ; the discoloration of
the surface was a bright brown, except in the immediate neighbourhood of
the point of inoculation, where the colour was darker for about 1 cm.

October 12. M. cinerea had extended through about two-thirds of
each apple, the surface on that side being black in colour ; the skin was
hardly shrunken and bore no pustules. M. fructigena had made less
progress, about one-third of the surface being affected ; the skin was bright
brown in colour, much shrunken, and bore numerous yellow pustules.

October 25. There was no further change except that the shrinkage
was more pronounced, particularly on the side infected with M. fructigena.

These results were essentially the same as those obtained in 1916,
when a strain of M '. fructigena obtained from a plum had been compared
with the Blossom Wilt form of M. cinerea (see Figs. 4 and 5).

Experiment 2.

~ . . ( Monilia cinerea forma mali.

Strains used! r

\Moniha cinerea forma prum.

Two apples were each inoculated on one side with the apple Blossom
Wilt strain used in Experiment 1, and on the other side with a c Wither
Tip ’ strain of M. cinerea from a plum tree. The inoculations were made
on September 14, 1917.

376 Wormald. — ‘ Brown Rot ’ Diseases of Fruit Trees.

Result.

Apple No. i on side inocu-
lated with M. cinerea forma
mali.

Apple No. i on side inocu-
lated with M. cinerea forma
pruni.

Apple No. 2 on side inocu-
lated with M. cinerea forma
mali.

Apple No. 2 on side inocu-
lated with M. cinerea forma
pruni.

Sept. 2i.

Discoloration extending 4-4-5
cm. from inoculated wound,
dark brown in zones, no pus-
tules present, conidiophores
along cut

Discoloration extending 2-5-3
cm., from wound, bright brown
with a slightly darker margin ;
a few minute scattered pustules.

Discoloration extending 4-6
cm. dark brown in zones ;
a few small scattered papillae ;
conidiophores along cut.

Discoloration extending 1.5-3
cm. from wound ; many small
pustules present and conidio-
phores along the cut.

Oct. 12.

A little more than half the
surface of the apple black , not
shrunken ; no pustules, but a
few small barren papillae
present.

This side (rather less than half
surface') brown and distinctly
marked off from the black
portion ; not shrunken ; no
powdery pustules, but numerous
papillae present.

As in Apple No. 1.

Numerous small grey pul-
verulent pustules present ; skin
distinctly shrunken and
wrinkled, brown.

October 25. No further definite change in any of the apples except
that the shrinkage is a little more pronounced.

The two strains used in this experiment were the same as those used
in the inoculation of apple flowers as described in the paper on ‘ A Wither
Tip of Plum Trees’ (1918); in that paper it was shown that the Wither
Tip strain failed to induce the typical ‘ Blossom Wilt ’ condition on an
apple tree, while on the same tree inflorescences inoculated with the Blossom
Wilt strain quickly succumbed. In the case of these two strains the degree
of the virulence of their parasitism on apple flowers is associated with
differences in their physiological relations with the host tissues when
growing on the fruit of the apple tree.

Experiment 3.

1 Monilia cinerea forma mali.

Monilia cinerea forma pruni.

Strains used- Monilia cinerea forma americana.

1 Monilia fructigena, strain from an apple spur.

' Monilia fructigena , strain from a f Black Apple’.

Fifteen apples (all of one variety, viz. Bramley’s Seedling) were selected
as being free from blemishes, divided into groups of three, and the groups
respectively inoculated with the five strains of Monilia . The strains of the
forms mali and pruni of M. cinerea were the same as those used in
Experiment 2, and the strain of M. fructigena obtained from an apple
spur was that used in Experiment 1. The present experiment, therefore,
served as a duplicate of the previous ones, and also introduced for com-

W or maid. — ‘ Brown Rot ’ Diseases of Fruit Trees. 3 77

parison the American form of M. cinerea and a £ Black Apple ’ strain of
M. fructigena.

The apples were inoculated on October 26. ‘ Brown Rot ’ soon

appeared in all of them except ^one of those inoculated with the £ Black
Apple * strain of M. fructigetia , and as, with this exception (in which
infection failed), the results obtained in any one series were approximately
uniform, they are described in the table in general terms.

Strain of Monilia.

M. cinerea
f. malt.

M. cinerea
f. prnni.

M. cinerea
f. americana.

Result.

Nov. 3.

The rot had extended 2. 8-4*0 cm.
from point of inoculation ; pustules
absent; distinct but irregular dark
brown zone at 1 -5-2.5 cm. from the
wound.

Extension of rot 2. 2-3-5 cm. ;
numerous grey pustules on one
apple and a few on the others.

Extension of rot 2.0-3. o cm. ;
discoloration brown, with a darker
zone at o^-i-o cm. from wound;
pustules few, small (about 1 mm.
diam.), and grey.

Nov. 30.

One apple quite black, the other
two black over nearly the whole
surface, the remaining portion being
dark brown ; pustules minute, few
in number ; skin very slightly
wrinkled.

Surface of all three a bright brown ;
no nigrescence except for a few
millimetres immediately round the
wound ; numerous grey pustules
about 1 mm. diam. ; skin much
shrunken and wrinkled, particularly
w-here the pustules were closely
aggregated.

All three quite black with the
exception of a small brown patch on
one of them ; pustules few, small,
grey ; skin slightly wrinkled.

M. fructigena.

Strain from apple
spur.

Extension of rot 1.8-2. 5 cm.;
pustules absent ; discoloration
brown, with a narrow peripheral
zone a little darker.

All three brown to dark brown ;
pustules yellow, to 3 mm. diam.,
very numerous ; surface of apples
much shrunken and wrinkled.

M. fructigena.

Strain from a ‘Black
Apple ’.

Extension of rot 1.5-2. 7 cm.;
pustules absent ; discoloration
brown, with a narrow peripheral
zone a little darker.

All three brown to dark brown ;
pustules yellow, to 3 mm. diam.,
very numerous ; surface of apples
much shrunken and wrinkled.

Strains used

Experiment 4.

Monilia cinerea forma mali.

Monilia fructigena , strain from an apple spur.

On July 6, j 9 1 7, six apples (var. James Grieve), growing in the open,
were inoculated with M. cinerea and eight with M. fructigena ; a number
of apples wounded but not inoculated served as controls. In each series
infection failed in two of the apples. Those which became infected had
all fallen by July 20, so that it was decided to repeat the experiment,
and other apples were inoculated with the same strains on July 254, as
described under Experiment 5. The results obtained to July 20 are to
be noted, however, for comparison with those recorded in the next
experiment.

378 W or maid. — ‘ Brown Rot ’ Diseases of Fruit Trees .

The apples infected with M. fructigena became within eight days
discoloured over more than half the surface ; in one case the whole surface
was brown. At this stage a pale raised circular pustular zone, covered by
the epidermis, had developed at approximately i cm. from the point of
inoculation ; a few days afterwards yellow pulverulent fructifications of
M. fructigena burst through the skin in that zone,, and later numerous
pustules appeared on the rest of the surface.

Of the apples infected with M. cinerea two had become discoloured
over three-fourths of the surface, the other two over the whole surface, but
no pus tides had developed.

In both series the apples in which inoculation had failed to produce
infection were still on the tree on July 20, as were also all the control
apples.

Strains used

Experiment 5.

Monilia cinerea forma mall

Monilia fructigena , strain from an apple spur.

This experiment was carried out on apples (var. James Grieve) growing
in the College plantation. The apples were inoculated on July 24 by
making in each a single puncture with a sterile needle, and inserting in the
puncture a particle of a pustule obtained from a pure culture of the fungus
growing on sterilized potato. Ten apples were inoculated with each of the
two strains, and, to serve as controls, ten apples were punctured but not
inoculated.

M. cinerea
f. mali.

Result.

July 26.

Rot had commenced in all the
apples, the brown areas round the
punctures varying from 3 to 13 mm.
in diameter.

July 30.

About half the surface of each was
discoloured ; four of the apples bore
no pustules whatever, four had a few
scattered pustules, and on one only
were they at all comparable in
number to those occurring on the
apples infected with M. fructigena ;
the pustules were ashy grey in colour
and the largest was about 0-5 mm.
in diameter.

M. fructigena. Rot had commenced in all, the About half the surface of each was

affected area being 3-13 mm. in discoloured and all bore yellow
diameter. (light buff) pustules to 2 mm. in

diameter ; the pustules were almost
localized to a definite circular zone
at about 1 cm. from the point of
inoculation.

No rot appeared on any of the control apples.

Strong winds, which occurred early in August, detached all the
inoculated apples except one. The exception was one infected with
M . fructigena. which had been in contact with the bark of the branch ;
the development of numerous pustules served to attach the apple to the

Wormald.- — ‘ Brown Rot ’ Diseases of Fruit Trees . 379

bark, so that although the stalk had become almost severed at the point of
its insertion on the fruiting axis, being connected only with a narrow strand
of fibrous tissue, the apple still remained in situ .

Of the apples found on the ground those inoculated with M. fructi-
gena were by this time almost entirely covered with yellow pulverulent
pustules, while on those inoculated with M. cinerea the pustules were few
and small or absent altogether. Most of the apples used as controls were
still on the tree.

Experiment 6.

Monilia fructigena , when growing in stored apples, frequently causes
a ‘ Black Rot ’ similar in appearance to that produced on those apples
artificially inoculated with M. cinerea f. mali. Spinks (1915), investigating
a ‘ Black Rot ’ of cider apples, found that ‘ the apples of the same variety
showed the same type of rot irrespective of the fungus with which they
were infected ’, and that ‘ it seemed certain that the type of rot produced in
an apple by Monilia fructigena depended only on the apple itself ’.
An experiment carried out at Wye in 1916 shows that this is not invariably
the case, as seen by the results here recorded.

Strains used

'Monilia fructigena , strain from a plum.

Monilia fructigena , strain from a ‘ Black Apple ’.

Four apples (variety Bramley’s Seedling) were each inoculated on one
side with a strain isolated from a pustule of M. fructigena growing on
a plum, and on the other side with a strain isolated from the fleshy tissue
of an apple affected with ‘ Black Rot ’ ; the inoculations were made on
September 8.

Result.

Side inoculated with Plum strain.

Side inoadated with 1 Black Apple ’
strain.

September 13.

A brown discoloration extended
from point of inoculation for 2.5-
3 cm. ; pustules from 60 to 90 in
number. The discoloration was
a uniform brown, no dark circles at
the lenticels.

Discoloration extended 2*5-3 cm.
from point of inoculation ; the
pustules on the four apples numbered
respectively 1, 4, 2, and 13. The
discoloration was darkest towards
centre of affected area, shading off
to a brown of the same tint as that
on side infected with the plum
strain ; dark brown circles round
lenticels.

September 18.

The whole side was now a uniform
brown ; no black circles at lenti-
cels ; pustules numerous.

Brown colour still darker round
point of inoculation ; pustules few
and scattered; black circles round
the lenticels.

October 12.

Pustules numerous, in an almost
continuous layer, but showing some
tendency to form concentric circles
round the centre of infection; the
skin, where it could be seen between
the pustules, was dark brown to
black,

Pustules few and scattered ; skin
dark brown to black, nigrescence
most conspicuous immediately round
the lenticels.

380 W or maid. — ‘ Brown Rot ’ Diseases of Fruit Trees.

Since this experiment pointed to a difference in the physiological
reaction of the two strains to the tissues of the apple in which they were
growing, the experiment was repeated in 1917 (see Experiment 7) for
confirmation of the results, using the same two strains, which in the interval
had been cultivated on sterilized media in the laboratory. The results
were even more striking than in 1916, showing that the difference was still
maintained even after cultivation for twelve months, under similar conditions,
as saprophytes.

Experiment 7.

Strains used — as in Experiment 6.

Two apples were inoculated, as in the previous experiment, on one
side with the strain from a plum, and on the other with the ‘ Black Apple ’
strain ; the inoculations were made on September 14, 1917.

September 21.

October 12.

Result.

Side inoculated with Plum strain.

The affected area extended 4-5-5
cm. from point of inoculation ; it
was bright brown in colour with
a rather darker narrow peripheral
zone. Numerous yellow pustules,
to 2 mm. diam., were present, grow-
ing in irregular concentric circles,
the first at i cm. from the centre.

The whole of this side was now
a bright brown and bore numerous
yellow pustules ; it was much
shrunken and the skin wrinkled.

Side inoculated with 1 Black Apple ’
strain.

The rot extended 1-2.3 cm. from
the point of inoculation ; one apple
was of a distinctly darker brown on
this side than on the side infected
with the plum strain, particularly
in a zone 1-2 cm. from the centre,
while on the second apple this
deeper shade was represented only
by two blackish spots at 1 cm. from
the centre. No pustules were pre-
sent, but conidiophoreshad developed
along the wound.

Skin black and but very slightly
wrinkled ; no pustules present.

On October 12 the line along which the two strains met was sharply
marked, and the black colour of the one side, with its almost smooth skin
and absence of pustules, formed a striking contrast to the other (Fig. 7).

By October 25 there was no further change except that the
shrinkage was more pronounced, particularly on the side infected with the
plum strain.

Summary of Results of Inoculations on Apples.

Monilia fructigena and M. drier e a, when growing on apples, can be
distinguished morphologically, the former producing large (up to 2 or even
3 mm. in diameter) yellow pustules, the latter smaller grey ones.

In each species there are two forms which are different physiologically :
one which, when growing under the conditions which obtained during the
course of the experiments, develops many pustules, and produces a brown

Wormald. — ‘ Brown Rot 9 Diseases of Fruit Trees, 381

discoloration throughout the affected tissues, and another which develops
few or no pustules and causes a discoloration which, primarily brown,
gradually becomes darker in the superficial layers until eventually the whole
surface is quite black.

Growing apples infected with either species are far more easily
detached from the tree than the sound fruit, unless they become attached
to the bark, or to other apples in contact with them, by means of the
pustules at the point of contact. This fact suggests a reason for the rare
occurrence of M. cinerea . on apples, for the small and comparatively few
pustules which it produces appear to be insufficient, to attach the fruit to
the tree even should infection occur. The writer has occasionally found
M. cinerea f. mali on the very young fruit, but never on any approaching
maturity, even on trees severely attacked by the Blossom Wilt disease,
while M. frnctigena , which usually develops numerous large pustules on
maturing apples, is extremely common.

Apples, when infected with a form which produces numerous pustules,
soon become shrunken and wrinkled, while the skin of those infected with
strains which do not develop pustules under those conditions often remains
firm and smooth for some time after it has become quite black. The rapid
desiccation of the tissues when pustules are present is probably due to two
causes : (a) the rupture of the ep.idermis permitting evaporation from
within ; (b) loss of water by reason of the respiratory and transpiratory
processes in the cells of the hyphae and conidiophores of the pustules.1

(b) Plums inoculated with the Tzvo Species .

These experiments were carried out in two series: (1) inoculations
made with the object of comparing the morphology of the two species
when growing on plums ; (2) inoculations with strains of Monilia cinerea
for comparing results obtained with the form mali with those of the form
pruni.

The results obtained from inoculating growing plums with a ‘ Wither
Tip ’ strain of M. cinerea have already been published (1918). A similar
experiment was made about the same time, i. e. July 1917, using
M. frnctigena ; the resulting brown rot was indistinguishable in general
appearance from that produced by M. cinerea , but the pustules which
developed were larger, and yellow in colour. Both species were able to
cause infection of uninjured plums in contact with diseased ones by the
development of modified pustules at the point of contact, a pad of hyphae
being formed which was able to penetrate the skin.

For confirmation of these results, and to obtain a more exact com-
parison of the two when growing on plums, an experiment was started

1 When apples bearing numerous M Ottilia pustules are placed in a closed glass vessel, moisture
condenses on the internal surface of the vessel within a few hours.

E e 2

382 Wormald. — f Brown Rot ’ Diseases of Fruit Trees,

in which inoculations were made simultaneously with the two species on
plums in close proximity and also on opposite sides of the same plum.

Experiment i.

'Monilia fructigena, strain isolated from a plum.

Strains used-! Monilia cinerea , strain isolated from a ‘Wither Tip ’ twig of
a plum tree.

Plums (variety Victoria) growing in the open were numbered and
labelled as follows :

1, 2, and 3 were each a pair of plums at the same node ; one of each
pair was inoculated with M. fructigena , the other with M. cinerea. 4, 5,
and 6 were single plums, each inoculated on one side with M . fructigena,
and on the other side with M. cinerea. In the accompanying table the
plum or side inoculated with the former is indicated by f and with the
latter by c.

The inoculations were made on July 17, 1917, by making, in each
case, a single puncture through the skin with a sterile needle and placing
conidia from a pure culture in the wound.

Six plums , three

No. of mm. through

inoculated with M.

tv hie h rot had ex-

fructigena, three with

tended from point of

M. cinerea.

inoculation by July 20.

1/

5-7

1 c

5-7

2/

8-9

2 c

6-8

3/

5-8

0 c

4-6

Three plums , each
inoculated on one side
with M. fructigena,
on the other with

M. cinerea.

4/

9-12 )

c

6-9 5

5/

8-9 }

c

5-7 )

6/

9-10 )

c

5-6 \

Result on Jtily 26.

The whole

yellow pustules

the

fruit - stalk

surface was

were present ;

was

brown for

discoloured ;

3 mm.

V

numerous

grey pustules

„ 4 mm.

yy

yellow pustules

>>

„ 3 mm.

yy

grey

>>

,, 12 mm.

yy

yellow ,,

,, 3 mm.

y y

grey

yy

,, 3 mm.

The two fungi had met in a plane approximately
midway between the two points of inoculation ;
M. fructigena had produced fairly numerous yellow
pustules, M. cinerea numerous grey ones ; the
stalk was brown for 8 mm.

As in No. 4, but stalk brown for 3 mm.

As in No. 4, but stalk brown for 12 mm.

The discoloration of the plums was a dull purple brown with both
species ; on the whole, the distance from the point of inoculation reached
by M. fructigena after three days was a little greater than that attained

Worm aid.- — ‘ Brown Rot ’ Diseases of Fruit Trees. 383

by M. cinerea , the maximum extension for the former being 12 mm. and
for the latter 9 mm. The brown colour on the fruit-stalk extended
upwards from the point of insertion on the plum, indicating that the
disease was advancing from the fruit, along the stalk, towards the branch.

The pustules of M.fructigena were to 1*5 mm. in diameter, usually about
1 mm., and their colour was ‘ Light Buff’ of Ridgway’s colour charts;1
those of M. cinerea were conspicuously smaller, reaching a maximum diameter
of o*8 mm., the usual diameter being about 0-4 mm., and their colour was
‘ Smoke Grey ’ to { Light Greyish Olive \

On July 27 plums Nos. 2 f and 2 c were removed from the tree and
photographed, together with a sound plum from the same tree (Fig. 8) ;
the plum No. 6 was also photographed on the same day (Fig. 9).

The results obtained in this experiment prove conclusively that
M. fructigena and M. cinerea are equally able to cause a 5 Brown Rot ’ of
plums, and that under these conditions the two species are morphologically
quite distinct, as shown by their fructifications.

Experiment 2.

The experiment recorded here is one of a series carried out with the
object of ascertaining whether the two forms mali and pruni of Monilia
cinerea could be distinguished when growing on plums. The experiments
were suggested by the fact that of all the strains of M. cinerea obtained
from plums or cherries (more than 20 in all), not one could be identified, by
the characters given later in this paper,2 as forma mali, and a reason was
sought for this absence of the apple form from species of Primus. M. cinerea
f. mali produces pustules less freely on sterilized potato and on apples (as
shown in preceding pages) than f. pruni , and it was thought that the former,
if it did occur occasionally on plums, was unable to become established
there, for experiments on apples in the open showed that pustules were
necessary for the diseased fruit to be retained on the trees as mummies.
Preliminary experiments in the laboratory proved that the form mali grows
readily when inoculated into picked plums, again with a tendency to develop
fewer pustules than does the form pruni.

During the summer of 1918 plums growing in the College plantation
were inoculated on June 21, June 24, and July 15 ; on each occasion the
strains used were :

M. cinerea forma mali, strain from a 6 Brown Rot Canker \

,, ,, mali, „ „ an apple spur.

„ ,, pruni, ,, „ a mummied plum.

„ „ pruni , ,3 „ a mummied cherry.

1 Color Standards and Nomenclature. Washington, 1912.

2 These features will be discussed in Part II of this paper.

384 Wormald . — ‘ Brown Rot ’ Diseases of Fruit Trees.

All the strains readily produced on the infected plums the characteristic
‘ Brown Rot ’ and numerous pustules. A slight difference could be detected
in the productivity of pustules in the two forms in a similar experiment
started a little later in the season, viz. Aug. 1, when the fruit was approach-
ing maturity, and the detailed results of this experiment are here tabulated.
The pustules are described as ‘ numerous ’, * many or ‘ few ’ in the following
sense :

Pustules numerous — occurring scattered over the whole surface and
often also becoming confluent to form continuous zones or irregular
patches.

Pustules many — scattered over the whole affected surface ; continuous
patches absent or few and small.

Pustules few — isolated and scattered over a portion (half or less) of the
discoloured area.

Two trees (variety Victoria) were reserved for the experiment, ten
plums being inoculated on each tree as shown in the table.

The method of inoculation adopted was similar to that used in
Expt. 1.

TREE I.

Strains used ^
in the inocula- |
tions ^

( Aug. 1).

M. cinerea 1

f. mail.

Strain from a
‘ Brown Rot ’
Canker on an
apple tree.

Aug. 6.

Aug. 13.

Aug. 28.

Half the sur- Whole surface discoloured
face affected ; and wrinkled, plum
pustules few. shrunken ; pustules many ;

two other plums in contact
with it were discoloured
over their whole surface and
bore a few pustules.

The three plums
were shrunken
and wrinkled
and bore many
pustules.

2

Half the sur-
face affected ;
pustules ab-
sent.

Whole surface wrinkled,
plum shrunken ; pustules
many; in contact with in-
oculated plum were one
wholly discoloured and
another with § of the surface
affected, both with a few
pustules.

The plum pri-
marily inocu-
lated had in-
fected 4 others ;
all were shrunk-
en and bore
many pustules.

3

The rot had
extended 1-5-
2 cm. from
point of inocu-
lation ; pus-
tules none.

Whole surface affected ;
pustules many ; another
plum, infected from con-
tagion, showed a rot ex-
tending 1-1.5 cm. from the
point of contact.

Both were

shrunken and
bore many

pustules.

4 The rot had Whole surface affected ; Fallen,
extended 1.3- pustules many.
i-8 cm.; pus-
tules none.

5

Half the sur- Whole surface affected ;
face affected ; pustules few.
pustules none.

Much shrunken
and bearing
many pustules.

TREE I.

TREE II.

W or maid. — ‘ Brown Rot ’ Diseases of Fruit Trees. 385

Strains used ^
in the inocula- § ^
tions ^

{Aug. 1).

M. cinerea 1

f. pruni.

Strain from
a mummied
plum.

Aug. 6.

Aug. 13.

Nearly half
the surface
affected ; pus-
tules none.

Whole surface affected ;
pustules numerous ; in con-
tact with it were one wholly
discoloured with two almost
continuous zones of con-
fluent pustules, and another
with half the surface af-
fected and bearing few
pustules.

2 Ditto Whole surface affected ;

plum shrunken and
wrinkled ; pustules nu-
merous.

Aug. 28.

One other had
also become in-
fected from con-
tagion ; all four
were shrunken
and bore nu-
merous very
pulverulent pus-
tules becoming
confluent and
forming patches
to 5 mm. diam.

Pustules more
numerous; plum
still more

shrunken and
wrinkled.

One-third of Ditto

the surface
affected ; pus-
tules none.

Pustules more
numerous.

4

Ditto

Nearly half
the surface
affected ; pus-
tules none.

Ditto

As above, but with another
plum in contact with it also
discoloured over the whole
surface and bearing many
pustules.

Pustules more
numerous;along
one side was a
long continuous
band (3x1 cm.)
of confluent
pustules.

Both plums
much shrunken
and bearing
numerous pus-
tules.

M. cinerea
f. mali.

Strain from a
flowering spur
of an apple
tree.

1

2

3

4

5

The rot ex-
tended 0-5-
i*5 cm. from
point of inocu-
lation ; no pus-
tules.

Slight dis-
coloration
only, imme-
diately round
the wound.

Extension of
rot i*o-i. 8
cm. ; no pus-
tules.

Whole surface discoloured
and wrinkled, plum
shrunken ; pustules many.
Another plum in contact
with it was discoloured
over half its surface and
bore a few pustules.

Whole surface discoloured
but not wrinkled and plum
not shrunken ; pustules
none.

Whole surface discoloured,
plum a little shrunken ;
pustules many.

Extension of As in No. 3, but pustules
rot 1 *0-1*5 few.
cm. ; no pus-
tules.

Extension of p. s in No. 3 ; pustules
rot i* 3-1 *5 many,
cm. ; no pus-
tules.

Both plums
shrunken and
bearing many
pustules.

Wrinkled and
shrunken ; pus-
tules few.

Wrinkled and
shrunken ; pus-
tules many.

Wrinkled and
shrunken ; pus-
tules few.

Wrinkled and
shrunken ; pus-
tules many.

386 Wormald . — ‘ Brown Rot ’ Diseases of Fruit Trees.

Strains used
in the inocula-
tion.

(Attg. i).

TREE II. M. cinerea
f. pruni.

Strain from
a mummied
cherry.

2

One-third of
the surface

affected ; no
pustules.

Whole surface discoloured ;
shrinkage slight ; pustules
many.

Wrinkled and
shrunken ; nu-
merous pus-

tules.

3

Nearly half
the surface

affected ; a few
pustules.

As in 2.

As in 2.

4

Nearly half

the surface

affected ; no
pustules.

Whole surface discoloured,
plum shrunken ; pustules
numerous.

Fallen.

5

One-third of
the surface

affected ; no
pustules.

As in 4.

Fallen.

Aug. 6.

Aug. 13.

Aug. 28.

Half the sur-
face affected ;
no pustules.

Whole surface discoloured
and wrinkled, plum
shrunken ; pustules nu-
merous. One other in
contact discoloured over
the whole surface but bear-
ing no pustules.

Both plums
shrunken and
bearing nu-
merous pus-
tules.

On August 28 some of the plums on these and adjoining trees were
ripe ; thus those affected from contact with plums artificially inoculated
must have become infected just as they were ripening, so that the observa-
tions covered the period from the time the plums were quite small (i. e.
June 21, when they were not half grown) to their maturescent period. In
the experiment started on August 1 (results tabulated) there is evidence
that on plums infected near the time of ripening the apple form of Monilia
cinerea produces fewer pustules than the Primus form ; the difference,
however, is not striking and both forms readily cause infection of other
plums in contact with those primarily infected. The experiments there-
fore afford no clear explanation of the rare occurrence (perhaps absence) of
the form mali on naturally infected plums.

The experiment is interesting as illustrating the rapidity with which
the rot traverses infected plums. Thus in most cases one-third to one-half
the surface was discoloured on the fifth day after inoculation, with the
development of pustules in two instances, while on the twelfth day not only
were all the primarily inoculated plums affected throughout, but others in
contact with these were often also discoloured over their whole surface and
bore pustules.

It may here be pointed out that experiments carried out at Wye
suggest that in this country plums are infected by the ‘ Brown Rot ’ fungi
only through wounds. Inoculations made in 1917 by placing conidia of

W or maid. — 4 Brown Rot ’ Diseases of Fruit Trees. 387

Monilia fructigenci and M. cinerea on the uninjured skin of the immature
fruit gave negative results. A similar result was obtained in 1918 when
conidia of the strain of M. cinerea obtained from a plum (the strain used in
the experiment just described) were placed on the uninjured skin of 12
young Monarch plums (not half grown) under conditions favourable for their
germination, i.e. a gentle rain was falling at the time and the atmosphere
was saturated with moisture for at least 12 hours after the inoculations
were made. A few days later 12 Victoria plums were similarly treated, and
again no infection occurred. Valleau (1915), working in America with the
form of Monilia which is found there, obtained different results, for he finds
‘that infection may take place through the uninjured skin at any time
during the development of the plum fruit’.

(e) Plum Flowers inocidated with Strains of Monilia cinerea.

During the month of April, 1918, a series of three experiments was
carried out on flowers of plum trees in the open, the number of flowers
inoculated altogether being 39.

The strains of Monilia used in each experiment were :

M. cinerea f. mali, strain from a Brown Rot Canker of an apple tree.

,, f. pmmi , strain from a mummied plum.

„ f. pruni , strain from a mummied cherry.

The inclement weather which prevailed during the latter half of April
removed many of the inoculated flowers at an early stage in the experi-
ments, but a sufficient number remained long enough for the following
conclusions to be drawn.

All three strains were equally able to cause infection of the flowers.
Each strain was able not only to kill the inoculated flower but to invade the
axis of the inflorescence and so cause the death of all the flowers at that
node. In two of the experiments, in which the conidia were placed on the
stigmas, the results were similar to those already published (1918) for
inoculations carried out in 1917 on plum flowers with a ‘Wither Tip ’ strain
of Monilia cinerea , except that the progress of the disease, particularly in
the early stages, was retarded, this being in all probability due to the lower
temperature. The first symptom of infection after inoculation of the
stigma is a brown discoloration of the stigma itself, usually within two
days ; this is followed by an extension of the browning downwards along the
style, which can be followed day by day until the ovary is reached and soon
the whole flower is affected.

In the third experiment the conidia were placed inside the flowers so
that the disc became inoculated ; in this case the first external evidence of
infection was the appearance of a brown patch at one side of the calyx tube.
Since the method adopted in making the inoculations and the results

388' Wormald. — ‘ Brown Rot ’ Diseases of Fruit Trees .

obtained in the early stages of infection in this experiment were different
from those of previous experiments the details are given in full.

Small particles of potatoes bearing conidiophores were cut from a pure
culture of the fungus growing on sterilized potato and taken to the garden
in a sterilized Petri dish, a separate dish being used for each strain. One
of the particles was inserted, on the point of a sterilized needle, within the
flower in such a way that 'the conidiophores came in contact with the disc
and deposited conidia. The potato particle was then replaced in the dish
and another taken for the next flower. Flowers were selected in which
there was sufficient space between the stamens and ovary to allow of this
operation being carried out without injuring the organs.

The inoculations were made on flowers of Monarch plum trees in the
College plantation on April i 2 ; twelve flowers were inoculated, four with
each of the three strains.

On April 21 no difference could be detected between the inoculated
flowers and others in the vicinity except in the case of one flower (No. 4,
inoculated with the cherry strain), the stamens and style of which were
withering. Three days later, however, on most of the inoculated flowers
there was evidence that infection had occurred.

Strains used in inoculations.

M. cinerea f. mali.

Strain from a * Brown Rot ’
Canker of apple.

Result , April 24.

1. No discoloration to be detected.

2. Slight browning on inner surface of calyx tube

3. No discoloration.

4. No discoloration.

M. cinerea f. pruni.
Strain from plum.

1. Ovary and base of style brown ; one side of calyx tube brown

on inner and outer surfaces.

2. Inner surface of calyx tube brown on one side.

3. One side of calyx tube brown on both surfaces.

4. No discoloration.

M. cinerea f. pruni. 1. Slight discoloration on inner surface of calyx tube.

Strain from cherry. 2. One side of calyx tube brown on both surfaces.

3. Slight discoloration on inner surface of calyx tube.

4. One side of calyx tube brown on both surfaces ; style and

stamens brown.

When the flowers were next examined, May 7, all had been blown off
except two, viz. No. 2 inoculated with the apple strain, and No. 3 with the
cherry strain. The former by this time had become withered to the base
and the disease had invaded the flowering axis and caused infection of
a second flower (also withered) inserted there, while the latter showed
a similar result, but in this case both infected flowers bore grey Monilia
pustules.

The wilting of plum flowers may be produced therefore by inoculation
of either the stigmas or the floral disc with conidia of Monilia cinerea.

Wormald . — 'Brown Rot 9 Diseases of Fruit Trees. 389

(d) Apple Flowers inoculated with Strains of Monilia cinerea.

In the course of the investigation of the ‘ Wither Tip ’ disease of plum
trees it was discovered that two morphologically similar strains of Monilia
cinerea had the power to infect apple flowers in different degrees of inten-
sity. A strain obtained from a diseased plum twig, although it was able to
induce withering of the actual flowers inoculated, was unable to proceed
beyond the base of these, and the rest of the flowers of the same inflores-
cence were not affected, while a strain obtained from an apple spur not
only readily infected apple flowers but invaded the tissues of the axis of
the inflorescence and caused a wilting of all the flowers and leaves borne on
that axis (Figs. 10 and 11). These results suggested the occurrence of
‘ Biologic Forms 5 within the species Monilia cinerea ; for confirmation of
this conclusion further experiments were carried out in 1918, using other
strains of M. cinerea.

One of the strains selected had been isolated from a tree of Pyrus
japonica which was affected with a Blossom Wilt resembling that of the
apple. This strain, though obtained from a species of the same genus as the
apple, showed certain physiological characters similar to those of strains
isolated from species of Prunus. It had been isolated from a wilted flower
in July, 1917, and when used for inoculations had been cultivated saprophy-
tically on artificially prepared media for ten months. In the experiment in
which it was used, a strain obtained from an apple spur in March, 1917, was
taken for comparison.

The first experiment of the series was carried out with one strain of the
apple form of Monilia cinerea originally isolated from a ‘ Brown Rot ’ Canker
in 1916, but re-isolated in 1917 and again in 1918 from an apple spur which
had been infected after artificial inoculation of a flower with a pure culture
in 1916. Thus in 1918 the original and two sub-strains were available for
the experiment, viz. (1) the original strain which had been growing on
artificial media for two years, (2) sub-strain grown for about twelve months
artificially, (3) sub-strain isolated a few weeks previous to the inoculations.
The experiment was carried out with the object of ascertaining whether the
form of M. cinerea which causes the Blossom Wilt of apples retains its
virulence after continued culture on artificially prepared media.

The strains used in this series of experiments on apple flowers were
from various sources and hosts as shown below :

Strain Ar — Isolated in April 1916 from a ‘Brown Rot 5 Canker of
a Cox’s Orange Pippin apple tree (specimen sent from Berkshire),
and afterwards cultivated in pure cultures in the laboratory.

Strain A2. — Isolated in March 1917 from an apple spur which had
become infected in the College plantation after artificial inocula-
tion in 1916 with a pure culture of Strain Ar

390 Wormald. — ‘ Brown Rot ’ Diseases of Fruit Trees .

Strain Aa. — Obtained from the same spur as A2, but cultures started
in March, 1918.

Strain B. — From a naturally infected spur of a Lord Derby apple tree
in the College plantation in April, 1918.

Strain C. — From a dead plum twig in the College plantation, isolated
March, 1918.

Strain D. — From a mummied plum sent from Cambridgeshire, March,
1918.

Strain E. — From a mummied cherry sent from Mid-Kent, March, 1918.

Strain F. — From a flower of Pyrus japonica from Mid-Kent, July,
I9I7*

The experiments were all carried out on apple trees of the James
Grieve variety growing in the plantation. Spurs, each bearing an umbel of
several flowers, were labelled and two flowers (a and b) in each umbel were
inoculated. The situation of the inoculated flowers on the spur was noted
so that a comparison could be made between inoculated and non-inoculated
flowers on each umbel, the latter thus serving as controls during the early
stages of infection. The inoculations were made as in the experiment on
plum flowers, except that in the present case the conidia-bearing surface of
the potato particles was brought in contact with the stigmas.

Experiment i.

fAj Apple Blossom Wilt strain, isolated 1916.

Strains used jA2 „ „ „ 1917.

I.A3 „ „ „ 1918.

The inoculations were made on May 8, 1918, and the results to May 21
are given in the accompanying table :

Strain. Spur .

£

May 14.

May 18.

May 21.

$

Ai 1

a.

Styles brown for 1-8

All the flowers of the in-

The whole inflores-

mm.

florescence dead ; leaves

cence, together with

at the base of the umbel

leaves at base, was now

b.

Stigmas only brown.

wilting.

brown and dead; flowers
recurved and leaves

curled.

2

a.

Styles brown to base. '

Ditto

Ditto

b.

Ditto

3

a.

Ditto

Both inoculated flowers
had brown withered

Ditto

b.

Ditto

stamens ; pedicels brown
and wilting ; some of the

leaves were wilting, but
the non-inoculated flowers

were upright.

Wormald. — ‘ Brown Rot' Diseases of Fruit Trees . 391

Strain. Spur.

1

May 14.

May 18.

May 2 1.

A2 i

a.

Styles brown to base.

Brown to base of pedicel ;

Both flowers dead ;

stamens and calyx lobes

leaves beginning to

b.

brown.

wilt.

Ditto

Stamens and calyx lobes
brown and withered.

2

a.

Ditto

Both flowers brown and

Whole inflorescence

withered to the base of

dead ; flowers brown,

b.

Ditto

pedicels.

withered, and recurved ;
leaves brown and

curled.

3

a.

Ditto

Both flowers .brown and
withered. The other

Ditto

b.

Ditto

flowers on this spur and
the leaves at base were

just beginning to wilt.

A3 1

a.

Two styles with

Both flowers had brown

Both flowers brown and

brown stigmas only,

withered stamens.

withered to base of

the others brown to
base.

pedicel.

b.

All the five styles
brown to base.

2

a.

Styles brown for 1-4

Both flowers brown to

Whole inflorescence

mm.

base of pedicels.

dead; flowers and leaves
brown and withered.

b.

Styles brown to base.

3

a.

Two styles with

Both flowers 1 withered ;

Ditto

brown stigmas only,
the others brown for

stamens and calyx brown.

1-4 mm.

b.

Styles brown to base.

Controls.

Flowers not inocu-

The rest of the flowers

On the rest of the tree

lated on these and on
other spurs of the
same tree had, gener-
ally, brown stigmas
only, but a few
showed a slight
browning of the styles
also.

had brown styles, but the
stamens were upright,
with white filaments, and
the calyx lobes were green
and spreading.

the flowers at this time
were just ‘ setting ’ into
fruit.

On May 25 the two flowers of spur No. 1 inoculated with strain A3
had fallen ; the spur itself was not affected and one of the non-inoculated
flowers was ‘ setting ’ into fruit. The fungus had by this time advanced
some distance into the tissues of the other infected spurs, as distinctly
shown in those cases where the spur was branched and bore two inflores-
cences, one of which bore inoculated flowers ; the non-inoculated umbel
and the accompanying leaves were withered, thus indicating that the
transpiration current had been interrupted at its junction with the main
axis of the spur, which therefore must have been invaded by the fungus

392 W or maid — ‘ Brown Rot ’ Diseases of Fruit Trees .

travelling downwards from the other (infected) umbel. To bring about this
result the fungus must have traversed a distance of from 4-5 to 5-5 cm.
between the time of inoculation, on May 8, and May 25.

This experiment proves conclusively that the virulence of the apple
Blossom Wilt form of Monilia cinerea is not diminished after from one to
two years’ culture as a saprophyte on artificially prepared media in the
laboratory. It also shows that the conidia produced on a spur during the
second year after infection occurs are as virulent as those produced during
the first year subsequent to infection.

Experiment 2.

Strains usedJ

B. Apple Blossom Wilt strain, isolated 1918.

C. A 4 Wither Tip’ strain from a plum tree, isolated

1918.

D. From a mummied plum, isolated 1918.

E. „ „ cherry, „

The inoculations were made on May g, 1918.

It will be seen from the table that during the first six days after
inoculation the symptoms of infection were generally similar for all the
four strains ; later the apple . Blossom Wilt strain made rapid progress and
caused, in the case of two spurs, the death of the whole inflorescence and
the leaves borne on the spur, while with the other strains the disease was
confined to the flowers actually inoculated, i. e. the tissues of the spurs were
not invaded and the leaves were unaffected.

On May 15 a comparison of the inoculated and the non-inoculated
flowers showed that in the former infection had occurred in every caso;
this, together with the fact that of the eighteen flowers inoculated with
strains C, D, and E all had fallen except two, leads to the conclusion that
these strains either kill the flowers directly or at least infect the styles and
so prevent pollination, the final result being the same, viz. the arrest of any
further development of the flowers, which in consequence wither and fall
off. The one instance in which the ovary did begin to swell probably
means that pollination had occurred in that case before the inoculation
was made.

Strain. Spur. May 15. May 19. May 22. / May 28.

]3# 1 a. Styles brown to base. Both flowers brown and withered All the flowers and leaves on Cortex brown to base of spur,

b. Ditto to base of pedicel ; calyx lobes the spur brown and withered. i. e. for 5 cm. from the insertion

withered. °f the flowers ; a vegetative

shoot on same spur dead.

Wormald. — ‘ Brown Rot' Diseases of Fruit Trees. 393

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f A2. Apple Blossom Wilt strain, isolated 1917.
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The inoculations were made on May n, 1918.

Wormald. — ‘Brown Rot1 Diseases of Frtiit Trees . 395

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Wormald. — ‘ Brown Rot' Diseases of Fruit Trees.

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Wonnald. — ‘ Brown Rot ’ Diseases of Fruit Trees. 397

Again observations on the sixth day after inoculation showed that
infection of the styles had occurred. As before, one inoculated flower
developed into fruit ; the rest all became withered and fell off.

The results of these four experiments, together with those obtained in
the experiment carried out in 1917, may be summarized as follows :

Results of Inoculations made on Apple Flowers with
Strains of Monilia cinerea.

No. of
flowers
inoculated.

No. of spurs on
which the in-
oculatedflowers
were situated.

No. of
spurs
killed.

No. of inoculated
flowers which
developed into
fruit.

‘ Blossom Wilt

1918

Ax

6

3

3

0

and Canker ’

a2

10

5

4

0

strains of Monilia

a3

6

3

2

0

cinerea from ap-
ple trees

B

6

3

2

1

I9I7

A2

4

4

4

0

Total .

32

18

L5

1

Other strains of

1918

Plum

10

5

0

1

M. cinerea from
various sources

Cherry
‘ Wither

10

5

0

0

Tip’ of

plum

10

5

0

1

Pyrns
japonic a

8

4

0

0

-

1917

‘ Wither

Tip ’ of
plum

10

4

0

0

Total .

48

23

0

2

Thus of the 18 spurs bearing flowers which had been inoculated with
the strains from apple trees, 15 were killed outright, with all their flowers
and leaves, while the inoculation of 48 flowers with strains from sources
other than the apple did not produce in any one instance infection of the
tissues of the spur, although there was evidence that infection of the flowers
actually inoculated had occurred.

The conclusion is, that the ‘Blossom Wilt and Canker Disease’ of
apple trees is caused by a specialized form of Monilia cinerea.

Woronin (1900) stated, as a result of his own inoculation experiments
on apple flowers, that M. cinerea was unable to produce a Blossom Wilt of
apple trees. The host from which he obtained the strain used in his
experiments is not stated, but in all probability it was a cherry or plum ;
had he worked with a strain taken from a dead spur or canker of an apple
tree he might have obtained a different result.

VI. Conclusions.

A general discussion of the results recorded in the present article is
reserved for a future occasion, when they will be correlated with those of

F f 2

398 Wormald.— Brown Rot ’ Diseases of Fruit Trees.

certain physiological and cultural experiments carried out with the same
fungi. It will be convenient, however, to summarize briefly the results of
the observations and experiments described in the preceding pages, as
follows :

1. In this country two distinct species of Monilia occur as parasites
on fruit trees, viz. M . frnctigena, Pers., and M. cinereay Bon.

2. Each species has two forms distinguished by the effects produced
on mature apples inoculated under laboratory conditions.

3. The morphological species Monilia cinerea includes two ‘ biologic ’
forms, one of which produces a ‘ Blossom Wilt and Canker Disease ’ of
apple trees, and another which is unable to cause infection of the apple
inflorescence other than the flower actually inoculated.

Bibliography.

