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ILLINOIS BIOLOGICAL
MONOGRAPHS

VOLUME XII

PUBLISHED BY THE UNIVERSITY OF ILLINOIS

oy URBANA, ILLINOIS

EDITORIAL COMMITTEE

Joun THEODORE BUCHHOLZ
FRED WILBUR TANNER
CHARLES ZELENY, Chairman

ee 70, ‘ 2

at kine

Oa ee 0 CofA p=

TABLE OF CONTENTS

Nos. PAGES

1. Morphological Studies of the Genus Cercospora. By
RP SEHELMNERBREARD, SOLTIEIM 6 5c)6)c \ii5 sae yee si eialal sea etele 1

2. Morphology, Taxonomy, and Biology of Larval Scarabaeoidea.
EM ICLIAne .PATRIOR EAVES. 4 Noah x ibe e saloon fosae haces 85

3. Sawflies of the Sub-family Dolerinae of America North of

PPesico) wat HDRBERT 11. ROSS Wao iin io Nase Se le, eae 6 ove 205
4. A Study of Fresh-water Plankton Communities. By
MEL ODM i lees ste} es « EON. REET UALR ROME RNG a maar Ae Ne 321
CO As
af VU Ee a o

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=o > Tn eae hE i em .
fe : coe § aoe Se = a> > oD
ie as - —— 4 ~ To ? = he eS
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> A . ‘sh
a 9

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, eS
~~ ~ 7 ‘
: P -&

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a
LIBRARY ce
OF THE =f
5 UNIVERSITY OF ILLINOIS
‘ '
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be f “ ane 2 ’ i 7
a @ * oe 7
. Pa . = ee ares ¥
ee yg Oe ny

ILLINOIS BIOLOGICAL
MONOGRAPHS

Vol. XII April, 1929 No. 2

EDITORIAL COMMITTEE

STEPHEN ALFRED FORBES FRED WILBUR TANNER

HENRY BALDWIN WARD

PUBLISHED BY THE UNIVERSITY OF ILLINOIS
UNDER THE AUSPICES OF THE GRADUATE SCHOOL

DISTRIBUTED

June 18. 1930

MORPHOLOGY, TAXONOMY, AND
BIOLOGY OF LARVAL
SCARABAEOIDEA

WITH FIFTEEN PLATES

BY

WILLIAM PATRICK HAYES
Associate Professor of Entomology in the University of Illinois

Contribution No. 137 from the Entomological Laboratories of the
University of Illinois

sil haa ars wee aN:

Te saa
4
TABLE OF CONTENTS

I RARrerR a AA EN Nos AS iC Waa cb cake lates ln Ma WIIG Sa ayaen SR Mephei eae a8 7
Hcomomic importance... - 20.5.6. e eee eae seen tenet eee ences 8
Mem rm RN hoa 0 1 oe occ: Gemstone ese MRIS MRA SI ocasclns ciel aie hate: stayed 10
er eRe om. etc A va A ae Me sd Chaim A eho Orme Dew eerse BAe: 11
Biological and ecological literature... ...... 0-6-6... eee erent eee eee es 12
Materials and methods............2. cece cect eee eee e tence teense renee 13
PirlemawlCEOTACTES, 6 ss. es oe nee sais es sae ph eee ee rm e en de ee Rams eee: 15
MM Tae ice Ste vee Pur sas .c ae kangen Ons vam deans As sininss = vein sae Smee 16
The head and its appendages... .... 2.2... 0 eee eee eee eter ees 17
TEREST eee ee EE ere TP IE eee SoSTOTOMN te EME RSMte aT Ren ges cB aE SORES 18
lypewsiand labrum: 6... 1.5). ses sae eonlee s Sd ere reales nag cee oe 20
RABAT 5 ofc ooo 2, Sian toa nyse. tale woe aguas seins aie a ewer ee 22

Tea FST Ee oe eet EES are nus oo char om cnc 33
(SUT SE Seip aml leaner a ce! ie fie Teele bts i anit at A Rear irae eke SPP Ab 37

MEU ORNE YT ee ee Les es eS ee ties Oke ie a clear niga were rising anne 39

STEAD TUU TER eee rete UU ee Get BPR, BE re eM eete a, stet npedeh oe yedecees ten etiane amie: 40

Ora avid aADUOMEN s « -) sik 21. Leleteed alc nd aes Ste lala ah cus edhe woe ect satis Me ua alaee le 40
SemMENEREION,, 2). <1! 5:04, ¢ fas ao 80, 2 ee AU GEER RMON I Steer GMS cr ea ere Es ete 40
Say Ay Ta a Se i EG ROE SCR Cte APL tcc: Sots cet Sie Ghia Creation any 41

Tenet koi rig aie Sa Beir fe ee earn es i ee ep EAT Aap ake A aie iat ae cet otra 41

2 aise ieatyte Satay Qe dese ied ie ee Ra ce aie tra rence a Ee See EI 42

Sea ePT ESE Si hct ets Sgt tava Std as Marne one ches abel Sls sell vtoe, Semengttne Wisrees 43

PAAR T LATO ane hee es Lee i ie ot rhe Neral orcenals sek eR UR te eS yale 43

Dreans of, StrigtGlAtions...)... 5 ices iajaie pe cech we te mares eres sheen oe 44
Postembryonic development and biology of the Scarabaeidae............-.-.+-+-+:- 47
EL Fy RASA Aare Ae eee De tatecl tie aS car oan 47
Oviposition preferences... . 2.202 een et en ee oe ee 47
Description and length of egg stage........-. 20 -- eee e eee etree eens 48

Ege burster and hatching.............-----e 0s ese eeeee eet e eee e es 48

Beieued MevelOpMENE «5. yo a4 <2 seen lee on od (pe enim Pane tee ot 50
RR es ee eee eR ate cin im Sitnm g macldn beh heat hece opel eo Regehr aaa 50
Postembryonic changes............. 00.00 e cree eee eee eet eee ete eens 54

Mice PEELS ts SR EAI tiers at eae eae eae 54
Relative abundance...:....0....02 06022 ceg er eens beeen ee eee ee een ee 58

12 Bi bYoret Cte) 21 Soe ot nS Eo ARN a Teli ec non caeT cru NS ROPE OLE Ss oa Pu 61

eRe TARN Pos Nove ak ie eas s/h Goes aay ge Aad gee 68 Sake ae oa 63
Wate GE Ie yee: «0c ois. oe ie =) egaerine + og ae ies Sees Baa 64

0s Lay ETAT See eel eee el aoe emi nirtes uniter ies Inia aisle ccna ake 64

RARER UTIL Cee ee eae te PIS al oak ofalio. Seal ayaa ietngeysviestr se eh syeleieis ato 66

Barras areen tb Se es ee ie RAL, 5g Bel ea an 67
Geto Te ee Pe te ccs oo eNO eB en rely ue are aes toee peers Na eae 70
RMSE scot oo «hut Pinwistninattice his siorn? Biss? Pace an erat: eae Ree 71
TRE Cone eu ie NRE eR wire oa tect wane ear Nc 72
a a lg Sas ccd peak evans ln Os DSc BbeLE a Sean tence Bete AND eae ae 73
LAER RR se ee ne Be a tle eee eas eae fivce nie ne Nr atpneelanm pe sense 81
Pe cieitearacesd gy hd I st A A Fe ale sR Began oie 82
Bees AMMIEIONY DE PILE to ie hw = Ose he oa Fa os ee nay agile eee ie bn a 8 85

a 0 . . ; rd é a PKR foe i
CRA RoR * | nah” ot ad ee head Xi ca os ER tae ol iat
0 f : We tse cnet wg ;
‘ a ee a " eyitene TAA gigas a
Hex § ; ; a NS ;
Hist D Te: > er es
av! Patek: F ae i ; Fi
‘ x ~ e ch aE. é ¥, 8
r 4 ; . i
rs Ses yg a ae : 4 : ‘ ay y 3 Ae , ;
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tw)
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‘ Ahir Bein
“- pee thie “
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. ; ef i E eek ca : ¥. ; oe
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reat e) fi-ge
Kah 4 § Rae,
a secbalipsete 3

; | 4 3 : : ¥ ; 55 5 phe P eaieany se "i ,
Daas en Mort Rea tern wel es
+5 giovadt Peveraih

‘

91] LARVAL SCARABAEOIDEA—HAYES 7

INTRODUCTION

The larvae of the superfamily Scarabaeoidea are commonly called
white grubs or grubworms. Forbes, writing in 1891 on insects of this
group in relation to their life histories, said that “‘it is necessary that the
observer should learn to distinguish species of these insects in the grub and
larval stage.”” Among the numerous genera, the species of which are usually
more readily recognized in the adult form, there are many species that are
almost indistinguishable from one another in the larval stage. To identify
them it is usually necessary to rear the specimens. This requires a long
period of time and often involves dangers of loss from one cause or another
during the period of rearing. In a number of groups, especially in the sub-
family Melolonthinae, the life-cycle covers a period of from two to three
years, and in northern latitudes even four years. Sucha long larval stage
makes rearing difficult. Moreover, since the larval life is spent under the
surface of the soil, it is difficult to maintain rearing conditions as near nor-
mal as necessary. Not only do’ the representatives of the various sub-
families differ in length of life in various localities, but they may exhibit
wide degrees of variance even in the same localities.

Rapid strides have been made in our knowledge of the life histories
of these insects within the last twelve years (1917-29), and it is becoming
increasingly more important, as we survey the great differences exhibited,
that we be able to recognize the larval forms. As with all other groups
of insects, our knowledge of the developmental stages lags behind our
knowledge of the adults. This is especially true in the fields of morphology
and taxonomy and to a lesser extent in the field of biology. Prior to the
studies by Davis and others, which have materially increased our knowl-
edge of the group, most of our knowledge of the biology of these insects
has been based on fragmentary accounts scattered in the literature. The
present work deals with morphological, taxonomic, and biological studies of
the various species of white grubs. The morphological studies have aided
materially in constructing the diagnostic keys to the various genera which
are included. Life-history studies made by the writer, some of which have,
in part, appeared in different publications, are here brought together and
briefly summarized to make the present work as nearly a complete unit as
possible.

8 ILLINOIS BIOLOGICAL MONOGRAPHS ; [92

Economic IMPORTANCE

Of the four families, Passalidae, Lucanidae, Scarabaeidae, and Trogidae,
comprising the superfamily Scarabaeoidea (or Lamellicornia), the family
Scarabaeidae is the best known and most important. The others have only
slight economic importance.

The family Passalidae, which inhabits decaying wood, is represented
in tropical forests by numerous species but in North America by only
one species, Passalus cornutus Fab. Some species of this family are of
biological interest because of a certain degree of social organization ascribed
to them, the adults being known to attend the larvae and care for them
throughout their period of development to maturity. The adults chew the
woody food and prepare it before feeding it to the larvae. The hastening
of decay in rotten logs can be said to be a beneficial phase exhibited by this
group of insects.

The Lucanidae, or stag-beetles, exhibit wide sexual differences in the
adult stage. Their larvae, like the Passalidae, live in rotten logs or roots.
About 300 species of Lucanidae occur throughout the world, but only 30
species are recorded by Leng (1920) from North America. Aside from their
biological interest, the unique stridulation structures of the larvae and
the benefits incurred from the hastening of decay, the family can be con-
sidered of little importance.

The family Trogidae is one of our newer families, having recently
been raised to its present position from subfamily rank in the Scarabaeidae.
Of the genera occurring in North America, the genus Trox is the most
important. The larvae of Trox are scavengers and are usually found in
dried, decomposing, animal matter or on the soil under such matter.
Little is known of their life history.

The Scarabaeidae in the adult stages are known as chafers, May
beetles, June bugs, dung beetles, and dor beetles. They constitute a large
family with about 14,000 species known from all parts of the world. The
family is divided into two categories, or groups, the Laparosticti and the
Pleurosticti. The Laparosticti are, for the most part, coprophagous in
habits. The Coprinae, Aphodinae, and Geotrupinae are the better known
subfamilies with coprophagous habits. A few of the Coprinae are known to
be myrmecophilous and live as symphiles in the nests of ants. The copro-
phagus habit is, by far, the most important. The group Pleurosticti contains
a large number of important economic insects. These occur in four sub-
families: the Melolonthinae, the Rutelinae, the Dynastinae, and the
Cetoniinae. :

The larvae of the subfamilies here considered are recognized in many
parts of the world as pests of planted crops and are almost universally
known as ‘“‘white grubs.’’ One of the most notorious members of the group
is the European ‘‘Hanneton,’”’? Melolontha melolontha, which has been

93] LARVAL SCARABAEOIDEA—HAYES 9

known for over a century as a destructive enemy of the roots of crops.
It belongs to the subfamily Melolonthinae, to which our common American
species of May beetles, or June bugs, are assigned. Certain species of
Phyllophaga (Lachnosterna), both adults and larvae, are perhaps the
most destructive members of the family in North America, and their
injury is too well known to require extended discussion.

In some of the states west of the Mississippi the greatest loss from
white grubs occurs where the larvae of P. lanceolata (Say) attack the
roots of wheat and often destroy thousands of acres in a single season.
Considering the country as a whole, most of the principal crops as well
as native prairie pastures, meadows, and lawns have suffered injury from
various species. In some localities gardens suffer. Potatoes especially
have paid a heavy toll in the last few years. Strawberry beds have been
the object of regular attacks, and ornamentals of all kinds, particularly
those recently set out, have been seriously damaged. Many lawns have been
killed by the grubs, and serious loss has occurred in the bluegrass pastures.
According to Davis (1918), alfalfa is usually considered free from injury,
but it has been found damaged in a number of localities. In attacking this
crop, the grub enters the tap-root an inch or two below the surface of the
soil, excavates a cavity, and burrows upward and downward in much the
same manner as some of the root-boring insects.

- Among the Rutelinae, two species, Pelidnota punctata L. and Cotalpa
lanigera (L.) are notably injurious in the United States. The damage caused
by the spotted grapeleaf beetle, Pelidnota punctata, to the foliage of grapes
during some years attracts considerable attention, but the larvae, living
in rotten wood, such as logs and old stumps, can be regarded as beneficial
because their activities in these situations hasten decay. The goldsmith
beetle, Cotalpa lanigera, has been reported by Davis (1916) as ranking
next in importance to the species of Phyllophaga. He says that the grubs
in Michigan are destructive to raspberry bushes, strawberries, corn, and
grass. Other native species of Rutelinae treated here are not of so much
economic importance, but Anomala innuba at times becomes numerous.
The beetles of this species do some damage to the kernels of growing wheat,
which they attack while ‘in the milk,’ and the grubs feed on the roots of
various plants. Two important imported members of this subfamily are the
Japanese beetle, Popillia japonica Newm., and the Asiatic beetle, Anomala
orientalis (Waterhouse). :

Among the representatives of the Dynastinae dealt with herein,
Ligyrodes relictus Say is not known to be a crop pest, but a near relative,
Ligyrus gibbosus DeGeer, is an important enemy of carrots and domesti-
cated sunflower crops, and is known as the carrot beetle.

The best known American species of the Cetoniinae are the bumble
flower beetle, Euphoria inda L., and the green June beetle, also called the

10 ILLINOIS BIOLOGICAL MONOGRAPHS [94

fig eater, Cotinis (Allorhina) nitida L. The bumble flower beetle is a some-
what general feeder, being found upon flowers, eating the pollen, and upon
corn stalks where it feeds on the green cob by sucking the juices. It also
occurs on peaches, grapes, and apples, and occasionally its injury becomes
serious. The larva is not known to cause damage. The green June beetle,
on the other hand, is a pest in the grub stage, feeding upon the roots of
grasses and often doing immense damage to tobacco plantings, lawns, and
golf courses (Chittenden and Fink, 1922). Two species of Euphoria,
E. sepulchralis Fab. and E. fulgida Fab., are neither of great importance
economically. They feed in the adult stage on the pollen and nectar of
flowers. The beetles of E. sepulchralis feed on the tips of ears of corn,
making way for further injury by the green June beetle, Cotinis nitida.
The species of Osmoderma pass their developmental periods in decaying
wood, as do also the larvae of Trichiotinus (Trichius), and are only of
minor significance.
HISTORICAL REVIEW

Some members of the families Scarabaeidae and Lucanidae have been
known from ancient times. The Romans frequently hung the mandibles of
Lucanus on the necks of children or wore them in the form of armulets to
ward off disease. In Germany, Lucanus was known as the “‘fire-starter”’
because it was said to carry live coals into houses with its pinchers, thereby
starting conflagrations. The people would often cooperate in their efforts
to drive them away. The sacred beetle of Egypt has made the family
Scarabaeidae renowned, and many interesting tales and superstitions have
been connected with it. These myths and legends are too numerous to be
discussed here and, except for historical value, are irrelevant in a work of
this nature.

The meaning and origin of the word Scarabaeus is clouded in doubt
and uncertainty. Papis, a grammarian of the eleventh century, says the
word comes from cabus or caballus, meaning horse, because the insects
according to the ideas of the times were thought to be born from the
cadaver of a horse. Bochart derives the word from chaphas, which signifies
an excavator, in view of the characteristic action of coprophagous species.
Fabricius derives it from the Greek ¢o dig, and MacLeay from the Greek
to scratch or scrape. Mulsant, Martini, and others accept Aristotle’s
interpretation, which derives it from a Greek word signifying an insect that
is unknown to us.

The first splitting of the group, as defined by Linnaeus, occurred when
Scopoli (1763) separated the genus Lucanus from Scarabaeus. Fabricius,
Olivier, and others followed with many new genera, until ultimately the
two groups represented by Scarabaeus and Lucanus were elevated to family
rank under the superordinal appellation Lamellicornia, a term which was
first used either by Lamark (1817) or Latreille (1817). According to

95] LARVAL SCARABAEOIDEA—HAYES 11

Burmeister, it is not known which of the two was the originator of the term,
but it is generally attributed to Latreille, to whom is also credited the origin
of our modern conception of the family group. The termination -idae was
for the first time generalized in entomology by MacLeay in 1819. Leng
(1920) in his recent check list of North American Coleoptera considers the
Lamellicornia under the superorder Scarabaeoidea, recognizing three
families, Scarabaeidae, Lucanidae, and Passalidae. The recent supplement
to Leng’s list, by Leng and Mutchler (1927), considers the subfamily
Troginae as of family rank, so that as now constituted there are four
recognized North American families, namely, Scarabaeidae, Lucanidae,
Passalidae, and Trogidae.

There have been several European attempts to work out the classifica-
tion of larval stages of the Scarabaeoidea. The anatomical descriptions of
individual species are fairly numerous in scattered foreign works, but the
problem in America has been given little attention. Until recently there has
been no attempt at a general classification, and isolated descriptions are
scarce and in many instances inadequate.

TAXONOMIC LITERATURE

A study of the distinguishing characters of American lamellicorn
larvae has been a long-felt need. Moreover, their economic importance
makes such a study of extreme value. It is highly desirous to be able to
recognize the different genera at least, and, when possible, the species
belonging to the genera. Forbes (1894) in his Eighteenth Report (p. 97)
stated that ‘‘life-histories are not sufficiently different to make discrim-
ination of species a matter of practical importance, and for economic pur-
poses, consequently, the white. grubs may usually be classed as one.”” A
little later in the same report (footnote, p. 105), in speaking of the verifi-
cation of life-histories, he says “‘it is necessary that the observer should
learn to distinguish species or at least groups of species of these insects in
the grub and larval stage.’”” Forbes then pointed out differences between
Ochrosidia (Cyclocephala) and Phyllophaga (Lachnosterna) grubs. The
latter genus was divided into three groups: the hirticula-rugosa, fusca-
inversa, and gibbosa (now futilis) group. Except for the work of Forbes and
scattered isolated descriptions, no attempt was made in this country to
characterize the various groups of the family until Boving (1921) published
a short key dealing with several allied genera of the green Japanese beetle
(Popillia japonica), which is based in part on the work of Schiddte (1874).
This generic key indicated the distinguishing characters of one European
and five American genera. .

In contrast to the work done in America on this group, a number
of European papers are available which, although dealing with but few
genera occurring in this country, are of value in a study of this nature.

12 ILLINOIS BIOLOGICAL MONOGRAPHS . [96

Chapuis and Candeze (1855, p. 452) noted that the habits and metamor-
phosis of no group of European beetle larvae were as well known as the
lamellicorns. The first to attempt a classification of these larvae was
DeHaan (1836), who used both external and internal characters to dis-
tinguish eight genera. DeHann made use of the malpighian tubules, and
in his work the drawings of the alimentary canal are especially good. The
next attempt at classification was made by Mulsant (1842), who compiled a
key based on external characters alone. The same year (1842) Burmeister
published in a large measure the groupings of DeHann. Erichson (1848)
presented a study of the group and used an arrangement of the families,
which we now recognize as subfamilies. Erichson’s key is also found in the
catalogue of coleopterous larvae in which Chapuis and Candeze in 1855
brought together the references to descriptions of larvae known at that
time. Schiddte’s classical work on the larvae of Coleoptera appeared in
1874 in several parts, of which Part VIII deals with the lamellicorn larvae.
The drawings in this work are indeed excellent. Three years later Perris
(1877) published his well-known work which contains the most complete
key to genera that we have. He added many new descriptions of lamellicorn
larvae. Recently Ritterschaus (1927) has described somewhat completely
the morphological details of Anomala aenea Geer and Phyllopertha horticola
L. This work is perhaps the first to give any detailed consideration to the
epipharynx of white grubs. More will be said concerning this work later.
A recent paper by the writer (1928) on the epipharynx of the larvae contains
a preliminary generic key, including a few species, based in great part n
characters of the epipharynx. This key with corrections, additions, and
emendations is used in the present work as a basis of generic distinction.

BIOLOGICAL AND ECOLOGICAL LITERATURE

In America the life-cycles of the Lucanidae and Passalidae are little
known and not thoroughly worked out. The Trogidae are as yet untouched.
The economic species of the Scarabaeidae have, in recent years, become
better known, although scarcely anything has been done on the copropha-
gous forms. Previous to 1916, our knowledge of the life-cycles of the
American species of Phyllophaga was confined to the work of Chittenden
(1899) who reared a single specimen of P. fervida (arcuata) and to those of
Davis (1913) who reported a two-year life-cycle for P. tristis. In 1916,
Davis discussed the length of life of 18 species of the genus, but did not
determine the length of the various stages. This work is of great importance
to our knowledge of the group. Smyth (1917) published the results of life-
history studies of certain Porto Rican species of Phyllophaga, in which
our first account is available concerning the length of the various instars.

The writer has from time to time published life-history studies of various
species of the family. The life-cycle of P. lanceolata was noted as having a

97] LARVAL SCARABAEOIDEA—HAYES 13

two-year period of development with quite varied habits from the majority
of species of Phyllophaga. In another paper (1920) seven species, futzlis,
rubiginosa, vehemens, crassissima, rugosa, implicata, and submucida of the
same genus were reported as having a two-year or a three-year life-cycle.
This was followed by a more comprehensive report (1925) of the studies
made on ten other species of Phyllophaga and some other members of the
family belonging to different subfamilies. Along with these were recorded
data on the development of three species of Rutelinae, one Dynastinae,
and two Cetoniinae. In the present work these studies will be brought to-
gether for the purpose of comparison.

In the subfamily Rutelinae the species of the tribe Anomalini require
one year for completion of their life-cycle. Anomala binotata and A. innuba
were found by the writer (1918 and 1925) to have a one-year period. The
same time is required for Strigoderma arboricola (Hayes, 1921). The
Oriental Anomala and the Japanese beetle are likewise known to have a
one-year life-cycle. In the tribe Rutelini, of the subfamily Rutelinae, the
life-history is longer. It has been shown (Hayes, 1925) that Pelidnota
punctata requires two years to mature and Cotalpa lanigera needs either
two or three years.

All-the species of the Dynastinae so far studied by the writer and by
others require but a single year to develop, with the exception of Strategus
quadrifoviatus (Smyth, 1916) which requires more than one year but
considerably less than two years. The species of the subfamily Cetoniinae,
as far as known, usually occupy one year in the completion of growth.
Cotinus nitida requires one year (Chittenden and Fink, 1922) while the
writer (1925) recorded the same length of life for Euphoria fulgida and E.
sepulchralis.

MATERIALS AND METHODS

The methods of study for the data herein reported are of two distinct
types, biological and morphological. The biological end of the problem
demanded rearing methods which enabled the handling of the immature
stages over a long period of time; while the morphological studies, made
primarily for taxonomic results, required the collection and preservation of
definitely known larvae and some slight laboratory technique.

On account of their subterranean habits and long period of develop-
ment, white grubs are difficult to rear to the adult stage. The difficulty
arises not only from their prolonged life-cycle, but also because of the many
parasitic fungi and other diseases attacking the grubs while being reared
under artificial conditions. In order to be sure of having some specimens
mature, it was necessary to handle large numbers of eggs and larvae;
and in order to study molting, it was necessary to keep them isolated.
Davis (1915) and Smyth (1917) have devised methods of rearing white
grubs and May beetles, and suggestions of these two writers were fol-

14 ILLINOIS BIOLOGICAL MONOGRAPHS [98

lowed in this work. These methods with some others are here briefly
summarized.

To procure eggs it was only necessary to confine the beetles over a
few inches of damp, well-packed soil. Any sort of cage could be used, but
most of them were one-gallon tins, half-filled with moist earth, the tops
being perforated. The leaves of various trees were frequently supplied for
food by merely placing them on the surface of the soil. The earth was sifted
or carefully gone over for eggs every second day. It was found that disturb-
ing the soil every day produced a tendency for the beetles to lay fewer eggs.
The eggs were transferred to individual cavities in closely packed, damp-
ened soil in one-ounce or two-once tin salve boxes, where they were kept
until hatched. From 25 to 50 eggs can be cared for in each box in this
manner. Upon hatching, each grub was placed in a one-once salve box
where it was kept until it matured or died. These salve boxes, at times
numbering over 5,000, were kept in the rearing cave described by McCol-
loch (1917) in which there was a nearly constant temperature, and thus the
grubs were not subjected to the daily fluctuations of temperature in the
outdoor insectary. The grubs were examined, with the aid of student
assistants, twice a week during the warmer parts of the year, once a week
in spring and autumn, and once a month during the winter months, and at
each examination the soil was changed and new food (generally a few
grains of wheat, which soon germinated) was added, except in the winter
when the food was omitted. When a grub reached the prepupal stage, the
soil in the box was tightly packed and the grub placed in a depression to
simulate a pupal cell. These prepupae were then isolated from the others
and examined daily to obtain the dates of pupation and maturity.

All of the species whose life histories are herein discussed were thus
handled with the exception of Pelidnota punctata, whose habit of living
in rotten logs during the larval stage made some changes in the above
procedure necessary. This species, the most difficult of any to rear, failed
to thrive in individual salve boxes in which rotting pieces of wood were
substituted for the grains of wheat. Only one specimen was thus reared.
Other specimens, however, were reared in decaying wood placed in one-
gallon tins and left undisturbed. This method does not permit the making of
observations to determine the molting periods.

One other slight deviation from the general method of rearing was
necessary in the case of Ligyrodes relictus and the Euphoria grubs whose
larval stage is passed in manure and other decaying vegetable matter.
In these cages, instead of feeding wheat grains to the grubs, which, how-
ever, they will eat, the soil in which they were placed was made more to
their liking by adding to it an equal amount of dried manure.

The material for morphological and taxonomic work was obtained in
great part during the course of life-history studies carried on by the writer.

99] LARVAL SCARABAEOIDEA—HAYES 15

The majority of the specimens were reared from eggs laid by definitely
determined beetles. However, certain species which can be distinguished
by their habits or the habitat in which they live were studied when their
identity was certain. As an example, large grubs found in rotting hay-
stacks can be determined with comparative surety as Ligyrodes relictus
(Say), and other instances could be cited. The molted exuviae of reared
grubs were preserved and have proved quite helpful in this study. They
possess the advantage of having all the chitinous parts of the mouthparts
intact without the presence of muscles and tissues, and this dispenses with
necessity of putting them through a clearing process. The molted exuviae
are transparent and readily studied and dissected under the miscroscope.

ACKNOWLEDGMENTS

The collections of the Illinois State Natural History Survey have been
used freely through the courtesy of Dr. T. H. Frison, and quite recently
the collections of Prof. J. J. Davis, now the property of the U. S. National
Museum, have been received for study through the courtesy of Professor
Davis, Dr. Adam G. Boying, and Mr. S. A. Rohwer. The latter collections
consist mainly of a large number of reared species of Phyllophaga but in-
clude also some other genera, three or four of which were not in the writer’s
collections. Most of the drawings were made by one of my students, Mr.
Carl Mohr, through the aid of a grant from the Graduate School of the
University of Illinois.

Besides acknowledging indebtedness to the aforementioned persons
who have rendered aid in this work, the writer desires to express his grati-
tude to the officials of the Kansas Agricultural Experiment Station, espe-
cially to Professors J. W. McColloch and George A. Dean, under whose
direction the life-history studies were carried out.

16 ILLINOIS BIOLOGICAL MONOGRAPHS [100

MORPHOLOGY

The following descriptions of larvae were made in most instances
from reared specimens concerning whose identification there is no doubt.
A few species were studied which are readily recognizable by their habitus,
habitats, or habits, and were not reared because there is reasonable
certainty of their correct identification.

The external anatomy of American species of white grubs has been
given but slight consideration. Few complete or detailed descriptions of the
morphological features are available. With the exception of a few widely
scattered descriptions of some known larvae, little has been done. The
writer recently (1927) presented somewhat detailed morphological des-
criptions and figures of the immature stages of Anomala kansana H. and
McC. Boving’s work (1921) on the Japanese beetle has already been
mentioned, but nowhere have any comprehensive comparisons been made
of American species. Grandi (1925) has presented comparisons of three
Italian species. Reference has been previously made to European works on
scarabaeid larvae.

The larvae of the Scarabaeoidea (Fig. 1 to 12) are quite similar to one
another but easily distinguished from other beetle larvae. The body is
elongated, subcylindrical, and in most cases normally bent in the form of a
letter C. From this shape is derived the term “‘scarabaeiform”’ used to
describe this type of larva. The body in many species is nearly constant in
diameter from the anterior to the caudal end. In the Cetoniinae (Fig. 11)
the caudal end is frequently enlarged, while in many Rutelinae (Fig. 8) it is
tapering. The body is distinctly differentiated into a well-formed head and
a series of twelve segments making up the thorax and abdomen. The three
segments of the thorax bear three pairs of well-formed legs, except in
Passalus (Fig. 3) which has but two well-developed pairs. The legs are not
as important organs in locomotion as they are in digging. In some Cetoni-
inae the legs are not used at all for walking. Such species crawl upon their
back by the aid of body contractions, in which they are assisted by the
erect setae with which the body segments are provided. When placed
upon their feet, these larvae invariably turn over on their backs in order
to move themselves along. The head is more heavily chitinized than the
rest of the body, which is paler in color, and the integument is somewhat
transparent. The body segments are usually divided into a series of deep
folds forming subsegments or annulets. There are usually three sub-
segments in most of the segments, although in a few species they are in-
distinct or lacking. The segments in the Lucanidae are less conspicuously
subdivided, and in Passalus there are no annulets present.

