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LIBRARY

"bSSSfe^1 OF TKE

UNITED STATES
DEPARTMENT OF AGRICULTURE

Class L

_ Book£d/J2^H

Bui. 92, Bureau of Entomology, U. S. Dept. of Ag'icuiture.

Plate I.

Fig. 1.— Orange Covered with Sooty '.

Fig. 2.— Leaf of Orange Coated with Sooty Mold.

'/

n?

U. S. DEPARTMENT OF AGRICULTURE,
BUREAU OF ENTOMOLOGY— BULLETIN No. 92.

L. O. HOWARD, Entomologist and Chief of Bureau.

A3 63V

WHITE FLIES INJURIOUS TO CITRUS
IN FLORIDA.

•' 0.

r°n. J of A/

A. W. MORRILL, Ph. D.,

AND

E. A. BACK, Ph. D.

a ?<«*

Issued July 12, 1911.

z%

WASHINGTON:

GOVERNMENT PRINTING OFFICE.

1911.

BUREAU OF ENTOMOLOGY.

L. 0. Howard, Entomologist and Chief of Bureau.
C. L. Marlatt, Entomologist and Acting Chief in Absence of Chief.
R. S. Clifton, Executive Assistant.
W. F. Tastet, Chief Clerk.
F. H. Chittenden, in charge of truck crop and stored product insect investigations.
A. D. Hopkins, in charge of forest insect investigations.
W. D. Hunter, in charge of southern field crop insect investigations.
F. M. Webster, in charge of cereal and forage insect investigations.
A. L. Quaintance, in charge of deciduous fruit insect investigations.
E. F. Phillips, in charge of bee culture.

D. M. Rogers, in charge of preventing spread of moths, field work.
Rolla P. Currie, in charge of editorial work.
Mabel Colcord, librarian.

cod

LETTER OF TRANSMITTAL

United States Department of Agriculture,

Bureau of Entomology,
Washington, D. C, March 2, 1911.

Sir: I have the honor to transmit herewith, for publication as
Bulletin 92 of the Bureau of Entomology, a manuscript prepared by
Drs. A. W. Morrill and E. A. Back, dealing with the life history of
the white flies injurious to citrus trees in Florida.

The investigation of the citrus white flies in Florida, under the
general direction of the assistant chief of this bureau, Mr. C. L. Marlatt,
was begun in 1906, and is now approaching completion. There has
already been published a bulletin (No. 76) dealing fully with the
general subject of fumigation with hydrocyanic-acid gas for the white
fly. A circular (No. Ill) has also been issued, giving brief directions
for winter fumigation.

The present publication is a general account of the two species of
white flies which are of special economic importance to the citrus
grower in Florida. The publication includes the history of these
insects in the United States, their distribution and food plants, and
a very detailed study of the habits and life cycle of the two species.
A great deal of painstaking and minute work has been done, and the
information secured furnishes an accurate foundation for the develop-
ing of the best means of control.

Supplementing this publication, which deals largely with life his-
tory and habits, it is proposed to publish a bulletin on control by
sprays, fungi, and other enemies, and to supplement or reissue in
revised form the bulletin dealing with fumigation.
Respectfully,

L. O. Howard,

Entomologist and Chief of Bureau.
Hon. James Wilson,

Secretary of Agriculture.

CONTENTS.

Page.

Introduction 9

Species of white flies affecting citrus 10

The citrus white fly (Aleyrodes citri R. and H.) 11

Historical review 11

Origin i 11

Early history in the United States 12

Literature 14

Injury 17

Nature of injury 17

Loss of sap 17

Sooty mold 17

Extent of injury 19

Injury to fruit 19

Injury to trees 23

Summary of losses 23

Increased cost of maintenance 24

Distribution 25

In the United States 25

In foreign countries 27

Food plants 28

Authentic and questionable records 28

Economic significance of food plants and interrelationship between

food plants and insects 31

Citrus 32

China trees and umbrella trees 34

Cape Jessamine 39

Privet hedges 40

Japanese and wild persimmons 41

Lilac 42

Prickly ash 42

Coffee 43

Occasionally infested food plants 43

Spread in the United States 43

Checks on successful establishment 43

Flight of adults 44

Winds 48

Vehicles, railroad trains, and boats 48

Citrus nursery stock and ornamental plants 49

Accidental spread by man 50

Life history and habits 51

Summary 51

Methods of study 52

The egg 53

Description 53

Duration of egg stage 54

5

6 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

The citrus white fly — Continued. Page.

Life history and habits — Continued.
The egg — Continued.

Parthenogenesis 57

Hatching 57

The larval and pupal stages 58

Description of stages 58

Duration of stages 62

Locomotion 63

Growth 64

Molts 64

Feeding habits of larvae and pupae 65

The adult 65

Description 6£

Emergence 67

Duration of life 71

Mating 71

Oviposition 72

Proportion of sexes 77

Influence of weather conditions on activity of adults 78

Feeding habits of adults 78

Multiplication 79

Length of life cycle 80

Seasonal history 81

Generations of the citrus white fly 81

Seasonal fluctuations in the numbers of adults or so-called "broods".. 84

The cloudy- winged white fly (Aleyrodes nubifera Berger) 86

History 86

Amount of injury by the cloudy-winged white fly 87

Distribution 89

Food plants 90

Spread 90

Life history and habits 91

The egg 91

The larval and pupal stages 94

The adult 98

Length of life cycle 100

Seasonal history 101

Generations of the cloudy-winged white fly 101

Seasonal fluctuations in numbers of adults or so-called "broods " 102

Index 105

ILLUSTRATIONS

PLATES.

Page.
Plate I. Fig. 1. — Orange covered with sooty mold. Fig. 2. — Leaf of orange

coated with sooty mold Frontispiece.

II. Fig. 1. — Aleyrodes mori on mulberry. Fig. 2. — Woolly white fly
{Aleyrodes howardi) on orange. Fig. 3. — Paraleyrodes persese on
orange. Fig. 4. — Woolly white fly (Aleyrodes howardi) showing
eggs in circles, and adults. Mg. 5. — Aleyrodes sp. on sea grape. . . 10

III. Fig. 1. — Sooty mold on orange following white-fly attack; broken and

falling from leaf. Fig. 2. — Sooty mold on cinnamon tree following
attacks by cinnamon scale 18

IV. Fig. 1. — China tree defoliated during winter. Fig. 2. — Same tree in

full foliage in summer 34

V. Fig. 1. — Leaflet of umbrella China tree showing infestation by A.
eitri. Fig. 2. — Umbrella China tree infested by A. citri, showing
orange trees in rear of house 34

VI. Fig. 1. — Nursery citrus trees infested with white flies, set out in an
isolated noninfested grove without having leaves removed. Fig.
2. — Buggy in an orange grove; buggy-top full of adult white flies
ready to be carried to other groves. Fig. 3. — Train at station; adult
citrus white flies swarming from near-by umbrella China tree into
coaches ready to be carried for miles down the Florida east coast. . 48
VII. Fig. 1. — Rearing cages in position on orange trees. Fig. 2. — En-
larged rearing cage 52

VIII. Fig. 1. — Leaf showing pupa cases of A. citri; also pupae and eggs.
Fig. 2. — Leaf showing heavy infestation by A. citri. Fig. 3. —
Leaf showing pupa cases of A. nubifera 62

IX. Fig. 1. — Tender shoot swarming with adult citrus white flies. Fig.

2. — Leaf of same, enlarged 66

X. Fig. 1. — Adults of A. nubifera, the cloudy-winged white fly, and
many eggs scattered over leaf. Fig. 2. — Larvae and pupae of both
the citrus white fly and cloudy- winged white fly killed by fumi-
gation, and eggs of the citrus white fly along midrib 98

TEXT FIGURES.

Fig. 1. Map showing distribution of the citrus white fly (Aleyrodes citri) in

Florida 26

2. Diagram of laboratory grounds at Orlando, Fla 37

3. The citrus white fly: Eggs 53

4. The citrus white fly: Larva, first instar, dorsal view 59

5. The citrus white fly: Larva, first instar, ventral view 59

6. The citrus white fly: Antenna and left hind leg; first instar larva 59

7. The citrus white fly : Larva, second instar, ventral view 60

8. The citrus white fly : Larva, third instar, ventral view 60

7

8 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

Page.

Fig. 9. The citrus white fly : Pupa and details 61

10. The citrus white fly: Adult and details 66

11. Diagram showing annual generations of the citrus white fly 82

12. Diagram showing abundance of adults of the citrus white fly at Or-

lando, Fla., throughout 1909 84

13. Map showing distribution of the cloudy- winged white fly (Aleyrodes

nubifera) in Florida 90

14. The cloudy-winged white fly: Eggs 91

15. The cloudy- winged white fly: Larva, first instar, ventral view 94

16. The cloudy- winged white fly : Larva, third instar, ventral view 95

17. The cloudy- winged white fly: Pupa and details 95

18. The cloudy- winged white fly: Dorsal view of pupa, showing adult

insects about to emerge 95

19. Diagram showing relative abundance of adults of the cloudy- winged

white fly and the citrus white fly, throughout 1909. at Orlando. Fla. . 103

WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

INTRODUCTION.

The present bulletin includes the principal results of studies of the
two species of white flies most destructive to Citrus in the United
States, commonly known as the citrus white fly (Aleyrodes citri ~R.
& H.) and the cloudy- winged white fly (Aleyrodes nubifera Berger).
With these pests successful control measures must be based on a
complete understanding of the insects themselves. On this account
the study of the insects, their life history, seasonal history, habits,
food-plant relationships, and related topics has occupied an unusually
important position in the white-fly investigations.

The authors have concluded that unless natural enemies capable
of controlling the two white-fly pests are existent and are secured,,
control measures will require permanent expert supervision for the
most satisfactory and economical results — not supervision of work in
individual citrus groves, but supervision aimed principally to prop-
erly correlate individual efforts and to take full advantage of favoring
local conditions. For supervision of this nature, a good foundation
of extensive and reliable studies of the insects is necessary. While
the portion of the white-fly investigations herein reported is com-
paratively extensive, it is necessarily not exhaustive and in the
course of time certain features of this work can undoubtedly be con-
tinued with profit as an aid to the future improvement of control
measures.

The white-fly investigations now in progress were begun in July,
1906, by the senior author, who was in field charge up to the time of
his resignation from the bureau in August, 1909, The junior author's
connection with these investigations dated from June, 1907. The
life-history studies of the first two years have been largely superseded
by the more extensive work of the third year. Practically all of the
data presented under the subjects of the life history and habits and
the seasonal history of each species are based on studies by the junior
author and were written by him. The remainder of the bulletin was
written by the senior author.

9

10 WHITE FLIES INJURIOUS TO CITRUS IX FLORIDA.

SPECIES OF WHITE FLIES AFFECTING CITRUS.

Twelve species and one subspecies of the family Aleyrodidse are
known to breed upon citrus. The list of these insects, the authority
for the original description, the recorded distribution, and the food-
plant records are given in Table I :

Table I. — Aleyrodidse that breed upon citrus.

Species.

Described by-

Occurrence.

Food plants other than
citrus.

Aleyrodes citri (syn.
rantii).1

Aleyrodes floccosa

Aleyrodes floridensis.

Aleyrodes giffardi .
Aleyrodes howardi

Aleyrodes marlatti

Aleyrodes mori

Aleyrodes mori arizonensis
Aleyrodes nubifera

Aleyrodes spinifera

Aleyrodes struthanthi .

Aleyrodes vitrinellus 2
Paraleyrodes persese. .

Riley and

ard.
Maskell....
Quaintance .

How-

Kotinsky...
Quaintance.

....do...
do...

Cocker ell.
Berger...

Quaintance .
Hempel

Cockerell —
Quaintance.

North and South America,
Asia, Japan.

Mexico, Jamaica

United States ( Florida)

Hawaii

Cuba, United States (Flor-
ida).

Japan

United States (Florida)...

United States (Arizona) . . .

United States (Florida,
Louisiana), Cuba.

Java

Brazil

Mexico

United States (Florida)....

See list, p. 29.

Guaiacum officinale.
Persea gratissima (alligator

pear), Psidium guajava

(guava).
None recorded.
Do.

Do.
Mulberry, sweet gum, etc.
None recorded.
Ficus nitida.

Rosa spp.

Michelia flava, Loranthus
(struthansus) flexicaulis.
None recorded.
Do.

1 Mr. A. L. Quaintance, after careful comparison of material from Maskell's collection, evidently type
material, with A . citri, concluded that Maskell's aurantii was the same as Riley and Howard's citri. Through
the kindness of Mr. Quaintance the authors have had an opportunity to examine the material referred to
and agree with him in considering aurantii a synonym of citri.

2 There seems to be some doubt as to the idehtity'of the food plant of this species, for in connection with
the description the authority for it gives the following food plant record: " On the under side of leaves which
appear to be those of orange."

Of the Aleyrodidse referred to above, A. citri, A. giffardi, A. howardi
(PL II, figs. 2, 4), and A. nubifera are known to be orange pests or
capable of becoming orange pests. A. floridensis, A. mori (PL II,
fig. 1), A. mori arizonensis, and Paraleyrodes persese (PL II, fi.g. 3)
apparently -are not likely to cause injury to citrus, while the remainder
of those listed are doubtful in this respect.

Paraleyrodes persese is found in all sections of Florida and is fre-
quently quite abundant, but in only one instance has it been known
to cause blackening of the foliage of citrus trees. This was in the
winter of 1906-7 and occurred in a pinery where in one section citrus
nursery trees were being grown. In the course of two or three months
after being first noticed the insects were reduced to the point of
scarcity through parasitism by a new species of Encarsia, winch
Dr. L. O. Howard has described under the name of Encarsia variegata.
Observations extending over three years indicate that this parasite
will effectively control P. persese and that it is unlikely that tins
aleyrodid will ever cause noticeable injury under ordinary conditions.
It is, however, possible that the appearance of a prolific hyperparasite
of Encarsia variegata might seriously interfere with the present equi-
librium hi nature.

il. 92, Bureau of Entomology, U. S. Dept of Agriculture.

Plate II.

Florida White Flies Mistaken for Citrus and Cloudy-Winged White Flies.

Fig. 1.— Aleyrodes mo
Fig. S.—Paraleyrod,

ing eggs in circles and adults. Fig. 5. — Alcyrodcs sp. on sea grape. * (Original.)

n mulberry. Fig. 2.— Woolly white fly (Alcyrodcs howardi) on orange.
persess on change. Fig. 4.— Woolly white fly (Alcyrodcs howardi), show-

THE CITKUS WHITE FLY: HISTORICAL REVIEW. 11

The woolly white fly (Aleyrodes howardi Quaintance (PL II, figs. 2,
4)) was first discovered in this country at Tampa, Fla., by the junior
author in November, 1909. The insect appears to be of recent intro-
duction, since the infested area has been under observation at inter-
vals during the past three and a half years by the several men
connected with these investigations.1

Of the four species known to be destructive to citrus, Aleyrodes
citri and A. nubifera are included in the investigations herein reported.

THE CITRUS WHITE FLY.

(Aleyrodes citri R. & H.)

HISTORICAL REVIEW.

Origin.

The origin of the citrus white fly is by circumstances quite defi-
nitely indicated to be Asiatic. The present known occurrence of it
in Japan, China, and India will be referred to under the subject of
distribution. The list of food plants, showing as it does the natural
adaptations in this respect, indicates in itself that the fly is not
native to either North or South America, but to Asia. Moreover, if
the citrus white fly were a species native to the Gulf coast region of
North America, or if it had been introduced before 1850, it would
almost certainly have become a pest worthy of mention by Townend
Glover in his reports on the orange insects of Florida published in the
United States Agricultural reports for 1855 and 1858. According
to these reports orange growing was very extensive in proportion to
the population and very profitable in spite of the temporary check
due to the freeze of 1835. The principal orange-growing district in
Florida was, at the time of the reports of Glover, already mentioned,
the northeastern section of the State, along the St. Johns River and
at St. Augustine. Orange growing on a large scale gradually spread to
the south and southwest, the center of production being correspond-
ingly moved. To-day citrus fruits are generally grown in all the
counties of the peninsula of Florida, yet, according to the authors'
estimates, only about 40 per cent of the orange groves of the State are
infested by A. citri.2 These infestations in the different sections are
almost without exception readily traceable to the ordinary sources
of dissemination, with all the evidence strongly against the fly having
been a native species infesting uncultivated food plants. The same
may be said in regard to the occurrence of the citrus white fly in
orange-growing regions in Mississippi, Alabama, Louisiana, and Texas.

1 The Woolly White Fly, a New Enemy of the Florida Orange. Bulletin 64, Part
VIII, Bureau of Entomology, U. S. Department of Agriculture, 1910.

2 A. nubifera alone occurs in not more than 5 per cent of the groves. In 15 of the
40 per cent above mentioned both A. citri and A. nubifera occur.

12 WHITE FLIES INJUKIOUS TO CITEUS IN FLORIDA.

Early History in the United States.

Riley and Howard give the following account of the status of the
citrus white fly previous to 1893:

For many years an important and interesting species of the type genus has been
known to infest orange trees in Florida and in more northern greenhouses, and more
recently the same form has appeared in injurious numbers in the orange groves of
Louisiana. In the Florida Dispatch, new series, volume 11, November, 1885, this
species received the name of Aleyrodes citri at the hands of Mr. Ashmead. The Florida
Dispatch, however, is a local newspaper of no scientific pretensions, and the descrip-
tion accompanying the name was entirely insufficient to enable recognition aside from
the food plant. We adopt the name in connection with a full description, not with a
view of encouraging such mode of publication, which is not sanctioned by the canons
of nomenclature formulated and generally accepted, but as a manuscript name, satis-
factory in itself, the authority to be recognized for it being comparatively immaterial.

Our first acquaintance with the species was in June, 1878, when we found it occur-
ring in profuse abundance on the leaves of the citrus trees in the orangery of this
department. Some observations were made upon its life history during that summer,
and all of its stages were observed. During the following years we observed it in
Florida, and it was studied by two of our agents, Mr. H. G. Hubbard, at Crescent City,
and the late Joseph Voyle, at Gainesville. The species was not treated in Mr. Hub-
bard's report on the insects affecting the orange, as we wished to give it a fuller consid-
eration than could then have been given, and other duties prevented doing so in time.
Moreover, at the time when Mr. Hubbard's report was prepared the insect had not
become of especial economic importance.

Since that time many further notes have been made in Washington, and we have
received the species from Pass Christian, Miss. ; New Orleans, La. ; Baton Rouge, La. ;
Raleigh, N. C; and many Florida localities; and during the past year or two it has
become so multiplied in parts of Louisiana and Florida as to deserve immediate
attention.

The authors quoted above specifically recorded the occurrence of
the white fly in Florida only at Gainesville (Alachua County), Cres-
cent City (Putnam County),1 and Manatee (Manatee County). Dr.
H. J. Webber in 1897 (basing his statement on records in 1893 and
1894) referred to the occurrence of the white fly at the following addi-
tional points: Evinston (Alachua County), Ocala and Citra (Marion
County), Ormond (Volusia County), Panasoffkee (Sumter County),
Orlando (Orange County), Bartow (Polk County), and Fort Myers
(Lee County) . Prof. H. A. Gossard in 1 903 mentioned only the follow-
ing additional localities specifically: Tallahassee (Leon County), Lake
City (Columbia County), Jacksonville (Duval County), and Candler
(Marion County). In the same publication the following additional

1 Examination of the specimens of white flies in the collection of the Bureau of
Entomology, collected by Mr. H. G. Hubbard in 1895 and bearing the locality label
"Crescent City," indicate that this record with little doubt refers to Aleyrodes nubifera.
Circumstances known to the authors, but which need not be discussed here, show that
with little doubt the citrus white fly was the species present at Crescent City before
the freeze of the winter of 1894-5. The specimens collected by Mr. Hubbard probably
came from the Hubbard grove at Haw Creek, several miles southeast of Crescent City.

THE CITRUS WHITE FLY: HISTORICAL REVIEW. 13

counties were reported more or less infested without reference to
definite localities: Baker, Jefferson, Leon, and Brevard.

Messrs. Riley and Howard and Dr. H. J. Webber advance no theo-
ries in regard to the original Florida infestations. Prof. Gossard,
however, has the following to say in regard to the matter:

The fly seems to have been first known throughout the region comprised in Volusia,
Marion, Lake, Alachua, and Orange Counties, from which I have little or no doubt
it was transferred to the Manatee country and to local centers along the northern
borders of the State.

According to reliable information received from Mr. M. S. More-
man, of Switzerland, Fla.; Mr. A. M. Terwilliger, of Mims, Fla., and
Mr. T. V. Moore, of Miami, Fla., the citrus white fly appeared in the
northern part of St. Johns County at a date which indicates that this
section was one of the first or possibly the first to be infested in the
State of Florida. Mr. Terwilliger informs us that he first observed
the white fly at Fruit Cove on the St. Johns River in 1879 in a grove
of large seedling trees owned by Col. McGill. The McGill grove
adjoined the grove of the Rev. T. W. Moore, whose son, Mr. T. V.
Moore, corroborates Mr. Terwilliger on the point of the occurrence
of the white fly in this section prior to 1880. According to Mr.
Moreman the white fly was known in the vicinity of Switzerland on
the St. Johns River in 1882, and was first discovered in his own grove
in 1888. The species concerned is with little doubt the citrus white
fly, A. citri, for the authors and Mr. W. W. Yothers have been unable
to find specimens of any other species at Switzerland or St. Augus-
tine, the two points visited in the northern part of St. Johns County,
or at Green Cove Springs, located a few miles below Switzerland on
the west side of the St. Johns River in Clay County. These early
reports of the citrus white fly in this section of the State are supported
by the fact that the earliest collected specimens of this species in the
collection of the Bureau of Entomology bear the date 1888 and the
locality label "St. Nicholas/' a point located in Duval County about
15 miles north of Fruit Cove.

Interesting information concerning the early history of white-fly
infestations in Florida has been obtained from Messrs. Borland and
Kells, citrus growers at Buckingham, Lee County, Fla., formerly of
Citra, Marion County. According to these gentlemen, the presence
at or near Panasoffkee, in Sumter County, Fla., of a small white
insect which caused blackening of the foliage of orange trees became
known among orange growers around Citra, at that time in the
heart of the orange-growing district of Florida, in 1881 or 1882.
The grove of Bishop Young, of Panasoffkee, was one of the first
reported infested. It is believed that Bishop Young, after traveling
in Asia (Palestine V), brought back with him plants which he set out,
and in a year or two thereafter blackening of the foliage of near-by

14 WHITE FLIES INJURIOUS TO CITRUS IK FLORIDA.

citrus trees in association with a new insect pest first became notice-
able. The white fly affecting citrus trees at PanasofTkee was exter-
minated by the freeze of 1894-1895 and, so far as the authors can
learn, has not reappeared. There seems to be at present no means of
determining whether the report given above refers to the citrus
white fly or to the cloudy-winged white fly.

Mr. A. J. Pettigrew, of Manatee, Fla., a reliable observer who has
been in the citrus nurseiy and orange-growing business in Manatee
County since 1884 and who has been familiar with the white fly since
its first discovery in that country, has furnished the authors with a
statement concerning the early history of the pest in that section of
Florida. According to Mr. Pettigrew, Messrs. C. H. Foster and F. X.
Horton each received from Washington, D. C, 6 tangerine trees in
1886 or 1887 — as near as can be determined at this time, although
possibly earner by a year or two. A year or two after the trees were
received and planted, the fly was noted by Mr. Pettigrew as abundant
on a rough lemon near one of these tangerines, and the following year
it was first noted as abundant in a seedling orange grove near by.
At Mr. Pettigrew's suggestion specimens were sent to the Department
of Agriculture at Washington and identified as a white fly. These
specimens were probably sent to Washington in 1891, for a letter
from Mr. Foster, dated January 8 of that year, was published in
Insect Life1 with the reply. The oldest specimens of the citrus
white fly now in the collection of this bureau, which were collected
in Manatee County, Fla., bear the date of March 5, 1891, with "Man-
tee" as the locality record. These were probably sent in by Mr.
Foster in connection with later correspondence than that referred
to above.

Concerning the history of the citrus white fly in Louisiana, Prof.
H. A. Morgan in 1893 made the following statement:

This pest, common from Baton Rouge to the Gulf, is known as the white fly. Orange
growers claim that it has been recently introduced — that is, within the last ten years —
and it is supposed to have come in upon plants brought to the New Orleans exposition
in the year 1885. The present wide distribution of the white fly in the southeastern
United States is due to the lack of restrictions, until very recently, against shipments
of infested nursery stock and of privets and the Cape jessamine.

Literature.

The citrus white fly was first given a valid scientific name and
adequately described by Riley and Howard in an article published
in Insect Life2 in April, 1893. Following the account of the early
history heretofore quoted, these authors describe the different stages
of the insect in detail, give an account of the habits and life history,
and give records with discussion of results obtained by a correspondent

1 Insect Life, vol. 4, p. 274. 2Id., vol. 5, no. 4, pp. 219-226, 1893.

THE CITRUS WHITE FLY: HISTORICAL REVIEW. 15

in Manatee County, Fla., who had undertaken some cooperative
experiments in spraying.

During the same year (1893) Prof. H. A. Morgan, then entomologist
of the Louisiana Agricultural Experiment Station, gave an account of
the citrus white fly in Louisiana in a bulletin of that station.1

The Division of Vegetable Physiology and Pathology of the United
States Department of Agriculture began investigations of citrus
diseases in Florida in 1893. These included investigations of the
"sooty mold" resulting from white-fly infestation, and the first report
on the subject was published by Swingle and Webber in 1896 2 and a
more extended report by Dr. H. J. Webber in 1897.3 Conclusions
from a series of spraying experiments are included in this publica-
tion and many important observations are recorded, particularly in
connection with the two most useful fungous enemies of the white fly
which were discovered by Dr. Webber in the course of his work.

Prof. H. A. Gossard, then entomologist of the Florida Agricultural
Experiment Station, published, in 1903,4 an account of the white fly
situation up to that time, with his conclusions from observations
extending over several years.

In a volume entitled " Citrus Fruits," published in 1904 by Prof.
H. H. Hume, four chapters are devoted to citrus insect pests and
methods of control, the white fly receiving due attention.

Since the present investigations by the Bureau of Entomology have
been in progress, Dr. Berger, entomologist of the Florida Experiment
Station, has published two bulletins 5 which present a summary of
white-fly conditions with recommendations for control, particularly
with reference to the use of fungous enemies. In the later pub-
lished of the two mentioned, the specific distinctions are pointed out
and illustrated, separating from the common A. citri the form which
Dr. Berger has named A. nuhifera.

Messrs. P. H. Rolfs and H. S. Fawcett, in a bulletin issued in July,
1908,6 discuss in a general way the use of fungous parasites of the white
fly in Florida and give recommendations for the introduction of the
three most common species. The most important contribution to our
knowledge of the fungous parasites of the citrus white fly is contained
in a paper by Prof. H. S. Fawcett, published in 1909.7

1 The Orange and Other Citrus Fruits. By W. C. Stubbs and H. A. Morgan. Spec.
Bui. La. Agr. Exp. Sta., pp. 71-73, 1893.

2 The Principal Diseases of Citrus Fruits in Florida. By W. T. Swingle and H. J.
Webber. Bui. 8, Division of Vegetable Physiology and Pathology, pp. 25-28, 1896.

3 The Sooty Mold of the Orange and its Treatment. Bui. 13, Division of Vegetable
Physiology and Pathology, U. S. Department of Agriculture, 1897.

4 White Fly. Bui. 67, Fla. Agr. Exp. Sta., June, 1903.

5 White Fly Conditions in 1906, the Use of Fungi. Bui. 88, Fla. Agr. Exp. Sta., Jan-
uary, 1907; White Fly Studies in 1908, Bui. 97, Fla. Agr. Exp. Sta., February, 1909.

6 Bui. 94, Fla. Agr. Exp. Sta., July, 1908.

7 Special Studies No. 1, University of State of Florida, 1909.

16 WHITE FLIES INJURIOUS TO CITEUS IN FLORIDA.

In Louisiana the demand for information concerning the citrus
white fly has resulted in a publication on this subject by Mr. A. H.
Kosenfeld in 1907.1 The discovery of the white fly in California in
the same year led to the publication, by Prof. C. W. Woodworth, of a
circular of general information,2 and of a second circular3 dealing
with the methods of eradication that were being employed in that
State. A very complete account of the white-fly infestation in Cali-
fornia was given by Mr. C. L. Marlatt, assistant entomologist of the
Bureau of Entomology, before the Entomological Society of Wash-
ington.4

The foregoing paragraphs refer to the principal publications in
which the citrus white fly is treated, exclusive of short papers in hor-
ticultural periodicals, press bulletins, experiment station reports, and
transactions of the Florida State Horticultural Society. Numerous
press bulletins have been issued by the Florida State Experiment Sta-
tion dealing with several phases of white-fly control and written from
time to time as the occasion demanded by Prof. Gossard, Dr. Sellards
Dr. Berger, and Prof. Fawcett.

Reviews of the white-fly situation for the year, with notes on new
observations, have been included in their annual reports by each of
the first three named, who have served successively as entomologist
at the Florida Experiment Station. Many important papers and dis-
cussions on the white fly have been published in the Transactions of
the State Horticultural Society, but for the most part these have
been incorporated or the ground covered more fully in the regular
bulletins referred to.

Taken as a whole, the literature on the citrus white fly is quite
extensive, giving a fairly good idea of the status of the white fly and
progress in methods of control from year to year since the publi-
cation of the paper by Riley and Howard referred to in the opening
paragraph.

The description of the different stages and the account of the life
history and habits of the citrus white fly by Riley and Howard have
been followed quite closely by subsequent writers, few additional
records having been made up to the beginning of the present investi-
gations. Records of food plants, miscellaneous life-history records,
general results of field experiments, and conclusions from general
observations on the efficiency of spraying, fumigating, and natural
control by fungous diseases have been published by Messrs. H. J.
Vebber, H. A. Gossard, E. H. Sellards, E. W. Berger, and H. S.
Fawcett. Comparatively little real data has been published so far in

1 Circular 18, State Crop Pest Commission of Louisiana, 1907.

2 Circular 30, California Agricultural Experiment Station, 1907.

3 Circular 32, California Agricultural Experiment Station, 1907.

4 Proceedings of the Entomological Society of Washington, vol. 9, pp. 121-123, 1908.

THE CITRUS WHITE FLY: INJURY. 17

connection with experimental work with the white fly. A review of
all the literature to date shows that data have been published on the
effect of kerosene emulsion on white-fly eggs, by Riley and Howard;
on the subject of effects of cold upon white-fly larvae and pupae, by
Prof. Gossard; on the percentage of trees infected by the spore-
spraying method of introducing the fungous parasites, and on the
amount of honeydew secreted by the larvae of the insect, by Dr. E. W.
Berger; upon subjects related to fumigation,1 by the senior author of
the present bulletin; and on laboratory experiments with the fungous
parasites, by Prof. H. S. Fawcett. Aside from the above, practically
no data have been heretofore published.