1796. Persoon, C. H. : Observationes Mycologicae, p. 26. Lipsiae, 1796.

1801. : Synopsis Methodica Fungorum, p. 693. Gottingae, 1801.

1805. Albertini, J. B. de, und Schweinitz, L. D. de : Conspectus Fungorum in Lusatiae superioris
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1885. Smith, W. G. : Gard. Chron., vol. xxiv, new series, pp. 51-2, July 11, 1885.

1886. Arthur, J. C. : Rotting of Cherries and Plums. Oidium fructigenum , S. and K. New

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1887. Thumen, F. von : Die Pilze der Obstgewiichse. Wien, 1887.

1888. Briosi, G., e Cavara, J, : I funghi parassiti delle piante coltivate od utiles, fasc. v, No. no,

Ovularia necans. Pass., 1888.

1 I wish to thank the Editors of the Gardeners’ Chronicle for sending me a typewritten copy of
this article.

Wormald . — ‘ Brown Rot ’ Diseases of Fruit Trees. 399

1888. Sorauer, P. : Die Schaden der einheimischen Kulturpflanzen durch thierische und pflanzliche

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1889. Galloway, B. T. : Brown Rot of the Cherry. Monilia fructigena, Pers. U. S. Dept. Agr.

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1891. Drathen, von : Schleswig-Holsteinsche Zeitschrift fur Obst- und Gartenbau, 1891, p. 53.
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— _ Wittmack : Jahresbericht des S onderausschusses fiir Pflanzenschutz. Arbeiten der Deutschen

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Bull., 19, pp. 1-16, 1892.

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pp. 209-12.

1893. Humphrey, J. E. : On Monilia fructigena. Bot. Gaz., 1893, pp. 85-93.

.Massee, G. : British Fungus Flora, vol. iii, p. 283. London, 1893.

Schroter, C. : Kryptogamen -Flora von Schlesien, Bd. iii, p. 67. Pilze, 1893.

1894. Bailey, L. H. : Impressions of the Peach Industry in Western New York. N.Y. (Cornell)

Agr. Expt. Sta. Bull., 74, pp. 379-81, 1894. #

Taft, L. R. : Peach and Plum Culture in Michigan. Mich. Agr. Expt. Sta. Bull., 103,

pp. 55-6, 1894.

■ Wittmack and Frank : Gartenflora, 1894, p. 302.

1895. Massee, G. : British Fungus Flora, vol. iv, p. 281, London, 1895.

■ Wehmer, C. : Beitrage zur Kenntnis einheimischer Pilze. Jena, 1895.

Wortmann, J. : Einige Beobachtungen fiber den Grind des Obstes, hervorgerufen durch

Oiclium fructigenum. Ber. d. kgl. Lehranstalt flir Obst-, Wein- und Gartenbau zu
Geisenheim a/Rh. fiir das Etatsjahr 1894-95, pp. 64-7.

1896. Wehmer, C. : Pilzkrankheiten land- und forstwirthschaftlicher Kulturgewachse im Hannover-

schen wahrend des Sommers 1896. Cent. f. Bakt., 2. Abt., Bd. ii, 1896, p. 780.

1897. Aderhold, R. : Uber die in den letzten Jahren in Schlesien besonders hervorgetretenen

Schaden und Krankheiten unserer Obstbaume und ihre Beziehungen zum Wetter. Bot.
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; Proskauer Obstbau-Zeitung, 1897, p. 108.

— — : Zur Monilia-Epidemie der Kirschbaume. Gartenflora, 1897, pp. 429-33.

Frank, B., und Kruger, F. : Die Monilia-Epidemie der Kirschbaume. Ibid., p. 320 and p. 393.

• Goff, E. S. : The Culture of Native Plums in the North-west. Wisconsin Agr. Expt. Sta.

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Island Agr. Expt. Sta., 9th Ann. Rept. (for 1896), pp. 191-2.

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des parasites vegetaux, vol. ii, 1897.

Woronin, M. : Kurze Notiz fiber Monilia fructigena , Pers. Zeitschr. f. Pffanzenkr., Bd. vii,

1897, pp. 196-8.

Zschokke, A. : Ueber den Ban der Haut und die Ursachen der verschiedenen Haltbarkeit

unserer Kernobstfrachte. Landwirtschaftliches Jahrbuch der Schweiz, Bd. xi, 1897,
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1898. Behrens, J. : Beitrage zur Kenntnis der Obstfaulnis. Cent, f . Bakt., 2. Abt, Bd. iv, 1898,

p. 514 et seq.

Biemuller : Das Beschneiden der vom Pilz befallenen Kirschbaume, insbesondere der

‘ Ostheimer Weichsel \ Gartenflora, 1898, p. 107.

Frank, B. : Massregeln gegen die Monilia-Krankheit der Kirschbaume. Ibid., pp. 47-9.

Zur Bekampfung der Monilia-Krankheit der Obstbaume. Ibid., p. 617.

— — : Massregeln gegen die Monilia-Krankheit der Kirschbaume. Deutsche landwirt-

schaftl. Presse, 1898, No. 9, p. 95.

400 Worm aid. — ‘ Brown Rot 9 Diseases of Fruit Frees.

1898. Frank, B., und Kruger, F. : Der Ueberwinterungszustand der Kirschbanm- Monilia. Garten-

flora, 1898, p. 96.

Goethe, R. : Bericht d. kgl. Lehranstalt fiir Obst-, Wein- und Gartenbau zu Geisenheim

a. Rh. fiir das Etatsjahr 1897-8. Wiesbaden, 1898.

Reuter, E. : In Norwegen im Jahre 1896 aufgetretene Krankheitserscheinungen. Zeitschr.

f. Pflanzenkr., Bd. viii, 1898, p. 209.

— — Wehmer, C. : Die Monilia-Krankheit ( Monilia fructigena) unserer Obstgarten. Beilage ziir
Hannoverschen Land- und Forstwirthschaftlichen Zeitung, 1898, Nos. 3 and 8.

: Monilia fructigena , Pers. (= Sclerotinia fructigena ), und die Monilia-Krank-
heit der Obstbaume. Berichte der Deutschen Botan. Gesellsch., Bd. xvi, 1898, p. 298.

Woronin, M. : Monilia cinerea , Bon., und Monilia fructigena , Pers. (Vorlaufige Mittheilung).

Botan. Centralblatt, Bd. lxxvi, 1898, pp. 145-9.

1899. Aderhold, R. : Proskauer Obstbau-Zeitung, iv. Jahrg., 1899, pp. 20, 55, 83, 115.

• Behrens, J. : Kupferpraparate und Monilia fructigena. Cent. f. Bakt., 2. Abt., Bd. v, 1899,

pp. 507-9.

Cordley, A. B. : Brown Rot (Monilia fructigena, Pers.). Oregon Agr. Expt. Sta. Bull., 57,

1899.

Frank, B., und Kruger, F. : Ueber die gegenwartig herrschende Monilia-Epidemie der

Obstbaume. Landwirtsch. Jahrb., Bd. xxviii, 1899, pp. 185-216.

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Schellenberg^H. C. : Ueber die Sclerotinienkrankheit der Quitten. Berichte der Deutschen

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Sorauer, P. : Erkrankungsfalle durch Monilia . Zeitschr. f. Pflanzenkr., Bd. ix, 1899,

PP- 2 2 5-3 5-

; Zuv Monilia-Krankheit. Berichte der Deutschen Bot. Gesellsch., Bd. xvii,

i899, pp. 186-9.

1899-1900. : Erkrankungsfalle durch Monilia. Zeitschr. f. Pflanzenkr., Bd. ix,

1899, PP- 225-35 5 Bd. x, 1900, pp. 148-54, 274-84.

1900. Aderhold, R. : Zwei gefahrliche Erkrankungsfalle unseres Kemobstes. Prosk. Obstbau-

Ztg., Jahrg. v, 1900, pp. 39-42.

• : Eine dem e fireblight ’ Amerikas ausserlich ahnliche Krankheit des Apfel-

baumes. Cent. f. Bakt., 2. Abt., Bd. vi, pp. 628-9.

Muller-Thurgau, H. : Die Monilienkrankheit oder Zweigdiirre der Kernobstbaume. Ibid.,

PP- 653-7-

■ : Die Monilienkrankheit oder Zweigdiirre der Kernobstbaume.

Schweizer Zeitschr. f. Obst- u. Weinbau, Nos. 13, 14, 1900, pp. 198-203.

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. Sorauer, P. : Schutz der Obstbaume gegen Ivrankheiten, p. 125, 1900.

* Wehmer, C. : Pilzkrankheiten von Kulturpflanzen in der Provinz Hannover. Cent. f. Bakt.,

2. Abt., Bd. v, pp. 55-6.

Waugh, F. A. : Plum-tree Canker. Vermont Agr. Expt. Sta. Rept., No. 13, pp. 37°~3-

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St. Petersbourg, viii. ser., vol. x, No. 5, Phys. Math,, pp. 1-38.

1902. Clinton, G. P. : Apple Rots in Illinois — Brown Rot. 111. Agr. Exp. Sta. Bull., 69, p. 190.
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Norton, J. B. S. : Sclerotinia fructigena. Trans. Acad. Sci. St. Louis, vol. xii, pp. 91-7-

Osterwalder, A. : Die Bliiten- und Zweigdiirre bei Cydonia japonica. Gartenflora, Jahrg. 51.

1903. Alwood, W. B., and Price, H. L. : Notes on spraying Plums. Virginia Agr. Expt. Sta.

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Bos, J. Ritzema : Tijdschrift over Plantenziekten, ix, p. 128.

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1904. Aderhold, R. : Uber eine vermuthliche zu Monilia fructigena . Pers., gehorige Sclerotinia ,

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W or maid % — ‘ Brown Rot ’ Diseases of Fruit Trees . 401

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• Die Monilia- (Sclerotinia-) Krankheiten unserer Obstbaume und ihre Be-

kampfung. Kaiserl. Biolog. Anst. f. Land- und Forstwirtschaft. Flugblatt, Nr. 14.

Clinton, G. P. : Notes on Fungus Diseases. Conn. Agr. Exp. Sta. Rept. for 1904, pp. 316-17.

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1907. Faurot, F. W. : Brown Rot of Peach. Missouri State Hort. Soc. Rept., 1907, pp. 285-9.
Scott, W. M. : A Promising Treatment for Brown Rot and other Peach Diseases. Proc.

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1909. Pollock, J. B. : Notes on Plant Pathology, nth Rept. Mich. Acad. Sci., pp. 51-4, 1908-9.
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Soc. Proc., xxxiii, pp. 96-104.

1910. Kock, G. : Beobachtungen iiber den Befall verschiedener Kirschen- und Weichselsorten durch

den Moniliapilz ( Sclerotinia cinerea , (Bon.) Schrot.). Sond., Zeitschr. f. d. landwirt.
Versuchsw. in Osterr., Jahrg. 13, 1910, p. 889.

Lewis, A. C. : Brown Rot Experiments in 1909. Ga. State Bd. Ent. Bull., 32, pt. 2,

pp. S5-48-

Massee, G. : Diseases of Cultivated Plants and Trees, p. 270. London, 1910.

Muller-Thurgau, H. : Die Moniliakrankheit der Apfelbaume. Schweizer Zeits. f. Obst-

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: A ‘ Canker ’ of Apple Trees caused by the ‘ Brown Rot ’ Fungus. Gard.

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1911. Scott, W. M., and Quaintance, A. L. : Spraying Peaches for the control of Brown Rot,

Scab, and Curculio. U.S. Dept. Agr. Farmers’ Bull., 440.

1912. Bruschi, D. : Attivita enzimatiche di alcuni funghi parassiti di frutti. Atti R. Accad. Lincei,

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• Ewert, R. : Verschiedene Uberwinterung der Monilien des Kern- und Steinobstes und ihre

biologische Bedeutung. Zeitsch. f. Pdanzenkr., Bd. xxii, pp. 65-86, 1912.

Gussow, PI. T. : A New Disease of Peaches. Canadian Expt. Farm Rept., 1911, p. 25T, 1912.

402 Wormald, — ‘ Brown Rot ’ Diseases of Fruit Trees .

1912. Sorauer, P. : Weswegen erkranken Schattenmorellen besonders leicht durch Monilia ? Zeits.

f. Pflanzenkr., Bd. xxii, pp. 285-92, 1912.

Voges, E. : Uber Monilia-Erkrankung der Obstbaume. Ibid., pp. 86-105, 1912.

Westerdijk, Joh. : Die Sclerotinia der Kirsche. Mededeelingen uit bet phytopathologisch

Laboratorium ‘ Willie Commelin Scholten Bd. iii, pp. 39-41.

Whetzel, H. H. : The Fungous Diseases of the Peach. Proc. New York State Fruit

Growers’ Assoc., 1912.

1913. Broz, O. : Die Moniliagefahr. Separatabdruck aus ‘ Der Obstziichter ’, Nr. 7.

Cook, M. T. : Report on the Plant Pathologist for 1912. New Jersey Agric. Expt. Sta.

Eriksson, J. : ZurKenntnis der durch Monilia-Filze hervorgerufenen Bliiten- und Zweigdiirre

unserer Obstbaume. Mycol. Central bl., Bd. ii, pp. 65-78.

Jehle, R. A. : The Brown Rot Canker of the Peach. Phytopath., vol. iii, pp. 105-10.

Matheny, W. A. : A Comparison of the American Brown Rot Fungus with Sclerotinia

fructigena and S. cinerea of Europe. Bot. Gaz., vol. lvi, pp. 418-32.

Rabat£, E. : Ann. servant aux Epiphyties, Mem. et Rap., tom. ii, pp. 341-6. (Plum

Diseases : Abstract in Exp. Sta. Rec., vol. xxxvi, p. 751, 1917).

Salmon, E. S. : The ‘ Brown Rot’ Canker of the Apple. Jour. S. E. Agric. Coll., Wye,

Kent, No. 22, pp. 446-9.

1914. Conel, J. L. : A Study of the Brown Rot Fungus in the Vicinity of Champaign and Urbana,

Illinois. Phytopath., vol. iv, pp. 93-102.

Cooley, J. S. : A Study of the Physiological Relations of Sclerotinia cinerea , (Bon.) Schroeter.

Ann. Missouri Gard., vol. i, No. 3, pp. 291-326.

Faes, H.: Terre Vaud., tom. vi, No. 25, pp. 282-3. (A Disease of Apricot in Valais

Abstract in Exp. Sta. Rec., vol. xxxv, p. 49, 1916.)

Howitt, J. E. : Notes on the Apothecial Stage of Sclerotinia cinerea in Ontario. Ottawa

Nat., vol. xxvii, No. 11, pp. 158-60.

Jehle, R. A. : Peach Cankers and their Treatment. Cornell Univ. Agr. Expt. Sta. Circ., 26.

Orton, C. R. : Some Orchard Diseases and their Treatment. Proc. State Hort. Assoc.,

Penn., vol. lv, pp. 43-56.

Salmon, E. S. : The ‘ Brown Rot ’ Canker of the Apple. Gard. Chron., Aug. 1, 1914, p. 85.

1915. Bailey, F. D. : Experimental Spraying of Prunes for Control of Brown Rot. Oregon Agr.

Exp. Sta. 2nd Bienn. Crop Pests and Hort. Rept. for 1913-14, pp. 241-4.

Cayley, D. M. : Brown Rot of Fruit. Gard. Chron., Oct. 30, 1915, p. 269.

Chifflot, J., and Massonnat: Rev. Hort. (Paris), tom. lxxxvii, No. 27, pp. 540-1. (A

Disease of Apricot in Rhone Valley. Abstract in Exp. Sta. Rec., vol. xxxv, p. 50,

1916.)

: Compt. Rend. Acad. Agr. France, tom. i, No. 1 5, pp. 473—7.

(Apricot Disease in the Rhone Valley. Abs. in Exp. Sta. Rec., vol. xxxv, p. 249, 1916).

Darnell-Smith, G. P., and Mackinnon, E. : Fungus and other Diseases of Stone Fruits.

Agr. Gaz. N.S. Wales, vol. xxvi, No. 7, p. 589 ; No. 9, p. 749.

— — Jackson, H. S. : Prune Brown Rot on Dried Fruit. Oregon Exp. Sta. 2nd Bienn. Crop
Pests and Plort. Rept. for 1913-14, pp. 276-7.

• Posey, G. B. : Studies of Monilia Blight of Fruit Trees. Science, vol. xlii, No. 1086, p. 583.

Spinks, G. T. : A Black Rot of Apples. Ann. Rept. Agric. and Hort. Res. Sta., Long

Ashton, Bristol, 1915, pp. 94-6.

Stakman, E. C., and Rose, R. C. : Experiments in the Control of Brown Rot of Plums.

Minn. Hort., vol. xliii, No. 5, pp. 231-3.

Valleau, W. D. : Varietal Resistance of Plums to Brown Rot. Jour. Agric. Res., vol. v,

PP- 365-95-

Voss, G. : Flugbl.-Samml. ii . Pflanzenschutz, K. Landw. Akad. Bonn-Poppelsdorf, No. 7,

p. 4. ( Monilia on Fruit Trees. Abstract in Exp. Sta. Rec., vol. xxxv, p. 655, 1916.)

1916. Bartram, H. E. : A Study of the Brown Rot Fungus in Northern Vermont. Phytopath.,

vol. vi, pp. 71-8.

Brooks, C., and Cooley, J. S. : Temperature Relations of Apple Rot Fungi. Jour.

Agric. Res., vol. viii, pp. 139-63.

— — Brooks, C., and Fisher, D. F. : Brown Rot of Prunes and Cherries in the Pacific North-
west. U.S. Dept. Agr. Bull., 368.

W or maid. — ‘ Brown Rot ’ Diseases of Fruit Trees . 403

1916. Hesler, L. R. : Diseases of the Plum: Brown Rot. New York Agric. Dept. Bui., 79,

pp. 1 192-5.

Spinks, G. T. : A Black Rot of Apples. Ann. Rept. Agric. and Hort. Res. Sta., Long

Ashton, Bristol, 1916, pp. 153-5.

Mansfield, A. B. : Ripe Rot of Stone Fruits. Jour. Agr. (New Zeal.), vol. xii, No. 3,

pp. 214-16.

1917. Peglion, V.: Atti R. Acad. Lincei, Rend. Cl. Sci. Fis., Mat. e Nat., 5aser., vol. xxvi, No. 12,

pp. 637-41. (A Gummosis of Apricot. Abstract in Exp. Sta. Rec., vol. xxxviii, p. 650,

1918.)

Wormald, H. : A Blossom Wilt and Canker of Apple Trees. Ann. Applied Biol., vol. iii,

No. 4, April, 1917, pp. 159-204.

— : The ‘Blossom Wilt and Canker’ Disease of Apple Trees. Jour. Bd. Agric.,

vol. xxiv, No. 5, Aug., 1917, pp. 504-13.

1918. Cockayne, A. H. : Report of the Biologist : Plant Diseases. New Zealand Dept, of Agric.,

Industries, and Commerce, Ann. Rept. for 1917-18, p. 38.

Cunningham, G. H.: Brown Rot in Cherries controlled. Jour. Agr. (New Zeal.),

vol. xvi, No. 1, pp. 38-39.

McCubbin, W. A. : Peach Canker. Dom. of Canada Dept. Agric. Bui. 37, 1918.

Wormald, H. : ‘Brown Rot* of Apples. Jour. Bd. Agric., vol. xxv, No. 3, June, 1918,

pp. 299-302.

A ‘ Wither Tip’ of Plum Trees. Ann. Applied Biol., vol. v, No. 1, July,

1918, pp. 28-59.

1919. McCubbin, W. A. : Brown Rot of Stone Fruits. Agric. Gaz. of Canada, May, 1919,

pp. 429-32. ^

EXPLANATION OF PLATES XXV AND XXVI.

Illustrating Mr. Wormald’s paper on the ‘Brown Rot’ Diseases of Fruit Trees.

PLATE XXV.

Fig. 1. Plums naturally infected, above with Monilia cinerea, the two below with M. fructigena.
Fig. 2. Plums naturally infected, the one on the right with M fructigena , the one on the left
with both M. fructigena (right side) and M. cinerea (left side).

Fig. 3. Fruiting spur of apple bearing pustules of M. fructigena in late summer ; infection
occurred through the fruit, the stalk of which is seen at the upper end.

Fig. 4. Apple (var. Bramley’s Seedling) inoculated with pure cultures, on the left with M. frucli-
gena , on the right with M. cinerea f. mali : result on seventh day after inoculation. At this stage
the dark rings round the lenticels on the side infected with M. cinerea f. mali are a characteristic
feature.

Fig. 5. The apple shown in Fig. 4, but 13 days later; the right side of the apple was quite
black by this time.

Fig. 6. Apple inoculated from pure cultures, on the right with M. cinerea f. mali, on the left
with M. cinerea f. pruni.

Fig. 7. Apple inoculated from pure cultures with two strains of M. fructigena, on the left
a strain from a plum, on the right a strain from an apple affected with ‘ Black Rot ’.

Fig. 8. On the left a plum inoculated from a pure culture of M. fructigena, on the right a plum
inoculated from a pure culture of M. cinerea. Control plum, from the same tree, in the centre.

Fig. 9. Plum inoculated from pure cultures, on the left with M. fructigena , on the right with
M. cinerea. (The experiments illustrated by Figs. 8 and 9 were carried out in the open, the
specimens being removed from the tree immediately before the photographs were taken.)

PLATE XXVI.

Fig. 10. Above, on the left, an inflorescence of an apple tree (var. Lord Derby), of which
a single flower had been inoculated with conidia from a pure culture of M. cinerea f. mali ; infection
has reached the base of the spur and a canker is just making its appearance on the stem. Result
16 days after inoculation.

G g

404 W or maid. — ‘ Brown Rot ’ Diseases of Fruit Trees .

P'ig. ii. As in Pig. io, but 5 days later ; the canker has nearly girdled the stem.

Fig. 12. A canker, from an apple tree infected with M. cinerea f. mali , bearing pustules during
the third year after infection ; photographed in January, 1919. (The same canker photographed in
1917, one year after infection, is shown in the Jour. Bd. Agric., Aug., 1917, p. 504, Pig. r.)

Fig. 13. Dead spur and canker from an apple tree (var. Warner’s King) photographed Mar. 22,
1918 : result of inoculating a single flower of the inflorescence in May, 1916, with conidia from a pure
culture of M. cinerea f. mali. The canker produced in 1916 is nearly covered by callus, but the spur
still bears pustules of viable conidia.

Fig. 14. Dead spur and canker of an apple tree (var. James Grieve), winter condition, the
result of the natural infection of the fruit with M. fructigena during the previous summer : the fruit-
stalks, from which the diseased apples had fallen, are seen at the apex of the spur. The fungus was
isolated from barren pustules on the spur and from mycelium in the canker. (Compare Fig. 3,
which shows the summer condition of the fungus on an apple spur.)

Fig. 15. Above are two flowering spurs which had become infected by M. cinerea f. mali ,
resulting in a canker on the branch. The check to the upward flow of sap stimulated buds below
the canker to grow out into weak vegetative shoots.

Fig. 16. Section through an infected spur and canker of an apple tree. The lesion on the
branch is being covered by callus, x 2.

-

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EDITED BY

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LATELY HONORARY KEEPER OF THE JODRELL LABORATORY, ROYAL BOTANIC GARDENS, KEW

-V * - ( ’ ; . ' • \ ,

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PROFESSOR OF BOTANY, ROYAL COLLEGE OF SCIENCE, LONDON

FRANCIS WALL OLIVER, M.A., D.Sc., F.R.S.

QUAIN PROFESSOR OF BOTANY, UNIVERSITY COLLEGE, LONDON

AND

ROLANEF THAXTER, M.A, Ph.D.

PROFESSOR OF CRYPTOGAMIC BOTANY IN HARVARD UNIVERSITY, CAMBRIDGE, MASS., U.S.A.

ASSISTED BY OTHER BOTANISTS

_ ' -/ - °0 \

( NOV 2 9 1919 ) V

LONDON

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Edinburgh, Glasgow, New York, Toronto
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1919

Printed in England at the Oxford University Press.

CONTENTS.

Farlow, William Gibson . . . . . . . . . . . i— ii

Petch, T.— Mocharas and the Genus Haematomyces. ' With two Figures in the Text . 405

WORSDELL, W. C. — The Origin and Meaning of Medullary (Intraxylary) Phloem in the

Stems of Dicotyledons. II. Compositae. With twenty-seven Figures in the Text . 421

;ARber, Agnes. — Studies on Intrafascicular Cambium in Monocotyledons (III and IV).

With seven Figures in the Text . . 459

Carter, Nellie. — The Cytology of the Cladophoraceae. With Plate XXVII and two

Figures in the Text . . . • • • ....... 467.

Willis, J. C. — On the Floras of Certain Islets outlying from Stewart Island (New Zealand).

With one Map in the Text . . . . . . . . . . . 479

Osborn, T. G. B. — -Some Observations on the Tuber of Phylloglossum. With Plate XXVIII

and forty-three Figures in the Text . . . . . . .- . . . 485

Smith, A. Malins. — The Temperature-coefficient of Photosynthesis : a Reply to Criticism.

With two Figures in the Text . 517

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Mocharas and the Genus Haematomyces,

BY

T. PETCH,

Government Botanist and Mycologist , Ceylon .

7

With two Figures in the Text,

HE genus Haematomyces was established by Berkeley and Broome in

1873 (Jour. Linn. Soc., xiv, p. 108) on a specimen sent from Ceylon
by Thwaites The generic description runs as follows :

‘ Haematomyces . Tremelloides , sinuato-lobatus , gyrosus , subcerebrinus ,
immarginatus ; asci vesicular es ; sporidia elliptical

The type species was named Haematomyces spadiceus , B. and Br. No
formal description of the species was given, but it was said to look exactly
like a Tremella , and to have spores, 6-25 \x long, which bore a small propor-
tion to the wide, obovate, vesicular asci. Berkeley and Broome added the
note, ‘ There can be no doubt that the genus is good ; but it is to be hoped
that a further supply of specimens will be procured. The asci are quite
unlike anything in Bulgaria, to which we were at first inclined to refer it.
Black when dry.’

The genus was duly included in Saccardo, ‘ Sylloge Fungorum,’ in the
Bulgarieae. Another species had by that time been described by Peck, viz.:

Haematomyces orbicularis , Peck, Sessilis , pulvinatus , orbicularis , sub -
tremellosus , gyroso-convohttus , nigricanti-brunneus , particulis minutis rujis
punctatus ; ascis anguste clavatis , apice subacutis ; sporidiis oblongo-fusoideis,
continuis , 15-18 x 3-4 y ; paraphysibus numerosis, filiformibus.

The generic character on which Berkeley and Broome laid so much
stress, viz. the obovate, vesicular asci, was apparently considered of minor
importance.

Subsequently Peck added a third species :

Haematomyces fagineus , Peck, Tremelloides , cerebriformis , 2-2-5 cm-
diam., gyroso-lobata, glabra , nit e ns, extus intusque rubra {raisin colour);
ascis subcylindraceis , 8 -sporis, 60x7*5 I1 5 paraphysibus gradlibus, supra
lenissime incrassatis ; sporidiis plerumque monos tic his, anguste ellipsoideis ,
7*5 x 3*5~5 \x' tr uncos Fagi ferrugineae. Habitus Tremellae .

[Annals of Botany, Vol. XXXIII. No. CXXXII. October, 1919.]

H h

406 Petch. — Mocharas and the Genus Haematomyces .

A fourth species was described by Rick from Brazil :

‘ Haematomyces eximius , Rick, Ascomate gelatinoso , cerebriformi et
tremelloideo, prorumpente , convolutionibus eras sis, fir mis, globoso, 5 diam.,
castaneo ; ascis cylindraceis, 130x6-8 y ; sporidiis ellipsoid eis , 6-8 y longis,
4 ijl cr., biguttulatis , apicidatis v. etiam apice truncatis , viridido-hyalinis , dfem
olivascentibus , biserialibus , unilocidaribas ; paraphysibus filif omnibus, apice
paulatim minute incrassato , hyalinis , versus pedem viridulo-olivaceis

And Rick adds ‘ Haemat. spadiceo ajfinis \ a remark which strikingly
illustrates the futility of comparisons based on descriptions only.

In £ Fragmente zur Mykologie ’, VI. Mitt., p. 126, von Hohnel writes,
‘ Another Discomycete genus with an immarginate disc is Haematomyces ,
Berk. This genus appears to me to be an immarginate Ombrophila .
Presumably those species of Psilopeziza which are brilliantly coloured
( flavida , aurantiaca , xylogena , aquatic a) would be better regarded as species
of Haematomyces.

£ To this genus, no doubt, belongs also Pezizella orbilioides , Feltgen
(£ Vorstud. Pilzflora von Luxemburg,5 III. Nachtr., p. 53), which I formerly
referred to Ombrophila . It must now be named Haematomyces orbilioides ,
(Feltg.) v. H. It corresponds admirably with this genus.5

Apparently the accepted idea of Haematomyces is a pulvinate, convoluted,
or cerebriform stroma, more or less gelatinous or tremelloid in consistency,
which bears a palisade layer of asci and paraphyses over the whole of its
exposed surface, without any definite margin. The spores are continuous
and hyaline. None of the descriptions states explicitly that the asci are
arranged as suggested, but that conclusion appears to be warranted by the
inclusion of the genus in the Bulgarieae. Berkeley and Broome made the
shape of the asci a generic character, but that has been ignored by all
the describers of subsequent species.

Berkeley and Broome’s material appears to have been scanty. There is
a specimen, part of the original gathering, in the Peradeniya herbarium, but
as for twelve years I did not meet with any species which coincided with the
current idea of Haematomyces , it was not examined. During 3918, however,
I collected, in the low country, an ascomycete which formed a pulvinate,
cerebriform stroma, up to 1-5 cm. diameter, purple-red to flesh colour,
and somewhat subtranslucent and tremelloid. The whole of the exposed
surface was covered by a palisade layer of asci. As this species appeared
to agree with the description of Haematomyces , an examination of the cotype
was undertaken.

The cotype in Herb. Peradeniya (Thwaites’ 59) was evidently obovate
when fresh, about 8 mm. high, and 5 mm. broad. It has become laterally
compressed in drying, and slightly folded towards the apex, but it is
scarcely f subcerebrinus \ Its colour is dark purple-brown, and its surface
minutely rough. On cutting sections, it is found that there is no palisade

Petch . — Mocharas and the Genus Haematomyces . 407

layer of as ci. The stroma consists of a dense brown cortex, about 100
thick, succeeded internally by paler tissue, or by alternate zones of hyaline
and brown tissue. This tissue shows numerous lines which appear to be the
walls of partially disorganized hyphae. These walls run irregularly for
a short distance, usually strongly and closely flexuose, and are then lost in
the general mass. But the general arrangement of these walls is concentric,
and parallel to the outer surface.

Surface sections show that the exterior is composed of large, more or
less polygonal cells, but as these do not appear in the cross-section they are
evidently very thin, or have collapsed.

Embedded here and there in the internal tissue are the wide, obovate,
vesicular asci noted by Berkeley and Broome. These may reach a length
of 1 00 ijl and a breadth of 40 or 50 //. They contain a varying number of
subangular bodies, which are sometimes arranged in a row, but more usually
lie in a group on one side of the cell, and occupy, as stated by Berkeley and
Broome, only a very small part of it.

It will be evident that this structure is not that of the Bulgarieae, and
that, if it were a fungus, Haematomyces would have to be classed perhaps in
the Plectascineae.

On staining with cotton blue in lactic acid, the whole of the tissue
turns pale blue, but it does not swell up to any marked extent. But on
staining with iodine, the apparent spores stain black and are evidently starch
or amyloid grains. This immediately renders it improbable that the obovate
bodies are asci, and that the specimen is a fungus.

On considering the matter further, it occurred to me that Haematomyces
spadiceus was not rare, but was to be found in abundance at Peradeniya.
Moreover, I had frequently examined it, without ever suspecting that it
might have been mistaken for a fungus. Fortunately, fresh material
happened to be available at the time, and an examination of it confirmed
the idea suggested by the type specimen.

An Exudation from Bombax malabaricum.

One of the most conspicuous trees at Peradeniya is the Bombax ( Bombax
malabaricum , DC.), the red cotton tree, and most visitors to Peradeniya
remember the row of giant trees which borders the road from the station to
the Botanic Gardens, especially if they have passed that way in the early
part of the year when the ground is covered with its large, red, shuttlecock-
like flowers. The tree is a rapid grower, and its -wood is brittle. Con-
sequently its huge limbs are frequently wrenched off by the wind, and, as
they are of little use except for firewood, they are left lying until they begin
to decay. As seven trees of the row referred to stand along the frontage of
my garden, I have had several opportunities during the last twelve years of
observing the changes which take place in the fallen branches.

H h %

408 Petch. — Mocharas and the Genus Haematomyces .

After a branch has been lying on the ground for a few weeks, it begins
to exude, through cracks in the bark, a yellowish, pasty, somewhat viscid
substance. This appears in pulvinate masses, or runs down the side in
thick strands, assuming all the varied forms associated with an exudation of
gum or resin. If the cortex has been stripped off any part of the branch,
this substance emerges from between the wood and the cortex, i. e. from
the site of the cambium, and it issues from the same place on the cut end of
a fallen branch or stem. It soon acquires a yellow-brown, polished, outer
skin, and this increases in thickness and deepens in colour as the exudation
ages. Sometimes the skin ruptures under the pressure of the exuding mass,
and further projections grow out from the apex of the structure first formed.
When old, it is red-brown to purple-brown, usually with a polished surface.
As it dries it hardens and contracts, sometimes falling into irregular folds
and convolutions, sometimes retaining its shape but becoming hollow. This
exudation is Haematomyces spadiceus.

The following recent occurrence illustrates its usual mode of appearance.
A branch about' 35. feet long, and 9 inches in diameter at the butt, was
blown down at the beginning of July, during the rains. In falling, the outer
half of it lodged in a small tree, so that it stood in a nearly vertical position
with the thicker end on the ground. During August, the upper part of the
branch, above a height of 20 feet, produced numerous green shoots, while
the lower end which rested on the ground began to produce the usual
exudation. During dry weather in September, shoots arose from the lower
end also, and the condition on September 24 was as follows : The exudation
was issuing from cracks in the lowest 4 feet, and the same region bore green
shoots up to a length of about 9 inches, but the shoots were situated chiefly
in the lowest 2 feet 6 inches. On the next 10 feet above that, the bark was
dead, but the uppermost 20 feet bore green shoots, up to a foot in length,
without any exudation. During a week’s drought at the end of September,
the shoots on the upper part began to wither, and the exudation began to
issue in small amount from the same region. It would appear from this, and
other similar observations, that this exudation is only formed in living
cortex. When, on a fallen branch or stem, a bud bursts through the cortex,
the yellow mass frequently appears at or near its base.

Mocharas.

This exudation from the Bombax has long been known in India, where
it is sold as a drug in the bazaars under the name of Mocharas, or Mochras,
or Mocherus, &c. Mocharas means the juice ( ras ) of the Mocha, the latter
being the Sanskrit name of the Bombax. The ‘ Dictionary of the Economic
Products of India ’ describes it as a brown, astringent, gum-like substance,
which occurs in the form of light or dark brown tears, often hollow, and
much resembling galls. Owing to the usual confusion attending the native

P etch— Mocharas and the Genus Haematomyces. 409

names of drugs, there was formerly some difference of opinion whether
Mocharas was obtained from the Bombax or the Areca palm. Birdwrood,
as quoted by Cooke, favoured the latter, and stated that all his attempts to
obtain gum of any kind from Bombax completely failed in Bombay, and he
had no hesitation in saying that the red cotton tree afforded no gum what-
ever. It is, however, now definitely settled that Mocharas is the produce of
the Bombax, and Birdwood’s failure to obtain anything of the kind from
standing trees is quite in agreement with the experience of other observers.

Mocharas was included in the collection of Indian gums and resins
submitted to Cooke and is referred to by him on p. 40 of his Report. He
quotes from the Pharmacopaeia of India that ‘ The astringent gummy
exudation occurs in opaque, dark-brown, knotty pieces, some presenting
a remarkable gall-like appearance, inodorous, of a strongly astringent
taste.’ Cooke included it in his section on Astringent Gums, and stated that
many pounds of it had been broken up, but no evidence had been found that
it was an insect gall. ‘ They are not galls, but gall-like exudations, for
there is every appearance of their having exuded, in a manner similar to gum,
in a semi-fluid state/

Some further light was thrown on the subject by an article by
•B. H. Baden- Powell in the ‘Indian Forester’, viii (1882), pp. 153-5.
The following extract is quoted from his account :

‘ In my garden at Lahore there are two large and well-grown Bombax
trees, which must be as old as the very earliest British resident who came to
Lahore, if not earlier. ... I detached bits of the bark from one of these
trees, made incisions, cut into the surface only, and down to the sap-wood,
but no gum or any other exudation of any kind appeared. But the other
tree, which divides into two stems at about eight or ten feet from the ground,
is covered, as to its lower part, with a clustering mass of the lovely “ pink
coral creeper” (Antigonum leptopus ). Having occasion to trim this, and
remove the old stems or bine, I disclosed the surface of the tree, and saw
that, close to the fork of the two branches, the stem was somewhat swelled,
the bark was all broken up and excoriated, as if in fact a large sort of
unhealthy swelling sore was there : a mass of brownish or blackish powder,
or rather friable grains, had also fallen and collected at the foot of the tree.
This residue looked rather like the excreta of some insects boring into the
bark, but I could not detect any trace whatever of any bark-eating insects,
or any aphides, &c. A great deal of this powdery stuff was to be brushed
off the wood itself, seeming to come from the disintegration of the bark over
the sore. From all parts of this sore I found great masses of the Mochras
which had exuded and dried there : much of it was old and partly rotten,
but some that was fresh looked like deep brown bubbles or shells that had
irregularly contracted in drying. I cleared away all the powder, and
picking out the best bits of Mochras to go to Dr. Cooke, I cleared away the

410 Petch . — Mo char as and the Gemts Haematomyces .

old rotten stuff. After a few days, I observed new Mochras form : to my
surprise it issued in various shaped masses, or worm-like pieces, as if one
squeezed oil paint out of a tube ; this gradually curled up or coagulated
into a mass as chance would have it. It consisted of a rather firm, slightly
translucent, dirty whitish-yellow jelly.

‘To the taste it was almost insipid, but with a slight roughness
indicating astringency. It proved wholly insoluble in cold water, and
nearly so in boiling water, though I think it went into a pulp under such
treatment. It did not appear, either, soluble in pure spirits of wine, but
imparted a red colour to the liquid.

‘ This jelly, when dried by the air and heat of the sun. acquired a dark
brown colour ; the surface dried first, and the inner part gradually shrunk
afterwards, accounting for the blister-like irregular pieces. This then is
Mochras (at least one kind of it).’

The above experience differs from that of other observers in that the
exudation was obtained from a living, though damaged, tree. But it agrees
with others in that wounding the tree did not induce its formation.

Dymock, in the £ Materia Medica of Western India ’, gives the following
information regarding Mocharas :

‘ When first exuded it is a whitish fungous mass which gradually turns
red, and finally dries into brittle mahogany-coloured tears. The larger tears
are hollow in the centre, the cavity being produced during the gradual drying
of the jelly-like mass which first exudes. Dry Mocharas when soaked in water
swells up, and resumes very much the appearance of the fresh exudation.
The taste is purely astringent, like tannin.

‘ Mocharas is not a simple juice, but the product of a diseased action,
which consists in a proliferation of the parenchyme cells of the bark.
Upon making a section of the diseased part a number of small cavities are
seen which contain a semi-transparent jelly-like substance, consisting of
oblong cells with botryoidal nuclei. At the margin of the cavity the
columns of healthy cells are seen breaking up, and the cells separating to
join the jelly-like mass : this gradually increases in size and finds its way to
the surface to be extruded as Mocharas. Upon its first appearance it is of
an opaque, yellowish-white colour, firm externally, but semi-fluid internally,
and there is no central cavity. The cause of the diseased condition of the
bark which produces Mocharas has not been determined.’

Dymock further states that Mocharas only exudes from portions of the
bark which have been injured by decay or insects.

The majority of observers have recorded that they have not been able
to induce the formation of this exudation by wounding a healthy tree.
There is some possibility of error in these observations, owing to the
peculiar character of the Bombax cortex. On a well-grown tree, the
cortex at the base of the stem is very thick, and the inner layers readily

Petch. — Mocharas and the Genus Haematomyces. 41 1

separate into thin sheets. When a piece of cortex is cut out, it may split
off along one of the inner layers, and unless the exposed tissue is examined
microscopically, one is very apt to mistake the smooth, white, cortical layer
for the surface of the wood. It appears to be essential for the formation
of Mocharas that the wound, on a living tree, should extend to the
cambium.

The following observations were made at Peradeniya on the foregoing
point, during October, 1918 :

A rectangular piece of cortex, about 6 cm. by 4 cm., was cut out, down
the wood, from the stem of a young tree about 30 cm. in girth. The cortex
was 6 mm. thick. No Mocharas was formed.

Fourteen young stems, of about the same girth as the last, were
pollarded at a height of about 4 feet. In one case, a small quantity of
Mocharas emerged, about six weeks afterwards, at one point on the cut
surface, from between the wood arid the cortex. In another, the pollarded
stem produced new shoots near the apex, one of which was wrenched off
later, and a small quantity of Mocharas was subsequently produced where
the young shoot had been torn off.

A piece of cortex, about 5 cm. square, was cut out of the stem of
a well-grown tree at a height of 4 feet, the girth of the tree at that
height being i<x\ feet. The thickness of the cortex was 35 mm. About
three weeks afterwards, Mocharas emerged in small quantity from the line
of the cambium, the total amount not exceeding a cubic centimetre. It
issued chiefly along the lower edge of the opening.

Mocharas. therefore, can be obtained by wounding standing trees, but
the quantity is very small in comparison with the amount which issues
from fallen branches or felled logs.

The Structure, etc., of Mocharas.

At Peradeniya, Mocharas occurs on sound branches which have been
broken off by the wind, or on felled Bombax, in either case after they have
been lying on the ground for a few weeks. It issues as a yellowish- white
pasty mass, soft and only slightly viscid. The surface soon becomes yellow
and forms a thin, polished skin, while the inner part remains, for some time,
whitish, subtranslucent, and soft. If it is broken, the inner tissue rapidly
turns brown. Finally, it dries &nd hardens, becoming red-brown to purple-
brown : sometimes the outer skin collapses and the mass becomes irregu-
larly folded, but in other cases it retains its shape and becomes hollow
internally.

When examined in an early stage, the soft, internal tissue is found
to be composed of large cells, either spherical, 40-90 fx in diameter, or more
generally oval, up to 130x100 n . These are thin walled and readily
collapse. Each of them contains a varying number of small, subangular,

412

Petch . — Mocharas and the Genus Haematomyces.

starch for amyloid) grains, from half a dozen to over fifty, usually in a group
towards one side of the cell. As a rule the cells are free from one another,
but sometimes a few may be united in pairs. They are bound together
by a comparatively small quantity of a finely granular slime. The external
covering consists merely of an outer layer of the same cells, browned,
collapsed, and glued together by the hardened slime : it may attain a
thickness of ioo /x.

If the cortex from which Mocharas is issuing is stripped off the wood,
a thin layer of the same substance is usually found lying between the two.
This layer is not continuous, but is interrupted by small islands of tissue
from one to five millimetres in diameter, or sometimes by large continuous
sheets. There are also other smaller masses of tissue, projecting from the

surface of the wood, or the inner surface
of the cortex, but lying beneath the slimy
layer. These patches are usually more
numerous on the cortex than on the wood.
On exposure the slime rapidly turns
brown.

