FIELDIANA
Geology

Published by Field Museum of Natural History

Volume 26, No. 2 January 9, 1973

On Some Phyllocarids and the Origin
of the Hoplocarida

Frederick R. Schram

Department op Zoology, Eastern Iixinou University
Charlerton, Illinois

INTRODUCTION

Recently I (1969b) described some new Middle Pennsylvanian
hoplocarids. In addition to Tyrannophontes theridion, a rapacious
species related to the stomatopod hoplocarids living today, two
swimming, filter-feeding species were recognized, Kallidecthes rich-
ardsoni and Aratidecthes johnsoni. All these forms, though conform-
ing to the basic hoplocarid body plan', exhibit such diversity as to
indicate that the hoplocarids underwent an extensive radiation in the
Late Paleozoic.

In discussing the evolution of the hoplocarids, I (1969a) suggested
the possibility that the entire superorder Hoplocarida was independ-
ently derived from the leptostracans. Their origin would be separate
and distinct from that of the caridoid eumalacostracans. At that
time, reference was made (p. 281) to an "unnamed leptostracan"
from the Middle Pennsylvanian Essex fauna of Illinois which seemed
to fulfill many of the requirements of a hoplocarid ancestral type
within the leptostracans. This paper will describe and discuss that
animal.

In my 1969 papers the term "leptostracan" was used in the sense
of Caiman (1909), i.e., malacostracans were divided into two groups,
Leptostraca and Eumalacostraca. Although this classification is

1 These characters are: carapace covering the thorax; a kinesis dividing the
cephalon into an anterior procephalon, which bears the eyes and first antennae, and
a postcephalon ; moveably articulated rostrum; thoracopods with a three-segment
protopod, four segment inner branch, and a flap-like outer branch; enlarged ab-
domen; styloid tebon with caudal furcae; and blade-like uropods.

Library of Congress Catalog Card Number: 72-97565

Publication 1158 77

78 FIELDIANA: GEOLOGY, VOLUME 26

adequate for neozoological work, consideration of fossil forms re-
quires some emendation of the taxonomy. Rolfe (1969) has set up a
more useful systematics and his taxonomy will be used here. The
term "Leptostraca" of my earlier papers is to be equated here with
the subclass Phyllocarida as delineated by Rolfe.

In the following description references are made to specific speci-
mens. Prefixes denote the collections in which they are to be found.

PE Field Museum of Natural History

A Hunterian Museum, Glasgow, Scotland

HTP Private collection of Mr. and Mrs. Ted Piecko, Chicago,

Illinois
K Private collection of Mr. and Mrs. James Konecny, Mo-

kena, Illinois

SYSTEMATICS
Subclass Phyllocarida Packard, 1879
Order Hoplostraca, new

Diagnosis. — Carapace not hinged and covering no more than the
thorax; abdomen considerably longer than the thorax; thoracopods
not enclosed laterally by the carapace; anterior abdominal somites
shorter than the posterior somites. (This order is principally based
on the distinctive nature of the body tagma.) L. Carb. — U. Carb.
(M. Penn).

Family Sairocarididae, new

The characteristics of the family will remain, for the time being,
the same as the characters of the order.
Type. — Sairocaris, Rolfe, 1963.

Kellibrooksia, new genus

Diagnosis. — Phyllocarid of moderate size; the carapace not cov-
ering the dorsal portion of the three posterior thoracomeres; the
carapace laterally developed as large lappets which completely cover
the sides of the thorax and only the bases of the thoracopods; most of
the thoracopod not covered by the carapace; abdomen very elon-
gate, somewhat over three times the length of the thorax; the first
four abdominal somites relatively short, the last three somites long;
pleopods on the first five abdominal segments; telson styliform with
furcae as very short spines. M. Penn.

s

Fig. 1. Kellibrooksia macrogasUr. A, HTP 86 displaying ghost-like appendage
preservation and shape of carapace. X 2. B, HTP 4243 with "paddle-like" an-
tennal scales. X 2.