INJURY.
Nature of Injury.

The direct injury by the citrus white fly may be included under
two main heads: (1) Injury by removal of sap from foliage, and (2)
injury from fungous growth known as sooty mold (Meliola), which
develops upon foliage and fruit on the excretions of the insects.

The direct injury is principally included as loss in value of trees,
extra expenses of maintenance, and losses from scale insects and dis-
eases, which more seriously affect white-fly infested trees.

LOSS OF SAP.

The amount of sap extracted by the insects is not generally con-
sidered an item of great importance compared with the injury from
sooty mold. While the extraction of sap by itself probably would
not cause sufficient injury to make the white fly rank as an important
citrus pest, it is doubtless of considerable importance when combined
with the lowered assimilative powers of the foliage due to the sooty
mold. As mentioned more in detail under the subject of feeding
habits, it has been estimated that the loss of sap per day amounts to
about one-half of a pound for 1,000,000 larvae and pupae.

SOOTY MOLD.

Sooty mold is the principal evidence of white-fly injury, and is the
most important element of damage, affecting both the foliage and fruit.
(See PI. I, frontispiece.) No special attention has been given by the
authors to its botanical aspects, but the following notes concerning it
are taken mainly from Dr. H. J. Webber's report on this subject:2

1 Fumigation for the Citrus White Fly as adapted to Florida Conditions. Bulletin
76, Bureau of Entomology, U. S. Department of Agriculture, Oct. 31, 1908.

2 Bulletin 13, Division of Vegetable Physiology and Pathology, U. S. Department
of Agriculture, pp. 5-11, 1897.

59131°— Bull. 92—12 2

18 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

The sooty-mold fungus is a species of the genus Meliola 1 of the
order Pyrenomycetes. Dr. Webber states that in Florida and Loui-
siana it is quite generally known as smut or black smut, but as the
fungus concerned is not a smut fungus these terms are erroneous,
and their use should be discontinued. When abundant on leaves and
fruit of citrus, this fungus forms a dark-brown or black membranous
coating composed of densely interwoven branched mycelial filaments.
At first this coating covers only limited spots or is not thick enough
to form a distinct membrane, but later, if the honeydew-secreting
insects are abundant, the coating becomes thick enough to be entirely
removed from the leaf and torn like paper. (PI. Ill, figs. 1,2.)

Frequently the fungus membrane becomes detached at some point
and is caught by the wind and large fragments torn off. These
fungus fragments are found scattered about in badly infested groves
in the fall, being especially noticeable during the winter after a high
wind or after the trees have been sprayed.

Dr. Webber recognized several forms of reproductive agents, which
are easily distributed by various means, but principally by winds.
The fungus is entirely saprophytic in so far as known, deriving its
nourishment from the honeydew secreted by certain insects. As such
honeydew falls mostly on the upper surface of the leaves and on the
upper half or stem end of the fruit, the sooty mold develops most
densely in these places, but it is usually present to a greater or less
extent on the lower surface of the leaves, sometimes developing in
tufts on drops of honeydew which diseased insects fail to expel in a
normal manner. Sooty mold also develops on the twigs and in
some cases on the sides of buildings when heavily infested trees are
growing near by.

Seasonal history of sooty mold. — The sooty mold resulting from the
attacks of the citrus white fly is most abundant late in the season.
Very little sooty mold develops during the winter months, while the
films of blackish mycelium gradually become removed from the leaves
by winds and rains and much is knocked off in picking the fruit, in
spraying, pruning, fumigating, etc. The thicker the coating of sooty
mold, the more readily and thoroughly it is removed. By the time
of the appearance of the new spring growth the greater part of the
sooty mold on the old leaves has disappeared and from this time to
the 1st of May there is very little, if any, evidence of a new growth
of this fungus. Slight blackening of spring growth has been noted
as far north as Island Grove in Alachua County, Fla., as early as
May 20, the average number of live larvae and pupae per leaf being
estimated as about 50, not including old leaves which were practically
uninfested. By June 20, leaves from Mcintosh, in the same county,

Generally referred to M. camellia (Catt.) Sacc., but perhaps including more than

one species

Bui. 92, Bureau of Entomology, U. S. Dept. of Agriculture.

Plate III.

Sooty Mold.

Fig. 1.— Sooty mold on orange leaf following white-fly attack; broken and falling from leaf.
Fig. 2.— Sooty mold on cinnamon tree following attacks by cinnamon scale. (Original.)

THE CITRUS WHITE FLY: INJURY. 19

with an average of about 11 live larvae and pupa cases1 per leaf, were
slightly blackened. In general, heavy coats of sooty mold on leaves
are common in Florida by the 1st of June in groves heavily infested
by the citrus white fly.

Effect of sooty mold on leaf functions. — Dr. Webber has discussed
the effect of sooty mold on leaf functions in the report already referred
to, and as there is nothing to add at this time, the following paragraph
(pp. 10-11) is quoted:

When it is remembered that various investigations have shown that the process of
phytosyntax 2 is almost entirely checked in a plant placed in the back part of a living
room, opposite a window, where the light is fairly bright, but diffused, it can readily
be judged that the effect of the dark, compact mycelial membrane of the sooty mold
covering the leaves would be to almost wholly check the process of phytosyntax in the
orange tree. Quite bright or direct sunlight is necessary for the best results. The
injurious effects of sooty mold on the phytosyntax was clearly demonstrated by Busgen.
He removed the fungus membrane from a small portion of a leaf and exposed the leaf
to the sun. In the evening, after a sunny day, the leaf was plucked and the chlorophyll
extracted with alcohol. After this leaf was treated with iodine, the parts from which
the membrane had been removed in every case stained a dense blue, indicating the
formation of an abundance of starch, while the surrounding portions of the leaf, which
were protected from the sun by the fungus membrane, remained entirely uncolored,
showing that no starch was formed. The stoma ta, or breathing pores, are also to some
extent closed by the sooty mold, and in this way the passage of gas is more or less
hindered. In the orange leaf, however, the stoma ta are confined to the lower surface,
where generally there is but little sooty mold. In plants where the stoma ta are on the
upper surface of the leaf also, the damage resulting from the obstruction of the passage
of gases would probably be considerably greater.

Extent of Injury.

In the following discussion the statements concerning injury and
the estimates of the extent of this injury by the citrus white fly refer
to groves in which the fly has become well established and in which
no remedial measures have been practiced.

INJURY TO FRUIT.

Unless otherwise stated, oranges and tangerines are referred to.
These constitute more than 88 per cent of the citrus fruit crop of
Florida. The total injury to grapefruit by the citrus white fly is
rarely over 15 per cent and is frequently inappreciable.

Ripening retarded. — Ripening of fruit on heavily infested citrus trees
is greatly retarded, and in case of the formation of a very heavy coat-
ing of sooty mold on the upper half of the orange the rind underneath
it may remain green indefinitely while the lower half of the fruit is

1 Some of the first generation had matured, but are properly included with the
insects responsible for the sooty mold present.

2 ' ' Phytosyntax ' ' refers to the process of the formation of complex carbon compounds
out of simple ones under the influence of light; ' 'photosynthesis" is a more common
term for this process of assimilation.

20 WHITE FLIES INJURIOUS TO CITRUS IX FLORIDA.

well colored. The retardation of ripening, delaying as it does in some
cases the time when the fruit is marketable and materially increasing
the percentage of culls, causes injury which is very conservatively
estimated to range from 2 to 5 per cent of the value of the crop. The
injury to grapefruit in retardation of ripening by the citrus white fly
is much less, varying from none at all to 2 or 3 per cent.

Number and size. — The greatest injury by the white fly is in the
reduction of the salable crop of fruit. Dr. Webber on this point
makes the following statement:1

The effect of the sooty mold on the orange is very noticeable, the growth being
usually greatly retarded and the blooming and fruiting light. In serious cases growth
is frequently entirely checked, and blooming and fruiting wholly suppressed until
relief is obtained.

Prof. Gossard has estimated 2 that during a six-year period the
reduction in yield due to the citrus white fly is from 25 to 40 per cent.

Replies to a circular letter of inquiry addressed to orange growers
and the observation of the authors in Florida indicate that the reduc-
tion in yield due to the citrus white fly amounts to 50 per cent, on
the average, when no artificial methods of control are practiced.

From information received from many growers and from personal
observation, the authors would estimate that with continued good care
and with the additional fertilizer usually given infested trees the
reduction in yield in different groves in a series of years amounts to
an average between 20 and 50 per cent.

The decrease in yield due to white-fly infestation ordinarily consists
of a decrease in the actual number of fruit produced and also in the
packing size. From information obtained it seems a conservative
estimate to consider that oranges and tangerines are reduced either
one or two packing sizes as a result of white-fly attack. For each
packing size, the number of reduced fruit remaining the same, the
reduction in the crop would average about 12.5 per cent.

Expense of cleaning. — Fruit noticeably affected with sooty mold
requires cleaning before marketing. One of the most economical
machines for washing fruit used in Florida is a California washer used
by Mr. F. D. Waite, of Palmetto, and Mr. F. L. Wills, of Sutherland.
The cost of washing with these machines ranges from 1.4 to 2.5 cents
per box. The cost of cleaning with the simplest machines is about
5 cents per box. Mr. E. H. Walker, of Orlando, Fla., estimates the
cost of hand cleaning oranges at 10 cents per box as a minimum and
7 cents a box for cleaning grapefruit. In consideration of the fore-
going it is estimated that the range in cost of cleaning the sooty
mold from fruit to be from 1 to 10 per cent of the value of the crop.

Shipping and keeping quality. — The sooty mold produced by the
white fly and other citrus pests does not, so far as known, affect the

1 Loc. cit., p. 9. 2 Bui. 67, Fla. Agr. Exp. Sta., p. 617.

THE CITRUS WHITE FLY: INJURY.

21

shipping quality of the fruit directly, but the processes of cleaning
have been proved to be of considerable importance in this respect.
The subject of the deterioration in shipping quality of citrus fruits
has been thoroughly investigated in California by agents of the
Bureau of Plant Industry under the direction of Mr. G. H. Powell.1
Their report shows in a conclusive manner that the amount of decay
in shipment is very materially increased by brushing or washing the
fruit to remove the sooty mold. Table II, arranged from data pub-
lished in the report referred to, shows the effect of dry brushing and
washing fruit on the percentage of decay.

Table II.— Effect, on decay, of cleaning sooty mold from fruit.

Record

No.

Unbrushed
fruit ap-
parently
sound.

Dry
brushed
fruit ap-
parently
sound.

Washed
fruit ap-
parently
sound.

1

2

3

Per cent.

2.7
1.9

Per cent.
6.6
4.2

1.8

Per cent .
17.8
10.0
2.6

It will be observed that dry brushing increased the amount of
decay to about two and one-half times the decay in the unbrushed in
record No. 1, and to about two and one-fifth times in record No. 2.
Washing increased the amount of decay to about six and two-thirds
times in record No. 1, and to about five and one-fifth times in record
No. 2.

The injury from cleaning the fruit is due to the increased opportu-
nities for infection with spores of the blue mold and to mechanical
injuries in the process of cleaning. The chances of decay are still
further increased whenever the fruit is not thoroughly dried before
packing. Washing in constantly running water or by running the
fruits through brushes with water constantly sprayed- over them is
considered much less objectionable than the ordinary systems.

Flavor. — The attack of the white fly is generally supposed to affect
the quality of the fruit in a marked degree. Dr. Webber and Prof.
Gossard describe the flavor as insipid as a result of heavy infestations.
The latter presents the results of chemical analyses of samples of the
fruit of tangerine trees in two adjoining groves. In one grove the
white fly was completely controlled by spraying; in the other the fly
was unchecked. The analyses showed that there was, in the samples
from the latter grove, 15 per cent less reducing sugar, 15 per cent
less sugar dextrose, and 5 per cent less citric acid. While oranges
and tangerines are frequently much affected in flavor, thoroughly
blackened groves in many cases produce as well flavored fruit as can

1 Bulletin 123, Bureau of Plant Industry, U. S. Department of Agriculture.

22 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

be found in the market. When trees are supplied with as much
fertilizer as they can use to advantage the white fly does not ordi-
narily affect the flavor of the fruit to such a noticeable extent as is
commonly believed. It is suspected that a well-grounded prejudice
against the white fly rather than a discriminating taste is responsible
for a large part of the supposed effect on the flavor of the fruit in
infested groves.

Increased injury from scale insects and from 'plant diseases. — The
number of culls is in some cases very much increased by diseases and
insect pests which thrive after the trees have been weakened by the
white fly. There are no data available showing the usual increase in
percentage of fruit injured by scales and by diseases of the trees as
a result of white-fly infestation, but this is a consequence observed
by many citrus growers and is properly considered a factor of white-fly
injury. As such it is conservatively estimated to vary from 1 to 5
per cent in groves thoroughly infested, although an instance of a
valuable crop being completely ruined by secondary scale attack has
come under the authors' observation.

Market value. — Imperfections in fruit rind due to diseases and
insect pests as followers of the white fly and to failure of fruit rind to
color up normally, in addition to the direct effect on the size of the
marketable crop as heretofore discussed, usually lower the average
grade even after the fruit is cleaned by the most approved methods.
A few growers claim that after being cleaned their oranges and tanger-
ines bring as good prices as any, and leaving out of consideration
instances where it is claimed that most or all of the fruit is rendered
absolutely unsalable under any conditions, we may conservatively
estimate the depreciation in market value to range from none at all
to 10 per cent.

Sooty-mold-blackened oranges shipped without cleaning have a
market value . ordinarily from 25 to 50 cents less per box than the
same fruit would have cleaned.1 Certain Florida brands of oranges
well advertised, carefully graded, and packed, would fail to bring within
a dollar a box of their average value if they appeared on the market
blackened by sooty mold.

Losses to growers estimated on basis of prices paid by orange buyers. —
The authors are indebted to Mr. E. H. Walker, of Orlando, for the
information that during the season of 1907-8 orange buyers in Florida
paid from $0.75 to $1.45 for oranges free from white-fly effects, and
from $0.50 to $1 per box for fruit blackened by white fly; during
the season of 1908-9 the price paid for clean fruit varied from $0.60
to $1 per box, and from $0.50 to $0.75 for fruit blackened by sooty
mold. The loss to the growers is not entirely represented by these

1 Statement based on information from Mr. E. H. Walker, Orlando, Fla.

THE CITRUS WHITE FLY: INJURY.

23

figures, since, according to Mr. Walker, the best prices were not paid
for sooty-mold-blackened fruit until late in the season after the clean
fruit had nearly all been shipped or disposed of. Clean fruit at this
time would have been proportionally more profitable.

INJURY TO TREES.

Weakening of vitality. — It is doubtful if the white fly is ever the
direct cause of the killing of trees, limbs, or twigs in well-fertilized
groves. It does, however, seriously stunt the growth of all heavily
infested trees, and may temporarily entirely check the growth of
young trees. Its greatest effect on the vitality of the tree is an indi-
rect one. Infestation by the white fly appears to weaken the resist-
ance of orange and tangerine trees to foot rot, die back, melanose,
wither tip, and drought, and favors the multiplication of the purple
and long scales which are second to the citrus white fly as citrus pests
in the Gulf coast regions.

Depreciation in value. — The selling values of citrus groves are greatly
reduced by white-fly infestation, and citrus nurseries have their ter-
ritory for sales much restricted and values reduced. Concerning the
reduction in value of groves of bearing trees one of the most experi-
enced dealers in orange groves in the State estimates that it is in
general about one-third. For years California has been closed to
Florida nurserymen as a field for the sale of citrus nursery trees, and
a similar quarantine regulation has recently gone into effect in Ari-
zona. In Florida and in citrus-growing sections of other Gulf coast
States a guaranty of freedom from white fly is generally required,
especially when the purchaser contemplates planting a more or less
isolated grove.

SUMMARY OP LOSSES.

The estimates in the foregoing pages refer to ordinary losses where
the white fly is unchecked by natural enemies or by artificial methods
of control and not to exceptional or occasional losses. These esti-
mates, as applying to the fruit, are summarized in Table III.

Table III. — Estimates of losses to orange crops by white fly in uncontrolled condition.

Maximum.

Minimum.

Mean.

Ripening retarded

Per cent.
5

50

10

6

5

10

Per cent.
2
20
1
2
1
0

Per cent.
35

Number and size of fruits

Cost of cleaning

Deterioration in shipping quality

5*

4

Indirect injury: Increased scale and disease effects on fruit

3

Loss in market value

5

Total

86

26

56

24 WHITE FLIES INJURIOUS TO CITRUS IX FLORIDA.

The mean of the total percentage of estimated loss is considered by
the authors to represent about the normal loss which the citrus white
fly is capable of causing in orange groves. It is estimated that the
condition is reduced to about 45 per cent loss in the average infested
grove as a result of net profits from spraying with contact insecticides
and of the natural efficiency of fungous diseases.

From extensive records obtained in the course of their investiga-
tions the writers estimate that the citrus white fly infests at present
45 per cent of the citrus groves in Florida. Of this, 5 per cent is a
sufficient allowance to represent the groves so recently infested that
normal abundance of the pest has not been reached. An injury of
45 per cent in 40 per cent of the groves is equal to about 18 per cent
of the entire value of the crop as it presumably would have been if
the white fly were not present.

The latest Florida citrus crop concerning which statistics are avail-
able is that of 1907-8. x The orange crop for that season is valued
at $3,835,000. With an estimated total loss of about 15 per cent
this represents 85- per cent of the value of the crop if not affected by
the white fly. Accordingly, the estimated loss in Florida is calcu-
lated to have been about $680,000 for oranges and similarly on the
basis of 10 per cent loss to grapefruit on a valuation of $469,700, the
percentage of infested groves the same as in the case of the orange
groves, a loss of $16,700 is estimated, making the total loss in valua-
tion of fruit about $696,700 for the crop of 1907-8. The crop of
1908-9 was doubtless affected to the extent of $750,000 by the citrus
white fly.

At present the spread of the fly into uninfested groves is undoubt-
edly faster than at the rate of 5 per cent new infestations per year.
Even on this basis, however, the annual increase in depreciation in the
value of Florida citrus groves due to white-fry infestation is more than
$200,000 per year.2 In addition, the citrus nursery business in Florida
is affected to an extent hard to estimate, but which would be only
nominally represented by $50,000 per year.

Figures are not available which would allow approximate estimates
to be made of the damage by the citrus white fly in the Gulf coast
citrus-growing sections outside of Florida, but the widespread occur-
rence of the white fly in those States indicates that the losses are
heavy.

INCREASED COST OF MAINTENANCE.

The items of expense of maintenance principally affected by the
white fly are fertilization, spraying, and fumigation. In Florida

1 Tenth Biennial Report of the Commissioner of Agriculture of the State of Florida.

2 This is not shown by actual depreciation, for the number of groves coming into
bearing for the first time each year more than covers the loss.

THE CITRUS WHITE FLY: DISTRIBUTION. 25

ordinarily the expense of the fertilizer necessary to maintain orange
trees in good productive condition varies from 10 to 20 cents per box
of fruit produced. The wide range given is largely due to differences
in soil conditions. Mr. E. O. Painter, in response to an inquiry on
the subject, writes that citrus trees infested with white fly in his
opinion require at least 15 per cent increase in fertilizer for best
results under the circumstances. On the basis of cost of fertilizer
amounting to 10 to 20 cents per box and an increase of 15 per cent
due to white fly infestation, the extra expense which may be charged
as white fly injury amounts to 1.5 to 3 cents per box.

Cost of control measures properly chargeable to increased cost of main-
tenance.— Estimates based on the experience of the writers in fumi-
gating and in spraying for the white fly give the range in expense of
the former method of control as 5.5 to 14 cents per box of oranges
produced, and of the latter method 12.5 to 20 cents per box. These
estimates refer to thorough control, with the result that production is
entirely unaffected by the white fly. The minimum estimate on the
expense of fumigation refers to groves so located that the migrations
of adults from outside groves does not make treatment necessary more
than once in two years. The maximum estimate refers to conditions
where treatment every year is required to prevent loss. Increase in
production, due to destruction of scale-insect pests, is not taken into
consideration. In the estimates of expense of control by spraying
the minimum estimate refers to cases where three applications of in-
secticide per year have resulted in satisfactory control. This result
can be attained only after the insect has been brought into complete
subjection, such as referred to in the introductory paragraph of the
subject of artificial control. Insecticides costing more than 1J cents
per gallon when mixed ready for application have not been taken
into consideration.

DISTRIBUTION.

As has been shown in the historical review, the citrus white-fly
at present is generally distributed in North America. In the north-
ern part of the United States it occurs in greenhouses, and in the
southern part, and in limited districts in California, it occurs on
citrus, China trees, privet, cape jessamines, and other food plants.
In the present publication we are concerned only with the distribu-
tion of the species in the citrus fruit-growing regions of the United

States.

In the United States.

According to the statistics of the Florida commissioner of agricul-
ture, in 1905 there were 17 counties in the State reporting more
than 5,000 bearing citrus fruit trees. In all but two of these, Dade
and St. Lucie , the citrus white fly (Aleyrodes citri) occurs to a greater

26

WHITE FLIES INJURIOUS TO CITRUS IX FLORIDA.

or less extent. (See fig. 1.) The 17 counties referred to, arranged in
order of the number of bearing citrus trees, is as follows: Orange, Lake,
Volusia, Polk, Putnam, Brevard, Hillsboro, De Soto, Lee, Manatee,
Dade, Marion, St. Lucie, Osceola, Sumter, St. John, and Alachua.
Palm Beach as well as Dade and Monroe Counties are infested with the
cloudy-winged white fly, as hereafter noted, but so far as known the
citrus white fly does not occur there. In order of the percentage of
groves infested the foregoing counties which are known to be infested
would be arranged about in the following order, so far as our obser-
vations and records show: Marion, Alachua, St. John, Manatee,
Orange, Lee, Volusia, Polk, Putnam, Lake, Hillsboro, Sumter, De
Soto, Osceola, and Brevard. If the groves infested by the cloudy-
winged white-fly only were also taken into consideration, Hillsboro

and Lake Counties
would be transposed
in the list, as would
Osceola and Brevard,
but aside from this
there would be no
change. The arrange-
ment is only approxi-
mate, being based on
observations made
by the various men
connected with the
white-fly investiga-
tions upon informa-
tion and samples of
infested leaves re-
ceived from corre-
spondents and upon
nearly 250 replies received in response to circular letters sent out in
the spring of 1907.

At the present time the writers estimate that throughout the State
of Florida about 40 per cent of the citrus groves are infested by the
citrus white fly, and that an additional 5 (or 10) per cent are infested
by the cloudy-winged white fly alone.

The citrus white fly occurs in nearly all the larger towns in north-
ern Florida, infesting the various food plants which are grown as
ornamentals as well as the citrus fruit trees which are grown to a
limited extent. The insect is of common occurrence, principally on
China trees, cape jessamines, and on privet and hedges of Citrus
trifoliata in South Carolina and in southern Georgia, Alabama, Mis-
sissippi, Louisiana, and Texas. In the last two States citrus fruits
are being grown quite extensively, and a large percentage of the
citrus-growing localities are infested.

Fig. 1.

-Map showing distribution of the citrus white fly (Aleyrodes
citri) in Florida. (Original.)

THE CITRUS WHITE FLY: DISTRIBUTION. 27

Aside from the Gulf coast States, citrus fruits in the United States
are grown only in California and Arizona. The citrus white fly does
not occur in Arizona. In California the pest was first discovered in
May, 1907. Mr. C. L. Maria tt has given the following account of
the distribution of the white fly in that State in 1907 11

Marysville is situated a few miles north of Sacramento, and the first infestation
seemed limited to this town, but toward the end of the summer the white fly was
discovered well established at Oroville, in Butte County, some 26 miles to the north
of Marysville. The Marysville infestation was confined to the town and to yard trees
or small garden orchards. Oroville lies in a considerable orange district, and the
white fly had been carried from the town into several of the adjacent orchards and
had become rather widely scattered. Shortly after the discovery of the fly at Marys-
ville it was found also to have established itself locally near Bakersfield,2 in the south-
ern end of the San Joaquin Valley, and separated only by a mountain range from the
citrus districts of southern California.

In Foreign Countries.

For years the citrus white fly has been supposed to be an intro-
duced species, and much interest has been attached to its occurrence
elsewhere than in North America. Prof. H. A. Gossard in 1903
stated that Mr. Alexander Craw, of the California State commission
of horticulture, had received this species on plants from Chile, where
it was reported to be a great pest. Mr. G. W. Kirkaldy, in his cata-
logue of the Aleyrodidse, in 1907, gives "Mexico, Brazil, and Chile
(?)" as the known habitats of the citrus white fly outside of the
United States. The writers are informed by Prof. A. L. Quaintance
that he was told in person by the late Prof. Rivera, of Santiago,
Chile, that the citrus white fly was abundant in that country. Prof.
Carlos Camacho, chief vegetable pathologist at Santiago, Chile, is
also, according to Prof. Quaintance, authority for the statement that
it occurs there.

The Bureau of Entomology received, in 1906, specimens of an
aleyrodid on orange leaves from China which Prof. Quaintance
determined as Aleyrodes citri,3 and still more recently it received,
through Mr. August Mayer, in charge of plant-introduction garden,
and through the California state commission of horticulture, speci-
mens of orange leaves infested with what Prof. Quaintance has
identified as this species from different parts of China and Japan.

The occurrence of the citrus white fly in India (northwestern Hima-
layas) has recently been established by Prof. Quaintance, who has
compared MaskelTs A. aurantii, collected in the region mentioned

1 Proceedings of the Entomological Society of Washington, vol. 9, pp. 121-122,
1908.

2 Specimens of the species present at Bakersfield were examined by the senior
author at the California State Insectary at Sacramento and found to be the cloudy-
winged white fly (A. nubifera).

3 Proceedings of the Entomological Society of Washington, vol. 8, Nos. 3-4, p. 107.

28 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

above, with A. citri, and failing to find any differences in the egg and
pupal stages found it necessary to regard the name given by Maskell
as a synonym of that given by Riley and Howard.

The citrus white fly does not occur in Cuba, so far as known,
although it is not unlikely to be found there, since there have been
heavy shipments of nursery stock from infested citrus nurseries in
Florida to that country during the last few years.

FOOD PLANTS.
AUTHENTIC AND QUESTIONABLE RECORDS.

The separation as distinct species of two forms formerly considered
as belonging to the species Aleyrodes citri makes it necessary that
all of the reported food plants of the citrus white fly be verified.
Nearly 60 species of the genus Aleyrodes have been recorded for
North America. Of these less than 20 have been described in the
first larval stage in a manner which distinguishes them, although
when carefully studied this stage has been found to have striking
specific characters. The second and third larval stages rarely possess
distinguishing characters. The fourth or pupal stage, or the empty
pupa case, is used as the basis of specific descriptions in the Aley-
rodidae, but even in this stage a careful microscopic examination is
usually necessary to positively determine the species. Good specific
distinctions in the adult stage have been found only in a few species,
and even those entomologists who have made a specialty of the Aley-
rodidae do not attempt to distinguish the different species in this
stage. It is obvious, therefore, that a list of food plants should
properly include only those verified by entomologists, with determin-
ations of the species made since the status of the two most abundant
citrus-infesting species of Aleyrodes has been fully recognized. Dr.
E. W. Berger has recently arranged the full list of food plants and
reported food plants in a graphic manner, separating the list into
two classes according to the degree of preference, and each class is
subdivided into native and introduced species. This method of
grouping the food plants is here adopted (see Table IV) with the
transposition of the lilac and coffee from class II to class I and omit-
ting certain reported food plants in order to restrict the list to include
only positive records, leaving the others for a separate discussion.
Dr. Berger has recently discovered the citrus white fly on wild olive,
and has also verified Prof. Gossard's report of the citrus white fly on
Viburnum nudum. Both of these food plants, together with the
green ash, probably will eventually be found to be subject to heavy
infestation and be placed in class I.

THE CITRUS WHITE FLY I FOOD PLANTS. 29

Table IV .—Definitely known food plants of the citrus white fly (Aleyrodes citri).

Class I. Preferred.
Introduced :

1. Citrus (all species cultivated in America).

2. China tree (Melia azedarach).

3. Umbrella China tree (Melia azedarach umbraculifera) .

4. Cape jessamine (Gardenia jasminoides) .

5 . Privets (Ligustrum spp . ) .

6. Japan persimmon (Diospyros kaki).

7. Lilac (Syringa sp.).

8. Coffee (Coffea arabica).
Native :

9. Prickly ash (Xanthoxylum clava-herculis) .

10. Wild persimmon (Diospyros virginiana).

Class II. Occasionally Infested.
Introduced:

11. Allamanda (Allamanda neriifolia).

12. Cultivated pear (Pyrus spp.).

13. Banana shrub (Magnolia fuscatum) .

14. Pomegranate (Punica granatum) .
Native:

15. Smilax (Smilax sp.).

16. Cherry laurel (Prunus laurocerasus) .

17. Wild olive or devilwood (Osmanthus americanus) .

18. Viburnum ( Viburnum nudum) . ♦

19. Green ash (Fraxinus lanceolata).

In addition to those in the foregoing list J there are several plants
reported as food plants of the citrus white fly which, while probably
true food plants, can not consistently be included in the recognized
list until the observations have been repeated and the infesting spe-
cies positively identified. In some instances where eggs or larvae
have been found there is doubt as to whether the white fly could
develop to maturity on the plants in question. ' Plants upon which
the insect is unable to develop to maturity can not properly be con-
sidered true food plants. The following is the list of plants reported
as food plants, but which in each case require further observations
either as regards the ability of the insect to reach maturity thereon
or as regards the species of white fly concerned, in view of the recent
separation of A. citri and A. nubifera: Water oak, reported by Prof.
A. L. Quaintance; Ficus altissima, Ficus sp. (from Costa Rica), and
scrub palmetto, reported by Prof. H. A. Gossard; honeysuckle and
blackberry, reported by Dr. E. H. Sellards; oleander, reported by

* In addition to those already mentioned as being food plants in Florida, the follow-
ing plants are on record at the State insectary at Sacramento, Cal., as food plants of the
citrus white fly observed at Marysville and Oroville by agents of the State commission
of horticulture: English ivy (Hedera helix), yellow jessamine (Jasminum odoratissi-
mum), Ficus macrophylla, bay (Laurus nobilis), tree of Heaven (Ailanthus glandulosa),
and crape myrtle (Myrtus lagerstrcemia) . Information concerning the authorities for
the plants listed is not available.