101] LARVAL SCARABAEOIDEA—HAYES 17

The general body form of some of the coprophagous beetles is distinctly
“hump-backed” in outline. This is seen in such genera as Canthon,
Copris, Pinotus (Fig. 1), and Onthophagus (Fig. 4). Such species usually
develop in balls or packs of manure formed by the parents at the time of
oviposition.

THE HEAD AND ITS APPENDAGES

The head (Fig. 13 to 24) is hypognathous, that is, situated at right
angles to the long axis of the body and with the mouthparts directed
ventrad. It is more strongly chitinized than the remainder of the body and
varies considerably in color with the various species, ranging from light-
yellow or tan in some through all degrees of brown almost to black.
The Rutelinae and Melolonthinae contain some of the lighter forms;
while the Dynastinae, as represented by Xyloryctes, have darker heads.
The general form is convex or subglobose (Fig. 13 e¢ al) and usually sym-
metrical, although some species (Fig. 23) are decidedly asymmetrical.

The head capsules of Phyllophaga crassissima (Fig. 16), Ligyrus
gibbosus (Fig. 19), Cotalpa lanigera (Fig. 20), Euphoria inda (Fig. 21),
and Canthon laevis (Fig. 13) are typical representatives of five separate
subfamilies of the Scarabaeidae. In general, they bear a striking resem-
blance to each other. In color, they vary from a light to a dark tan almost
brownish. The size of the head is variable, depending of course upon the
instar of the grub and also the species concerned. It has been suggested that
the relative size of the head capsule, being thought constant in the various
instars, would be of value in distinguishing the different species; but
careful observation shows a gradual increase in size between molts.

The cephalic aspect of all species presents the same general gross
features, in which is evident the epicranial suture (Fig. 13 es) dividing the
epicranium, or vertex, and bounding with its branching arms (ea) the
lateral margins of the front, or frons (f). Between the arms of the epicranial
suture, on the frons, in Canthon laevis (Fig. 13), Euphoria inda (Fig. 21),
and others, is an extended Y-shaped depression resembling a second
epicranial suture and setting off an area quite similar to the adfrontal area
found in some lepidopterous larvae. This impression may be a secondary
suture. If this condition is an extension of the true suture, it is so closely
fused that in £. inda there is scarcely any trace of it on the inner surface,
while in C. laevis the inner surface presents a decided ridge, or carina,
which does not extend into the arms. The epicranial suture splits at the
time of molting and usually the split is continued into the arms of the Y.
In C. laevis, however, the split does not extend into the arms, reaching only
to the point of branching. In C. Jaevis and in E. inda there is a tendency
for splitting in the secondary Y. An examination of E£. inda alone would
lead to the conclusion that the secondary Y is merely a depression in the
front; but if C. Jaevis is the more primitive of the two, the presence of

18 ILLINOIS BIOLOGICAL MONOGRAPHS [102

the carina may indicate that a suture is disappearing during special-
ization.

Coincidentally, these two species present a series of four rounded de-
pressions, two on the front and two on the vertex near the arms of the
epicranial sutures. At first these suggest remnants of ocelli. In the
genera Trichiotinus and Strategus in which ocelli do occur, they are
located near the base of the antennae and seem to have no relation to the
depressions in Canthon and Euphoria. The two depressions on the front
are perhaps the external evidence of the points of attachment of the
dorsal arms of the tentorium.

The clypeus (Fig. 13 clp) adjoining the front is trapezoidal in shape
and to it is attached the flap-like labrum (/ab) with its laterally rounded
sides. Laterad of the clypeus and labrum are the prominent mandibles
(md). The antennae (ant) are the only segmented appendages evident
on the cephalic aspect, except in Canthon laevis where the maxillae may
protrude from under the mandibles and thus expose the maxillary palpi.
In no case are the labial palpi discernible from this view.

In a caudal view (Fig. 92, 93) with the head removed from the thorax
the relatively large occipital foramen (of) is seen to be bounded by the
fused areas of the postgenae and occiput. Surrounding the foramen is a
slight ridge, represented in the drawings by the dotted lines, to which is
attached the cervical membrane. The labium is divided into three regions.
The submentum (sm) is the basal, or proximal, sclerite to which is joined
distally the mentum (m), and in turn the stipula (st) joins the mentum.
The maxillae (mx) lie laterad of the mentum, and under the maxillae lie
the mandibles (md).

The heads of the species of the other three families of the super-family—
Lucanidae (Fig. 23), Passalidae (Fig. 24), and Trogidae (Fig. 22)—present
no striking differences from those of the Scarabaeidae just described.
There is a greater tendency for the head to be asymmetrical which is quite
pronounced in the head of Sinodendron (Fig. 23) and less so in Trox (Fig.
22). The head of Passalus (Fig. 24) is more like the Scarabaeidae in being
nearly symmetrical but is somewhat broader in proportion to its height.

In all species, the head is the most heavily chitinized area of the body.
The surface is frequently smooth and impunctate, in other species it is
rugose or rugulose. A few setae may be noted. There are frequently four
rather conspicuous setae on the clypeus.

ANTENNAE

Three pairs of segmented head appendages are evident from the caudal
aspect, the antennae, maxillary palpi and labial palpi. The number of
antennal segments has been a matter of discussion. The proximal seg-

103] LARVAL SCARABAEOIDEA—HAYES 19

ment in nearly all species is fused to the head and not articulate. Some
writers disregard it as a segment while others count it as a true division
of the appendage. Osten-Sacken (1874) in speaking of the antenna of
Pleocoma says it is ‘‘three-segmented”’ and does not consider the basal,
or fused, region which he termed the “‘scapus.”’ Schiddte (1874) also dis-
regards it and considers it a “‘palpiger.’’ Later workers have called it a
separate segment, and in this study it will be considered as the first anten-
nal or basal segment. The view of Perris (1877, pp. 93-94) on the number
of antennal segments is presented below:

D’apres Erichson et les savants naturalistes de Lyon, ces organes seraient composés de
trois 4 cinq articles, le premier n’etant pour eux qu’une saillie tuberculeuse qui simule un
article. Je ne puis me ranger 4 cette opinion. Je ne prétends pas dire qu’elle constitue une
appréciation erronée de la structure des antennes, mais comme cette saillie tuberculeuse existe
dans toutes les larves, que si, par suite de sa retractilité ou autrement, elle laisse quelquefois
place au doute, elle présente habituellement la physionomie d’un véritable article; comme aussi
la plupart des auteurs, y compris les entomologistes éminents que je viens de citer, lui ont le
plus souvent donneé ce caractére dans leurs descriptions, je crois qu’il faut le lui maintenir
sous peine d’avoir 4 rectifier presque tout ce qui a été dit jusqu’ici sur les antennes. Je ferai
remarquer en outre que, sicet article basilaire devait éntre retranché, il serait inexact de dire
que les antennes des larves de Lamellicornes ont de trois 4 cinq articles, car alors il y aurait
des larves qui, avec l’article basilaire, en auraient six, ce que je n’ai jamais vu.

In most subfamilies of the Scarabaeidae, the antennae are five-seg-
mented (Fig. 95, 96). The first, or basal, segment being short and conical,
the second, third, and fourth are much longer than the first and vary
somewhat in size with the different species. The fourth segment at its
distal end is frequently extended into a more or less acute or obtuse pro-
cess (Fig. 95). The fifth segment is usually shorter than the penultimate.
In some species it is of fair size and tapers to a point or else ends bluntly.
In many of the coprophagous species the last segment is greatly reduced
in size and appears almost like a small papilla (Fig. 13) on the end of the
fourth segment. Frequently, large sensory pits are evident in the fifth
segment. These vary in number in different species in which they occur.

Among some of the coprophagous species of Scarabaeidae, in the Trogi-
dae, and in some Lucanidae, there are but four antennal segments, and in
most instances of this sort the terminal segment is small and papilla-like.
The antennae of Passalus cornutus (Fig. 94) in the Passalidae are but three-
segmented. The proximal segment is short but greatly widened, being
several times wider than long, or about equal in width to the length of
the third segment. The second segment is less widened, somewhat longer,
and somewhat conical in shape. The third or distal segment is two or
three times longer than wide and somewhat pointed. The composite
form of all three segments presents the appearance of a rather uniform
cone.

20 , ILLINOIS BIOLOGICAL MONOGRAPHS [104

CLYPEUS AND LABRUM

The clypeus presents little that is striking in variation in the different
species. It is usually somewhat trapezoidal or subrectangular in outline,
and frequently its lateral margins are slightly emarginate, while the proxi-
mal and distal margins are usually subparallel. It is much wider than long,
and in many species the distal half is less heavily chitinized, with a some-
what sharp line of demarkation, presenting the appearance of a clypeal
suture, thus dividing the structure into a preclypeus (Fig. 18, pc) and a
postclypeus (Fig. 18, psc).

In Canthon laevis Drury (Fig. 13) the clypeus (clp) is about twice as
wide as it is long, the anterior and posterior margins are subparallel, and
the lateral margins are emarginate and converge slightly distally. The
labrum (Jab) is rounded on the sides, and the anterior margin is distinctive,
certain subfamilies having a double emargination that causes the median
lobe to appear quite prominent. In none of the forms observed is the
labrum exactly symmetrical.

A study of Canthon ebenus Say indicates its similarity to C. laevis.
The clypeus and labrum are quite similar, having as their most conspicuous
feature the biémarginate labrum. Onthophagus pennsylvanicus Harold
has the same general features of the clypeus and labrum with the biémar-
ginate anterior margin and prominent median lobe. Perris (1877, pl. 3)
figured Copris lunaris L. with a labrum of this type, while Osten-Sacken
(1862) figured Pinotus (Copris) carolina (L.) with an excision in the prom-
inent median lobe. In a study of P. carolina specimens before the writer,
this excision of the median lobe is not present (Fig. 90, 127). The margin
is biémarginate with a conspicuous median lobe showing no excision as in
Osten-Sacken’s drawing.

The labrum in the species of Aphodius studied—probably A. fimetarius
(L.)—is biémarginate, asymmetrical, and trilobed (Fig. 14). It is nearly as
long as wide. Schiddte (1874) has figured the labrum of A phodius rufipes
(L.) which is quite similar. Both resemble the form of the labrum in
Canthon.

Phyllophaga crassissima (Blanch.) (Fig. 16) has the clypeus of somewhat
the same general shape as Canthon laevis. It is trapezoidal in form with the
lateral sides less deeply emarginate. The labrum lacks the lobes on the
anterior margin and is somewhat pointed. It is as long as broad and
circular in outline. The anterior margin is slightly crenate. Phyllophaga
lanceolata (Say) has much the same general form of clypeus and labrum
with no apparent external difference.

An undetermined species of Diplotaxis has the clypeus and labrum
about twice as broad as the length of either single part. In order words,
the combined length of clypeus and labrum is equal to their breadth. The
clypeus is trapezoidal in shape, and the labrum is broadly oval. Schiddte

105] LARVAL SCARABAEOIDEA—HAYES 21

(1874) figures the clypeus and labrum of Rhizotrogus fallenit Gyll. and
Serica brunnea L. with a somewhat different form, especially in the shape
of the clypeus. The same is true of his figure of Melolontha vulgaris Fab.

The clypeus of Cotalpa lanigera (Fig. 20) is nearly three times as broad
as long. The anterior and posterior margins are parallel, while the lateral
margins are deeply emarginate and converge posteriorly. The labrum is
almost as long as broad, subcircular in outline, but not as pointed anteriorly
as in Phyllophaga. Both sclerites are larger than in most species. There is
a striking resemblance in these sclerites to Polymoechus brevipes Lec.
except for a proportionately smaller size and the absence of the deep
emarginations on the lateral margins of the clypeus.

Anomala binotata Gyll. and A. kansana (Fig. 18) have a clypeus with-
out lateral emarginations. It is twice as broad as long. The labrum is
slightly broader than long, and the sides converge to a somewhat pointed
margin. This point is not as sharp as in Phyllophaga. Schiddte figured
Anomala aenea De Geer (Euchlora frischii Fab.) which also has the clypeus
without the lateral emarginations and the labrum of the same shape as in
A. binotata but with a more deeply rugose surface.

The clypeus and labrum of Ligyrus gibbosus De Geer (Fig. 19) is pro-
portionately larger than in Phyllophaga, but smaller than Cotalpa lani-
gera, the increase in size over Phyllophaga being expressed in width.
The clypeus is trapezoidal, and the labrum is broader and more of an oval
than in either C. lanigera or P. crassissima.

In Ligyrodes relictus Say both the clypeus and labrum are much broader
than long and proportionately larger. The labrum is the most broadly
ovate of any of the forms observed. The broad condition of the labrum
holds for Ochrosidia immaculata (Oliv.) and the anterior margin is notice-
ably crenate. In comparison with the species of Ligyrus the labrum is
much longer proportionately. There are no important differences in the
clypeus.

The clypeus of Euphoria inda (Fig. 21) does not converge anteriorly as
in the other subfamilies, the whole being nearly a parallelogram with
rounded corners. It is twice as broad as long. The labrum has about the
same proportions, being broadly ovate with two anterior emarginations
producing a small median lobe as in the Coprinae but not so prominent.
Euphoria sepulchralis has the clypeus of the same rectangular shape and
has double anterior margins on the labrum, but is somewhat smaller than
E. inda, The same characteristics of clypeus and labrum are also found
in Stephanucha pilipennis K., a rare species of Scarabaeidae that occurs
only in Kansas. All of the Cetoniinae noted are more nearly symmetrical
than other species studied.

The clypeus of Trox sp. (Fig. 22) is unique in being limited proximally by
a conspicuously arched fronto-clypeal suture. It is divided into a precly-

22 ILLINOIS BIOLOGICAL MONOGRAPHS [106

peus and postclypeus as in the Scarabaeidae, but with the preclypeus some-
what less heavily chitinized. The labrum is very similar in form to that of
the Coprinae.

In the Lucanidae as represented by Sinodendron rugosum Mann. the
general form of both the clypeus and labrum approaches that of the Cetoni-
inae in being more nearly symmetrical. No noticeable emargination is
present, but the whole is decidedly crenate, and the median lobe is lacking.
The clypeus of Passalus cornutus Fab. (Fig. 24) is nearly twice as wide as
long, and subrectangular. The labrum is subovate with a prominent median
lobe on the anterior margin, in this respect resembling that of the Trogidae
and the Coprinae.

EPIPHARYNX

The epipharynx, although an internal structure, is one that is easily
accessible and can be examined without injury to the specimen by merely
inserting a needle under the labrum and raising it up. It can also be studied
in living larvae without any apparent harm being done to the individual.
The characters of the epipharynx have not been given detailed considera-
tion by previous workers. Schiddte (1874) figured the epipharynx of
Geotrupes, and his drawing of this genus is copied here (Fig. 58). Béving
(1921) has figured and briefly described the epipharynx of Popillia japonica
Newm. Neither of these writers has attempted to name the various parts.
A German worker (Ritterschaus, 1927) has described in some detail the
epipharynx of Anomala aenea De Geer and Phyliopertha horticola L. She
is the first to assign names to some of the various parts. Her terms will be
mentioned later. The writer (1928) attempted to show the value of the
epipharynx as an aid in the discrimination of the various genera. Further
study has emphasized the importance of these characters, which are de-
scribed below in detail because of their use in the generic keys in this work.

The epipharynx (Fig. 25 to 69) is defined as the ental wall of the labrum.
Its proximal extent is limited by the tormae, which are situated at the
lateral extremes of the clypeo-labral suture. However, a few of the setae
and an important sensory area, located between the mesal ends of the tor-
mae, are proximad of this suture and are thus on the ental surface of the
clypeus. 5

The tormae (¢) are heavily chitinized structures on the ends of the cly-
peo-labral suture (cist) which extend toward the mesal line and in some
larvae of this group meet and fuse on the mesal line. In many insects they
serve as a landmark in determining the extent of the clypeus and labrum
when the clypeo-labral suture is indistinct or absent. In the present group
of larvae, the tormae exhibit various sizes and shapes, and further study
may find them of more taxonomic importance. They were useful in the
separation of Canthon and Onthophagus. The lateral lobes (//) and
median lobes (m/),as here considered, apply tothe lateral and distal margins

107] LARVAL SCARABAEOIDEA—HAYES 23

of the labrum of conspicuously biémarginate species. The lateral striae
(is), occurring in Melolonthinae and a few other forms, are short trans-
verse carinae at the bases of setae on the lateral margin. In Phyllophaga a
second group of carinae, more distal and somewhat removed from the
margin, are called submarginal striae (sms). On the median line and some-
what removed from the distal margin is an important area, here called the
distal sensory area (dsa), containing various sensillia and strong chitinous
spines. The structures in this region which are, in most cases, obviously
strong spines were called by Ritterschaus (1927) ‘‘chitinous pegs,”’ and the
area upon which they are situated, and upon which are also found numerous
pore-like sensillia, was called a “chitinous plate.’”’ The chitinous pegs are
here called spines (sp) and the chitinous plate is the distal sensory area. The
sensillia (sa) are located at the bases of the spines, being between them
and the distal margin.

The proximal sensory area (psa) is the region between the ends of the
tormae and in many species proximad of the clypeo-labral suture (c/st). This
region contains a strong, rounded tubercle called by Ritterschaus the sense-
cone (sc). High magnification shows it to contain about four sensillia (Fig.
69). One of these sense-cones is described in detail in the description of the
epipharynx of Phyllophaga futilis. On the right side of the sense-cone (left
in drawings) is a variously shaped, chitinous plate (cp), which is not present
in some species. On the left side of the sense-cone is a non-setose area which
in some forms (Phyllophaga) contains 20 to 25 pore-like sensillia. In other
species two or three sensillia are found in this area, and in still others none
occur. These may be called the clypeal sensillia (c/s) since they are usually
on the clypeus. The remaining surface of the epipharynx is covered with
variously arranged articulate setae (st), which are usually so arranged as to
leave a clear, non-setose area in the center of the epipharynx. Frequently
there are interspersed among these setae numerous groups of more delicate,
non-articulate spines, especially in the region of the clypeo-labral suture.

Coprinae

Tribe Scarabaeinit.—The epipharynx of Canthon laevis Drury (Fig. 55) is
symmetrical and rather strongly developed and is rather densely covered
with strong, hooked setae. The lobe is continued on the ental surface into a
prominent, rounded process which bears six shorter setae. There is a central
pair of setae arranged transversely, and laterad of these on each side is
another pair arranged longitudinally. Still farther laterad are two pit-like
structures which somewhat resemble alveoli from which setae have been
removed but which are more probably sensoria. The lateral lobes are rather
densely covered with long, slender, curved setae. Mesad of these on the
ental aspect is located a group of not over a dozen more robust, but shorter,
setae which are recumbent, their apices being directed mesad. These are
apparently unequal in number on the two sides, with a few more present on

24 ILLINOIS BIOLOGICAL MONOGRAPHS [108

the right than on the left side. Behind, or proximad, of the median lobe in
cleared specimens, is a dark, transverse, oval structure which probably
would not be apparent in fresh specimens. Near the clypeo-labral suture a
few slender setae are grouped on each side; they are recumbent and their
points are direct mesoproximad. The tormae are not as well developed as in
some other scarabaeid larvae. They appear strongly curved on the sides,
and each extends on its mesal end transversely across the epipharynx to
meet and fuse with the torma of the other side.

Tribe Coprini—Copris tullius Oliv. (anaglypticus Say) also has the
labrum symmetrical, strongly trilobed, and biémarginate (Fig. 64). The
following description is made from a single specimen whose details are
difficult to make out. Its median lobe bears four long setae hooked at the
tips and also some shorter setae. The lateral lobes have only a few short
setae. No distinct distal sensory area can be distinguished, and there is
apparently a group of short setae arranged in the form of a circle. Near the
clypeo-labral suture a darker area may be the sense-cone of the proximal
sensory area. Other than the circle of setae only a few short, scattered setae:
are apparent on the ental surface of the lateral lobes. The tormae appear
branched, one of the branches being long and extending far onto the cly-
peus. The epipharynx of Onthophagus (Fig. 67) shows quite a different
arrangement of the tormae and a somewhat similar circular group of setae
in the central area. The distal margin is provided with intermixed long and
short, strongly hooked setae.

A phodinae

Tribe Aphodini.—The species of Aphodius (Fig. 56) considered here
was taken in large numbers from manure. None having been reared, the
specific identity is uncertain, but from the large size of the grubs it is pro-
bably Aphodius fimetarius (L. ), which is one of our largest and most com-
mon species. The epipharynx bears comparatively few setae both on the
margin and on its inner surface. The margins are smooth proximally but
rather irregular distally where they are produced into a broad, single lobe.
The widest area is about in the middle, where a single articulate seta is
situated with another slightly disto-mesad. Between the broadest point of
the lateral margins and the distal lobe six setae, two long and four short,
are found on each side. The distal lobe bears two long and four short setae
on the margin and about four short setae remote from the margin. Behind
the median lobe on each side are two irregularly triangular chitinized areas.
Between these and immediately distad of a prominent circle of short chiti-
nous processes, or spines, are two sense-cones. The circle of chitinous pro-
cesses, or spines, at first glance resembles setae, but they are blunt at their
tips, non-articulated, and at the base of some of the distal spines there is an
indication of a sensory pore. This circle extends to the clypeo-labral suture.

109] LARVAL SCARABAEOIDEA—HAYES 25

The tormae meet and fuse on the middle line, whence a chitinous process
extends distad to the center of the circle of spines and then expands slightly
on the end. On the clypeus are two small chitinous plates found near the
fused tormae.

Geotrupinae

Tribe Geotrupini.—No specimens of this genus were available. The
drawing of Geotrupes stercorarius L. (Fig. 58) isa copy of Schiddte’s drawing.
In general it is somewhat similar in shape to Canthon laevis, being symmetri-
cal and trilobed. The inner aspect has comparatively few setae. The
median lobe is strongly produced on the inner aspect. Its margin
shows eight strong setae, and eight others, apparently recumbent and di-
rected proximad, are found just within the margin on the inner aspect. A
strongly curved, transverse, darker area is proximad of these spines, and
two series of small setae, semi-circular in arrangement, are proximad of this
darker area. The median lobe is produced into a blunt, rounded process
which crosses the clypeo-labral suture. The surface of the lateral lobes bears
setae that are shorter and stouter than those of the lateral margins. They
are, as in Canthon, unequal on the two sides, with a few more present on the
right side than on the left. They are recumbent and their apices are directed
mostly toward the meson. The tormae are not shown in Schiddte’s drawing.

Glaphyrinae

The epipharynx of Amphicoma sp. (Fig. 61) is described from specimens
in the Davis collection from Hadley, Mass., collected May 29, 1916, by H.
E. Smith. Unlike most of the Laparosticti, the labrum is only slightly
trilobed and only faintly biémarginate. On the margins, both distal and
lateral, there are interspersed long and short setae, the long ones being
several times longer than the short ones. The median lobe bears the distal
area, which is almost on the margin and which contains about twelve
sensillia in the form of small, rounded pores. The pores seem to be set off
from the rest of the epipharynx by a darker, chitinous, semi-circular
band which bears a few setae. The remaining surface of the epipharynx is
covered with rather densely placed setae arranged in a circle, with the
larger and stronger setae on the distal rim of the circle. In the cleared circle
and proximad of the larger setae are a few small rounded areas that may
be sensillia or trichopores. The right torma is extremely long, reaching far
beyond the median line. The left torma is much shorter. The proximal
sensory area, which is behind the right torma in the area formed by a strong
curve of the torma, is composed of a strong tubercle-like sense-cone, with
two smaller cones to the right. A few minute spines of varying sizes are to
be seen proximad of the right torma, and two or three pore-like sensillia are
mesad of the sense-cone.

26 ILLINOIS BIOLOGICAL MONOGRAPHS [110

Melolonthinae

Tribe Sericini.—The epipharynx (Fig. 31) is described from specimens
in the Illinois Natural History Survey collection, determined as Serica sp.
by Dr. A. G. Béving. They agree closely with the description of Triodonta
(Serica) aquila Cast. by Perris (1877, p. 116). The labrum is more sym-
metrical than in most of the Melolonthinae and has its distal lobe rather
strongly produced. The lateral lobes are margined on the inner aspect
by the series of lateral striae. The margins of all three lobes are provided
with rather numerous setae, which increase in length distally. There are
three prominent spines in the distal sensory area, but no sensillia have been
found. Close study may probably show that they are present. The surface
of the epipharynx is covered with small setae except for a cleared central
space. The tormae are unequal in size and dissimilar in shape. The right
torma reaches almost to the median line, and at its end is located the con-
spicuous sense-cone of the proximal sensory area.

Tribe Melolonthini.—Diplotaxis sp. is described from a first instar larva
(Fig. 34). The epipharynx is broadly oval, with only the distal end bearing
setae, about eight in all. The ental surface bears a small patch of com-
paratively long setae, which are directed meso-distad. They meet on the
meson and overlap each other. Between these and the distal margin are a
few short, broad setae. The lateral margins lack the series of lateral striae
which occur in other Melolonthinae and also in the tribe Anomalini. The
distal sensory area is located at the base of four spines with apices directed
proximad. Five sensillia can be distinguished at the base of these spines.
An irregular series of short setae extends from these spines to the clypeal
area. The tormae are poorly developed, the left one being more heavily
chitinized than the right, which is almost obsolete. In the area of the
epipharynx, distad of the right torma, is a darkened, narrowly chitinized
area, which extends disto-proximad. This may be a structure that is not
normally present. A small dark area distad of the left torma is probably a
sense-cone of the proximal sensory area.

The labrum of Phyllophaga futilis (Lec.) (Fig. 37) is asymmetrical, and
its distal margin is extended to form a lobe which is covered with a mass of
long, slender, articulate setae. The lateral margins are rounded and bear on
each side about 16 broad and rather strongly curved, articulate setae. Near
the base of each of these setae on the ental aspect is a narrow ridge, or
carina, extending toward the meson. This series of carinae give each mar-
gin a file-like aspect. They are the lateral striae. Immediately behind the
distal lobe and slightly laterad of the meson is another series of ridges, about
nine in number. The individual ridges extend nearly disto-caudad, while
the series taken as a whole lies obliquely. These are the submarginal striae.
Immediately mesad of the submarginal striae on the right (left in sketches)
is a darkened, more heavily chitinized area—the distal sensory area. Near

111] LARVAL SCARABAEOIDEA—HAYES 27

the meson and slightly in front of the middle is a group of six strong spines
pointing proximally and having their bases arranged in almost a semi-
circle. Three or four other spines of the same nature are situated caudad of
the semi-circular group of six. These spines are distinguishable from the
neighboring setae by their larger size and the fact that they are not articu-
late at the base. Distad of the spines and located near their base is a group
of pore-like sense-cones arranged somewhat semi-circularly but irregular as
to their distance apart. There are six comparatively large cones and five
smaller ones alternating with them about the semi-circle. Proximad of the
series of spines and sense-cones in the distal sensory area is a large number
of articulate, recumbent setae whose apices are directed mesad and meso-
caudad. They likewise are semi-circularly arranged, leaving an area in the
center with no setae. The series extends to the tormae on the proximal mar-
gin of the labrum. On the left of the clear central area (right in sketch),
near the proximal margin, is a cluster of long, slender, fixed spines. These lie
in part between the branched arms of the left torma. The tormae, located on
the clypeo-labral suture, are long, irregular, and asymmetrical. The right
torma extends almost to the meson and is unbranched; while the left torma
is shorter and is two-branched near its mesal end, with one of the branches,
long and slender, extending far onto the labrum. At the mesal end of the
left torma is another clump of fixed, slender spines, and mesad of these are
about 25 clypeal sensillia. Between these sensillia and the end of the right
torma, slightly off the median line, is a triangular chitinized area, almost
spine-like, called the chitinous plate by Ritterschaus. It is directed meso-
distad. Immediately mesad of the chitinous plate, and apparently partly
underlying it, is a broader, less heavily chitinous area pointing in the same
direction and covered with long, slender spines (Fig. 69). In cleared speci-
mens, four sense-cones are apparent, which are intermediate between the
sensillium ampullaceum and sensillium coeloconium types. Each of these
consists of a sunken, fungiform cone which connects with a long, somewhat
bottle-shaped canal. The central stucture containing the sense-cone is
called the ‘‘sense-cone’’ by Ritterschaus. The ental surface of the clypeus,
upon which we find the chitinous plate and the area bearing the sense-cones,
is called the ‘‘epigusta’”’ by some writers (MacGillivray, ef al.). Just behind
the sensory area is a long, transverse, strongly bowed, chitinous bar. All of
the structures between the tormae comprise the proximal sensory area.

The epipharynx of Phyllophaga lanceolata (Say) (Fig. 26) differs in some
detail from the common epipharyngeal form found in this genus, the most
conspicuous differences being a more nearly symmetrical outline of the
labrum and the presence of only four prominent spines in the distal sensory
area. A closely allied species, P. cribrosa (Fig. 35), is of the typical form,
including the usual number of spines on the distal sensory area. Another

28 ILLINOIS BIOLOGICAL MONOGRAPHS (112

species, P. tristis (Fig. 27), differs in having but three prominent spines in
the distal sensory area.

In the genus Polyphylla (Fig. 25), which also belongs to the tribe Melo-
lonthini, the characters are quite similar to those of Phyllophaga except for
a somewhat different arrangement of the spines on the distal sensory area.
The lateral striae are also shorter and less distinct.

Tribe Macrodactylini—The epipharynx of Macrodactylus subspinosus
(Fab.) (Fig. 28) is described from specimens in the Davis collection of the
U. S. National Museum. The labrum is asymmetrical, with a single emar-
gination of the distal margin slightly to the right of the median line. The
margins, both lateral and distal, are provided with intermixed long and
short setae. Lateral striae are present on the inner surface of the lateral
margins. Beginning at the notch, or distal emargination, is a more darkly
chitinized, irregular plate, which extends proximad to the distal sensory
area. In this area is a group of pore-like sensillia arranged in an irregular
semicircle. Some of the sensillia are arranged in pairs. From this same area
four strong spines are directed toward the clypeo-labral suture. Between the
distal sensory area and the clypeo-labral suture a number of setae are
arranged in a circle with a non-setose area in the center. The tormae are
unequal in size, the left one being considerably smaller than the right. At
the end of the left torma is a prominent row of slender, elongate spines. The
right torma extends nearly to the median line where the sense-cone of the
proximal sensory area is located. In some specimens the cone is a single
tooth-like structure, while in others it appears as two teeth (Fig. 28).

Rutelinae

Tribe Anomalini.—The epipharynx of Popillia japonica Newm. is quite
similar to other species in the tribe. Its close relationship to the Melolon-
thinae is shown by the presence of the lateral striae, which occur only in
these two groups, and by the resemblance in the form and arrangement of
the sensory area including the spines, which, however, are fewer in number
than in the Melolonthinae. The following species were available for study:
Popilla japonica (Fig. 41), Strigoderma arboricola (Fig. 52), Anomala orient-
alis (Fig. 40), A. kansana (Fig. 43), A. binotata (Fig. 49), and A. innuba
(Fig. 46). Except for some variation in the number and arrangement of the
spines of the various species, they exhibit rather marked uniformity in
structure. The same can be said of Anomala phyllopertha, which has re-
cently been described by Ritterschaus (1927). Boéving (1921) has figured
the epipharynx of Popillia japonica but has not given a detailed description
of its structure. The labrum (Fig. 41) is strongly asymmetrical, as in the
others studied in this tribe except Anomala orientalis, which is nearly
symmetrical. The distal margin is usually produced into an acute lobe
covered with rather long setae. The lateral margins are strongly rounded

113] LARVAL SCARABAEOIDEA—HAYES 29

and bordered with short, curved setae, at the bases of which are to be found
the lateral striae, and with a few extremely long setae intermixed. The distal
sensory area has three strong spines and two large articulate setae which
might be confused with the fixed spines. At the bases of the fixed spines
there are about eight sensillia arranged in a curved line. Between the distal
sensory area and the clypeo-labral suture numerous smaller setae are cir-
cularly arranged with the customary, smooth, non-setaceous, central area.
The tormae are of nearly equal size and do not reach the median line. At
the mesal end of the right torma a pointed, chitinous plate and a tubercle-
like sense-cone comprise the proximal sensory area. Two pore-like clypeal
sensillia are to be found in the cleared area mesad of the sense-cone and
proximad of the distal end of the left torma. Latero-proximad of these
pores are a number of minute spinules only noticeable under high magnifi-
cation.

