THE FIRE BLIGHT DISEASE IN NURSERY STOCK

A THESIS

PRESENTED TO THE FACULTY OF THE GRADUATE SCHOOL

OF CORNELL UNIVERSITY FOR THE DEGREE OF

DOCTOR OF PHILOSOPHY

BY

VERN BONHAM STEWART

[Reprint of Cornell Agricultural Experiment Station Bulletin 329, April, 1913]

+o SR
CONTENTS

PAGE
BHOSG PEAS act cde ba ots + Ss vee « Szee eens ee eine ee ck ea 0 aia eat 317
Species ahd varieties affected ..... 2.) \.gesu. oe hj Oe aoe ee eee 317
Economic importance of the nursery industry. - <7): 9. <7.) 0.25.7 oc eee 317
PAE GISCASE 5 isccy f 5's sa a > ole sc nine ees bi eebaeete ee eens Ce be et 318
BRPSEOLY cis )S coin ca, 2s phen wise ole Gtetthe mun OP NNR ee He eee Sete wie ete nen 318
INDIES so.) LS. 5A gS Sale eeiane cctheen so ee tetar oa, ee 318
Occurrences...) 00. PE re Bae erh o clane ecg 318
Iptdenaies . a0). 22..:. 06. Poe pie ee» ee 319
Theories as to ‘cause. |... 55). 5% vs wee ae tues lel cde ike eek head 319
Geographical distribution... o f.2..08 Se one ws dete ss as eae 321
Beenomie importance... 2). occ eee eee ae ins ee ae ee 321
SV MPLOMAS. Ss... 5s oS eee hake bibs BIS ky Aire ORI ee Es i en 321
Blossom ‘blight...... . .. Sos ea die ak Pays a Secs piece 2 eee ee 322
Pivig ‘blight. 72.7. . oF. SR Sin es tare ie sare teens okt ae ane 322
Body ‘blight... . Sia ip ca ieee oie mete tg nce nee ne eae a ae 323
Winter injury versus fire blight...... ES Me aly As OPN 3 ter Se 323
FEtOlG RY os 2) Soils Es. sold, sees ee ele pes eh ek Se ete. Sy ee eer 325
Namie of parasite. 2. 2620.50.07 Pusu nies emia eE oi iete eet ek ee 325
Description of Bacidlus amylworas. 52). 05k, oes eee 326
Tafa mastory. 330.2 Sakic oe oe 5 bike's ere mene cielet pce © ne lea enn 338
The pyle. «7... Gein Rayce thee oe ke Oo eae os ie ene eee 338
Disseminating agents. Pr .y oie tie poss eed nae eee ee eee 339
Disseniination by priuting tools) ssa 1 me oe ene 342
Spécial orchard considerations: 225)... oSin sis: sles oe neers 344
Hold-overblight 37 5 raise Sere wre Gin cares) «oe ae ne 345
Influence of weather,ou-blight). (bane. ok ou se eee eee 346
Cultivation and manuring as affecting fire blight................... Here lrg
Varictal susceptibility yn 2.30 eS Naik, aecyale soos 1c so ake eee 350
Special! inoculatiansexperiments. 2) ie. cs 4. ss tak site oe eee 354
Pathological histology oi) .-<2'y < sre tate ts etio cele «isle hu near ee 356
Gontrole ste. . DNs air ee ee Ee 6 361
Tree teeditig sip... Sg Peikdee b olabede, ote aheoe bob» Tons ovine eigen 362
Sprayne vacant 40 bs SARL iste se otto esate opp iol eee oss kn ee en 362
PatentsmOstruams oc.) oa col. depeieseie cee s eiske ies Soe tie eet ee amen Sie 363
General plan of control........ Nt SHS age Bhs oc: I RR ureoe eae ee eet em Bese pee 363
@Gatrol ininirsery stock. Fac 25,250 Pew -, cap ie ete eee oe 364
Erspettions so... Lg. on eee stele e eer ete et ibe eee 364
Destruction of insect agents. ss; . so ase» some - sce cere ole 368
Bibliograplyeirnrs p25... «WRI Pea a Si is we atin wee erates A ene 368

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THE FIRE BLIGHT DISEASE IN NURSERY STOCK*

V. B. STEWART
HOS? 2EANTS

SPECIES AND VARIETIES AFFECTED

Fire blight is undoubtedly a native disease of the American indigenous
species of Pomeae. It is known to affect the pear, quince, apple, apricot,
plum, species of Cratzegus, Amelanchier canadensis, Pyrus americana, and
a few of the native species of the apple family. Waite (’o7) reports its
occurrence on the evergreen Eriobotrya japonica, and states that this
species is somewhat commonly attacked by the disease in Florida, Georgia,
and California. He has also observed the blight affecting the red-berried
California holly (Heteromeles arbutifolia Roem.) in various parts of Cali-
fornia, where this native species of Pomeae occurs in the vicinity of
cultivated orchards.

The disease is most destructive on the cultivated varieties of the pear
(Pyrus communis), the apple (Pyrus malus), and the quince (Cydonia
vulgaris). Intensive cultivation and artificial propagation have evidently
tended to reduce the resistance to the blight in these plants. As a rule
the pear and the quince suffer most, although the apple is often seriously
injured and may be killed. This is particularly true of nursery stock
and young orchard trees. Plums are seldom affected, but Jones (’o2)
found that the disease occurs on and kills the twigs of the Cheney plum
(Prunus americana nigra). Paddock (’03) reports the same disease
occurring on the fruit and twigs of the apricot. The cherry and the
peach are not known to be attacked.

ECONOMIC IMPORTANCE OF THE NURSERY INDUSTRY

Although the nursery business is a somewhat specialized industry, it
is, nevertheless, of considerable economic importance. The figures re-
cently published in this connection by the Department of Statistics of
the Bureau of the Census (’12) are of special interest. Within recent
years the nursery business of the country has shown a rapid increase.

* Also presented to the Faculty of the Graduate School of Cornell University, January 27, 1913,
as a major thesis in partial fulfillment of the requirements for the degree of Doctor of Philosophy.

AUTHOR’S ACKNOWLEDGMENTS. — The writer’ js: *n@ebted tp Professors H. H. Whetzel and Dona'd
Reddick, under whose immediate direction the work was conducted, for helpful criticisms and sugges-
tions. :

(02) Jones, L. R. Studies on plum blight. Centbl. Bakt. u. Par. 2, 9 : 835-841. 1902.

('03) Paddock, Wendall. An apricot blight. Colorado Agr. Exp. Sta. Bul. 84: 5-14. 1903.

(07) Waite, M. B. A new native host for pear blight. Science n. s. 25 : 286-287. 1907.

(12) Press Notice, Department of Statistics of the Bureau of the Census. June 25, 1912.

317

318 BULLETIN 329

The total value of nursery products reported from 5,582 establishments
in 1909 was $21,051,000; this was an increase of 591 establishments, or
11.8 per cent, and $10,927,000, or 107.9 per cent, in ten years. In 1909
the Middle Atlantic division ranked first, with products valued at
$4,355,000 as compared with $2,523,000 in 1899 —an increase of
$1,832,000, or 72.6 per cent, during the decadefrom 1899 to1909. Although
the number of establishments reporting nursery products was greatest in
the East North Central division, being 1,159, this division ranked fourth
in value of products, being exceeded by the Middle Atlantic, West North
Central, and Pacific divisions. In percentage of increase the Pacific
division ranked first, with 377 per cent; the West South Central division
second, 179.4 per cent; and the South Atlantic division third, 117.4 per
cent.

The three States ranking highest in value of nursery products in 1909
were: New York, $2,751,000; California, $2,213,000; and Texas, $1,253,000.
The standing in 1899 was, New York, Iowa, Illinois. An increase in
value of nursery products was reported from all States except Maine,
Vermont, Virginia, and South Carolina; and also excluding the District
of Columbia. In the State of Washington the value of products in 1909
was almost twenty times as great as that in 1899.

THE DISEASE
HISTORY

Names

The disease has been a theme for incessant discussion by horticulturists
since the earliest days of fruit culture in this country. Various common
names have been applied to the disease, depending to some extent on
the host that is attacked and on the effect produced. Among the names
most frequently used are fire blight, pear blight, blight, blossom blight,
twig blight, fruit blight, sun scald, canker, and blight canker. The term
“fire blight ’’ is preferable, since it applies equally well to the character-
istic symptoms of the malady on any of the different hosts.

Occurrence

Occurring as a disease of the indigenous wild crab-apple and hawthorn
of eastern North America, the blight spread readily to orchards of pome
fruits when the cultivated varieties were introduced into this country.
It was first observed about 1780 in the Hudson River Highlands of New
York State by William Denning (1794), an orchardist of that section.

(1794) Denning, William. On the decay of apple trees. Trans. New York Soc. Prom. Agr. Arts and
Manfr. 12: 219-222. 1794. [Second edition 12: 185-187. 1801.]

tap thet epee Giern-ee~ erate reeieegiiiestes ar

THE Fire Briicut Disease in Nursery Stock 319

Later, with the increase of the orchard industry, the disease became
more prevalent and gradually worked its way westward, as the plantings
followed the settlement of the country beyond the Allegheny Mountains.

Epidemics

It was early maintained that the malady was more or less periodic
in its occurrence, the periods of time being placed at five, ten, or twenty
years. A careful examination of the literature of the subject gives little
support to these views, but indicates that the lapse of time between
epidemics of the disease has been irregular and has often varied for dif-
ferent sections of the country.

The years 1826 and 1832 were notable for increased prevalence of the
malady, and one of the most widespread and destructive epidemics is
recorded by Beecher (1844) as having occurred in 1844. Few orchards
escaped without partial or total loss of many trees and some orchards
were completely ruined. Since that time epidemics have occurred in
different sections of the country, among which might be mentioned the
serious outbreak of the disease about 1860 in Massachusetts and border-
ing States, as recorded by Cooke (1867).

The most important epidemic of recent years was the appearance of
the blight for the first time beyond the Rocky Mountains, reported by
Pierce (’o2) as having occurred in the pear orchards of California in 1902.
In this and the succeeding two years it is reported by Smith (’06) to have
wrought such havoc as has seldom been known.

Theortes as to cause

The disease being so common, various theories were enunciated, natur-
ally, as to the cause, it generally being regarded as resulting from several
factors either acting together or brought about by dissimilar circumstances.

Action of sun.— Coxe (1817) in his horticultural book, which is said
to be the oldest publication on fruit culture in this country, was one of
the first to advance an hypothesis. He ascribed the cause of the disease
to the hot rays of the sun, and admirably characterized the symptoms
of this in the following words: ‘“‘ That species of blight which is some-
times called fire blight, frequently destroys trees in the fullest apparent
vigor and health, in a few hours, turning the leaves suddenly brown as
if they had passed through a hot flame, and causing a morbid matter to
exude from the pores of the bark of a black ferruginous appearance.

(1817) Coxe, William. Cultivation of fruit trees. Pear blight, 175-176. 1817.

(1844) Beecher, H. W. The blight in the pear tree: its cause and a remedy for it. Mag. Hort.
IO: 441-456. 1844

(1867) Cooke, 3 "S. Pear blight. Gardeners Monthly 9 : 73-78. eee

(02) Pierce, Newton B. Pear blight in California. Science n. s. 16 : 93-194. 1902.

CoG) Waite, MM. B., and Smith, R. E. Pear blight. Ann. Rept. California Fuit sows Assoc. 31:
I37-I161. 1906,

320 BULLETIN 329

This happens through the whole course of the warm season, more fre-
quently in weather both hot and moist.” ¢

Insects — The ambrosia beetle, Xvyleborus dispar Fabricius (Scolytus
pyrt Peck), was also believed to be the cause, and among the prominent
supporters of this view was Patrick Barry (1847), a pioneer nurseryman
of New York State.

Frozen sap.— The next hypothesis that attracted general attention was
known as the ‘‘frozen sap theory,” and was first promulgated by Reverend
H. W. Beecher (1844). About this time we find the only mention of
the disease with reference to nursery stock until the publications of more
recent years. Gookins (1846), Ernst (7848), and James (1849) give
brief mention of its occurrence in nursery trees.

Fungus theory.— The fungus theory of the cause of fire blight was
advanced by Dr. J. H. Salisbury (1863), and twelve years later Dr. J. G.
Hunt (1875) thought he confirmed the opinion that it was due to a fungus.

Electricity — Electricity was believed by some investigators to be the
cause of the blight, since diseased trees were often particularly noticeable
after a thunderstorm.

Bacteria.— The last hypothesis of historical importance is the bacteria
theory, advanced by Professor T. J. Burrill (1879), a pioneer pathologist
of this country. In 1878, after the blight had been known for nearly
a century, Professor Burrill distinctly stated that he believed the cause
to be due to bacteria which he found occurring in great abundance in
the tissues of diseased branches. ‘Three years later he reported (1881)
the results of his inoculation experiments, whereby he caused healthy
pear twigs to blight by inoculating them with the juices of diseased ones.

Later, Arthur (1885) confirmed the resultsof Dr. Burrilland extended the
cultural and inoculation experiments. His work proved absolutely that the
malady is caused by bacteria. Since that time there have been a number of
contributions to the knowledge of this disease, among which are to be men-
tioned the work of Waite (1808), Jones (’02), Whetzel (’06), and Jones (’o9).

(x eee Beecher, H.W. The blight in the pear tree: its cause and a remedy for it. Mag. Hort. 10 : 441—-
456. 1844

pera) Gookins, S. B., and Downing, A. J. Remarks on pear blight of the West. Hort. 1 : 253-256.
1846.

(1847) Barry, Patrick. Insect blight. Genesee Farmer 8: 218. 1847.

(1848) Ernst, A. H., and Downing, A. J. Fire blight in pear trees. ee 2 : 328-332. 1848.

(1849) James, J. H. Blight in pear trees. Mag. Hort. 15 : 13-23. 18

autsos) Salisbury, J. H. Pear, apple, and peach trees affected with blight. * Ohio Agr. Rept. 1863 : 450—-
460, 469. 1864.

(1875) Meehan, Thomas, and Hunt, J. G. Pear blight. Gardeners Monthly 17: 245. 1875.

(1879) Burrill, aT J. Fire blight. "Trans. Illinois State Hort. Soc. 12 : 77-81. 1879

(1881) Burrill, T. J. Anthrax of fruit trees: or the so-called fire blight of pear and twig blight of apple
trees. Proc. Amer. Assoc. Adv. Sci. 29 : 583-507. 1881.

(1885) Arthur, J. C. Proof that bacteria are the direct cause of the disease in trees known as pear
blight. Proc. Amer. Assoc. Adv. Sci! 34 : 295-208. 1885.

(1898) Waite, M. B® Life history and characteristics of the pear blight germ. Proc. Amer. Assoc.
Adv. Sci. 47 : 427-428. 1808.

(02) Jones, L. R. Studies on plum blight. Centbl. Bakt. u. Par. 2, 9 : 835-841. 1902.

(06) Whetzel, H. H. The blight canker of apple trees. New York (Cornell) Agr. Exp. Sta. Bul.
236 : 104-138. 1906.

(09) Jones, D. H. Bacterial blight of apple, pear, and quince trees. Ontario Agr. Col. Bul. 176 : 1-63.
1909.

THe Fire Biicut DisEAsE IN NurRSsERY STOCK 321

GEOGRAPHICAL DISTRIBUTION

The disease occurs throughout the United States and Canada in practi-
cally every section where pomaceous fruits are grown. No authentic
records have ever been made of its occurrence in Europe or on any of
the other continents. Its restriction to this country may be attributed,
no doubt, to the fact that the quantity of stock of pomaceous fruits ex-
ported from America is comparatively small, thus eliminating to a con-
siderable extent the possibility of the disease being transported across
the ocean.

Fire blight is common in all the nursery districts of New York State
and has frequently been destructive in the plantings of the Southern
States, especially Alabama, Florida, and Georgia. It is a well-known
malady in the nurseries of the Central and Middle West and has been
reported by Orton (’o2) as being especially abundant in Texas and
Louisiana. The disease is somewhat generally distributed over the
pear-growing section of the Pacific Coast, particularly in California and
Oregon.

ECONOMIC IMPORTANCE

Without question, fire blight is the most important disease affecting
the pomaceous fruits. Being of an epidemic nature, it may suddenly
appear in a locality with increased prevalence and cause complete de-
struction or severe injury to the fruit-tree industry of that section. Pear
orchards, especially, are severely attacked, and often an orchard is entirely
destroyed in one season. Although the blight may have subsided as an
epidemic, it is usually found to a limited extent in any locality and under
conditions favorable for its development and propagation it again be-
comes a destructive disease. Usually, in the nursery it means total loss
to the trees affected, and with its rapid spread through the blocks where
the trees are thickly planted, often within a comparatively short time,
thousands of young trees are ruined. In some cases entire blocks of
apples, pears, and quinces have been destroyed. Such a condition pre-
vailed in one of the nursery districts of New York State in 1908, and
practically every nurseryman in that section suffered heavy losses from
the disease.

