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THE LIFE OF CRUSTACEA

THE

LIFE OF CRUSTACEA

BY

W. T. GALMAN, D.Sc.

WITH THIRTY-TWO PLATES AND EIGHTY-FIVE FIGURES

METHUEN & CO. LTD.

36 ESSEX STREET W.C.
LONDON

First Published in igu

PREFACE

^jpHIS sketch of the Natural History of the
Crustacea deals chiefly with their habits and
modes of life, and attempts to provide, for readers
unfamiliar with the technicalities of Zoology, an
account of some of the more important scientific
problems suggested by a study of the living animals
in relation to their environment.

I am indebted to the Trustees of the British
Museum for leave to reproduce certain figures pre-
pared for the “ Guide to the Crustacea, Arachnida,
Onychophora, and Myriopoda exhibited in the
Department of Zoology”; also to Sir Ray Lan-
kester, K.C.B., F.R.S., and to Messrs. A. and C.
Black for the use of a number of figures from my
volume on Crustacea in the “ Treatise on Zoology,”
edited by Sir Ray Lankester.

v

VI

THE LIFE OF CRUSTACEA

The source of these figures is indicated in the
explanation attached to each. Of the remaining
illustrations, some are reproduced from photographs
of specimens in the collection of the British
Museum ; the others have been drawn from Nature,
or copied from the original figures of various authors,
by Miss Gertrude M. Woodward, to whom I am
much indebted for the care and skill which she has
given to their preparation.

W. T. C.

CONTENTS

CHAPTER PAGE

I. Introductory ------ i

II. The Lobster as a Type of Crustacea - 6

III. The Classification of Crustacea - - - 34

IV. The Metamorphoses of Crustacea - - 66

V. Crustacea of the Seashore - - - - 88

VI. Crustacea of the Deep Sea - 117

VII. Floating Crustacea of the Open Sea - - 138

VIII. Crustacea of Fresh Waters - 157

IX. Crustacea of the Land .... 188

X. Crustacea as Parasites and Messmates - - 207

XI. Crustacea in Relation to Man - - - 237

XII. Crustacea of the Past .... 256

Appendix :

I. Methods of Collecting and Preserving Crus-

tacea - - - - - - - 271

II. Notes on Books - 277

vii

Index

280

LIST OF ILLUSTRATIONS
IN THE TEXT

FIG- PAGE

1. The Common Lobster ( Homarus gammarus), Female,

from the Side ------ 7

2. One of the Abdominal Somites of the Lobster, with

its Appendages, separated and viewed from in
Front ------- 9

3. Third Maxilliped of Lobster - - - 11

4. Walking Legs of Lobster - - - - 12

5. Appendages of Lobster in Front of Third Maxil-

liped ------- 13

6. Dissection of Male Lobster, from the Side - 16

7. Gills of the Lobster, exposed by cutting away the

Side-flap of the Carapace (Branchiostegite) - 18

8. First Larval Stage of the Common Lobster, x 4 - 28

9. Side - view of Rostrum of (A) Common Lobster

( Homarus gammarus) and (B) American Lobster
[Homarus americanus) - - - - 32

10. The “Fairy Shrimp” ( Chirocephalus diaphanus), Male.

x 2 - - - - - - - 35

11. Estheria obliqua , One of the Conchostraca - - 36

12. Daphnia pulex, a Common Species of “Water-flea.”

Much enlarged - - - - - - 37

13. Shells of Ostracoda. Much enlarged - - 38

14. Cyclops albidus, a Species of Copepod found in Fresh

Water - - - - - - 39

15. A Tebalia bipes. Enlarged - - - - - 44

16. Mysis relicta , One of the Mysidacea. Enlarged - 47

17. Gnathophausia willemoesii, One of the Deep-sea Mysi-

dacea. Half Natural Size - - - - 48

8. Diastylis goodsiri, One of the Cumacea. Enlarged - 49

IX

X

THE LIFE OF CRUSTACEA

FIG. PAGE

19. Apseudes spinosus , One of the Tanaidacea. Enlarged 50

20. A Woodlouse ( Porcellio scaber), One of the Isopoda.

Enlarged - - - - - 51

21. An Amphipod ( Gammarus locusta). Enlarged - - 53

22. Two Species of Caprellid^ - - - - 54

23. Paracyamus boopis, the Whale-louse of thf Hump-

back Whale - - - - - 55

24. Meganyctiphanes norvegica , One of the Euphausiacea.

Twice Natural Size - - - - 56

25. Larval Stages of the Common Shore Crab ( Carcinus

mcenas — see Plate IX.) - - - - 68

26. Last Larval Stage of the Common Porcelain Crab

( Porcellana longicovnis — see Fig. 41, P. 113). x 9 70

27. First Larval Stage of Munida rugosa (see Plate VI.)

x 10 - - - - - - 71

28. The Phyllosoma Larva of the Common Spiny Lobster

(Palinurus vulgaris — see Plate V.). Much enlarged 72

29. Larval Stages of the Prawn Pencms (see Plate IV.).

x 45 74

30. Newly - hatched Young of a Crayfish ( Astacus

fluviatilis). Enlarged - - - - 76

31. Young Specimen of an African River Crab ( Potamon

johnstoni), taken from the Abdomen of the Mother.

Much enlarged - - - - - 78

32. Early Larval Stage of a Species of Squilla, prob-

ably S. dubia. x 10 - - - 80

33. Larval Stages of the Brine Shrimp ( Artemia salina)- 81

34. Early Nauplius Larva of a Copepod (Cyclops). Much

ENLARGED - - - - - - - 82

35. Larval Stages of the Common Rock Barnacle

(Balanus balanoides — see Plate III.) - - 83

36. A Common Hermit Crab ( Eupagurus bernhardus) removed

from the Shell- - - - - 91

37. Pylocheles miersii, a Symmetrical Hermit Crab - - 94

38. Callianassa stebbingi (Female), a Sand - burrowing

Thalassinid from the South Coast of England.
Natural Size - - - - - - 103

39. The Common Sand-hopper ( Talitrus saltator), Male,

from the Side, x 3 - - - - - 108

LIST OF ILLUSTRATIONS

xi

FIG.

40. A, a Piece of a Tropical Sea-weed ( Halimeda ) ; B, a

Crab (Huenia proteus) which lives among the Fronds
of Halimeda , and closely resembles them in Form
and Colour. Reduced -----

41. The Common Porcelain Crab ( Porcellana longicornis),

slightly enlarged, and One of the Third Maxil-

LIPEDS DETACHED AND FURTHER ENLARGED TO SHOW

the Fringe of Long Hairs -

42. A Deep-sea Lobster ( Nephropsis stewartii), from the

Bay of Bengal. Reduced -

43. Munidopsis regia , a Deep-sea Galatheid from the Bay

of Bengal. Reduced -

44. Thaumastocheles zaleucus. Reduced

45. A Deep-sea Crab ( Platymaia wyville-thomsoni). Reduced

46. Polycheles phosphorus , One of the Eryonidea, Female,

from the Indian Seas -

47. Eryon propin quus, One of the Fossil Eryonidea, from

the Jurassic Rocks of Solenhofen -

48. Conchcecia curta, an Ostracod of the Plankton, x 40 -

49. Mimonectes loveni. A Female Specimen seen from the

Side and from Below, showing the Distended-
balloon-like Form of the Anterior Part of the
Body, x 3

50. The Zoea Larva of a Species of Sergestes, taken by

the “ Challenger ” Expedition, x 25

51. The Nauplius Larva of a Species of Barnacle of

the Family Lepadid^e, showing greatly-developed
Spines. From a Specimen taken in the Atlantic
Ocean, near Madeira, x ii •

52. Calocalanus pavo , One of the Free-swimming Copepoda

of the Plankton. Enlarged

53. Copilia quadrata (Female), a Copepod of the Family

CORYC/EID.E, SHOWING THE PAIR OF LARGE “TELE-
SCOPIC ” Eyes, x 20

54. Phronima colletti, Male. From a Specimen taken in

Deep Water near the Canary Islands, x 12

55. The Brine Shrimp ( Artemia salina)

56. Chydorus sphcsricus, a Common Species of Water-flea.

x 50

PAGE

no

113

122

123
129

131

133

135

144

145

146

147

148

153

154
164

166

xii THE LIFE OF CRUSTACEA

FIG. PAGE

5 7. A Water-flea ( Daphnia pulex), Female, with Ephip-

PIUM CONTAINING TWO “ RESTING EGGS.” X 20 - 167

58. Bythotrephes longimanus, Female, with Embryos in the

Brood-sac. x 12 - - - - - 169

59. Diaptomus cceruleus, Female, x 25 - - -171

60. Asellus aquaticus, Female, x 4 - - - - 173

61. Map showing the Distribution of Crayfishes - 175

62. A Well Shrimp (Niphargus aquilex). x 7 - - 185

63. The Sea-slater ( Ligia oceanica ). About Twice Natural

Size ....... 200

64. Structure of the Breathing Organs of Porcellio

scaber ------- 202

65. Armadillidium vulgare. x 2\ - - - - 203

66. Two Branches of a Coral ( Seriatopora ) showing

“Galls” inhabited by the Crab Hapalocarcinus
marsupialis. On the Right the Female Crab,

EXTRACTED FROM THE GALL AND FURTHER ENLARGED 211

67. Hyperia galba, Female. Enlarged - - - 213

68. A, The Crab Melia tessellata clinging to a Branch of

Coral, and carrying in Each Claw a Living Sea-
anemone ; B, One of the Claws further enlarged

TO SHOW THE WAY IN WHICH THE ANEMONE IS HELD 2l6

69. The Common Pea Crab ( Pinnotheres pisum ), Female.

Natural Size ------ 217

70. Cirolana borealis. About Twice Natural Size - - 219

71. A, Front Part of Body of a Prawn ( Spirontocaris

polaris), from Above, showing on the Right Side
a Swelling of the Carapace caused by the
Presence of the Parasite Bopyroides hippolytes in
the Gill Chamber ; B, the Female Parasite
extracted and further enlarged ; C, the Male
Parasite on Same Scale as the Female - - 222

72. A Fish-louse ( Caligus rapax ), Female, x 5 - 225

73. Stages of Development of Lerncea branchialis. F is

SLIGHTLY, THE OTHER FIGURES GREATLY, ENLARGED - 226

74. Stages of the Life-history of Hcemocera dance , One

OF THE MONSTRILLID^E - - - - - 229

75. Free - swimming Stages of Sacculina carcini. Much

ENLARGED -

232

LIST OF ILLUSTRATIONS

FIG.

76. Early Stage of Sacculina within the Body of a

Crab -------

77. Rostrum and Fore Part of Carapace, seen from

Above, of (A) Red - clawed Crayfish ( Astacus
fluviatilis ) and (B) White-clawed or English Cray-
fish [Astacus pallipes) - - - - -

78. The Common Shrimp ( Crangon vulgaris). Natural Size

79. The Norwegian Deep-water Prawn ( Pandalus borealis),

Female -------

80. The Gribble ( Limnoria lignorum). Much enlarged

81. Restoration of a Trilobite ( Triarthrus becki), showing

the Appendages. Upper Side on Right, Under
Side on Left. Slightly enlarged -

82. Ceratiocaris papilio , One of the Fossil Phyllocarida -

83. Pygocephalus cooperi, from the Coal-measures : Under

Side of a Female Specimen, showing the Over-
lapping Plates of the Brood-pouch

84. The Tasmanian “Mountain Shrimp” ( Anaspides tas-

manice ), a Living Representative of the Syncarida.
Slightly enlarged -----

85. Prceanaspides precursor, One of the Fossil Syncarida,

from the Coal-measures of Derbyshire. Slightly

ENLARGED -------

FULL-PAGE PLATES

PLATE FACING

I. Male and Female Lobsters, showing the Differ-
ence in the Relative Breadth of the Abdomen
in the Two Sexes. This Figure also illustrates
the Dissimilarity of the Large Claws, and the
Fact that the “Crushing Claw” may be on
either the Right or Left Side of the Body.
[From Brit. Mus. Guide) -----

II. Apus cancriformis from Kirkcudbrightshire. Slightly

ENLARGED -------

xiii

PAGE

234

242

244

246

254

258

262

263

264

265

PAGE

26

63

XIV

THE LIFE OF CRUSTACEA

hi.

FACING TAGE

Group of Specimens of the Goose Barnacle^
(Lepas anatifera ), One showing the Cirri ex-
tended as in Life. Natural Size. ( From Brit.

Mus. Guide) } 42

Group of a Common Species of Acorn-shell or
Rock Barnacle ( Balanus balanoides). Natural
Size

IV. Penceus caramote , from the Mediterranean. About

Half Natural Size. ( From Brit. Mus. Guide) - 57

V. The Common Spiny Lobster ( Palinurus vulgaris).

Much reduced. (From Brit. Mus. Guide) - - 59

VI. Munida rugosa. British. Reduced - - 60

VII. The Common Hermit Crab, Eupagurus bernhardus, in
the Shell of a Whelk. Reduced. ( From Brit.

Mus. Guide) - - - - - 62

VIII. The “Northern Stone Crab,” Lithodes maia.

Much reduced. The Last Pair of Legs are

FOLDED OUT OF SlGHT IN THE GlLL CHAMBERS.

(From Brit. Mus. Guide) - - - 63

IX,

{The Common Shore Crab (Carcinus mcenas). Re-
duced

Dromia vulgaris , carrying on its Back a Mass of
the Sponge, Clione celata. British. Reduced

68

X. Calappa flammea. Brazil. Reduced - - 72

XI. The Giant Japanese Crab, Macrocheira kcempferi.

Male. The Scale of the Figure is given by
a Two-foot Rule placed below the Speci-
men. ( From Brit. Mus. Guide) - - 76

XII. Squilla mantis , from the Mediterranean. About

One-half Natural Size. ( From Brit. Mus. Guide) 80

XIII.

CA Swimming Crab, Portunus depurator. British.
J Reduced

j A Spider Crab, Maia squinado , dressed in Frag-
^ ments of Weeds. British. Reduced

96

LIST OF ILLUSTRATIONS

xv

PLATE

XIV.

r Corystes cassivelaunus. Male (on Left) and Female')
(on Right). British. Reduced !j

Albunea symnista, One of the Hippidea. Indian f
Seas. Reduced J

T Ocypode cursor. West Africa. Reduced
XV. -[ Gelasimus tangeri. Male above, Female below.
West Africa. Reduced

XVI. A Deep-sea Hermit Crab, Parapagurus pilosimanus,
sheltered by a Colony of Epizoanthus. From
Deep Water off the West of Ireland.
Slightly reduced -----

XVII. A Deep - sea Prawn, Nematocarcinus undulatipes.
Slightly reduced. {From Brit. Mus. Guide)

XVIII. Bathynomus giganteus. About One-half Natural
Size. ( From Lankester's “ Treatise on Zoology ,”
after Milne-Edwards and Bouvier)

XIX.

r Latreillia elegans, One of the Dromiacea which'

RESEMBLES A SPIDER CRAB. FROM THE

Mediterranean. Natural Size
The Gulf-weed Crab, Planes minutus. Slightly

ENLARGED

The Murray River “ Lobster,” Astacopsis '
xx spinifer. New South Wales. Much reduced
The Land Crayfish, Engceus cunicularis. Tas-
mania. Natural Size

XXL Palamon jamaicensis. A Large Freshwater
Prawn of the Family Palzemonid^. West
Indies. Much reduced ... -

XXII. Atya scabra. A Freshwater Prawn of the
Family Atyid^e. West Indies. Reduced

(The River Crab of Southern Europe, Potamon
edule (or Telphusa fiuviatilis). Reduced
Sesarma chiragra. A Freshwater Crab of the
Family Grapsidze. From Brazil. Slightly

PAGE

IOO

IO4

124

128

131

155

177

179

180

182

REDUCED

XVI

THE LIFE OF CRUSTACEA

PLATE FACING

XXIV. JEglea Icevis. South America. Natural Size -

XXV. The Blind Crayfish of the Mammoth Cave
of Kentucky, Cambarus pellucidus. Natural
Size ......

XXVI.

'A West Indian Land Crab, Gecarcinus ruricola.'
Reduced

A Land Hermit Crab, Ccenobita rugosa . Re-
duced

XXVII. The Coco Nut Crab, Birgus latro. Much re-
duced

XXVIII. Group of Barnacles, Coronula diadema , on the
Skin of a Whale. Japan. Reduced -

XXIX.

ICymothoa oestrum. An Isopod Parasite of Fish.
Slightly enlarged

Sacculina carcini attached under the Abdomen
of a Common Shore Crab. Reduced

XXX. The “ Norway Lobster,” Nephrops norvegicus.

About One-third Natural Size. ( From Brit.
Mus. Guide ) - - -

XXXI. The Common Edible Crab, Cancer pagurus.
British. Much reduced

XXXII. Piece of Timber from Ryde Pier, showing
Damage caused by Limnoria and Chelura.
{From Brit. Mus. Guide) -

PAGE

184

186

190

196

209

220

240

248

255

THE LIFE OF CRUSTACEA

THE LIFE OF CRUSTACEA

CHAPTER I
INTRODUCTORY

EVERYONE has some acquaintance with the
animals that are grouped by naturalists under
the name Crustacea. The edible Crabs, Lobsters,
Prawns, and Shrimps, are at least superficially
familiar, either as brought to the table or as
displayed in the fishmonger’s, and the most un-
observant of seaside visitors must have had his
attention attracted by living specimens of some of
the more obtrusive species, such as the common
Shore Crab. Many, however, will be surprised to
learn that the Barnacles coating the rocks on the
seashore, the Sand-hoppers of the beach, and the
Woodlice of our gardens, are members of the same
class. Still less is it suspected, by those who have
not given special attention to the subject, that the
living species of the group number many thousands,
presenting strange diversities of structure and habits,
and playing important parts in the general economy
of Nature.

i

2

THE LIFE OF CRUSTACEA

In addition to those just mentioned, a few Crus-
tacea are sufficiently well known to be distinguished
by popular names, such, for example, as Crayfish
and Hermit Crabs, but for the vast majority no
names are available except those of technical
zoology. In the following pages, therefore, while
technical terms have been introduced as sparingly
as possible, the unfamiliarity of the animals them-
selves makes it needful to use many unfamiliar
names.

In the classification of the Animal Kingdom, the
Crustacea form one of the divisions of a compre-
hensive group, or Phylum, known as Arthropoda.
The typical members of this group have a more or
less firm external skeleton, the body is divided into
segments, there are jointed limbs, and some of these
are modified to serve as jaws. The chief divisions
or classes of the Arthropoda are — (i.) Insecta, in-
cluding Butterflies, Moths, Bees, Wasps, Flies,
Beetles, and the like ; (ii.) Chilopoda, or Centipedes ;
(iii.) Diplopoda, or Millipedes1; (iv.) Onychophora, in-
cluding the curious worm-like Peripatus ; (v.) Arach-
nida, or Scorpions, Spiders, Mites, and their allies ;
and (vi.) Crustacea.

It is not easy to summarize in a few words the
characters common to all Crustacea, and distinguish-
ing them from the other groups of Arthropoda. As

1 The Chilopoda and Diplopoda are sometimes regarded as
forming a single class — Myriopoda.

INTRODUCTORY

3

a rough guide to classification, it is useful to remember
that an Insect can generally be recognized by having
three pairs of walking legs, an Arachnid by having
four pairs, and a Centipede or Millipede by having a
great many pairs, all nearly alike. The Crustacea,
on the other hand, show great diversity in the number
and arrangement of their walking or swimming legs,
but they rarely show any special resemblance to those
of the other large groups of Arthropoda. Thus, for
example, a common species of Woodlouse, Armadil-
lidium vulgare , is very similar at first sight to the
Millipede Glomeris marginata , but it has only seven
pairs of walking legs, while the Millipede has seven-
teen or nineteen pairs.

More precisely, it may be said of the great majority
of Crustacea that they are aquatic animals, breathing
by gills or by the general surface of the body, having
two pairs of “ feelers,” or antennae, on the front part
of the head, and at least three pairs of jaws. Excep-
tions to each of these statements will be mentioned
in later chapters in dealing with parasites and other
highly modified types. In such cases, however, the
larval or young stages afford indications of affinity,
and comparison with less modified forms enables us
to trace a connection with the typical Crustacea.

The best way to form a conception of a group ot
animals, however, is not to attempt in the first place
to define its limits, but to begin by studying the
structure of some typical and central species, and

4

THE LIFE OF CRUSTACEA

afterwards to note the divergences from this type
presented by other members of the group. Speaking
very generally, it may be said that these divergences
are of two kinds. On the one hand there are char-
acters that have no apparent relation to the animal’s
habits and mode of life, and on the other hand there
are modifications of structure which are more or less
plainly of use to the animal. It is to characters of
the former class that we look for evidence of an
animal’s affinities, and it is upon them that our
systems of classification are chiefly based. The
characters of the second class — “ adaptive ” char-
acters, as they are called — become of importance
when we study the animal “as a going concern,”
so to speak, and endeavour to understand how its
life is carried on in relation to its surroundings.

In pursuance of this plan of study, the next chapter
will be devoted to a description of the Common
Lobster as a type of the Crustacea. In the third
chapter a survey of the classification of the group
will be given ; since, however, the characters on
which the classification is based cannot be explained
fully without entering into technical details which
are beyond the scope of this work, this survey will
be restricted to what is necessary for comprehension
of the succeeding chapters. In the fourth chapter
some account is given of the young or larval stages
of Crustacea, and of the changes they undergo in the
course of development.

INTRODUCTORY

5

In the next five chapters the Crustacea are classified
according to their habitats, and those living in the
shallow waters, the depths, and the surface of the
ocean, in the fresh waters, and on land, are discussed
in turn ; while a separate chapter is devoted to the
curious forms that live as parasites on, or as associates
with, other animals. The last two chapters deal
respectively with the Crustacea as they affect man,
and with the past history of the group as revealed
by fossil remains.

CHAPTER II

THE LOBSTER AS A TYPE OF CRUSTACEA
HE most noticeable feature distinguishing the

J- Lobster1 (Fig. i) at first sight from other
familiar animals is the jointed shelly armour that
encases its body and limbs. Over the fore part of
the body this armour is continuous, forming a shield,
or carapace , which projects in front, between the
eyes, as a toothed beak, or rostrum ; on the hinder
part — the tail, or abdomen — it is divided into six
segments, or somites , connected with each other by
movable joints. Each of these somites carries on
the under-side a pair of fin-like limbs, or swimmerets ,
the last pair of which (uropods) are much larger than
the others, and are spread out at the sides of a middle
tail-plate, or telson, forming what is known as the
tail-fan. Since the fore part of the body also has a
series of paired limbs, constructed, as will be shown

1 The account given here of the structure of the Lobster
applies almost equally well to the River Crayfish or the Norway
Lobster. The student is recommended to follow the description
with a specimen of one of these animals before him.

6

THE LOBSTER AS A TYPE OF CRUSTACEA 7

later, on the same plan as the swimmerets, it is
concluded that this part also is built up of somites,
which have become soldered together. That this
conclusion is correct is shown by comparison with
some of the lower Crustacea in which this part of
the body is divided up into eight separate somites,
like those of the abdomen, each carrying, in place of

Fig. 1 — The Common Lobster ( Homarus gammarus), Female,
from the Side. (From British Museum Guide.)

the swimmerets, a pair of walking legs. In front of
these eight somites, forming what is called the thorax ,
is the head — a part of the body which is never, in
any Crustacean, broken up into distinct somites, but
which, since it carries five pairs of appendages, must
consist of at least five somites. The part of the
body covered by the Lobster’s carapace includes
both the head and the thorax, and is known, there-

8

THE LIFE OF CRUSTACEA

fore, as the cephalotkorax. It is necessary to bear in
mind that the parts of the body to which the names
head, thorax, and abdomen, are applied in Crustacea
are by no means exactly equivalent to those which
bear the same names in Insects, for example, and
that, beyond a rough similarity in position, they
have no sort of relation to the parts so named in the
body of a vertebrate animal.

There are altogether twenty pairs ot appendages
attached to the body of the Lobster. In front of the
head are the stalked eyes (of which the nature will be
discussed later) and two pairs of feelers — the anten-
nules and antennce (sometimes called the first and
second antennae). Near the mouth on the under-
side of the head are three pairs of jaw-appendages
— the strong mandibles and the flattened, leaf-like
maxillulce and maxillce. Following these are the
appendages of the thorax, of which the first three
are intermediate in form between the true jaws and
the legs, and are therefore termed foot-jaws, or
maxillipeds. The remaining five pairs of thoracic
limbs are the legs , the first pair forming the large
and powerful pincer-claws, or chelipeds, while the
others are the walking legs. The six pairs of
swimmerets on the abdomen have already been
mentioned.

If one of the somites of the abdomen be separated
from the others, it will be seen (Fig. 2) to consist of
a shelly ring, to which the two swimmerets are

THE LOBSTER AS A TYPE OF CRUSTACEA g

attached, wide apart, on the under-side. The arched
upper part of the ring is known as the tergum , and
the more flattened under-part as the sternum. On
each side the tergum overlaps the sternum, and
hangs down as a side-flap, or pleuron. On the
upper side of the abdomen
the terga of the somites
overlap, the front part of
each being pushed under
the tergum in front when
the abdomen is straight-
ened, and only exposed to
view when the abdomen is
bent. Below, the sternum
of each somite is seen to
be only a narrow bar, con-
nected with those in front
and behind by soft mem-
brane, and there is no over-
lapping. At the sides the somites are connected
together by hinge-joints, which allow them to move
only in a vertical plane. Thus the abdomen can be
straightened out or bent downwards and forwards,
but cannot be moved from side to side. In life the
Lobster can swim backwards through the water by
vigorously flapping the abdomen.

The carapace which covers the upper side of the
head and thorax is not formed, as might be thought,
simply by the terga of the somites becoming soldered

Fig. 2 — One of the Ab-
dominal Somites of the
Lobster, with its Appen-
dages, SEPARATED AND
VIEWED FROM IN FRONT.

(From British Museum
Guide.)

10

THE LIFE OF CRUSTACEA

together. This is shown by a comparison with
certain shrimp-like Crustacea ( Mysidacea ) in which
the carapace arises, like a fold of the skin, from the
hinder edge of the head, and envelops, like a loose
jacket, the distinctly segmented thorax. In the
Lobster this fold has become adherent to the
thoracic somites down the middle of the back, but
at the sides it hangs free, enclosing on each side
a cavity within which lie the gills.

It seems at first sight strange to include in the
same category as “ limbs” or “ appendages ” organs
which differ so much in form and function as do
the swimmerets, the walking legs, the jaws, and the
antennae. Nevertheless it can easily be demon-
strated that all of them are constructed on the same
general plan, and arise in the embryo from rudiments
which are, for the most part, exactly alike. This is
expressed in technical language by saying that the
appendages of the whole series are homologous with
one another. A full discussion of this interesting
fact would require more space than can be devoted
to it here, but a few examples may be given to illus-
trate what is meant by the “ serial homology ” of
the appendages in Crustacea.

If one of the swimmerets be detached from the
third abdominal somite, it will be seen (Fig. 2) to
consist of a stalk, known as the protopodite, bearing
two branches, of which that on the outer side is
called the exopodite , and that on the inner side the

THE LOBSTER AS A TYPE OF CRUSTACEA n

endopodite. The protopodite consists of two seg-
ments, the first very short, and the second much
longer. It can easily be seen that the side-plates of
the tail-fan (the middle plate, as already mentioned,
is the telson) are simply the swimmerets of the sixth
abdominal somite. They are much larger than the
other swimmerets, and have the endopodite and
exopodite broadened
out into large plates ;
while the protopodite
is very short, and not
divided into segments.

If now the third max-
illiped (Fig. 3) be ex-
amined, it will be found
that, like the swim-
meret, it consists essen-
tially of two branches springing from a stalk of
two segments. The exopodite, however, is much
smaller than the endopodite, and it ends in a flexible
lash made up of many small segments. The endo-
podite forms the main part of the limb, and has
five segments, so that, with the two segments of the
protopodite, there are seven segments in the main
axis of the limb ; the second and third segments
are partly soldered together, but the line of union
can be plainly seen. Attached to the outer side of
the first segment is a membranous plate, known as
the epipodite , on which is inserted, near its base, a

Fig. 3 — Third Maxilliped of
Lobster. (From British Mu-
seum Guide.)

12

THE LIFE OF CRUSTACEA

brush-like structure, which is one of the gills. In
the natural position the epipodite and its gill lie in
the gill chamber, hidden from view by the side-flap
of the carapace.

The legs (Fig. 4) can, without difficulty, be seen
to consist each of seven segments like those of the

maxillipeds, but there
is no exopodite. In the
young Lobster, when
just hatched from the
egg, however, each of
the legs has a large
exopodite like that of
the third maxilliped.
These exopodites, which
are used in swimming,
are afterwards lost as
the animal grows ; but
their presence in the
young is interesting as
confirming the conclusion that the legs, like the
maxillipeds, are built on the same plan as the swim-
merets. The large claws, and also the first and
second pairs of walking legs, end in pincers, or chelcz,
the penultimate segment projecting in a thumb-like
process against which the last segment works. Each
leg, except those of the last pair, has on its first
segment an exopodite with a gill like those of the
maxilliped.

Fig. 4 — Walking Legs of
Lobster

A, Of first pair ; B, of third pair

THE LOBSTER AS A TYPE OF CRUSTACEA 13

Following the series of appendages forwards from
the third maxilliped (Fig. 5), it is easy to trace the
gradual reduction of the endopodite and exopodite ;

Fig. 5 — Appendages of Lobster in Front of Third Maxilliped

A, Eye-stalk ; B, antennule ; C, antenna (the flagellum is cut short) ;
D, mandible; E, maxillula ; F, maxilla; G, first maxilliped ; H,
second maxilliped. en, Endopodite ; ep, epipodite ; ex, exopodite ;
gn, gnathobases, or jaw-plates; p , palp of mandible; sc, scapho-
gnathite

14

THE LIFE OF CRUSTACEA

while the two segments of the protopodite become
flattened and broadened inwards to form the jaw-
plates. The mandibles (Fig. 5, D), which are the
chief organs of mastication, consist mainly of the
much enlarged basal segment of the protopodite,
with a strongly toothed inner edge, where it works
against its fellow of the opposite side ; and the rest
of the limb is reduced to a small sensory “ palp,”
which represents the second segment of the protopo-
dite and the endopodite.

The antennae (Fig 5, C) can be shown, without
difficulty, to conform to the same plan of structure
as the other appendages. The two segments of the
protopodite are short, but distinct ; the endopodite
forms the long lash, or flagellum , composed of very
numerous small segments ; the exopodite is reduced
to a small movable scale or spine.

The antennules (Fig 5, B) seem at first sight to
present the two-branched type of structure in its
simplest form ; but there is considerable doubt as to
whether the two lashes which each bears on a three-
segmented stalk are really equivalent to the endopo-
dite and exopodite.

The movable stalks which carry the eyes (Fig. 5, A)
have been considered by some to belong to the series
of the appendages, and to be, in fact, modified limbs.
If this be the case, we have here the greatest simpli-
fication which the limb undergoes in the Lobster, for
each eye-stalk consists only of two segments : the

THE LOBSTER AS A TYPE OF CRUSTACEA 15

first small and incompletely formed, the second in
the form of a short cylinder, having the eye at
its end. There are, however, reasons for doubting
whether the eye-stalks are really appendages.

The hard outer covering of the Lobster not only
protects and gives support to the internal organs,
but also affords points of attachment for the muscles
by means of which the animal moves. In other
words, it plays the part of a skeleton ; but since,
unlike the skeleton of vertebrate animals, it is outside
instead of inside the soft parts of the body, it is
known as an exoskeleton. Closer examination shows
that this outer covering is really continuous over the
whole of the body and limbs, but is thin and soft
at the joints, allowing the parts to move one upon
another. It is composed of a horn-like substance
known as chitin , which, except at the joints, is
hardened by the deposition in it of carbonate and
other salts of lime.

As this external covering does not increase in size
after it has been formed, and as it cannot stretch to
any great extent, the Lobster requires to cast its
shell at intervals as it grows. In this process of
moulting the integument of the back splits between
the carapace and the first abdominal somite. The
body and limbs are gradually worked loose and
withdrawn through the opening, leaving the cast
shell with all its appendages almost entire. The
new covering, which had been formed underneath the

i6

THE LIFE OF CRUSTACEA

old before moulting, is at first quite soft, and the
animal rapidly increases in size owing to the absorp-
tion of water. The shell then gradually hardens by
the deposition of lime salts.

The internal anatomy (Fig. 6) presents many points
of interest which can only be briefly touched on here.
The food-canal consists of a short gullet leading into
a capacious stomach, from which the straight in-

Ofiening of Liver- (fuel
Op,tic Nerve * Heart

\ Brain l^er

Stomach

Superior alt dominOl artery
Intestine

First Ganglion of
Ventral Nerve-chai-n

Fig. 6 — Dissection of Male Lobster, from the Side. (From
British Museum Guide.)

testine runs to the vent on the under-side of the
telson. The stomach has a most remarkable and
complicated structure. It consists of two chambers,
a larger in front and a smaller behind, which are
lined by a continuation of the chitinous outside
covering of the body. This chitinous lining is
thickened in places to form a system of plates and
levers connected with three strong teeth set in the
narrow opening between the two chambers. By the

THE LOBSTER AS A TYPE OF CRUSTACEA 17

action of muscles attached to certain of these plates
the teeth work together so as to divide up the food
more finely than had been done by the mandibles
and other jaws. The whole apparatus, in fact, serves
as a kind of gizzard, and is known as the gastric
mill .

A small part of the intestine at the hinder end is
lined, like the stomach, by a continuation of the
chitinous covering, which is turned in at the vent.
This lining and that of the stomach, with the plates
and teeth of the gastric mill, are cast and renewed
when the shell is moulted.

On each side of the food-canal in the thorax lies a
large mass of soft tissue, yellowish-green in colour.
This is the digestive gland, or “ liver,” which secretes
the digestive juice, discharging it into the food-
canal by a short duct on each side just behind the
stomach.

The heart lies in the middle of the back, just under
the hinder part of the carapace, and gives off, in
front and behind, a number of arteries which carry
the blood to the various organs of the body. From
the smaller branches of these arteries the blood
passes, not, as in vertebrate animals, into capillaries,
but into the spaces lying between the organs of the
body, and it finds its way back to the heart, not in
definite veins, but by ill-defined venous channels
which open into the pericardium, or space surround-
ing the heart. From the pericardium the blood

i8

THE LIFE OF CRUSTACEA

enters the heart by six openings in its walls, each
guarded by a pair of valves which close when the
heart contracts, and prevent the blood from returning
to the pericardium.

The venous channels which convey the blood
back to the heart are so arranged that most of the

Fig. 7 — Gills of the Lobster, exposed by cutting away the
Side-flap of the Carapace (Branchiostegite)

blood passes first through the gills , for the purpose
of respiration, before it reaches the heart and is
again distributed through the body. These gills,
as already mentioned, lie in the two branchial
chambers under the side-flaps of the carapace
(Fig. 7), and are attached, some to the epipodites
of the thoracic limbs (as described above), and
some to the soft membrane of the joints between
the limbs and the body; while others are attached

THE LOBSTER AS A TYPE OF CRUSTACEA 19

to the side-wall of the thorax itself. Each gill is
somewhat like a bottle-brush in shape, consisting
of a central stalk set round with rows of soft hair-
like processes. As the blood streams through the
minute channels inside these filaments, it is separated
only by a thin membrane from the surrounding
water, and the absorption of oxygen and discharge
of carbon dioxide can go on easily. For this purpose,
however, it is necessary that the water within the
gill chamber should be constantly renewed, and this
is effected in the following way : the front part of
the gill chamber forms a narrow channel running
forward under the side - wall of the carapace.
Within this channel lies a large plate known as the
scaphognathite, attached to the outer side of the
maxilla, which during life is constantly in move-
ment, causing a current of water to flow forwards
through the channel. The water enters the gill
chamber by the narrow slit-like space between the
lower edge of the carapace and the bases of the
legs, and is discharged in front at the sides of the
head, where its movement is helped by the vibrating
exopodites of the maxillipeds.

At the sides of the stomach, in the front part of
the head, lie a pair of glands which, from their
colour, are known as the green glands. These are
the excretory organs, corresponding in function to
the kidneys of the higher animals. Each has con-
nected with it a thin-walled bladder, which opens to

20

THE LIFE OF CRUSTACEA

the outside through a small perforation on the
under-side of the first segment of the antenna.

The chief part of the nervous system is the ventral
nerve-chain, which runs along the under-side of the
body. This is a long cord having at intervals a
series of knots or swellings, the ganglia or nerve-
centres, from which nerves are given off to the
appendages and to the organs of the body. In the
hinder part of the thorax and in the abdomen there
is a ganglion in each somite, but in front these
ganglia become crowded together and coalesced, so
that we find only a single large ganglion, correspond-
ing to the somites from that of the mandibles to
that of the third maxillipeds. Between the ganglia
the cord is really double, although for the greater
part of its length the two parts are more or less
completely fused into one. In front of the head and
above the gullet is a ganglion which sends nerves to
the eyes, antennules and antennae, and is known as
the brain , although it is, perhaps, hardly so important
as that name would suggest. It is connected with
the ventral chain by two cords that pass on either
side of the gullet.

The eyes , as already mentioned, are set on movable
stalks, so that they can be turned in any direction at
the will of the animal, and are of the type known as
“ compound eyes.” If the convex black area at the
end of the eye-stalk be examined with a strong lens,
it will be seen that the membrane which covers it is

THE LOBSTER AS A TYPE OF CRUSTACEA 21

divided up into a beautifully regular series of square
facets. This membrane is a thin and transparent
continuation of the chitinous covering of the body,
and if it be stripped off and examined under a micro-
scope, it will be found that each facet is capable of
acting as a lens and forming an image of external
objects. It is not to be supposed, however, that the
Lobster sees a separate image in each of the facets,
some thirteen thousand in number, which go to
make up each eye. In the interior of the eye, at
some distance from the surface, are a large number
of rod-like bodies, connected with the fibres of the
optic nerve, and believed to be the actual organs for
the perception of light. Each rod corresponds to
one of the facets, and as it lies at the bottom of a
long conical tube, of which the walls are covered
with dark pigment, it can only receive light from a
single point in line with the axis of the tube. In
this way the image of any object will be built up,
like a mosaic, out of the impressions of light and
darkness received through the separate facets, and
transmitted to the underlying rods. It has been
shown in some Crustacea that, when the animal is
in a very dim light, the curtain of pigment separating
the tubes is partially withdrawn, so that the light
from each facet can reach, not one, but several rods.
In this way the images of objects received are much
brighter, although they are less sharply defined.

It might be thought that in animals like the

22

THE LIFE OF CRUSTACEA

Lobster, enclosed in a hard shelly covering, the sense
of touch must be very dull, if not altogether absent.
This, however, is not the case. What is probably a
very delicate tactile sense is provided for by the
numerous hairs which are found, of many sorts and
sizes, all over the body and limbs. Each of these
hairs is really a hollow outgrowth of the chitinous
covering, containing a delicate prolongation of the
soft tissues underneath, and also supplied, in many
if not in all cases, with a nerve-fibre, so that the
slightest movement of the hair caused by contact
with a solid body is perceived by the animal. Many
of these hairs are themselves beset with delicate
secondary hairs, arranged so that the whole looks
like a feather or like a bottle-brush. These hairs
are adapted for detecting slight movements or vibra-
tions in the surrounding water.

Whether Crustacea living in water can hear , in
the sense in which the word is used of animals
living in air, is doubtful ; but it is certain that they
are extremely sensitive to vibrations only a little
coarser, so to speak, than those we know as sound.
The Lobster, and many other Crustacea, do indeed
possess a structure which was long supposed to be
an organ of hearing, and may possibly in part fulfil
that function, although it is now known that that is
not its only or even its chief use. It consists of a
small cavity in the basal segment of the stalk of the
antennule, opening to the outside by a narrow slit

THE LOBSTER AS A TYPE OF CRUSTACEA 23

on the upper surface of the segment. The cavity is
lined by a delicate continuation of the chitinous
covering of the body, and has on its inner surface a
series of feathered hairs of the kind described above,
which are richly supplied with nerve-fibres from a
large nerve entering the base of the antennule.
Within the cavity, and for the most part entangled
among these hairs, are a number of grains of sand.
When the Lobster moults, the lining membrane of
this cavity is thrown off like the rest of the exo-
skeleton, and with it the contained sand-grains.
While the shell is still soft after moulting, and the
lips of the slit are not rigid, as they afterwards
become, fresh sand-grains find their way into the
cavity to take the place of those which have been
cast off. Perhaps, like some other Crustacea, the
Lobster buries its head in the sand to insure that
some grains may find their way in ; for its pincers
are too clumsy for it to pick up sand-grains and to
place them in the cavity, as some Prawns have been
seen to do. At all events, if a freshly moulted
Prawn be placed in a vessel of sea-water, and
supplied, instead of sand, with powdered glass or
metal filings, particles of glass or metal will after a
short time be found in its antennular cavities. This
habit has been utilized in a very ingenious experi-
ment by which the function of these organs was
demonstrated. A Prawn had been induced in this
way to place particles of iron filings in the cavities,

24

THE LIFE OF CRUSTACEA

and a strong electro-magnet was brought near the
side of the vessel in which it was kept. It was
observed that the Prawn, which had been swimming
in the usual horizontal position, at once turned the
under-side of its body towards the magnet, and swam
about on its side as long as the magnet was in
action. When the current exciting the magnet was
cut off, the animal resumed its ordinary position.
This experiment shows that these organs, to which
we may now give their proper name of statocysts ,
are organs for perceiving the direction of the force
of gravity. The magnetic force acted on the
particles of iron in the same way that the force of
gravity acts on the sand-grains in normal conditions,
and the Prawn felt the weight of them, so to speak,
pulling towards the side instead of the bottom ot
the vessel, and turned its body accordingly, to swim,
as it supposed, right side up. It is now known that
those parts of the human ear called the “ semi-
circular canals ” have a somewhat similar function
as “ organs of orientation,” although to animals
walking on the solid ground this function is not so
important as it doubtless is to animals swimming in
water.

The sense of smell is believed to have its seat
chiefly in the antennules. The outer branch of each
antennule bears tufts of peculiar hairs, in which the
chitinous covering is extremely delicate, so that sub-
stances dissolved in the water can easily pass through

THE LOBSTER AS A TYPE OF CRUSTACEA 25

and affect the nerve-endings within. These hairs are
known as “ olfactory filaments.”

The sense of taste in aquatic animals is, perhaps,
not sharply defined from that of smell, but it is
not very rash to assume that certain hairs on the
mouth parts and on the fleshy upper and lower lips
which bound the opening of the mouth have to do
specially with this sense.

The relative importance of the various senses in
the Lobster is well illustrated in the following account
of its habits given by Dr. H. C. Williamson in the
Report of the Scottish Fishery Board for 1904.
After noticing that, in daylight at least, the Lobster
appears to be “ purblind,” only distinguishing light
from shadow, Dr. Williamson goes on : “ It tests
a shadow with its antennae, or sometimes, when a
strong shadow is thrown on it, it jumps at it with
its chelae outstretched and snapping. It is dependent
on its antennae for guiding it in safe places. It
is especially careful in testing any hole before it is
satisfied with it. It discovers the cavity by means
of its antenna, which is waved well out to the side
and in front as it walks. It searches the innermost
depths of the hole with the antenna, and then inserts
its chela. If the examination with the chela is also
satisfactory, it immediately turns and backs smartly
into the hole. In feeding it is guided to the food by
the antennules. A piece of food which is dropped
near a Lobster may fall quite unnoticed unless it

26

THE LIFE OF CRUSTACEA

happens to touch the antenna or the [legs]. It is
not seen at all. But sooner or later, according as
the distance is short or great, the scent of the food,
carried by the currents set up by the exopodites of
the maxillipeds, reaches the Lobster. The Lobster
is immediately excited, although previously it was
lying quite inert in its hole. It whips the water
with its antennules in a staccato fashion, and feels
about with the antennse and chelae, at first without
leaving its hole. At once both antennules are seen
to be whipping in the direction in which the food
is lying, and an active search is made with the
antennae. If they do not succeed in locating the
bait, the lobster rather reluctantly leaves its hole,
but cautiously, feeling all round about with its
antennae. It goes off straight in the direction in
which the food is lying, and, if it misses it with its
antennae and chelae, walks over it and gets it with
its chelate [walking legs]; it usually picks up its
food with the second [walking leg]. Meanwhile
the expected feast has by association stimulated the
maxillipeds, which are actively working as if they
were already masticating the food. Once the food
is seized it is conveyed to the maxillipeds, and the
Lobster retreats to its hole, there to enjoy its meal.”