79

80

FIELDIANA: GEOLOGY, VOLUME 26

Fig. 2. Kellibrooksia macrogaster.
age preservation and eye. X 2.

K 11-0009 with typical ghost-like append-

Type of the genus. — Kellibrooksia macrogaster Schram, new
species.

Remarks. — This is a relatively rare crustacean of the Middle
Pennsylvanian Essex fauna (Johnson and Richardson, 1966). Be-
cause of the resemblances of Sairocaris elongata (Peach) and K.
macrogaster to the hoploid morphotype and their apparent distinct-
ness from other phyllocarids, the Sairocarididae are made the basis
of a separate order within the phyllocarids.

Kellibrooksia macrogaster new species. Figures 1-7.

Occurrence. — Francis Creek Shale, Carbondale Fm.

Diagnosis. — Since only one species is recognized at this time, the
diagnosis of the species is the same as that of the genus.

Description. — This animal was approximately 5-6 cm. long from
the anterior point of the carapace to the posterior tip of the telson.
The carapace is very distinctive in outline, somewhat ax-like. Two
definite regions of the carapace can be recognized: an anterior
cephalic portion, ovoid in outline, covering the cephalic segments

FIG. 3. Kellibrooktia macrnga»trr. K 11-0041. A, with carapace showing
location of mandible. X 6. B, closeup of mandible.

81

82 FIELDIANA: GEOLOGY, VOLUME 26

anterior to the mouth, and a posterior thoracic portion developed as
large "branchiostegal" lappets directed ventrad and posteriad (HTP
86, fig. 1).

Details of the cephalothoracic appendages are vague. All these
appendages except the toothed mandibles were only slightly sclero-
tized. The first antennae were apparently directed forward. The
second antennae seem to have had a large "paddle-like" scale (K 11-
0009, fig. 2). K 11-0041 (fig. 3) displays a mandible with a heavy
gnathal lobe located under the carapace between the anterior cephalic
and posterior thoracic areas. The thoracic appendages have only
been seen as ghost-like outlines and none of their structural detail is
discernable (HTP 86); they are only basally enveloped by the
carapace. Eye-like structures projecting from the anterior tip at
the carapace have been observed on a number of specimens (K 11-
0009, fig. 2; K 11-0017).

The carapace was free from at least the posterior thoracic somites.
The thorax is nearly one-third the length of the abdomen.

The first four abdominal somites are short while the last three
are at least twice as long as any one of these. The telson is long and
styliform (PE 15647; K 11-0041, fig. 4), while the caudal furcae are
developed as very small spines. Ghost-like pleopods can be seen on
the first five abdominal segments of K 11-0045 (fig. 5) and other
specimens, but again no structural detail can be discerned.

No sexual dimorphism was noted in the specimens at hand.

A reconstruction and a comparison with Sairocaris elongata are
offered in Figure 6.

Remarks. — The inability to study the appendages of this animal
in detail is disappointing, as much of the life style of crustaceans can
be deduced from their appendages. In this regard, Kellibrooksia is
like other fossil phyllocarids in which the appendages are typically
not preserved. The ghost-like quality of the preservation might
indicate a poorly sclerotized limb, perhaps foliaceous, probably
adapted for swimming.

The relationship of the thoracic legs to the carapace in the sairo-
carids is surely very significant. John Cisne (personal communica-
tion) has investigated the feeding mechanism and behavior of Epine-
balia in Tomales Bay, California. These animals feed on the detritus
in the algal mats in which they live. They filter tremendous amounts
of water in the course of a day, forming boli of detritus which they
will then eat at their leisure. The carapace almost completely en-
velops the thoracic legs and helps to form a food groove. Kelli-

FlC. 4. Telson of Krlhbrookaia macroganlrr. A, PE 15647. X 7. B, K 11-
0041 with arrow pointing to caudml furca. X 6.

n

84

FIELDIANA: GEOLOGY, VOLUME 26

brooksia does not employ the carapace in this manner. The thora-
copods are laterally exposed and as a result K. macrogaster cannot
have fed in the same manner as the living leptostracans, or even
perhaps as the Archaeostraca, who also apparently enclosed the
thoracopods with the carapace.