SYMPTOMS

The limbs, blossoms, twigs, and fruit may be attacked. In the nursery
the disease is most commonly found affecting the twigs, one exception
being the two- and three-years-old quince stock. These trees often blossom
profusely in the spring, and under this condition blossom blight fre-
quently occurs.

(oz) Orton, W. A. Plant diseases in the United States in ro01. Pear blight. U.S. Dept. Agr. Year-
book 1901 : 669. 1902.

322 BULLETIN 329

Blossom blight

Sometime in the early part of the season, about two or three weeks
after the blossoming period, the blight first attracts special attention
and by a close examination the
blighted blossoms may be detected
even somewhat earlier. The first
evidence of the trouble is the
brown and subsequent blackened
appearance of the young leaf tufts
and the blossoms, from which the
disease rapidly extends into the
fruit spurs (Fig. 112). It prevents
the development of the fruit and
may even involve the larger twigs
and branches.

Twig blight

The wilted and brown or dead
appearance of the stem and foliage
is the characteristic
symptom of twig
blight (Fig. 113)
The progress of the
disease down the
stem, in the early

Fic. 112.— Blossom blight

stages, may be in advance of any
marked discoloration of the foliage,
and to a considerable degree the
blighted twigs resemble green brush
that has been only partially burned.
There is generally a viscid, milk-white
substance exuding in small drops
on the surface of the twig or the
petioles, which later becomes oxidized
into an amber-yellow or slightly
brownish, then finally into a dark
brown or almost black, gum.

The extent of the disease in advance
of any discoloration of the foliage may
be determined by the sappy and juicy
appearance of the tissue. A faint amber-yellow or reddish discoloration
of the tip is often a means of detecting recently affected apple shoots.

Fic. 113.— Twig blight

Tue Fire BLicHT DisEASE IN NURSERY STOCK 323

In pear twigs an intensive blackening of the tissue is usually character-
istic, even in early stages of the infection. However, in all host plants
the blight ultimately produces the same effect — the leaves shrivel, turn
brown or black, and resemble foliage that has been killed by frost. One
of the most striking symptoms of fire blight to be recognized is in the
twig or limb with dead, brown or black leaves clinging to it, contrasting
sharply with the dark green foliage in summer and the naked branches
of the trees in winter. In no other disease of the pome fruits do the
leaves cling so tenaciously to the dead twigs.

Body blight

The blight often works down the twigs or branches into the trunk of
the tree and within a short time may extend into the roots, causing the
destruction of the whole tree. While the disease is active in the trunk
or the larger branches, the affected tissue is darker in color, often with
a brownish or reddish tinge. The abundance of sap gives the bark a
water-soaked, or occasionally a slightly raised and blistered, appearance.
(The blisters have also been observed even in the smaller pear and quince
twigs.) The characteristic exudation is common and, when the disease
is especially active, it may be so abundant that it flows slowly down the
side of the tree (Fig. 114).

With unfavorable conditions — as, for example, at the termination of
the growing season, when the plant tissues harden and there is a dimi-
nution in the sap supply —the active progress of the blight becomes checked
by natural causes. The diseased bark shrinks and subsides, resulting in
a sharp line of demarcation between the healthy and the diseased tissues.

When only a definite area is affected, the diseased part surrounded by
healthy bark is known as a canker (Fig. 11s). The inner tissue of the
diseased bark appears brown or dead, making a distinct contrast with
the pale green or white, healthy tissue. In many cases the blight may
still be present in a latent form cr may remain throughout the winter
in apparently nondiseased tissue. With favorable conditions the follow-
ing spring it again becomes active and progresses farther into the adjoining
healthy bark. Hold-over cankers, in which the blight remains in a latent
form throughout the dormant season, are rather common.

WINTER INJURY VERSUS FIRE BLIGHT

Diverse weather conditions during the dormant season may cause
severe injury to the fruit stock in the nursery and frequently such injury
is confused with fire blight. The results of winterkilling are usually
manifest early in the spring by the injury to the trunks of the trees.

324 BULLETIN 329

There occur large cankered areas, which may completely girdle the tree
and partially interfere with, or totally inhibit, the development of the
new growth. If the injury has not been too severe some new growth

Fic. 114.— Cankered limb, showing exuding milky drops

may be made; but for lack of nourishment the young shoots soon wilt,
turn brown, and die within a very short time, their condition thus
resembling that brought about by fire blight. On the other hand, winter-
killed trees show a uniform browning or dying of all the foliage; while
with fire blight, in the early stages the dead discoloration is from the tip

THE Fire Biicut DIsEAsSE In NuRSERY STOCK 225

uv

downward as the disease progresses toward the main part of the tree.
The shoots of winterkilled trees appear wilted and dried out, due to in-
adequate food supply, and there is no gummy exudation nor water-soaked
appearance which is so common with
blighted twigs.*

ETIOLOGY

Name of parasite

The disease is caused by the
bacterial parasite Bacillus amylivorus
(Burrill) Trev. The organism was
first described by Dr. T. J. Burrill
(1883) and named Micrococcus
amylivorus, the description of which
is reproduced here:

New Species of Micrococcus (Bacteria) —
Micrococcus amylivorus. Cells, oval, single
or united in pairs, rarely in fours, never
in elongated chains, imbedded in an abun-
dant mucilage which is very soluble in
water; movements oscillatory; length of
a separate cell .00004 to .000056 inch; width
.000028 inch; length of a pair .oo008 inch;
of four united, about .ooo12 inch.

In the tissues of plants causing the so-
called “fire blight” of the tree and similar
phenomena in many other plants. Through the action of the organism the stored
starch is destroyed by fermentation and carbonic acid and hydrogen is given off
(American Association for the Advancement of Science, 1880; Tenth Report Illinois
Industrial University, 1880).

The species was at first referred to the genus Bacterium, but this came from too
exclusive attention having been given to its shape. It is only found in tissues of
affected plants or oozing from their cells and smearing the surface. It may, however,
be cultivated in pure starch in water maintained at the temperature of ordinary summer
weather. No doubt other nutritive ingredients would make the culture easier and more
prompt.

Fic. 115.— Canker on limb of tree

The only recent system of classification of bacteria available at that
time was that of Cohn (1872). Apparently Burrill placed considerable
weight on the property of motility, and the fact that he did not observe
this phenomenon in the fire blight organism (movements oscillatory)
led him eventually to place it under the genus Micrococcus with the
statement, ‘‘ This species was at first referred to the genus Bacterium,
but this came from too exclusive attention having been given to its shape.”’
In the arrangement of Schizomycetaceae by De Toni and Trevisan in

* It has been the experience of the writer that in blocks of two- and three-years-old apple and quince
trees, when an abundance of {both fire blight and winter injury is apparent, winter-injured trees seldom,
if ever, blight.

(1872) Cohn, Ferdinand. Untersuchungen tiber Bacterien. Biologie der Pflanzen 12: 127-224. pl. 3.

1872.
(1883) Burrill, T. J. New species of Micrococcus (Bacteria). Amer. Nat. 17:319. 1883.

326 BULLETIN 329

Saccardo’s Sylloge (1889), the species is transferred (page 984) to the
genus Bacillus with a reference to Trevisan (1889). An attempt has
been made to see this pamphlet by Trevisan but all efforts to locate it in
libraries of the United States have thus far been fruitless. It seems
reasonably certain, however, that the rearrangement was made by
Trevisan, not by De Toni as is sometimes stated.

The specific name amylivorus as originally proposed by Burrill has not
been adopted by any other worker. The term amylivorus does not seem
to be orthographically incorrect, and in conformity with the Vienna code
of botanical nomenclature the writer has employed Burrill’s name. It
should be noted in this connection that Saccardo’s reference to ‘ Mit-
teilungen der CEsterreichischen Versuchs-Station fir Brauerei und Malzerei
in Wien” as the place of original description is incorrect. Burrill’s
description is brief, but there can be no question whatever regarding
the organism that he saw and described.

Description of Bacillus amylivorus

Several descriptions of Bacillus amylivorus based on cultural characters
have appeared thus far in literature. Most of them, however, are incom-
plete and in several instances the various authors disagree concerning
certain reactions of the organism.

The first cultural studies on the organism were made by Arthur (1887).
He grew the bacteria in various kinds of broth or liquid media, and to a
limited extent on solid media. Waite (1898) published a brief and con-
densed description of the characters in his article on the life history of
the organism. The next description to appear is that of Chester (’or),
based on the study of a single pure culture of the causal organism from
a diseased pear twig. The organism was grown in but a relatively small
number of kinds of media, and the reactions recorded differ strikingly
from those obtained by L. R. Jones (02). The work of Jones was based
on a study of the bacillus from blighted twigs of both pear and plum,
carried in parallel series through many kinds of media. Whetzel (’06)
also reports some cultural work with the fire blight organism, and the
results obtained apparently agree in general with the work of Jones.
D. H. Jones (’o9) of the Ontario Agricultural College has published the

MB ene J. C. History and biology of pear blight. Proc. Philadelphia Acad. Nat. Sci. 38 : 322-
341 1557

(1889) Saccardo, P. A. Sylloge Fungorum 8 : 923-1087. 1889

(1889) Trevisan di Saint-Leon, Vittore. I generi e le specie delle batteriaceae; prodromo sinottico.
Milano. 1889 : 1-36. 1889.

(1898) Waite, M. B. Life history and characteristics of the pear blight germ. Proc. Amer. Assoc.
Adv Sci. 47 : 427-428. 1808.

(or) Chester, F. D. Notes on pear blight. Ann. Rept. Delaware Agr. Exp. Sta. 12 : 38-46. 1901.

(02) Jones, L. R. Studies on plum blight. Centbl. Bakt. u. Par. 2, 9 : 835-841. 10902.

(06) Whetzel, H. H. The blight canker of apple trees. New York (Cornell) Agr. Den Stas esis
236 : 104-138. 1906

(‘o9) Jones, D. H. " Bacterial blight of apple, pear, and quince trees. Ontario Agr. Col. Bul. 176 : 1-63.
1909.

THE Fire Biicut Disease In Nursery Stock 327

first description of Bacillus amylivorus since the adoption of the chart
by the Society of American Bacteriologists.

For the cultural studies made by the writer, nine different cultures
were used. Most of these were
obtained from different sources
in order to determine, if possible,
any variations in the reactions
as influenced by environmental
conditions or by the period of
time that the causal organism
had been cultured artificially.
For convenience each culture
was designated as a different
strain and, unless otherwise
stated, all nine strains were
included in each test. The
source and number of each
strain is as follows:

No. 1. Isolated from pear tree,

October 10, i909, Cornell Fic. 116.— Bacillus amylivorus, showing peri-
campus, near old forcing- trichic flagella. Moore's modification of

Loeffler’s flagella stain

house.

No. 2. Obtained from Professor T. D. Beckwith, Oregon Agricultural

College, November, rort.

No. 3. From same tree on Cornell campus as No. 1. Isolated in

November, 1910.

No. 4. From the same pear tree as numbers 1 and 3. Isolated in

October, rort.

No. 5. From Professor D. H. Jones, Guelph, Ontario, Canada. Isolated
from apple tree. Received culture from him in October, roro.

No. 6. Isolated from pear by Professor W. G. Sackett, Colorado Agricul-
tural Experiment Station. Received culture from him in March, rortr.

No. 7. Isolated from small pear twig by Professor W. G. Sackett,

Mork 21, 1ort — Colorado:

No. 8. From two-years-old quince tree in nursery. Orleans, New York,
jime. Tors.
No. g. From apple tree, West Hill, Ithaca, New York, October, rorr.

In general, the reactions in different media for all the strains were
fairly uniform and no marked differences were noticed; the behavior of
the organism in milk cultures showed the greatest variation. It should
be noted that a strain from Colorado, No. 7, always made a slower growth
than any of the others; while No. 9, recently isolated from apple at Ithaca,

328 BULLETIN 329

New York, was usually the most rapid grower. Commonly the first
indications of growth by No. 7 were not apparent until several hours after
that of the other strains. When there were any differences in the reactions,
strain No. 8, from quince, was always taken as a basis for comparison.
' Morphological characters.— Vegetative cells. The fire blight organism is
a bacillus of slightly variable length, usually within the limits of .6 to .9
by 1 to 1.84. Short rods with rounded ends, mostly single, sometimes
in twos and occasionally in chains of three or four. Taken directly from
fresh gummy exudate of diseased quince twig and stained with alcoholic
carbol fuschin, the single rods measured .6 to .8 by 1.4 to 1.84. A two-
days-old culture on agar when stained with carbol fuschin gave the
measurements .7 to .8 by 1.5 to1.7u. Measurements of the same strain,
No. 8, on agar cultures sixty days old were slightly less, .6 to .7 by 1.2
to 1.4u. When taken from a three-days-old culture of bouillon and
stained with carbol fuschin, the limits of size were .7 to .9 by 1.6 to
1.8u. In. general, the measurements in length of strain No. 7, from
Colorado, were slightly less, the rods being somewhat shorter. Taken
from six-days-old bouillon culture and stained with carbol fuschin, the
size of rods was .7 to .8 by 1.2 to 1.3p.

Endospores. No endospores have been observed.

Flagella. The organism is motile by means of peritrichic flagella,
usually two or three in number, stained by Moore’s modification of
Loeffler’s flagella stain (Fig. 116).

Capsules. None demonstrated.

Zoogloee. None formed. In his work on the history and biology of
pear blight, Arthur (1887) illustrates zoogloeal formations. These were
no doubt due to the presence of other organisms often found on the surface
of diseased tissues, as was later pointed out by Miss Snyder (1898).

Involution forms. None observed.

Staining reactions. The organism stains readily with watery and
alcoholic solutions of gentian violet, carbol fuschin, and methylene blue.
Gram’s stain, and also Ziehl-Neelson, proved negative.

Cultural characters.— In the preparation of the culture media the direc-
tions as given by Smith (’05) were followed as closely as possible. Dis-
tilled water was used in preparing all media unless otherwise stated.
The beef broth was made from minced lean beef and Witte’s peptone.
All media containing nutrient bouillon titrated +15, Fuller’s scale, unless
otherwise stated; N/2. sodium hydroxid was used for titrations, with
phenolphthalein as an indicator.

(CEB) eaten, J. C. History and biology of pear blight. Proc. Philadelphia Acad. Nat. Sci. 38 : 322-
341. 1887.

ee sarder, Lillian. A bacteriological study of pear blight. Proc. Amer. Assoc. Ady. Sci. 47: 426-
427. 1808.

(os) Smith, E. F. Bacteria in relation to plant diseases I : I-285. 1905.

Tue Fire Buicut Disease in Nursery Stock 329

Agar colonies. Colonies appear on second day, characteristic on
fifth day, at 23° C. When isolations are made from diseased tissue, the
colonies appear on the second day at a temperature of 23° C., becoming
characteristic on the fourth or fifth day. The surface colonies are usually
small, not more than two to three millimeters in diameter. They have
a somewhat shiny luster, and are smooth, white, flat or slightly raised,
having a finely granular or cloudy circular growth, with a dense opaque,
sharply defined, white center. The margin is entire or slightly undulate.
Older colonies are coarsely granular to grumose. Deep colonies are
globose, or more often lens-shaped, with dense opaque center. Plates
poured from young beef-broth cultures show colonies developing usually
after forty-eight hours.

Agar stroke. Moderate growth, filiform, slightly raised, glistening,
slightly gray. A moderate growth after twenty-four hours at 23° C.,,
more characteristic, however, after forty-eight hours; filiform, has a glisten-
ing luster, opalescent. The white streak does not branch on the surface
nor penetrate the agar. The growth often widens, becoming more diffuse,
spreading mainly toward the bottom where moisture is present on surface
of agar. Often in isolated colonies or beaded above before becoming
diffuse and spreading at bottom. Water of condensation at base of
streak turbid and with flocci. Does not stain the agar on which it grows.
It is free from odor. Slightly to considerably raised, more or less pul-
vinate in cross-section, semi-opaque.

Agar stab. Growth filiform, uniform, nontypical. Feeble growth after
twenty-four hours at 23° C., most characteristic after forty-eight hours,
filiform, best toward the top. Surface growth smooth, with general
tendency to spread somewhat. Agar not liquefied nor softened.

Nutrient gelatin colonies. Colonies are round, slightly raised, entire,
grayish. In plates poured from a three-days-old beef bouillon culture
the colonies were rather numerous but very small, appearing as tiny
specks after three days. In the dilution plates the colonies were some-
what larger; after the fifth day they appeared finely granular under low
power of microscope and later became grumose. Liquefaction of gelatin
very slow, only slightly evident after fifteen days.

Gelatin stab. Growth moderate, slight liquefaction after fifteen days.
Growth slow and feeble for the first two or three days on +15 nutrient
gelatin at 20° C. Slight tendency to be beaded or granular along lower
line of platinum needle stab. After eight days moderate increase in
growth, with indication of slight liquefaction after fifteen days. Crateri-
form to stratiform.