Lobsters, like most other Crustacea, are of separate
sexes. The females (see Plate I.) may be distin-
guished from the males by the fact that the abdomen
is broader and has deeper side-plates, and by differ-

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THE LOBSTER AS A TYPE OF CRUSTACEA 27

ences in the form of the first two pairs of swimmerets.
In the female the first pair, which have only one
branch, are short and slender filaments, while in
the male they are stout and peculiarly twisted rods.
The second pair in the female are similar in form to
the succeeding pairs, but in the male they have an
additional lobe on the inner branch. The openings
of the generative organs will be found in the male
on the basal segments of the last pair of legs, while
in the female they occupy the same position on the
legs of the last pair but two. The testis of the male
lies in the thorax, just below the heart. The ovary,
which has the same position in the female, is usually
much more conspicuous, and from its red colour in
the cooked lobster it is known as the “ coral.” On
the under-side of the thorax of the female, between
the last two pairs of legs, is a three-lobed structure
enclosing a cavity known as the “sperm-receptacle.”
Its function is to receive the fertilizing substance
from the male, and to retain it until the eggs are
ready to be deposited.

In the Lobster, as in many other Crustacea, the
eggs are carried by the female until they hatch.
After being extruded from the oviducts, they are
attached by a kind of cementing substance to the
swimmerets, where they hang in bunches. The
swimmerets are kept constantly moving, so that the
eggs may obtain the oxygen necessary for the de-
veloping embryos within. A female Lobster carrying

28

THE LIFE OF CRUSTACEA

eggs in this way is said by the fishermen to be “ in
berry,” and may carry, according to its size, from
about 3,000 to nearly 100,000 eggs. A period of
about ten months elapses between the deposition
of the eggs and hatching.

The young Lobster when first hatched (Fig. 8)
differs considerably in general appearance from the

adult animal. The
abdominal somites
have a row of spines
down the middle of
the back, and the
telson has a forked
shape. There are no
swimmerets, but, as
already mentioned, the legs bear large exopodites,
which are used like oars, and by means of these
the larval Lobster swims about at the surface of the
sea. The claws or chelae are at first hardly larger
than the other legs, but later they increase in size,
the swimmerets are developed, the exopodites of
the legs are lost, and the young Lobster, sinking to
the bottom of the sea, takes on the creeping habits
and gradually assumes the shape of the adult.

In many Crustacea the changes of shape or meta-
morphoses undergone after hatching are much
greater than in the Lobster. Some of these changes
and their probable significance will be considered at
greater length in a later chapter.

Fig. 8 — First Larval Stage of
the Common Lobster, x 4.
(After Sars.)

THE LOBSTER AS A TYPE OF CRUSTACEA 29

The two large claws of the Lobster (see Plate I.)
are not quite alike in size or in shape. The smaller
of the two has the inner edges of the fingers sharp
and set with saw-like teeth ; the larger has the
fingers armed with blunt rounded knobs. The
larger claw is adapted for crushing the shells of the
animals on which the Lobster feeds, while the smaller
serves for holding and tearing the prey. In the
Lobster, as in many of the higher Crustacea in which
this asymmetry occurs, the larger claw may be
indifferently on either side of the body. There are
certain cases, however, among Crabs where the large
claw is constantly on the same side of the body, or,
in other words, all the individuals are either right-
handed or, more rarely, left-handed.

If a Lobster be caught by one of its claws or by a
leg, it very readily parts with the limb in its struggles
to escape ; and if one of the limbs be crushed or
otherwise injured, it is often cast off by the animal.
The separation always takes place at the same point,
near the base of the limb, and is not simply due to
the limb breaking at its weakest part. It is a reflex
act, brought about by a spasmodic contraction of
some of the leg muscles. At the place of separation,
corresponding to the junction of the second and
third segments of the limb, which, as already men-
tioned, are soldered together, the internal cavity is
crossed by a transverse partition, having only a small
aperture in the centre through which the nerves and

30

THE LIFE OF CRUSTACEA

bloodvessels pass. When the limb is cast off, this
small opening quickly becomes closed by a clot of
blood, and further bleeding is stopped. If, as some-
times happens, a limb which has been seriously
injured is not cast off, the animal not infrequently
bleeds to death. This power of self-mutilation or
autotomy, as it is called, is frequently used by Crus-
tacea as a means of escaping from their enemies,
and is closely connected with the power of regenera-
tion of lost appendages. Beneath the scar which
forms on the stump of a separated limb a sort of
bud grows, and gradually assumes the form of the
lost segments. At the next moult this straightens
out, and, increasing in size at succeeding moults, it
ultimately provides, in normal cases, a new member
similar in every detail to that which had been lost.
Occasionally it happens, under circumstances not
yet altogether understood, that the process of re-
generation may, so to speak, go wrong, and in this
way various malformations and abnormalities result.
For instance, it has been found that, if the larger,
crushing claw of a very young Lobster be removed
by operation or by accident, the limb which grows
in its place may assume the form of the smaller,
toothed claw. Further, in some other Crustacea
(but not in the Lobster, except in the very youngest
stages), it is found in such cases that, after removal
of the large claw, the claw of the other side assumes
at the next moult the form of a crushing claw, so
that there is a “ reversal of asymmetry.”

THE LOBSTER AS A TYPE OF CRUSTACEA 31

A still more remarkable change sometimes occurs
when one of the eye-stalks is injured. If only the tip
of the eye-stalk be cut off, so that the nerve-ganglion
which lies in the basal part of the stalk remains
uninjured, it will be found that a normal eye is in
course of time regenerated. If, however, the whole
eye-stalk be amputated, and with it the optic ganglion,
there grows in its place, not a new eye-stalk, but a
segmented appendage similar to one of the flagella of
the antennules. This fact is considered by some
zoologists to indicate that the eye-stalks are, like the
antennules, true appendages, homologous with the
mouth parts and limbs, but this is a much-disputed
question into which we cannot enter further here.

Lobsters vary a good deal in colour, but as a rule
a living Lobster is of a more or less mottled dark blue*
becoming nearly black on the back, and shaded off
into orange yellow or red on the under-side. This
coloration resides in the shell, and does not change
much after the shell has hardened. In this respect
the Lobster is unlike many of the smaller Crustacea
which have a thin and more or less transparent
exoskeleton, and in which the colour resides in certain
living cells (chromatophores) of the underlying
skin. Many of these Crustacea possess the power
of changing their colours to a remarkable degree,
by the expansion and contraction of the branched
chromatophores.

The question which is often asked, “ Why does a

32

THE LIFE OF CRUSTACEA

Lobster turn red when it is boiled ?” is one to which
it is not easy to give a simple answer. A chemical
change takes place under the influence of heat in the
pigment of the shell, which changes it from blue to
red ; how slight the change is, is perhaps shown by
the fact that occasionally living Lobsters are found of
a red colour almost as brilliant
as that which is assumed on
boiling.

The Common Lobster is found
on the coasts of Western
Europe, from Norway to the
Mediterranean, living in shallow
water, generally a little way
below low-tide mark, wherever
a rough, rocky bottom affords
suitable lurking-places. On the Atlantic coast of
North America, Lobsters are also found abundantly
in similar situations. These American Lobsters, if
examined carefully, will be found to differ from the
European kind in certain small details of structure,
of which the most conspicuous is the presence, on the
under-side of the rostrum, of two spines or teeth. In
the European Lobsters the under-side of the rostrum
is smooth (Fig. 9). In the nomenclature of technical
zoology, these two kinds or species of Lobster are said
to constitute (along with a third species found at the
Cape of Good Hope) the genus Homarus, the
European species being known as Homarus gam-

A.

B.

Fig. 9— Side-view of
Rostrum of (A)
Common Lobster
( Homarus gammarus)
and (B) American
Lobster ( Homarus
americanus)

THE LOBSTER AS A TYPE OF CRUSTACEA 33

marus, and the American as Homarus americanus.
The so-called “ Norway Lobster ” or “ Dublin
Prawn,” which differs from the Common Lobster in
having large kidney-shaped eyes and long and
slender claws, and in many other details of structure,
is placed in a distinct genus, and is known as Nephrops
norvegicus. The genera Homarus and Nephrops ,
together with some others, constitute the family
Homaridae, which again is grouped with other
families in a tribe, Nephropsidea, forming a part
of the order Decapoda. These groups are intended
to express the varying degrees of resemblance and
difference in structure between the species of animals
which make up the class Crustacea. Since we have
good grounds for believing that all these species have
arisen by some mode of evolution, this classification
also represents the varying degrees of actual rela-
tionship between the different forms, so far as this
relationship can be discovered. In the next chapter
a brief sketch of the chief subdivisions of the
Crustacea is given, with such details as to the
characteristics of each as are necessary to render
intelligible the succeeding chapters on their habits
and modes of life.

3

CHAPTER III

THE CLASSIFICATION OF CRUSTACEA

Table of Classification of Crustacea

Class CRUSTACEA.

Subclass Branchiopoda

OSTRACODA

COPEPODA

'Order

-{

Series

ClRRIPEDIA - |

Malacostraca.
LEPTOSTRACA -
EUMALACOSTRACA.
Division Syncarida

Peracarida

Eucarida

Hoplocarida

I

\

99

99

99

99

Anostraca.

Notostraca.

Conchostraca.

Cladocera.

Myodocopa.

Podocopa.

Eucopepoda.

Branchiura.

Thoracica.

Rhizocephala.

Nebaliacea.

Anaspidacea.

Mysidacea.

Cumacea.

Tanaidacea.

Isopoda.

Amphipoda.

Euphausiacea.

Decapoda.

Stomatopoda.

OCCASIONALLY there may be found in rain-
water puddles and the like, in the South of
England, a beautiful, transparent, shrimp-like animal,
an inch or more in length, to which the name of

34

THE CLASSIFICATION OF CRUSTACEA 35

“ Fairy Shrimp” has been given (Fig. 10). It is
known in technical zoology as Chirocephalus di-
aphanus, and is a representative of the subclass
Branchiopoda. The members of this group are
distinguished from other Crustacea by their flattened,
leaf-like feet, each of which is divided into a number
of lobes, and has a gill plate on the outer side. In
Chirocephalus there is no carapace, and the head is
followed by eleven distinct body segments, each
bearing a pair of leaf-like, or rather fin-like, feet.

Fig. 10— The “Fairy Shrimp” {Chirocephalus diaphanus),
Male, x 2. (After Baird.)

The hinder part of the body has no appendages,
and ends in a forked tail. In the female a large
pouch hangs from the under-side of the body, just
behind the limb-bearing part, and is often found
filled with eggs. In the male, a pair of remarkable-
looking appendages, each shaped somewhat like a
hand with webbed fingers, hang in front of the head.
These are connected with the antennae, and are
known as the “ claspers,” from their function in
seizing and holding the female. The eyes are set on
movable stalks. Those Branchiopoda which, like

36

THE LIFE OF CRUSTACEA

Chirocephalus, have no carapace, form the order
Anostraca.

A second order, the Notostraca, is represented
by A pus cancriformis (Plate II.), which occurs in

Fig. ii —Estheria obliqua, One of the Conchostraca.
(After Sars, from Lankester’s “ Treatise on Zoology.”)

A, Shell of female, from the side ; B, male, from the side, after
removal of one valve of the shell. (Enlarged.) a', Antennule ;
a"f antenna ; ad, muscle which draws together the valves of the
shell ; /, tail fork ; md, mandible

many places in Europe in ponds and puddles, and
very rarely indeed in Britain. In A pus there is a large

PLATE //

Apus cancriform is, from Kirkcudbrightshire, (slightly enlarged)

THE CLASSIFICATION OF CRUSTACEA 37

dorsal shield, or carapace, covering the greater part of
the body, which consists of a large number of seg-
ments (about twenty-
eight), and ends be-
hind in a pair of
long antenna-like fila-
ments. The fin-like
feet are also very nu-
merous (about sixty-
three pairs). The eyes
are not stalked, but
are set close together
on the upper surface
of the carapace.

The third order of
the Branchiopoda,
the CONCHOSTRACA
(Fig. 11), are not re-
presented in Britain,
though several
species occur on the
Continent of Europe.

, , Fig. 12 — Daphnia pulex , a Common

In these the cara- Species of “Water-flea.” Much

pace forms a bivalved |NU^ED- (From British Museum

shell, Completely en- Female carrying eggs in the brood-
closing the body and chamber

limbs, and closely resembling that of a small mollusc.

The fourth order, the Cladocera, comprises the
so-called “ Water-fleas,” which are abundant every-

38

THE LIFE OF CRUSTACEA

where in ponds and lakes (Fig. 12). They are all
of small size, almost or quite microscopic. The
carapace, as in the Conchostraca, forms a bivalved
shell, but does not enclose the head. There is a
single large eye, which really corresponds to two
eyes fused together. A pair of large antennae, each
with two branches, carrying long feathered hairs,
project at the sides of the head, and are used in

Fig. 13 — Shells of Ostracoda. Much enlarged. (From Lan-
kester’s “Treatise on Zoology,” after Brady and Norman, and
Muller.)

A, Philomedes by end a (Myodocopa) ; B, Cypris fuscata (Podocopa) ;
C, Cythereis ornata (Podocopa). n, Notch characteristic of the
Myodocopa ; e , the median eye ; a , mark of attachment of the
muscle connecting the two valves of the shell. A and C are
marine species ; B is from fresh water

swimming with a peculiar jumping motion, from
which the popular name of the animals is derived.
There are not more than six pairs of feet. The
“ Water- fleas,” of which Daphnia pulex is one of the
commonest species, are very beautiful and interesting
objects for microscopic examination, on account of
their transparency, which allows many details of their
internal structure to be studied in the living animal.

The Ostracoda (Fig. 13), which form the second

THE CLASSIFICATION OF CRUSTACEA 39

subclass in the system of classification here adopted,
are nearly all microscopic animals, and are found
abundantly in fresh water as well as in the sea. The
carapace forms a bivalved shell, which completely
encloses the body and limbs, and is often sculptured
in an elegant fashion. The Ostracoda are remark-

Fig. 14 — Cyclops albidus , a Species of Copepod found in
Fresh Water. (After Schmeil.)

Female specimen carrying a pair of egg-packets. The actual
length is about one tenth of an inch

able for the very small number of their appendages.
There are not more than two pairs of limbs behind
the maxilla. Most of the species are included in two
orders, the Myodocopa and the Podocopa, of which
the former may generally be distinguished by a
notch in the anterior part of the margin of the shell
(Fig. 13, A, n). In the Podocopa the margin is entire.

4°

THE LIFE OF CRUSTACEA

The subclass Copepoda comprises animals, for
the most part of microscopic size, which are abundant
in fresh water and in the sea. The common fresh-
water genus Cyclops (Fig. 14) furnishes a good
example of the type of structure characteristic of
the class. The body is somewhat pear-shaped, with
a narrow abdomen ending in a “ caudal fork.” The
body is divided into somites, and there is no over-
lapping carapace, although the head and the first
two thoracic somites are coalesced. There are four
pairs of two-branched, oar-like, swimming feet, and a
fifth pair, found in some other Copepoda, is repre-
sented in Cyclops by minute vestiges on the first
segment of the narrow posterior part of the body.
The antennules are very large, unbranched and com-
posed of numerous segments ; the antennae are
much smaller. In addition to the usual mandibles,
maxillulae, and maxillae, there is a pair of maxillipeds
which really represent the first pair of trunk limbs.
There is a single red eye in the middle of the front
of the head. This eye is not formed, like the single
eye of the Cladocera, by fusion of a pair of eyes, but
it corresponds to a median eye of simple structure
which is found in the Branchiopoda, Ostracoda, and
many other Crustacea, in addition to the paired
compound eyes. From the fact that this median
eye is the only one present in the earliest larval
stage of Crustacea, the Nauplius (see Chapter IV.),
it is sometimes known as the “ nauplius eye.” The

THE CLASSIFICATION OF CRUSTACEA 41

female Cyclops carries her eggs until they hatch, in
two oval packets attached to the sides of the
body.

Forming a separate order (Branchiura) apart from
the more normal Copepoda (order Eucopepoda) is
the little group of the Carp-lice, one of which,
Argulus foliaceus, is common in England, living as a
parasite on different species of fresh-water fish, and
often found swimming free in ponds and rivers It
has a broad, flat, and very transparent body, about
three-sixteenths of an inch in length. It differs
from Cyclops in a great many points, of which,
perhaps, the most conspicuous is the possession of a
pair of true compound eyes in addition to the
median eye. On the under-side of the head are a
pair of large round suckers, by means of which the
animal fixes itself on to its prey. A study of their
development shows that these suckers are really the
maxillae, which in the young animal are jointed
limbs ending in a strong claw, but later become
changed into the suckers of the adult. A sharp
spine, which can be protruded in front of the mouth,
is connected with what is believed to be a poison-
gland. The eggs are not carried in packets by the
female as in Cyclops , but are deposited on stones or
water-weeds.

The fourth subclass, Cirripedia, comprises the
Barnacles and Acorn-shells. These are very unlike
any of the other Crustacea, and, in fact, they were

42

THE LIFE OF CRUSTACEA

long classed by naturalists with the Mollusca. It
was not until their larval development was made
known that they were recognized as Crustacea.
The common Goose Barnacle ( Lepas anatifera —
Plate III.) is found adhering to the bottoms of ships
and to floating timber. It has a fleshy stalk or
peduncle which is fixed at one end to the supporting
object, and bears at the other end a shell, made up
of five separate plates, enclosing the body of the
animal. The stalk corresponds to the front part of
the head, and careful examination may discover at
its end, among the hardened cement which fixes it
to the support, the remains of the antennules by
which the attachment of the young animal was first
effected. The body of the animal within the cara-
pace or shell bears the usual mandibles, maxillulae,
and maxillae, close to the mouth, and six pairs of
long, tendril-like feet. These feet have each two
branches, composed of numerous short segments
and fringed with long hairs. They can be protruded
from the slit-like opening of the shell, forming a sort
of “ casting-net ” for the capture of minute floating
prey.

The Acorn-shells, of which one species ( Balanus
balanoides — Plate III.) is abundant everywhere on
our coasts, covering rocks and stones just below
high-water mark, differ from Lepas and its allies in
having no peduncle. The shell is cemented directly
to the rock, and is conical in shape, like a small

PLATE III

u ^

8*

< ^
fc, s
o

w

“ « «

1/5

Mvj
a, <;
05 U K
z hi 5

hs

<

tL. W

THE CLASSIFICATION OF CRUSTACEA 43

limpet, with a hole at the top which is closed by
four movable valves.

The Stalked Barnacles, like Lepas (suborder
Pedunculata), and the Sessile Barnacles, or Acorn-
shells, like Balanus (suborder Opevculata), together
form the order Thoracica. Of the other orders
which compose the subclass Cirripedia, the only one
that need be mentioned here is the Rhizocephala,
which comprises strangely degenerate parasites living
on other Crustacea.

The Cirripedia are unlike nearly all other Crus-
tacea in the fact that, with few exceptions, they are
hermaphrodite, having both sexes united in each
individual. In certain species of the Stalked Bar-
nacles, however, there are minute male individuals
that are attached, like parasites, to the large her-
maphrodites. In a few species the large individuals
only possess female organs, so that the separation of
the sexes is complete.

The remarkable larval metamorphoses of Cirripedes
and the modifications of structure presented by some
parasitic forms will be described in later chapters.

The fifth and last subclass, that of the Malacos-
traca, is by far the largest and most important, and
will require to be considered in more detail than any
of the others. The animals composing the various
orders into which the subclass is divided differ very
greatly in structure, but they all agree in having
typically the same number of appendages as the

44

THE LIFE OF CRUSTACEA

Lobster — namely, nineteen pairs (or twenty, if the eye-
stalks be included). They also agree in the very
important character that the trunk limbs are divided
into two sets, thoracic and abdominal, the former of
eight, and the latter of six pairs.

The first order of the Malacostraca, the Neba-
liacea, comprises a few Crustacea of small size,

Fig. 15 — Nebalia bipes. Enlarged. (From Lankester’s
“ Treatise on Zoology,” after Claus.)

a', Antennule ; a", antenna ; ab'-ab6, the abdominal limbs ; ad,
muscle joining the two valves of the shell ; /, tail-fork ; p, palp
of maxillula; r, rostral plate; t, telson ; 1-7, the seven somites of
the abdomen

which differ in some very important characters from
all the other orders. Nebalia bipes (Fig. 15), which
occurs on the southern coasts of the British Isles, has
a large bivalved carapace enclosing most of the
limbs. In front, a small “ rostral plate ” is joined
to the carapace by a movable hinge, and partly
covers the stalked eyes. The eight pairs of thoracic

THE CLASSIFICATION OF CRUSTACEA 45

feet are all alike, and are flattened and leaf-like in
form, resembling those of the Branchiopoda. The
first four pairs of abdominal limbs are large two-
branched swimming feet, but the last two pairs are
reduced to small vestiges. Two of the most impor-
tant points in which the Nebaliacea differ from all
the other Malacostraca are that there are seven
instead of six somites in the abdomen (the last
somite has no appendages), and that the telson has
connected with it a pair of movable rods forming a
“ caudal fork ” like that of the Branchiopoda. On
account of the leaf-like thoracic feet and the posses-
sion of a caudal fork and other features, the Nebaliacea
were formerly classified with the Branchiopoda,
but a closer examination of their structure has
shown that they are true Malacostraca. In having
an additional somite in the abdomen and in other
points, however, they may be regarded as forming a
link between the Malacostraca and the lower forms
of Crustacea, and for this reason they are set apart
as a series Leptostraca, while the other orders
form a series Eumalacostraca.

The orders of the Eumalacostraca, again, are
grouped, as shown in the table of classification, into
four divisions. The first of these, the Syncarida,
includes only one order, comprising a few small
Crustacea (see Fig. 84, p. 264) which have recently
been discovered in fresh water in Tasmania and
Australia. They have no carapace, and all the

46

THE LIFE OF CRUSTACEA

thoracic somites, or all but the first, are distinct.
The antennules are two-branched, the antennae may
have a scale-like exopodite, and the last pair of ab-
dominal appendages form, with the telson, a tail-fan.
The eyes are sometimes stalked, but in one species
they are sessile. The thoracic limbs, which are not
clearly divided into maxillipeds and legs, carry a
double series of plate-like gills or epipodites. As
will be shown later, the living Syncarida are espe-
cially interesting on account of their resemblance to
certain very ancient fossil Crustacea.

The second division of the Eumalacostraca, the
Peracarida, includes five orders, the members of
which differ very greatly in appearance. They all
agree, however, in certain important points of struc-
ture, of which the most conspicuous is the posses-
sion, in the female sex, of a brood-pouch for carrying
the eggs and young. This brood-pouch is formed
by a series of overlapping plates attached to the
bases of the thoracic limbs.

The first order of the Peracarida, the Mysidacea,
consists of small, free-swimming, shrimp-like animals
(Fig. 16). Many species are common in the sea
round the British coasts, and from their possession
of a brood-pouch, in which the young are carried,
they are sometimes known as “ Opossum Shrimps.”
The eyes are stalked, and the carapace is well
developed, although it does not unite with all the
thoracic somites. The antennae have a flattened,

THE CLASSIFICATION OF CRUSTACEA 47

scale-like exopodite, probably of use for keeping the
animal balanced in swimming. Only one pair of the
thoracic limbs are modified to form maxillipeds, and
all the legs (as in the larval Lobster) have exopodites
which form the chief swimming organs. The uro-
pods and telson form a “ tail-fan.” One of the most
curious points in the organization of some Mysidacea

Fig. 16 — My sis relicta, One of the Mysidacea. Enlarged.
(From Lankester’s “Treatise on Zoology,” after Sars.)

cs, Cervical groove of the carapace ; m, brood-pouch

is the possession of a pair of statocysts in the endo-
podites of the uropods. Each statocyst consists of a
small cavity containing a cake-shaped concretion
known as a “ statolith,” resting on a group of
sensory hairs. There is reason to believe that these
organs have the same function as the statocysts of
the Lobster, although they are placed at the other
end of the body. The statolith serves the same
purpose as the sand-grains found in the Lobster’s
statocyst, although, unlike these, it is not introduced

48

THE LIFE OF CRUSTACEA

from outside, but is formed in position by secretion
from the walls of the sac.

Most of the Mysidacea have no special organs of
respiration, that function being discharged (as in
many of the smaller Crustacea) by the general
surface of the body, and especially by the thin
carapace ; but certain deep-sea Mysidacea (Fig. 17)
have tufted gills attached at the base of the thoracic

Fig. 17 — Gnathophausia willemoesii, One of the Deep-sea Mysi-
dacea. Half Natural Size. (From Lankester’s “Treatise on
Zoology,” after Sars.)

gr, A groove dividing the last abdominal somite

legs. In all cases the maxilliped has a plate-like
epipodite, which lies under the side-fold of the cara-
pace, and no doubt assists respiration, causing by its
movements a current of water to flow under the
carapace.

The members of the second order of the Pera-
carida, the Cumacea (Fig. 18), are small marine
Crustacea in which the anterior part of the body
is generally stout, while the abdomen is slender and
very mobile. The short carapace does not cover

THE CLASSIFICATION OF CRUSTACEA 49

more than the first three or four of the thoracic
somites. The eyes are not stalked, and are usually
fused together to form a single organ on the front
part of the head. Swimming branches (exopodites)
are usually present on some of the thoracic legs, at
least in the males, which are more active swimmers
than the females. In the males, also, the swimmerets
of the abdomen are often more or less developed,

Fig. 18 — Diastylis goodsiri, One of the Cumacea. Enlarged.
(From Lankester’s “ Treatise on Zoology,” after Sars.)

a', Antennule ; 1 1-l5, the five pairs of walking legs ; m, brood-pouch ;
ps, " pseudo-rostrum ” formed by lateral plates of the carapace ;
t, telson ; ur , uropods

but they are always absent in the females. The
uropods do not form a tail-fan, but are slender
forked rods carrying comb-like rows of spines, said
to be used in cleaning the anterior appendages from
the mud among which these animals generally live.
The telson is often absent, or, rather, it is coalesced
with the last somite of the abdomen. Under the
side-fold of the carapace on each side lies, as in the
4

50

THE LIFE OF CRUSTACEA

Mysidacea, the epipodite of the maxilliped ; but in
this order it forms a gill, and usually carries a row
of flattened gill lobes.

The third Order, that of the Tanaidacea (Fig. 19),
is of special interest, since in many respects it forms
a transition to the next. It comprises a number of
minute Crustacea, generally found burrowing in mud
in the sea. They have a small carapace, which only
involves the first two thoracic somites, the rest of

ex.

Fig. 19 — Apseudes spinosus, One of the Tanaidacea. En-
larged. (From Lankester’s “ Treatise on Zoology,” after
Sars.)

ex, Vestiges of exopodites on second and third thoracic limbs ; oc,
the small and immovable eye-stalks ; sc, scale or exopodite of
antenna ; ur, uropod

the somites being distinct. The side-folds of the
carapace enclose a pair of small cavities, within
which lie, as in the case of the last two orders,
the epipodites of the maxillipeds. The eyes are not
movable, although they are set on little side-lobes of
the head, representing the vestiges of eye-stalks. The
first pair of thoracic limbs are maxillipeds, and the
second pair are very large, and form pincer-claws
(chelae). Minute vestiges of exopodites are some-

THE CLASSIFICATION OF CRUSTACEA 51

times found on the second and third pairs, but they
are not used for swimming, and only help to keep a
current of water flowing through the gill cavities.
The abdomen is very short, with small swimmerets,
and the telson is not separated from the last somite.
The uropods are generally very
small, and do not form a tail-
fan.

Unlike the Tanaidacea, the
Isopoda, which form the fourth
order of the Peracarida, are
very numerous in species, and
very varied in structure and
habits. The most familiar are
the Woodlice, or Slaters, which
are commonly found in damp
places, under stones and the
like. Besides these, however,
the order includes a vast
number of forms living in the
sea and a few that live in fresh
water. The examination of a
common Woodlouse, such as Oniscus or Porcellio
(Fig. 20), will give a general idea of the form and
structure of a typical Isopod, although many curious
modifications are found, some of which will be men-
tioned in later chapters.

There is no distinct carapace, but the last vestige
of one may be indicated by the fact that the first

Fig. 20 — A Wood-
louse ( Porcellio
scaber), One of
the Isopoda. En-
larged. (From Lan-
kester’s “ Treatise on
Zoology,” after Sars.)

52

THE LIFE OF CRUSTACEA

thoracic somite is completely fused with the head.
All the other somites of the body are distinct (in
some Isopods, however, the abdominal somites are
coalesced), but the telson is not separate from the
last somite. The eyes are not stalked, but are sessile
on the sides of the head. The antennules have only
a single branch, and in the Woodlice are very small.
The antennae have no exopodite, although in a few
other Isopods a minute vestige is present. The
thoracic limbs never have any trace of exopodites.
The first pair are maxillipeds, and if they carry an
epipodite it is never enclosed in a gill cavity, as in
Tanaidacea. The swimmerets form one of the most
characteristic features of the Isopoda, for they are
always flattened into thin plates, which act as gills.
In the Woodlice, which breathe air, certain curious
modifications of the swimmerets are found, which
will be described in a later chapter. In some
Isopods that live as parasites on fish or on other
Crustacea, each individual is at first a male, and later
becomes a female. They are almost the only Crus-
tacea, except the Cirripedes already mentioned,
which are normally hermaphrodite.

The fifth order of the Peracarida, the Amphipoda,
is also a very large one. The “ Sand-hoppers,”
which are very common on sandy coasts, belong to
this order, as do also a very large number of other
forms found in the sea and in fresh water, which
have no popular names. A common species is

THE CLASSIFICATION OF CRUSTACEA 53

Gammarus pulex, sometimes called the “ Fresh-water
Shrimp,” which is found everywhere in streams
and ditches. Several closely allied species, such as
G. locusta (Fig. 21), are found in the sea. The body
is flattened from side to side, and the abdomen is
generally bent upon itself. There is no carapace,

Fig. 21 — An Amphipod ( Gammarus locusta). Enlarged. (From
Lankester’s “Treatise on Zoology,” after Sars.)

a', Antennule ; a", antenna ; acc, accessory (inner) flagellum of anten-
nule ; br , gill plate ; cx, coxal plate (the expanded first segment
of the leg) ; gn, the two pairs of gnathopods (prehensile legs) ;
plp"\ abdominal appendage of third pair ; prp', prp", first and
second peraeopods, or walking-legs ; t , telson ; ur, uropod ; II,
VIII, second and eighth thoracic somites; i, 6, first and sixth
abdominal somites

but, as in the Isopods, the first thoracic somite is
fused with the head. The eyes are sessile on the
sides of the head. The antennules have a small
inner branch, and the antennae have no exopodites.

54

THE LIFE OF CRUSTACEA

The thoracic limbs, of which the first pair form
maxillipeds, have no exopodites, and are partly
hidden by a row of shield-like plates along the sides
of the thorax. These plates are formed by the

A. iv. v.

Fig. 22 — Two Species of Caprellid^e. (From Lankester’s
“ Treatise on Zoology,” after Sars.)

A, Phtisica marina, a species which retains the fourth and fifth pairs
of thoracic limbs {j>rp\ prp") ; B, Caprella linearis, in which these
limbs are represented only by the gills ( br ). (Enlarged.) a',
Antennule ; a ", antenna ; abd , vestigial abdomen ; gn, gnathopods ;
m, brood-pouch ; IV, V, fourth and fifth thoracic somites

enlarged and flattened basal segments of the limbs
themselves, and on the inner side they carry a series
of oval plates, which are the gills. The abdominal

THE CLASSIFICATION OF CRUSTACEA 55

appendages are divided into two sets : the first three
pairs have each two slender, many-jointed branches,
and are used in swimming ; the last three pairs

are short, stiff, and
directed backwards,
and are used in
pushing the animal
through mud or
among water-weeds.
In many Amphipods,
such as the Sand-
hoppers, the last
three pairs of abdo-
minal limbs are used
in jumping by sudden
backward strokes of
the abdomen.

Two families of the
Amphipoda differ so
much in general ap-
pearance from the
others that they de-
serve mention. The
Caprellidae (Fig. 22)
have the body drawn
out to a thread-like

a'.

Fig. 23 — Paracyamus boopis , the
Whale-louse of the Hump-
back Whale. (From Lankester’s
“Treatise on Zoology,” after
Sars.)

A, Male, dorsal view, enlarged ; B,
the maxillipeds detached and fur-
ther enlarged. a', Antennule ; a",
antenna; abd, vestigial abdomen;
br, gills ; gn, gnathopods ; IV, V,
fourth and fifth thoracic somites

slenderness, and the abdomen reduced to a mere
vestige. The fourth and fifth pairs of thoracic limbs
are generally absent, though the corresponding gills

56

THE LIFE OF CRUSTACEA

remain. The animals live in the sea, clambering
among sea-weeds or zoophytes in a fashion which
recalls the movements of “ looper ” caterpillars. The
Cyamidcz, or “ Whale-lice ” (Fig. 23), are, as the name
implies, parasites on the skin of whales, and are
closely related to the Caprellidse. They have, how-
ever, a broad, flattened body, more like that of an

Isopod than an ordinary Amphipod, and their legs
have strong curved claws with which they cling to
the skin of their host.

The third division of the Malacostraca, the
Eucarida, consists of two orders of very unequal
interest and importance. The first of these, the
order Euphausiacea (Fig. 24), comprises only a
single family of small, shrimp-like Crustacea found
swimming freely at the surface or in the depths of

PLATE 11

Petueus caramote from the mediterranean, (about half natural size)
( From Brit. Mns. Guide )

THE CLASSIFICATION OF CRUSTACEA 57

the sea. In these the carapace fuses with all the
thoracic somites, the eyes are stalked, the antennules
have two flagella, and the antennae have a broad
scale. None of the thoracic limbs are modified into
maxillipeds, and all carry swimming exopodites.
The uropods and telson form a tail-fan. A single
series of feathery gills are attached to the bases of
the thoracic limbs. Nearly all the Euphausiacea
possess the power of emitting light, and are furnished
for the purpose with a number of organs which were
formerly supposed to be “ accessory eyes.”

The second order of the Eucarida, the Decapoda,
is by far the largest of the orders of Crustacea, and
it includes all the larger and more familiar members
of the class. It is necessary, therefore, to give a
considerably fuller account of its subdivisions than
has been given in the case of the other orders.
The typical characters of the Decapoda are well
illustrated by the Lobster, which has been already
described. As in the Euphausiacea, the eyes are
stalked, and the carapace fuses with all the thoracic
somites. From the Euphausiacea the Decapoda
differ in the fact that three pairs of the thoracic
limbs are modified as maxillipeds, the remaining five
pairs forming the “ ten legs ” to which the name of
the order alludes. Further, the gills are arranged
in more than one series, not all attached to the
bases of the legs, as in the Euphausiacea, and
covered over by the side -flaps of the carapace

5»

THE LIFE OF CRUSTACEA

instead of being freely exposed. While agreeing in
these essential characters, however, the members of
the order Decapoda differ very widely among them-
selves in structure and in general form, and they are
classified (in the arrangement adopted here) in two
suborders, which are again subdivided into sections
and tribes.

Order DECAPODA.

Suborder Natantia

,, Reptantia.

Section Palinura
,, Astacura

,, Anomura
„ Brachyura

The suborder Natantia includes the numerous
species of what are commonly known as Prawns
and Shrimps. These are characteristically powerful
swimmers, with lightly armoured bodies, more or
less flattened from side to side, with a thin, saw-
edged rostrum, and with large swimmerets which are
the chief organs of swimming ; in addition, some of
the more primitive Natantia have swimming branches,
or exopodites, like those of the Euphausiacea, on the
thoracic legs. This suborder is divided into three

fTribe Penseidea.

' Stenopidea.

Caridea.

Scyllaridea.

Eryonidea.
Nephropsidea.
Galatheidea.
Thalassinidea.
Paguridea.

Hippidea.

Dromiacea.
Oxystomata.
Brachygnatha.

Subtribe Brachyrhyncha.

PLATE V

the common spiny lobster ( 'Palinurus vulgaris). (much reduced)
(Front Brit. Mus. Guide)

THE CLASSIFICATION OF CRUSTACEA 59

tribes. The Penctidea include the large Prawns of
tropical seas (Penceus — Plate IV.), which have the
first three pairs of legs provided with chelae, and
not differing greatly in size. The Stenopidea are a
small group of forms resembling the Penceidea in
having chelae on the first three pairs of legs, but the
third pair are much larger than the others. The
Caridea comprise our common Prawns (Leander,
Pandalus) and Shrimps (Crangon), besides a host of
less generally known forms ; in these the third legs
are never chelate, although the first and second
often are.

The second suborder, that of the Reptantia,
is much more diversified, but the animals composing
it are united by certain characteristics, of which the
most obvious are their creeping habits (although
some species can swim well), their heavily armoured
bodies, often more or less flattened from above
downwards, with the rostrum never thin and saw-
edged, and the swimmerets not used to any great
extent for swimming.

The first section of the Reptantia, the Palinura,
includes the Spiny Lobsters, Rock Lobsters, or Sea-
Crawfish, and their allies, forming the tribe Scylla-
ridea. They are distinguished by having no large
pincer-claws, though the last pair of legs may have
small pincers in the female sex. One species, the
Common Spiny Lobster (Plate V.), is found ion the
southern and western coasts of the British Islands.

6o

THE LIFE OF CRUSTACEA

The other tribe belonging to this section is the
Eryonidea, comprising a number of small lobster-like
forms living in the deep sea. They have pincer-
claws on the first four, or on all five, pairs of legs,
and they are of special interest on account of their
geological antiquity.

The section Astacura contains only a single tribe,
Nephropsidea, formed by the true Lobsters and the
fresh-water Crayfishes. They have pincer-claws on
the first three pairs of legs, and the first pair are
much larger than the others.

The third section of the Reptantia, the Anomura,
comprises forms in which the abdomen is variously
modified, being either bent upon itself or, if extended,
more or less soft and feebly armoured. The last pair
of legs are commonly reduced in size, and not used
in walking. The members of the four tribes com-
posing the section differ widely in their general
appearance.

The Galatheidea (Plate VI.) are small, flattened,
lobster-like animals which have the abdomen bent
under the body. In one family ( Porcellanidce ) the
animals have quite the appearance of little Crabs
(see Fig. 41, p. 113), but they may be distinguished
from the true Crabs (Brachyura) by the fact that
there are only three pairs of walking legs behind the
great chelae, the last pair of legs being very small
and carried folded up at the sides of the body, or
even within the gill chambers.

PLATE VI

Miinida rugosa . British, (reduced)

THE CLASSIFICATION OF CRUSTACEA 61

The Thalassinidea are small lobster -like animals
which burrow in sand and mud, and have generally
a more or less soft abdomen (see Fig. 38, p. 103).

The tribe Paguridea includes the Hermit Crabs
(Paguridcd) and their allies. The typical Hermit
Crabs (Plate VII.), which are familiar objects in
seaside rock-pools, live in the empty shells of Whelks
and other Gasteropod Molluscs, which they carry
about with them as portable shelters. The structure
of the animals is modified in adaptation to this
curious habit. The abdomen, which is protected
during life by the borrowed shell, is soft and
unarmoured, and is spirally twisted. The swim-
merets, which have only the function of carrying
the eggs in the female, are much reduced, and are
usually present only on one side of the body. The
uropods no longer form a tail-fan, but are adapted
for firmly wedging the hind part of the body into
the coils of the shell. One of the chelipeds is much
larger than the other, and serves to block up the
opening when the animal withdraws into its shelter.
In tropical countries certain Hermit Crabs ( Cano -
bitidce) have become adapted to a life on land, and
one of these, the well-known Coconut Crab, or
Robber Crab (Birgus latro), which is the largest
species of the tribe, has given up the habit of
protecting itself with a shell, and its abdomen has
again acquired a strong armour on the upper side.
The marine Lithodidce — to which the British Stone

62

THE LIFE OF CRUSTACEA

Crab, Lithodes maia (Plate VIII.) belongs — seem at
first sight to have little resemblance to the Hermit
Crabs, for they have the abdomen very small, and
tucked up under the body as in the true Crabs.
Like the Porcellanidae, mentioned above, however,
the Lithodidse have only three pairs of walking legs
behind the chelipeds, the last pair being feeble and
usually folded out of sight within the gill chambers.
The relationship of the Lithodidae to the Hermit
Crabs is shown by the abdomen, which is more or
less twisted to one side, and has swimmerets only on
one side in the female, and quite wanting in the male.

The Hippidea are curious little Crabs found burrow-
ing in sandy beaches in the warmer seas. They
have the abdomen tucked under the body, and the
legs flattened for shovelling the sand.

The Brachyura, or true Crabs, form the fourth
section of the Reptantia, and are distinguished by
having the abdomen reduced to a tail-flap, which is
doubled up under the cephalothorax, and is usually
without any trace of the uropods which are present
in all the groups already mentioned, with the single
exception of the Lithodidse. At the sides of the
head the side-plates of the carapace become firmly
soldered to the “ epistome,” a plate which lies in
front of the mouth, and in this way there is formed
the “ mouth-frame,” within which lie the jaws,
covered in by a pair of “ folding-doors ” formed by
the flattened third maxillipeds.

PLATE VII

THE COMMON HERMIT-CRAB, EupagUI'US bemharduS , IN THE SHELL OF

(reduced)

( From Brit. Mus. G Hide )

PLATE VI II

‘northern stone-crab,” Lithodes maia , much reduced, the last pair of legs are folded

OUT OF SIGHT IN THE GILL CHAMBERS

THE CLASSIFICATION OF CRUSTACEA 63

The first tribe of the Brachyura, the Dromiacea,
comprises a number of Crabs that in many points of
structure resemble the Lobsters, and are regarded as
the most primitive members of the section. Dromia
vulgaris (Plate IX.), a furry, clumsy-looking Crab,
occasionally found on our southern coasts, has the
last two pairs of legs short and carried up over the
back, where they are used for holding a mass of
living sponge which the Crab uses as a cloak to pro-
tect and conceal itself. At the sides of the abdomen,
wedged in between the telson and the last somite,
a pair of small plates may be seen, which are the
last vestiges of the uropods. These are wanting in
the other tribes of the Brachyura.

The Oxystomata (Plate X.), which form the second
tribe of the Brachyura, are distinguished by the
form of the mouth-frame, which is narrowed in front
so as to be triangular instead of square in outline.
The passages through which the water passes out
from the gills, which in other Crabs open at the
front corners of the mouth-frame, are carried for-
wards to the front of the head. The Oxystomata
are most abundant in tropical seas, but are repre-
sented on the British coasts by species of Ebalia,
small and compact Crabs which are not unlike
pebbles of the gravel among which they live.

The remaining Crabs form the tribe Brachygnatha ,
in which the mouth-frame and the maxillipeds that
close it are more or less quadrilateral in shape.

64

THE LIFE OF CRUSTACEA

The tribe is divided into two subtribes, which may
be recognized by the general shape of the carapace.
In the Brachyrhyncha this is generally rounded or
square-cut in front, without a projecting rostrum.
In this subtribe are included the great majority
of Crabs. The Edible Crab and the Shore Crab
(Plate IX.) are familiar examples. In the Oxy-
rhyncha , on the other hand, the carapace is generally
narrowed in front, with a projecting rostrum, either
simple or forked, and is often armed with spines.
In this subtribe are included the long-legged Spider
Crabs, several species of which are common on our
coasts. The Giant Spider Crab of Japan (Plate XI.)
is the largest of living Crustacea.