Tribe Rutelini—Three species of this tribe were studied. They differ
strikingly from the tribe Anomalini of the same subfamily and exhibit
affinities toward the Dynastinae. Polymoechus brevipes Lec. (Fig. 47) is
decidedly irregular in outline; Pelidnota punctata (L.) (Fig. 44) is more
regular and is wider than long; while Cotalpa lanigera (L.) (Fig. 50) is
longer than wide. The arrangement of the distal sensory area is sometimes
hard to make out. It varies more markedly than in the Anomalini. In
Cotalpa the general form is only slightly asymmetrical, the sides are
gradually rounded and no prominent lobes or emarginations are formed.
The lateral margins are covered with curved setae which are comparatively
short in the proximal region but become longer distally. No lateral striae
are present. The distal sensory area is composed of a single chitinous struc-
ture produced into a point resembling a spine. Proximad of this structure
are a few strong, spine-like, articulated setae. They are directed toward the
clypeus, while the remaining setae covering the epipharynx are directed
toward the meson witha smooth area in the middle. The tormae are irregu-
lar, the left one being curved distad while the right lies transversely. A
fold in the integument at the mesal end of the left torma makes this torma
appear much longer than it is. At the end of the right torma is the proximal
sensory area, composed of a minute, triangular, chitinous plate and a
broadly rounded sense-cone.

Dynastinae

Tribe Cyclocephalini.—The epipharynx of Ochrosidia immaculata (Oliv.)
(Fig. 53) is characterized by the absence of lateral striae along the ental
surface of the lateral margins and by the presence of two broad chitinous
spines in the distal sensory area. The right spine is nearly twice as broad as
the left, and its apex is more rounded. In cleared specimens three sense-
cones can be distinguished in this spine. The left spine is more pointed and
has at least one sense-cone in it. The lateral margins of the labrum are

30 ILLINOIS BIOLOGICAL MONOGRAPHS [114

comparatively smooth and strongly rounded. They bear about 14 broad
and strongly curved setae pointing distally, each of which is slightly longer
than the preceding one. The distal margin is more rugose and is armed with
a group of long setae. Between this group of setae and the spines described
above there is a small, narrow, somewhat curved, chitinous plate, or ridge,
which lies obliquely. There are two sense-cones located in the space be-
tween this chitinous structure and the two broad spines. A large series of
setae of various sizes lie between the spines and the clypeo-labral suture.
The setae are inclined in all directions and are so arranged as to leave a
cleared area in their center.

The tormae are comparatively short and decidedly asymmetrical. The
torma on the left is at first directed proximad, but it soon makes a promi-
nent bend and narrows down toward its extremity, which is near the clypeo-
labral suture. The right torma is at first curved proximad but has a less
conspicuous curve, so that it extends in an almost transverse direction. At
its distal end in the proximal sensory area on the clypeus are two chitinous
processes pointing distally. The one almost abutting the end of the torma,
and slightly overlapping it, is the larger. This is the chitinous plate. No
sensillia were noted in it, but the smaller process which is the sense-cone
shows one sensillium. Scattered throughout the large central group of setae
are a number of very small dots which are circular in outline and exhibit
within them another concentric circle. These are doubtless pore-like sensil-
lia.

Representatives of three other of the five North American tribes of this
subfamily have been studied—Ligyrodes (Ligyrus) relictus (Say) (Fig. 42)
and Ligyrus gibbosus DeGeer (Fig. 45) of the Pentodontini, Strategus antaeus
(Fab.) (Fig. 48) of the Oryctini, and Dynastes tityrus (L.) (Fig. 54) of the
Dynastini. They differ from Ochrosidia immaculata principally in that the
chitinous portion of the distal sensory area is produced into a single point,
except in Dynastes which has two projections located much closer to the
margin and much larger proportionally than in Ochrosidia.

Cetoniinae

Tribe Gymnetini.—The Cetoniinae are characterized by having the |

labrum symmetrical and usually biémarginate and trilobed. The distal
sensory area is composed of a group of comparatively short, strongly curved
setae which are stouter than the remaining setae. In a few species (Osmo-
derma ef al.) these setae are apparently not articulate and, as such, are
considered as spines.

In Cotinis nitida (L.) (Fig. 59) the labrum is deeply biémarginate on its
ectal surface but not strongly so on the ental aspect. The trilobed condition
of the epipharynx, therefore, is not strongly marked. The lateral lobes have
a few short setae, which become more numerous and longer distally. The

115] LARVAL SCARABAEOIDEA—HAYES 31

median lobe has only a few long setae. It is marked off internally on its
lateral areas by a darkly chitinized band extending on each side from the
margin to the distal sensory area. Between these bands and at the base of
the circular row of setae are two pore-like sensillia. The circular row is
composed of about 15 setae, and proximad of these are other setae of
similar size. The remaining surface of the epipharynx is covered with
longer and more slender setae which become shorter laterally. There is left
on the central disk a comparatively small area devoid of setae. The tormae
are shorter than in most groups, and the right one is a little longer than
the left. Between them in the distal sensory area is a single large sense-
cone. The chitinous plate of this area is absent. Some distance proximad
of this sense-cone are two pore-like clypeal sensillia.

Among the other species studied in this subfamily, Trichiotinus piger
(Fab.) (Fig. 66) is the only one that differs radically from others of the
group. It was studied in a first instar larva. It does not show the trilobed
feature, nor is the circular row of setae in the distal sensory area as marked.
Cremastocheilus sp. (Fig. 65) was studied from a cast skin in which the
epipharynx is nearly devoid of setae, apparently because they were rubbed
off, since numerous trichopores are present having the characteristic ar-
rangement of the group. A single sense-cone is present in the proximal sen-
sory area. Three species of Euphoria (Fig. 57, 60, 63) are markedly similar,
while Stephanucha pilipennis Kr. (Fig. 68) appears to lack the sense-cone
of the proximal sensory area and has the setae of the distal sensory area
more obliquely curved.

Trogidae

This subfamily of Scarabaeidae has recently been raised to family rank.
Tillyard (1926) has pointed out in his book, ‘Insects of Australia and
NewZealand,”’ that the Trogidae are intermediate between the Scarabaeidae
and Lucanidae. This is also apparent in the larvae in the condition of the
stridulating apparatus of the meso- and metathoracic legs and the feebly
trilobed anal area, which suggest relationships to the Lucanidae.

The epipharynx of Trox sp. (Fig. 39) is symmetrical and neither tri-
lobed nor emarginate. Its lateral margins are almost devoid of setae except
distally where five or six large setae are continuous with those of the distal
margin. The median distal margin is produced into four conspicuous
tubercles, each of which bears a strong seta. The distal sensory area is
indistinct, and in the specimens examined its detail is hard to distinguish.
Only a few setae are scattered over the lateral lobes, about four on each
lobe. The central area is darkened in the specimens, and no detail can be
made out. The tormae are small, the right one being the larger. No detail
of, or evidence of, a proximal sensory area is apparent.

32 ILLINOIS BIOLOGICAL MONOGRAPHS [116

Lucanidae

The subfamily Dorcinae (Fig. 30), represented in the University of IIli-
nois collection by some larvae labeled Dorcus sp. with no other data, lacks
the prominent circle of spines found in Sinodendron and is more setaceous
both on its distal margin and its ental surface. The distal lobes are not so
strongly evident, the emarginations being not so marked. The distal mar-
gin is densely setaceous, but the lateral margins are nearly bare of setae.
The general shape of the labrum is much like Sinodendron, being somewhat
subquadrate. The entire ental surface is sparsely set with short setae inter-
spersed with small pores which may be sensillia but also may be the tri-
chopores, or alveoli, of setae which have been broken. No circular area of
spines is present, but near the middle of one specimen is a semi-circular
depression which does not appear to be a normal structure. The tormae are
strongly curved at the lateral margin. They extend transversely mesad to
unite on the middle line, where another chitinous process projects distad
along the mesal line a little more than one-third the distance of the labrum.
Behind the fused tormae is a long, narrow sense-cone which is somewhat
rounded distally and which ends caudally in three parts. Three, small,
cleared areas near its distal end may be sensillia. On the left side of this
structure is a much smaller, more transparent, chitinous plate, the distal
end of which is rounded. On the right side of the sense-cone is a much
larger, backward-pointing, chitinous plate which ends in a sharp point. No
trace of sense-cones is evident in these lateral processes.

Aesalinae.—The general shape of the labrum of Sinodendron rugosum
Mann (Fig. 33) is subquadrate. Its lateral margins are smooth, non-setose,
and slightly divergent toward the distal end, where they round off to form
the distal margin, which is slightly three-lobed, the lobing being produced
by two emarginations, one on each side of the meson. The central lobe
bears four setae on its margin and two others that are submarginal. Each of
these setae arise from a small papilla. On the ental surface the median lobe
is rather strongly convex. On the left of the meson behind the setae is a
slight, chitinous spine which is frequently hard to find. Overlapping the
median lobe and extending to the clypeo-labral suture is a prominent,
almost circular row of spines enclosing a slightly depressed, smooth area.
The lateral lobes of the distal margin bear five or six setae, in one specimen
five, on the right lobe and six on the left lobe. The rest of the epipharynx
is smooth. The tormae are stout on the lateral margins. A pointed process
extends meso-distally while another transverse process meets a similar one
from the other side to fuse mesally where a pointed projection extends
distally along the meson into the clear area surrounded by the circle
spines. On the clypeus, proximad of the central chitinized process of the
tormae, are two chitinized plates somewhat setaceous on their distal ends,
and between these is a long tooth-like process. No sensillia, as found in

117] LARVAL SCARABAEOIDEA—HAYES 33

Phyllophaga, can be made out in these processes even with the oil-immer-
sion lens. The setaceous distal ends of the lateral plates are probably sen-
sory, while the central process shows under high power a clear central area
that may be thinner and may serve in a sensory capacity.

Passalidae

The epipharynx of Passalus cornutus Fab. (Fig. 36) is trilobed and
nearly symmetrical. The lateral lobes are clothed with a mixture of long
and short setae, but the median lobe has only seven setae on its margin and
is bare of setae on the ental aspect nearly to the middle of the epipharynx,
where there are two rather well defined curved rows of short setae, with
their apices directed distally—not as in the epipharynx of other species
studied—and laterad of these rows are a number of long setae with their
tips directed mesally. No sensillia have been found, but closer study of the
distal margin of the median lobe may reveal their presence. The tormae are
unequal in size, the left being the larger. They are comparatively small.
The present description is made from the specimen shown in Figure 3.
Other specimens show the setae of the median area to be arranged some-
what differently.

MANDIBLES

The mandibles (Fig. 70 to 89) are strongly chitinized and somewhat
longer than wide. The distal area is usually much darker than the proximal
area, which is generally of the same color as the head. A given species may
exhibit a marked difference in the shape of the right and left mandible.
Perris (1877, p. 93) points out that they are usually provided with teeth,
having two teeth on the right mandible and three on the left asarule. The
mandibles exhibit two distinct regions, a proximal and a distal area. Boving
(1921) has termed the proximal region the manducatorial region, or the
grinding area (also called the molar area, Fig. 81, mo), and the distal part
the scissorial region (sc), or cutting area. The molar area of the left man-
dible is, as a rule, larger than that of the right mandible. Behind the molar
area is a thinly chitinous, setaceous area, the acia (ac). This appears to arise
on the ventral aspect, where it can be observed that the right acia is long
and pointed while the left one is shorter and more rounded. On the dorsal
aspect (Fig. 70) is the acetabulum, or preartis (pa), by which the mandible
articulates with the condyle, or precoila, at the ends of the fronto-clypeal
suture. An enlarged sketch of this articulation is shown in Figure 77, in
which the preartis is seen to articulate with a condylar precoila (pcl). The
lateral aspect of each mandible presents a flattened surface, or scrobe (sd),
bearing a few setae.

The cephalic or anterior surface of the mandibles (Fig. 70 to 80) presents,
on the whole, a convex contour, and in all but Canthon laevis and a few
others it shows two distinct regions limited by a ridge, which is represented

34 ILLINOIS BIOLOGICAL MONOGRAPHS [118

by the dotted lines in the drawings. This ridge, and in most cases a change
of contour, indicates the areas covered and uncovered by the labrum when
the mandibles are in repose.

The caudal surface of the mandibles (Fig. 81 to 89) presents the notched
aspect of the scissorial area (sc) in much the same manner as the cephalic
aspect but possesses in some species a transversely striated area (sa) in the
form of an oval. This is part of a so-called stridulating apparatus which
occurs in a number of scarabaeid larvae and has been described by Schiédte
(1874) and others. Opposed to this series of transverse striations on the
maxillae is a variable number of stridulating teeth (Fig. 97, 113, 106 ms)
which will be described in connection with the maxillae.

On the caudal aspect of the molar area can be noted the acia (ac),
described above, and in addition, on the right mandible (Fig. 81), a some-
what rounded, lobe-like structure which is apparently absent on the oppo-
site mandible and which overlaps the hypopharynx when the mandible is
closed. This lobe plays an important role in the grinding of food. It will be
mentioned later in connection with the hypopharynx. This aspect presents
a condylar articulation, the postartis (pia), on each mandible, which articu-
lates, as seen in Fig. 109, with an acetabular postcoila (pic) located on the
gena. Attached to each mandible, but shown in only a few sketches (Fig.
70, 81, 89), are two chitinous processes for the attachment of muscles,
which have been described as tendons. The mesal tendon has been termed
the rectotendon (rt) and the lateral one the extensotendon (et). The right
mandible of Canthon laevis (Fig. 78, 85) has the scissorial area prolonged
into a narrow blade with no emarginations forming teeth. The left mandible
(Fig. 78, 85) has the regions notched to form three strong and quite distinct
teeth, and the manducatorial area has a single tooth larger than the others
and truncate at the end. The same area on the right mandible lacks the
tooth, but the whole is produced into a convex grinding area that fits into
the concave grinding area of the left mandible. This species bears a series
of small rugosities in place of the ovate series of transverse, stridulating
striae.

The shape of the mandibles in Canthon ebenus is not the same as in C.
laevis. The right mandible has two teeth, and the left has three, on the
scissorial area. Onthophagus pennsylvanicus seems to resemble C. laevis
more closely. The right mandible has a long narrow scissorial tooth, while
the left has three, and the manducatorial area has one large truncate tooth.
The scissorial area of the right mandible of Phyllophaga crassissima (Fig.
76, 84) is a long blade-like structure devoid of any notches producing teeth.
The manducatorial area is comparatively small, compared to that of the
left, and is somewhat concave when viewed on the dorsal aspect. The
scissorial area of the left mandible (Fig. 76, 84) is stouter than the right and
from the dorsal aspect presents, on the inner side, an irregular margin

119] LARVAL SCARABAEOIDEA—HAYES 35

scarcely strong enough to be called toothed. When viewed from the ventral
side, there appear two rather prominent teeth on the cutting edge. The
grinding area is much stouter on the left and bears near its base a strong
tooth. Phyllophaga lanceolata differs from P. crassissima in having a promi-
nent tooth on the scissorial area of the right mandible and two somewhat
less conspicuous teeth on the left. The same difference in size of the molar
area is here noted as in P. crassissima. As in the Coprinae, the transverse,
stridulating striae are replaced by a slightly rugose surface.

In Diplotaxis the right scissorial area is long and blade-like with a single
prominent tooth, and the manducatorial area is small, compared to that of
the scissorial region. The scissorial area of the left mandible is proportion-
ately more slender and ends in a sharp point. There are two conspicuous
teeth on the inner edge, and the manducatorial region is produced to form
a rather noticeable tooth near its cephalic margin. The scissorial and molar
areas of Cotalpa lanigera (Fig. 74, 83) are proportionately much stouter than
in the species of the Melolonthinae studied. The right scissorial area has a
serated inner edge, and the tip end is broadly obtuse. The grinding area is
somewhat smaller in the left mandible and bears three conspicuously
elevated grinding surfaces. The scissorial region of the left mandible has a
small tooth on the cutting edge, which is rather sharp, and the molar sur-
face presents quite an irregular margin, thus differing somewhat from the
right mandible.

In Polymoechus brevipes the scissorial region is quite similar in both
mandibles. The area ends in a rather sharp point, near the tip of which
there is a single sharp tooth. The molar areas are of approximately the
same size on both mandibles, but one is slightly concave to fit the convexity
of the other. The right scissorial area of Anomala binotata is comparatively
smooth on the inner edge, no teeth being present, and the structure has a
rather truncate termination. The left mandible is likewise truncate, but
its cutting edge bears two teeth, one rather obtuse and the other acute. The
right molar surface is rather flat and smooth and about the same size as the
left. In Anomala aenea, figured by Schiédte, both the scissorial areas end
acutely and the inner cutting edges each bear a single tooth. All Rutelinae
studied have an ovate series of transverse stridulating striae. The mandibles
of Ligyrus gibbosus (Fig. 75, 88) are quite dissimilar in shape. The right
scissorial area has a smooth cutting edge and is truncate on the end. The
left is rounded at the tip, arid the cutting edge bears three rather obtuse
teeth. The grinding regions are approximately the same size, but the left
bears a tooth, as in Phyllophaga crassissima, which is lacking on the right
molar surface. Ligyrodes relictus has two obtuse teeth on the cutting edge
of the mandible. The right is truncate and the left is broadly rounded as in
L. gibbosus. Likewise the grinding areas are similar to those of L. gibbosus,
and the whole mandible is proportionately broader and stouter. The man-

36 ILLINOIS BIOLOGICAL MONOGRAPHS [120

dibles of Ochrosidia immaculata are acutely pointed and more slender, and
the cutting edge of the left bears two teeth, one of which is obtuse and the
other acute, while the grinding surface has numerous teeth with an espe-
cially large one at the cephalic margin. The right scissorial area is acutely
pointed, and the inner edge has one conspicuous tooth that is obtusely
pointed. This subfamily has the transverse stridulating striae on the caudal
aspect. The mandibles of Euphoria inda (Fig. 73, 82) are proportionately
shorter than in the other groups except the Coprinae. The right scissorial
region is notched at the end, giving the appearance of a broadly truncated
tooth and a small, somewhat acute tooth. The molar area is larger than
the cutting region. It is slightly concave and has two teeth. The left
scissorial area is truncate at the end and has two large teeth on the cutting
edge, while the manducatorial area is convex and bears three broad, short,
grinding teeth. All Cetoniinae, as far as known, have an oval stridulating
area on the caudal aspect. In the specimens studied of the genus Trox”
(probably T. unistriatus Beauv.), the mandibles do not differ strikingly
from those of other genera previously described. The stridulating area on
the caudal surface is not present. The scissorial area of the right mandible
presents a long terminal tooth and another formed by a small notch on the
mesal margin. The molar area on this mandible consists of one large,
broad tooth and a smaller, but longer, isolated tooth distad of the larger one.
The scrobe bears a conspicuous ridge, or carina. The left mandible is quite
similar in the scissorial area, and the molar area differs but little im size.
Practically the entire structure is very darkly colored. In Sinodendron
rugosum Mann (Fig. 80) the mandibles are entirely black in color. They
are, as in the others, asymmetrical. The distal end of the scissorial area of
the left mandible bears three teeth, which are nearly subequal, while the
right has but two, of which the terminal one is longer and more slender than
the adjacent one. The molar area of the left mandible is larger than that on
the right. The stridulating area is absent. In Ceruchus piceus (Web.) the
dentation of the scissorial area is similar to Sinodendron, and the opposing
molar areas are dissimilar in shape and size. Specimens of the genus Dorcus
show no striking differences from Ceruchus and Sinodendron. In both Ceru-
chus and Dorcus no stridulating area is present on the caudal aspect.
Perris (1877, pl. 5, fig. 157) shows a right mandible of Lucanus with three
terminal teeth and no stridulating surface, thus corresponding to the genera
here described. The mandibles of Passalus cornutus differ considerably from
those of the Lucanidae (Fig. 79, 89). The terminal teeth of the scissorial
area are three in number on both mandibles, and the molar area is nearly
similar on both. It consists of a broad, cup-like tooth, which is strongly
depressed on the mesal aspect. Both more nearly approach each other in
symmetry than in any other members of the superfamily. The stridulating
surface on the caudal aspect is lacking.

121] LARVAL SCARABAEOIDEA—HAYES 37

MAXILLAE

The maxillae (Fig. 97 to 100 and 103 to 104) present the usual number
of parts found in a chewing type except that the galea and lacinia may or
may not be fused to form the single structure known as the mala (m). The
cardo (cd) articulates with the postgena (eg) (Fig. 109) by an articular
acetabulum, the parartis (pra), which fits into the paracoila (prc) located on
the postgena. There are two divisions of the cardo, a subcardo (sc) which
bears the articulation and an alacardo (ac) lying between the subcardo and
the stipes. The stipes (s) is quadrilateral in outline on the caudal aspect,
except at its distal end where it is fused to the mala, while on the cephalic
aspect it is not separated from the mala. The palpifer (ff) is borne on the
dorso-lateral margin of the stipes. On the mesal margin is a narrowly
elongate sclerite, the parastipes (ps), or subgalea of many authors. A mem-
brane termed the labacoria (/c) by MacGillivray (1923) is attached to the
inner margin of the cardo, parastipes, and stipes. This membrane attaches
to the labium and helps close the oral aperture. The mala (m) is densely
setaceous and distally bears a series of strong spines (Fig. 115 to 117).
In many larvae of the coprophagous Scarabaeidae, all the Lucanidae,
Passalidae, and Trogidae, the lacinia and galea are distinctly separate and
show no traces of fusion. The series of teeth-like structures found on the
cephalic aspect are variable in number (Fig. 111 to 114 and 118, 119, 124,
125), there being usually more on the right than on the left maxilla (Fig.
112). These teeth may point and curve toward the distal extremity of the
stipes or may be short, blunt, and not curved (Fig. 113, 118). They usually
lie in opposition to the oval, file-like area on the mandible (Fig. 81, 88).
These stridulating structures, if such they be, have been described by
Schiddte (1874), who asserts that the teeth of the maxillae differ in number
and form according to the genera, and further notes that they vary in
number from five to twenty, sometimes being straight but more often being
extremely sharp and curved. The maxillary palpi (mp) are three- or four-
segmented.

The cephalic aspect of the maxillae (Fig. 97 to 100, 103, 104) is slightly
different from the ventral aspect and will, therefore, be described separately.
The cardo is large and subquadrate in all the genera figured. The stipes is
limited by a suture from the cardo and may, or may not, be differentiated
from the galea, while on the ventral surface there usually appears a suture
separating the stipes and galea. The maxillary lobes (galea and lacinia) are
separate or bifed in some of the genera, while in others there is a deep
longitudinal sulcus which is the limiting line between the two parts.

In the Coprinae (Canthon laevis, Fig. 98) the cardo is subquadrate and
has a longitudinal suture dividing it into a larger and a smaller area. The
stipes likewise is subquadrate and bears on its mesal margin the lacinia
which terminates in a single, strong tooth (Fig. 117). On the latero-anterior

38 ILLINOIS BIOLOGICAL MONOGRAPHS [122

margin of the stipes is a smaller sclerite, probably the palpifer or a portion
of the galea, from which is articulated the maxillary palpus. Distad of the
palpifer is the lobe-like galea which is rounded at the end and bears numer-
ous setae. Canthon ebenus also has the two regions, galea and lacinia,
separated. The same is true of Aphodius (Fig. 100), Onthophagus pennsyl-
vanicus, all the Lucanidae, Trogidae, and Passalidae (Fig. 103).

The Melolonthinae, Dynastinae, Rutelinae, and Cetoniinae present
much the same appearance dorsally and will not be described separately.
In each the cardo is subquadrate; the stipes and galeae are not separated;
and the two lobes, galea and lacinia, are fused but are limited on the dorsum
by a distinct suture. On the dorsum of the stipes are the stridulating teeth
which lie opposite the stridulating areas of the mandibles. Concerning
these Schiddte (1874) says:

“Les dents de la tige des mandibules servant 4 rdcler les granulations mandibulaires
différent de nombre et de forme selon les genres: il y en a de six jusqu’a vingt et au dela;
quelquefois elles sont droites et trésfortes, mais le plus souvent elles sont extrémement aigués
et recourbées en crochet.”

In Canthon laevis (Fig. 119) there are six, large, pointed teeth and a
number of very minute teeth immediately cephalad of the larger ones.
Phyllophaga crassissima (Fig. 118) has fourteen rather blunt or quadrate
teeth; Ligyrus gibbosus (Fig. 124) has thirteen; Euphoria inda (Fig. 125)
has six, which are long and pointed; while in Cotalpa lanigera (Fig. 114)
only five rather blunt teeth are found. These teeth have been observed
only in the Scarabaeidae.

On the caudal aspect the important differences from those of the cepha-
lic are the sharp delineation of the stipes from the galea, the absence of the
longitudinal sulcus marking the fusion of the galea and lacinia, and a few
indistinct sutures dividing the cardo into a number of irregular areas. The
galea and lacinia of Canthon laevis and others with a bifed mala are separate
as on the cephalic aspect, while the two are completely fused in other groups.
The palpifer is distinctly evident in most species. .

The spines and setae found on the galea and lacinia are shown from
the mesal aspect in Figures 115, 116, 117, 120, and 121. Upon closer study
these may prove of decided taxonomic value. The stronger spines are
termed unci (singular-uncus) by Béving (1921).

Canthon laevis (Fig. 117) has on the terminal end of the lacinia a single
uncus. On the fused lobes of Phyllophaga crassissima (Fig. 121), there are
three rows of unci, with four to six teeth per row. Ligyrus gibbosus (Fig.
115) has a single terminal uncus and two others standing close together.
Euphoria inda (Fig. 120) has one terminal and five mesal unci and a number
of strong setae.

The fusion of the galea and lacinia seems to be typical of the higher
Scarabaeidae. On the dorsal surface of the maxillae there remain traces of

123] LARVAL SCARABAEOIDEA—HAYES 39

this fusion indicated by the longitudinal sulcus. This condition may be
correlated with the food habits. The families Trogidae, Lucanidae, and
Passalidae (Fig. 103) all resemble the coprophagous Scarabaeidae in having
the galea and lacinia separated.

HyYPoPHARYNX

The hypopharynx consists of a densely setaceous area on the ental
aspect of the fused glossae and paraglossae and a strongly chitinized area
(Fig. 128 to 132), termed by Boéving (Joc. cit.) the hypopharyngeal chitini-
zation (ic). The hypopharyngeal chitinization (Fig. 134) is decidedly
asymmetrical and somewhat less densely chitinized on the lateral extremi-
ties where it is irregularly inflexed to fit snugly against the molar region of
the mandibles (Fig. 133) and, in the opinion of the writer, serves as an
accessory organ of mastication. The caudal margin of the chitinized area
is continuous with the pharynx (Fig. 134), which is probably held open by
rod-like structures extending dorsally to the epipharynx. In one prepara-
tion it was noticed that there is a direct connection between the ental aspect
of the clypeus and the hypopharynx. These connecting bands, of what ap-
pear to be slightly chitinized membranes, are shown in Figure 91, extending
between the clypeus (c/) and the hypopharynx (hc). On the dorsal aspect,
near the lateral angles, is a series of small setae which are similar to the
structures described by Carpenter (1912) as the maxillulae which Crampton
asserts are homologous to the crustacean paragnatha.

The hypopharynx consists also of a series of thickly set spines located on
the glossa. They vary considerably in the genera studied. Immediately
behind the setae is the heavily chitinized, assymetrical hypopharyngeal
chitinization (Fig. 134). The setae of the hypopharynx of Canthon laevis
(Fig. 130) are arranged in the form of a semicircle and seem in this respect
to differ entirely from the other genera studied. In Phyllophaga crassissima
(Fig. 131) and Ligyrus gibbosus (Fig. 132) the setae are arranged in a circu-
lar group, with their points directed toward the center. In Cotalpa lanigera
(Fig. 128) they are arranged in a triangle, and most of them are pointed
distally. In Euphoria inda (Fig. 129) there is a double longitudinal series,
one within the other, of setae which tend to converge distally and which
point toward the median line.

The hypopharyngeal chitinization of the higher Scarabaeidae is quite
similar (Fig. 128 to 134). Canthon laevis (Fig. 130) differs markedly.
It appears to have the chitinized area divided into two irregular structures
both of which are more heavily chitinized on the right side. The structure
in the other four genera figured is obliquely transverse and has the right
side produced into a more or less blunt end which is more heavily chitinized.
The hypopharynx of the families other than the Scarabaeidae has not been
carefully studied. In the Passalidae and Trogidae it is more simple, not

40 ILLINOIS BIOLOGICAL MONOGRAPHS [124

being as heavily chitinized, while in the Lucanidae this structure is more
pronounced and approaches the higher Scarabaeidae in degree of develop-
ment. Further study of the hypopharynx may reveal characters of tax-
onomic value in these structures.

LABIUM

The labium (Fig. 92) is small and usually concealed. It is partly covered
on its lateral margins by the maxillae. The submentum (sm) is large and
somewhat quadrate. It is bordered laterally by the maxillae (mx). A
smaller, narrow, transverse area represents the mentum (m#) which is
sharply differentiated from a wider transverse, stipula (s#). Laterally, the
stipula may be prolonged into a deflexed, broadened lobe which is covered
by the maxilla. The stipula is broadly rounded on the distal margin. It is
strongly setose and bears a pair of small, two-segmented labial palpi
(Ip). Since the labia of the various genera differ from each other less than
any other structures of the mouthparts, they are not given extended con-
sideration, although the shape of the various parts differs somewhat, as

do also their size and proportion.

THORAX AND ABDOMEN
SEGMENTATION

The thorax (Fig. 1 to 12) consists of the usual three segments, each of
which, except in the Passalidae, bears a well-developed pair of jointed
legs. The Passalidae have but two pairs of well-developed legs on the pro-
and mesothorax and a greatly reduced pair of metathoracic legs. The
prothorax (Fig. 8, J) may (Fig. 12), or may not (Fig. 1 and 3), be divided
dorsally into two or three annulets. The division of.the cephalic annulets
usually does not extend onto the pleuron. Sometimes a small area of the
cervix lying in front of the cephalic annulet is apparent, depending on the
degree of extension or retraction of the head. This may cause the pro-
thoracic segment to appear broken up dorsally into four annulets. The
cephalo-ventral angle of the propleuron frequently extends forward to
partially overlap the head capsule. The propleuron in some forms (Trox,
Fig. 7) is more deeply pigmented and slightly more -heavily chitinized.