30 WHITE FLIES INJURIOUS TO CITRUS IX FLORIDA.

the senior author of the present publication: camellia, reported by
Dr. E. W. Berger. In the case of the last two plants mentioned
the uncertainty as to their proper standing is on the possibility of
the insect reaching maturity thereon and not on the identity of the
infesting species.

The present status of the plants which have heretofore been listed
by entomologists as food plants of the citrus white fly is shown in
the foregoing paragraphs. There are doubtless numerous additional
introduced species and a few additional native species of plants occur-
ring in the United States which serve or are capable of serving as
food plants of the citrus white fly, but for the reasons connected with
the identification of the insects, stated in the opening paragraph under
the subject of food#plants. reports of food j)lants other than those
included in classes I and II should never be credited unless verified
by or made by an entomologist. There are no important food plants
occurring in the Gulf coast region omitted from this list, and future
additions to the list probably will be of little significance economically
as affecting the control of the pest. There is a widespread belief that
many other common trees, shrubs, and vines in Florida are food plants
of the citrus white fly, but the correctness or falsity of this belief
can be readily ascertained in the case of the individual plants sus-
pected by submitting specimens of the foliage and of the infesting
insect to the Bureau of Entomology or to the State experiment station.

There are three common causes for erroneous reports concerning
citrus white-fly food plants. The first is the presence of sooty mold
on many plants, due to other honey dew-secreting insects, such as
aphides, scale insects, and mealy bugs. The insects themselves are
not seen in this case and the mistaken idea is due to ignorance of the
fact that other insects than the citrus white fly excrete honeydew on
which the same species of sooty mold fungus thrives. The second
cause for erroneous reports in this respect is the misidentification of
the insect concerned. The necessity for the identification of the in-
festing insect by an entomologist has been discussed. The third
cause is the frequent occurrence of the adult citrus white fly on the
foliage of plants upon which it does not breed and upon which it sel-
dom or never deposits an egg. In the course of the present investi-
gation by the Bureau of Entomology several trees and shrubs have
been thoroughly tested as possible food plants by cage experiments,
and observations have been made on these and other plants, showing
that if it is possible for the citrus white fly to develop on one of them, it
is, at the most, of too rare occurrence to be of any significance. Cage
tests have been made with oak (Qucrcus brevifolia), magnolia (Mag-
nolia fatida), blackberry (Rubus spp.), laurel cherry or mock orange
(Prunus caroliniana), and cultivated figs (Ficus carica) and crape
myrtle (Myrtus lagairocmia). In each case a rearing cage (PL VII)

THE CITRUS WHITE FLY: FOOD PLANTS. 31

was attached to the end of a branch covering new growth and from
50 to 100 adults of A. citri were confined therein. Except in the case
of the blackberry, in which no observation was made on the point,
the adults were noted as resting contentedly and apparently feeding on
the leaves for one or two days after being confined. In every case,
however, all the adults were dead on the fourth day after confinement
on the plants noted, although check lots of adults collected at the same
time but confined on branches of citrus trees lived for a normal period.
No eggs were deposited in any of the tests, although the check lots
deposited eggs on the citrus leaves in a normal manner.

Each of the five plants tested with the cage experiments have in
addition been subjected to very careful examinations by the writers
under such circumstances that the opportunities for infestation by
the citrus white fly were at their best. In addition, particular atten-
tion has been given to examinations of species of oaks (Quercus spp.)
and bays (Persea spp.), guavas (Psidiwn spp.) and mulberries (Morus
spp.), when located near, and in some cases with branches intermin-
gling with infested citrus or other favorite food plants.

Economic Significance of Food Plants, and Interrelationship Between Food

Plants and Insects.

Entomologists familiar with the present white-fly situation agree
in their conclusion that a requisite for satisfactory control of this
pest is proper attention to food plants other than citrus fruit trees.
Mr. H. G. Hubbard, who was a well-known authority on orange
insects, being a special agent of the Bureau of Entomology, was a
strong advocate of destroying food plants of the white fly that were
of no value. Dr. Sellards, formerly entomologist at the Florida Ex-
periment Station, Dr. Berger, the present entomologist, Prof. P. H.
Rolfs, director of the Florida Experiment Station, and the authors
have each emphasized the importance of the relation of the various
food plants to white-fly control.

The following paragraph from the senior author's bulletin on the
subject of fumigation for the citrus white fly x states in a general way
the situation in this respect as viewed by entomologists who have
investigated the white fly :

The presence of food plants of the white fly other than citrus trees, in citrus fruit-
growing sections, constitutes a serious menace and in itself often prevents successful
results from remedial work. Fortunately the list of food plants is limited, and the
greater number of those thus far recorded is subject to infestation only when located
near or in the midst of heavily infested citrus groves. The food, plants which are of
most importance in connection with the white-fly control are the chinaberry trees,
privets, and cape jessamine, and these — except for the last, in certain sections where
grown for commercial purposes — can be eradicated readily, or their infestation may
be prevented where community interests precede those of the individual in controlling

1 Bulletin 76, Bureau of Entomology, TJ. S. Department of Agriculture, pp. 9-10.

32 WHITE FLIES IXJURI0I7S TO CITRUS IX FLORIDA.

public sentiment. These food plants favor the rapid dissemination of the white fly
from centers of infestation and their successful establishment in uninfested localities.
They seriously interfere with the success of fumigation, as well as of all other remedial
measures, by furnishing a favored breeding place where the white fly can regain
its usual abundance in a much shorter time than would be the case if it were entirely
dependent upon citrus fruit trees for its food supply. The plants mentioned, together
with Citrus trifoliata (except where used in nurseries), and all abandoned and useless
citrus trees should be condemned as public nuisances and destroyed in all communi-
ties where citrus fruit growing is an important industry.

Xot only is a knowledge of the relation of the various noncitrus
food plants to white-fly- injury of great importance, but it is also of
considerable importance to growers to know the capability of the
insect for multiplying on the different citrus fruit trees in order that
advantage may be taken of it in the arrangement of new groves and
the improvement of old groves.

It is a matter of common observation that injury from the white
fly is most marked on citrus fruits of the Mandarin group. This
group includes the Tangerine, Satsuma, and King of Siam. The
sweet oranges are next to the mandarins in this respect, followed by
the kumquats and grapefruits.

The relatively less injury to grapefruit by the citrus white fly
{A. citri) is sometimes obscured by the presence of A. nuhifera.
Blackening of foliage and fruit by the citrus white fly is more notice-
able on grapefruit trees when they are surrounded by or are otherwise
unfavorably located in respect to oranges or tangerines. Solid
blocks of grapefruit trees rarely show more than slight effects of
white-fly infestation when only the citrus white fly is present. An
example of this is the Manavista Grove at Manavista, Manatee
County, Fla. This grove consists of 22,000 grapefruit trees, and
appreciable blackening of the foliage is rarely seen except occasionally
where orange groves adjoin. Only one record, based on actual
examination of leaves, illustrating the difference in the degree of
infestation of adjoining blocks of grapefruit and orange trees is
available. The grapefruit block consisted of about 400 trees located
immediately north of a block of 200 or 300 orange trees and separated
on the west by a public road from a grove of about S00 orange trees.
On April 23, 1909, after practically all the overwintering pupa? had
matured, an examination of 100 or more leaves collected at random
from each grove, counting the pupa cases, showed an average of 8
insects that had reached maturity on the grapefruit leaves. 27 on
the orange leaves of the block south, and 56 on the orange leaves of
the block west. Xo studies have been made to determine the differ-
ent degrees of susceptibility to white-fly injury among the different
varieties of grapefruit, but the Royal variety appears to be more

THE CITRUS WHITE FLY: FOOD PLANTS. 33

nearly immune than any other of those commonly grown. This was
first pointed out by Mr. F. D. Waite, of Palmetto, Fla. In this con-
nection it should be noted that the Koyal variety in its general
characteristics is not a typical grapefruit.

The reason for the partial immunity of grapefruit trees to white-fly
injury is as yet obscure. Several observations on grapefruit and
orange trees growing side by side give no basis for the supposition
that it is a matter of food-plant preferences of the adult flies. In
some cases the differences in the amount of new growth must be
taken into consideration. Counts of adults, pupa cases, and hatched
eggs of the citrus white fly on alternating grapefruit and orange
trees, six in all, located on the laboratory grounds at Orlando, were
made on June 4, 1909, when no new growth was present on the trees.
The leaves were selected at random and, with the exception of a few
upon which adults were counted, they represented the spring growth
of 1909. The difference between the number of the adults on 500
grapefruit and 500 orange leaves, 87 and 104, respectively, is not as
great as would be expected, considering the much greater number
of insects that had matured on the orange up to the time of the exam-
ination. There were about twenty times as many pupa cases on
the 100 orange leaves as on the 100 grapefruit leaves, or 6 and 120,
respectively. This was offset by the presence of about three times
as many live pupae on 10 grapefruit as on 10 orange leaves, 41 and 14,
respectively, making the sum of the pupa cases and live pupae 4.16
per leaf in the case of the grapefruit and 2.6 per leaf in the case of the
orange. This is about the same proportion as the number of hatched
eggs on the two food plants. The condition of the leaves, as shown
by this data, fails to indicate any cause for the partial immunity of
grapefruit trees.

The examinations by Mr. W. W. Yothers of two leaves picked at
random from each tree in a small isolated grove consisting of 41
grapefruit and 28 tangerine trees gave rather striking figures, show-
ing more rapid multiplication of the citrus white fly on the latter
than on the former. The first examination was made on November
4, 1908, and the second on June 8, 1909. On the former date the
average number of live and dead white-fly larvae and pupae per leaf
was 31.9 on the grapefruit and 96.2 on the tangerine, 16.6 and 80.9,
respectively, being alive. During the winter a series of fumigating
experiments reduced the numbers of the white fly so that at the
second examination the number per leaf was 1.1 on the grapefruit
and 2.25 on the tangerine. The arrangement of the two kinds of
trees in the grove was such that they had equal chances of becoming
reinf ested by the insects which escaped the effects of the experimental
tests.

59131°— Bull. 92—12 3

34 WHITE FLIES IXJTTRIOTrS TO CITRUS IX FLORIDA.

The difference in the degree of injury between orange and tangerine
trees is less marked than between tangerine and grapefruit or orange
and grapefruit, but the difference is nevertheless usually quite notice-
able. The practical application of this difference in the degree of
adaptation of the citrus white fly to the various citrus food plants
will be discussed in a forthcoming bulletin dealing with the artificial
control of the white fly.

CHINA TREES AXD UMBRELLA TREES.

While China trees (PL IV) and umbrella China trees (PL V), when
grown for shade and ornamental purposes, are, as has been pointed
out. very injurious to citrus fruit-growing interests, the investigation
of the utility of these plants as trap foods gives an increased import-
ance to a definite knowledge concerning them as citrus white-fly food
plants. Their injuriousness to citrus growers is veiy clear to pro-
fessional entomologists, but not as generally appreciated by the citrus
growers themselves as is desirable.

The umbrella tree is recognized by botanists as a variety of the
China tree. This variety is the one most commonly grown except
in a few localities, and observations reported herein specifically refer
to it and not to the China tree. The latter tree has, however, been
under observation by the authors, and no noticeable difference has
been observed between the two trees in their relation to the citrus
white fly, and the data and observations are in the main fully as
applicable to the one as to the other.

The numbers of the white fly which mature on individual umbrella
trees have been estimated in three instances and found to range
between 25.000.000 and 50.000.000 where trees are favorably located
with respect to nondeciduous food plants. Examinations were made
by selecting 10 or more leaves at random and from each selecting
a leaflet which appeared to represent the average condition of all
the leaflets composing the leaf. In two instances it was found that
the infestation was fully as great toward the top of the tree as on the
lower parts. In one instance an extensive examination of different
parts of an infested umbrella tree showed a decrease from lower
branches to top branches of 50 per cent. In order to be fully con-
servative, this percentage has been used as the basis of the calcula-
tions, making the average infestation throughout the tree 75 per
cent of the infestation of the leaves of the lower branches. Full-
grown leaves were found to consist of about eighty-two leaflets.
Complete records were made of eggs and of live and dead larvae and
pupae, but only a part of this data will be presented. The estimates
and counts of both leaves and insects in the case of the first tree were
made by the senior author; in the cases of the second and third trees
the estimates of the number of leaves per tree represent the average

Bui. 92, Bureau of Entomology, U. S. Dept. of Agriculture.

Plate IV.

The China Tree.

Fig. 1.— China tree defoliated during winter. Fig. 2.— Same tree in full foliage in summer.

(Original.)

il. 92, Bureau of Entomology, U. S. Dept. of Agriculture

Plate V.

THE CITRUS WHITE FLY: FOOD PLANTS.

35

of three estimates — one by the senior author, one by the junior author,
and one by Mr. W. W. Yothers. The counts and estimates of insects
were made by the senior author in the second instance and by the
junior author in the third. The data obtained in these examinations
bearing on the number of insects the umbrella trees are capable of
maturing are given in Table V.

Xable V. — Number of citrus white flies developing on umbrella China trees.

Tree.

Date of exam-
ination.

Estimated

number of

leaves on

tree.

Number
of pupa

cases
per leaf.

Number
of live
pupae

per leaf.

Estimated
number of
insects ma-
tured on
tree.

Estimated
number of
larvae and
pupae alive
at time of
examina-
tion.

1

2
3

Oct. 28,1906
Aug. 19,1908
Aug. 25, 1908

20,000
25,000
12,000

2,478
1,910
2,230

4.1
13.2
4.0

49,560,000
47.752,000
26, 760, 000

82.000
330,000

58, 800

The three trees examined are not in any way exceptional as regards
the degree of infestation, but may be considered as representative of
the condition of China trees and umbrella China trees in localities
where the citrus white fly is established. Tree No. 1 was located by
the roadside near a 5-acre grove of newly bearing budded orange and
grapefruit trees which were lightly infested by the white fly and on
which it is estimated that not over 100,000 insects could have matured
on any one tree during the season. Tree No. 2 was located most
unfavorably for a heavy infestation, standing in a vacant lot in the
business section of Orlando and having its source of citrus white-fly
infestation in the spring almost entirely restricted to two neglected
and worthless orange trees of small size growing within a radius of
100 feet. Tree No. 3 was located in front of the laboratory at
Orlando, with 36 orange and grapefruit trees on the grounds. The
least conservative of the authors' estimates would place the number
of white flies which matured on any one of these citrus trees during
the year 1908 as not over 500,000, with the average of the 36 trees at
about one-half this number. It is estimated, therefore, that the one
umbrella tree produced upward of three times as many adult citrus
white flies during the year 1908 as the 36 citrus trees on the labora-
tory grounds combined. The important relation of the remarkable
multiplication of the citrus white fly on China and umbrella trees to
the spread of the pest will be discussed under the heading " Spread. "

Two new points of importance have been established by the present
investigations in regard to umbrella China trees as citrus white fly
food plants. First, this insect shows in one respect a greater degree
of adaptation to this food plant than to citrus plants, as shown by
the very low rate of mortality in the immature stages. Table VI
gives the data obtained by Rye counts made at Orlando, Fla., during
these investigations.

36

WHITE FLIES INJURIOUS TO CITRUS IX FLORIDA.
Table VI. — Mortality of citrus white fly on umbrella China tree leav<

Date.

Pupa
cases.

Live

larvae

andpupae.

Dead

larvae
andpupae.

Mortality.

Oct. 28, 1906...
JulvS, 1908....
Jul v 21, 1908...
Aug. 19. 1908..
Aug. 25, 1908..

Total...

806

113
232

312

1

338

256

49

169

Ill
192

51
152

70

Per cent.
12.0
18.7
12.1
35.1
13.4

1.960

813 | 596

18.2

The record made on August 19, 190S, showing the highest per-
centage of dead stages of the white fly, was based upon 10 leaflets
selected from a single leaf and is not considered so typical of the con-
dition throughout the tree examined as is the case in the other
records. In contrast to the low mortality records as shown by the
insect forms present on the leaves of the umbrella trees, 26 records of
mortality in citrus groves gave an average of 57.9 per cent dead on
the leaves. These records were based on the examination of about
2,000 leaves and over 100,000 white-fly forms. It should be noted
that the mortality in the above records is based on the number of
live and dead larvae and pupae, and of pupa cases present on the
leaves at the times of the examinations. The actual mortality would
be represented by the difference between the total live larvae, live pupae,
and pupa cases and the number of hatched eggs. On umbrella China
tree leaves this difference is slight and represented for the most part
by the number of dead larvae and pupae found on the leaves. In the
case of the citrus trees, on the other hand, the number of citrus
white-fly forms on the leaves ordinarily represents only from 25 to
30 per cent of the total number of eggs deposited. This disappearance
from the leaves is discussed elsewhere. Its significance in this con-
nection is that the actual mortality on citrus leaves is much higher
than the average per leaf of 57.9 would indicate. The citrus white
fly forms on the leaves show a mortality on the umbrella tree amount-
ing to only one-third of the mortality on citrus trees. The considera-
tion of the number of hatched eggs as a basis for mortality estimates
would reduce this to about one-fifth. The figures refer to citrus groves
where the citrus white fly is well established. In newly infested
groves the rate of mortality is much smaller as a rule.

The second important point established in the course of the investi-
gations reported herein is that adult citrus white flies are so strongly
attracted b}T growing leaves of umbrella trees that under certain
conditions with umbrella and citrus trees growing side by side more
adults collect on three or four umbrella leaves than are present on
entire citrus trees of medium size.

THE CITRUS WHITE FLY: FOOD PLANTS.

37

Ofte/VGE TREES

OR/INGE
TREES

It has been frequently observed that when the citrus white fly is
first becoming established in a grove, if China trees or umbrella China
trees are near, adults often can be found on these when none can be
found on surrounding or intervening citrus trees. In order to obtain
a more definite idea of the relative attractiveness of umbrella China
trees and citrus trees, 4 records were made by the senior author on
the laboratory grounds (fig. 2) at Orlando. In observation No. 1, the
count on citrus was
ndeon4tr,™ JISEK* *££•**""**

f, ' A Im S = STORAGE SHED, L = LABORATORY.

C, and the observa-
tions on umbrella
China trees were
made on 2 small
trees located about
6 and 20 feet, re-
spectively, south-
west of 4 A. These
umbrella China trees
were slender 2-year-
old growths about 4
and 5 feet high and
together bearing
about 40 leaves.

Observation No. 2
was made on grape-
fruit and orange
trees E 6, E 5, E 4,
D 5, D 4, and F 3
and two stems of
the umbrella China
tree cluster in space
F 7 nearest to tree
E 6. Observation
No. 3 was made on
tree A 4 and the
nearest umbrella China tree sapling. This latter had been defoliated
since observation No. 1 was made. Observation No. 4 was made on
citrus trees D 7, E 6, E 5, E 4, E 3, and F 3 and on two stems of
the umbrella cluster which had been defoliated since observation
No. 2. The data obtained by the four observations are given in
Table VII.

Fig. 2.

I

5

-Diagram of the laboratory grounds at Orlando, Fla.
(Original.)

38

WHITE FLIES INJURIOUS TO CITRUS IX FLORIDA.

Table VII. — Relative attractiveness to the citrus white fly of foliage of umbrella China

trees and citrus trees.

Observa-
tion No.

Date.

Citrus trees. Umbrella China-trees.

Number

of
minutes.

Number
of adults
counted.

1ST **«**■

Number
of adults
counted.

Approx-
imate
number
of leaves
exam-
ined.

1

2

1909.
Mav 18
...do....

5
5
3
5

257
19
34
52

4 5 508
6 5 615
1 3 ! 477
6 5 j 830

25

30

6

15

3

4

June 11
...do....

Total .

18

362

17 IS 2,427 76

In all, 2,789 specimens were counted, of which 88 per cent were on
umbrella China tree leaves. It was estimated that in each record on
a citrus tree approximately 2,000 leaves were examined, making
34,000 in all. The individual leaflets composing the 76 umbrella-
tree leaves numbered approximately 6,000. For practical purposes
these leaflets are more comparable to the citrus leaves although the
latter have on the average fully twice as much surface. With this
basis for comparison it can be figured from the above data that there
was about one adult white fly per 100 leaves on the citrus trees while
there were about 40 adults per 100 leaflets on the umbrella trees.

As has been indicated, the difference between the number of China-
tree leaves in numbers 3 and 1 and between 4 and 2, respectively,
represents the oldest spring growth, which was removed on May 24,
leaving only a few growing leaves. No direct comparison was made
between the attractiveness of the older growth of citrus and umbrella
trees but apparently there is no striking difference between the two
food plants in this respect. New watershoots were present on the
citrus trees on both dates when observations were made but only in
the case of one tree, 4 A, were many adults found on this growth.
In observation No. 1 on the tree mentioned (4 A) 200 adults were
counted on two watershoots. Except for watershoots there was no
new growth on any of the citrus trees.

At Orlando the umbrella trees usually start to put on new foliage
in the spring before new growth appears on citrus trees. As a con-
sequence China, and umbrella trees located near infested citrus trees
receive large numbers of adults of the citrus white fly which migrate
in search of attractive food. On February 22, 1909, the authors
noted on the laboratory grounds that the shoots of the umbrella tree
were beginning to put out new growth, the leaves not fully unfolded.
The citrus white fly was found seatteriiigly on the umbrella leaves
but on citrus trees specimens could be found only after careful
search.

THE CITRUS WHITE FLY: FOOD PLANTS. 39

On March 27, 1907, near the laboratory, then located in the grove
of Mr. J. M. Cheney, a striking example of the attractiveness of the
umbrella tree was observed. The tree referred to was about 25 feet
high and the leaves which were on the average only about half
developed were estimated to number 5,000. Ten leaves were
selected at random within 10 feet of the ground and the number of
adults and eggs was counted, the former numbering 5.3 per leaf
on the average and the latter 160 per leaf. The tree was cut down
and an examination of the topmost leaves showed an average of 186
eggs per leaf; the adults, being disturbed, were not counted, but
judging from the number of eggs present they evidently were more
rather than less numerous than on leaves near the ground. Con-
sidering the average .of 5.3 per leaf, however, the total number of
adults on the tree would be estimated at 26,500, and at 160 eggs per
leaf the number of eggs deposited would be estimated at 800,000.
At the time of this observation about 50 per cent of the insects which
overwintered on the citrus leaves had matured. The citrus white
fly had been much reduced throughout the grove, in some sections
by unexplained influences, in others by these influences and fumi-
gation experiments combined, and on a few tangerine trees by a
fungus parasite, red Aschersonia. The location of the umbrella tree
did not seem to be a favorable one as regards opportunities for
white-fly infestation, but examination showed the infestation to be
at least 100 times greater, as regards the number of adults present,
than on any citrus tree in the grove. There were, in fact, too few eggs
deposited on the leaves of the citrus trees to allow of sufficient multi-
plication of the white fly during the season to cause any blackening
of foliage or fruit.

CAPE JESSAMINE.

The cape jessamine has long been recognized not only as a favorite
food plant of the citrus white fly, but as especially important eco-
nomically on account of its retaining its foliage throughout the year.
From a statement by Kiley and Howard x concerning observations
by Mr. H. G. Hubbard and statements by Dr. H. J. Webber, Dr.
Montgomery, and others in the discussions on the citrus white fly at
a meeting of the Florida State Horticultural Society, 2 it appears that
the freezes of December, 1904, and February, 1905, which completely
defoliated citrus trees when not especially protected, failed to defo-
liate cape jessamines. In many localities it is probable that this food
plant was responsible for the survival of the white fly at the time
referred to. According to Dr. Sellards, 3 temperatures as low as

1 Insect Life, vol. 7, p. 282.

2 Proceedings of the Florida State Horticultural Society, 1896, p. 78.

3 Press Bulletin 56, Florida Agricultural Experiment Station, p. 2.

40 WHITE PLIES INJURIOUS TO CITRUS IN FLORIDA.

16° above zero at Lake City, between January 26 and January 29,
1905, failed to defoliate cape jessamine.

Except where grown for commercial purposes, as is the case at
Alvin, Tex., where the blooms are shipped to northern markets, or
where grown in nurseries, cape jessamines have not been observed
growing in sufficient abundance to materially affect near-by citrus
trees in sections where the white fly is already established. If over-
looked in connection with the fumigation of citrus groves or defolia-
tion of citrus trees by cold, cape jessamines might become a serious
hindrance in the control of the white fly. The greatest economic
importance of the cape jessamine as a food plant lies in the great dan-
ger it presents as a distributer of the white fly. This will be referred
to again under the subject of methods of spread.

The subject of the adoption of the cape jessamine by the citrus
white fly is not of sufficient importance to have been given more
than incidental consideration. In general the degree of adoption
seems to be less than is the case with the umbrella and China trees.
On November 17, 1907, an examination made of 30 leaves picked at
random from both old and new growth of a cape jessamine which
appeared to be in an ordinary condition of infestation as observed
when growing near infested citrus trees showed that there existed an
average of 45.1 forms per leaf.

The extensive growth of cape jessamines, or gardenias, as the
blooms are sometimes called, for commercial purposes is known to
the authors and occasions a conflict of interests only in Alvin, Tex.
From the orange grower's standpoint this, at the most, applies to a
location adjoining an orange grove where the citrus white fly is uncon-
trolled. Fortunately, however, for the citrus growers, it is of great
importance to the success of the florist's business that the white fly
be kept in subjection in gardenias.

PRIVET HEDGES.

Privet hedges are not uncommon in citrus-growing sections, and
heavy infestations by the citrus white fly occur in parts of Georgia
and South Carolina, where no citrus trees are grown. As a food
plant the privets are of economic interest in the same respects as is
the cape jessamine, but they are more extensively grown and of pro-
portionally greater importance. No studies have been made of the
degree of adaptation and attractiveness, but the several species of
privet observed in infested localities have shown the propriety of
classing them with citrus, China trees, umbrella China trees, cape
jessamine, and other preferred food plants. The senior author ob-
served a migration of adults from privet hedges in Victoria, Tex., in
the summer of 1904, which indicated that a hedge of this material

THE CITRUS WHITE FLY: FOOD PLANTS. 41

might well be compared in its injurious influence on citrus-growing
interests to one or more umbrella or China trees. The privet, like
the cape jessamine, is hardy, and the disadvantages of the former in
this connection are the same as those mentioned in discussing the
latter food plant.

JAPANESE AND WILD PERSIMMONS.

Japanese and wild persimmons are attractive to the citrus white
fly early in the season, but appear to be very little or not at all so
late in the season. Being deciduous, their economic importance as
white fly food plants is proportionally small. Under certain condi-
tions the Japanese persimmons appear much more attractive to the
citrus white fly than citrus trees. These conditions have not been
investigated, but they are probably dependent upon the appearance
of new growth in the spring a little earlier on persimmon than on
citrus. On June 16, 1909, an examination of a large bearing per-
simmon tree surrounded by citrus nursery trees and bearing citrus
trees of different kinds showed that the first spring growth of the
persimmon was much more attractive to the first brood of adults
than were the citrus trees. The second brood of adults, however,
found the persimmon comparatively unattractive and showed a
marked preference for the citrus trees. The earliest citrus growth of
the spring had become fully matured, and no new growth appeared
until after the second brood of adults had practically disappeared.
The comparative condition of infestation is shown by counts made
on leaves picked at random from the persimmon tree and from the
surrounding citrus trees, including the sweet orange, sour orange,
tangerine, and grapefruit. The average infestation with first-
generation forms of the citrus white fly on 25 leaves each of per-
simmon and citrus was in the ratio of 10.9 to 1.3, while that of the
same number of leaves by the second generation was in the ratio of
no forms on the persimmon leaves as compared with 191 on the citrus,
thus showing the great preference of the second generation of adults
for citrus growth.

Neither the Japanese nor the wild persimmons are usually infested
by the citrus white fly to the extent of causing noticeable blackening
from sooty mold. The infestation, however, might be between from
five to ten times as great as on the leaves from the trees referred to above
without producing this result. Small wild persimmon bushes have
been observed in a growing condition at the time the adults of the sec-
ond brood are on the wing, and at such times they sometimes appear to
be very attractive as food plants. Mr. W. W. Yothers has observed
near Hawthorn, Fla., on April 29, 1909, the citrus white fly on wild
persimmon bushes growing in pine woods at distances upward to one-

42 WHITE FLIES INJURIOUS TO CITEUS IN FLORIDA.

fourth of a mile from any citrus grove, and the junior author has
made similar observations along roadsides near Orlando, Fla., in
June, 1909, the insects being in the adult stage only in this latter
case. On the other hand, the senior author noted on June 18, 1909,
that wild persimmon bushes growing in a vacant lot with China trees
and abandoned citrus trees were only very slightly infested, although
the citrus trees and the China trees were heavily infested. The
wild persimmon had made vigorous growth, but its white-fly infesta-
tion consisted of less than 10 eggs per leaf and an occasional adult.
The examination of leaves of the China tree showed hundreds of
pupae and pupa cases per leaf, with a few adults and newly deposited
eggs. The old citrus leaves bore many larvae, pupae, and pupa
cases, and the new leaves bore hundreds of unhatched eggs. The wild
persimmon bush was as favorably located with respect to citrus trees
as was the China tree. Notwithstanding the exceptions noted in
degree of attractiveness, the Japanese and the wild persimmons very
evidently rank well below citrus trees, China trees, and umbrella
China trees. ;

In so far as observed the persimmons have little effect on the con-
trol of the citrus white fly, but in special cases they may rank as
important food plants. The fact that the Japanese persimmon is a
producer of fruit of some commercial value makes its ordinary light-
ness of infestation a matter of gratification. The wild persimmon, on
the other hand, is of practically no value either for shade or fruit, and
can easily be destroyed where advisable.

Lilac is not commonly grown in the citrus-growing regions of the
Gulf States, and on this account, so far as observed, presents no
element of menace to orange groves. In company with all of the
ornamental plants listed as preferred food plants this one must be
considered, however, as undesirable for introduction and growing
in citrus-growing regions.

PRICKLY ASH.

Belonging to the family Rutaceae, to which the genus Citrus also
belongs, it is not strange that the prickly ash is a favorite food plant
of the citrus white fly. This plant seems to be highly attractive to
the adult flies, frequently being observed infested with more adults
than many near-by citrus trees combined. The prickly ash is common
in Florida and in some localities, wiiere growing in abundance along
roadsides, it constitutes a distinct menace to citrus groves through its
connection with the spread of the white fly from city and town to
country and from grove to grove.

THE CITKUS WHITE FLY I SPREAD. 43

Dr. E. W. Berger has reported having observed a coffee tree thor-
oughly infested with as many eggs on its leaves as citrus leaves may
have. This food plant is too rarely grown in the Gulf States in
orange-growing regions to be of any importance economically as a
white-fly food plant.

OCCASIONALLY INFESTED FOOD PLANTS.