The last division of the Eumalacostraca, the
Hoplocarida (Plate XII.), is one of very small
extent, comprising only a single order ( Stomatopoda )
of very remarkable Crustacea which are common
in tropical seas, and of which at least one species,
Squilla desmarestii, is occasionally captured on the
south coast of England. The Stomatopoda are
prawn-like Crustaceans, usually with a flattened
body, and are easily recognized by the form of the
large claws (the second pair of thoracic limbs), in
which the last segment shuts down, like the blade
of a pocket-knife, on the preceding segment, and
forms a very efficient weapon, so that the larger
species are not to be handled without caution. The
resemblance of these claws to those of the mantis-

THE CLASSIFICATION OF CRUSTACEA 65

insect of Southern Europe led to a common
Mediterranean species receiving long ago the name
Squilla mantis (Plate XII.).

The Stomatopoda have a small carapace, which
does not cover the last four thoracic somites, and
has in front a small flattened rostrum, attached
by a movable hinge, like that of the Leptostraca.
The eyes are stalked, and, like the antennules, are
attached to a separate movable segment of the front
part of the head — a peculiarity not found in any
other Crustacea. There are small plate-like gills
attached to the bases of some of the thoracic limbs,
but the chief organs of respiration are large feathery
gills attached to the pleopods or swimmerets.

The Stomatopoda are all found in the sea, gener-
ally in shallow water, burrowing in sand or hiding in
crevices of rocks or corals. Some species are more
than a foot in length.

5

CHAPTER IV

THE METAMORPHOSES OF CRUSTACEA
HE great majority of Crustacea are hatched

from the egg in a form very different from that
which they finally assume, and reach the adult state
only after passing through a series of transformations
quite as remarkable as those which a caterpillar
undergoes in becoming a butterfly, or a tadpole in
becoming a frog. Many of these young stages were
known for a long time before their larval nature
was suspected, and it is one of the curiosities of the
history of zoology that, even after the actual changes
from one form to another had been observed and
described in several Crustacea, many eminent
naturalists refused to believe in the possibility of
their occurrence. This scepticism was largely due
to the fact that the common fresh- water Crayfish,
when hatched from the egg, has practically the same
structure as the adult, and it was assumed that other
Crustacea were developed in a similar fashion.
Although certain cases of metamorphosis had been
actually seen and described by naturalists in the
eighteenth century, these observations were for-

66

THE METAMORPHOSES OF CRUSTACEA 67

gotten or misunderstood till they were confirmed
by Mr. J. Vaughan Thompson, a naval surgeon
stationed at Cork, the first part of whose “ Zoological
Researches ” was published in 1828. Thompson’s
statements were much disputed at the time, but they
have been confirmed by subsequent research, and it
is now known that the majority of Crustacea undergo
a more or less extensive metamorphosis after leaving
the egg, although, as will be seen later, there are
many important exceptions to this rule.

If a fine muslin net be towed at the surface of the
sea on a calm day, and the contents turned out into
a jar of sea-water, it will usually be found to have
captured, among other things, clouds of animated
specks, which dance in the water or dart hither and
thither with great rapidity. Many of these specks,
when examined with the microscope, will be found
to be Crustacea. Besides adult animals belonging
to various groups, such as the Copepoda, which pass
the whole of their life swimming near the surface of
the sea, there will be numerous larval stages of species
which in their adult form live on the sea-bottom.
The identification of the species to which the various
larvae belong is a matter of considerable difficulty,
and, although the general course of development is
now well known for all the chief groups of Crustacea,
there are very many even of the common British
species in which the larval transformations have not
yet been worked out in detail.

68

THE LIFE OF CRUSTACEA

As an example of the larval history of the higher
Crustacea, we may take the case of the Common
Shore Crab, Carcinus mcenas (Fig. 25). The young
stages are common in tow-net gatherings round the

Fig. 25 — Larval Stages of the Common Shore Crab ( Carcinus
mcenas — see Plate IX.). (Partly after Williamson.)

A, Young zoea, shortly after hatching ; B, megalopa stage ;

C, young Crab. A x 20, B and Cxio

British coasts in the summer-time. The youngest
larvae (Fig. 25, A) are translucent little creatures
about one-twentieth of an inch long. They have
the head and front part of the body covered by a
helmet-shaped carapace, with a long spine standing

PLATE IX

the common shore-crab ( Carcimts mcznas). (reduced)

Dromia vulga?is, carrying on its back a mass of the sponge Clione celata.

BRITISH. (REDUCED

THE METAMORPHOSES OF CRUSTACEA 69

out from the middle of the back, and another pro-
jecting, like a beak, in front.

The narrow abdomen or tail is very flexible, and
can be doubled up under the body or stretched out
behind ; it ends in a forked telson. There are two
pairs of swimming limbs, each with endopodite and
exopodite, and the short antennules and antennse
are seen on either side of the rostrum. There are a
pair of very large compound eyes, which are not set
on movable stalks, but are under the front part of
the carapace. The two-branched swimming feet are
really the first and second maxillipeds (the mandibles,
maxillulae, and maxillae, can be found in front of
them), but none of the other thoracic limbs are yet
developed, and, although the somites of the abdomen
are distinct, there are no swimmerets. This type of
larva is known as a zoea, a name which was given
to it when it was supposed to be an independent
species of Crustacean. As a matter of fact, the zoea
just described is not quite the earliest stage of the
Shore Crab, for when hatched from the egg it is
without the spines on the carapace, and is slightly
different in other respects. A few hours after hatch-
ing, however, it casts its skin for the first time, and
becomes a fully-formed zoea. It swims rapidly about
at the surface of the sea, feeding on the minute
floating animals and plants which are found there,
and growing in size with repeated castings of its
skin. In the later stages of the zoea the rudiments

70

THE LIFE OF CRUSTACEA

of the hinder thoracic limbs and of the swimmerets
appear as little buds. In the next stage (Fig. 25, B)
all the appendages are present, the dorsal spine of
the carapace has disappeared, the eyes are stalked
and movable, and the animal has all the appearance
of a little Crab, except that the abdomen is stretched
out instead of being tucked up under the body, and
the swimmerets are used as paddles in swimming.
In this stage the larva, which is known as a megalopa,

Fig. 26 — Last Larval Stage of the Common Porcelain
Crab ( Porcellana longicornis — see Fig. 41, p. 113). x 9. (After
Sars.)

swims at the surface of the sea, but later it sinks to
the bottom, and, moulting again, appears as a little
Crab (Fig. 25, C), with tucked-up abdomen and
swimmerets no longer adapted for locomotion.

Most of the true Crabs (Brachyura) have a larval
history similar to that just described, and pass
through zoea and megalopa stages which differ only
in details from those of Carcinus. The Anomura are
also hatched as zoeae, and one of the most remark-
able forms common in tow-nettings in British waters
is the zoea of the little Porcelain Crabs (Porcellana —
Fig. 26). In this larva the carapace has two long spines

THE METAMORPHOSES OF CRUSTACEA 71

behind, and a rostral spine which is several times
as long as the body of the animal. A great develop-
ment of spines also
characterizes the larva
of Muni da (Fig. 27).

The larval form of
the Common Lobster
has already been de-
scribed, and it will be
noticed that the dif-
ferences from the
adult are much less
than in the case of
the Crab. From the
fact that this larva
has swimming exopo-
dites on its legs, like
the adult Mysidacea
and Euphausiacea

(formerly grouped to- Fig. 27 — First Larval Stage of

, . Munida rugosa (see Plate VI.).

gether as SchlZO- x 10. (After Sars.)

poda ”), it is said to

be in the “ schizopod stage.” The larva of the
Norway Lobster ( Nephrops norvegicus) is essentially
of the same type, but the great development of the
spines on the abdomen and of the forked telson
gives it a striking appearance.

A very remarkable type of larva is found among
the Spiny Lobsters and their allies (Scyllaridea).

7 2

THE LIFE OF CRUSTACEA

This larva, known by the name of phyllosoma
(Fig. 28), is very broad, thin, and leaf-like, and
quite transparent, so that some of the larger kinds
were formerly known as “ Glass Crabs.” The thin
oval carapace does not cover the whole of the
thoracic region, which is disc-shaped, with four pairs

Fig. 28 — The Phyllosoma Larva of the Common Spiny

Lobster (Palinimis vulgaris — see Plate V.). Much enlarged.

(After J. T. Cunningham.)

of long slender legs, each with an exopodite. The
abdomen is relatively small. The intermediate
stages between the phyllosoma and the adult are
still very imperfectly known. In tropical seas
phyllosoma larvae of large size are found, sometimes
reaching two or three inches in length. The larva
of the Common Spiny Lobster (Palinurus vulgaris),
however, does not exceed half an inch in length.

PL A TE X

Calappa flammed brazil, (reduced)

THE METAMORPHOSES OF CRUSTACEA 73

The Shrimps and Prawns of the tribe Caridea are
mostly hatched as zoeae, and pass through a “ schizo-
pod” stage comparable to that of the Lobster, in
which they swim by means of exopodites on the legs.
Some of the Prawns belonging to the tribe Penaeidea,
however, have a still more remarkable metamorphosis,
which is very important on account of the resem-
blance of the earlier stages to those of the lower
Crustacea. Fritz Muller discovered in 1863 that
Penceus is hatched from the egg as a Nauplius
(Fig. 29, A), a form of larva which was previously
known among the Copepoda, Branchiopoda, and
Cirripedes. The nauplius, unlike the larvae which
we have been considering, has an unsegmented body?
and has only three pairs of limbs. The body is
pear-shaped in outline, and near the front end is
seen the median eye, sometimes called, from its
presence in this type of larva, the “ nauplius-eye
the paired eyes are not yet developed. The three
pairs of limbs are shown by their later development
to be the antennules, antennae, and mandibles ; the
first pair are unbranched, the second and third
divided into exopodite and endopodite. It is in-
teresting to notice that the antennae and mandibles,
which in the adult animal are so widely different
that it is difficult to trace any resemblance between
them, are in the nauplius almost identical in form.
Further, the antennae, instead of being placed in
front of the mouth as in the adult, lie on either side

74

THE LIFE OF CRUSTACEA

of it, and each has at its base a hooked spine which
projects inwards and serves for seizing particles of
food and passing them into the mouth ; the antennse
of the nauplius, in fact, serve as jaws, while it is
only later that the mandibles take on this function.

Fig. 29 — Larval Stages of the Prawn — Penceus (see
Plate IV.). x 45. (After F. Muller.)

A, Nauplius ; B, young zoea ; C, older zoea ; D, early “ schizopod ”

stage

In the further development of the larva, the body
increases in length and becomes divided into somites
which increase in number by new somites appear-
ing behind those already marked off ; the rudiments

THE METAMORPHOSES OF CRUSTACEA 75

of the limbs also appear in regular order from before
backwards ; the dorsal shield of the nauplius grows
out into a carapace, beneath which the paired eyes
begin to develop in front. Thus after passing
through metanauplius and protozoea stages (Fig. 29, B)
the larva becomes a zoea (Fig. 29, C), resembling that
of the Crab already described in that the swimming
organs are the maxillipeds, but differing in having
the uropods well developed and forming a tail-fan at
the end of the abdomen, the hinder thoracic somites
marked off and their appendages present as rudi-
ments, and the stalked eyes free from the carapace.
This is followed by a schizopod stage (Fig. 29, D), in
which the prawn-like shape is assumed and the
thoracic legs have large exopodites used for swim-
ming. Later these exopodites diminish in size,
though they do not quite disappear in the adult
Penczus, and the function of swimming organs is
taken over by the abdominal swimmerets.

In Penaus the larvae are of comparatively simple
form, but in the allied genus Sergestes the zoea has
a very remarkable appearance. The carapace is
armed with long spines, each bearing two comb-like
rows of secondary spines. The development of
spines and other outgrowths of the surface of the
body is a very common characteristic of organisms
that, like these larvse, float or swim in the open sea ;
its probable significance will be discussed in a later
chapter.

76

THE LIFE OF CRUSTACEA

The shrimp-like Euphausiacea have a larval
development very like that of Penceus. Most, if not
all, of the species are hatched from the egg in the
nauplius stage, and pass through stages very similar
to those described above. The adult animals, how-
ever, may be said to remain in the “ schizopod ”

Fig. 30 — Newly-hatched Young of a Crayfish ( Astacus
fluviatilis). Enlarged

stage, since the exopodites of the thoracic legs remain
large and are used in swimming.

Even among the Decapoda, however, there are
many species that are hatched from the egg in a form
that does not differ essentially from the adult, and
are therefore said to have a direct development.
This is often the case with species which live in
fresh water or in the depths of the sea. For
example, the young of the fresh-water Crayfish

PL A TE XI

THE GIANT JAPANESE CRAB, MdCVOcheira kcElllpferi , MALE. THE SCALE OF THE FIGURE IS GIVEN
BY A TWO-FOOT RULE PLACED BELOW THE SPECIMEN
(From Brit. Mils Guide)

i

THE METAMORPHOSES OF CRUSTACEA 77

(Fig. 30), when hatched, possess all the appendages
of the adult except the first pair of swimmerets and
the uropods, or outer plates of the tail-fan. The
carapace is almost globular, owing to the presence
inside the body of a large amount of food-yolk,
which supplies the nourishment necessary for the
young animal in the early stages of its development.
The chelse have hooked tips, by means of which the
young animal clings securely to the swimmerets of
the mother. After a time it moults, and the uropods
are set free, the chelae lose their hooked tips, the
carapace assumes nearly its final shape (the food-
yolk having been largely absorbed), and the young
Crayfish leaves the protection of its parent, to shift
for itself. The essential point of difference between
the development of the Crayfish and that of the
closely related Lobster (see Fig. 8, p. 28) is not so
much that the changes in structure which occur
after hatching are less profound in the former case,
but that there is no free larval stage. In the
Lobster the earlier stages are capable of indepen-
dent existence, and they differ from the full-grown
animal not only in structure, but also in habits,
swimming at the surface instead of creeping at the
bottom of the sea.

A similar case to that of the Crayfishes is found in
the River Crabs of tropical countries, belonging to
the family Potamonidse These Crabs are as closely
related to some marine Crabs as are the Crayfishes

78

THE LIFE OF CRUSTACEA

to the Lobsters, yet the difference in their mode of
development is even more pronounced. Instead of
beginning life as minute pelagic zoeae, they leave the
shelter of the mother’s abdomen as perfectly-formed
little Crabs (Fig. 31).

Amongst the Decapoda, instances of direct develop-
ment like those just described are exceptional, but in
some of the other orders of the Malacostraca direct
development is the rule. In the great division
Peracarida, as we have already seen, the females are

Fig. 31— Young Specimen of an African River Crab ( Potamon
johnstoni), taken from the Abdomen of the Mother.
Much enlarged

The adult of an allied species is figured on Plate XXV

provided with a pouch, or marsupium (from which
the name of the division is derived), in which the
eggs are carried. Within this pouch the young
undergo the whole of their development, and they
only leave it, as a rule, when they have attained the
structure of the adults. Among the more familiar
representatives of this division, the Sand-hoppers
(Amphipoda), the Woodlice (Isopoda), and the
Opossum Shrimps (Mysidacea), may be mentioned

THE METAMORPHOSES OF CRUSTACEA 79

as examples of this mode of development. The
Woodlice and their immediate allies differ a little
from the other members of the division in the fact
that the young leave the brood-pouch with the last
pair of legs still undeveloped, though in other
respects they are like miniature adults.

In those Crustacea which have a direct develop-
ment without free-swimming larval stages, it is
sometimes possible to find traces of such stages in
the early development of the embryo. This is
shown most clearly, perhaps, in the Opossum
Shrimps (Mysidacea). In these the embryo be-
comes free from the egg-membrane (or may, in a
sense, be said to “ hatch ”) at a very early stage, and
lies free within the brood-pouch as a maggot-shaped
body, on which three pairs of rudimentary limbs can
be made out. The later development shows that
these three rudiments correspond to the antennules,
antennae, and mandibles, so that the maggot-shaped
embryo is, in fact, a disguised nauplius without the
power of swimming or of leading an independent
existence. In other cases — as, for instance, in the
Crayfish, where the earlier stages are confined
within the egg-membrane (or “ egg-shell ”) — the
nauplius stage, although more difficult to examine,
is quite as well marked.

Of the other groups of the Malacostraca, the Syn-
carida and Leptostraca are hatched in nearly the
adult form, but the Stomatopoda have a long series

8o

THE LIFE OF CRUSTACEA

of larval stages. These larvae (Fig. 32) are all dis-
tinguished by the large size of the carapace, which
in some cases envelops the greater part of the body.
Some stomatopod larvae, in the warmer seas, attain

to a relatively great
size, sometimes exceed-
ing 2 inches in length,
and their glass-like
transparency gives them
a very striking appear-
ance.

As we have seen, it
is exceptional to find a
free-swimming nauplius
larva among the Mala-
costraca, but it is the
commonest larval stage
in the other subclasses
of Crustacea. Most of
the Branchiopoda are
hatched in this form
(Fig. 33), and reach the
adult state by a very
gradual series of
changes in which new somites and appendages are
added in regular order from before backwards till the
full number is reached. The Water-fleas (Cladocera),
however, differ from most of the other Branchiopoda
in having a direct development. The eggs are

Fig. 32 — Early Larval Stage
of a Species of Squilla, prob
ably 5. dubia. X 10. (After
Brooks. )

PLATE XII

Squilla mantis , from the mediterranean,
about one-half natural size
( From Brit. I\1us. Guide)

THE METAMORPHOSES OF CRUSTACEA 81

carried in a brood-pouch under the back of the
carapace, and in this the embryos undergo their
development. In the common Daphnia , for instance,
numerous eggs or young can generally be seen
through the transparent carapace (see Fig. 12, p. 37).

Fig. 33 — Larval Stages of the Brine Shrimp ( Artemia
salina). (After Sars.)

A, Nauplius, just hatched ; B — E, later stages, showing progressive
increase in number of somites and appendages. The adult
form of this species is shown in Fig. 55, p. 164

Many of the Ostracoda have a direct development,
but in some cases the young animal, on hatching,
6

82

THE LIFE OF CRUSTACEA

has only the first three pairs of appendages, and is
therefore regarded as a nauplius, although it possesses
a bivalved shell like that of the adult, and is very
unlike the nauplius larvae of other Crustacea.

Most of the Copepoda also leave the egg in the
nauplius stage ; and, indeed, it was to the young of
the common fresh-water Cyclops (Fig. 34) that the
name of Nauplius was first given by the Danish

Fig. 34 — Early Nauplius Larva of a Copepod {Cyclops). Much
enlarged. (From Lankester’s “ Treatise on Zoology.”)

a', Antennule ; a", antenna ; gn, jaw-spine of antenna ; Ibr, upper
lip ; md, mandible

naturalist, O. F. Muller, in the eighteenth century,
in the belief that it was an adult and independent
species of Crustacea. In the Copepoda, the changes
which transform the nauplius into the adult are
gradual, and consist chiefly in the successive addition
of new somites and appendages.

The development of the Cirripedia is of special

THE METAMORPHOSES OF CRUSTACEA 83

interest, since it was the discovery of the larval
stages by J. Vaughan Thompson that first demon-
strated to naturalists that the Barnacles were
Crustacea and not, as had been supposed, Molluscs.

Fig. 35— Larval Stages of the Common Rock Barnacle
(Balanus balanoides — see Plate III.)

A, Nauplius stage (after Hoek) ; B, cypris stage (after
Spence Bate)

The earliest stage is generally a nauplius (Fig. 35, A)
of very peculiar and characteristic form, with a pair
of horns projecting sideways from the front corners
of the dorsal shield, and a forked spine on the under-

84

THE LIFE OF CRUSTACEA

side behind. The later development is very unlike
those which have been described above, for after a
series of nauplius stages the larva passes suddenly,
at a single moult, into a stage in which the body
and limbs are enclosed in a bivalved shell (Fig. 35, B).
From the superficial resemblance of the shell to that
of an Ostracod, this is known as the cypris stage.
Through the valves of the shell a pair of large com-
pound eyes can be seen, as well as six pairs of
two-branched swimming feet, while in front a pair
of antennules project between the valves. On each
antennule is a sucker-like disc by means of which
the larva, after swimming freely for some time,
attaches itself to a stone or some other object, where
it remains fixed for the rest of its life. A cementing
substance produced by a gland at the base of the
antennules attaches the front part of the head firmly
to the support ; the valves of the shell are cast off,
and replaced by the rudimentary valves of the adult
shell ; the six pairs of swimming feet grow out into
tendril-like cirri ; the compound eyes disappear, and
the animal assumes the structure of the adult.

The parasitic Rhizocephala have a very remark-
able life-history, which will be described in a later
chapter ; but it may be mentioned here that their
free-swimming larval stages resemble very closely
those of the ordinary Barnacles. It was the dis-
covery of this fact which led to its being recognized
that the Rhizocephala are highly modified and

THE METAMORPHOSES OF CRUSTACEA 85

degenerate Cirripedes, although their structure in
the adult state gives little evidence of their affinities.

A number of interesting problems in specula-
tive biology are suggested by the larval stages of
Crustacea. A full discussion of these problems
would involve matters too technical for these pages,
but some indication of the broader issues may be
attempted.

The obvious question, Why do some Crustacea
pass through a complicated metamorphosis while
others do not ? is, like many obvious and simple
questions, one of the most difficult to answer. It
will be pointed out later, in dealing with the fresh-
water Crustacea, that one of the most general
characters of fresh-water animals as compared with
their marine allies is the absence of free-swimming
larval stages. This applies, for instance, to the case
of the Crayfishes and the marine Lobsters, and to
that of the River Crabs, as compared with those
which live in the sea. But it does not apply to all
fresh-water Crustacea, and, on the other hand, there
are many cases of direct development in marine
species.

Some of the advantages gained by the possession
of free-swimming larval stages are obvious enough.
Many Crustacea which live on the sea-bottom, and
are not very powerful swimmers, have their progeny
scattered far and wide by winds and currents while
in the surface-living larval stages. In the extreme

86

THE LIFE OF CRUSTACEA

case of the Barnacles, which are fixed to one spot
when adult, a locomotive larval stage is clearly a
necessity. But, here as elsewhere, to demonstrate
the usefulness of any character is to go only a very
little way towards explaining its origin. Moreover,
the mere necessity for a locomotive larva throws no
light on the remarkable resemblances between the
larval stages of widely different species. In the
adult state, a Branchiopod, a Copepod, an Ostra-
cod, a Barnacle, and a Penaeid Prawn, are separated
by enormous differences of form and structure ; yet,
as we have seen, all these are hatched from the egg
as six-limbed nauplius larvae differing from each
other only in trivial details. It seems hardly possible
to imagine any other interpretation of this very
striking fact than is afforded by the theory of Evolu-
tion. We are forced to assume that all these diverse
forms of Crustacea are descended from very similar
or identical ancestral types, and that the modifica-
tions arising in the course of their evolution have
affected the adult but not the larval stages. Some
naturalists would go farther than this, and would
apply the so-called “ theory of recapitulation ” to
the larval stages of the Crustacea. According to
this theory, the stages in the development of any
animal tend to recapitulate, more or less closely, the
history of the race. Thus it is assumed, for instance,
that the nauplius reproduces the structure of a six-
limbed ancestral form, from which, in the distant

THE METAMORPHOSES OF CRUSTACEA 87

past, all the diverse branches of the Crustacean
class took their origin. There are, however, con-
siderable difficulties in the way of this view. That
some such ancestral type did exist may be regarded
as tolerably certain ; that it resembled in its adult
state the nauplius larvae of present-day Crustacea
is, on the whole, unlikely ; but it is not at all
improbable, whatever its adult structure may have
been, that it hatched from the egg as a nauplius
larva.

With regard to some of the other larval forms,
it is possible to speak with a little more confidence.
There are good grounds for believing, apart from the
evidence of development, that the Lobster and its
allies have descended from Crustacea which, like the
existing Euphausiacea, possessed swimming branches
(exopodites) on the thoracic legs ; and there seems
no reason to doubt that the “ schizopod ” larva of
the Lobster does recapitulate this stage in the evolu-
tion of the race. On the other hand, it is impossible
to believe that any of the ancestors of the Shore
Crab resembled, even remotely, the zoea stage with
which the life-history of the individual now begins.

CHAPTER V

CRUSTACEA OF THE SEASHORE
HE tract of seashore which is laid bare by the

retreat of the tide offers on most coasts a rich
collecting-ground to the student of Crustacea. In
places where shelving, weed-covered rocks run out to
sea, innumerable Crustacea have their home in the
rock-pools, or lurk in crannies awaiting the return of
the tide. On sandy beaches, at first sight apparently
barren of life, a closer search will reveal a whole
fauna, amongst which burrowing Crustacea of various
orders are prominent. Further, the shore collector
will find from time to time stray specimens of forms
that have their proper habitat beyond low-tide mark,
and occasionally their remains are thrown in quan-
tities on the beach by storms. It is convenient,
therefore, to treat the Crustacea of the shore as a
sample of those inhabiting the shallower waters of
the ocean. In these shallower waters — down to the
limit where light no longer penetrates from above,
where vegetable life ceases, and where the strangely
modified inhabitants of the deep sea begin to appear

88

CRUSTACEA OF THE SEASHORE 89

— the sea-bottom is perhaps the most densely popu-
lated of all parts of the earth’s surface. Nowhere,
at all events, do we find so wide a range of animal
forms, from the simplest organisms (Protozoa) up to
highly-organized Vertebrates. Nowhere, perhaps, is
the struggle for existence more keen, and it is not
without justice that some naturalists have regarded
the shallow waters of the sea as “ one of the great
battle-fields of life,” where, in the long course of
evolution, the main branches of the animal kingdom
have had their origin.

Conspicuous among the animals of this region are
Crustacea of all sorts and sizes. To identify all the
species that may be obtained in a single haul of the
dredge in British seas would sometimes be a hard
task even for the most expert student of the group.
Our present purpose, however, is not to compile a
faunistic catalogue, but merely to give some idea of
the endless diversity of form, and to note a few of
the “shifts for a living” — of the ways in which
structure and habit are adapted to the conditions
of life in the Crustacea of the shore and of shallow
water.

Though it might seem that the heavily armoured
Lobsters and the larger Crabs would be sufficiently
protected against most enemies when once they have
attained their full size, yet they are preyed upon by
the Octopus, which seizes them with its suckers and
pierces their armour with its powerful beak, injecting

go

THE LIFE OF CRUSTACEA

a poison that paralyzes its victims. Some years ago
a “ plague ” of Octopus very seriously affected the
Lobster fishery in the English Channel. To escape
from enemies such as these, the Lobsters and many
Crabs have the habit of lurking in crevices of the
rocks, while in case of sudden alarm the Lobster
may escape from danger by swimming, or rather
darting, with great swiftness, tail foremost, through
the water by powerful strokes of the abdomen and
tail-fan. In the more lightly armed Prawns and
other Crustacea of the tribe Natantia, which are
characteristically swimmers, the power of rapid
motion is probably the chief means of protection
against enemies. There is reason to believe that
the Lobsters have been derived from prawn-like
swimming forms which have sacrificed some of their
agility in developing their heavy armour -plating,
retaining, however, the power of sudden and rapid
motion in emergency. This power, again, has been
lost by the typical Crabs (Brachyura), in which the
abdomen is reduced in size and without a tail-fan,
so as to be useless for swimming. While most of
the Crabs, however, are somewhat slow of move-
ment, trusting to their armour and their powerful
pincers for defence, the Swimming Crabs (Portunidae
— Plate XIII.) have reacquired the power of swimming
by means of the paddle-shaped legs of the last pair.
Some of the tropical species of Portunidae are prob-
ably the most expert swimmers among the Crustacea,

CRUSTACEA OF THE SEASHORE gi

and are described as shooting through the water like
fish.

The Lobster’s habit of seeking shelter in rock-
crevices or under stones is one which is shared by a

Fig. 36 — A Common Hermit Crab ( Eupagurus bernhardus) removed
from the Shell

very large number of shore Crustacea. From some
primitive kind of Lobster which discovered the
advantages of a portable shelter have been derived
the Hermit Crabs. In rock-pools one may often see
whelk or periwinkle shells tumbling about with an

92

THE LIFE OF CRUSTACEA

activity quite foreign to the nature of their original
molluscan inhabitants, and closer examination will
show that each contains a Hermit Crab, which
retreats into the shell when disturbed. If extracted
from the shell, the Crab (Fig. 36) can be seen to be
most beautifully adapted to its peculiar mode of life.
The abdomen is soft and spirally twisted to fit into
the interior of the spiral shell, and the uropods,
instead of forming a tail-fan, are modified into
holding organs, with roughened, file-like surfaces
which can be pressed outwards against the walls of
the shell, and wedge the body so firmly that an
attempt to drag the animal forcibly from its retreat
often results in tearing it in half. The front part of
the body, which is exposed when the animal is
walking, retains its shelly armour. One of the
pincer-claws, most commonly the right, is much
larger than the other, and serves to block the open-
ing of the shell when the body is withdrawn into it.
The next two pairs of legs are long and slender, and
are used for walking ; but the last two pairs are
short, with a roughened surface at the end, and
serve to steady the body in the mouth of the shell.
The swimmerets on the right side of the body,
which is pressed against the central pillar of the
shell, have disappeared, but those of the left side
remain.

As the Hermit grows, it is necessary for him to
remove from time to time into a larger dwelling.

CRUSTACEA OF THE SEASHORE

It has been stated that he will sometimes dispossess
the rightful owner of a whelk-shell for this purpose,
dragging him out piecemeal and eating him ; but
other observers deny that this ever happens, and in
most cases, at all events, the Hermit is content to
wait until he finds an empty shell of suitable size.
After turning this over and exploring the interior
with his claws, to satisfy himself that it is un-
occupied, he deftly whips the unprotected hinder
part of his body into the new habitation, keeping
hold of the old one meanwhile, so that he can return
to it if the other proves unsuitable. The Hermits
are very pugnacious, and fight with one another for
the possession of desirable shells, the victor dragging
his opponent out and establishing himself in his
place. Besides appropriating the shell of a dead
Mollusc, many Hermits seem to go into partnership
with living animals of various kinds, and some of
these associations will be noticed in a later chapter.
A number of species adopt other dwellings than
molluscan shells, and some tropical Hermits, for
instance, are found living in the cavities of water-
logged stems of bamboo (Fig. 37); while others,
relinquishing the advantages of a portable shelter,
live in holes in corals or in the canals of living
sponges. Although in some of these cases the body
is straight, it usually shows traces of its original
adaptation to a spiral shell in having no swimmerets
on the left side.

94

THE LIFE OF CRUSTACEA

The only Hermits which have a full series of
swimmerets are the primitive Pylochelidas (Fig. 37),

which come very near
to what we imagine
the ancestral form of
the group to have
been like, and can
hardly be separated
from the mud-bur-
rowing, lobster-like
Thalassinidea. A
few Hermits have
given up altogether
the use of any pro-
tective covering.
One of these is the
Coco n u t Crab
( Birgus ), to be men-
tioned when we come
to deal with the Crus-
tacea of the land.
Another is the Stone
Crab (Lithodes —
Plate VIII.) of our
own seas, and its
kindred, which have
redeveloped shelly
plates on the back of the abdomen, but carry it
doubled up under the body like the true Crabs.

Fig. 37 — Pylocheles miersii, a Sym-
metrical Hermit Crab. (After
Alcock.)

The upper figure gives an end view of
the animal lodged in a tube of water-
logged mangrove or bamboo, its
large claws closing the opening.
The lower figure shows the animal
removed from its shelter.

CRUSTACEA OF THE SEASHORE 95

These also preserve some traces of the original
twisting of the abdomen, and have swimmerets only
on one side.

Some Crustacea construct habitations for them-
selves. On turning over a flat stone between tide-
marks, one often finds a little mass of bits of weed
and rubbish attached to it, and if this be torn open
a greenish-brown, shrimp-like animal, about three-
quarters of an inch long, is seen slithering away on
its side. This is an Amphipod ( Amphithoe mbricata)
which builds the shelter for itself, sticking the frag-
ments together with threads of a cementing material
produced by glands on the surface of its body and
legs. Other Amphipods construct more neatly
finished tubular dwellings of mud, or even of small
stones, which are attached to sea-weeds and the like ;
and some make portable shelters of the same kind,
which they carry about with them like the caddis-
worms of fresh-water streams.

Some of the true Crabs also employ portable
shields for purposes of defence or of concealment.
The species of Dorippe which are found in tropical
seas have the last two pairs of legs short, elevated
on the back so that they cannot be used for walking,
and ending in a kind of grasping claw. By means
of these claws the Crab holds over its back some
object, generally one valve of a molluscan shell,
sometimes even a mangrove-leaf, to supplement the
protection afforded by its carapace. The “ Sponge

g6

THE LIFE OF CRUSTACEA

Crabs” ( Dromiidce ), of which one species, Dromia
vulgaris (Plate IX.), occurs on the southern coasts
of Britain, have also the last two pairs of legs
elevated on the back and used in a similar way ; but
in this case the covering is usually a mass of living
sponge, one of the Sea-squirts (Tunicata), or some
similar organism.

Even more remarkable are the “ masking ” habits
of the Spider Crabs (Oxyrhyneha). In these the
carapace is almost always covered with sea-weeds,
zoophytes, and other organisms which afford a very
effective disguise. For example, specimens of the
British species of Hyas ( H . araneus and H. coarctatus )
and Maia (. M . squinado — Plate XIII.), which are very
common on our coasts, readily escape the notice of
the collector, as they lurk in the rock-pools. They
are slow-moving animals, and the carapace and
limbs are usually quite hidden by dense tufts of
growing sea-weed, sponges, and other organisms.
By observing the Crabs in an aquarium, it has been
found that they actually dress themselves, plucking
pieces of weed and the like and placing them on the
carapace, where they are held in position by numerous
hooked hairs. The transplanted fragments continue
to live and grow until the Crab appears like a minia-
ture moving forest. Still more strange is the fact
that the Crabs appear to be able in some degree to
adapt the nature of their covering to their surround-
ings. It has been found that specimens dressed in

PLATE XIII

A swimming crab, Portunus depurator. British, (reduced)

a spider-crab, Main squinado , dressed in fragments of weed. British
(reduced)

CRUSTACEA OF THE SEASHORE 97

sea-weeds, when placed in an aquarium among
sponges, picked off the weeds from their bodies and
limbs, and planted fragments of sponge in their
place. Not only does this habit afford the Crabs
protective concealment, but it may also in some
cases serve as a source of food-supply. The late
Dr. David Robertson, of Cumbrae, one of the most
observant of marine naturalists, saw the Crab Steno-
rhynchus (or Macropodia) longirostris picking food-
particles from among the vegetation on its body, and
conveying them to its mouth.

Many Crustacea of different orders seek conceal-
ment and protection by burying themselves in sand.
A pool left by the tide on a sandy beach may at first
sight appear empty of all life, but if it be watched
for a little while a greyish, shadowy form may often
be seen to dart across it, to settle on the bottom
with a little puff of sand, and to disappear. Even a
close scrutiny of the spot will hardly discover any-
thing, but with a hand-net one may succeed in
scooping up, before it can dart away again, a
specimen of the Common Shrimp ( Crangon vulgaris
— see Fig. 78, p. 244), whose translucent body is
finely mottled with greyish-brown so as to match
exactly the sand among which it rests.

If a spadeful of sand from between tide- marks be
stirred up in a bucket of sea-water and allowed to
settle for a few seconds, and the water then poured
off through a fine muslin net, a wonderful assemblage
7

gS

THE LIFE OF CRUSTACEA

of minute Crustacea may often be obtained. Numer-
ous species of Ostracods, Copepods, and Amphipods,
and some Isopods, can be collected in this way, and
some of these, at least, show peculiarities of structure
which appear to be adapted to a sand-burrowing
habit. Perhaps the most remarkable Crustacea
living in such situations, however, are the Cumacea.
In these, as already mentioned, the gills, which are
attached to the first pair of thoracic limbs, lie one
on each side of the thorax in a cavity enclosed by
the carapace. These cavities are continued forwards
to the front of the head, where they unite in a single
opening from which a transparent tube (or a pair of
tubes) can be protruded. It appears probable that
this very peculiar arrangement of the respiratory
system is adapted to enable the animals to breathe
while buried in sand or mud. The water is probably
drawn in behind through the narrow slit between
the side-plates of the carapace and the bases of the
legs, and is expelled through the tube which is
protruded from the front of the head. In this way
the delicate gills are protected from injury and kept
from becoming clogged with sand, while the effete
water, loaded with the products of respiration, is
carried off to a safe distance, so that it does not
re-enter the gill chamber.

In the case of such minute forms, however, it is
very difficult to determine the precise details of their
mode of life by observation of the living animals. In

CRUSTACEA OF THE SEASHORE

99

the larger Decapods, which can be watched in their
natural haunts, or more closely in aquaria, many
interesting adaptations to burrowing in sand have
been discovered. Many Crabs belonging to the tribe
Brachyrhyncha often take refuge in sand or gravel,
burying themselves till only the eyes remain exposed.
The Swimming Crabs (Portunidse — PlateXIII.)ofour
own coasts have been found to use the paddle-shaped
last pair of legs for digging as well as for swimming.
In the sand, the Crab keeps its large claws, or
chelipeds, folded close up to the front edge of the
carapace, which is cut into sharp, saw-like teeth.
Between these teeth the water passes, to reach the
entrance to the gill chamber which lies at the base of
each cheliped, and in this way an efficient strainer is
provided, which in coarse sand at least prevents the
clogging of the respiratory passages. The out-going
current of water from the gills passes through chan-
nels that open on either side of the mouth-frame.

A more complex adaptation of structure to the
habit of sand-burrowing is found in the Masked Crab
(Corystes cassivelaunus — Plate XIV.). This Crab is
common on the British coast, living in moderately
deep water wherever the bottom is sandy, and it has
received its English name from the fact that the
furrows on the back of the carapace give it a grotesque
resemblance to a human face. It is noteworthy,
among other things, for the marked difference between
the sexes, the male having very long, slender chelipeds,

100

THE LIFE OF CRUSTACEA

while those of the female are quite short. The most
remarkable features of its organization, however,
have to do with its habit of burrowing in sand. The
antennae, which in most Crabs are extremely short,
are in this species as long as the body, and each bears
a double fringe of stiff hairs disposed along the upper
and under sides of the antenna, but curved inwards, so
that when the two antennae are brought together
parallel with each other, the hairs interlock and form
a long tube. At its base this tube communicates
with a space in front of the mouth, into which open
the channels from the gill chamber at the front
corners of the mouth-frame. The Crab burrows in
fine sand, and the process is thus described by Pro-
fessor Garstang : “ The Crab sits upright on the
surface of the sand; the elongated, talon-like claws
of the four hindmost pairs of legs dig deeply into the
sand ; the body of the Crab is thus forcibly pulled
downwards by the grip of the legs, and the displaced
sand is forced upwards on the ventral side of the
body by the successive diggings and scoopings of the
legs; the slender chelate arms of the first thoracic
pair assist in the process of excavation by thrusting
outwards the sand which accumulates round the
buccal region of the descending Crab.” In this way
the Crab descends deeper and deeper, until nothing is
visible above the surface of the sand but the tips of
the antennae. The antennal tube keeps open a
channel leading from the buried Crab to the water

PLATE XIV

Corystes cassivelaunus. male (on left) and female (on right). British
(reduced)

CRUSTACEA OF THE SEASHORE ioi

above. Since this tube communicates at its base
with the passages through which the water passes
out from the gill chamber in most Crabs, it was
assumed by the older observers that the antennal
tube served to carry the outflowing water to the
surface of the sand. It has recently been shown,
however, by Professor Garstang that when the
Masked Crab is buried in sand the normal respiratory
current is reversed, water being drawn down the
antennal tube, into the gill chambers, and passing
out through the openings at the base of the chelipeds
which, when the Crab is not buried, serve for its
entrance.

Most, if not all, of the Crabs belonging to the tribe
Oxystomata are sand-burrowers, and the structure of
the mouth parts characteristic of the tribe appears
to have been acquired as an adaptation to this habit.
As already mentioned, the mouth-frame in these
Crabs is triangular instead of square, being produced
forwards between the eyes, and the third maxillipeds,
which cover it, are also elongated. In this way the
exhalent channels carrying the water from the gill
chambers open on the front margin of the head, and
are exposed even when the Crab is buried. In the
different families of this tribe the inhalent openings
by which the water enters the gill cavities are pro-
tected in various ways, and so arranged that respira-
tion can go on without danger of the gills becoming
clogged by sediment.

102

THE LIFE OF CRUSTACEA

The members of the tribe Hippidea (sometimes
called “Mole Crabs”), among the Anomura, have
habits somewhat similar to those of the Crabs just
described. They are common on sandy beaches in
the warmer parts of the globe, and they burrow with
great rapidity by means of the curved, flattened
end-segments of the legs. The carapace is generally
smooth and oval, and the body is compact, the short
abdomen being folded up as in the Crabs.

In Albunea (Plate XIV.), which belongs to this
tribe, a long “ antennal tube,” which looks very like
that of Corystes, is believed to have a similar func-
tion in connection with respiration when the animal
is buried. In this case, however, the tube is formed,
not by the antennae, as in Corystes , but by the anten-
nules, so that it affords a striking example of the
independent evolution of similar structures from
quite different origins.

Hippa emerita , which is found on the coasts of
North and South America, has the mouth parts
imperfectly formed, and not adapted for biting ; and
it is stated by Professor S. I. Smith that the animal
feeds in the way that an earthworm does, swallowing
the sand through which it burrows, and extracting
the nutriment which it may contain. This habit,
however, is not followed by other members of the
tribe, for Mr. Borradaile found that a species of
Remipes in the Maidive Islands could “ easily be
caught by a bait of Crab at the end of a line,

CRUSTACEA OF THE SEASHORE 103

pouncing on it with its sharp maxillipeds, and
allowing itself to be flicked out of the sand if the
rod be sharply lifted.”

In the cases mentioned above, the Crustacea do
not bury themselves much below the surface of the
sand, and do not form definite burrows ; but there
are many Crustacea which live in open tunnels dug
deep into the sand. Some of these belong to the

Fig. 38 — Callianassa stebbingi (Female), a Sand - burrowing
Thalassinid from the South Coast of England. Natural
Size

category of amphibious forms, to be mentioned
presently ; but there are others which live in deeper
water, and of which the habits are less open to
observation.

Nearly all the Thalassinidea (Fig. 38) live in
burrows, often of considerable depth, in sand or
mud. Although now classed with the Anomura,
these animals are lobster-like in form, loosely built,
generally with short carapace and long, soft abdomen.

104 THE LIFE OF CRUSTACEA

They have usually very small eyes, which appear
as if they were not of much use for vision ; and
some of the hinder pairs of legs are short, and
carried folded against the sides of the body, probably
for use when the animal is moving up or down in its
burrow.

Most of the Stomatopoda resemble the Thalas-
sinidea in their mode of life, and show some curious
similarities to them in structure, although by no
means closely related. They are described as lying
in wait for prey at the mouth of their burrows,
darting out on passing fish or other animals, which
they seize with their great saw-toothed claws, and
retreating with great rapidity to the bottom of the
burrow.

Most of the Crustacea mentioned live below tide-
marks, and at all events are rarely seen when the
sand in which they burrow is left bare by the tide ;
but there are others, especially on tropical shores,
which seem to have their chief period of activity
when the sand or mud banks on which they live are
exposed to the air. Chief among these amphibious
forms in the warmer seas are the Crabs of the genera
Ocypode and Gelasimus and some of their allies.

Some of the species of Ocypode (Plate XV.) dig
their burrows between tide-marks, where they are
swamped by the advancing tide, and must be ex-
cavated afresh when the water retreats. Other
species, however, live above high-water mark, and

PL A TE XV

Ocypode cursor, west Africa, (reduced )

Gelasimus tangeri. male above, female below.