The meso- and metathorax in Passalidae are similar to the prothorax
in not being divided into annulets. In all other species noted there are two
or three annulets present. In Pinotus (Fig. 1) but two annulets occur, while
many show three distinct divisions. Perris (1877, p. 94) wrote that the
meso- and metathorax, in those species with annulets, were equally divided
by a single fold and that the largest division was anterior in the mesothorax
and posterior in the metathorax.

The number of abdominal segments is variously counted as nine by
some workers (Perris, 1877) and ten by others (Béving, 1921). In Passalus

125] LARVAL SCARABAEOIDEA—HAYES 41

(Fig. 3) there are ten distinctly evident segments, and in many others
(Anomala, Fig. 8) ten can be easily discerned. Some genera such as Apho-
dius (Fig. 6) and Euphoria (Fig. 11) show a tendency towards a coalescence
of the ninth and tenth segments. The first eight segments of Passalus show
a slight diagonal depression tending towards the formation of a small
anterior and a large posterior annulet. The Lucanidae (Fig. 2) and
some of the Scarabaeidae (Fig. 1, 4) show but slight annulations. The first
six or seven segments of the more common Scarabaeidae are thrown into
deep folds; forming usually three distinct annulets. The caudal segments
are not so constricted. The integument appears stretched and often is
partly transparent. The last segment has been called the ‘‘sac” by Erich-
son (1848), which is a term that is used by some European workers to
designate the region of the abdomen behind the last spiracle-bearing
segment. The sac on its dorsal surface is usually divided by a transversely
impressed line which gives in many groups the appearance of two body
segments behind the last spiracle-bearing segment. The Cetoniinae lack
this transverse impression and appear as having but a single segment be-
hind the segment which bears the posterior spiracle.

SETATION

The Passalidae, Lucanidae, and some Scarabaeidae, such as Pinotus,
are sparsely provided with setae scattered over the body. They are usually
lacking in short, stiff spines, except on the ventral part of the last abdominal
segment. Most of the Scarabaeidae have in addition to the scattered
setae a varying number of rows of short, stiff spines that are more.notice-
able on the dorsal annulets of the anterior body segments and become
less dense on the posterior segments. Amphicoma (Fig. 139) is especially
densely setaceous, and all degrees occur between its condition and that
of Passalus. The setation of the last ventral segment presents a wide
difference in the arrangement of the various spines and setae (Fig. 138
to 191), which have been made use of in the keys in the taxonomic section
of this work. These will be described under the term “radula.” Arrow
(1910, p. 11) points out that the spines on the body aid in progression “‘and
probably also render the grub a less agreeable article of food.”’ It is well
known that many Cetoniinae do not use their legs but crawl on their backs,
and in this they are aided by the dorsal spines.

RADULA

The radula (Fig. 138 to 191) is the rake made up of the spinose and
setose area located on the ventral aspect of the last abdominal segment.
The function of this structure was described by the writer (1927) as serving
as a rake to clean the mouthparts. Ritterschaus in a paper appearing a short

42 ILLINOIS BIOLOGICAL MONOGRAPHS [126

while later (1927) suggests the same function. The radula may or may
not possess a median, longitudinal, double row of non-articulating spines,
usually recumbent, and with their apices directed toward the median line.
Frequent use of the presence or absence of this character is made in tax-
onomic keys. The setae of the radula are articulate and may or may not
be hooked at their tips. This group of setae is frequently figured by workers
with white grubs. It has had no name and as far as was previously known
no function had been suggested for it. In a study of the digging habits of
white grubs in observation cages the writer has frequently noticed the
grubs making use of this structure to rake off the mouthparts, which
often become covered with soil as the larvae burrow through the soil,
especially if it is very wet and sticky. Since the general term ‘“‘ventral
aspect of the last abdominal segment” is cumbersome, it is preferable to
speak of it as the rake, or radula. The radula does not differ strikingly in the
second or third instars, but in the first instar it is not well developed and
some of the spines and setae are wanting.

THORACIC LEGS

The legs (Fig. 101, 102, 135, 136, 137) are normally three pairs, but
Passalus (Fig. 3, 137) has only two well-developed pairs, with the posterior
or metathoracic pair greatly reduced and specialized to function as an organ
of stridulation. The nature of this organ and of somewhat similar modifica-
tions, but without reduction in size of the metathoracic leg, as occurring in
the Lucanidae, the Trogidae, and some Scarabaeidae will be described later
when the stridulating organs are discussed.

Following the interpretation of the parts of the leg (Fig. 101, 102) as
given by Béving (1921) in his description of the Japanese beetle, we find
a long, cylindrical coxa (cx) followed by a short trochanter (ir). The
femur (fm) is long and slightly clavate, while the next segment (¢) is
interpreted as the tibia with the tarsus either absent or, what is more
probable, fused with the tibia, since this structure bears the single tarsal
claw (cl). Arrow (1910, p. 11) considers the claw-bearing segment as the
“tibio-tarsus,’’ assuming that the two parts are fused into the one part.
It is difficult to say what part is homologous to the small, stridulating leg
of the metathorax in the Passalidae. In the Coprinae no tarsal claw is
present.

In most cases, the anterior pair of legs are the shortest, the intermediate
pair next in length, and the last pair the longest. The legs are not used
to a great degree in walking but are important aids in digging through the
soil. As pointed out previously, the Cetoniinae do not use their legs in
walking but thrust them in the air and crawl on their backs.

—

127] LARVA SCARABAEOIDEA—HAYES 43

4

SPIRACLES

The spiracles (Fig. 122, 123), although not closely studied, are probably
characters of importance for the larger groups. Béving (1921) has de-
scribed them in some detail for Popilla japonica and some allied forms,
and Boas (1893) has written concerning the histological features of Euro-
pean Melolonthinae. Schiddte (1874) has also figured the minute structure
for some European species. Each spiracle is usually surrounded by a well-
defined peritreme (fp). The peritreme in Trox (Fig. 123) is not so well
defined and does not resemble that of other species. Normally the peri-
treme is a half-moon or nearly circular in form. It encloses an area known
as the bulla (6). The peritreme is usually provided with minute openings
or pores. (See the drawings of the two authors cited above.)

The thorax has but one pair of spiracles, located on the caudal margin
of the prothorax. There are eight pairs of abdominal spiracles, making
nine pairs in all. The meso- and metathorax and the last two abdominal
segments are without spiracular openings.

The arrangement of the opening, or emargination, of the peritreme
differs considerably in the various groups. In Passalus (Fig. 3) the pro-
thoracic spiracle has the open, or emarginate, side of the peritreme on its
cephalic margin; while in the succeeding eight segments the emargination
is on the caudal margin. In most of the Scarabaeidae (Fig. 8 to 12) the
condition found in Passalus is reversed; 7.e., the emargination of the pro-
thoracic spiracle is on the caudal margin and the remaining spiracles have
the peritreme ‘‘open’”’ on the anterior margin. In Pinotus (Fig. 1) and other
Coprinae the emargination of the peritreme of all spiracles is on the ventral
margin. In Trox (Fig. 123) the shape of the area surrounding the bulla
is markedly different from other species. It consists of an indefinite area
dorso-ventrally striated and having no definite emargination of the peri-
treme.

ANAL ORIFICE

The anal opening, frequently called the anal slit, is usually figured in
published illustrations of the radula. It differs considerably in form in the
various groups, and some use of this is made, especially with the Lucanidae,
in the appended taxonomic keys. Davis (1916, p. 266), in listing the various
characters of scarabaeid larvae, refers to the anal slit as “‘obtuse” or “‘trans-
verse.” In the obtuse slit a broad angle is formed, with its vertex directed
ventrally (Fig. 156 to 189), while the transverse slit is nearly straight or
slightly rounded (Fig. 143 to 150). In the Trogidae (Fig. 151) itis Y-
shaped, with three slits converging at a central point. This type represents
an intermediate condition between that found in the Scarabaeidae and
in the Lucanidae. In Sinodendron (Fig. 153) and Dorcus (Fig. 154), as
well as others of the family Lucanidae, the anal slit is made up of three

44 ILLINOIS BIOLOGICAL MONOGRAPHS [128

slits, as in Trox. In Dorcus and others the slits are surrounded by three
more or less conspicuous lobes, which are not so evident in Sinodendron
and Trox. In Passalus (Fig. 152) the slit consists of a long transverse
opening in the middle of which is a short, ventrally directed slit.

Davis (1916) has pointed out that Phylophaga and Polyphylla (Fig.
141) larvae have an obtuse anal slit. The same condition is found in Serica
(Fig. 140) and Macrodactylus (Fig. 142) and probably holds good for most
of the subfamily Melolonthinae. Davis writes: “The grubs of Anomala,
Listochelus, and Phytalis are very close to those of Lachnosterna [Phyl-
lophaga], and we are unable to satisfactorily distinguish between grubs of
these four genera.’”’ In the case of Anomala, they may be separated from
Phyllophaga by the presence of a transverse instead of an obtuse anal
slit. Apparently most of the larvae of the Scarabaeidae have a trans-
verse slit, for such is the condition of the specimens examined in the sub-
families Rutelinae (Fig. 144), Dynastinae (Fig. 145), Cetoniinae (Fig. 148
to 150), Aphodinae (Fig. 138), and Glaphyrinae (Fig. 139).

It is of interest to note that Riley (1870, p. 295) in a description of the
larva of Pelidnota punctata has figured the anal slit of some lucanid which
occurs in decaying wood as does also the larva of Pelidnota punctata.
He apparently found a newly transformed adult of Pelidnota which he
associated with the larva of the lucanid that is figured in his article.

ORGANS OF STRIDULATION

The organs of stridulation in lamellicorn larvae are of two types:
those of the mouthparts, which are developed on the mandibles and
maxillae; and those of the legs, in which the middle and hind legs are
modified for stridulation. The stridulating organs of the mouthparts are
confined to the Scarabaeidae and differ somewhat in some of the sub-
families. The Lucanidae, Trogidae, and Passallidae have no stridulating
organs on the mouthparts but have the legs modified to produce sound.
Schiddte (1874) was the first to describe these organs, although DeHaan
(1836) had previously figured the striae on the mandibles. Schiddte’s
description of these structures in the Scarabaeidae is as follows:

“Chez les larves des Dynastides, des Cétonides, des Rutélides, des Mélonlonthides, des
Séricides et des Coprides, il se trouve, sur la face supérieure de la tige maxillaire (stipes maxil-
larium), une créte longitudinale munie d’une rangée de dents desposées de maniére 4 pouvoir
atteindre et racler, par le mouvement d’avant en arriére des maxilles, des granulations
spéciales diversement placées et groupées sur la face inférieure des mandibules.

“Les granulations des mandibules chez les larves des Dynastides et des Cétonides (X ylotry-
pes, Oryctes, Parastasia, Cetonia, Osmoderma) sont rangées en cétes transverses assez fortes
et formant une plaque 4 peu prés elliptique, nettement circonscrite, située vers la base des
mandibules, en dehors de la partie molaire. Les larves des Rutélides (Anomala, Phyllopertha)
different seulement par leurs c6tes beaucoup plus fines, plus numbreuses et plus serrées.
Chez les Mélolonthides (Melolontha, Rhizotrogus), des Séricides (Serica) et des Coprides
(Ateuchus, Aphodius, Ammoecius), les granulations des mandibules ne sont pas rangées en

129] LARVAL SCARABAEOIDEA—HAYES 45

cétes. Chez les larves des deux derniéres tribus, elles sont d’une petitesse extréme et placées
prés de la base des mandibules; chez les larves des Mélolonthides, elles sont plus visibles et
occupent un espace transversal au milieu des mandibules.”

His article continues with a description of the stridulating appara-
tus on the legs of Passallidae, Lucanidae, and the genus Geotrupes of the
Scarabaeidae.

The mouthpart stridulating apparatus, found only in the Scarabaeidae,
consists of two types, one being more highly developed than the other.
In the larvae of all Rutelinae, Dynastinae, and Cetoniinae examined, there
appears on the caudal aspect of each mandible a minute series of sharp
ridges, transversely arranged (Fig. 81, 82, 83, 87, 88). The longest ridges
are the median ones. The others become gradually shorter to give the
whole a uniform oval appearance. Opposite to these ridges of the man-
dibles, on the cephalic aspect of the stipes of the maxillae, is a row of teeth,
which, in some cases, are decidedly blunt (Figs. 118 and 124), in others,
long and pointed (Fig. 111), and in still others, long, pointed, and decidedly
curved (Fig. 113) toward the distal extremity of the maxilla. They differ
’ in number in different genera. They have not been given careful con-
sideration in this study, but it was noted in Anomala kansana that one
maxilla bore six curved teeth (Fig. 113) while the opposing maxilla had
but one (Fig. 112). One maxilla of Phyllophaga crassissima (Fig. 118)
had fourteen short, truncate teeth; Ligyrus gibbosus (Fig. 124) had thirteen;
Cotalpa lanigera (Fig. 114) five; Euphoria inda (Fig. 125) six; and Amphi-
coma sp. (Fig. 111) ten. These teeth, by movements of the mouthparts,
rasp against the ridges on the mandibles to produce a “faint high-pitched
note” (Arrow, 1910, p. 11).

In the subfamilies Coprinae and Melolonthinae the ridges of the
mandibles are lacking, and in their places is a minutely rugose surface
which is indefinite and difficult to discern (Fig. 84, 85). According to
Arrow (1910, p. 12), this apparatus is comparatively imperfect and it
“has not yet been definitely ascertained what sound, if any, is produced
by these.’’? The writer has never heard Phyllophaga grubs produce any
sound.

In the genus Geotrupes of the Scarabaeidae, Schiddte and Arrow have
both described the leg type of sound production, which is similar to that in
the Lucanidae. Arrow points out that the hind leg is considerably shortened
and “the joints appear solidified, while from the base to the tip runs a
row of sharp horny teeth.” These rasp against a horny area at the base
of the second pair of legs, which is provided with a series of fine ridges.
The rasping structures in this genus, being on the middle leg, are reversed
from similar organs in the Lucanidae in which the file, or series of ridges,
is on the hind leg. The writer has not seen specimens of Geotrupes larvae.

In the Lucanidae (Fig. 135, 136) there is a strongly chitinized area on

46 ILLINOIS BIOLOGICAL MONOGRAPHS [130

the coxae of the middle pair of legs which is covered with small sharp spines
or tubercles. On the trochanter of the hind legs is an elongated file com-
posed of a series of transverse ridges. The trochanter of the posterior legs
is drawn across the coxae of the middle legs to produce sound. The stridulat-
ing organ of Passalus cornutus (Fig. 137) is frequently figured in discussions
of sound organs because of the unique reduction in the size of the hind pair
of legs, the parts of which are reduced to small paw-like structures that are
provided with a series of small hooks which are drawn across a microscopic-
ally ridged chitinous plate on the coxae of the middle pair of legs. Gravely
(1916, p. 139), in a discussion of oriental Passalidae, states that the larvae
are all much alike. He figures an oriental species much like our Passalus
cornutus of North America, which has this modification of the larval leg
for stridulation.

Gravely (1915, p. 498) has described the action of the stridulating
organs of the mouthparts of Oryctes rhinoceros as follows:

“Concerning the action of the stridulating organs of Oryctes rhinoceros nothing yet seems
to have been published. I have had great difficulty in obtaining any evidence as to the use
of the so-called stridulating organ found in the larva. When a specimen is tightly held by the
head, however, it may be seen to move the mandibles and maxillae in a manner likely to
bring the organ into action, and a faint rasping sound may sometimes be heard if the specimen
be brought close to the ear. No definite vibrations have been felt, and the movements of the
mandibles and maxillae are those which would probably be used, in order to free itself, by
any insect similarly placed. Pressure on the body does not seem to induce any such movements
but they are sometimes indulged in by larvae which find themselves on their back on a hard
surface in the open. The movements are often greater in extent than their use for stridulating
purposes requires; the mandibular part of the organ is, indeed, sometimes fully exposed at
intervals, and could not then be scraped at all by the maxillary portion. The rasping seems,
nevertheless, to be produced only when these movements occur. It is therefore probable
that it is produced by the organs in question, and it is noteworthy that the movement of the
mandibles and maxillae is often very small—as it should be to keep the two parts of the organ
in contact—and that this does not interfere with the sound produced.”

e
In conclusion of this consideration of these stridulating organs, it must
be pointed out that Sharp (1918, p. 198) maintains that these mouthpart
structures are “but little adapted for the purpose of producing sound.”

131] LARVAL SCARABAEOIDEA—HAYES 47

POSTEMBRYONIC DEVELOPMENT AND BIOLOGY
OF THE SCARABAEIDAE

Since the writer has had no experience with life-history studies of
the Lamellicornia other than in the family Scarabaeidae, most of the
following statements will be confined to that family. However, it is
of interest to recall that the eggs of the Trogidae are laid in carrion
while those of the Lucanidae and Passalidae are laid in partly decayed
wood. Arrow (1910, p. 20) suggested the possibility of Passalidae being
viviparous, but Gravely (1915, p. 495) states that, on a visit to Berlin,
he called the suggestion of Arrow to the attention of Dr. Ohaus, who im-
mediately refuted it by producing eggs of American species of Passalidae
from his collections.

Eccs

Oviposition Preferences

Among the Scarabaeidae the egg-laying habits are rather diverse,
even within the various subfamilies. The eggs of Canthon laevis are laid ina
ball of dung buried in the soil. Pinotus carolina and Strategus mormon
fill their burrows with manure and afterwards lay their eggs in it. Accord-
ing to Arrow (1910, p. 19), Lefroy has recorded the finding of an egg ball of
Heliocopris dominus eight feet below the surface of the ground. The
progeny of these dung-feeding beetles is not large, some species having been
noted to lay less than a dozen eggs; others are more prolific, as Davis
(1916, p. 263) has noted that individual females of Phyllophaga have been
observed to lay between 50 and 100 eggs. In the writer’s experience, fewer
than 50 eggs was the rule with this genus, but this may be due, in part, to
the type of oviposition cages used. The eggs of Phyllophaga and other
Melolonthinae are laid in the ground, usually in hard, packed soil covered
with vegetation, but collection studies show that they are by no means
confined to this sort of soil for oviposition, as grubs are frequently found in
soil that has been plowed year after year.

Among some Rutelinae (e.g., Cotalpa lanigera) and some Cetoniinae
(Osmoderma spp.) there is an apparent selection of situations for ovi-
position near decaying wood in which the larvae must develop. The
writer has found hundreds of eggs of Pelidnota under decaying logs and has
succeeded in getting Osmoderma to oviposit in soil in cages on which decay-
ing wood had been placed. Other Rutelinae lay their eggs in soil, as do the
Melolonthinae, while many Cetoniinae prefer to oviposit in manure and
other decaying organic matter. Eggs of the Dynastinae are deposited in
decaying organic matter or in the soil about the roots of plants. One
species, Ligyrodes relictus, lays its eggs in decaying hay and straw stacks, as

48 ILLINOIS BIOLOGICAL MONOGRAPHS [132

well as in manure piles; while a related species, Ligyrus gibbosus, lays its
eggs preferably at the roots of sunflowers. The Aphodinae deposit their eggs
in dung, and many species seek out and prefer the excrement of a definite
animal.

Description and Length of Egg Stage

The eggs of the Scarabaeidae, being deposited by individuals of many
sizes, naturally exhibit enough difference in size to make a general state-
ment of little use. It is obvious that the eggs of smaller beetles, such as
Serica, some Diplotaxis, and many others, would be considerably smaller
than the eggs of larger species, such as Dynastes or Strategus. A broad
statement might be made, that they vary in size from one to four milli-
meters. When freshly deposited they are, as a rule, elongate-oval in shape,
being two or three times longer than wide. As development proceeds, there
is an increase in width, so that the eggs just before hatching are much more
broadly oval or nearly round. The color is somewhat variable, even within
the species. Some are milky-white, others are pearly-gray. The chorion
is transparent, so that previous to hatching the dark mandibles and the
segmentation of the body can be discerned through it. With those species
which oviposit in the soil, there is usually found adhering to the eggs a
sticky secretion from the colleterial glands which causes the surrounding
soil to become attached to the eggs and form an enveloping ball of earth
around each egg. This ball is usually broken when searching for eggs in
the soil, but parts of it can usually be seen still clinging to the egg.

Egg laying occurs in the spring and summer months. It may extend
over a considerable period in some species. As far as known, none are
ever carried over the winter. Table I, compiled mostly from the writer’s
observations under conditions as described on page 14, and with the ad-
dition of excerpts from other works, shows the length of the egg stage of the
Scarabaeidae. It is interesting to note that all of the species listed belong
in the four subfamilies of the Pleurosticti, very little being known of the
life histories in the Laparosticti.

Egg Burster and Hatching

Many insects possess, in the late embryonic stage, certain spines which
aid in the rupture of the chorion during hatching. These have been called
hatching spines, ruptor ovi, or egg bursters. In the Colorado potato beetle
they consist of three pairs of spines on the thorax, while in other insects
the structure may be a single spine on the head. Ritterschaus (1925 and
1927) has mentioned the occurrence of egg bursters in two species of
European Scarabaeidae (Anomala aenea and Phyllopertha horticola).
The structure is described as two triangular-shaped, chitinized spines;
one on each dorso-lateral aspect of the metathorax. Accompanying the

TABLE I.—THE LENGTH OF THE EGG STAGE IN SCARABAEIDAE

Species

Melolonthinae
Strigoderma arboricola...

Phyllophaga
APPADWS. obs cde sete oe
ipaKtita ss. helo.
MeGrrasa) fo os 2.
Submucida...........
WebEMENS ...)2 5.0)... ./0 «

Longitarsa............
Pretermissa..........

Hirticula var. comosa. .
imiplicita’..( 3...» ..22...3,-

Rutelinae—Tribe Anomalini
Popillia japonica........
Anomala binotata.......
Anomala kansana.......
Anomala innuba........

Rutelinae—Tribe Rutelini
Pelidnota punctata......
Cotalpa lanigera........

Dynastinae
Ligyrus gibbosus........
Ligyrodes relictus.......
Ochrosidia immaculata
Strategus titanus........
Strategus quadrifoveatus
Dyscinetus trachypygus
Dyscinetus barbatus.....
Euetheola rugiceps......

Cetoniinae
Euphoria inda..........
Euphoria fulgida........
Euphoria sepulchralis. .. .
Cotinus nitida...........

Osmoderma eremicola....

Number
of Eggs

Hatching] Maximum} Minimum } Average

140

Number of Days

Comment

Eggs collected in
field shortly after
deposition.

Data from Smith
and Hadley.

Data from Smyth.

“ “ «

Data from Phillips
and Fox.

Data from Chitten-
den and Fink.
Data from Sweet-

man and Hatch.

50 ILLINOIS BIOLOGICAL MONOGRAPHS [134

spine is a stiff bristle, or seta, about twice as long as the hatching spine.
Since these are discernible through the chorion before hatching and are not
present after the first molt, this author maintains that, by the aid of
muscular contractions, they assist the embryo to break the shell during the
hatching process.

Such a structure has never been described in North American Scara-
baeidae. I have examined many eggs and newly hatched larvae of various
species dealt with in this study and have never been able to satisfy myself
of the presence of any such a specialized structure. It is true that many
strong setae are present, but no strong spine such as described for these
European species can be distinguished. Since Ritterschaus has figured
these through the chorion of the egg and in larvae which have hatched, it
seems probable that further study will show their presence in at least some
North American species. It is quite probable that the many strong setae
located on the back of most of the body segments aid the insect, in some
degree, in its struggle to burst the egg shell.

A scarabaeid egg which is about to hatch can be readily distinguished
by its more oval shape in contrast to the elongate-oval form which it
presents at the time of oviposition. Moreover, before hatching, the embryo
can be seen clearly through the chorion. On the ventral aspect the darkened
mandibles are the most distinct, but the tips of the maxillae and antennae
can be noted. On the lateral aspect the legs and the darkened spiracles are
quite evident, while on the dorsal aspect the body segments and spines can
be observed. The mandibles are frequently seen to open and close under the
chorion, and perhaps they aid other body contractions in the rupture of the
egg shell.

The breaking of the shell occurs across the back in the region of the
thorax and first abdominal segments. Ritterschaus (Joc. cit.) has figured
this split as coming directly across the metathorax in the region of the
egg burster. The break continues until the dorsum of the thorax is exposed,
after which the head is freed and the shell is worked backwards over the
end of the abdomen. In rearing cages, many of these newly hatched grubs
are unable to remove this shell from the dorsal segments of the abdomen
and can be observed carrying it about with them. Sometimes a portion of
the shell is cast off over the head. In many instances, newly hatched grubs
die before they can entirely free themselves of the egg shell. In a few cases
these newly hatched larvae were seen to be feeding on the shell.

LARVAL DEVELOPMENT

Molting
Ecdysis occurs twice before the pupal molt. In two-year grubs as
observed, the two molts previous to pupation occur, as a rule, during the
same season that the egg is hatched, but rarely the second molt may be

135] LARVAL SCARABAEOIDEA—HAYES 51

delayed until the following summer. Among the three-year grubs, only the
first molt occurs during the season the egg is hatched, and the second occurs
the following year. To illustrate: two-year grubs hatching in 1928 would
molt twice in 1928 as a general rule, but in a few instances the second molt
would be delayed until 1929. The three-year species hatching in 1928 would
molt once during the summer of 1928 and once in 1929. All of the grubs
molt again at pupation, and generally the pupa lies within the exuvia.

In species having a one-year cycle the customary two molts occur
during the growing season of summer and autumn. Occasionally, in Cotalpa
lanigera, the grubs may undergo three molts before becoming prepupae.
The time from hatching to first molt in Cotalpa averaged 23.6 days for 49
individuals, and 282.8 days from the first to the second molt, with extremes
of 28 and 326 days; that is, some individuals molted the second time
during the season in which they hatched and others delayed the second molt
until the following season. The period from the second to the third molt
varied from 41 to 292 days, with an average of 143.8 days. In no instance
was the third molt observed to occur the first season after hatching, but a
sum of the three minimum periods shows that it may be possible for the
grubs to have their third molt 89 days after hatching. The low minimum
of 41 days between the second and third molts was noted in cases where the
second molt occurred the second season, and the maximum of 292 days is
secured in those instances where the second molt occurred the first season
and the third molt the second season.

The period between the second molt and the time of becoming prepupa,
therefore, depends upon whether or not there is a third molt. In 19
instances where the third molt was absent, the length of the instar varied
from 66 to 432 days, with an average of 334.6 days. In only one case was
the time between the third molt and prepupation noted. This individual
had molted twice the first season, and the third molt occurred the second
summer. There were 379 days between the third molt and prepupa (fourth
instar). In all cases (five) where a third molt occurred, the grubs were
destined to be three-year grubs. The active larval period varied from 362 to
743 days in 21 cases noted.

The length of each instar, or the period between molts, in the genus
Phyllophaga, has been taken as the normal period between molts in those
individuals having but two molts before pupation. These data are sum-
marized for a few of the representative species in the tables which follow.
In Table II is given the average length of time between hatching and the
first molt for the species listed. In addition, the maximum and minimum
numbers of days between these phenomena are noted, as well as the num-
bers of individuals under observation. In no case was the minimum period
under 11 days (P. bipartita), and the longest period occurred in the same
species, where 63 days were required before the first molt. The average
period ranges from 28 days (P. affabilis) to 45 days (P. vehemens).

52 ILLINOIS BIOLOGICAL MONOGRAPHS [136

TABLE II—INTERVAL BETWEEN HATCHING AND FIRST MOLT
IN PHYLLOPHAGA

Number of Days

Sheet Number of
pecies ae
Individuals Maximum Minimum Average

P. praetermissa 16 49 19 35.8
P. bipartita 100 63 11 39.9
P. vehemens 2 47 43 45
P. corrosa 237 58 17 39.4
P. hirticula

var. comosa 41 46 26 35.5
P. crenulata a 54 35 44
P. affabilis 33 44 23 28
P. tristis 22 52 22 33.9
P. longitarsa 67 42 17 24.1

The length of the second instar is more variable, as is to be noted
in Table III, which includes species with a one, two, or three-year life
cycle. In general it may be said that the one-year and two-year species
listed correspond more closely, in the length of the second instar, to the
periods given in the minimum column, while the three-year species and
some two-year species more nearly approximate the maximum dates. The
shortest period noted for this instar was 7 days (P. corrosa) and the longest
was 374 days (P. praetermissa). This means that the second molt may occur
as early as 7 days after the first or as late as 374 days.

TABLE III—INTERVAL BETWEEN FIRST AND SECOND MOLTS
IN PHYLLOPHAGA

gua. Number of Number of Days
Individuals Maximum Minimum Average

P. praetermissa 16 374 20 263
P. bipartita 34 335 284 39.9
P. vehemens 2 314 28 171
P. corrosa 136 326 7 218.1
P. hirticula

var. comosa 41 323 266 294
P. crenulata 1 284 284 284
P. affabilis 19 304 33 198.8
P. tristis 22 28 10 18
P. longitarsa 67 286 11 69.7

137] LARVAL SCARABAEOIDEA—HAYES 53

To understand the length of the third instar it is necessary, because of
the way in which the data were recorded, to present the figures in two
tabulations (Tables IV and V). A short time before pupation the larvae
cease feeding, shed their meconium, and tend to shrivel up in preparation
for the change to the pupal stage. This is the beginning of the prepupal
stage. The data on the length of the third instar (up to the prepupal stage)
are given in Table IV, and the data on the length of the prepupal stage,
which must be added to the figures in Table IV are given in Table V. It
will be observed that the third instar is much longer than the others and,
as mentioned previously, depends on whether the second molt occurs during
the summer in which the larva hatches from the egg or whether the molt
is delayed until the following summer.

TABLE IV—INTERVAL BETWEEN SECOND MOLT AND PREPUPA
IN PHYLLOPHAGA

Number of Days

Species Number of
Individuals Maximum Minimum Average
P. praetermissa 5 429 320 397.6
P. bipartita 9 423 70 3a/ 2
P. vehemens 2 339 66 202.5
P. corrosa 32 440 97 346.1
* P. hirticula
var. comosa 1 412 412 412

P. crenulata 1 59 59 59
P. affabilis 5 292 35 228
P. tristis 4 372 361 364.7
P. longitarsa 67 388 35 270.6

TABLE V—LENGTH OF PREPUPAL STAGE IN PHYLLOPHAGA

Number of Days
Species Number of
Individuals Maximum Minimum Average
P. praetermissa 15 12 3 6.7
P. bipartita 9 17 x) 9.2
P. vehemens 3 7 7 7
P. corrosa 25 15 2 6.6
P. hirticula
var. comosa 25 16 4 8.7

P. crenulata 2 8 7 7.5
P. affabilis 5 5 4 4.2
P. tristis 3 7 5 6
P. longitarsa 58 16 2 4.1

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54 ILLINOIS BIOLOGICAL MONOGRAPHS [138

Postembryonic Changes

During larval development there are no conspicuous postembryonic
changes. The most marked is the gradual increase in size. This, of course,
varies considerably with the different species. Grandi (1925), ina comparison
of the newly hatched larva and the larva one-year old, says that there is
little difference between them except for dimensions, and goes on further
to point out the slight differences which occur in those characters which
present variation of any importance. These characters are the antennae,
the labrum, maxillae, labial palpi, and abdomen. Of these, he notes that
the antennae become longer and more slender; the labrum presents slight
changes in shape; in the maxillae the change comes in the proportions of
the palpi, and the same is true of the labial palpi and legs. In the abdomen
the changes are more marked in the setation of the last abdominal segments.
For this reason, the characters in the larval key, as herein presented, are
based on third instar larvae, since no satisfactory study has yet been made
of the first and second instars.