The plants listed in Class II as a whole are of very little importance
as regards their bearing on white-fly control. Banana shrub, cherry
laurel, and cultivated pear might well be considered in a third class
for rarely infested plants. Although not uncommon, their attraction
for the citrus white fly is so slight as to make it safe to ignore them
except in the matter of introducing the fly on them into noninfested
districts. In unpublished notes Dr. Berger has recorded the wild
olive as a food plant. He has observed the wild olive infested in com-
paratively isolated places. The junior author has observed wild olive
heavily infested in Charleston, S. C, and in several places in Orange
County, Fla. The wild olive, being an evergreen, if neglected may
prove to be of considerable importance as a food plant when growing
in abundance near a fumigated grove or when citrus trees have been
defoliated by cold.

Dr. Berger has recorded pomegranate, allamanda, and smilax as
food plants, and has verified Prof. Gossard's record of Viburnum
nudum as a food plant of the citrus white fly. The positions of
these plants as regards their attractiveness to the citrus white fly has
not been fully determined, and further observations will perhaps
show one or more of them to be of fully as high if not of higher rank in
this respect than the persimmons. In general, however, like the coffee
and lilac of Class I, they are not of sufficiently common occurrence in
the Gulf coast citrus-growing regions to be of much economic impor-
tance as citrus white-fly food plants.

SPREAD IN THE UNITED STATES.

There is seldom positive evidence in regard to the means by which
the citrus white fly has become established in a previously non-
infested grove or locality. Such direct observations, however, as it is
possible to make, aided by strong circumstantial evidence, give us a
sufficient knowledge of the methods of spread to show the advisa-
bility of certain restrictive measures.

Checks on Successful Establishments.

Fortunately the chances are greatly against the successful estab-
lishment of the citrus white fly in a previously uninfested locality,
which is outside the limits affected by large numbers of migrating

44 WHITE FLIES INJURIOUS TO CITRUS IX FLORIDA.

adults. If this were not so the pest would have become established
in every grove of the State long before the present time. Except for
spread by direct flight and on nursery trees and ornamental plants,
the chances are against more than a few insects being introduced into
a particular grove by any of the other methods discussed hereafter.

In the case of a single adult there are two chances in three that it
would be of the reproductive sex. If, as would be probable, the
specimen were a female, there would be about one chance in three
that it would not have been fertilized. In this case the second
generation of adults would all be males, as shown by the observations
recorded under the subject of Parthenogenesis. This would, of course,
end the infestation directly due to the single specimen introduced,
as the original female would have died several weeks before the first
male matured. In case the originally introduced specimen were a
female and fertile the chances of a male appearing among the second
generation are not definitely known , but are with little doubt only
small. The chances of such a male appearing at a favorable time to
meet with and to fertilize a female of the same parentage are practi-
cally negligible, though possible as a result of the great variation in the
length of the life cycle as recorded under life history. The third
generation would, therefore, in all probability, be all males, and the
infestation ended. The chances that a single adult specimen intro-
duced into an isolated grove or into a previously noninfested com-
munity would successfully establish a permanent infestation are
extremely smaU. The chances are only slightly increased by an
increase to 5 or even 10 in the number of adults originally introduced
into a single grove.

From the foregoing considerations it is evident that two or more
distinct introductions of even a few individuals at proper intervals
during a single season might greatly increase the chances for the suc-
cessful establishment of the pest.

Flight of Adults.

The flight of adults is the most important method of local distribu-
tion and is also an important element in its association with spread by
means of winds and vehicles, railroad trains, and boats.

The distance to which the insect is capable of flying. — It would be
almost impossible to obtain positive records on the distance the adult
citrus white fly is capable of flying. Mr. TV. W. Yothers, on April 29,
190S, found on wild persimmon first and second generations of this
species of fly at a distance of one-fourth of a mile from the nearest
orange grove, which was also the nearest point of the occurrence of a
food plant upon which the insect could have passed the winter. The
infested persimmons were in pine woods and the insects were in such
numbers that it was evident that spread through pine woods might

THE CITKUS WHITE FLY: SPREAD. 45

easily greatly exceed one-fourth of a mile. Mr. W. C. Temple, of
Winter Park, Fla., states that he has observed adults migrating into
one of his groves on Lake Maitland under circumstances plainly indi-
cating that they had traveled over the water for If miles. Dr.
Berger has recorded an instance which presents strong evidence that
adult white flies have heavily infested citrus trees through flights of a
mile or more. On the other hand, there are orange groves within
three-fourths of a mile of the city limits of Orlando, Fla., and within
2 miles of the courthouse which have only so recently become infested
that no blackening of the foliage has taken place, although the citrus
white fly has occurred at Orlando for more than 10 years with migrat-
ing adults in summer about as abundant as in any town in the State.
As regards the capability of flight of the citrus white fly, it may be
said to be undoubtedly more than a mile and perhaps several miles
when aided by a gentle breeze. Distances of even a mile, however,
are not usually attained except under certain circumstances which
are largely preventable and which are discussed in the following
paragraph.

Cause of extensive migrations by flight. — Overpopulation of food
plants, usually associated with the emergence of adults in large num-
bers at seasons when the new and attractive growth is scarce or en-
tirely wanting, is the main cause for migrations from citrus, cape
jessamine, and privet. Migrations from China trees and umbrella
trees, probably the most potent factors in the spread of the pest, are
not due directly to overpopulation, so far as observed, since leaves are
never overcrowded in a manner comparable to the overcrowding
on citrus leaves. An average of 25 live larvae or pupae and pupa
cases per square inch of lower leaf surface would represent an un-
usually heavy infestation of a China or umbrella tree and is rarely
exceeded, whereas an average of 50 or 60 per square inch is not un-
usual for citrus leaves. In the case of China and umbrella trees, mi-
grations are evidently due to lack of attractiveness of the foliage to the
adult white flies at the times when the migrations occur. There are
comparatively few live larvae and pupae on the foliage after the middle
of August at Orlando. The greater part of these represent delayed
emergence from the second generation of white flies and not the result
of eggs deposited by the third brood of adults. This supports direct
observations to the effect that the third brood of adults, which is con-
cerned in the most extensive migrations, deposits practically no eggs
on the China and umbrella trees.

China and umbrella trees as a factor in dissemination. — Umbrella
and China trees are extensively grown throughout the Gulf coast
citrus-growing regions, and they are almost entirely responsible for
the hundreds of millions of adults which in midsummer appear on
the wing throughout most of the towns where the citrus white fly

46 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

occurs. That these are principally those which have bred upon
China and umbrella trees is shown clearly by the fact that at Gaines-
ville, Lake City, Tallahassee, and other points in the northern part of
Florida, where other food plants are too few to produce noticeable
numbers of migrating adults, the numbers are apparently not less
than where both citrus trees and China and umbrella trees are exten-
sively grown, as at Orlando. On this point, Dr. Berger states:1
"The principal food plants in Gainesville and north Florida are China
and umbrella trees, there being only enough citrus, privet, and other
evergreen food plants to bring about the restocking of the deciduous
trees every spring." These considerations indicate very positively
the main source of the enormous number of migrating adult flies on
trees in midsummer, sometimes observed between the middle of
May and the middle of June. These adults are the second brood of
the season and the first to mature on the food plants mentioned. The
newer growth of these trees is, as has been shown, very attractive to
the adult flies, and if there is an abundance of it comparatively few
migrate. The third brood, composed mainly of individuals of the
second and third generations, matures over a more extended period,
in general covering the months of July and August in different sec-
tions of Florida.

Estimates of the number of adult citrus white flies breeding on
umbrella trees and on citrus trees as given under the subject of food
plants have shown that a single umbrella tree of medium size may
produce as many adult white flies by midsummer as could be pro-
duced on 7 acres of orange trees. The maturity of so many adults
on single trees, and their migration therefrom in search of a more
desirable food supply than China and umbrella trees afford in mid-
summer, cause the rapid spread of the pest throughout the towns,
directly by flight of the adults and by mediums hereinafter dis-
cussed into the surrounding country and from town to town along
railway lines and watercourses.

Dissemination hy flight when citrus trees only are concerned. — It has
been shown under the subject of food plants that the citrus white fly
does not ordinarily increase to the point of overcrowding on grape-
fruit. Migrations of adults in noticeable numbers from solid blocks
of these trees probably never occur under ordinary circumstances,
and spread through such blocks or groves from the first point of infes-
tation is very slow if no other food plants are concerned. The spread
in groves of orange or tangerine trees or of both is more rapid, but
not as much so as ordinarily considered. The white fly is rarely
observed during its first 3^ear's appearance in a citrus grove. Atten-
tion is usually first attracted to its presence through the blackening
of foliage on one or a few trees. This blackening of foliage in itself

1 Press Bulletin 10S, Florida Agriculture Experimental Station, February 13, 1909.

THE CITRUS WHITE FLY: SPREAD. 47

is almost positive evidence of the presence of the fly in the grove
during at least the preceding two years unless the infestation is due
to migrations from China or umbrella trees or from overstocked
neighboring citrus groves. In such cases infestation may become
quite general throughout several acres in one season and extensive
blackening of the foliage may result early in the next season, or in
about one year after the first introduction. In the case of new infes-
tation in any locality, however, the beginning doubtless is usually
the introduction of a few insects by some one of the means herein-
after discussed. In a mixed grove of tangerine and orange the pest
is discovered first as a rule on tangerine, and in a grove of seedling
trees with a few budded trees intermixed usually the latter are first
discovered to be infested. Many citrus growers who have groves,
such as those mentioned, and who have watched carefully for the
appearance of the pest in their groves, have finally found it well
established on a single tangerine or budded orange tree before any
evidence of the presence of the insect was observed elsewhere.
Through the hindrances to successful establishment and the checks
on multiplication, principally those discussed in connection with
parthenogenesis and natural mortality, the white fly frequently
develops so slowly after its first introduction that it may not increase
to the point where it is usually first observed for three or four years.
It is a common error to consider that the first discovery of the white
fly in a grove is an indication of its very recent introduction. This
may or may not be the case. Usually it is not the case. It should
be borne in mind in this connection that in the most careful inspec-
tion, even by a competent entomologist, the failure to discover a
single specimen of the white fly is not positive proof that it is not
present. The foregoing generalizations are based upon many
observations by the agents of this bureau who have been engaged in
these investigations, more particularly the authors of this bulletin
and Mr. W. W. Yothers.

The rapidity of spread into a citrus grove from neighboring infested
groves is a subject which becomes temporarily important when a
nonisolated grove becomes infested for the first time. It is a subject
of more far-reaching importance in connection with fumigation, and it
is in this connection that the most extensive studies in this line have
been made. The result of these studies will be published in a final
report on fumigation.

The slowness with which the citrus white fly increases in numbers
and spreads from the first point of infestation has been noted by
many citrus growers who have been observant enough to discover
the white fly soon after its introduction into their groves. When
the rate of spread of the white fly through the grove is affected by
the presence of migrating adults from China or umbrella trees, the

48 WHITE FLIES INJURIOUS TO CITRUS IX FLORIDA.

difficulties in effectively utilizing artificial checks, spraying and fumi-
gation, are greatly increased. As the infested area in a newly infested
grove or locality becomes larger the rate of spread by flight increases,
aided by secondary centers of infestation which become established
by various means.

Winds.

Light winds are an important adjunct to flight in the local distri-
bution of adult white flies, but strong winds are ordinarily of slight
consequence. The effect of light winds is shown by the influence
of almost imperceptible movements of the air on the direction of
migrations. This is especially noticeable in the vicinity of China
and umbrella trees during a season when adults are emerging in abun-
dance. The principal effect of the movement of the air under such
conditions is not in carrying the insects, but in causing the flight
energy of the insect to be expended in one general direction rather
than to be wasted in zigzag lines with comparatively little real pro-
gression. Other conditions being equal, the adult white flies migrate
in greatest abundance when the atmosphere is calmest, and con-
versely show the least tendency to migrate in strong winds. It
is possible that isolated infestations may sometimes result from
spread of adults by strong winds, but it is seldom that there is not
a more plausible explanation obtainable. With the white fly pres-
ent in abundance for many years in Orlando, Fla., and other towns
and cities in important orange-growing sections of Florida, the fact
that there are still many noninfested citrus groves within a radius
of 5 miles of nearly all such centers of infestation is in itself an indi-
cation of the minor influence of winds in this connection. Strong
breezes or winds exert some check on the spread of adults by causing
them to cling tenaciously to their support, as pointed out by Frof.
H. A. Gossard.1

VEHICLES, RAILROAD TRAINS, AXD BOATS.

In towns in Florida where the citrus white fly occurs and China
trees and umbrella trees are abundant it is a matter of common
observation that during the periods of migration large numbers of
adults alight upon automobiles, carriages, wagons, and railroad coaches.
The authors have seen covered carriages with more than 100 adults
resting on the inside of the top and sides. In driving through a
heavily infested citrus grove in late afternoon at certain seasons,
hundreds of adults may be observed on the carriage (PL VI, fig. 2).
Newly infested groves show the first infestation so frequently on trees
close to a driveway or road that conveyance of the citrus white fly by
means of carriages, wagons, and automobiles must be considered one of
the most important methods of spread from town to surrounding

1 Bulletin 67, Florida Agricultural Experiment Station, p. 13.

Bui. 92, Bureau of Entomology, U. S. Dept. of Agriculture.

Plate VI.

Dissemination of White Flies.

Fig. 1.— Nursery citrus trees infested with white flies set out in an isolated noninfested grove
without having leaves removed. Fig. 2.— Buggy in an orange grove; buggv top full of adult
white flies ready to be carried to other groves. Fig. 3.— Train at station; adult citrus white
flies swarming from near-by umbrella China trees into coaches ready to be carried for miles
down the Florida east coast. (Original.)

THE CITKUS WHITE FLY: SPREAD. 49

country or from grove to grove. At Orlando, in July, 1906, adult
citrus white flies were observed late in the afternoon alighting on the
sides of coaches and flying into the windows and doors of coaches
of a passenger train standing at a railroad station (PL VI, fig. 3).
Hundreds of adults were carried west toward Wildwood through
points which, so far as known, were not infested at the time. The
presence of China, umbrella, or citrus trees near railroad stations
increases the chances for successful introduction by railroad trains.
In this connection the recent action of the Atlantic Coast Line Rail-
road and Seaboard Air Line Railway in destroying such trees along
their right of way is to be commended. A map of Florida showing
the distribution of the citrus white fly plainly indicates the relation
between the railroads and the main lines of dissemination. This is
shown in an incomplete way by figure 2, in which are given the points
infested by the citrus white fly in Florida according to the records
made in connection with the present investigation and such other
records as are undoubtedly correct or which have been verified. The
infestation at Arcadia, Fla., first discovered in January, 1907, but
which probably resulted from an introduction of citrus white flies
in 1905, was with little doubt due to the introduction of adult flies
by means of railroad trains. An examination of the situation in
February, 1907, by the senior author showed the center of infestation
to be located near railroad stations, and careful inquiry concerning
other possible sources showed that railroad trains were the most
likely means of introduction. North of Arcadia no nearer infested
point was known than Bartow and toward the south no nearer
infested point than Fort Myers. The distance in each case was about
40 miles. So far as known there were at that time no intermediate
points infested between Arcadia and the two points mentioned.
Here again the factors unfavorable to the successful establishment
of the pest in a previously uninfested locality play an important role,
as shown by the fact that even at the present writing the citrus white
fly is not generally distributed between Bartow and Fort Myers.
As we have no record and have heard no report of the occurrence of
the fly at any other point than Arcadia, it is unlikely that other
infested points exist.

Steamboats are used quite extensively on the rivers and along the
coast of Florida in transporting citrus fruits and have in a degree a
similar status to railroad trains in transporting the citrus white fly.

Citrus Nursery Stock and Ornamental Plants.

The carriage of the citrus white fly in its egg, larval, and pupal
stages by means of citrus nursery stock (PL VI, iig. 1) and ornamental
plants has always been an important factor in the spread of the

59131°— Bull. 92—12 4

50 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

insect. The citrus white fly was without doubt introduced into the
United States and distributed to the most important centers of
infestation by this means. In Florida the white fly was probably
introduced first on citrus nursery stock into some citrus grove on the
St. Johns River in St. Johns County, and later by the same means
into Manatee and Fort Myers. Gainesville, Ocala, Orlando, and
Bartow were probably among the points to which the white fly was
introduced on nursery stock. The distribution of the citrus white
fly along the Gulf coast citrus-growing regions west of Florida has
been largely due to shipments of infested citrus nursery stock,
umbrella trees, privets, and cape jessamines. Of all methods of
spread which are operative over greater distances than the flight of
adults, introductions of live immature stages on trees or shrubs for
transplanting purposes are by far the most certain to result in the
successful establishment of the species. Fortunately it is practicable
to prevent spread by this method by defoliating the trees as they leave
the nursery. Much has been accomplished in the past by individual
citrus growers, but more attention should be given to this matter in
communities not now infested by both of the white flies treated in this
bulletin.

Accidental Spread by Man.

Carriage oj the adult white flies on human oeings. — Man is doubtless
responsible to a limited extent for the spread of adult white flies.
During migrating periods, when in heavily infested orange groves or
in towns where there are infested China and umbrella trees, adults are
frequently observed on the clothing. Prof. H. A. Gossard states
that he has carried adult white flies for nearly half a mile on his
clothing after standing beneath a heavily infested tree.

Introduction in pickers' outfits. — In some instances the citrus
white fly is believed to have been introduced into previously unin-
fested localities by orange pickers. In this case the principal danger
lies in introducing live pupae on citrus leaves accidentally brought
in with picking sacks and field boxes. The authors consider that there
is practically no danger of the carriage of adults of the citrus white
fly by pickers' outfits between December 1 and March 1. The few
adults present in citrus groves during this period would rarely result
in their transference to uninfested groves by such means, and the
unfavorable factors heretofore discussed would almost certainly
prevent the successful establishment of the pest. It would be
almost impossible to conceive of any likely method by which a suc-
cessful introduction of the citrus white fly into a noninfested grove
could be accomplished by the carrying of leaves infested by eggs or
larvae. Leaves infested with live pupae, however, particularly about
the time of the beginning of emergence of the first spring brood,

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS. 51

might readily produce a sufficient number of adults to successfully
establish the pest. Such leaves, after introduction, would need to
have a favored location, for exposure to much sunlight or to too
much moisture would soon destroy the insects.

Introduction on leaves infected with parasitic fungi. — The matter of
spread of the white fly in connection with the attempt to introduce
parasitic fungi is a subject of considerable importance. The danger
here is due to the failure to recognize the distinction between the
citrus white fly (Aleyrodes citri) and the cloudy-winged white fly
(Aleyrodes nubifera). The owner of a grove infested by the latter
species only, would provide a very favorable opportunity for the
introduction of the first and most destructive species if in introduc-
ing parasitic fungi he should obtain his supply of leaves from certain
sections of Florida. The spread of the cloudy-winged white fly has
been encouraged in a similar manner. The tree-planting method of
introducing the fungi, especially the brown fungus, is the most dan-
gerous practice in this connection. Of somewhat less danger in the
individual cases, but of far greater danger on account of the more
frequent opportunities presented, is the introduction of fungus-
infected leaves for pinning or for spraying the spores. The pinning
of leaves as a means of introducing the parasitic fungi has little more
to recommend it than the tree-planting method, but it has without
doubt been the means of introducing the citrus white fly on many
occasions. Leaves introduced for the spore-spraying method of
spreading the fungus parasites are an element of much danger under
certain conditions. Some sections of Florida in which only the cloudy-
winged white fly occurs are in more danger of having the citrus white
fly introduced by some uninformed person in this way than they are
of its introduction in any other manner. Specific examples might be
cited where the introduction of either A. citri or A. nubifera was
with little doubt due to introducing fungus-infected leaves or trees,
but the danger is too obvious to require further discussion in this place.

LIFE HISTORY AND HABITS.

Summary.

The eggs of the citrus white fly (fig. 3) are laid scatteringly, with
few exceptions, on the underside of the leaves of the various food
plants, and hatch in from 8 to 24 days, according to the season.
During ordinary summer weather from 75 to 100 per cent hatch
on the tenth to twelfth day. Infertile eggs hatch as readily as fertile
eggs and produce adults of the male sex only. After hatching, the
young larva (figs. 4-6) actively crawls about for several hours, when
it ceases to crawl, settles upon the underside of the leaf, and begins
to feed by sucking the plant juices. It molts three times before

52 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

becoming a pupa. After the first molt (see fig. 7) the legs become
vestigial; hence thereafter it is impossible for it to materially change
its location upon the leaf. Larval life averages in length from 23 to
30 days. The pupa (fig. 9) closely resembles the grown larva (fig. 8)
and requires from 13 to 304 days for development. The adult fly
(Rg. 10) has an average life of about 10 days, although several females
have been Known to five 27 days. Females may begin depositing
eggs as soon as 6 hours after emergence and continue ovipositing
throughout life. The maximum egg-laying capacity is about 250
eggs, although 150 more nearly represents the number laid under
grove conditions. Unfertilized females deposit as many eggs as
fertile females.

The entire life cycle from egg to adult requires from 41 to 333
days; the variation in the number of days required from eggs laid
on the same leaf on the same day is very remarkable. During the
course of the year the fly may pass through a minimum of two gen-
erations and a maximum of six generations. The generation started
by the few adults that emerge during the winter is entirely dependent
upon weather conditions and may or may not occur. Each genera-
tion except those started after the middle of August is more or less
distinctly two-brooded.

Methods op Study.

As it is impossible to rear citrus white flies through their entire
fife cycle on detached leaves, a gauze-wire cage was devised by the
senior author which has proved of great value and convenience in
carrying on life-history studies under conditions as nearly normal as
it is possible to get them. This cage (PI. VII), which is cylindrical
in shape and open at one end, may be made any size, but one 6^
inches long by 3J inches in diameter has proved most convenient.
It can easily be made by fashioning two rings of heavy wire to which
is soldered the wire gauze, as shown in the illustration. To the open
end is attached a piece of closely woven cheesecloth long enough
to extend about 4 inches beyond the cage. After the leaf, or leaves,
to be caged have been cleaned of all stages of the white fly by means
of a hand lens and cloth, the cage is slipped over the foliage. The
adult flies are then introduced, if desired, and the cloth attached to
the cage wrapped around the stem of the shoot or petiole of the leaf,
as the case may be, in such a manner that the flies can not escape
nor the ants and other predaceous insects enter. To keep the entire
weight of the cage from falling on the petiole of the leaf or its short
stem, and to regulate the position of the leaf within the cage, a cord
is tied around the outer end of the cage and attached by the loose
end to a convenient branch.

Jul. 92, Bureau of Entomology, U. S. Dept of Agricultur

Plate VII.

Cages for Rearing White Flies.
Fig. 1.— Rearing cages in position on orange trees. Fig. 2.— Enlarged rearing cage. (Original.)

THE CITRUS WHITE ELY: LIFE HISTORY AND HABITS. 53

A very satisfactory method of definitely marking larvae in order
that no mistake may be made in identifying field notes with the
individual larva? to which they refer, is to scratch lightly on the
epidermis of the leaf, with a thorn or pin, a bracket or other mark
and outside this a number that shall correspond with that used in
the note book. In marking larvae care should be taken in scratching
the leaf to allow for the future growth of the insect and not to injure
the epidermis of the leaf too severely. In this manner a large number
of larvae were marked as soon as they settled and their growth noted
by daily observations.

In determining the sums of effective temperature, 43° F. has been
taken as a basis in accordance with Dr. Merriam's general law
although this has led to certain inaccuracies of which the authors
are aware. The determination of the effective
temperature in the case of the white fly would
require a special study which it has been imprac-
ticable to undertake.

The Egg.
description.

The eggs of the citrus white fly (fig. 3) are so
small that they appear to the unaided eye as
fine particles of whitish dust on the under sur-
face of the leaves. Their minute size is empha-
sized by the fact that 118 placed end to end would measure but an
inch, while about 35,164 could be placed side by side in one square
inch. Under the magnifying lens they appear as smooth, polished,
greenish-yellow objects shaped much like a kernel of wheat. Fol-
lowing is a more minute description:

Length, 0.2-0.23 mm.; width, 0.08-0.09 mm. Surface highly polished, without
sculpturing, color pale yellow with faint greenish tinge when first deposited, paler than
the under surface of the leaf. Egg elongate, subellipsoid, slightly wider beyond the
middle or at about the point where the eyes of the embryo subsequently appear; borne
at end of a comparatively slender brownish petiole or footstalk, slightly shorter than
the width of the egg, and somewhat knobbed at base.

As the embroyo approaches maturity its purple eyes may be seen
showing distinctly through the egg membranes at a point beyond the
middle of the egg. At about this time, also, the hitherto uniformly
colored egg contents become orange or golden at the proximal end and
whitish translucent on the distal three-fourths. The egg surface
sometimes assumes a white pruinose appearance, due to the presence
of wax rubbed from the bodies of the adults while crawling over the
eggs. Eggs deposited on leaves from which the adults have been
excluded after egg deposition do not show this pruinose condition.

Fig. 3. — The citrus white
fly (Aleyrodes citri): Eggs.
G reatl y enlarged . ( 0 r igi-
nal.)

54 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

Eggs in which the embryonic development is normal do not turn dark
in color, but those killed through attack by thrips or by other agency
frequently become bronze colored, thus resembling the eggs of A.
nuhifera from which the waxy sculpturings have been rubbed.

DURATION OF EGG STAGE.

That no doubt might arise concerning the exact age of the eggs
used in obtaining the data incorporated into Table VIII, suitable
leaves were selected from which all eggs previously deposited were
carefully removed by the aid of the hand lens and a cloth. Similar
attention was given the leaf petiole and the stalk, and wads of cotton
were tied about the latter both above and below the leaf to prevent
crawling young from reaching the leaf along the petiole (PL VII, fig.
1). These preliminary steps completed, a rearing cage containing
adult white flies was placed over the leaf and allowed to remain the
length of time desired, usually from 1 to 24 hours, with preference
shown the latter number. The cage was then removed and an
empty one put in its place. By this method all doubt was removed
as to the period of time over which deposition took place. As there
is scarcely a leaf in a grove infested with the citrus white fly that
does not bear from a few to many eggs, this becomes an important
point and failure in its recognition has led in the past to statements
greatly underestimating the minimum duration of the egg stage dur-
ing the warmer months.

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS.

55

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56 WHITE FLIES INJURIOUS TO CITE ITS IX FLORIDA.

The conclusions presented herewith are drawn from the data pre-
sented in Table YIII, based upon daily observations of over 5,000
eggs deposited at intervals from February to October. From these
and other data not included, it can be stated that the eggs hatch dur-
ing a period of from S to 24 days after deposition, according to the
season of the year. While there are no data regarding the length of
the incubation period for eggs deposited by the few female flies occa-
sionally seen during the winter months, as noted under seasonal his-
tory, it is probable that hatching extends over even a greater number
of days during the winter season. The deposition of such eggs is,
however, a comparatively rare occurrence and will receive no further
mention here. In no instance have eggs been seen to hatch before
the eighth day from deposition, even during the months July and
August, 1907, when the average mean temperatures were slightly
above normal, while under the most favorable summer weather con-
ditions from 75 to 100 per cent of the eggs hatch during the period
from the tenth day to the twelfth day from deposition.

In general, the warmer the season the shorter and more nearly uni-
form is the period of egg development or incubation. During the
months of July and August, when the normal monthly temperatures
at Orlando range from about 72° F. as the mean of the minimums to
about 93° F. as the mean of the maximum records, practically all the
eggs hatch from the tenth day to the twelfth day. Even at this most
favorable season, in one instance hatching was delayed for 19 days.
During the somewhat cooler weather of late September and early
October and the decidedly cooler months of February, March, and
April, hatching is more or less delayed according to the prevailing
temperature and is scattered over a larger number of days. This
same result is brought about, only in a less degree, by a cool period
occurring in an otherwise warm season, as shown under record 4
(Table YIII).

Reference to the daily rate of hatching in Table VIII, and to the
accompanying degrees of accumulated effective temperatures, shows
that regardless of the time of year deposited and the number of days
required for incubation, over 90 per cent of the eggs, on an average,
hatch between the accumulation of from 375° to 475° of effective
temperature.

Exception to this statement must be taken in records 1 and 2
(Table VIII). The number of degrees of effective temperature
required seems to be greater at this season, although this might not
prove to be the case if, as is probable, an error has arisen from using
43° F. as the basis for calculating the effective temperature.

Reference to the two preceding tables shows that considerable
variation exists in the length of the egg stage among eggs deposited
on the same day, or even within the same hour, and subsequently

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS. 57

subjected to identical conditions of heat and moisture. Even when
hatching was most concentrated during the heat of summer and 99.8
per cent of the eggs hatched on the tenth and eleventh days from
date of deposition, hatching extended over a period of from 9 to 19
days. Hatching over a period of from 6 to 7 days after the first
crawling young appears is an ordinary occurrence during the cooler
portions of the season of activity. In this respect, white-fly eggs are
markedly different from the eggs of most other insects deposited in
batches which usually hatch within one or, at the most, a few hours
of each other.

PARTHENOGENESIS .

The existence of parthenogenesis among aieyrodicls was first rec-
ognized by the senior author * in connection with his investigations
of the greenhouse white fly (A. vaporariorum) . His prediction at that
time that this method of reproduction would ultimately be proved to
occur among many if not all the species of Aleyrodes has been strength-
ened by the results of the present investigations. While there are no
definite data to the effect that parthenogenetic eggs are deposited
under natural conditions, there is practically no doubt that such depo-
sition does occur, especially by females not yet mated or by females
appearing at unseasonable times or when males are decidedly in the
minority. Scattered females emerging during the winter, or resulting
from the comparatively few pupae surviving fumigation, either never
have the opportunity to mate or deposit many of their eggs before
such opportunity presents itself.

That virgin females of A. citri, emerging from pupae kept separately
in vials, and later confined in rearing cages under normal grove con-
ditions, except for the exclusion of males, will readily deposit the nor-
mal number of eggs, and that these eggs will develop normally and
will produce adults of the male sex, has been thoroughly demonstrated.
Of the five separate cage experiments started with parthenogenetic
eggs, all of 111 adults emerging in four of the cages were males, while
of 208 more adults emerging from the fifth cage, all but 4 individuals
were males ; the 4 females emerging under such conditions as to lead
to the supposition that they came from fertile eggs overlooked in
preparing the leaf for the experiment.

HATCHINCx.

In hatching, the egg membranes rupture at the end opposite the
pedicel, and then split down each side sufficiently to permit the
young larva to crawl out. The glistening eggshell, somewhat resem-
bling in appearance a bivalve shell, eventually becomes shriveled
and loses its original form.

1 Notes on Some Aleyrodes from Massachusetts, with Descriptions of New Species.
Psyche, April, 1903, p. 81. Technical Bulletin No. 1, Mass. Agr. Exp. Sta., pp. 31-33.