Stab cultures were made in tubes of nutrient gelatin with the following
acidities: neutral, +10, +15. In these cultures, strains numbers 1, 7, and

330 BULLETIN 329

8 were used. At a temperature of 23° C. there was a slight growth in
all tubes after twenty-four hours, more marked, however, after three days.
The most vigorous strain was No. 8, and there was considerable surface:
growth in this strain; while No. 7 showed the weakest development, with
surface growth but slight. The +10 and +15 tubes were somewhat
more favorable for the organism than was the neutral medium. Although
the liquefaction in the acid cultures was only slight after fifteen days, it
was still less in the neutral cultures.

Potato plug. Growth moderate, nonviscid, glistening white, no odor,
spreading. Growth generally appearing after forty-eight hours, not so
rapid nor so abundant as on agar streak. Slightly elevated, glistening,
moist, pearly white, slowly spreading over the surface of the potato,
entire margin, not viscid. It is free from odor and turns the potato plug
grayish, which later becomes darker in color.

Loeffler’s blood serum. Growth moderately slow, colorless, no lique-
faction. Feeble growth after forty-eight hours, more characteristic after
four days at 23° C. No branching of the white streak on the surface nor
penetration of the medium. Slight tendency to spread at the base,
slightly raised, sometimes beaded or in isolated colonies, glistening.
Does not stain nor liquefy the serum. (Strain No. 1 was used for these
studies.)

Starch jelly.* Growth moderate, diastatic action absent or feeble,
medium unstained or slightly stained. The experiment was repeated
several times, but no marked changes as recorded by Jones (’o9) were
observed. One or two of the tubes showed a very slight liquefaction
when left at 25° C. In the enzyme studies, subsequently discussed
(under ‘‘ Pathological histology ’’), tests were made for the production
of diastase; but the results were negative except in one or two cases, when
a slight test for reduction of starch was obtained.

Bouillon +15 with 1 per cent Witte’s peptone. Cloudiness uniform,
moderate, no pellicle, no ring, no odor. Tubes of +15 peptonized beef
bouillon were inoculated from sixteen-days-old slant agar culture. After
twenty-four hours at 23° C. there was a uniform clouding with flocci and
slight sediment. After forty-eight hours, cloudiness increased, flocci
abundant and more or less persistent. No pellicle formed and odor not
marked. Culture fluid showed tendency to clear after seventeen days.

Sugared peptone water. Growth very moderate with apparently no
staining of the fluid, in flasks of sterilized lake water containing Witte’s
peptone, c. p. glucose, and Baker’s c. p. calcium carbonate.

Milk. Coagulation slow, extrusion of whey beginning only after
several days. Partial to complete digestion of curd. Tubes of sterile

* For composition see Smith, ‘‘ Bacteria in relation to plant diseases ’’ 1: 196. 1905

(‘o9) Jones, D. H. Bacterial blight of apple, pear, and quince trees. Ontario Agr. Col. Bul. 176 : I-63.
1909.

Tur Fire BiicHt DiszasE IN NURSERY STOCK 331

milk titrating +8 with phenolphthalein were inoculated with a one-
millimeter loop of a beef bouillon culture, two days old, and kept at 23° C.
No apparent change was observed until after nine days, when there was
a slight formation of whey as a shallow layer on the surface of the milk.
After twenty days coagulation was more advanced. At the end of five
weeks there was a tendency for partial to complete digestion of curd.
No discoloration of coagulum.

Litmus milk. Reduction of litmus slow. Tubes of sterile litmus
milk were inoculated with a one-millimeter loop of a two-days-old beef
broth culture and kept at 23° C. After ten days there was a very slight
increase in the blue color. In twenty days the ‘reduction of the litmus
was apparent, with the formation of whey at the surface. Tubes after
forty to fifty days showed a return of the neutral lavender color, with a
slight change to red after sixty days. Coagulation slow, with partial
to complete peptonization of the curd which was wholly bleached.

Although several tests were made with the growth of the organism
in milk cultures, there was never any rapid separation and digestion of
the coagulum such as Jones ('o9) describes. The changes in the medium
were always slow.

The most constant and marked differences in growth of the various
strains were also apparent in the milk cultures. The general tendency
for all strains was a slow separation and digestion of the curd. However,
as is to be noted in the table below, the completion of this process was
more marked in some cases than in others.

TABLE 1. REACTION OF STRAINS OF BACILLUS AMYLIVORUS IN STERILE, LAVENDER,
BLuE Litmus MiLk aT 23° C.

Strain Ten days Sixty days

Loo CE Slightly bluer than check. Complete digestion of curd, white bacterial
precipitate in bottom, whey lavender to red

Dre Sakae: Slightly bluer than check. Complete digestion of curd, white bacterial
precipitate in bottom, whey rose purple

3.........| slightly bluer than check.| Moderate digestion of curd, wholly bleached,
whey reddish

Bo ticteo res Slightly bluer than check. ee i complete digestion of curd, whey
reddis

Goat Sey CREE Winehrameed sane tc ster. ee Moderate digestion of curd, whey rose purple

OPC Ieee Blverichanecheckey spe. Slight digestion of curd, wholly bleached, whey
red

7.........| Much bluer than check... Very slight digestion of curd, wholly bleached

8.........{ Slightly bluer than check. Partial to complete digestion of curd, whey
lavender to red

g.........| Slightly bluer than check.| Partial to complete digestion of curd, whey
red

(‘o9) Jones, D. H. Bacterial blight of apple, pear, and quince trees. Ontario Agr. Col. Bul. 176: 1-63.
1909.

232 BULLETIN 329

Cohn’s solution. No growth.

Uschinsky’s solution. Growth moderate, not viscid. Tubes of Uschin-
sky’s solution were inoculated from a beef broth culture two days old.
After twenty-four hours at 23° C. a scanty growth was apparent, slightly
clouding the solution by the granular particles suspended in the liquid.
At the end of four days the maximum growth was teached. The liquid
was moderately cloudy; did not become fluorescent or viscid. There was
no pellicle formed, but a slight sediment was apparent in the bottom of
the tube.

Sodium chlorid bouillon. Six per cent of sodium chlorid inhibits
growth. Five per cent inhibits or retards growth. Transfers were made
with a one-millimeter loop from a two-days-old,+15, peptonized bouillon
culture to +15 bouillon tubes containing 2, 3, 4, 5, and 6 per cent of
c. p. sodium chlorid. At the end of two days there was a good growth
in the tubes containing 2 and 3 per cent of sodium chlorid, but the growth
in the 3- and 4-per-cent solutions was best after four days. There was
a gradual retardation of growth up to 6 per cent of sodium chlorid, which
inhibited the growth of the organism in practically all cases. Apparently
5 per cent of sodium chlorid is about the limit for the development of
the organism. Most recently isolated strains appeared least adapted to
the high concentrations of the solution.

Best media for long-continued growth. Cultures in litmus milk, milk,
and bouillon and on agar stab, which had been growing for five months,
showed growth when transferred to +15 bouillon. Cultures on potato
and gelatin of the same age showed no growth.

Growth in bouillon over chloroform. Growth inhibited. Transfers of
a two-millimeter loop from a two-days-old, +15, peptonized bouillon
culture were made to Erlenmeyer flasks containing 30 cubic centimeters
of +15 peptonized bouillon. To each flask was added 15 cubic centi-
meters of chloroform (Squibb’s). The tops of the flasks were covered
with oil-paper in order to prevent evaporation. No growth occurred
after ten days in any of the flasks.

Quick tests for differentiation purposes. The following are perhaps
the most satisfactory tests: agar colonies, agar stroke cultures, gelatin
stab, behavior in Cohn’s solution, growth on starch jelly and also in beef
bouillon, inoculation into young succulent twigs of apple, pear, or quince
trees.

Fermentation tubes. No gas is produced and the organism is aerobic
in its tendencies. A solution was made by adding 2 per cent of Witte’s
peptone to filtered lake water. From this, six solutions were then made,
each containing 1 per cent, respectively, of one of the following carbon
compounds: cane sugar, dextrose, glycerin, mannite, maltose, and

Ture Fire BuicHt DiszASE IN NURSERY STOCK a8

lactose. Four fermentation tubes were filled with each of the solutions
and sterilized in an Arnold steamer for twenty minutes, on three days in
succession. Three tubes of each set were inoculated and one was left
for control. The inoculations were made by transferring a one-milli-
meter loop from a three-days-old, +15, peptonized beef bouillon culture.
Three days after inoculation all tubes showed a slight cloudiness in the
open ends of the tubes. After five days the cloudiness was more marked
in the tubes containing dextrose, cane sugar, mannite, and maltose than
in the glycerin and lactose. After eighteen days the cloudiness had
extended slightly beyond the middle of the U in the dextrose, cane sugar,
and mannite tubes, and in all solutions there was a distinct, moderately
flocculate precipitate formed, with solid particles floating in the liquid.
The precipitate in the glycerin and maltose was slightly less; however,
the cloudiness extended to the bend in the tube. The least growth was
obtained in the lactose solution; there was a moderate amount of pre-
cipitate, which had a tendency to be stringy, and the cloudiness extended
nearly to the middle of the U.

There was but little variation in the appearance of the different strains
of the organism grown in the above solutions, and tests made after nine-
teen days with respect to the acidity of the different cultures gave uniform
results for all the strains. Tests made with litmus gave the following
reactions for the cultures in the different solutions, the increase in acidity
being proportionate to the amount of growth in the various solutions:

Lactose — strongly alkaline
Glycerin — alkaline

Maltose — alkaline

Mannite — neutral to weakly acid
Cane sugar — weakly acid
Dextrose — strongly acid

Another series of tubes gave the same tests after the cultures had been
running fifteen days.

Two-per-cent ammonium lactate and two-per-cent carbon compounds.
Moderate growth with cane sugar and slight growth in the mannite
solution. A solution was made by adding 2 per cent of c. p. ammonium
lactate to filtered lake water. Six solutions were made, from cane
sugar, dextrose, mannite maltose, glycerin, and lactose. The solutions
were placed in test tubes and sterilized in an Arnold steamer for
twenty minutes, on three days in succession. Inoculated tubes re-
ceived a one-millimeter loop of peptonized beef bouillon culture, six days
old. All nine strains were used and cultures were grown at a temperature
of 23° C. After five days there was a faint cloudiness in the mannite

334 BULLETIN 329

solution and a moderate growth occurred in all the tubes containing cane
sugar. There was a moderate reduction of the cane sugar to glucose, and
the cultures were slightly acid to litmus. No growth in any of the other
solutions after fifteen days. Fermentation tube cultures made at the
same time showed no gas production.

Potassium nitrate and carbon compounds. Slight growth in tubes
containing dextrose. Six solutions were made, containing 1 per cent
c. p. potassium nitrate and distilled water plus one of the following carbon
compounds: cane sugar, dextrose, mannite, maltose, glycerin, and
lactose. Tubes of these solutions were inoculated with a one-millimeter
loop from a five-days-old, +15, bouillon culture.

A faint cloudiness was apparent in the dextrose solution tubes, but no
growth occurred in any of the others after fifteen days. All dextrose
tubes gave alkaline reaction with litmus. No gas production in fer-
mentation tubes containing the above solutions.

Two per cent asparagin. Slight to moderate growth. Sterile tubes of
a 2-per-cent solution of asparagin and filtered lake water were inoculated
with a one-millimeter loop from a three-days-old, +15, bouillon culture.
A slight to moderate growth occurred after five days at 23° C. This
would indicate that the organism is able to obtain both its nitrogen and
its carbon from asparagin.

Ammonia production. None produced.

Nitrates. Nitrates are not reduced. Transfers of each of the nine
strains were made to ro cubic centimeters of +15 peptonized beef bouillon,
to which had been added enough potassium nitrate to make a 1-per-cent
nitrate bouillon solution. After three days there was a distinct cloudy
growth in the tubes, and tests were made for nitrites as follows: To the
inoculated tubes that had grown for four days, 1 cubic centimeter of boiled
starch water and 1 cubic centimeter of potassium iodide solution (1-200)
were added, then there were added a few drops of strong sulfuric-acid
water (2:1); but no blue color resulted, indicating that there was no
formation of nitrites. Other tests made with various strains at different
intervals always gave negative results for the presence of nitrites.

Indol. None formed. The indol tests were made by using concen-
trated sulfuric acid and dilute sodium nitrate (1-200 in water). Tests
were made with all nine strains of the organism. Two-days-old pep-
tonized beef bouillon cultures were tested, and also similar cultures eleven
and twenty days old respectively. No trace of indol was detected in
any of the cultures, even on heating to 80° C. after the sulfuric acid and
nitrate were added.

Toleration of acids. Toleration of acids is slight. Transfers from
a two-days-old, +15, bouillon culture were made to tubes of +8, +10,

Tue Fire BLicHt DISEASE IN NURSERY STOCK 335

+32, +15, +16, +19, +20, +23, +25, and +27 peptonized beef
bouillon.* After four days, growth was apparent in all tubes up to +23.
No growth occurred in +23, +25, and +27. The addition of malic
acid in small amounts to +10 beef bouillon favored a slight increase in
growth. Increasing the acidity from +-10 to +12 by malic acid appeared
to favor the growth of the bacilli. No growth occurred in +15 peptonized
beef broth acidified to +25 by addition of normal malic acid.

Toleration of potassium hydroxid. Toleration of alkalies rather low.
Tubes of bouillon titrated with phenolphthalein to —4.5, —5.5, —6.5,
—7, and —8 were inoculated with a one-millimeter loop from a three-
days-old, +15, bouillon culture. At 23° C. after six days, growth occurred
in all the tubes except the —7 and the —8.

The experiment was repeated, and after four days there was a faint
cloudiness in the —4.5 tubes. Two days later slight growth was apparent
in all tubes up to the —7. In the —7, strain No. 1 showed a slight cloudi-
ness in three of the five tubes. An alkalinity of -—6 is about the limit
for growth of the organism.

Optimum reaction for growth in bouillon. The optimum reaction lies
between +8 and +16 on Fuller’s scale. From studies made on toler-
ation of acids and alkalies, the optimum reaction appears to be between
+8 and +16. The limits for growth in peptonized beef broth are between
—7 and +25, Fuller’s scale.

Temperature relations Thermal death-point. The death-point is
about 47° C. Tests were made by exposing for ten minutes in +15
peptonized beef bouillon. Preliminary tests indicated that the thermal
death-point must lie between 43° and 49° C. Three different strains of
the organism were used in these tests, numbers 1, 7, and 8. The tubes of
peptonized beef broth were inoculated with a one-millimeter loop of a
two-days-old beef bouillon culture, and then placed in water at practi-
cally constant temperatures of 46°, 47°, and 48° C., respectively. At the
end of ten minutes the tubes were removed from the water bath and
incubated at a temperature of 22° to 24° C. After four days, growth
was apparent in the tubes subjected to the temperature of 46° C. No
growth occurred in any of the others. The experiment was repeated
three times with the same result, which indicates that the thermal death-
point of this organism is about 47° C. No differences were noticed for
any of the strains used.

Optimum temperatures. Best growth between 22° and 25° C.
Growth on +1s nutrient agar was much better at 23° C. than at 32°.
A temperature of 10° to 12° C. also retarded the growth of the
organism.

* The bouillon for these tests was made from Liebig’s beef extract instead of from fresh minced beef.

336 BULLETIN 329

Cultures in incubator. Transfers of strains numbers 1, 7, and 8 were
made to peptonized +15 bouillon from a two-days-old bouillon culture
and immediately placed in the incubator at a temperature of 37° C.
No growth appeared after twelve days. Check cultures made good
growth at 23° C.

Resistance to drying. Moderate resistance to drying. ‘Tiny drops of
a ten-days-old peptonized beef bouillon culture were transferred to sterile
cover-glasses in a covered sterile petri-dish and allowed to dry in the
dark at a temperature of 20° to 22° C. The covers were then taken up
by means of sterile forceps and dropped into tubes of sterile bouillon,
one to each tube, with the following results: number of days dried, 1, 2,
3, 4, 5, all cultures were alive and gave good growth in the bouillon tubes.
The experiment was repeated, using a two-days-old peptone bouillon
culture. The drops were about the same size as in the previous tests.
Covers were kept in the dark. Results as follows; first tests made after
six days drying:

6 days — 4 tubes — all good growth
7 days — 2 tubes — all good growth
9 days — 2 tubes — no growth

12 days — 2 tubes — no growth

14 days — 2 tubes — no growth

Minimum temperature. Organism resistant to prolonged freezing.
Freshly poured agar plates were made from a six-days-old peptonized
beef bouillon culture of strain No. 8. The plates were wrapped in paper
and immediately placed in a tin can, which was imbedded in an ice-salt
mixture contained in-a granite pail. The temperature obtained by means
of the mixture varied from —14° to —16° C. Two plates were removed
at each of the following intervals: three hours, four and one half hours,
seven hours, twenty-three hours; and in each case the plates were im-
mediately placed in the incubator at a temperature of 23° C. Colonies
developed in abundance in all the plates. Plates subjected to the freezing
temperature for twenty-three hours showed some retardation; however,
there was practically no decrease in number of colonies that developed.