In addition to the changes pointed out by Grandi, there is a marked
change in many species in the proportions of the head and body. In the
first instar (Fig. 193) the head is much larger in proportion to the rest
of the body than it is in the second (Fig. 194) or third (Fig. 1 to 12)
Although no definite measurements have been made, it is quite evident,
to one handling and feeding larvae during the summer months, that be-
tween the molts there is a slight increase in the size of the head capsule as
well as a corresponding increase in the size of the thorax and abdomen.
Most of this increase occurs shortly after the completion of ecdysis.

Food Habits

During the course of a series of biological studies of the family Scara-
baeidae carried on at the Kansas State Agricultural Experiment Station,
considerable data were amassed on the relative numbers, as well as the
habitat and food preferences, of larvae of various common species. The
results have been published by Hayes and McColloch (1928). Some of the
data on the food preferences are taken from that publication and presented
here for the sake of completeness. :

Collections of larvae of this family of beetles were begun in 1916
and extended over a period of eight years, including 1923. The specimens
collected were transported to the laboratory and reared to the adult
stage in individual salve boxes in an underground cave. Because of the
difficulty in rearing, and in some cases because of the long life-cycle,
less than one-third of the numbers collected in the field were reared to adult-
hood for determination of the species. During the eight years 18,781
grubs were collected, of which 5,884 were matured under artificial condi-
tions. These 5,884 reared specimens represented 17 genera, with a total of

LARVAL SCARABAEOIDEA—HAYES 55

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56 ILLINOIS BIOLOGICAL MONOGRAPHS {140

37 species. The largest number of species belonging to a single genus was
the 17 species of Phyllophaga. The other genera distributed among the
various subfamilies of Scarabaeidae contained but one, two, three, or four
species.

In Table VI are shown the habitat preferences of all species collected.
These are indicative of the food preferences as a whole but not as related
to the individual species, which are shown in Tables VII and VIII. In
Table VII it is shown that the most individuals of Phyllophaga were taken
in blue grass sod, 234 specimens being found there. The next in preference
is corn land, with 140 individuals, which is closely approached by the 126

TABLE VII—FOOD PREFERENCE OF PHYLLOPHAGA GRUBS

n

see 5

: a E 2 lh ee o |: 3 S

= 15 3)| 8 SB owe aoe ae ues a}/wls5
Sle 810] O laa] e41a fol ee eee

P. crassissima...... 23 | 202 7) 45) —| 94°22) 199) Se) 45 7) of ooo
P. rubiginosa...... 10} 16] 1 18 2116{ 1/1416) 20} 14] 20) 135
PNrugosae iy. aes 18 4} 6] 19] —] 3}—]—| 6] 19] 36] 14} 125
P. lanceolata....... 45 1/ — 5] —j|26; 1;—|— —| 1] 79
P. submucida...... 7} —| 2 6 1 3 | 56 — 1| 3] 79
P.implicata. . ...<. 10 1} 3] 44 Dae ee ae ae
P. hirticula........ —{| —/| 4s] —F}] —!-—-|]-J-—- —}|—|] —
var. comosa... 5/ —]| 9 2}; — 1/—{]—| 6;—] —] 1] 24
P. praetermissa.... 2 8| — —] —] 3}/-—-Jo4—-Ii—-! —l|—-] BB
P. longitarsa....... 3; —-} 4 - Sp 8
P, bipartita........ 1 =| =| = 1 BN 6
Pi futilis:) 2. scr — 2; —]| — 14h. = 4 == Lf — | ed 5
PS COELOSA).5 er ree 1 a | 5
P. glabricula....... —|— —| —| 4/—/;]—7}—|]—| —| 1 5
IPiusca eee ees 1} — 1}; —} —J]—J]-{— — _ 3
P. crenulata....... —!-—; -— 1 —;—}—J] 4 —-]— 1] — 2
Ptristisey aur —}; —; 4 —-!|] —} 1 1}— —|]-—-| -t|— 2
P, affabilis,, ....< :<o7 St he a —| LL) — ) i 1
Lotalicno.ee 126 | 234 | 29] 140] 11 | 74 | 62 | 4 | 50! 46 | 101 | 87 | 964

larvae taken from wheat. Pasture land, with 74 grubs, ranks fifth, and prob-
ably to this type of food should be added a majority of those listed under
the heading ‘‘manure” for in many cases these were found on pasture
land. It is perceivable that P. crassissima, P. rubiginosa, P. implicita,
and P. rugosa are quite generally distributed, while P. lanceolata shows a
preference for wheat first and pasture sod second. The majority of the 56

141] LARVAL SCARABAEOIDEA—HAYES 57

grubs of P. submucida taken under manure were in pasture land. This
species seems to have a preference for the upland soils of the region. The
data on the other species are limited, but from adult collections it is known
that P. longitarsa and P. praetermissa prefer the sand-hill regions along the
rivers while P. tristis is usually taken near the oaks growing on the up-
lands.

The food preferences of other larvae of the family Scarabaeidae are
indicated in Table VIII. In the total numbers reared, wheat shows a pre-
dominance of individuals, with oats and corn following in the order given.
Analyzing the data by species brings out some interesting points. Ochrosidia
tmmaculata is taken far more abundantly in wheat than elsewhere, although

TABLE VIII—FOOD PREFERENCE OF OTHER SCARABAEID LARVAE

wn

3

ge ~ I

= ye o | v0 & S
Species 2/58 s 2 g = Ele | sl sis al
o | o evo} ee Cetee | [ete [PR ea Perera ees Po erie Fi Der) a

SEIZE el sle2Zi 2/S/ElSlsi e181 8
ASlOlO[A al al] AlLOl a f[alola] a

Ochrosidia immaculata.|1787| 32 | 143} 479} 49] 79} 10} 3) 141] 10) 138) 199) 3070

Ligyrus gibbosus...... 125, — | 189) 17; — 4; 11] 2} 19) —| 1) 24] 392
Anomala binotata..... 122} 2 | 1644 4) — le | | es
Anomala kansana..... Z35\~ i By See 2 1S ees 256
Anomala innuba....... Sho PRIG Sei) 488 dd). =) eet
Anomala undulata..... —| 8 =| S|] —f HS Fa Te et 8
Cotalpa lanigera....... 113) — —| 28) —| —) i—- 6-—; —| 1} 149
Pelidnota punctata.... 2| — ee 1} 118
Ligyrodes relictus..... —| i —| —| — 2} 120; —| —j —|) — —| 123
Euphoria inda........ —| — 1) —| —/} — 444-7 —-| -— 4 46
Euphoria sepulchralis..| —| — —| -—| — yp SS SS 9
Aphodius sp........... —| — —| —}- —} =) 53) =] —) So SS
Canthon laevis........ —| — —| —| — ey SS 4
Aromispic ck) She A ed —| — =| | — | HS SH Or SO 122) «122
Polymoechus brevipes..} —| — A fo el
Cremastocheilus nitens.| —| — ee ee il
Ataen usinops........ —+—-—-;/4— 4 -| 4] 4-4-4 — 77 «681
Trichiotinus piger..... — — | | S| 8S Ss ST op 8
Stephanucha pilipennis.| —| — | —| —| — A en 1
Polyphylla hammondi..| —| — rn Ne RI | dd 1

i EE St 2389} 44 | 569] 536] 204 | 143] 248) 17} 167] 11] 142] 450} 4920

it occurs rather abundantly in corn and oats. The adults apparently show
a preference for land that is frequently plowed. Ligyrus gibbosus exhibits
the same preference, being found most often in oats and wheat and less
often in corn land. The same can be said for Anomala binotata, while

58 ILLINOIS BIOLOGICAL MONOGRAPHS [142

A. kansana occurs more frequently in wheat. Cotalpa lanigera occurs in
wheat and corn, usually in the sand-hill area. Davis (1918) has reported
this species doing considerable damage to raspberry bushes, strawberries,
corn, and grasses.

The following species live in fallen logs and stumps: Pelidnota punctata,
Polymoechus brevipes, Trichiotinus piger, and Polyphylla hammondi.
Table VIII shows 21 individuals of Cremastocheilus nitens taken from logs.
These were in ant nests on the surface of the soil under a log on the
sand dunes. Several species show a preference for manure and decaying
vegetation, such as rotten hay or straw stacks. Among these are Ligyrodes
relictus, Euphoria inda, Euphoria sepulchralis, Ataenius inops, and
Aphodius sp. The 122 individuals of Trox sp. listed in the miscellaneous
column were taken under a dead horse.

TABLE IX—COLLECTIONS OF PHYLLOPHAGA AS DETERMINED BY REARING

Year of Collection

Species oe
1916 | 1917 | 1918 | 1919 | 1920 | 1921 | 1922 | 1923 Total
P. crassissima 15 36 40 33 196 52 18 6 396
P. rubiginosa 11 7 15 22 10 41 25 4 135
P. rugosa 14 4 9 33 22 24 14 5 125
P. lanceolata 2 16 9 50 1 — 1 — 79
P. submucida — 2 2 — — — 66 9 79
P. implicita 6 4 4 8 20 1 28 5 76
P. hirticula
var. comosa — 2 —_ —_— 4 18 — _ 24
P. praetermissa = = 3 —_— 8 —_— —_ 2 13
P. longitarsa = 1 4 — _— —_— 3 = 8
P. bipartita — _ 1 3 — — — 2 6
P. futilis _ —_ — — — 2 5
P. corrosa — —_— 2 —_ — 1 — 2 5
P. glabricula — 2 — — — — — 3 5
P. fusca —— — — — — 3 — _ 3
P. crenulata _— _— 1 — — — 1 = 2
P. tristis 1 — — — — = — 2
P. affabilis —_ — — — — 1 — 1
Total 49 74 90 | 149 |°264 | 141 156 41 964

Relative Abundance

J. W. McColloch and the writer, in an eight-year study of scarabaeid
larvae, made collections of grubs in all kinds of situations and reared many
to adulthood. The following discussion of the various collections, for
convenience, is divided into two groups. The genus Phyllophaga, with 17
species represented, will be considered as one unit while the remaining

143] LARVAL SCARABAEOIDEA—HAYES 59

16 genera will be considered jointly. Table IX shows the various species
as to the year in which they were collected and not the year of maturity.
The order of arrangement is based on numbers collected and not on their
relationships.

As shown in Table IX, 964 individuals representing 17 species were
reared from the total of 18,781 grubs of all species collected. Since many
individuals of this genus failed to live through the rearing period, a per-
centage of those reared based on the number collected would be unfair.
However, the percentage reared based on the total species gives an inkling
of the relative proportions of Phyllophaga to other species of the family.
Of the total (5,884) beetles, only 964, or 16.3 per cent, belonged to this
genus. Table IX, as indicated in the column of totals, offers further data
on the relative numbers of all the various species found in the locality con-
sidered. Of the 964 individuals of all species reared, P. crassissima ranks
first, with a total of 396 individuals, or about 41 per cent; P. rubiginosa
ranks second, with about 14 per cent; and P. rugosa third, with nearly 13
per cent.

If we compare the individual total of each species with the total
adults collected during the first seven years (1916-1922) of the eight during

TABLE X—RELATIVE ABUNDANCE OF PHYLLOPHAGA ADULTS
AND REARED LARVAE

Total Adults Comparative
Rank Species Larvae Collected Ranking of
Reared 1916-1922 Adult Abundance
1 P. crassissima 396 31,996 : First
2 P. rubiginosa 135 15,130 Third
3. P. rugosa 125 4,010 Fifth
4, P. lanceolata 79 15,851 Second
5 P. submucida 79 57 Eighteenth
6 P. implicita 76 982 Tenth
7 P. hirticula
var. comosa 24 1,696 Ninth
8. P. praetermissa 13 115 Sixteenth
9. P. longitarsa 8 909 Eleventh
10. P. bipartita 6 35020 Seventh
11. P. futilis 5 10, 362 Fourth
12. P. corrosa 5 3,732 Sixth
13. P. glabricula 5 440 Twelfth
14, P. fusca 3 135 Fourteenth
15. P. crenulata 2 127 Fifteenth
16. P. tristis 2 114 Seventeenth
17 P. affabilis 1 44 Nineteenth
18. P. vehemens 0 2,001 Fighth
19. P. congrua 0 135 Thirteenth

60 ILLINOIS BIOLOGICAL MONOGRAPHS [144

which this study was in progress (see Table X), some interesting facts are
brought out. P. crassissima, the most abundant species among the adults
collected, is seen to be also the most numerous among those species
collected as grubs. P. lanceolata, while second in number of adults, is fourth
in the grub collections. This may be, in part, due to the slightly longer
life-cycle of P. lanceolata (Hayes, 1919). P. rubiginosa, while third among
the adults, was second among the grubs; and P. rugosa was fifth in the
beetle collections and third among the larvae. On the whole, these four
important species rank very close, while greater differences are disclosed
among the other species. An interesting observed fact is that more indi-
viduals of P. submucida were collected as grubs and reared to adults than
were taken in the adult collections. The two species, P. vehemens and P.
congrua, which ranked eighth and thirteenth, respectively, in the adult
collections, were not reared from grubs.

TABLE XI—THE RELATIVE ABUNDANCE OF SCARABAEID LARVAE
OTHER THAN PHYLLOPHAGA

Miscelianeous Year of Collection
Species of SEE ERE eee eee
Scarabaeid Larvae | 1916 | 1917 | 1918 | 1919 | 1920 | 1921 | 1922 | 1923 Total

Ochrosidia immacu-

lata 32 2) 155 255 ih 723 1 S15 OF3 Aa 3070
Ligyrus gibbosus 5 17 2 BN 227 23 | 116 = 392
Anomala binotata 145 4 — — 37 42 47 27 302
Anomala kansana == == 3 1: a54 4 Sy, 37 256
Anomala innuba 1 = 9 45 21 — 15 53 144
Anomala undulata | — — _ — — -- 7 1 8
Cotalpa lanigera = — — — — 1 23, | 125 149
Pelidnota punctata = 2 10 1 1 7 5 92 118
Ligyrodes relictus 13 _ 10 19 1 74 6 ae 123
Euphoria inda — — _- 1 14 6 46
Euphoria sepulchralis} — — 1 — — 4 2 2 a
Aphodius sp = = — — — — — 53 53
Canthon laevis — — — —_ — 4 — — 4
Trox sp. == = — — — — |-— | 122 122
Polymoechusbrevipes} — — — — — ~ 12 = 12
Cremastocheilus

nitens = — 20 — — — 1 — 21
Ataenius inops — —- — _ — -- 81 — 81
Trichiotinus piger = = 2, == 2 1 iT 8
Stephanucha

pilipennis — — -— -- — — 1 = 1

Polyphylla hammondi} — — — — — — — 1 1

Total 221 25 | 212 | 223 | 1167 | 489 | 1352 } 1231 4920

145] LARVAL SCARABAEOIDEA—HAYES 61

In addition to the collections of Phyllophaga, 20 species representing
16 other genera of the family Scarabaeidae are available for comparison
with the genus Phyllophaga. These were, for the most part, incidental to
the white grub collections, but since all that were found were collected,
the data available show the years of abundance as well as the relative
numbers. These data are summarized for the various species and the years
in which they were collected in Table XI. It will be noted that the two most
numerous species are Ochrosidia (Cyclocephala) immaculata (Oliv.) and
Ligyrus gibbosus (DeG.). The number of Ochrosidia reared (3,070 indi-
viduals) far exceeds that of any other species and is more than three times
the number of all Phyllophaga combined, whose total figure is 964. It
must be borne in mind, however, that the one-year life-cycle of Ochrosidia
compared to the two-year and three-year cycles of Phyllophaga makes
rearing much easier with less mortality. Space does not permit a dis-
cussion of all the facts apparent in Table XI, but it will be noted that the
collection contains representatives of the most important subfamilies of
the Scarabaeidae.

Hibernation

Our knowledge of the depth to which such insects as white grubs and
May beetles penetrate the soil to escape the rigors of cold weather, and to
pass their period of hibernation, is limited to a small number of casual ob-
servations. Only a few general statements pertaining to the subject are to
be found in the literature. While writers assert that such-and-such a species
passes the winter “‘below the frost line” or ‘‘below the plow line,” no specific
attention or careful study has been given to the subject. This is due, in
part at least, to the difficulty of studying the habits of insects that live with-
in the soil. Another factor involved, and perhaps the most important, is
the difficulty of making specific identification of the immature stages of
the specimens found in the soil. In most instances they must be reared
through their developmental periods to the adult before they can be
identified. Furthermore, winter studies of insects in the soil require careful
excavation, involving considerable manual labor which must be done during
the coldest and most disagreeable part of the year.

Criddle (1918) records that in Canada the grubs of certain species of
Phyllophaga and allied genera penetrate to a depth of 74 inches, and that
the beetles may burrow as deep as 47 inches during the winter. This state-
ment indicates at what depth grubs may be found in a more northern
climate, but no data are available in regard to the actual depth of the vari-
ous species in the more temperate regions of the United States. No doubt
the climate has a direct bearing on the subject, and the depth of penetration
will vary with the region. In fact, the present study shows that white
grubs do not penetrate as deeply in Kansas as Criddle observed in Canada.
A discussion of the literature of this subject has been presented by McCol-

62 ILLINOIS BIOLOGICAL MONOGRAPHS [146

loch and Hayes (1923), and the following is taken from a discussion by these
writers in collaboration with H. R. Bryson. (1928).

The depth at which these insects pass the winter is important in
connection with the recommendation of fall, winter, or early-spring plowing
as methods of control. In order to make such recommendations intel-
ligently, it is essential to have definite information relative to the depth of
hibernation of the insects. It was primarily to secure data along this line
that the studies reported herein were undertaken. It also seemed desirable
to further check the studies of McColloch and Hayes (loc. cit.) in the fall and
spring reversals of temperature conditions on the surface and subsurface
layers of soil, and the bearing of such changes upon the activities of soil
insects in general.

An attempt was made to rear to the adult stage all grubs taken in this
work. A summary of these rearings is presented in Table XII, which shows
the number of grubs of each species identified and the depths at which they
were taken. The data on Phyllophaga lanceolata, which are incorporated in
this table, were secured from a series of excavations in a wheat field at
Goddard, Kansas, March 13, 1919.

TABLE XII—SUMMARY OF THE DEPTH OF HIBERNATION
OF WHITE GRUBS

Depth in Inches
Species Total
Collected 2 Weighted
Maximum | Minimum Average
All white grubs 1,188 40 3 13-2
Qchrosidia immaculata 101 30 4 13.9
Phyllophaga crassissima 3 17 13 15.0
Phyllophaga rugosa 4 26 10 18.0
Phyllophaga glabricula 3 19 16 17.7
Phyllophaga submucida 1 14 14 14.0
Phyllophaga rubiginosa 1 14 14 14.0
Phyllophaga bipartita 1 15 15 15.0
Phyllophaga corrosa 1 16 16 16.0
Phyllophaga lanceolata 66 20 3 10.3
Anomala innuba 99 15 4 8.9
Anomala ludoviciana 2 30 20 25.0
Diplotaxis sp. 1 15 15 15.0
Bolbocerosoma bruneri 5 15 10 11.6

Table XII brings out the fact that the average depth of hibernation of
all species was below the plow line. In fact, grubs of only two species were
found above the 6-inch level in the work at Manhattan, while a few grubs
of Phyllophaga lanceolata were taken at three to six inches at Goddard.

,

147] LARVAL SCARABAEOIDEA—HAYES 63

While very few determinations were made of the grubs of Phyllophaga
collected at Manhattan, it is interesting to note that all were several inches
below the plow line.

Grubs of Ochrosidia immaculata predominated in practically all collec- -
tions. Out of a total of 101 grubs of this species, only 12 were found above
the plow line. The remaining 89 were found at depths ranging from 7 to
30 inches, with the majority at the 14-inch level.

Of Anomala innuba, which ranked second in number of grubs identified,
99 specimens were taken. This species does not burrow downward to any
great extent for hibernation. The average depth for it was 8.9 inches, with
extremes of 4 and 15 inches. Axnomala ludoviciana, on the other hand,
apparently burrows deeply into the soil, as evidenced by the two specimens
taken at depths of 20 and 30 inches.

Pupation.—In a previous paragraph mention was made of the prepara-
tion made by the larva in anticipation of the transformation to the pupal
stage. This period of inactivity, known as the prepupal stage or semi-
pupal stage, is of short duration before the actual molt to the pupal condi-
tion occurs. The period is characterized by internal activity, a cessation of
feeding, some body shrinkage, and the cleaning out of the alimentary canal.
The final molt having been completed, the pupa has now asumed a condi-
tion more nearly like the adult form. When freshly transformed, the body
is a creamy white, but as development proceeds many of the adult colors
are assumed. Hayes and McColloch (1920) have pointed out that during
the later stages of development sexual differences of the adult may be dis-
tinguished in the antennae and the genitalia, which may be discerned
through the cuticula of the pupa. In many cases, these characters are
apparent throughout the last half of the pupal stage.

Pupation occurs in late summer and autumn in many species (e.g.,
Phyllophaga), and transformation to the adult occurs shortly thereafter,
to enable the insect to pass the winter in the adult stage. Others (e.g.,
Anomala) pupate in the late spring and early summer, and at the end of the
pupal period, after a few days of inactivity, are ready for flight. In the case
of those species transforming in the fall it is usually stated in the literature
that the winter is passed by the adult at the place of pupation, usually
within the exuvia of the pupa. In observations made by McColloch and
the writer there is some reason for believing that many adults leave this
place of pupation and burrow beneath the frost line.

No systematic study has been made of the pupae of the Lamellicornia
and no keys are available for their identification. Causal observation indi-
cates that there are many differences, and when enough material becomes
available it may be possible to describe their recognition characters. It
is noteworthy that most pupae of the Melolonthinae are characterized by
a pair of pointed caudal appendages, while Anomala and a number of other

64 ILLINOIS BIOLOGICAL MONOGRAPHS {148

genera have a rounded, blunt caudal end. Without going into details
of the morphology of the pupa, it is sufficient to point out that most of the
external characters of the adult are apparent (Fig. 195).

The Passalidae and Lucanidae pass the pupal period in the decaying
wood in which they develop. The coprophagous Scarabaeidae, as a rule,
pupate and remain within the ball or mass of manure in which the larvae
have developed, while higher Scarabaeidae may merely lie within the molt-
ed larval exuviae in the soil. A number of Scarabaeidae, such as Pelidnota
punctata and many Cetoniinae (e.g., Euphoria), construct a cocoon in which
the pupal period is undergone. In the case of Pelidnota, the cocoon con-
sists of fragments of wood, while in the Cetoniinae (e.g., Euphoria) it is
made of bits of manure in which the larva grew. Others may use the soil
or root-fibers. These cocoons, made of the food material, are oval in form.
The outer surface is rough while the inner walls are smooth and polished.
They are built by the larva before the transformation of the pupal stage,
and the material which holds the structure together is a glandular secretion
ejected from the hind intestine. The larva, by its mouthparts and body
movements, is able to mold the material into a compact water-tight cocoon.
The length of the pupal stage in the many species varies from a week or
more to a month and even longer in cooler weather. Emergence is accom-
plished by a splitting of the cuticula along the back.

LENGTH OF LIFE-CYCLE

Melolonthinae

The length of the life-cycle in the subfamily Melolonthinae is extremely
variable. It has long been known that Melolontha melolontha requires three
years for development in France and southern Germany and four years in
northern Germany. In Mauritius it has been found that Phytalus smithi
Ar. has a life-cycle of slightly over one year (De Charmoy, 1912).

Although the species of Phyllophaga have been known as important
pests for a number of years, only scanty information has been available
concerning their life-histories, particularly with reference to the length of
the various stages. This is due, in a large measure, to the fact that practi-
cally all of their period of development is spent beneath the surface of the
soil, where it is difficult to observe their life activities. Chittenden (1899)
was the first to report the rearing of a species of this genus. He found, in
the case of one individual of P. fervida, that 781 days were required from
the date of egg laying to the transformation of the pupa to the adult. This
makes a life-cycle of three years for the species if the winter period of adult
hibernation is included. Davis (1916), reporting on the length of the
life-cycle of 18 species of the genus, notes in his summary that one species,
P. tristis, invariably has a two-year period in the region of Lafayette,
Indiana, and eleven other species, namely, P. fervida, P. fusca, P. vehemens,

149] _ LARVAL SCARABAEOIDEA—HAYVES 65

P. rugosa, P. ilicis, P. grandis, P. fraterna, P. hirticula, P. inversa, P.
bipartita, and P. congrua, without exception, have a three-year life-cycle. .
Two species, P. crenulata and P. crassissima, have a three-year cycle that
may be extended to four years, and certain other species, as P. futilis, P.
ephilida, and P. implicata, ordinarily have a three-year cycle that is often
reduced to two years. From this it can be seen that the more important
species have, in the latitude of Lafayette, a three-year cycle. Smyth (1917)
has found that the life-cycle of P. vandinei occupied approximately one
year in Porto Rico. These citations contain practically all our knowledge
of the life-cycle of members of the genus, and except for the work of Smyth
very little has been learned concerning the length of the immature stages.

In a study of the life-history and development of white grubs carried
on by the writer in Kansas, seventeen species of the genus Phyllophaga
were reared in varying numbers from the egg to the adult state. The devel-
opment of one species, P. lanceolata, was described in 1919 and six others
in 1920. In 1925, ten others were described and a comparison of their devel-
opment made with those previously reported. To generalize, it can be
asserted that the results are in accord with those of Davis in showing a
decided variation of the length of the life-cycle in most of the species, this
variation being found in the length of the larval period. For example, some
species have, in the vicinity of Manhattan, Kansas, either a one-, two-, or
three-year life-history.

With the exception of four species, P. affabilis, P. submucida, P. longi-
tarsa, and P. lanceolata, all of the Phyllophaga reared by the writer pupate
in the fall and pass the winter as adults. Accordingly, in considering the
life-cycle, eight or nine months should be added to the figures presented
in the following table to arrive at the total period of life from the time of
oviposition to the normal time of death. In the four exceptions noted above,
pupation occurs in the spring or early summer and the adults emerge soon
after transformation.

To further compare the life-cycle of Phyllophaga, it should be noted
that Davis (1916) found a two-year cycle in P. tristis and P. lanceolata; a
two- and three-year period for P. burmeisteri, P. futilis, and P. implicata;
a three-year period for P. arcuata, P. bipartita, P. congrua, P. fraterna, P.
fusca, P. grandis, P. hirticula, P. ilicis, P. inversa, P. rugosa, and P.
vehemens; and a three-year and possibly a four-year cycle in P. crassissima
and P. crenulata.

Smyth (1917), in Porto Rico, found for 14 complete records of P. van-
dinetSmyth an average period of 306 days from egg to adult with a maximum
of 395 days and a minimum of 212 days, or expressed in months, from
seven to thirteen months with an average of about ten months. Except in
the case of P. tristis, this is one of the shortest life-cycles reported. It is
somewhat shorter, but is probably comparable to the one-year periods of

66 ILLINOIS BIOLOGICAL MONOGRAPHS [150

P. affabilis and P. longitarsa as here recorded. Criddle (1918) reports
that P. nitida, P. drakii, P. anxia, and P. rugosa have in Manitoba,
Canada, a four-year life-cycle, but gives no definite data on the length of
the various stages.

Based on actual rearings by the writer, the summaries of the life-cycles
of the 17 species under observation are given in Table XIII.

TABLE XIII—SUMMARY OF THE LIFE-CYCLE IN THE GENUS PHYLLOPHAGA

Number of Days from

: Number of Egg to Adult Life-cycle
Species Individuals :
— ————_]_ in Years
Reared Maximum | Minimum | Average
Prafiabilisse ie. ee Ses 4 389 369 376.6 1
Pabipartite: 2)..3. oebla 2: 3 815 495 703.0 2 and 3
iPAConrosaee she ate 19 791 429 501.8 2 and 3
P. submucida............ 13 734 708 720.3 2
P. vehemens............. 3 838 459 591.3 2 and 3
PMbristiseae, Hc Me el ce 4 474 137 380.0 1 and 2
Pephuscan mn eekey 3chy eae 1 461 461 461.0 2
PNcrenulatasy sce. lot 1 424 424 424.0 Z
POON IESESS «ois eho ds 48 701 327 356.4 2 and 3
P. praetermissa.......... 2 811 434 628.5 2 and 3
IPSrugsOsaleiae icy Mee ce cine 21 836 445 735.7 2 and 3
P. rubigmosa 22) 010.0 7... 29 839 447 791.5 2 and 3
Blanceolatass ais sae 23 723 357 675.7 1 and 2
Beh tilise eter ste eee 16 494 457 469.7 2
PEVGrassisSiitita, es. t) 81 816 449 588.3 2 and 3
P. hirticula var. comosa... 2 789 780 784.5 3
Peynnvscatad. ee ace 22 790 442 470.4 2 and 3

Other members of the subfamily are little known. The rose chafer,
Macrodactylus subspinosus, has been studied and found to have a one-year
life-history. Other important genera, such as Polyphylla, Serica, Diplo-
taxis, and Dichelonyx, are practically unknown as far as knowledge of their
life-history is concerned. ;

Rutelinae

It is evident that there are two distinct types of development in the
two tribes of the subfamily Rutelinae. In the tribe Anomalini there appears
to be invariably a one-year life-cycle, while in the tribe Rutelini it is known
that at least two years and often three years are needed to complete the
life-history.

In the Anomalini, Hadley (1922) has pointed out that Popillia japonica
requires one year to develop. The writer (1918) has shown that Anomala
binotata matures in one season. The larvae require, on an average, 83

151] LARVAL SCARABAEOIDEA—HAYES 67

days to develop, and pupation occurs in the fall. On the contrary, Anomala
innuba normally matures in the spring, but only requires one year to com-
plete growth. Two instances were’ noted wherein the larvae of A. innuba
pupated in December. Anomala kansana also has a life-cycle quite similar
to that of A.imnuba. It has also been shown (Hayes, 1921) that Strigoderma
arboricola Fab., another Anomalini, has a one-year life-cycle, in which
development is completed in from 351 to 358 days. In this case the larvae
pass the winter and pupate in the spring. In the tribe Rutelini, Pelidnota
punctata requires two years to mature, while Cotalpa lanigera needs either
two or three years (Hayes, 1925). A summary of the life-cycle in this sub-
family, based mostly on rearings by the writer, is given in Table XIV.

TABLE XIV—SUMMARY OF THE LIFE-CYCLE IN RUTELINAE

Number of Days from

a Egg of Adult Life-cycle
Species Individuals a ae
Reared Maximum |} Minimum } Average
Anomalini
Anomala binotata —_— 100 119 — 1 year
Anomala innuba — 330 356 342.9 1 year
Anomala kansana 16 376 339 368.3 1 year
Strigoderma arboricola 4 got 358 — 1 year
Popillia japonica* = = — _— 1 year
Rutelini
- Pelidnota punctata 1 698 698 698 2 and prob-
ably 3 years
Cotalpa lanigera 21 416 806 604.6 |2and3 years

® Data on maximum and minimum periods not available.