58 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

Proportion of eggs that hatch. — Observations covering many thou-
sands of eggs, both in the cage experiments and in the grove, have
demonstrated that the number of eggs that fail to hatch is too insig-
nificant and has too little practical bearing to warrant the collection
of data on this point. It is safe to say that considerably less than 1
per cent do not hatch. In fact, it seems evident that no egg would
fail to hatch except owing to the dropping of the leaf or unless sub-
jected to attack from without. In many instances failure to hatch
can be directly traced to attack by several species of insects and a
fungous parasite.

Effect of drying of leaves on hatching. — In 10 instances leaves bearing
many thousand eggs were so placed that the eggs were exposed to
direct sunlight or to partial shade, and although frequent observa-
tions were made none of the eggs were known to hatch. In general
the drying of leaves to which eggs are attached prevents hatching of
all except those eggs containing nearly mature embryos. This fea-
ture is probably common to all aleyrodids, since the senior author
has noted a similar occurrence in the case of the greenhouse white fly
(A. vaporariorum) .

The Larval and Pupal Stages,
description of stages.

THE LARVA.

The larva? * are thin, translucent, elliptical, scalelike objects, found
usually on the underside of the leaves, though more rarely upon the
upper surface. When normally attached to the leaf they are so
nearly transparent as to be seen with difficulty. They readily
become visible, however, by either bending or rubbing the fingers
along the opposite side of the leaf, thus loosening them and allowing
the air to get beneath them. They then appear whitish (PL X, fig. 2).
So very inconspicuous are the live larvae and their attack so unac-
companied by any visible effects on the leaves, aside from the black-
ening of the foliage, that their presence is very frequently overlooked
by the casual observer. A detailed description follows:

First instar larva (figs. 4-6). Length, 0.3 to 0.37 mm.; width, 0.182 to 0.22 mm.
Body flat, scalelike, somewhat swollen ventrally, especially in the cephalothoracic
region; margin entire, with 30 small tubercles, each bearing a horizontally directed
spine of which 6 cephalic and 4 anal are proportionately longer. Spines of second
pair, counting from anterior end of body, arising from tubercles not on, but slightly
posterior to, margin on ventral surface. Relative lengths of the 15 pairs of spines as
follows:

Pair 1 _2_^Jt 5 6 7 10 11 12 13 14 15
Spaces ll' 9.8' ll' 6.5' 5.4' 5.5' 6' 4' 4' 4 ' 18' 5.4' 18.5'

1 The larvae and pupae are frequently called by many growers the "egg" of the
white fiy. This misapplication of terms should be discouraged as it leads to unde-
sirable confusion when referring to the various stages through which the white fly
passes during its growth from egg to adult.

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS.

59

Fig. 4.— The citrus white fly:
Crawling young; first in-
star, dorsal view. Greatly
enlarged. (Original.)

No marginal wax fringe appears before or after crawling young settles. Cephalo-
thoracic and thoracic articulations invisible; 8 or possibly 9 abdominal segments are
seen with little difficulty. Segments at posterior end of body modified by vasiform
orifice. Latter nearly semicircular in outline, somewhat
longer than wide, bordered laterally by chitinous thicken-
ings which do not meet posteriorly; operculum semicircu-
lar, nearly equaling in size the vasiform orifice itself, cover-
ing the ligula and bearing on its median posterior margin
what appear to be two pairs of small spines, the penulti-
mate pair of which is about twice as long as the ultimate.
Ligula darker in color and broadly
crescentic in shape . On either side
of, and slightly anterior to, the vasi-
form orifice is a short backwardly
directed spine arising from a small
tubercle. The two pairs of rounded,
simple, reddish-brown eyes, less
than 0.01 mm. in diameter and 0.096
mm. apart — a dorsal pair and a ven-
tral pair — are situated mesad and
slightly anterior to the fifth pair of
marginal spines, the dorsal pair be-
ing nearer the margin and slightly
anterior to the ventral pair.

Antennae, legs, and mouth-parts on the venter. Antennae
anterior and mesad to the anterior pair of legs, 0.1 mm. long,
very slender; apparently 4-segmented, articulations between
the segments seen with difficulty and frequently that be-
tween the third and fourth entirely wanting, while in a few
specimens the second segment appears to be divided into
two parts: Segment 1 short, stout, fleshy; segment 2 one-half
as wide and twice as long as segment 1; segment 3 narrower than segment 2 and about
four times as long; segment 4 very slender, less than one-half as long as segment 3, and
bearing on its proximal posterior side a minute spine, and distally a long spine. Legs
short, moderately stout, where ex-
tended about one-third the width
of the body; coxae very short and
stout, the two posterior pairs on
the posterior inner side with a
moderately stout spine about
equal in length to the diameter of
the coxae and directed backward
and inward; trochanters distin-
guished with difficulty, about
one-third as long as wide and
collar-shaped; femora more elon-
gate, slightly tapering distally,
about four times as long as tro-
chanters; tibiae much narrower,
somewhat longer than the femora,
with numerous short bristles, two on the outer proximal portion longer and more easily
seen, on the outer distal portion with a long bristle forwardly directed and curving
inward toward the tip of the tarsi; tarsi short, ending distally in an enlarged disk-
like process.

Fig. 5.— The citrus white
fly: Crawling young; first
instar, ventral view.
Greatly enlarged. (Orig-
inal.)

r

Fig. 6.— The citrus white fly: Antennae and left hind leg,
first instar. Highly magnified. (Original.)

60

WHITE FLIES INJURIOUS TO CITRUS IX FLORIDA.

Fig. 7.— The citrus white
fly: Second larval instar,
ventral vie w . Greatly en-
larged. (Original.)

Midway between the anterior pairs of legs in the middle of the body is the fleshy
mouth papilla from which arise the mouth setae, at first when bent backward reaching
only to slightly beyond the posterior coxae, but later becoming more elongate. Ante-
rior to the mouth papilla is the semiovate prostomal plate, extending anteriorly as
far as a line connecting the antennae, and divided longitudinally by two curved
sutures into one elongate median and two shorter lateral pieces. At the anterior end
of the prostomal plate is a pair of small papillae, each papilla
bearing a small forwardly directed spine.

On the venter beneath and to the side of the vasiform
orifice is a pair of spines arising from small tubercles,
normally directed backward and outward, equal in length
to the distal tibial spine .

Second instar larva (fig. 7). — Length, 0.37 to 0.43 mm.;
width, 0.24 to 0.29 mm. Broadly ovate, dorsum densely
rugose, all marginal tubercles and spines wanting except 2
cephalic and 4 anal, the three pairs, counting from the

1 2 3

cephalic region, giving the relative lengths: — -, — — , -x-p.

y.o 4.0 iu.o

Eyes smaller and less regular in outline than in the first
instar, but distinctly evident. Antennae greatly reduced,
unsegmented, directed backward and slightly outward,
tapering, reaching nearly to base of first pair of legs; on
inside near base with a distinct spinelike projection, and on
basal portion with numerous roughenings; legs almost rudimentary, reduced to short,
stout, fleshy processes without distinct segments, composed of a very stout, tapering
basal portion, and a comparatively small, rounded, thick terminal disc; the second
and third pairs of legs on the inner side at the base with a minute spine. Mouth
parts as in previous stage; prostomal plate anteriorly indis-
tinct and its pair of spines wanting. Spines on either side
of vasiform orifice, both on dorsum and venter, as in first
instar. A marginal pore, on either side of body opposite
base of first pair of legs, and formed by an upward fold of the
integument, becomes very evident in this instar.

Third instar larva (fig. 8). — Length, 0.62 to 0.78 mm. ; width,
0.43 to 0.58 mm. Very similar to second instar but larger;
the most striking difference presented by the antennae, which
have migrated backward so as to arise from a tubercle
slightly anterior to base of first pair of legs. Antennae im-
movable, directed mesad for about two-thirds of their length,
and then suddenly doubled backward so that the distal third
lies in the same plane as the basal portion. Legs smaller in
proportion than in second instar and prostomal plate less de-
veloped, but the marginal pores and anal cleft more fully developed. A waxen
rod is seen often protruding from the marginal pores. Relative lengths of the mar-

. , • 12 3

gmalspmes: _, -, -.

Fig. 8.— The citrus white
fly: Third larval instar,
ventral view. Greatly
enlarged. (Original.)

The introductory remarks regarding the general appearance of the
larva apply with equal force to the young pupa (fig. 9, a, b, and c),
with the exception that the pupa is larger, being nearly one-sixteenth
of an inch long, is more easily seen, and on either side of the thoracic
region 3 distinct curved lines representing the outlines of the legs

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS.

61

are very distinct. As the pupa becomes older it becomes thicker,
more rounded and opaque, and the outlines of the legs are obscured
by the contents of the body. At the approach of maturity a bright
red or orange spot develops on the back, and from three to eight days
before emergence the eyes of the adult become visible. A detailed
description is as follows :

Length, 1.10 mm to 1.40 mm; width, 0.60 mm to 1.0 mm. Body broadly elliptical,
thin, not raised from leaf on vertical wax fringe, color pale yellowish-green, becoming
more yellowish and thicker on approaching maturity; thoracic lobes, representing out-
lines of the three pairs of legs, and a line extending from between first two pairs of
legs and from the vasiform orifice to edge of body distinctly more yellowish, as are also
the lines representing the union of the body segments although these last are promi-
nent. As body thickens thoracic lobes become less distinct due to body contents, a
bright orange or red medio-dorsal spot develops
at anterior end of abdomen, and later, a few
days before emergence, the purple eyes of adult
become very distinct, as also do the white devel-
oping wing pads; rim of vasiform orifice brown or
yellowish. All marginal bristles lost except one
anterior and one posterior pair of minute bris-
tles. A low medio-dorsal ridge or carina and
corresponding depressions on each side extend
from the head to the anal ring, traversed by short
transverse ridges on the thorax and abdomen,
terminating in a low subdorsal ridge hardly per-
ceptible; from these last numerous very fine
granulated striae radiate all around the body to
the lateral margin. A short transverse ridge
appears near posterior margin of head with a
curved impressed line in front. A minute brown
tubercle at the anterior end of the subdorsal
carina is sometimes to be seen. From a pore at the edge of the body, between head
and thorax and top of anal slit, issues a very fine, glistening- white, curled thread
of waxen secretion. These so-called "pores" in margin of the cephalo-thoracic
region are formed by a slight upfolding of the body which extends from margin to
cephalo-thoracic spiracle and forms an outlet for secretions from same. Location of
spiracles and respiratory system as already described for aleyrodids. Legs and
antennae easily seen with high-power lens. Antennae located as shown in fig. 9,
partially concealing front pair of legs, apparently 3-segmented but division into seg-
ments not distinct; last segment as long as other two combined, with quite a number
of irregular annulations; tip provided with a stout spine. Legs short, very stout,
especially the two posterior pairs; front legs projected forward; all without distinct
segmentation; tarsus very short, stout, and rounded. Vasiform orifice nearly semi-
circular (for details and shape see fig. 9, b).

Pupa case. — White, firm, retaining definite shape, and remains firmly attached to
leaf unless forcibly detached. (See PL VIII, fig. 1.)

Fig. 9.— The citrus white fly: a, ventral
aspect of pupa; b, vasiform orifice of
same; c, margin of body of same, a,
Greatly enlarged; b, c, highly magnified.
(Original.)

62

WHITE FLIES INJURIOUS TO CITRUS IX FLORIDA.

DURATION OF STAGES

LARVAL INS TARS.

Data upon the duration of the larval instars nave been secured by
daily observations of over 300 specimens marked as soon as the
young larvae had settled, supplemented by frequent counts of several
thousand specimens in various life-history cages.

From these records those included in Table IX have been chosen
as representative. A study of these will give a very accurate knowl-
edge of this subject, and will impress upon one the considerable
variation in the duration of the several instars of larvae hatching
at the same time, feeding upon the same leaf, and consequently sub-
ject to the same weather conditions. The data also emphasize the
retarding effect of cool spring and fall weather upon the length of
larval life, although this has not been found to be as great as many
have thought. The period of larval growth ranges from an average
of 23 days during the warmest months to an average of 30 days
during the cooler months.

Table IX. — Duration of larval instars of the citrus white fly.

Speci-
men
No.

Period of growth.

Number of
days in —

Sum of
effec-
tive
tem-
pera-
tures.

Speci-
men
No.

Period of growth.

Number of
days in—

Sum of
effec-
tive
tem-
pera-
tures.

In-
star
1.

In-
star
2.

In-
star
3.

In-
star
1.

In-
star
2.

In-
star
3.

1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32

Mar.22-Apr.26...
do

13
11
9

10
11
9
9

8
8
8
7
8
8
8
8
8
8
7
8

8
7
7
6
7
6
5
5
7
7
6
7

10

12 1.044

33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
5S
59
60

Aver-
age..

Oct. 3-Oct. 27

Oct, 3-Oct. 30

Oct, 3-Nov. 11

Oct. 3-Oct. 29

Oct. 3-Dec. 4

Oct, 3-Nov. 4.....

Oct. 3-Nov. 1

Oct. 3-Nov. 2

Oct. 3-Nov. 3

do

7
5
7
7
31
12
8
8
9
11
8
7
8
10
7
7
7
7
5
5
8
9
8
9
8
10
11
6

5
8

15
8

14

8
7
7
7
8
4
8
7
7

10
9
7

17
8
8
8
6
8
9
6

34
8

12
14
17
11
17
13
13
15
15
13
13
17
12
15
22
19
14
13
11
13
18
14
13
12
14
11
died.
13

736
811

1,102
792

1,644
922
843
868
894
894
843

1,060
828
922

1.012

1,012
868
783
932
768
952
883
783
834
883
783

"*767*'

do

do

...do

|

do

1

do

June 26- July 18...
June 26-July 19...
June 26- July 16...
June 26-July 18...
June 26- Julv 20...
June 26- July 18...
June 26-July 29...
June 26- July 18...
June 26- July 21...
June 26- July 18...
June 26- July 16...
June 26- July 18...
June 27- July 19...
June 27- July 20...
do

7
5
5
6
4
5
5
5
5
5
5
5
5
5
8
5
6
9
5
4
4
10
6
7
9

7
10

7

9
12

9
20

9
12

9

8

9
10
10

8

7
11
14

9
19
12
30
12
10

7

898
938
813
898
978
898

1,365
898

1,015
898
813
898
902
942
942
777
938

1,220
821

1,141
866

1,365
780
727
635

Oct. 3-Nov. 1

Oct. 3-Nov. 10....

Oct. 3-Oct. 31

Oct. 3-Nov. 4

Oct. 3-Nov. 8

do

Oct. 3-Nov. 2

Oct. 5-Nov. 1

Oct. 5-Nov. 7

Oct. 5-Oct. 31

Oct. 5-Nov. 8

Oct. 5-Nov. 5

Oct. 5-Nov. 1

Oct. 5-Nov. 3

Oct, 5-Nov. 5

Oct. 5-Nov. 1

Oct. 5-Nov. 19....
Oct. 5-Oct. 31

JJune26-Aug.l8...
\Sept. 28-Dec. 4...

June 27- Julv 16...
June28-Julv21...
June 28- Julv 28...
June 28- Julv 18...
June29-Julv27...
Julv28-Aug.l8...
Sept.28-Nov. 14..
Sept.30-Oct.25...
Sept.30-Oct.23...
Oct.l-Oct.21

7.2
17.8

5.4
28.3

10.5
14.3

945.7
903.4

i Does not include No. 37.

Does not include No. 59.

Bui. 92, Bureau of Entomology, U. S. Dept. of Agriculture.

Plate VIII.

Pupa Cases of the Citrus and the Cloudy-Winged White Flies.

Fig. 1.— Leaf showing pupa cases of Aleyrodes citri; also a few pnpse and eggs. Fig. 2.— Under
surface of orange leaf, showing heavy infestation by citrus white fly. Fig. 3.— Leaf showing
pupa cases of A. nubifera. Note delicate structure as compared with those of A. citri. (Original. )

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS.

63

PUPAL STAGE.

One of the most interesting phases of life-history studies has been
the wide range in the duration of the pupal stage; a range of from 13 to
304 days. Considering the relatively slight variation in the length of
the larval life, this range among specimens passing into the pupal
stage at practically the same time is remarkable. In view of the fact
that the effect of this variation upon the duration of life and number
of annual generations will be fully discussed under those headings and
brought out in Tables XV and XVII and figure 12, only a few of the
large number of records on file are given in Table X to illustrate this
range in pupal life during different parts of the year.

Table X. — Duration of pupal stage of the citrus white fly.

Speci-
men
No.

Period of growth.

Num-
ber of
days.

Sum of
effective
tempera-
tures.

Speci-
men

No.

Period of growth.

Num-
ber of
days.

Sum of
effective
tempera-
tures.

1
2
3
4
5
6
7
8
9
10

Apr. 30-May 13 .

Apr. 30-June 20

Apr. 30-Aug. 3

May 18-June 5

May 18- July 31

Mayl8-Mar. 18

July 15-July 30

July 15-Aug. 4

Aug. 15-Aug. 27

Aug. 15-Aug. 28

13
51
64
18
74
304
15
20
12
13

410
1,833
2,564

664
2,866

11
12
13
14
15
16
17
18
19
20

Aug. 15-Sept. 6

Aug. 16-Mar. 18....
Aug. 16-Mar. 20....

Aug. 17-Mar. 25

Aug. 18-Sept. 10...

Aug. 18- Apr. 1

Sept. 30-Mar. 31...
Oct. 28- Apr. 19....

Nov. 1-Apr. 17

Nov. 8-Mar. 25....

22
214
216
220

23
226
182
173
167
137

885
5,414
5,479
5,574

931
5,752
4,473
4,167
4,069
3,256

602
808
479
521

It will be noticed that pupae pass either a comparatively few or a
comparatively large number of days in this stage and that ordinary
temperatures and humidity do not have the oower to determine which
it shall be.

LOCOMOTION.

On hatching from the egg the young larva is provided with well-
developed legs, as shown in figure 5, by the aid of which it crawls
about the leaf for several hours and then settles and begins to feed.
Because of the aimless way in which it crawls, frequently doubling
on its own course and turning aside for the least obstacle, it travels
over a very limited area. It is therefore improbable that the crawling
larvae ever leave the leaf upon which they were hatched, unless carried
on the feet of birds or insects or blown or dropped from one leaf to
another. After settling, the larva does not change its position on the
leaf, while with the first molt its legs become vestigial (see fig. 7) and
unfit for locomotion. Larvae frequently move slightly, especially
directly after or during molting when they merely describe an arc
of 180°, using their mouth parts as a pivot. The larva passes into the
pupal stage without materially changing its position on the leaf. The
only time, then, during the life cycle when the white fly is capable
of moving about from place to place is during the winged adult stage
and the crawling larval stage.

64 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

Pronounced and striking growth in size occurs only at molting,
when the soft flexible skin of the larva or pupa is able to stretch before
assuming its normal rigid condition. With each successive molt the
larva greatly increases its horizontal dimensions, until by the time it
reaches the pupal stage these are about eighteen times as great as in the
newly hatched larva. When first settled after molting the larva is very
thin, papery, and transparent, being seen with difficulty except with
the aid of a lens, but after feeding several days it slowly becomes
thickened until, from two to five days, sometimes longer, before molt-
ing into the next instar, it is decidedly plump and whitish opaque in
color. Oftentimes before molting the larva becomes very much
swollen as though gorged with liquid. This appears to be an abnor-
mal condition, since many that become thus unduly enlarged either
fall or die without molting. During the increase in thickness follow-
ing feeding, there is no increase in the horizontal dimensions. On
the contrary, increase in the former is secured at a slight expense of
the latter.

Daily observations on over 300 marked individuals from time of
settling to emergence of adult have conclusively demonstrated that the
larva passes through but three instars 1 before reaching the pupal
stage, instead of four as has been previously supposed. Each larva,
then, molts or casts its skin three times before becoming a pupa. The
process of molting was first described by Riley and Howard 2 and as
observed by the authors is as follows :

In preparing for a molt the insect curves the abdomen upwards at considerably
more than a right angle, moving it also occasionally up and down. The margin of
the abdomen has at the same time a slightly undulating motion. During these move-
ments the insect is shrinking away from the lateral margin until it eventually occupies
only about one-third of the original lateral space, causing a distinct dorsal and ventral
median ridge. The skin then splits, not on the dorsum, as would be expected, but
either at the anterior end or underneath the head. The head and prothorax are then
pushed out and the skin is gradually worked backwards by means of the abdominal
motions, the portion already out swelling as soon as it is free.

As the insect flattens after molting it appears milky white, the head,
thoracic lobes, and abdominal segments being more greenish. At
this time the legs, which resemble much the prolegs of a caterpillar,
are very active, and there appears a pair of fleshy protuberances more
or less movable, not as large as the legs, but apparently of the same

1 This agrees with the senior author's observations on the greenhouse white fly
(A. vaporariorum) and the strawberry white fly (A . packardi) , which are the two species
of the genus which have previously been studied in greatest detail. Tech. Bui. 1,
Mass. Exp. Sta. and Can. Ent., vol. 35, pp. 25-35.

2 Insect Life, vol. 5, p. 223, 1893.

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS. 65

structure, which act as sucking disks to aid the insect in reattaching
itself. These protuberances are later withdrawn so that no trace of
them remains. While becoming attached to the leaf the insect may
be seen occasionally to rotate itself through an arc of 270°, in the mean-
while frequently raising and lowering the abdomen. The cast skins
are usually blown away by the breeze or fall from the leaf as soon as
molted, but not infrequently are found partially pinioned beneath
the body of the insects. Molting occurs most actively during hours
of high humidity. Newly molted larvae are abundant during the early
morning when the humidity ranges between 100° and 90°.

FEEDING HABITS OP LARVyE AND PUP^E.

As the white flies, or Aleyrodidae, belong to the Hemiptera, or
sucking insects, the larvae and pupae do not eat the tissue of the leaf,
but insert their thread-like mouthparts and suck the plant juices by
the aid of a suction apparatus located in the head. Their ravages are
not accompanied by any visible effect upon the leaf itself, but may
be detected by means of the sooty mold which develops after the fly
becomes very abundant. Our only means of estimating the amount
of sap taken up by the insect is by the amount of waste material, or
honeydew, ejected by it. A first-instar larva, on being watched under
the compound miscroscope for 20 consecutive minutes with the tem-
perature at 90° F., was seen to eject honeydew 48 times, or an average
of about 10 times every 5 minutes. A pupa with well-developed eye-
spots, in March, with the temperature at 85° F., ejected honeydew
4 times in 5 minutes. This difference in the amount of honeydew
secreted is due in part to the different temperatures at which the
observations were made as well as to the difference in the degree of
development.

A very interesting observation on the amount of sap extracted by
larvae and pupae of the white fly has been made by Dr. Berger *
Leaves with live larvae and pupae were placed between glass plates so
that the ejected honeydew was collected on the glass. By weighing
it was found that each live insect had excreted about 0.0005 gram in
48 hours. At this rate a tree infested with 1,000,000 white-fly larvae
and pupae would lose one-half pound of sap per day.

The Adult.

The adult citrus white fly is very small, measuring only about one-
sixteenth of an inch in length, and with a wing expanse of less than
one-eighth of an inch. The natural color of the body, antennae, legs,
and wings is entirely obscured by secretions of delicate white wax par-
ticles, so that the insect appears snowy white (PL IX; text fig. 10, a-i)

1 Bulletin 97, Florida Agricultural Experiment Station, pp. 63-64, 1909.
59131°— Bull. 92—12 5

66

WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

without spots or traces of darker shades upon the wings. Only the
purple eyes are free from the white wax, and are in sharp contrast to
the color of the rest of the body. A detailed description of the adult,
by Riley and Howard, follows:

DESCRIPTION.1

9 . — Length, 1.4 mm. ; expanse, 2.8 mm. ; four-jointed rostrum about as stout as legs;
joint 1 shortest, joint 2 longest, and about as long as 3 and 4 together; joint 3 some-
what longer than joint 1 and a little shorter than 4. Joint 1 of the 7-jointed antennae very-
short, as broad as long, subcylindrical, slightly wider distally; joint 2 twice as long as 1,
strongly clavate, and at tip somewhat broader thanl, bearing 3 or 4 short hairs arising
from small tubercles; joint 3 longest, about twice as long as 2, slenderer than this and with
a very narrow insertion, rather abruptly stouter at apical third, corrugated and ter-
minating above in a small callosity resembling a similar organ in Phylloxera; joints 4

Fig. 10.— The citrus white fly. Adult, a, Male; b, claspers of male; c, female; d, ovipositor of female;
e, side view of head of female; /, antenna; g, enlarged margin of wing; h, tarsus and claws; i, tibia.
a, c, Greatly enlarged; 6, d-i, more enlarged. (Adapted from Riley and Howard.)

and 5 subequal in length, each nearly as long as 2, joint 5 bearing a short spine ante-
riorly near apex; joints 6 and 7 subequal in length, each somewhat longer than 2, 7 with
a stout spine at tip; joints 4 and 7 somewhat corrugate or annulate but less so than
apical third of 3. The 2-jointed tarsi about half the length of the tibia, joint 1 of the
hind tarsus bearing 6 rather stout spines on each side; joint 2 supporting at base 3
rather prominent claws, the middle one longest. Ovipositor short, acute, and retrac-
tile. Eyes divided into two by a curved pointed projection from middle of cheek,
the upper portion being smaller than the lower portion. Wings clear, colorless; costa
delicately serrate. General color, light orange yellow, tip of rostrum black, tarsi and
part of tibia orange.

$ . — The male resembles the female in all important respects except in being
smaller. Claspers about as long as preceding abdominal joint, or one-fifth the length

1 Riley and Howard, Insect Life, vol. 5, p. 222, 1893.

Bui. 92, Bureau of Entomology, U. S. Dept. of Agriculture.

Plate IX.

Adults of the Citrus White Fly on Foliage of Orange.

Fig. 1.— Tender growth swarming with adults. Fig. 2.— Leaf of same enlarged. (Original.)

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS. 67

of the abdomen, curved gently upward and inward, each bearing 4 or 5 equidistant
minute cylindrical piliferous tubercles on upper and outer edge; style almost as long
as claspers, rather stouter at base, more slender toward tip, terminating in a stout spine
at upper end. Head and abdomen with heavy tufts of wax soon after issuing from
pupa.

Examination of a large number of antennae shows that the relative
length of the antennal segments is subject to slight variations. The
average relative lengths are about as follows:

Segment A A A A A A A Spine.
10, 24, 43, 16, 16, 18, 22, 3

Although they have examined thousands of males both at and for
some time after emergence and as they occur at all times throughout
the grove, the authors have never been able to observe males with the
tufts of wax on head and abdomen mentioned in the above descrip-
tion and illustrated in connection with its original publication.

EMERGENCE.

DESCRIPTION OF THE PROCESS.

The emergence of the adult occurs soon after its purple eyes and
folded whitish wings can be seen distinctly through the pupal skin.
About 20 minutes before the pupal skin is ruptured the body of the
adult shrinks gradually away from it and assumes its natural shape.
This gradual shrinking away from the edges of the pupa, and the
accompanying thickening of the body, brings a pressure to bear on
the pupal skin which causes it to split from margin to margin between
the thorax and abdomen and along the median line from this
rupture to the anterior margin. Through the T-shaped opening
thus formed the insect first pushes its thorax, then its head, with
little apparent exertion. The body now projects almost perpendicu-
larly from the pupa case, as the pupal skin is called, with the an-
tennas, legs, and abdomen still in their pupal envelopes. By a series
of backward and forward movements the antennae and legs are freed
from their membranes and are in constant motion. The abdomen is
now so nearly out of the pupal case that the fly is practically free,
holding on only by means of the end of the abdomen. With a sudden
forward bend of the body the legs are brought in contact with the leaf,
and with their aid the fly frees the rest of its abdomen and crawls
away rapidly.

The period covered between the time the insect ruptures the pupal
skin and the time it becomes entirely free from the case and is crawl-
ing is from 7 to 10 minutes. Not infrequently flies die during
emergence.

1 These represent the spaces read on eyepiece micrometer when 1-inch eyepiece
and ^-inch objective are used, and the miscroscope tube is drawn to 160.

68 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

CHANGES AFTER EMERGENCE.

Immediately after emergence from the pupa case the adult differs
from the more mature individuals in that the lemon-yellow color of
the body is not obscured by the white waxy secretion that subse-
quently appears. Also the wings, which appeared as crumpled
whitish pads when the thorax was first protruded from the pupa
case, have had time only to partially expand. As the fly crawls away
from the case the wings are held perpendicularly above the back, but
as the wrings gradually unfold and assume their normal shape they
are lowered to their natural position. It requires, about 7 minutes
for the wings to become straightened after the fly leaves the case,
and from about 14 to 17 minutes from the time they first begin to
expand. When fully expanded, the wings are colorless and trans-
parent, with the costa pale yellowish. The powTdery whiteness so
characteristic of the flies as seen in the grove gradually appears as
the wax glands secrete their particles of wax. In about one and three-
fourths hours the wings and body have become perfectly white.

CONDITIONS AFFECTING EMERGENCE.

Aside from that inherent influence affecting the development of the
citrus white fly and determining wiiether the adult shall emerge
during the first or second general emergence period, as hereinafter
described under "Seasonal history/' many field observations made at
all seasons during the past three years, supplemented by laboratory
experiments, have emphasized the great influence which temperature
has on emergence. While a normal amount of humidity is necessary
for emergence to occur, it is not so controlling a factor as temperature
during ordinary Florida weather, as will be shown later. Light also
seems to affect emergence under certain conditions.

EFFECT OF TEMPERATURE ON EMERGENCE.

Conclusions drawn from field notes, supplemented by laboratory
experiments, show that emergence seldom occurs outside the range of
62° F. to 85° F., with preference to temperatures ranging from 70°
to 85°. During the winter months of December, January, and
February, when the average monthly mean is about 60° F., no emer-
gence occurs except to a slight degree during warm spells of several
days' duration. In January, 1906, when the average monthly mean
temperature was 59.6°, or practically normal, no flies wTere noted on
wing at Orlando, Fla., except in small trees beneath pinery sheds
where the temperatures averaged several degrees higher than outside.
During late December, 1908, and early January, 1909, the tempera-
ture had been sufficiently high to cause a limited amount of new
growth to appear on some trees in Orlando, and on January 4 a com-
paratively large number of adult wiiite flies were seen feeding and

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS.

69

depositing eggs on new growth in a very sheltered place. The average
mean temperature of the 6 days preceding this observation was 66°
F., while, for the 6 days preceding these, when no white flies were
on wing, the average mean was about 58.5° F. Adult white flies
were not seen in the laboratory grove in February, 1909, until about
the 20th, or until the temperature records for the grove showed an
average daily mean of about 64.5°. It is from the above facts that
the lowest temperature at which emergence occurs has been deter-
mined to be about 62° F. This conclusion, drawn from general field
observations, is strengthened by emergence records kept in con-
nection with cage life-history work during the period of active spring
emergence of March, 1908, when the monthly mean was 71°. Refer-
ence to the data contained in Table XI brings out the fact that while

Table XI. — Relation of temperature to emergence* of the xitrus white fly .