On February 3, 1912, three bouillon tubes and three agar slant tubes
freshly inoculated from an agar slant culture of strain No. 8 were placed
in a quinine can containing a mixture of pulverized ice and salt. The
can, being provided with holes in the bottom in order to allow the escape
of water from the melting ice, was placed in a granite pail. The freezing
apparatus was kept out of doors and the temperature of the mixture
was recorded three times a day. The cultures were re-iced twice each
day, a new supply of salt (about three tablespoonfuls) also being added

THE Fire Buicut DisEAse In Nursery Srock 237

each time. The average temperature was about —14° C.; owing to
extreme cold weather, however, it was as low as —28° C. on one or two
occasions.

After five days of constant freezing, one agar and one bouillon tube
were removed. A very slight growth was apparent on the agar slant,
and on melting the bouillon it showed a faint cloudiness. The tubes
were placed in the incubator at a temperature of 23° C., and after eighteen
hours agar plates were poured in which developed the characteristic
fire blight colonies. On the eleventh day of freezing two more tubes
were removed and placed in the incubator. After thirty-six hours, growth
was apparent in both the agar and the bouillon tubes. The last two
tubes were removed from the freezing mixture on the fourteenth day and
they gave good growth after thirty-six hours at 23° C.

Effect of sunlight Freshly poured agar plates were exposed on ice to
direct sunlight after covering a part of each plate with heavy pasteboard.
Plates exposed for one hour showed several colonies developing after
four days incubation at 23° C. Plates exposed for four hours and then
incubated at about 23° C. gave no growth in the unprotected parts.
The temperature of the agar throughout the exposure was between 23°
and 36° C.

Ferments.— Invertase. The different strains of the organism were
grown for nineteen days in sterilized filtered pond water containing 2
per cent of Witte’s peptone and 1 per cent of c. p. cane sugar.

Tests were made for glucose with Fehling’s solution. All tubes showed
considerable reduction, being the strongest in cultures of strains numbers
2,5,7,and 8. The checks gave a negative test for glucose. It is to be
inferred from these tests that a moderate amount of the invertase fer-
ment is produced.

Crystals.— Silky, needle-like crystals were formed in old litmus-milk
cultures. The washed crystals were sparingly soluble in water; and
when this aqueous solution was mixed with a solution of mercuric nitrate
a yellow precipitate was produced, which, when boiled with dilute nitric
acid, acquired an intense red color. This reaction is used as a test for
tyrosine. The crystals were also tested with Mormer’s reagent (1 volume
formaldehyde, 45 volumes distilled water, and 55 volumes concentrated
sulfuric acid), which gives a green color with aqueous solution of tyrosine.

Germicides.— Poured agar plates were made with strain No. 8 of the
organism after exposure to various concentrations of copper sulfate,
mercuric chlorid, and formaldehyde solution.

Poured plate cultures showed growth after three days when exposed
for ten minutes to copper sulfate 1:10,000; no growth occurred when
exposed for fifteen and twenty minutes to the same strength. No growth

338 BULLETIN 329

in poured plate culture after ten and twenty minutes exposure to mer-
curic chlorid 1: 20,000. Plate cultures showed growth after three days
when exposed for ten and twenty minutes to formalin 1 : 750, also r : 1,000.
Growth occurred after ten minutes exposure to formalin 1:500, but
none after twenty minutes. Checks gave good growth in all cases.

Pathogenicity.— The organism is pathogenic to many species of genera
in the tribes Pomeae and Pruneae of the Rosaceae family.

Loss of virulence—In cultures carried for several months there was
a slight loss of virulence as compared with cultures recently isolated.
But little difference could be noticed in cultures that had been carried
for one year and three years, respectively.

Group number.— The group number, according to the descriptive chart
of the Society of American Bacteriologists, is 211.2322033.

LIFE HISTORY

The cycle

Following the work of Burrill and Arthur, subsequent investigations
were concerned more with the question of the life cycle of the organism
and the conditions under which blight occurs. Waite (1898) has con-
tributed the most to our knowledge of the life history of the germ and
advanced the first authentic evidence as to how blossom and twig blight
are brought about. He proved that insects, such as flies and bees, carry
the bacteria from oozing cankers to opening blossoms and from there
to other trees, spreading the bacteria to the blossoms. More recently
the observations of other investigators tend to show that a number of
other insects are responsible agents in spreading the disease. The bacteria
are probably not blown by the wind, as they are contained in a sticky
gum. It would be practically impossible for them to be carried in this
manner. Furthermore, Waite has shown that the probability of
infection being produced in this way is very small, since a consider-
able mass of the organism is required in order to produce infection,

As previously stated, the bacteria that remain alive throughout the
winter in “ hold-over’”’ cankers become virulent with the ascent of sap
and the increased temperature of spring. They multiply and spread into
the adjoining healthy bark. Often, when their increase is augmented by
warm, rainy weather, the gummy exudation, laden with bacteria, oozes
out of the lenticles and cracks of the infected tissue. This exudation,
containing millons of the minute bacteria, usually takes place first about
the time when the blossoms are opening. Various insects, such as wasps,
honeybees, and flies, are attracted to these hold-over cankers by the

(1898) Waite, M. B. Life history and characteristics of the pear blight germ. Proc. Amer. Assoc.
Adv. Sci. 47 : 427-428. 18098.

THE Frre Buicut DisEAsE In NursERY SFOCK 339

sweet, gummy exudate, become smeared with it, and carry the infection
material to the blossoms. Here some of the bacteria brought by the
infected insect are left in the nectar of the flower. The sweet solution
greatly favors their increase in
numbers, and the next bee or other
insect carries the organism to all
the succeeding blossoms that are
visited.

After the parasite has established
itself in the nectary of the blossom,
the tissues of the flower soon be-
come diseased and within a short
time the characteristic symptoms
of blossom blight are apparent.
After the blossoming period, or
sometimes even before it is entirely
over, the blight may appear in the
young succulent shoots, or twigs.
Ordinarily in the nursery, where
blossoms are not common except
in the two- and_ three-years-old
quince stock, the first occurrence
of the blight in spring is in the
twigs. However, instances have
been observed when the disease
first appeared in the quince blossoms
and was later spread to the succulent shoots. Not only do the new
infections occur throughout the summer, but the disease continues to
spread in an affected tree and, unless checked in some manner, may
involve the entire tree. Infections usually occur through the tips of the
shoots, but the bacteria are frequently introduced into the tissues at the
base of a petiole (Fig. 117).

Fic. 117.—Blighted shoots. Infection
occurred at base of petiole

Disseminating agents

Such agents as bees and wasps have been conceded, largely on evidence
presented by Waite (1898), to be important in the spread of blossom
blight. In recent years certain other insects have been associated with
abundant twig infections. It has been definitely proved that the aphids
(Aphis pomt De Geer) spread the disease (page 341), and observations during
the past two seasons indicate that several other sucking insects may dis-
seminate the blight bacteria in the nursery. On July 1, 1912, the following

(1808) Waite, M. B. Life history and characteristics of the pear blight germ. Proc. Amer. Assoc.
Adv. Sci. 47 : 427-428. 1808.

340 BULLETIN 329

species of sucking bugs were collected from apple nursery stock by Pro-
fessor C. R. Crosby of the Department of Entomology, Cornell University:
Reduviolus ferus Linn., Plagiognathus politus Uhler, Platymetopius acutus
Say., Empoasca mali Le Baron, Typhlocyba rosae Linn., Compylomma
verbasct Meyers, and Lygus pratensis Linn.

It has not as yet been definitely determined that these species do spread
the disease, but a large percentage of them are undoubtedly active agents
in disseminating the blight bacteria. Visiting blighted tissues, the
insect becomes smeared with the gummy exudate and carries the bacteria
to the tender twigs; here, in sucking the sap, the insect punctures the
tissues, thus forming a means of entrance for the blight germs, with the
result that the twigs may soon become infected.

Tarnished plant bug.— It is believed that one of the most important
agents in transmitting the blight parasite to healthy trees, for the last
two seasons at least, has been the tarnished plant bug (Lygus pratensts
Linn.). This insect has been recognized for many years as causing severe
injury to peach stock, but until recently it has never been considered
a serious pest to other nursery trees. Due to the stinging of the terminal
shoot of first-year peach buds, there is a tendency for the trees to make
a stunted, bushy growth, thus failing to reach the proper height. Not
only has peach stock been injured in this way, but also considerable
damage was apparent during the season of 1g11 in several blocks of
first-year apple buds.

The same trouble was again noticed in 1912, and a large number of
apple shoots that had been stung by the insect a few days previous de-
veloped infections of fire blight. Apparently this tarnished bug was
responsible for the infections that occurred. Being abundant also in
blocks of two-years-old apples where there was considerable blight, the
insects frequently visited the sweet, gummy exudation on infected trees.
It is possible that in this manner they not only spread the disease in the
larger trees, but also carried the bacteria to adjoining blocks of one-year-
old apple stock, where infections occurred through the punctures made by
them. ,

During the month of July the tarnished bugs are most abundant on
the apples, and as a rule the blight has become more prevalent with their
appearance. In two large nurseries this was especially noticeable in the
season of 1912. The presence of the insects greatly augmented the spread
of the blight. New infections continued to occur. After some time
(about the middle of August), when the tarnished bugs left the apple
stock, the disease subsided. Comparatively few new infections occurred
throughout the remainder of the season, even though the trees continued
for some time to make a succulent growth.

THE Fire Buiicut Disease in Nursery STock 341

Aplhids.— The common green aphids (Aphis pomt) have also been
associated with the blight disseminators, and their importance was espe-
cially noticeable during the season of 1909 when there was an unusually
severe aphid infestation on fruit stock throughout New York State. In
one of the large nurseries considerable blossom blight had occurred in
a block of two-years-old quince trees; and with the appearance of the
aphids, not only did the disease become more abundant in the quinces,
but the bacteria were carried to the blocks of apples. From all indications
the blight followed the path of the aphid infestation, since no infections
had been observed in any of the apples until after the appearance of the
aphids. By dipping the infested shoots in whale-oil soap solution, seven
pounds to fifty gallons, thus eradicating the aphids, the prevalence of
the blight was soon greatly reduced.

Jones (’o9), in his studies and investigations on fire blight, is also
led to conclude that aphids are important in the dissemination of the
blight bacteria, both in the nursery and in the orchard. He suggests
that possibly blight epidemics can be associated with years when aphids
are unusually common. The writer, however, is inclined to the opinion
that the occurrence of aphids does not play such an important part in
the spread of the disease. Without question, when aphids appear in
trees that are blighted, there is a tendency for the bacteria to be more
widely disseminated; but a number of instances may be cited in which
entire nurseries have been severely infested with aphids and yet practi-
cally no blight has appeared in the same season. It is also an important
point that periods of prolonged dry and hot weather are favorable to
aphids, whereas such conditions can hardly be considered conducive to
blight epidemics. Blight infections occur regularly only in succulent
tissues, and in the nursery, especially, where the rapidity of growth is
greatly decreased by such diverse weather conditions, it is not to be
expected that infections will occur so abundantly. However, the infec-
tion experiments conducted by the writer during the winter of 1o11—
1912 in the greenhouse proved conclusively that blight infections do
occur through aphid punctures in young succulent tissues.

Shoots of three pear seedlings were smeared by means of a camel’s-
hair brush with an agar culture of Bacillus amylivorus, and a number of
aphids (Aphis pomi) were transferred to these shoots. In the same
manner shoots of two other seedlings were smeared with the agar culture
of the organism, but no aphids were transferred to these trees. All the
trees were covered with large bell glasses, and on the tenth day four of
the aphid-infested shoots showed the characteristic symptoms of fire

(09) Jones, D, H. Bacterial blight of apple, pear, and quince trees, Ontario Agr. Col, Bul, 176:1-63.
I909.

342 BULLETIN 329

blight. Of the shoots from which the aphids had been excluded, none
blighted. In another experiment a number of aphids were smeared with
an agar culture of Bacillus amylivorus and placed on the shoots of two
seedlings. The shoots of two other seedlings were smeared with the agar
culture as in the experiment above. All trees were covered with bell
glasses, and on the eleventh day three of the aphid-infested shoots were
blighted. None of the other shoots became diseased. Isolations were
made from the blighted twigs and a pure culture of Bacillus amylivorus
was obtained.

When the aphids were present to puncture the tissue and thus furnish
a means of entrance for the bacteria, about fifty per cent of the shoots in
the above experiments became diseased. No infections occurred when
the shoots were smeared with the culture of the organism and the insects
excluded. The best results were obtained with the use of tender and
succulent shoots, and no doubt the percentage of infections would have
been greater had it been possible to select the tenderest growth in every
case.

Dissemination by pruning tools

Besides the general distribution of the blight germs by insects, man
himself is often an active agent in spreading the parasite. Pruning tools
are certainly a frequent means of transmitting the organisms. Whetzel
(06) has demonstrated this point, and the experience of others proves
fairly conclusively that the disease may be transmitted by the tools in
use. Waite (’06) states: ‘‘In Maryland the writer once saw a nursery
block of 10,000 trees of Bartlett and other pears completely destroyed
by blight. This block, as determined by the specimen, carried actual
samples of hold-over blight in the stocks. When the stocks were cut
off above the dormant buds in the spring, the pruning tools became in-
fected and the disease was transmitted to nearly every tree reached by
the pruners. Instead of the buds pushing up, the cut surface began to
gum and blight.”

A somewhat similar incident occurred during the season of 1910 in one
of the nurseries of New York. A large number of scions of Kieffer pears
were obtained from a nursery in Alabama and used for budding several
thousand seedlings (Fig. 118). Some time later, when the block was
being rebudded, a number of the stocks showed the characteristic symp-
toms of blight in the region where the buds had been inserted. Other
varieties were rebudded at this time, and after a period of about ten to
fourteen days blighted stocks were common over the entire block. With-

('06) Whetzel, H. H. The blight canker of appie trees. New York (Cornell) Agr. Exp. Sta. Bul.

236 : 104-138. 1906.
('06) Waite, M. B., and Smith, R. E. Pear blight. Ann. Rept. California Fruit Growers Assoc.

31 : 137-161. 1906.

Tue Fire Biicut Disease 1n Nursery STOCK 343

out question the disease was transmitted to other stocks from the seedlings
budded with Kieffer scions, by means of the infected budding-knives.
All indications were that the blight was first introduced with the Kieffer
buds, which had no doubt been cut from diseased trees; and at rebudding
time, the knives becoming infected, the spread of the disease was general.

During the summer of 1912 the source of infection of a number of
blighted apple seedlings, as determined by scions examined, was attributed
to the use of diseased buds that had been cut from a block of two-years-
old trees on which there had been considerable blight. Not only did the

Fic. 118.— Budding pear seedlings

seedlings blight which were budded with the diseased buds, but the
bacteria were carried on the budder’s knives to other seedlings. Later,
at rebudding time, the budders, being unfamiliar with the disease, fre-
quently attempted to rebud the blighted stocks, their knives became
infected, and the bacteria were transmitted to other seedlings. The
number of diseased seedlings was also increased when the strings used for
tying the buds were cut. Frequently, in cutting a string a slight incision
was made in the bark, and many trees were inoculated in this manner,
the blight germs having been carried on the knives from the diseased
stocks.

344 BULLETIN 329

Blight may also be introduced into the seedling block by means of
insects that carry the bacteria to the tender shoots (Fig. 11g). Occasion-
ally entire trees become diseased in this manner.
It is the opinion of the writer, however, that
twig infections are seldom, if ever, so abundant
in seedlings as to be the source of an epidemic.
On the other hand, an attempt to bud any
such infected stock would tend to favor the
more rapid spread of the disease, the blight
bacteria being carried on the budding-knives.

Special orchard considerations

In general, blight infections in the nursery
occur through the twigs and blossoms; in the
orchard, however, infections are frequently
produced in a number of other ways. Jones
(rr) has observed the work of a fruit bark-borer,
Scolytus rugulosus, in spreading the blight in
pear and apple orchards.
Fic. 119.— Blighted shoot on In puncturing the

Epis etene diseased area the borer
becomes infected, and later spreads the disease to
healthy branches. In cuttings from a living
branch of Bartlett pear, which was perforated
by the fruit bark-boring beetle immediately
below each of thirty leaf or fruit spurs, there
was a beetle in every hole and the bark sur-
rounding eight of these was developing blight. Ba

Occasionally the bacteria are introduced into4
green fruit by such insects as curculio, causing \_
what is known as fruit blight (Fig. 120). .

Waite (1896) has observed instances in which
sap suckers, becoming infected by puncturing Sp
cankers of hold-over blight, spread the disease to w

: Fic. 120.— Blighted apple.
healthy trees. Bacteria introduced nto

P. J. O’ Gara is authority for a statement, fruit by curculio. Note the
published by Smith (11) in his bulletin on "4 ond the oozing drops

crown gall, that fire blight cankers have been known to develop around

(1896) eis, M. B. Cause and prevention of pear blight. U.S. Dept. Agr. Yearbook 1895 : 295-
300. 1806.