Dynastinae

The subfamily Dynastinae is remarkable for the fact that it contains
some of the largest coleopterous insects. One has only to recall such genera
as Dynastes and Strategus to realize this fact. The group contains a num-
ber of species whose depredations on crops make them of considerable
economic importance, especially in the southern part of the United States
and in the West Indies. One species, Ochrosidia (Cyclocephala) immaculata
Burm., is very injurious in the larval stage to the roots of staple crops in
the central states; and another, Ligyrus gibbosus DeGeer, known as the car-
rot-beetle or muck-worm, is destructive in the adult stage to carrots,
sunflowers, and other plants. Both of these have been under observa-
tion during the course of this study. Ochrosidia immaculata has been reported
under the name of Cyclocephala villosa (Hayes, 1918) and the life-cycle
was given as one year. Likewise, Ligyrus gibbosus was found (Hayes, 1917)

68 ILLINOIS BIOLOGICAL MONOGRAPHS [152

to have a one-year life-cycle. Ochrosidia differs from Ligyrus in passing the
winter as a larva and maturing in the spring.

Smyth (1916) has reported on the period of development of five species
representing three genera of this subfamily. He found that Strategus titanus
Fab., in Porto Rico, required an average of 338 days to reach maturity,
Strategus quadrifoveatus Beauv. required slightly over one year, and Ligyrus
tumulosus only 77 days. Two other species, Dyscinetus trachypygus and
Dyscinetus barbatus, complete their growthin 104 and 144 days, respectively.
Phillips and Fox (1917) report the development of Euetheola rugiceps in
about 88 days. Smyth (1920) made further reports on the life-cycle in
Strategus.

The writer has reared three species of this subfamily, Ligyrodes relictus,
Ligyrus gibbosus, and Ochrosidia immaculata. A summary of the chief
points of interest in their development is given here.

Adults of L. gibbosus are present-in the soil throughout the winter and
early spring. During the latter part of April or the first few days of May,
and continuing throughout the summer, they emerge at night and fly to
lights, returning to the soil before daybreak. During the summer of 1916,
eggs were plentiful from the last of May to late in July. Larvae were present
from June throughout the remainder of the summer and early fall, and
pupae from the last of July to the last of October. The length of each
stage of development is shown in Table XV.

Ligyrodes relictus is to be regarded as a beneficial species, living as it
does in manure and rotting haystacks and thus materially hastening the
processes of decomposition. Smith (1902) reported the beetles injuring the
roots of hardy pyrethrums and the roots of sunflowers, but his statement
that the species is smaller than the ordinary June-bug and more roughly
sculptured, leads to the suspicion that his determination was incorrect.
These two characters and the habit of attacking sunflowers would suggest
that Ligyrus gibbosus was the species in question. Smith appears to be the
only writer who considers Ligyrodes relictus as an injurious species. There
are no citations in the literature treating of the life-history of the species,
and scarcely any habits are mentioned except that the beetles and grubs
live in decaying vegetable matter. The average periods of development of
the different stages have been found to be: for the egg stage, 9.3 days;
the active larval period, 46 days; the prepupal period, 4.1 days; and the
pupal period, 13.1 days. The total of 72.4 days for complete development
thus approximates very closely the full period computed from the length of
the different stages. Davis (1916) has reported that the species develops
in one year, but gives no data on the length of stages. The beetles appear
above ground in April or May for the spring flight, returning to the soil
each day, where mating occurs. They disappear for a short time in June

153[ LARVAL SCARABAEOIDEA—HAYES 69

and July, and the new brood appears in July and August for a second period
of flight.

The genus Ochrosidia (Cyclocephala) contains some of our common and
most injurious white grubs. Forbes (1891, p. 40) reports the grubs of O.
immaculata infesting grass-land, corn on sod, roots of corn, and young oats.
Titus (1905, p. 14) found them at the roots of grass and sugar-cane stubble,
and Riley (1870, p. 307) recorded them in strawberry beds. Davis (1916,
p. 264) states: “Cyclocephala immaculata is frequently found in compost
heaps and in cultivated fields, and may obtain its full growth on decaying
matter alone or may become a serious field pest, damaging crops similar
to those attacked by Lachnosterna grubs.’’ To summarize, the life-cycle of
O. immaculata is one year. Adults appear at lights in June, July, and early
August. Eggs, which are laid in soil, hatch after 9 to 25 days. The larva
passes the winter in hibernation. The larval stage was found to average
347 days. The pupal stage varied in length from 8 to 24 days.

A comparison of the life-cycles of these three species with others re-
ported in the literature is given in Table XV. In this table it is to be noted
that, of the species whose life-history is known, the average period of devel-
opment ranges from 72 days, or slightly over two months for Ligyrodes, to
430 days, or more than a year, for Strategus quadrifoveatus.

TABLE XV—SUMMARY OF THE LIFE-CYCLE IN DYNASTINAE

Egg to
Egg Stage Larval Stage Pupal Stage ‘Adult
Species z ————_—_——
Aver- ‘ Mec _ |Aver- ,
age Max.| Min.} age | Max.| Min. age Max.| Min.| Average

Ligyrodes relictus 9 |] 11 8 5b 2 |e" S| 26 9 72
Ligyrus tumulosus® U8) | 55; —] —|14)]—]— 77
Ligyrus gibbosus 10 | 22 7 59} 80| 43] 19 | 29} 11 88
Ochrosidia immaculata 1S 2S bird 3 | BAF SBA BSS ike Ba QF in BS 379
Strategus titanus* Vfl vc 2 beled 5h SAS olga ea DS |p DA tem 338
Strategus quadrifoveatus*| 20 | — | — | 385| —] —| 27} —] — 430
Dyscinetus trachypygus* | 12 | 18 } 10 81}; —| —] 13 16: }° 12 104

Dyscinetus barbatus® 13 | — | — | 106} —| — | 15 | 18 |} 13 144~
Euetheola rugiceps> 144, —]— 60; —| —| 4) —)}] —- 88

® Data from Smyth (1916).
b Data from Phillips and Fox (1917).

Arrow (1910, p. 259), in his summary of the habits and metamorphoses
of this subfamily, points out the following facts. They are mostly confined
to the warmer climates and are of somewhat retiring habits, and our know-
ledge of their metamorphoses and modes of life is exceedingly scanty. With
but few exceptions they are nocturnal or crepuscular and are not easily

70 ILLINOIS BIOLOGICAL MONOGRAPHS {154

found, and in few cases have their early stages been traced. He points out
the increase in the size of the eggs, which is discussed on a previous page, as
being characteristic of most scarabaeid eggs. Further comment is made that
the larvae “‘do not differ in any marked degrees from those of the Cetoniinae
and allied subfamilies,” and like the Cetoniinae feed upon decaying vege-
table matter, and sometimes upon living roots or woody tissues. A discus-
sion of the nest-building habits of Strategus antaeus, as quoted from Manee
(1908), shows these larvae to feed first on leaves stored in the nest and then
probably on oak roots. Various Dynastinae are known to feed on the roots
of grasses, one is known to destroy the roots of sugar cane, and Oryctes
nasicornis is found in the refuse-heaps of tanneries, where the larvae feed
on the decomposed bark.

Cetoniinae

Several members of the subfamily Cetoniinae are injurious to vegeta-
tion in the United States. Chief among these are the bumble flower-beetle,
Euphoria inda, and the green June-beetle, or fig-eater, Cotinus nitida. Asa
rule, the mandibles of the adults of this subfamily are poorly developed
and are fitted only for the eating of such light foods as pollen and sap.

There is very little American literature on the life-history of American
species of this group. Euphoria inda is commonly assumed, and probably
correctly, to have a one-year life-cycle, and the green June-beetle, Cotinus
nitida, has been reported by Chittenden and Fink (1922) to have a one-year
period of development. In the present study, a number of species have
been under observation, such as Euphoria inda, Trichiotinus piger, Osmo-
derma eremicola, and Cremastochelius nitens. The life-cycle of none of these
has been completely worked out, but two species, Euphoria fulgida and
Euphoria sepulchralis, have been carried through to maturity and the re-
sults are here summarized (Hayes, 1925).

TABLE XVI—SUMMARY OF THE LIFE-CYCLE IN CETONIINAE

Number of Days from

: Egg to Adult Length of
Species Se eh ok A SR a A Td SS Life-cycle
Maximum Minimum Average
Euphoria fulgida 434 323 381.3 1 year
Euphoria sepulchralis 123 74 92.9 1 year
Euphoria inda — —_— — 1 year
Cotinus nitida® — — _ 1 year
Osmoderma eremicola> —_ — —_ 3 years

® Data from Davis and Luginbill, 1921.
> Data from Sweetman and Hatch, 1927.

155] LARVAL SCARABAEOIDEA—HAYES 71

Arrow (1910, p. 24) says of this subfamily, “Of the metamorphosis and
habits of the species we know lamentably little.” There are, according to
him, about 2,500 species in the world. Of those occurring in America but
few are of economic significance, and except for the green June-beetle,
Cotinis nitida, three species of the genus Euphoria, and one of Osmoderma,
nothing has been done toward working out their life-histories. Recently
Sweetman and Hatch (1927), in rearing a larva of Osmoderma eremicola for
18 months, concluded that, allowing for outdoor periods of hibernation, the
life-cycle would be three years for this species. It is interesting to note that
all whose life-cycle has been studied require but one year to develop while
Osmoderma with entirely different habits requires a much longer time. The
little that is known of the development in this subfamily is summarized in
Table XVI.

Laparostictt

For an interesting account of the biology of the Coprinae and other
dung-feeding larvae, the reader is referred to Fabre’s The Sacred Beetle and
Others (English translation, 1924). Here is to be found this author’s study
of the development of the sacred beetle (Scarabaeus sacre), the Gymnop-
leuri, Copris, Onthophagus, and Geotrupes. Space will not be taken here
to quote it. No complete American work has been done on any of our
species of the subfamily. Neither has there been any investigation into the
length of life of our Aphodinae. The following account of this subfamily is
a translation of Schmidt’s account in Genera Insectorum, fascicle 110,
(1910).

The life-history and development of the Aphodinae are little or not well known. It is
generally observed that their eggs are laid in dung, from which the developing larvae obtain
their nourishment, and that pupation occurs in or under the food material. Many species
apparently prefer and seek out the excrement of a definite animal. Certain species develop
in the excrement of the sheep or deer, others in that from cattle, some from horses; while
others may prefer either that of horses or cattle. Certain European species are known to
develop in human wastes. Hubbard has reported A. troglodytes as living in the burrows of
the land tortoise, Gopherus polyphemus, and Chapman states that A. porcus lays its eggs in the
brood chambers of the scarabaeid larvae, Geotrupes, or the material upon which the Geotrupes
feed. Another species occurs only in rabbit dung. Psammobius and Rhyssemus inhabit sandy
regions. Their habits have not been studied, but it is thought that some species of Rhyssemus
live on vegetable materials while others live in dung. Ohaus has noted some species of Ataenius
in dung and others under the bark in rotten wood of fallen trees. Some exotic genera of this
subfamily (Euparia and Friedenreichi) live with ants, while others (Chaetopisthes, Corytho-
derus, and Termitodius) inhabit termite dwellings.

72 ILLINOIS BIOLOGICAL MONOGRAPHS [156

TAXONOMY

Early students of American insects confined themselves to a study of
the anatomy and classification of adult insects and the working out of their
life-histories. This has resulted in descriptions of numerous new genera and
species from adult characters and the description of the eggs, larval and
pupal stages, and the host plants of numerous species. The number of
known life-histories has been greatly increased by the establishment of
state and federal experiment stations and the appointment of entomologists
for the study of injurious and related species. There has been a great
increase in the number of persons interested in the study of immature
insects; and there have been published, not only in Europe but also in
America, many systematic studies attempting to furnish tables for the
identification of immature as well as adult insects. All classification is
based on anatomical characters and any attempt at identification must be
preceded by morphological studies. The anatomy of immature insects in
many cases, while similar in general to that of the adults, is frequently very
different, especially when the insects are examined in detail. The larvae
contain many structures peculiar to themselves, being in most cases fitted
to live a life very different from that of the adults.

A study of the anatomy of immature insects is of value from three
points of view: ontogeny, morphology, and classification. It has been
shown repeatedly that the complete history of the individual—its ontogeny
—throws much light upon the relationship of organisms and upon their
differentiation, not only as to species and genera but also as to families and
orders. Investigators have found that what had been considered as a single
species, from a study of the adult alone, proved to be a complex of two or
more species when the immature stages were known, and that characters
previously believed to be worthless could be used for separating the adults.
Ontogenetic and morphological studies should proceed hand in hand. Many
structures that are complex and difficult to interpret in the adult are easily
understood by a comparison with the conditions found in immature insects.
By comparative studies of this sort, the homology and homodynamy of
various structural parts are easily determined. While it is impossible,
without at least some morphological knowledge, to attempt the identifica-
tion of adult specimens, such knowledge is equally pertinent for one under-
taking the study of the anatomy of immature insects. The classification
and identification of such insects is of the greatest value to the economic

157] LARVAL SCARABAEOIDEA—HAYES #3

worker, because the investigator in this field almost invariably meets with
the stages that are doing the damage—the nymphs or larvae—and, unless
it is a species with which he is familiar, it would be impossible to identify
the pest, if no analytical tables were available, until the adult has been bred.
It is hoped that by a careful study of the morphology and classification of
immature insects, the labor of identification can be lessened.

With these facts in mind, the foregoing morphological studies have been
made for the purpose of producing analytical keys to the various groups
of white grubs. The author realizes their incompleteness. This is due, in
great part, to the fact that many species are yet unknown, that in many
instances only one or two specimens of known species are available and no
extended consideration of the problem of variation can be made at this time
because of the present state of our knowledge of the group. The following
keys are therefore submitted as a preliminary step toward the further
progress of the work. In the key to genera a few known species have been
included. This key appeared in a recent paper by the writer (1928) and is
here included with corrections and additions. It is gratifying to note, in
view of the previously published statements that larvae of these families
could not be separated, that one of Prof. J. W. McColloch’s student’s
reports that this key, as it first appeared, has been helpful in his work with
white grubs. The key to species of the genus Phyllophaga contains less
than one-third of the known North American species of this genus, but until
further progress is made with biological studies of the group little advance
can be expected in our acquaintanceship with the many species now un-
known in the larval stage.

LARVAL KEY TO FAMILIES OF THE SUPER-
FAMILY SCARABAEOIDEA

1. Posterior pair of legs small, undeveloped (Fig. 137); coxae modified into scraping, stridulat~
ing apparatus; antennae three-segmented (Fig. 94); body segments not distinctly divided
into annulets and nearly devoid of spines and setae (Fig. 3). . PASSALIDAE, genus Passalus

1. Posterior pair of legs normally developed, legs may or may not be used for stridulation (Fig.
135, 136); antennae four or five-segmented; body segments usually distinctly divided into
annulets and more or less covered with spines and setae ..............-.------00005s 2

2. Anal segment not trilobed on cadual aspect, legs not modified for stridulation except in
ewemeie Meee TI) ds eae ts LS take, C) es oe is cote ead a es SCARABAEIDAE

2. Anal segment trilobed on caudal aspect (Fig. 151, 154); meso- and metathoracic legs modi-
cee eer ree tee (Gap hs GG): Foe eS ho ee trey ea cee oceans: 3

3. Labrum usually biémarginate on its distal magin, trilobed (Fig. 33, 36); emargination of
peritreme of anterior spiracles on caudal margin as is the case with the remaining spi-
racles; anal segment strongly trilobed; larvae feed in wood (Fig. 2).......... LUCANIDAE

3. Labrum not biémarginate on its distal margin, more rounded, not trilobed on distal mar-
gin (Fig. 25); spiracular peritreme of all segments small, open on dorsal margin, poorly
defined (Fig. 123); anal segment feebly trilobed (Fig. 151); larvae feed in carrion (Fig. 7)

Be Rea aA ae SONA cra aC Ra Ae era ay Maen aitey ated res wee che SR TROGIDAE, genus Trox

ILLINOIS BIOLOGICAL MONOGRAPHS [158

LARVAL KEY TO THE SUBFAMILIES OF SCARABAEIDAE

. Galea and lacinia of maxilla not fused (Fig. 98, 100), that is, the mala is deeply bifed;
usually. coprophagous larvae! sia. 43s valid omiad «pb dad «ioaiz harsh eae LAPAROSTICTI 2
. Galea and lacinia of maxilla fused to form the mala (Fig. 97, 104); mostly “leaf chafers”
BEN PRPs ar caapehs ee archon seis, wife ee Spe Ae re eLnte somata a ease Nes Nags set actic TG eg Ree ene PLEUROSTICTI 6
. Tarsi without claws (Fig. 1), a distal seta may be present; abdomen strongly “humped”
on the dorsum (Fig. 1); labrum trilobed and biémarginate (Fig. 64).................. 3
. Tarsi with claws or the tarsus is bilobed on its distal end, abdomen not “humped” on the

» sAmbenitia POUL-SCPMCBEEE oi. ohio eisck a a tasye po chan ngs a ares aie d 3h nme CopRINAE, genus Copris
. Antenna five-sepmented » .. 0 ys..56 46 wees oo ease pln ew se ope ae fins aes) 4
. Tarsus strongly rounded or blunt on its distal end; tormae of labrum (Fig. 55, ¢) not meeting
on the median line; ential sete of lateral lobes of the epipharynx (Fig. 55, J/) numerous
(moré) than erght).dhicok soe laa da alae dee CopRINAE, genus Canthon
. Tarsus terminating in a long seta; tormae of labrum meeting on the median line (Fig.
67. #); ental setae of lateral lobes of the epipharynx scarce (usual one on each lobe)
ETI a bNRN nb ei SIA i, Do oi ote eta ee A enh, Seen RG eee CoprINAE, Onthophagus (Fig. 4)
. Tarsus without claws, bilobed on its distal end; posterior pair of legs considerably shortened
(not as much so as in Passalidae); second and third pairs of legs modified for stridulation
SD AOS EAE C AM CNET OCT CEMCSE RT EA ee eEN eC ORDA FOES pear ee GEOTRUPINAE, genus Geotrupes
. Tarsus with claws which are longer than trasus; legs not modified for stridulation; third pair
of legs not noticeably shortened; body densely setaceous (Fig. 139); anal slit transverse
BWI) eg oeacie secant he etree aoe GLAPHYRINAE, genus Amphicoma
. Mandibles on their caudal aspect without an oval, stridulating area made up of transverse
striae (Fig. 84); radula usually with two longitudinal rows of mesad pointing spines (not
present in Serica) (Fig. 156 to 189); anal slit in the form of an obtuse angle (Fig. 156 to
AB ON kB 0a WE -ecsheh inl. adc Boa Na ena Ma ie buaere tae TM agh GR ier Al he eaee MELOLONTHINAE
. Mandibles on their caudal aspect, with a distinct oval, stridulating area made up of trans-
verse striae (Fig. 81, sa); with or without two longitudinal rows of mesad pointing spines
on radula; anal slit not angulate (Fig. 138) and more transverse................---- 7
. Labrum symmetrical (Stephanucha is not symmetrical but it is a rare species), usually tri-
lobed (except in Trichiotinus which is usually recognized by the presence of ocelli):
epipharynx with a conspicuous, curved row of small spines in the region of the distal
sensory area (Fig. 57, st); dorsum of abdomen behind the last spiracle-bearing segment not
divided transversely by an impressed line thus appearing as one segment (Fig. 11); some
species are “black crawlers,” others found in soil, wood, and manure...... CETONIINAE
. Labrum asymmetrical, not trilobed; epipharynx without a conspicuous, curved row of
small spines in the region of the distal sensory area (Fig. 42); dorsum of abdomen behind
the last spiracle-bearing segment divided transversely by an impressed line making it
appear as two segments (Fig. 10); species of varied habits. .... sess «cacy 8
. Ental aspect of the labrum with a series of transverse striae on the lateral margins at
bases of lateral setae (Big. 200s?) es ioe ec ce veces Tribe Anomalini RUTELINAE
. Ental aspect of the labrum without a series of transverse striae on the lateral margins at
bases of lateral setae (Fig.50) 5.2.2. 6a 00. bas ltt maine see ae eres © bina he 9
. Stridulating teeth of maxillae (Fig. 106, ms) sharply pointed and curved, apices directed
distally (Fig. 114); distal segment of maxillary palpus usually without a distinct, setaceous
SENSOTY* ANCA 3. o'e rsaklne ts etn voehs cis eee RMAC iol els is eae acteeuskeenyayaeae Tribe Rutelini RUTELINAE
. Stridulating teeth of maxilla not pointed but ser truncate being as broad as long, not
curved, and not directed distally (Fig. 124); distal tooth of the series of stridulating maxil-
lary teeth twice as wide as the others in the series; distal segment of the maxillary palpus
usually ending in a setaceous SensOry area... . 1... eee DyYNASTINAE

159] LARVAL SCARABAEOIDEA—HAYES 75

LARVAL KEY TO GENERA OF SUBFAMILY MELOLONTHINAE

1. Anal slit obtusely angulate, not trilobed (Fig. 156); tarsal claws of posterior legs less than
half as long as claws of the other legs; distal sensory area of epipharynx usually with seven

to eight strong spines (Fig. 25). A few species of Phyllophaga, e.g., lanceolata (Fig. 26),
have less than seven spines but can readily be distinguished by the lateral striae of the
EE eS is mcs Cans Sg ed wae Fogle e oe eS eM wiht nal cue Sos Ce On Sa ae ep we 2

1. Anal slit more acutely angulate, faintly trilobed (Fig. 140); tarsal claws of posterior legs
more nearly equal in length to the claws of the other legs, never less than half as long;
distal sensory area of epipharynx never with more than four strong spines (Fig. 31, sp). .3
2. Longitudinal double row of spines of radula short, scarcely more than eight spines to a row
(Fig. 141); head dark brown in color; dorsum of abdominal segments very densely
spinose; striations of lateral margins of epipharynx indistinct (Fig. 25); epipharynx never
with a Submarpinal, distal row of striaé................02 2. ccs e eee ene Polyphylla

2. Longitudinal double row of spines of radula longer, usually more than ten spines to a row
(Fig. 156); head light yellow in color; dorsum of abdominal segments less densely spinose;
striations of lateral margins of epipharynx distinct (Fig. 26, st), epipharynx with a sub-
marginal, distal row of striae, sometimes difficult to observe in some species (Fig. 26, sms)

ee cee Pee Cece Ae She Sate ene aie Wotan etl ante eee Phyllophaga
3. Epipharynx with three strong spines in distal sensory area (Fig. 31); radula with a con-
spicuous transverse row of spines (Fig. 140)............. 00. sce e eee eee eee Serica
3. Epipharynx with four strong spines in distal sensory area (Fig. 34)................-- 4

4. Setae of radula not hooked at the tip; presence or absence of double longitudinal rows of
spines on radula questionable;! Distal end of abdomen sparsely clothed with shorter,
stronger setae; claws of posterior tarsi less than half as long as those of other tarsi... .
=o ch chcy ne pte eR N ee dca ic coh ac ER RPE AE ae Na Bag ea ara ee a Diplotaxis

4. Setae of radula hooked at the tip (Fig. 142); radula with a short, double row of longitudinal
spines; distal end of abdomen densely clothed with long delicate setae; anal opening
sharply acute; claws of posterior tarsi equal in length to claws of other tarsi........-..

Macrodactylus

ee ec

LARVAL KEY TO GENERA OF SUBFAMILY RUTELINAE

1. Ental aspect of the labrum with a series of transverse strie on the lateral margins near
eens a aera setae (ris. 21. St) ot. es Soe cee Seat e nee Tribe ANOMALINI 2

1. Labrum without such transverse striae on its ental lateral margins (Fig. 44)............
3 So's aS Diep ask Naas ielpsh bent eh ASS et ae a a pts ee eer rose Tribe Rutetint 4

2. With two of the four spines of the distal sensory area of the epipharynx strongly fused at
the base making a large spine with its distal end bifed (Fig. 52, sp); longitudinal, double

row of spines of radula parallel, not divergent, with eight spines in the left row and nine
IMBEDETIO ME TOW sie cise cere aes cere eee ee Ce rere Mets nah Strigoderma arboricola

2. Without two spines of the distal sensory area of the epipharynx fused at base to form a
bifed spine; longitudinal double row of spines of the radula either parallel or diverging
ISECEIOUVE Mette er cme RCT RR Oe me Te eee le ear a aloe mete ee eee 3

3. Radula with longitudinal rows of spines short, about seven spines in each row; rows
strongly divergent posteriorly; sensilliae of distal sensory area of epipharynx at bases

of distal spines about equal in size and arranged nearly semicircularly (Fig. 41)......

Re tri aca ied Sher ajo wa tated tas 19 wee Ses Lee orig Naso gaeeds, inate amass Sabie Popiilia japonica

3. Radula with longitudinal rows of spines usually longer, with twelve to thirteen spines in
each row (Fig. 143); rows more or less parallel and frequently converging posteriorly;

1 The only specimen of “Diplotaxis” available does not show the radula distinctly. A specimen in the Illinois
Natural History Survey Collection labeled ‘‘Diplotaxis” is apparently a species of Serica.

76 ILLINOIS BIOLOGICAL MONOGRAPHS {160

sensilliae of distal sensory area of epipharynx at bases of distal spines unequal in size and
not arranged as definitely in a semicircle (Fig. 40, 43, 46)................... Anomala
4, Larvae found in rotten logs or stumps, sometimes under dried manure, Labrum wider than
long; with or without (Fig. 144) two longitudinal rows of spines on radula; setae of lateral
margins of labrum of various lengths but not strongly curved (Fig. 44, 50)........... 5
4, Larvae usually formed in sandy soils, labrum (Fig. 50) as long as wide, strongly rounded
but asymmetrical; without longitudinal rows of spines on radula; lateral margins of
labrum with strongly curved, flattened setae which increase in length distally........
eo ay Seana sd Nenad acetate MEAS ase CUS GR Sepa COSA ciao el GSI Tec Lae Cotalpa lanigera
5. Larvae found in rotten logs or stumps, without two longitudinal rows of spines on radula
(Fig. 144); distal sensory area not produced into a single large, chitinous tubercle, without
sermicumeular rine at base (Bi: AS). css cic gece io px aes een ee ee Pelidnota punctata
5. Larvae under rotten logs or stumps, or under dried manure on sandy soils; with two
longitudinal rows of spines on radula; distal sensory area of epipharynx produced into a
single large chitinous tubercle, having between its base and the distal margin a narrow
chitinous semicinclesiy.) ccasceokele ns he heesyo sie asec aie ean eos oe caer Polymoechus brevipes

LARVAL KEY TO GENERA OF SUBFAMILY DYNASTINAE

1. With ‘a single ocellar spot at: base of: antenna: . 5) ..200. J...0 2-9 eae ee 2
. Without an ocellar spot at base of antenna). . 2)... 6. 2.05. 04 752 eee 4
2. Radula with a longitudinal cleared area surrounded by recumbent spines similar to other
spines of radula, spines not strongly differentiated as in other subfamilies having the
double longitudinal row of spines; usually found in manure. . Ligyrodes (Ligyrus) relictus
2. Radula without such a longitudinal, non-setose area formed by the absence of spines or

oy

3. Distal sensory area of epipharynx produced into a long, proximal pointing, chitinous
process which is curved at its apex, at its base are numerous large setae (Fig. 48, dsa);
head brownish-tan in color; usually found in burrows near manure........... Strategus

3. Distal sensory area of epipharynx not produced into a long, proximal pointing, chitinous
process nearly devoid of setae in the region of the distal sensory area (Fig. 151); head
nearly black in color, densely punctate; usually found on soil among dead leaves in woods
SPW sc RET TEI, fA MNOS SOO TEE TRE HERE tee Tee ee X yloryctes

4. Epipharynx with the chitinous portion of the distal sensory area produced to form a single
broad tubercle (fig. 45); labrum strongly asymmetrical; sides of labrum strongly rounded;
setae of radula very short, not hooked (Fig. 145).................--- Ligyrus gibbosus

4, Epipharynx with the chitinous portion of the distal sensory area produced to form two
tubercles or spines (Fig. 53, 54), labrum more nearly symmetrical; sides of labrum less
DOMME i! oad aig ewe ak Lena ES SR cpa EE tke Willcom ple cole sk ale 3

5. Distal sensory area of the epipharynx produced in the form of two broad tubercles close to
the distal margin of the labrum (Fig. 54); head and mandibles almost black in color; head
strongly punctured; prothorax with a large, brown more heavily chitinized area on the
sides which is deeply bipunctate; usually extremely large grubs........ Dynastes tityrus

5. Distal sensory area of the epipharynx produced in the form of two small spines and more
remote from the distal margin of the labrum (Fig. 53); head yellow in color; sparsely and
finely punctate; prothorax without brown, chitinous areas on sides; never extremely
latpe orbs. decaneice eu aie cin is ee Ochrosidia (Cyclocephala) immaculata®

2 Dyscinetus has not been studied. Davis (1916) states that D. trachypygus has “a dark brown head which is
inconspicuously reticulate and covered with irregularly placed fine punctures, in this respect differing from all
species (which he mentions) except Strategus, the head of which is much more coarsely punctate and the species is
much larger. The ventral surface of the anal segment bears a patch of hooked spines and the upper surface of the
same segment is covered, excepting along the median line, with fine hairs, those at the tip being shorter, stouter
and more spine-like.”’

161] LARVAL SCARABAEOIDEA—HAYES 77

_

LARVAL KEY TO GENERA OF SUBFAMILY CETONIINAE

. Labrum almost as long as wide, not distinctly trilobed (Fig. 66); emarginations of labrum

relatively shallow; a distinct ocellar spot at base of each antenna; distal sensory area of
epipharynx produced into a conspicuous chitinous tubercle; larvae live in wood........
» yO Ot Saat ae is SR 2s AG ine RE ae aa kt Ae ge ee aR a Trichiotinus

. Labrum considerably wider than long, distinctly trilobed, relatively deeply emarginate

(Fig. 62); no ocellar spot at base of antenna; distal sensory area not produced into a chit-
inous tubercle; larvae live in various situations, one genus, (Osmoderma,) in wood. . .2

. Epipharynx with a chitinous, semicircular carina near distal margin of the median lobe

(Fig. 65); proximad of this ridge is a semicircle of about sixteen sensory pores.’ On the
side of the epipharynx additional pores apparently make the semicircle continuous almost
to the clypeo-labral suture; tarsal claws normal, curved and sharply pointed; larvae live
To ROE pe ani eal car ee rd hapa a Seah eae Arai a. koe rae Cremastochetlus

. Epipharynx without a chitinous, semicircular carina on distal margin of median lobe; the

median lobe is provided with a conspicuous semicircle of spines (Fig. 68); tarsal claws
usually modified into blunt, cylindrical, setaceous tubercles!...................-055 3

. Epipharynx with about ten spines in a semicircular row in distal sensory area; placed

somewhat obliquely (Fig. 68); no chitinous sensory tubercle in proximal sensory area
near clypeo-labral suture mesad of tormae; larva live in sandy soil (rare) . . Stephanucha

. Epipharynx usually with more than ten spines (about 15-17) in a semi-circular row in

distal sensory area; placed almost transversely; with a well-defined sensory tubercle in
proximal sensory area near cylpeo-labral suture (Fig. 57, 59); larvae crawl on their

. Radula of last abdominal segment without a longitudinal, double row of mesad pointing

spines; larvae live in wood..........0...0 ccc cc ee eee ee eeeeees Osmoderma eremicola

. Radula of last abdominal segment with a longitudinal double row of mesad pointing spines;

larvae live in manure or soil that is rich in decaying organic matter................. 5

. Radula of last abdominal segment (Fig. 150) with spines of the longitudinal rows short,

separated from each other by a distance nearly equal to the length of the spines; apices
of opposing spines distant from each other by less than the length of an individual spine;
spines about twice as long as their width at base; antepenultimate antennal segment
longer than the terminal segment; usually found in rich, sandy or loam soil..... Cotinis

. Radula of last abdominal segment (Fig. 148, 149) with spines of longitudinal rows longer,

separated from each other by a distance much less than the length of the spines; apices
of opposing spines separated from each other by a distance greater than the length of an
individual spine; spines considerably more than twice as long as width at base; antepenul-
timate antennal segment not longer than the terminal segment, larvae usually found in

. Radula of last abdominal segment with spines of longitudinal rows diverging posteriorly

((Byhecs 012 LS URE ak oer Gece fe ee aN TORR ee rg aS OER ee PE Euphoria sepulchralis

. Radula of last abdominal segment with spines of longitudinal rows converging posteriorly

eee ee ete. PaO Sy eis os Se Go Ae Euphoria inda and Euphoria fulgida

LARVAL KEY TO GENERA OF FAMILY LUCANIDAE

pre MMRIAME AVC -REOTIERTOR 8. oo. 6. njc.e = aid'syaje net alee a,b, 6 eS aro A main wie aiwin a ole anes sisheaias 2
a ER MERE’ BEATS OPI CIS IN 5502 di5. 25 <5) «Se iegejce ode es eee ove & pial alerai a n eteca. nea lo amie winch een ale acne 3
. Dorsal lobe of the three anal lobes acutely pointed on its ventral margin, lateral lobes with

3 In the only specimen available for study the epipharynx is almost devoid of setae but in their place numerous

pores are present which may be trichopores whose setae have been lost, or they may, in fact, be sensillia.