Date.

Range in
tempera-
ture.

Average
mean tem-
perature.

Emergence records.

No. 1.

No. 2.

No. 3.

No. 4.

1908.
Mar. 19
Mar. 20
Mar. 21
Mar. 22
Mar. 23

°F.
62-89
63-90
54-65
60-80
66-90

°F.
75.5
76.5
59.5
70.0
78.0

4

5
0
10
17

6

78

1

69

71

2
4
1
15
4

18

0
15
35

emergence had been going on actively two days before and after March
21, when the average mean temperature was about 75° F., a drop in
the mean temperature on the 21st to 59.5° F. practically prevented
any white flies from emerging. The 1 white fly that is recorded
under Nos. 3 and 4 may have emerged on the 20th after the daily
record had been taken. Such emergences are not rare at this season
of the year, as will be shown later. Of 2 lots of about 100 pupae
each, from which adults were nearly ready to emerge, 1 was placed
in a refrigerator at about 56° F, and the other kept at room tempera-
ture which ranged between 70° F. and 80° F. while emergence was
taking place. Of those kept on ice, but 1 white fly emerged
during the first 12 hours, as compared with 17 from pupae kept
at room temperature. White flies continued to emerge on 3
consecutive days from pupse kept at the latter temperature. No more
emerged from the refrigerated pupae. It is therefore evident that
emergence may occur at as low a temperature as 56° F., though very
rarely.

That white flies seldom emerge after the temperature reaches 85°
F. may be concluded from the following facts : During the months of
July and August, when the average daily mean is about 82° F., a
newly emerged adult is rarely seen in the grove after 8 a. m. Prac-

70 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

tically all adults at this season emerge between 4 and 7 a. m. This is
true both in the laboratory and in the grove. Of 233 white flies
emerging separately in vials in the laboratory during August, 1907,
212 emerged between 3.30 and 8 a. m., and the remaining 21, with
one exception, emerged between 8 and 9.30 a. m. In the grove over
95 per cent of the white flies emerge before 7 a. m. At this time of
day the temperature ranges between 70° F. and 85° F. During the
early spring, when the daily maximum temperature does not usually
exceed 85°, emergence is not restricted to the early morning as during
the heat of summer, but occurs at all times of the day. It may also
be added that like conditions exist in October and November, but
because of difference in seasonal history, they affect chiefly the spotted-
wing white fly.

EFFECT OF HUMIDITY ON EMERGENCE.

Under normal Florida conditions at Orlando, at any season of the
year, the relative humidity rises to nearly or quite 100 per cent by
from 6 to 10 p. m., and there remains until about 6 a. m., when it
normally drops rapidly, sometimes to as low as 19 per cent, though
more often to from 35 to 60 per cent. It has already been stated that
over 95 per cent of the white flies will have emerged before 7 a. m. or
before the humidity has fallen far from the saturation point. That
temperature and not humidity is the more important factor governing
emergence in Florida, can be inferred by a comparison of the humidity
and temperature records of Table XIII. It so happened that the
cold wave of March 21, 1908, was accompanied by a higher average
humidity, but the temperature and not the humidity prevented
adults from emerging. Again, during the spring, when the daily
maximum temperature is seldom above 85° — usually less — emergence
goes on even at midday when the humidity has dropped to as low as
33°. In this connection attention should be called to the fact that the
humidity in the corked vials mentioned under the preceding heading
remained at about 100 per cent throughout the greater part of the
experiment.

There are, however, times of abnormal weather conditions when
lack of humidity seems to play an important part in preventing
emergence. During the month of March there sometimes occur dry
winds of several days' duration, accompanied by more or less heat,
which seriously check emergence, and, as far as can be determined,
cause many pupae from winch adults are about to emerge to die.

Two such periods occurred during March, 1909, from the 3d to the
6th, and from the 25th to the 27th, respectively. During these
periods the relative humidity was extremely low, on one day dropping
to 19 per cent. For 42 hours during the latter period the humidity
ranged below 50 per cent and for 36 hours above 50 per cent. During

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS. 71

these periods emergence was noted to be seriously checked and at the
end of the latter upward of 30 per cent of the pupse were dead, appar-
ently from no other cause.

EFFECT OF LIGHT ON EMEEGENCE.

During the summer months light seems to have an influence on
emergence. At this season emergence in the laboratory and grove
begins at about daybreak. Observations made at hourly intervals
on the emergence of 233 adults, from 3.30 and 4 a. m. show that white
flies rarely emerge before this time. In one instance only about one-
third as many white flies emerged from pupae kept in the dark as from
those kept in the open, and their emergence was noticeably delayed.
During the cooler months the low morning temperatures prevent the
white flies from responding to this apparent stimulation due to light,
and they emerge at various times after the temperature has risen
sufficiently high.

DURATION OF LIFE.

Without food. — In none of the experiments conducted to determine
the length of adult life without food have white flies lived longer than
30 hours, and a very large percentage has died before the end of 24
hours. When confined on leaves of plants other than those recognized
as food plants, life is usually longer than this, but never approaches
the normal length. White flies confined on crape myrtle in July died
as soon as those kept in empty cages, but flies caged on oak, in March,
lived as long as 4 days ; those on fig, in August, 3 days ; and on banana
shrub, in July, 2 to 3 days. In all these tests flies were placed only
on the tenderest growth.

With food. — Adult life under normal outdoor conditions averages
about 10 days, although individual white flies kept in cages have been
known to live as long as 27 days. Adults are so fragile and so easily
killed by winds and heavy showers and by numerous species of spiders
and ants that their duration of life is at most very uncertain. Cage
experiments during March, April, July, August, and September show
that, in the cages at least, there is little difference in the length of
life at various times of the year.

The courtship of the citrus white fly has been observed to begin
within 2 hours after emergence, and in one instance even before the
wings of either male or female had become whitened. There is no
time in the day when the males can not be seen courting the females.
The male appears unable to locate the female at a distance much
greater than one-fourth of an inch, according to Prof. H. A. Gossard.
Observations made during the present investigations show that when
males and females are placed in separate receptacles and separated

72 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

only by a very porous cheesecloth they show absolutely no attraction
to each other. Mating, therefore, is not so likely to occur when the
adults are scarce, as it seems to be the result of chance meeting upon
the leaves rather than to such a definite attraction as exists between
males and females of many moths.

Upon detecting the female, the male approaches her nervously,
stopping at intervals, especially as the distance lessens, and swinging
his body about excitedly in a semicircle, the head being used as a pivot,
his wings in the meanwhile opening and closing spasmodically. While
no movement is made by the female, she is repeatedly approached
from many directions before coition occurs. More often the male lies
alongside the female and courts her in this position, raising and low-
ering his wings as above described, and raising and swinging his abdo-
men from side to side. During these antics of the male the female
remains quiet, only occasionally flittering her wings. While males
may be seen courting females at all times of the day, it is seldom that
one sees a pair in coitu except late in the afternoon and evening. Be-
cause of the uniformity of color and the ease with which adults are
disturbed and made restless the duration of copulation can not be
stated with certainty, but it probably lasts but a short time. Experi-
ments to determine the duration of fertility have thus far proved
unsuccessful.

OVEPOSITION.
AGE AT BEGINNING OVIPOSITION.

Virgin females in confinement have deposited eggs within 6 hours
after emergence. In one instance 35 virgins deposited 58 eggs between
5 and 9^ hours after emergence during summer weather, with the
temperature ranging from 80° to 92° F. However, even at this tem-
perature single females occasionally did not deposit eggs for over 24
hours. Prof. H. A. Gossard x states that egg laying begins at from
18 to 30 hours after the emergence when the temperature ranges from
65° to 75° F. Laboratory tests have shown that lack of fertilization
does not prevent a female from depositing eggs, but that she will
readily deposit infertile eggs until opportunity for mating presents
itself.

PORTION OF PLANT SELECTED.

If not numerous, the females deposit almost exclusively on the under
surface of the leaves, laying over 75 per cent of their eggs on the half
of the leaf bordering the midrib. It is only when very abundant
and pressed for room that they deposit eggs thickly over the entire
lower surface and more sparingly on the upper surface, the petioles,
and the stems of twigs. Next to the portion bordering the midrib,
the natural depressions and the curled margins of the leaf, especially

1 Bui. 67, Fla. Agr. Exp. Sta., p. 609, 1903.

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS.

73

of the tender growth, are favorite places for oviposition, and not
infrequently as high as 40 per cent of the eggs are there laid, even
when the adults are not very abundant. Although eggs may be
deposited along the leaf margin, it is seldom that they are laid on the
margin itself, as is the case with the cloudy-winged white fly. Even
when not crowded for leaf space, the adults sometimes settle upon the
under side of young fruit, where they deposit eggs freely and appar-
ently feed.

DAILY RATE OF OVIPOSITION.

Previous to these investigations no data have been published on
the daily rate of oviposition. In obtaining the data given in Table
XII, the females recorded were collected at random throughout the
grove, without regard to age, and, together with males not mentioned,
were caged over leaves cleaned of all eggs and larvae of the white
fly and allowed to remain the recorded time, when the adults were
removed and the eggs counted.

Table XII. — Daily rate of oviposition of the citrus white fly.

Record
No.

Date deposited.

Number

of
females.

Duration
of egg
laying.

Number
of eggs
depos-
ited.

Average
number
of eggs per
female
per 24
hours.

Average
mean

tempera-
ture.

1
2
3

4
5
6

7
8
9
10

Feb. 23-24, 1909

Apr. 11-15, 1907

Apr. 20-21, 1909

Apr. 21-22, 1909

June 16-17, 1909

July 17-18, 1907

July 22-23, 1907

July 24-26, 1907

Aug. 17-18, 1907

Sept. 21-22, 1908

14
3

50
40
30
255
105
50
70
35

Hours.
26
103
24
24
24
21
24
46
24
24

197

98

454

405

360

2,533

1,216

1,331

805

405

13
7.6
9.1
10.1
12
11.3
11.6
13.8
11.5
11.6

° F.
* 74.5

68.2

77.2

78.2

82

82

85

84

81

79

Number eggs per day per female, grand average, 11.2.

The generally uniform results obtained in the nine records when
the average mean temperature was about 75° F. or above, together
with the grand average daily rate of oviposition for individual
females whose age was definitely known, as shown in Table XIII,
indicate that each female normally deposits on an average 10 or 11
eggs a day. Varying degrees of temperature above a daily mean
of 75° F. do not correspondingly increase the number of eggs
deposited. However, temperatures below an average mean of 72° F.
(estimated) have a distinct checking effect upon oviposition, as shown
by record No. 2.

Notwithstanding the general average number of eggs per day
deposited by the females of all ages in Table XII, and the same for
the females of known ages for the total number of days they lived,
in Table XIII, reference to the daily oviposition records in the latter

74

WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

shows that as many as 14, 19, 27, or even 33 eggs may be deposited
by a single female in one day. It will also be noted that much
variation exists between the number of eggs deposited by several
different females on the same day and by the same female on suc-
cessive days without any apparent reason, and that there exists no
appreciable difference between the rate of deposition by virgin and
by fertilized females.

Table XIII. — Number of eggs deposited by single females of t

he citrus white fly.

Flv Date of first

Condition of female.

Dailv rate of opposition bv individual females.

No. daily record.

1

2

3

4

5

6

7

8

9

1Q

n

12

1

Aug. 8, 1907. .
do

8
5
3
5
5
6
8
?

19
19

9
14

22
12

5
4
14
5
14
14

11
12
13

3

12
33
17

9

2
15
9

15
13
16

6

14
8
1

13
16
7

c1)

(1

0
14
15

1

?

do

3

do

do

9 ! 13

12 | 17

13 15
16 17

8 16
18 ! 16

15
6
10
14
4
q

19
3
9

10
2
9

14

4

do

Aug. 15,1907.
do

20 5

12 1 15

13 , 23

ii ; 16

2 1 13

6

fj

9

6

do

3

7

do

do

4

8

do

15 fi

1

Fly

Daily rate of oviposition by individual females.

Total , Number L^SR,
number of; of days np^b!Lo1
eggs laid, j lived. ' ^f^1

No.

13

14

15

16

17 18 19

20

21 22

23

24

1

92
104
206
112
179
211

8 1 11.5

2

8
22
19
16
17
17

u

13

3
4

13

5
5
19

8

1

9

10
20

"a"

27

5
2
11
11
14
3

ii io

2 3

2 (3)

.64
12 2

8
0

6

8

9

(2)

6 1 (i)

9.4

6.0

11.2

6

12.4

7

146

144

8.6

8

(5)

10.3

iDead.

- Dead; 13 eggs in abdomen.
3 Dead; 18 eggs in abdomen.

Number of eggs per day per female, grand average. 10. 3.

1 Dead; 11 eggs in abdomen.
5 Dead; 7 eggs in abdomen.

The eight records in Table XIII are selected from about forty
similar records on file and are considered as representing an average
condition Of oviposition. Although the general average of 10.3 eggs
per day throughout life for the 8 females recorded in Table XIII
agrees very closely with the similar average obtained in Table XII,
there is sufficient evidence in the data in Table XIII to warrant
the statement that the daily rate of oviposition for individual females
is usually greater during the early part of the insect's life and de-
creases with each successive week of existence. Leaving out of con-
sideration the first day, when the flies had not reached their normal
egg-laying capacity, a little calculation shows that the average daily
deposition for the three successive weeks is 12.8, 8.5, and 6.1, respec-
tively. This same decrease in the number of eggs deposited with
increase in age is perhaps better brought out by a study of the number
of eggs deposited by the individual females over 5-day periods.
Thus No. 6 averaged 16.2 eggs per day for the first 10 days, but for

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS. 75

the next 5 dropped to an average of 7.8; Nos. 4 and 7 showed a sharp
falling off during the second 5 days. . No. 3 is an exception to the
above statement, maintaining an average of from 9.8 to 11.8 eggs
per day for the first three periods of 5 days each, and during the
fourth period of 5 days deposited as many eggs as during the first
5 days. It will be noticed, however, that No. 3 deposited compara-
tively few eggs during the early part of her life. In view of the fact
that the average adult life is only about 10 days, the higher rate of
deposition during early life has an influence on multiplication.

NUMBER OF EGGS DEPOSITED BY SINGLE FEMALES.

First mention of the egg-laying capacity of the citrus white fly
was made by Riley and Howard,1 who based their conclusions on
the number of eggs that could be counted in the abdomen of the
females when mounted in balsam, and not upon daily counts of eggs
deposited by the females throughout life. Their estimate of about
25 eggs as the probable total number of eggs deposited by a single
female during life has been generally accepted by subsequent writers,
none of whom has ever placed the maximum number deposited
above this figure. The present investigations, however, have demon-
strated that this estimate is far too low and that the number of well-
developed eggs to be found in the abdomen of the female at any one
time is not indicative of the number of eggs deposited throughout
her life. Females have been known to deposit more than this number
of eggs in a single day. As will be seen by reference to Table XIII, as
many as 211 eggs have been actually deposited by one female, and
should the 1 1 well-developed eggs found in her abdomen at death be
added a total of 222 eggs would be obtained. As this female, No. 6,
lived but 17 days and others have been known to live 28 days, it is
even probable that as many as 250 eggs more nearly represent the
maximum egg-laying capacity under most favorable conditions. How-
ever, it is seldom that a female lives sufficiently long to deposit her
full quota of eggs. With the average length of adult life curtailed to
about 10 days, the average of 149.2 eggs per female, as shown in
Table XIII, is beyond doubt high. An average of 125 eggs per female
is nearer the number of eggs deposited during life in the grove.

ACTIVITY IN OPPOSITION DURING DIFFERENT PARTS OF THE DAY.

In order to determine that portion of the day when eggs are most
freely deposited by females during summer weather, adults were
inclosed in a rearing cage over leaves from which all previously
deposited eggs had been removed, and allowed to remain for a period
of two hours, when the cage with adults was removed to another leaf
and the deposited eggs counted, with results shown in Table XIV.

1 Insect Life, vol. 5, p. 222, 1893.

76 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

Table XIV. — Activity of the citrus white fly in oviposition during different parts of the day.

Time of day.

Mean tem-
perature
for period.

Number

of eggs

deposited.

Per cent of
total eggs
deposited.

6 a. m.-8 a. m...
8 a. m.-lO a. m.. .

10 a. m.-12m

12m.-2p. m

2p. m.-4p. m

4 p. m.-6p. m

6 p. m.-8p. m

8 p. m.-6 a. m

6 a. m.-6. a. m.. .

° F.

82

89

91

92

90

85

81

74
181.6

20.
55
35
65
30
197
248
103
753

2.6

7.3

4.7

8.7

4

26.1

32.9

13.7

100

1 Average temperature for entire day of 24 hours; not the average of the 8 periods.

From the data it will be seen that while oviposition occurs at all
times of the day, nearly 60 per cent of the eggs are deposited between
4 p. m. and 8 p. m., and that oviposition does not cease on the ap-
proach of darkness. The variation in the number of eggs deposited
during the periods from 6 a. m. to 4 p. m. has little significance. It
was noted that the least number of eggs were deposited when the
bright sun fell directly upon the cage.

In further evidence of the greater activity of oviposition during
the latter part of the day; two other cages were started on August I,
1909. One cage placed repeatedly over the tenderest growth resulted
in 698 eggs being laid between 10.15 a. m. and 4.15 p. m., as com-
pared with 895 eggs laid between 4.30 p. m. and 7.30 p. m. The
second cage, covering spring growth, gave 115 as compared with 786
eggs deposited during the same periods.

Relation between oviposition and food supply. — As the egg-laying
capacity of a single female is close to 250 eggs and but 25 well-
developed eggs have ever been seen in her abdomen at any one time,
it is necessary that she obtain nourishment sufficient to mature her
numerous "potential" eggs. There remain many interesting obser-
vations and experiments to be made on the relation between oviposi-
tion and food supply. That females deposit fewer eggs when feeding
upon many of the recognized food plants other than citrus than they
do on the latter is a subject of considerable interest. While adults
feed apparently as contentedly upon new growth of China trees and
umbrella China trees, they do not appear to deposit as many eggs
per female on these host plants as on citrus. The extremely small
number of eggs laid by females swarming over new growth of wild
persimmon in June at Orlando is even more astonisliing considering
the marked preference shown by the females for this growth over the
spring growth of orange. Even on citrus itself oviposition is influ-
enced by the ages and corresponding toughness of the leaves, though
not as markedly as is that of the cloudy-winged white fly. In one
instance equal numbers of adults were confined on a tender and an

THE CITRUS WHITE FLY: LIFE HISTORY AND HABITS. 77

old leaf of orange for two hours, when the adults were removed and
576 eggs were found to have been laid on the tender leaf and but 25
on the old leaf. Again, under practically the same conditions, 364
eggs were deposited upon tender growth and but 2 on very old growth.
The difference between oviposition on tender August growth and
spring growth is not as great as this, though very marked, as about
90 per cent of the third-brood adults fly to the new growth put on
by the trees late in July and early in August.

From the foregoing it is evident that the number of eggs deposited
is strongly influenced by the nature of the insect's food. Females
confined in empty cages never deposit eggs, neither do those resting
upon thick bark, ladders, or picking boxes, and, as has been stated
under "Food plants," oviposition is entirely checked1 when females
are confined with leaves of nonfood plants. This difference in the
number of eggs deposited on various plants may prove of value from
the standpoint of trap foods, and become a factor in the control of
this pest.

PROPORTION OP SEXES.

Examination of thousands of adult citrus white flies at all seasons
of the year has shown that after a grove has become well infested an
equilibrium between the proportion of males and females is estab-
lished from which there is under ordinary conditions little variation.
In such groves it has been found that from 60 to 75 per cent of the
adults are females. Of the records on file, about 66 per cent give
percentages of 60 and over for females, while 66 to 76 per cent are
more frequent percentages where adults are abundant.

In groves where the progress of the white fly has been very seri-
ously and suddenly checked by natural or artificial causes, the pro-
portion of sexes is subject to a much wider variation and there follow
for a time fluctuations between a predominance of males and females.
In one such grove where the white fly had been greatly reduced in
numbers because of the scarcity of adults of the first brood, there was
a very large percentage of males appearing with the second brood,
which in turn resulted in the third brood of 90.5 per cent females.
In a second grove, where over 99 per cent of the white fly were killed
by fumigation, the few females of the first brood, because of their
isolation due to scarcity in numbers, were forced to deposit mostly
infertile eggs, which resulted, in the second brood, in a reduction of
females to 18.6 per cent.

Dependence of sex upon parthenogenesis. — The proportion between
the sexes is largely and evidently entirely dependent upon partheno-
genesis. It has been shown that infertile females deposit eggs in as

1 Three hundred adults of A. citri confined on the tenderest spring growth of oak
for three days deposited 1 egg.

78 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

large numbers and as frequently when males are not given access to
them as do fertile females, and that the adults developing from these
eggs are all males. Whether the adults from fertile eggs are invari-
ably females has not been proved, although the evidence leaves little
doubt that they are. If otherwise, it would be difficult to account
for the fluctuations in sexes mentioned under the preceding heading,
or to explain the great predominance of females over males after the
species has become well established.

INFLUENCE OF WEATHER CONDITIONS ON ACTIVITY OF ADULTS.

During the cooler portions of the year, when adults are present on
the trees, very few are seen flying about from tree to tree unless
abundant. The morning and evening temperatures easily chill them;
hence their activities are confined to the warmer part of the day.

However, after summer weather has become established the white
flies rest very quietly on the under surface of the leaves during the
greater part of the day. They shun the bright sunshine and prefer
leaves in shaded places. When exposed to the sun without protec-
tion they soon die. As the temperature falls during the late after-
noon, and especially after afternoon showers when the humidity has
risen to 90° or even to 100°, they become very active, and about 4
o'clock begin to fly about from leaf to leaf and from tree to tree, and,
when very abundant, swarm in such large numbers about the groves
and town streets as to arrest the attention of pedestrians, to whom
they become at times a source of much aggravation, becoming en-
tangled in the hair, crushed upon the clothing, breathed in with the
air and causing choking, and flying into the eyes.

FEEDING HABITS OF ADULTS.

The adult insects, having well-developed sucking mouth parts, feed
upon the plant juices in the same maimer as do the larvae and pupas,
but with the advantages of not being confined to the same location.
They do not leave any external evidence of the feeding except on
very young growth, when the feeding of a large number of adults
frequently produces a crinkling of the foliage.

It is difficult to determine positively whether or not an adult citrus
wliite fly is feeding when it is resting on a leaf or stem. Adults rest
contentedly during the warm portions of the day upon the underside
of leaves of plants upon which they have never been known to de-
posit eggs. Under these circumstances they even appear to mate,
and it seems probable that they feed to a limited extent. When on
one of the principal food plants of the species, however, it is safe to
consider that adults feed wherever eggs are deposited in noticeable
numbers. It is because of this indiscriminate settling upon vege-
tation upon which they are not able to subsist, and upon which they

THE CITRUS WHITE FLY i LIFE HISTORY AND HABITS. 79

never breed, that the belief has received such an unfortunately wide
circulation among orange growers that the citrus white fly breeds on
all kinds of hammock trees, shrubs, and grasses. Regardless of the
food plant, the adults feed almost exclusively upon the under surface
of the leaves, more rarely upon the fruit, and never upon the woody
portions of the tree. When new growth is very young and the leaves
have not expanded, adults often feed upon both surfaces of the leaf,
the petiole, and even the tender shoots, but this lasts only for a short
time. At all seasons the newest growth is preferred, as indicated
by the data under the caption of the relation of food supply to ovipo-
sition, and the portion of the plant selected coincides with that
already discussed for oviposition. It should be noted here that the
decided preference of the adults for the new growth has a checking
effect, as noted elsewhere, upon multiplication, as they are entirely
lacking in instincts preventing over-oviposition

Multiplication .

The relation of multiplication to food supply and the restrictions
upon multiplication due to overcrowding, natural mortality, drop-
ping of leaves after freezes, parthenogenesis, and attacks by insects
and other predaceous enemies and fungi will be found treated else-
where. It has been estimated that not more than 5 per cent, at the
most, of the eggs deposited throughout the State result in the develop-
ment of mature insects. If each female deposited her full number
of eggs and all the forms lived, it has been estimated, the progeny of
a single pair of white flies emerging in January would amount to
about 55,000,000,000 in one year.

80

WHITE FLIES INJURIOUS TO CITRUS EN FLORIDA.

Length of Lite Cycle.

Data concerning the duration of the egg, larval, and pupal instars
of the citrus white fly have already been given, but not in a form readily
showing the relation to the complete life cycle. From some of the
more important and complete of the life-history studies the data in
Table XV have been arranged to illustrate the important points in
this connection:

Table XV. — Length of life cycle of the citrus white fly at Orlando, Fla.

Lot No.

Eggs de- First fly
posited, emerged.

Last At First flv T t fl
emerged i emerged z££z2ZK
in fall, in spring. anetSeo.

Xo. 1.

No. 2..
No. 3..
No. 4..
No. 5..
No. 6..
No. 7..
No. 8..
No. 9..
No. 10.
No. 11.
No. 12.
No. 13.
No. 14.
No. 15.

Feb. 23
Mar. 3
Aor. 3
Apr. 20
June 16
Julv 17

..do

Julv 19
July 26
Aug. 1
Aug. 3
Aug. 8
Aug. 9
Sept. IS
Sept. 21

Apr. 30
May 9
May 30
June 7
Julv 30
Aug. 27
Sept. 4
Sept. 2
Sept. 6
Sept. 19
Sept. 25
Sept. 19
Mar. 30
Mar. 16
Mar. 12

Sept. 10
SeDt. 17
Sent. 21
Sept. 20
Sept. 26

..do

Sept. 27
0
0
0

Mar.
Mar.
..do.
Mar.
Mar.
Mar.

Mar. 18

16 Apr. 16

17 May 4
... May 1

Mar.
Mar.

Mar.

May 10
Apr. 6
Apr. 15

May 12
Apr. 28
May 10

Lot No.

Least

Largest

Per cent

Per cent

number of

number of

winter-

davs for

davs for

before

winter.

ing over

develop-

develop-

to emerge

ment.

ment.

m spring.

67
67
57

100.0
100.0
100.0

0
0
0

48

333

44
41

273

56.9

43.1

49

291

30.8

69.2

45

286

12.7

S7.3

42

2\S

29.8

70.2

49

248

5.5

94.5

53

255

3.6

96.4

42

2.7

97.3

223

276

0

100.0

179

222

0

100.0

172

231

0

100.0

Smallest
number
degrees
effective
tempera-
ture for
develop-
ment.

Degrees
accumu-
lating
before
spring
emer-
gence.

Degrees
accumu-
lating
before
last fly
emerged.

No. 1 .
No. 2.
No. 3.
No. 4.
No. 5.
No. 6.
No. 7.
No. 8.
No. 9.
No. 10
No. 11
No. 12
No. 13
No. 14
No. 15

From this table it will be seen that the period of development for
individuals hatching from eggs laid upon the same leaf within a few
hours of each other is subject to an astonishing variation, ranging
from 41 to 333 days. Tins variation is absolutely independent of
both temperature and humidity influences. It will be noted that
the sums of effective temperatures required for the minimum dura-
tion of immature stages for individuals developing from eggs de-
posited between February 23 and August 8 vary from 1.641° to
2.153°, with an average of 1,846°, which may be regarded as very
nearly the normal for minimum development up to the time when

THE CITRUS WHITE FLY: SEASONAL HISTORY.

81

all individuals winter over as pupae. It should also be noted that
the number of maximum degrees of effective temperature is more
strongly influenced by the time of year the eggs are deposited — the
nearer the winter months deposition takes place the fewer the degrees
accumulating before the last fly emerges. This is due to the equal-
izing effect of the cooler winter temperatures.

This same equalizing effect of the winter temperatures upon the
length of the life cycle for individuals developing from eggs laid on
September 20 is brought out in Table XVI:

Table

XVI . — Duration

of instar s of the citrus white fly.

Instar.

Speci-
men
No.

First.

Second.

Third.

Pupal.

Total
num-

Duration of
instar.

Num-
ber
of
days.

Duration of
instar.

Num-
ber
of
days.

Duration of
instar.

Num-
ber
of
days.

Duration of
instar.

Num-
ber
of
days.

ber of

days.

1

2

3

4

5

1908.

Oct. 3-10

Oct. 3-10

Oct. 3-15

Oct.3-Nov.2.
Oct. 3-10

8
8
13
31

8

1908.
Oct. 10-15..
Oct. 10-24..
Oct. 15-22..
Nov. 2-16..
Oct. 10-18. .

5
14

7
14
8

1908.

Oct. 15-27

Oct. 24-Nov. 10
Oct.22-Nov.4..
Nov. 16-Dec.3..
Oct. 18-29

12
17
13
17
11

1908.
Oct. 27- Apr. 28
Nov. 10-Apr. 17
Nov. 4-Apr. 8 . .
Dec. 3-Apr. 6. . .
Oct. 29-Mar.26.

173
158
155
128
148

198
197
188
190
175

From this table it will be seen that retardation in growth during
any one instar does not affect materially or show a corresponding
increase in the total number of days required for development when
the individual passes the winter in the pupal stage. Also, that an
unusually large number of days spent in one instar does not neces-
sarily mean that the individual insect will be equally backward
in the next instar. These records of daily observation on individual
specimens from hatching to adult are only 5 of 85 similar obser-
vations for the same period. Nos. 2-5 were insects on the same leaf.

SEASONAL HISTORY.
Generations of the Citrus White Fly.

It has been generally understood in the past that there are three
generations annually of the citrus white fly, although Prof. H. A.
Gossard,1 states that ''four generations a year doubtless often occur,
but not in sufficient numbers to obscure three well-defined broods
as the rule." In the greenhouses at Washington, Riley and Howard 2
found that there were but two generations annually. The life-history
work of the present investigations has shown that while the general

1 Bui. 67, Fla. Agr. Exp. Sta., p. 612, 1903.

2 Insect Life, vol. 5, p. 224, 1893.
59131°— Bull. 92—12 6

82

WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

observations of the past leading to the statement of three more or
less distinct periods of emergence are correct, the number of genera-
tions annually ranges from two to five, or, under unusually favorable
conditions, from three to six. In figure 11 the maximum and mini-
mum number of generations as actually known to occur in groves
at Orlando during 1907-9 has been plotted. Figure 11 is based
upon the development of individuals in rearing experiments. The
generation between January and March may or may not occur,
according to whether the winter weather is warm or cold, but when
present is numerically insignificant. The other generations are
more confused than can be indicated diagrammatically. As may

(/JtM/V.