(‘r1) Jones, D. H. Scolytus rugulosus as an agent in the spread of bacterial blight in pear trees. Phy-
topath. 1: 155-158. pls. XXIJI-XXIV. t1o11.

(11) Smith, E. F., Brown, Nellie A., and Townsend, C.O. Crown-gall of plants: its cause and remedy.
Crown-gall followed by hold-over blight. U.S. Dept. Agr., Bur. Plant Indus. Bul. 213 : 186. IgI1I.

THE Fire Biicut DISEASE IN NuRSERY STOCK 345

galls produced by the crown gall organism (Bacterium tumefaciens) on
Esopus apple trees, the blight bacteria having gained an entrance
through the gall.

Whetzel (’06) has also noted it to be a common occurrence for cankers
to develop on the trunk
or the collar of orchard
trees, the bacteria
having gained entrance
through a water sprout
or a tender young shoot
(Fig.121). This point
is of interest, since in
the West, especially,
the use’ of Le Conte
stocks in preference to
French seedlings has
been advocated, owing
to the tendency of trees
budded on Le Conte
stocks to sprout less
from the collar of the
tree. When French
seedlings are used the
abundance of sprouts
affords a means of
entrance for bacteria,
and losses from blight
are increased.

Hold-over blight

The general opinion
has prevailed that
blight bacteria remain
alive over winter only in those cankers that are more or less protected from
drying out; also, that the number of hold-over cankers in which the organ-
isms survive the winter is comparatively few. However, some evidence
has been produced that under favorable conditions the parasite may live
over in blighted shoots or twigs, as well as in larger diseased branches or
limbs. Burrill (1882) cites a case in which a nurseryman experienced

Fic. 121.—Blighted water sprouts on trunk of large pear tree

(1882) Burrill, T. J. Have we any new light on pear blight or yellows? Rept. Michigan State Hort.
Soc. 1881 : 133-139. 1882.
(06) Whetzel, H. H. The blight canker of apple trees. New York (Cornell) Agr. Exp. Sta. Bul.

236 : 104-138. 1906.

346 BULLETIN 329

heavy loss due to the blight in grafts newly made that winter. Some of
the scions stored for grafting purposes had evidently been cut from blighted
trees. When the grafts were made with these scions the grafting-knives
became infected, thus favoring the transmission of bacteria to the non-
diseased grafts.

Sackett (’11) has recently shown that in Colorado the blight organism
lives over winter in small blighted pear twigs. Numerous isolations
were made from diseased pear twigs in February and March, and the
parasite was frequently obtained in pure culture.

Isolations made in March by the writer from diseased twigs (less than
one centimeter in diameter) of Bartlett pears, taken from an orchard
near Newark, New York, gave about the same results as did those of
Sackett. An attempt was made to isolate the organism from five blighted
twigs, and a pure culture of Bacillus amylivorus was obtained from two
of these. The organism isolated produced the characteristic blight when
used for inoculating the tender twigs of quince trees growing in the green-
house.

In the same month, the fire blight organism was isolated also from pear
seedlings that had blighted the previous season. The trunks of the
diseased seedlings were about one half inch in diameter.

Hold-over blight in budded seedlings is of special significance since it
furnishes a source for early infection the following spring. More atten-
tion must also be given to hold-over blight in small twigs and branches,
which until recently has been considered of little importance; for it is
evident that these small cankers frequently furnish a means for existence
of the bacteria over winter.

Influence of weather on blight

Weather conditions at certain times during the growing season are an
important consideration in connection with the dissemination of blight
in the nursery. Prolonged hot and dry weather in the early part of the
season tends to check the rapid development of the young shoots, causing
them to make a hard and woody growth. The terminal buds close up
and cease growing. Such shoots are not so liable to infection, and usually
epidemics of the disease subside somewhat during a hot, dry period.
Later, with increased precipitation the growth of the trees is accelerated,
and their tissues become tender and succulent and are naturally in
a condition to be more susceptible to attacks of the causal organism.

The spread of blight is also more noticeable in the infected trees after
abundant rainfall followed by periods of hot, cloudy weather. The

(11) Sackett, W. G. MHold-over blight in the pear. Colorado Agr. Exp. Sta. Bul. 177 : 2-8. 1011.

Tue Fire Biicut DisEAsE IN NursEeRY STock 347

tissues are gorged with sap thus favoring increased activity of the bacteria,
and the disease becomes more destructive.

Cultivation and manuring as affecting fire blight

Horticulturists and pathologists generally agree that cultivation, and
the application of nitrogenous manures or of any material that tends to
induce rapid and succulent growth, favor the serious development of
blight, at least in pear trees. However, it seems that this general opinion
is based on observation alone and that no carefully conducted experiments
have been made in order to determine anything definite on this phase
of the question.

Usually, blighted trees are more common among those growing in
rich soil, and it is generally conceded that the condition of the tree has
much to do with the amount of damage produced after the malady appears.
As a rule, the more succulent the tree, the more severely it is attacked.

In the account of an experiment in orchard fertilization conducted by
J. P. Stewart (’12) of the Pennsylvania Agricultural Experiment Station,
certain observations with reference to fire blight are recorded. The
trees in the manured plots, and those in general that had made the most
rapid growth throughout the preceding four or five years, blighted more
severely than did those that had not received such excessive manuring.

Period of growth-actitity.— Observations and experiments made by the
writer indicate that the most important factor influencing the spread of
the disease is the period of growth-activity of the host plant. As shown
by inoculation experiments subsequently discussed, succulence of the
host tissue is essential in order to insure infection by the blight organism.
For a period of time in early spring the new growth that develops shows
practically no difference in its tenderness and succulence, regardless of
the conditions under which the host exists. The young, tender shoots of
trees growing in sod are as liable to infection as the twigs of cultivated
trees. Later, with the lack of cultivation and fertilizers, trees in sod
make a slower growth, and the new shoots become hard and woody and
do not blight so readily as do those of trees that are well cared for, in
which the period of growth-activity and succulence is extended throughout
the greater part of the growing season. It is also natural to expect,
under such conditions, that the damage to cultivated trees will be greater,
when once attacked, than to trees that are less succulent. Abundant
twig and blossom infection has been observed frequently on orchard
pear trees growing in sod, but usually the blight does not progress so
rapidly into the larger branches and limbs.

(12) Stewart, J. P. Factors influencing yield, color, size, and growth in apples. Relation of fertili-
zation to fire blight. Rept. Pennsylvania Agr. Exp. Sta. 1910-1911 : 467. I9g12.

348 BULLETIN 329

The importance of the period of growth-activity as influencing blight
infection is strongly emphasized by the experiments conducted throughout
the past few years.

Experiment of t910.— Thirty two-years-old Bartlett pear trees were
set in the plant-disease garden on the university farm in the early spring
of 1910. There were three plats with ten trees in each. Plat 1 was
manured heavily with stable manure and kept well cultivated. Plat 2
was cultivated, but not manured. Plat 3 was in sod in Roberts’ pasture,
which has not been broken for about thirty years; this plat received no
manure nor cultivation throughout the experiment.

During the summer of 1910 plats 1 and 2 were each cultivated three
times, and at the end of the season there was a noticeable difference in
growth between the cultivated trees and those in sod.

Experiment of 1911.— In the spring of 1911 plat 1 was again heavily
manured, and both plats 1 and 2 had received two cultivations up to
July 1. At this time there were marked differences in the growth of the
trees; those in sod had made but little growth and the new shoots were
short, hard, and woody, with indications that the growth for the season
was practically completed. In the cultivated plats the trees had made
a rapid growth and the development of young, tender shoots had been
abundant. Many of these were still very succulent, especially on the
trees that had been manured and cultivated. _

On July s, under ideal conditions for blight infection — a hot, cloudy
day following a heavy rain —all the trees were inoculated with a four-
days-old bouillon culture of Bacillus amylivorus, recently isolated from a
blighted quince tree. An effort was made to choose the tenderest twigs
in every case and three shoots on each tree were inoculated.

Five days later, when some of the infections had become apparent,
considerable differences were noticed. No infections had occurred in
the trees in sod, in which it had been necessary to make the inoculations
into hard, woody tissue. Inoculations of the trees cultivated but not
manured showed about twenty-five per cent of the twigs infected. Practi-
cally all the inoculated twigs on the heavily manured trees showed
infection, as yet indicated only by a water-soaked appearance and slight
discoloration. Four days later the progress of the malady in the infected
shoots was considerably advanced and about forty per cent of the inocu-
lated twigs in plat 2 were diseased. Only two infections developed in
the trees growing in sod.

It was strikingly noticeable that infections occurred only in twigs that
were still making an active growth, indicating that succulence of the
tissue is the primary factor in liability to infection by the bacteria. The
hard and woody twigs of trees growing in sod were more resistant than

THe Fire Biicut Disease in Nursery Stock 349

were the tender shoots of cultivated trees. Judging from results obtained
the following year, had the inoculations been made earlier in the season
the number of infections for the trees in sod would have been greater.

Experiment of 1912.— Early in the spring of 1912 plats 1 and 2 were
again cultivated and plat 1 was manured. On May 28 the inoculations
as described above for 1911 were
repeated. At this time the new
shoots on all the trees were tender
and succulent. But little differ-
ence was apparent, except that
the shoots on the trees in sod
were shorter and not so
numerous.

After five days all the inocu-
lated shoots in plats 1 and 2 were
evidently diseased, and out of a
total of twenty-eight inoculated
shoots in plat 3 only three failed
to blight. Later in the season
(July 22) many of the trees that
had been cultivated were badly
blighted (Figs. 122 and 123),
new infections had _ occurred,
and the larger branches and
limbs were diseased. On the
other hand, the trees in sod
(Fig..124) were not so severely
attacked, no new infections had
appeared, and the blight had
progressed only a short distance
(about six inches) from the

; z ; Fic. 122.— Bartlett pear tree in plat 1, highly
points of inoculation. cultivated and manured. The blight practically

Inconnection withthe question — "4 the entire tree

of succulence as influencing the amount of blight in the nursery, it is of
interest to note also certain differences in growth-activity for various
kinds of pome fruits when grown under the same conditions. Pear
_ trees especially make their most rapid development early in the
season, and after the middle of July the shoots are, as a rule, too hard
and woody for blight infections to occur. Infection experiments
during the latter part of July in 1910 and in 1911 on the two-years-
old pear trees in the nursery gave but few positive results. In the
greater number of cases the inoculations were a failure. Inocula-

350 BuLLETIN 329

tions were successful, however, when made as late as September 1 the
same years on adjoining blocks of two-years-old apples and quinces. All
trees had received the same amounts of culti-
vation and fertilizer.

It is believed that such a condition is a deter-
mining factor with reference to the dissemina-
tion of the blight bacteria by such insects as the
tarnished plant bug. Serious outbreaks of the
disease have occurred in blocks of apples and
quinces where the rapid spread of the parasite
was attributed to the presence of the tarnished
bug. Although the same insects infested near-
by and adjoining blocks of pears, practically
no blight appeared. In the writer’s opinion
this is due to the fact that the shoots had
passed their period of most rapid development
and were not in a condition to be so
readily attacked by the bacteria.

Varietal susceptibility

Opinions disagree
considerably regard-
ing the susceptibility
of different varieties of
pears to this disease.
Bartlett and Flemish
are generally reported
as being most severely
attacked and much
more susceptible, in different sections of the
country, than Kieffer and Seckel. Among
apples, Esopus and certain crab varieties are
known to blight somewhat readily; but the
difference in resistance for other varieties is

Fic. 123.— Bartlett pear tree
in plat 2, cultivated but not

manured. Such trees did
not suffer so severely when
inoculated with the fire
blight organism as did those
im plat I

considered not so constant, most of them being
more or less affected.

However, from observations and inoculation
experiments the writer is inclined to believe
that for nursery stock, at least, but little
difference is shown by the several varieties in

their ability to withstand the attacks of the blight.

Fic.
tree growing im sod in

124.— Bartlett pear

plat 3. The progress of
the blight was very °
limited, only the tender
growth of the inoculated
shoots becoming diseased

The enormous

amount of conflicting data that have been accumulated on the question

THE Fire Biicut DIsEASE IN NuRSERY STOCK 351

of varietal resistance of orchard trees to fire blight, indicate that only
such factors as the source of infection, the abundance of disseminating
agents such as insects, and the period of growth-activity of the host
plants are the criteria to be considered in determining the difference
in susceptibility. As far as is known, all varieties are attacked under
conditions favorable for the development and propagation of the malady.

Inoculation experiments.— Believing that any differences manifested are
governed more by external factors than by a natural immunity of certain
varieties, a series of varietal inoculations was conducted on quinces, apples,
and pears. From the results obtained it is conclusive that the varieties
inoculated showed practically no difference in their resistance to attacks
of the causal organism. All were susceptible.

In the table below are listed the varieties inoculated, the dates on which
the infections appeared, and the total number of infections for each. A
four-days-old bouillon culture of Bacillus amylivorus was used for all
inoculations. This strain was isolated in August, 1911, from quince.
An effort was made to choose the tenderest growth in every case and a
single shoot on each of five different trees of each variety was inoculated
by pricking the tip of the shoot with a needle that had been dipped into
the bouillon culture.

TABLE 2. VARIETAL INOCULATIONS OF BACILLUS AMYLIVORUS ON Two-YEARS-OLD
QUINCES. STRAIN No. 8. INOCULATIONS MADE AUGUST 13, 1912

Number of infections and dates Total Total
: on which they appeared number number
Variety | of inocu - of in-
August 17] August 18 | August 19] lations fections
IBoUncedbes .) ta seeren es: (0) sae one 5 5 5
Whramipionys.\s aac. aie ahs = Gall een oes lh meaeerere ene 5 5
MICS CIIEM ieicy ss cinetns Chou. os he Bo | aan Aes eta ea a 5 5
IRA GEL aly eR oar in a a ML wat an eee all aR tae 82 5 5
SCTUbL EVs Mol we arses Neuse Rs tree (0) I 4 5 5
Oran erty FA et Si atin cack CoE oO By lags ohare ae 5 5

*Nomenclature according to code adopted by the American Pomological Society in 1903.

TABLE 3. VARIETAL INOCULATIONS OF BACILLUS AMYLIVORUS ON Two- AND THREE-
YEARS-OLD APPLES. STRAIN No. 8. INOCULATIONS MADE JUNE I8, I912

Number of infections and dates on which they appeared Total Total

Variety number | number
June | June | June | June | June | June | June | July jof inocu-jof infec-
23 24 25 26 27 28 30 2 lations tions

Two-years-old
(Gicleonite heat. aise ace ee ee Rear Cl deere 2

Late Strawberry.........
Sep lAWTENCe jy) cieysne.ce ««

ANSP pp. sosi5s wrde Ss
siraniscendent,....08 o¢.. 5: ara sy Bs are ee ace sears Soanele
Were ttc paces ols. Aincts.e) ond e's hist iievete sa || arenas De llvciersvire (ernie I

UMnnunnnin
aAunununnnnn ow
Bannnnwnnp

352

BULLETIN 329

TABLE 3 (concluded)

Variety

Number of infections and dates on which they appeared

June
23

June
24

June | June
25 26 o7

Two-years-old
eX CeISION co seia teen eree tr
Wikia Sn eee ae oa.
NV ESthicldeeenne hae ae
Early Strawberry........
BISIMAT CIC epee ccereis epscey votes
\Widorivotn eiur ao eree cere eea

Jersey Sweet............
Sops-of-Wine........-..-
Syaanhn aw Gite keng Ree ng oe acecnec

lOve Se Ato eto hp ocort
Winter Pearmain*.......
Tvayyn (ee ee Een ed OREO
\iigoltt 2S hieieen mean peace tie ete
RedeActrachane: ae. ee. <
Qonmtplans Kang. oe. oc
INontusotar ton iran sects

Porters. wah SUES oa aero
Newtown Pippin.........

Olfenburcr- ieee es
Yellow Transparent......
RhotewWsland ss 32)s.te chs <<.
BenwDawsis'25. cees Ginn) ot
Gravenstein. 2. .acccs sate
Aricansaseb laGks: os aise. os

Paldwinknys a see ie soe
A\Gcillaki ave! Sey ea pei ce
Bottle Greening.........
Monabharicye: Semis. 45.6 ies
Opalescenti. Sis. ssn Oe.
Walbridve st ie mesa
Ried Canaday. ate oar oe
Staysianieee. «se crete ae

Three-years-old
MeIntosha 2 4) se see cts

ior limpentalesy: semcr cine
Pewatkees crate dice ce cre
Tolman

ISioviierale Ropie Heme poe
Winesap

Northern" Spyies me...
Northwestern Greening...
Gano

Gro, GY Rae ae ie

BR: PARBENEWWNHWWHE HOME:

Pall pac)

CSasIOMEES ee.