On cutting out a piece of the cortex,
with the underlying wood still attached,
the following conditions are found : Im-
mediately external to the wood is a layer
of parenchyma, consisting of rectangular
cells arranged regularly in radial rows.
This layer may be 2 mm. thick. The
cells do not contain any of the sphaero-
crystals which are a prominent feature of
normal Bombax cortex, and the layer
lacks the lignified fibres which occur so
abundantly in the outer normal tissue.
Instead of the latter, there are usually two, sometimes three, longitudinal
bundles of lignified vessels, often running somewhat irregularly, with
scalariform thickenings. These vessels, like the normal Bombax cortical
fibres and stone cells, give the usual lignin reaction with phloroglucin.
They may run singly through the parenchyma, or be united in bundles
of two or three. Sometimes they bear a slight resemblance to the vessels
of the Bombax wood, though much smaller in diameter, but as a rule they
are distinctly scalariform. The walls of this parenchyma do not stain with
Sudan glycerine : a number of globules in the cells take the stain, but
this occurs also in normal cortex. The walls are stained yellow-brown by
chlor-zinc-iodide : they do not stain with phloroglucin.

No layer corresponding to this is found in normal Bombax cortex. In
the latter, the cortex consists chiefly of rows of lignified fibres, with narrow

Fig. i. Inner surface of the cortex
of Bombax malabaricum , when producing
Mocharas. The white areas are unaltered
cortical tissue ; the intervening shaded
spaces are the galleries. Natural size.

Fetch . — Mocharas and the Genus Haematomyces. 413

bands of parenchyma up to 0-5 mm. wide. The cells of the normal cortical
parenchyma contain large numbers of starch grains, and many contain large
sphaero-crystals.

The examination of this abnormal cortex and the exudation has been
rather of a preliminary character, as it was undertaken chiefly to determine
whether Mocharas was a fungus or not. Many interesting, and apparently
novel, features await further investigation.

When the cortex is exuding Mocharas, this tissue is permeated by
numerous galleries parallel to the cambium and anastomosing freely.
In an advanced stage, the cortex is in some places separated from the
wood, or divided tangentially by cavities which leave only a few layers
of cortical parenchyma overlying the cambium, while in other places it is
united to the wood by narrow columns of parenchyma. Hence when it is
stripped away from the wood it presents the irregular appearance already
described.

Fig. 2. Longitudinal section of the cortex of Bombax malabaricum, when producing Mocharas.
Diagrammatic, a, wood ; b, abnormal cortex ; C, normal cortex with lignified fibres; D, galleries
of Mocharas ; e, browned tissue, showing extension of Mocharas formation ; f, lignified vessels.

The formation of Mocharas begins with' the disorganization of a small
group of parenchymatous cells, and extends until a gallery is formed. The
gallery, in section, may be circular, but is more usually narrow-oval, or
oblong with rounded ends, the long axis of the gallery being parallel to the
cambium. In the cases observed, this has generally begun about the middle
of the abnormal cortical zone.

The radial rows of unaltered cortical cells meet the long flatter sides
(i. e. the outer and inner) of the gallery perpendicularly, but at the curved
boundary they may be displaced so as to be normal to the curve. The
narrow radial boundary of the gallery usually abuts on a normally radial
row of cells, and in many cases a wedge-shaped mass of browned cells
stretches from this boundary through the parenchyma, parallel to the
cambium, indicating an early extension of the gallery in that direction.
All the cortical cells round the gallery are in a state of rapid division by
cross walls parallel to its surface, except, in some cases, those which border
on the shorter sides where the gallery is in process of extension laterally.

The first appearance noted in the cells which are undergoing trans-
formation into Mocharas is a browning and swelling <E)f the cell-walls.

414 Petch.—Mocharas and the Genus Haematomyces.

This swelling appears to take place in the inner layers, i. e. those bordering
on the lumen of the cell. At the same time hyaline globules appear on
the inner surface of the cell-wall and increase in number until in some cases
they almost fill the cells : frequently these globules form short chains, Gl-
are united in botryoidal masses. The cells then separate along the middle
lamella, and intercellular spaces are formed which become filled with slime.
The loose cells lose their brown colour, and their walls are reduced to
a thin membrane and collapse. These collapsed cells, embedded in slime,
completely fill the gallery with a disorganized mass.

The globules on the cell-walls, or in the cells, at first stain yellow-
brown with chlor-zinc-iodide. They do not stain with Sudan III. But
in the older modified cells, they stain black with chlor-zinc-iodide. This
change appears to take place from the centre of the globule, as many of
them stain black in the centre, with a yellow-brown translucent margin.
It thus appears that these starch (or amyloid) bodies are formed from some
constituent of the cell-wall. The grains observed in the cells of the exuded
Mocharas are not the residual starch of the cortical parenchyma. On
staining a section of the abnormal cortical layer with chlor-zinc-iodide,
it is very noticeable that while innumerable granules in the disorganized
mass stain black, nothing of the kind occurs in the surrounding unaltered
parenchyma. There is no starch in the unaltered cells of the abnormal
cortical layer.

A similar formation of Mocharas takes place in the old normal cortex
in small pockets between the fibres, but this occurs only to a small extent,
and it does not seem to contribute much to the amount exuded. The
chief source of the exudation is the abnormal layer of cortical parenchyma
which is developed after the tree is felled. Consequently, Mocharas exudes
principally along the line of the cambium, or from cracks which extend
almost completely through the cortex.

The lignified vessels of the abnormal cortical layer do not form part
of Mocharas. They are pushed to one side, as the galleries are enlarged
by the disorganization of the surrounding cells.

When the mass exudes, the cells expand and assume an oval or
spherical shape. A few are brown, with brown contents, but the majority
are hyaline, and contain a cluster of amyloid bodies. No crystals occur in
the exudation. The red-brown or purple-brown coloration of the outer
layer appears to be produced not only by exposure to the air, but also by
a transfer of some colouring matter from the interior outwards. When
first exuded, Mocharas is pale yellow, or yellowish white, but when the
outer layer has turned red brown, the interior appears distinctly whiter.

When a piece of Mocharas, about three or four weeks old, was boiled
in water, it swelled up and resumed its original shape. At the same time
its colour changed to yellow, and the water became deep red. When left

Petch. — Mo char as and the Genus Haematomyccs. 415

in water, the inner part swelled further, burst the outer wall, and issued in
mucous-like masses.

When Mocharas from the same sample as above was immersed in cold
water, it swelled up and resumed its original shape more gradually. The
colour of the outer layer remained unchanged, but the water was nevertheless
tinged brown. After twenty-four hours, the outer layer had split and the
inner part was emerging in white masses. Twenty- four hours later, these
extruded masses had swollen still further and their boundaries were
translucent.

The reactions yielded by this substance with different reagents vary in
some degree with its age or condition. For example, when it is two or
three days old and has acquired a thick, outer, brown coat the behaviour
of the internal white mass is not quite the same as that of freshly exuded
material, which is covered merely by a thin yellow-brown skin. The
differences, however, are in degree only.

In water, material taken from the interior of a piece two or three days
old swells up slightly into a translucent jelly in which the individual cells
are visible, more or less in lines, like the ova of some aquatic animal. The
water is coloured brown almost immediately. The external brown layer
does not undergo any appreciable change. The same phenomena occur
when this material is immersed in a ,5 per cent, solution of cane sugar, but
the liquid usually is not coloured and the swelling is generally greater.

When freshly exuded material is immersed in water, it spreads out in
an opaque, cream-coloured, slimy layer over the bottom of the tube, the
water being coloured brown as before. Some part of the original mass
may retain its shape, but the bulk of it spreads out over the base of the
tube, instead of swelling up into a definite, pulvinate, translucent mass, as
in the case of the older material. In a day or two, the slime swells still
more and extends up the tube, driving before it the brown liquid, but still
leaving an opaque, creamy layer at the base. In 5 per cent, cane sugar
solution the same happens, but the liquid in this case is tinged brown,
though only slightly, and more of the original mass remains coherent than
in water.

If the freshly exuded material is fixed to the side of the tube, in water,
the bulk of it falls to the bottom and forms a creamy layer as before, but
some of it remains adherent to the side, and swells into translucent strands
in which the cells are embedded. No difference has been observed in the
reactions of these two portions, except as regards the starch grains. Those
in the cells which sink to the bottom turn evidently blue in chor-zinc-iodide,
but those in the cells in the strands take at first a brownish tinge, before
becoming opaque. Treated in the same way in 5 per cent, sugar solution,
comparatively little falls to the bottom of the tube, the bulk swelling into
a cream-coloured mass still adherent to the side.

4i 6 Petch. — Mocharas and the Genus Haematomyces.

Alcohol, ether, and chloroform have no action on either fresh or old
material.

In to per cent, caustic potash, the slime swells up and dissolves. In
small quantity, on a slide, the material turns red-brown, but when immersed
in bulk it becomes purple. The slime dissolves, and the liquid becomes
a deep wine colour. Alcohol discharges the colour, and causes a cloudiness
which, however, disappears on standing. If the liquid is neutralized with
hydrochloric acid, the colour changes to yellow, and no cloudiness occurs
when alcohol is added.

With chlor-zinc-iodide, both the slime and the cell-walls stain yellow-
brown. Occasionally a small patch of the slime stains violet. After
forty-eight hours in io per cent, caustic potash, the cell-walls stain violet,
and the starch grains purple-brown to reddish-brown.

Neither the slime nor the cell-walls dissolve in copper-oxide-
ammonia.

In strong chromic acid both the slime and the cells dissolve, with
evolution of gas from the former. With fresh material, the cell walls are
dissolved in about two hours, but after being soaked in water for forty-eight
hours they dissolve in a few minutes.

There is no effervescence with hydrochloric acid, sulphuric acid, or
acetic acid. Dilute hydrochloric acid induces a granular deposit in the
cells which renders them opaque. No calcium crystals are formed with
either hydrochloric or sulphuric acid, or with ammonium oxalate after
heating with 2 per cent, hydrochloric acid.

With methylene blue, both the slime and the cells stain blue, not
violet. Acetic acid does not destroy the colour. Alcohol discharges the
colour very slowly : after an immersion of twenty-four hours in 80 per cent,
alcohol, the cell-walls have lost all colour, but the slime remains green.
Immersion for the same length of time in glycerine leaves both the slime
and the cells pale blue.

Ruthenium red stains the cell-walls red, but does not stain the slime.

Alcoholic alkannin does not stain the slime or the cells after an
immersion of eighteen hours.

With Sudan III in glycerine, numerous granules in the slime stain red,
but the cell-walls and the general mass of the slime remain uncoloured.
Immersion for twenty-four hours in dilute alcoholic Sudan III, transferring
to glycerine, and heating, as recommended by Kiister, only stains the
granules as before.

No coloration is produced by phloroglucin.

Aniline blue stains the slime blue or greenish blue ; eosin stains
it red.

The coloration of the cell-walls in chlor-zinc-iodide, before and after
treatment with caustic potash, and their insolubility in copper-oxide-

Petek . — Mocharas and the Genus H aematomyces. 417

ammonia indicate that they are suberised. On the other hand, they
dissolve in chromic acid, rapidly if previously soaked in water, and they
do not stain with alkannin or Sudan III.

The coloration of the slime with methylene blue is not that of pectic
compounds and it is not discharged by alcohol or glycerine. The slime
does not stain with ruthenium red. It would appear that it is not
a pectose slime.

A small amount of the slime stains blue with chlor-zinc-iodide, and
is probably cellulose slime, but the main mass is not, as it stains yellow-
brown with chlor-zinc-iodide and is insoluble in copper-oxide-ammonia.

The slime gives the reactions for callose in that it is insoluble in
copper-oxide-ammonia, readily soluble in caustic potash, and stains,
though scarcely typically, with aniline blue. But it also stains with eosin,
which does not stain callose : and it does not dissolve in concentrated cold
sulphuric acid.

Mocharas is rich in tannin. Ferric chloride produces a green colora-
tion, potassium bichromate an intense red-brown, and ammonium molyb-
date yellow.

I regret that I am unable to institute any comparisons with the results
of previous investigations of the slimes which occur in the Bombacaceae
or Malvaceae, as no literature on the subject is at present accessible.

I have not been able to find any evidence that the formation of
Mocharas is induced by the action of fungi or bacteria.

When recently exuded, Mocharas is usually quite free from bacteria,
or fungus spores or hyphae. Pieces taken from the interior of the mass
with the customary precautions showed no growth when placed in culture
flasks in [a) water, (b) a solution containing 5 per cent, cane sugar and
1 per cent, asparagin, or (c) standard nutrient solution. Agar plates of
(b) and (c) gave the same result.

Mocharas, according to the evidence obtained, is derived from an
abnormal layer of cortical parenchyma which is formed in the stems of
Bombax malabaricum after they have been felled, or in some instances,
though apparently rarely, after the cortex has been injured. It consists
of the remains of the walls of the cortical cells, which retain their
continuity though much reduced in thickness, bound together by a slime.

Haematomyces.

Haematomyces spadiceus , B. and Br., is dried Mocharas. The
supposed disorganized hyphae seen in a section are the walls of the collapsed
and distorted cells, while the few cells which retain, more or less, their
original oval shape constitute the 4 obovate, vesicular asci \ The bodies
which Berkeley and Broome considered spores are amyloid grains.

41 8 Petch. — Mocharas and the Genus Haematomyces .

The genus Haematomyces , as originally described, consequently falls,
for even if it should subsequently be demonstrated that Mocharas owes its
origin to the action of a fungus, the exudation itself, which is the material
on which the genus was founded, is not a fungus. The three species of
Haematomyces since described bear no relation to the original species, if
their descriptions can be relied upon.

The simplest way out of the difficulty which thus arises would appear
to be that the generic description of Haematomyces should be amended in
accordance with the ideas which have been associated with the name by
Peck, Rick, and mycologists in general ; and, though the writer is aware
that he is venturing on very dangerous ground in classifying fungi from
their descriptions only; the following is proposed :

Haematomyces (Char, emend.). Stroma superficial, pulvinate, often
cerebriform or convoluted, tremelloid or fleshy-waxy, bearing a palisade
layer of asci and paraphyses over the whole exposed surface, immarginate :
spores continuous, hyaline.

The genus appears to be out of place in the Bulgarieae, and should
probably be placed in the Helvellaceae. In many points it appears to be
too close to Psilopezia , Berk.

The following new species has recently been collected in Ceylon :

Haematomyces carneus.w. sp. Pale purple-red to flesh colour, pulvinate,
cerebriform, up to 1*5 cm. diameter, superficial, subtranslucent, tremelloid.
Asci cylindric, 160 x 10-13 /x, not operculate, eight-spored, spores obliquely
uniseriate. Paraphyses stout, inflated at the apex, diffluent. Spores
hyaline, oval, thick walled, ends subtruncate, 15-^18 x 8-9 /x, exceptionally
36x10 fj„ On dead wood, leaves, &c. Delwita, Ceylon, June 1918;
No. 5767 in Herb. Peradeniya. The whole ascus stains blue with iodine,
the spores and paraphyses staining yellow.

Summary.

1. Mocharas is an exudation from wounded or, more commonly, felled
Bombax malabaricum. It is formed from a special layer of cortical
parenchyma, and consists of the remains of cortical cells united by
a slime.

3. This substance was made the type of a new genus of fungi,
Haematomyces , by Berkeley and Broome in 1873, the type species being
named Haematomyces spadiceus.

3. As the substance is not a fungus, Berkeley and Broome’s genus falls,
but the name is here retained for those species which have been placed in
the genus by subsequent authors.

4. A new species of Haematomyces is described.

Petch . — Moc haras and the Genus Haematomyces. 419

Literature.

1. Baden-Powell, B. H. : Mochras, an Exudation from the Bark of Bombax malabaricum . Indian

Forester, vol. viii, 1882, pp. 153-5.

2. Cooke, M. C. : Report on the gums, resins, oleo-resins, and resinous products in the India

Museum, or produced in India. London, 1874.

3. Dictionary of the Economic Products of India. Article Bombax.

4. Dymock, W. The Vegetable Materia Medica of Western India. Bombay, n.d. (1883).

The Origin and Meaning of Medullary (Intraxylary)
Phloem in the Stems of Dicotyledons.

II. Compositae.

BY

W. C. WORSDELL.

With twenty-seven Figures in the Text.

Introductory.

IN the issue of this journal for October, 1916, the writer set forth the
essential features of the vascular structure of the axial and foliar organs
of the Cucurbitaceae, showing that this structure is fundamentally a ‘ Mono-
cotyledonous ’ one, consisting of a system of scattered bundles of which the
‘ internal-phloem 5 strands constitute an inner series, having completely lost
their xylem.

It can be deduced from the facts presented in this paper that the
vascular structure of the stems and leaves of Compositae belongs to the same
type, having also been derived from an ancestral scattered or ‘ Mono-
cotyledonous ’ system of bundles. Eor the Compositae represent one of the
Natural Orders many members of which exhibit ‘ internal ’ or medullary
phloem in their stems, and it can be shown that the medullary phloem-
strands really represent an innermost series of vascular bundles belonging to
the primitive scattered system.1

What was stated in the previous paper, viz. that such relatively conser-
vative organs as the mature stem, peduncle, and foliage-leaf are to be studied
in connexion with ancestral characters of this kind rather than the seedling
stem, is here again emphasized.

It will thus be seen that the view-point from which the subject is
envisaged is entirely different from that of any of the authors mentioned
below or, indeed, from that of any previous investigator. Hence the treat-
ment of the subject is different, viz. along lines which tend to emphasize
chiefly those facts which have more directly and obviously to do with the
main thesis. Many details of fact which are inessential to the elucidation of

1 In the following pages the structure is usually described as seen in transverse section.
[Annals of Botany, Vol.XXXlII. No. CXXXII. October, 1919.]

422 Worsdell. — Origin and Meaning of Medullary

the principal argument are omitted, while stress is laid upon other facts
which most authors, from their standpoint, would probably deem unworthy
of notice.

Historical.

Petersen, in a general paper on bicollateral bundles in various orders,
describes a number of Compositae amongst the Cichoriaceae which exhibit
intraxylary phloem, e.g. Sonchus , Lactuca , and Tragopogon , and mentions
the presence of some xylem in connexion with this tissue. He gives a long
list of Cichoriaceous genera in which he could find no trace of medullary
phloem. Crepis, L contodon3 Picridium , and Rodigia are included in this
list, in all of which medullary phloem has since been found.

Weiss, in the following year, 1883, contributed an important treatise on
the subject. He seems to have been one of the first to show that the
bundles of the main vascular system of the stem possessing internal phloem
are not true bicollateral bundles in the original acceptation of that term. The
result of his investigations is that the medullary phloem of the stem is in
every case a leaf-trace.

For instance, with reference to Scorzonera hispanica he states : ‘ that
the phloem-bundles to the inside of the protoxylem cannot be regarded as
an integral part of the bundle extending in the same radial line outwards is
clear, for they arise later, and they are also the continuation in the pith of a leaf-
trace occurring in the cylinder in the internode above the node concerned.’
With reference to the case of Lactuca saliva he held that the two smaller
lateral phloem-strands occurring near each protoxylem-group of the bundle
of the cylinder are the direct continuation of those occurring opposite
a bundle in the leaf-base. Here the medullary phloem is directly a leaf-
trace. But other phloem-strands pass into the pith from the ordinary
external phloem of the cylinder, and as this phloem has entered the cylinder
from a leaf at a higher node, such medullary phloem-strands may be
regarded as indirect leaf-traces.

Kruch’s lengthy thesis on the medullary bundles of Cichoriaceae affords
us the results of by far the most thorough and complete investigation of the
matter extant. In Part I he deals with the distribution and diffusion of the
strands, whether they occur exclusively at the periphery of the pith, are
partly peripheral and partly central, or scattered irregularly and uniformly
throughout the pith. In Part II the course of the strands is dealt with ; the
conclusion, after an intricate and painstaking study, being that, for the most
part, the medullary strands of the stem are either the direct continuation of
flower-traces or of the medullary strands of branches , as in Tragopogon . In
a minority of instances they are leaf and cauline strands, as in Lactuca ,
where there is no medullary phloem in the branches (at least in their basal
part) and that of the leaf- bundle enters the pith of the stem when the leaf-
bundle joins the vascular ring (as seen in transverse section), while other

Phloem: in the Stems of Dicotyledons. II. 423

medullary strands enter the pith from the vascular ring ; and this latter is
the case with the bundles of the peduncle.

Peter made an investigation of the genus Scorzoiiera and concluded
that the grouping of the species according to the systematists does not agree:
with that according to anatomical data. He classifies the species into four
groups according to the arrangement and structure of the bundles of the
stem : (1) Bundles arranged irregularly in several indistinct series or rings,
all collateral (2) Bundles in two indistinct series of unequal-sized bundles,
within or without which lie smaller ones ; (3) One regular series of bundles ;
phloem-strands scattered in the pith, with or without xylem ; (4) One series
of bundles only ; no medullary strands ; bundles either collateral or
bicollateral.

Col, in an important account of the arrangement of the bundles in the
stem and le&ves of certain Dicotyledons, cited some interesting facts
regarding the presence of internal phloem in the leaves and axial organs of
some Compositae.

Miss K. Barratt observed in a fragment of an internode of the stem of
Helianthus annnus the passage of a bundle of the vascular ring into the
pith, becoming there an amphivasal bundle. She draws no inferences from
this fact. But the present writer has observed many such cases in other
plants (cf. Tolpis ), and regards them all as instances of partial reversion to
the primitive scattered disposition of the bundles composing the main
vascular system of the stem. It is, perhaps, a more widely-spread pheno-
menon in the Compositae than is generally' known.

Miss E. Whitaker studied the structure of the vascular cylinder of the
stem of species of Solid ago, with special reference to the mode in which the
leaf-trace bundles leave the vascular ring. She starts out from the a priori
standpoint that the woody type of stem is the more primitive in the Com-
positae. There is a single reference to the subject of the present paper, as
follows : ‘ internal phloem in the leaf-bundles of the cortex is a general
feature of the genus and probably of the family. It seemingly perpetuates
a condition which was once characteristic of the bundles of the axis.’

Original Observations.

ClCHORIACEAE.

Tragopogon pratensis, L.

The stem of this plant has frequently been selected to serve as an
example of the occurrence of ‘internal phloem’ immediately within the
xylem of many of the bundles of the main vascular system, such bundles
being, therefore, as in Cucurbitaceae, of the ‘ bicollateral * type. As a matter
of fact, this particular structure is characteristic of only a certain region, viz.
the higher portion of the aerial stem. The object of the present investiga-

424 Worsdell. — Origin and Meaning of Medullary

tion, a continuation of that undertaken for the Cucurbitaceae, is to discover
the meaning and origin of these internal-phloem strands.

The method adopted has been to make transverse sections, successive
and continuous where necessary, from the extreme base of the stem upwards
to, and including, the peduncle. The nature, position, and course of the
internal strands were thus studied in all parts of the axis ; upper and lower,
node and internode.

The general course and origin of the medullary strands, as seen in the
lower region of the stem, and which is typical of the genus as a whole, is
shown in Fig. 2., representing a median radial section.1

Stem 1.

Like nearly all plants of this order, the primary bundles composing the
vascular ring are strongly individualized and more or less irregular in their
alinement, as seen in transverse section. There is a wide pith which at
certain levels becomes in part lacunar.

In the extreme base of the stem, at, or just below, the ground-level, and
below that of the insertion of the lowest leaves, viz. immediately above
where root-structure ends and a pith makes its appearance, two or three
vascular bundles pass into the centre Off the pith from the vascular ring. Of
these bundles, one rejoins the ring at a slightly higher level, while the two
others die out, i.e. end blindly in situ. Before one of them has died qut,
a few large bundles pass into the periphery of the pith from the ring, where
they branch and anastomose and, at a rather higher level, give rise to
a number of bundles in the pith-centre. Where all this occurs is the region
of the lower crowded leaf-nodes. Higher n,p, these bundles constituting the
central system die out in situ. But before they have all died out a new
system of peripheral bundles arises close to the vascular ring ; these
bundles arise de novo, i.e. in the pith without any relation to the ring. At
first consisting of phloem only, they soon acquire a considerable amount of
xylem nearly all round the phloem. At a higher level some of the largest
of these bundles join the ring. Slightly higher still, great numbers of tiny
phloem-strands arise de novo in the central region of the pith and, a little
higher up, the peripheral bundles above cited dwindle in size, and, together
with the central small strands, form a single system of medullary strands
throughout the pith. The smaller strands, consisting of phloem only, occur
everywhere, even in the embouchement of the rays in the vascular ring.
Tracing the structure still higher, the central strands and the smaller of those
at the periphery decrease greatly in number, until only a few remain over
in the central region ; at the same time the larger peripheral strands give

1 All the figures illustrating this paper are diagrammatically drawn. The parts shown black
represent xylem, the dotted areas represent phloem.

Phloem in the Stems of Dicotyledons . II. 425

rise by branching to a fresh system in that region, all of which are vascular
bundles and are closely contiguous to the xylem of the ring-bundles.

The above-described structure obtains in the lower region of the stem.

At a node in a higher region of the stem where a branch is given off,
two or three of the peripheral medullary bundles, occurring on the side on
which the branch and the leaf-bundles are inserted, increase much in size
from below upwards and become incompletely amphivasal in structure ; they
eventually anastomose with the bundles of the ring, and then pass outwards
through the gap to form the adaxial portion of the vascular cylinder of the
branch, becoming perfectly amphivasal before doing so.

The medullary strands of the stem pass up into the peduncle , in the
lower part of which they consist of phloem only. As the lacuna makes its
appearance the central strands die out in situ> so that in the higher part of
the organ the strands, which have here nearly all acquired a little xylem on
their outer side, are peripheral, one occurring opposite each bundle of the
ring and forming with it the vascular supply of a floret.

Stem z.

This was a thicker-stemmed individual than the last. In the swollen
subterranean portion of the stem, at the level of insertion of the lowest leaves
and where, as seen in transverse section, the leaf-traces are passing out, two
or three vascular bundles arise de novo at the periphery of the pith. Here
we see a difference from what obtained in the individual last described,
where the first-appearing medullary strands arose from the vascular ring.
Almost at the same time as these bundles arise de novo they form
connexions with the vascular ring : this case may be thus regarded as
a transitional one between those in which the bundles arise de novo and
maintain for some distance an independent course and those in which the
bundles arise from the vascular ring. A short distance below where these
bundles arise the pith is seen to be full of short tracheides scattered
promiscuously through the tissue.

The medullary bundles at once divide up and anastomose together and
give off branches into the centre of the pith. The large peripheral ones
appear to be directly connected with the leaf-traces, but are not direct
continuations of these last, which is a very different thing. Rather smaller
bundles occur here and there in the embouchement of the rays.

At a higher level, the bundles of the two medullary systems, viz. the large
anastomosing peripheral, and the.smaller, central, branching bundles, become
entirely devoid of lignified xylem. At a still higher level, viz. at about the
top of the swollen underground portion of the stem, the central strands die out
in situ for the most part, but a few of them unite with the peripheral ones.

From a study of the medullary system of the stem in these two

426, Worsdell. — Origin and Meaning of Medullary

Fig. i. Tragopogon orientatis. Transverse sections of the extreme base of the central cylinder
of the stem, numbered from below upwards. The medullary strands are lettered alphabetically in
the order of their appearance. (Diagrammatic.) Fig. 2. Tragopogon. Longitudinal section of
the lower part of the central cylinder of the stem, showing the typical origin and course of
the medullary strands in the genus. (Diagrammatic.) It = leaf-trace ; mb — medullary bundle ;
mps = medullary phloem-strand ; vs = main vascular system (referred to in other diagrams as the
‘ vascular .ring’). Fig. 3. Tragopogon orientalis. Segment of vascular ring, showing internal-
phloem strands ( mps). x 10.- Fig. 4. . Tolpis barbata. Vascular ring, showing transitions

between some of its constituents and the medullary bundles (mb). Rudimentary medullary
strands (bundles and phloem-strands) shown at ms. x 4.

427

Phloem in the Stems of Dicotyledons . IP

individuals it can be seen that very considerable variation occurs in the
lowest region of the organ as regards the origin of the bundles below and
their history and behaviour on being traced upwards.1 But the essential
ground-plan of the structure' is the same in both.

The structure of T, orientalise L. (Figs, i and 3), and T. porrifolius, L.,
is essentially the same. In the latter plant the arc-shaped internal-phloem
strands, of the higher part of the stem, each closely adpressed around the
sclerotic sheath of a bundle of the vascular ring, and giving the bundle its
‘ bicollateral ’ character, pass upwards into the^capitulum and go to form
part of the normal phloem belonging to the bundles of the individual florets.
But some of the medullary phloem-strands die out in situ before reaching
the inflorescence.

Leaf.

The leaf in this genus is rather reduced and grass-like. Hence we
should expect a corresponding condition of the vascular system. This
consists of a curved row or arc of alternately larger and smaller bundles.
In T. pratensis internal-phloem strands are completely absent, at least in all
leaves examined by the writer.

In T. orientalis internal-phloem strands occur throughout the typical
portion of the stalk of the radical leaf on the ventral side of the five larger
median bundles of the row, but are absent from the smaller lateral bundles.
One to three strands occur opposite each bundle. The internal-phloem
strands die out completely in situ in the basal sheathing portion of the leaf,
so that in the extreme base of the leaf they are absent. They also die out
above in the midrib of the lamina.

In T. porrifolius the three or four median bundles of the row, about
half an inch or more above the base, have each several small strands of
internal phloem arranged in an arc either closely contiguous to the bundle
or separated therefrom by two or three layers of cells ; the lateral bundles
are devoid of them. The internal-phloem strands die out below, and the
bundles in the leaf-base are entirely without them.

Hence it will be seen that the internal-phloem strands of the stem in
this genus have no connexion whatever with those of the leaf, though they
are doubtless entirely homologous, and, in the writer’s opinion, will have
been ancestrally directly continuous, therewith.

Scorzonera.

Stem .

This plant is very closely allied to Tragopogon. In conformity here-
with the character of the medullary bundle-system is extremely similar.
The same individual variations obtain as in that genus. For example, in

1 In the higher aerial internodes and in the peduncle the structure of both stems is almost
identical. In the stem-base of other species a strand may arise de novo in the centre of the pith.

428 Worsdell. — Origin and Meaning of Medullary

one specimen of S. Hispanic a, L., all the medullary strands, when traced
downwards, die out in situ in the extreme® base of the stem, while in another
specimen they all pass into the vascular ring. In one individual the
medullary strands are complete vascular bundles throughout the axis of the
plant, in another vascular bundles and phloem-strands occur together.
A mode of origin of the medullary strands was observed in this plant which
was not described for Tragopogon } In 5. hispanica the vascular ring of
a vegetative branch was traced downwards to its complete union with that
of the main stem. As this took place the medullary strands of the branch
pass into the pith of the stem, fusing up there to form a few large strands.
Also a bundle from the middle of the abaxial portion of the vascular ring of
the branch passes into the same region of the pith of the stem, its place in the
branch-ring being filled by the incoming median leaf-trace bundle. Where
the incoming branch is a peduncle , most of the inverted medullary bundles,
occurring in juxtaposition to the bundles of the ring, do not change their
position as these last pass inwards to form part of the vascular ring of the
stem. Both in this species and in S. purpurea, L., minute phloem-strands
may arise, either from the vascular ring at the point of junction of the two
axes, or de novo , and form a rudimentary central medullary system of the
branch. In vS. purpurea it was noted that the slenderer branches of the stem
have no medullary strands, but at their nodes a medullary bundle may
appear in the bay caused by the exit of the cylinder of a secondary branch.

In a fairly strong leafy lateral peduncle medullary bundles occur in the
first two or three internodes, but completely die out above.

Leaf.

In S. hispanica there is the same structure as in Tragopogon , with
internal-phloem strands which die out below. But on the adaxial side of
the pith there are a few small bundles, devoid of internal phloem, each
situated at a different radial distance from the leaf-centre, in a portion of
tissue projecting into the large lacuna. These bundles probably represent
a remnant of the ventral portion of the erstwhile existing vascular ring of
the leaf, and are an indication that this organ, which has the same external
conformation as in Tragopogon , has been reduced in size.

In S. purpurea the internal phloem behaves in the same way. But it
was noted, in the case of one node in the stem, that while the median bundle
of the dorsal row of the leaf was traversing the cortex three minute internal-
phloem strands arose de novo on its ventral side ; immediately before the
bundle passes into the vascular ring of the stem the internal-phloem strands
unite with the ordinary external phloem of the stem.’

1 Essentially the same thing was, however, observed in T. pralensis .

Phloem in the Stems of Dicotyledons. II. 429

Podospermum laciniatum, DC.

Stem.

Herbarium material only.

Very numerous small phloem-strands occur in the pith, aggregated
towards the centre : none occur at the periphery.

P. calcitrapifolium, Boiss.

Stem.

Herbarium material only.

No medullary bundles or phloem-strands were found.

Scolymus.

Stem.

This genus possesses numerous small phloem-strands at the periphery
of the pith, which are continuous into the branches. Opposite the leaf-trace
bundles they are in the form of vascular bundles of much larger size, which
unite with the vascular ring after the leaf-bundles ‘exit’. The medullary
phloem-strands, if traced downwards into the base of the stem, become fewer
in number, and, for the most part, well-constituted amphivasal bundles. At
the lowest level, i.e. immediately below the entrance of the lowest leaf-
traces, they die out in situ . The phloem-strands (a bundle here and there
amongst them) persist into the highest part of the stem and peduncle, and
go to form part of the supply system of the capitulum.

.S', macidatus , L., was the species examined specially for the course of
the strands. 5. hispanicus , L., has essentially the same structure.

Leaf.

There is a simple arc of large, widely-separated bundles. There is no
trace of intraxylary phloem in any part of the petiole or midrib.

This is, therefore, one of the rather rare cases in which the leaf exhibits
a more advanced, i.e. reduced, structure than the stem.

Picridium tingitanum, Desf.

Stem.

Kruch found medullary strands in this plant. The present writer
found that the three specimens which he examined from the Herbaceous
Ground at Kew were entirely devoid of them, save for the invagination into
the pith of two amphivasal bundles in the lower end of one of the branches.

Leaf

There is a simple arc of large bundles alternating with very small
vestigial ones.

430 Worsdell— Origin and Meaning of Medullary

Tolpis barbata, Gaertn.

Stem.

There are two kinds of medullary bundles occurring as an invariable
feature of this plant. Minute bundles and phloem-strands arise de novo in
each internode opposite the bundle of the ring which eventually passes out
as the median bundle of the leaf-system ; they form an arc around its xylem
(Fig. 4, ms). After the leaf-bundle has passed out, they unite with the ring
on each side of the gap.

At each node, at the mouth of the bay formed by an outgoing branch,
similar medullary strands arise de novo and, after the exit of the branch, die
out in situ , though one or two may join the ring of the stem.

In another stem, in one of the shortest, lowest internodes, eight or ten
small, variously-orientated, amphivasal bundles arise de 7iovo all round the
periphery of the pith ; in succeeding internodes above they gradually
die out.

Here also the same small medullary strands arise opposite the outgoing
median leaf-bundle.

Besides the above-mentioned medullary strands, another set, of quite
different origin, sometimes occur in certain internodes. These are well-
developed bundles of the ring which pass into the pith and become amphi-
vasal (Fig. 4, mb). More often, they are seen as constituent parts of the
ring projecting into the pith. In fact, this plant is one of the best for
showing how the vascular ring of the stem of Compositae has been derived
from an original scattered system of bundles.

Leaf.

As the three main leaf-bundles pass outwards into the cortex they
each acquire on their ventral (inner) side a number of small inverted bundles ;
these are derived from the stem-ring ; they persist upwards into the leaf,
and represent the peripheral medullary system of strands of that organ.

Lactuca virosa, L.

Stem.

Medullary strands occur throughout the stem. In the higher part of
this organ phloem-strands only occur (Fig. 6). In the basal region they
acquire xylem and become bundles (Fig. 5). In this basal region, at a still
lower level, they lose the xylem, and eventually either die out in sitii or
join the vascular ring. The amount of xylem in the medullary strands
varies with the thickness of the stem, and is always secondary in origin.
The fate of the strands, if traced upwards, is fourfold. Some of them end
blindly in the pith. Some pass into the vascular ring. Others pass out to
form the medullary system of a branch ; but in one and the same plant

43i

Phloem in the Stems of Dicotyledons. II.

the branch-system may arise both in this way and also de novo in its pith-
tissue. The small peripheral phloem-strands persisting in the higher part
of the stem and peduncle become part of the ordinary vascular system of
the flowers.

The above structure is also exhibited by L. Scariola , L., L. saligna) L.,
and L. sativa , L.

In L. ( Mulgedium ) alpina , Bth. and HK., L. Plumieri , Gren. and Godr.,
L . Bourgaei , L. macrantha , C. B. CL, and L . perennis , L., the medullary

Fig. 5. Lactuca virosa. Segment of vas- Fig. 6. Z. virosa. Ditto from upper part

cular ring from lower part of stem ; in the pith of stem, showing are-shaped internal-phloem

are scattered bundles and phloem-strands, x 4. strands, x 4.

strands (both bundles or of phloem only) are few in number or completely
undifferentiated and vestigial. In some species they only occur at a certain
level of the stem, in others solely at the nodes.

In L . hastata , DC., and L . macrophylla , A. Gray, medullary strands are
completely absent.

Leaf.

In L. alpina and L. Plumieri there is a complete vascular ring.
A medullary system of very small scattered bundles and phloem-strands
occurs close round the central lacuna, and also a peripheral system of fewer

Fig. 7. Lactuca Plumieri. Petiole, show-
ing vascular ring ( vr ) and medullary strands
(ms) ; la, lacuna, x 4.

Fig. 8. Lactuca alpina. Petiole, showing
vascular ring and medullary strands (ms) ;
la , lacuna, x 4.

strands (Figs. 7 and 8). The medullary system ends blindly in the tissue
below, as do also the smallest bundles of the ring. This structure is also
shown by one or two other species.

432 Worsdell. — Origin and Meaning of Medullary

In the leaf of L. virosa there is a simple dorsal arc of bundles ; but
vestiges, in the form of minute bundles, of the adaxial portion may occur.
The medullary system consists of small phloem-strands occurring on the
immediate inner side of the dorsal bundles ; they arise both from these
latter and de novo in the pith.

In L . Scariola medullary phloem has vanished from the leaf. In
L. macrophylla the typical region of the petiole (about half-way up) has
a complete vascular ring, some of the adaxial bundles of which are very
minute and end blindly below , while the rest unite with those on the dorsal
(abaxial) side. The same thing happens in the upper region of the petiole.
Thus, we see in one and the same organ the evolution of the more recent
simple arc of bundles (in other species characteristic of the entire petiole)
from the more primitive ring (characteristic of the entire petiole of still
other species). In one section a minute rudimentary medullary strand was
observed. In those species in whose stems medullary strands are either
absent or almost absent, they often occur, in the form of small phloem-
strands, on the ventral side of the leaf-bundles in the cortex in or near
a node. It is important to note that that segment of the stem-cortex in which
bundles occur which have passed in from a leaf, the place of insertion of
which latter may be a considerable vertical distance above, must be regarded
as constituting part of the leaf, viz. its decurrent base. Further, the small
phloem-strands occurring on the ventral (inner) side of leaf-bundles in
this region are to be regarded as belonging to the peripheral medullary
system of the leaf. In some species, as in L . perennis, these small phloem-
strands occur on the inner side of the median leaf-trace bundle while it still
forms part of the stem-cylinder ; they end blindly in the pith-tissue if
traced downwards. These strands in that species do not pass out into the
cortex with the median leaf-bundle, but they fill up the gap in the outer
portion of the vascular ring of the axillary branch caused by the median
leaf-bundle passing outwards from it. Much the same sort of thing was
observed in Z. macrantha . but, at least in one node, the median leaf-bundle
was devoid of internal phloem at every stage. In all these species the
lateral leaf-bundles also have internal-phloem strands which are derived
from the ordinary external phloem of the stem-ring.1 Before the bundles
pass out into the free petiole the internal phloem fuses completely with the
external phloem of the bundle.

This nodal region of the stem, where the leaf-bundles are passing in
towards the ring, is a conservative region where ancestral characters would
be likely to persist.

The presence of phloem-strands on the ventral side of the median
leaf-bundle while it still constitutes part of the stem-ring is a fact of the

1 In L. Bourgaei it was noted that the more lateral of the internal-phloem strands of the median
leaf-bundle have the same origin.

• 433

Phloem in the Stems of Dicotyledons . II.

first importance, for two chief reasons : in these species these phloem-strands
represent the last vestigial remnant of medullary bundles in the stem, and
it is of paramount interest that they occur in connexion with the main or
median leaf-bundle ; as the phloem-strands are in all respects perfectly
similar to those which occur on the ventral side of the leaf-bundles in the
cortex (i. e. in the decurrent leaf-base), the two sets must be regarded as
homologous ; it follows, further, from this that they must be regarded as
homologous with the phloem-strands (or bundles) occurring on the ventral
side of the bundles of the petiole of other species. The final obvious deduction
is that the small ventral strands of the bundles of the petiole, not only of
this genus but of all genera in which they occur, represent a peripheral
medullary bundle-system of the petiole which is homologous with that of the
stem. And the point of chief interest is that, where they occur in the leaves
of those plants whose stems show no trace of me dullary strands , they indicate
that medullary strands were once a constant feature of those stems.

Even were the above deductions unconvincing, there is no other possible
explanation of these small ventral strands of the leaf.

The medullary phloem-strands or bundles, whether peripheral (‘ internal
phloem ’) or central, of the free petiole arise, as regards their immediate
origin, quite independently, and have no connexion with the internal-phloem
strands of the ‘cortex’ of the stem above described. But this fact does
not interfere with the conclusion that the two sets are completely homologous
with each other. In a case like that of L. per ennis medullary strands are
absent in the free petiole, but we see them beginning to be abstricted off
from the external phloem of the larger bundles. In the decurrent base
of the leaf (‘ stem-cortex ’) they have been completely abstricted off and
occur on the ventral side of the bundles.

Sonchus.

This genus is closely allied to Lactuca. There is space only for a brief
mention of the structure.

S. asper, Hill.

Stem.

The medullary phloem-strands constitute a fairly independent system ;
they form connexions at the node with the bundles of the vascular ring of
both stem and branch.

The most median of the internal-phloem strands of each leaf-bundle
enter the pith and form there an independent strand, but the more lateral
ones unite with the external phloem of the stem-cylinder. The former of
these two facts is of great interest in connexion with what was observed in
the case of Lactuca.

434

W or sdelL- — Origin and Meaning of Medullary

S. arvensis, L.

Stem .

There are medullary phloem-strands at the periphery of the pith, and
at the nodes they are also scattered throughout the pith.

Leaf .

An arc of bundles. The median one has two small internal-phloem
strands ; these die out just before the bundle enters the stem.

Crepis.

C. biennis, L.

Stem .

Considerable variation in the development of medullary strands was
found in this species. In cultivated specimens traces of them were found.
In wild specimens no trace of them could be discovered. In those cases
in which they occur it is in the lower portion of the stem, the higher being
devoid of them.1 Moreover, they are always found at, or in the near
neighbourhood of, a node. They arise both de novo and from the vascular

Figs. 9, 10. Crepis biennis. Segments of vascular ring of stem, showing medullary strands
(ms) in the bay formed by the outgoing median leaf-bundle (mlb). One of the lateral leaf-
bundles at lib. x 9.

ring, as seen in tracing them from below upwards, and they branch and
anastomose, as is usual in other genera. They occur, either as vascular
bundles or phloem-strands, always opposite and contiguous to a leaf- and
branch-trace (Figs. 9 and 10). ‘ Most of them pass out into either a branch-
or leaf-trace to constitute part of the normal vascular tissue, but others
were seen to join the cylinder of the stem. The fate of one strand was
interesting. It arose de novo in the outer part of the bay formed by an
outgoing branch-cylinder. It first of all branched into two ; each strand
so arising formed connexions with the branch-cylinder on either side.
They then passed out, after one of them had again divided into two, with
the leaf-trace bundle, while the branch-cylinder closed up to the inside of

1 In another cultivated specimen, from a distinct batch of seedlings, one or two nodes in the
upper part of the stem exhibited each a well- developed medullary amphivasal bundle.