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(4)JtW£,J(/LY
1 > I <

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1

3rd. 4th. 5th. 4th. 5th, 6th. 3n/.

* ADULTS EMEPG//VG /IT TH/S T/M£ ARE fffOM EGGS DEPOS/TED
0EFORE THE /St/r. OF /I (/GUST.

Fig 11.— Diagram showing generations of the citrus white fly. (Original.)

have oeen inferred from data in Tables XV and XVII, the variation in
the number of generations is due almost entirely to the length of the
pupal stage, which, as has already been pointed out, is subject to
wide variation, the cause of which can not be traced to food, tem-
perature, humidity, or location on the tree. The most striking
variation in the length of life cycle, with its effect upon the possible
number of annual generations, is found among individuals developing
from eggs deposited in April and May. In one instance eggs depos-
ited on April 20 produced adults on June 5, July 31, and in the
following March. In the main, each generation has two more or
less distinct periods of emergence, as reference to the data in Tables
XV and XVII will show.

THE CITRUS WHITE FLY: SEASONAL HISTORY. 83

Table XVII. — Emergence of adult citrus white flies at Orlando, Fla.1

Record

Eggs depos-
ited.

April.

May.

June.

July.

August.

No.

1-15

16-30

1-15

16-31

1-15

16-30

1-15

16-31

1-15

16-31

1

Feb. 22

Mar. 3

Mar. 18-25". . .

Apr. 20

June 16

July 17

July 17

July 19

July 26

Aug. 1

Aug. 8

Aug. 9

Sept. 18

Sept. 21

0
0
0
0
0
0
0
0
0
0
0
0
0
0

1
0
0
0
0
0
0
0
0
0
0
0
0
0

85
44
1
0
0
0
0
0
0
0
0
0
0
0

2

44
51
0
0
0
0
0
0
0
0
0
0
0

3
4
5

30.3
50.1
0
0
0
0
0
0
0
0
0
0

2.9
28.6
0
0
0
0
0
0
0
0
0
0

0
0
0
0
0
0
0
0
0
0
0
0

4.9
8.2
(3)
0
0
0
0
0
0
0
0
0

9.9
0

0
0

6
7
8
9
10
11
, 12
13
14

0
0
0
0
0
0
0
0
0

32.1

a

0
0
0
0
0
0
0

Record

Eggs deposited.

September.

October to
March.

March.

April.

May.

No.

1-15

16-30

1-15

16-31

1-15

16-30

1-15

16-30

1

Feb. 22

2

Mar. 3

3

4

Mar. 18-25

Apr. 20

0
0

0
(2)

0
0

0
0

0
0

0
0

0
0

0
0

0
0

5

June 16

6

July 17.

24.4
23.9

8.7
23.8
0
0
0
0
0

0.4

6.9

1.7

6.5

3.3

2.7

0

0

0

0
0
0
0
0
0
0
0
0

0
0
0
0
0
0
0
0
0

43.1
67.3
89.2
64.3
85.6

0

1.9

.4

5.4

11.1

0
0
0
0
0

0
0
0
0
0

0

7

July 17

0

8

July 19

0

9

July 26. . . .

0

10

Aug. 1

0

11

Aug. 8

12

Aug. 9. . .

98.7
38.3
38.6

1.3

46.8
47

6
14.9
14.7

0
0
0

0

13
14

Sept. 18

Sept. 21

0
0

1 This table is introduced to demonstrate the two emergence periods for individuals developing from
eggs deposited at the same time. It is not intended to represent the abundance of adults at different
times of the year. Figures represent percentages. ' |

2 Only one fly survived to winter over. '

3 One fly emerged July 30. Leaf was broken off on same day. Development of flies indicated that at
least 50 per cent would have emerged during August.

This makes it possible for adults emerging during the first period
to deposit eggs for a second generation, a portion of the adults of
which (first brood) will emerge at the time of the second emergence
period (second brood) for the first generation, while a large proportion
of the remaining individuals on the leaf to all appearances remain
stationary in their development, though actively secreting honeydew,
until the approach of the first emergence period of the second genera-
tion started by the second brood of the first generation, when they
rapidly mature and emerge with this brood. However, this double-
brooded character of each generation up to and including generations
started in early August does not obscure the three well-defined
" broods" of adults, to be discussed under " Seasonal fluctuations in
the numbers of adults or so-called 'broods,'" but shows that the
adults appearing during the three general emergence periods do not,
strictly speaking, represent a single brood of one generation, but
different broods of different generations. By far the greater number

84

WHITE FLIES INJURIOUS TO CITRUS IK FLORIDA.

of wintering-over pupae belong to the fourth, fifth, and sixth genera-
tions, with the last two most abundantly represented. The number
of third-generation pupae — or second generation should the first gen-
eration in figure 11 not occur — to winter over is insignificant.

Seasonal Fluctuations in the Numbers of Adults or so-called " Broods."

During winters of unusual mildness there is a tendency for con-
tinuous breeding, and adults in varying numbers can be found on
the wing at different times, but these are as a rule too few in number
to be of importance in effecting the general seasonal history of the
citrus white fly. With the exception of the limited number of larvae
developing from eggs deposited by these unseasonal adults, the
white fly passes the winter in the pupal stage. The first general
spring emergence of adults begins after the daily mean temperatures
have risen to about 65° F., which at Orlando in 1909 was about Feb-
ruary 20.

There are three periods throughout the year when adult citrus
white flies are so much more abundant than at other seasons that it
is generally said there are three broods of white flies each year,

frBfiUst/ry

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Fig. 12.— Diagram showing abundance of adults of the citrus white fly at Orlando, Fla., throughout

1909. (Original.)

although, as already noted under the subject of generations, the term
brood in this case is somewhat misleading. The dates at which these
adults appear is subject to such variation in groves in the same
county, town, or even on individual trees of the same grove, that no
accurate statement of the dates between which the broods occur
throughout the State as a whole can be made. The authors, there-
fore, have chosen to follow the history of the white fly in a single
grove at Orlando during the season of 1909 as a specific example, as
a basis, and present in figure 12 a curve representing the abundance
of adults throughout that season. In all its essential features the
curve is regarded as representing the appearance of adults in any
grove, when it is remembered that variations of from one to three
or four weeks may occur in the appearance of the broods.

While it is generally believed that adults appear earlier in the spring
throughout southern Florida, it is a fact that there is very little dif-
ference in time of emergence between that and the central portion.
Emergence throughout the northern portion of the State is, according
to the season, from one to four weeks later than in the central and

THE CITRUS WHITE FLY: SEASONAL HISTORY. 85

southern portions. Prof. H. A. Gossard has stated that at Lake
City in 1902 white flies began to appear no earlier than April 14, and
continued to appear until late in May, although the majority of them
emerged during the latter half of April, while in 1903 the same trees
produced adults as early as March 12, or but one week later than
groves at Orlando and Palmetto. While the spring brood of adults
at Orlando in 1909 had begun to emerge as early as February 20 and
had reached their height and begun to decline by March 27, on the
latter date in St. Augustine only 5 per cent of the pupae had devel-
oped the eyes of the adult and practically no adults had emerged.
Professor Gossard also is authority for the statement that at " Tampa,
30 to 40 miles north of the Manatee section, the spring brood of
white flies has in some seasons preceded their appearance about
Bradentown and Manatee by two weeks." By June 18, 1909, more
than twice as many adults of the second brood had emerged at
Manatee as at Island Grove about 125 miles north in Alachua County,
while by July 7 of the same year the white fly in a grove at Alva in
Lee County was no further advanced than at Orlando.

From the curve in figure 12 it will be noticed that there are two
periods of about three weeks during the summer between the broods
when adults are comparatively very scarce. While reference to
Table XVII shows that a few wintering-over individuals continue
to emerge as late as early May, the period between the first and sec-
ond broods of adults is exceptionally free from adults of the citrus
white fly. This, however, is not true of the like period between the
second and third broods as before this time the generations of the
white fly have become somewhat confused, due to variation in life
cycle, and adults continue to emerge in appreciable numbers through-
out the period.

In speaking of the entire citrus belt, including Florida and the
Gulf States, the greater part of the spring brood may be said to
emerge during March and April; the second brood to emerge during
late May, June, and July, and the third brood during August and
September. It should be noted here that the greater part of the
adult white flies appearing in October and November in the central
and southern part of Florida are the cloudy-winged white fly, A.
nuhifera, although in the northern part adult specimens of A. citri
have been seen in small numbers on the wing in St. Augustine as
late as November 15.

86 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

THE CLOUDY-WINGED WHITE FLY.

(Aleyrodes nubifera Berger.)
HISTORY.

Specimens of the cloudy- winged white fly (eggs, larvae, and pupse)
in the collection of the Bureau of Entomology show that this species
occurred on oranges in the United States as early as 1889. The
records in connection with the specimens show that it was collected
in Mississippi and North Carolina in 1889, in Louisiana in 1890, and
in Florida in 1895. Outside of the United States it is known to occur
only in Cuba. Its introduction into the United States from Cuba
does not seem as probable as its introduction into Cuba from the
United States. At present there is no evidence concerning the
probable origin of the insect except in the absence, so far as is known,
of other food plants than citrus, which would seem to indicate the
introduction of the insect with its only known food plant.1

Several writings on the citrus white fly (Aleyrodes citri) have in part
included the cloudy- winged white fly (A. nubifera). Prof. H. A.
Morgan,2 in 1893, previous to the publication of the original descrip-
tion of Aleyrodes citri, briefly described the egg of Aleyrodes nubifera
and figured it, the description of the pupa and adult given at the
same time evidently being based on specimens of A. citri. The
species to which Prof. Morgan referred the specimens was Aley-
rodes citrifolii Riley MS. The original description of the citrus
white fly,3 while unquestionably defining the species generally recog-
nized as A. citri, included in part reference to what is probably the
cloudy-winged white fly. In the text the description of the first
stage or instar of the larva was evidently based on a specimen of the
cloudy-winged white fly and the illustration of the first instar4 was
also based on this species with little doubt. One figure of the pupa 5
and one of the pupa case 6 evidently were based upon specimens of
the same species. In the writings of Prof. Gossard there are no
references in the text which evidently refer to the cloudy-winged
white fly, but what is probably this species is represented in an
illustration of the first stage.7

1 Its recent discovery on Ficus nitida, rubber tree, in greenhouses at Audubon Park,
New Orleans, La., points to its possible introduction from India.

2 The Orange and Other Citrus Fruits. Special Bulletin Louisiana Agricultural
Experiment Station, p. 72, 1893.

3 Insect Life, vol. 5, pp. 220-222, 1893.

4 Id., vol. 5, p. 219, fig. 23, d.

5 Id., vol. 5, p. 219, fig. 23, h.

6 Id., vol. 5, p. 219, fig. 23, i.

7 Bulletin 67, Florida Agricultural Experiment Station, pi. 2, fig. 1. See also
Bulletin 88, pi. 2, fig. 1, and Bulletin 97, fig. 11, Florida Agricultural Experiment
Station, and Circular 30, California Agricultural Experiment Station, pi. 2, fig. 1.

THE CLOUDY- WINGED WHITE ELY: INJURY. 87

The white fly known as the cloudy- winged white fly was first
determined as specifically distinct from the citrus white fly by Dr.
E. W. Berger in 1908. Dr. Berger has recently given this species
its scientific name in connection with a synopsis of the principal
distinctive characters and illustrations of egg and larval and pupal
stages.1

AMOUNT OF INJURY BY THE CLOUDY-WINGED WHITE FLY.

The injury caused by the cloudy-winged white fly is at present
much restricted by several factors. In Florida the distribution of
this species is limited as compared with that of the citrus white fly.
Its food-plant differences and adaptations are such that orange
trees 2 are not as a rule subject to as heavy infestations as by the
citrus white fly, although with grapefruit trees this situation is
usually reversed. Most important as a factor limiting the injury
from the cloudy winged white fly is that when both occur in an
orange grove the citrus white fly almost invariably predominates
and the cloudy-winged white fly assumes a position of comparative
insignificance. Owing to the difference in the seasonal history of
the two species of white fly this latter point is not always apparent
to the casual observer. An observation made between the broods
of adults of the citrus white fly, or at any time after the middle of
September up to December 1, may result in noting a great pre-
ponderance of the cloudy-winged white fly, leading one to conclude,
perhaps, that it is this latter species which is causing the most injury.
An examination of the leaves during the winter months, when there
are practically no adults of either species, will probably show an
entirely different situation. In many groves near Orlando and
Winter Park in Orange County, Fla., both species of white fly are
well established and practically have assumed their normal rela-
tive positions in point of numbers. Examinations of leaves varying
in number from 85 to 400 picked at random in 11 of such groves
furnish data which illustrate the general situation as regards the
importance of the two species of white fly under the conditions
mentioned. (See Table XVIII.) All the examinations were made
during the winter months, using pupa cases and live pupae as the
basis of the comparison.

1 Bulletin 97, Florida Agricultural Experiment Station, pp. 68-70, figs. 12, 14, 16,
18, 19.

2 According to the latest statistics available (Ninth Biennial Report of Commis-
sioner of Agriculture, State of Florida) there were more than five times as many orange
trees as grapefruit in Florida, 1,786,944 orange trees being reported for 1905 as against
373,008 grapefruit trees.

88

WHITE FLIES INJURIOUS TO CITRUS IN" FLORIDA.

Table XVIII.— Com?

abundance of Aleyrodes citri and Aleyrodes nubifera in
0 roves infested by both species.

Grove Nos.

Tangerine.

Grapefruit.

Orange.

Grapefruit and
orange.

Citri per
leaf.

Nubifera
per leaf.

Citri per
leaf.

Nubifera
per leaf.

Citri per
leaf.

Nubifera
per leaf.

Citri per
leaf.

Nubifera
per leaf.

1

44.2

7.5

1.6

1.4

2

33.2

4
14.5

4.6

0.5

1.2

.4

.2

3

4

5

6

8.8

2.4

11.2
21.

1.1

1.6

8

9

33
30

.56

7.

10

11

.9

.2

.8

3.7

Average.
Per cent

22.5
86.7

3.6
13.3

3.7
59.6

2.5

40.3

19.9
97.7

.59
2.3

16.1
92.6

1.3
7.4

Owing to the great attraction of new growth for the cloudy- winged
white fly, which is discussed elsewhere, the scarcity of new citrus
growth at certain seasons which causes concentration on water
shoots, and other factors, this species, when it occurs by itself in a
tangerine or orange grove, does not as frequently as the citrus white
fly cause noticeable blackening of the foliage before the middle of
June. At the end of the season the cloudy- winged white fly by itself
may cause tangerine and orange trees to become as heavily blackened
with sooty mold as the citrus white fly when the latter is at its great-
est abundance. As has been stated, the cloudy- winged white fly is
more likely to heavily infest grapefruit trees than is the citrus white
fly. The cloudy- winged white fly seems to be subject to more exten-
sive fluctuations from year to year, aside from the effects of fungus
parasites, than is the citrus white fly, and frequently after infesting
an orange grove for several years fails to cause enough injury to
make washing of the fruit necessary or to make necessary the wash-
ing of more than one-fourth or one-third of the crop each year.

As a whole, the injury is not as extensive in groves where the
cloudy-winged white fly occurs alone as in groves where the citrus
white fly occurs alone. When the two species become well estab-
lished, the former does comparatively little damage except to grape-
fruit. The authors would estimate that there are about 5 per cent
of the orange and tangerine groves in the State infested by the
cloudy-winged white fly that are not also infested by the citrus
white fly, and that there are in addition 1 per cent of orange and
tangerine groves infested by both species but in which the citrus
white fly has not as yet attained injurious abundance. The average
damage from the cloudy- winged white fly is estimated at about 10
to 15 per cent lower for oranges where that species alone infests the
grove than where the citrus white fly is the species concerned. For

THE CLOUDY- WINGED WHITE FLY : DISTRIBUTION. 89

injury to grapefruit the authors consider 25 per cent a fair estimate
of the injury by the cloudy-winged white fly as compared with about
10 or 15 per cent by the citrus white fly. The total loss in Florida
due to the cloudy- winged white fly is estimated by the authors at
between $100,000 and $125,000 per annum at the present time.

DISTRIBUTION.

So far as known at the present writing the cloudy-winged white fly
occurs in 12 counties in Florida. The locality list is given below:1

Brevard County: Mims, Sharpes, Titusville.
Dade County: Miami.

Hillsboro County: Biverview, Thonotosassa, Ybor City, Clearwater, Dunedin,
Largo, Ozona, Safety Harbor, Saint Petersburg, Sutherland.
Manatee County: Bradentown, Oneco, Palmetto.
Monroe County: Key West.

Orange County: Geneva, Maitland, Ocoee, Orlando, Oviedo, Waco, Winter Park.
Palm Beach County: Palm Beach, West Palmbeach.
Polk County: Auburndale, Bartow, Lakeland, Winterhaven.
St. Lucie County: Fort Pierce.
Sumter County: Wildwood.
Volusia County: Haw Creek, Holly Hill, Port Orange, Pierson.

Outside of the State of Florida the only available records of the
occurrence of the cloudy-winged white fly are those of the Bureau of
Entomology in connection with specimens in the collection. Mr.
A. L. Quaintance has identified as this species specimens from New
Orleans (1890) and Baton Rouge, La. (1891), Pass Christian, Miss.
(1889), and Raleigh, N. C. (1889). In a brief examination at Audu-
bon Park, New Orleans, in August, 1909, the senior author was
unable to find any evidence of the presence of this species, although
the citrus white fly was prevalent on citrus trees, privets, and other
food plants.

As stated in the footnote on page 27, the species occurring at
Bakersfield, Cal., in 1907 was the cloudy- winged white-fly. Owing
to the fact that the insect is, so far as known, confined to citrus as a
food plant and only a limited number of these in an isolated location
were infested, the thorough measures adopted by the agents of the
State commissioner of horticulture met with complete success, and
there is no record of this species occurring at present in this State.

Its occurrence in Cuba has already been noted, specimens having
been received from Santiago de las Vegas in 1905.

The distribution of the cloudy-winged white fly in Florida, so far
as now known, is shown in figure 13. The territory included in the

1 The authors have determined as Aleyrodes nubifera specimens from all of the
localities listed above except the following, which are listed upon the authority of
Dr. E. W. Berger: Holly Hill, Ybor City, Bartow, Clearwater, and Safety Harbor.

90

WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

infested area is not generally infested, and the same . precautions
should be observed within this area as outside of it to avoid unneces-
sary spread of the pest.

FOOD PLANTS.

The cloudy-winged white fly is not known in Florida to breed
upon any other food plant than citrus. It has recently been dis-
covered infesting the rubber trees (Ficus nitida) growing in the green-
houses in Audubon Park, New Orleans. Extensive examinations
for possible food plants have been made by the authors and by
Dr. Berger, and it is reasonably certain that no important food

plant will be found
in Florida citrus-
growing sections
which will interfere
with the control of
this species.

Examinations of
prickly ash (Xan-
thoxylum clava-7ier-
culis), the most com-
mon representative
of the family Ruta-
cea3 to which the
citrus belongs, indi-
cate that this species
of white fly never
breeds on this plant,
regardless of the con-
dition of infestation of neighboring citrus trees. Reports of blacken-
ing of the foliage of prickly ash by the white fly in sections where
only the cloudy-winged white fly of the two herein treated occurs,
are doubtless erroneous and probably based upon the blackening due
to an aphis or to some other insect. In addition the following plants
have been examined under favorable conditions to determine if sub-
ject to attack by the cloudy-winged white fly, but so far without
results :

China trees and umbrella China trees, cape jessamine, privets,
Japan and wild persimmons, oaks, wild cherry, guava, fig, grape,
cherry laurel, blackberry, and magnolia.

Fig. 13,

-Map showing distribution of the cloudy-winged white fly
(Aleyrodes nubifera) in Florida. (Original.)

SPREAD.

The dissemination of the cloudy-winged white fly is limited by the
same factors which have been discussed as unfavorable to the suc-
cessful establishment of the citrus white fly. Aside from these factors

THE CLOUDY- WINGED WHITE FLY: LIFE HISTORY AND HABITS. 91

its chief limitation is in its lack of important food plants other than
citrus. Migrations of adults are not an important factor in the spread
of this white fly except between adjoining groves. Its spread through-
out a newly infested grove and to adjoining groves is perhaps favored
by its greater degree of attraction to new growth. It has been
observed frequently in newly infested groves that it is found to be
present in very small numbers over a considerable area, whereas the
citrus white fly, when at a corresponding numerical status, would
be expected to be more localized. Winds are doubtless concerned
with the spread of the insect from local centers, but, as with the citrus
white fly, they are evidently a factor of small consequence in spread
to distant points.

Flying insects and birds as carriers of the crawling larvae are neces-
sarily of little or no consequence in the spread of the cloudy-winged
white fly, as with the species previously discussed. Between groves
vehicles of various kinds are of much importance in distributing this
white fly, as is generally recognized. Without doubt infested citrus
nursery stock has been the principal factor in the
spread of the cloudy-winged white fly. Nursery
stock from Mims, Fla., is quite definitely known
to have been the source of this white fly at
Sharpes, Fla. At the present time it seems to
be the most probable source of this white fly at
Fort Pierce, Palm Beach, and Miami.

The species here considered are apparently as
likely to be carried on the person from an in- fig.i^— The cloudy-winged
fested grove as is the citrus white fly, the degree ^^: ^^^
of infestation being equal. The same may be
said of pickers' outfits. The introduction of fungus-infected leaves
into groves infested only by the citrus white fly in connection with
the introduction of fungus parasites has doubtless assisted in the
spread of the cloudy-winged white fly, but not to the same extent
that this has assisted in the spread of the former species.

LIFE HISTORY AND HABITS.

The Egg.

The egg (fig. 14) of the cloudy- winged white fly differs from that
of the citrus white fly in that it is not greenish-yellow and highly
polished, but bluish or grayish black and roughened by a film of wax
arranged in an hexagonal pattern. To the unaided eye the eggs
appear as fine particles of blackish dust scattered over the leaves
(PI. X, fi.g. 1). Because of their dark color they are more readily
seen on the tender citrus growth by the average observer than are
the eggs of the citrus white fly. When first deposited they are not
blackish, but are dull white or cream colored and under the micro-

92 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

scope the waxy coating appears tinged with red. The eggs remain
pale for three days, when about 96 per cent turn black, the rest taking
sometimes as long as seven or eight days to darken. Meanwhile the
waxy coating has turned gray. Because of the dark color and much
tougher chorion, the eyes of the embryo are not as easily seen as are
those of the citrus white fly. The eggs are attached to the leaf by a
pedicel arising from the proximal end similar to that of A. citri.

A study of the contents of Tables VIII and XIX will prove that
what has been said of the duration of the egg stage, variability under
identical temperature conditions, and effect of temperature in gen-
eral, regarding the citrus white fly, applies almost equally well to this
species.

THE CLOUDY- WINGED WHITE FLY: LIFE HISTORY AND HABITS. 93

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WHITE FLIES INJURIOUS TO CITRUS IX FLORIDA.

The duration of the egg stage, however, is in general slightly longer.
As the bulk of the eggs hatch from 1 to 10 days later, a slightly higher
number of degrees of accumulated effective temperature are neces-
sary, and hatching is more evenly distributed though not always
extending over a larger number of days.

The process of hatching, proportion of eggs that hatch, and the
effect of drying of leaves in hatching do not appreciably differ from
what has been stated of A. citri; in hatching, however, the egg mem-
branes split only about one-third the length of the egg from the tip
and on one side only, and on account of the tougher chorion do not
shrivel, but retain their original form. Frequently, after the larva
has escaped, the membranes spring back into their original position,
thus causing the eggs to appear unhatched; as a rule, however, this
does not occur, and the opening made by the
escaping larva does not close. While no adults
have yet been reared from larvae hatching from
infertile eggs, it has been proved that virgin
females of the cloudy-winged white fly will
deposit eggs and that these readily hatch and
produce healthy larvae, and the evidence in
case of the citrus and greenhouse white flies
leaves no doubt that adults resulting from in-
fertile eggs will prove to be of the male sex.

The Larval and Pupal Stages,
the larva.

Fig. 15.— The cloudy-winged
white fly: Ventral view of
crawling larva of the first
in star. Greatly enlarged.
(Original.)

The larva of the cloudy-winged white fly
does not differ in general appearance from
that of the citrus white fly except that it is
a trifle larger. With the aid of the microscope
the first instar may be separated from that

of A. citri by the possession of 36 instead of 30 marginal bristles.

No structural differences between the second and third instars of the

two species have been discovered. Following is a more detailed

comparative description:

First larval instar (fig. 15).— Length, 0.29-0.32 mm. ; width, 0.19-0.22 mm. Similar
to the corresponding instar of A. citri, but differing in being proportionately broader,
in possessing 18 instead of 15 pairs of marginal bristles, and in developing soon after
settling a marginal irregular wax fringe eventually equaling in width the length of
the marginal spines. Relative length of marginal spines as follows:

Pair 1 2 3 J_ _5_ 6 ? 7 8 ? 9

Spaces 10.5' 7.5' 10.5' 8.5' 7. 0' 5.5' 6. 0' 5. 0' 6.0

Pair 10 11 12 13 14 15 f 16 < 17 ^ 18 ,

Spaces 5. o' 5. 0' 5. 0* 5. 0' 5. 0 6. o 15. 5' 6. 5' 15. 5

THE CLOUDY- WINGED WHITE FLY: LIFE HISTORY AND HABITS. 95

The relative lengths and location of other spines of the body do not differ from
similar spines on A. citri, neither do there appear differences in the structure of the
antennse, legs, vasiform orifice, or mouthparts when examined under a one-sixth inch
objective. Particles of wax secretions are found in varying
amounts on the ventral surface, sometimes in such abun-
dance as to make microscopic examinations difficult.

Second larval instar.— Length, 0.42-0.51 mm.; width
0.28-0.37 mm. Except in point of size no differences

have been discov-
ered between this
and the correspond-
ing instar of A. citri.
Third larval instar
(fig. 16).— Length,
0.66-0.9 mm.; width,
0.48-0.68 mm. Ex-
cept in size no differ-
ences have been dis-
covered between this
and the correspond-
ing instar of A. citri.

Fig. 16.— The cloudy-winged
white fly: Ventral view of
crawling larva of the third
instar. Greatly enlarged.
(Original.)

Fig. 17.— The cloudy-winged white fly.
Pupa: a, Ventral view; 6, enlarged vasi-
form orifice; c, enlarged margin, a, Greatly
enlarged; b, c, highly magnified. (Origi-
nal.)

THE PUPA.

In general appearance the pupa of
the cloudy-winged white fly (fig. 17, a,
b, c) resembles very closely that of the
citrus white fly. No striking structural differences have been dis-
covered between them. They are, however, very distinct, and one who
has examined them carefully can readily separate them without the aid
of a lens. The most important differences are
in the larger size and thinner and flatter appear-
ance of the pupa of the cloudy-winged white
fly. The difference in outline is shown in figs.
9, c, and 17, c. Their skins are more mem-
branous, making them more delicate and easily
crumpled. Furthermore, after thickening be-
fore maturity they do not develop the bright
red or orange spot on the middle of their backs,
md the wing pads and body of the adult (fig.
i8) are more easily seen. The pupa case (PI.
VIII, fig. 3) is much thinner, more membranous,
and falls from the leaf more readily. Its walls
do not remain rigid as do those of A. citri, but
because of their more delicate structure col-
apse after the emergence of the adult and present the crinkled
«. jpearance shown in the illustration.

Fig. 18.— The cloudy-winged
white-fly: Dorsal view of
pupa, showing adult insect
about to emerge. Greatly
enlarged. (Original.)

96

WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

DURATION OF INSTARS.

Larval instars. — By comparing the data in Tables IX. and XX it
will be found that the larva? of A. nubifera are slower in maturing
than those of A. citri. While this difference is not so pronounced
during the warmer months of the year, the total average number of
days being 25.9 and 23.1, respectively, during the cooler months it is
very striking, the total average number of days then being 56.7 for
A. nubifera, as compared with 30.4 for A. citri. In other respects
the statements made on the duration of the larval instars for A. citri
apply to A. nubifera.

Table XX. — Duration of larval instars of cloudy-winged white fly.

Speci-
men
No.

Period of growth.

Number of days
in —

Sum of
effec-
tive
tem-
pera-
ture.

Speci-
men
No.

Period of growth.

Number of days
in —

Sum of
effec-
tive
tem-
pera-
ture.

In-
star
1.

In-
star
2.

In-
star
3.

In-
star
1.

In-
star
2.

In-
star
3.

1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32

June 26- July 19...

June27-July 20...

June 27- July 21...

June 27- July 26...

June27-July 19...

June 27- July 21...

June27-Julyl7...

June 27- July 19...

June27-July 20...
do

June 27- July 21...

June 27- July 19...

June 28-July 27...

June 28-July 29...

June 28-July 24...

June 28-July — ...

June 28-July 19...

June 28-July 24...

June 29- July 29...

June 29- July 24...

June 29- July 29...

June 30- July 30...

June 30-July 29...

Sept. 30-Nov. 1...

Sept. 30-Nov. 20..

Sept. 30-Nov. 30..
do

9
6
8
9
9
8
7
5
7
7
7
7

14
7
11
9
6
7
6
7
8
8
12
5
8
12
14
12
8
8
8
8

6
6
6
7
7
8
6
7
6
6
6
6
8
6
8
21
6
9
15
7
8
8
7
10
16
12
15
23
10
21
13
14

8
11

10
13
6
8
7
10
10
10

11

9

7

18
7

938

942

979

1,179

902

, 979

820

902

942

942

979

902

1,179

1,260

1,056

33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60

Aver-
age
age.

Sept. 30-Nov. 20..
Sept. 30-Nov. 23..
Sept. 30-Dec. 20..
Sept. 30-Dec. 3...
Sept. 30-Nov. 23..
Sept. 30-Dec. 3...
Sept. 30-Nov. 27..
do

8

11

11

8

8

11

9

8

8

9

8

8

10

7

8

9

7

8

7

11

10

10

10

10

11
11

9
66

15
12
14
19
14
12

9
14
14
11
15
14

9

9

23-
10
12

9
11
18
17
16
23
15
20
20
11
died.

28
31
46
37
32
42
40
36
42
34
48
42
47
21
26
27
27
33
28
27
35
40
28
35
33
31
18

1,322
1,401
1,831
1,670
1,401
1,670
1,513
1,513
1,670
1,513
1,831
1,670
1,704
1,060
1,524
1,235
1,235
1,332
1,235
1,414
1,561
1,662
1,536
1,510
1,561
1,561
1,000

Sept. 30-Dec. 3...
Sept. 30-Nov. 23..
Sept. 30-Dec. 10..
Sept. 30-Dec. 3...