WEST AFRICA. (REDUCED)

CRUSTACEA OF THE SEASHORE 105

are practically terrestrial animals, only entering the
water occasionally, and, indeed, unable to survive
prolonged immersion. The work of excavating the
burrows has been watched in several species. The
Crab comes out of the burrow sideways, carrying a
load of sand between two of the walking legs on the
rear side. By a sudden movement the sand is jerked
away to some distance, where it accumulates in a
little heap, and the Crab dives into the burrow for
another load. Most of the Crabs belonging to this
genus possess a curious “ stridulating organ ” on one
of the large claws, by means of which they can
produce a buzzing or hissing sound. On the inner
surface of the “hand” there is a raised patch,
which, when examined with a lens, is seen to be
made up of a series of fine ridges, like the teeth of
a file. When the limb is bent in towards the body,
this patch can be rubbed up and down against a
sharp-edged ridge or scraper on the third segment of
the limb, and in this way the sound is produced.
What the use of the sound may be is not quite clear,
but there is probability in Dr. Alcock’s suggestion
that it serves to warn intruders that the burrow is
already occupied. These Crabs run very swiftly, and
one species was seen by Professor S. I. Smith to
catch Sand-hoppers (Amphipods of the family Tali-
tridse) by springing on them suddenly, “ very much
as a cat catches mice,” but it also fed on dead fish
and the like.

106 THE LIFE OF CRUSTACEA

Of somewhat similar habits are the numerous
species of the genus Gelasimus (“ Fiddler Crabs” —
Plate XV.), which abound on sand and mud flats of
tropical shores. These little Crabs are remarkable
for the great dissimilarity between the sexes in the
form of the chelipeds. In the female both chelipeds
are small and feeble, but in the males one of them,
either the right or the left, is enormously enlarged,
sometimes exceeding in length and breadth the body
of the Crab which carries it. What the precise use
of this enormous claw may be does not seem to be
quite certainly known. It is said to be used as a
weapon by the males in fighting with one another,
but it seems too clumsy to be very efficient for this
purpose. It is often brilliantly coloured, and has
been supposed to be a sexual adornment.

In Ocypode and Gelasimus the respiratory apparatus
is modified for the purpose of breathing air. The
gills are similar to those of purely aquatic Crabs, and
no doubt serve for respiration when the animal is in
the water; but the gill chambers are much more
spacious than usual, and the lining membrane is
richly supplied with bloodvessels. Air is admitted
to the gill chambers by an opening, protected by a
brush of hairs, between the second and third pairs of
walking legs on each side. It is believed that in
this way the gill chamber is fitted to be used as a
lung when the animals are out of the water. Similar
arrangements in some of the more exclusively

CRUSTACEA OF THE SEASHORE 107

terrestrial Crustacea will be mentioned in a later
chapter.

There are many Shore Crabs, however, which lead
a more or less amphibious existence without showing
any marked modifications of structure as compared
with their more purely aquatic relatives. On our
own coasts, the Common Shore Crab ( Carcinus
mcenas — Plate IX.) commonly spends several hours
each day exposed to the air, and in an aquarium it
will voluntarily leave the water if the opportunity be
afforded it. On tropical coasts the species of Grapsus
and allied genera are often seen clambering with
great agility about exposed rocks.

Analogous habits to those of the sand-burrowing,
amphibious Crabs described above are shown on a
small scale by the Amphipods of the family Tali-
tridse, known as “ Sand-hoppers ” or “Beach-fleas.”
Everyone who has walked over the firm sand near
high-water mark on our own shores must have
noticed the myriads of actively hopping little crea-
tures disturbed at every step. The commonest
species of Sand-hopper on the British coasts is
Talitrus saltator (Fig. 39), but Orchestia gammarellus
is also common. Both species occur together on
sandy beaches or among decaying sea-weeds, and
are among the most important scavengers of the
seashore, picking clean the bones of fish or other
animals cast up by the tide. In this country the
Sand-hoppers do not, as a rule, venture far above

108 THE LIFE OF CRUSTACEA

high-water mark ; but in warmer climates species of
Talitridse live in the damp forests at great distances
from the sea, and deserve to be ranked among the
terrestrial Crustacea.

It has been mentioned above that the Common
Shrimp is protected, not only by its habit of lying
half buried in sand, but also by its close resemblance
in colour to the sand among which it lives. There

Fig. 39 — The Common Sand-hopper ( Talitrus saltator), Male,
from the Side, x 3. (After Sars.)

are many others among the shore Crustacea which
show what seems to be a “protective resemblance”
in colour and form to their surroundings. It is
necessary to be cautious in interpreting these re-
semblances as necessarily protective, since the fish
and other enemies which prey on these Crustacea
see them with eyes very different from ours, and
probably, in many cases, are guided to their prey by
the sense of smell rather than by sight. The
“masking” habit of the Spider Crabs, already

CRUSTACEA OF THE SEASHORE 109

described, strongly suggests, however, that conceal-
ment from sight is an important protection to some
shore Crustacea, and helps to make it probable that
the same end is reached in other cases by modifica-
tions of form and colour.

There can be no doubt, at all events, that many
Crustacea are very inconspicuous to human eyes
when they remain motionless in their natural sur-
roundings. Thus, for example, the Caprellidae, or
“ Skeleton Shrimps ” (see Fig. 22, p. 54), are hard to
detect without very close search, as they cling to the
feathery branches of the hydroid zoophytes among
which they are usually found. They are strangely
modified Amphipods, in which the body is slender
and thread-like, and generally of a semi-transparent,
whitish or yellowish colour, like the zoophytes on
which they live. They clamber about among the
branches with a movement like that of a “ looper ”
caterpillar, and often remain clinging by means of
the hooked claws of the hinder pairs of legs, with
the fore part of the body gently waving about.

The little Crabs of the family Leucosiidae (Oxy-
stomata), of which the British representatives are
several species of the genus Ebalia, are often ex-
tremely like pebbles of the gravel among which they
live. In many tropical species the carapace is pitted
and eroded, so as to resemble a worn fragment of
coral shingle. One of the most striking cases among
the Crabs, however, is that of Huenia proteus

IIO

THE LIFE OF CRUSTACEA

(Fig. 40), one of the Spider Crabs (Oxyrhyncha),
which is found in the Indian and Pacific Oceans.

In this little Crab the carapace is flat, and is extra-
ordinarily variable in form. In most of the males it

is triangular in outline, but
in most of the females and
in some males it is broadened
by leaf-like expansions of the
side edges. Borradaile has
pointed out that these broad
individuals are usually found
among the sea-weed Halt-
meda , and that they closely
resemble the fronds of this
weed in form and in their

Fig. 40 — A, a Piece of a
Tropical Sea-weed
( Halimeda ) ; B, a Crab
( Huenia proteus) which

LIVES AMONG THE

Fronds of Halimeda , and

CLOSELY RESEMBLES THEM

in Form and Colour.
Reduced. (After Borra-
daile.)

greenish colour.

A number of Crustacea are
known to possess a chame-
leon-like power of changing
their colour. The mechanism
by which this change is ef-
fected is similar to that found

in other animals, such as fish and frogs, which have
the same power. The pigment which gives its colour
to the animal is lodged in microscopic star-shaped
bodies known as chromatophores, lying for the most
part just below the skin. Each chromatophore
consists of a central body from which a number of
branching filaments radiate. The pigment may con-

CRUSTACEA OF THE SEASHORE hi

tract into the centre of the chromatophore, forming
a minute and hardly visible speck, or it may spread
out into the branching filaments, forming a distinct
spot of colour. Each chromatophore may in some
cases contain several colours of pigment, and these
may expand or contract independently of each other,
so that a whole series of changes may be produced by
a single chromatophore. In the larger Crabs and
Lobsters the visible colour of the animals depends
on pigment in the shelly exoskeleton, which is thick
enough to hide the chromatophores in the living
tissues underneath, and no very rapid or considerable
changes are apparent ; but in the smaller forms, in
which the exoskeleton is thin and translucent enough
to allow the underlying colours to appear through it,
the changes in the chromatophores may produce
striking effects. Thus, Fritz Muller describes a
species of Fiddler Crab of the genus Gelasimus , in
which the hinder part of the carapace was brilliantly
white, but five minutes after the Crab was cap-
tured it had changed to a dull grey. Many other
cases of colour change have been described, but
most remarkable and the most fully studied is that
of the Prawn, Hippolyte varians, which is very
common on our own coasts, and has recently been
the subject of a very elaborate series of researches by
Professors Keeble and Gamble. The specimens of
this Prawn show “ a bewildering variety of colour
and of colour-pattern”; they may be uniformly

1 12

THE LIFE OF CRUSTACEA

coloured in various shades of brown, green, or red,
or they may be “ blotched,” “ barred,” or “ lined,”
with colour. These different varieties are generally
found among sea-weeds, which they resemble in
colour and pattern, the “ lined ” forms, for instance,
frequenting finely branched and feathery weed. Like
many other protectively coloured animals, they are
of sedentary habits, clinging to the weed, and seldom
moving by day. If a specimen be removed from its
habitat and placed in an aquarium with different
kinds of sea-weed, it will take refuge among that
which it most closely resembles. It appears that
this resemblance in colour-pattern is acquired during
the growth of the Prawn, and that a young specimen
kept among finely branched sea-weed will acquire the
“ lined ” pattern, while others, living among coarser
weed, become “ barred,” “ blotched,” or “ mono-
chrome.” Even in the adult Prawns the colour
(though not the pattern) becomes changed in a day
or two if they are placed among weed of a different
colour — from green to brown, or the like. Within
certain limits still more rapid changes of colour take
place. If kept in the dark, or if placed on a white
background (for example, in a porcelain dish) in the
light, the Prawn quickly becomes nearly colourless,
by contraction of the chromatophores, a transparent
bluish tint alone remaining, due to a substance which
diffuses from the chromatophores into the fluids of
the body. In natural conditions this phase is assumed

CRUSTACEA OF THE SEASHORE 113

at night ; and the interesting observation has been
made that Prawns kept in the dark continue for
three or four days to show a periodic expansion and
contraction of the chromatophores, corresponding
to the alternation of day and night. It seems that
the rhythm of light and darkness has become im-
pressed on the chromatophore system of the animal,

Fig. 41 — The Common Porcelain Crab ( Porcellana longicornis),

SLIGHTLY ENLARGED, AND ONE OF THE THIRD MAXILLIPEDS

DETACHED AND FURTHER ENLARGED TO SHOW THE FRINGE OF

Long Hairs

and the movement of the pigments is regulated by
something analogous to memory.

It has already been mentioned, in dealing with the
Lobster, that certain Crustacea have the power of
voluntarily throwing off some of their limbs (auto-
tomy). In many cases, as in the Lobster, this power
is mainly of use in enabling the animal to discard an
injured limb; but there are some Crustacea which
seem to adopt it as a means of escaping from the
attack of an enemy. On our own coasts the shore
8

THE LIFE OF CRUSTACEA

114

collector will often find, on turning over a large
stone, one or more specimens of the little Porcelain
Crabs (Porcellana platycheles, or P. longicornis — Fig. 41)
clinging to its under-side. If these Crabs be seized
by one of the large claws, they frequently leave the
claw in the captor’s hand and scuttle off without it ;
and it cannot be doubted that, as in the case of
lizards and other animals which have a similar power
of self-mutilation, this habit often enables them to
escape from their natural enemies.

Although the Crustacea as a whole are pre-
dominantly active animals, many examples have
already been mentioned of species which are more
or less sluggish and sedentary in their habits. The
extreme degree of passivity is reached by the
Barnacles (Cirripedia), which differ from all other
Crustacea (except some parasites) in being fixed to
one spot, and quite without the power of locomotion
in the adult state. Most of the Barnacles met with
on the shore or in shallow water belong to the
division of the Sessile Barnacles or Acorn-shells
(Operculata). Every visitor to the seashore has
noticed the little conical shells which cover exposed
rocks as if with a coat of rough-cast. On the
British coasts the commonest species is Balanus
balanoides (Plate III.), though other species closely
resembling it are also common. They are to be
found almost up to high-water mark in situations
where they are left uncovered for many hours every

CRUSTACEA OF THE SEASHORE 115

day ; but the valves which close the opening of the
shell fit so tightly that a little sea-water is enclosed,
and the animal is protected from drying up even when
exposed to the heat of the sun. If a stone or a chip
of rock, with a few of these animals on it, be placed
in a jar of sea-water, their peculiar mode of obtaining
food can easily be watched. The valves will presently
be seen to open a little, and the curled cirri will be
protruded, opened out like the fingers of a hand,
and withdrawn again with a sort of grasping motion.
These movements are continued without stopping
while the animal is under water. If the cirri be
examined with a pocket-lens or under a microscope,
it will be seen that they are fringed with stiff bristles,
so that, when they are opened out, the whole forms
a kind of “ casting-net.” As it is swept through the
water, this net entangles minute floating particles of
animal or vegetable matter, and carries them into
the shell, so that they can be seized by the jaws and
swallowed. The cirri, as we have already seen, are
really the modified thoracic limbs, so that, in Huxley’s
words, “ A Barnacle may be said to be a Crustacean
fixed by its head, and kicking the food into its
mouth with its legs.”

A mode of obtaining food by “ net-fishing,” not
unlike that employed by the Barnacles, is found in
certain Crustacea belonging to a widely different
group — the little “ Porcelain Crabs” (Fig. 41)
mentioned above. Mr. Gosse observed that the

n6 THE LIFE OF CRUSTACEA

Broad-clawed Porcelain Crab ( Porcellana platycheles )
employed its third pair of maxillipeds, which are
thickly fringed with long feathered hairs, in making
alternate casting movements “ exactly in the manner
of the fringed hand of a Barnacle, of which both the
organ and the action strongly reminded me.”

CHAPTER VI

CRUSTACEA OF THE DEEP SEA

IT has already been mentioned that the animals
living on the sea-bottom in shallow water do not
differ greatly in character from those that may be
found between tide-marks. As we go farther out
from land, however, into the deeper water, the
character of the fauna gradually changes. One by
one the species found near the shore become rare
and disappear, and their places are taken by others
characteristic of the intermediate depths. These in
their turn give way to others, till in the abysses of
the great oceans we find an assemblage of strange
animals adapted to the conditions of life in the great
depths, and differing widely in many respects from
the more familiar inhabitants of the coastal waters.
In this “ fauna of the deep sea,” which extends to
the greatest depths reached by the dredge or trawl,
the Crustacea occupy a prominent place. Before pro-
ceeding to discuss some of these peculiar forms,
however, it is necessary to attempt to form some
idea of the conditions under which they live.

117

n8

THE LIFE OF CRUSTACEA

In the first place, the character of the sea-bottom
changes very greatly as we pass away from the
coast. Near the shore it is extremely diversified,
consisting in one place of rocks swept bare by the
tides or overgrown with jungles of sea-weed, in
another of banks of gravel or shingle, of sand or of
mud, but in all cases derived from the “waste” of
the land, as it is eaten away by the waves or washed
down by the rivers. As the distance from land
increases, the deposits become finer and finer, till
they shade off into a soft oozy mud, composed of
the finest particles brought down by the rivers. In
the neighbourhood of large rivers this mud may
sometimes extend for hundreds of miles from the
land, but there is a limit to the distance to which
even the finest particles can drift before they settle
to the bottom, and beyond this limit the floor of the
ocean is covered by sediments which owe their
origin, not to the land, but to the ocean itself. The
surface waters of the ocean everywhere teem with a
vast variety of floating animals and plants, and, as
these die, their remains sink to the bottom “ like a
perpetual shower of rain.”

Among the most abundant floating organisms —
in the warmer seas, at any rate — are certain minute
animals known as Foraminifera , which belong to
the lowest class of the animal kingdom, and
have shells composed, in most cases, of carbonate
of lime. Over vast areas the bottom of the ocean

CRUSTACEA OF THE DEEP SEA ng

is covered with a soft grey ooze, made up almost
entirely of the dead shells of Foraminifera rained
down from above. Since the commonest species
of Foraminifera found under these circumstances
belong to the genus Globigerina, the deposit is
known as “ Globigerina ooze.”

In certain regions of the ocean the shells of other
floating organisms largely replace those of the
Foraminifera in covering the ocean floor, and in
the deepest abysses — so deep that the shells of
surface animals are dissolved before they can sink
to the bottom — there is found a deposit known as
the “ red clay,” which appears to be derived largely
from the impalpable volcanic and cosmic dust that
floats in the atmosphere. It is not necessary for
our present purpose to enter more fully into the
interesting questions connected with these deep-sea
deposits, but it is important to remember that,
generally speaking, the floor of the deep sea is
everywhere soft ooze, without rocks or stones,
except for an occasional water-logged lump of pumice
or a stone dropped by a melting iceberg. This fact
is probably of great importance in the life of deep-
sea animals.

One of the most peculiar and characteristic of the
physical conditions in the deep sea is the enormous
pressure under which life has to be carried on. At
the surface of the sea the pressure of the atmosphere
is, roughly speaking, 14J pounds per square inch.

120

THE LIFE OF CRUSTACEA

At a depth of only 33 feet of water this pressure is
doubled, and at greater depths the pressure increases
in proportion, till at 2,000 fathoms it is more than
2\ tons on the square inch. As a matter of fact,
however, the animals at the bottom of the sea are
probably but little affected by this enormous pressure.
Only, when they are brought up by the dredge the
sudden release of pressure causes the fluids of the
body to expand and destroys the tissues, so that the
animals are generally dead or dying when they reach
the surface.

More important than the pressure in its influence
on life is the darkness of the depths. The light of
the sun only penetrates the water of the sea to a
comparatively small depth. At 200 fathoms there
is not enough light to produce any effect on a photo-
graphic plate. Even at a considerably less depth
the absence of light puts an end to all plant-life,
except for the ubiquitous bacteria, and it follows
that all the animals of the deep sea ultimately depend
for their food-supply on the rain of dead bodies of
surface animals which, as already mentioned, is con-
stantly falling on the sea-bottom.

The temperature at the bottom of the deep sea is
always very low. Dr. Alcock states that “ in the
open part of the Bay of Bengal, where the mean
surface temperature is about 8o° F., the temperature
at a depth of 100 fathoms is only about 6o° F., at
a depth of 300 fathoms not quite 50° F. ; while at a

CRUSTACEA OF THE DEEP SEA 121

depth of 2,000 fathoms the temperature all the year
round is only 30 above freezing-point.”

Finally, it is important to notice the uniformity of
the conditions at the bottom of the sea ; not only
are the alternation of night and day and the progress
of the seasons unfelt in the abysses, but the con-
ditions are practically the same over vast areas in all
the oceans.

In the case of deep-sea Crustacea, we are fre-
quently confronted with a difficulty which does not
occur in the case of some other groups of animals —
Corals or Echinoderms, for example — the difficulty,
namely, of deciding whether the animals really lived
on or near the bottom, or were captured by the open
mouth of the trawl on its way to the surface. When
the animals are plainly not well adapted for swim-
ming— as, for instance, most of the Crabs — it may
be assumed that they did actually live on the
bottom ; but, with the prawn-like forms, the possi-
bility that they may really be inhabitants of the
intermediate depths must always be taken into
consideration.

In animals that live in perpetual darkness we
should expect to find, in accordance with the prin-
ciple of adaptation which runs through the whole
of organic nature, that the eyes are wanting or
imperfectly developed. In a great many deep-sea
animals this is indeed the case. The deep-sea
Lobsters of the genus Nephropsis (Fig. 42), which

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THE LIFE OF CRUSTACEA

are very closely allied to the Norway Lobster
(Nephrops) of shallow water, have very short and
slender eye-stalks hidden under the rostrum, and
showing at the tip only the merest traces of what

Fig. 42 — A Deep-sea Lobster ( Nephropsis stewartii), from the
Bay of Bengal. Reduced. (After Alcock and Anderson.)

was once an eye. In the lobster-like Eryonidea
(see Fig. 46, p. 133), the reduced eye-stalks are firmly
fixed in notches in the front edge of the carapace.
Some of the deep-sea Crabs and Prawns seem also
to be totally blind. In a great many cases degenera-

CRUSTACEA OF THE DEEP SEA 123

tion has not quite gone so far, and the eyes are
present, although much reduced and modified. Thus,

Fig. 43 — Munidopsis regia, a Deep-sea Galatheid from the Bay
of Bengal. Reduced. (After Alcock and Anderson.)

the very numerous deep-sea species of Galatheidae,
belonging to the genus Munidopsis (Fig. 43) and its

124

THE LIFE OF CRUSTACEA

allies have, as Alcock says, “ pallid, milky-yellow,
lack-lustre eyes which, though they may perhaps
serve to distinguish between light and darkness, can
never form a definite visual image.” It is probable,
indeed, that these pale-coloured eyes are specially
adapted for vision in a dim light, for it has been
shown that in certain deep-sea Euphausiacea the
pigment-sheaths between the separate elements of
the compound eyes are greatly reduced, and are
fixed in the position temporarily assumed by those
in the eyes of normal Crustacea when kept in the
dark. Be this as it may, there are many deep-sea
Crustacea which have well-developed and darkly-
pigmented eyes. Some of these are swimming forms,
which may at times migrate into the upper strata
of water to which some rays of light penetrate ; but
there are some cases of Crabs and other bottom-
living species that have well-developed eyes, although
they live at great depths. This would seem to sug-
gest that, although shut off from the light of day,
they are not condemned to grope in perpetual dark-
ness. Many deep-sea animals are known to be
phosphorescent, and it seems probable that the
large-eyed species may profit by the light emitted
by the glow-worms and fireflies of the abyss. Thus,
Alcock points out that the deep-sea Hermit Crab
Parapagurus pilosimanus (Plate XVI.), which lives in
partnership with a colony of sea-anemones which it
carries about with it, has large eyes, although it

PLATE XVI

A DEEP-SEA hermit-crab, Parapagtirus fiilosimanus ,
SHELTERED BY A COLONY OF EpizoantllUS . FROM
DEEP WATER OFF THE WEST OF IRELAND

(slightly reduced)

CRUSTACEA OF THE DEEP SEA 125

descends to depths of at least 2,000 fathoms ; and
he suggests that the Crab may be able to see its way
by the light emitted by the zoophytes.

Some of the Crustacea, however, are themselves
luminous. Thus, Alcock records how specimens of a
deep-sea Prawn, Heterocarpus alphonsi , “poured out,
apparently from the orifices of the ‘ green glands ’ at
the base of the antennae, copious clouds of a ghostly
blue light of sufficient intensity to illuminate a bucket
of sea-water so that all its contents were visible in
the clearest detail.” Certain other Prawns are
known to possess special light-producing organs on
various parts of the body and limbs. It is in the
Euphausiacea, however, that these organs have been
most fully examined, and although the members of
this group (see Fig. 24, p. 56) are by no means all
deep-sea animals, some of them occurring at the
surface of the sea, the structure of their luminous
organs, or “ photophores,” may appropriately be
described here. They are situated on the under-
surface of the abdomen, in the basal segments of
some of the thoracic legs, and on the upper surface
of the eye-stalks. Each consists of a globular cap-
sule covered by a layer of pigment, except on the
outer side, where there is a transparent biconvex
lens. In the centre of the capsule is a peculiar
“ striated body ” which seems to be the actual seat
of luminescence, and behind it is a concave reflector
composed of concentric lamellae, and having a silvery

126

THE LIFE OF CRUSTACEA

lustre. Before their luminosity was observed, these
organs were described as 4 4 accessory eyes,” but there
can be little doubt that they serve rather as search-
lights, although, from the positions that some of
them occupy on the body, it is not easy to see how
they can illuminate objects within range of the eyes.
That the function of phosphorescent organs is not
always that of giving light for their possessor to see
by is shown by the fact that many luminous animals
are blind. It is important to notice, however, that
these blind animals never have complex “ photo-
phores” like those just described, but only exhibit
a diffuse luminosity or give off luminous secretions ;
as an example among Crustacea, the blind Eryonidea
(see Fig. 46, p. 133) may be mentioned, one species of
which was observed by Alcock to be “luminous at
two points between the last pair of thoracic legs,
where there is a triangular glandular patch.” In a
recent discussion of the whole question of phos-
phorescence in marine organisms, Dr. Doflein con-
cludes that the part it plays in the life of the
animal probably differs in the different cases. In
some it may serve to attract prey, as moths are
attracted to a candle ; in others it may help
individuals of the same species to keep together
in a swarm or to find their mates, the varying
arrangement of the photophores producing character-
istic light-patterns that serve as “ recognition marks ”
like the colour-patterns of animals that live in the

CRUSTACEA OF THE DEEP SEA 127

light of day. The clouds of luminous secretion thrown
out by Heterocarpus and other Prawns, and by certain
Mysidacea and Ostracods, may serve to baffle
pursuers, like the cloud of ink thrown out by a
Cuttlefish, and in some cases the more complex
organs may illuminate objects within the range of
vision. That this does not exhaust the possibilities
of speculation on the subject, however, is shown by
the case of certain deep-sea Prawns which have
been recently discovered to possess photophores
placed so as to illuminate the interior of the gill
cavities. What function they can discharge in this
position seems beyond conjecture.

The colours of deep-sea Crustacea are very curious.
Few of them have the blanched appearance common,
for instance, in animals that live in the darkness of
caves ; on the contrary, their colours are often very
vivid, but they are nearly always uniform, without
spots or markings, and in a large proportion of cases
are in some shade of red or orange. This red colour
seems to be associated, in some way that we do not
understand, with the darkness of their habitat. The
general absence of markings is very striking. Dr.
Alcock remarks that in deep-sea Crustacea we never
see “those freaks of colour, or those labyrinthine
mottlings and dapplings, that excite our curiosity
when handling the Crabs and Shrimps of the reefs.”
Possibly the explanation of this may be that in these
dwellers in darkness colour is merely, as it were, an

128

THE LIFE OF CRUSTACEA

accident, a by-product of physiological processes
directed to other ends, not a character of protective
or warning value, as in animals that hunt and are
hunted in the light of day. It is a curious fact,
which may have some bearing on this problem, that
in many cases, while the adults are coloured in some
shade of red, the eggs carried by the female are
bright blue or green.

Some of the peculiarities of structure observed in
deep-sea Crustacea seem to be correlated with the
difficulties of resting or moving about with security
on the soft ooze of the sea-floor. Among the Crabs
we find a preponderance of long-legged species, not
only among the true Spider Crabs (Oxyrhyncha), but
also in other groups (Dromiacea like Latreillia ,
figured on Plate XIX., and Oxystomata), the
members of which assume the same spider-like form.
In some cases the legs are fringed with long stiff
hairs, which may help to prevent the animal from
sinking in the ooze, and the spines on the body and
legs of many species may have the same effect.
Among the deep-sea Prawns, the species of the
family Nematocarcinidae (Plate XVII.) have ex-
tremely long and slender legs, which we may assume
to be used like stilts for walking over the soft ooze.

Not much is known regarding the food of deep-
sea animals. In the absence of plant-life they must
of necessity be all carnivorous, and all ultimately
dependent on the food-supply falling from above.

PLATE XVII

deep-sea prawn, Nematocarcinus undulatipes. (slightly reduced)
(From Brit. Mus. Guide)

CRUSTACEA OF THE DEEP SEA 129

Some species have been found to have the food-
canal filled with Globigerina ooze, which they no
doubt swallow, as earth-worms do the soil in which
they burrow, for the purpose of extracting the nutri-
ment that it contains. In one species of deep-sea

Fig. 44 — Thanmastocheles zaleucus. Reduced. (After Spence Bate.)

Cumacea (Platycuma holti ), which appears to feed in
this manner, the food-canal is coiled, a condition
very rare in Crustacea ; in all probability this is due
to the necessity for an increase of the absorptive
surface, since it is common to find such an increase,
either by lengthening and consequent coiling of the
9

130

THE LIFE OF CRUSTACEA

gut, or by infolding of its walls, in animals that have
to swallow large quantities of relatively innutritious
food material. Many species, however, no doubt
have more selective habits of feeding. The lobster-
like Thaumastocheles (Fig. 44), which was dredged by
the Challenger expedition in the West Indies at a
depth of 450 fathoms, and has since been got from
deep water off the Japanese coast, has one of the
chelae enormously enlarged, with long and slender
fingers set with spines like the teeth of a rake. It
has been suggested that this remarkable claw may
be used for raking or sifting the ooze for small
animals on which the Thaumastocheles feeds. A
similar function may be suggested for the long and
spiny first pair of walking legs in the Spider Crab
Platymaia (Fig. 45).

In many deep-sea Crustacea the eggs are of very
large size, indicating that the young are hatched in
an advanced stage of development. For example,
in the numerous species of the genus Munidopsis the
eggs are always large and correspondingly few in
number, in striking contrast to the closely allied
genus Galathea, from shallow water, in which the
eggs are small and very numerous. Alcock mentions
that a deep-sea Prawn of the genus Psathyrocaris ,
although only about 3J inches long, has eggs nearly
a quarter of an inch in length. It would seem that,
in some way or other, the conditions are unfavour-
able for a free-swimming larval life ; but they cannot

PLATE XVIII

Bathynomus giganteus , about one-half natural size

(From Lankester's “ Treatise on Zoology after Mihi e-Edwards
and Bouvier )

CRUSTACEA OF THE DEEP SEA 131

be altogether prohibitive, for there are a good many
characteristically deep-sea Crustacea, such as the
Eryonidea, that have small eggs and presumably a
larval metamorphosis.

The uniformity of the physical conditions over
vast areas in the deep sea is no doubt the cause of
the enormously wide geographical range of many

Fig. 45 — A Deep-sea Crab ( Platymaia wyville-thomsoni). Reduced.
(After Miers.)

species of deep-sea animals. There are many
examples of this among Crustacea, and they are
added to by every deep-sea dredging expedition.
For example, the giant Isopod Bathynomus
(Plate XVIII.) was first discovered in West Indian
seas, and the same species has since been dredged
near Ceylon, while a second species has been found
off the Japanese coast. Of the strange lobster-like

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THE LIFE OF CRUSTACEA

Thaumastocheles (Fig. 44), mentioned above, only
four specimens are known — one dredged by the
Challenger in the West Indies, and three others
more recently brought from Japan.

The low temperatures prevailing in deep water,
even in tropical seas, render it possible for many
Crustacea to live there which are closely allied to,
or identical with, species occurring in shallow water
in the colder seas of the North and South. Many
examples of this are mentioned by Dr. Alcock in his
discussion of the deep-sea fauna of Indian seas ; for
example, the Lobster Nephrops andamanicus , found at
depths of 150 to 400 fathoms in the Indian seas, is
very closely allied to the Norway Lobster (Nephrops
norvegicus) of our own coasts. To some extent this
fact affords an explanation of the phenomenon that
has been called “ bipolarity ” in the distribution of
marine animals. It has been observed that certain
families, genera, and even species, are found in the
Arctic and Antarctic seas, although they seem to be
entirely absent from the intervening tropical zones.
In some cases, however, it has been found that these
forms occur in the deep sea in the warmer regions
where the cold water offers them a connection
between North and South without any great differ-
ence of temperature.

In the early days of deep-sea exploration, when
naturalists were becoming aware of the rich fauna
inhabiting the abysses of the ocean, which till then

CRUSTACEA OF THE DEEP SEA 133

had been supposed to be barren of all life, it was
confidently expected that representatives would be
discovered of some of the
animals known as fossils
from the earlier geological
periods. It was believed
that the great ocean basins
had remained unchanged
for vast periods of geologi-
cal time, and that numer-
ous “ living fossils” would
be found surviving in the
depths. These hopes have
not been fully realized, for
the deep-sea fauna as a
whole has proved to be of
a comparatively modern
type ; nevertheless, it does
include a considerable
number of primitive and
old-fashioned forms of life,
some of which belong to
groups elsewhere extinct.

This is conspicuously the
case among the Crustacea. Fone6ofP™^Vrto»idea

The lobster-like Eryonidea, f^Fr^BriSh Museum
which at the present day Guide, after Alcock.)

are only found in the deep sea, were long known as
fossils before they were discovered to survive as living

I34

THE LIFE OF CRUSTACEA

animals. The existing species (Fig. 46) are all blind,
with only vestiges of eye-stalks, and they may be
readily distinguished by the fact that the first four, and
sometimes all five, pairs of legs end in chelae, no other
Decapods having more than three pairs of chelate
legs. The fossils occur in rocks of the Secondary
Period, from the Trias to the early Cretaceous.
Some of them, at least, had well-developed eyes, and
probably lived in shallow water. This was almost
certainly the habitat of those (Fig. 47) that are found
preserved in a marvellously perfect state in the litho-
graphic limestone of Solenhofen (famous for the
discovery of Archceopteryx and many other remark-
able fossils), which is believed to have been deposited
in a lagoon. After the early part of the Cretaceous
epoch, the Eryonidea are no longer found as fossils,
and it is, at all events, a probable conjecture that
about that period they forsook the shallow waters
for the deeper recesses of the ocean, where their
descendants have held their own till the present day.

Another group of deep-sea Crustacea which has
affinities with certain fossil forms is the little family
Homolodromiidse among the Crabs. It has already
been mentioned that the Dromiacea are the most
primitive tribe of the Brachyura, and Professor
Bouvier has shown that among these the Homolo-
dromiidse approach most nearly to the lobster-like
forms from which the Crabs have been derived. He
has further shown that the members of this family

CRUSTACEA OF THE DEEP SEA 135

closely resemble in the arrangement of the grooves
upon the carapace the extinct Prosoponidse, which

Fig. 47 — Eryon propinquus , One of the Fossil Eryonidea, from
the Jurassic Rocks of Solenhofen. (From Lankester’s
“ Treatise on Zoology,” after Oppel.)

are known as fossils from Jurassic and Cretaceous
rocks.

136

THE LIFE OF CRUSTACEA

It is in the deep sea also that we find the curious
Hermit Crabs of the family Pylochelidcz (Fig. 37, p. 94),
which are perfectly symmetrical and show no trace
of having ever adopted the habit of living in Gastro-
pod shells ; so primitive, indeed, are these forms that
it is not easy to find characters by which to define
them from the lobster-like Thalassinidea or from the
true Lobsters themselves, and, although no fossil
representatives are yet known, there seems no reason
to doubt that the Pylochelidse are nearly related to
the primitive stock from which the other Hermit
Crabs have been evolved. Among the deep-sea
Prawns there are many forms, both of Penaeidea and
of Caridea, which are more primitive than most of
their relatives from shallow water ; and although in
these cases also the geological records are faulty, we
may assume, if we cannot prove in detail, a general
similarity to the fossil Prawns of Mesozoic rocks.

When all has been said, however, perhaps the most
surprising thing about the deep-sea fauna is, not that
the animals are unlike those living in shallow water,
but that they differ from them so little. When we
consider the physical conditions of the oceanic
abysses — the absolute darkness, the freezing cold,
the pressure measured in tons on the square inch —
it would seem inevitable that the physiological pro-
cesses of deep-sea animals must differ greatly from
those of animals living in shallow water ; yet in
very many cases these differences of function are

CRUSTACEA OF THE DEEP SEA 137

accompanied only by the most trivial differences
in structure. To take one example, the “ Pink
Shrimp” ( Pandalus montagui), which we may find
commonly between tide-marks on our own coasts,
differs only in inconspicuous details from species of
the same genus living at a depth of 600 fathoms ;
while other genera of the family Pandalidae range
downwards to 2,000 fathoms or more, without any
important divergences in structure.

CHAPTER VII

FLOATING CRUSTACEA OF THE OPEN SEA

IT is only rarely that the floating organisms of the
surface of the sea are so large or so abundant
as to catch the attention of the casual observer.
Except for an occasional shoal of porpoises or of
flying-fish, the waste of waters seen from the deck
of a ship in mid-ocean usually seems to be barren of
life. Nevertheless, there is probably no region of
the ocean where the tow-net will not reveal the
existence of a more or less varied fauna and flora.
Sometimes, indeed, these organisms, though minute,
are so numerous as to discolour the water over large
areas ; whalers in the Arctic seas know by the
appearance of “ whale-food ” where whales are likely
to be found, and herring or mackerel fishermen
recognize the changes in colour of the water among
the “ signs ” which guide them when and where to
shoot their nets.

The organisms which make up this “pelagic”
fauna and flora may be grouped into two classes,
which may be termed the “swimmers,” or Necton,

138

PELAGIC FLOATING CRUSTACEA 139

and the “ drifters,” or Plankton. The former include
the larger and more active animals, such as fish,
whales, and the like, whose movements are more or
less independent of the movements of the water;
the latter comprise the plant-life and the floating or
feebly swimming animals that drift at the mercy of
waves and currents. A great deal of attention has
been given in recent years to the study of the
plankton, and it has come to be recognized as filling
a very important place in the balance of life in the
sea. In the sea, as on land, all the animals are
ultimately dependent on plants for their food. The
larger and more conspicuous sea-weeds which grow
on the sea-bottom, however, can only flourish in
comparatively shallow water, and the region which
they occupy forms only a narrow fringe round the
land-masses of the globe. It is only necessary to
look at a map of the world, showing the depth of
the sea, to realize what an insignificant part of the
area of the oceans contributes in this way to the
food-supply of marine animals. The microscopic
plant-life of the plankton, however, makes up for the
individual minuteness of its constituents by their
incalculable numbers. The lowly organisms known
as “ diatoms,” familiar to the microscopist from the
beauty of their flinty skeletons, are among the most
numerous and important of these, and they are
associated with a great variety of other single-celled
algae and allied organisms, some of them so minute

140

THE LIFE OF CRUSTACEA

that they pass through the finest silk plankton-nets,
and have to be sought for by special methods of
collection recently devised for the purpose. All
these organisms possess the green colouring matter
(chlorophyll) that enables them to live, as the higher
plants do, on the carbon dioxide and other sub-
stances dissolved in the water. The smaller animals
of the plankton feed on these vegetable organisms,
and in their turn serve as food for larger animals.
The Herring, the Mackerel, the gigantic Basking
Shark, and the still more gigantic Greenland Whale,
all feed directly on the animal plankton, and we
have already seen that the animals of the deep sea
depend entirely on the same source of food-supply.
Further, very many of the bottom-living animals of
shallow water swim at the surface in the early stages
of their life, and feed on the other plankton animals
and plants. Indeed, it is no exaggeration to say
that “ all fish is diatom ” in the same physiological
sense as “ all flesh is grass,” and the study of the
plankton is thus of practical importance as well as
of scientific interest.

Of all the minute animals that form the inter-
mediate links in the chain between diatom and fish
or whale, the Crustacea are the most important and
the most numerous both in species and in individuals.
The Copepoda are more richly represented than any
of the other groups, and it would be difficult to find
a sample of marine plankton from which they were

PELAGIC FLOATING CRUSTACEA 141

altogether absent. Associated with them we find
one or two species of Cladocera, a larger number of
Ostracoda (chiefly of the family Halocypridse), a few
Mysidacea, the Amphipoda of the suborder Hyperi-
idea, the Euphausiacea, and some of the shrimp-
like Decapods ; while the larval stages of these and
other groups also form an important part of the
plankton.

It is necessary to make a distinction between the
“ neritic ” plankton of shallow water near the coast
and the “ oceanic ” plankton of the open sea. In
the inshore waters the plankton consists not only of
organisms that pass the whole of their life at or near
the surface, but also, and very largely, of the free-
swimming larvae of bottom-living species, and of
others that make occasional and temporary excur-
sions to the surface. For example, if the tow-net
be used a short distance from land — say in some
sheltered bay on our own coasts — the catch will
often be found to consist largely of larval Crustacea.
The zoea and megalopa stages of Crabs, the zoea
and schizopod stages of Prawns and Shrimps, are
often conspicuous by their numbers, or we may find
swarms of the nauplius and cypris larvae of Barnacles.
Sometimes, and especially at night, numbers of
Cumacea may be found in the tow-net ; and it is
noteworthy that these are usually males, which leave
the females burrowing in the mud at the bottom,
and swarm to the surface for a brief period of

142

THE LIFE OF CRUSTACEA

activity. Besides all these more or less temporary
visitors, however, there are numerous species, even
in the inshore waters, which are adapted to a
floating life, and pass their whole existence as
members of the plankton. Copepoda of many kinds,
some Mysidse, Amphipods like Hyperia — which is
commonly found sheltering under large jellyfish —
some species of actively swimming Isopods, and
many other forms, are only to be captured by the
tow-net ; and now and then, in certain localities,
winds and currents may drive into coastal waters
shoals of species whose proper home is the open
ocean.

In a similar way the strictly neritic forms may
sometimes be carried far out to sea, so that it is
nowhere possible to draw a hard-and-fast line be-
tween the regions occupied by the neritic and the
oceanic plankton. With increasing distance from
land, however, the larval stages of bottom-living
species become fewer, and finally disappear alto-
gether, and there is left an assemblage of animals
whose whole existence is passed floating at the
surface or at the intermediate depths. How far
down from the surface this floating fauna actually
descends is a question which has been much debated.
It appears now to be certain that there is no stratum
of water between the surface and the bottom of the
ocean which is devoid of life, although the upper
layers (not at, but some distance below, the surface)

PELAGIC FLOATING CRUSTACEA 143

are probably much more densely populated than
those of the abyss. Many of the species appear to
undertake more or less extensive migrations in a
vertical direction, coming nearer the surface at
certain stages of their life-history, and sinking into
deeper water at others. Further, some species at
least seem to rise to the surface at night, and to
sink again during the day. Apart from these vertical
movements, which are as yet only imperfectly under-
stood, it is desirable to distinguish between the
“ epiplankton,” comprising the organisms which
inhabit the superficial strata of the ocean down to
about 100 fathoms, and the “ mesoplankton,” found
at greater depths. The plant-life which is dependent
on sunlight belongs to the epiplankton, while the
animals of the mesoplankton are dependent, like
the bottom animals of the deep sea, on the supply
of dead food material falling from above. A third
division, the “ hypoplankton,” has been established
for those animals which live immediately above the
bottom, but its distinctness from the mesoplankton
has not yet been satisfactorily established. Indeed,
many of the swimming forms which have already
been mentioned in dealing with the Crustacea of the
deep sea are probably rather to be considered as
belonging to the deep mesoplankton — at least, where
their size and swimming powers do not entitle them
to be ranked with the “ necton.”

Many of the modifications in structure character-

144

THE LIFE OF CRUSTACEA

istic of pelagic animals may be traced to the necessity
for keeping continuously afloat with a minimum of
exertion. The Crustacea of the plankton never
carry the heavy armour found in bottom -living
species. Thus, the thick-shelled Ostracoda of the
bottom are represented in the plankton chiefly by
the family Halocypridse (Fig. 48), in which the shell
is thin, uncalcified, and almost membranous. Many
species, particularly of the Copepoda, are seen,

Fig. 48 — Conchoecia curta, an Ostracod of the Plankton, x 40.

(Partly after G. W. Mtiller.)

under the microscope, to have large globules of oil
distributed through the tissues of the body, and
these no doubt serve as floats, increasing the
buoyancy of the animal. The same purpose is
probably served, in many cases, by having large
spaces, filled with fluid, within the body. This is
characteristic of pelagic animals, and is well seen
in many of the Crustacea in which the viscera and
muscles occupy a relatively small part of the interior
of the animals, the intervening spaces being filled
with colourless transparent fluid. Many of the

PELAGIC FLOATING CRUSTACEA 145

Hyperid Amphipoda show this peculiarity — for
example, the relatively gigantic Cystisoma, which is
mesoplanktonic in deep water; and it reaches its
extreme in Mimonectes (Fig. 49), in which the anterior
part of the body is, as it were, blown out into a

Fig. 49 — Mimonectes loveni. A Female Specimen seen from the
Side and from Below, showing the Distended-balloon-
like Form of the Anterior Part of the Body. x 3.
(After Bovallius.)

balloon, giving the animal the aspect of a small
jellyfish rather than an Amphipod.

If, as seems probable, the body-fluid of these
animals is of a lower specific gravity than the sea-
water, it will act like the oil-globules of the Co-
pepoda in keeping the animals afloat. Even if the
specific gravity be the same, however, the distension
10

146

THE LIFE OF CRUSTACEA

of the body with fluid acts in another way, by
increasing the surface exposed to friction with the
surrounding water, and so retarding sinking. The

Fig. 50— The Zoea Larva of a Species of Sergestes , taken by
the “ Challenger ” Expedition, x 25. (After Spence Bate.)

principle involved is illustrated by the fact that a
soap-bubble sinks much more slowly through the
air than the drop of water into which it collapses.