435

Phloem in the Stems of Dicotyledons. II.

them. The three strands, consisting of phloem only, formed, subsequently,
connexions with the phloem of the branch-cylinder, and eventually they
constituted the internal-phloem group of the median leaf-bundle in the
cortex.

The lateral leaf-bundles in the cortex possess internal-phloem strands
which are derived from the normal phloem of the stem-cylinder.

In C. virens , L.. medullary strands occur in some individuals, of both
wild and cultivated specimens, in fair numbers; in other individuals they
are quite absent.

In C. laraxacifolia , Thuil., a cultivated specimen showed a single sub-
amphivasal, medullary bundle at one node in the bay formed by an outgoing
leaf-bundle; at a lower level it joined the cylinder. Two wild specimens
showed no trace of medullary strands.

In C. nicaeensis, Balb., and C. sibirica , L,, medullary strands are quite
absent from the stem.

Leaf.

The following description relates to C. taraxacifolia :

The vascular structure of the petiole in this species is of a rather more
ancestral type than that of the other
four, with which, otherwise, it generally
conforms. That of C. biennis is shown
in Fig. it.

At the extreme base' is the usual
simple arc of bundles. Higher up,
in the typical region, a row of minute
bundles with inverse orientation (xylem
towards the centre) occurs, represent-
ing the ventral or adaxial portion
of the vascular ring. Between this
adaxial row and the abaxial one are
scattered minute phloem-strands, with
here and there a bundle ; these repre-
sent the medullary system of strands.

There is a small central lacuna.

All these minute bundles and

phloem-strands, i. e. the adaxial portion of the ring and medullary system,
arise de novo below; in other words, end blindly if traced downwards. If
traced upwards they also end blindly at about the level where the petiole
merges into the midrib.

The large median bundle of the dorsal ov abaxial row is more or less
arched and abstricts off on either side a small bundle or phloem-strand,
with inverted orientation, on to its ventral side.

central medullary strands ( cms ), and the
peripheral medullary strands {pms) ; /a,

the lacuna, x 12.

436 Worsdell. — Origin and Meaning of Medullary

The smaller strands of the abaxial row, alternating with the larger
ones, are situated at a slightly shorter radial distance from the lacuna than
the larger bundles ; this is , important as indicating that they represent
a transitional series between the central medullary strands and the larger
bundles of the abaxial row.

The vascular structure of this genus is instructive. We have seen that
medullary strands occur in the stem of some species, but not in that of
others ; and in the stem of certain individuals of the same species, but are
absent in that of other individuals. Moreover, in the latter cases they may
occur in certain internodes of the same stem but are absent in others.
These facts clearly point to the conclusion that the medullary strands are
vestigial (i. e. ancestral) structures which are on the verge of extinction in
the stem.

On the other hand, the petioles of all species examined showed the
very obvious presence of medullary strands in larger or smaller numbers ;
but they are always of extremely small size and on the verge of extinction,
hence no longer of any use to the plant. They represent an ancestral
feature which once prevailed in both stem and leaf of all species.

Picris hieracioides, L.

Both wild and cultivated specimens were investigated.

Stem 1.

Medullary strands are absent from the internodes and from the
branchless nodes. But in the nodes at which branches are given off they
occur, as in the stem of Crepis biennis , to which genus Picris is closely
allied.

At one node -a bundle passed into the stem-ring from the vascular
ring of the branch and took up a position in the inner entrance of the
branch-bay, where it divided into two ; these two bundles then gradually
died out at a higher level in the node as the stem-ring closed up behind
the outgoing branch-ring. At another node two medullary bundles arose
de novo at the bay-entrance, fused together, and died out in situ while the
ring closed up. At another node two bundles arose de novo , one of which
divided; of these three one had apparently died out in the next section ;
the remaining two also died out before the ring had closed up. At two
other nodes the same events occurred. All the above-mentioned nodes are
at successively higher levels on the stem.

Stan 2.

At all the nodes in the lower part of the axis where no axillary
branches, but only small buds, occur no medullary strands are to be found.
In the lowest of the branch-nodes, however, medullary strands occur and

Phloem in the Stems of Dicotyledons. II. 437

behave as in stem 1. But in all higher branch-nodes no medullary strands
exist at all.

A feature of the stem of this species is the very narrow cortex, the
wide pith, and the existence of minute bundles (sometimes reduced to phloem
only) between, and slightly farther to the outside of, the large bundles of
the ring (Fig. 12). These rudimentary bundles, which can hardly represent
an adaptive, but rather a vestigial character, and their relative position
furnish evidence of the primitive scattered arrangement of the bundles of
the ring in this plant, it being merely a
rather good example of what has happened
in the stems of most other Compositae,
viz. a pushing outwards of the larger, inner-
most bundles towards the periphery, whereby
the outer smaller ones inevitably become
reduced and on the way to extinction owing
to lack of adequate-space.

The xylem of all the bundles in the
nodal region is very V-shaped (Fig. 12);
this means that each of these bundles per-
tains partly to the pith and partly to the
vascular ring, hence their semi-amphivasal
structure ; in other words, that they are
the constituents, in this conservative region,
of an original scattered system of bundles.

This is but typical of what occurs in
most Compositae ( 1'olpis barbata and Picris
strigosa are merely cases of this in more primitive form).

P. strigosa, Bieb.

Stem.

Herbarium material only was available of this species. The vascular
ring, as seen in transverse section, consists of bundles with rather V-shaped
xylem, with very numerous tiny ones between them at the same level.

The medullary system of bundles is very striking and pronounced, consist-
ing of a ring of large, perfectly circular amphivasal bundles with protoxylem
in varying positions (Fig. 13). They occur at the periphery of the pith,
and are connected with the ring by two or three bundles of an intermediate
series. This species, therefore, shows the more primitive structure of
the two.

Leaf.

In the typical part of the rachis (there is no petiole) of P. hieracioides
there is an arc of alternately large and small bundles, some of the latter

K k

Fig. 12. Picris hieracioides.
Vascular ling of stem, showing its
vestigial outermost constituents
{vvr) and two peripheral medullary
bundles {mb), x 9. (In this figure
the small vestigial strands have been
placed slightly farther to the outside
than they are in the actual specimen.)

438 Worsdell. — Origin and Meaning of Medullary

being reduced to phloem. As in the case of Crepis , the median bundle
abstricts off a small phloem-strand on either side. There are no central
medullary bundles or phloem-strands. But the small bundles or phloem-
strands alternating with the larger bundles of the arc really represent the
outermost series of a medullary system, as shown by their situation slightly
nearer the ventral side than the large bundles and also close to the edge
of the lacuna. But these last, again, represent the outermost (dorsal) of the
whole system of scattered bundles which once existed in the leaf of all
Compositae. Ihese remarks also apply to the structure of the petiole of
Crepis and I^actuca.

Helminthia echioides, Gaertn.

Stem i (Wild).

The characteristic feature of this plant is the large number of very
small phloem-strands which are scattered uniformly throughout the pith
(Fig. 14). No instance was seen of the occurrence of any xylem in these
strands, and they are of very uniform size. A few arise de novo in the pith

Fig. 13. Picris strigosa. Vascular ring
and medullary bundles ( mb ). x 10.

Fig. 14. Helminthia echioides. Segment
of cylinder of stem, showing vascular ring and
the scattered medullary phloem-strands {mps).
x 12.

of the extreme thickened base of the stem, where they branch up rapidly
to form the large number seen at a higher level in the thinner aerial
portion. They have connexions with the phloem of the ring through the
leaf-trace rays.

The medullary phloem-strands are entirely devoid of hard bast.

At the node, in the bay formed by an outgoing branch, the medullary
strands increase in size ; some of them here join the phloem of the stem-
ring, others pass out and become the medullary strands of the branch.
Here we see that where a medullary system is well developed in the stem
it is continuous with a similarly well-developed system in the branch.

In three cultivated stems, which are more robust than those of the
wild plant, the structure is precisely the same throughout.

In the peduncle the medullary phloem-strands are very minute and
rudimentary and sometimes completely absent.

Phloem in the Stems of Dicotyledons. II.

439

Leaf.

In the midrib the scattered arrangement of the bundles is very evident
The largest bundle is situated by itself on the dorsal side. Farther to the
ventral side is an arc of fairly large bundles, the terminal ones of the arc
being at the inner coiners of the midrib. Unevenly distributed in the
remainder of the space to the inner side of the arc are eight or nine very
much smaller bundles of varying sizes, three or four of which on the extreme
ventral (adaxial) side are very rudimentary and almost extinct. The small
medullary bundles are orientated like those of the arc. We thus see that
the medullary strands of the leaf are better developed and less reduced
than those of the stem, the latter having completely lost their xylem, while
the former have retained it. This is another piece of evidence in favour
of the leaf-structure representing the ancestral type. The very rudimentary
strands on the extreme ventral side of the midrib may represent the reduced
adaxial portion of the original cylinder.

Taraxacum officinale, Weber.

Peduncle.

The vascular ring consists of three sizes of bundles, all practically in
a line, representing, as in so many of such cases, the original scattered
triserial arrangement which existed before the advent of the wide lacuna
of the pith.

- Leaf

The above-stated view, that in the stem (or peduncle) of this plant,
and of all Cichoriaceae, there was an aboriginal scattered system of bundles,
is confirmed by the structure of the leaf. Here, around the central lacuna,
are a large number of very scattered strands of which only a few (3-5) near
the edge of the lacuna on the dorsal side are well-developed bundles ; lying
between and to the outside of these last are considerable numbers of widely-
distributed and, in many cases, exceedingly small and rudimentary phloem-
strands of obviously vestigial nature.

Cynaroideae.

Cynara Cardunculus, L.

Stem.

This is one of the Compositae in which the scattered arrangement of
the bundles is most pronounced. The vascular ring consists of this complex
system, many of the bundles being inversely orientated, others orientated
sideways. They are of all sizes : some extremely small, others reduced
to mere rudiments and fragments. One or two of the large inverted bundles

K k 3

440

WorsdelL — Origin and Meaning of Medullary

are seen to have an arc of three or four small normally-oriented bundles around
their xylem. Such curious groups of concentrically-arranged bundles are
what one so frequently encounters in the leaves of this order ; it is
exceedingly rare to find such bundle-groups passing in® as in this case,
to constitute part of the stem-ring ; it must be regarded as one of the
primitive features of this last.

The great radial thickness of the ring, consisting of scattered bundles,
the very diverse orientation of the latter, their great variation in size, the
presence of numerous rudimentary bundles intercalated amongst the others,
must all be regarded as primitive features, for none of them can be solely
explained on the grounds of adaptation to the very large capitulum with its
great multitude of florets. For there is clearly no reason why the bundles
should be scattered instead of being ranged in line, nor why they should
be diversely orientated, or of different sizes and degrees of development.
It is simply that the considerable thickness of stem in this plant affords
room and play for the original primitive structure of the cylinder ; hence
this has been retained.

C. Scolymus, L.

Peduncle.

All the features described above for the stem of that species are present,
especially in the upper part of the peduncle of this species, in a greatly
accentuated form. The structure probably represents the m6st extreme

Fig. 15. Cynara Scolymus. Segment of vascular cylinder and cortex (V) of uppermost portion
of peduncle, showing the scattered disposition of the bundles. Some of these are inversely orientated
(ib) ; others are partially amphivasal ( ab ) ; others lie sideways. There is here no distinction
between medullary strands and those of the ring. x 4. Fig. 16. Cynara Cardunculus.
Petiole, showing scattered disposition of the bundles, x 4.

case in the Compositae of the primitive scattered disposition of the bundles
composing the vascular ring (Fig. 15). The radial thickness of the ring
here equals the diameter of the pith. The majority of the bundles are
much smaller than those of the stem of the last species, and there are
a larger number of rudimentary strands. A few of the innermost bundles
are completely amphivasal, which is another primitive feature to be added

Phloem in the Stems of Dicotyledons . II. 441

to those already enumerated. Most of these bundles represent traces from
the large involucral bracts. There is no discernible limit between stele
and cortex.

Leaf.

That the extremely marked scattered disposition of the bundles in the
stem and peduncle has no direct connexion, as regards origin, with the
supply of the numerous florets in the capitulum is shown by the fact that
this same scattered arrangement occurs in pronounced form in the petiole of
the leaf (Fig. 16). The bundles are less numerous relatively to the available
space, but exhibit the same differences in size and orientation, and are also
here and there in a rudimentary condition. None of these features can be
represented as in any sense adaptive to the needs of the plant ; it therefore
follows that they are primitive and ancestral. This conclusion thus applies
to the structure of both leaf and stem. According to the view which is
set forth throughout this paper, the leaf has imposed its structure on the
stem, not vice versa.

Centaurea.

Stem.

In C. macrocephala , Puschk., there is a very large capitulum ; this
implies a stout roomy stem and peduncle to support and feed it. Hence
this allows space for the primitive scattered disposition of the bundles to
reappear, which is, in fact, what we find in this species. All the features,
with the exception of amphivasal bundles, described above for Cynara
occur here, but on a very reduced scale.

In all other species the bundles are almost in line, though the ring
betrays in every case its derivation from a scattered system of bundles.

Arctotideae.

Gundelia Tournefortii, L.

Stem.

Herbarium material only was investigated.

Small phloem-strands occur scattered, at wide distances apart, in the
pith (Fig. 17).

Senecionidae.

Senecio Petasites, DC.

Stem .

At the periphery of the pith and opposite, and exactly median to,
the arc of leaf-bundles in the cortex which has recently left the vascular ring,
occur five or six rudimentary medullary strands, one or two being attached

442 Worsdell. — Origin and Meaning of Medullary

to the sclerotic tissue covering the xylem of the ring-bundles. This is the
only case in which medullary strands have been observed in this tribe.

S. clivorum, Maxim.

Leaf.

The petiole contains a large number of variously orientated and sized
bundles scattered indiscriminately throughout the tissue (Fig. 18). The
petiole of S. Petasites does not show this scattered disposition, but a more
reduced type of structure which has evidently been derived therefrom, and
is much more primitive than that of the stem.

Fig. 17. Gundelia Tournefortii Segment Fig. 18. Senecio clivorum. Petiole,

of cylinder of stem, showing scattered medul- showing extreme scattered disposition of the

lary phloem-strands (?nps). x 4. bundles, x 5.

Petasites officinalis, Moench.

Peduncle {Male Plant).

The scattered disposition of the bundles composing the main vascular
system is very pronounced, especially in the upper part of the organ
(Fig. 19). The presence of small, rudimentary, and abnormally orientated
strands suggests the derivation from an even more pronouncedly ‘ Mono-
cotyledonous ’ type of structure.

Petiole.

This organ exhibits one of the best examples known of the primitive
scattered distribution of the bundles, this feature being directly connected
with the large size of the leaf, adequate space being present for the preserva-
tion of the original structure. There is a complete vascular ring with great
numbers of bundles of varying size and orientation, some of which are rudi-
mentary, distributed throughout the ground-tissue (Fig. 20). In the basal
region, where the central lacuna has greatly dwindled in area, further strands
of rudimentary structure appear nearer the centre.

Phloem in the Stems of Dicotyledons . II. 443

It would be difficult to attribute an adaptive significance to the vascular
structure of this organ ; it must, therefore, be aboriginal.

Helianthoideae.

Rudbeckia maxima, Nutt.

Stem and Peduncle .

There are two well-marked features of the vascular ring which strongly
suggest its derivation from a primitive scattered system of bundles, viz.
(i)'the extreme irregularity of alinement of its component bundles, which
are at very variable radial distances from the centre of the pith, and (2)

Fig. 19. Pctasites officinalis. Peduncle of male plant, showing scattered disposition

of bundles, x 5.

the great difference in the size of the bundles, some being very small and
even rudimentary, and irregularly orientated.

There are very well developed medullary bundles, of perfect amphi-
vasal structure, forming a ring about half-way between the ring and the
central lacuna. Nearly all are seen to be branching into two or three
(Fig. 22). In the peduncle some of the medullary bundles occur nearer the
ring, and some are extremely rudimentary.

If traced downwards the medullary bundles are all seen to die out in
situ in the region of the primary node, just above where root-structure
begins. If traced upwards they, in some plants, disappear in the peduncle,
either dying out in situ or passing into the ring. In other plants they persist
into the receptacle of the capitulum, the same fate befalling them there.1

1 In the uppermost region of the peduncle, and also in the receptacle, the lacuna has disappeared
and, as a consequence thereof, medullary bundles occur in the centre of the pith.

444 Worsdell. — Origin and Meaning of Medullary

It is an interesting fact, by no means confined to this genus, that in
the receptacle or axis of the capitulum the bundles of the ring become
completely amphivasal like those of the pith in the peduncle and stem.
This the writer regards as the retention of a primitive feature, there having
been no call for its modification in this part of the plant-axis as there has
been in the case of the vascular ring of peduncle and stem. It cannot be
explained as a necessary structure for the supply of the florets, but has
been retained through not being adversely adapted to this purpose.

Leaf.

In the petiole and midrib there is a simple, regular arc of alternately
large and small (some very minute) bundles (Fig. 23). Apart from the
great disparity in size of the bundles, which is a primitive character, the
structure is an advanced (reduced) one as compared with that of the stem,
the bundles of the arc being regularly alined and there being a complete
absence of medullary strands.

R. digitata, Mill. (. R . laciniata , L.).

Stem and Peduncle .

The vascular ring shows the same features as in the last species. The
cortex is extremely narrow. Medullary bundles are completely absent,
although the lacuna is not more extensive than it is in the last species
(Fig. 21).

Receptacle of Capitulum .

The vascular ring consists of three series of bundles of which the
structure is amphivasal. The innermost are the largest. There are no
central medullary bundles.

Leaf.

The structure is the same as in the last species.

In R. calif or nica, A. Gray, R. occidentalism Nutt., R. Newmani , Loud.,
R. columnar i$m Sims, R. peduncularis , Ton*, and Gray, and others, medullary
bundles are completely absent, and the leaf has a simple arc of bundles.

Echinacea purpurea, Moench.

Stem.

In the higher part of the stem there occur in the centre of the pith six
or seven small bundles of amphivasal structure, consisting of soft bast
entirely enclosed by xylem-fibres ; one or two small vessels or tracheides
were noticed in one bundle ; one or two bundles are quite rudimentary,
consisting of xylem-fibres only (Fig. 24). Owing to lack of material the

445

Phloem in the Stems of Dicotyledons . II.

fate of these medullary bundles in the lower region of the stem was not
ascertained. One or two internodes higher up they have increased in
number by division and are thus smaller,, and for some distance upwards

Fig. 20. Petasites officinalis. Petiole, showing well-developed medullary system of bundles.
Bundles of adaxial portion of vascular ring at avr. x 4. Fig. 21. Rudbeckia laciniata. Vascular
cylinder of stem, showing absence of medullary strands. x 4. Fig. 22. Rudbeckia maxima.
Ditto, showing presence of medullary bundles (mb) ; la = lacuna, x 4. Fig. 23. Rudbeckia

maxima. Leaf, showing complete absence of medullary bundles, x 4. Fig. 24. Echinacea

( Rudbeckia ) purpurea. Vascular cylinder of stem, showing rudimentary central medullary bundles
(mb), x 4.

they traverse the nodes without any change in position or number. In the
higher internodes they gradually dwindle in numbers as a result of fusion
and of dying out in situ until, immediately below the second leafy node
from the capitulum, they completely vanish;

The lateral branches are quite devoid of medullary bundles. In the
peduncle small vestigial bundles or phloem-strands occur on the ventral
side of the bundle which leaves the vascular ring to supply a floret ; they
arise de novo either in the sclerenchyma composing the ventral side of the
bundle or free in the ground-tissue.

446 Worsdell. — Origin and Meaning of Medullary

A smaller specimen examined showed no medullary bundles in the
internodes, unless the two or three small insignificant strands of scleren-
chyma opposite a few of the ring-bundles represent their vestiges. In the
nodes, at each corner of the bay formed by the outgoing vascular ring of
a branch, a bundle enters the pith and becomes amphivasal, only tore-enter
the ring at a higher level just before the branch leaves the stem.

Leaf.

The scattered disposition of the bundles is very obvious in the petiole.
In one specimen are two distinct series, of which' the innermost consists of
very small bundles, evidently vestigial and of no particular or useful
function. In another specimen there are one or two minute, normally-
orientated bundles opposite to, and within, the larger ones ; one of the

larger inner bundles is almost amphivasal,
while other smaller ones have oblique
orientation. In another specimen there
are three distinct series of bundles, of
which the innermost consists of numbers
of very small, normally - orientated
bundles, some of which end blindly
below in the region where the bundles
fuse up to form the simple arc which
eventually passes into the stem ; some
also are seen to end blindly if traced
upwards (Fig. 25).

Some of the outermost (dorsal)
bundles have on their ventral side, and
also at their inner corners, one, two, or
three very small, inversely-orientated
bundles, which, in the base of the
petiole, fuse laterally with the large
bundle (Fig. 25). One or two of these outer bundles are quite concentric,
with central xylem, due to the fact that the small bundles, which in those
just described are detached from the sides and become distinct strands on
the ventral side, are in these cases never detached, but remain a constituent
part of the whole bundle.

Dahlia excelsa, Bth.

Peduncle.

Herbarium material only was investigated.

There is a wide lacuna. In the pith, at wide distances apart, are
a few more or less rudimentary concentric strands consisting, in some cases,
of phloem only with cambial cells all round it ; in other cases, in addition,

Fig. 25. Echinacea (. Rudbeckia ) pur-
purea. Petiole, showing medullary bundles
{mb). The most peripheral of these
{pmb) are recent lateral derivatives from
the arc-bundles to which they are opposed,
x 4-

Phloem in the Stems of Dicotyledons . II. 447

of protoxylem and one or two secondary vessels on the outer side. These
medullary strands are very variable in size, some being very small.

D. Merckii, Lehm.

Stem.

The bundles of the ring have very V-shaped xylem, are very variable in
size, and thus suggest their original derivation from a scattered disposition.

D. sp.

Leaf.

In the petiole is an incomplete ring of separate bundles and a complete
absence of medullary strands.

Hemizonia corymbosa, Ton*, and Gray.

Stem.

Medullary bundles, about three in any transverse section, occur each
close to a bundle of the ring ; they are amphivasal in structure, with xylem
mostly enclosing the phloem.

The bundles of the ring have clearly been set back into line from an
original scattered arrangement, being of very varying sizes and distinctly
individualized.

Inuloideae.

Inula Helenium, L.

Stem.

In two individuals medullary strands were observed near the base and
in the upper part of the stem respectively, and in one case in the base of
a branch and in the peduncle. They occur near the vascular ring, and some
of them are united with the sclerenchyma surrounding the xylem. They
die out above. Each consists of a central strand of soft bast surrounded by
lignified tissue which is probably sclerenchyma, but may be fibrous xylem.
These medullary strands are distinctly rudimentary and evidently on the
verge of extinction (Fig. 26).

The bundles of the ring were clearly once scattered in the ground-
tissue.

Leaf.

The original vascular system of the stem of this plant is revealed, as in
so many cases, by a glance at the present vascular system of the petiole.
In this organ the scattered disposition of the widely-separated (tangentially
and radially) bundles is obvious. They are distinctly two-ranked and of

448

Worsdell. — Origin and Meaning of Medullary

three or four sizes, the largest being situated farthest to the outside, while
the smallest, save for a few inverted ones on the immediate ventral side of
one or two of the largest bundles, occur nearest the centre of the organ.
Some of these smallest bundles are quite rudimentary (Fig. 27).

Further, an index to the primitive stem-structure, as regards the
distribution of the main tissues, is here found in the fact that there is
absolutely no distinction between cortex and pith : the two tissues are
one and indivisible ; the structure is astelic, a general endodermis being

Fig. 26. Inula Helenium. Segment of
vascular ring of stem, showing medullary phloem-
strands {mps). Leaf- bundles at lb. x 9.

Fig. 27. Inula Helenium. Petiole,
showing well-marked scattered disposition
of the bundles, and the small inverted
bundles {pms) on the ventral side of the
median bundle of the arc. x 3.

absent, and a particular one around each bundle being present. The whole
structure supports the view, with which the present writer agrees, that the
pith is cortical in its origin.

Summary.

The following are the main facts concerning the vascular structure of
the stem and leaf in Compositae :

1. The vascular cylinder of the stem is loosely constituted, the com-
ponent bundles being markedly individualized.

2. Their alinement in the vascular ring is more or less irregular, being-
situated at varying radial distances from the centre of the stem.

3. The stems of the vast majority of Compositae are herbaceous.

4. Where vascular strands occur in the medullary region of stem or
leaf they, as a rule, exhibit great variety of development ; some being
throughout well-developed vascular bundles, others consisting of phloem
only ; some possessing both xylem and phloem during part of their longi-
tudinal course, while in another part of their course the same strands possess
phloem only, or have lost the lignified portion of their xylem. Many
bundles dwindle in size when traced upwards or downwards, lose their
xylem, then their functional phloem, and finally die out in situ , — in other
words, end blindly in the parenchymatous tissue.

5. Within the same genus, some species possess medullary strands in
the stem, while other species are completely devoid of them, e. g. Rudbeckia ,
L actuca.

449

Phloem in the Stems of Dicotyledons. II.

6. Within the same species, some individuals possess medullary strands
in the stem, while other individuals are devoid of them, e. g. Crepis biennis ,
C. virens , Picridinm tingitanum }

y. Where the medullary system of bundles is completely or almost
completely absent in the stem, it is frequently conspicuously present in the
leaf, e. g. Arctium Lappa , Crepis taraxacifolia , Senecio clivorum.

8. There are plenty of genera in the order which do not exhibit, either in
stem or leaf, the remotest trace of medullary strands ; but in almost all
the features referred to under (i) and (2) are present, as they are also in the
leaves of Rudbeckia, Tragopogon , and Scolymus. The vascular system of
such genera is, on the writer’s view, the most advanced and has evolved out
of that in which a medullary system was present.

The course of the medullary system of strands through the main stem
and the peduncle might have been described in the reverse direction, viz.
from above downwards. If that had been done it would have been clearly
seen that, as Kruch already pointed out, some of the medullary strands
arise from the flowers , some from the vascular ring of the lateral branches
of the stem, others from the vascular ring of the main stem. Great numbers
arise de novo in the pith-tissue and may either pass into the vascular ring
at a lower level or may form part of a system which ends blindly, i. e. dies
out in situ below. Some individual strands are seen to leave the vascular
ring and almost immediately rejoin it at a very slightly lower level. It
would also be noticed that, on approaching the extreme base of the stem,
a great reduction in the number of the medullary strands occurs either by
means of extinction in situ , as mentioned above, or by anastomosis and
copious fusion until a very few large amphivasal bundles, with well-developed
xylem, occur at that level. Each of these bundles is the exact morpho-
logical equivalent of the strand of internal phloem situated immediately on
the inner, side of each bundle of the ring at a higher level in the stem.
These bundles at a lower level either pass into the vascular ring, or, after
losing their xylem, die out in situ.

The medullary bundles are certainly not leaf-traces. The origin of
some of them from flowers and branches has been stated above. Others
derive from the vascular ring of the stem, which has been built up by leaf-
traces ; such medullary bundles may be, therefore, regarded as leaf-traces
of very indirect origin. The writer could find no evidence for the view set
forth, e. g. by Weiss, that a particular medullary strand may be a leaf-trace
which has entered the vascular ring from a leaf at the node above, pre-
serving its individuality through the intervening internode till it enters the
pith at the node below.

The medullary strands of the stem are not continuations of those of the

1 In P. tingitanum Kruch reports having found medullary strands, while the present writer
could find none in the specimens he examined.

450 Worsdell. — Origin and Meaning of Medullary

leaf, which has its own independent system. On the other hand, they are
sometimes, as in the cases of Scorzonera and Helminthia , direct continua-
tions of those of the branches.

Discussion and Conclusions.

The position assumed in this paper is that the Compositae are primi-
tively and aboriginally herbaceous plants in habit and consistence, a view
which is borne out by the fact that shrubby and arborescent forms are rare
in the order. It is in this way that the writer accounts for the vascular
structure of the stem and leaf throughout the order. The very irregular
alinement of the bundles composing the vascular ring of the stem,1 the
presence in so many forms of medullary bundles or a scattered disposition
of the ring-bundles both in stem and leaf, are brought forward as evidence
in favour of the above view.

It seems to the writer a matter of considerable importance to try and
determine what was the primitive type of vascular structure of the vegetative
organs of the Compositae, and to endeavour to settle the question as to
whether the medullary or scattered system of bundles, occurring either in
stem or leaf, is a comparatively recent, adaptive structure or whether, on
the contrary, it is an ancient, vestigial one. For the structure, viewed as
a whole, must have one or the other origin.

What are the arguments in favour of what may be termed the ‘ adap-
tive theory ’ ?

It has been suggested to the writer that the presence of medullary or
scattered bundles in the stem may be the result of the acquirement of
a congested ' ype of inflorescence in this order known as the ‘ capitulum ’.
This particular type of vascular system would result, in the axis of the
inflorescence, from the excessive shortening of the internodes in that region,
combined, possibly, with a relative increase in the diameter of the axis.
(As a matter of fact, it regularly occurs in the axis of the congested
inflorescences of Compositae, Umbelliferae, and Dipsaceae.) The scattered
system there established might then extend, in more or less accentuated
form, throughout the peduncle and the vegetative stem. If, however, inhibit-
ing factors prevailed, such as the reduction in diameter of these organs, the
necessity for resisting bending-strains in an elongated axis, or the formation
of a hollow pith (central lacuna), medullary bundles would either not be
formed at all, or in very reduced numbers, or rarely. Further, if the
scattered system occurred in the vegetative stem from the cause just men-
tioned this might induce, by correlation, a similar structure in the petiole of
the leaf.

The scattered system of bundles would have been first laid down when
the original loose spicate or racemose inflorescence first began to acquire the

1 The reader must be again reminded that the structure is described from the transverse section.

Phloem in the Stems of Dicotyledons. II. 451

capitulum character, and inflorescence-axis, peduncle, and vegetative
stem would become dominated by this type of vascular structure. The
presence of rudimentary, imperfect strands amongst the others or alone is
explained on the assumption that certain factors arose, some of which are
mentioned above, which induced a reduction amongst the constituents of
the scattered system.

It has also been suggested to the writer that while in Compositae the
scattered system of the stem may have arisen by the above method, in
other Natural Orders, where a quite similar scattered system obtains, a geo-
phytic habit may have given rise to it in the lower region of the stem, and
it would subsequently extend upward into the higher regions of the axis.
In the same way the scattered disposition of the bundles in the petiole may
have had an origin as stated above, while in other cases it may be due to
the fact that there has been no mechanical necessity in that organ for the
bundles to be arranged in a ring (owing, e. g., to the relative absence of
bending-strains). Moreover, the scattered system may have arisen inde-
pendently in both stem and petiole ; it may have already occurred in the
petiole (if a fairly large organ) before the inflorescence became congested with
its consequent appearance in the stem, and the scattered system in both
organs would then have become mutually adjusted to produce the inter-
dependent and continuous structure in the two organs such as we see, e. g.,
in the case of Cynara. This view involves the quasi-independent origin
and development of stem and leaf.

The ideas embodied in the above statements have, doubtless, on the
face of them, a certain plausibility from the point of view of those who
hold that stem and leaf have an independent and coeval origin (e. g. from an
aboriginal thalloid ancestor). It is a question, between the hypothesis set
forth above and that of the present writer, as to which is the most reason-
able and likely to be true after the widest possible survey of all the available
facts. For definite proof, either one way or the other, is not forthcoming.
There can be no doubt that the inquiry into the real nature and origin of
the vascular system of the Compositae is a very important one in view of
the attention which this order attracts amongst botanists, the number and
variety of forms it contains, and its wide geographical distribution.

As already stated, the present writer holds the Compositae to be, as
regards its vascular structure, a type of a very large number of Dicotyle-
donous orders, and the conclusions drawn in this paper with regard to the
nature and origin of its vascular system will apply, once and for all, not
only to this order but to all others in which scattered bundles, medullary
strands, or intraxylary phloem occur. For the writer regards these
phenomena as essentially the same in every one of these orders, varying only
according to the idiosyncrasy of the particular order in which they occur.
He has investigated too many instances to harbour any longer a doubt on

452 Worsdell. — Origin and Meaning of Medullary

this matter. Hence the reason why it is deemed necessary to give as full
and complete a discussion as possible on the whole subject while treating of
the Compositae.

Now, in view of the belief just stated, and of various facts to be brought
forward below, the writer regards the hypothesis of a dual origin for the
scattered system 1 in the stems of Angiosperms as an extremely unlikely
one. It seems much more probable that the vascular system of Angio-
sperms has been founded and built up on a common ground-plan, and that,
therefore, the scattered system has the same origin and meaning in all.2 If
not, then an adequate explanation should be forthcoming for the presence
of medullary bundles in every Natural Order in which they occur. If their
occurrence in Compositae is due to the congested type of inflorescence,
then one might expect a similar explanation of their presence in those
Umbelliferae, e. g. Eryngium , which also possess a congested type of
inflorescence. As a matter of fact the scattered system obtains in the axis
of the inflorescence of this genus. But the vegetative habit and external
conformation of some species of this genus, e. g. E. Serra , is indistinguish-
able from that of a Monocotyledon, and the scattered system of bundles in
their stem and leaf almost entirely resembles that in- the stem and leaf of
Monocotyledons. Hence the conclusion may fairly be drawn that the
vascular structure in the stem and leaf of these plants has the same mean-
ing and origin as it has in Monocotyledons, viz. a result of the geophytic
habit, and is not an extension downward of that obtaining in the axis of the
inflorescence, which, on the adaptive theory, is for the purpose of supplying
the crowded florets. In this connexion it may be pointed out that in the
axis of the inflorescence of E. amethystinum there is a system of medullary
bundles which have nothing whatever to do with the supply of the florets,
for they die out both above and below without forming connexions with the
peripheral bundles, and therefore are clearly vestigial structures, having
been retained in this region where bending-strains are absent, while, on the
writer’s view, they have been purposively eliminated from the peduncle and
vegetative axis of this species.

In other, less Monocotyledon-like genera of Umbelliferae, e. g.
Ferida , whose inflorescence is not congested like it is in Eryngium, the
scattered system of the stem is equally well marked. It may be admitted
that the complete absence of the scattered system in the stems of Dipsaceae 3
and Proteaceae, both of which have congested inflorescences, may be due to
the development of a hollow pith in the stem of some members of the
former and to the woody; xerophytic habit of the stem in the latter. But

1 In this part of the paper ‘scattered system’ and ‘medullary bundles’ stand for the same
phenomenon.

2 An exception must, perhaps, be made for the important group of the Amentiferae, which may
have a distinct origin from other Dicotyledonous orders.

8 It is present in the axis of the inflorescence of this order.

453

Phloem in the Stems of Dicotyledons. II.

this seems an inadequate excuse for their absence in Dipsaceae, which
ought, one would think, to exhibit this feature if it is primarily due to the
congested inflorescence, for in a stem of Morina elegans investigated by the
writer there is a very wide solid pith, yet medullary strands are absent.

Again, medullary strands are a very marked feature of the Melasto-
maceae, occurring in numerous genera, yet there is no congested inflor-
escence in this order, nor numerous floral parts, nor is there any other
special character in the order which may account for their presence, unless
it be the ring formed by the continuous bundles in the stem, ensuring
adequate resistance to bending-strains, and therefore precluding the neces-
sity of a hollow pith with the consequent elimination of medullary strands ;
yet this cannot be the explanation, for Lasianthus strigosus , with a similar
vascular ring, possesses no medullary strands. If the Melastomaceae have
descended from arboreal or shrubby forms (which is the view generally
held) the medullary strands would be, probably, a recently-acquired
feature and adapted for some special function. But it is very difficult to
see, on this view, for what function they have been acquired, why they
occur in some forms and not in others, and why they are well-developed in
some places and rudimentary in others.

Again, to take at random two instances which are typical of others,
why should the almost precisely similar intraxylary phloem-strands in the
stems of Tragopogon (Compositae) and Nicotiana (Solanaceae) be supposed
to have two quite different origins? For in Solanaceae a congested type of
inflorescence does not occur ; hence some other cause for the presence of
intraxylary phloem in this order must be found than that which is held, on
the above view, to account for its presence in Compositae. Yet, in the
present writer’s opinion, it is more than probable that a structure which is
identical in both orders must have had the same origin in each.

Nor, indeed, has the occurrence of phloem in the pith, such, e. g., as
obtains in the Gamopetalae, ever yet been explained on purely adaptive
grounds. Why phloem should occur in this (for it) wholly abnormal
situation is a problem which requires solution, but which no anatomist has
hitherto attempted to solve !

The sporadic occurrence of medullary bundles both in Compositae and
other Natural Orders can with difficulty be accounted for on the theory
which is opposed to that of the present writer. The case of Rudbeckia may
be taken as an illustrative one. It might be assumed that the medullary
bundles of R. maxima are retained owing to the greater diameter of the stem
of that species as compared with that of most of the others, and that their
presence in R. ( Echinacea ) purpurea is owing to the absence of a lacuna in
the pith. But these differences in the stems of the various species appear to
the writer to be insufficiently great or important, and therefore inadequate
to account for the sporadic occurrence of the medullary bundles on the view

h 1

454 Worsdell. — Origin and Meaning of Medullary

that these are to be regarded as a comparatively new and adaptive feature.
It is, on this view, still more difficult to account for their presence in the
stems of some species of Lactuca 1 and their complete absence in other
species, and the writer is unable to discover any adaptive features which
should explain this remarkable fact.

Again, the writer cannot agree that the scattered disposition of the
bundles in the petiole (where it occurs) can have two distinct modes of
origin ; here also, there must be a single underlying cause for the pheno-
menon not only in the Compositae, but in all other Dicotyledons which
exhibit it. A survey of all the facts strongly points to this conclusion.

The hypothesis, as stated above, that the scattered system may have
had a quite independent origin in stem and leaf is, on the view that these
organs are quasi-independent the one of the other, a quite possible one.
But, having regard to all the facts in all Natural Orders concerned, it is
a very inadequate hypothesis, especially in view of the intimate connexion
and relationship between stem and leaf. A single fact which is detrimental
to this view may be cited, viz. the continuation of typical leaf-structure, in
so many cases, into the cortex of the stem.

The theory held by the writer is that the leaf, in its anatomical organi-
zation, is identical with that of the stem ; that it has an epidermis, cortex,
vascular system, and pith which are morphologically identical, and aborigi-
nally one and continuous, with the similar tissues of the stem. The morpho-
logical and anatomical history of the two organs are inseparably bound up
together. Further, the leaf is a more conservative organ than the stem. To
cite a single physiological fact : the leaf has not been obliged, to the same
extent as is the case with the stem, to adapt its structure for the resistance
of bending-strains. This being so, and if the medullary system of strands
of the stem represents, as seems obvious for the reasons set forth above, an
ancestral character, then we should expect this system to be more frequently
present in the leaf than in the stem or, if it occurs in the stem, that it
would often occur in a better developed condition in the leaf. This is, in
fact, exactly what we find.

In the stem of Senecio medullary bundles are practically extinct — only
extremely rudimentary traces of them were observed in A. Petasites. Yet
in the petiole, for example, of N. clivorum , medullary bundles represent an
extremely well-developed system. A similar state of things exists in the
case of Inula Helenium .

In the genus Crepis medullary bundles are either absent or very rare in
the stem ; whereas in the petioles of all species examined by the writer
they are present in considerable numbers, although in a very rudimentary

1 They probably have some use, or they would not have been preserved ; but it is much more
easy to account for their distribution in this genus on the vestigial theory than on the theory that
these strands are recently-acquired adaptive structures.

Phloem in the Stems of Dicotyledons. II. 455

forrrf, the adaxial portion of the vascular ring being frequently also in
a correspondingly rudimentary state (Fig. it).

The genus Lactuca , as regards the occurrence of medullary strands in
stem and leaf, exhibits interesting variations. L. Plumieri , e. g., has almost
lost them in the stem, whereas they are abundant in the leaf, although in
a rudimentary form.

In L. mctcrophylla they are completely absent in the stem, and only
the slightest remnants of them can be found in the leaf, a fact which is
obviously due to the presence of a very large lacuna in the pith. Where
the lacuna is quite small or absent, medullary strands are usually present,
as in L. Plumieri and L. hastata ; in the last-mentioned species medullary
strands are entirely absent from the stem. In L. Scariola medullary
strands are exceedingly well developed in the stem ; in the leaf they are
quite absent.

This last fact shows that, although the leaf is a more conservative
organ than the stem, there are cases in which its vascular system has
become more reduced than that of the stem. The medullary strands in the
stem of L. virosa , L. saligna , L . Scariola , and L. sativa have been retained
in order to subserve some useful function ; they are not merely vestigial
but, in all probability, also adaptive structures.1

In the leaf no necessity for their retention exists, and at the same
time this organ, as compared with that of L. Plumieri and L . alpina , has
become reduced in size. The same phenomenon recurs in the case of
Rudbeckia. In some species medullary strands occur in the stem, in other
species they are absent. But in the leaf of all species except R. {Echinacea)
purpurea they are completely absent, the entire vascular system having
been reduced to a comparatively short arc of bundles, a fact which is
probably due to the petiole having been relatively reduced in size.2

A striking example again is afforded by Tragopogon . The stem of all
species has very numerous medullary strands. The leaf has become much
reduced and almost grass-like in its organization, in accordance with which
fact the medullary strands, in the case of T . pratensis , have become quite
extinct in the leaf, while in the case of the other species investigated they
are small and insignificant as compared with those of the stem, dying out
in the leaf-base.

The theory, therefore, is that in Compositae the vascular structure of
the leaf, wherever it is large and well developed, constitutes a reliable index
to the fact of the former universal presence of medullary strands in the
stem. But it must be taken in conjunction with the fact of the prevalently
imperfect, rudimentary character of the medullary system of the stem
(wherever this occurs), and with the phyton-theory as a basis (viz. that

1 This must be true in all cases where the medullary strands consist of functional tissues.

2 The lamina may be of quite large size.

L 1 %

45 6 Worsdell. - — Origin and Meaning of Medullary

stem and leaf are really one and indivisible, the former being built up of
leaf-bases). The theory undoubtedly receives confirmation from a study of
the vascular system in other Natural Orders.

In Polygonaceae the genus Rumex contains some species which possess
in the stem a medullary system of strands, always in a more or less imper-
fect, rudimentary form ; while in the stem of other species it is completely,
or almost completely, absent. But in the petiole of the leaf of all species,
with the possible exception of the small, reduced R. Acetosella , medullary
bundles occur, not in an imperfect, rudimentary, but in a very well-
developed condition. This uniformity in the vascular structure of the
leaf as compared with the variableness and inconstancy of that of the stem
is strongly in favour of the view that the vascular structure of the leaf repre-
sents, of the two systems, the more ancient type, that, viz., in which a well-
pronounced, scattered system of bundles occurred in both stem and leaf.

In Umbelliferae there are a large number of cases in which, where the
stem exhibits no trace of medullary strands, they are well developed in the
petiole. The markedly imperfect, rudimentary nature of the medullary
system of the stem, in the majority of cases where it occurs, clearly shows
this feature to be an ancestral, vestigial one, which, in many species, has
been preserved in its pristine condition in the more conservative foliar
organs.