The overall body form is similar to that of a bottom dweller or
animal with a burrowing habit. The shape is long and fusiform, and
might indicate a behavior in which the creature at least partially bur-
ied itself at times. The mandibles are quite large with well-devel-
oped teeth; such usually indicate tearing or grinding. Although in-
conclusive, certain aspects of the anatomy of K. macrogaster are
similar to those of modern stomatopod hoplocarids (such as body
form, the elongate abdomen, the carapace not covering the posterior
thoracomeres, and a considerable separation between the sense or-
gans at the anterior tip of the cephalon and the mouth). Though
this similarity may only be convergent, it does suggest affinities

Fig. 5. Kellibrooksia macrogaster.
showing ghost-like pleopods. X 4.

K 11-0045, very poor preservation, but

86 FIELDIANA: GEOLOGY, VOLUME 26

between the two. No gut fillings have been noted in any specimens
to date. Gut fillings commonly form prominent preservations in
many of the crustacean species in the Essex fauna. The complete
lack of these in K. macrogaster fossils might indicate a possibly car-
nivorous diet which did not contain a great deal of detritus.

One of the most peculiar aspects of the anatomy of Kellibrooksia
is the large antennal (?) scales. Because of their position on the
body, the scales appear to be associated with the second antennae.
These structures are typically preserved in the position in which
they are displayed in Figures 1 and 2. On a few specimens, however,
such as PE 10363 (not illustrated), they are dropped back toward
the thoracic portion of the carapace. The living leptostracans have
no antennal scale, the exopod being absent on the second antenna,
and the first antenna has a tiny scale associated with the first an-
tennal flagellum.

There are several possible uses such a peculiar structure may have
been put to: the condition of PE 10363 and the paddle-like nature of
the structure suggests that the scale may have been lying along the
side of the carapace or perhaps even inside the "branchiostegal"
chamber. A twisting or oar-like movement could possibly have
helped to set up a feeding current. The paddle portion of the scale
could have helped to create a temporary suction-like pull either in
the chamber or alongside the carapace, drawing a feeding current
back toward or to the thoracic appendages. Although none of the
living phyllocarids employ such a specialized structure to set up a
feeding current, the much elongated cephalic area may have re-
quired it.

The scale might also have been directed laterad in life. A beat-
ing of the scales when the animal was on or near the muddy bottom
could then have served to stir up the sediment. The animal might
then have fed on the small animals and organic debris suspended in
the cloud.

Another possibility lies in the scales being used as accessory swim-
ming organs. In this case the paddles would have been extended
outward like wings and used like oars in facilitating movement for-
ward. One could also easily imagine copulatory, olfactory, fossorial,
or defensive uses for these structures. Any of these suggestions
could have been possible. There are no modern analogs with which
to compare these scales since modern phyllocarids do not have a
scaphocerite and no eumalacostracans have anything so big. As a

FlC. T. HolotypC "f Krllthrnrmkia marrogaMltr, PK I2"iOI. X 2.

|7

88 FIELDIANA: GEOLOGY, VOLUME 26

personal preference, the first suggestion above seems acceptable.
The nature of the jaws, however, may indicate that alternative two
is more likely.

K. macrogaster is rare in the Essex fauna. Except for their ap-
pendages, the specimens are very nicely preserved, but they are too
scarce for biometric analysis.

This genus is named in honor of my colleague Dr. H. K. Brooks
of the University of Florida whose persistent efforts over the years
have served to place the study of Paleozoic malacostracans on a
sound scientific basis.

Holotype.—FE 12201 (fig. 7). Generously donated to Field Mu-
seum by Mr. and Mrs. Francis Wolff of Park Forest, Illinois.