4 Claws of Stephanucha have not been examined.

ILLINOIS BIOLOGICAL MONOGRAPHS [162

a concentric oval line (Fig. 154). 2.02522... ie Dorcus
. Dorsal lobe of the three anal lobes with its ventral margin strongly rounded; lateral lobes
without a concentric/ovalJdines.4./). obi Sal. hee Ss Bie ee Ho ee Lucanus
. Caudal region of radula of the last ventral segment with spinose setae; anal opening on
each side </. 4102. ea i alae ets Le eA ie iad Eee Platycerus®
. Caudal region of radula without spinose setae (Fig. 153)............- 0200 eee e eee 4
. Lateral lobes of anus large, subtriangular, not emarginate at their ventral point of union;
superior lobe larges 22 5 20 sed Xp aih jake eles Vb Dade he be ee Ceruchus
. Lateral lobes of anus plainly eliptical, emarginate at their ventral point of union; superior

lobe-smalli:( Pigs 453) i vs4a es adage eds vale idas ees 22 Sinodendron

ARTIFICIAL KEY TO SOME KNOWN THIRD INSTAR LARVAE
OF THE GENUS PHYLLOPHAGA

. Longitudinal rows of radula with less than five spines (usually four in right and three in
left row); the tips of opposing spines greatly overlapping, extending almost to the bases
of the opposing spines (Southwestern species) (Fig. 157)..............- cribrosa (Lec.)
. Longitudinal rows of radula with more than five spines in each row; the tips of opposing
spines never greatly overlapping (excepting /ongitarsa which has 8 to 12 spines)...... 2
. Each longitudinal row of radular spines composed of a series of spines varying from two
rows at the anterior end to three and four rows posteriorly, these compound rows and
space between them being rather strongly divergent posteriorly; cephalic spines usually
shorter than the caudal spines (Southwestern species) (Fig. 158).......... farcta (Lec.)
. Each longitudinal row of radular spines composed of a single series of spines, not composed
of several rows as in farcta, may or may not diverge posteriorly; spines of various lengths .3
. Longitudinal rows with never more than 16 spines in each row, usually less but not fewer
Han five sf. 12 ee Rk a SA 4
. Longitudinal rows with more than 16 spines in a roW..... 2... ee eee eee eee 10
. Two rows of longitudinal spines arranged in the form of a distinct oval; with 12-13 spines
in each row; spines short, scarcely as long as the distance separating the bases of ad-

joing spines" (Pig. 188)! 2.0 2.) ot Be Bees A tristis (Fab)
. Two rows of longitudinal spines arranged in nearly parallel rows; with from 5-16 spines
in each row; spines variable in length and distance apart. .........---.eeee eee eeees 5

. Majority of spines in each row separated from each other at base by a distance that is less
than the length of the individual spines; each row of spines strongly irregular; with 8 to
f6' spines in edch! Few) ').229 2. 2 OSs SRI eR Oe Oe Stale Sia 6
. Majority of spines in each row separated from each other at base by a distance equal to,
or greater than the length of the individual spines; each row of spines more nearly regular
or parallel; number of spines in each row never more than 14................-+--5- 7
. Spines 14 to 16 in a row; apices of opposing spines separated by a distance equal to or
slightly less than the length of the individual spines; the majority of spines directed
Cephadlo-mesad (Fie AGO RO) AR. Dwain. eee gracilis (Burm.)
. Spines 8-12 in a row; apices of opposing spines extending beyond the meson and over-
lapping or crossing each other; the majority of spines directed caudo-mesad (Fig. 162)
bese hc AS SE OR Se Re Sa eee longitarsa (Say)
. Most of the apices of opposing spines separated from each other by a distance equal to or
greater than the length of the individual spines; 11 to 13 spines in each row (Fig. 180)
ERNE RIE A PE NEI, 1 PUR AT ROAR BORER, AP implicita (Horn)
. Most of the apices of opposing spines separated from each other by a distance less than
the ‘length of the individual spines. } 3 .).¢ 9.3.05 .0 des ars se ee en cae ae ae eR 8

5 Genus not seen. The characters given above are from Perris (1877) after Mulsant.

163] LARVAL SCARABAEOIDEA—HAYES 79

8. Most of the apices of opposing spines reaching the meson and very narrowly separated

from each other; 12-13 spines in each row (Fig. 171)................ vehemens (Horn)
8. Most of the apices of opposing spines not reaching the meson with the opposing apices
more widely separated from each other; 13-14 spines in each row................... 9
9. Spines shorter, much less than half the length of the distance separating the majority of
adjacent spines at their base; 13 spines in each row (Fig. 156)......... lanceolata (Say)
9. Spines longer, usually greater than half the length of the distance separating the majority
of adjacent spines at their base; 14 spines in each row (Fig. 175)........ drakei (Kby.)

10. Spines of radular rows not stout; individual spines usually equal in length or shorter than
the intervening distance between the bases of adjacent spines; the bases of the spines
much narrower than the interval between the spineS............... 00000 eee eeeee 11

10. Spines of radular rows usually stout; individual spines in most instances much longer
than the intervening distance between the bases of adjacent spines; in many species the
bases of the spines are wider than the interval between the adjacent spines......... 18

11. Apices of most of the opposing spines meeting, or slightly overlapping each other, on the
meson; 19-22 spines in each row; a conspicuous transverse row of setae between the
radular spines and the anal opening (Fig. 161).................020005. ephilida (Say)

11. Apices of most of the opposing spines not meeting on the meson, the tips of opposing
spines being separated from each other by a distance equal to or greater than the length
of the individual spines; 19-29 spines in each row; no conspicuous transverse row of setae

between the radular spines and the anal opening. .............. 00s eee eee eee eee 12
12. Spines of radula arranged in nearly parallel rows; 29 spines in left row, 25 in right row;
spines short, scarcely longer than their width at base (Fig. 173)......... horni (Smith)
12. Spines of radular rows arranged in more irregularly parallel rows, no rows with more than
27 spines; most spines considerably longer than their width at base................ 13
13. Longitudinal rows with from 25 to 27 spines........ 2... 60-s cee e seen e eee ees 14
$a ioumtudmal.rows. with from 17 to.21 spines: ) sa). ise lee ee ces ase ote ae 15

14. Rows of spines very irregularly parallel: with 25 spines in right row and 27 in left row;
spines about equal in length to the distance between adjacent bases (Fig. 189)........
RUPP hi RNS CCG os aa i Nae Se Are cg Gra Sits oe dain, oboe ness inversa (Horn)

14, Rows of spines more regularly parallel; with 26 spines in each row; spines usually shorter

than the distance between adjacent bases (Fig. 160).................-- latifrons (Lec)
15. Radular rows of spines diverging anteriorly... ........... 2... e eee eee 16
15. Radular rows of spines not diverging anteriorly............. 002s eee cece ee eens 17

16. Radular rows of spines approximate at caudal ends (distance between opposing apices of
caudal spines less than the length of the spines); 19 to 20 spines in each row (Fig. 183)
ey a a nor cua ea rol Slt | 5 Rim ppd nt ea tele Seber cbutyl day. et Reh e delata (Horn)

16. Radular rows of spines less approximate at caudal ends of rows (distance between opposing
apices of caudal spines at least equal to or greater than the length of the spines); 17 to

i aes mene sows. 102) cvs ox) sa liewes gonads aduiwewe eh Lanes fusca (Froel.)
17. With 19 to 21 spines in each longitudinal row; the two rows constricted at middle® (Fig.
AG) RRA SER i a AO ees eG ay ut ATER Ia pete Scat cictels Ghd asp marginalis (Lec.)

17. With 18 spines in each longitudinal row; the two rows not constricted at middle (Fig. 174)
PT NN i et ak oo aE ea) rama fervida (Fab.)
18. Spines of radular rows short, scarcely longer than the intervening spaces at their bases;
the rows of spines strongly diverging caudally then converging near their caudal ends. .19
18. Spines of radular rows considerably longer than the intervening spaces at their bases;
not strongly divergent but in a few species becoming gradually curved near caudal ends
20

in Sate alae, hin afeOwhw nie leh alba mm wleta «iw Sy fea le an Whe: emis Sede (aw) a, epee oe) ele ie ie 6) Oho) we) 6: of aiieliish ei a) Says le6 lee, p's

6 In the single third instar of this species studied this.constriction appears but this may be an abnormality
since several second instar grubs available do not show this constriction.

80

19.

19.

20.

20.

2a.

es

22:
22.
23.

23;

ILLINOIS BIOLOGICAL MONOGRAPHS [164

Spines of radular rows strongly divergent before the middle; rows not meeting at their
anterior and posterior ends; with 23 spines in each row (Fig. 186)........ vetula (Horn)
Spines of radular rows becoming suddenly strongly divergent at or behind middle; rows
meeting at anterior end; left row with a conspicuous interval devoid of spines; with 27
and''28 spines in ‘the rows (Figs 167). 0009.00) oe Gi) calceata (Lec.)
Rows nearly parallel; apices of most opposing spines separated by a distance less than the
lene th of the spines (FigiL64) 2.42 209. cn Oe futilis (Lec.)
Rows more or less parallel or gradually curving; apices of the majority of opposing spines
separated by a distance equal to or greater than the length of the spines........... 21
Rows short, occupying less than half the distance between the anal opening and the
anterior margin of the segment; spines regularly placed and rows slightly curving near
caudal end; 20 to 22 spines per row (Fig. 187).............-....2---- affabilis (Horn)
Rows longer, occupying one-half or more of the distance between the anal opening and
the anterior margin of the segment; spines of varying arrangement; usually, but not

always, with more than 22 spines per row... ......--.-0 eee ee eee ete eee ees 22
Spines short, not more than twice as long as width at base.......................- 23
Majority of spines considerably more than twice as long as width at base........... 25

Spines of uniform size and length, rows more regularly spaced and gradually curving out-
ward at center and approaching one another at each end; with 24 spines in one row and 29

incthevother (Bigs 171) ee RM hae ee eee ee fraterna Harris
Spines not of uniform size and iength, rows more irregularly spaced and not gradually
curving outward; with not less than 27 spines in any row.........---...02++e000: 24

. Rows of spines nearly parallel, but with rather jagged rows not noticeably approaching

each other at the ends; with 27 in one row and 29 in another (Fig. 165)..prunina (Lec.)

. Rows of spines not parallel, slightly curving and approaching each other at caudal end;

with 33 spines in one row and 32 in another (Fig. 184)................. ilicts (Knoch)

. Rows strongly curved anteriorly to form a rounded cephalic end composed of smaller

spines, one row with 24 spines, the other with 28 spines leaving two conspicuous spines
at caudal end with no spines opposing them in the other row (Fig. 185)............--
crenulata (Froel.)

25. Rows not conspicuously rounded at anterior end; without unopposed spines at caudal end
OE OWE OW a0: on, 285 vos. s stain adnl ds beep re ASR. A, te eae 26
26. Rows of spines longer, with 32 spines in one row and 31 in the other (Fig. 179)........
x ses hatycag:cerahs Rie yates nae Ra hc ac es Be a URNA ENS OS Oa profunda (Blanch.)
26. Rows of spines shorter, with less than 30 spines in any row..........----.++++000-- 27
27. Spines irregularly placed, forming jagged rows..............0-0000ce0ee eee eeeeees 28
27. Spines regularly placed, forming more even rowS.........---- 2-2 ee eee eee 30
28. Three caudal spines of each row not more than half as long as the majority of the spines
cephalad of them: with 25 spines in one row and 24 in the other (Fig. 181)..balia (Say)
28. Three caudal spines not differing greatly in length from the cephalic ones........... 29
29, With 27 spines imesch row (Pic. 166). ei Jay a 0 ee congrua (Lec.)
29. With 25 spines in one row and 26 in the other (Fig. 168)......... crassissima (Blanch.)
30. With both rows of spines bent or constricted mesally near the middle of the rows, 29
Spinesin each Tow (ig. Jao) cn san co regcnk ckapnin anon aie een eee hirticula (Knoch.)
30. With not more than one, or none, of the rows constricted near the middle of the row; not
more! than 26 spinesiin each Tow: {2.10.26 co.te ais odes wie ote les eet 31
31. Apices of most of the opposing spines widely separated, being nearly twice the length of
the spines apart. G69 Hone ete PE Re RR AS, 32
31. Apices of most of the opposing spines not as widely separated, being considerably less
than. twice the length of the spines apart...............22200 0:00 40+ 02" ecu 33

32.

With the right row of spines constricted or bent near its middle; 28 spines in one row and
2a ae the ‘ether Lie ya vey. ce ee TSR a BO Reelin tel corrosa (Lec.)

165] LARVAL SCARABAEOIDEA—HAYES 81

32. With neither row of spines constncted or bent near the middle; 23 spines in one row and 20
MME MEER UCM MRE TNNS fe Sia Dhak tities ATRL Be anni @ ahaha es Hemel AEN SRS torta (lec.)
33. Rows of spines rather regularly curved throughout; with 22 spines in one row and 25
Reem HAEME CN RLO) isco os a pct ui vane Sema ad Heese shee es oe micans (Knoch)
33. Rows of spines somewhat bulging behind the center; with 24 spines in one row and 26 in
RST ELAR AMA Peo NY a dics ai ieee das Min «inated a) ys Wace 2's bipartita (Horn)

SUMMARY

The foregoing study of the larvae of North American Lamellicornia,
including the now recognized families—Scarabaeidae, Lucanidae, Trogidae,
and Passalidae—attempts to bring together our knowledge of their biol-
ogy, including the writer’s life-history studies, and presents keys for their
identification based on morphological studies. No comparative studies of
the structural characters of these insects have hitherto been attempted,
and it is hoped that this work, though far from being complete, will afford
a stepping-stone to further progress in our knowledge of the group.

For taxonomic purposes the characters of the mouthparts and the last
abdominal segment have proved the most useful. The analytical keys can
be considered only preliminary, inasmuch as a great many of our species
are still unknown in the larval stage. The long life-cycle in many species
makes rearing very difficult.

In the discussion given to biology, there have been brought together,
in a comparative way, the more general facts concerning postembryonic
development. Some consideration is given to the late embryonic processes,
and larval development is considered in a general way, as is also pupal
development. This is followed by more-detailed life-history studies in the
sub-families Melolonthinae, Rutelinae, Dynastinae, Cetoniinae, and the
coprophagous species of the family Scarabaeidae.

82 ILLINOIS BIOLOGICAL MONOGRAPHS [166

BIBLIOGRAPHY
Arrow, G. G.
1910. Coleoptera Lamellicornia (Cetoniinae and Dynastinae). The Fauna of British
India including Ceylon and Burma. 322 pp., 2 pl. Taylor and Francis, London.
Boas, J. E. V.
1893. Ueber die Stigmen der Melolonthalarve. Zool. Anz. Jahrg., 16 (No. 431): 389-391.
Bovine, A. G.

1921. The larva of Popillia japonica Newman and a closely related undetermined ruteline
larva. A systematic and morphological study. Proc. Ent. Soc. Wash., 23: 51-62.
2 pl.

BurRMEISTER, H. C. C.
1842. Handbuch der Entomology, 3: 550-68. Berlin, Reimer, 1832-1855.
Cuapuis, M. F., AND CANDEZE, M. E.

1855. Catalogue des larves des coleoptéres connues jusqua ce jour avec la description
de plusieurs especes nouvelles. Mem. Soc. Scien., Liege, 8: 341-653 [also ap-
peared as a separate]

CARPENTER, G. H.
1912. Mouthparts of some beetle larvae. Quart. Jour. Micr. Soc., 57: 373-376.
CHITTENDEN, F. H.
1899. Some insects injurious to garden and orchard crops. U.S. D. A. Bur. Ent. Bul.
19: 1-77.
CHITTENDEN, F. H., AND Fink, D. E.
1922. The green June beetle. U.S. D. A. Bul. 891: 1-52. 7 fig., 10 pl.
CrIppDLE, N.
1918. The habits and control of white grubs in Manitoba. Can. Agr. Gaz., 5: 449-454.
Davis, J. J.

1913. The life-cycle of Lachnosterna tristis Fabr. Jour. Econ. Ent., 6: 276-278.

1915. Cages and methods of studying underground insects. Jour. Econ. Ent., 8: 135-139.

1916. A progress report on white grub investigations. Jour. Econ. Ent., 9: 261-281.

1918. Common white grubs. U.S. D. A. Farm. Bul. 940: 1-28. 21 figi

Davis, J. J., AND LUGINBILL, P.
1921. The green June beetle or fig eater. N. C. Agr. Exp. Sta. Bul. 242: 1-35. 9 fig.
Der CHarmoy, D. C.

1912. Rapport sur Phytalis smithi (Arrow) et autres scarabies s’attacquant a la cannea

sucre 4 Maurice, 355 pp., 10 pl. Port Louis. [not seen]
DEHAAN, W.

1836. Memoires sur les metamorphoses des coleoptéres. Nouv. Ann. Mus. Nat. Hist.,

4: 125 [also appeared as a separate] -
Ericuson, W. F.

1848. Naturgeschichte der Insecten Deutschlands, Erste Abt., Coleop., Vol. 3. 968 pp.

Nicolai, Berlin.
Fasre, J. H.

1924. The sacred beetles and others. Translated by A. T. de Mattos. 425 pp. Dodd,

Mead, and Co., New York.
ForBES, S. A.

1891. On the common white grubs (Lachnosterna and Cyclocephala). Ill. Ent. Rep.,
17: 30-53.

1894. A monograph of insect injuries to Indian corn. Ill. Ent. Rep., 18: 1-171. 15 pl.

167] LARVAL SCARABAEOIDEA—HAYES 83

Grant, G.
1925. Contribute alla conoscenza biologica e morphologica di alcuni Lamellicorni fillo-
fagi. Boll. Lab. Zool. Gen’l. e Agraria, Portici, 18: 159-224.
GRAVELY, F. H.
1915. Notes on the habits of pase insects, myriapods and arachnids. Ind. Museum
Record, 11: 483-539.
1916. Some lignicolous beetle-larvae from India and Borneo. Ind. Museum Record,
12: 137-175.
Hap tey, C. H.
1922. The Japanese beetle. N. J. Dept. Agr., Bur. Stat. and Insp., Circ. 45: 1-20.
Hayes, W. P.
1917. Studies on the life history of Ligyrus gibbosus DeG. (Coleoptera). Jour. Econ. Ent.,
10: 253-261.
1918. Studies on the life history of two Kansas Scarabaeidae. Jour. Econ. Ent., 11:
136-144.
1919. The life-cycle of Lachnosterna lanceolata Say. Jour. Econ. Ent., 12: 109-117.
1920. The life histories of some Kansas Lachnosterna. Jour. Econ. Ent., 13: 303-318.
1921. Strigoderma arboricola Fab.—Its life-cycle (Scarab., Coleop.). Can. Ent., 53:
121-124.
1924. The biology of Anomala kansana. Jour. Econ. Ent., 17: 589-594.
1925. A comparative study of the history of certain phytophagous scarabaeid beetles.
Kans. Agr. Exp. Sta., Tech. Bul. No. 16. 146 pp., 10 pl.
1927. The immature stages and larval anatomy of Anomala kansana H. and McC.
(Scarab., Coleop.). Ann. Ent. Soc. Amer., 20: 193-203. 3 pl.
1928. The epipharynx of lamellicorn larvae (Coleop.) with a key to common genera.
Ann. Ent. Soc. Amer., 21: 282-306. 3 pl.
Hayes, W. P., anp McCottocg, J. W.
1920. Some observations on the genitalia of Lachnosterna. Ann. Ent. Soc. Amer., 13:
75-80. 1 pl.
1928. Ecological studies of Kansas scarabaeid larvae (Coleop.). Jour. Econ. Ent., 21:
249-260.
Lamark, J. B. P. DE.
1817. Histoire naturelle des animaux san vertébres. Tome IV. 587 pp. Verdiere, Paris.
LATREILLE, P. A.
1817. (Insects). Cuvier, Regne Animal..... 1, 782 pp. Paris.
Lene, C. W.
1920. Catalogue of Coleoptera of Benerica North of Mexico. 470 pp. J. D. Sherman,
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Lene, W. C., AND MuTcHLer, A. J.
1927. Supplement to the Leng Catalogue of Coleoptera of America North of Mexico.
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MacGitttvray, A. D.
1923. External insect anatomy. 388 pp. Scarab Pub. Co., Urbana, Illinois.
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1908. Some observations at Southern Pines, N. Carolina. Ent. News, 19: 286-289.
McCottocg, J. W.
1917. A method for the study of underground insects. Jour. Econ. Ent., 10: 183-187.
.McCott1ocs, J. W., AND Hayes, W. P.
1923. Soil teinpetatnins and its influence on white grub activities. Ecology, 4: 29-36.
McCottocgu, J. W, Hayes, W. P., AND Bryson, H. L.
1928. The hibernation of ebriles scarabaeids and their Tiphia parasites. Ecology, 9:
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84 ILLINOIS BIOLOGICAL MONOGRAPHS [168

Motsant, E.
1842. Histoire naturelle des coleopteres de France, Part II. Lyon (et Paris), Maison.
(later Paris, Magnen and Blanchard Co.) Part 2, Lamellicornes. 624 pp., 3 pl.
OsTEN-SACKEN, R.
1862. Descriptions of some larvae of North American Coleoptera. Proc. Ent. Soc. Phila.,
1: 105-130. 1 pl.
1874. Description of the larva of Pleocoma. Trans. Amer. Ent. Soc., 5: 84-87.
PERRIS, E.
1877. Larves des coleoptéres. 590 pp., 14 pl. (Lamellicorns, pp. 91-122, pl. 4, 5.) Dey-
rolle, naturaliste, Paris.
PuILiies, W. J., AND Fox, H.
1917. The rough-headed corn stalk-beetle in the Southern states and its control. U.S.
D. A. Farm. Bul. 875: 1-10. 8 fig.
Rirey, C. V.
1870. White grubs in strawberry beds. Amer. Ent. and Bot., 2: 307.
1870. Insects injurious to the grape vine. Amer. Ent. and Bot., 2: 295.
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1925. Eine neue Art von Eisprengern bei Lamellicornien-larven (Phyllopertha horticola
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1927. Studien zur morphologie und biologie von Phyllopertha horticola L. und Anomala
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ScHI6pTE, I. C.
1874. De metamorphosi Euleutheratorum observations. Naturalist. Tiddskrift (series
3) 9: 227-376, pl. VIII-XIX.
1874. Note sur les organes de stridulation chez les larves des coleoptéres lamellicornes.
Ann. Soc. Ent. France, 5th series, 4: 39-41.
ScHumopT, A.
1910. Coleoptera Lamellicornia Fam. Aphodiidae. Genera Insectorum. Fasc. 110.
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SHARP, D.
1918. Insects. Cambridge Natural History, Vol. 6. 626 pp. Macmillan & Co., London.
Scopout, J. A.
1763. Entomologia carniolica . . . . Vindobonas, 420 pp.
SmiTH, J. B.
1902. An injurious root chafer. N. J. Agr. Exp. Sta. Ent. Rep. for 1901. Reference, p.
490.
STEINKE, G.
1919. Die Stigmen der Kaferlarven. Archiv. fur Naturges.,85 :(Abt. A) 1-58. 3pl.
SuitTu, L. B., AND HapLey, C. H. ;
1923. The Japanese beetle. U.S. D. A. Dept. Circ. 363: 1-66.
SmyTH, E. G.
1916. Report of the South Coast Laboratory. Porto Rico Dept. Agr. Rep. pp. 45-50.
1917. The white grubs injuring sugar cane in Porto Rico. II. The Rhinocerus beetles.
Porto Rico Dept. Agr. Jour. 4 (No. 2): 3-29.
SWEETMAN, H. L., anp Hatcu, M. H.
1927. Biological notes on Osmoderma with a new species of Ptiliidae from its pupal case
(Coleoptera). Bul. Brook. Ent. Soc., 22: 264-266.
Titus, E. S. G.
1905. Some miscellaneous results of the work of the Bureau of Entomology. The sugar-
cane beetle (Ligyrus rugiceps Lec.). U.S. D. A. Bul. 54: 7-18.

169]

LARVAL SCARABAEOIDEA—HAYES

PLATE I

85

86

Fig. 1.
Fig. 2.
Fig. 3.
Fig. 4.
Fig. 5.
Fig. 6.

ILLINOIS BIOLOGICAL MONOGRAPHS

EXPLANATION OF PLATE,I
LATERAL ASPECTS OF THE LARVAE OF SCARABAEOIDEA

Pinotus carolina.

Sinodendron rugosum.

Passalus cornutus.

Onthophagus vaca (after Mulsant).
Amphicoma sp.

Aphodius sp. (probably jfimetarius).

[170

ILLINOIS BIOLOGICAL MONOGRAPHS VOLUME XII

ae
SINODENDRON
RUGOS

PASSALUS
CORNUTUS

+)
AMPHICOMA

6 APHODIUS SDP.

LARVAL SCARABAEOIDEA PLATE I

a oe
ot. o

yes <ye val at iy

‘ j ° Doms Ley

\ a”
‘ mt “al & a’ e
ee ee ee

‘
*
«9
*
ea 8
= ’
%
, he ¥ ¥.
“ne
5 ; ‘hn
<a
:
. >
i . y
CMe =
i ' 2 y
’
a i
~ My ‘
Ong . i
F (¢
oe =
~
‘ ~
,
" .
. 2
nv
a9 j -
=A .

"

/ 4
? \
a
; =
=
,
7
= iil bo
“;
a =a
=
, - had
‘ : J
el er
li - y
¢ weal ffs a ee hat
re : 7 ’
7 7
~ “Tr
)
7 ri «
‘ ; , ,
rn ’ nN ; * f 7
=. = , -
a’ f oa 4 ‘
- . 4 = = _ : yt g
i ~~" oa aa The : - a
“ane vent ee * ca s < - .
{ - . nes : “ o
- ? f~ i 74 um
2 - a
me 3 j a : : si Pa) _
oe ey | <7 : re
J ; Pn) ri * a) } ae. cS ye fi
7 f a ; aov ,e - are
q aAL.S oy. ade A = Pe ee am = 9 ,
iz a vs aan P oo as a
A ° _ a Se a =
- = _ ea. hl id oe TE Lb | oe

171]

LARVAL SCARABAEOIDEA—HAYES

PLATE Ut

87

88

Fig. 7.

Fig.
Fig.
Fig.
Fig.
Fig.

8.
a:
10.
at
12.

ant
as

ge7te

ILLINOIS BIOLOGICAL MONOGRAPHS

EXPLANATION OF PLATE II
LATERAL ASPECTS OF THE LARVAE OF SCARABAEOIDEA

Trox sp.

Anomala kansana.
Ochrosidia immaculaia.
Ligyrus gibbosus.
Euphoria inda.
Phyllophaga crassissima.

ABBREVIATIONS EMPLOYED

antenna pe preclypeus

anal slit pse postclypeus
epicranial suture r radula

front I prothorax

labrum II mesothorax
mandible Il metathorax
maxillary palpus 1-10 abdominal segments

{172

ILLINOIS BIOLOGICAL MONOGRAPHS VOLUME XII

;
‘ 0 j
: 2

VEN BO SA
> Aa xs

cy D

12 PHYLLOPHAGA
CRASSISSIMA

HAYES LARVAL SCARABAEOIDEA PLATE II

5
\
7

>

’
.
*
Pa
|
eA
—e
oe *
7
aren. ta
ete ow

6 eee pete 8

173]

LARVAL SCARABAEOIDEA—HAYES

PLATE III

89

90 ILLINOIS BIOLOGICAL MONOGRAPHS [174

EXPLANATION OF PLATE III
CEPHALIC ASPECT OF THE LARVAL HEADS

Fig. 13. Canthon laevis.

Fig. 14. Aphodius sp.

Fig. 15. Amphicoma sp.

Fig. 16. Phyllophaga crassissima.
Fig. 17. Serica sp.

Fig. 18. Anomala kansana.
Fig. 19. Ligyrus gibbosus.
Fig. 20. Cotalpa lanigera.

Fig. 21. Euphoria inda.

Fig. 22. Trox sp.

Fig. 23. Sinodendron rugosum.
Fig. 24. Passalus cornutus.

ABBREVIATIONS EMPLOYED

ant antenna mda mandible
aa epicranial arm pe preclypeus
es epicranial suture pel precoila

tS front psec postclypeus
Ses fronto-clypeal suture F] vertex

1 or lab labrum

ILLINOIS BIOLOGICAL MONOGRAPHS VOLUME xII

eae
15 AMPHICOMA

MY () .
14 APHODIUS SP SP

20 COTALPA LANIGERA 21 EUPHORIA INDA

19 LIGYRUS GIBBOSUS

22 _TROX SP SINODENDRON KUGOSUM* 24 FASSALUS CORNUTUS

HAYES LARVAL SCARABAEOIDEA PLATE III

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175]

LARVAL SCARABAEOIDEA—HAYES

PLATE IV

91

92

Fig.
Fig.
Fig.
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Fig.
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Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.

ILLINOIS BIOLOGICAL MONOGRAPHS [176

EXPLANATION OF PLATE IV

EPIPHARYNX

. Polyphylia decemlineata.

Phyllophaga lanceolata.

. Phyllophaga tristis.
. Macrodactylus subspinosus.

Phyllophaga fusca.
Dorcus sp.

. Serica sp.