The adaptive theory, as set forth on an earlier page, cannot account
for the very frequent presence of rudimentary, imperfect strands both in
stem and petiole. If they represent a comparatively recent acquisition
resulting from the congested type of inflorescence, then the very widely-
diffused presence in Compositae of the scattered system (or medullary
strands) in an imperfect condition of development can with difficulty be
accounted for and is inconsistent with its having been recently acquired ;
there should be, one would think, some very definite explanation thereof
forthcoming. The writer, however, knows of no adequate explanation of
the phenomenon from the point of view of the theory opposed to his own.

On the writer’s view, there must be one single theory to cover all the
facts of the case, which is essentially the same for all the Natural Orders
concerned ; a single theory to account for the medullary system in both
stem and leaf in whatever condition, perfect or imperfect, it may occur.

The writer is acquainted with but one theory which will accomplish
this, viz. that the Compositae, as also the great majority of Dicotyledonous
Natural Orders, are derived from a c Monocotyledonous ’ or geophytic stock
in which the grandifoliate character prevailed, the leaf dominating the stem,
and the latter being primarily built up of leaf-bases. The two organs, stem
and leaf, would be thus in reality one and indivisible, and their vascular
structure identical, such as we see in the typical Monocotyledon of the
present day.

457

Phloem in the Stems of Dicotyledons . II.

Although all types of inflorescence and all kinds of vegetative habit
are found in the Monocotyledons, yet no one has ventured to suggest
that the scattered disposition of the bundles in stem and leaf is due to more
than a single cause, that cause being recognized as lying in the geophytic
habit (modern or aboriginal) of the plants corhposing the class. In the
same way, it is more than likely that there must be a single cause for the
same type of vascular system of the closely-allied class of Dicotyledons.

Just as we regard the two great classes as having had a common
origin in the past, in the same way we must regard the vascular system
of each as being derived from a common ancestral type of vascular
system.

The question therefore arises, What has this ancestral type of vascular
system been ? Has the structure of Compositae (a type of most other
Dicotyledonous orders) been derived from that which consisted of a scattered
disposition of the bundles in stem and leaf, or from that which consisted of
a ring of bundles (as seen in transverse section) in the stem and either a ring,
or arc, of bundles in the leaf? Another form of the question is : Were the
ancestors geophytes, or were they non-geophytic herbaceous or arboreal
forms ?

A comprehensive survey of all the facts clearly suggests that the
ancestors were either geophytes or semi-geophytes. The Compositae and
the other Dicotyledons are now emerging from this ancestral condition ;
a small minority of Compositae have, indeed, actually become arboreal in
habit ; but the herbaceous habit is certainly primitive in this order, as most
systematists who are conversant with it will probably agree.

Jeffrey gives an account, in his chapter entitled ‘The Herbaceous
Dicotyledons ’, of the structure of the vascular ring of the stem of Compo-
sitae at the point where the leaf-trace is detached. He compares the
structure of the more woody and the more herbaceous types respectively.
He concludes, in effect, that the facts constitute clear evidence that the
herbaceous type of structure has been derived from the woody type. The
present writer desires, however, to state most emphatically his complete
inability to discover any evidence whatsoever in the facts set forth by
Jeffrey with regard to the structure of Compositae, or any other order,
which would tend to indicate that the herbaceous type of structure has been
derived from the woody type. The entire chapter is devoid of scientific
argument, consisting of scarcely more than a descriptive statement of the
structural facts.

If the view be held that the Compositae are primitively herbaceous,
then the sporadic occurrence of medullary bundles, their presence in some
individuals, species, or genera, and not in others, their predominantly rudi-
mentary, imperfect development and structure, as also their late ontogenetic
appearance as compared with that of the main vascular system, all become

45 8 W 'or s dell. — Medullary Phloem in Stems of Dicotyledons. II.

easily explicable ; for these are the very features which always characterize
vestigial, ancestral structures.

The writer does not feel called upon, for the purposes of the present
thesis, to determine the precise factors which govern the sporadic distribu-
tion of the medullary strands : why, for example, they occur in the stem of
Lactuca saligna and not in that of L. macrantha. The fact by itself is all-
important and self-sufficient. To cite comparable cases : the presence of
staminodes in the flower of some Primulaceae (e. g. Samolus ) and not in
others, and the presence of inflorescence bracts in some genera of Cruciferae
and their complete absence in others. It is enough that these facts indicate
that an outer whorl of stamens and inflorescence bracts were once constant
and normal features respectively in the ancestors of these plants.

Having now weighed all the facts and hypotheses bearing on the
question, the writer arrives at the final conclusion that the intraxylary
phloem occurring in the stem of Compositae (a type of many other orders)
is the vestige of a formerly well-developed system of medullary bundles
which, along with the bundles of the vascular ring, constituted a scattered
system of bundles, which was the normal feature of the stem in every
member of the order, or its ancestry, at a time when the geophytic or semi-
geophytic habit prevailed in these plants. The more conservative foliar
organs very often retain, the ancestral structure, more or less well preserved,
when it has become extinct, or almost so, in the stem.

The writer is indebted to the authorities of the Royal Gardens, Kew,
for the greater part of the material used in this investigation. He also
desires to thank Mr. L. A. Boodle, F.L.S., for some critical suggestions, and
for taking part in numerous discussions, affecting certain aspects of the
theory embodied in the paper.

Bibliography.

Barr att, Miss K. : A Note on an Abnormality in the Stem of Helianthtis annuus. Ann. of Bot.,
vol. xxx, July, 1916.

Col : Recherches sur la disposition des faisceaux dans la tige et les feuilles de quelques Dicotyle'dones.

Ann. Sci. Nat., Bot., Ser. 8, vol. xx, 1904.

Jeffrey, E. C.: The Anatomy of Woody Plants, 1917, pp. 386-408.

Kruch : Fasci midollari delle Cichoriaceae. Ann. R. 1st. bot. di Roma, vol. iv, fasc. 1, 1890.
Peter : Der anatomische Bau des Stengels in der Gattung Scorzonera. Nachr. v. d. Konigl.

Gesellsch. d. Wiss. zu Gottingen, Heft 1, p. 9, 1898.

Petersen : Ueber das Auftreten bicollateraler Gefassbiindel in verschiedenen Pflanzenfamilien und
iiber den Werth derselberi fur die Systematik. Englers Bot. Jahrb. f. syst. Pflanzengesch.
und Pflanzengeogr., vol. iii, p. 359, 1882.

Weiss, J. E. : Das markstandige Gefassbiindelsystem einiger Dikotyledonen in seiner Beziehung
zu den Blattspuren. Bot. Centralbl., vol. iii, 1883, p. 283.

Whitaker, Miss E. : Anatomy of certain Goldenrods. Bot, Gaz., vol. lxv, March, 1918, p. 259.

Studies on Intrafascicular Cambium in Monocotyledons

(III and IV).1

BY

AGNES ARBER, D.Sc., F.L.S.,

Fellow of Newnham College , Cambridge.

With seven Figures in the Text.

Contents.

PAGE

III. On the Development of the Foliar Bundles in Veratrum album L. . . 459

IV. New Records of the Occurrence of Intrafascicular Cambium . . . 462

Methods 464

Summary 464

Acknowledgements 465

III. On the Development of the Foliar Bundles in
Veratrum album l.

THE part of the vegetative, shoot of Veratrttm album L. visible above
ground during, the spring and summer appears at first glance to con-
sist of an erect axis bearing spirally arranged sessile leaves. But on closer
examination the ‘ axis ’ proves to be merely the extremely long cylindrical
leaf-sheaths, which successively enclose one another, the true stem being
subterranean. The life and growth of the leaves are markedly protracted.
If the plant be examined towards the end of August, when — at least in
plants cultivated in this country — the leaves of the current year are fully
mature and already beginning to fade, next year’s leaves will be found,
beneath the level of the ground, enclosed in a flask-like dilatation of this
year’s leaf-sheaths. The outermost of next year’s leaves take the form of
closed conical scales, and surround the normal foliage leaves with their short
sheaths and delicately plicate blades.

In the mature leaves, gathered towards the end of July, each of the
main bundles of the lamina, as seen in transverse section, is surrounded by

1 These studies form a continuation of : —

I. Arber, A. (1917) : On the Occurrence of Intrafascicular Cambium in Monocotyledons.
Ann. Bot., xxxi, p. 41.

II. Arber, A. (1918) : Further Notes on Intrafascicular Cambium in MonQcotyledons. Ann.
Bot., xxxii, p. 87.

[Armais of Botany, Vol. XXXIII. No. CXXXII. October, igig.

460 Agnes Arber. — Studies on Intrafascicular Cambium

a fibrous sheath (Fig. 3, f), interrupted in the region between the xylem
and phloem. The phloem is remarkable for the arrangement of its elements
in extremely long radial files — an evidence of an unusual degree of cambial
activity. The xylem consists of three highly distinct types of element —
protoxylem (px.), large lumened metaxylem (mx.) and, on the side
towards the phloem, a zone of elements of much smaller calibre with
scalariform sculpturing (xy2.). This occurrence of relatively narrow, ligni-
fied elements, adjacent to the larger metaxylem vessels on the phloem side,
is not infrequently seen in transverse sections of the leaves of Mono-
cotyledons, though it is seldom so strikingly displayed as in Veratrum
album. I have observed it, for instance, in varying degrees, in examining
sections of the following species :

Liliaceae.

Albuca nelsoni N. E. Br.

Allium fistidostim L. (Fig. 4).

A. p or rum L.

A. ursinum L.

Anthericum sp.

Arthropodium panicidatum R. Br.

Colchicum byzantinum Ker-Gawl.

Hemerocallis fidva L.

Hyacinthus (garden var.).

Kniphofia caidescens Baker.

P hormium tenax Forst.

S cilia hispanica Mill.

Smilax laurifolia L.

Veratrum album L. (Fig. 3).

Haemodoraceae.

Anigozanthos sp. (Fig. 5).

Amaryllidaceae.

Crinum sp.

Cyrtanthus sanguinea Walp.

Narcissus pseudo-narcissus L. (garden var.).

Iridaceae.

Crocus (garden var.).

Iris orckioides Carr.

I. sisyrincliium L.

/. sp.

Moraea polystachya Ker-Gawl.

ZlNGIBERACEAE.

Hedychium sp.

In most of the cases enumerated in the above list it is difficult, owing to

461

in Monocotyledons ( III and IV).

the irregular disposition of the small xylem elements in question, to say with
certainty how far they are the result of cambial activity and how far sliding
growth may be a factor in their origin. Some obscurity exists on this point
in the case of Veratrum. But in Anigozanthos sp. (Fig. 5), Kniphojia caule-
scens, Phormium tenax , and Iris sp., I have seen clear indications that these
elements are truly secondary and are derived from the cambium.

Figs. 1-5. Transverse sections of leaf-bundles (x 190 area), f. = fibres; px. = protoxylem ;
mx. = metaxylem ; xy2. — secondary xylem ; pph . = protophloem ; ph. = phloem ; l.b. — lateral
bundle. Figs. 1-3. Development of bundle in leaf-blade of Veratrum album L. ; Fig 1, from
young leaf for next year still enclosed in terminal bud (August 22); Fig. 2, from leaf beginning
to develop in succeeding spring (March 22); Fig. 3, from mature leaf (July 28). Fig. 4. Allium
fistulosum L. Fig. 5. Anigozanthos sp. Figs. 3-5 show the mode of attachment of the xylem
of a branch vein {l.b.) to that of the bundle from which it arises.

Lateral veins are a relatively inconspicuous feature in the leaves of
most Monocotyledons, but there seems to be some evidence that where
they occur in species showing this differentiation of the xylem, their tracheal
elements tend to be connected exclusively with the secondary wood of the

462 Agnes Arber .■ — Studies on Intrafascicular Cambium

longitudinal veins. This is conspicuously the case in Veratrum (Fig. 3, Lb .),
and I have noticed the same thing in some of the other Liliaceae — Allium
(Fig. 4), Kniphojia , Hemerocallis , and Anthericum — and in Iris orchioides .
But I have not investigated the point fully enough to generalize upon it.
In one case in Anigozanthos I observed a lateral vein whose xylem, though
attached in part to the secondary elements, was also connected with the
metaxylem ; but in the bundle drawn (Fig. 5) the connexion was apparently
with the secondary xylem alone.

Apart from the differentiation of the xylem, the leaf-bundles of
Veratrum are of special interest as furnishing a conspicuous case of what
we may call deferred cambial activity. The cambium formed in one season
survives the winter, and is operative in the succeeding year. Fig. 1 shows
a bundle belonging to a leaf taken in August from next years bud ; here
cambium is already visible. Fig. 2 represents the stage reached by
a similar bundle in March of the following year, when the cambium is
actively dividing, while Fig. 3 shows the bundle in July when it is fully
mature and all the work done by the cambium can be recognized. A
Monocotyledonous bundle in which cambium is active in two succeeding
seasons has hitherto been described in only one case — that of the tubers of
Gloriosa superba L.1 But no doubt other examples will come to light
when organs which persist through two or more years are examined from
this point of view.

IV. New Records of the Occurrence of Intrafascicular

Cambium.

Since the publication of my former list of Monocotyledonous families 2
in which the occurrence of cambium has been recorded, I have observed it
in the following additional cases
JUNCACEAE.

Juncus glaucus Sibth. In the leaf-bundles there is distinct cambial
activity, which seems — as is generally the case in the related Liliaceae — to
be chiefly directed to phloem production.

Haemodoraceae. ,

Anigozanthos sp. Cambium occurs in the leaf-bundles and gives rise
to both xylem and phloem elements (Fig. 5).

Amaryllidaceae.

Narcissus pseudo-narcissus L. (garden var.). In the mature leaf, traces
can be detected of a cambium which gives rise to phloem — possibly also to
xylem elements.

1 Queva, C. : Contributions a l’anatomie des MonocotyHdondes. 1. Les Uvulariees tubereuses.
Trav. et Mem. de l’Universite de Lille, T. 7, Mem. xxii, 162 pp., n plates, 1899.

2 Arber, A. (1918), l.c.

in Monocotyledons ( III and IV).

463

Iridaceae. •*

Crocus sp., Iris sp., Moraea polystachya Ker-Gawl., and Sisyrinchium
sp. Since in my previous paper1 cambium in this family was only recorded
in one case ( Tritonia ), it may be worth while to note here its occurrence in
the leaves of members of these four additional genera.

Cyclanthaceae.

Carludovica rotundifolia H. Wendl. The vascular bundles of the axis
of this plant, in the region near the growing apex, show cambial activity
which, though somewhat irregular, is quite well marked (Fig. 6). This case
is of interest because there has hitherto been no record of cambium from
this Cohort (Synanthae).

Fig. 6. Carludovica rotundifolia H. Wendl. Transverse section of bundle from near growing
point of axis ( x 258 circa). Fig. 7. Sciaphila purpurea Benth. Transverse section of a bundle
from an axis less, than 1 mm. in diameter (x 424 circa). t>x. — protoxylem ; mx. — metaxylem ;
ph. = phloem.

Triuridaceae.

I have examined two species of Sciaphila , as representatives of the small
Cohort of the Triuridales. This saprophytic genus has leaves reduced to
little scales, and the development of the vascular tissue is correspondingly
slight. Fig. 7 represents a bundle from the transverse section of an axis of
Sciaphila purpurea Benth., which was less than 1 mm. in diameter. The
arrangement of the elements may perhaps be interpreted as indicating
a vestigial trace of cambial activity.

Arber, A. (1918).

464 Agnes Arber. — Studies on Intrafascicular Cambium

Methods.*

In cases where it has been necessary to use dried herbarium material
for sectioning, I have employed the method of preparation devised by
Dr. R. C. McLean.1 The basis of this method is prolonged treatment with
dilute solutions of caustic potash. For purposes of economy I substituted
impure waste spirit (less than 90 per cent.) for the absolute alcohol recom-
mended by McLean for the first stages of his process, and I also dispensed
with an air-pump, but in spite of these modifications the method gave most
successful results, even with such delicate structures as the inflorescence
axes of the Triuridaceae. The treatment of the material took place in
a room which was kept at such high temperatures that the fluids nearly
always felt tepid to the touch, and I think that this continuous warmth
probably assisted the recovery of the tissues considerably.

Summary.

III.

Attention is drawn to the development of the leaf-bundles in Veratrum
album L., because this is the only case among Monocotyledons (except that
of the tubers of Gloriosa superba described by Queva) in which an intrafas-
cicular cambium formed in one year has been observed to persist through
the winter and to function in the succeeding year. These bundles also show
a clear differentiation between primary metaxylem and secondary xylem
consisting of a group of elements of smaller calibre. The same differentia-
tion has been observed in varying degrees in a number of other Mono-
cotyledons. There is some evidence that it is usual for the xylem of the
lateral veins to be attached exclusively to the secondary xylem of the
bundles from which they arise.

IV.

The existence of intrafascicular cambium is recorded for the first time
in the Juncaceae, Haemodoraceae/ Amaryllidaceae, and Cyclanthaceae.
The Monocotyledonous families in which it is known now number nineteen.
I pointed out in 1918 that cambium had then been recorded in nine out of
the eleven Cohorts of Monocotyledons. In the present paper I have been
able to establish its existence in a tenth Cohort, the Synanthae. In the
case of the extremely reduced bundles of the eleventh Cohort — the Triuri-
dales — the arrangement of the elements suggests a vestigial trace of cambial
activity. This group can therefore scarcely be regarded as forming an
exception to the general rule that intrafascicular cambium occurs in all the
Cohorts of the Monocotyledons.

1 McLean, R. C. : The Utilization of Herbarium Material. New Phyt., xv, 1916, pp. 103-7.

in Monocotyledons ( III and IV ).

465

Acknowledgements.

I wish to express my gratitude to the Director, and to the Keeper of
the Herbarium, the Royal Botanic Gardens, Kew, for material of Carln-
dovica and the Triuridaceae, and also to Professor Seward, F.R.S., for the
opportunity of examining members of the latter family in the Cambridge
Botany School Herbarium. I am indebted to Dr. Schonland of Grahams-
town for kindly sending me leaves of Moraca polystachya and to Mr. R. Irwin
Lynch, M.A., Curator of the Cambridge Botanic Garden, for all the rest of
the material examined.

Balfour Laboratory,

Cambridge.

November 7, 1918.

The Cytology of the Cladophoraceae.

BY

NELLIE CARTER, D.Sc.

With Plate XXVII and two figures in the Text.

.THOUGH the nature of the cell-wall and branching of Cladophora

1Y and Rhizoclonium has recently been investigated by Brand (1895,
1898, 1899, 1901, 1902, 1904, 1906, 1908, 1909), and a systematic
account of the genus Rhizoclonium has been given by Stockmeyer (1890),
no exact information has been obtained concerning the cytology of the
Cladophoraceae, and with the exception of the rather scanty observations
made by Borzi (1883), Schmitz (1879,- 1882), Gay (1891), and others, and
the more recent work of Wille (1901) on Rhizoclonium , very little is known
of the internal structure of the frequently very large coenocytes which form
the thallus in species of this family.

In Kiitzing’s original descriptions of the three genera Chaetomorpha ,
Rhizoclonium , and Cladophora , no information at all is given concerning
the internal structure of Chaetomorpha , whilst for Cladophora he gives the
description, ‘ Substantia gonimica primum cryptogonimica, effusa, demum
granulosa et amylacea, saepissime in lineas laxe spirales ordinata ', and
for Rhizoclonium, ‘ substantia gonimica viridis subtiliter granulosa et
aequaliter diffusa \

Schmitz (1879) noticed the variability of the chloroplasts in Cladophora
glomerata and CL fracta , and remarks that in these two species and also
in Chaetomorpha the cell-cavity is usually traversed by an internal network
of protoplasm, and that on some occasions chloroplasts are also contained
in these internal protoplasmic strands. In a later work (1882) Schmitz
figures the chloroplast of Cladophora arcta as a much perforated parietal
sheath, and says that in other species of the genus the chloroplast is much
more perforated and lobed, and from it arise numerous band-like outgrowths
which penetrate the interior of the cell and fill it with a coarse green net-
work. He also observed that in many members of the Siphonocladiaceae,
including species of Cladophora , the single parietal cylinder seems to have
been divided to form numerous small plates of varying size and form.

Strassburger (1880) also found that the chloroplast in Cladophora
consisted of a more or less netlike parietal sheath or else plates of irregular

I Annals of Botany, Vol. XXXIII. No. CXXXII. October, 1919.]

468 Carter . — The Cytology of the Cladophoraceae.

outline, whilst Gay (1891) also figures coarsely reticulated chloroplasts in
CL fr acta and Rhizoclonium hieroglyphicum .

Kjellmann (1897) gives an account of the chloroplast ot Aegagropila
canescens , which he says consists of a cylindrical parietal sheath, from which
arises a network penetrating into the interior of the cell and consisting of
very thin, almost colourless lamellae bound up in a cell-like mass. Kjellmann
gives figures to illustrate this internal network, and it seems to be rather
different from the coarse network described by Schmitz (1882), neither has
any structure comparable with it been observed during the present work.

Brand (1899, 1901, 1906 a) remarks on the form of the chloroplast
in Cladophora. In the first paper he discusses the occurrence of chloroplasts
in the form of spiral bands as described by Kiitzing (1843) for the summer
condition of Cl. fracta , and Roth (1797— 1806) for Cl. crispata , and since he
himself had never observed such chlorophyll bands, comes to the con-
clusion that this appearance was not normal. In the second paper he
remarks that in all the freshwater species of Cladophora he had examined,
the characters of the chloroplast were similar to those described by Schmitz
(1879, 1882), Strassburger (1880), and Kjellmann (1897), with the exception
of the internal network, which could only be demonstrated in certain cases.
Brand never observed a nearly uninterrupted parietal sheath such as was
figured by Strassburger (1880), and is also of the opinion that the very thin
drawn-out networks, and also the completely free small plates described by
earlier investigators, are only found in extraordinary circumstances ; the
former condition being general in cells which have become abnormally
lengthened by long exposure to strong light, and the latter in cells turned
away from the light and about to form rhizoids. In the last-mentioned
paper Brand again comments on the so-called spiral chloroplasts of
Cl. crispata .

The genus Rhizoclonium has been investigated by Wille (1901), who
finds that a peculiar feature of Rh. riparium is the presence of numerous
short outgrowths proceeding from the external surface of the chloroplast
towards the cell-wall. In Rh. Kerneri these outgrowths were much smaller,
and in neither species could they be distinguished in the fixed and stained
condition. Wille seems to think that these outgrowths of the chloroplast
are obliterated during the process of fixation.

With regard to the number of nuclei, it has generally been believed
that the segments of Cladophora and Chaetomorpha contain very numerous
nuclei, whereas in Rhizoclonium they are very reduced in number. Thus
Borzi (1883) found that in Rh. hieroglyphicum the shortest cells contained
only one nucleus, whilst in the longer segments there were sometimes as
many as four, and Gay (1891) in one instance found five. Wille (1901)
never observed more than four nuclei in either Rh . riparium or Rh.
Kerneri.

469

Carter. — The Cytology of the Cladophoraceae.

Brand (1898) considers the question of the number of nuclei in the
Cladophoraceae and comes to the conclusion that it is not the character of
the genus and the length of the cells which are important in this respect,
as was formerly believed, so much as the cubical content of the cell. In
a later work Brand (1909 B) points out that in certain conditions, for
example in the ‘ statu subsimplex certain thin varieties of Cladophora may
only have one or few nuclei in each segment, so that the number of nuclei
cannot be used as a systematic distinction between the two genera
Rhipocloniitm and Cladophora.

Thus the cytology of the larger members of the Cladophoraceae has
not been thoroughly investigated and there has long been some doubt with
regard to their exact nature. The statements of Schmitz (1879, 1882)
and Kjellmann (1897) that the chloroplast is not confined to the parietal
positions but also penetrates into the interior of the cell have been doubted
by Brand (1901, 1902), and it was felt that the only means of obtaining
accurate information was by cutting sections. Professor G. S. West therefore
suggested that this work should be undertaken.

Methods . For the Cladophoraceae the best fixing solution was found
to be corrosive sublimate, 3 grm., glacial acetic acid, 1 c.c., and 50 per cent,
alcohol, 100 c.c. The solution was used cold, and was allowed to act for
about 30 seconds. The solution used for the fixing of Desmids, which was
exactly similar but contained 3 per cent, acetic acid, was found to have
a too violent action on the cell-wall for it to be satisfactory in the case of
Cladophora ; cf. Brand (1901). The subsequent treatment was similar to
that used in the case of Desmids.1

Some of the material was embedded in paraffin and sectioned, since,
owing to the large size of the cells and the dense nature of the cell-contents,
particularly in the autumn condition when starch is accumulated in large
quantities, it is quite impossible to come to any conclusion about their
structure from mere superficial observation.

Cytology.

The algae examined were freshwater species of Chaetomorpha , Rhizo-
clonium , and Cladophora , since only these were available.

The cytology of these genera was found to be quite similar, although
the exact condition of the segments was liable to variation according to the
relative profuseness of the cell-contents.

The chloroplast invariably consists of an extensive parietal sheath
mantling the whole cell-wall, including the transverse septa, and which in
segments with plentiful contents forms an almost uninterrupted layer
(Text-fig. 1, B).

1 Carter, N. : Studies on the Chloroplasts of Desmids. I. Ann. Bot., xxxiii, 1919.

M m

470

Carter .— The Cytology of the Cladophoraceae.

Where the cell-contents are not quite so profuse, however, this external
layer is often more or less perforated, so that considerable patches of the cell-
wall are left uncovered (PI. XXVII, Fig. 3). In Text-fig. 1, C, a segment of
this kind is seen in section, and it is quite clear that the chloroplast does not

Text-fig. i. Rhizoclonium hieroglyphicum-, .(KWtz.) Stockm. a, transverse section of a fila-
ment in the autumn condition ; B, external view of part of a similar filament ; C and D, transverse
sections of a very narrow form ; E and F, transverse sections of a much larger form ; G, part of
a longitudinal section of a similar filament ; st , starch-grains. All x 910.

cover the whole cell-walk The size of the perforations depends entirely on
the amount of chloroplast available in the particular segment, and therefore
often varies in different parts of the same thallus. This is particularly
noticeable in Cladophora glomerata, (L.) Kiitz., in which the younger apical
segments are often densely filled with cell-contents, and here the cell-wall
is usually completely mantled by the chloroplast, whilst in the lower cells

47i

Carter . — The Cytology of the Cladophoraceae.

of the branches the parietal layer of chloroplast is often more or less
coarsely reticulated. Numerous small free plates such as those described
by Schmitz (1882) have never been observed during this work, except in
the case of a form of Cladophora which had been kept indoors in abnormal
conditions for several weeks and was obviously in very bad condition.
This observation supports those of Brand (1901), who also expressed the
opinion that this condition of the chloroplast was not normal.

The small outgrowths described by Wille (1901), projecting from the
external surface of the chloroplast in Rhizoclonium riparium , have never

c, Ch. Liniim , (Muell.) Kiitz. Longitudinal section, x 51c. pp , protoplasm.

been observed in any of the species examined during this work Nor is it
likely that their absence was due to the process of fixation, since quite
similar structures have been well preserved in Desmids which were subjected
to the same treatment. The chloroplast was found in every species to be
closely applied to the interior of the cell-wall and its external surface was
always quite smooth (Figs. 1-8 ; Text-figs. 1 and 2).

Sections revealed the fact that the chloroplast, as has already been stated
by Schmitz (1879, 1882), is not always confined to the periphery of the cell,

M m 2

47 2 Carter. — The Cytology of the Cladophoraceae.

but frequently penetrates into the interior and ramifies in all directions
(Figs, i, 2, 4, 6, and 7 ; Text-fig. i, A, F, and G, Text-fig. 2, B).

Again, the extent of this depends on the individual cell. In the older
segments of Cladophora and the large segments of Chaetomorpha Linum ,
(Muell.) Kutz., the entire chloroplast is confined to a very thin parietal
lining layer, and the interior of the cell is occupied by a large vacuole, being
destitute of both protoplasm and chloroplast (Figs. 5 and 8 ; Text-fig. 2, c).

In the younger segments of Cladophora , however, and the rather smaller
segments of Chaetomorpha gracilis, Kutz., and some forms of Rhizoclonium
hieroglyphicum , (Kutz) Stockm., which are much richer in cell-contents, the
interior of the cell is often traversed by irregular ramifying strands of
chloroplast (Figs. 1, 2, 4, 6, and 7 ; Text-fig. 1, A, F, and G, Text-fig. 2, B).

The pyrenoids are very numerous, particularly in Chaetomorpha and Cla-
dophora, and are to be found in every part of the chloroplast (Figs. 1-8 ;
Text-figs. 1 and 2). It was noticed in Rhizoclonmm hieroglyphicum that
the pyrenoids in the internal strands of chloroplast were much larger in
size than those occurring in the thin parietal lining layer, possibly because
they can develop far more freely in this position (Text-fig. i,f).

When the interior of the segment is filled by these ramifying strands of
chloroplast it is often very difficult to distinguish between the chloroplast
and the colourless cytoplasm. Of course, when the external parietal sheath
of chloroplast is reticulated it is quite easy to demonstrate the colourless
cytoplasm filling in the perforations in the chloroplast (Fig. 3). Where the
chloroplast is almost continuous over the whole cell-wall, however, colourless
cytoplasm is often apparently non-existent. In sections, also, it often
appears that every available strand of cytoplasm is occupied by chloroplast
and pyrenoids (Figs. 1 and 6). It is sometimes possible, however, to dis-
tinguish extremely delicate, nearly colourless, granular strands, destitute of
pyrenoids and usually of nuclei also, which doubtless represent the colourless
cytoplasm (Text-fig. 2, b) ; but very frequently the chloroplast is so extensive,
and penetrates both the lining layer of cytoplasm and the internal strands
traversing the lumen of the cell so completely, that the colourless proto-
plasm is reduced to an extremely thin film enveloping the chloroplast — so
thin that it cannot be detected.

The relation of the nuclei to the chloroplast is rather unusual in these
three genera. In other algae where there is a definite chromatophore, the
nucleus is usually confined to the colourless cytoplasm, but in Cladophora
and Chaetomorpha particularly the nuclei are nearly always more or less
completely immersed in the chloroplast. They are scattered throughout
both the parietal lining sheath of chloroplast and also in the internal strands
traversing the cell-cavity (Figs. 1, 2, 4-8 ; Text-figs. 1 and 2). In the parietal
layer no definite colourless cytoplasmic sheath can be detected round the
nucleus, and in the interior of the cell they usually occur in such close

473

Carter . — The Cytology of the Cladophoraceae .

association with the pyrenoids that here also it is quite impossible to
distinguish between definite colourless cytoplasm containing nuclei and
chloroplast with pyrenoids (Figs, i and d).

The structure is very suggestive of -that described by Timberlake (1901)
for Hydrod ictyon . Timberlake found that in this alga the nuclei and pyre-
noids often occurred in such intimate connexion that he was unable to
distinguish a definite chromatophore, and so he decided that the chlorophyll
must be diffuse and evenly distributed throughout the cytoplasm. The
nuclei are nearly always in the same close association with the pyrenoids
in the Cladophoraceae, but since it is sometimes possible to distinguish
a coarsely reticulated chloroplast lying against the cell-wall with colourless
interstices, it is quite obvious that in this case the chlorophyll cannot be
diffuse. In these forms it is rather that the chloroplast has become so
massive and has invaded the cytoplasm to such an extent that it naturally
engulfs the nuclei as well. Moreover, the nuclei seem to prefer this position
within the chloroplast rather than the colourless cytoplasm itself, for even
in cells where the parietal film of chloroplast is very scanty, and more of
the lining layer consists of colourless cytoplasm than is occupied by the
chloroplast, the nuclei are still to be found in the chloroplast itself, although
there is plenty of room for them in the colourless cytoplasm filling in the
interstices (Fig. 3).

Borgesen (1913), although not remarking particularly on the position of
the nuclei, similarly figures these bodies apparently within the chromato-
phores in two members of the Siphonocladiales, Cladophoropsis membranacea 1
and Siphon ocladus tropicus .2 • In another species, however, Boodlea Siam -
ensis ,3 the nuclei are figured in the colourless cytoplasm lining the cell-
wall, between the chloroplasts, whilst in Dictyosphaeria favulosaf Chamae-
doris Peniculump and Ernodesmis verticillata 6 the nuclei are described as
being either near to or underneath the chloroplasts in the cell-plasma. Thus
it is quite possible that Borgesen really intended that in the first two species
also, the nuclei should be imagined to lie in the protoplasm under the
chromatophores, but this point is not made absolutely clear.

There seems to be no doubt, however, that in the species of Cladophora
and Chaetomorpha examined during this investigation most of the nuclei
are immersed directly in the chloroplast. It is only very rarely that one
meets with a nucleus in the interior of the cell which is not in close asso-
ciation with pyrenoids, and might possibly be quite free from the chloro-
plast.

The same remarks apply with very slight modification to Rhizoclonium
hieroglyphicum . In a very narrow form examined, the chloroplast was con-
fined almost entirely to the peripheral parts of the cell, forming a very thin,

1 p. 47- 2 P- 66. 3 p. 50. 4 p. 34.

5 p. 58. 6 p. 68.

474 Carter. — The Cytology of the Cladophoraceae.

more or less reticulated parietal film. The nuclei were in this form of very
large size in comparison with the small diameter of the cell, and therefore
projected considerably from the thin parietal film of chloroplast into the
cell-cavity. Thus they were usually not entirely immersed in the chloro-
plast (Text-fig. i, c and d).

In a rather thicker form examined the condition approached more
nearly that found in certain forms of Cladophora (Text-fig. i, E-G).

The projecting of the nuclei into the cell-cavity is often observed in
some forms of Cladophora and Chaetomorpha in which the lining parietal
film of chloroplast is extremely thin (Figs. 4 and 5 ; Text-fig. 2), but this is
far more pronounced in the narrow form of Rhizoclonium hieroglyphicum
described above.

With regard to the number of nuclei occurring in the segments of
Rhizoclonium hieroglyphicum , the narrower form very often had only two,
although four and eight were also very frequent, whilst in some very well-
nourished filaments, the cells of which had very dense cell-contents, the
nuclei were often as many as sixteen. In the larger form the nuclei were
always more numerous (Text-fig. 1, G), eighteen to twenty-four being com-
monly found in segments of medium size. In opposition to this it was
noticed that in Cladophora crispata , (Roth) Kiitz., the nuclei in many of the
segments having very scanty cell-contents were very reduced in number,
sometimes to eight or nine.

These observations tend to support those of Brand (1898), that the
number of nuclei depends not on the genus itself but largely on the cubical
content of the cell, and also show that the relative abundance of the cyto
plasmic contents of the segment also plays some part in this respect.

Both Rhizoclonium and Cladophora accumulate large quantities of starch
during the autumn months of the year, and material was therefore examined
in this condition in order to get exact details of its storage. In the external
view the parietal film of chloroplast is usually seen to be quite continuous,
and its protoplasmic reticulum is very coarse, the cavities between the
meshes being occupied by innumerable starch-grains (Text-fig. 1, B).

Thus the whole of the chloroplast between the pyrenoids is densely
packed with starch-grains, and these also extend into the films of chloro-
plast between the nuclei and the cell-wall, so that the nuclei are often
pushed farther into the interior of the cell. This is better seen in sections
(Fig. 2; Text-fig. 1, a).

The strands of chloroplast traversing the lumen of the cell are similarly
packed with starch, and become very distended, occupying even more of
the cell-cavity. In this condition no trace of colourless cytoplasm can be
detected, and the nuclei are even more completely enveloped by the
chloroplast (Figs. 2 and 7 ; Text-fig. 1, A).

In Rhizoclonium the cell becomes nearly solid with pyrenoids and starch,

Carter. — The Cytology of the CladopJioraceae. 4.75.

the vacuoles diminishing as the chloroplast becomes more and more
distended (Text-fig. i,a).

In Ctadophora it is quite certain that these starch-grains which accumu-
late in the chloroplast had their origin in the pyrenoids, as explained by
Timberlake (1901), since they correspond fairly well with the starch-grains
of the starch-sheaths in size and shape, and are often seen grouped in circles
round the pyrenoids, having just been thrown off. In Rhizoclonimn , however,
this is not quite so clear, for most of the grains lying free in the chloroplast
are somewhat smaller in size than the large and peculiar grains which make
up the sheaths of the pyrenoids.

Division of the Nucleus.

Division of the nucleus was observed in Ctadophora gtornerata , var.
simplicior , Kiitz., and also in Rhizoclonimn hieroglyphicum , and was found to
be very similar in both species. The resting nucleus is a more or less
spherical body with one or more deeply staining karyosomes (Figs. 9, 23,
and 24).

In the particular form of Ctadophora examined the nucleoli were often
particularly numerous, as many as three to five being present in some of the
nuclei (Figs. 24 and 25). The nuclear reticulum contains practically no
chromatin.

The beginning of division is marked by the gradual disappearance of
the nucleoli, the chromatin becoming dispersed through the whole nucleus*
finally becoming associated into a spireme which in both species is very
long, thin, and convoluted (Figs. 10-12 and 25-28). The contraction of
the spireme was particularly clear in the case of Rhizoclonimn (Figs. 12-14).

The shortened and thickened spireme was later observed to have split
into a number of chromosomes which arranged themselves on an equatorial
plate (Figs. 15, 29, and 30). The chromosomes are in both cases rod-like
structures and are so numerous that it is almost impossible to count
them. Division of the chromosomes evidently takes place whilst they are
on the equatorial plate, for in the next stage two still very large groups of
chromosomes are seen being pulled to opposite poles by the fibres of the
nuclear spindle (Figs. 16-18 and 31).

The telophase of the division is characterized by the gradual separation
by constriction of the daughter nuclei. This is accomplished by the con-
traction of the spindle in the region of the equator, some of the fibres being
still visible for some considerable time (Figs. 18-20 and 32-34).

Thus the daughter nuclei remain connected by a bundle of fibres which
gradually diminishes in thickness and finally disappears altogether, leaving
the two nuclei quite isolated (Figs. 21 and 35).

Meanwhile, within the daughter nuclei themselves the chromosomes
lose their identity and the chromatin rearranges itself, forming first a rather

476 Carter . — The Cytology of the Cladophoraceae .

indistinct daughter spireme and finally the typical resting nucleus with one
or more nucleoli (Figs. 20-3 and 35-7).

Some very peculiar nuclear division figures at the anaphase stage were
observed in Cladophora glomerata, var. fascicidcita, (Kiitz.) Brand. In these
nuclei the migration of the chromosomes to opposite poles was extremely
disorderly, the chromosomes following one after the other in an irregular
fashion instead of being pulled apart by the fibres of the spindle in two compact
masses, whilst the spindle itself was often bent (Figs. 38-40). These peculiar,
stages were taken from segments in which rapid nuclear division was taking
place preparatory to the formation of zoogonidia, but whether this apparently
abnormal mitotic figure is general in such cases could not be ascertained.

Summary.

Thechloroplast in Cladophora , Chaetomorpha , and Rhizoclonium consists
invariably of a parietal film lining the cell-wall and often more or less per-
forated or reticulated according to the relative abundance of the cell-contents.
In most cells with plentiful contents there arise from this lining layer irregu-
lar strands which traverse the lumen of the cell, and in many cases are so
numerous that they occupy a considerable part of the cell-cavity. In mature
cells, or cells with very scanty cell-contents, this internal network of chloro-
plast may be wanting.

Pyrenoids are very numerous and are scattered in both the peripheral
and internal parts of the chloroplast.

Colourless cytoplasm is very difficult to distinguish except where the
lining parietal layer of chloroplast is perforated, and the nuclei are almost
invariably confined to the chloroplast, not. being found as a general rule in
the colourless cytoplasm.

In some narrow forms of Rhizoclonium the nuclei are of large size in
comparison with the small diameter of the cell, and in these the nuclei may
not be wholly immersed in the chloroplast, but may often project into the
cavity of the cell.

The nuclei in Rhizoclonium hieroglyphicum are not so restricted in num-
ber as was formerly believed to be the case, since in some thick forms they
frequently number twenty-four in a cell.

In the autumn much starch is accumulated and is stored in the form of
small grains, which are lodged in the interstices of the protoplasmic reticulum
of the chloroplast. As a result of this the chloroplast becomes very dis-
tended, and occupies relatively much more of the cell-cavity.

During mitosis the nucleus of Rhizoclonium and Cladophora is charac-
terized by the formation of a long thin spireme, which gives rise to very
numerous chromosomes. After the migration of these to opposite poles of
the spindle the daughter nuclei are separated by constriction of the spindle
in the region of the equator.

477

Carter. — The Cytology of the Cladophoraceae.

In conclusion, I wish to acknowledge "my indebtedness to the late
Professor G. S. West, who not only suggested this subject for study, but
also gave much help and advice during the investigation.

The Botanical Laboratory,

University of Birmingham.

Bibliography.

Borgesen, F. (1913) : The Marine Algae of the Danish West Indies. Pc. I. Chlorophyceae.
Copenhagen, 1913.

Borzi, A. (1883) : Studi Algologici. Messina, 1883.

Brand, F. (1895) : Ueber drei neue Cladophoraceen aus bayrischen Seen. Hedwigia, Bd. xxxiv,
1895.

(1898) : Culturversuche mit zwei Rhizoclonium- Arten. Botan. Centralbl., Bd. lxxiv,

1898.

(1899) : Cladophoi'a- Studien. Bd. lxxix, 1899.

(1901) : Ueber einige Verhaltnisse des Baues und Wachsthums von Cladophora. Botan.

Centralblatt Beihefte, Bd. x, Heft 8, 1901.

(1902): Die Cladophora- Aegagropilen des Sfisswassers. Hedwigia, Bd. xli, 1902.

(1904 a) : Ueber Cladophora humida n. sp., Rhizoclonium lapponicum n. sp., und deren

bostrychoide Verzweigung. Ibid., Bd. xliii, 1904.

(1904 b) : Ueber die Anheftung der Cladophoraceae und iiber verschiedene polynesische
Formen dieser Familie. Botan. Centralblatt Beihefte, Bd. xviii, Abt. i, 1904.

(1906 a) : Ueber Cladophora crispata und die Sektion Aegagropila. Hedwigia, Bd. xlv.

1906.

(1906 b) : Ueber die Faserstruktur der Cladophora- Membran. Deutsch. Botan. Gesellsch..
Bd. xxiv, Heft 2, 1906.

(1908) : Ueber Membran, Scheidewande und Gelenke der Algengattung Cladophora .

Ibid., Bd. xxvi, 1908.

(1909 a) : Ueber die .morphologischen Verhaltnisse der Cladophora- Basis. Ibid.,

Bd. xxvii, Heft 6, 1909.

— (1909 b) : Zur Morphologie und Biologie des Grenzgebietes zwischen den Algengattungen

Rhizoclonium und Cladophora. Hedwigia, Bd. xlviii, 1909.

Gay, F. (1891) : Recherches sur le ddveloppement et la classification de quelques algues vertes.
Paris, 1891.

Kjellmann, F. R. (1898) : Zur Organographie und Systematik der Aegagropilen. Upsala, 1898.
Kutzing, F. T. (1843) : Phycologia generalis, 1843.

Roth, A. W. (1797-1806) : Catalecta botanica, I— III. Lipsiae, 1797-1806.

Schmitz, F. (1879) : Beobachtungen fiber die vielkernigen Zellen der Siphonocladiaceen. Festschrift
zur Feier des hundertjahrigen Bestehens dei* Naturforscher-Gesellschaft zu Halle a. S.,
i879.

• (1882): Die Chromatophoren der Algen. Verhandl. des Naturwissensch. Vereins d.

preuss. Rheinlande u. Westfalens, 1883.

Stockmeyer, S. (1890) : Ueber die Algengattung Rhizoclonium. Verhandl. d. k.-k. zool.-botan.
Gesellsch. in Wien, 1890.