PHYLOGENETIC CONSIDERATIONS

Rolfe (1969) offers the most complete and recent discussion of
phyllocarid evolution. Any presentation of primitive malacostra-
can phylogeny can be only tentative because of the incomplete na-
ture of phyllocarid fossils. Phyllocarids were apparently among the
earliest of arthropods. The middle Cambrian Burgess Shale fauna
contains a number of carapaces referred to this group. But most of
the fossil phyllocarid material of any age consists only of carapaces,
carapace fragments, isolated telsons, and a few abdominal somites.
Very seldom does one find an intact animal, and almost nothing is
known of the appendages. Rolfe does offer a valuable summary of
what little has been described on fossilized phyllocarid limbs.

Ideas on the evolution of the phyllocarids are consequently based
on limited data. As Rolfe has indicated, one uses what is available
for descriptive work, and this is frequently no more than one or two
characters such as segment size or telson shape. We must still seek,
however, within this poorly understood group, the ancestral eumala-
costracan stocks even though only general body form can be con-
sistently utilized.

In this regard, the Mazon Creek assemblages are of considerable
assistance. Although important characters of the appendages are
lacking in Kellibrooksia macrogaster, general form and relationship
of parts are preserved, features typically unavailable in fossils from
other localities. This is due to the intact-body and soft-part preser-
vation of the Mazon Creek concretions.

From the Paleozoic hoplocarids an array of characters, the hop-
loid facies, was developed (Schram, 1969a, b) to elucidate a gen-

SCHRAM: ON PHVLLOCAUIDJ5 AND HOPLOCARIDA

eralized morphotype. To \\ hat extent do the sairocand* 511 the role
of a phyllocarid ancestor ti» such an hoploid morpi. The

carapace does cover tlu- thorax, although the dorsal portion*, of M.me
of the posterior somites are exposed. The arrangement of th-
tennae seems to indicate a cephalic kinesis. The first antennae
to hi' directed straight forward and the iecond antennae outward in
some fashion, as in the Paleoxoic hoplorarids. Even though the
kinesis itself is not observable, such an arrangement ha* been in-
terpreted as indicating a moveable area in thecephalon between the
antennae. No rostrum has been seen on any hopliwtraran spect-
mens (it is possible that there may not have been any and the exact
nature of the appendages is unknown. Hut the abdomen ia quite
large, some three times the length of the thorax. In addition, it ia
the anteriormost abdominal segments of both Satrotari* and KM-
brooksia which are reduced. This reduction may prefigure the pos-
sible fusion of the first and second abdominal segments in the reduc-
tion to six abdominal segments in thr ttomatopod hoploejuida. Thr
telson is styliform with furcae, although th«Tv an* no uro|»od*.

There appear to U* some morphologic differences in Sairocaru
related to age as indicated by size. I am Nil to thin from study of thr
original descriptions <»f Ceratiocaru flongaia, ('. *rorpioi</«-« IVach.
1882 . and Acanthocaria attrmiatu* Peach, lHH.'i and examination
of four specimens Dr. Rolfe loaned me from the lluntenan Museum.
The abdomen to thorax ratios appear to In- greater in the *mall«*r.
younger specimens. This ratio decreases in the larger, older speci-
mens. Younger Sairocaru rUmgnia .seem to have relatively longer
abdomens than the older adults.

The differences between Krllibrovksta maerogoMler and Sairaearii
ebngata would seem to warrant maintaining stparau i for

these forms. Sairocaru does not have the extreme development of
the carapace into cephalic and thoracic region*. Although th«
a slight delineation in Sairocaru of an anterior cephalic jnirtion and a
posterior thoracic area, thi a whole i* mc»re »ub-tnangu-

iar than "ax-like." Sairocaru has only the two |>o»terior thoca-
comeres exposed, and the enlarge! abdomen d«*-» not cjuite reach
the extreme of KeUibrooksia. The abdomen of Sairocan*. according
to Rolfe, is only about 2'.. time* the length of the thorax, though
Peach's 1882, 1883 original descriptions indicate an abdomen up
to three to four tim«-s an long. That of Kflltbtook*ta m slightly
threc times as long as the thorax Thr pro|»ortion» of the abdominal

&r

/

/ ^'••

&**■ y

?ji&

\-

J****"'

Fig. 8. Sairocaris elongata. A, A-2016b with posterior portion of thorax and
abdomen of a younger individual. X 2. 3. B, A-2213 with thoracic fragment and
abdomen of an older individual. X 2. 3. Arrows indicate thorax-abdomen bound-
ary. Note the slightly longer abdomen in the apparently younger individual.