HN

* NWNH

NRA Ne 8 se

NHHHNNHWUH: MNWNWH-:

NNN:

WRHHN: HNHNWW

Que:

WRNH-:

WHUNNNHWWNHHNHHHHARNHNN-

June
28

June
30

-

July
2

Total
number
of inocu-
lations

Total

number
of infec-

tions

oS} on fe

| HNWHe ss e

NHHHHe
H

; HWHWH: + + +

H

OV OT OL GS OL UE UN Ut TT TT TT TT CUMUMIUMANOTTt

MAU UT

OT GN GU A TT TT TTT TT

BOW UT OE TT LT TT TT TT COUMPUAUUNUNAL ANH

AMUNNAMNUANANAnAnNpwh ann

* Winter Pearmain.
+ Red Canada.

Two rows inoculated by mistake, making ten inoculations.
Only three inoculations, by mistake.

aw ae

——s

THE Fire Biicut DIsEASE IN NuRSERY STOCK 353

TABLE 4. VARIETAL INOCULATIONS OF BACILLUS AMYLIVORUS ON THREE-YEARS-
OLD PEAR TREES. STRAIN No. 8. INOCULATIONS MADE
JUNE 19, 1912

Number of infections and dates on which they appeared

Total Total
: number | number
Variety of inocu-|of infec-

June | June | June | June | June | June | June | July | lations tions

23 24 25 26 27 28 30 2

Garber tered er alee 3 3 oe 5 5
ieihensste re: hem. Seo ais I I 3 As 5 5
ECC te yea See ee I Tt | 2 I 5 4
inh(o\ Ste apy te ne heer etitete I I 3 a 5 5
(S]aVE Gh). apie tiga nite SP eee Tih ia oats ee I 5 2
Vermont Beauty... .... Sov eee ee: me: I I 5 5
PMP OULMEnc lace ern aroe.: iaoge LA tee ae Fate i Liters 2: 5 4
Glapp Bavoritero- 2a. 025 we: ae near op aaron hr sa 3 5 4
GO OnCer conte ttace Mates Al Pro eon Tle seats 5 2
ilemaistime se pers eeckes areoate I Tes |eecaate ei be 5 2

In the above experiments the failure of some of the inoculated twigs
to blight was attributed to the hard and woody condition of the tissues,
rather than to any natural immunity on the part of the host. Varietal
inoculations on pears later in the season did not yield such a high per-
centage of infections. Some of the varieties had made a slower growth
than others and were not so readily attacked by the bacteria. In com-
paring tables 4 and 5, it is to be noted that the varieties included in both
are practically the same and that in Table 4 all are shown to be susceptible.

The later inoculations were made on July 8, with a five-days-old bouillon
culture of the same strain of Bacillus amylivorus as was used in other
experiments. The tenderest growth was chosen in every case and the
tip of a single shoot on each of three different trees was inoculated. The
condition of the twig as to succulence and tenderness was also recorded.

TABLE 5. VARIETAL INOCULATIONS OF BACILLUS AMYLIVORUS ON Two-YEARS-OLD
PEAR TREES. INOCULATIONS MADE JULY 8, I9I2

Number of infections and
dates on which they ap-
peared Total Total
a ——]| number | number
Variety Condition of shoots of inocu-lof infec-
July | July | July | July | lations tions
I2 13 14 16
Bets ite Tee ee Foye rae hove ua ra acon foes MENG har. acres ee A 3 fo) fo) oO 3 3
Sisvelkokovinig ous ls gameene Same es een Mendenweatns waite ne oO I 2 0 3 3
Wilreko esol Ojai h' Sateen eerie eee Medium tender..... I I oO (0) 3 2
AI ROUIEMER. |. seen. ue ment Medium tender..... 2 I o oO 3 3
ES earau lestitpa este pies Sot ec cwcnavce Penh Medium tender..... I ty) I iy 3 3
Glappatavoritesin acs <ucge wee Medium tender..... o I fe) o | 3 I
Wayiiastnlsao, jedtne + obi Oa eo mo Medium tender..... I 0 0 0 |} 3 I
(Cebitlolsrta ge a a ie eraeaeeee Gi odems - pie a Medium tender..... ca oO oO o | 3 I
Hard and woody.... (0) (6) fo) I a I
Hard and woody.... (0) I 0 to) 3 I
Hard and woody.... (a) (0) (6) (a) 3 fo)
Hard and woody.... (0) (6) (0) to) 3 (a)

354 BULLETIN 329

Natural resisiance-— As determined by the experiments, all varieties
of pome fruits tested were susceptible to blight when inoculations were
made during the period of most rapid development of the trees. Instances
may be cited, however, when certain varieties have shown to some degree
a natural freedom from the disease. In the summer of 1912 the blight
made its first appearance at one nursery during the first week in June,
affecting two rows of Transcendent (crab) at one end of a large block of
two-years-old apples. The disease was practically confined to this variety
for several weeks, spreading gradually to the three rows of Fall Pippin
adjoining the Transcendent. About the first part of July, with the appear-
ance of the tarnished plant bug the blight became epidemic and was
spread over one end of the block.

Bearing in mind that the varieties which suffered most were in the
vicinity where the disease first appeared, a few comparisons may be made.
Fall Pippin and Transcendent blighted badly. Other varieties severely
attacked were General Grant, St. Lawrence, Late Strawberry, Ontario,
Mann, and Smith Cider. The Martha (crab) immediately next to the
Transcendent blighted to only a slight extent, and the same is true of
Excelsior and Whitney. By virtue of their position, it is evident that
these varieties were for some reason less liable to blight as brought about
by natural infection.

Due to the fact that the athe varieties were somewhat removed from
the center of the epidemic, no definite statements can be made concerning
their liability to infection. From previous observations at different
times, it may be stated that in general the Yellow Transparent, Golden
Russet, Sutton, Alexander, Ralls, Fameuse, Wagener, Tompkins King,
Rhode Island, Baxter, and Rambo are more often affected than Baldwin,
Ben Davis, Red Astrachan, Oldenburg, and Gravenstein.

It is not possible, however, to place much reliance on differences mani-
fested by ccrtain varieties in their liability to blight. The behavior of
the trees toward the disease is no doubt greatly influenced by local con-
ditions. This point is well illustrated from observations recorded by
Crandall (1898) in Colorado. In a row of crabs, Martha and Whitney
alternating, the Whitney trees were all severely attacked by the blight
while not a single Martha tree blighted. It is interesting to note that in
the nursery the Whitney variety was observed by the writer to be practi-
cally free from the disease. The Martha also blighted to only a slight
degree, although this variety has been known to blight readily in other
localities.

Special inoculation experiments

Pathogenicity tests— March 31, r912. Inoculations of the nine cultures

growing in bouillon which were used for the cultural studies were made

(1898) Crandall, C.S. Blight and other plant diseases. Colorado Agr Exp. Sta. Bul. 41:3-14, 1808.

THE Fire Buiicut Disease In Nursery Stock any

into shoots of quince trees growing in the greenhouse. Two shoots
were inoculated with each culture. After ten days all inoculated shoots
showed infections except those inoculated with culture No. 2, on which
infections appeared one day later. It is of interest to note that culture
No. 7, from Colorado, appeared to be the most virulent, the infection
appearing after eight days; this culture gave the slowest reactions on
the cultural media. Practically no difference could be noticed in the
virulence of numbers 1, 3, and 4, which were cultures isolated in different
years from the same pear tree.

Blossom inoculations.— February 23, 1912. Ten blossoms on two-years-
old Yellow Transparent apple trees growing in the-greenhouse were sprayed,
by means of an atomizer, with a bouillon culture of Bacillus amylivorus.
The blossom parts were thoroughly moistened with the solution and the
blossoms were then covered for thirty-six hours with lamp chimneys
stoppered with cotton. Checks were run by spraying four blossoms
with sterile water. The checks were covered in the same manner as
were the other blossoms. After nine days the inoculated blossoms showed
symptoms of the disease, and after thirteen days the blight had not only
involved the pedicels but was apparent in the older and more woody
tissue of the blossom spurs. All the inoculated blossoms blighted; none
of the checks became diseased. °

March 8, 1912. Inoculations into quince blossoms on trees growing
in the greenhouse were. made as follows: A small piece of absorbent
cotton saturated with a bouillon culture of Bacillus amylivorus was placed
in each of four blossoms. Care was taken in the manipulation not to
injure any of the tissues. Two other blossoms were treated in the same
manner except that the cotton was saturated with sterile water instead
of with the culture of the organism. After ten days all the inoculated
blossoms were blighted and the checks remained healthy.

Biossoms were also caused to blight by gently brushing the nectarial
surfaces with a camel’s-hair brush that had been dipped into a bouillon
culture of Bacillus amylivorus.

Loss of virulence.— March 24, 1912. A culture of Bacillus amylivorus
that had been isolated from pear in the spring of 1911 was used for inoculat-
jing some young pear shoots on trees in the greenhouse. When the
infections appeared the organism was reisolated and obtained in pure
culture. Bouillon cultures of the recent reisolation and also of the original
culture isolated in 1911 were inoculated into different shoots on the same
pear tree. After four days the reisolated culture had produced an infection,
but the twigs inoculated with the old cultures did not show signs of the
disease until nine days after the inoculations. From these results it
appears that there is a tendency for the recently isolated cultures to be

356 BULLETIN 329

more virulent and that artificial propagation seems to reduce the
virulence to some extent.

Pathological histology

Historical.— Burrill (1881) appears to have been the first to study the
effects of Bacillus amylivorus on diseased tissues. He states that “ the
most conspicuous changes that can be observed by the aid of the micro-
scope, in the tissues affected with the blight, is the disappearance of the
stored starch.”’ He further states that ‘“ the cell walls are not dissolved
or altered in any way except by staining, which sometimes takes place
through oxidation, in the later stages of the disease.’”’ He observed that
the bacteria occupy the lumen of the cells in diseased tissue, but he found
it difficult to explain how they penetrated the cell wall. He further
observed that in the tips of apple twigs diseased with the blight, all the
tissues, even the xylem and pith, are invaded; but that in older limbs
only the bark is attacked and the outer bark, or cortex, is usually first
affected. The bast fibres are never diseased and the eambium frequently
escapes invasion.

Waite (1898) in more recent investigations, being unable to demonstrate
the diastatic action of the organism on starch, holds that “its principal
food consists of nitrogenous matter, sugars and probably, to some extent,
organic acids, the very substances which occur in vigorous young growing
tissues of the host.’’ Bacterial cavities of considerable size are often formed,
gorged with the viscid mass of the pathogen. Waite (’o6) states further
that ‘‘ very often it has progressed much farther in the bark of the branches
than appears on casual examination, for as a general rule it works only
in the bark, leaving the mature wood at first unharmed. The sap,
therefore, is able to continue to flow upward in the wood so that the leaves
and branches, though girdled and doomed to destruction, may still carry
their foliage or even mature their fruit.” Such a condition as Waite
describes may result in hyperplasia (Fig. 125) of the bark tissue above the
lesion or diseased area, due to the accumulation of products formed in
the metabolism of the tree. The girdling of the branch prevents the
conduction of the products downward beyond the point of lesion.

Tissues affected A microscopic examination of sections of young
diseased twigs shows a necrosis of the cells and a somewhat shrunken
condition of the tissue. The cells are plasmolyzed and stained brown;
the contents, having lost all semblance of organized cell contents, are
thick and amorphous. The blight bacilli are present in great numbers
~ (1881) Burrill, T. J. Blight of pear and apple trees. Rept. Illinois Industrial Univ. 10 : 62-84. 1881.
es ey se ieee es and characteristics of the pear blight germ. Proc. Amer. Assoc.

(‘06) Waite, M. B., and Smith, R. E. Pear blight. Ann. Rept. California Fruit Growers Assoc.
31 : 137-161. 1906.

Tue Fire Biicut DisEAsE IN Nursery Stock 357

in the intercellular spaces and to some extent within the cells. The
cortical parenchyma is most severely attacked. Sometimes the cambium
layer is affected. This is especially true of twigs in the more advanced
stages of the disease and in larger limbs and branches. The bacteria
may invade the pith and also the xylem tissue of young, tender shoots,
but apparently the organism does not migrate for any great distance
through these tissues.

After their introduction into the tissues through a wound or an insect
puncture, the organisms multiply
rapidly and extend in all direc-
tions from the point of entrance.
Although the lateral development
is often sufficient to girdle and
kill large limbs or even whole trees,
the spread of the organism upward
and downward is greater, often
being several meters. There is a
breaking and splitting apart of the
cells, with the formation of pockets
that are filled with bacteria sus-
pended in a sticky substance.
This gummy material is presum-
ably a mixture of the cell sap
and the decomposed substances of
the tissues that have been formed
in the metabolic processes of the
bacteria.

Frequently, with the active de-
velopment of the bacilli, ruptures
or fissures are produced and the Fic. 125.— Pear limbs girdled by fire blight
gummy material laden with the ETS, aS OD ea aN Oh he Sa
organisms fills these cracks in the
bark and oozes out as the characteristic exudation previously described
(page 323). The tissues around the lenticels are also invaded and
with the breaking down of the cells the bacterial exudation occurs through
these openings. In newly affected shoots the bacteria may invade
only a small area of the cortical parenchyma in their lateral develop-
ment, but proceed for some distance downward. On reaching a
lenticel, or with the formation of cracks or fissures, the exudation may
occur before any marked external symptoms of the disease are apparent.
This is especially true in young, tender shoots, when the progress of the
bacteria downward is very rapid.

358 BULLETIN 329

In a recent paper by Miss Bachmann (’13) the results are given of a
careful examination into the histological relations of host and parasite,
and several questionable points are cleared up with reference to the
migration of the organisms in the tissues. For these studies inoculated
blossoms of pear, water-shoots of apple, young pear seedlings, young
shoots of pear and plum, and fruits of pear and apple were used.

Miss Bachmann states that “‘ the first evidence of infection in the tissues
of the fruit or shoot is a transparency around the point of inoculation,
followed later by a browning in the same region.’ The transparency
is attributed to the removal of air from the intercellular spaces, this
being replaced by the liquid in which the bacteria live. By an examina-
tion of stained and unstained sections of inoculated tissues it was evident
that the large intercellular spaces of the cortex provide a ready path for
the migration of the organism. It was found also that the bacteria
enter the xylem tubes very readily near the apex of young shoots, and
frequently the tubes may be so packed with bacteria that transmission
of sap in such a region is apparently impossible. From the author’s
observations it is to be assumed that the entrance of the bacteria into
the xylem vessels is near the apex of the shoot and their presence in this
tissue at some distance below is due to their migration downward. The
greatest invasion of the xylem by the organism is always near the apex
of the shoot.

A study of inoculated green fruits also indicated that the bacteria
were most abundant in the intercellular spaces. The organisms seldom,
if ever, enter the cells —at least, not before the death of the tissues.
Miss Bachmann is of the opinion that the bacteria cause plasmolysis of the
cellular contents and that the cells die owing to the extraction of water
into the intercellular spaces, although chemical changes in the protoplast
may accompany this loss of water. Bacteria were frequently observed
between cells of tissue that still appeared perfectly normal. From this
condition Miss Bachmann concludes “ that the substances produced in
the metabolism of the organisms are not at all strongly or quickly toxic
in their effect on the cells.”” The film of liquid in which the bacteria
move is not extracted in such amount that it precedes the bacteria to
any extent. It is also considered possible to explain the broken walls
and the formation of cracks or fissures on a purely physical basis, and Miss
Bachmann suggests that ‘it may be that the osmotic pressure of the sub-
stance in which the bacteria are found is sufficiently great to rupture the
cell walls.”

Cavity formation.— The theory advanced by Miss Bachmann as an
explanation for the splitting of the cell walls does not appear to be entirely

(13) Bachmann, Freda M. The migration of Bacillus amylovorus in the tissues of the host. Phy-
topath. 3: 3-17. pls. I-Il. figs. I-2. 1913.

THe Fire Biicut DisEAsE IN Nursery STocK 350

satisfactory. It is difficult to conceive of any great osmotic pressure
being exerted in such tissues. By the killing of the protoplasm the plasma
membrane would become functionless and exhibit no further ability to
reject or permit the passage of certain substances through it. Under
such conditions, owing to the permeability of the cell wall, any pressure
exerted outside the cells, due to increased concentration of the solution
or to the excess extraction of water from the cells, would only cause the
solution to pass back into the dead ceils until an equilibrium would be
established, the pressure outside and inside becoming practically equal.
There might be a tendency to force the medium containing the bacteria
farther along in the intercellular spaces; but it does not seem to the writer
that a pressure due to osmosis could be created which would be strong
enough to rupture the cell walls.

In a general discussion of bacterial actions on the plant, Smith (11)
states that ‘“‘ the gum diseases rupture the bark and ooze extensively on
the surface. Pear blight does this also to a lesser degree. Some, perhaps
all, of this class of bacteria reach the surface through fissures due to surface
tensions set up in dead tissues by the parts still alive and growing.”’ Pres-
sure of sap in the tissues might be transmitted to diseased parts and favor
the exudation of the gum; or, due to increased growth of surrounding
healthy tissues, a tension might be developed sufficient to cause rup-
turing of the dead cell walls. Such a tension could not, however, be
correctly called surface tension. Surface tension, as such, could scarcely
be said to have any influence on the splitting apart of the cell walls.
The chief activity that could be attributed to it might be the rounding
up of the cell contents of the individual cells as they shrink and dry up
after plasmolysis.