Strassburger, E. (1880) : Ueber Zellbildung und Zelltheilung im Pflanzenreiche. Jena, 1880.
Timberlake, F. G. (1901) : Starch-formation in Hydrodictyon utriculatum. Ann. Bot., vol. xv,
1901.

WiLLE, N. (1901) : Studien fiber Chlorophyceen, I-VII. Vid.-selsk. Skrifter, I. Math.-naturw.
Klasse, 1900. (Christiania, 1901.)

47&

Carter . — The Cytology of the Cladophoraceae .

DESCRIPTION OF PLATE XXVII.

Illustrating Dr. Nellie Carter’s paper on the Cytology of the Cladophoraceae.

Figs. 9-40 all x 1423.

Fig. 1. Cladophora glomerata , var. fasciculata, (Kiitz.) Brand. Transverse section of a young
segment, x 6ro.

Fig. 2. CL glomerata , var. callicoma , (Kiitz.) Rabenh. Transverse section of a young segment
in the autumn condition, the chloroplast distended with starch-grains ( st.] ). x 610.

Fig. 3- CL crispata , (Roth) Kiitz. Portion of a young segment, x 510.

Figs. 4 and 5. Cl. fracta, Kiitz. Transverse sections of young and older segments respectively.
X 810.

Fig. 6. CL glomerata , var. simplicior , Kiitz. Transverse section of a fairly old segment,
x 810.

Fig. 7. Cl. glomerata , var. callicoma , (Kiitz.) Rabenh. Longitudinal section of a young
segment in the autumn condition (st. = starch), x 610.

Fig. 8. Cl. glomerata, var. fasciculala, (Kiitz.) Brand. Transverse section of a very old segment
with the epiphytic diatom Cocconeis Pediculus. x 610.

Figs. 9-22. Rhizoclonium hieroglyphicum , (Kiitz.) Stockm. Successive stages in the division of
the nucleus. Fig. 9, resting nucleus; Figs. 10 and 11, disappearance of the nucleolus; Figs. 12-14,
formation of spireme; Fig. 15, appearance of spindle and chromosomes; Figs. 16-18, anaphase;
Figs. 19-21, telophase; Fig. 22, daughter nuclei.

Figs. 23-37. Cladophora glomerata , var. simplicior , Kiitz. Division of the nucleus. Figs. 23
and 24, resting nuclei; Figs. 25-27, disappearance of the nucleoli ; Fig. 28, formation of spireme;
Fig. 29, formation of chromosomes and spindle; Fig. 30, the spindle in end view; Figs. 31-33,
anaphase ; Figs. 34-36, telophase ; Fig. 37, daughter nuclei, the chromatin in one being not yet
entirely collected into a nucleolus.

Figs. 38-40. Cl. glomerata , var. fasciculala, (Kiitz) Brand. Abnormal nuclear division at the
anaphase stage.

cJ

\

.%> ' '

.

••

tAnncds of Botany 7

CARTER— CLADOPHOR AC EAE .

Vo i.xxxni, pi. xxvii.

Hixth, L on-don.

On the Floras of Certain Islets outlying from
Stewart Island (New Zealand).

BY

J. C. WILLIS, M.A., Sc.D., F.R.S.,

European Correspondent , Botanic Gardens , Rio de Janeiro.

With one Map in the Text.

AN interesting little paper by Poppelwell on the flora of Long Island, which
jT\. is separated by one and a half miles of water from the south-west of
Stewart Island, has called my at-

tention to further papers on the
islets which outlie from Stewart,
especially the Breakseas and So-
lan ders, the former close to the
east coast of Stewart, the latter
about thirty-five miles from the
north-west coast and rather nearer
to the South Island of New Zealand.

These papers 1 are best considered
together ; they illustrate very
clearly the extraordinary applica-
bility of age and area to the New
Zealand flora, and suggest a way
in which it may be applied even to
the flora of Great Britain, where
the effects of man’s occupation are
now so predominant.

The simplest way of dealing with the matter will probably be to first of
all arrange these little floras in parallel columns, classified for convenience as
in Cheeseman’s ‘ Flora ’.

New Zealand and outlying islands. The dotted
line is the 1,000 fathom limit.

1 Poppelwell : Notes of a’ Botanical Excursion to Long Island. Trans, and Proc. N.Z. Inst.,
xlix, 1917, p. 167.

Notes on the Plant Covering of the Breaksea Islands, l.c., xlviii, 1916, p. 246.

Cockayne: On a Collection of Plants from the Solanders, l.c., xli, 1909, p. 404.

[Annals of Botany, Vol. XXXIII. No. CXXXII. October, 1919.]

480 Willis . — On the Floras of Certain Islets outlying from

Table I.

Species in italics are peculiar to one island.

Long Island .

Breakseas.

Solanders.

CRUCIFERAE

Cardamine heterophylla

Cardamine heterophylla

—

Lepidium oleraceum

—

PITTOSPORACEAE

lJittosporum Colensoi

—

ROSACEAE

Rnbas australis

—

SAXIFRAGACEAE

Weinmannia racemosa

—

—

CRASSULACEAE

Tillaea moschata

Tillaea moschata

Tillaea moschata

DROSERACEAE

Drosera spathulata

Drosera spathulata

—

MYRTACEAE

Leptospermum scoparium

Leptospermum scoparium

—

Metrosideros lucida

Metrosideros lucida

ONAGRACEAE

Fuchsia excorticata

—

FICOIDEAE

Mesembryanthemum australe

Mesembryanthemum australe

Mesemb. austr.

Tetragonia trigyna

Tetragonia trigyna

—

UMBELLIFERAE

Ilydrocotyle Novae-Zeelandiae

—

Apium prostratum

Apium prostratum

Apium prostratum

Ligusticum intermedium

Ligusticum intermedium

Ligust. intermedium

ARALIACEAE

Aralia Lyallii

Aralia Lyallii

Aralia Lyallii

Panax Edgerleyi

Panax Edgerleyi

—

Colensoi

—

—

CORNACEAE

Griselinia littoralis

Griselinia littoralis

—

RUBIACEAE

Coprosma lucida

Coprosma lucida
* areolata

—

foetidissima

foetidissima

—

Colensoi

—

—

Nertera depressa

Nertera depressa

—

coMPOsrrAE

Olearia angustifolia

Colensoi

Olearia angustifolia

Colensoi

Olearia Colensoi

Traillii

—

arborescens

arborescens

—

Celniisia longifolia

Cotula coronopifolia (probably

—

Senecio bellidioides

introduced)

—

Senecio lautus

—

_

Senecio Stewartiae

rotundifolius

rotundifolius

rotundifolius

—

Sonchus littoralis

• —

STYLIDIACEAE

•

Donatia Novae- Zeelandiae

—

—

Oreostylidium subalatum

—

GOODENIACEAE

Selliera radicans

—

ERICACEAE

X

Gaultheria antipoda

— —

Stewart Island ( New Zealand ).

Long Island .

EPACRIDACEAE
Pentachondra pumila
Styphelia acerosa

empetrifolia

Dracophyllum longifolium
MYRSINACEAE

Suttonia chathamica

GENTIANACEAE

BORAGINACEAE
Myosotis albida
SCROPHULARIACEAE
Veronica elliptica
buxifolia

PLANTAGINACEAE

URTICACEAE
Urtica australis
ORCHIDACEAE

LILIACEAE
Phormium tenax

Cookianum
Enargea parviflora
Astelia linearis
nervosa
JUNCACEAE
Luzula campestris
RESTIONACEAE

CYPERACEAE
Scirpus aucklandicus
nodosus

Gahnia procera
Oreobolus pectinatus
st rictus
Carex lucida
trifida

GRAMINEAE
Hierochloe reddens
Microlaena avenacea
Poa foliosa
Astoni

CONIFERAE
Podocarpus ferrugineus
Dacrydium intermedium

HYMENOPHYLLACEAE

Hymenophyllum rufescens
CYATHEACEAE
Dicksonia squarrosa

Ilemitelia Smithii

Table I ( continued ).

Breakseas. Solanders.

Pentachondra pumila —

Styphelia acerosa —

Dracophyllum longifolium —

Rapanea Ui~villei —

Gentiana saxosa —

Myosotis albida Myosotis albida

Veronica elliptica Veronica elliptica

Planiago Raoulii —

Thelymitra longiflora —

uniflora Thelymitra uniflora

Microtis unifolia —

Prasophyllum Colensoi —

Pterostylis Banksii —

australis —

Caladenia bifolia —

Phormium tenax —

Cookianum —

Luzula campestris

Leptocarpus simplex —

Scirpus aucklandicus — •

Carpha ajpina - —

Gahnia procera —

Oreobolus pectinatus —

Carex lucida — >

trifida Carex trifida

Hierochloe redolens —

Poa foliosa Poa foliosa

t Astoni Astoni

Dacrydium biforme

Dicksonia squarrosa

48 2 Willis . — On the Floras of Certain Islets outlying from

Long Island.

POLYPODIACEAE
Polystichum vestitum
Asplenium obtusatum
scleroprium
lucidum
flaccidum
bulbiferum
Blechnum durum
capense
Histiopteris incisa
Pteridiitm esculenttim
Polypodium diversifolium
GLEICHENTACEAE
Gleichenia circinata
SCHTZAEACEAE
Scliizaea fistulosa
LYCOPODIACEAE
Lycopodium varium

ramulosum Lycopodium ramulosum —

It is clear, from the fact that these islands are separated from Stewart
by some breadth of water, that they must have a very old flora, older on the
whole than that of Stewart itself, especially the Solanders, which are over
thirty miles away, but are a little nearer to the South Island of New Zealand
(so that they might contain species not known in Stewart). We shall there-
fore expect all their floras to be small, especially that of the Solanders. In
actual fact, 73 species are recorded from Long Island, 69 from the Break-
seas, and 19 from the Solanders.

One will expect, just as in the more extended case of the Kermadecs,
Chathams, and Aucklands, with which this may be compared, that much of
the floras will be the same in all the islands. If we take the 19 species of
the Solanders, we find in fact that 16 of them also occur both in the Break-
seas (on the other side of Stewart) and in Long Island, one occurs in Long
Island only, and one in the Breakseas only. These two last quite probably
occur in both these islands, but have not yet been recorded, and there remains
only Senecio Stewartiae , which is also recorded for Herekopere Island in
Foveaux Strait (as near the Solanders as Stewart itself) and the Snares.

Long and Breaksea islands have much larger floras, and we find on
comparison that besides the ] 6 already mentioned which they have also in
common with the Solanders, they have 29 in common between themselves
only, making 45 in all. Long Island has 27 species not recorded from the
Breakseas, and the Breakseas 23 not recorded from Long Island. These are
printed in italics above. Glancing at the lists, it is fairly safe to say that about
a dozen at least of those given for the Breakseas only, e. g. the orchids,
ought certainly to be found also in Long Island, if it were examined at a
different period of the year. On the whole, the resemblances between the
floras of these three island groups are very striking. Poppelwell notes these
resemblances, but puts them down to similarity of conditions, a cause which

Table I ( continued ).

Breakseas. .

Solanders.

Polystichum vestitum
Asplenium obtusatum
scleioprium
lucidum
flaccidum

Blechnum durum
capense
Histiopteris incisa

Asplenium obtusatum
lucidum

Blechnum durum
Histiopteris incisa

Polypodium diversifolium

Stewart Island (. New. Zealand ). 483

in the light thrown upon geographical distribution by age and area can no
longer be accepted as sufficient to account for such phenomena.

Just as we found the flora of Stewart, as older, to be composed of the
larger (in general, older) families and genera of New Zealand proper, so here
we shall expect the flora of these islands to be composed of the larger families
and genera of the Stewart flora, and that of the Solanders especially so.
Testing this we find that of the New Zealand families 22 are above the
average in size (in New Zealand) and 69 below. Of the former 21 (95 per
cent.) occur in Stewart, of the latter only 39 (56 per cent.) Of the Stewart
families 15 are above the average (in Stewart) and 45 below. Of the former
1 3 (86 per cent.) occur in the islets, of the latter 17 (37 per cent.). Of the
islet families 9 are above the average and 21 below. Of the former 6 (66
per cent.) occur in the Solanders and of the latter 4 (19 per cent.) only. It
is thus clear that on the average a family is represented everywhere in pro-
portion to its size in the neighbouring country. We may put this in another
way, thus. The average size in New Zealand and the surrounding islands of
a family occurring there (91 fams., 1,392 species) is 15 species. The average
size in New Zealand of families occurring in Stewart is 21 species, or much
higher. The average size in New Zealand of the families that occur in the
islets now under consideration is 35 species (30 fams., 1,059 species). And
finally, the average size in New Zealand of the families occurring in the
Solanders (11 fams., 765 species) is 69 species. The figures thus form
a progressive series, showing clearly that on the whole the larger in New
Zealand a family is, the greater in the New Zealand area is its r&nge.

We shall further expect that, as usual, there will be more families in
proportion to genera, and more genera in proportion to species, the farther
out we go from the centre of New Zealand.

Table II.

Fams.

Gen.

Spp.

Gen. per fam.

Spp. per

New Zealand

91

329

1392

3*6

4 • 2

Stewart

60

l6y

383

2.8

2.2

Islets

30

56

98

1.8

i*7

Solanders

11

13

15

1. 1

1. 1

The prediction is fully borne out.

As one goes outward from New Zealand in this way, the plants will on
the average become steadily older, so that one will expect to find the pro-
portion in common with the outlying islands (Kermadecs, Chathams, Auck-
lands), which also have old floras, steadily increasing. Testing this gives

Table III.

Occur in Reach K., Ch ., or Au. %.

New Zealand, 1301

199

* 5

Stewart, 383

Jr3

40

53

Islets, 98

Solanders, 1 5

52

9

60

484

Willis,* — On the Floras of Certain Islets .

Again a steadily increasing percentage, bearing out the prediction.
Further, one will expect the proportion of wides, which on the whole
are older, to increase relatively to that of endemics as one goes outwards
from New Zealand to the Solanders.

Table IV.

Occur in

Wides,

Endemic ( N.Z .

New Zealand

301 or 23 %

1000

Stewart

129 or 34 %

240

Islets

2 1 or 35 %

49

Solanders

6 or 40 %

9

If the ferns be included, the result is more clearly marked.

It is thus clear that for restricted areas like New Zealand and its neigh-
bouring islands age and area can be relied upon to explain the general
composition of any of the floras that occur ; and in our next paper we shall
go somewhat farther afield, endeavouring to trace the invasions of New
Zealand from Indo-Malaya.

Some Observations on the Tuber of Phylloglossum.

BY

T. G. B. OSBORN.

With Plate XXVIII and forty-three Figures in the Text.

WHEN, towards the end of the growing season 1917- the opportunity
offered to study Phylloglossum Drummondii in the field near Adelaide,
it was felt that some observations of interest might be made upon the
ecology of the plant, with special reference to the behaviour of the tuber as
an organ of perennation. The scope of the inquiry was unexpectedly
extended by the discovery that accidentally damaged or detached leaves
might themselves form new tubers as they lay upon the soil near naturally
growing plants. A series of observations was therefore made during the
growing season (May to October) 1918, the results of which are also given
here. Without wishing at this stage to reopen a discussion as to the
morphology of Phylloglossum Drummondii , it is felt that the facts now
presented throw some light on the nature of the tuber that is of importance
in considering its morphology.

Field Observations on Phylloglossum.

The external morphology of Phylloglossum has been so many times
described that a further account might be deemed superfluous. In the
present paper, the tuber, formed the previous season, from which arise the
stem, leaves, roots, and strobilus (should one be produced), and which is
consequently in process of exhaustion, is termed the ; current tuber \1

The term ‘ old tuber , is restricted to those of previous years, which
may be found in the soil beside growing plants.2 These may throw a light
upon the past history of the plant near which they are found.

On the Depth of Tuber Formation — Descriptive.

On examining any large number of plants of Phylloglossum collected
towards the end of their growing season, the two tubers are usually observed
side by side at about the same depth below the ground-level. Unlike the

1 Wernham, H. F. (1910) : Ann. Bot., xxiv, p. 335.

2 Thomas, A. P. W. (1902): Proc. Roy. Soc., London, lxix, p. 288.

[Annals of Botany, Vol. XXXIII. No. CXXXII. October, 1919.]

N n

486 Osborn. — Some Observations on the Tuber of Phylloglossum.

perennating organs of many geophytes, these two structures, products of
successive seasons’ activities, are not directly connected. The new tuber is
linked to the current one only by its stalk, which is given off from the
stem of the plant usually some distance above the current tuber. Clearly,
then, the new tuber is produced sunken in the soil because of the downward
growth of its stalk. Whilst the growth is usually of such an amount as to
cause the two tubers to lie side by side, this is by no means always the
case.

Not infrequently plants are found in the condition shown in Text-fig. 1.
Here the new tuber is produced at the end of a relatively short stalk, and is

Text-fig. i. Four-leaved sterile plant showing current tuber buried about 18 mm. New
tuber formed on short stalk at shallower depth (Oct. 1917). x 3^.

Text-fig. 2. Two-leaved sterile plant with current tuber 4 mm. below ground-level. New
tuber formed on long stalk. Sunken about 11 mm. (Oct. 1917). x 3|.

Text-fig. 3. Single-leaved plant with current tuber partially exposed. New tuber as yet
scarcely swollen, but sunken to 7 mm. (Sept. 14, 1918). x 3|.

thus placed vertically in the soil several millimetres nearer the surface than
the current tuber.

Or again, specimens may be found in which the current tuber lies just
below the surface of the soil (Text-fig. 2) or even partially exposed (Text-
fig. 3). Here the new tuber is produced at the end of a relatively long

Osborn.— Some Observations on the Tnber of Phy l l og l os sum. 487

stalk, hence it may be buried in the soil two or three times its own length
deeper than the current tuber.1

The examination of any considerable number of plants collected at one
time from the same locality shows that the depth at which the new tuber
is formed in the soil in relation to ground-level is not a matter of chance,
but is the result of definite growth of the plant producing it. If, for any
reason, the current tuber is buried by deposition of more soil above it, the
burial is compensated for by the development of a short stalk bearing the
new tuber. Conversely, if, by removal of surface soil, the current tuber is
brought near to the surface, the new tuber is sunken to a greater depth.

There are two sets of climatic conditions that tend to produce an
alteration of the ground-level in the area where Phylloglossum has been
studied near Adelaide.2 In the wet season (April to October) or during
periods of heavy precipitation, which occasionally occur in the summer,
there is, owing to local irregularities in the ground, a flow of water over the
surface in many places. This causes a removal of soil from some areas and
its consequent deposition over others. Since the ground over the greater
part of the area is almost flat, the amount of change in level is slight ; but
very slight changes have a considerable effect on such a minute plant.

On the other hand, during the dry season, when for weeks together the
surface layers of the soil are desiccated, atmospheric denudation causes
similar slight changes in ground-level. Such variations may not exceed
a few millimetres rise or fall, but they influence to a marked degree a plant
whose total length from tip of leaf to base of tuber may be less than 3 cm.
and the optimum depth for whose tuber lies between 10 and 12 mm.

On the Depth of Tuber Formation — Statistical.

In order to gain a clear idea of the depths at which the tubers of
a number of Phylloglossum plants taken from any area may occur, three
typical groups of plants were selected in October (i. e. near the close of the
growing season) and a sod of soil some 10 cm. square cut from each. The
three sods were carefully removed to the laboratory, where every plant was
dissected out. Two measurements were then made upon each plant, viz.
the maximum depths of the current and new tubers. The points of
measurement selected were the ground-level (usually sharply defined by the
development of chlorophyll) and the deepest point of the tuber. It was
found desirable to include the length of the tuber in the measurement in
order to avoid minus quantities when the tuber was partly exposed, and also
because the distal end of the tuber is well defined while the proximal end
passes gradually into the stalk.

1 Bertrand’s figure of Phylloglossum reproduced in Campbell, D. H., Mosses and Ferns,
p. 501, Fig. 290 A, shows this condition, but to a less extreme degree than either of the plants figured
above. I regret I have not been able to consult a copy of Bertrand’s memoir in Australia.

2 Osborn, T. G. B. (1918) : Trans. Roy. Soc., S. Aus., xlii, p. 7.

N n 2

488 Osborn. — Some Observations on the Tuber of Phylloglossum.

In all 1 86 plants were obtained from the 300 sq. cm. (approx.) of soil.
The figures obtained are surprising in the close way they agree with the
result that field observations had indicated.

Text-fig. 4. Graph showing variation in depth of current and new tubers on 1S6 plants col-
lected from (approx.) 300 sq. cm. soil (Oct. 1917).

Phylloglossum Drummondii , 186 plants from 300 sq. cm. soil.

Depth of tubers in mm.

Current. Neiv.

Average

io-5' io-6

Minimum

1 6

Maximum

20 15

Mean

10.5 10.5

The graphic representation of the results shown in Text-fig. 4 is
specially interesting. The depths of the current tubers give a very irregular
flat curve with the mode at 11-5 mm. but with secondary maxima at 8 mm.
and 14 mm. The depths of the new tubers, on the other hand, give an
almost symmetrical curve about the mode at 10 mm. The curve, moreover,
is a steep one, over 80 per cent, of the individuals falling between 9 mm.
and 12 mm.

On the Direction of Growth by the New Tuber.

At this stage it may be well to record an observation that bears on the
factors determining the direction of growth by the new tuber. The new
tuber has always been found upright in the soil, its long axis being vertical.
This suggests that gravity is the determining factor in the direction of
growth. In compensating for excessive depth at which the current tuber
may have been buried, the new tuber never grows erect or even hori-
zontally. A shallower depth is attained merely by the slight amount of
elongation made by the new tuber stalk. The flexure made by this stalk
is always sharply downwards. Since the point upon the stem from which
the new tuber arises is apparently determined by morphological reasons
(this is certainly so in the case of sterile plants),1 it may happen that when

1 Bower, F. O. (1886),: Phil, Trans., clxxvi, p. 669.

Osborn . — Some Observations on the Tuber of Phyllog lossum. 489

the current tuber is very deeply sunken the plant cannot in one season
adjust the new tuber to the normal or average depth. Thus two plants
having the current tuber buried to 30 mm. produced their new tubers at
1 5 mm. and 14 mm. respectively. Assuming no change occurred in the
ground-level, the new tubers of the ensuing season would also be on short
stalks ; thus two, or even three, seasons might pass before the average
depth was established.

An example of the influence of gravity upon the direction of growth of
the new tuber stalk was furnished by a plant growing in the laboratory.
In cutting a sod of soil, to be kept moist under a bell-glass for experimental
purposes, the trowel accidentally exposed, without damaging, the new tuber
stalk of a five-leaved sterile plant. The stalk at that date (July 31, 1918)
was still short, the apex unswollen. It continued to grow, exposed
to light, descending vertically through 19 mm. before it buried itself in the
silt at the bottom of the dish (October 21, 1918). The growth here was
clearly geotropic. Light had no influence upon it, for the stalk, though it
developed chlorophyll throughout its whole exposed surface, made no
phototropic response. This observation is of some importance when con-
sidering the behaviour of tubers produced by detached leaves.

On the Rate of Development of Fhylloglossum in
Successive Seasons.

The sporeling of Phylloglossum described by Thomas1 is single leaved
and rootless 2 in the first season of its growth. The number of leaves may
be assumed to increase from year to year as successive seasons’ activities
allow more starch to accumulate in the new tubers.3 Thomas records that
the further development of the sporophyte appears to be slow. ‘ In many
cases the plant comes up a second and third year with only a single leaf.’
This he determined by carefully dissecting plants from the soil, and so
finding the remains of former years’ tubers and roots.4

After a little practice it was found possible to remove the remains of
the old tubers, together with the plant to which they belonged, without
disturbing their relative position one to the other. Text-fig. 5 shows
a single-leaved plant collected about a month after the first winter rains.
The root is hardly developed and no new tuber is visible at this date, but,
in addition to the current tuber, the decaying remains of the tubers formed

1 Loc. cit., p. 288.

2 Sampson, K. (1916) : Ann. Bot., xxx, p. 605. The sporeling described by Miss Sampson
was also single leaved, but had a slender root.

3 The number of leaves in any season, of course, is not determined until after germination of the
tuber. Bovver, F. O. (1886) : loc. cit , p. 667.

4 Loc. cit., p. 288.

490 Osborn. — Some Observations on the Tuber of Phylloglossum.

in two previous years are visible. Such a single-leaved plant is entering on
at least the fourth season of its growth.

Text-figs. 6 and 7 show plants of two and three leaves respectively.
In Text-fig. 6 three old tuber coats are to be seen. These lie just below
the surface of the soil, the current tuber being several millimetres deeper.
The past history of this plant, as shown by its old tuber coats, affords
a further example of the depth adjustment referred to above. The plant
was collected July 1918 ; the current tuber, therefore, had been formed in
the 1917 growing season. That year, the then current tuber, now O.T.j,
lay close below the surface of the soil, so that the plant produced its new
tuber, C.T. in the figure, at the end of an elongate stalk. Evidently the

Text-fig. 5. Single-leaved plant with current tuber c.T. and two old season’s coats O.T., and
0.t.2. This plant is entering on the fourth season of growth. At this date the root is short and no new
tuber visible (June 13, 1918). x 3|.

Text-fig. 6. Two-leaved plant with current tuber c.T. at 11 mm. depth, new tuber n.t. just
forming. Coats of three previous seasons’ tubers (o.t.x, 0.t.2, o.t.s) are just below ground-level,
showing depth adjustment in 1917 (July n, 1918). x 3^.

Text-fig. 7. Three-leaved plant with current tuber c.T. at 9 mm. depth. Old tuber coats (o.t.,
&c.) of four previous seasons at shallower depth (July 11, 1918). x

lowering of the ground-level occurred some time subsequent to the 1916
growing season, for lying at the same depth as O.T.j are 0.T.2 and 0.T.3,
tubers of two previous seasons.

Around another plant no less than four old tuber coats were found
(Text-fig. 7), all lying above the current tuber, again demonstrating the
burial of the perennating organ to a safe depth. This plant, though it
possesses but three leaves, was entering on at least the sixth year of its
growth.

Such examples illustrate Thomas’s observation on the slow rate at
which the sporophyte develops. They also show to a slight extent the
precarious existence led by the Phylloglosstmi in some areas, as it seesaws

Osborn.— Some Observations on the Tuber of Phylloglossum. 491

in the ground, threatened by burial or desiccation, as a result of theedaphic
and climatic conditions under which it grows. Development is by no
means always a steady progress in which, through successive seasons, the
tuber gradually attains a maximum size. In cases where considerable
depth adjustment has to be made, or where the early onset of the dry
season brings vegetation to a standstill,1 the new tuber formed may be
smaller in size than that from which the plant producing it was derived.

Production of Tubers by Leaves.

Field Observations 1917.

In 1917, when dissecting plants of Phylloglossum from the soil for the
statistical investigation above, a specimen was found which at first could
not be interpreted. A small green leaf-like structure was found lying in the
soil (Text-fig. 8), pointed at one end, the other terminating bluntly, smooth,
and rounded. When removed from the soil it was found that this blunt
end had a colourless cylindrical prolongation, nearly as long as the aerial
portion of the structure, descending vertically into the ground. Its apex
showed a minute white spot, and resembled the apices of young tuber
stalks of Phylloglossum . In the angle made by the two portions a few
colourless rhizoids were developed.

When searching for similar structures the leaf shown in Text-fig. 9 A was
found. This was obviously a detached leaf of Phylloglossum, but near its
proximal end a slight swelling of adventitious tissue had developed on the
side next the soil. Such a pad of adventitious tissue, which in the follow-
ing pages will be termed the ‘ cell mass ’ for convenience of reference, has
been invariably observed as a preliminary development in growth from
detached leaves of Phylloglossum . Further search yielded two similar leaves,
Text-figs. 10 and 3 1 A, also a third, in which, however, the cell mass was
better developed (Text-figs. 12 A, B, and C). This last leaf was somewhat
curved and lay upon the soil with its proximal end slightly elevated. It
had produced laterally, from the convex side, a cell mass about 2 mm. long ;
this was swollen irregularly at the farther end and was partly embedded in
the soil. The cell mass was green where exposed to the light, while from
the lower side of the swollen end rhizoids were produced. From the under
surface of this swelling a colourless, almost cylindrical process descended
into the soil.

It now became apparent that detached leaves of Phylloglossum were
capable of producing, after more or less adventitious growth resulting in
a cell mass, a structure resembling the stalk of a tuber, such as the plant
normally forms each growing season. The structure shown in Text-fig. 8

1 See p. 508, for rainfall record at Belair, S.A., near which township Phylloglossum has been
studied. In 1915 only 1-37 in. of rain fell during the last three months of the year.

49 2 Osborn — Some Observations on the Tuber of Phyllogiossum.

Osborn . — Some Observations on the Tuber of Phylloglossum . 493

was evidently such a leaf on which the cell mass was small in size, but had
almost obliterated the scar formed when the leaf was detached. This scar,
somewhat exaggerated in the figure, was so minute that it was not recog-
nized when first examining the leaf.

Two further plants of interest were found in the field that season. One,
a single-leaved plant, had suffered an injury about 1 mm. above the soil.
The leaf was broken through and lay along the soil, but was not actually
detached. The wounded surface had healed over, and a new tuber was
forming normally (Text-fig. 13). The broken leaf, however, had not died,
but was turgid and green beyond the zone of injured tissue. It had, more-
over, begun to form a cell mass upon the lower surface. The second plant
was a three-leaved one, one leaf of which had been broken and lay along the
soil. Again the wound had healed on both sides of the injury, and the
damaged leaf had developed a cell mass near to the proximal end, from the
surface of which several rhizoids arose (Text-fig. 14).

The growing season for Phylloglossum was almost over in 1917 when
these observations were made, so that experimental work was impossible.
The two leaves shown in Text-figs. 9 A and 11 A, however, were laid upon
soil from the locality in which they had been found, placed in a Petri dish,
and kept moist in the laboratory. After about seven weeks it became
necessary to stop the experiment as the leaves were beginning to decay.
That shown in Text-fig. 9 A had developed a further swelling, irregularly
spherical, closely connected with the first (Text-fig. 9 B). The new swelling
was opaque, white, and bore short rhizoids. The other leaf (Text-fig. 1 1 A)
showed an unexpected development. No stalk-like structure had formed,
but the original cell mass was considerably enlarged (Text-fig. 1 1 B), and
a minute green leaf-like scale (/) had developed.

Experimental Development, 1918.

In 1918 five series of experiments upon the production of tubers by
detached leaves were carried out in the laboratory, the results of which are
here given in tabular form, and are further discussed below.

Series

Letter.

Date Expt.
started .

No. of
Leaves.

No. formed
single tuber.

No. formed
single cell
mass. .

No. formed
several cell
masses.

No. died of)
without apparent
growth.

A.

13. VI

8

1

(1)

6

—

B.

ir. VII

8

7

1*

—

—

C.

21. VII

10

5t ( + 3)

(D

i§

—

D.

21. VII

10

1

I* (+ 2)

1

5

E.

13. IX

12

—

5

. —

7

48

14 ( + 3)

7 ( + 4)

8

12

f In one of these cases two tubers formed (Fig. 18 d).

* Leaf died off before experiment finished.

§ Developed two ‘ leaflets ’ only.

The numbers in brackets refer to leaves fixed for microtoming before fully developed.

494 Osborn . — Some Observations on the Ttiber of Phylloglossum .

Experimental work was confined to the laboratory for convenience of
examination, and because of the uncertainty of the season. The 1917
growing season was a wet one,1 especially during the critical months
September-October, when most active growth in tuber-production occurs.
In 1916 also there had been more than average rainfall, but there was no
reason to expect a continuance of the conditions in 1918, as indeed proved
to be the case. In the different experiments the aim was usually not so
much to reproduce the conditions of humidity that obtain in the field, as to
maintain a constant moisture. It is not suggested that an atmosphere so
near saturation would be maintained in the field for long together, though

in some years, e.g. 1916, a high rain-
fall occurred during the last three
months of the year, and conditions
might remain favourable to tuber pro-
duction over considerable periods.

In each experiment freshly de-
tached leaves were laid on soil from
the locality, kept moist and covered
by glass. In the first experiment the
soil was lightly tamped down in a
Petri dish, but in the subsequent series
a sod several centimetres square in
which Phylloglossu m plants were grow-
ing was used. This method was more
successful, as will be seen from Series B
and C, in which 8 and 10 leaves gave
respectively 7 and 8 positive results,
but the first method gave a valuable
series of abnormalities, discussed later.

In addition to the five series of
experiments, odd leaves were injured
but not detached from plants kept in
the laboratory, the object being to
repeat the conditions under which such plants as those shown in Text-figs.
13 and 14 grew. Text-fig. 15 shows the result of such an experiment. One
of the three leaves of a plant growing undisturbed in a sod of soil was
severely injured but not detached. The plant was dug up and sketched
after nearly four months’ growth. It had formed a new tuber in the normal
way, and the injured leaf, too, had produced a tuber sunken on a short
dropper below the surface of the soil. Text-fig. 15 should be compared
with Text- fig. 14, which shows a plant collected in the field. The results
are closely similar, except that in the experiment the leaf-borne tuber had

1 See p. 508 below.

Fig. 15. Three-leaved plant grown in
laboratory. One leaf, injured July 17, 1918,
has developed an adventitious tuber. * Marks
the wounded surfaces which are contiguous in
specimen (Nov. 10, 1918). x 3J.

Osborn.— Some Observations on the Tuber of Phylloglossum. 495

almost reached maturity, while in Text-fig.’ 14 the cell- mass stage only had
been attained by the injured leaf.

An attempt to effect regeneration from portions of cone peduncles
gave a negative result. The fragments, about 1 cm. long, were laid (July
21) on the same sod of soil as the leaves of Series C. They remained
green and turgid for over two months, but early in October began to look
unhealthy. On October 21 one only was noticed to have formed a minute
swelling near the middle on the upper side, but this peduncle fragment,
like the others, had completely collapsed by the end of the month. It is
remarkable, as will be seen below, for what length of time a broken frag-
ment of Phylloglossum will remain green and apparently healthy on damp
soil. On the other hand, once decay sets in it is very rapid, and in a day
or two, since there is no hard tissue in the plant, little but the cuticle
is left.

(i) Series B.

It will be convenient to consider this series first in some degree of
detail, since it gave a high percentage of positive results.

On July 11, 1918, a sod of soil containing many Phylloglossum plants
was brought into the laboratory and placed in a glass dish. Eight leaves
were broken off various well-developed plants growing in it and laid on the
soil. The dish was covered and placed in the strong diffuse light of a south
window.

During the first month no growth was apparent ; the leaves remained
turgid and green, the only visible change being a curving of some of the
leaves in the vertical plane. This curving, however, was much less apparent
than in some of the other series, especially A.

I was unavoidably absent from the laboratory for the fortnight
August 15 to 31. Before leaving, the leaves of this and the other series
were examined under a hand-lens and the note made that none showed any
growth. It was feared that all the experiments were failures (Series A
had then been running for two months without apparent result). However,
every leaf appeared healthy, turgid, and almost as bright green as when first
laid upon the soil.

Returning to Adelaide, it was surprising to find, on August 31, that
every leaf of the series showed a distinct protuberance at or near the
proximal end (Text-figs. 16-22). Three of the leaves were still lying hori-
zontally ; two had the proximal end slightly elevated ; the three others were
curved crescent-wise with both ends elevated.

The development after this date was comparatively rapid. On
September 16 four of the leaves were removed, sketched under the dissect-
ing microscope, and carefully replaced in their original positions (Text-figs.
16 A, 17 A, 18 a, and 19 a). They all showed irregular, greenish-yellow cell

496 Osborn . — Some Observations on the Tuber of Pkylloglossum.

Osborn . — Some Observations on the Tuber of Phylloglossum, 497

masses. In one case (Text-fig. 16 a) this was all the development visible,
but two of the others (Text-figs. 17 A and 18 A) showed in addition a minute
white conical projection, arising from the cell mass and growing vertically
into the soil. In one case (Text-fig. 18 a) rhizoids were visible arising from
the cell mass close to the leaf. The fourth leaf (Text-fig. 19 a) showed
a comparatively small cell mass, but from it there descended a cylindrical
process, 2 to 3 mm. long, that terminated below the soil in a blunt apex.
The structure resembled the stalk from which the new tuber of a Phyllo-
glossum plant arises.

By September 24 the leaf shown in Text-fig. 17 A had made further
growth, the growing-point observed upon it having given rise to a descend-
ing shaft. It was sketched (Text- fig. 17B) and fixed for microtoming. At
the same time it was noticed that the leaf shown in Text-fig. 18 A showed
two new features. First, the growing-point, already observed upon it, was
distinctly bilobed ; second, from the upper surface of the cell mass, a minute
green leaf-like process was emerging (Text-fig. 18 B). The further history of
this leaf is shown in Text-figs. 18 c and D, drawn October 8 and November 16
respectively.. The green process developed into a slender ‘ leaflet ’ 4-5 mm.
long, whilst each growing apex developed a white tuberous body at the end
of a short stalk.

On October 8 two other leaves were found to have developed leafy
processes, one of which is shown in Text-fig. 20 a. The figure also serves
to indicate the extent of tuber formation by this date. There is a distinct
stalk which carries the growing-point into the soil. The growing-point is
swollen and whitish, but as yet quite smooth. The cell mass and such
portions of the stalk as are exposed to the light are green. The presence
of rhizoids upon the cell mass was found to be inconstant at this stage.
Sometimes they could be distinguished, but more often they were absent.
This, however, may have been due to injury, though every care was exer-
cised in removing leaves for observation. Later, as will be seen, the tuber
develops many rhizoids.

On October 19 one leaf of the series, that had previously been
observed to be changing to a dull watery green, was quite collapsed. It

DESCRIPTION OF FIGS. ON OPPOSITE PAGE.

Text-figs. 16-22. Leaves of Series B, detached and put on soil July it, 1918. The dates below
in brackets are those on which the figures were drawn. All x 5J. Pig. 16 A. Cell mass forming
(Sept. 16). Fig. 16 b. Same with adventitious tuber (Nov. 16). Fig. 17 a. Growing-point just visible
on cell mass (Sept. 16). Fig. 17 B. Same, showing elongation of stalk (Sept. 24). Fig. 18 a. Cell
mass with rhizoids and short stalk bearing growing-point (Sept. 16). Fig. 18 B. Same developing
two growing-points from cell mass, also ‘leaflet’ (Sept. 26). Fig. 18 C. ‘Leaflet’ enlarged, two
tubers forming (Oct. 8). Pig. 18 D. Same; tubers are smaller and less regular than those formed
singly by other leaves of the same series. Rhizoids absent (Nov. 16). Fig. 19 a. Small cell mass,
stalk, and growing-point (Sept. 16). Pig. 19 b. Same (Nov. 16). Fig. 20 a. Portion of leaf showing
celf mass. Leaflet stalk and tubers beginning toi swell. No rhizoids at this date (Oct. 8). Fig. 20 b.
Same original leaf beginning to rot (Nov. 16). Fig. 21 and 22. Two remaining leaves of series (Nov. 16).

49 8 Osborn. — Some Observatio?is on the Tuber of Phy Hog l os sum.

was too rotten to remove for sketching, but, on examination, a white
rounded body, barely 2 mm. in diameter, was found on the under side near
the proximal end of the leaf. This was the only failure in the series, and
it was not a completely negative result.

By November 16 it was found necessary to stop the experiment, and
the remaining six leaves were all sketched before fixing. At this date the
original leaves were yellowed, and though they still retained their shape
they were found to be mere hollow shells, the mesophyll being quite
collapsed. The leaflets also were yellowing, but the cell mass appeared
turgid and green. Text-fig. 18 D shows that the two tubers developed
from the single leaf were without any rhizoids. These tubers were opaque
and white, but smaller and less regular than those formed singly by the
other leaves. The remaining five leaves (Text-figs. 16 D, 19 B, 20 B, 21, and
22) all showed tubers, borne at the end of more or less elongate stalks,
externally resembling the tubers normally produced by Phylloglossum
plants, and having the usual abundant development of rhizoids that
characterizes the later stages of tuber growth. In most cases (Text-figs.
16 B, 20 B, 21, and 22) the tuber was sunken for less than 4 mm. below the
surface of the soil. In Text-fig. 19 B the stalk is seen to be much longer.
As will have been noticed from Text-fig. 19 A, this leaf showed quite early
in the experiment a pronounced upturning of the ends, so that it rested
upon the soil by a small portion of its surface only. The resistance offered
by the soil to the downward growth of the stalk caused the proximal end
to be still further elevated, thus the stalk became unusually elongated.

(ii) Series C.

On July 21 ten leaves were broken off plants of Phylloglossum g rowing
in a sod of soil as before, and laid horizontally upon it. In this experiment
the sod was placed in a large china developing dish and covered with
apiece of plate-glass, in order to secure better illumination. Under these
conditions the atmosphere was at a less constant humidity than in Series B,
for the glass plate did not fit tightly. While care was taken to prevent the
soil drying up, no precautions were taken to keep it constantly damp, for it
was felt that by allowing drier periods to alternate with wet ones, field
conditions would be more closely reproduced.

It is unnecessary to describe the results in detail. The leaves, as in
Series B, showed no visible change other than curving until after August 1 5.
By August 31 several were noticed to be forming cell masses near the
proximal end, and one was removed for microtoming. It then showed an
irregular nodular swelling, yellowish in colour (Text-fig. 23). Three other
leaves were removed early in October. Two of these showed irregular cell
masses, from the bases of which white growing apices were projecting.

Osborn. — Some Observations on the Tuber of Phy 1 1 oglossu m . 499

These subsequently proved to be the growing-point in process of invagina-
tion.1 The third leaf showed signs of damping off, but it had a short stalk
bearing a slightly swollen tuber, enclosed in which the growing-point could
be discerned. No rhizoids were present at this stage. All the others
appeared healthy, but showed, with one exception, little development above
ground. The exception had two ‘ leaflets1 about 4 mm. long, one arising
on each side of the leaf and springing from the lower side. Unfortunately,
when examined three or four days later, this leaf had collapsed too much to
draw. Each leaflet appeared to be attached directly to the main leaf, with
no noticeable swelling on or beneath the surface of the soil.

Text-figs. 23-29. Leaves of various series. The dates below in brackets are those on which
the various figures were drawn. Allx5^. Fig. 23. Leaf of Ser. C. The cell mass is nodulose;
a T.S. of this leaf is seen Fig. 38 (Sept. 24). Fig. 24 a and b. Leaf of Ser. C. This leaf curved
on soil in horizontal plane. Adventitious growth from convex side (Nov. 16). Fig. 25. Leaf ot
Ser. D. Note absence of definite growing-point, and formation of many starchy cell masses
(Oct. 21). Figs. 26-29. Leaves of Ser. E; for further explanation see text (Nov. 25).

By November 16, almost four months after the experiment was started,
the remaining leaves were seen to be yellowing rapidly. They seemed to
be mere hollow shells for the greater part of their length, and collapsed
when lifted. The base of the leaf, however, was still green, as was the
small cell mass. The leaves were all curved, four with their apices erect ;
the fifth lay curved C-shaped on the soil. In this case also the adventitious
growth was from the convex side and so placed that the cell mass originally
would not have been in direct contact with the soil (Text-fig. 34 A and B).
Each of the leaves had developed a short stalk bearing a tuber, on which
rhizoids were just appearing.

See p. 504 below.

500 Osborn. — - Some Observations on the Tuber of Phylloglossum.

(iii) Series D.

This series was grown on a similar sod of soil to Series C and in the
same dish. It was, however, much less successful. The leaves were often
buried by the castings of small animals or overgrown by Bryophytes. Two
leaves fixed early in October presented a similar appearance to that shown
in Text-fig. 23. By the end of the month six of the remainder had damped
off. Only one of these showed any adventitious growth, a whitish swelling
about 1 mm. in diameter near the proximal end on the lower side. The
last two leaves were fixed at the end of November, when one showed
a dropper, the apex of which was hardly swollen. The other had a series
of nodular swellings extending almost around the leaf near the cut surface ;
several of these appeared white, like minute tubers (Text-fig. 25).