90

i'HYLUK IRIDS UtD HOPLOCARIDA »!

n\ In KfUtbtualvi* the first four
s"m 1 u'imjui the *an> i reduced; the last thrw are

a" : ami long. In .s'oirord'M ihr first *n aegment* in-

[HwUnoriy. while the seventh srgmmt u greatly en-
larged. Some examples of >'. rlongttta from ihr HunttTtan Museum
an- illustrate! in Figu

The difference* note*! hen rtainly a* great a» or greater

than those that .separate other genera of phyllocarida. Ytw example.
the carapaces of the Devonian genera ('alitor ami /'ryrAaroru are
almost identical in outline. The anterior tuU-rcle on f VW/iror it more
ventrally liK-at«-<l than on I'tyclmcati* l*lyekaear%* has some an-
terior nodes and a lateral ridge which CoUisot lack*. The differ-
ences l)etween Kleuikeroearu and Momttea mall / frulaero-
caris has shallow anlerodorsal griN.\en on iu carapace instead of
deep grooves, the lateral ridge is shorl and it only anterior and dor»
not extend to the posteroventral spine. V^gocan* differ* from An*-
in having a more |>ointed anterior horn, a |*»inte«l median
posterodorsal process, and a thinner cuticle In short, the differ-
ences between the above generic juir* (selected at random ■
amples) are ones of carapace decoration, difference* which in cumala-
costracans might be used to merely * ;... The differ-
ences between Sairocaru and Kftltbrooktia are great enough to war-
rant a generic separation.

It would seem that the hoplostrarans are certainly distinctive
phyllocarids. Given the current knowledge and understanding of
Paleozoic hoplocarids, this dittinctiveneat would teem to justify
separating these two genera from the Archacostraca and placing them
in a separate order. The purpose of taxonomy is to reflect rnir cur-
rent concepts of phytogeny (tee fig 9 It still appemn that then- is
a distinct dichotomy within the Kumalacostraca. The boploidt
exist, on one hand, with their emphasis on the abdomen as a r^
tacle for the major organs, and the caridoidt, on the other, with their
emphasis on the thorax xh the visceral receptacle Such a dichotomy
must extend hack into the phyllocarids. The hoplostracan* could
represent part of the line that culminated in the hoploids Slewing
1956 interpreted the 1»w«t Devonian XaMetan* *i*rtt:% as a can-
doid ancestral type; however. Rolfe 1969* disagrees with this. The
lines leading through the phyllocarids to the hoploid and randoid
types should Im- recognized a.s our knowledge of phyllorand fossils
improves. Pre-hoploid and pre-caridoid phyllorands probably

FIELDIANA: GEOLOGY, VOLUME 26

Caridoid

Super-order s

Hoplocarida

Archaeostraca

Sairocariidae

Leptostraca

Hoplostraca

Hymenostraca

92
<

I—
C/>

O

—I
<

UJ

^<

g

<

u

O

_i
_j

>■

X

Q.

Fig. 9. Inter-relationships of the four orders of the subclass Phyllocarida and
the various superorders of the Eumalacostraca. The order Hoplostraca, of which
the sairocarids are members, probably contains the ancestral type of the Eumala-
costracan superorder Hoplocarida. The Archaeostraca may be ancestral to the
caridoid eumalacostracans. The Leptostraca (containing the only living forms of
the Phyllocarida) seem to stand by themselves, but comparison with the fossil
orders is difficult. The Hymenostraca, though sharing the unhinged carapace
characteristic with the Hoplostraca, are also difficult to relate to other phyllo-
carids.

underwent extensive radiations in their own right as did other phyl-
locarid forms. There are late Paleozoic and Mesozoic-Cenozoic
radiations of the eumalacostracans, and the phyllocarids without
question had a similar history of their own in the early Paleozoic.
We should be able to identify remnants of these radiations in the
fossil record.