PELAGIC FLOATING CRUSTACEA 147

The same result is produced if the surface is increased
by outstanding spines or hairs, just as, for instance,
a downy feather sinks slowly through the air, but

Fig. 51 — The Nauplius Larva of a Species of Barnacle of
the Family Lepadid<e, showing greatly-developed Spines.
From a Specimen taken in the Atlantic Ocean, near
Madeira, x ii. (After Chun.)

drops rapidly if it is rolled into a ball between the
fingers. This is, no doubt, one function of the
spines with which plankton Crustacea, and particu-
larly larvse, are frequently provided, though they

148

THE LIFE OF CRUSTACEA

may also serve in some cases as a protection
against enemies. The spines have been already
alluded to in describing the various larvae, but it may
be noted here that they are most strongly developed
in larvae which live in the open ocean ; for example,
the most elaborately armed of all Decapod larvae are
the zoea stages of Sergestes (Fig. 50), which, like the

adults, belong to the oceanic plankton. The nau-
plius larvae of Cirripedes are all more or less spiny,
and the spines reach an exaggerated development in
the larvae of the genus Lepas (Fig. 51), of which the
adults are attached to floating drift-wood or the like,
and belong to the oceanic fauna, although hardly to
be classed with the plankton.

PELAGIC FLOATING CRUSTACEA 149

The large feathered bristles that decorate the
limbs or tail of many plankton Copepoda have no
doubt the same function in assisting flotation. In
the genus Calocalanus (Fig. 52), for example, the
tail setas are large and brilliantly coloured feathery
plumes, and in one species, C. plumulosus, one of
these setae is of relatively enormous size, five or six
times as long as the body of the animal itself.

Among the most singular of plankton Crustacea
are the Phyllosoma larvae (see Fig. 28, p. 72) of the
Spiny Lobsters and their allies (Scyllaridea), which
have been already described. These larvae are
sometimes found far out at sea, and it seems likely
that their larval life is unusually prolonged, and that
they may be drifted to great distances by ocean
currents. At all events, they are well adapted for
pelagic life, since the broad flat body, hardly thicker
than a sheet of paper, can be sustained in the water
like a “ hydroplane ” by comparatively slight efforts
of the swimming legs.

The watery character of the body, together with
the thinness of the exoskeleton, helps to explain the
glassy transparency which is a feature of most
plankton Crustacea. This transparency has been
regarded as a protective adaptation rendering the
animals inconspicuous in the water, and it has
indeed that effect to human eyes, but it is very
doubtful whether the animals derive much benefit
from this. Many of the animals — such as Herring

150 THE LIFE OF CRUSTACEA

and other pelagic fishes — that prey upon plankton
Crustacea appear to swallow them in bulk, with-
out much selection ; and the Greenland Whale, as
it swims open-mouthed through the sea, is not likely
to be guided by the greater or less visibility of the
Copepods that it sifts out on its baleen plates.
Further, this glass-like transparency is by no means
universal, for many plankton Copepoda are brightly
coloured. In some, as in the beautiful blue Anomalo-
cera, common in British waters, the colour is due to
pigment in the fluids and tissues of the body ; in
others the feathery hairs on the body and limbs
show brilliant metallic colours, produced, like the
colours of a peacock’s feather, not by pigments,
but by the diffraction of light in the texture of
the organ. The most beautiful of all Copepoda is
Sapphirina , in which the surface of the body
absolutely sparkles with iridescent colours.

The striking phenomenon known as the “ phos-
phorescence of the sea ” is familiar to every ocean
voyager, and is seen from time to time on our own
coast. On a dark night the crest of every wave
often seems to break in a pale glow, the wake of the
vessel is a trail of light, and an oar dipped in the
water seems on fire. This luminosity is due to
the animals of the plankton, largely to the lowly
Protozoa and the jellyfishes, but in part also to
certain Crustacea. A number of pelagic Copepoda
have been shown by Giesbrecht to secrete, from

PELAGIC FLOATING CRUSTACEA 151

special glands on the surface of the body, a sub-
stance which becomes luminous on coming in contact
with the water. Even specimens which had been
dried were found to give out light on being wetted.
Some pelagic Ostracods of the family Halocypridse
have been observed to emit clouds of a luminous
secretion from a gland in the neighbourhood of the
mouth. A similar habit has been seen, as already
mentioned, in certain deep-sea Prawns and Mysidacea,
which may perhaps belong to the deeper part of the
mesoplankton rather than to the bottom fauna. The
complex light-producing organs of the Euphausiacea
have already been described in dealing with deep-sea
Crustacea. A great many species of this group,
however, are members of the epiplankton, and in
these the phosphorescent apparatus is quite as fully
developed as in species coming from greater depths.
Meganyctiphanes norvegica (Fig. 24, p. 56), which is
one of the largest of the Euphausiacea, is common
at no great depths in many places in British seas.
If a jar of sea-water in which specimens of this
species are swimming be brought into a dark room,
a tap on the glass will cause the photophores to flash
out like a row of tiny lamps along the side of the
body. After shining for a few seconds the light dies
out, to appear again if the tapping be repeated.

There are certain peculiarities in the structure of
the eyes in some plankton Crustacea which suggest
that the sense of sight is of special importance to

152

THE LIFE OF CRUSTACEA

their possessors, although we can hardly do more than
guess at their special significance. Most Copepoda
have only a single eye in the middle of the head,
corresponding to the single eye of the nauplius larva,
and of far simpler structure than the paired com-
pound eyes of most other Crustacea. In many
plankton species, however, this simple eye becomes
much enlarged and complicated in various ways.
The three parts of which it is normally made up
may become separated from each other, and are
sometimes increased in number to five, while lenses
serving to concentrate the light are often developed
by thickening of the overlying cuticle. The most
elaborately constructed eyes are found in the family
Corycaeidse. In Copilia (Fig. 53) a pair of eyes of
relatively enormous size are present. Each has in
front a large biconvex lens set at the end of a conical
tube which extends backwards to a smaller lens (like
a telescope with object-glass and eyepiece), behind
which, again, are the sensory cells, corresponding to
the retina, enclosed in a tube of dark pigment, the
whole apparatus being more than half the length
of the body. These eyes, although paired, do not
correspond to the paired compound eyes of other
Crustacea, but have arisen by the separation and
enlargement of two of the three divisions of the
typical median Copepod eye.

A peculiarity of the paired compound eyes found
in plankton Crustacea of several different orders

PELAGIC FLOATING CRUSTACEA 153

consists in the division of each eye into two parts,
which differ in structure. In many Euphausiacea
and Mysidacea, especially in those haunting the

Fig. 53 — Copilia qtiadrata (Female), a Copepod of the Family
CoRYC^EID^E, SHOWING THE PAIR OF LARGE “ TELESCOPIC ” EYES.

x 20. (After Giesbrecht.)

deeper strata (mesoplankton), this division of the
eyes is well marked, a frontal or dorsal part having
the separate elements of the eye (ommatidia) greatly

154

THE LIFE OF CRUSTACEA

lengthened and with reduced pigment, while the
lateral part is of more normal structure. It seems
probable, from the researches of Professor Chun,
that the fronto-dorsal division is adapted for the
perception of very faint light, while the lateral
division will give a more accurate image of brightly
illuminated objects.

Fig. 54 — Phronima colletti, Male. From a Specimen taken in Deep
Water near the Canary Islands, x 12. (After Chun.)

In the pelagic Amphipoda, forming the suborder
Hyperiidea, the eyes are of very large size, generally
occupying almost the whole surface of the head, and
giving the animals a very characteristic appear-
ance, in contrast to the small-eyed, bottom-living
Gammaridea. In the family Phronimidse (Fig. 54)
the eyes are each divided into two parts, differing in
structure in the way just described.

PLATE XfX

Latreillia elegans, one of the dromiacea which resembles a spider-crab.

FROM THE MEDITERRANEAN. (NATURAL SIZE)

THE GUI.F-WEED CRAB, PlatlCS minutuS. (SLIGHTLY ENLARGED)

PELAGIC FLOATING CRUSTACEA 155

There are a few Crustacea living habitually on the
high seas which cannot be reckoned as belonging
either to the true plankton or to the necton, since
they depend on outside help for keeping themselves
afloat. Among these are the Barnacles which cluster
on logs of drift-wood, and are among the most
important causes of the “ fouling ” of ships’ hulls on
long voyages. The stalked Barnacles of the genus
Lepas are especially common in such situations, and
the characters of their larvae have been already
alluded to. Certain species of sessile Barnacles are
constantly found attached to large marine animals.
For example, Chelonobia adheres to the shell ol
Turtles, while Coronula and some allied genera are
found on Whales.

The little “ Gulf-weed Crab ” ( Planes minutus —
Plate XIX.) is found clinging to floating drift-weed
nearly everywhere throughout the temperate and
tropical seas of the globe, and is especially common
in the area known as the Sargasso Sea, in mid-
Atlantic. It is occasionally drifted to the south
coasts of the British Islands. In Sloane’s “ Natural
History of Jamaica,” published in 1707-1725, it is
stated of the Gulf-weed Crab that “ Columbus, find-
ing this alive on the Sargasso floating in the sea,
conceived himself not far from some land, on the
first voyage he made on the discovery of the West
Indies.”

A few other Crustacea also form part of the

156 THE LIFE OF CRUSTACEA

peculiar fauna which is associated with the Sargasso
weed, notably a swimming Crab, Neptunus sayi , and
two or three species of Prawns. All of these are
coloured olive-green, like the weed among which
they live.

CHAPTER VIII

CRUSTACEA OF FRESH WATERS

HE Crustacean fauna of fresh water is much

-1* less rich and varied than that of the sea.
Although the number of individuals in a pond or
lake may be enormous, they will be found to belong
to a comparatively small number of species. All the
subclasses of Crustacea with the exception of the
Cirripedia have representatives in fresh water, but
in most of them only a very few of the families and
genera comprise truly fresh-water species. In spite
of the comparative poverty of the fauna, however, it
is of very great interest, more especially with regard
to the problems of geographical distribution ; and
the ease with which specimens may be collected
everywhere, and kept in small aquaria, renders it
a particularly attractive subject of study for the
amateur naturalist.

The general uniformity of the fresh-water fauna
throughout the world has often been remarked.
Darwin says : “ When first collecting in the fresh
waters of Brazil, I well remember feeling much

THE LIFE OF CRUSTACEA

158

surprise at the similarity of the fresh-water insects,
shells, etc., and at the dissimilarity of the surround-
ing terrestrial beings, compared with those of
Britain.” This uniformity is well illustrated by
many of the smaller Crustacea. In a gathering of
Cladocera, Copepoda, and Ostracoda, from Central
Africa or from Australia, we find that most of the
genera, and even some of the species, are identical
with those found in similar situations in this country.
It is by no means the case that all the species and
genera are thus universally distributed, for there are
many, especially among the larger forms, which
have a very restricted range ; but this does not
render less striking the general uniformity of the
fauna over very wide areas.

When we consider the physical environment of
fresh-water animals, it seems at first sight as if this
wide distribution were the reverse of what might
have been expected, for the area occupied by them
is far more discontinuous than in the case of terres-
trial or marine animals. The inhabitants of a pond
or lake are to a great extent isolated ; and although
they may spread to other ponds and lakes by way of
communicating streams or rivers, where these are
not too swiftly flowing and are not interrupted by
falls, yet direct passage from one river system to
another is rarely possible. Further, since practically
the whole of the fresh water on the surface of the
globe is constantly flowing, more or less rapidly,

CRUSTACEA OF FRESH WATERS 159

towards the sea, the smaller feebly swimming forms
tend to be swept down with the current, and ulti-
mately carried to perish in the sea. It follows that
only those forms which possess special adaptations
for dispersal are able to flourish in fresh water. In
many cases, as will be described below, the eggs of
tlie smaller Crustacea can survive being dried up,
and in this state they may be blown about by wind
or carried to great distances in mud, adhering to the
feet of migratory wading birds. Darwin says : “ The
wide-ranging power of fresh-water productions can,
I think, in most cases be explained by their having
become fitted, in a manner highly useful to them,
for short and frequent migrations from pond to
pond, or from stream to stream, within their own
countries ; and liability to wide dispersal would
follow from this capacity as an almost necessary
consequence ” (“ Origin of Species,” sixth edition,
chapter xiii.). In accordance with this, we find that
it is just those groups of Crustacea which show these
adaptations for dispersal that are most universally
distributed in fresh water. On the other hand, the
larger Crustacea, like the Crayfishes and River
Crabs, which cannot so easily be transported from
one locality to another, have as a rule a more
restricted range. These larger forms, from their
size and powers of swimming or creeping, can make
their way upstream and spread throughout a river
system, and in some cases they can leave the water

THE LIFE OF CRUSTACEA

160

and journey for short distances overland. On the
other hand, since free-swimming larvse would be
liable to be swept out to sea, most of them have
a direct development, the young only leaving the
protection of the mother when they have attained
the form and habits of the adult. When all these
factors have been taken into account, however, there
still remain many cases where the distribution of
individual species or of groups is hard to explain,
and shows indications of dating from a time when
the outlines of continents and the connections of
river systems were different from what they are now.

Before proceeding to mention some of the more
characteristic forms of fresh-water Crustacea, it
should be mentioned that in large lakes, as in the
sea, we can distinguish a littoral fauna in the shallow
waters close to the shore, a plankton fauna of the
surface waters, and a deep-water fauna. The littoral
fauna does not differ in general characters from that
found in smaller ponds and gently-flowing rivers;
the plankton comprises many peculiar species show-
ing adaptations for flotation, as in the case of the
marine plankton ; and the deep-water fauna is very
poor in species and in individuals, and shows some
relations with the subterranean fauna to be men-
tioned later.

Of all the subclasses of Crustacea, the Branchio-
poda are the most characteristically fresh-water
animals, only a few Cladocera being found in the

CRUSTACEA OF FRESH WATERS 161

sea, and some Anostraca in salt lakes and brine
pools.

The larger Branchiopoda (Anostraca, Notostraca,
and Conchostraca) are generally found in small,
shallow ponds which are liable to be dried up
in summer. The “ Fairy Shrimp ” ( Chirocephalus
diaphanus ; see Fig. io, p. 35) has been found in
swarms in the water standing in deep cart-ruts in
a country lane in England, and Apus sometimes
appears suddenly in rain-water puddles of a few
square yards in area, which dry up after a few weeks
of hot weather. The eggs of these animals, when
dried in the mud, may remain dormant for long
periods, and many species have been hatched out
from samples of dried mud brought by travellers
from distant countries. In such a sample from the
Pool of Gihon at Jerusalem, it is recorded that the
eggs of Estheria (see Fig. 11, p. 36) were found to
be capable of hatching after being kept dry for nine
years. In some species it is said that the eggs will
not develop unless they have been first dried, but
this is not the case with Chirocephalus. In favour-
able conditions development takes place very rapidly.
Messrs. Spencer and Hall, in describing the Branchi-
opoda of Central Australia,, say : “ Certainly not more
than two weeks after a fall of rain, and probably
only a few days, numberless specimens of Apus ,
measuring in all about z\ to 3 inches in length, were
swimming about ; and, as not a single one was to be

11

162

THE LIFE OF CRUSTACEA

found in the water-pools prior to the rain, these
must have been developed from the egg.”

From what has been said, it is apparent that the
larger Branchiopoda are particularly well fitted to
be distributed by the agency of birds, and this is no
doubt the explanation of the way in which many of
the species suddenly appear in localities where they
were previously unknown, and, after swarming for
a longer or shorter time, sometimes for several suc-
cessive seasons, as suddenly vanish. A striking
example of this is afforded by Apus cancriformis
(see Plate II.), which formerly occurred in several
localities in the South of England, and appears more
or less irregularly in many parts of the Continent of
Europe. No British specimens had been recorded
for over forty years, and the species was believed to
be extinct in this country, when it was found in 1907
by Mr. F. Balfour Browne in a brackish marsh near
Southwick, in Kirkcudbrightshire. It can hardly be
supposed that so large an animal as Apus, and one
so easily recognized, would have escaped notice alto-
gether had it occurred regularly in any part of the
British Islands. It is much more probable that the
Scottish specimens found in 1907 had developed
from eggs accidentally transported by some bird
from the Continent. In 1908 a careful search
in the same locality failed to reveal a solitary
specimen.

The Anostraca and Notostraca usually swim with

CRUSTACEA OF FRESH WATERS 163

the back downwards. Particles of mud and of animal
and vegetable matter are drawn by the currents pro-
duced in swimming, into the ventral groove between
the pairs of feet, and are passed forwards to the
mouth to serve as food. Some species of Conchos-
traca are said to swim in the same inverted position ;
but Messrs. Spencer and Hall, in the memoir already
quoted, state that the Australian Conchostraca swim
back uppermost. They attribute the difference in
habit between the Conchostraca and Notostraca
to the fact that in the former group the valves of
the shell can be rapidly closed to protect the soft
and vulnerable appendages, while no such protection
is possible in the Notostraca. They found on one
occasion a specimen of Apus (Notostraca) attacked
by three Water-beetles, which were tearing its soft
appendages, and they suppose that Apus generally
escapes such attacks by swimming upside down.

The breeding habits of the Branchiopoda are also
of interest, from the prevalence in many species of
reproduction by unfertilized eggs, or “partheno-
genesis.” This may go on for many generations,
and in Apus, for instance, it is possible to examine
thousands of specimens before finding a single male,
although, for some unexplained reason, males are
sometimes comparatively common. It is probable
that males must appear sooner or later, otherwise
the series of parthenogenetic generations will come
to an end: but it is not certain that this is the

164

THE LIFE OF CRUSTACEA

case, and there are some species of Conchostraca
of which the males have never been seen.

The genus Artemia (Fig. 55), among the Anostraca,
is peculiar in its habitat ; for, while most of the

A, Female, under-side, x 6 ; B, head of male, upper side, further
enlarged, showing the large clasping antennae. The larval
stages of this species are shown in Fig. 33, p. 81

Branchiopoda inhabit fresh or brackish water, it
flourishes in concentrated brine. In the South of
Europe it is found, as it was formerly in England,
in the shallow ponds in which sea-water is exposed

CRUSTACEA OF FRESH WATERS 165

to evaporation for the manufacture of salt, and in
these it occurs in such numbers as to give the water
a reddish colour. It is also found in salt lakes, like
the Great Salt Lake of Utah, in the United States,
and in many other parts of the world. The specimens
from different localities often differ considerably,
especially in the form of the tail-lobes ; but it has
been shown that these differences are more or less
directly correlated with the degree of salinity of the
water in which the animals live, and it is probable
that the forms which have been described are all
variations of a single cosmopolitan species ranging
from Greenland to Australia, and from the West
Indies to Central Asia. Artemia is the only one of
the Anostraca that is known to be parthenogenetic,
some colonies consisting entirely of females, while
in others males are abundant. The reddish colour
above alluded to is found also in Branchipus, Apus ,
and other Branchiopoda, and is due, as Sir Ray
Lankester first showed, to the presence in the body-
fluids ot haemoglobin, the red colouring matter of
the blood of Vertebrates, which is important in the
process of respiration.

The smaller Branchiopoda known as “ Water-fleas,”
forming the order Cladocera, are abundant every-
where in fresh water. Daphnia pulex and other
speces of the genus, and the little Lynceidae, of
which Chydorus sphcericus (Fig. 56) is the commonest
species, are to be found in ponds and ditches, and

i66

THE LIFE OF CRUSTACEA

often swarm in farmyard ponds where the water is
foul with decaying matter. In most gatherings from
such localities only female specimens will be found,
and nearly all of these will be seen to carry a cluster
of eggs or of developing embryos in the “ brood-
chamber ” between the back part of the body and
the shell. In Daphnia pulex (see Fig. 12, p. 37) a
single brood may consist of
thirty young, and occasionally
of more than twice that number.
As the broods may succeed each
other at intervals of two or
three days, it will be seen that
the multiplication of the species
in favourable circumstances may
be exceedingly rapid. It has
been calculated that in sixty
days the progeny of a single
female might amount to about 13,000,000,000. In
addition to these parthenogenetic eggs, which hatch
at once while still within the brood-chamber, the
Cladocera produce, at certain seasons, another kind of
egg which requires to be fertilized by the male before
it will develop. These eggs are dark in colour and
are enclosed in a thick shell, and they do not hatch
at once, but are cast off when the shell of the female
is moulted. Very commonly these “ resting eggs,”
as they are called, are produced in the autumn and
lie dormant until the following spring, and they can

Fig. 56 — Chydorus
spharicus, a Common
Species of Water-
flea. x 50. (After
Lilljeborg.)

CRUSTACEA OF FRESH WATERS 167

survive drying or freezing without injury, while the
thin-shelled parthenogenetic eggs within the brood-
chamber of the mother are easily killed. In addition
to having thick shells, the resting eggs are further
protected in most, but not in all, cases by the
moulted carapace of the parent, which is specially
thickened for the purpose.

This modification of the cara-
pace is most highly developed
in the family Daphniidse
(Fig. 57), where a saddle-
shaped area on the dorsal
side, known as the “ ephip-
pium,” becomes thickened,
and on moulting separates
from the rest of the carapace
to form a compact case en-
closing the two resting eggs.

The outer wall of the ephip-
pium is divided up into small
hexagonal cells, which become filled with air, causing
the ephippium to float at the surface of the water.
In this position the ephippia readily become en-
tangled in the feathers of birds, and in some cases
the shell is provided with spines or hooks, which
facilitate transport to other localities by such means.

The appearance of males and the production of
ephippial eggs — in other words, the “ sexual period”
— is generally more or less restricted to one season

Fig. 57 — A Water-flea,
(Daphnia pulex), Female,
with Ephippium con-
taining Two “ Resting
Eggs.” x 20. (Partly
after Lilljeborg.)

The Antenna is cut short.
Compare Fig. 12, p. 37.

i68

THE LIFE OF CRUSTACEA

of the year. In most species, particularly in those
which live in lakes, the sexual period occurs in the
late autumn, and the ephippial eggs lie dormant
during the winter, and hatch in the spring. In
species living in small ponds exposed to the risk of
overheating or of drying up during summer, there is
often a distinct sexual period in the spring, when
ephippial eggs are produced to tide over the un-
favourable conditions of the warmer months of the
year. Although no species is known to be exclusively
parthenogenetic, yet it appears that purely partheno-
genetic colonies of certain species may be found in
favourable localities, where they may reproduce from
year to year without males ever being found.

Certain species of Cladocera belong to the plankton
of lakes and large ponds, and show modifications
which adapt them for a floating life. Some of these
belong to the genus Daphnia , and differ from the
species found in other situations by their glassy
transparency. As in the case of many marine
plankton Crustacea, this transparency is probably
due to the thinness of the shell and to the general
watery condition of the body, giving the necessary
buoyancy to enable the animal to remain constantly
afloat. The same effect is no doubt produced by the
long terminal spine of the carapace and by the great
helmet-shaped crest into which the upper part ot
the head is often produced. A form very character-
istic of the plankton of large lakes is Bythotrephes

CRUSTACEA OF FRESH WATERS 169

(Fig. 58), which is found in the lakes of Scotland,
Ireland, Wales, and the Lake District of England.
In Bythotrephes the carapace does not enclose the
body, but is reduced to a small brood-sac; the
addomen, however, is drawn out into a long spine,
which may be two or three times as long as the
body. A further point of interest is the division of
the eye into a dorsal and a ventral portion, differing

Fig. 58 — Bythotrephes longimanus, Female, with Embryos in the
Brood-sac. x 12. (After Lilljeborg.)

in structure in much the same way as do the two
divisions of the eyes in certain marine plankton
Crustacea (see p. 152). Another very remarkable
lacustrine form is Leptodora, the largest of all the
Cladocera, being sometimes more than half an inch
in length. In this case also the carapace is very
small, and does not enclose the body. The swimming
antennae are very large, and the abdomen is long and
divided into several segments.

Leptodora is further remarkable on account of its
mode of development. The parthenogenetic eggs,

170

THE LIFE OF CRUSTACEA

as in other Cladocera, develop directly, but the
resting eggs give rise to larvae of the nauplius type.

Holopedium, which is found in similar situations,
surrounds itself with a mass of a jelly-like substance
which it secretes. A similar envelope of jelly is
found in some marine plankton animals, though not,
so far as is known, in any Crustacea, and it no
doubt serves to give buoyancy to the animal.

The Copepoda of fresh water are as abundant and
universally distributed as the Cladocera. Species
of the genus Cyclops (see Fig. 14, p. 39), easily
recognized by the pear-shaped body and the two
egg-packets carried by the female, are to be found in
almost every pond and ditch. The genus Cantho-
camptus comprises species of smaller size, with
slender, flexible body, and carrying only a single
egg-packet. The plankton of lakes and ponds
includes species of Diaptomus (Fig. 59), which have
a narrow body and very long antennules. The latter
are held out stiffly while the animal swims by rapid
movements of the antennae and mouth parts, making
occasional sudden leaps by means of its oar-like feet.
In this genus also the egg-packet is single. The
development can easily be studied by keeping egg-
carrying females of Cyclops in a jar of water, when
the nauplius larvae will soon hatch out.

Although the Copepoda, unlike the Cladocera, are
ot parthenogenetic, it has been found that certain
species of Diaptomus produce resting eggs capable of

CRUSTACEA OF FRESH WATERS 171

surviving freezing or drying. In the early part of
the breeding season the eggs have thin shells, and
they hatch after a short time. In the autumn,
however, thick-shelled eggs are produced, which lie
dormant in the mud until the following spring. It
has recently been discovered that species of Cyclops
and Canthocamptus pass through a resting stage, in

Fig. 59 — Diaptomus coeruleus , Female, x 25. (After Schmeil.)

which the animal surrounds itself with a cocoon-like
capsule of mud held together by a glutinous secretion
produced by glands on the surface of the body and
limbs. The encapsuled animals, in the cases
observed, lie dormant in the mud during the
summer, to resume active life in the colder months
of the year. It is very probable that they can also
be dried without injury, and that the “ cocoons ”

172 THE LIFE OF CRUSTACEA

serve the same purpose as the resting eggs of other
species.

Numerous species of Ostracods, belonging to the
genus Cypris (see Fig. 13, B, p. 38), and other closely
related genera, occur in fresh water. Like the
Cladocera, they reproduce largely by partheno-
genesis, and the males of many species are rarely
found, while in some species they have not }’et been
discovered. In Professor Weismann’s laboratory
at Freiburg a colony of Cypris was kept in an
aquarium for eight years, and during the whole of
that time no males made their appearance, the
colony reproducing exclusively by parthenogenesis.
Probably in all species the eggs survive drying.

The common “ Freshwater Shrimp ” ( Gammarus
pulex), which has already been described, may be
taken as a type of a large number of Amphipoda, for
the most part closely allied, which are widely dis-
tributed in most regions of the world, with the
exception of the tropics. G. pulex itself ranges from
the British Islands to Mongolia. As the eggs
are carried, till they hatch, in the brood-pouch of
the parent, and are not known to survive drying, it
is difficult to understand in what way Gammarus
and its allies contrive to spread from one locality
to another.

The little fresh- water Isopod Asellus aquaticus
(Fig. 60) is common in ponds and canals in this
country. It may be recognized by its general resem-

CRUSTACEA OF FRESH WATERS 173

blance to a Woodlouse, with very long antennae, and
with a pair of long, slender, forked uropods project-
ing behind. The species is widely distributed in
Europe, and other species of the same and closely
related genera are found in North America.

In Australia and New Zealand the Isopoda are
represented in fresh waters by a very peculiar group

of species, forming the suborder Phreatoicidea,
which have more the aspect of Amphipods than of
Isopods, since the body is more or less flattened
from side to side, instead of from above downwards.

With regard to the mode of distribution of the
fresh-water Isopoda, there is the same difficulty as
in the case of the Amphipoda, for the eggs are

174

THE LIFE OF CRUSTACEA

carried in a brood-pouch, and do not seem to be in
any way protected against drought. It is no doubt
in consequence of this that the fresh-water species
and genera of both Amphipoda and Isopoda, though
widely distributed, do not have the world - wide
range of many of the more minute Crustacea
described above.

The common Crayfish, Astacus (or Potamobius)
pallipes , is the only truly fresh-water Decapod found
in England, although a small Prawn, Palcemonetes
varians , which usually inhabits brackish water, may
occasionally be found in places where the water is
practically fresh. The structure of the Crayfish is
very similar to that of the Lobster, but, as already
mentioned, it differs in its mode of development,
having no free-swimming larval stage. From its
size, and from the fact that the eggs are carried by
the female, the Crayfish cannot be transported from
one locality to another by the agencies which dis-
tribute the smaller fresh-water Crustacea. On the
other hand, the adult animals can live out of the
water for days, or even weeks, if they are kept moist,
and the English species is stated to leave the water
occasionally, and to make short excursions on land.
Many species found in foreign countries are still
more truly amphibious in their habits. It is clear,
however, that the means of dispersal of the Cray-
fishes are very limited, and on this account the
problems connected with their geographical distribu-

Fig. 6i — Map showing the Distribution of Crayfishes. (Partly after Ortmann.)

The dotted areas are those occupied by the Northern Crayfishes (family Astacidas). The black patches mark the areas
inhabited by the Southern Crayfishes (family Parastacidae)

176

THE LIFE OF CRUSTACEA

tion are of great interest. An admirable discussion
of the subject will be found in Professor Huxley’s
book on the Crayfish, and the conclusions reached
by him have hardly been modified by thirty years
of subsequent research. Only a very brief outline
can be attempted here.

Crayfishes are found in the fresh waters of the
Northern and Southern Hemispheres (Fig. 61), but in
each case they are practically confined to the tem-
perate regions, and are absent from a broad inter-
vening tropical zone. The Northern Crayfishes,
forming the family Astacidse (or Potamobiidse) are
distinguished, among other characters, by having a
pair of appendages on the first abdominal somite,
at least in the male sex ; the Southern Crayfishes
have no appendages on that somite, and for this and
other reasons are regarded as constituting a distinct
family — Parastacidae. There is thus a general corre-
spondence between the geographical distribution of
the Crayfishes and the more important structural
differences expressed in their classification. There
can be no doubt that the two families have been
derived from a common stock of marine lobster-like
animals, and it is reasonable to suppose that two
branches of this stock became independently adapted
to a fresh-water habitat in the North and in the
South, giving rise to the Astacidse and the Par-
astacidse respectively.

The distribution of the individual genera is, how-

PL A TE XX

THE MURRAY RIVER “LOBSTER,” Asians Sfiinifer. THE LAND CRAYFISH, EngCBUS cunicularis .

NEW SOUTH WALES. (MUCH REDUCED) TASMANIA (NATURAL SIZE)

CRUSTACEA OF FRESH WATERS 177

ever, not so easy to understand. The species found
in Europe all belong to the genus Astacus, which
also penetrates into Asia as far as Turkestan and the
basin of the River Obi.

Throughout the greater part of Asia no Crayfishes
are found until we come to the Far East, where we
find an isolated colony in the river-system of the Amur,
in Korea, and in the north of Japan. These far eastern
Crayfishes, however, differ so much from the typical
species of Astacus that they are now placed in a
subgenus (sometimes regarded as a distinct genus),
Cambaroides . Curiously enough, the typical genus
Astacus reappears again on the other side of the
Pacific, where several species occur in that part of
North America which lies west of the Rocky Moun-
tains. East of the Rockies, again, numerous species
are found belonging to a distinct genus, Cambarus,
which ranges from Canada to Central America and
Cuba, and this genus is allied in certain respects to
the Cambaroides of Eastern Asia. If the systematic
relations of these genera have been properly inter-
preted, it is by no means easy to understand in what
way their present distribution has been brought
about.

The Southern Crayfishes have an even more scat-
tered and discontinuous range. In New Zealand the
genus Paranephrops occurs, in Australia and Tasmania
the genera A stacopsis (Plate XX.), Cheraps and Engceus
(Plate XX.). A single species of Cheraps has been re-

12

178

THE LIFE OF CRUSTACEA

corded from New Guinea, but no Crayfishes are found
in any part of the Malay Archipelago, in Southern
Asia, or on the continent of Africa, although,
curiously enough, a single species of a peculiar
genus (. Astacoides ) is found in Madagascar. In South
America species of Parastacus are found in Southern
Brazil, Argentina, and Chili. It is evident that
these various genera of Parastacidae, which are now
so widely isolated from each other, must have reached
their present habitats when the relative distribution
of land and sea in the Southern Hemisphere was
very different from what it is now. What exactly
the nature of the land connection between the various
islands and continents was, whether by way of an
Antarctic continent or otherwise, is a question that
can only be suggested here. To attempt to answer
it would involve the consideration of the distribution
of many other groups of animals besides Crayfishes.

Before leaving the Crayfishes, it may be mentioned
that certain species have become adapted to almost
terrestrial habits. A number of species of Cambarus
in North America are often found at considerable
distances from open water, burrowing in damp earth,
their burrows reaching down to the ground-water.
In many cases they throw up chimney-like piles of
mud at the mouths of their burrows, and in places
their chimneys are so numerous as to “ hamper
farming operations by interfering with the harvesting
machines, clogging and ruining them.” The species

PLATE XXI

Palcemon jamaicensis , A large freshwater prawn of the family

PALADMONIDAJ. WEST INDIES. (MUCH REDUCED)

CRUSTACEA OF FRESH WATERS 179

of Engceus (Plate XX.), found in Tasmania, are there
known as “ Land Crabs,” and burrow in marshy
places and in the forests up to an elevation of
4,000 feet.

The broad equatorial belt which separates the
regions inhabited by the Northern and the Southern
Crayfishes is characterized by the presence of several
other groups of fresh-water Decapoda. The large
River Prawns, which are found nearly every-
where within the tropics, belong to the genus
Palcemon (Plate XXI.), which is very closely related
to the common marine Prawns (Leander) of our own
coasts. Some of these Prawns grow to a foot or
more in length of body, and the large claws may
measure as much again. From the Crayfishes, for
which they are sometimes mistaken, they may be
easily distinguished by the fact that the large pincer-
claws are not the first, but the second pair of legs.
Another widely-spread group of River Prawns, for
the most part of small size, is the family Atyidas
(Plate XXII.), in which the two pairs of pincer-
claws are feeble, and have the fingers tipped with
brushes of long hairs, used in sweeping up minute
particles of food from the mud. The distribution of
these Prawns presents many difficult problems, as an
example of which we may mention the presence of
identical or closely related species in the fresh waters
of West Africa and of the West Indies.

The Brachyura (or Crabs) include many species

i8o THE LIFE OF CRUSTACEA

that live in fresh water. Some of these, like the
species of Sesarma (see Plate XXIII.) and some other
genera of the family Grapsidae, are common through-
out the tropics, passing up the rivers from the
brackish water of estuaries, and being often found
long distances inland in quite fresh water. The true
River Crabs, however, belong to the family Potamo-
nidse, and are very common throughout the warmer
regions of the globe. One species, Potamon edule
(Plate XXIII.), formerly called Telphusa fluviatilis, is
found in the South of Europe (Italy, Greece, etc.).
Very numerous species, as yet only imperfectly
known, occur throughout the whole of Africa, in
Southern Asia, and in the Malay Islands, extending
to Australia in the south and Japan on the north.
In the New World the River Crabs are found in
South America, and extend north to Mexico and the
West Indian Islands. Many of the River Crabs are
amphibious in habits, and may be found burrowing
in marshy ground or in damp forests. The young
are hatched from the egg with all the appendages
developed, and they remain clinging to the abdomen
of the mother until after the first moult, when they
are perfectly-formed little crabs (see Fig. 31, p. 78).

The groups which have been mentioned are all
characteristic inhabitants of the fresh waters over
considerable areas of the surface of the globe. There
are, however, in addition to these, certain Crustacea
which occur in isolated localities, and have no close

PLATE XXII

(reduced)

CRUSTACEA OF FRESH WATERS 181

allies in fresh waters elsewhere. In the streams of
Southern Brazil and Chili there is found a small
Crustacean (Mglea lezvis — Plate XXIV.), not unlike
the Galatheas of our own coasts, which is interesting
as being the only species of the Anomura found in
fresh water. Still more remarkable are the Syn-
carida, which are represented by two species of
“ Mountain Shrimps ” (see Fig. 84, p. 264) in Tas-
mania, and by a third species found near Melbourne.
These forms have no near allies among living
Crustacea, but appear to be related, as will be shown
in a later chapter, to certain fossil Crustacea found
in Palaeozoic rocks.

Belonging to a different category from any of
those mentioned are certain Crustacea closely allied
to, or identical with, species living in the sea, which
inhabit inland lakes where no direct passage from
the sea is now possible. Attention was first called
to these in the case of some of the large lakes of
Sweden, in which Professor Loven found some Crus-
tacea— Mysis relicta (see Fig. 16, p. 47), Mesidotea
entomon, Pontoporeia affinis — almost or quite identical
with species inhabiting the Baltic, the Arctic Ocean,
and the North Atlantic. There is geological evidence
to show that these lakes were once fjords, or arms
of the sea, and have become cut off from com-
munication with the Baltic by gradual elevation of
the land. The marine animals which they contained
would thus be imprisoned, and as the water became

182

THE LIFE OF CRUSTACEA

less and less salt, by the inflow of rivers, certain
species which were able to accommodate themselves
to the altered conditions would survive. Some of
the species living in the Swedish lakes have since
been found to have a wider distribution. Thus,
Mysis relicta , which should perhaps be reckoned as
only a variety of the Mysis oculata of Arctic seas, has
been found in lakes in Russia, North Germany, and
North America (Lake Superior and others), and has
lately been discovered in Lough Neagh and some
other lakes in Ireland.

The brackish waters of the Caspian Sea contain a
very remarkable assemblage of animals, including
many Crustacea, which, although now quite isolated
from the oceans, are certainly of marine, and in part
of Arctic, origin. Among these are some species
closely allied to or identical with those of the Swedish
lakes already mentioned, together with a great variety
of species of Mysidacea, Cumacea, and Amphipoda,
which appear to have been evolved from marine
forms since the Caspian was cut off from communica-
tion with the Arctic Ocean.

To such assemblages of animals derived from
marine species and isolated in inland lakes the name
of “ relict ” faunas has been given. It is necessary to
use caution, however, in extending this explanation
of their origin to every case of peculiar lake faunas.
For example, there are difficulties in the way of
supposing that Lake Baikal was ever in open and

PLATE XX HI

the river-crab of southern Europe, Potamon edule (or Telphnsa fluviatilis)
(reduced)

Sesarma chiragra, a freshwater crab of the family grapsid.e.

FROM BRAZIL. (SLIGHTLY REDUCED)

CRUSTACEA OF FRESH WATERS 183

direct communication with the sea, although it con-
tains many animals, such as seals, which are certainly
of marine origin. The chief Crustacea of the lake are
numerous species of Amphipods belonging to the
genus Gammarus, and other genera closely related
thereto, and for these, at all events, there is no need
to assume a “ relict ” origin.

One of the most remarkable lakes in the world
from a zoological point of view is Lake Tanganyika
in Africa. When it was found that this lake con-
tained a fauna very different from that of the other
great lakes of Africa, it was rashly assumed that it
must be of relict origin, and some remarkable specula-
tions were indulged in as to the former connection
between the lake and the sea. Further research,
while it has greatly emphasized the peculiar nature
of the fauna, has entirely disposed of the view that
it originated in this way. The Crabs and Prawns,
for example, are not nearly related to marine forms,
but belong. to groups that are characteristic of fresh
waters in the tropics. While Nyassa and the
Victoria Nyanza have as yet only yielded a single
species of Prawn, and that one of enormously wide
distribution (from the Nile to Queensland), Tangan-
yika contains no fewer than twelve species, all of
which are peculiar to the lake, while all except one
belong to genera unrepresented elsewhere. Similarly,
the Crabs found in the other great lakes of Africa
belong to commonplace types of River Crabs of the

184

THE LIFE OF CRUSTACEA

genus Potamon ; in Tanganyika, in addition to some
of these, there are three species of a remarkable
genus, Platytelphusa, not known from any other
locality. The Copepoda and Ostracoda of Tangan-
yika comprise a remarkably large number of species,
many of them peculiar to the lake. A most unusual
feature is the entire absence of Cladocera. It is not
easy to explain the occurrence of this remarkable
fauna in Tanganyika, but the evidence from other
groups of animals, such as Mollusca and fishes, tends
to suggest that the lake must have been, until recently,
completely isolated from the other lakes and river-
systems of Africa, that it had no outlet, and that the
water was consequently more or less brackish.
Under these conditions the fauna of the lake,
originally similar to that of the other African lakes,
has evolved along lines of its own.

A very interesting division of the fresh-water fauna
is constituted by those animals which inhabit under-
ground waters. In the South of England there is
found not unfrequently in the water of wells a small
colourless transparent Amphipod known as the
“ Well Shrimp ” ( Niphargus aquilex — Fig. 62), distin-
guished from the common Iresh-water Gammarus by
the slenderness of its body, by the elongation of the
last pair of tail appendages (uropods), and by the
absence of eyes. The proper habitat of Niphargus is
not actually in the wells, but in the subterranean
reservoirs and streams by which the wells are fed.

PLATE XXIV

VEglea Icevis. south America, (natural size)

CRUSTACEA OF FRESH WATERS 185

These subterranean channels intercommunicate over
wide areas, and are now known in many parts of the
world to contain a peculiar assemblage of animals
which become accessible to the naturalist in wells and
in the streams and lakes of large caves. Further,
the scanty “ abyssal ” fauna of deep lakes is partly
made up of species which enter the lakes by sub-

Wrzesniowski.)

terranean channels, and find a suitable habitat in
the deep water. Species of Niphargus , for example,
have been dredged in Lough Mask in Ireland and in
some of the Swiss lakes.

Several species of blind Crayfishes have been found
in caves in North America, the best known being one
(Cambarus pellucidus — Plate XXV.) found in the
Mammoth Cave in Kentucky ; and blind Prawns

i86

THE LIFE OF CRUSTACEA

belonging to various genera have been discovered in
caves in America and Europe.

A very remarkable feature of the subterranean
fauna is that a number of the animals appear to be
more closely allied to marine species than to any
known from fresh waters above-ground. This is
especially the case with some of the Isopoda belong-
ing to typically marine families like the Cirolanidae
and Anthuridae, and it has been suggested that these
have been derived from marine species which have
entered the underground waters directly from the sea
by way of submarine fissures in the crust of the
earth.

The environment in which these subterranean
animals live resembles that of the deep-sea animals
in the absence of light, and the consequent absence of
plant-life. They must ultimately depend for food on
animal and vegetable debris washed down from the
surface, but the food-supply must be scanty, for the
water in which they live is usually very clear and
free from organic matter. It is not surprising to find
that nearly all of them are blind, and the few species
provided with visual organs which have been described,
from caves, are probably only temporary or accidental
immigrants. Whether the degeneration of the eyes
is the direct effect of disuse, or is due to natural
selection ceasing to keep the eyes up to the standard
of usefulness, is a question which has been much
debated, and its answer, were we sure of it, would

PLATE XXV

THE BLIND CRAYFISH OF THE MAMMOTH CAVE OF KENTUCKY,

Cambarus pellucidus. (natural size)

CRUSTACEA OF FRESH WATERS 187

settle some of the most fundamental problems of the
evolution theory.

At all events, we do not find in any truly subter-
ranean species large and peculiarly modified eyes
like those of many deep-sea animals, and this may
be associated with the complete darkness of their
habitat, not lighted by phosphorescent organisms as
the deep sea is. In another respect these animals
differ from those of the deep sea, for they are all
colourless or nearly so ; while many of the inhabitants
of the deep sea, as we have already seen, are brilliantly
coloured.