It is difficult to account for the comparative failure of this series, unless
it were due to competition with various organisms.

(iv) Series E .

This series was not started until September 13, when twelve leaves
were laid on soil in a glass dish as above. Three of these collapsed in
about a fortnight, and five others before the end of November. Of the
remaining four, three (Text-figs. 26-28) each formed a small irregular cell
mass near the distal end. Two of these (Text-figs. 26 and 28) produced
• leaflets \ and all showed rhizoids, but no dropper was developed. The cell
masses themselves appeared opaque white, like resting tubers. The fourth
leaf (Text-fig. 29) only produced a minute white structure about 1 mm.
diameter. This swelling was developed from the surface of the leaf remote
from the soil.

(v) Series A.

The consideration of this series has been postponed until the other
experiments had been described, because, of the eight leaves used, only one
formed a single tuber (Text-fig. 30) in the manner described above. All
the remainder produced abnormalities.

As has been explained, the conditions of the experiment were slightly
different, in that soil from the locality in which Phylloglossum was growing
was placed in a Petri dish and lightly tamped down, instead of using an
undisturbed sod. Water was sprayed over the soil from time to time to
keep it moist. Though the experiment was begun on June J 3, nearly
a month before any other series, no development occurred until the latter
end of August, by which date all other series also showed growth. The
only noticeable feature displayed by the leaves during the first two months
was the remarkable curving exhibited by them. With a single exception,
in which case the leaf lay flat along the soil throughout the five months the

Osborn.— Some Observations on the Tuber of Phyltoglossum . 501

experiment lasted, all the leaves early began to curl upwards, becoming J-
or U-shaped as one or both ends were elevated.

The curling was not due to the effect of light, for frequently the
proximal end was elevated, whilst the apex showed no response. It was
noticed that in dry weather the leaves of plants growing in the field might
show a marked incurving of their tips. It therefore appeared probable that
the curving was due to some alteration in the turgidity of the leaf. This
point is further discussed later (p. 510).

By August 31 all the leaves* showed more or less adventitious growth
near the proximal end. Most of the cell masses were lifted above the soil
owing to the curvature of the leaf. All of them had an irregular contour.
The appearance about this date is shown in Text-figs. 31 and 32 A, drawn
September 16. As it was feared that the cell masses might dry up because
of the elevation of the proximal ends, some of the leaves were laid flat upon
the soil. On October 21 the leaf shown in Text-fig. 32 A was sketched
again (Text-fig. 32 B). It will be seen that the cell mass now showed
distinct scattered nodules. These were green, no white growing-point
being seen.

By the middle of November it was necessary to stop the experiment.
Only one leaf (Text-fig. 30), that which lay horizontally, showed a single
tuber resembling those formed in the other series. Text-fig. 32 C shows
the condition of the leaf drawn in Text-figs. 32 A and B. The nodular
growths noticed before had most of them elongated to form minute stalks
terminating in slightly swollen- white heads. Text-fig. 33 A shows another
leaf viewed from above. The cell mass is seen to be near the proximal
end, but on the convex side of the curved leaf. Stalklets bearing small
white heads are visible. Viewed from the side (Text-fig. 33 b) it is seen
that these minute tuber structures, developed irregularly over the cell mass,
are markedly geotropic in their growth, though several of the stalks were
not sufficiently elongated to bury their apices. The leaf shown in Text-
fig. 34 A (also drawn from above) had its apex erect. From the under
surface of this (Text-fig. 34 B) many irregular white nodular structures of
various sizes were developed.

The leaf shown in Text-fig. 35 is interesting. In this case the
adventitious cell masses were scattered over a greater length of leaf
than is usual. The majority of them merely developed short stalks in the
white swollen heads. Two of the growths, however, developed leaflets as
well as descending portions. By November 17 the original leaf was
obviously dying off, so that it was necessary to fix it, and further develop-
ment could not be followed. It will be noticed, however, that each leaflet-
bearing structure resembles that shown in Text- fig. 20 A, but at an earlier
stage.

O o

502 Osborn. — Some Observations on the Tuber of Pkylloglosstim.

Text-figs. 30-35. Leaves of Series A, detached and put on soil, June 13, 1918. The dates
below in brackets are those on which the figures were drawn. All x 5J. Fig. 30. Adventitious tuber
arising from side (Nov. 16). Fig. 31. Extreme case of leaf curvature in vertical plane. Cell mass
nodular (Sept. 16). Fig. 32 a. Leaf showing vertical curvature. This leaf appears to be an
exception to rule that adventitious growth occurs from convex surface (Sept. 16). Fig. 32 B. Same,
viewed from above ; note nodular development of cell mass. This leaf was laid flat on soil Sept. 16
(Oct. 21). Fig. 32 c. Same; note many short-stalked, white, swollen bodies (Nov. 27). Fig. 33 a.
Leaf viewed from above, and B, viewed from side, showing geotropic curvature of the many minute,
stalked tubers (Nov. 27). Fig. 34 A. Leaf viewed from above, and B, viewed from below (Nov. 26).
Fig- 35- Portion of leaf, viewed from side, with several scattered centres of adventitious growth.
Two have developed leaflets and small tubers (Nov. 17).

Developmental History.

The first stage in adventitious tuber formation is the development of
a pad of tissue or cell mass, projecting from the epidermis, at or near the
proximal end of the detached leaf. This projection is due to the activity
of certain epidermal cells ; usually several are involved, but it would appear

Osborn. — Some Observations on the Tuber of Phyllog lossum. 503

from those abnormal cases in which a number of minute tuberous bodies is
formed (e. g. Series A) that each may arise from the activity of a single
epidermal cell (Text-fig. 36).

The epidermal cells, which are considerably elongated in the direction

Text-fig. 36. Portion of transverse section of leaf showing adventitious growth from single
epidermal cell. Stomate seen to left, x 180.

Text-fig. 37. Transverse section of leaf showing considerable cell mass of epidermal origin,
interrupted by stomate at St. Growth is becoming localized by development of growing-point
seen at right, x 44.

Text-fig. 38. Transverse section of leaf (see Fig. 23). Two growing-points are developing;
the anticlinal walls separating the groups of epidermal cells involved are plainly seen, x 44.

Text-fig. 39. Portion of longitudinal section showing junction of leaf tissue and cell mass
showing epidermal origin of latter. Cell mass developed stalk in which a ‘ tracheide ' is seen.
X44.

of the leaf axis, first divide transversely, and at the same time the seg-
mented cells enlarge in a radial direction. The radial elongation is accom-
panied by periclinal division.

O O 2,

504 Osborn. — Some Observations on the Tuber of Phylloglossum.

The evenness of contour of the cell mass thus produced depends on
how nearly equal the stimulus to division has been in neighbouring cells, and
upon the absence of stomates from the proliferating area (Text- fig. 37 and
PI. XXVIII, Photo 1). In Text-fig. 38 and Photo 2 it is obvious that growth
has been less regular, the boundary between original groups of epidermal
cells being clearly shown by anticlinal planes of division, extending for as
many as eight or nine cell rows. There is thus developed a considerable
cell mass due entirely to proliferation of the epidermis* Concurrently the
sub-epidermal cells enlarge somewhat, and a few irregular walls are formed.
These are best seen in a section tangential to the leaf-surface, when they
resemble the secondary changes that may occur in the cortex of some
herbaceous plants (Photo 4). In no case has the sub-epidermal tissue been
observed to take any part in the structure of the main adventitious cell mass
(cf. Text-fig. 39 and Photo 5), though in cases where the growth is close to the
injured surface the activity of the sub-epidermal cells is greater than usual
(Photo 4). The changes that occur within it are of such a nature as to
reduce the amount of intercellular space below the adventitious mass, thus
permitting of freer translocation between it and the leaf.

The size of the cell mass produced appears to be directly related to
conditions of growth. In contact with the soil or in very humid atmosphere,
it may be small in amount ; in drier conditions growth is slower and a con-
siderable and very irregular mass may be produced before further differen-
tiation proceeds. A further factor, that of the age of the regenerating leaf,
is discussed below. It has already been noticed that rhizoids were not of
constant occurrence upon the cell mass, though they invariably occur in
large numbers upon the tuber in the later stage of development.

Once the cell mass is formed the next stage is the localization of
growth at one or more centres by the differentiation of growing-points
(Text-figs. 37-8 and Photo 3) consisting of a group of meristem cells.
The growing-point is definitely geotropic, and quickly becomes buried in
the soil. When, owing to its growth, the apical meristem has become
buried, an invagination of the growing-point occurs as a result of unequal
growth. This is well shown in Text-fig. 40 and Photo 6, which shows the
growing apex already invaginated, and lying at the base of a short pit.
In the case of this leaf a considerable irregular cell mass was formed owing
to there being more than one centre of proliferation. However, only one
growing-point developed.

The subsequent growth of the stalk, after invagination of the apex,
resembles that described for the normal new tuber. The apex is buried by
intercalary growth of the stalk cells, which become considerably elongated
in the vertical plane (Text-fig. 39 and Photos 5, 8, and 9). As in the
normal tuber, the apex is in communication with the exterior along a
channel (‘Canal de Braun’ of Bertrand) (Text-fig. 41). This, as usual,

Osborn. — Some Observations on the Tuber of Phylloglossutn . 505

dilates at the distal end to form a chamber into which the growing-point
projects (Text-figs. 41 and 42 and Photos 7, 8, 9, and 11).

In the majority of cases it is not until the apex is well buried that
growth takes place in all directions, resulting in a tuber. This has the usual
conical meristem seated on a spherical mass of parenchyma (Photo 7). All
the essential features of a normal tuber of Phylloglossu m are shown in this
section made from a detached leaf after three months’ growth. At this

Text-fig. 40. Transverse section of leaf ; epidermis indicated by faint line. An irregular cell
mass has formed, and the growing-point has begun to invaginate. c. — opening of channel, v.b.
— vascular supply of leaf. Camera lucida outline. x 26.

Text-fig. 41. Portion of longitudinal section through cell mass, stalk (which was accidentally
bent), and tuber. ‘ Vascular supply ’ seen from its expansion in cell mass to cup of * tracheides’
around growing apex ( x ). Apex projecting into the chamber and seated on spherical mass of
starchy tissue. The whole length of channel shown, c = opening of channel. Camera lucida
outline, x 26.

Text-fig. 42. Longitudinal section of adventitious growth on leaf in Fig. 20 B. Apex ( x ) seen
projecting into chamber ; extent of starchy tissue shown by faint line. Greater part of ‘ vascular
supply * seen, extending towards * leaflet ’ (/.) (which passes out of plane of section), but no 1 leaflet ’
bundle differentiated. Camera lucida outline, x 26.

stage, however, tuber and dropper consist entirely of parenchyma. Sub-
sequently a 4 vascular supply ’ is developed and differentiation proceeds
within the tuber.

The ‘ vascular supply ’ consists of a strand of tracheidal cells, with
loose spiral or reticulate markings, extending from the original cell mass
along the dropper to a point at the level of the apical meristem. This
development is most active during the last month of growth, and results in
the lignification of certain of the parenchyma cells. These agree with their

506 Osborn,— Some Observations on the Tuber of Phylloglossum,

neighbours in size and shape, hence in the cell mass the ‘ tracheides * are
more or less isodiametric (Photo 10), while in the dropper they are elongate.
Within the adventitious cell mass the ‘ tracheides * form a broad core

Text-fig. 43. Detail of apex of tuber seen Fig. 41. Starchy tissue indicated by heavier

outline to cells, x 27 o.

extending towards the original leaf but not reaching so far as sub-
epidermal tissue, hence, of course, they never form a connexion with the
leaf trace. In the tuber stalk it is interesting to observe the vascular
supply may expand to form a cup of ‘ tracheides * around the apex (Text-
fig. 43), as has been described in the normal tuber.1 Whilst lignification is
1 Wernham, H. F. (1910) : loc. cit.; p. 388.

Osborn. — Some Observations on the Tuber of Phylloglossum. 507

proceeding the tuber becomes further differentiated. The outer layer or
coat consists of rather large cells with stout cell walls, and numerous rhizoids
are developed (Photos 8, 9, 10, and xi). The coat rarely is more than one
cell thick, and in irregular tubers may be absent. In this respect it differs
from the new tuber coat described by Bower,1 which consists of two or
three cell layers besides the epidermis, the latter having characteristically
thickened walls and rhizoid-like hairs. The tissue comprising the main
body of the tuber consists entirely of parenchyma, with few intercellular
spaces. This tissue is packed with minute starch grains, and forms an
almost spherical body of cells, near the upper pole of which the growing
apex is found. The cells of the apex are clearly differentiated from the
rest of the tuber by their large nuclei, abundant protoplasm, and the absence
of cell inclusions. The appearance of a fully-developed adventitious tuber
is well shown in Text-figs. 41, 42, and Photos 8, 9, 11, especially Text-fig.
41, which shows the ‘ tracheide ’ strand from its expansion in the adventitious
cell mass, throughout its whole length, to the cup around the tuber apex.
The same section also shows the channel throughout its whole length,
including the rather prominent opening to the exterior (see also Photo 10).
The position of this shows that invagination of the apex did not occur till
after an appreciable amount of geotropic growth had occurred. Only two
adventitious tubers showing 4 leaflets ’ developed from the cell mass have
been examined in serial section. The 4 leaflet ’ structure is exceedingly
delicate, and consists of an epidermis, a spongy mesophyll, with large inter-
cellular spaces and a central strand. In one 4 leaflet 5 this central strand
consists of elongate parenchyma only, and, as the main leaf had already
begun to rot when fixed, little further development could have occurred.
In the other case there was a well-developed vascular strand seen in trans-
verse section to consist of 4-6 larger 4 tracheides * around two or three
smaller ones. This vascular strand passed down the leaflet and connected
with the tracheidal cells in the cell mass. It was noted that certain
epidermal cells of the leaflet near to its apex developed fine rhizoid-like
processes.

General Results and Conclusions.

The observations on the behaviour of the tuber of Phylloglossum
recorded in the opening sections of this paper serve to emphasize the
importance of the structure as an organ of perennation. This view, referred
to by Professor Bower in his Presidential Address to Section K of the
British Association, 19 14, 2 expresses more nearly the true value of the
tuber than one which regards it as an annually produced protocorm
developed by a permanently embryonic Lycopod.

1 Bower, F. O. (1885) : loc. cit., p. 666.

2 Bower, F. O. (1914) : Brit. Ass. Report, p. 565.

508 Osborn. — Some Observations on the Tuber of Phylloglossum .

In South Australia the geophytic element in the flora of certain areas
is very large.1 Physiologically the tuber of Phylloglossum is comparable
with the tubers, corms, &c., of the spermophytes among which it grows.
Like them, it has an average depth to which the perennating organ is
sunken, a depth that it maintains in spite of accidental circumstances that
tend to bury or expose the tuber. In this respect its behaviour agrees with
that of the geophytes of other countries.2

The analogy drawn by Wernham 3 between the tuber of Phylloglossum
and the stalked droppers of Tulipa and Erythronium described by
Mrs. Arber 4 seems particularly apt, though other workers have found
nothing to justify his conclusions as to the morphological nature of the
tuber.

It may naturally be asked how far the development of adventitious
tubers upon leaves is a normal occurrence and so of value for purposes of
vegetative reproduction. Unfortunately no definite answer could be given
to such a question. In 1917 seven leaves in various stages of tuber forma-
tion were collected in the field. Had these been left undisturbed, possibly
not more than two of them, those shown in Text-figs. 8 and 12, would
have developed sufficiently to be of value for vegetative propagation before
the oncoming dry season put a stop to all growth. On the other hand, in
certain seasons the district near to Adelaide in which Phylloglossum grows
may remain green and growth be possible until the end of December. In

Rainfall in Inches at Belair, South Australia.
Altitude 1,009 ft.

Year.

Jan.

Feb.

Mar.

A pi.

May.

June.

July.

Aug.

Sept.

Oct.

Nov.

Dec.

Total.

1915

0-62

0.03

0.46

2.58

4.20

6.92

3.88

4.67

5.09

0.94

0.36

0.07

29.82

1916

0.65

0.12

0-40

2.18

1*20

11.08

3-55

5-69

1.96

2.41

4*08

1.26

34-58

1917

0.50

2.77

3-27

i-39

6-92

4*53

5*9i

4.41

5-54

3.10

1.23

1.29

40.86

1918

Average '

0.63

0.68

0.46

1.58

3.86

4.88

3*32

4,]r4

i*35

4*39

o-45

c*6o

26-34

Rainfall
for 38
years

0.99

0.65

i-39

2-59

3-39

4*95

3*55

3-52

2-81

2.24

i-43

1*12

28-63

such circumstances there is a reasonable chance that most leaves which
began to form tubers would mature them. In this connexion it is interest-
ing to recall that in some spots a considerable percentage of single-leaved
plants was observed at the close of the 1917 growing season.5 Many of
these plants were very minute, yet all were from tubers of a preceding
season. The year before, 191b, was unusually wet during November.6 It

1 Osborn, T. G. B. : loc. cit., p. 9. 2 Goebel, K. (1905): p. 466.

3 Wernham, H. F. : loc. cit., p. 343. «4 Robertson, A. (1906): Ann. Bot., xx, p. 429.

5 Osborn, T. G. B. : loc. cit., p. 4. Of 184 plants 39 had one leaf only.

6 I am indebted to Mr. E. Bromley, State Meteorologist, Commonwealth Meteorological
Bureau, who has kindly furnished the rainfall records at Belair which are given above.

Osborn . — Some Observations on the Tuber of Phylloglossum . 509

is possible that some of these single-leaved plants were formed from leaves
detached during the 1916 growing season, especially as in many instances
the tubers from which they arose were very small and placed near to the
surface of the soil. When plants of Phylloglossum are turgid their leaves
are brittle and easily broken through. Apart from animal agency, a blow
from a falling twig' or even a wind-swept leaf of Eucalyptus might
detach one.

The production of adventitious tubers by leaves of Phylloglossum has
an interest quite apart from considerations of the morphology of the plant
producing them, namely, as an instance of regeneration. It will have been
observed that the adventitious cell mass produced on injured leaves invari-
ably arises at or near to the proximal end of the leaf. In this respect it
differs from the position of the cell mass formed in regeneration from
detached leaves of Lycopodium ramulosum described by Holloway.1

There the leaf shows no polarity and the adventitious structure may be
produced from any point. However, this may result from the small size
and apparently unspecialized nature of the leaf in question. In Phyllo -
glossum , the consistent development of the adventitious growth at the leaf
base agrees with Goebel’s generalization — c that the place for the formation
of new organs in regeneration is definite and is primarily dependent upon
the direction in which the plastic substance moves in the uninjured
plant.’ 2

But a further consideration arises which is obvious from a study of the
figures, namely, that while the cell mass invariably arises near the leaf base,
it is apparently immaterial upon which side it develops in relation to the
soil. In most cases it is developed from the side of the leaf next the soil,
even when this is elevated by curvatures of the leaf well above the wet
ground. But Text-figs. 12, 24, 33, show that it may be lateral to the leaf
as it lies on the soil, and in one case, Text-fig. 29, it is from the upper side,
i.e. that remote from the soil. Moreover, it has been noted that, with a
single possible exception, the adventitious growth in those leaves which
exhibit curvature is always from the convex side. Hence it seems that it
is not merely the stimulus of contact with the damp ground which deter-
mines the position of adventitious growth, but a morphological factor must
be taken into consideration as well. Unfortunately it was not thought
necessary to mark the morphological upper surfaces when detaching the
leaves, and, as these appear nearly cylindrical, it is difficult to recognize
afterwards, but it is possible to arrive at some conclusion from a considera-
tion of structure. The anatomy also serves to explain the curving of the
leaves to which reference has already been made.

The main features in the structure of the leaf are already well known.

1 Holloway, J. E. (1916) : Trans. N.Z. Inst., xlix, p. 88, Figs. 14-20.

2 Goebel, K. (1900) : p. 45.

510 Osborn. — Some Observations on the Tuber of Phy llog loss um.

In section it is said to have an almost circular outline.1 This is true of the
leaf for the greater part of its length, but towards the base it is usually
decidedly elliptical and sometimes becomes, by compression against the
other leaves, segment-shaped. The usual result of this is that the leaf, when
detached, lies either on the abaxial or adaxial surface, generally the latter,
aud seldom on its side. Further, the simple leaf bundle, which is said to
lie in ‘ the centre of the transverse section \ only has this position in the
upper portion of the leaf. Towards the base it lies on the minor axis of
the ellipse but displaced from the median line, being nearer to the adaxial
surface (Text-fig. 40 and Photos 2 and 6). More than ‘ four or five xylem
elements ’ have been found in transverse section ; the number is usually ten
or more near the base. This eccentric position of the leaf bundle within
the somewhat flattened leaf has the effect of producing curvature when
turgidity is reduced, and it is the abaxial surface which becomes convex
under such circumstances. The inference, therefore, is that the adventitious
growth occurs from the abaxial surface. This conclusion is supported by
the transverse sections seen in Text-figs. 37, 38, and 40 and Photos 2 and 6.
It is less easy to judge from longitudinal sections, in which plane most of
the leaves were cut, but Photo 7 supports this conclusion.

The amount of adventitious growth made by the leaves of the various
series was markedly different. The difference can be correlated with the
period of the growing season at which the leaves were detached. The series
may be conveniently placed in three groups : A, started early in the growing
season (June 13), a little after the tips of the largest leaves were noticed
above the soil; B, C, and D, started in July, when the plants had been
growing for at least six weeks in the field ; and E, started two months later
(September 13). Series B and C were very successful.2 Of the 18 leaves
involved, 12 matured tubers and 3 others would probably have done so had
they not been removed for sectioning before the tubers were fully developed.
The remainder all showed some growth. Series E, on the other hand, was
a comparative failure. Unlike the leaves of the other series, which remained
green for four months or longer, many of the leaves of this series quickly
rotted away. Four only formed any growth, and in the case of one of
these it was very slight. The remaining three leaves only developed as far
as the cell mass ; this, however, became white and starchy and in two
instances formed a ‘ leaflet \ During the two months, July 21 to September
13, which elapsed between starting Series C and E, considerable develop-
ment occurred in the new tubers formed by plants growing in the field. In
July the new tuber merely showed a stalk in process of elongation with
a small unswollen apex. By September the stalk had reached its full

1 Bower, F. O. (1885) : loc. cit., p. 673. The other quotations in this paragraph are from
the same source.

2 It seems legitimate to neglect Series D, since its failure may be attributed to other reasons
than the age of the leaves.

Osborn . — Some Observations on the Tuber of Phylloglossum. 5 1 1

length and the new tuber was appreciably swollen, showing that considerable
plastic material had been transferred to it. By the latter date the leaves of
the growing plant were presumably depleted, although they did not appear
senile, and the phase at which regeneration could be successfully accom-
plished was nearly over.

In regeneration a cell mass is invariably formed first. Upon this
a growing apex usually differentiates, from which the starch-containing
tuber develops. But in some cases no apex is formed and the cell mass
itself becomes starchy as the growing season concludes (Series A and E).
Thus the cell mass may, under some circumstances, behave as a perennating
organ. The essential feature of the cell mass is that it is a roughly
spherical structure, in which carbohydrate material may accumulate, but
which is capable of producing further growth after differentiating a growing-
point. The occurrence of a ‘ leaflet ’ upon the cell mass is variable. In
Series E two of three leaves developed one, but in Series B the three leaves
that did so produced the ‘ leaflet ’ only after a considerable amount of
adventitious growth had taken place. This suggests that the ‘ leaflet * is
a structure of secondary importance, produced in response to some such
physiological stimulus as a failing or insufficient carbohydrate supply.
The cell mass is, as it were, the first foothold secured by a young plant,
a starting-point from which further developments may occur, circum-
stances being favourable. Small parenchymatous swellings containing
starch are not uncommon amongst minute plants in regions of rapidly
varying humidity. A species of Fossombronia growing beside Phyllo-
glossum has a thallus with a markedly swollen midrib. The tubers of
certain Australian species of Anthoceros are well known. Near to the
locality in which Phylloglossum occurs, A?iogramme leptophylla grows in T
abundance. This has a peculiar prothallus with a small, starchy tuber.1
Bearing in mind the climatic conditions under which it grows, the
early and constant production of a cell mass gives special interest to the
behaviour of regenerating leaves of Phylloglossum , and to any comparison
that may be made between them and those of certain species of Lycopodium.

Cases of vegetative reproduction in the genus Lycopodium are well
known, the example of adventitious shoots produced by the first leaves
of embryo plants of Lycopodium inundatum cited by Goebel 2 being of
special interest in considering the behaviour of Phylloglossum. Our know-
ledge of vegetative reproduction and regeneration within the former genus
has been considerably extended of late by Holloway.3 Specially valuable for
comparison with the structures described in Phylloglossum are the gemmae
produced from old roots and from detached leaves of L. ramulosum . The
. gemmae 4 formed from detached fragments of roots are stated to arise from

1 Goebel, K. (1905) : p. 216. 2 Goebel, K. (1900) : p. 46.

3 Holloway, J. E. (1916) • loc. cit. 4 Loc. cit., p. 85.

512 Osborn . — Some Observations on the Tuber of Phylloglossum .

cortical cells. The youngest stages show the development of transverse
walls in certain cells from which a cell mass subsequently forms, which
swells externally and produces a 4 protophyll ’. The following account 1 of
development of leaf bulbils is given. 4 An adventitious bud on a leaf shows
first as a small, roundish, green cushion of meristematic tissue which has
originated probably from one or more epidermal cells. This cushion
develops into a roundish or egg-shaped cell mass which gradually elongates,
and on which at an early stage rhizoids arise. The attachment of the young
bud . . . shows that the main tissue of the leaf is undisturbed.’ These buds
produce one to three 4 protophylls ’ and are firmly attached to the sub-
stratum by rhizoids. Both 4 protophyll ’ and swelling are packed with
starch grains, especially the latter, which develops a storage tissue. The
parent leaf is 4 greenish at its upper portion but yellowish below and is
always obviously broken off at its lower extremity The bulbil is subse-
sequently freed by rotting away of the leaf. These bulbils Holloway
compares with the protocorm of L. cernuum .

If the term 4 protocorm ’ is to have any morphological value it is well
that it should be limited to certain structures such as the extra-prothallial
swelling of the embryo of L. cernuum and to the similar structures formed
in L. laterale 2 and L. ramulosmn ? In the last two species the protocorm
is of unusual size, but Holloway points out that in this’ large structure two
portions may be recognized, 4 the original protocormous tuber surmounted
by its two protophylls ’ and 4 the rhizomatous extension — an added feature
to be interpreted apart from the original tuber ’. From an examination of
material of L. laterale , collected by him in Tasmania, the writer is inclined
to agree with this distinction. It is thus 4 the protocormous tuber ’ of
L. laterale which is the homologue of the protocorm of L. cernuum .
However, seeing 4 that vegetatively produced plants (from bulbils, gemmae'
&c.) tend in their development to pass through stages in elaboration similar
to young plants developing from spore or zygote’,4 Holloways extension
of the term protocorm to the starch-containing bulbils of L. ramidosum and
L. laterale seems perfectly justifiable. But it is unlikely that the protocorm,
even so defined, has any phylogenetic significance.6 It seems preferable to
regard it as 4 an opportunist local swelling . . ., which, though biologically
important ... is not really primitive.’ 6

The biological importance of the protocorm becomes increasingly
obvious as our knowledge of the ecology of those species of Lycopodium
which produce it is enlarged. From Holloway we learn that the three New

1 Holloway, J. E. (1916): loc. cit., p. 88.

2 Holloway, J. E. (1914) : Trans. N.Z. Inst., xlvii, p. 73, and ibid. (1915), p. 277.

3 Holloway, J. E. (1915) : loc. cit., p. 285.

4 Lang, W. H. : Brit. Ass. Report, 1915, p. 706.

6 Bower, F. O. (1908) : p. 225.

6 Bower, F. O. (1914) : p. 565.

Osborn. — Some Observations on the Tttber of Phy l! agios sum. 513

Zealand species of. Lycopodium? which form protocorms all have short-lived
prothalli 1 and grow in localities that are subject to summer drought.2

In Phylloglossum the prothallus is stated to be of the L. cernuum type,3
whilst the climatic conditions under which it grows are also those of a winter
rainfall and a dry summer period. The gametophyte generation and the
conditions of growth are thus similar to those of the protocorm-producing
species of Lycopods. It is not surprising, then, that Phylloglossum should
produce a protocorm, since this structure appears to be essentially of
biological importance in the life-history of plants having a short-lived
prothallus of the L. cernuum type and growing under special climatic con-
ditions. Many workers have regarded the tuber of Phylloglossum as a
protocorm, but this is hardly a legitimate use of the term. By comparison
with species of Lycopodium it will be recognized that it is the cell mass
formed by regenerating leaves, and not the tuber which may arise from it,
that must be considered as the protocorm, since it corresponds to the proto-
corm of Lycopodium spp. in developmental history and in function.
Unfortunately the embryology of Phylloglossum is as yet imperfectly known,
but such evidence as we have indicates that a swollen cell mass is formed
before the initiation of the tuber.4 Miss Sampson has recently described
a sporeling of Phylloglossum, and from her account 5 it is obvious that there
is both ‘ an embryonic swelling’ and a tuber. Unfortunately the account
was limited to a single specimen, and it could not be determined whether the
embryonic swelling was epibasal in origin, corresponding with the proto-
corm of L. cernuum. This seems probable, and there can be little doubt
that biologically it is similar, functioning as a primary storage structure.

In the tuber of Phylloglossum we have a different structure. It has
repeatedly been emphasized that, in the process of vegetative reproduction,
tuber and cell mass or protocorm are two structures, the former arising from
the latter only if conditions be favourable for continued growth. Such
meagre facts as we have of the embryology are capable of a similar inter-
pretation. The tuber is something extra, a structure in which Phylloglossum
has ‘bettered’ the mode of life of certain species of Lycopods 6 (e.g.
L. inundatum , which annually dies off to the tip of its shoot), since a
definite tuber is unknown in that genus. Borrowing a term from another
branch of biological science, the tuber may be regarded as a character of
considerable ‘ survival value ’, for the climatic and edaphic conditions under
which Phylloglossum has been studied are severe ; but it seems hardly
legitimate to style the tuber of Phylloglossum a * protocorm ’ if any morpho-
logical value is to be retained for that term. That there is a distinction
between these two organs is borne out to some extent by their differing

1 Holloway, J. E. (1915): loc. cit., p. 276. 2 Loc. cit., p. 263.

•° Thomas, A. P. W. : loc. cit., p. 289. 4 Thomas, A. P. W. : loc. cit., p. 288.

6 Sampson, K. : loc. cit., p. 607. c Bower, F. O. (1914) : loc. cit., p. 565.

514 Osborn.— Some Observations on the Tuber of Phy lloglossu m .

response to the stimulus of gravity. It has been pointed out that the new
tuber is definitely geotropic. The adventitious tuber behaves similarly, but
the cell mass or protocorm, which is developed first by the regenerating leaf,
does not. It may grow from any side of the leaf in relation to the ground,
and, even when developed in contact with it, shows no penetration into the
soil beyond such amount as is due to expansion of the group of cells. The
cell mass is a transitory structure and rarely attains any size, but where, as
in Text-fig. 12, an unusually large one has formed, its growth is plagio-
tropic rather than geotropic.

It is not intended to discuss the morphology of the tuber at any length,
but the following remarks maybe deemed pertinent. In 1886 it was shown
by Bower that the new tuber in sterile plants is formed directly from the
apex of the plant, while in fertile plants, the apex of which develops the
peduncle and cone, the new tuber is an adventitious growth bearing no
relation to the leaf arrangement. This is substantially our position to-day,
though recently Miss Sampson 1 has on anatomical grounds attempted to
show that in fertile plants the apex bifurcates and that the new tuber is of
the nature of a branch. The vascular anatomy of a minute plant such as
Phyiloglossiim is subject to considerable variation, as was shown by Bower.2
The writer has hardly examined sufficient plants in serial section to be able
to affirm or refute Miss Sampson’s contention, but it seems significant that
in two fertile plants recently studied no connexion existed between the
vascular supply to the new tubers and the stele of the plant producing it.
In one case, a four-leaved plant with two roots, the vascular strand from the
new tuber completely died out in the stem before the xylem masses of the
two roots coalesced, and far below the point to which any leaf trace pene-
trated. It is therefore hardly legitimate to assume that in all cases the
tuber of fertile plants of Phylloglossum is a modified branch, or, indeed, that
it represents 4 a highly specialized leafy axis’. The ‘ vascular supply ’ to the
adventitious tuber has been shown to be a late development and in no case
connected with the tracheides in the regenerating leaf. The wide tracheidal
cells of the 4 vascular supply ’, with their loose spiral or reticulate lignifica-
tion, resemble rather 4 storage tracheides’ than conducting elements. Such
a function affords a reasonable explanation of the cup of tracheides formed
at the distal end of the stalk round the new tuber apex. The reproduction
of tubers by detached leaves agreeing, even to details of vascular supply,
with those formed normally by the plant in each growing season, suggests
that caution is necessary before adopting a generalization as to the
morphology of the tuber which is based entirely on anatomical evidence.

1 Sampson, K. (1916): Ann. Bot., xxx, p. 331.

2 Bower, F. O. (1885) : loc. cit., p. 674, and PI. 70, Figs. 42, 43.

Osborn . — Some Observations on the Tuber of Phy l log loss u m . 5 1 5

Summary.

1. Phylloglossum Drummondii occurs in South Australia as a member
of the geophytic element in the flora of an area subject to prolonged summer
desiccation.

2. The examination of a number of living plants has shown that, whilst
the average depth of the current tuber is about 1 c.m., owing to various
accidental causes it may range from a surface position to a depth of at
least 2 cm.

3. Whatever the depth of the current tuber, the growing plant tends to
form its new tuber at an average depth of 1 cm. This adjustment is effected
by variation in length of the tuber stalk.

4. A new method of vegetative reproduction is described for Phyllo-
glossum. This consists in regeneration from leaves, injured or detached by
accidental causes.

5. In regeneration there is first produced an adventitious cell mass, at
or near the proximal end of the leaf and arising from the abaxial surface.
This cell mass is regarded as the protocorm.

6. From a growing-point differentiated on the cell mass a tuber
develops which resembles that formed by the normal plant.

7. Reasons are advanced for regarding the protocorm and tuber as two
distinct and independent structures.

8. The results of the investigation emphasize the biological value of
the tuber, and morphological interpretations, based on anatomical evidence
only, should be accepted with caution.

I am greatly indebted to Professor W. H. Lang, F.R.S., for his kindness
in seeing this paper through the press.

Botanical Department,

University of Adelaide.

Literature cited.

Bower, F. O. (1885) : On the Development and Morphology of Phylloglossum Drummondii.
Phil. Trans. Roy. Soc., London, vol. clxxvi, pp. 665-78.

— (1908) : The Origin of a Land Flora.

(1914): Address to the Botanical Section. Brit. Ass. Report, Australia, 1914,

pp. 560-72.

Goebel, K. (1900) : Organography of Plants. Part I. General Organography.

(1905): Organography of Plants. Part II. Special Organography.

Holloway, J. E. (1914) : Preliminary Note on the Protocorm of Lycopodium laterale , R. Br,
Trans, and Proc. N.Z. Inst., vol. xlvii, pp. 73—5.

(1915): Studies in the New Zealand Species of Lycopodium. Part I. Ibid.,

vol. xlviii, pp. 253-303.

. (1916) : Studies in the New Zealand Species ot Lycopodium. Part II. Methods

of Vegetative Reproduction. Ibid., vol. xlix, pp. 80-93.

5 1 6 Osborn . — Some Observations on the Tuber of Phylloglossum.

Lang, W. H. (1915) : Address to the Botanical Section. Brit. Ass. Report, Manchester, 1915,
pp. 701-18.

Osborn, T. G. B. (1918) : On the Habitat and Method of Occurrence in South Australia of Two
Genera of Lycopods hitherto unrecorded for the State. Trans. Roy. Soc., S. Aus.,
vol. xlii, pp. 1-1 2.

Robertson, A. (1906) : The Droppers of Tulipa and Erythroniuin . Ann. Bot., vol. xx,

pp. 429-40.

Sampson, K. (1916) : The Morphology of Phylloglossum Drummondii , Kunze. Ann. Bot.,
vol. xxx, pp. 314-31.

(1916) : Note on a Sporeling of Phylloglossum attached to a Prothallus. Ibid.,

pp. 605-7.

Thomas, A. P. W. (1902) : Preliminary Account of the Prothallium of Phylloglossum. Proc. Roy.
Soc., London, vol. lxix, pp. 285-91.

Wernham, H. F. (1910) : The Morphology of Phylloglossum Diummondii. Ann. Bot., vol. xxiv,
PP- 335-47-

EXPLANATION OF PLATE XXVIII.

Illustrating Mr. Osborn’s paper on Some Observations on the Tuber of Phylloglossum.

All figures x 20.

c.m. = cell mass ; g.p. = growing-point ; t.s. — tuber stalk ; v.b. = vascular bundle of detached
leaf ; v.s. = ‘ vascular supply ’ in tuber stalk.

Photo 1. Transverse section of leaf showing considerable cell mass. A growing-point has
begun to differentiate.

Photo 2. Transverse section of leaf showing cell mass. The proliferation of individual epider-
mal cells is shown on left. Two growing-points are differentiating, and the cell mass between
them shows a continuous anticlinal wall for several cell rows. Some rhizoids ( r.h .) have developed
on left side.

Photo 3. Longitudinal section (somewhat oblique) of leaf found in field (Text-fig. 10), showing
differentiation of growing-point on cell mass. The greater part of this is of epidermal origin, but
secondary divisions have occurred in two mesophyll layers.

Photo 4. Longitudinal section of leaf, showing large cell mass and unusually marked secondary
development in mesophyll. Note the injured surface of this leaf is oblique.

Photo 5. Longitudinal section of leaf with small cell mass and stalk of tuber. The essentially
epidermal origin of the adventitious structure formed in regeneration is seen.

Photo 6. Transverse section of leaf with irregularly lobed cell mass. The larger lobe has
formed a growing-point which has invaginated and lies at the base of a short pit, the channel.

Photo 7. Longitudinal section of leaf and adventitious tuber after three months’ growth. The
tuber has swollen and the growing-point is situated in a chamber at the upper pole. The tuber as yet
shows no differentiation, nor is there any ‘ vascular supply ’ in the stalk.

Photo 8. Transverse section of leaf bearing adventitious tuber, which is nearly fully developed.
Storage tissue, tuber coat, and growing-point are all visible, and rhizoids are present on the tuber
and stalk.

Photo 9. Longitudinal section of leaf and adventitious tuber at about the same stage as that in
Photo 8. The bend on the tuber stalk is accidental.

Photo 10. Somewhat tangential section of same leaf as Photo 9, showing ‘tracheides’ of
‘ vascular supply ’ in the cell mass, and tuber stalk, with expansion at the distal end of the latter.
The opening of the channel to the exterior ( o.c .) is seen.

Photo 11. Longitudinal section of adventitious growth from detached leaf (Text-fig. 20) with
tuber coat, bearing rhizoids, storage tissue, and growing-point. The ‘ leaflet ’ (/.) is seen passing out
of the plane of the section on left.

Photo 12. Transverse section of leaf (Text-fig. 25) bearing many cell masses, one of which is
becoming tuberous {i.b.) directly, without fanning a definite apex.

Jfwwbtj; of Botany,

V. b.

VoLJZBJrPLJZm.

v.b.

Huth, London.

OSBORN — PHYLLOGLOSSUM.

The Temperature-coefficient of Photosynthesis :
A Reply to Criticism.1

BY

A. MALINS SMITH, M.A. (Cantab.).

With two Figures in the Text.

Introduction.

THREE papers have recently appeared in the ‘Philippine Journal of
Science \ two by Brown and Heise and one by Brown alone, adversely
criticizing several current conceptions with regard to the rate of carbon
assimilation in plants and the influence of the factors of temperature and
light upon it. In the first (1917 «) Brown and Heise oppose the view that
the temperature-relations of this process are such that it conforms to the
van’t Hoff rule. In the second (1917#) they oppose the view that the
magnitude of carbon assimilation is directly proportional to the intensity of
illumination, holding that when the light is increased by equal increments
the increments of photosynthesis form a rapidly declining series. In the
third (1918), by Brown alone, some attack is made upon the evidence for the
conception of limiting factors.

The first of these papers is the most considerable, and is directed against
the conclusions reached in a series of papers by Blackman and his co-
workers, especially against the work of Matthaei (1904). The view of Brown
and Heise is that carbon assimilation in plants is governed by low tempera-
ture-coefficients, such as have been found to characterize photochemical
reaction in vitro (1-04 to 1-42 for a rise of io° C.), instead of by coefficients
of the magnitude of about 2-o, which are the rule for ‘ dark ’ reactions in
vitro.

Brown and Heise have not worked upon this subject themselves and
provide no new data, but they endeavour to establish their position by
selection, rejection, and correction of the published results of experimental
workers in this field. The intensity of their conviction that these results
must be wrong when they have no data of their own to start from would be
rather puzzling were it not made evident that, having grasped the general-
ization that all photochemical reactions have low temperature-coefficients,
they have thereupon decided, quite a priori, that photosynthesis must really

1 This paper forms Part XII of ‘ Experimental Researches upon Vegetable Assimilation and
Respiration carried out in the Botany School, Cambridge.

[Annals of Botany, Vol. XXXIII. No. CXXXII. October, 1919.]

Pp

- 1 8 Smith. — The Temperature-coefficient of

have low coefficients also, however strong the evidence may appear to be
against this. They therefore, without any misgivings, set out to explain
away or discredit all measurements of carbon assimilation in plants which
indicate high temperature-coefficients. There is nothing judicial or scientific
in their method. Data are adopted or rejected quite apart from the amount
of evidence supporting them. Sound progress can, however, only be made
by shaping theories to fit facts and not vice versa. It has not occurred to
them that though certain stages in the complex chain of reactions of carbon
assimilation are certainly photochemical, yet other subsequent stages are
‘ dark reactions \ From this conception it follows that it would be a matter,
not for a priori dogmatism, but for experimental investigation, whether the
temperature relations of the total process were those of a ‘ light , or of
a { dark ’ reaction.

This view of the complex nature of carbon assimilation has been held
by teachers and workers for many years now, and it has generally been
accepted, on the available evidence, that the dark reactions govern the
maximal possibilities of the system. The attack upon this view that Brown
and Heise have made consists of a mass of detailed criticism of individual
measurements of photosynthesis. As few readers are likely to weigh all
these criticisms for themselves, it seems unfortunately necessary to point out
in some detail how arbitrary and unsound they are.

Assimilation and Temperature.

Brown and Heise first discuss the work of van Amstel (1916) on
E lode a.

Experiments of van Amstel on El ode a.

**

Miss van Amstel investigated the output of oxygen by Elodea in
a current of water laden with C02 at a few temperatures, namely, 240, 36*5°,
and 400.1 She set out to measure the temperature-relations for these points,
but admits that it is a difficult and complicated matter to get critical values
for high temperatures. In one experiment only (Table V) did she compare
the effect of the temperatures 240 and 36*5° on the same shoot of Elodea ,
and the observed increased rate indicated 1-26 as the value of K10. This
observation is the only low value for a temperature-coefficient of photo-
synthesis available in the literature, and it is of course eagerly adopted by
Brown and Heise without any examination of credentials. It must first be
pointed out in fairness to Miss van Amstel that she expressly disclaims that
she has succeeded in establishing trustworthy ratios for these high tempera-
tures. She says on p. 3 : ‘ Thus the experiments, which are to be discussed
here, will lead to the conclusion that in fact we did not measure the
influence of temperature on the C02 assimilation itself, but that physical

1 All temperature figures are in C°.

Photosynthesis : a Reply to Criticism. 519

processes have exerted their limiting influence.’ 5 In spite of this circum-
stance we are publishing our results now because they may indicate to
others the probable way to obtain the desired results.’