32. Phyllophaga rugosa.
33. Sinodendron rugosum.
34. Diplotaxis sp.
35. Phyllophaga cribrosa.
36. Passalus cornutus.
37. Phyllophaga futilis.
38. Phyllophaga corrosa.
39. Trox sp.
ABBREVIATIONS EMPLOYED
cp chitinous plate psa proximal sensory area
cls clypeal sensillia sa sensillia
clst clypeo-labral suture SC sense cone
dsa distal sensory area SMS submarginal striae
u lateral lobe sp spines
ls lateral striae st setae
ml median lobe 3 torma

ILLINOIS BIOLOGICAL MONOGRAPHS VOLUME XII

26 PHYLLOPHAGA LANCEOLATA ©6927 PHYLLOPHAGA = TRISTIS

—-,
ene
28 macropAcTYLUs SUBSPINOSUS

32 PHYLLOPHAGA RUGOSA 33 SINODENDRON RUGOSUM

1 sr ot
__y-2,-SC
835 PHYLLOPHAGA CRIBROSA

39 TROX SP.

HAYES LARVAL SCARABAEOIDEA PLATE IV

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177]

LARVAL SCARABAEOIDEA—HAYES

PLATE V

93

94

ILLINOIS BIOLOGICAL MONOGRAPHS

EXPLANATION OF PLATE V

EPIPHARYNX

. Anomala orientalis.

. Popillia japonica.

. Ligyrodes relictus.

. Anomala kansana.

. Pelidnota punctate.

. Ligyrus gibbosus.

. Anomala innuba.

. Polymoechus brevipes.
. Strategus aniaeus.

. Anomala binotata.

. Cotalpa lanigera.

. Xyloryctes satyrus.

. Strigoderma arboricola.
. Ochrosidia immaculata.
. Dynastes tityrus.

ABBREVIATIONS EMPLOYED

chitinous plate psa
clypeal sensillia sa
clypeo-labral suture se
distal sensory area sms
lateral lobe sp
lateral striae st
median lobe

proximal sensory area
sensillia

sense-cone
submarginal striae
spines

setae

torma

[178

ILLINOIS BIOLOGICAL MONOGRAPHS

Sc
40 ANOMALA

46 ANOMALA

52 STRIGODERMA ARBORICOIA

HAYES

ORIENTALIS

INNUBA

50 COTALPA LANIGERA

sc
53 OCHOROSIDIA IMMACULATA

LARVAL SCARABAEOIDEA

a EN

GYRUS GIBBOSUS

VOLUME XII

Ss
s
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dsa

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tees ANTAEUS

TITYRUS

PLATE V

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179]

LARVAL SCARABAEOIDEA—HAYES

PLATE VI

95

96

Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
. Fig.
Fig.
Fig.
Fig.
Fig.
Fig.

ILLINOIS BIOLOGICAL MONOGRAPHS

EXPLANATION OF PLATE VI

EPIPHARYNX

. Canthon laevis.

. Aphodius sp.

. Euphoria fulgida,

. Geotrupes stercorarius. (after Schiddte)
. Cotinis nitida.

Euphoria sepulchralis.

. Amphicoma sp.
. Osmoderma eremicola.
. Euphoria inda.

Copris tullius.

. Cremastocheilus sp.

Trichiotinus piger.

. Onthophagus sp.
. Stephanucha pilipennis.

Phyllophaga futilis. sense cone

ABBREVIATIONS EMPLOYED

chitinous plate psa proximal sensory area
clypeal sensillia sa sensillia

clypeo-labral suture SC sense-cone

distal sensory area sms submarginal striae
lateral lobe sp spines

lateral striae st setae

median lobe torma

[180

ILLINOIS BIOLOGICAL MONOGRAPHS VOLUME XII

ps
56 APHODIUS

‘58 GEOTRUPES . STERCORARIUS 59 COTINIS NITIDA 60 EUPHORIA SEPULCHRALIS

AFTER SCHIODTE

z Vp =m
sQAPT77

—_
aa
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63 EUPHORIA INDA

dsa
'

64 cOPRJS TULLIUS
dsa

67 ONTHOPHAGUS SP. 68 STEPHANUCHA PILIPENNIS 69 PHYLLOPHAGA FUTILIS

HAYES LARVAL SCARABAEOIDEA PLATE VI

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Bs. ;
7
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: 4 ah) aah: ’ '
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181]

LARVAL SCARABAEOIDEA—HAYES

PLATE VII

97

98

ILLINOIS BIOLOGICAL MONOGRAPHS

EXPLANATION OF PLATE VII

RIGHT AND LEFT MANDIBLES.—CEPHALIC ASPECT

. Anomala kansana.

. Aphodius fimetarius.

. Stephanucha pilipennis.

. Euphoria inda.

. Cotalpa lanigera.

. Ligyrus gibbosus.

. Phyllophaga crassissima.
. Mandibular articulation.
. Canthon laevis.

. Passalus cornutus.

Sinodendron rugosum.

ABBREVIATIONS EMPLOYED

acia pa preartis
brustia pel precoila
dentes rt rectotendon
extensotendon sb scrobe

molar area SC scissorial area

[182

ILLINOIS BIOLOGICAL MONOGRAPHS VOLUME XII

£5 ox

70 ANOMALA KANSANA 71 APHODIUS FIMETARIUS

S

72 STEPHANUCHA PILIPENNIS

iy GD

74— COTALPA LANIGERA 75-LIGYRUS GIBBOSUS

OOE A:

C¢ MANDIBULAR = 78 CANTHON LAEVIS
PHYLLOPHAGA CRASSISSIMA

2 be

79 PASSALUS CORNUTUS 80 SINODENDRON RUGOSUM

73 EUPHORIA INDA

HAYES LARVAL SCARABAEOIDEA PLATE VII

183]

LARVAL SCARABAEOIDEA—HAYES

PLATE VIII

99

100

Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.

ILLINOIS BIOLOGICAL MONOGRAPHS [184

EXPLANATION OF PLATE VIII

RIGHT AND LEFT MANDIBLES—CAUDAL ASPECT AND EPIPHARYNX

. Anomala kansana.

. Euphoria inda.

. Cotalpa lanigera.

. Phyllophaga crassissima.

. Canthon laevis.

. Amphicoma sp.

. Stephanucha pilipennis.

. Ligyrus gibbosus.

. Passalus cornutus.

. Pinotus carolina. Epipharynx.
. Anomala kansana. Showing connection of epipharynx and hypopharynx.

ABBREVIATIONS EMPLOYED

acia pe precoila

clypeus pla postartis

dentes rt rectotendon
extensotendon sa stridulating area
hypopharyngeal chitinization SC scissorial area

molar area t torma

ILLINOIS BIOLOGICAL MONOGRAPHS VOLUME XII

ANOMALA K ae ey 82 EUPHORIA INDA

O20 |

83 COTALPA LANIGERA gq _si—p cRASSISSIMA

P 8

85 CANTHON LAEVIS

AMPHICOMA SP

OM Ba

87 STEPHANUCHA PILIPENNIS 88 LIGYRUS GIBBOSUS

90 PINOTUS

89 PASSALUS CAROLINA 91 ANOMALA
CORNUTUS KANSANA

HAYES LARVAL SCARABAEOIDEA PLATE VIII

ge

a
wm,

2

ii

185] LARVAL SCARABAEOIDEA—HAYES 101

PRAVE BS

102 ILLINOIS BIOLOGICAL MONOGRAPHS [186

EXPLANATION OF PLATE IX

CAUDAL AND LATERAL ASPECTS OF HEAD; ANTENNAE, MAXILLAE AND Parts, SPIRACLES, LEGS
Fig. 92. Phyllophaga crassissima. Caudal aspect of the head.

Fig. 93. Canthon laevis. Caudal aspect of the head.

Fig. 94. Passalus cornutus. Antenna.

Fig. 95. Stephanucha pilipennis. Antenna.

Fig. 96. Anomala kansana. Antenna.

Fig. 97. Ligyrus gibbosus. Cephalic aspect of right maxilla.

_ Fig. 98. Canthon laevis. Cephalic aspect of right maxilla.

Fig. 99. Amphicoma sp. Cephalic aspect of right maxilla.

Fig. 100. Aphodius sp. Cephalic aspect of right maxilla.

Fig. 101. Anomala kansana. Prothoracic leg.

Fig. 102. Anomala kansana. Metathoracic leg.

Fig. 103. Passalus cornutus. Cephalic aspect of right maxilla.

Fig. 104. Stephanucha pilipennis. Cephalic aspect of right maxilla.
Fig. 105. Anomala kansana. Caudal aspect of right maxilla.

Fig. 106. Anomala kansana. Cephalic aspect of right maxilla.

Fig. 107. Anomala kansana. Articulation of maxilla and postgena.
Fig. 108. Anomala kansana. Lateral aspect of the head.

Fig. 109. Articulation of mandible and maxillae with head capsule.
Fig. 110. Anomala kansona. Labrum.

Fig. 111. Amphicoma sp. Stridulating teeth of right maxilla.

Fig. 112. Anomala kansana. Stridulating tooth of left maxilla.

Fig. 113. Anomala kansana. Stridulating teeth of right maxilla.
Fig. 114. Cotalpa lenigera. Stridulating teeth of right maxilla.

Fig. 115. Ligyrus gibbosus. Mesal aspect of fused galea and lacinia.
Fig. 116. Cotalpa lanigera. Mesal aspect of fused galea and lacinia.
Fig..117. Canthon laevis. Mesal aspect of divided galea and lacinia.
Fig. 118. Phyllophaga crassissima. Stridulating teeth of right maxilla.
Fig. 119. Canthon laevis. Stridulating teeth of right maxilla.

Fig. 120. Euphoria inda. Mesal aspect of fused galea and lacinia.
Fig. 121. Phyllophaga crassissima. Mesal aspect of fused galea and lacinia.
Fig. 122. Anomala kansana. Left prothoracic spiracle.

Fig. 123. Trox sp. Left prothoracic spiracle.

Fig. 124. Ligyrus gibbosus. Stridulating teeth of right maxilla.

Fig. 125. Euphoria inda. Stridulating teeth of right maxilla.

ABBREVIATIONS EMPLOYED

ac alacardo of occipital foramen

ant antenna opg occipito-postgenal suture
cd cardo pa preartis

al claw pe preclypeus

cx coxa tel precoila

es epicranial suture of palpifer

f front pg postgena
jm femur pra parartis

g gena pre paracoila

1 labrum ps parastipes or subgalea
le labacoria psc postclypeus

lp labial palpus ple postartis

m mala ple postcoila

md mandible s stipes

mla maxillaria or maxillary pleurite sé subcardo

mp maxillary palpus sm submentum

ms maxillary scraper st stridulating tooth

mt mentum th terbio-tarsus

mx maxilla ty trochanter

oc occiput v vertex

ILLINOIS BIOLOGICAL MONOGRAPHS VOLUME XII

B

96 ANOMALA Q
KANSANA.

(} PHYLLOPHAGA
CRASSISSIMA

97
LIGYRUS

ane 113 ANOMALA 114cOTALPA

N)) *A18PHYLLOPHAGAS® = 119CANTHON
AC) | Sy

124 LIGYRUS 125 EUPHORIA

(O}

Ss

HAYES LARVAL SCARABAEOIDEA PLATE IX

= f . :
a . ‘om

8) ge YN bt Se Oe oe erg 6 we eel
s ' - :

187] LARVAL SCARABAEOIDEA—HAYES 103

PLATE X

104 ILLINOIS BIOLOGICAL MONOGRAPHS [188

EXPLANATION OF PLATE X
Crpuatic AsPpECT OF HEAD; HYPOPHARYNX, STRIDULATING LEGS

Fig. 126. Ochrosidia (Cyclocephala) immaculata. Cephalic aspect of the head.

Fig. 127. Pinotus (Copris) carolina. Cephalic aspect of the head.

Fig. 128. Cotalpa lanigera. Hypopharynx.

Fig. 129. Euphoria inda. Hypopharynx.

Fig. 130. Canthon laevis. Hypopharynx.

Fig. 131. Phyllophaga crassissima. Hypopharynx.

Fig. 132. Ligyrus gibbosus. Hypopharynx.

Fig. 133. Anomala kansana. Hypopharynx and mandibles showing their relation to each
other.

Fig. 134. Anomala kansana. Hypopharynx with pharynx attached.

Fig. 135. Ceruchus piceus. Metathoracic leg showing stridulating surface on the trochanter.

Fig. 136. Ceruchus piceus. Mesothoracic leg showing stridulating surface on the coxa.

Fig. 137. Passalus cornutus. Meso- and metathoracic legs showing the stridulating modifi-

cation.
ABBREVIATIONS EMPLOYED
cx coxa mil metathoracic leg
jm femur ph pharynx
he hypopharynx pla postcoila
md mandible tt tibio-tarsus

msc mesothoracic leg iv trochanter

ILLINOIS BIOLOGICAL MONOGRAPHS

VOLUME XII

127 pinoTuS CAROLINA

ZN
IoKSY
\ ya N
/L MU I\

nn YE

130 cANTHON
129 EUPHORIA INDA LAEVIS

PHYLLOPHAGA
CRASSISSIMA.

132

Hy PoP YNX
LIGYRUS GIBBOSSUS 133 dalle

134 HYPOPHARYNX
AND MANDIBLES AND PHARYNX

mt]
/

136 CERUCHUS PICEUS 43'7 PASSALUS CORNUTUS
LARVAL SCARABAEOIDEA PLATE X

189] LARVAL SCARABAEOIDEA—HAYES 105

PLATE XI

106

Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.

138.
139.
140.
141.
142.
143.
144.
145.
146.
147.
148.
149.
150.
151.
£52:
153;
154.
155.

ILLINOIS BIOLOGICAL MONOGRAPHS

EXPLANATION OF PLATE XI
RApDULA OF LAST VENTRAL ABDOMINAL SEGMENT

A phodius sp.
Amphicoma sp.
Serica sp.

Polyphylla variolosa.
Macrodactylus subspinosus.
Anomala kansana.
Pelidnoia punctata.
Ligyrus gibbosus.
Strategus anteaus.
Dynastes tityrus.
Euphoria inda.
Euphoria sepulchralis.
Cotinis nitida.

Trox sp.

Passalus cornutus.
Sinodendron rugosum.
Dorcus sp. (Dorsal).
Dorcus sp. (Ventral).

[190

ILLINOIS BIOLOGICAL MONOGRAPHS VOLUME XII

(Ge AG Nit
DAN

WPA)
Ly, ANN x
at MN

,

STRATEGUS ANTEAUS DYNASTES TITYRUS

149
148 EUPHORIA INDA FypHoRIA SEPULCHRALIS 150

COTINIS NITIDA

| f : }
153 154 155 vores, SP

SINODENDRON RUGOSUM = DORCUS. SP

151 TROX SP

152
PASSALUS CORNUTUS

HAYES LARVAL SCARABAEOIDEA PLATE XI

a =~ PA 2 i

A het eee oh ey yt Cal) oaPmanives — ol Ap 4 ety bb ek eee

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191]

LARVAL SCARABAEOIDEA—HAYES

PLATE XII

107

108

Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.

156.
157.
158.
159.
160.
161.
162.
163.
164.
165.
166.
167.

ILLINOIS BIOLOGICAL MONOGRAPHS

EXPLANATION OF PLATE XII
RADULA OF LAST VENTRAL ABDOMINAL SEGMENT IN PHYLLOPHAGA

Phyllophaga lanceolata.
Phyllophaga cribrosa.
Phyllophaga farcia.
Phyllophaga toria.
Phyllophaga latifrons.
Phyllophaga ephilida.
Phyllophaga longitarsa.
Phyllophaga gracilis.
Phyllophaga futilis.
Phyllophaga prunina.
Phyllophaga congrua.
Phyllophaga calceata.

[192

ILLINOIS BIOLOGICAL MONOGRAPHS VOLUME XII

P CRIBROSA 158

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2

th CUTIE py
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r

4, uw =e
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PTORTA 161 PEPHILIDA

163 PR GRACILIS

166 PCONGRUA 167 P CALCEATA

HAYES LARVAL SCARABAEOIDEA PLATE XII

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LARVAL SCARABAEOIDEA—HAYES

PLATE XIII

109

110

Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.

168.
169.
170.
171.
172.
173:
174.
175:
176.
177:
178.
179.

ILLINOIS BIOLOGICAL MONOGRAPHS

EXPLANATION OF PLATE XIII
RADULA OF Last VENTRAL ABDOMINAL SEGMENT IN PHYLLOPHAGA

Phyllophaga crassissima.
Phyllophaga bipartita.
Phyllophaga micans.
Phyllophaga vehemens.
Phyllophaga fusca.
Phyllophaga horni.
Phyllophaga fervida.
Phyllophaga drakei.
Phyllophaga marginalis.
Phyllophaga fraterna.
Phyllophaga corrosa.
Phyllophaga profunda.

[194

ILLINOIS BIOLOGICAL MONOGRAPHS VOLUME XII

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— Cee > Satay,

171 P VEHEMENS 173 PHORNI

174 175 PDRAKEL

FP PROFUNDA

177 2 FRATERNA 178 BP CORROSA 179

HAYES LARVAL SCARABAEOIDEA PLATE X11

195]

LARVAL SCARABAEOIDEA—HAYES

PLATE XIV

111

112

>.

ILLINOIS BIOLOGICAL MONOGRAPHS

EXPLANATION OF PLATE XIV

[196

RADULA OF Last VENTRAL ABDOMINAL SEGMENT IN PHYLLOPHAGA, OCHROSIDIA, AND PINOTUS

Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.

180.
181.
182.
183.
184.
185.
186.
187.
188.
189.
190.

191

Phyllophaga tmbplicita.
Phyllophaga balia.
Phyllophaga hirticula.
Phyllophaga delata.
Phyllophaga ilicis.
Phyllophaga crenulata.
Phyllophaga vetula.
Phyllophaga affabilis.
Phyllophaga tristis.
Phyllophaga inversa.
Ochrosidia immaculata.
. Pinotus carolina.

ILLINOIS BIOLOGICAL MONOGRAPHS VOLUME XII

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187 PAFFABILIS 188 FETRISTIS

190 OCHROSIDA IMMACULATA 191 PINOTUS CAROLINA

HAYES LARVAL SCARABAEOIDEA PLATE XIV

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PLATE XV

114

Fig. 192
Fig. 193
Fig. 194
Fig. 195
Fig. 196

ILLINOIS BIOLOGICAL MONOGRAPHS

EXPLANATION OF PLATE XV

LiFe STAGES AND INSTARS OF A TYPICAL SCARABAEID, Anomala kansana

(For third instar of this species see figure 8, Plate II)

. Egg stage.

. First larval instar.

. Second larval instar.
. Pupal stage.

. Adult stage.

ABBREVIATIONS EMPLOYED

al anal slit
ant antenna

ce compound eye
clp clypeus

es epicranial suture

f front
fw fore wing

gt developing genitalia
hw hind wing

I labrum of larva
la labium

lb labrum of pupa

md mandible

ml mesothoracic leg
mp maxillar palpus
mtl metathoracic leg
mx maxilla

pe preclypeus

pl prothoracic leg
psc postclypeus

pt prothorax

st thoracic sterna
ts tarsal segments

I-III thorax
I-10 abdominal segments

[198

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ANOMALA KANSANA -LIFE STAGES

8 om,

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HAYES LARVAL SCARA BAEOIDEA PLATE XV

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Abundance, 58

Aesalinae, 32

Allorhina, 10

Ammoecius, 44

Amphicoma, 41
epipharynx, 25

Anal orifice, 43

Anomala, 44, 45, 63
abdominal segments, 41

Anomala aenea, 12, 48
clypeus and labrum, 21
epipharynx, 22
mandibles, 35

Anomala binotata, 13, 57
clypeus and labrum, 21
epipharynx, 28
life-cycle, 66
mandibles, 35

Anomala innuba, 9, 13, 63
epipharynx, 28
life-cycle, 67

Anomala kansana, 16, 45, 58
clypeus and labrum, 21
epipharynx, 28
life-cycle, 67

Anomala ludoviciana, 63

Anomala orientalis, 9
epipharynx, 28

Anomala phyllopertha, 28

Anomalini
epipharynx, 28
life-cycle, 66

Antennae, 18

Aphodinae, 8
epipharynx, 24
oviposition, 48

Aphodini, 24

Aphodius, 20, 44
abdominal segments, 41
epipharynx, 24
food, 58
maxillae, 38

A phodius fimetarius, 20, 24

Aphodius porcus, 71

Aphodius rufipes, 20

Aphodius troglodytes, 71

Asiatic beetle, 9

Ataenius inops, 58

Ateuchus, 44

Bumble flower beetle, 9, 10

INDEX

Canthon, 17, 18, 22, 25
Canthon ebenus
clypeus and labrum, 20
mandibles, 34
maxillae, 38
Canthon laevis, 17, 18
clypeus, 20
epipharynx, 23, 25
hypopharynx, 39
labrum, 20
mandibles, 33, 34
maxillae, 37, 38
oviposition, 47
Carrot beetle, 9
Ceruchus piceus, 36
Cetonia, 44
Cetoniinae, 8, 70
epipharynx, 30
key to genera, 77
life-cycle, 70
maxillae, 38
oviposition, 47
spines, 41
Chaetopisthes, 71
Clypeus, 20
Coprinae, 8
epipharynx, 23
mandibles, 35
maxillae, 37
stridulation, 45
Coprini, 24
Copris, 17, 71
Copris carolina, 20
Copris lunaris, 20
Copris tullius (anaglypticus), 24
Corythoderus, 71
Coltapa, 29, 51
Cotal pa lanigera, 9, 13, 17, 45, 58
clypeus and labrum, 21
epipharynx, 29
hypopharynx, 39
life-cycle, 67
mandibles, 35
maxillae, 38
molting, 51
oviposition, 47
Cotinis nitida, 10, 58
epipharynx, 30
life-cycle, 70, 71
Cremastochelius, 31
Cremastochelius nitens, 70
Cyclocephala, 11, 61, 67, 69

115

116 ILLINOIS BIOLOGICAL MONOGRAPHS [200

Cyclocephala immaculata, 69 Geotrupes, 71
Cyclocephala villosa, 67 epipharynx, 22
Cyclocephalini, 29 striculation, 45

Geotrupes stercorarius, 25
Geotrupinae, 8
epipharynx, 25
Glaphyrinae, 25
Goldsmith beetle, 9
Gopherus polyphemus, 71
Green June beetle, 10
Gymnetini, 30
Gymnopleuri, 71

Development, 50
Dichelonyx, 66
Diplotaxis, 48, 66
clypeus and labrum, 20
epipharynx, 26
mandible, 35
Dor beetles, 8
Dorcinae, 32
Dorcus, 43, 44
epipharynx, 32
mandibles, 36
Dung beetles, 8
Dynastes, 48, 67
Dynastes tityrus, 30
Dynastinae, 8
epipharynx, 29
key to genera, 76

Habitat preferences, 55
Hatching, 48
Heliocopris dominus, 47
Hibernation, 61
Historical review, 10
Hypopharynx, 39

Japanese beetle, 9, 42

life-cycle, 67 June bags ,i6
maxillae, 38
oviposition, 47 Keys 158!
Dyscinetus barbatus, 68 :
; Labium, 40
Dyscinetus trachypygus, 68 Tabrim, 20
Lachnosterna, 11, 44, 69
Economic importance, 8 Lamellicornia, 8
Eggs, 47 Laparosticti, 8
Epipharynx, 22 life-cycle, 71
Euchlora frischii, 21 Legs, 42
Euethola rugiceps, 68 Ligyrodes relictus, 9
Euparia, 71 clypeus and labrum, 21
Euphoria, 14, 18, 41, 64 epipharynx, 30
Euphoria fulgida, 10, 13 food, 58
life-cycle, 70 life-cycle, 68
Euphoria inda, 9, 17, 45 mandibles, 35
clypeus and labrum, 21 method of rearing, 14
food, 58 oviposition, 47
hypopharynx, 39 Ligyrus, 21, 68
life-cycle, 70 Ligyrus gibbosus, 9, 17, 45, 57, 61
mandibles, 36 clypeus and labrum, 21
maxillae, 38 epipharynx, 30
Euphoria sepulchralis, 10, 13 hypopharynx, 39
clypeus and labrum, 21 life-cycle, 67, 68
food, 58 mandibles, 35
life-cycle, 70 maxillae, 38
oviposition, 48
Fig-eater, 10 Ligyrus tumulosus, 68
Food habits, 54 Listochelus, 44

Friedenreichi, 71 Literature, 11, 12

201]

Lucanidae, 8
abdominal segments, 41
antennal segments, 19
economic importance, 8
epipharynx, 32
hypopharynx, 40
importance of family, 8
key to genera, 77
maxillae, 37
number of species, 8
oviposition, 47
setation, 41
sexual differences, 8
stridulation, 45
Lucanus, 10
mandibles, 36

Macrodactylini, epipharynx, 28
Macrodactylus, 44
Macrodactylus subspinosus
epipharynx, 28
life-cycle, 66
Materials, 13
May beetles, 8
Maxillae, 37
Melolontha, 44
Melolontha melolontha, 8
life-cycle, 64
Melolontha vulgaris, 21
Melolonthinae, 8
epipharynx, 26
key to genera, 75
life-cycle, 64
mandibles, 35
maxillae, 38
oviposition, 47
spiracles, 43
stridulation, 45
Methods, 13
Molting, 50

Ochrosidia, 11, 61, 68, 69
Ochrosidia immaculata, 57, 61, 63
clypeus and labrum, 21
epipharynx, 27, 30
life-cycle, 67, 68, 69
mandibles, 36
Onthophagus, 17, 22, 24, 71
Onthophagus pennsylvanicus, 20
mandibles, 34
maxillae, 38

INDEX

Oryctes, 44

Oryctes nasicornis, 70

Oryctes rhinoceros, 46

Osmoderma, 10, 44
epipharynx, 30

Osmoderma eremicola, 70, 71

Oviposition, 47

Parastasia, 44
Passalidae, 8
antennae, 19
economic importance, 8
epipharynx, 33
hypopharynx, 39
legs, 40
maxillae, 37
oviposition, 47
setation, 41
stridulation, 45
thoracic annulets, 40
Passalus, 16, 18, 41, 42, 43, 44
Passalus cornutus, 16
antennal segments, 19
clypeus and labrum, 22
epipharynx, 33
food 8
mandibles, 36
stridulation, 46

Pelidnota punctata, 9, 13, 44, 58, 64

epipharynx, 29

life-cycle, 67

method of rearing, 14

oviposition, 47
Phyllopertha, 44
Phyllopertha horticola, 12, 48

epipharynx, 22

117

Phyllophaga, 9, 11, 13, 15, 21, 23, 28, 33, 44,

45, 47, 51, 56, 58, 59, 60, 61, 63

abundance, 59

food, 56

hibernation, 61

key to species, 78

life-cycle, 66

molting, 51

oviposition, 47

pupation, 63

stridulation, 46
Phyllophaga affabilis, 51

life-cycle, 65, 66
Phyllophaga anxia, 66
Phyllophaga arcuata, 12

life-cycle, 65

118 ILLINOIS BIOLOGICAL MONOGRAPHS

Phyllophaga bipartita, 51
life-cycle, 65
Phyllophaga burmeistert, 65
Phyllophaga congrua, 60
life-cycle, 65
Phyllophaga corrosa, 52
Phyllophaga crassissima, 13, 17, 45, 56, 59, 60
clypeus and labrum, 21
hypopharynx, 39
life-cycle, 65
mandibles, 34, 35
maxillae, 38
Phyllophaga crenulata, 65
Phyllophaga cribrosa, 27
Phyllophaga drakii, 66
Phyllophaga ephilids, 65
Phyllophaga fervida, 12
life-cycle, 64
Phyllophaga fraterna, 65
Phyllophaga fusca, 64, 65
Phyllophaga futilis, 13
epipharynx, 23, 26
life-cycle, 65
Phyllophaga grandis, 65
Phyllophaga hirticula, 65
Phyllophaga ilicis, 65
Phyllophaga implicata, 13, 56
life-cycle, 65
Phyllophaga inversa, 65
Phyllophaga lanceolata, 9, 56, 60, 62
clypeus and labrum, 20
epipharynx, 27
life-cycle, 12, 65
mandibles, 35
Phyllophaga longitarsa, 57
life-cycle, 65, 66
Phyllophaga nitida, 66
Phyllophaga praetermissa, 52, 57
Phyllophaga rubiginosa, 13, 56, 59, 60
Phyllophaga rugosa, 13, 56, 59, 60
life-cycle, 65, 66
Phyllophaga submucida, 13, 57, 60
life-cycle, 65
Phyllophaga tristis, 57
epipharynx, 28
life-cycle, 12, 64, 65
Phyllophaga vandinei, 65
Phyllophaga vehemens, 13, 51, 60
life-cycle, 64, 65
Phytalis, 44
Phytalis smithi, 64
Pinotus, 17, 40, 43

[202

Pinotus carolina
labrum, 20
oviposition, 47
thoracic annulets, 40
Pleocoma, 19
Pleurosticti, 8
Polyphylla, 44, 66
epipharynx, 28
Polyphylla hammondi, 58
Polymoechus brevipes, 58
clypeus and labrum, 21
epipharynx, 29
mandibles, 35 :
Popillia japonica, 9, 11, 43
epipharynx, 22, 28
life-cycle, 66
Psammobius, 71
Pupation, 63

Radula, 41
Rhizotrogus, 44
Rhizotrogus fallenti, 21
Rhyssemus, 71
Rutelinae, 8
epipharynx, 28
key to genera, 75
life-cycle, 66
mandibles, 35
maxillae, 38
oviposition, 47
Rutelini
epipharynx, 29
life-cycle, 66

Sacred beetle, 10
Scarabaeidae, 8
abdominal segments, 41

abundance, 60

antennal segments, 19

economic importance, 8

egg stage, 48

food, 54, 57

hypopharynx, 39

key to subfamilies, 74

maxillae, 37

_striculation, 45

Scarabaeoidea, 8

key to families, 73
Scarabaeus, 10, 71
Scarabaeus sacre, 10
Segmentation, 40

203]

Serica, 44, 48, 66
epipharynx, 26
Serica brunnea, 21
Setation, 41
Sinodendron, 18, 43, 44
epipharynx, 32
mandibles, 36
Sinodendron rugosum
clypeus, 22
epipharynx, 32
mandibles, 36
Spiracles, 43
Spotted grapeleaf beetle, 9
Stag-beetles, 8
Stephanucha pilipennis
clypeus and labrum, 21
epipharynx, 31
Strategus, 18, 48, 67
Strategus antaeus, 70
epipharynx, 30
nest-building habits, 70
Strategus mormon, 47
Strategus quadrifoviatus, 13
life-cycle, 68, 69
Strategus titanus, 68
Stridulation, 44
Strigoderma arboricola, 13
epipharynx, 28
life-cycle, 67

INDEX

Taxonomy, 72
Termitodius, 71
Trichiotinus, 10, 18
Trichiotinus piger, 58, 70
epipharynx, 31
Trichius, 10
Triodonta (Serica) aquila, 26
Trogidae, 8
antennal segments, 19
economic importance, 8
epipharynx, 31
hypopharynx, 39
maxillae, 37
oviposition, 47
striculation, 44
Trox, 8, 18
clypeus and labrum, 21
epipharynx, 31
food, 8
importance, 8
mandibles, 36
peritreme, 43
propleuron, 40

Xyloryctes, 17
Xylotrypes, 44

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