It is probable that the above phenomenon of rupturing of the tissue
may be more closely associated with some toxic or enzymic reaction which
as yet is unknown. In view of some of the recent. work on enzymes it
seems natural to incline toward the enzymic theory.

Toxins.— With present knowledge it is impossible to state exactly
how the killing of the tissue is brought about. Arthur (1886) has shown
that solutions in which the bacteria were grown caused no rotting of
ereen fruits when filtered. He used the sterile filtrate of a strong solution
of blighted tissue for inoculating green pears. However, there always
remains the possibility that the toxin, or substance which affects the tis-
sues, may be destroyed (that is, absorbed by the filter or actually filtered
out) in the process of separation, and by the removal of the toxin no
deleterious effect on the tissue would be expected.

(7886) Arthur, J. C. Report of Botanist. Pear blight. Rept. New York (Geneva) Agr. Exp. Sta.
4 : 242-248. 1886.
(11) Smith, E. F. Bacteria in relation to plant diseases 2:69. I9QII.

360 BULLETIN 329

Following the method of study as outlined by L. R. Jones (’10)
in his work on the enzymic production of Bacillus carotovorus, an
attempt was made by the writer to isolate the enzymes produced
by Bacillus amylivorus. But all tests for the production of diastase
and the cell-wall-dissolving enzymes, pectinase and cellulase, proved
negative. *

An aqueous solution of the substance isolated apparently had no effect
on sections of pear and quince shoots. It is to be noted, however, that
the extractions were made only from bouillon cultures of the organism,
and under such conditions it is possible that the toxins or enzymes that
act on the tissues were not produced. It has been shown that the nature
of the culture medium in which an organism is grown exerts an important
influence in the production of certain enzymes. This point is especially
emphasized by the work of Knudson (11) on the production of the
enzyme tannase.

Miss Bachmann (’13), having observed fire blight bacteria in the
intercellular spaces of apparently normal tissue, concludes that the toxic
action of the products formed by the organisms is at least very slow.
It seems evident, however, that with the presence of the bacteria in the
intercellular spaces some toxic action is necessary in order to cause plas-
molysis of the protoplast, with resulting extraction of water from the cells.
The plasma membrane must be acted on in some way by a product formed
in the metabolism of the organisms. The phenomenon could hardly
be brought about by the action of the bacteria with products of the host
outside the cells, resulting in such an increased concentration of a sub-
stance that would cause plasmolysis of the protoplast. If there were a
tendency for increased concentration in this manner, the process would
be very gradual; and under such conditions, presumably the protoplasm
of the plant would be able to adjust itself to the change and there would
be no permanent plasmolysis. It is well known that the protoplasm is
often able to overcome partial plasmolysis caused by increased concen-
tration of solutions outside the cell. This is evident in the case of cells
of Tradescantia, which are able to recover when partially plasmolyzed
by a solution of glucose sugar. If allowed to remain in this solution, the
protoplasm will gradually adjust itself to the concentration and revert
to its normal condition. The writer is of the opinion that, in view of
the fact that only a limited amount of work has been done along this

* As previously mentioned (page 337), the cane-sugar-reducing enzyme, invertase, was isolated by the
above method.

(10) Harding, H. A., Morse, W. J., and Jones, L. R. The bacterial soft rot of certain vegetables.
Vermont Agr. Exp. Sta. Bul. 147 : 243-360. 1910.

(11) Knudson, Lewis. Regulatory formation of the enzyme tannase. Science n. s. 34 : 219-220.
IQII.

(13) Bachmann, Freda M. The migration of Bacillus amylovorus in the tissues of the host. Phy-
topath. 3: 3-17. pls. I-Il. figs. 1-2. 1913.

Tue Fire Biicnt DisEASE IN NURSERY STOCK 361

line of investigation, sufficient evidence has apparently not been produced
to warrant drawing definite conclusions as to exactly how the bacteria
affect the tissue.

Penetration of cell— Although in the majority of cases the greatest
invasion by the bacteria is in the intercellular spaces, they do occur in
the cells to some extent. As with many other bacterial diseases, it has
been impossible to demonstrate how the organism gains an entrance into
the cell. With no apparent openings in the cell wall that would permit
the passage of the bacteria, it may be assumed that the bacteria push
or dissolve their way through thin places in the wall or through pits by
mass action. In support of this view the following is quoted from Smith
(rr) in his discussion of the bacteria in the cells: “‘ The most striking
example, perhaps, is the voluminous intracellular occupation in the root
nodules of Leguminosae. Here the cells are often crowded with bacteria
with no visible opening for entrance. They seem to enter by mass action,
the bacteria being compacted into strands. Often there is a trumpet-
like expansion where the strand touches the cell wall. The writer has
seen what appears to him to be a similar dense occupation of unruptured
cells in the bark of the pear attacked by Bacillus amylovorus. The
particular tissue which shows this to best advantage is the pitted col-
lenchyma toward the outer part of the bark. Ina few cases it has seemed
as if bacteria could actually be traced from one cell into another across
a narrow pit, but of the absolute correctness of this view I have not yet
fully satisfied myself.”

In sections of quince and apple bark the compacted masses of bacteria
as mentioned by Smith have been observed also by the writer, but it
has not been possible to determine whether this is the manner in which
the bacteria enter the cell. There still remains the possibility that their
entrance is due to some toxic or enzymic action which as yet has been
overlooked.

CONTROL

_ From the time that fire blight-first became known, many recommenda-
tions have been given and experiments tried for control of the disease;
but previous to the discovery of the causal organism, little advancement
was made in checking the malady. When all was conjecture, with no
direct evidence available, no sharply defined treatment could be expected;
but with the classical works of Burrill, Arthur, Waite, and others, better
knowledge of the disease was obtained, and since the appearance of these
works more rapid advancement has been made in control of fire
blight.

(11) Smith, E. F. Bacteria in relation to plant diseases 2:77. IQII.

362 BULLETIN 329

TREE-FEEDING

Feeding the trees in order to make them immune, by the introduction
of various solutions into the sap, has not as yet been definitely proved
to be successful despite the claims of many manufacturerers of blight
remedies. Bolley (’04 and ’o7) also claims to have cured trees suffering
from blight by feeding them formalin and various other materials. It
is to be regretted, however, that no definite statements with regard to
the work have been published, except that positive results have been
obtained and that the treatment requires too careful manipulation to be
recommended to the general public.

SPRAYING

Spraying the trees with a fungicide is generally not considered effective.
The very nature of the method of introduction of the causal organism
into the trees precludes this in most cases as an effective means of pre-
vention. Apparently the bacteria are unable to penetrate the cuticle
of the host tissue, and can produce infection only when a means is afforded
for their entrance into the bark tissue through a wound or puncture.

It is to be noted, however, from the experiments in blossom infection
previously described, that no injury to the host tissue was necessary
when the bacteria were sprayed with an atomizer into the open blossoms.
Waite (1898) makes the following statement with reference to blossom
blight: ‘“‘ Beginning in the spring the germs on the new growth of the
season first appear on the nectar disks of the blossoms. The bacilli live
and multiply in the nectar and are able to enter the nectar glands without
a puncture or injury and thus normally get inside their host.”

It has been suggested that spraying into the blossoms* might
tend to decrease the amount of blossom blight, the fungicide serving as
a means of prevention when the bacteria are carried to the blossom by
insects. Unpublished observations made by Dr. Donald Reddick, of
this Department, seem to indicate that spraying might possibly be
effective in reducing the amount of blossom blight. On the other hand,
apple blossoms on trees growing in the greenhouse were susceptible to
blight when sprayed with lime-sulfur solution, 1-40, and the following
day sprayed with a bouillon culture of Bacillus amylivorus.

Eales See of New York it is a penal offense to spray vrhen the trees are in blossom. This law was
Dundl Usa. euevine fut eee wei poison, hey cencen who ell Giny Gi ae ee rr
poison or any poisonous substance to fruit trees while the same are in blossom, is guilty of a misdemeanor,
PiCisod) “Warts, MB. Lite titer? ead chacactedstcs af the pee Biche geeks Pacer Aone ee
Adv. Sci. 47 : 427-428. 1808.

oa) Bore, a L. Tree feeding and tree medication. Ann. Rept. North Dakota Agr. Exp. Sta.

4:5 9
poe Bolley, H. L. Tree feeding and tree medication. Ann. Rept. North Dakota Agr. Exp. Sta.
16 : 35. 1907.

I

Tue Fire Buicut DiszASE IN NuRSERY STOCK 363

PATENT NOSTRUMS

Certain manufacturers have placed blight remedies on the market,
but as yet none of these have proved of value; in fact, in most cases those
tested have been injurious to the trees themselves. The experiments
of Whetzel (09) with Callahan’s blight specific proves conclusively that
this substance is worthless as a blight remedy and even causes injury to
the trees.

During the summer of 1gro three blight remedies were tried in the
nursery, by the writer. California pear blight remedy, Warnock’s tree
paint, and Leffler’s insecticide and blight remedy were the substances
used. All were applied according to the directions given. Although the
experiment was not carried to completion and the treated trees were not
inoculated with the blight organisms in order to test their immunity, it
suffices to state that in every case the remedies proved injurious to the
trees. With the California pear blight remedy and the Leffler’s insecticide
and blight remedy applied in solution form to the soil, the two-years-old
Bartlett trees treated were stunted at the end of the season as compared
with untreated trees. In some cases part of the foliage fell prematurely.
The Warnock’s tree paint caused a splitting and cracking of the bark
and the trees were unsalable when dug in the autumn.

It is suggested that the general use of commercial blight remedies, at
least on nursery stock, be avoided except when tried experimentally on
4 small scale in order to test the value of the remedy.

GENERAL PLAN OF CONTROL

For the most satisfactory means of controlling fire blight, reference is
made to the plan of operation outlined in a bulletin by Whetzel and
Stewart (’o9). Strict sanitation and an attempt to eradicate the disease
from the locality affected are believed to be the most essential factors in
the control of the malady. All sources of infection should be destroyed.
A systematic inspection of all apple, pear, and quince stock should be
made early in the spring, and trees with hold-over blight should be
promptly removed and burned.

Old orchard trees of pear, apple, and quince in the vicinity of the nursery
usually favor the blight, in that frequently these large trees become diseased
and for years are sources of infection for nursery stock. Unless such trees
are given special attention and kept free from disease by strict control
methods, their presence is usually a menace to the nursery. Judging
from the experiences and observations of the writer, old neglected orchard

(09) Whetzel, H. H. Fire blight remedies. Proc. West. New York Hort. Soc. 54 : 119-126. 1909.
(oo) Whetzel, H. H., and Stewart, V.B. Fire blight of pears, apples, quinces, etc. New York (Cornell)
Agr. Exp. Sta. Bul. 272 : 31-52. 1909.

364 BULLETIN 329

trees should be removed from the vicinity of the nursery and every effort
should be made to keep the surroundings clean and free from sources of
disease. Old hawthorns and wild crab-apple trees along fence rows or
in near-by pastures frequently harbor the blight. Such trees should be
destroyed. Too much emphasis cannot be laid on the necessity for
a thorough and systematic cleaning-up of all diseased trees before growth
starts in the spring.

A regular inspection of all orchard trees should be made at least once
each week during the summer, beginning as soon as the blossoms fall.
Cut out all blighted twigs, shoots, and water sprouts, disinfect the cuts
with corrosive sublimate 1-1,0o00, and burn the prunings. If all cut
surfaces are disinfected, any bacteria left on them by the tools or any
brought to them subsequently by insects will be destroyed.

A thorough cleaning-up and removal of all sources of disease in the
early spring naturally reduces the possibility of blight infection in the
nursery. However, as previously pointed out, bees and other insects
frequently carry the bacteria from oozing hold-over cankers to the blossoms
that often appear on the two-years-old quince stock. Since the pro-
duction of fruit by such trees not only causes a stunted growth for the
tree, but also furnishes a source of infection at blossoming time, it is
considered good practice to pinch off or remove before they open all
blossom buds from the two-years-old quince trees.

CONTROL IN NURSERY STOCK

Inspection

The plan of operation described above was successfully performed in
two large nurseries in 1912. By the removal of the blossom buds it is
believed that an early epidemic of the disease was prevented. This
opinion is based on the fact that through oversight an occasional blossom
bud was missed and was allowed to open. Later several of these blos-
soms were blighted. The amount of blossom blight would doubtless
have been much greater if the blossom spurs had not been removed.

With the presence of the disseminating agents that greatly favor the
spread of twig blight, thorough and frequent inspections of all susceptible
stock become necessary in order to keep the disease under control. It is
often necessary to inspect certain blocks daily, the diseased twigs being
cut out as fast as they appear. In every case the cut surface should be
disinfected with corrosive sublimate 1-1,000. For the work of inspection
the equipment illustrated in Fig. 126 has proved very convenient. An
ordinary pruning knive is used for removing the diseased twigs, which
are carried away in a sack and burned. The supply of corrosive subli-

THE Fire Biicut DIsEAsE IN NuRSERY STOCK 365

mate can be carried in a bottle, and the sponge used for swabbing the
wound can be moistened from time to time.
With thorough and systematic inspections the number of new infections

can be reduced
greatly, and often by
prompt and careful
work in removing the
first infections an epi-
demic can be averted
completely. In cut-
ting out new infec-
tions it is advisable to
remove the entire
twig, making a clean
cut at the trunk; this
gives greater likeli-
hood that all the
blighted tissue has
been removed. Severe
pruning of the young
twigs of nursery trees
leads to a _ bushy
growth rather than
to the ordinary de-
velopment of long,
unbranched shoots.
When the infections
have progressed
rapidly down the twig,
extending into the
trunk of the tree, the
removal of the entire
tree is advisable.
When budded stock
of the first year be-
comes diseased the
blighted trees should

Fic. 126.— Cutting blight from nursery stock. Note the bag
for holding the blighted shoots, the hottle of corrosive
sublimate, and the sponge at the end of a string

be immediately grubbed out. Usually the bacteria are extremely
active in such tender growth and the greater part of the tree is soon
involved by the disease. Cutting back below the diseased area causes
a crook in the trunk of the tree and such stock can seldom be put on the

market.

366 BULLETIN 329

The plan of blight control as discussed with reference to the removal
of new infections under orchard conditions, as fast as they appear
throughout the summer, has been questioned by some investigators.
O’Gara ('o9) has offered special criticism to this procedure. He is of
the opinion that summer cutting is advisable where there is only a little
blight in the orchards, but under other conditions the work is only half
satisfactory. He makes the statement, apparently copied from a previous
article by Waite (’06), ‘‘ that summer cutting is generally a failure for
the reason that new infections, invisible at the time the work is done,
may develop in a few days, so that a week after the most thorough cutting
out of the blight a new crop of infection is found appearing.”

If badly blighted trees are given only occasional attention during the
summer, practically no satisfactory results in blight control can be
expected.

Data are presented in Bulletin 272 of the Cornell University Agricul-
tural Experiment Station, which indicate that thorough, frequent, and
systematic inspections of the pear orchard throughout the summer, with
immediate removal of any diseased parts, will prove effective, under
western New York conditions, in the control of fire blight. Observations
made by various members of the Department of Plant Pathology at
Cornell University, of practical attempts in control of fire blight, indicate
that when the above recommendations are closely followed pear orchards
may be saved.

The experience of Gammon (’12) indicates, further, that cutting out
the blight in summer is practicable also in the West, despite the claims
of some investigators who have worked in that section of the country.
The results of active effort for seven years in the control of the disease
in a large orchard in California were highly satisfactory. Careful prun-
ing and thorough disinfection throughout the summer greatly reduced
the annual loss of trees.

When the disease is once established its eradication is, as a rule, im-
possible. However, by inspection, as previously described, the blight
can be held in check not only in orchard trees but also in nursery stock.
Frequently the removal early in the season of a single blighted shoot will
prevent the loss of an entire tree. Cutting out infections not only pro-
tects the remainder of the tree, but also eradicates a source of infection
for neighboring trees.

In tables 6 and 7 are included a careful estimate of the number of
infections occurring in apples, quinces, and pears, and also the number

('06) Waite, M. B., and Smith, R. E. Pear blight. Ann. Rept. California Fruit Growers Assoc.
31: 137-161. 1906.

(‘o9) O’Gara, P. J. Control of pear blight on the Pacific coast. Ann. Rept. Washington State Hort.

Assoc. 5 : 36-55. 1909.
(12) Gammon, E. A. Pear blight control. Calif2rni1 Hort. Com. Mo. Bul. 1: 37-41. 1912.