In the results presented only five are at temperatures other than 240 :
three at 36°, one at 40°, one at 450. Of those at 36° only one can be com-
pared with assimilation at 240 because the other two were done on smaller
and undefined amounts of material. Throughout this work no adequate
uniformity in the amount of material employed is attained, and the values
for ‘apparent assimilation’, under as uniform conditions as possible, vary
from experiment to experiment, 0-152, 0-166, 0-168, 0-186, 0-189.

Our present interest is therefore entirely concentrated on the case
where, with constant light (2,482 Hefner candles), constant C02 supply
(350 c.c. of water containing 0-152 mg. free C02 per litre every 4! to 5
minutes), the observed output of oxygen was 0-189 mg. per minute at
240, while it rose to 0-238 mg. at 36*5°, thus indicating a ratio which would
make K10= 1-26.

For these values to be significant it is absolutely essential that each
must represent the maximal value possible at that temperature. This can
only be established by producing evidence that neither light nor C02 supply is
limiting the assimilation to a value below the appropriate specific maximum.
The value of 0-189 mg. 02 we can accept as maximal for 240 C., because
raising the temperature alone considerably increased the value. But can we
accept 0-258 mg. as maximal for 36-5° ? Van Amstel has given no proof in
her paper that 0-258 is a maximal value. There is no experiment in which
the temperature was raised from 36-5° to any higher value, using the same
shoot. For information as to the possibilities of assimilation at 40° we
must turn to an experiment on a different shoot from that which furnished
the value 0-258 mg. This second shoot gave at 40° an average assimila-
tion of 0-242 mg. Since, however, it had already at 240 given a lower
value than the first shoot, van Amstel obtained, by allowing for its lower
assimilatory activity, a figure for its assimilation at 40° which was 5 per
cent, higher than that of the first shoot at 36*5°. There are no data from
which to calculate the probable error of van Amstel’s experiments. In
their absence it is safe to say that there is no proof that this rise of 5 per
cent., obtained in such an indirect way, represents a real rise in assimilatory
activity due to the higher temperature. Consequently it is unproven that
0-258 is the maximal value possible at a temperature of 36*5°.

Van Amstel was of opinion that she had given proof that both C02
supply and light were more than sufficient for the assimilation possible at
any of the temperatures used in her experiments. Closer inquiry, however,
may lead to a different conclusion. With regard to C02 supply, she
trusted only to alteration of rate of flow ; the concentration of C02 in the
water-supply was the same in the whole of her experiments, The shoot

P p 2

520

Smith. — The Temperature-coefficient of

occupied the axis of the cylindrical vessel through which the water flowed
and most of the flow would be along the unimpeded track at the periphery
of the vessel. Now the important thing is the concentration in the more
stagnant layers at the surface of the leaves and the diffusion gradient main-
tained from them into the leaf tissue. So when she found in one experiment
that halving the total flow-rate through the cylinder did not appreciably
lower the rate of photosynthesis, we cannot conclude that the concentration
at the surface of the plant was seriously diminished by the reduced flow out
beyond it. Experiments made at Cambridge by Mr. F. Summers on the
bubbling of water-plants in a stream of tap-water supersaturated with air
showed that doubling the rate of flow only increased the bubble-rate by
15 per cent. Indeed, if the flow is very fast, a further increase of 20 per
cent, in rate may not increase the bubble-rate at all. Concentration of C02
is the only significant thing, especially in a water medium where diffusion is
so sluggish, and it is a pity that the whole of van Amstel’s work was done
with but one concentration.

As proof that the light, 2,482 Hefner candles, was sufficient for the full
assimilation at 36-5° van Amstel furnishes one experiment in which at
this temperature an increase of light to 3,377 candles did not increase the
assimilation (van Amstel, Table II). The value of the assimilation in this
experiment (0-148 mg.) is, however, so widely different from that obtained
in the later experiment at 36*5° (0-258 mg.) that, unless some explana-
tion of the discrepancy is forthcoming, the result cannot be considered
significant. For all these reasons, therefore, the figure 0-258 mg. 02 per
min. cannot be regarded as having been proved to be maximal for a tem-
perature of 36-5°.

Further, there is the important point that no account is taken of the
respiratory gas-exchange going on at the same time as photosynthesis. At
low temperatures this will be small, but at high temperatures it cannot be
neglected for exact work. Therefore at 36-5° the real photosynthesis
value must be appreciably higher than the apparent value actually observed
by just the amount of oxygen that is circulating round and round in the
respiration of the moment.

It appears, therefore, that the temperature-coefficient of 1*26 is not
sufficiently substantiated.

The Work of Blackman and Smith.

Brown and Heise quote experiments made by Blackman and Smith
(1911) and calculate therefrom three temperature-coefficients for assimilation
in Elodea. The first, 2*05, between 70 and 330, agrees with the calcula-
tions of that paper. The second, 1-75, between 70 and 2i°, and the third,
1-35, between 130 and 2i°, were not calculated in the paper, because there
was no proof that the figure obtained at 2i° was the real measure of the

Photosynthesis : a Reply to Criticism .

52i

full temperature effect. In all probability it was the measure of a light
effect. As will be seen from Fig. 7 of the paper in question, a temperature
of 2i° should allow of considerably more assimilation than was obtained
at that temperature in either of the Expts. D or E. It was stated implicitly
concerning Expt. D, and specifically of Expt. E, that the values obtained
at 2i° were light-limited values. Until Brown and Heise can bring forward
proof that this was not the case, they are not entitled to use the results at
210 in order to calculate therefrom a coefficient for temperature.

It appears, therefore, from a reconsideration of the work of van Amstel
and of Blackman and Smith that of the five coefficients given in Brown and
Heise’s Table III, four are worthless because they are calculated from results
in regard to which there is no proof that temperature was exerting its
maximum effect. On the contrary, there is every probability that some
other factor was limiting the intensity of the assimilation. The remaining
coefficient, 2*05, is perfectly sound and is of a magnitude which agrees with
the van ’t Hoff rule.

Brown and Heise’s Table III.

Range of Temperature. Coefficient.
7-130 2.05

7-210 1.75

13-2 I*35
24-36.5° 1.28

36.5-40° 1.25

Calculated from data of
Blackman and Smith, p. 402

„ pp. 400, 401

van Amstel

>>

The Work of Kreuster.

Kreusler (1887) worked with one shoot of Rubus , kept in his chamber
for three weeks and exposed to a different temperature every day.
Matthaei (1904) showed that the activity of the shoot is declining day after
day and that the material soon becomes quite unsound, so that it is impossible
to analyse out pure temperature effects from it. At the end the shoot makes
little response to change of temperature, while at the beginning it may make
a large response. Brown and Heise, though aware of this criticism, welcome
the results of the abnormal material as being nearer to their ideal of 1-04
for the value of the temperature-coefficient. It hardly seems necessary to
go further into this line of evidence.

The Work of Matthaei on Cherry-laurel.

The work of Matthaei (1904) on Cherry-laurel has been the chief
experimental groundwork for the calculation of temperature-coefficients for
carbon assimilation and has formed the chief support of the statement that
such temperature-coefficients are in agreement with the van ’t Hoff rule for
ordinary chemical processes in vitro. Brown and Heise make a detailed
attack on Matthaei’s work, and it will therefore be necessary to consider
somewhat fully their criticisms.

522

Smith. — The Temperature-coefficient of

The method of Matthaei was to adopt only those numbers as measures
of the influence of the temperature-factor which were obtained under condi-
tions in which the temperature was shown to be limiting and the other
factors in considerable excess. Working with one fixed light and a series
of increasing temperatures, she found for that series a curve of the well-
known inflected form with a rising limb for the lower temperatures, followed
by a horizontal limb for the higher temperatures. Starting all over again
with a more intense light, this finding repeated itself with the inflexion point

at a higher temperature, and similarly with still more intense lights, the
collection of curves being shown in Fig. I.

Her interpretation is that the rising limb is a true measure of tempera-
ture effect, while the horizontal limb is limited by light and merely expresses
the light intensity, uninfluenced by temperature. Now, since the object of
Brown and Heise is to show that assimilation is very little affected by
temperature, they proceed on the general plan of casting doubts upon the
soundness of the numbers in the rising limb of the curve (and upon these
only) by appealing to seasonal changes, experimental errors, or other
unsupported hypotheses. They are then left with merely a set of horizontal

Photosynthesis : a Reply to Criticism . 523

limbs, one for each intensity of light used by Matthaei. As each horizontal
limb does cover assimilation over a fair range of temperature, they thus
reach the desired conclusion that temperature has practically no effect upon
assimilation.

We must now consider in some detail the criticisms levelled at the
rising limbs of each of Matthaei’s four curves, which were carried out with 1,
1, 4, and 8 arbitrary units of light respectively. The first of these curves sets
forth the results of twenty-one experiments ranging from —6° to +33°,
all in unit intensity of light. The curve is of very definite form, and it is
clear from it that the results obtained at temperatures below 30 increase in
proportion to increasing temperature, while the remainder of the results show
the limiting effect of unit light. The eight experiments on the rising part
of the curves are in direct opposition to Brown and Heise’s contention, and
they therefore simply rule them out of the discussion by announcing their
intention of confining their consideration to values obtained between 4-3°
and 330. This method of arbitrarily choosing a lower limit (30) which
will be convenient for their theory is felt by them to be too summary
a procedure to pass unsupported by any argument. They therefore say,
‘ The part of the curve below 30 shows very much higher temperature-
coefficients than would be called for according to the van’t Hoff principle.
At these temperatures many plant processes are just coming into activity.
Under such conditions it would not be surprising to find that a general ratio
would not hold for any particular function.’

To this it may be replied that results below 30 with weak light are
perfectly consistent with results above 30 in somewhat stronger light when
treated from the point of view of Matthaei, Blackman (1905), Kanitz (1915),
and many others who accept the application of the van ’t Hoff rule. This is,
therefore, in favour of their outlook and against the view of Brown and Heise,
who have to assume a sudden discontinuity of principles at this temperature,
passing from big temperature-coefficients below it to very small ones
above it.

Brown and Heise then pass to Matthaei’s second curve, expressing the
results at different temperatures with light of twice unit intensity. It will be
seen that the general form of the curve is the same as that for unit light just
discussed. The important point is that though double light may produce
increased assimilation, as pointed out by Brown and Heise, yet it only does
so when the temperature is raised. So long as the temperature remains low ,
no amount of light increase causes increased assimilation. This fact,
unchallenged, would be fatal to Brown and Heise’s whole contention. They
deal first of all with Matthaei’s proof that at temp. 0-4° doubling the light
does not increase the assimilation, while at temperatures 90, n°, and 250 the
assimilation is thereby almost doubled. Their comment is as follows :

‘ The temperature is below that which we are considering. It may be

524 Smith.— The Temperature-coefficient of

said, however, that with unit intensity of light the result at 0-4° is very
similar to those obtained at all higher temperatures, and so is greater than
would be expected from the more complete results recorded in Table I and
plotted in Fig. 1. This figure shows an increase in assimilation of consider-
ably more than 50 per cent, between 0-4° and 3*6°. Doubling the intensity
of light did, however, increase this apparently too high result in Table II
for unit intensity of light at 0-4°.’

This passage is obscure, and has been rendered more so by carelessness
in the citation of tables. Table I should evidently be Table V and Table II
should be Table VI. In Matthaei’s paper these results are incorporated in
Figs. 2 and 3 respectively.

The first sentence of their comment is a repetition of their evasion of data
which do not suit them. The statement that the result in Matthaei’s Fig. 3
(Fig. 1 of this paper) for 0-4° is greater than would be expected from the
more complete results in Matthaei’s Fig. 2 is very curious, for comparison
will show that the values from the two curves are exactly the same.
Apparently Brown and Heise suppose that the figure for 0-4° should in
every series of experiments be the same proportion of the result for 3*6° as
it is in Matthaei’s Fig. 2. A moment’s consideration will show the
improbability of such a supposition. The value for the higher temperatures
shown in Matthaei’s Fig. 3 (Fig. 1 of this paper) for unit light is depressed
because of a lowered seasonal activity of the leaves. This phenomenon is
perfectly familiar to any one who has worked with either land or water
plants, and, though its causes are obscure, it is best expressed in Matthaei’s
words : ‘ It appears as if in the sluggish condition of the leaves more light
were necessary to do the same amount of work.’ The assimilation for unit
light is therefore lower in Matthaei’s Fig. 3 than in her Fig. 2. But at 0-4°,
where, according to all the evidence, light is not the limiting factor, but tem-
perature, there is no reason why the assimilation should be depressed from
its usual temperature value. The result at 0*4° and light intensity one unit
is therefore not too high, but, as has already been remarked, exactly the
same and confirmatory of the result in Matthaei’s Fig. 2. The result at
the same temperature and light intensity two units is the same within the
probable error of the experiment, and this constitutes a proof that a tem-
perature of 0-4° is the limiting factor, for results of another order altogether
are obtained when .temperature is not limiting, as is shown by the three
concordant experiments at 90, n°, and 250.

It is well established, therefore, that with light intensity of two units
a temperature of 0*4° is limiting and a fortiori that lower temperatures are
limiting also. This is important, for it cannot be expected that in every
fresh series of experiments with more intense light the proof that these
lower temperatures are limiting should again be repeated. When, therefore,
Matthaei comes to the experiments with light intensity of four units she is

Photosynthesis : a Reply to Criticism .

525

perfectly justified in adopting these already well-established values at which
temperature is limiting as part of her curve. This must be said, because
Brown and Heise deal with the five experiments with light intensity of four
units as an isolated set of experiments with no relation to previous values or
results. These five experiments are part of the whole body of results and
must be viewed in the light of them. They yield four separate temperature
values, those for 9-3°, 11*4°, 24-8°, and -25*2°. . These values, as plotted by
Brown and Heise, seem to exhibit inconsistency, but let us look at them in
the light of previous results. The curve for four units of light must be
allowed to have associated with it the temperature-values well established in
the previous series, e. g. those at — 6° and at 04°. When these are added to the
four values of the four-unit series itself there are obtained a series of six results
which can only be consistently explained in the way adopted by Matthaei,
namely, by the omission of the result for 24-8°, given by a leaf believed to
be abnormal. We are not confined to the two alternatives offered by Brown
and Heise, who say: ‘ If the figures for 11*4° and 24*8° are correct, there is
very little or no rise in the rate of assimilation ; if the results for 9-2° and
2,5*2° are reliable, there is a considerable rise.’ They conclude that ‘ the
results are such that no reliable conclusions can be drawn from them \
Even if only the four values obtained at four units light are considered there
is a third explanation, the one adopted by Matthaei, viz. that the results at
9*2°, n*4°, and 25*2° are reliable and the one at 24*8° irregular. Reinforced
by the values at — 6° and 0*4° her interpretation gives a consistent explanation
of five out of six results, whereas the only conclusion from Brown and Heise’s
theory is that the whole series is valueless, a very unlikely hypothesis.
Matthaei’s treatment of the data is substantiated by her pointing out that
the one value which is too low (at 24*8°) is given by a leaf that in a previous
experiment had given an unusually low result for a less intense illumination.
It is worth while to calculate the ratio for this particular leaf and compare

assimilation at 4 units light

it with the ratio for normal leaves.

485

The ratio . ,

assimilation at unit light

The same ratio for the normal leaf

for the leaf in question = - = 2*70.

610 I^°

is = 2-77* The closeness of these two ratios supports Matthaei’s view

that the experimental result at 24*8° is due to the lower assimilatory power
of the leaf in question. Nor is this view upset by the fact that at unit light
the results from the two types of leaves are close enough to be within the
limits of experimental error.

It is necessary here to consider the peculiar views held by Brown and
Heise as to experimental error. They say * the percentage of increase
between the figure for 9*2° and the one for 11*4°, and four units of light, is,
moreover, within the possible limits of experimental error, indicated in our
Table V, Expts. 13 and 14 ’.

526 Smith.— The Temperahtr e-coefficient of

Now Expts. 13 and 14 of Brown and Heise’s Table V (Matthaei’s
Fig. 2) differ by 0-00088. It is therefore not true to say that o-ooioo, the
difference between the experiments at 9*2° and 11*4° with four units of light,
is within the previous extreme limits of error. It is outside those limits.
Moreover, that error in itself was an extreme error and one which by the
laws of chance would occur extremely rarely. This is made perfectly clear
when one sets out precisely the probable error of the long series of fourteen
experiments with light of unit intensity, ranging from —6° to +33-1°.

The set of fourteen experiments gives a mean value of 0-0029 and

a standard deviation of 0*000235, so that the probable error of a single

experiment works out at +0*000158.

That the small deviations throughout the series are devoid of any
significance is shown by considering them in three groups: ( a ) the five

coldest observations, (b) the four medium observations, and (c) the five

hottest observations. The probable error between the mean of a group of
four and the mean of a group of five is, according to the formula kindly
given me by Mr. G. Udny Yule, +0-000158 x + £ = +o-ooon. As the
actual means of the three groups respectively are (a) 0-00286, (b) 0-00292,
(c) 0-00288, the differences between these means are found to be actually
only about half the probable error.

Brown and Heise go against all the probabilities in saying that such
a large difference between two values as o*ooio is not significant and is to
be attributed to experimental error, for the unlikely deviation of +0-00044
only occurred once.

Having claimed q-ooioo, i. e. +0-00050, as within the limits of experi-
mental error, Brown and Heise immediately go on to claim a much smaller
difference, i. e. + 0-00020 (the difference between the results for light
intensities of four and six units at 11*4°), as a real light effect, not due to
experimental error, indicating that further increase of light would increase
still further the assimilation. This is surely merely juggling with figures in
the interests of a theory. As a matter of fact, Matthaei is interpreting the
results according to the probabilities, considering the general form of all
her previous curves and considering how little wider this variation is than
the probable error of her previous experiments, in claiming that these two
results are the same within the limits of experimental error.

Brown and Heise next turn their attention to the results embodied in
Matthaei’s Fig. 4. These are the results of eleven experiments with eight units
of light at temperatures of n° (one expt.), 25*4° (2 expts.), 32-1° (2 expts.),
38-3° (2 expts.), 40-9° (2 expts.), and 42-9° (2 expts.). With the exception
of the two highest temperatures, over 40°, these results, like those of previous
sets with less light, present an initial rising curve, followed by a flat top.
The difference between the results at n° and 25-4° here is too great to be
attributed by Brown and Heise to experimental error, y<st, as it is necessary

Photosynthesis : a Reply to Criticism. 527

for their theory to throw doubt upon the result at 1 1 °, they have recourse to
another suggestion, which I hope to show is equally improbable. ‘ The
difference (between the result at n° and those at 25*4° and 32*1°) can
readily be explained as due to differences in the seasonal activity of the
leaves/ say Brown and Heise. Now the experiment at n° was done on
Mar. 4, the experiments at 25-4° on Jan. 30 and 31, and the experiments at
32*1° on Feb. 4 and 5. In discussing the change in the seasonal activity of
the leaves, Matthaei, who along with Blackman and independently had
worked with Cherry-laurel leaves for some years, states that the change in
the seasonal activity of the leaves occurred comparatively suddenly at the
beginning of April, with the onset of warmer weather, and thus long after
Mar. 4. She found in 1901 and 1902 a high assimilatory activity through
March, and from her experience she felt justified in regarding this experiment
of early March as belonging to the same category, as regards assimilatory
activity, as the experiments at the beginning of February. Against this
testimony it will need more than the unsupported assertion of Brown and
Heise, who are observers in a tropical climate and have never carried out
a single experiment on a Cherry-laurel leaf, that they can readily explain the
difference between the result at n° (Mar. 4) and the result at 25*4° (Jan. 31)
as due to difference in the seasonal activity of the leaves. We may
conclude that these experiments agree with all the previous ones and
establish that with sufficient light the values put forward as characteristic of
— 6°, 0*4°, 9*2°, and n° are limited by the temperature and that the true
effect of increase of temperature is a rapid rise in assimilation.

Finally, Brown and Heise consider the experiments at high tempera-
tures with very intense light and with thermo-electric records of the internal
temperature of the leaf. From these experiments Matthaei obtained
a rapidly rising curve. As, however, in the first three experiments both
light and temperature were increased, it was necessary for Matthaei’s
hypothesis that she should furnish evidence that the temperature and not
the light was the controlling factor. This she did by comparing these
experiments with those of a former series in which in each case a larger
amount of assimilation was obtained with a less intense light. The inference
was drawn that the lower values in the present series were due to the
limiting effect of temperature. Brown and Heise’s criticism is that Matthaei’s
comparison was made between two sets of leaves plucked at two different
seasons and therefore differing in assimilatory activity. They say that the
results in the second series are lower than would be expected from the
temperature of these experiments, judging from the results of the first series,
and that the only possible conclusion that can be drawn from a comparison
of these experiments is that the leaves used in April (the second series)
were less active than those used in March (the first series). Now I propose
to show that while there is indeed an error in Matthaei’s reasoning, yet we

528 Smith . — The Temperature-coefficient of

are by no means confined to the barren conclusion suggested by Brown and
Heise. It is obvious that, the leaves in the second series were less active
than those in the first series, and Matthaei pointed this out and was fully
aware of it. This lessened activity implies that the less active leaf requires
more light to perform the same assimilation as the more active leaf. Now,
since more light is needed for the same assimilation, comparisons cannot
safely be made between the more active and the less active leaves. Thus,
when Matthaei says, as a result of the comparison between the less active
leaf of Expt. 56 and the more active leaf of Expt. 37, that the former must
be exposed to nearly twice the light necessary for the same assimilation in
a normal leaf, we cannot accept her conclusion without further inquiry.
For while the more active leaf performed 0-0072 assimilation with 8 units
of light, the less active leaf would certainly require more light than this for
the same assimilation, and we do not know exactly how much more. It is,
indeed, probable that by increasing the light to 13 units (i. e. by 65 per cent.)
a sufficient margin was provided, but it is not certain. It is a practical
certainty that the margin was insufficient in Expt. 57, for the light used was
more than three times that used in Expt. 38, and it could scarcely therefore
have been limiting even for the more sluggish leaf. But even in the case
of Expt. 56 it is possible to calculate approximately whether the light
provided was in excess. If the experiments of Matthaei’s Fig. 3, made in
April with unit light, are compared with those of her Fig. 2, made in
February with unit light, it is seen that on the average the activity of the
more sluggish leaf is about 75 per cent, of that of the more active one,

° °°2j = 0-77. It follows that if the more active leaves perform 0-0072
0-0022

assimilation with 8 units of light the less active ones will require § x f =
10-7 units for the same assimilation. Therefore 13 units of light is in excess
and cannot be the factor limiting the assimilation of Expt. 56 to 0-00705.
Thus Matthaei’s assumption is justified.

A similar calculation will show that the margin in Expt. 57 compared
with Expt. 38 is so large that full allowance can be made for the lessened
activity of the leaves and yet the light must be in excess and therefore the
temperature limiting. Though no exact calculation can be made for
Expt. 58 compared with Expt. 50, yet the probability again is that the light
is in excess. This is confirmed by the result of Expt. 59, in which, though
the light is not increased, the assimilation (both the initial and the average
values) is greater.

This increase is therefore obviously due to the rise in temperature, show-
ing that at 30*5° C. the temperature was the limiting factor. In this case
the proof does not depend upon the comparison of leaves of differing activities
at all. This fact has been dealt with by Brown and Heise as follows :

‘ Expt. 59, at a temperature of 37-5° and light intensity of 45 units,

Photosynthesis : a Reply to Criticism. 529

shows a marked increase in the rate of assimilation over that shown in
Expt. 58 with the same light and a temperature of 30*5°. The rate
of assimilation at 37*5° fell off very rapidly with successive readings. This
shows that at this temperature there are complicating side-reactions of
considerable magnitude, so that it is not to be expected that a photo-
chemical ratio would hold. The importance of side-reactions will be shown
in another connexion. Moreover, one experiment under extreme conditions
cannot be regarded as reliable when we consider the magnitude of the
experimental error with medium temperatures. For the above reasons we
have thought it best not to attempt to draw any conclusion from the
experiment at the temperature of 37*5°. It is interesting to note that
Expts. 42 and 43 (Matthaei, Table VII), with light intensity of eight
units and temperature of 38-3°, do not show the decrease in the rate of
assimilation that is seen in Expt. 59.’

Their first sentence recognizes a fact which they are quite unable to
explain, as they will not admit the obvious solution that temperature, the
Only factor altered, was limiting in Expt. 58. The fact that assimilation fell
witl} time in Expt. 59 makes their difficulty greater, for obviously it is
the higher values which most nearly represent the true assimilatory activity.
Hypothetical side-reactions, therefore, do not help them. Their statement
about experimental error is incorrect. The difference of the first readings
in Expts. 58 and 59 is 0-00080, i. e. five times the probable error, which has
been shown to be +o-cooi6, so that it cannot be held.to be insignificant. Nor
is this experiment an isolated one. It is part of a concordant series. Nor,
indeed, is the temperature condition of 37*5 an ‘extreme 5 condition. After
casting up this cloud of unjustified innuendo the authors can only say that
they find it best to leave the experiment out of account altogether.

The Work of Blackman and Matthaei.

Blackman and Matthaei (1905) have shown that the temperature-
coefficient of Heliantlms is even greater than that for Cherry- laurel and is
probably about 2*5. They base their temperature-curve upon the results
of four experiments, in each of which definite proof is given that the
temperature was the controlling factor. Brown and Heise’s comment on
these four experiments is as follows : ‘ It is not evident why the changes
in the rate of assimilation cannot be explained as due to variation in light
intensity, especially since it is evident from their individual experiments
that fluctuations in light intensity are accompanied by marked changes in
assimilation.’ It will scarcely be believed, after this comment, that in each
of the four experiments quoted Blackman and Matthaei gave specific proof
that increase of light did not increase the assimilation at that temperature.
Since, however-, this does not seem to have been made clear to Brown and
Heise, it will be necessary to study each of the experiments mentioned.

530 Smith. — The Temper ahtr e-coefficient of

Take first Blackman and Matthaei’s Expt. X. The experimenters’ statement
is as follows :

‘ For the first four readings the temperature was kept down to about
1 8°, and again in the last two the temperature was the same. In all these
readings except the first, which was low, due to the extremely overcast
leaden sky, the assimilation numbers are remarkably uniform, 0*0089,
0*0090, 0*0089, 0*0089, 0*0092 ; while the light varied up and down, being
especially brighter in the last two readings. This can only be interpreted
as being due to the fact that the assimilation is limited by the temperature,
which has been kept steady throughout. Striking confirmation of this is
obtained by raising the temperature for the fifth reading. The sky was
7io lighter than before , but yet, on the temperature being brought up to
30*5°, the assimilation at once doubled, becoming 0*0163.’

In Expt. XI it is shown that the same assimilation value is obtained
at the sixth reading as at the first, although the light was much brighter at
the sixth reading. This can only be due to the controlling influence of
temperature, as claimed by Blackman and Matthaei.

In Expt. XVI also, two readings were obtained at a temperature
of 30°, in the second of which a considerable proportion of the illumination
was cut off by a wooden tube, yet the assimilation did not fall, proving that
temperature and not light was the limiting factor.

When there are provided these definite proofs in each experiment that
the temperature was the controlling factor, of what scientific avail is Brown
and Heise’s statement that they would prefer to attribute all the changes to
variations in illumination ?

In their final discussion of the temperature-coefficient of assimilation
Brown and Heise have attempted to show that its value is 1*04 + 0*03, i. e.
that assimilation is practically unaffected by temperature. They claim that
this value is supported by the results of the investigators named in
their Table I.

Name of Investigator. Name of Plant used . ^ndHdse^

Matthaei Cherry-laurel 1.0 +

Prjanischnikow Typha i.o +

Kreusler Rub?is 1.16

Blackman and Smith Elodea 1-35

van Amstel Elodea 1.26

The results of all these workers have now been reviewed in this paper
with the exception of those of Prjanischnikow (1876), which are not
sufficiently accurate in method to merit discussion in this connexion, and it
has been shown that the only accurate and trustworthy values for the
coefficient are those of Matthaei on Cherry-laurel, which is 2*1 ; of Blackman
and Smith on Elodea , which is 2*05; and of Blackman and Matthaei on
Helia7ithis , which is not definitely given, but is probably about 2*5. All

Photosynthesis : a Reply to Criticism. 531

these values are in agreement with the van ’t Hoff rule for 4 dark ’ reactions
and are much higher than photochemical coefficients. Recently Osterhout
and Haas (1919) have obtained a coefficient of 1 *8 1 for Ulva , which is
nearer to the values characteristic of ‘ dark ’ reactions than to those usual
in ‘ light ’ reactions. Even this figure, however, is probably not high
enough, for in the very brief details given of their experiments in the low
C02 tension of sea-water they provide no evidence against the natural view
that low C02 tension, based on slow dissociation, and diffusion were limiting
their observed value at 370 to something lower than would have been
obtained had temperature been exerting its maximum effect.

It was stated in the introduction to this paper that carbon assimilation
is a complex process involving both ‘ light ’ and ‘ dark ’ reactions, and that
the 1 dark ’ reactions govern the maximal possibilities of the system. The
survey since made of the work done on this problem has shown that the
reliable experimental evidence is all in favour of the idea that the velocity
of the whole process is determined by some reaction having a high
temperature-coefficient, and not a low coefficient such as is characteristic
of pure photochemical reactions.

Assimilation and Light Intensity.

In their second paper Brown and Heise (1917 b ) maintain that the
relation between light and assimilation is not one of direct proportionality,
as has been held broadly by Blackman and his co-workers. They state
that the relation is such that from each increase in light intensity there
results a progressively smaller increase in the velocity of assimilation.
This contention is based upon the experiments of Matthaei (1904), Pantanelli
(1903), Reinke (1883), and Timiriazefif (1889). Brown and Heise themselves
state that Timiriazefif’s results are based upon faulty experimentation.
They do not, therefore, put these results forward as independent evidence for
their thesis. There is thus no need for any discussion of Timiriazefif s
results here. The results of the other workers as interpreted by Brown
and Heise need, however, some consideration.

The Work of Matthaei on Cherry -laurel.

In Fig. 3 of their first paper Brown and Heise have drawn a curve
supposed to represent the relation of light intensity and carbon dioxide
assimilation in Cherry-laurel based on Matthaei’s data. It is clear that
such a curve ought to consist of the results of experiments in which light has
been definitely proved to be the limiting factor. Now of the ten values
which make up this curve it can be asserted of only three that there is proof
that they are light-limited values obtained from normal leaves. The value
o*oo22 with unit light is light-limited, as is proved by increasing the light to
two units, resulting in a large increase of assimilation at the same tempera-
tures. The value 0*0038 with two units of light is light-limited, as is shown

532 Smith. — The Temperature-coefficient of

by the fact that an increase of light to four units increases the assimilation
at the same temperatures. The value o-oo6i at 250 and L. In. — 4 is light-
limited, as it is much lower than is obtained at the same temperature with
greatly increased light (cf. assimilation o*ojoi at 23-7° and L In. == 26, Expt.
LVII) from leaves at the same season of the year. On the other hand, 0-00365
at 9-2° and L. In. = 4 is quite clearly limited by the temperature, since all
the remaining values for the same light at higher temperatures are consider-
ably greater. The value 0-00485 is obtained from an abnormal leaf (see
previous argument, p. 525). The value 0-00465 at 11-4° is limited by tempera-
ture, since an increase to temp. 25-2° is followed by a considerable increase
of assimilation at the same illumination. The value 0-00505 with L. In. = 6
and temp. 11-4° is limited by the temperature, as it lies, within the limits of
probable error, upon the temperature-curve. The value 0-0063 at 25-2° does
not exist. It is an erroneous addition on the part of Matthaei to her sum-
mary table and does not appear in her full tables or in her curve.

The remaining values, 0-0070 at 150 and L. In. = 13; o-oioi at 23-7°
and L. In. = 26 ; and 0-00136 at 30-5° and L. In. = 45, are all values limited
by the temperature for reasons already fully set forth. Thus Brown and
Heise’s curve is partly a light-curve, but principally a temperature-curve, and
therefore does not show the relation between light intensity and assimilation
as asserted by them.

The Work of Pantanelli.

In the paper by Blackman and Smith (1911) it was shown that Panta-
nelli’s curve was of the usual compound nature, only the first part showing
a true light effect, the later part showing probably the effect of limiting
C02 supply or possibly of temperature. Brown and Heise reject this
explanation of Pantanelli’s curve and draw the curve again in such a way
that they can interpret it as giving support to their thesis. Now in their
exposition, in addition to minor matters of questionable soundness which are
here omitted for lack of space, Brown and Heise have arbitrarily omitted
from their curves all values above unit light. Yet Pantanelli conducted
experiments at light intensities of 4, 9, 1 6, 25, 36, 49, and 64 units. It has
been shown in our paper that while the values obtained in the highest
intensities of light are justly omitted from the curve, giving smaller values,
attributed to ‘ fatigue ’ of the chloroplast, yet the values at 4 and 9 units
form an important part of the whole evidence. If it be asked why Brown
and Heise have omitted, without any explanation or reference to the fact, all
the results in light intensities greater than unity, the only answer at all
possible is that these results are entirely fatal to their theory. Whether
the stationary results at medium intensities of light or the depressed results
at higher intensities are considered, there is here a long range of experiments
in which the assimilation does not increase at all and the values cannot be

533

Photosynthesis : a Reply to Criticism.

represented by a rising curve of any kind, logarithmic or other, but simply
by a straight horizontal line or indeed later a falling curve. Just as Brown
and Heise, in the interests of their a priori theory, ignored the low tempera-
ture results of Matthaei, so here, and for the same reason, they ignore the
results of Pantanelli at the higher intensities of light.

The Work of Reinke.

Brown and Heise have used Expt. VIII of Reinke as the chief basis of
the argument in which they attempt to obtain support for their theory
from Reinke’s work. The curve of Expt. VIII, however, can be interpreted,
with greater probability, as one which shows the action of two limiting

Intensity of Light, i unit = intensity of sunlight.

Fig. 2. Reinke’s results. Curve A. Average of all results in Tables I to VIII. B. Average of
all results except those obtained after the plant had been once exposed to 16 units of light.

Reading 60? with unit light in Expt. VI omitted from both curves.

factors, first the light and later the C02 supply. But Expt. VIII does not
show this so conclusively as do some of the other experiments, notably
Expts. I, III, and VIII. In order to avoid all theoretical bias in the inter-
pretation of Reinke’s experiments, Fig. 2, Curve A, has been drawn showing
the average of all the experiments made by Reinke with his first arrangement
of lighting, i.e. all the results shown in his Tables I to VIII. There can be no
doubt that the curve obtained is one of the familiar type showing the action
first of light as the limiting factor and later of C02 supply. Already at unit
light the assimilation reaches its maximum and remains sensibly at that
figure up to an intensity of l6 times sunlight.

Brown and Heise’s Table II gives the results for all Reinke’s experi-
ments, and they say, ‘ These results are in agreement with the more detailed
calculations given in Table I for Reinke’s Table VIII ’. As a matter of
fact, the results in their Table II do not support their hypothesis. In
Expts. I, III, and VII no increase is shown between unit sunlight and 16

Qq

534 Smith. — The Temper ature- coefficient of

units. In fact the only figures which give their hypothesis a semblance of
support are those in Expts. IV, V, and the later portions of VIII. It
will be noticed that in these cases the plant has been exposed for some time
to high intensities of light, and that on being taken back into lower intensi-
ties its curve is slightly different from that of a fresh plant. It seems clear
that the plant has been to some extent injuriously affected by the intense
light. This supposition is supported by the fact that in Expt. VIII,
where the plant is twice exposed to a light intensity of 16 units, the bubble
emission gradually falls off through the experiment, so that the last row of
figures is throughout the smallest of the whole series. In order to avoid
this source of error Curve B, Fig. 2, has been drawn, representing the readings
after ignoring all those taken after the plant has been once exposed to t 6
units of light. This curve is a typical limiting factor curve and cannot 'pos-
sibly be interpreted as supporting the hypothesis of Brown and Heise. It
is significant of the small amount of support which Brown and Heise can
obtain from any of the experiments, that Curve B is scarcely more con-
clusively in favour of the interpretation of Blackman and Smith than is
Curve A, obtained from all Reinke’s readings whatsoever. In fact Brown
and Heise practically admit this when they say, ‘ This progressive falling
off in assimilation per unit of increase of light is very rapid, and it is, there-
fore, not surprising that with high light intensities increasing the intensity
does not greatly augment the rate of assimilation ’, and later, ‘ if a direct pro-
portionality is found in such a case (i.e. in low intensities of light) this is
due to the selection of a particular range of light intensities ’. In the first
of these sentences they admit the fact that at higher intensities increase of
light does not increase assimilation, and in the second that at the lower
intensities the assimilation is proportional to the light. It only remains for
it to be noted that the latter is true up to half sunlight and the former from
unit sunlight to 1 6 units in order to make it clear that the hypothesis of two
limiting factors is correct, on Brown and Heise’s own admission, through the
whole range of intensities used in Reinke’s experiments.

Recently Boyson-Jensen (1918) has given curves showing the effect of
light upon assimilation. As he points out, these curves are of a dual nature,
showing first the limiting effect of light and later that of C02 supply. Owing,
however, to the fact that individual variations were not eliminated, the results
are not sufficiently exact to form a decisive test between the interpretation
of Brown and Heise and that of Blackman.

Assimilation and Limiting Factors.

In a third paper W. H. Brown (1918) has made an attempt to prove
that the results of Blackman and Smith (1911) on Elodea and Fontinalis can
be more accurately represented by a so-called optimum curve than by the

535

Photosynthesis : a Reply to Criticism .

limiting factor curve drawn in that paper. A critical glance at Brown’s
Fig. i will show that the so-called improvement in presentation put forward
by Brown is merely a matter of drawing a line arbitrarily between the
various experimental values, so as to produce an illusory effect of convex
curvature, rather than horizontality. His proposed correction of the latter
part of the curve by allowing for the temperature-coefficient is quite
illegitimate, for convincing evidence was given that both the values to which
Brown has applied this correction were already much below the maximal
values for those temperatures. The values were, in fact, kept low ^y the
controlling influence of some other factor, presumably light. As, therefore,
they are not temperature-values at all, they cannot be subjected to a correc-
tion for temperature-coefficient. Apart from this proposed change, the
difference between Brown’s curve and that put forward by Blackman and
Smith is insignificant. The attempt made by Brown to separate the earliest
part of the curve into two individual parts is seen, when closely examined, to
involve him in inconsistencies. It is not proposed, however, here to follow
him into these details of interpretation, for it is not upon such details as
these that the validity of the theory of limiting factors as applied to carbon
assimilation depends. This theory does not depend upon any single curve,
nor can it be overthrown by suggesting, as Brown has done, minor differences
in the interpretation of any single curve. Thus Matthaei’s supposition that
in her earliest curve light was the limiting factor at all temperatures higher
than 30, did not become established from a consideration of the form of that
particular curve, but from the fact that by subsequent increases of the inten-
sity of the light she obtained a whole series of similar inflected curves, each
one higher than the last in correspondence with the increased light. In
a similar way, though not so completely, Blackman and Smith, in the paper
under discussion, showed that a light of 6- o units was limiting the assimila-
tion in their general curve, because raising the light from 4*2 to about 6- o
units caused an increase in the rate of assimilation.

The revival by Brown of the hypothesis that there exists an { optimum
concentration of carbon dioxide which is indicated by his drawing of
Blackman and Smith’s curve, has surely very little value in the light of the
experimental proof that the assimilation corresponding to that optimum can
be varied as desired by changing the intensity of the light used in the
experiments. When such a series of curves is obtained, as was obtained by
Matthaei for Cherry-laurel in increasing intensities of light, any one of these
curves may perhaps be of the form preferred by Brown, i. e. such as he
would call an optimum curve. But how can all the curves be optimum
curves, and what is the value of the idea of an optimum which changes with
every change of one of the factors conditioning the experiment ?

It is not claimed that a limiting factor curve always adheres rigidly to
a typical form with a sharp angle at the point of change of the limiting factor.

536 Smith. — The Temper ature- coefficient of Photosynthesis.

It is conceivable, and is indeed probable, that when, so to speak, two factors
are close to the limiting value a change in the one not limiting may have
some appreciable effect on assimilation. This will show itself about the in-
flexion of the curve where the limiting factor is changing. For example,
when C02 is limiting, increase of temperature may cause a small increase of
assimilation by increasing the rate of diffusion of the C02. But all minor
details like these apart, the hypothesis of limiting factors rests broadly on the
possibility by its means of interpreting simply and logically the greatest
number of the known facts about the rate of carbon assimilation.

Finally, Brown reveals his singular lack of appreciation of the com-
plexity of the system involved in assimilation when he asks how such
a principle as that of limiting factors can hold in the phenomena of assimi-
lation when he can see no sign of this principle at work in the action of
hydrochloric acid upon marble or the solution of a gas in water.

I am glad to acknowledge the valuable assistance of Dr. F. F. Blackman,
F.R.S., with whom I have discussed many of the points raised in this paper.

List of References.

Blackman, F. F. (1905) : Optima and Limiting Factors. Ann. Bot., vol. xix.

Blackman and Matthaei (1905) : A Quantitative Study of Carbon Dioxide Assimilation and Leaf-
* temperature in Natural Illumination. Proc. Roy. Soc., B., vol. lxxvi, pp. 402-60.

Blackman and Smith (1911) : On Assimilation in Submerged Water-plants and its Relation to the
Concentration of Carbon Dioxide and other Factors. Proc. Roy. Soc., B., vol. lxxxiii,
p. 389.

Boyson-Jensen (1918) : Studies on the Production of Matter in Light- and Shade-plants. Bot.
Tidsskrift, 36 Bind, 4 Hefte.

Brown and Heise (1917a): The Application of Photochemical Temperature-coefficients to the
Velocity of Carbon Dioxide Assimilation. Philippine Journ. of Science, Botany, vol. xii, p. 1.

(1917 b) : The Relation between Light Intensity and Carbon Dioxide Assimila-
tion. Phil. Journ. Sci., Bot., vol. xii, p. 85.

Brown, W. H. (1918) : The Theory of Limiting Factors. Phil. Journ. Sci., Bot., xiii, p. 345.

Kanitz (1915) : Temperatur und Lebensvorgange.

Kreusler (1887) : Beobachtungen iiber die Kohlensaure-Aufnahme und -Ausgabe der Pdanzen.
Landwirthschaftliche Jahrbiicher, p. 711.

Matthaei (1904) : On the Effect of Temperature on Carbon Dioxide Assimilation. Phil. Trans.,
Series B, vol. cxcvii, pp. 47-105.

Osterhout and Haas (1919) : The Temperature-coefficient of Photosynthesis. Journal of General
Physiology, vol. i, p. 295.

Pantanelli (1903) : Abhangigkeit der Sauerstoffausscheidung belichteter Pdanzen von ausseren
. Bedingungen. Jahrb. f. wiss.. Bot., vol. xxxix.

PRJANISCHNIKOW (1876): Bot. Jahresbericht.

Reinke (1883) : Untersuchungen iiber die Einwirkung des Lichtes auf die Sauerstoffausscheidung
der Pdanzen. Bot. Zeit., pp. 1-14.

Timiriazeff (1889) : Sur le rapport entre l’intensite des radiations solaires et la decomposition de
l’acide carbonique par les vegetaux. Compt. Rend., 109, p. 379.

van Amstel (1916) : On the Induence of Temperature on the COo Assimilation of Elodea cana-
densis. Rec. Trav. Bot. Neerl., vol. xiii, pp. 1-29.

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