The sairocarids as now understood do not perfectly conform to
our expectations of an ancestral type, being specialized in the form
of the cephalothorax, the enlargement of the abdomen, and the pe-
culiar nature of the antennal scales. The appendage anatomy
could have been informative in this regard. The sairocarids thus
probably represent a specialized part of the hoplostracan radiation.
As direct ancestors of the hoploids they would tell us little. They do
indicate, rather, the existence of an extensive and diverse early
Paleozoic phyllocarid radiation.

SCHRAM: ON PHYLLOCARIDS AND HOPLOCARIDA 98

SUMMARY

A new species of Middle Pennsylvanian phyllocarid, Kellibrooksia
macrogaster, from the Middle Pennsylvanian Mazon Creek Essex
fauna of Illinois is described. The recognition of this form, combined
with a related species from the British Lower Carboniferous, Sairo-
caris elongata, warrants the erection of a new order to accomodate
the pre-hoploid phyllocarids.

ACKNOWLEDGEMENTS

The author wishes to thank Mrs. Helen Pieko and Mr. and Mrs.
James Konecny for their co-operation and Mr. and Mrs. Francis
Wolff for donating to Field Museum some years ago the specimen
that became the holotype. Drs. W. S. James, Eastern Illinois Uni-
versity; E. S. Richardson, Jr., Field Museum of Natural History; and
W. D. I. Rolfe, Hunterian Museum, Glasgow, Scotland, read the
manuscript and offered constructive discussion. Dr. Rolfe gener-
ously loaned me what material he had of Sairocaris elongata and
originally called to my attention the similarity between these ani-
mals. John Cisne, University of Chicago, offered discussion of
neballiacean behavior and its bearing on phylogeny. This does not
imply agreement, necessarily, by these people with my presentation.
Mrs. Susan Reis patiently typed the manuscripts in its various stages
of revision.

REFERENCES

Calman, W. D.

1909. Crustacea. In Lancaster, A Treatise on Zoology, Part 7, Black Ltd.,
London, 346 pp.

Johnson, R. G. and E. S. Richardson, Jr.

1966. A remarkable Pennsylvanian fauna from the Mazon Creek area, Illinois-
Jour. Geol., 74, no. 5, pp. 626 631.

Peach, B. N.

1882. On some new crustaceans from the Lower Carboniferous rocks of Rskdale
and Liddesdale. Trans. Roy. Soc. Edinburgh, 30, pp. 73-91.

1883. Further researches among the Crustacea and Arachnida of the Car-
boniferous rocks of the Scottish border. Trans. Roy. Soc. Edinburgh, 30,
pp. 511-529, pis. 28-29.

Rolfe, W. D. I.

1963. Morphology of the telson in Ceratiocarinl cornualletuti* (Crustacea:
Phyllocarida) from Czechoslovakia. Jour. Paleo., 37, no. 2, pp. 486-488.

94 FIELDIANA: GEOLOGY, VOLUME 26

1969. Phyllocarids. In Treatise on Invertebrate Paleontology, Part R, Ar-
thropoda 4, Crustacea, Myriapods, and Insects.

Schram, F. R.

1969a. Polyphyly in the Eumalacostraca? Crustaceana, 16, no. 2, pp. 243-250.
1969b. Some Middle Pennsylvanian Hoplocarida (Crustacea) and their phylo-
gentic significance. Fieldiana: Geol., 12, no. 14, pp. 235-289.

Siewing, R.

1956. Untersuchungen zur morphologie der Malacostraca. Zool. Jahrb., Anat.,
75, pp. 39-176.