THE FirE BiicHut DIsEASE IN NURSERY STOCK 367

of blighted trees removed, in two of the larger nurseries in New York
State. In each nursery were about 150 acres of apple, quince, and pear
stock. This work in nursery control was conducted during the summer
of 1911, which was an epidemic year for the blight over the entire State.
Frequent. inspections were made and a record was kept of the number of
infections cut out and the number of trees removed on each inspection.
In blocks where the disease was very abundant — as, for example, among
the two-years-old quinces — daily inspections were made until the blight
subsided. Some blocks of two-years-old apples and pears were not in-
spected more than once every four or five days.

The greater abundance of blight in nursery A, as recorded in Table 6,
is attributed to the fact that, with the presence of a large number of
hold-over cankers on trees that had blighted in the previous year, a greater
amount of blossom infection occurred in the two-years-old quinces.
On the first day of inspection over two thousand blighted blossom spurs
were removed. This condition naturally furnished an abundant source
of infection for the blocks of apples and pears near by. In nursery B
all hold-over blight had been cleaned up and the blossom infection of the
quinces was not so abundant. Under such conditions the possibilities of
checking the malady were more favorable.

TABLE 6. NuMBER OF INFECTIONS AND NUMBER OF TREES REMOVED, NursERY A

Number Number

Kind of stock of of trees

infections cut out
JSD. E (2) WICENSU UG Da a 540 40
ASOT EUG oN geti, (016) ey gga 1,700 800
Wiimnces CmvedrsrOlG)\riact osc tse wate si wsdes es be nee sees 3,500 290
PSS: (OS Saree I ae en a None None
Pema standard 2 years old)... : 0.0... tees Bees tenon 95 None
eeramaMete Dev CaTS Old). Cc cg cue eee os oa ane uawen 524 10
Feeeitan (IMC CUM OL) era deae ct oct uate e Licta ors bieectie's kates wee None None
Tia ah, 2B ee Ean a ae Rs: Dn a ee Re arn 6,359 1,140

TABLE 7. NUMBER OF INFECTIONS AND NUMBER OF TREES REMOVED, NuRSERY B

Number Number
Kind of stock of of trees |
infections cut out
AEM AESIS GI) 5 rn ar i a a 10 3
AV OSE (UTE er 76) (6 2) 5 Ee ea a a 69 30
LDL CE 2" Saas (0106 9 ae Re 236 25
SSL E 1 Sie ai) I aa a rr 145 40
Nee UNMET RCL ONY Ce ne Oko or oa )s 502 We oesly. weaves ew Ce None None
ae Rare emm eee Ss er A ee re oer A5 12

368 BULLETIN 329

It is evident from the above figures that a large percentage of the
infected trees were saved by prompt pruning and disinfection before the
disease involved the entire tree. This, of course, does not include the
large number of other trees that were entirely protected from the disease
by removal of the blighted trees and shoots that would have served as
sources of infection had they been left.

The four years of work for blight control in the nursery lead the writer
to believe that it is highly profitable to give careful attention to fire blight.
Eradicating the hold-over blight, removing quince blossom buds, and
inspecting diseased areas systematically will reduce the abundance of the
disease, without question.

Destruction of insect agents

The elimination of certain disseminating agents is an important con-
sideration. It has been demonstrated that controlling the aphids is
frequently an essential step in preventing the spread of the blight bacteria.
The greatest necessity at the present time, however, is a means of
eradicating from the nursery the numerous sucking insects that occur on
stock that is susceptible to fire blight. Of these blight disseminators the
tarnished plant bug (Lygus pratensis) appears at the present time to be
the most important.

BIBLIOGRAPHY

The following bibliography is by no means complete. However, it
includes practically all articles that are of importance. A large number
of citations have been omitted because, on consultation, they have been
found to be of slight consequence or to contain no points of advance in
the knowledge of the disease.

Adametz, L. Mikrococeen. Mikrococcus amylovorous Burrill. Mitt.
(Est. Vers. Stat. Brau. u. Malz. 1: 30. 1888.

Arthur, J.C. Diseases of pear. Pear blight. Rept. New York (Geneva)
Aer. Bap Shas 3 3357-307... boos.

Pear blight and its cause. Amer. Nat. 19: 1177-1185. 1885.

Proof that bacteria are the direct cause of the disease in trees

known as pear blight. Proc. Amer. Assoc. Adv. Sci.*34: 295-298.

1885.

Pear blight, cause and prevention. Ann. Rept. New Jersey
Hort. Soc. 1885: 1-16. 1886.

Report of Botanist. Pear blight. Rept. New York (Geneva)
Agr. Exp. Sta. 43 242-248. 1886.

History and biology of pear blight. Proc. Philadelphia Acad.
Nat. Sci. 38: 322-341. - 1887.

Pear blight. Rept. New York (Geneva) Agr. Exp. Sta. 5: 275-
290.4. 1087.

Important articles on pear blight. Rept. New York (Geneva)
Agr. Exp. Sta. 5: 300-315. 1887.

THE Fire BLiGHT DISEASE IN NuRSERY STOCK 360

Bachmann, Freda M. The migration of Bacillus amylovorus in the
tissues of the host. Phytopath. 3: 3-17. pls. I-I. figs. 1-2. 1913.

Barry, Patrick. Insect blight. Genesee Farmer 8: 218. 1847.

Beecher, H. W. The blight in the pear tree: its cause and a remedy for
it. Mag. Hort. 10: 441-456. 1844.

Bolley, H. L. Tree feeding and tree medication. Ann. Rept. North
Dakota Agr. Exp. Sta. 14: 55-58. 1904.

Tree feeding and tree medication. Ann. Rept. North Dakota
Aer Bp. Sta. 162 35. 1907.

Burrill, T. J. Pear blight. Trans. Illinois State Hort. Soc. 11: 114-116.
1878.

Fire blight. Trans. Illinois State Hort. Soc. 12: 77-81. 1879.
Anthrax of fruit trees: or the so-called fire blight of pear and
twig blight of apple trees. Proc. Amer. Assoc. Adv. Sci. 29: 583-597.
1881.

Pear and apple tree blight. Trans. Illinois State Hort. Soc. 14:
ES7—107. Loot.
Bacteria as a cause of disease in plants. Amer. Nat. 15: 527-531.

1881.

Blight of pear and apple trees. Rept. Illinois Industrial Univ.
10: 62-84. 1881.

Have we any new light on pear blight or yellows? Rept. Michigan
State Hort: Soc. 1881: 133-139. 1882.

New species of Micrococcus (Bacteria). Amer. Nat. 17: 3109.

1883.

Pear blight and peach yellows. Trans. Illinois State Hort. Soc.
ive. A0-AG.) -1Sd4.

Chester, F. D. Notes on pear blight. Ann. Rept. Delaware Agr. Exp.
Ota. 12: 38-46. © 190r.

Pear blight and pear canker. Delaware Agr. Exp. Sta. Bul. 52:

27s) SEQOE.

Treatment of pear blight cankers and inoculations. Ann. Rept.
Delaware Agr. Exp. Sta. 14: 40-43. 1903.

Cook, A. J. Pear blight and bees. California Cultivator 17 : 83-84.
IQOl.

Cooke, S.S. Pear blight. Gardeners Monthly 9: 73-78. 1867.

Coxe, William. Cultivation of fruit trees. Pear blight, 175-176. 1817.

Craig, J. Diseases of fruits. Apple and pear blight. Rept. Canada Exp.
Farms 1896: 168-171. 1897.

Crandall, C. S. Blight and other plant diseases. Colorado Agr. Exp.
ota. Bul. 41: 3-14. 1808.

Denning, William. On the decay of apple trees. Trans. New York
Soc. Prom. Agr. Arts and Manfr. 1? : 219-222. 1794. [Second edition
Pe s@o5-187; r8or.|

Eaton, L. C. Review of opinions of pear tree blight. Hort. 1: 459-463,
495-500. 1846.

Edwards, S. F. Bacterial diseases of fruits and vegetables. Bacterium
amylovorus. Ann. Rept. Ontario Agr. Col. 32: 136-137. 1907.

Ernst, A: H., and Downing, A. J. Fire blight in pear trees. Hort. 2:
220-332 ae Todo.

370 BULLETIN 329

Fulton, H. R. The persistence of Bacillus amylovorus in pruned apple
twigs. Phytopath. 1:68. rog1tr.

Gammon, E. A. Pear blight control. California Hort. Com. Mo. Bul.
T5374, LOU:

Gookins, S. B., and Downing, A. J. Remarks on pear blight of the West.
HMOrt.r s253—-260.-< 1546.

Halsted, B. D. Report of Botanist. Experiments with pear blight.
Rept. New Jersey Agr. Exp. Sta. 19: 352-354. 1899.

Report of Botanist. Experiments with pear blight. Rept. New

Jersey Agr. Exp. Sta. 20: 414-417. Igoo.

Report of Botanist. Experiments with pear blight. Rept. New
Jersey Agr. Exp. Sta. 22: 430-433. 1902.

Hull, E. B. Cryptogamous diseases and root pruning of the pear, a pre-
ventive of blight. Trans. Illinois State Hort. Soc. 1868: 35-37. 1869.

Isaac, John. Pear blight in California. Rept. California State Board
Hort 8: 53-05. — 1002.

Jackson, H. S. Fire blight of pear and apple. Oregon Agr. Exp. Sta.
ir. 7 2-16; “16970:

James, J. H. Blight in pear trees. Mag. Hort. 15: 13-23. 1849.

Jones, D. H. Bacterial blight of apple, pear, and quince trees. Ontario
Aor Col, Bul- 276: 1-63: 1900.
Scolytus rugulosus as an agent in the spread of bacterial blight
in pear trees. Phytopath. 1:155-158. pls. XXUI-XXIV. 1og1t.
Jones, L.R. Studies on plum blight. Centbl. Bakt. u. Par. 2, 9: 835-841.
1902.

Jones, L. R., and Morse, W. J. Orchard diseases and their remedies.
Plum blight. Rept. Vermont Agr. Exp. Sta. 15: 231-239. Igo2.

Lawrence, W. H. Important diseases of Washington. Fire blight.
Washington Agr. Exp. Sta. Bul. 83: 19-21. 1907.

Lowell, John. Pear blight. New England Farmer 5: 17-18, 42. 1826.

Meehan, Thomas, and Hunt, J. G. Pear blight. Gardeners Monthly 17:
DAC TOS.

Morse, W. J. Diseases of plants. Crotch injury caused by weather con-
ditions. Maine Agr. Exp. Sta. Bul. 164: 18-19. 1908.

O’Gara, P. J. Control of pear blight on the Pacific coast. Ann. Rept.
Washington State Hort. Assoc. 5: 36-55. 19009.

Control of pear blight on the Pacific coast. Better Fruit 57:
49-51, 54-50; 5°: 30-43, 52-57. IgTo.

Orton, W. A. Plant diseases in the United States in 1901. Pear blight.
U.S. Dept. Agr. Yearbook 1901: 669. 1902.

Disease resistance in plants. Ann. Rept. Amer. Breeders Assoc.
I: 202-207. 1905.

Paddock, Wendall. An apricot blight. Colorado Agr. Exp. Sta. Bul. 84:
5-14. 1903.

An old orchard disease in a new role. Fire blight of apricot.
Ann. Rept. Colorado Board Hort. 15: 75-77. 1904.

Pierce, Newton B. Pear blight in California. Science n. s. 16: 193-194.
1902.

Sa W. G. Bacterial diseases in plants. Pear blight. Michigan
Agr: Exp. Sta. Bul. 230; 205-210. 1905,

Tue Fire Biicut Disease In Nursery Stock Aux

Some bacterial diseases of plants. Pear blight. Colorado Agr.

Exp. Sta. Bul. 138: 6-14. 1909.

Hold-over blight in the pear. Colorado Agr. Exp. Sta. Bul. 177:
2-85 S010.

auiebaee H. Pear, apple, and peach trees affected with blight.
Ohio Agr. Rept. 1863: 450-460, 469. 1864.

Shear, F. C. Apple twig blight. Garden and Forest 9: 467-468. 1806.

Smith, E. F. Bacteria in relation to plant diseases 1:1-285. 1905; 2:
q—2Gloe) 2 EOd E,

smith, E. F., Brown, Nellie A., and Townsend, C. O. Crown-gall of
plants: its cause and remedy. Crown-gall followed by hold-over
bien. US. Dept. Agr., Bur. Plant Indus, Bul..213>186.. torr.

Smith, R. E. Report of Plant Pathologist. Pear blight. California
Agr. Exp. Sta. Bul. 184: 221-232. 10906.

Report of Plant Pathologist. Pear blight. California Agr. Exp.
Stas bul, 203: 18-24. T1909.

Smith, R. E., and Smith, Elizabeth H. California plant diseases. Pear
blight. California Agr. Exp. Sta. Bul. 218: 1154-1155. 1ro1t.

Snyder, Lillian. A bacteriological study of pear blight. Proc. Amer.
Assoc. Adv. Sci. 47: 426-427. 1808.

Stewart, J. P. Factors influencing yield, color, size, and growth in apples.
Relation of fertilization to fire blight. Rept. Pennsylvania Agr. Exp.
Sta. IQIO-IQII: 467. 10912.

Taylor, W. A. Pear blight. Science n. s. 15: 990-991. 1902.

Trevisan di Saint-Leon, Vittore. I generi e le specie delle batteriaceac,
prodromo sinottico. Milano, 1-36. 1889.

Waite, M. B. A remedy for pear blight. Science n. s. 1: 721. 1895.

Cause and prevention of pear blight. U.S. Dept. Agr. Year-

book 1895: 295-300. 1896.

Fungous diseases of the apple and pear. Proc. Michigan Hort.

Soc. 1897: 186-191. 1808.

Life history and characteristics of the pear blight germ. Proc.

Amer. Assoc. Adv. Sci. 47: 427-428. 1808.

Relation of bees to the orchard. California Cultivator 18:

390-391. 1902.

A new native host for pear blight. Science n. s. 25: 286-287.

IQO7.

Waite, M. B., and Smith, R. E. Pear blight. Ann. Rept. California
Fruit Growers Assoc. 31: 137-161. 1906.

Whetzel, H. H. The blight canker of apple trees. New York (Cornell)
Agr. Exp. Sta. Bul. 236: 104-138. 1906.

Fire blight and apple tree canker. Ann. Rept. Wisconsin Hort.

Soc. 36: 215-226. 10906.

Fire blight remedies. Proc. West. New York Hort. Soc. 54:
TIO=126:-~- Dead:

Whetzel, H. H., and Stewart, V. B. Fire blight of pears, apples, quinces,
etc. New York (Cornell) Agr. Exp. Sta. Bul. 272: 31-52. 1909.

Whipple, O. B. Pear blight. Colorado Agr. Exp. Sta. Bul. 118: 7—9.

1907.
Woods, A. F. The wastes of the farm. Pear blight.. U.S. Dept. Agr.
Yearbook 1908: 209. 19009.

JUN 9

CORNELL UNIVERSITY AGRICULTURAL,
EXPERIMENT STATION

THE FOLLOWING BULLETINS AND CIRCULARS ARE AVAILABLE FOR DISTRIBUTION TO
THOSE RESIDENTS OF NEw YorkK STATE WHO May DEsIRE THEM

266
272
273

283

285
286
289
291
292

205
297
208
302

303
305
307
309

WNIO COWH

Leni on!

BULLETINS
The black rot of the grape and its control 310
Fire blight of pears, apples, quinces, etc. 313
The effect of fertilizers applied to timothy
on the corn crop following it 314
The control of insect pests and plant 316
diseases 317
The cause of ‘* apoplexy’’ in winter-fed lambs
The snow-white linden moth 318
Lime-sulfur as a summer spray 320
The apple red-bugs
Cauliflower and brussels sprouts on Long 321
Island 322
An agricultural survey of Tompkins county 323
Studies of variation in plants
The packing of apples in boxes 324
Notes from the agricultural survey in
Tompkins county
The cell content of milk 325
The cause of ‘‘ apoplexy’’ in winter-fed lambs 327
An apple orchard survey of Ontario county 328
The production of ‘*hothouse’’ lambs
CIRCULARS
Testing the germination of seed corn 14
Some essentials in cheese-making I5
The elm leaf-beetle 16

Orange hawkweed or paint-brush

The chemical analysis of soil

Propagation of starter for butter-making
and cheese-making ~

Address

372

Soy beans as a supplementary silage crop

The production of new and improved vari-
eties of timothy

Cooperative tests of corn varieties

Frosts in New York

Further experiments on the economic value
of root crops for New York

Constitutional vigor in poultry

Sweet pea studies—III. Culture of the
sweet pea

Computing rations for farm animals

The larch case-bearer

A study of feeding standards for milk pro-
duction

A study of the biology of the apple mag-
got (Rhagoletis pomonella), together with
an investigation of methods of control

Cherry fruit-flies and how to control them

Methods of chick-feeding

Hop mildew

Working plans of Cornell poultry-houses
Legume inoculation .
The improved New York State gasoline-
heated colony-house brooding system
(Departmentof Animal Husbandry circular)
The formation of cow-testing associations

MAILING ROOM
COLLEGE OF AGRICULTURE

ITHACA, N. Y.

F INGRESS

wi

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