CHAPTER IX

CRUSTACEA OF THE LAND

THERE is every reason to believe that the
Arthropoda, like the other great groups of
the animal kingdom, had their origin in the sea ; but
they must have invaded the dry land at a very early
period, and most of the classes into which the group
is divided — the Arachnids, Myriopods, and Insects
— are now predominantly terrestrial in their habits.
The Crustacea alone have remained for the most
part aquatic animals, and only in a comparatively
few cases have they succeeded in adapting them-
selves completely to an air-breathing existence. As
already mentioned, a considerable number, both of
marine and of fresh-water species, are more or less
amphibious in their habits. Thus, the common
Shore Crab of our own coasts and the Grapsoid
Shore Crabs of warmer seas voluntarily leave the
water and scramble about among the rocks between,
and even above, tide - marks. Some Crabs, like
Ocypode and Gelasimus (see Plate XV.), have gone
farther towards becoming land-dwellers, since their

188

CRUSTACEA OF THE LAND 189

gill chambers are adapted to serve as lungs for
breathing air, and some species may even be drowned
by keeping them in water. The marsh-dwelling
or fresh-water Crabs of the genus Sesarma (see
Plate XXIII.) and allied genera are also apparently
to some extent air-breathers, and one species, Aratus
pisonii, is stated by Fritz Muller to climb mangrove
bushes and to feed on their leaves. Some Crayfishes,
like the Engczus of Tasmania (see Plate XX.), already
mentioned, are practically land animals. Finally,
some Amphipoda, closely allied to the Sand-hoppers
of British coasts, live in damp places on land,
although they do not show any conspicuous modi-
fications of structure to adapt them to this mode of
life. Of one of these Amphipoda, Talitms sylvaticus,
Mr. G. Smith writes : “ This species of land-hopper
is widely distributed in the highlands of Tasmania,
being found under logs and leaves in the forests on
Mount Wellington, and in very great abundance in
the beech -forests on the mountains of the west
coast.”

It will thus be seen that it is impossible to draw
any sharp distinction between aquatic and terrestrial
Crustacea, and it is chiefly from motives of con-
venience that we have left to be dealt with in this
chapter three groups of land-dwelling Crustacea —
the Land Crabs of the family Gecarcinidse, the
Land Hermits (Coenobitidae), and the Land Isopods,
or Woodlice (Oniseoidea).

igo THE LIFE OF CRUSTACEA

The Gecarcinidse are abundant in the tropics of
the Old and New Worlds. Some of the species at
least, probably all, visit the sea at intervals for the
purpose of hatching off the eggs carried by the
females, and the larval stages are passed in the sea.
In the case of Gecarcinus ruricola (Plate XXVI.), a
species very common in the West Indies, the migra-
tion to the sea takes place annually during the
rainy season in May. The Crabs are described as
coming down from the hills in vast multitudes,
clambering over any obstacles in their way, and even
invading houses, in their march towards the sea.
Stebbing states that “ The noise of their march is
compared to the rattling of the armour of a regiment
of cuirassiers.” The females enter the sea to wash
off the eggs which they carry attached to their
abdominal appendages, or rather, probably, to allow
the young to hatch out. The Crabs then return
whence they came, and are followed later by the
young, which, having passed through their larval
stages in the sea, leave the water, and are found in
thousands clinging to the rocks on the shore.

On Christmas Island, in the Indian Ocean,
Dr. C. W. Andrews studied the habits of another
Land Crab, of which the proper name seems to be
Gecar coidea lalandii. He says : “ This is the com-
monest of the Land Crabs inhabiting the island, and
is found in great numbers everywhere, even on the
higher hills and the more central portion of the

PLATE XXVI

A west Indian land-crab, Gecdrcinus ruricola. (reduced)

A LAND HERMIT-CRAB, Coenobitd TUgOSd. (reduced)

CRUSTACEA OF THE LAND

191

plateau. In many places the soil is honeycombed
by its burrows, into which it rapidly retreats when
alarmed. These Crabs seem to feed mainly on dead
leaves, which they carry in one claw held high over
the back and drag down into the burrows. From
their enormous numbers, they must play a great part
in the destruction of decaying vegetable matter and
its incorporation into the soil.’'

“ Once a year, during the rainy season, they descend
fo the sea to deposit [or, rather, to hatch out] their
eggs, and during this migration hundreds may be
seen on every path down steep slopes, and many
descend the cliff-face itself. They remain on the
beach for a week or two, and . . . afterwards gradually
make their way back to their accustomed homes.”

In the year of Dr. Andrews’ first visit to the
island (1898) this migration occurred in January.
On a subsequent visit to the island in 1908 he
obtained specimens of a large Megalopa larva (see
p. 70) which occurred in enormous quantities in
the sea shortly after the migration, and also of a
small Crab which appeared in similar numbers at a
slightly later date. It seems practically certain that
these larvae and young are those of Gecar coidea laiandii.
A second species of Land Crab, Car disoma hirtipes ,
found on Christmas Island, has very different habits
from the foregoing. Dr. Andrews says of it : “ In
this island, at any rate, this species must be regarded
as a fresh-water form, and, in fact, when a specimen

ig2

THE LIFE OF CRUSTACEA

was seen it might be taken as an indication that
fresh water was not far off. It lives in deep holes in
the mud at the sides and bottom of the brooks.”
Dr. Andrews tells me that he never saw this species
at or near the sea (in marked contrast to Gecar-
coidea), and this agrees with the observations of
other travellers on species of the genus Cardisoma , so
that the breeding habits remain unknown. There is
every probability, however, that in this case, also, the
young stages are passed in the sea.

The student will find, in many textbooks on
zoology, the statement that some Land Crabs of the
genus Gecarcinus develop without metamorphosis.
Although it is impossible, with our present know-
ledge, to state definitely that this is not the case,
there is absolutely no evidence to support it, and it
is an interesting example of the way in which
erroneous statements sometimes gain currency in
science.1 It is based upon the fact that in 1835
Professor J. O. Westwood described the early stages
of “ a West Indian Land Crab,” in a paper “ On the
Supposed Existence of Metamorphosis in the Crus-
tacea,” published in the Transactions of the Royal
Society. Professor Westwood found that the em-
bryos extracted from the egg possessed all the
appendages of the adult except the swimmerets, and
that young specimens clinging to the abdomen of

1 I am indebted to Mr. J. T. Cunningham for calling my
attention to some of the facts here recorded.

CRUSTACEA OF THE LAND

193

the parent were perfectly-formed little Crabs. The
specimens which he described were sent to him by
the Rev. Lansdown Guilding, of St. Vincent, who
also deals with the subject in a note published in
the Magazine of Natural History in the same year.
Neither Westwood nor Guilding refers to the Crab
as a Gecarcinus , although Guilding calls it the
“ Mountain Crab,” a name which Patrick Browne
in 1756 gives to the Gecarcinus ruricola of Jamaica.
So far as I am aware, the first writer to refer to
Westwood’s Crab as a Gecarcinus , was Professor
T. Bell, who in his “ British Stalk-eyed Crustacea,”
published in 1853, states that some of the original
specimens had come into his possession. They con-
sisted of the detached abdomens of female Crabs,
with eggs and young adhering to them. It would
be by no means easy to identify the species of Crab
to which a detached abdomen belonged, and there
is nothing in the whole history inconsistent with the
supposition that these observations really relate to a
River Crab of the family Potamonidae, of which at
least one species, Pseudothelphusa dentata, is known to
occur on the island of St. Vincent. As we have
already seen, some of these River Crabs are quite as
much land animals as the Gecarcinidae, and they are
known to have a direct development.

The Gecarcinidae possess well-developed gills, but
in addition the gill chambers are modified for air-
breathing, as in some other amphibious Crabs
13

ig4

THE LIFE OF CRUSTACEA

( Ocypode , Gelasimus, etc.). Each chamber is capacious
and vaulted, and the lining membrane is thick and
richly supplied with bloodvessels, and is folded so as
to divide off the upper part of the chamber as a sort
of pocket.

The Land Hermit Crabs of the family Cceno-
bitidse are found on the coasts of all tropical seas.
Like the Gecarcinidae, they visit the sea periodically
for the purpose of hatching off the eggs, and the
larval stages are marine. The species of the genus
Ccenobita (Plate XXVI.) resemble the marine Hermit
Crabs in general shape, and like them use the shells
of Gasteropod Molluscs as portable shelters. Where
shells are scarce, other hollow objects are occasion-
ally utilized; for example, large individuals will
sometimes carry about the shell of a broken coco-
nut, and a specimen has been seen to walk off in a
cracked test-tube discarded by a naturalist who was
investigating their habits. In one instance Pro-
fessor Alcock saw an individual “ so big that it
seemed to have given up hope of finding a house, and
was wandering about recklessly, with its tail behind
it all unprotected.”

The Coenobites often climb into bushes in search
of food, and Dr. Alcock “ once found one of them
busy, like a large bee, among the florets of a coco-
nut, which made me wonder whether they may not
sometimes play a part in fertilizing flowers.” They
are, however, by no means exclusively vegetarians.

CRUSTACEA OF THE LAND

195

The author just quoted describes a visit to Pitti
Bank in the Laccadive Archipelago, the breeding-
ground of two species of terns. The ground was
everywhere strewn with the dead bodies and clean-
picked skeletons of the young birds. “ We soon dis-
covered that one great cause of the wholesale
destruction of young birds was the voracity of
swarms of large Hermit Crabs ( Ccenobita ), for again
and again we found recently killed birds, in all the
beauty of their first speckled plumage, being torn to
pieces by a writhing pack of these ghastly Crus-
taceans. There were plenty of large Ocypode Crabs,
too (0. ceratophthalmus), aiding in the carnage.”

On Christmas Island Dr, Andrews found a species
of Ccenobita not unfrequently in the higher parts of
the island far from the sea, and he remarks that the
occurrence of large marine shells high up on the
hills seemed very puzzling until it was noticed that
they were brought by the Hermit Crabs.

The species of Ccenobita possess a very curious
adaptation for aerial respiration. The soft skin of
the abdomen is traversed by a network of blood-
vessels and acts as a kind of lung, and a pair of
contractile vesicles at the base of the abdomen serve
as accessory hearts in promoting a specially active
circulation in that part of the body. The lining
membrane of the gill chambers also appears to aid in
respiration as in other terrestrial Decapods.

The “ Robber Crab ” or “ Coconut Crab ” ( Birgus

196 THE LIFE OF CRUSTACEA

latro — Plate XXVII.) also belongs to the family
Coenobitidae, and has attracted much notice from its
relatively gigantic size and its singular habits. Al-
though resembling Ccenobita closely in essential
structure, Birgus differs from it and from most other
Hermit Crabs in not making use of a portable
shelter, perhaps owing to the difficulty of obtaining
one of suitable size. The necessary protection for
the abdomen is obtained by a redevelopment of the
shelly plates (terga) on the upper surface of the
abdominal somites. The abdomen is carried doubled
underneath the body to protect the soft under-
surface, and the animal, when threatened, seeks a
shelter for its vulnerable hinder part in the nearest
hole or cranny. The swimmerets are absent in the
male sex, and are present only on one side of
the abdomen in the female. This unsymmetrical
development of the appendages is interesting as
indicating the derivation of the Robber Crab from
ancestors adapted to living in the unsymmetrical
shells of Gasteropod Molluscs. The last pair of
abdominal appendages, which in other Hermit
Crabs serve to hold the body in the shell, are here
much reduced in size, and quite useless for that
purpose. The carapace is very broad posteriorly,
owing to the great development of the branchial
cavities, which are much too capacious for the very
small gills. As in the true Land Crabs, the lining
membrane of the gill cavity is thick and spongy, and

PLATE XXVII

THE COCO-NUT crab, Birgus latro. (much reduced)

CRUSTACEA OF THE LAND

197

traversed by numerous bloodvessels ; but in this case
its efficiency as a lung is added to by numerous
tufted papillae, which increase the surface exposed
to the air.

As in other Hermit Crabs, the last two pairs of
legs are shorter than the others, and they end in
small chelae. The last pair are very slender, and are
usually carried folded up within the gill chambers,
which they possibly serve to keep clear from foreign
bodies. The penultimate pair of legs are stouter,
and the two pairs in front of these are long walking
legs. The chelipeds are very strong and are of un-
equal size. When attacked, the animal defends
itself, not, as might have been expected, with its
chelipeds, but with the first pair of walking legs, the
sharp points of which form very efficient weapons.

The statement that the Robber Crab climbs lofty
trees was first made by the Dutch naturalist
Rumphius, in the beginning of the eighteenth
century. Its accuracy has been often doubted or
denied since then, and only finally put beyond
dispute by a photograph taken on Christmas Island
by Dr. Andrews, which shows one of these Crabs in
the act of descending the trunk of a sago-palm. It
seems not impossible that the habits of the animal
may vary to some extent in different localities, and
that where food is abundant on the ground the tree-
climbing habit may be in abeyance. If this were so,
it would explain the very definite statements made

198 THE LIFE OF CRUSTACEA

by some observers, that Birgus does not climb
trees.

In localities where coconut palms abound, Birgus
feeds largely on the nuts, tearing off the fibrous outer
husk and breaking open the shell by hammering
with its powerful claws at one of the “ eye-holes.”
According to Darwin in his “ Naturalist’s Voyage,”
the pincers of the penultimate pair of legs are used
for extracting the contents of the nut, but this
observation does not seem to have been confirmed.
In spite of its name of “ Coconut Crab,” however,
Birgus by no means feeds exclusively on coconuts.
On Christmas Island, where until recently there
were no coconut palms, the Crabs are exceedingly
abundant, and, according to Dr. Andrews, they “ eat
fruits, the pith of the sago-palm and the screw-pines,
dead rats andfother carrion, and any of their fellows
that may have been injured. . . . They are excellent
scavengers, and have a curious habit of often drag-
ging their food long distances before attempting to
eat it. I have seen a Crab laboriously pulling a
bird’s wing up the first inland cliff, half a mile or
more from the camp whence it had stolen it.”

Large specimens of the Robber Crab may be at
least a foot in length of body when the abdomen is
straightened out. Their great strength is illustrated
by the fact, related by Darwin, that specimens
placed in a strong biscuit-tin, of which the lid was
secured by wire, escaped by turning down the edges

CRUSTACEA OF THE LAND igg

with their claws, and in doing so actually punched
holes quite through the tin.

The breeding habits and mode of development of
the Robber Crab have often formed the subject of
inquiry by naturalists, but it is only recently that
Dr. Willey has been able to prove definitely that the
female visits the sea for the purpose of hatching off
the eggs, and that the young are hatched in the zoea
stage. The larvae obtained by Dr. Willey have been
described by Mr. Borradaile, who finds that, as was
to be expected, they closely resemble those of
Ccenobita. There appears, however, to be no such
simultaneous migration of the Crabs towards the sea
as has been described in the case of the Gecarcinidae.
The statement, quoted by Darwin, that Birgus visits
the sea every night for the purpose of moistening its
branchiae, cannot be universally applicable, since the
Crabs are often found, as on Christmas Island, at
distances from the sea which put a nightly journey
to it out of the question.

Of all Crustacea, the most completely adapted to
terrestrial life are the Land Isopods, or Woodlice,
which may be found in every garden. It is true
that most species are found in damp places, although
some that inhabit the sandy deserts of Asia and
Africa must be content with a very slight degree of
humidity ; and in no case is their dependence on
moisture greater than, for instance, that of many
Insects and Arachnids which are regarded as typically

200

THE LIFE OF CRUSTACEA

terrestrial animals. Since there is reason to believe
that the Woodlice have been derived from marine
ancestors — they show no special affinities to the
fresh-water Isopoda, like Asellus — it is interesting to
find that the most primitive forms, which have de-
parted least from the general Isopod type, are
commonly found on or near the seashore. The

Fig. 63 — The Sea-slater ( Ligia oceanica). About Twice
Natural Size. (After Sars.)

“ Sea-slater,” Ligia oceanica (Fig. 63), which is
abundant in rocky places on our own coast, is one
of the most primitive forms. It has a broad, flat-
tened, greenish-brown body, about an inch long, and
it runs quickly, creeping into narrow crevices of the
rocks, so that it is not easy to catch. The anten-
nules, as in the other land Isopods, are very minute,
but the antennae are long, and have, besides the five

CRUSTACEA OF THE LAND

201

segments which form the “ peduncle,” a “flagellum ”
of about twelve short segments. The uropods or
tail appendages are long, each with two slender,
pointed branches. On the under - side of the
abdomen can be seen the five pairs of pleopods, each
with two plate-like branches attached to a very short
peduncle. As in most aquatic Isopods, the plates of
the pleopods are soft and thin, and appear adapted
to act as gills, although the outer plate of each pair
is somewhat stiffer than the inner. The Sea-slater
is generally found just above high-water mark, prob-
ably always within reach of the salt spray, and it is
said sometimes to enter the water of rock-pools.

In almost every garden there may be found, under
flower-pots and the like, a Woodlouse, about two-
thirds of an inch long, of a brown colour, with
yellowish blotches arranged in a row on each side of
the back. This is Oniscus asellus , a species widely
distributed in Europe and North America. It has
the antennae shorter than in Ligia, and the flagellum
is composed of only three segments. The uropods
are quite short. The endopodites of the pleopods
are membranous gill-plates, which serve for respira-
tion in the moist air in which these animals generally
live. The exopodites are stiff plates which cover and
protect the delicate endopodites ; it is probable that
they also aid in respiration, for they contain a
system of minute channels, filled with air, where the
cuticle is separated from the underlying cells. As

202

THE LIFE OF CRUSTACEA

these channels are nowhere open to the outside, the
air must find its way in by diffusion through the
cuticle.

Even more abundant than Oniscus asellus, and
often found together with it, is Porcellio scaber (see
Fig. 20, p. 51). It is usually of a dark bluish-grey,
but occasionally it is irregularly mottled with a

Fig. 64 — Structure of the Breathing Organs of Porcellio scaber.

(From Lankester’s “Treatise on Zoology,” after Stoller.)

A, Exopodite of first pleopod, showing the tuft of air-tubes
(“pseudo-tracheae”), seen through the transparent cuticle; B,
vertical section through same ; C, part of section more highly
magnified, art, Point of attachment of exopodite to peduncle ;
c, cuticle; gr, grooved area of cuticle ; hy, hypodermis, or layer
of cells under the cuticle ; n, nucleus of hypodermis cell of air-
tube ; 0, external opening ; tr, air-tubes

lighter colour. The flagellum of the antenna has
only two segments. The most interesting difference
from Oniscus, however, is found in the pleopods. If
the under-side of the living animal be examined with
a pocket lens, a white spot will be seen on each

CRUSTACEA OF THE LAND

203

exopodite of the first two pairs of pleopods. When
the structure of the pleopods is investigated by
means of microscopic sections (Fig. 64), it is found
that the white spots are tufts of fine branching tubes
radiating into the interior of the exopodite from a slit-
like opening on the outer edge. These tubes arise by
an in-pushing of the integu-
ment, and they are lined
throughout by a delicate con-
tinuation of the external cuticle.

During life they are filled with
air, and they serve to aerate the
blood circulating in the interior
of the appendage.

Another Woodlouse common
in England is Armadillidinm
vulgar e (Fig. 65), a little slaty-
grey species with a very con-
vex body, which rolls itself
into a ball when touched. Like the last-mentioned
species, it has two segments in the flagellum of its
short antennse, and it has tufted air-tubes in the
exopodites of the first two pairs of pleopods. It is
often mistaken for an animal of widely different
structure, which it superficially resembles — the Pill
Millipede ( Glomeris marginata). The latter, however,
may easily be recognized by having either seventeen
or nineteen pairs of walking legs (instead of seven
pairs), set close together in the middle line of the

Sars.)

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THE LIFE OF CRUSTACEA

body, and by lacking the plate-like pleopods. The
resemblance between the two animals can hardly be
regarded as a case of “ mimicry,” since there is no
reason to believe that either benefits by its likeness
to the other. As in so many other cases of “ con-
vergent resemblance” between animals of different
structure, it does not seem possible to get beyond
the vague suggestion that a similarity in habits may
have led, in some way that we do not understand, to
a similarity in appearance.

The presence of air-tubes in the pleopods of many
Woodlice raises some questions which are of impor-
tance with reference to the classification of the
Arthropoda as a whole. The Six-legged Insects,
most Spiders and many of their allies, the Centi-
pedes and Millipedes, and the worm-like Peripatus,
all breathe air by means of fine tubes which pene-
trate throughout the body, and bring the air into
close contact with the tissues. These tubes, which
are known as “tracheae,” arise as ingrowths of the
outer layer of the embryo, and are lined by a delicate
continuation of the external cuticle. It has been
held by some zoologists that so peculiar a system of
breathing organs must indicate a common descent
of the animals that possess them, and accordingly
it has been proposed to separate the Insects, Arach-
nids, Myriopods, and Peripatus , as a group, Tracheata,
from the Crustacea and some other Arthropods which
have no tracheae. The air-tubes of the Woodlice,

CRUSTACEA OF THE LAND

205

however, are precisely like tracheae in structure
and function, and only differ from the tracheae
of the other groups in the fact that they are
confined to the appendages, and do not penetrate
into the body. Since the Woodlice are a small and
highly specialized branch of the Crustacea, we can
hardly suppose that they derive their tracheae from
any ancestral type which they had in common with
the widely different Arachnids, for example ; and if
tracheae have been evolved independently in these
two groups, there seems no reason why those of the
Insects may not have arisen independently of either.
This is only one example out of many which go to
show that, in attempting to reconstruct the genealogy,
or phylogeny, as it is called, of the animal kingdom,
we must constantly admit the possibility of “ con-
vergent evolution.”

Although Woodlice are very common animals, com-
paratively little is known of their habits. They
seem to live chiefly on vegetable food, and sometimes
damage seedlings and tender plants in gardens and
greenhouses, but occasionally they are carnivorous,
and even cannibalistic, in their habits. A few species
live as “ guests ” in ants’ nests, and one of these,
the little blind white Platyarthrus hoffmannseggii , is
common in many localities in this country. Why
the ants tolerate their presence we do not know,
for they do not seem to render any service to their
hosts, as do the plant-lice and some other insects

206

THE LIFE OF CRUSTACEA

that are kept by the ants for the sake of the secre-
tions which they yield.

The Woodlice, like some other Isopoda, have a
peculiar method of moulting. Instead of the whole
exoskeleton being cast off at one time, as in other
Crustacea, that of the hinder half of the body is
moulted first, and it is only after two or three days,
when the new cuticle has hardened, that the exo-
skeleton of the anterior half follows. As a result of
this arrangement, it occasionally happens that speci-
mens are found with the fore part of the body differing
in colour from the hind part, owing to the one having
been moulted more recently than the other.

Woodlice occur in most regions of the globe,
and one of the most remarkable features of their
geographical distribution is the extremely wide
range of certain species. This is probably due,
at least in many cases, to their accidental transport
by human agency. Thus, Porcellio scaber, so common
in this country, is also found in great abundance in
New Zealand ; but Professor Chilton notes that it
is usually found near buildings, and only rarely in
the native bush, so that there can be no doubt that
it has been introduced by artificial means.

CHAPTER X

CRUSTACEA AS PARASITES AND MESSMATES
HE life of every animal is in more or less

intimate relation with that of all the living
creatures which surround it. Some serve for its
food, or supply it with shelter or foothold ; others
prey upon it, or compete with it for the necessaries
of life; and others, again, influence it for good or
evil in countless ways more subtle than these, but
equally important. There are some associations or
a closer and more enduring nature, to which the
names of Symbiosis, Commensalism, and Parasitism,
are applied, and it is with examples of these that
the present chapter is concerned.

The term Symbiosis is strictly applied to an inti-
mate physiological partnership, such as we find in
some of the lower animals and plants, and in this sense
there are no truly symbiotic Crustacea. The word,
however, is sometimes used, in its literal sense of a
“ living together,” to embrace all cases of animals
living together for mutual advantage. Commen-
salism means, literally, “ sitting at the same table,”

208

THE LIFE OF CRUSTACEA

and ought to be applied only to cases where two
or more animals, living together as “ messmates,”
partake of the same food ; but it is sometimes used
more loosely to include instances where one of the
animals does not actually share in the food-supply
of the other. Parasitism, again, implies that the
parasite lives permanently at the expense of its host,
by sucking its juices or otherwise, and in this case
also there are innumerable degrees and varieties of
dependence, which defy inclusion in a strictly logical
scheme of classification. Even such typical parasites
as Tape-worms, for example, might strictly be regarded
as commensals, sharing in the host’s food only after
it has entered the alimentary canal. Finally, in all
these kinds of interrelation, we find cases where
the association is temporary, intermittent, or almost
accidental, and where there are no perceptible
adaptations of structure directed to its maintenance
in either of the partners. From these we may trace
a series of gradations leading to cases where the
associated organisms are never found apart, and
where the structure of both is profoundly modified
in adaptation to the particular form of association.

Perhaps the simplest form of association between
two animals is found where one utilizes the other
as a means of transport. The little Gulf-weed Crab,
previously mentioned, is very often found clinging to
the carapace or skin of large marine turtles. It is
not a parasite, since it can hardly derive any food

PLATE XXVI 1

group of barnacles, Coronula diadema, on
JAPAN. (reduced)

PARASITES AND MESSMATES 209

from the Turtle itself ; neither is it a commensal,
for there is no evidence that it shares in the Turtle’s
meals. It probably takes to a Turtle, when it can
find one, as giving it a wider range of operations than
is afforded by its usual drift-log or tuft of sargasso-
weed. A somewhat similar case is afforded by some
of the Barnacles that are found on the skin of
Whales. The species of Conchoderma, for instance,
are often found on certain Whales, but they may
also occur on inanimate floating objects. Other
Whale-infesting Cirripedes, however, are specially
adapted to their habitat, and never occur elsewhere.
For example, Coronula (Plate XXVIII.) is a genus
of sessile Barnacles in which the shell is elaborately
folded, forming a series of chambers into which pro-
longations of the Whale’s epidermis grow, securely
fixing the shell. Tubicinella is even more effectively
protected against dislodgment, for its shell is sunk
in the thickness of the Whale’s skin, with only the
opening exposed. Other genera of sessile Barnacles
(Chelonobia, etc.) are found adhering to the shell of
Turtles. The increased food-supply made available
by the host’s movements through the water is
probably the chief advantage that the Barnacles
gain in such cases. This is indicated by the fact
that certain small stalked Barnacles ( Dichelaspis , etc.),
found on large Crabs and Lobsters in tropical seas,
generally cluster on the mouth parts of their hosts,
near the entrances to, or even within, the gill
14

210

THE LIFE OF CRUSTACEA

chambers, profiting no doubt by the respiratory
currents and the food particles they carry.

A great variety of Crustacea find shelter and
defence in association with Sponges, Corals, and
other more or less sedentary animals. Sponges are
not eaten by many marine animals, the needle-like
spicules which often form their skeleton no doubt
helping to render them distasteful, and many small
Crustacea, Amphipods, Isopods, Prawns, etc., profit
by their immunity from attack, and take up their
abode in the internal channels and cavities of the
Sponge. The beautiful siliceous Sponge known as
“Venus’s Flower-basket” ( Euplectella ) very often
contains imprisoned within it specimens of a delicate
little Prawn (Spongicola venusta ) or of an Isopod
(jEga spongiophila). As these Crustacea share with
the Sponge the food particles drawn in by the currents
of water passing through the pores in its walls, they
are in the strict sense commensals.

The Corals and various other animal organisms
commonly known as “ Zoophytes,” forming together
with the Jellyfishes the group Coelentera, are very
effectively protected against the attacks of most
predatory animals by the possession of “ stinging
cells,” and this protection is shared by many other
animals which shelter among them. Thus, the
branching Coral stocks which grow in great luxuri-
ance on tropical coasts support a rich and varied
assemblage of animals, some of which may actually

PARASITES AND MESSMATES

211

prey upon the Coral polypes, but all of which profit
by the fact that few enemies venture to pursue them
in their retreats. Innumerable prawn-like animals
of the Alpheidae and other families, and many kinds
of Crabs, are found among living Corals. The Crabs
of the family Trapeziidae are especially characteristic
of such habitats, and their thin, flat bodies seem to
be adapted to slip into slits and crannies of the Coral
blocks. The most highly specialized of all Coral

Fig. 66 — Two Branches of a Coral ( Seriatopom ) showing
“Galls” inhabited by the Crab Hapalocarcinus marsupialis.
On the Right the Female Crab, extracted from the Gall

AND FURTHER ENLARGED

Crabs, however, are the species of the family Hapalo-
carcinidse, which modify in various ways the growth
of the corals on which they live. In some of the
more delicately branched kinds of Coral there may
sometimes be found hollow bulbous growths, each of
which contains imprisoned within it a little Crab —
Hapalocarcinus marsupialis (Fig. 66). It seems that
the female Crab (the habits of the male are not
definitely known) settles down among the branches

212

THE LIFE OF CRUSTACEA

of the Coral, and that the irritation of its presence
causes the branches to grow up and surround it,
coalescing with each other to form a kind of cage,
and ultimately leaving only one or two small open-
ings. Through these openings water can enter to
enable the Crab to breathe, and no doubt food
particles find their way in, but it is not possible for
the Crab to leave its prison. The production of
these abnormal growths of the Coral is closely
analogous to the formation of “galls” on plants as
a result of the irritation set up by the presence of
insect larvae or other parasites, and it is not inappro-
priate, therefore, to speak of them as “ Coral galls.”

The Medusae, or Jellyfishes, like other Ccelentera,
are provided with poisonous stinging cells, which, in
the larger species of our own seas, are powerful
enough to cause discomfort to bathers who come in
contact with them. The protection thus afforded is
no doubt of advantage to the little globular Amphi-
pods of the genus Hyperia (Fig. 67), which are almost
always to be found sheltering under the bells of the
larger Medusae. In what way the Amphipods escape
injury from the stinging cells of their host is not
known.

In all the cases mentioned, the advantages of the
partnership seem to be all on one side, but there
are numerous instances in which both partners seem
to reap some benefit. A species of Hermit Crab very
common in moderately deep water on many parts of

PARASITES AND MESSMATES

213

the British coasts, Eupagums prideauxi, is always
found to have a Sea-anemone ( Adamsia palliata )
attached to the shell which it carries. The Anemone
has a broad base which is wrapped round the shell,
the mouth, surrounded by the tentacles, being on the
under-side next the opening
seems no reason to doubt
that the presence of the
Anemone does afford some
degree of protection to the
Hermit, and that, on the
other hand, the Anemone
benefits by being carried
about, and shares in the
crumbs from the Hermit’s
meals. It is stated that,
when the Hermit removes to
a new shell, it detaches the Anemone from the old
shell with its pincers and places it in position on the
new one. It appears, however, that it is not always
necessary for the Hermit to remove to a larger shell
as it grows, for the enveloping Anemone, as it in-
creases in size, extends beyond the mouth of the
shell, and so enlarges the shelter. Further, the
Anemone in course of time dissolves the shell almost
entirely away, and the Hermit is enveloped only by
the soft fleshy mantle which it forms.

In a similar way the deep-sea Hermit Crab Para-
pagurus pilosimanus (see Plate XVI.) is always found

of the shell. There

Fig. 67 — Hyperia galba ,
Female. Enlarged.
(After Sars.)

214

THE LIFE OF CRUSTACEA

lodged in a fleshy mass formed by a colony of Sea-
amenones (Epizoanthus) , within which, when it is
cut open, may be found the remains of the shell
which the Hermit first inhabited. A further develop-
ment of the same habit is given by Paguropsis typica ,
found in deep water in Indian seas, which does not
inhabit a shell at any time, but carries a fleshy
blanket formed by a colony of Anemones.

In dredging off the British coasts, we often find
smooth rounded lumps of a Sponge ( Suberites ficus),
generally yellowish-grey in colour, having a round
opening in which the claws of a small Hermit Crab
(. Eupagurus cuanensis) may be seen. On cutting open
the Sponge, the body of the Hermit is seen to be
lodged in a spiral cavity, and at the apex may be
found the remains of a shell that has been corroded
away by the Sponge which settled on and replaced
it. Other species of Hermit Crabs constantly have
their shells covered with a horny crust formed by
Hydroid zoophytes (Hydractinia, etc.), and in this
case also the extension of the Hydroid colony beyond
the lip of the shell relieves the Hermit from the
necessity of so frequently changing to a larger shell
as it grows.

A number of other animals are found associated
with Hermit Crabs, without, as far as we can see,
rendering any service in return for the house-room.
The Whelk-shells inhabited by Eupagurus bernhar-
dus (see Plate VII.) often contain one of the bristle-

PARASITES AND MESSMATES

215

footed worms (A ereilepas fucata), which may some-
times be observed to protrude its head from the
shell when the Crab is feeding, and to snatch away
fragments of the prey from the very jaws of its host.
It is thus, in the strict sense of the word, a com-
mensal. Species of Copepods, Amphipods, Porce-
lain Crabs, and even a Mysid, have been found
sharing the lodging of Hermit Crabs in a similar
way, and in addition there are various parasites,
presently to be mentioned, found on the Crabs
themselves, so that each Crab forms the centre of a
whole community of widely diverse organisms all
more or less directly dependent on it.

A habit similar to those of some Hermit Crabs is
that of the Crab Dromia (see Plate IX.), mentioned
in a previous chapter, which carries, as a cloak,
a mass of living sponge, holding it in position by
means of the last two pairs of legs. Even the
“masking” habit of the Spider Crabs, already
described (p. 96), may be regarded as a kind of
symbiosis, since the sponges, zoophytes, etc., which
grow on the Crabs no doubt benefit by being carried
about in return for the protection they give.

One of the strangest habits is that of certain little
tropical Crabs, of which Melia tessellata (Fig. 68) is
the best known, which carry in each claw a living
Sea-anemone and use it as a weapon. The claws or
chelipeds are in this case of small size, so that they
woud be of little use by themselves for attack or

2l6

THE LIFE OF CRUSTACEA

defence ; but the fingers are provided with recurved
teeth, enabling them to take a firm hold of the
slippery body of the Anemone. Particles of food
caught by the tentacles of the Anemone are removed
and eaten by the Crab, which uses for the purpose
the long walking legs of the first pair. The same
limbs are also used in the process of detaching the

Fig. 68 — A, The Crab Melia tessellata clinging to a Branch
of Coral, and carrying in Each Claw a Living Sea-
anemone ; B, One of the Claws further enlarged to
show the Way in which the Anemone is held. (After
Borradaile.)

Anemones from the stone on which they may be
growing. The Anemones do not appear to suffer
from the rough treatment to which they are sub-
jected, but whether they can reap any benefit from
the partnership is very doubtful.

From remote antiquity it has been known that a
little Crab (Fig. 69) is frequently found living within

PARASITES AND MESSMATES 217

the shells of bivalve Molluscs, such as Oysters, Mus-
sels, and especially the large mussel-like Pinna , which
is common in the Mediterranean. Ancient writers
regarded this as a case of association for mutual
advantage, believing that the Pinnotheres warned the
Pinna of the approach of enemies or of the entrance
of prey between its gaping valves. It is even stated
that the Pinna and Crab were depicted in Egyptian
hieroglyphics to symbolize the dependence of a man
on his friends.

As a matter of fact, however, there is no reason to

Fig. 69 — The Common Pea Crab {Pinnotheres pisum ), Female.

Natural Size.

believe that the Molluscs which harbour species of
Pinnotheres and allied genera benefit in any way by
the presence of the Crabs. The latter probably feed,
as their hosts do, on particles brought in by the
current of water entering the mantle cavity. They
are therefore strictly “ commensals,” though it is
usual, and perhaps equally correct, to speak of them
as “ parasites.” The case is, indeed, an example of
the difficulty of defining these two terms. At all
events, the Pinnotherid Crabs show one of the
characteristics of parasites in being to some extent

2l8

THE LIFE OF CRUSTACEA

degenerate in their structure. The carapace and the
rest of the exoskeleton, no longer needed for protec-
tion, have become soft and membranous, and the eyes
and antennules, the chief organs of sense, are very
minute. As in many parasites, also, the eggs pro-
duced by the female are very numerous, and the
abdomen is very broad and deeply hollowed for their
reception.

While most of the Pinnotheridae live in bivalve
Molluscs, some species are associated with other
invertebrate animals. Pinnaxodes chilensis is found
in a species of Sea-urchin (Strongylocentrotus gibbosus)
on the coast of Chili. On opening the shell of the
Urchin, *Jhe Crab is found enclosed in a thin- walled
bag formed by enlargement of the terminal part of
the host’s intestine.

It did not escape the notice of Aristotle that a
little Shrimp sometimes occurred in the Pinna in
place of the Crab. This is Pontonia custos, and other
species of the same and allied genera have similar
habits.

The order Isopoda includes a very large number
of parasitic species. The extensive family Cymo-
thoidae presents a whole series of gradations in
habits and structure between actively swimming
predatory species and others which in the adult
state are permanently fixed to their host, usually a
fish, and are incapable of movement. At one end of
the series are the species of Cirolana, which have

PARASITES AND MESSMATES

219

powerful biting jaws. Of C. borealis (Fig. 70), Mr.
Stebbing remarks that “ it is a good swimmer, tena-
cious of life, a savage devourer of fish, and not to be
held in the human hand with impunity.” The species
is not uncommon in British seas, and numerous indi-
viduals will sometimes
attack a Cod or other
large fish, perhaps after
it has been caught on a
hook, and gnaw their
way into its body, so
that when brought to
the surface the fish con-
sists of little more than
skin and bone.

The little Eurydice
achatus, belonging to
the same subfamily,

Cirolaninae, is com-
monly taken in the
tow-net in sandy bays on our own coasts,
sometimes to attack bathers, and to
unpleasantly.”

More definitely parasitic are the species of JEga
and allied genera, which have piercing and suctorial
mouth parts, and suck the blood of fish. They are
usually found adhering closely to the skin of their
victim by means of the strong hooked claws of the
anterior pairs of legs ; but they have not lost the

Fig. 70 — Cirolana borealis.
Twice Natural Size.
Sars. )

About

(After

It is said
nip most

220

THE LIFE OF CRUSTACEA

power of locomotion, and, as females bearing eggs
are never taken on fish, it would appear that they
drop off after gorging themselves with blood, and
probably seek a retreat at the bottom of the sea,
where they may hatch their young in safety. The
digestive canal of JEga dilates into a large bag,
which becomes distended with a semi-solid mass of
blood. This mass, when extracted and dried, is the
“ Peter’s stone ” of old Icelandic folklore, to which
magical and medicinal virtues were attributed. The
species Mga spongiophila, already mentioned, differs
in its habits from all the other species of the genus,
since it lives, not on fish, but in the interior of a
sponge.

The most completely parasitic members of the
Cymothoidse are found in the subfamily Cymo-
thoinse, including the typical genus Cymothoa
(Plate XXIX.) and many others. The adult animals
are found clinging to the skin of fishes, the legs
being provided with strong hook-like claws that give
them a very firm hold. Some species, especially
common on Flying-fishes, cling to the tongue of the
fish, and almost prevent it from closing its mouth.
When young, the Cymothoinse swim freely, and the
shape of the body is not unlike that of the Ciro-
laninse ; but after they have settled on a host the
body often becomes distorted and unsymmetrical.
A still more remarkable change occurs in the repro-
ductive organs in some, if not in all members of this

PLATE XXIX

Cymothoa oestrum , an isopod parasite of fish
(slightly enlarged)

Sncculina carcini attached under the abdomen of a common shore-crab
(reduced)

PARASITES AND MESSMATES

221

subfamily. Each individual, when it first attaches
itself to a host, presents the characters of the male
sex. Later it becomes a female, develops a brood-
pouch, and produces eggs. The animals are, in fact,
hermaphrodite ; but it is to be noted that the
hermaphroditism is of a different kind from that
presented by the Cirripedia, since the organs of
the two sexes are successively, not simultaneously,
developed. Where, as in this case, the male phase
comes first in the life-history of the individual, the
condition is known as “ protandrous ” hermaphro-
ditism.

Another large group of parasitic Isopods is the
suborder Epicaridea, all the species of which are
parasitic on other Crustacea. It is not uncommon
to find specimens of the common Prawn (Leander
serratus) which have a large swelling on one side
of the carapace. If the lower edge of the carapace
be raised, it will be seen that this swelling is due to
the presence in the gill cavity of an Isopod parasite
(Bopyvus squillarum). A closely similar form, found
on Prawns of the genus Spiv onto car is, is Bopyroides
hippolytes, represented in Fig. 71. Other allied
species are found on Hermit Crabs and other
Decapods. When extracted, the parasite is seen
to have a flat and curiously distorted body, with
extremely short legs ending in hooked claws. The
under-side is generally occupied by a relatively
enormous mass of eggs, which is only partly covered

222

THE LIFE OF CRUSTACEA

in by the small brood-plates. The mouth parts form
a short piercing beak with which the parasite sucks
the blood of its host. On the under-side of the
abdomen may usually be found the minute male,
attached, like a secondary parasite, to the body of
the female.

The species of Epicaridea are very numerous, and
they infest Crustacea belonging to nearly all the

Fig. 71 — A, Front Part of Body of a Prawn ( Spirontocaris
Polaris), from Above, showing on the Right Side a Swelling
of the Carapace caused by the Presence of the Parasite
Bopyroides hippolytes in the Gill Chamber ; B, the Female
Parasite extracted and further enlarged ; C, the Male
Parasite on Same Scale as the Female. (After Sars.)

chief groups of the class, a few even being parasitic
on other Epicaridea. Many of them differ greatly
from the Bopyrus just described, and in some cases
it would be impossible to guess from the structure of
the adult animals that they were Isopoda, or even
Crustacea at all. The life-history is not yet com-

PARASITES AND MESSMATES

223

pletely known. When hatched from the egg, the
free-swimming larvae have a short and broad body,
and, as in other Isopod larvae, have only six instead
of seven pairs of legs. A later larval stage, just
before attachment to the final host, has a long
narrow body and the full number of legs. It has
lately been shown, however, that, in all probability,
between these two free-swimming stages there inter-
venes a stage in which the larvae is temporarily
parasitic on certain Copepoda. Further, some of the
Epicaridea, like the Cymothoinae described above,
are protandrous hermaphrodites, developing the male
organs when in the last larval stage, and passing
into the female phase after they have become attached
to the host. In Bopyrus and many other genera,
however, there is no evidence that the males ever
develop into females.

Some of the most remarkable Epicaridea are those
belonging to the family Entoniscidae, which are para-
sitic on Crabs. In these the parasite penetrates from
the gill chamber into the interior of the body of the
host, remaining enveloped, however, by a delicate
membrane which grows in with it from the wall of
the gill chamber. The body is distorted in an extra-
ordinary fashion, so that at first sight it seems
impossible to trace any resemblance to the form of
a typical Isopod.

Among the Amphipoda there are a few species be-
longing to various families of the Gammaridea which

224

THE LIFE OF CRUSTACEA

have suctorial mouth parts, and lead a semi-parasitic
existence ; but the only completely parasitic forms
are the Whale-lice, forming the family Cyamidse (see
Fig. 23, p. 55) in the suborder Caprellidea. Although
differing greatly in the broad, flattened shape of the
body from the slender, thread-like Caprellidse, they
closely resemble them in structure, particularly in
having the abdomen reduced to a mere knob. The
fourth and fifth pairs of thoracic limbs have dis-
appeared, although the gills corresponding to them
are very large ; and the last three pairs of legs have
long curved claws which enable the Whale-louse to
cling firmly to the skin of its host. The mouth parts
are adapted for biting, not for sucking blood, and
the animals seem to live by gnawing the skin of the
Whales. In one respect the Whale-lice are unique
among Crustacean parasites : they have not the
power of swimming at any period of their life-history.
The young settle down near their parents, and masses
of many hundred individuals of all sizes are found
clinging close together on the skin of the host.

No group of Crustacea exhibits more numerous or
more varied examples of parasitism than the Co-
pepoda. Every grade of transition between a free
predatory habit of life and the most complete
dependence upon a host may be traced in various
families of the subclass. Only a few examples can
be mentioned here.

The commonest “fish-lice” are the numerous

PARASITES AND MESSMATES

225

species of the family Caligidae, many of which,
belonging to the genera C aligns (Fig. 72), Lepe-
ophthirus, etc., are found on marine fishes on our
own coasts. In these the body is broad and flat,
but in many of them the resemblance, even in
general form, to the free-
living Copepoda is easily
traceable. The maxillipeds
form powerful hooked claws,
by means of which the ani-
mals cling to the skin of the
fish they infest, and in C aligns
the basal segments of the
antennules have a pair of
suckers which aid in ad-
hesion. The mouth parts
are adapted for piercing, and
are enclosed in a suctorial
proboscis.