Oct. 2-Dec. 7

Oct. 2-Nov. 10....
Oct. 2-Nov. 30....
Oct. 2-Nov. 19....
do...

9

10
9
11
14
14
10
18
28
38
33
32
17
35
40
42

861
1,056
1,222
1,018
1,222
1,229
1,188

912
1,322
1,593
1,593
1,670

963
1,670
1,593
1,670

Oct. 2-Nov. 23....
Oct. 2-Nov. 19....
Oct. 3-Nov. 27....

Oct. 3-Dec. 3

Oct.3-Dec. 7

Oct. 3-Dec. 2

Oct. 3-Dec. 1

Oct. 3-Dec. 3

do

Oct. 5-Nov. 11....
Oct. 5-Dec. 10....

) June 26- July 30...
[Sept. 30-Dec. 10..

Sept. 30-Dec. 3...
Sept. 30-Nov. 3...
Sept. 30-Dec. 3...
Sept. 30-Nov. 30..
Sept. 30-Dec. 3...

8
9.1

7.8
14.4

10.1
33.2

1,031.7
1,475.6

Pupal instar. — That little difference exists between the .length of
the pupal stages of the two species of white fly in question is shown
by a comparison of the data in Tables X and XXI. The minimum
length of the pupal stage (17 days) will average but a trifle above
that of A. citri. But the maximum length is so dependent upon the
seasonal history that a direct comparison is difficult; this subject,
therefore, is more profitably discussed under the caption of seasonal
history. What has been said in connection with the maturing of
specimens of A. citri passing into the pupal stage at practically the
same time is equally true of the cloudy-winged white fly, A. nubifera.

THE CLOUDY- WINGED WHITE FLY: LIFE HISTORY AND HABITS. 97
Table XXI. — Duration of pupal stage of cloudy-winged white fly.

Speci-
men
No.

Period of growth.

Num-
ber of
days.

Sum of
effective
tempera-
ture.

Speci-
men
No.

Period of growth..

Num-
ber of
days.

Sum of,
effective
tempera-
ture.

1
2
3
4
5
6
7
8
9
10

May 24- June 11

May 26- June 14........

May 26- July 19

May 26

18
19
24

694

741

2,107

11
12
13
14
15
16
17
18
19
20

Oct. 12-Mar. 27

Oct. 31-Mar. 23

Nov. 1-Mar. 25

Nov. 14-May 29

Nov. 20-May 4

Nov. 23-Mar. 28

Dec. 3-Mar. 27

Dec. 3-Apr. 29

Dec. 7-Mar. 28

Dec. 11-Mar. 24

167
23
145
196
165
125
114
147
111
104

3,500
2,893
2,920
5,102
4,318
2,981
2,702
3,662
2,681
2,476

July 16 i-Aug. 2

July 18-Aug. 5

Oct. 9-Oct. 26

Oct. 9-Oct. 28

Oct. 9-Oct. 30

Oct. 9-Oct. 26 . .

17
18
17

18
21
17

689
714
466
519
562
466

1 It is to be regretted that the falling of the leaf upon which Nos. 5 and 6 matured prevented gathering
data on the maximum length of stage at this season of year.

GROWTH, MOLTS, LOCOMOTION, AND FEEDING HABITS.

Concerning growth, molts, locomotion, and feeding habits, there is
little to add to that already stated in connection with the larvae and
pupae of the citrus white fly. The two species are alike as regards
the number of larval ins tars and in their crawling and sedentary
habits. Their manner of feeding is similar also, with the exception
that when crowded the larvae of the cloudy-winged white fly settle
freely upon the upper surfaces of shaded leaves, where they frequently
reach maturity.

MORTALITY AMONG LARV.E AND PUP^E.

Remarks relating to mortality among the larvae and pupae of the
citrus white fly apply with greater force to the cloudy-winged white
fly. This mortality appears to result from the same causes in the
latter as in the former species. Life-history work has shown that
mortality due to spring droughts and dropping from leaves is prac-
tically the same for the two species, but that general mortality
including "unexplained" mortality is about 3 per cent higher for
A. nubifera. In this last respect, however, observations throughout
groves where infestation is much heavier than on leaves used in the
life-history work, and counts of forms on leaves infested with both
species of fly, show that the comparative susceptibility to the influ-
ences producing mortality of all kinds is often at least twenty times
greater for A. nubifera. This greater susceptibility appears to be
due not only to the more delicate structure of the larvae and pupae and
their need of more room for development because of their larger size,
but also to the adults' habit of crowding the new growth with eggs
far beyond its capacity for maturing the larvae hatching therefrom.

As may have been inferred already from statements upon the sub-
ject of oviposition, it is this insatiable desire of the adults for feeding
and ovipositing on new growth that is a most powerful factor lead-
ing to the insect's control. While a large amount of data might here
59131°— Bull. 92—12 7

98 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

be presented illustrating the disastrous effect on the species resulting
from overcrowding, the data itself would differ in no respect from
that already presented under the general consideration of A. citri.
Nevertheless, there is a great difference in the extent and practical
bearing of this mortality among the immature forms of the two
species.

The Adult.

The adult of the cloudy- winged white fly is similar to that of the
citrus white fly, but is at once separated from it by the dark spot
or shading on the outer portion of the upper wings (PI. X, fig. 1).
Except for the further fact that the female is appreciably more robust
the adults of both species are structurally much alike. The antennae
of A. nubifera are not as highly corrugated as those of A. citri, but
possess a terminal spine over three times as long as that of A. citri.
The eyes of A. nubifera are more nearly divided in many instances
than those of A. citri, although this is a character subject to variation
in both species.

On nearly all features of lif e history and habits this species closely
resembles the citrus white fly, and these subjects are therefore dealt
with in a comparatively brief manner. The principal points wherein
the cloudy-winged white fly differs from the citrus white fly may
be stated summarily as follows : It is more closely restricted to citrus
for its food supply as well as in oviposition; it shows a more strongly
developed tendency to feed and deposit eggs on new growth; its
arrangement of eggs and preferences for certain sections of leaves
for ovipositing are characteristic, and it is slightly less prolific. Its
apparent restriction to citrus as a food plant has been discussed under
the subject of "Food plants.'' Its strong preference for new growth
results in a situation which can be taken advantage of in the con-
trol of the pest by the pruning of water shoots.

The age at which oviposition begins and the activity in oviposition
during different parts of the day are the same as for A. citri. The
females, however, when not abundant deposit more readily along the
outer margin of the under surface of the leaf and along the edge
and upper surface, and not so freely along the midrib as is the case
with A. citri. Not infrequently 90 per cent of the eggs will be
deposited on the outer portion of the leaf while many are laid on the
edge of the leaf itself, from winch they often project perpendicularly.
The depositing of eggs on the leaf margin and on the upper surface
is peculiar to A. nubifera and is not the result of overcrowding. A
count of 4,000 eggs on nine moderately infested leaves showed that
8.1 per cent of the eggs were laid on the edge of the leaf, 86.8 per cent
on the lower surface, and 5.1 per cent on the upper surface. When
adults are very numerous both surfaces of the leaves of tender
growth and the petioles and shoot stems are thickly covered with

Bui. 92, Bureau of Entomology, U. S. Dept. of Agriculture.

Plate X.

The Cloudy-Winged and Citrus White Flies.

Fig. 1.— Adults of the cloudy-winged white fly, A. nubifera, showing cloud or spot at tip of
wings, and many eggs scattered about. Fig. 2.— Larvae and pupse of both the citrus white
fly and the cloudy-winged white fly killed by fumigation. During life they are nearly trans-
parent and seen only with difficulty. Note eggs of A. citri along midrib. (Original.)

THE CLOUDY- WINGED WHITE FLY: LIFE HISTORY AND HABITS. 99

eggs. While the citrus white fly deposits her eggs without any
definite arrangement, the cloudy- winged white fly, like many other
species of Aleyrodes, very frequently lays hers in arcs of various sizes,
and, as she is less restless while feeding, has a tendency to deposit
her eggs in groups. Tins arrangement, together with the difference
in color, makes easy the separation of the two species.

Reference to the data in Table XXII, especially when compared
with that in Table XII, shows that the daily rate of oviposition for
the cloudy-winged white fly is slightly less than for the citrus white
fly. As much of the data in Table XXII was obtained before typical
summer weather had set in, it is of more value as demonstrating the
relative rate of oviposition between the two species.

Table XXII. — Daily rate of oviposition of A. nubifera and A. citri compared.

Rec-
ord
No.

Date eggs
deposited.

Dura-
tion of

egg
laying.

Number of

females

of—

Number of eggs

deposited

by-

Average number

eggs per female

per 24 hours

laid by —

Average
mean

tempera-
ture.

Citri.

Nubifera.

Citri.

Nubifera.

Citri.

Nubifera.

1

2

3

Apr. 20-21,1909
Apr. 21-22,1909
do

Hours.
23

24
24
48
48
24
24

50
40

""36"

45
44
16
36
26
79
150

454
405

""366"

345
432
200
662
516
849
1,558

9.4
10.1

------

8

9.8
12.5

9.2

9.9
10.8
10.4

°F.
76
80
80
78
80
82
82

4

5

6

7

Apr. 22-24, 1909
Apr. 24-26, 1909
June 16-17, 1909
July 16-17,1907

The number of eggs deposited by single females has not been
definitely determined. However, as experiments have shown that
adults of A. nubifera are capable of living as long as those of A. citri
and have been known to maintain unimpaired an average of about
1 egg per day less than A. citri for at least seven days, it is safe to
say that the maximum egg laying capacity is not far from 200.

When all food plants other than citrus are eliminated, the remarks
covering the relation between oviposition and food supply for A.
citri hold for A. nubifera, with the exception that oviposition with
the latter species is far more dependent upon new growth. This
last fact, as discussed under mortality of larvae and pupae due to
overcrowding, has a most important bearing on the control of this
species.

After a grove has been well infested with the cloudy-winged white
fly there exists the same high percentage of females as recorded
under the same topic for A. citri. In fact, the same proportions of
sexes, and the same fluctuations and dependence of sex on partheno-
genesis, are found to occur with A. nubifera. A typical example is the
condition found in one grove infested entirely by this species. Dur-
ing the summer preceding winter fumigation the ratio between
females and males was 71.4: 28.6 pei cent. After fumigation, when

100

WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

over 99 per cent of the cloudy-winged white fly were killed, the
females of the spring brood were so very few in number and so scat-
tered that they deposited a very large percentage of infertile eggs,
resulting in a second brood in September, 62.8 per cent of which were
males. In other words, after the natural equilibrium between sexes
had been disturbed by fumigation, there followed as the result of
parthenogenesis a decided fluctuation between a predominance of
females in one and of males in the following generations. Gradually
this fluctuation diminishes until normal conditions obtain.

While less attention has been given the problems connected with
the emergence of tins species, observations have shown that the
process and time required for emergence and the changes in color
occurring thereafter are the same as for the citrus white fly, with the
exception of the cloud at the tip of the wing already mentioned.
Statements made concerning the conditions favorable and unfavor-
able for the emergence of the citrus white fly hold for this species.
An examination of the extensive daily emergence records on file and
summarized in Table XXIII show that even during October and
early November emergence did not occur below an average daily
mean temperature of 62° F. The emergence occurring later in the
fall, and consequently during cooler weather, does not appear to be
due to more resistance to cold, but to a difference in seasonal history.

Length of Life Cycle.

From a study of the length of the egg, larval, and pupal stages
already given one can obtain an accurate knowledge of the length
of the life cycle. A general summary of the data already presented
in connection with these various stages is presented in Table XXIII.

Table XXIII. — Length of life cycle of cloudy-winged white fly at Orlando, Fla.

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Apr. 20
June 16
Aug. 23

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334

1,800

No 2

Aug.
Oct.

2
14

47
52

1,849
1,899

No. 3..

Oct. 31

Mar. 20

May 16

266

64.7

35.3

5,205

7,062

No. 4..

Sept. 4

Oct.

23

Nov. 1

...do

Apr. 1

49

209

26.8

73.2

1,693

4,706

5,055

No. 5..

Sept. 18

Mar.

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Mar. 22

May 5

185

229

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4,650

5,915

No. 6..

Sept. 21

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Mar. 25

May 20

185

241

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4,638

6,318

No 7

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is

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Mar. 18

167

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4,006

4,006

No. 8.

...do

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"it

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Mar. 20

169

0

100

4.073

4,073

No. 9..

Oct. 22

Mar.

21

0

Mar. 21

Apr. 9

150

169

0

100 3, 549

3,549

4,056

It will be noted that 47, the least number of days required for
development, is but slightly higher than the minimum for A. citri,
even during most favorable weather conditions. The greater average

THE CLOUDY-WINGED WHITE FLY: SEASONAL HISTOBY.

101

number of days required for development, shown especially by com-
parisons of lots 1, 3, 6, and 7 of Table XXIII and lots 4, 5, 14, and
15 of Table XV, is not the result of chance circumstances, but actually
the result of slower general development under identical conditions.
This fact is perhaps more forcibly brought out by the data in Table
XXIV:

Table XXIV. — Rate of development of A. citri and A. nubifera compared.

Citri.

Nubifera.

Date.

Instar
1.

Instar
2.

Instar
3.

Instar
4.

Instar
1.

Instar
2.

Instar
3.

Instar

4.

July 6

P.ct.

11.7
2.1
.7
0
0
0
0
98.4
8.0
.6
.6
0
0
0
0
0
0

P.ct.

88.3

82.7

10.5

4.8

2.9

0

0

1.6

92.0

59.4

4.3

2.4

.9

0

0

0

0

P.ct.

0

15.2

89.8

86.1

20.6

6.1

0

0

0

40.0

90.7

17.2

1.9

1.9

0

0

0

P.ct.

0

0

0

9.0

76.7

93.9

100.0

6'

0
0
4.4
80.3
97.1
98.1
100.0
100.0

P.ct.

77.9

6.9

1.4

0

0

0

0

99.6

35.8

2.9

2.8

1.8

0

0

0

0

0

P.ct.

22.1

92.1

30.8

8.1

5.9

.8

0

.4

64.2

96.0

48.8

20.9

3.3

0

0

0

0

P.ct.

0

1.0

67.8

91.1

62.2

22.5

14.9

0

0

1.1

48.3

75.4

90.0

28.2

12.7

4.2

0

P.ct.
0

July 8

0

July 12. .

0

July 16

0.8

July 21. .

31.9

July 25

76.7

July 29

85.1

0

October 11

0

0

October 23

0

October 31

1.8

6.6

December 3

71.8

87.3

December 17

95.8

100.0

In this table is shown the corresponding progress of growth of
both species on various dates after egg deposition. The data con-
cerning development during July refer to larvae hatching from eggs
laid on June 16, 1909, and that during October, November, and
December to larvae hatching from eggs deposited on September 18,
1909. For these records, leaves on the same shoot were chosen for
deposition of the eggs of each species; hence both species were subject
to identical climatic and nutritive conditions.

A study of the data in Tables X and XXI will also prove that the
same statements made for A. citri concerning the equalizing effect
of winter on the length of the pupal stage for wintering-over pupae
are equally true for A. nubifera. The data show at a glance that
eggs deposited in late October are capable of producing adults the
following spring as early or even earlier than eggs deposited a month
or, as sometimes occurs, five months earlier.

SEASONAL HISTORY.

Generations of the Cloudy-winged White Fly.

Aside from the fact that the adults of this species have never been
seen by the authors on wing during January and early February, as
have those of A. citri, there being therefore no winter generation

102 WHITE FLIES INJURIOUS TO CITRUS EN FLORIDA.

corresponding to that of A. citri, the statements made regarding the
number of annual generations of A. citri is true of A. nubifera when
the additional statement is made that the height of the various
emergence periods occurs usually about two or four weeks later than
the corresponding periods for A. citri. The emergence of adults
brings about the same complications in broods and generations
described for A. citri, resulting from variation in length of life cycle,
and the double-brooded character of each generation is also to be
found in the life history of A. nubifera. Of eggs laid August 23,
1907, 1.5 per cent produced adults between October 1 and 15 and 63.2
per cent between October 16 and 31 ; of the rem ami rig pupas wintering
over, 34.6 per cent emerged between March 16 and 30 and 0.7 per cent
between April 1 and 15. From eggs laid September 4, 1907, 24 per cent
of the adults emerged between October 16 and 31, 2.8 per cent between
November 1 and 15, 71.8 per cent between March 16 and 30, and 1.4 per
cent between April 1 and 15. From eggs laid September 18, 1908, 81.6
per cent of the adults emerged between March 16 and 30, 4.1 per cent
between April 1 and 15, 10.2 per cent between April 16 and 30, and
4.1 per cent between May 1 and 15. From eggs deposited March 29,
1909, 44.5 per cent emerged between June 1 and 15, no further records
being kept.

It might be inferred from the slower development of A. nubifera
that it would pass through a less number of annual generations than
A. citri. This, however, is not true, inasmuch as its slower develop-
ment is offset by its seasonal history — it remaining active later in
fall and early winter.

Seasonal Fluctuations in the Number of Adults or So-called "Broods.''

Because the generations of the cloudy-winged white fly are of the
same general double-brooded character as those of the citrus white
fly, and are subject to the same unexplainable variation in the
length of the life cycle, the seasonal history of A. nubifera is not
unlike that of A. citri in nearly all essential features. In fact, the
same three periods of general emergence of adults occur as with A.
citri, but with the difference that the adults of each so-called " brood"
reach their numerical maximum usually from two to four weeks
later than the corresponding broods of A. citri. In figure 19 are
given curves representing the abundance of adults of A. citri and A.
nubifera at Orlando during 1909. As a result of this striking differ-
ence in the seasonal history of these two species, previous observa-
tions on this subject are considerably confused and should be disre-
garded unless one is positive of the species under consideration at the
time. As with A. citri, no one definite statement can be made to
cover the exact time when the emergence of various broods will begin.
Emergence is strongly influenced by local weather conditions. While
the curve in figure 19 represents the condition in one Orlando grove

THE CLOUDY-WINGED WHITE FLY: SEASONAL HISTORY.

103

in 1909, it is not meant to represent the abundance of adults in any
other grove in that city, much less in groves in various parts of the
State. The same variation in neighboring groves in the same county
and in a lesser degree in different trees in the same grove occurs with
A. nubifera, and this statement apparently holds for infested groves
in any part of the State. For example, groves at Dunedin and
Sutherland, in 1909, showed a difference of at least 10 days in the
beginning of the active spring emergence of adults.

The most striking difference in the seasonal history between A.
citri and A. nubifera which perhaps attracts most general attention
and leads to more confusion between the two species in the minds of
many is the much later appearance of adults of A. nubifera in the fall
of the year. The last large " hatching " of A. citri is on a rapid decline
at Orlando by the middle of September at the latest, while that of A.
nubifera at that time is only approaching its maximum and lasts well
toward the 1st of November, when its decline is rapid, although
adults can be found during moderately warm falls as late as the mid-
dle of December. Thus at Orlando in October 18, 1907, when adult

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Fig. 19. — Diagram showing relative abundance of the adults of Aleyrodes nubifera and A. citri,
throughout the year 1909, at Orlando, Fla. (Original.)

A. citri were practically off the wing and a large portion of the imma-
ture stages of A. citri had already reached the pupal stage, note was
made that adults of A. nubifera were appearing in numbers and that
pupa? of A. nubifera were rapidly developing eyespots on certain
growths, and that new growth in places was crowded with ovipositing
adults.

In consequence of the difference between the time of appearance
of these fall broods, the immature stages of A. citri have largely
reached the pupal stage and are prepared to winter over by the last
of October. At this time females of A. nubifera are crowding the
limited new growth with large numbers of eggs, and by far the larger
proportion of this species will be found in the egg and larval stages
up to the middle of December, and in a few instances third-instar
larvse may be found as late as the middle of February. It will be
seen, therefore, from this and the foregoing data that there is no
time during the season, except for about two months before spring
emergence first sets in, that all stages can not be found in the grove
in varying degrees of abundance.

INDEX.

Page.

Ailanthus glandulosa, reported food plant of Aleyrodes citri 29

Aleurodothripsfasciapennis, enemy of Aleyrodes citri 55

Aleyrodes aurantiv=Aleyrodes citri 10

citri 11-85

adult, description 65-67

duration of life with and without food 71

effect of weather conditions on activity 78

emergence 67-71

feeding habits 78-79

flight as means of spread 44-48

mating ". 71-72

oviposition 72-77

an orange pest 10

checks on successful establishments 43-44

distribution in foreign countries 27-28

United States 25-27

duration of adult life 71

egg, description 53-58

duration of stage 54-57

hatching 57-58

feeding habits of adults 78-79

larvae and pupae 65

flight of adults as means of spread 44-48

food plants 28-43

generations 81-84

growth 64

historical review 11-17

history, early, in United States 12-14

injury, extent 19-25

nature 17-19

to fruit 19-23

trees 23

killed by fungus parasite (red Aschersonia) 39

larval stages, description 58-60

duration 62

feeding habits 65

growth 64

locomotion 63

molts 64-65

life cycle, length..., 80-81

history and habits 51-86

literature 14-17

locomotion ot larval stages 63

losses, summary 23-24

mating 71-72

105

106 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

Page,

Aleyrodes citri, methods of study 52-53

molts 64

multiplication 1 79

occurrence 10

origin 11

opposition 72-77

parthenogenesis 57

proportion of sexes 77-78

pupa case, description 61

pupal stage, description 60-61

duration 63

feeding habits 65

restrictions upon multiplication due to various causes 79

seasonal fluctuations in the numbers oladults or "broods" 84-85

history 81-85

sexes, proportion 77-78

spread in United States 43-51

summary of life history and habits 51-52

fioccosa, occurrence, food plants 10

floridensis, occurrence, food plants 10

giffardi, an orange pest 10

occurrence, food plant 10

howardi, an orange pest 10

discovery in Florida 11

occurrence, food plant 10

marlatti, occurrence, food plant 10

mori arizonensis, occurrence, food plant 10

occurrence, food plant 10

nuUfera 86-103

adult, description and habits 98-100

an orange pest 10

distribution 89-90

duration of instars 96-97

egg 91-94

feeding habits of larvae and pupae 97

food plants 90

generations 101-102

growth 97

habits and life history 91-101

history 86-87

injury, amount 87-89

larval and pupal stages 94-98

stages, description 94-95

duration 96

feeding habits 97

locomotion 97

life cycle, length 100-101

history and habits 91-101

locomotion of larval stages 97

molts 97

mortality of larvae and pupae 97-98

occurrence, food plant 10

pupa case 95

INDEX. 107

Page.

Aleyrodes nubifera, pupa, description 95

pupal stage, duration 96-97

seasonal fluctuations in number of adults or ''broods". . . 102-103

history 101-103

spread 90-91

spinifera, occurrence, food plants 10

struthanthi, occurrence, food plants 10

vitrinellus, occurrence, possible food plant 10

Aleyrodidse. (See White flies.)

Allamanda, food plant of Aleyrodes citri 29, 43

neriifolia. (See Allamanda.)
Alligator pear. (See Persea gratissima.)

Aschersonia, red, fungus parasite of Aleyrodes citri in tangerines 39

Ash, green. (See Fraxinus lanceolata.)

prickly, food plant of Aleyrodes citri 29, 42

not a food plant of Aleyrodes nubifera 90

Banana shrub, food plant of Aleyrodes citri 29, 43

Bay. (See Laurus nobilis.)
Bays. (See Persea spp.)
Blackberry (see also Rubus spp.).

food plant of Aleyrodes citri 29

not a food plant of Aleyrodes nubifera , 90

Boats as means of spread of Aleyrodes citri 48-49

Camellia, food plant of Aleyrodes citri 30

Cape jessamine, occurrence of Aleyrodes citri thereon i. 26

Cherry laurel, food plant of Aleyrodes citri 29, 43

not a food plant of Aleyrodes nubifera 90

wild, not a food plant of Aleyrodes nubifera 90

China tree, food plant of Aleyrodes citri 29, 34-39

not a food plant of Aleyrodes nubifera 90

umbrella, food plant of Aleyrodes citri 29, 34-39

not a food plant of Aleyrodes nubifera 90

Citrus (see also Orange).

food plant of Aleyrodes citri 29

in Florida, injurious white flies 1-103

nursery stock as means of spread of Aleyrodes citri 49-50

relative susceptibility of species to injury by Aleyrodes citri 32-34

trifoliata, hedges, occurrence of Aleyrodes citri thereon 26

white flies that breed thereon throughout the world 10

fly. (See Aleyrodes citri.)
Coffea arabica. (See Coffee.)

Coffee, food plant of Aleyrodes citri 29, 43

Devilwood. (See Olive, wild.)
Diospyros kahi. (See Persimmon, Japanese.)
virginiana. (See Persimmon, wild.)

Encarsia variegata, parasite of Paraleyrodes persex 10

Ficus altissima, reported food plant of Aleyrodes citri 29

carica, cage test with Aleyrodes citri 30-31

macrophylla, reported food plant of Aleyrodes citri 29

nitida, food plant of Aleyrodes nubifera 10, 90

sp., reported food plant of Aleyrodes citri in Costa Rica 29

Fig, cultivated. (See Ficus carica.)

not food plant of Aleyrodes nubifera 90

108 WHITE FLIES INJURIOUS TO CITRUS IN FLORIDA.

Page.

Fraxinus lanceolata, food plant of Aleyrodes citri 29

Fungus parasite. (See Aschersonia, red.)
Gardenia jasminoides. (See Jessamine, Cape.)
Grapefruit. (See Citrus.)

Grape, not food plant of Aleyrodes nubifera 90

Guaiacum officinale, food plant of Aleyrodes floccosa 10

Gauva, food plant of Aleyrodes jloridensis 10

not food plant of Aleyrodes nubifera 90

Gauvas 31

Gum, sweet, food plant of Aleyrodes mori 10

Hedera helix, reported food plant of Aleyrodes citri 29

Honeysuckle, food plant of Aleyrodes citri 29

Humidity as affecting emergence of Aleyrodes citri 70-71

Ivy, English. (See Hedera helix.)

Jasminum odoratissimum, reported food plant of Aleyrodes citri 29, 39-40

Jessamine, cape, food plant of Aleyrodes citri 29, 39-40

not food plant of Aleyrodes nubifera 90

yellow. (See Jasminum odoratissimum.)
King of Siam. (See Citrus.)
Kumquat. (See Citrus.)
Laurel cherry. (See Prunus caroliniana.)

Laurus nobilis, reported food plant of Aleyrodes citri 29

Light as affecting emergence of Aleyrodes citri 71

Ligustrum spp. (See Privets.)

Lilac, food plant of Aleyrodes citri 29, 42

Loranthus (struthansus) flexicaulis, food plant of Aleyrodes struthanthi 10

Magnolia, cage test with Aleyrodes citri 30-31

not food plant of Aleyrodes nubifera 90

fcetida. (See Magnolia.)

fuscatum. (See Banana shrub.)

Man as agent in spread of Aleyrodes citri 50-51

Mandarin. (See Citrus.)

Melia azedarach. (See China tree.)

umbraculifera. (See China tree, umbrella.)
Meliola. (See Sooty mold.)

camellise. (See Sooty mold.)

Michelia flava, food plant of Aleyrodes struthanthi 10

Morus spp 31

Mulberry (see also Morus spp.).

food plant of Aleyrodes mori 10

Myrtle, crape. (See Myrtus lagerstrcemia.)

Myrtus lagerstrcemia, cage test with Aleyrodes citri 30-31

reported food plant of Aleyrodes citri 29

Oak (see also Quercus) .

water, reported plant food of Aleyrodes citri 29

Oaks 31

not food plants of Aleyrodes nubifera 90

Oleander, food plant of Aleyrodes citri 29

Olive, wild, food plant of Aleyrodes citri 29, 43

Orange, mock. (See Prunus caroliniana; see also Citrus.)

reported food plant of Aleyrodes vitrinellus 10

Ornamental plants as means of spread of Aleyrodes citri 49-50

Osmanthus americanus. (See Olive, wild.)

Palmetto, scrub, food plant of Aleyrodes citri 29

INDEX. 109

Page.

Paraleyrodes persese, host of Encarsia variegata 10

not likely to be injurious to orange 10

occurrence, food plant 10

Parasite, fungus, enemy of Aleyrodes citri. (See Aschersonia, red.)

Parthenogenesis as affecting proportion of sexes in Aleyrodes citri 77-78

in Aleyrodes citri 57

Pear, alligator. (See Per sea gratissima.)

cultivated, food plants of Aleyrodes citri 29, 43

Persea gratissima, food plant of Aleyrodes Jloridensis 10

spp 31

Persimmon, Japanese, food plant of Aleyrodes citri 29, 41-42

not food plant of Aleyrodes nubifera 90

wild, food plant of Aleyrodes citri 29, 41-42

not food plant of Aleyrodes nubifera 90

Pomegranate, food plant of Aleyrodes citri 29, 43

Prickly ash. (See Ash, prickly.)

Privets, food plants of Aleyrodes citri 26, 29, 40-41

not food plants of Aleyrodes nubifera 90

Prunus caroliniana, cage test with Aleyrodes citri 30-31

laurocerasus. (See Cherry laurel.)
Psidium gua.java. (See Guava.)

spp. (See Guavas.)
Punica granatum. (See Pomegranate.)
Pyrus spp. (See Pear, cultivated.)
Quercus (see also Oak).

brevifolia, cage test with Aleyrodes citri 30-31

Railroad trains as means of spread of Aleyrodes citri 48-49

Rearing cages for Aleyrodes citri 52-53

Rosa spp., food plants of Aleyrodes spinifera 10

Rubber tree. (See Ficus nitida.)

Rubus spp., cage tests with Aleyrodes citri 30-31

Satsuma. (See Citrus.)

Smilax, food plant of Aleyrodes citri 29, 43

Sooty mold resulting from work of Aleyrodes citri 17-19

Sweet gum. (See Gum, sweet.)
Syringa sp. (See Lilac.)
Tangerine. (See Citrus.)

Temperature as affecting emergence of Aleyrodes citri 68-70

Tree of Heaven. (See Ailanthus glandulosa.)
Umbrella China tree. (See China tree, umbrella.)

Vehicles as means of spread of Aleyrodes citri 48-49

Viburnum. (See Viburnum nudum.)

nudum, food plant of Aleyrodes citri 29 43

Weather as affecting activity of adults of Aleyrodes citri 78

White fly, citrus. (See Aleyrodes citri.)

cloudy- winged. (See Aleyrodes nubifera.)

investigations in Florida, commencement 9

woolly. (See Aleyrodus howardi.)

flies injurious to Citrus in Florida 1-103

species affecting Citrus throughout the world 10

Winds as means of spread of Aleyrodes citri 4g

Xanthoxylum clava-herculis. (See Ash, prickly.)

o

Entomology and Plant Quaran