When the young Caligid,
after passing through the
free-swimming larval stages,
first becomes attached to a
fish, it adheres by means of a

thread-like process issuing from the front of the head,
and formed by the secretion of a gland. At this
stage, formerly described as an independent species
under the generic name of Chalimns, the parasite is
unable to detach itself from its host ; but later, in

15

Fig. 72 — A Fish-louse
( Caligus rapax), Female.
x 5. (After Wilson.)

226

THE LIFE OF CRUSTACEA

many species, it re-acquires the power of swimming,
and specimens of Caligus, for instance, are commonly
found free in tow-net gatherings.

Fig. 73 — Stages of Development of Lerncea branchialis. F is

SLIGHTLY, THE OTHER FIGURES GREATLY, ENLARGED. (After

A. Scott.)

A, Nauplius, just hatched ; B, young female taken from gills of
Flounder ; C, free-swimming stage of female, after leaving
Flounder ; D, free-swimming male ; E, female just after settling
on gills of Whiting ; F, fully-developed female.

On the gills of Cod, Haddock, and other common
fish, we often find a red worm-like parasite, Lerncea

PARASITES AND MESSMATES

22 7

branchialis (Fig. 73, F), which at first sight seems
to bear no sort of resemblance to a Crustacean.
The soft body is curiously doubled up, and is
attached to the host by a narrow neck ; while dissec-
tion will reveal a small head buried in the flesh of
the fish’s gills, and having three branched outgrowths,
which penetrate into the surrounding tissues and
make the attachment of the parasite more secure.
Near the hinder end of the body are two coiled
threads, which are the egg-masses. The reduced
mouth parts and the microscopic vestiges of the
swimming feet may be detected on and near the
head, but apart from these it would be hard to
find any characters to show that the animal is a
Crustacean.

The life-history of Lerncea is very remarkable.
The young are hatched in the nauplius stage
(Fig. 73, A), and after passing through some further
free-swimming stages they become parasitic on a
fish. Curiously enough, however, they choose a
very different host from that on which the adults
are found, for at this stage (Fig. 73, B) they attach
themselves to the gills of one of the Flat-fishes
(Pleuronectidse), such as the Flounder, Plaice, etc.,
attachment being effected by a frontal cement gland
similar to that of the larval Caligidae, already
mentioned. The animal is now without the power
of swimming, its appendages becoming reduced to
stumps and losing their setae. After passing some

228

THE LIFE OF CRUSTACEA

time in this condition, the larva again acquires the
power of swimming, and leaves its host. Both sexes
become mature in this free-swimming stage (Fig. 73,
C, D), and impregnation is effected. The males
die without developing further, but the females seek
a second host, a fish of the family Gadidae, such as
the Cod, Haddock, etc., and, settling on the gills,
become metamorphosed (Fig. 73, E) into the adult
form described above.

Within the gill cavities of the strange-looking fish
known as the Angler or Fishing-frog ( Lophius
piscatorius) there may often be found specimens of
another parasitic Copepod, Chondr acanthus gibbosus .
It has a soft, unsegmented body about half an inch
long, provided with numerous blunt lobes which
give it a very irregular shape. On the under-side,
near the front, are forked lobes representing two
pairs of the swimming feet. At the hinder end are
usually attached a pair of long thread-like egg-masses.
Just at the point where the egg-masses are attached,
close inspection of the under-side of the body will
reveal a very minute maggot-like object. This is
a male individual, which is attached, like a secondary
parasite, to the body of the enormously larger female.

In all the cases mentioned, the animal is parasitic
in the final state of its existence — at least in the
female sex — but there are a few Copepoda which are
free-swimming, both when young and when adult,
but parasitic in the intermediate stages. Among the

Fig. 74 — Stages in the Life-history of Hcemocera dance, One
of the Monstrillid^e. (From Lankester’s “ Treatise on
Zoology,” after Malaquin.)

A, Free-swimming nauplius larva ; B, embryo after penetrating
into the body of the worm Salmacina ; C, D, E, successive stages
in the body of the host ; F, free-swimming adult female. (All
greatly enlarged, not to same scale.) a', Antennule ; br , brain ;
e , nauplius eye ; /, swimming feet; g.s., hairs on which the eggs
are carried ; m, position of mouth ; md, hooked mandible of
nauplius ; n, nerve cord ; ov, mass of eggs carried by female ; ovy ,
ovary ; pr, absorptive processes.

230 THE LIFE OF CRUSTACEA

Copepoda taken by the tow-net in British seas, there
may sometimes be found species of the family
Monstrillidae (Fig. 74, F), which are remarkable for
having no appendages between the antennules and
the first pair of swimming feet. They have no trace
of jaws, and only a minute vestige of a mouth-open-
ing ; while internally there is no food-canal, so that
the animals are incapable of taking nourishment.
Their development was for long a mystery, but it
is now known that the greater part of their life is
passed as internal parasites in certain bristle-footed
worms (Polychseta). The young are hatched as
nauplius larvse (Fig. 74, A) without mouth or food-
canal, but capable of swimming, and having the
third pair of appendages (mandibles) furnished with
strong hooks, by means of which they fasten on to
the worm which is to serve as their host. The
nauplius bores through the skin of the worm, casting
its cuticle and losing all its appendages in the
process, and making its way into one of the blood-
vessels in the form of a little oval mass of cells
(Fig. 74, B), within which no organs except the
degenerating nauplius eye can be detected. It later
becomes enclosed in a delicate cuticle, and from one
end two long finger-like processes grow out, which
are believed to have the function of absorbing
nourishment from the blood of the host (Fig. 74, C, D).
Within the cuticle the organs of the adult animal
are gradually differentiated (Fig. 74, E), and when

PARASITES AND MESSMATES

231

fully formed it bores its way through the tissues of
its host by means of rows of hook-like spines
surrounding the pointed posterior end of the sac.
On reaching the surface the enclosing membrane
bursts, and the adult animal is set free.

Of all Crustacean parasites, however, perhaps the
most remarkable in their structure and life-history
are the Cirripedes of the order Rhizocephala. It is
not uncommon on the British coasts to find specimens
of the common Shore Crab or other Crabs which
carry under the abdomen an oval fleshy body. This
is the Rhizocephalan Sacculina carcini (Plate XXIX.),
and it would hardly be possible to guess, from its
appearance or structure, that it was a Cirripede or a
Crustacean at all. It is attached to the under-side
of the Crab’s abdomen by a short stalk, and in the
middle of its opposite surface is a small opening
which leads into a cavity separating the outer
“ mantle ” from the body of the animal. Very often
this mantle cavity will be found to be full of eggs
enclosed in sausage-shaped packets. At the point
where the short stalk enters the abdomen of the
Crab, it gives off an immense system of fine branching
roots, which penetrate throughout the body of the
Crab, and even into its legs and other appendages.
By means of these roots the Sacculina absorbs
nourishment from the body-fluids of its host. Like
most Cirripedes, Sacculina is hermaphrodite, and the
body within the mantle cavity contains only the

232

THE LIFE OF CRUSTACEA

reproductive organs of the two sexes and a small
nerve ganglion representing the whole of the nervous
system. There is no mouth, no food-canal, and no
trace of appendages. Another Rhizocephalan, Pelto-
gaster, is not uncommonly found attached to the

Fig. 75 — Free-swimming Stages of Sacculina carcini. Much
enlarged. (After Delage )

A, Nauplius ; B, cypris stage.

abdomen of Hermit Crabs. Although the nauplius
larva of Sacculina was described, and its resemblance
to that of the Cirripedia pointed out, as long ago as
1836, by that acute observer, J. Vaughan Thompson,
it is only recently that the full life-history has been
made known by the researches of Professor Delage

PARASITES AND MESSMATES

233

and Mr. Geoffrey Smith. The nauplius larva
(Fig. 75, A) resembles that of the normal Cirripedes,
especially in the shape of the dorsal shield, which
is drawn out on either side in front into a pair of
fronto-lateral horns. It has, however, no mouth,
and the food-canal is quite absent. As in the normal
Cirripedes, the nauplius is followed by a cypris stage
(Fig. 75, B), also mouthless, and it is in this form
that the Sacculina seeks the Crab on which it is to
become parasitic. It would be almost impossible for
the cypris larva to settle on that part of the Crab
where the adult Sacculina is afterwards to appear,
since the Crab usually has its abdomen closely
pressed against the under-side of its thorax. The
larva therefore attaches itself on some exposed part
of the Crab, often on one of the legs, clinging to a
hair by means of its antennules. It bores through
the cuticle at the base of the hair, and the contents
of its body pass into the interior of the Crab as a
little mass of cells, the empty cypris shell being cast
off. This mass of cells, which constitutes the embryo
Sacculina , is carried about by the blood-currents of
the Crab till it reaches the under-side of the intestine,
where it becomes attached. It now begins to send
out roots (Fig. 76), and as it grows the central mass
travels backwards along the intestine of the Crab till
it reaches the place where the adult parasite is to
emerge. As the mass increases in size, and the
organs of the Sacculina become differentiated within

234

THE LIFE OF CRUSTACEA

it, its presence causes the living tissues between it
and the external cuticle to degenerate, so that when
the Crab moults an opening is left through which
the body of the parasite protrudes. Owing, no doubt,
to the drain on its system due to the presence of the
Sacculina , the Crab ceases to grow, and it does not
moult again as long as the parasite remains alive.

Fig. 76 — Early Stage of Sacculina within the Body of a Crab.

(After G. Smith.)

i, Intestine of the Crab ; s, body of the Sacculina , which afterwards
emerges on the under-surface of the Crab's abdomen ; r, roots of
the Sacculina .

In addition to this arrest of growth, Sacculina
produces in its hosts other changes, which affect
chiefly the reproductive organs and the structures
associated therewith. Crabs of either sex infected
with Sacculina are incapable of breeding ; the genital
gland (ovary or testis) is found on dissection to be
shrivelled up, and the external characters indicative
of sex become strangely modified. The changes have

PARASITES AND MESSMATES

235

been most fully studied in the case of a kind of
Spider Crab common at Naples — Inachus mauritanicus
In this species it is found that females infected with
Sacculina show no conspicuous external modification,
except that the abdominal appendages, which in the
normal females serve for the attachment of the eggs,
are greatly reduced in size. Infected males, how-
ever, may assume to a greater or less degree the
characters proper to the female sex. Some males
show little change, except that the chelipeds remain
small and flattened, as in the females and non-
breeding males. Other specimens have, in addition,
the abdomen much broader than in normal males,
and sometimes as broad as in the females. Finally,
some males develop on the abdomen, in addition to
the rod-like appendages on the first and second
somites, characteristic of the male sex, two-branched
appendages on the next three somites, as in the
females ; these individuals are, in fact, so completely
intermediate in character between the two sexes that
it is only by dissection that it is possible to recognize
them as modified males.

An indication of the way in which the degenerate
Rhizocephala have been derived from normal Cir-
ripedes is given by a peculiar species of pedunculate
Barnacle, Anelasma squalicola, which lives attached to
Sharks and Dogfish in the North Sea. In Anelasma
the peduncle becomes deeply buried in the flesh
of the Shark, and its surface is covered with short

236

THE LIFE OF CRUSTACEA

branching, root-like filaments. As in the case of
the Rhizocephala, these roots appear to absorb
nutriment from the host, and, although Anelasma
possesses a food-canal and mouth, the cirri are
reduced in size and devoid of hairs, so that they
cannot be used for obtaining food as in ordinary
Barnacles.

CHAPTER XI

CRUSTACEA IN RELATION TO MAN
HE Crustacea come into relation with human

-L life in the most obvious and direct way in the
case of those species that are used for food. The
number of species so used in various parts of the
world is very large, almost the only necessary condi-
tion being that the species shall be sufficiently large
and abundant to make it worth while to fish for it.

As most of the larger Crustacea belong to the
Decapoda, it is this order that supplies practically all
the edible species, almost the only exceptions being
a few Barnacles which are eaten in various parts
of the world. Thus the sessile Barnacle Balanus
psittacus , found on the coasts of Chili, and growing
to a length of 9 inches by 2 or 3 inches diameter, is,
according to statements quoted by Darwin, “ univer-
sally esteemed as a delicious article of food,” and the
pedunculate Pollicipes cornucopia is used for food on
the coasts of Brittany and Spain.

By far the most valuable of all the edible Crustacea
are the European and American Lobsters ( Homarus

238

THE LIFE OF CRUSTACEA

gammarus and H. americanus). The former is found
on the coasts of Europe from Norway to the
Mediterranean, living mostly a short distance below
low-water mark wherever the bottom is rocky. At
some places, as for instance at Worthing, Lobsters
are common on a sandy bottom, but as a rule they
seem to prefer localities where the crevices of a rough
hard bottom afford abundance of shelter. They are
usually caught in traps known as “ Lobster pots ” or
“ creels,” which vary in construction in different
localities. In some cases they are made of wicker-
work, hemispherical in shape, with a funnel-shaped
opening on top, so devised as to permit the Lobsters
to enter easily, while preventing their escape.
Another form is semi-cylindrical, with a framework of
wood covered with netting or with wooden spars, and
having two funnel-shaped entrances at the sides.
These traps are baited with pieces of fish, preferably
stale, and are sunk in suitable places, each attached
by a line to a buoy or float.

Important Lobster fisheries are carried on in
Norway, Scotland, England, Ireland, Heligoland, and
other parts of the coasts of Northern Europe. In the
South the Lobster fishery is of less importance, other
large Crustacea, especially the Spiny Lobster, being
more abundant and more highly esteemed.

The American Lobster, as already mentioned,
closely resembles the European species, the chief
difference being in the form of the rostrum (see

CRUSTACEA IN RELATION TO MAN 239

Fig. 9, p. 32). It is found on the Atlantic coast
from Labrador to Cape Hatteras, but it is not
abundant south of New Jersey. The canning of
Lobsters is a very important industry in Newfound-
land, the Maritime Provinces of Canada, and the
Northern New England States.

The only other species of the genus Homarus (H.
capensis) is found at the Cape of Good Hope, but it is
of small size and is of no economic importance.

The European Lobster rarely reaches a weight
of 10 pounds, although individuals of 14 pounds
weight have been caught. In America, there are
authentic records of Lobsters weighing 20 and even
23 pounds.

The bad effects of over-fishing have become
apparent of late years, especially on the American
coast, in the reduced average size of the Lobsters
caught rather than in a diminution of the total yield
of the fishery. Numerous experiments in legislation
have been made with a view to checking the deple-
tion of the fishing-grounds, but in no case with con-
spicuous success. A “ close time ” for the spawning
Lobsters has often been tried, but the fact that the
female carries the eggs attached to her body for
nearly a year after spawning makes it quite impos-
sible to give effective protection by this means. In
most Lobster-fishing districts a minimum size is
fixed by law, below which it is illegal to take or sell
Lobsters, and in many cases also the capture of

240

THE LIFE OF CRUSTACEA

females carrying spawn, or, as it is termed, “in
berry,” is prohibited.

The so - called “ Norway Lobster ” (. Nephrops
norvegicus — Plate XXX.), the “ Dublin Prawn ” of the
London fishmongers, is a smaller and much less
valuable species than the common Lobster. It may
be recognized at once by its long and slender claws,
furnished with rows of tubercles or blunt spines, and
by the sculptured markings on the somites of the
abdomen. When alive it is of an orange colour,
beautifully marked with red and white. It differs
considerably in its habits from the common Lobster,
living at a considerably greater depth (30 to 60
fathoms in Norway), and on a muddy bottom. It is
generally taken by trawling, and is captured in large
quantities by trawlers fishing in various parts of the
North Sea. Since it must be cooked soon after it is
caught, and cannot easily be brought to market alive
like the common Lobster, only a small number of
those actually caught are made use of. Formerly most
of those sold in London were caught in the Irish
Sea (whence the name of “ Dublin Prawn ”), but the
North Sea is now the chief source of supply. The
species is found in suitable localities from Norway
to the Mediterranean, and is especially abundant in
the Adriatic, where it is caught and sold in Venice
and elsewhere under the name of “ Scampo.”

The Spiny Lobster, Rock Lobster, or Sea-craw-
fish (Palinurus vulgaris — Plate V.), is common on the

PL A TE XXX

THE “NORWAY LOBSTER,’ NephrOpS HOnjeglCUS, ABOUT
ONE-THIRD NATURAL SIZE
( From Brit. Mus. Guide)

CRUSTACEA IN RELATION TO MAN 241

south and south-west coasts of the British Islands,
becoming rare in the north, although specimens
have been found as far north as Orkney, and there is
a single record of the species from the West of
Norway. It is far less commonly used for the table
in this country than in France, where it is known as
“ Langouste ” and is very highly esteemed.

Various species of Spiny Lobsters belonging to
the same family (Palinuridse) as the European
species are found in different parts of the world. In
tropical countries the species of Panulirus are com-
monly used for food (for example, P. interruptus in
California and P. fasciatus in India), as are species of
Jasus in South Africa, Australia, and New Zealand.
Recently a consignment of Spiny Lobsters {Jasus
lalandii) was sent to the London market from the
Cape, but it appears that the experiment was not
altogether successful.

Belonging to the same tribe (Nephropsidea) as
the Lobsters are the fresh-water Crayfishes. The
English Crayfish (Astacus pallipes) is common in
many rivers as far north as Lancashire, and in some
parts of Ireland, but is not found in Scotland. It is
not much esteemed for the table, and although small
numbers are sent to Billingsgate, chiefly from
Leicestershire, they are said to be used only for
garnishing dishes. The same species occurs on the
Continent of Europe, chiefly in the west and south
(France, Germany, Switzerland, Spain, Italy, and
16

242

THE LIFE OF CRUSTACEA

the Balkan Peninsula). It is known in France as
“ Ecrevisse a pattes blanches ” (from the whitish
colour of the under-side of the large claws), and in
Germany as “ Steinkrebs,” and is distinguished,
among other characters, by the shape of the rostrum
(Fig. 77, B), which has a tooth on each side close to
the point. Far more important as an article of food
is the larger Astacus fluviatilis , the “ Ecrevisse a
pattes rouges” or “ Edelkrebs,” which is found in

Fig. 77 — Rostrum and Fore Part of Carapace, seen from
Above, of (A) Red-clawed Crayfish ( Astacus fluviatilis) and
(B) White-clawed or English Crayfish (Astacus pallipes)

France, Germany, Austria, Southern Sweden, Russia,
etc. In this species the under-side of the large claws
is generally of a fine red colour, and the rostrum
(Fig. 77, A) has a pair of side-teeth about the middle
of its length, and a long slender point. The red-
clawed Crayfish is an important article of commerce
on the Continent, and is sent to the London market
in considerable numbers, chiefly from Germany and
South-West Russia. In France it is cultivated for
the market in “ Crayfish farms ” on a large scale.

A species of Crayfish (A . leptodactylus) occurring in

CRUSTACEA IN RELATION TO MAN 243

the Lower Danube and in other rivers flowing into
the Black Sea sometimes finds its way to the London
market, although it is less valued than the red-
clawed species. It is distinguished by its long and
slender claws, by the spiny edges of the rostrum, and
by other characters. A fourth species (A . torrentium),
occurring chiefly in Central Europe, is very closely
allied to A.pallipes , and, like it, is of little value for
the table.

Within the last thirty years the Crayfish fisheries
of Western Europe have suffered heavily from out-
breaks of an epidemic disease which has all but
exterminated these animals in certain districts.
In this country it is said to be responsible for the
almost complete disappearance of Crayfish from
localities where they were formerly plentiful, as, for
instance, in the neighbourhood of Oxford. The
cause of the disease is believed to be a protozoan
parasite belonging to the group Myxosporidia.

In other parts of the world it does not seem that
the fresh-water Crayfishes are of much importance
as an article of food. Some species of Cambarus are
so used to a limited extent in the United States, and
the gigantic Astacopsis serratus (Plate XX.) is known
as the “ Murray River Lobster ” in the markets
of Sydney and Melbourne.

The Decapods of the suborder Natantia comprise
a large number of edible species, generally known
as Shrimps and Prawns. The Common Shrimp,

244

THE LIFE OF CRUSTACEA

Crangon vulgaris (Fig. 78), which is plentiful on the
British coasts wherever the bottom is sandy, is about
two or three inches long, and when alive is of a
translucent greyish colour speckled with brown. It
differs from most of the Natantia in having the body
somewhat flattened from above downwards, and the

Fig. 78 — The Common Shrimp ( Crangon vulgaris). Natural Size

rostrum very short. When boiled, it is of a reddish-
brown colour, and from this it is sometimes known
as the “ Brown Shrimp.” On many parts of the
coast the Shrimp fishery is of considerable im-
portance. Most often the Shrimps are caught by
means of a large bag-net attached to a semicircular
hoop with a long handle, and pushed over the surface

CRUSTACEA IN RELATION TO MAN 245

of the sand by a fisherman wading in the water at
ebb-tide.

A variety of species are sold in England under the
name of Prawns. The largest of the native species,
to which the name of Common Prawn is perhaps
most properly restricted, is Leander serratus. It
grows to a length of over 4 inches, and has a long
serrated rostrum extending beyond the antennal
scales and curving upwards at the point. The first
and second pairs of legs end in small pincer-claws.
When alive the animal is very transparent, and
beautifully marked with bands of brown and red on
the body and limbs. A smaller species of the same
genus (L. squilla), distinguished by the much shorter
and straighter rostrum, and another very similar
species of which the proper name appears to be
L. adspersus (often known as L. fabricii ), are said to
be sold on some parts of the English coast as “ Cup
Shrimps.”

Much commoner, at least in the London market,
than the species of Leander is Pandalus montagui,
often sold under the general name of Prawn, but
sometimes called the “ Pink Shrimp.” This re-
sembles Leander serratus in having a long, serrated,
up-curved rostrum, but differs from it strikingly in
the form of the anterior pairs of feet. The first pair
appear to the naked eye to have no pincer-claws, but
to end in a sharp point, resembling the third maxilli-
peds, which are just in front of them. As a matter of

246

THE LIFE OF CRUSTACEA

fact, they do have pincers, but so minute that they
can only be detected by microscopic examination.
The feet of the second pair are unequal in length on
the two sides, that on the left side being the longer,
and are very slender. They end in small pincers,
and examination with a pocket-lens will show that
the carpus, or “wrist,” and the segment below it
(merus) are broken up into a large number of short

Fig. 79— The Norwegian Deep-water Prawn ( Pandalus borealis).
Female. (After Sars.)

The second leg of the right side is indicated by dotted lines.

segments, so that the limb is extremely flexible.
When alive, the animal is even more handsomely
marked than the Common Prawn.

A large species of Prawn is now imported to this
country in considerable quantities from Norway.
This is Pandalus borealis (Fig. 7 9), a species closely
allied to the last-named, but differing in the longer
and more slender rostrum and in many other
characters, as well as in its larger size (specimens

CRUSTACEA IN RELATION TO MAN 247

have been recorded of 6 inches in total length). It
also differs in its habitat, for while P. montagui lives
in shallow water, or even between tide-marks,
P. borealis occurs at depths of 30 to 60 fathoms in the
Norwegian fjords. The recent development of the
fishery for P. borealis in Norway is a striking example
of the practical- value of zoological research. Until
1898 the species was hardly known except to zool-
ogists, although a small fishery was carried on in
the Drammen Fjord, near Christiania. The investiga-
tions of the naturalists employed by the Norwegian
Department of Fisheries showed that the species
existed in vast numbers in the deeper water of many
of the fjords, and that it could be captured in abun-
dance by means of a suitably-devised trawl-net. As
a result, a very profitable fishery was established, and
the “ deep-water Prawns ” are now not only largely
consumed in Norway, but are exported in increasing
quantities to the English and other markets.

In the warmer seas the large Prawns of the genus
Penceus are of considerable importance. Thus, in the
Mediterranean countries, Penceus caramote (Plate IV.)
is highly esteemed for food, and P. setifer and
P. brasiliensis are largely consumed in the Southern
United States. P. monodon and other species are
eaten in India. An attempt has been made to send
a species of the same genus (apparently P. indicus) in
a frozen state from Queensland to the London
market.

248

THE LIFE OF CRUSTACEA

Numerous other species of Natantia are used for
food in various parts of the world, but the only ones
that need be further mentioned here are the River
Prawns of the genus Palcemon, which are abundant
in the fresh waters of most tropical countries, and
sometimes grow to a very large size. They are
generally distinguished by the fact that the legs of
the second pair are very long, forming powerful
pincer-claws. In the West Indies and Central
America, P. jamaicensis (Plate XXI.), which reaches
a length of 10 inches exclusive of the great claws, is
sold in the markets, while in India and elsewhere
in the East P. carcinus, which grows to an even
greater size, and other smaller species, are used for
food. The fresh-water Prawns of the family Atyidse,
on account of their small size, are not of much
importance from this point of view, but Professor
Hickson states that the little Caridina nilotica, a very
widely-distributed species, is eaten in Celebes.

Among British Crustacea, the next in importance
to the Lobster as an article of food is the Edible
Crab, Cancer pagurus (Plate XXXI.), known in
Scotland as the “ Partan.” Like the Lobster, it is
found on rocky coasts in shallow water, and young
specimens are often taken between tide-marks. It
grows to a size of more than 10 inches across the
shell, and may reach a weight of 12 pounds. The
means used for its capture are the same as in the
case of the Lobster, and the fishery is of considerable

PL A TE XXXI

CRUSTACEA IN RELATION TO MAN 249

importance on many parts of the British coasts.
On the other hand, a Connemara fisherman, who
was using these Crabs for bait, received with incre-
dulity the statement that they were good for human
food !

The Shore Crab, Carcinus mcenas (Plate IX.), is
not of much importance as food in this country,
although it is recorded that fifty years ago great
numbers were brought to the London market. On
the shores of the Mediterranean and Adriatic, how-
ever, and especially in Venice, this species is re-
garded as a delicacy, particularly in the soft-shelled
state after moulting.

On the Atlantic coast of North America, the
most important edible Crustacean after the Lobster
is the “ Blue Crab ” ( Callinectes sapidus), one of the
Swimming Crabs (Portunidse). This is consumed
in large quantities, especially in the soft-shelled state.
Several other species of Crabs are eaten in America,
including the little “ Oyster Crab,” a species ot
Pinnotheres living in the American Oyster. From
its small size, and the difficulty of obtaining it in
numbers, it is a very costly delicacy.

In the East Indies the most important edible
Crabs are various species of Portunidse, especially
the large Scylla serrata and Neptunus pelagicus.

Except as food, the Crustacea are of very little
direct use to man. Almost the only instance in
which they are otherwise utilized is in the case of

250

THE LIFE OF CRUSTACEA

a 'species of sessile Barnacle ( Balanus ) which is
cultivated in Japan for use as manure. The method
of culture has been described by Professor Mitsukuri.
Bunches of bamboo “collectors,” like those used
for the collection of oyster-spat, are fixed into the
ground on tidal flats. After two or three months
they are taken up, and the Barnacles with which
they have become covered are beaten off and sold
for use as manure.

Apart from their direct utility, however, the Crus-
tacea are indirectly of great importance as providing
a large part of the food-supply of marketable fishes.
From this point of view, a study of the habits and
distribution of the commoner species may be of
practical value in throwing light on the migrations
and other obscure points in the life-history of the
fishes that prey upon them. As an example of this,
we may refer to some investigations on the Mackerel
fishery recently carried out by the naturalists of
the Marine Biological Association at Plymouth. In
the spring and early summer months the Mackerel
migrate into inshore waters for the purpose of
spawning. During this period the fish congregate
in shoals at the surface of the sea, and are captured
in drift-nets. The extent of this “ shoaling ” varies
greatly from year to year, and determines whether
the season shall be a profitable one for the fishermen
or not. When shoaling, the fish feed exclusively on
plankton, consisting largely of Copepoda, and it has

CRUSTACEA IN RELATION TO MAN 251

been shown by Mr. G. E. Bullen that the fluctuations
in the yield of the Mackerel fishery from year to year
follow very closely the fluctuations in the abundance
of the Copepod plankton on the fishing-grounds.
The investigation has been carried a step farther by
Dr. E. J. Allen, who points out that the abundance
of Copepods is determined by the abundance of the
Diatoms and other minute vegetable organisms of
the plankton. These organisms are very largely
influenced by the amount of sunshine during the
period of their development in the earlier months of
the year. Dr. Allen gives a diagram showing for
each of seven years (1902-1908) the average number
of hours of bright sunshine during the months of
February and March in the South-West of England.
With this he compares the number of fish caught
in the month of May in each of these years by
certain vessels engaged in the western Mackerel
fishery. The correspondence between the two is
very striking indeed, and justifies his conclusion
that the amount of sunshine in the early months of
the year determines the abundance of the vegetable
life of the plankton, and through it of the Copepods
and other animals which form the bulk of the
plankton a little later in the year ; and although
there are doubtless other influences at work deter-
mining the success or failure of the fishery, it is
largely a matter of the richness or poverty of the
plankton harvest.

252

THE LIFE OF CRUSTACEA

None of the Crustacea can be regarded as directly
harmful to man. They have not the power of
inflicting envenomed wounds which renders some
other Arthropods, such as Scorpions, some Spiders,
Centipedes, and Insects, formidable in spite of their
small size ; and although blood-curdling tales of the
ferocity of the Land Crabs are to be found in the
accounts of old voyages, even the largest of these is
hardly an antagonist to be dreaded.

A considerable number of invertebrate animals,
not of themselves noxious, are now known to be
the indirect cause of much serious injury to human
life by harbouring and disseminating organisms
which produce disease. The progress of research is
adding, almost every day, to the number of species
known to be disease-carriers, and it is possible that
in the future some Crustacea as yet unsuspected
may be added to the list.

At present, however, there is only one case in
which a Crustacean has been shown to be concerned
in the transmission of a parasite of man. The
“ Guinea-worm,” Filaria (or Dracunculus) medinensis,
is a parasite belonging to the group of “ Thread-
worms ” (Nematoda) which causes dangerous ab-
scesses under the skin of the legs in many parts
of tropical Africa. It has been shown that the
embryos of the worm, which are discharged in vast
numbers on the bursting of the abscess, do not
develop unless they fall into water containing certain

CRUSTACEA IN RELATION TO MAN 253

species of the Copepod Cyclops (see Fig. 14, p. 39).
In some way not yet understood, the embryos
penetrate into the body cavity of the Cyclops, where
they undergo a metamorphosis. For their further
development it is necessary that the Cyclops should
be swallowed by man, as may easily happen in
drinking water from a pond. When the Cyclops is
digested the larval worms are set free, and they bore
their way through the tissues of their human host
till they reach the place (generally under the skin of
the leg) where they complete their development and
produce the innumerable embryos that are set free
in the way just described.

A few Crustacea inflict a certain amount of injury
on man in more indirect ways. In tropical countries,
Land Crabs are often troublesome in gardens, and
may cause serious damage to young plants in sugar-
cane plantations and rice-fields. In gardens in this
country, the Woodlice, as already mentioned, are
sometimes destructive to seedlings and delicate
plants. The little fresh-water Isopod, Asellus aquati-
ons, is accused of destroying the nets used in fishing
for Pollan in Lough Neagh in Ireland.

Probably the most important of all Crustacea,
however, as regards their destructive activity, are the
species which bore into wood, and sometimes do exten-
sive damage to the submerged timber of piers, jetties,
and similar structures. On our own coast the most
destructive is a little Isopod known as the “ Gribble ”

254

THE LIFE OF CRUSTACEA

{Limnoria lignorum — Fig. 80), which is distributed
from Norway to the Black Sea, |and ’occurs also on
the Atlantic coast of North America. Several species
of the same genus having similar habits are found in
other parts of the world. The Gribble was first
discovered as a British species by Robert Stevenson,
the celebrated lighthouse engineer, who found it in

Fig. 8o — The Gribble ( Limnoria lignorum). Much enlarged
(From British Museum Guide, after Sars.)

1811 destroying the woodwork employed in the
erection of the Bell Rock Lighthouse, and sent
specimens to Dr. Leach of the British Museum.
The animal is only about, one-eighth of an inch in
length, and its cylindrical burrow is about one-
fifteenth of an inch in diameter, and penetrates for a
depth of one or two inches. The excavation of the
wood is effected by means of the mandibles, which
are unusually strong ; and when the animals are

PLATE XXX II

PIECE OF TIMBER FROM RYDE PIER SHOWING DAMAGE CAUSED BY

Limnoria and Chelura

( From Brit. Mus. Guide)

CRUSTACEA IN RELATION TO MAN 255

numerous the burrows are driven so close together
that the surface of the wood is reduced to a spongy
mass which is rapidly washed away by the waves
(Plate XXXII.). The Gribble is often accompanied
by another Crustacean of similar habits, the Amphi-
pod Chelura terebrans. The latter is about one-fifth
of an inch in length, and differs from most Amphi-
pods in having the body somewhat flattened from
above downwards instead of from side to side. The
burrows made by Chelura are shallower than those of
the Gribble, and generally run more or less parallel
to the surface of the wood.

CHAPTER XII

CRUSTACEA OF THE PAST

SINCE the acceptance by naturalists of the theory
of Evolution as indicating the mode of origin
of the various forms of life now existing, one of
the chief lines of biological investigation has had
for its object the reconstruction of the pedigree (or,
as it is called, the “ phylogeny ”) of the larger groups
of the animal and vegetable kingdoms. In attempt-
ing to do this, there are three main sources from
which evidence maybe drawn. The results of Com-
parative Anatomy enable us to decide with more or
less confidence as to the degrees of relationship
between the groups of organisms, and to distinguish
between the more primitive and the more specialized ;
the study of Embryology is, at least, an indispensable
adjunct to Comparative Anatomy, even if it does not,
as was once supposed, give us an actual recapitula-
tion of ancestral history ; and, finally, the study of
Fossil Remains holds out the hope that we may be
able to find the ancestral types themselves.

It is clear that evidence from the last-named
256

CRUSTACEA OF THE PAST

257

source, when it is available, is the most important of
all, since the order of succession of the various types
is given by that of the rock strata in which they
occur, and we can be quite certain that we are
dealing, if not with the actual ancestors, at least
with the forerunners of existing species. The “ im-
perfection of the geological record,” however, is so
great that the organisms preserved in the fossil state
represent only an insignificant part of the whole
number of organisms that have lived on the globe
since life began ; and it is not surprising, therefore,
that in many groups the study of fossils has
hitherto afforded little help towards the working out
of their genealogical history. Thus, among Crus-
tacea there are many important groups such as the
Copepoda, which are entirely unknown as fossils,
their small and delicate bodies being ill adapted for
preservation, although there is every reason to
suppose that they are a very primitive and very
ancient group. In many fossil Crustacea only the
hard shell or carapace has been preserved, the
appendages being lost or represented only by in-
decipherable fragments, and in some cases it is
hardly possible to guess at the affinities of the
animals. Further, several important groups are
already represented in some of the oldest of the
fossil-bearing rocks at present known, and the
differentiation of these groups must have taken place
in the dark ages before the record of the fossils

258

THE LIFE OF CRUSTACEA

begins. In spite of these disadvantages, however,
the study of fossil Crustacea does throw considerable
light on the evolution of the group, and it is likely
that interesting results in this direction await future
investigations.

In the earliest fossiliferous rocks the most abundant
and important Arthropods are the Trilobites (Fig. 81),

Fig. 8i — Restoration of a Trilobite ( Triavthrus becki), showing
the Appendages. Upper Side on Right, Under-side on
Left. Slightly enlarged. (After Beecher.)

an extinct group which appears to have been related
to the primitive Crustacea. The name Trilobite
refers to the three-lobed form of the body when seen
from the dorsal side, most species having a pair of
grooves running lengthwise which divide off a middle
lobe containing the principal organs of the body from
two lateral “ pleural ” expansions covering the limbs.

CRUSTACEA OF THE PAST

259

The head-shield shows indications of being com-
posed of five segments, and bears a pair of sessile
compound eyes. It is followed by a number (up
to twenty-six) of free somites, and the body ends in a
tail-shield, or “pygidium,” which is often plainly com-
posed of several somites fused together. Although
Trilobites are among the commonest and most
familiar of fossils in the older rocks, the nature of
their appendages remained quite unknown until
within recent years, when specimens of several
species showing the structure of the limbs and
under-side of the body were discovered in America.
From these it appears that the head bore in front
a pair of long thread-like antennae and four pairs
of two-branched appendages, each with a jaw pro-
cess, or “gnathobase,” turned towards the mouth,
which is covered below by a large anterior lip, or
“ hypostome.” It seems probable that the five pairs
of head-appendages correspond respectively to the
antennules, antennae, mandibles, maxillulae, and
maxillae, of Crustacea ; but the second pair appear
to have acted as jaws, retaining the gnathobase which,
among Crustacea, is only hinted at by the hooked
spine on the antenna of the nauplius larva.

Each of the free somites and of those forming the
tail-shield bears a pair of two-branched appendages,
not differing greatly from the posterior appendages
of the head, but becoming smaller and more flattened
towards the hinder end of the body. The numerous

260 THE LIFE OF CRUSTACEA

genera and species of Trilobites present great differ-
ences in the form and ornamentation of the dorsal
surface of the body, and it is probable that con-
siderable differences may also have existed in the
structure of the limbs, which are only known in two
or three species. Some Trilobites are among the
most ancient of known fossils, being found in rocks
of the Lower Cambrian epoch. The group reaches
its maximum development in the Ordovician, and
the number of the species and size of the individuals
gradually diminish through the Silurian and Devonian
till they become extinct at the close of the Carbon-
iferous epoch, except for a single species found in
rocks of Permian age in America.

Although zoologists are not all agreed as to the
precise systematic place to be assigned to the Trilo-
bites, there can be little doubt that they were related
more or less closely to the most primitive Crustacea,
and they are of special interest as preserving for us
the stage in which the second pair of appendages
were still used as biting jaws, and had not moved
forwards in front of the mouth to become antennae,
as in all living Crustacea.

Contemporary with some of the earliest Trilobites,
however, are undoubted Crustacea, which, so far as
we know their structure, are not very different from
types now living. In the Cambrian epoch the
Branchiopoda appear to be represented by Protocaris,
which in its general form resembles Apus ; and

CRUSTACEA OF THE PAST

261

there are a variety of genera and species of Ostra-
coda, although, since their shells alone are preserved,
it is not possible to determine their exact relations
to existing forms. In the succeeding Ordovician
and Silurian epochs we first meet with the remains
of Barnacles, and it is interesting to note that some
of them are referred to the genera Pollicipes and
Scalpellum, which are represented by numerous
species in the seas of the present day. Along with
these, however, are some strange-looking forms
( Turrilepas , etc.), having the body covered with rows
of overlapping plates. If these are really Cirripedes,
they must have differed considerably in structure
from the more modern types.

The Malacostraca are more interesting from the
point of view of palaeontology than the other sub-
classes of Crustacea, since the evolution of the group
appears to have taken place within the period covered
by the fossil records, and it is possible to trace the
course of that evolution — at least, in its broad out-
lines. It has already been pointed out that the most
primitive of existing Malacostraca are the Phyllo-
carida (Nebalia and its allies), which are in several
respects intermediate between the higher Malacos-
traca and the Branchiopoda ; and it is interesting to
find that fossils apparently belonging to the Phyl-
locarida are found far earlier than any of the other
Malacostraca. In the Cambrian, and more abund-
antly in the Ordovician and Silurian, there are found

262

THE LIFE OF CRUSTACEA

Crustacea (Fig. 82) that resemble Nebalia in having
a large bivalved carapace, with a movable beak-like
plate in front, a projecting abdomen without con-
spicuous limbs, and a pair of large spines at the
sides of the telson. Unfortunately, we have almost
no knowledge of the structure of the limbs ; but it
can hardly be doubted that these very ancient
Crustacea were allied to the existing Phyllocarida,

m ,

Fig. 82 — Ceratiocaris papilio , One of the Fossil Phyllocarida.

(From Lankester’s “ Treatise on Zoology,” after H. Woodward.)

a, Traces of antennules ; m, possibly mandibles ; r, rostral plate

and that they included the forerunners of the higher
Malacostraca.

It is in the Carboniferous epoch, in all probability,
that we must look for the origin of most of the
existing orders of Malacostraca. In the rocks of
this age in different parts of the world there have
been found a number of undoubted Malacostraca,
nearly all of the shrimp-like form which there is
good reason to believe to be a primitive character-

CRUSTACEA OF THE PAST

263

istic. Some of these ( Pygocephalus — Fig. 83) have
recently been shown to possess a brood-pouch formed
of overlapping plates on the under-side of the thorax,
and thus resemble the existing Mysidacea, which
stand at the base of the Peracaridan series of orders.
Others have a pair of strong side spines near the tip
of the telson, and in other ways resemble the recent

Fig. 83 — Pygocephalus cooperi, from the Coal-measures : Under-
Side of a Female Specimen, showing the Overlapping
Plates of the Brood-pouch. (From Lankester’s “ Treatise on
Zoology,” after H. Woodward.)

Euphausiacea, so that they may have been primitive
members of the Eucaridan series.

Among the Crustacea of the Carboniferous and
Permian epochs, there are a number of forms of
which the affinities were until recently quite
obscure. They have two -branched antennules, a
scale-like exopodite on the antenna, and the last
pair of appendages (uropods) form, with the telson,

264

THE LIFE OF CRUSTACEA

a tail-fan. In these points they resemble the shrimp-
like forms, but there is no carapace, and all the
somites of the thorax are distinct, so that the form
of the body is rather that of an Amphipod or Isopod.
On the discovery of the remarkable Crustacean
Anaspides (Fig. 84), which lives in fresh-water pools
in the mountains of Tasmania, it was pointed out
that it agreed with the fossil genera Uronectes , Palceo-

Fig. 84 — The Tasmanian “Mountain Shrimp” ( Anaspides
tasmanicB ), a Living Representative of the Syncarida.
Slightly enlarged

c.gr ., “Cervical groove,” marking off the first thoracic somite;
ii-viii, the remaining thoracic somites ; 1-6, the abdominal
somites

caris , and their allies, in those very characters in
which they differed from all other Crustacea, and that
it must be regarded as a surviving representative of
the ancient group to which the name of Syncarida
had been given. The more recent discoveries of
living forms, Paranaspides from the Great Lake of
Tasmania and Koonunga from fresh-water pools near

CRUSTACEA OF THE PAST

265

Melbourne, and of the fossil Prceanaspides (Fig. 85)
from the Coal-measures of Derbyshire, have tended
to support this conclusion. There can be little
doubt that the Syncarida arose during the Carbon-
iferous epoch (or earlier) from primitive shrimp-like
forms which lost the carapace ; but, after flourishing
for a relatively brief period, the group dwindled away,

Fig. 85 — Praanaspides precursor, One of the Fossil Syncarida,
from the Coal-measures of Derbyshire. Slightly en-
larged. (After H. Woodward.)

although a few survivors have lingered on, like so
many other “ living fossils,” in the isolated Australian
region.

It must be pointed out that, in spite of the re-
semblance of the body of Anaspides to that of an
Amphipod, the Syncarida can have had no close
relation to the origin of the Isopoda and Amphipoda.
These have also been derived from a shrimp-like
type, but their possession of a brood-pouch, among

266

THE LIFE OF CRUSTACEA

other characters, shows that they are linked on to
the Mysidacea, and must have arisen from some
primitive member of that group, like Pygocephalus.
Although palaeontology as yet gives little help in
tracing the course of their evolution, we can im-
agine what the intermediate links must have been
like by comparison with the living Cumacea and
Tanaidacea.

It is possible, indeed, that the divergence of the
Isopod line of descent from that of the Mysidacea
took place earlier than the Carboniferous epoch,
for there has recently been discovered in rocks of
Devonian age in Ireland a single specimen of a fossil,
to which the name of Oxyuropoda has been given,
which has every appearance of being an Isopod.
At all events, undoubted Isopods make their appear-
ance in rocks of the Secondary Period, and some of
those from the Jurassic epoch are not very different
in general form from types still existing.

Some of the Carboniferous shrimp-like Crustacea
present characters which seem to point in the direc-
tion of the Stomatopoda, and fossils which clearly
belong to that group are found in Jurassic and
later deposits. In the Cretaceous epoch there were
Stomatopoda resembling modern types so closely
that they have been referred to the existing genus
Squilla. We are even able to say that they resembled
the living Stomatopoda in their mode of development,
for larvae of the type known as Erichthus have been

CRUSTACEA OF THE PAST

267

recognized in rocks of Cretaceous age from Lebanon.
This is a striking example of the way in which, by a
fortunate accident as it were, organisms apparently
ill-adapted for fossilization may occasionally be pre-
served.

Of the Decapoda the geological history is tolerably
full, and it is possible to trace in its broad outlines
the course of evolution of the various suborders.
Here again it is likely that the beginnings of the
group are to be sought for in the Carboniferous
epoch, and some of the obscure shrimp-like forms
of that age show hints of an affinity with the
Decapods. In the Triassic epoch, however, and
more abundantly in the succeeding Jurassic, a
number of types are found which seem to include
primitive representatives of several of the existing
groups of Natantia and Reptantia. It is noteworthy
that among them are some forms (Alger, etc.)
resembling the existing Stenopidea, a tribe which
in some respects is intermediate between these two
suborders. In the Stenopidea the first three pairs
of legs bear pincer-claws, as in the Lobster, but the
third pair is much the largest ; and Alger agrees with
them in this unusual character, though there is little
else, in what is known of its structure, to help to
determine its affinities.

The tribe Penseidea, which occupies in many
respects a primitive place among the Natantia, is
abundantly represented in the Jurassic epoch,

268

THE LIFE OF CRUSTACEA

especially in the lithographic stone (Upper Jurassic)
of Solenhofen, and by somewhat doubtful specimens
from the earlier Trias. All these agree in having
the first three pairs of legs with pincer-claws, and
not differing greatly in size. Some of the Jurassic
and later fossils are of so modern a type that they
have been referred to the existing genus Penceus.

The Upper Jurassic rocks also preserve the earliest
undoubted specimens of true Prawns of the tribe
Caridea, and some of these show swimming branches
(exopodites) on the thoracic legs, so that they were
probably related to the primitive family Acanthe-
phyridse, of which the existing members are found in
the deep sea. It is possible, however, that Caridea
were already in existence far earlier, for some of
the obscure Carboniferous forms seem to have the
broadened side-plates of the second abdominal somite,
which, so far as we know, are exclusively characteristic
of that tribe.

The Reptantia, forming the other large division of
the Decapoda, also had their origin at least as early
as the Triassic epoch, where representatives of the
tribes Eryonidea and Scyllaridea are found. The
history of the Eryonidea has already been discussed
(p. 133) in dealing with the deep-sea Crustacea. The
oldest representatives of the Scyllaridea belong to a
family (Glyphseidse) now wholly extinct, and are in
many respects more primitive and lobster-like than
any of the living Spiny Lobsters and their allies

CRUSTACEA OF THE PAST

269

(Palinuridse and Scyllaridae). Forms with greatly
thickened antennae, indicating a transition to the
Palinuridae, begin to appear in the Jurassic; and
in the later Cretaceous a genus, Podocrates, occurs
which is hardly to be distinguished from Linuparus,
now living in Japanese seas. The Scyllaridae have
the antennae modified into broad shovel-like plates,
and perhaps take their origin from Cancrinus, in the
Solenhofen lithographic stone (Jurassic), which has
broad and apparently flattened antennae. True
Scyllaridae are certainly found in Cretaceous de-
posits, and some, from the Upper Chalk, are even
referred to the existing genus Scyllams.

The Anomura are almost unknown as fossils, but
the true Crabs, or Brachyura, are abundantly repre-
sented. They first appear about the middle of the
Jurassic epoch, and, as already pointed out, the
earliest forms (Prosoponidae) are referred to the
Dromiacea, and appear to be closely related to the
primitive Homolodromiidae now living in the deep sea
(p. 134). One of the oldest, and at the same time one
of the most completely known, is Protocarcinus , from
the Great Oolite of Wiltshire, which is preserved (in
the only known specimen) with the abdomen partly
extended, possibly indicating that the abdomen was
less closely doubled under the body than in modern
Crabs.

The next group of Crabs to appear are the Oxysto-
mata, which are found from the middle of the

270

THE LIFE OF CRUSTACEA

Cretaceous epoch onwards. The Brachyrhyncha
perhaps begin to appear about the same time, but
the affinities of the earlier types are doubtful, and it
is only in the Tertiary that they become abundant
and unmistakable. Several living genera, such as
Cancer , date back to the Eocene. The Spider Crabs
(Oxyrhyncha) are rare as fossils, and the earliest
specimens are found near the beginning of the
Tertiary.

APPENDIX

I. METHODS OF COLLECTING AND PRESERVING
CRUSTACEA

IT may be useful to give here a few hints as to the
methods of collecting Crustacea. Of the species
that live in the sea, many may be found between tide-
marks by turning over stones and searching among
sea-weeds and in rock crevices. A small hand-net,
made by fastening a bag of coarse muslin to a stout
wire ring of a few inches diameter, is useful for fishing
in rock pools. Shore-collecting in this manner is
most productive at spring-tides, when the deeper
levels of the shore are open to exploration.

Many burrowing species are to be found by digging
in the sand near low-water mark. In addition to
Crabs and other large species, many minute forms,
Amphipods, Cumacea, and the like, inhabit such
localities. The best way of collecting these is to
stir up a spadeful of the sand in a bucket of water,
and, after allowing the sand to settle for a few
seconds, to pour off the water through a muslin bag.
After repeating the operation two or three times, the
contents of the bag are washed out into a jar or dish

271

272 THE LIFE OF CRUSTACEA

of sea-water for examination with a lens or under the
microscope.

Dredging is the most effective method of obtaining
Crustacea that live in deeper water. The dredge
usually employed by naturalists consists of a heavy
rectangular iron frame to which is attached a strong
bag-shaped net. The two longer sides of the frame
are sharp-edged and bevelled outwards, so as to
“ bite ” when the dredge is dragged along the sea-
bottom. To the shorter sides are hinged a pair
of arms ending in rings. The dredge-rope is made
fast to one of these rings, while the other is held
only by a “stopping” of yarn, which gives way if
the dredge should catch on a rock, and permits it
to be dragged sideways off the obstruction. The
size and weight of the dredge may vary according
to the depth at which it is to be used and the power
available for working it. A convenient size for use
with a small sailing boat at moderate depths has
a frame 20 by 5 inches.

Apart from dredging, many specimens from
moderately deep water may be picked out from
among the “ rubbish ” brought up on fishermen’s
lines or by the trawl, and various Crustacea besides
the edible species find their way into Lobster and
Crab pots. The true deep-sea fauna is, for the most
part, only to be reached by specially-equipped ex-
peditions, although specimens from great depths are
occasionally obtained during the operations for the
repair of submarine telegraph cables.

The floating animals of the surface of the sea are

COLLECTING AND PRESERVING 273

to be captured by means of the tow- net. This con-
sists of a conical bag of muslin, cheese-cloth, or, best
of all, silk “ bolting-cloth,” attached to a galvanized
iron ring of one or two feet in diameter, and having
a zinc can or a strong glass jar fixed to the narrow
end. The ring is attached by three equidistant cords
to the towing line, and the net is towed slowly at
or near the surface of the sea. When taken on
board, the contents of the can are emptied into a
jar of sea- water for examination. The tow-net is
best used when there is only enough way on the
boat to keep the net from sinking ; if towed more
rapidly, delicate organisms are apt to be crushed
by the pressure of the water, or the net itself may
be burst. The use of unnecessarily fine nets should
be avoided. A fine-meshed net may not capture a
single specimen of the larger Crustacea, even though
these may be swarming in the water through which
it is drawn.

By weighting the tow-net it may be used at various
depths to capture the floating animals of mid-water.
When it is so used, however, it is impossible to tell
from what depth any particular specimen may have
come, since it may have been captured during the
hauling in of the net. For more precise investiga-
tions in deep water, “ closing tow-nets ” of various
types have been devised, which can be opened by
a “ messenger ” sent down the line when the net has
reached the desired depth, and closed again by
another “ messenger ” before it is hauled in.

A simple method that has proved very successful
18

274

THE LIFE OF CRUSTACEA

for collecting small Crustacea living on a sandy
bottom in shallow water is to employ a light tow-net
with a cane ring, and with a heavy sinker attached
to the towing line at a distance of a few feet in
front of the net. As the sinker is dragged along
the bottom, the net floats up behind it, and catches
small animals stirred up by its passage.

For collecting the smaller fresh-water Crustacea —
Water-fleas and the like — a small muslin ring-net
may be used in ponds and ditches. The plankton
of the open water of lakes is best obtained by means
of a tow-net like that described above for use in
the sea.

The interesting blind species known as “Well
Shrimps ” are to be looked for in the water of springs
and wells. In wells fitted with a pump, Professor
Chilton found that “the Crustacea are often brought
up most abundantly when pumping is first com-
menced, and that jerking the handle of the pump
somewhat violently is often more successful than
pumping at the ordinary rate.” In disused open
wells, they may be trapped by baiting a muslin
ring-net with a piece of stale meat or fish, and
pulling it up rapidly after it has remained in the
well for a few hours. The subterranean waters of
caves have yielded many curious species in various
parts of the world. For the capture of species
living in the deep water of large lakes, a special
form of dredge has been devised with runners to
prevent it from sinking into the soft mud, while
the mouth of the net is raised a few inches above
the bottom.

COLLECTING AND PRESERVING 275

For preserving Crustacea the best medium to use
is 70 per cent, alcohol. Strong spirit diluted with
a little less than one-third its bulk of water gives
about the required strength. If too strong spirit
is used, the specimens tend to be hard and brittle,
and delicate organisms become shrivelled. Methy-
lated spirit as sold in the shops in this country
contains mineral naphtha, and turns milky when
water is added, so that it is unsuitable for preserving
specimens. Methylated alcohol without naphtha
can be bought, by permission of the Inland Revenue
authorities, but only in considerable quantities at a
time.

Formalin is very cheap and readily obtained, but
it is much less suitable than spirit for most Crustacea,
as it tends to make them stiff and fragile, and small
forms containing much lime, such as Cumacea, may
become decalcified. For Crustacea collected by the
tow-net, however, formalin gives good results. A
few drops of strong formalin, added to the water
into which the tow-net has been washed, kills the
animals in a few minutes. After they have sunk
to the bottom, the liquid may be poured off and
replaced by formalin diluted with sea-water (for
marine plankton), or by a mixture of formalin and
spirit. The most suitable strength of formalin varies
with different organisms, but 5 per cent, (i.e., 1 part
of commercial formalin to 19 parts of water) is
perhaps most generally useful.

Crabs, Prawns, and the like, if put alive into
strong spirit, may throw off some of their limbs,

276

THE LIFE OF CRUSTACEA

or else become so rigid that these break on the
slightest manipulation. This may often be avoided
by killing the animals in weak spirit (30 per cent, or
less) before preserving in strong spirit. Marine
species may also be killed by placing them in fresh
water, care being taken not to allow them to remain
in it longer than is necessary, as it causes distortion
of the membranous appendages.

The larger Crabs, Lobsters, and the like, may be
preserved dry, although in this state they are
unsuitable for examination of the more delicate
appendages. The carapace should be detached, and
the soft parts cleaned away as far as possible, a
bent wire being used, if necessary, to remove the
flesh from the legs. The specimens should be dried
in the shade, to preserve as much as possible of the
natural colour.

With specimens intended for permanent preserva-
tion in spirit, the use of corks should be avoided, as
they discolour the spirit, and ultimately the speci-
mens. Small specimens are most conveniently kept
in glass tubes closed with a piece of clean elder-pith
(not cotton-wool), and placed, upside down, in a
bottle of spirit. Labels to be placed inside the
tubes are best written with Indian ink, and allowed
to dry before immersion in the spirit.

NOTES ON BOOKS

2 77

II. NOTES ON BOOKS

The literature of Carcinology is bewildering in its
extent, and is for the most part scattered through
the volumes of scientific periodicals and the publica-
tions of learned societies in most of the languages of
Europe. A guide to the current literature is pro-
vided by the Zoological Record , the latest volume
of which, relating to the year 1909, enumerates no
fewer than 337 papers dealing wholly or in part with
this group of animals.

The following short list of books in the English
language may be of some help to the beginner.
Most of them give references to the literature which
will provide the necessary guidance towards a further
study of the subject.

General Works

Huxley , T. H. The Crayfish : an Introduction to the Study of
Zoology. International Science Series, vol. xxviii. London,
1880.

Stebbing , T. R. R. A History of Crustacea : Recent Mala-
costraca. International Science Series, vol. Ixxiv. London*
1893.

Caiman , W. T. Crustacea. A Treatise on Zoology, edited by
Sir Ray Lankester. Part vii., fascicle iii. London, 1909.

Smith , G., and Weldon, W. F. R. Crustacea. The Cambridge
Natural History, vol. iv. London, 1909.

Lister, J. J. Crustacea, in “A Student’s Textbook of Zoology,”
by Adam Sedgwick. Vol. iii. London, 1909.

278

THE LIFE OF CRUSTACEA

British Crustacea

Baird, W. The Natural History of the British Entomostraca.
(Ray Society.) London, 1850.

Bell , T. A History of the British Stalk-eyed Crustacea,
London, 1853.

Spence Bate , C., and Westwood, J. O. A History of the British
Sessile-eyed Crustacea. 2 vols. London, 1863 and 1868.

Brady , G. S. A Monograph of the Free and Semiparasitic
Copepoda of the British Islands. (Ray Society.) 3 vols.
London, 1878-1880.

These works, although still valuable, and indeed
indispensable, are now more or less out of date. A
list of British Malacostraca (except Amphipoda)
will be found in Mr. Stebbing’s volume mentioned
above.

Sars, G. O. An Account of the Crustacea of Norway. Vol. i.,
Amphipoda, 1890-1895. Vol. ii., Isopoda, 1896-1899.
Vol. iii., Cumacea, 1899-1900. Vols. iv. and v., Copepoda,
1903 (in progress). Christiania and Bergen.

A very large proportion of the British species in
the groups mentioned are described and figured in
this splendid series of volumes. The text is in
English.

Norman, A. M., and Scott, T. The Crustacea of Devon and
Cornwall. London, 1906.

Webb , W. M ., and Sillem , C. The British Woodlice. London,
1906.

Memoirs of the Liverpool Marine Biology Committee, edited
by Professor W. A . Herdman. A useful series of mono-

NOTES ON BOOKS

279

graphs on the structure and life-history of common British
marine animals and plants. The following relate to
Crustacea :

Memoir VI. Lepeophtheirus and Lernsea (Parasitic Copepoda).
By A. Scott. 1901.

Memoir XII. Gammarus (Amphipod). By M . Cussans.
1904-

Memoir XIV. Ligia (Isopod). By C. G. Hewitt. 1907.
Memoir XVI. Cancer (Edible Crab). By J. Pearson.

1908.

Descriptions of all the British species of Barnacles will be found
in Darwin's “ Monograph of the Sub-class Cirripedia.’’
(Ray Society.) 2 vols. London, 1851-1854.

INDEX

Abdomen of Lobster, 6
Abyssal fauna of lakes, 185
Acanthephyridae, 268
Acorn-shells, 41
JEga : in Sponges, 210; para-
sitic on fish, 219
AEger, 267
AEglea , 181

Air-breathing Crabs, 188
Albunea, 102

Alcock, A. : on habits of Ocy-
pode , 105 ; on temperature
of sea, 120; on eyes of deep-
sea Crustacea, 124; on colour
in deep-sea Crustacea, 127 ;
on luminosity of deep-sea
Crustacea, 125, 126; on eggs
of deep-sea Prawn, 130; on
Nephrops , 132; on habits of
Ccenobtta, 194, 195
Allen, E. J., on Mackerel
fishery, 251
Alpheidae, 21 1
American Lobster, 32
Amphibious Crustacea, 104,
188

Amphipoda, 52 ; seashore, 95,
107 ; plankton, 145 ; terres-
trial, 189; fresh -water, 172;
in Sponges, 210; on Jelly-
fishes, 212; and Hermit
Crabs, 215; parasitic, 223;
wood-boring, 255
Amphithoe, 95

Anaspides, structure and fossil
allies, 264

Andrews, C. W. : on Land
Crabs, 190 ; on habits of

Ccenobita, 195 ; on habits of
Birgus, 197, 198
Anomalocera, 150
Anomura, 60 ; fresh-water, 181
Anostraca, 36 ; habits, 162, 164
Antennae of Lobster, 8, 14 ;
use in respiration in Corystes,
100 ; in Albunea , 102
Antennule of Lobster, 8, 14
Ants, Woodlice living with,
205

Apseudes, 50

Apus, 36 ; habitats, 161 ; oc-
currence in Britain, 162;
habits, 163 ; haemoglobin in,
165 ; fossil allies of, 260
Appendages of Lobster, 8 ; of
Trilobites, 259
Aratus , 189
Argulus, 41

Aristotle on Shrimp living
with Mollusc, 218
Armadillidium, 203
Artemia : larvae of, 81 ; habi-
tat, 164

Arthropoda, 2 ; classification,
204

Asellus, 172 ; destroying fish-
ing nets, 253
Astacidae, 176
AstacoideSy 178

Astacopsis, 177 ; used for food,
243

Astacura, 60

Astacus : habits, 174 ; young,
76; distribution, 177; used
for food, 241

Asymmetry of Lobster, 29

INDEX

281

Atyidse, 179 ; used for food,
248

Autotomy, 113; in Lobster, 30

Baikal, Lake, 182
Balanus, 42 ; larvae, 83 ; habits,
1 14; used for food, 237 ; cul-
tivated for manure, 250
Barnacles, 41 ; development,
83; seashore, 114; of high
seas, 155 ; on Whales,
Turtles, and Crabs, 209 ;
parasitic, on fish, 235 ; used
for food, 237 ; cultivated for
manure, 250 ; fossil, 261
Bathynomus , 13 1
Beach-fleas, 107
Bell, T., on development of
Land Crabs, 193
“Berry,” Lobster in, 28
Bipolarity, 132

Btrgus, 94; habits and struc-
ture, 195 ; breeding habits,
199. See also Robber Crab
Bloodvessels of Lobster, 17
Blue Crab, 249
Bopyroides, 221
Bopyrus , 221

Borradaile, L. A. : on habits of
Remipes, 102 ; on Huenia ,
no; on larvae of Robber
Crab, 199

Bouvier, E. L on Dromiacea,
134

Brachygnatha, 63
Brachyrhyncha, 64 ; fossil, 270
Brachyura, 62 ; fossil, 269
Brain of Lobster, 20
Branchiopoda, 35 ; larvae, 80 ;

habitats, 16 1 ; fossil, 260
Branchiostegite, 18
Branchipus , 165
Branchiura, 41

Brine Shrimp, 164; larvae, 81
Brood-pouch of Peracarida, 46
Brown Shrimp, 244
Browne, F. Balfour, on Apus
in Scotland, 162
Browne, Patrick, on Mountain
Crab, 193

Bullen, G. E., on food of
Mackerel, 251
Bythotrephes, 168

Caligidae, 225
Caligus , 225
Callianassa, 103
Callinedes , 249
Calocalanus, 149
Cambaroides , 177
Cambarus : distribution, 177;
habits, 178; blind species,
185 ; used for food, 243
Cancer : used for food, 248 ;
fossil, 270. See also Edible
Crab

Cancrinus , 269

Canthocamptus, 170 ; resting
stage, 17 1
Caprella , 54

Caprellidae, 55 ; habits, 109
Carapace of Lobster, 6, 9
Carcinus : larval stages, 68 ;
habits, 107. See also Shore
Crab

Car disoma , 19 1

Caridea, 59 ; zoea of, 73 ; fossil,
268

Caridina, 248
Carp-lice, 41
Caspian Sea, 182
Caudal fork, 40
Cephalothorax of Lobster, 8
Ceratiocaris , 262
Chalimus , 225
Chela of Lobster, 12
Cheliped of Lobster, 8
Chelonobia , 155, 209
Chelura, 255
Cheraps , 177

Chilton, C., on Woodlice in
New Zealand, 206
Chirocephalus, 35, 16 1
Chitin, 15

Chondr acanthus, 228
Chromatophores, 31, no
Chun, C., on eyes of plankton
Crustacea, 154
Chydorus, 165
Cirolana, 218

282

THE LIFE OF CRUSTACEA

Cirripedia, 41 ; development,
82 ; on Whales, 209 ; para-
sitic, 231 ; fossil, 261. See
also Barnacles

Cladocera, 37 ; development,
80 ; habits, 165 ; in plankton
of lakes, 168 ; absence from
Tanganyika, 184
Claspers of Chirocephalus , 3 5
Classification of Crustacea,
table, 34 ; of Decapoda,
table, 58

Close time for Lobsters, 239
Coconut Crab. See Robber
Crab

Cocoons of Copepoda, 17 1
Coe?iobita : habits, 194; respira-
tion, 195

Coenobitidae, 61 ; habits, 194
Colour of Lobster, 31 ; deep-
sea Crustacea, 127 ; plank-
ton Crustacea, 150; Bran-
chiopoda, 165 ; subterranean
Crustacea, 187
Colour-change, no
Columbus and Gulf - weed
Crab, 155

Commensalism, 207
Conchoderma , 209
Conchcecia, 144

Conchostraca, 37; habits, 163
Convergent evolution, 205
Copepoda, 40 ; development,
82 ; of open sea, 140 ; plank-
ton, 149 ; luminosity, 150 ;
eyes, 152 ; of fresh water,
170; of Tanganyika, 184;
and Hermit Crabs, 215;
parasitic, 224; as food of
Mackerel, 250
Copilia, 152
Coral of Lobster, 27
Corals, Crustacea on, 210
Coronula, 155, 209
Corycaeidse, 152
Corystes, 99

Crabs : true, 62 ; sand-burrow-
ing, 99; of fresh water, 179;
of Tanganyika, 183 ; on
Corals, 21 1 ; carrying Sea-

anemones, 215 ; living with
Molluscs, 217 ; living in
Sea-urchin, 218 ; Isopods
parasitic on, 223 ; Rhizo-
cephala parasitic on, 231 ;
used for food, 248 ; fossil,
269. See also Shore Crab,
Edible Crab, etc.

Crangon, 59; habits, 97; fish-
ery, 244

Crawfish, Sea-, 59
Crayfish: young of, 76; habits,
174; distribution, 176; ter-
restrial, 178, 189; blind, in
caves, 185; in British Isles,
241 ; used for food, 241 ;
disease of, 243

Cumacea, 48 ; habits, 98 ; of
deep sea, 129; of plankton,
141

Cunningham, J. T., on de-
velopment of Land Crabs,
192

Cup Shrimps, 245
Cyamidse, 56; habits, 224
Cyclops , 40 ; nauplius, 82 ;
habits, 170 ; resting stage,
171 ; as host of Guinea-
worm, 252
Cymothoa, 220
Cymothoidse, habits, 218
Cymothoinae, habits, 220
Cypris, 38; reproduction, 172
Cypris stage of Barnacles, 84 ;

of Saccidina , 233
Cystisoma, 145
Cythereis, 38

Daphnia, 38; developmental;
habits, 165; in plankton of
lakes, 168

Darwin, C. : on fresh - water
fauna, 157, 159; on habits of
Birgus, 198, 199; on Bar-
nacles used for food, 237
Decapoda, 57 ; fossil, 267
Deep-water Prawn, 246
Delage, Y., on development of
Sacculina, 232

Development of Lobster, 28;

INDEX

283

of Crayfish, 77 ; of River
Crab, 78 ; of Peracarida, 78 ;
ofWoodlice, 79; of Opossum
Shrimp, 79; of Cladocera,
80; of Ostracoda, 81 ; of Cope-
poda, 82 ; of fresh - water
Crustacea, 160; of Epicar-
idea, 223 ; of parasitic Cope-
poda, 225, 227, 230 ; of

Rhizocephala, 232
Diaptomus, 170
Diastylis, 49

Diatoms, 139 ; relation to
Mackerel fishery, 251
Dichelaspis, 209
Digestive gland, 17
Dispersal of fresh-water Crus-
tacea, 159; of Crayfishes, 174
Distribution ofWoodlice, 206
Doflein, P., on luminosity in
marine animals, 126
Dogfish, Barnacle parasitic on,
235

Dorippe , 95
Dracunculus , 252
Dromia , 63; habits, 96; and
Sponge, 215

Dromiacea, 63; of deep sea,
128, 134

Dublin Prawn, 33 ; fishery, 240

Ebalia , 63; protective resem-
, blance, 109
Ecrevisse, 242
Edelkrebs, 242
Edible Crab, 64, 248
Eggs of Lobster, 27 ; of deep-
sea Crustacea, 130 ; of fresh-
water Branchiopoda, 161
Endopodite, 11

Eng<zus : distribution, 177 ;

habits, 179, 189
Entoniscidse, 223
Ephippium of Cladocera, 167
Epicaridea, habits, 221
Epiplankton, 143
Epipodite, 11
Epistome, 62

Erichthus larva, fossil, 266
Eryon, 135

Eryonidea, 60; eye-stalks of,
122; luminosity, 126; eggs
of, 131 ; fossil and living
species, 133, 268
Estheria, 36; habitats, 16 1
Eucarida, 56
Eucopepoda, 41
Eumalacostraca, 45
Eupagurus , 91 ; commensals,
213

Euphausiacea, 56; larvae, 76;
of deep sea, 124, 125 ; lumin-
ous organs, 125, 15 1 ; eyes,
153; fossil, 263
European Lobster, 32
Eurydice , 219
Evolution, 256
Excretory organs, 19
Exopodite, 10
Exoskeleton, 15
Eyes of Lobster, 20; of Cyclops ,
40; of deep-sea Crustacea,
121 ; of plankton Crustacea,
151 ; of Bythotrephes , 169;
degeneration in subter-
ranean Crustacea, 186
Eye-stalk of Lobster, 14

Fairy Shrimp, 35 ; habitats,
161

Filaria , 252

Fiddler Crab : habits, 106 ;

colour-change, 111
Fish : attacked by Isopods,
219; Crustacea as food of,
250

Fish-lice, 224
Flagellum, 14
Foraminifera, 118
Fossil Crustacea, 256

Galathea, 130
Galatheidea, 60
Galls on Corals, 21 1
Gamble, F. W., on colour-
changes, in

Gammaridea, eyes of, 154
Gammarus , 53 ; distribution,
172 ; in Lake Baikal, 183
Ganglia of Lobster, 20

284

THE LIFE OF CRUSTACEA

Garstang, W., on habits of
Masked Crab, 100
Gastric Mill of Lobster, 17
Geographical distribution of
Lobsters, 32; of Crayfishes,
174

Gecarcinidae, 190
Gecarcinus , 190 ; supposed me-
tamorphosis, 192
Gecar coidea, 190
Gelasimus, 188; habits, 106;

colour-changes, hi
Generative organs of Lobster,
27

Giant Crab, 64

Giesbrecht on luminosity of
Copepoda, 150
Gill chamber of Lobster, 18
Gills of Lobster, 12, 18; of
Mysidacea, 48
Globigerina ooze, 119
Glotneris, a Millipede, 3, 203
Glvphaeidae, 268
Gnathobases of Trilobites,
259

Gnathophausia , 48
Goose Barnacle, 42
Gosse, P. H., on Porcelain
Crabs, 115
Grapsidae, 180
Grapsus , 107
Green gland. 19
Gribble, 253

Guilding, L-, on development
of Land Crabs, 193
Guinea-worm, 252
Gulf -weed Crab, 155 ; on
Turtles, 208

Habitations of shore Crus-
tacea, 95
Hcemocera, 229

Haemoglobin in Branchiopoda,

165

Hairs of Lobster, 22
Hall. See Spencer and Hall
Halocypridae, 141, 144; lumin-
osity, 15 1

Hapalocarcinus , 21 1
Head of Lobster, 7

Hearing, sense of, in Lobster,
22

Heart of Lobster, 17
Hermaphroditism of Cirri -
pedia, 43 ; in Isopoda, 52 ;
of Cymothoinae, 221 ; of
Epicaridea, 223; of Rhizo-
cephala, 231

Hermit Crabs, 61 ; of seashore,
91; of deep sea, 124, 136;
terrestrial, 194; commensals,
213 ; Isopods parasitic on,
221

Heterocarpus , 125
Hickson, S. J.,on Caridina , 248
Hippa, 102

Hippidea, 62; habits, 102
Hippolyte, colour-changes, 111
Holopedmm, 170
Homaridae, 33
Homarus, 32 ; fishery, 238
Homolodromiidae, 134 ; fossil
allies, 269

Homologous organs, 10
Hoplocarida, 64
Huenia , 109

Huxley, T. H. : on Barnacles,
1 15 ; on distribution of Cray-
fishes, 176

Hyas , masking habits, 96
Hyperia, 142; on Jellyfishes,
212

Hyperiidea, 141 ; eyes, 154
Hypoplankton, 143
Hypostome, 259

Inachus infected with Saccu-
lina , 235

Intestine of Lobster, 16
Isopoda, 51 ; deep-sea, 131 ;
fresh - water, 172 ; subter-
ranean, 186; land, 199; in
Sponges, 210 ; parasitic, 218 ;
wood-boring, 253 ; fossil, 266

Jasus, 241

Jellyfishes, Amphipods on, 212

Keeble, F., on colour-changes,
hi

INDEX 285

Kidney, 19
Koo?iunga, 264

Land Crabs, 189 ; injuring
crops, 253

Land Hermit Crabs, 194
Land-hoppers, 189
Langouste, 241

Lankester, E. Ray, on haemo-
globin in Branchiopoda, 165
Larvae of Lobster, 28; of Nor-
way Lobster, 71 ; of Stomato-
oda, 80; of Brine Shrimp,
1 ; of Land Crabs, 191 ; of
Robber Crab, 199; fossil, of
Stomatopoda, 266
Larval stages, 66 ; significance
of, 85

Latreillia , 128

Leach, W. E-, on the Gribble,
y 254

Leander, 59, 179; Isopod para-
sitic on, 221 ; used for food,
245

Legs of Lobster, 8, 12
Lepas, 42 ; habitat, 155 ; nau-
plius, 148
Lepeophthirus , 225
Leptodora , 169
Leptostraca, 45
Lerncea, 226
Leucosiidae, 109
Ligia, structure and habits,
200

Limnoria, 254
Linuparus , 269
Lithodes, 62, 94
Lithodidae, 61
Liver of Lobster, 17
Lobsters: deep-sea, 121 ; fish-
ery, 238

Loven, S., on relict Crustacea,
181

Luminosity of deep-sea Crus-
tacea, 125; of plankton Crus-
tacea, 150
Lynceidae, 165

Mackerel feeding on plankton,
250

Macropodia, masking habits,
97

Maia , masking habits, 96
Malacostraca, 43 ; fossil, 261
Mammoth Cave, Crayfish of,

185

Mandible of Lobster, 8, 14
Masked Crab, 99
Masking of Crabs, 96, 215
Maxilla of Lobster, 8; of Ar-
gulus, 41

Maxillipeds of Lobster, 8, 11
Maxillula of Lobster, 8
Medusae, Amphipods on, 212
Megalopa of Shore Crab, 70
Meganyctiphanes, 56, 15 1
Melia, 215
Mesidotea , 18 1
Mesoplankton, 143
Messmates, 208
Metamorphosis of Lobster, 28 ;

of Land Crabs, 7 91
Metanauplius of Penceus , 75
Mimicry, 204
Mimonectes , 145
Mitsukuri, K., on cultivation
of Barnacles, 250
Mole Crabs, 102
Monstrillidae, 230
Moulting of Lobster, 15 ; of
Woodlice, 206

Mountain Shrimps, 181; struc-
ture and fossil allies, 264
Mouth-frame of Crabs, 62
Muller, Fritz : on larval stages
of Penceus, 73 ; on habits of
A rains, 189

Muller, O. F., on Nauplius,
82

Munida, larva of, 71
Munidopsis : eyes, 123; eggs,

130 1

Murray River Lobster, 243
Mussels and Pea Crab, 217
Myodocopa, 39

Mysidacea, 46; development,
79; luminosity, 127; eyes,
153 ; and Hermit Crabs, 215 ;
fossil, 263

My sis, 47 ; in lakes, 181, 182

286

THE LIFE OF CRUSTACEA

Natan tia, 58; used for food,

243

Nauplius of PencEus, 73; of
Crayfish, 79; of Opossum
Shrimp, 79 ; of Branchio-
poda, 80; of Cyclops , 82 ; of
Ostracoda, 82 ; of Barnacles,
83 ; of Lepas, 148; of Lepto-
dora, 170; of Sacculina, 233;
eye, 40

Nebalia , 44 ; fossil allies, 261
Nebaliacea, 44
Necton, 138
Nematocarcinidae, 128
Nephrops, 33; larva, 71; dis-
tribution, 132 ; fishery, 240
Nephropsidea, 33, 60
Nephropsis , 121
Neptunus , 156 ; used for food,
249

Neritic plankton, 141
Nervous system of Lobster,

20

Niphargus, 184
Northern Crayfishes, 176
Norway Lobster, 33 ; larva,
71 ; fishery, 240
Norwegian Prawn, 246
Notostraca, 36 ; habits, 162

Oceanic plankton, 14 1
Octopus preying on Crustacea,
89

Ocypode , 188; habits, 104; car-
nivorous, 195

Olfactory filaments of Lobster,

25

Oniscus, 51 ; structure and
habits, 201
Operculata, 43

Opossum Shrimps, 46 ; de-
velopment of, 79
Orchestia, 107
Orientation, organs of, 24
Ostracoda, 38 ; development,
81; luminosity, 127, 15 1 ;

plankton, 144; fresh-water,
172; of Tanganyika, 184;
fossil, 261

Ovar3r of Lobster, 27

Oxyrhyncha, 64 ; masking
habits, 96; fossil, 270
Oxystomata, 63 ; habits, 101 ;
protective resemblance, 109 ;
deep-sea, 128; fossil, 269
Oxyuropoda, 266
Oyster Crab, 249
Oysters and Pea Crab, 217

Paguridea, 61

Paguropsis and Sea-anemones,
214

Palczmon, 1 79 ; used for food,
248

Pcilccmonetes, 174
Palinura, 59

Palinuridae, 241 ; fossil, 269
Palinurus, larva of, 72; fishery,
240

Palp, 14

Pandalus , 59, 1 37 ; used for
food, 245
Panulirus , 241
Paracyamus , 55
Paranaspides, 264
Paranephrops , 177
Parapagurus, 124; and Sea-
anemones, 213
Parasitism, 208
Parastacidae, 176
Parastacus, 178
Partan, 248

Parthenogenesis, 163 ; of Cla-
docera, 166 ; of Ostracoda, 172
Pea Crab, 217
Pedunculata, 43
Peltogaster, 232
Penaeidea, 59; fossil, 267
Penceus , 59 ; larvae, 73 ; used
for food, 247 ; fossil, 268
Peracarida, 46 ; development,
78

Pericardium, 17
Peripatus , tracheae of, 204
Peter’s stone, 220
Philomedes , 38

Phosphorescence. See Lumin-
osity

Photophores of Euphausiacea,

125

INDEX

287

Phreatoicidea, 173
Phronima , 154
Phronimidae, eyes of, 154
Phtisica , 54
Phyllocarida, 261
Phyllosotna, 149 ; of Spiny Lob-
ster, 72

Phylogeny, 205, 256
Pill Millipede, 203
Pink Shrimp, 137, 245
Pinnaxodes, 218
Pinnotheres , 217 ; used for

food, 249
Planes , 155

Plankton, 139 ; of fresh water,
160; of lakes, 168,170; rela-
tion to fisheries, 250
Platyarthrns , 205
Platycuma , 129
Platymaia , 130
Platytelphusa, 184
Pleuron, 9
Podocopa, 39
Podocrates, 269

Pollicipes used for food, 237 ;

fossil, 261
Polycheles , 133
Pontonia, 218
Pontoporeia , 181
Porcelain Crab : zoea of, 70;
autotomy, 114 ; feeding, 115 ;
and Hermit Crabs, 215
Porcellana : zoea of, 70; au-
totomy, 1 14; feeding, 116
Porcellanidse, 60
Porcellio , 51 ; structure and
habits, 202 ; distribution,
206

Portunidae : swimming, 90 ;
sand-burrowing, 99 ; used
for food, 249
Potamobiidae, 176
Potamobius, 174
Potamon, 180 ; young of, 78
Prceanaspides, 265
Prawns, 58 ; luminosity of,
127 ; of deep sea, 136 ; of
fresh water, 174, 179; of
Tanganyika, 183 ; blind, in
caves, 185 ; in Sponges, 210 ;

Isopods parasitic on, 221 ;
Common, 245 ; used for food,
245 ; deep-water, 247 ; fossil,
268

Prosoponidae, 135, 269
Protandrous hermaphrodit-
ism, 221

Protective resemblance, 108
Proto car cinus, 269
Protocaris, 260
Protopodite, 10
Protozoea of Penceus, 75
Psathyrocaris, 130
Pseudothelphusa , 193
Pseudo-tracheae, 202
Pygidium, 259
Pygocephalus, 263
Pylocheles, 94

Pylochelidae of deep sea, 136

Recapitulation, theory of, 86
Red- clawed Crayfish, 242
Regeneration in Lobster, 30
Relict faunas, 182
Remipes, 102

Reproduction of Cladocera,
166; of Leptodora, 169; of
Cymothoinae, 220
Reptantia, 59

Respiration in sand-burrowing
Crabs, 99 ; in amphibious
Crabs, 106 ; in Land Crabs,
193 ; in Coenobita , 195 ; in
Birgus , 196; in Land Iso-
pods, 201, 202, 203
Resting eggs of Cladocera,
166 ; of Copepoda, 170
Resting stage of Copepoda,
171

Reversal of asymmetry in
Lobster, 30

Rhizocephala, 43 ; larvae, 84 ;
structure and development,
231

River Crabs: young of, 78;
habits and distribution, 180 ;
development of, 193
River Prawns, 179 ; used for
food, 248

Robber Crab, 61, 94; habits

288

THE LIFE OF CRUSTACEA

and structure, 195 ; breed-
ing, 199

Robertson, David, on habits
of Crabs, 97

Rock Lobster. See Spiny
Lobster

Rostrum of Lobster, 6
Sacculina, 23 1

Salt lakes, Branchiopoda of,

165

Sand-burrowing Crustacea, 97
Sand-hoppers, 52 ; habits, 107,
189

Sapphirina, 150
Sargasso Sea, 155
Scampo, 240
Scapellum , fossil, 261
Scaphognathite, 19
Schizopod stage of Lobster,
7 1 ; of Penccus , 75
Scylla, 249

Scyllaridae, fossil, 269
Scyllaridea, 59; Phyllosoma
larvae, 149 ; fossil, 268
Scyilarus, fossil, 269
Sea-slater, 200

Sea-anemones : and Hermit
Crabs, 213 ; carried by Crab,

215

Sea-crawfish. See Spiny Lob-
ster

Sea-urchin, Crab living in,
218

Sedentary Crustacea, 114
Self-mutilation in Lobster, 30
Senses of Lobster, 25
Sergestes , zoea of, 75, 148
Serial homology, 10
Sesarma , habits, 180, 189
Sessile Barnacles, 43
Sexes of Lobster, 26
Sexual characters of Crabs
infected with Sacculina , 235
Sharks, Barnacle parasitic on,
235

Shore Crab, 64 ; larval stages,
68; habits, 107, 188; in-
fested by Sacculina , 231 ;
used for food, 249

Shrimps, 58; fresh-water, 53,
172 ; Common, habits of, 97 ;
protective resemblance, 108;
living with Mollusc, 218 ;
fishery, 244. See also Brown
Shrimp, Pink Shrimp, etc.
Sight, sense of, in Lobster, 21
Skeleton Shrimps, 109
Slaters, 51 ; Sea-, 200
Sloane, H., on Gulf- weed
Crab, 155

Smell, sense of, in Lobster, 24
Smith, G. : on terrestrial Am-
phipoda, 189; on develop-
ment of Sacculina , 233
Smith, S. I., on habits of Ocy-
pode , 105

| Somites of Lobster. 6, 8
1 Southern Crayfishes, 176
Spencer and Hall on Aus-
tralian Branchiopoda, 161,
163

: Sperm-receptacle of Lobster,
j 27

Spider Crabs, 64 ; masking
habits, 96, 215 ; deep-sea, 128
Spiny Lobster, 59; larva of,

. 72; fishery, 240

I Spirontocaris , Isopod parasitic
on, 221

| Sponge Crab, 95
Sponges, Crustacea in, 210
Spongicola , 210

Squilla, 64 ; larva of, 80 ; fossil,
j 266

Stalked Barnacles, 43
Statocyst of Lobster, 24; of
Mysidacea, 47
Statolith, 47

Stebbing, T. R. R. : on Land
Crabs, 190 ; on habits of
Cirolana , 219
Steinkrebs, 242
Stenopidea. 59 ; fossil, 267
Stenorhynchus, 97
Sternum, 9

Stevenson, R., on the Gribble,
254

Stomach of Lobster, 16
Stone Crab, 61, 94

INDEX

289

Stomatopoda,®:64 ; larvae, 80 ;

liabits, 104; fossil, 266
Stridulating organ of Ocypode,

105

Subterranean Crustacea, 184
Swimmerets of Lobster, 6, 10
Swimming Crabs, 90; sand-
burrowing, 99 ; used for
food, 249
Symbiosis, 207

Syncarida, 45, 181 ; fossil, 264

Tail- fan of Lobster, 6
Talitridse, 107

Talitrus: habits, 107; terres-
trial species, 189
Tanaidacea, 50

Tanganyika, Lake, Crustacea
of, 183

Taste, sense of, in Lobster, 25
Telphusa , 180
Telson of Lobster, 6
Tergum, 8
Testis of Lobster, 27
Thalassmidea, 61 ; liabits, 103
Fhaumastocheles , 130, 132
Thompson, J. Vaughan: dis-
covery of metamorphoses of
Crustacea, 67 ; on larvae of
Cirripedia, 83 ; on develop-
ment of Sacculina , 232
Thoracica, 43
Thorax of Lobster 7
Thread-worms, 252
Touch, sense of, in Lobster, 22
Tracheae, 204
Tracheae, pseudo-, 202
Trapeziidae, 21 1
Triarthrus, 258

Trilobites, structure and his-
tory, 258

Tubicinella , 209
Turrilepas , 261

Turtles: Barnacles on, 209;
Gulf-weed Crab on, 209

Underground Crustacea, 184
Uropods of Lobster, 6

Venus’s Flower-basket, Crus-
tacea in, 210

Water-fleas, 37, 165
Weismann on parthenogene-
sis of Cypris , 172
Well Shrimp, 184
Westwood, J. O., on develop-
ment of Land Crabs, 192
Whales, Barnacles on, 209
Whale-food, 138
Whale-lice, 56 ; habits, 224
White-clawed Crayfish, 242
Willey, A., on breeding of
Robber Crab, 199
Williamson, H. C., on habits
of Lobster, 25

Wood-boring Crustacea, 253
Woodlice, 51 ; development
of, 79 ; habits and structure,
199 ; distribution of, 206 ;
destructive in gardens,
253

Worms: and Hermit Crabs,
215; Copepoda parasitic in,
230

Zoea of Shore Crab, 69; of
Caridea, 73 ; of Porcelain
Crab, 70; of Munido , 71 ; of
Penceus , 75 ; of Sergestes,
75, 148 ; of Robber Crab,
199

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Fiction

23

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CASTING OF NETS. Twelfth Edition.
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MRS. CURGENVEN OF CURGENVEN.
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24 Methuen and Company Limited

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25

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Fiction 27

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Fiction

3i

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GILES INGILBY.

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I CROWN THEE KING.

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GEORGE and THE GENERAL.

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A MARRIAGE AT SEA.

MY DANISH SWEETHEART.

HIS ISLAND PRINCESS.

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BALBARA’S MONEY.

THE YELLOW DIAMOND.

THE LOVE THAT OVERCAME.

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MR. SPONGE’S SPORTING TOUR.

ASK MAMMA.

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COUSINS.

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THE FAIR GOD.

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♦CAPTAIN FORTUNE.

Weekes (A. B.). PRISONERS OF WAR.

Wells (H. G.). THE SEA LADY.

White (Percy). A PASSIONATE PIL-
GRIM.

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