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FIELDIANA

Geology J^ss&aas;

Published by Field Museum of Natural History

Volume 30, No. 3 August 29 ,0?4

A Trematopsid Skull from the Lower Permian,

and Analysis of Some Characters of the Dissorophoid

(Amphibia: Labyrinthodontia) Otic Notch

John R. Bolt

Assistant Curator, Fossil Reptiles and Amphibians
Field Museum of Natural History

INTRODUCTION

The partial skull (UR 2400) described in this paper came from the
Lower Permian Fort Sill locality, Comanche County, Oklahoma.
This locality has been described elsewhere (see Gregory et ah, 1956;
Olson, 1967). Olson's faunal list contains eight genera, of which all
but one (Xenacanthus) are small tetrapods. This list can be expanded
to 11 by the addition of Basicranodon (Vaughn, 1958), Phlegethontia
(McGinnis, 1967), and Doleserpeton (Bolt, 1969). As Olson notes,
there are certainly a number of undescribed forms in the fauna, but
the usually disarticulated condition of materials and dispersal of col-
lections hampers study.

With the exception of Doleserpeton, UR 2400 is the first example
of even a partial labyrinthodont amphibian skull described from Fort
Sill. The specimen is thus important in providing a guide to associa-
tion of well-preserved but disarticulated labyrinthodont dermal bones
from Fort Sill. Excellent preservation of this skull fragment makes it
useful in understanding the morphology of other dissorophoid
labyrinthodonts, which are mostly known from less well-preserved
red-beds specimens. (The superfamily Dissorophoidea was originally
composed of Dissorophidae, Doleserpetontidae, and Trematopsidae
(Bolt, 1969). Boy (1972) has added the Micromelanerpetontidae and
Branchiosauridae, neither of which will be discussed here due to
unavailability of material). Finally, UR 2400 is of interest as a
possibly new species of trematopsid.

Library of Congress Catalog Number: 7U-82821
Publication 1189 67

i_r- I W ATM/

68 FIELDIANA: GEOLOGY, VOLUME 30

I am grateful to H. Barghusen, R. DeMar, and J. Hopson for
discussion and criticism. S. Grove did the figures.
Abbreviations used in this paper for repositories of specimens are:
AMNH— American Museum of Natural History
MCZ— Museum of Comparative Zoology, Harvard University
UC or UR— Field Museum of Natural History
UT— University of Texas Memorial Museum.
Materials Studied— All are from Lower Permian deposits. A com-
plete list is given in Table 1.

DESCRIPTION OF UR 2400

The roofing bones show well-developed, typically labyrinthodont
sculpturing. No attempt has been made to reproduce this sculpturing
exactly in the figures. The sculpturing suggests that UR 2400 was
not a juvenile (cf. Bystrov, 1935), but gives no information as to
maximum adult size. There is no development of bony knobs or
ridges on the outer skull table (cranial ornamentation in the sense of
Carroll, 1964). Presence or absence of ornamentation in a single
specimen is probably of low taxonomic importance, however (cf.
DeMar, 1968, on variation in this character). Some, perhaps all,
sutures are strongly interdigitated. Small clusters of pyrite crystals
(not shown) were scattered over the surface, especially on the outer
skull table, but occupied only a small percentage of the total area.
Although the pyrite tends to occur along suture lines and obscure
short segments of them, virtually all sutures could be accurately
determined.

The skull fragment as preserved is shown in Figures 1-3. The
tabulars are broken off posteriorly, but the natural borders of tabu-
lars and postparietals have been preserved on the occiput. Several
points which are not clear from the figures, or which will be discussed
below, merit comment:

1. The bone around the orbits is thickened. This is achieved with-
out producing a very noticeable circumorbital ridge. Thickening is
greatest at the level of the postfrontal-postorbital contact.

2. The squamosal bears a thin, transverse process (FSQ in fig. 3)
in front of the lamina ascendens of the pterygoid, and presumably
made contact with it originally.

3. The postfrontal-postorbital contact is strongly bevelled in the
orbital rim, with the postfrontal underlying the postorbital.

4. The lamina ascendens of the pterygoid is preserved on each
side, apparently in situ as the orientation is identical on both sides.

BOLT: TREMATOPSID SKULL 69

Each stands vertically and at approximately right angles to the
midline. The lamina is paper-thin dorsally, and ends just short of a
contact with the skull roof.

5. There is a pronounced thickened area or boss (B in fig. 3) on the
ventral surface of each postparietal. Each boss lies just anterior to an
occipital flap of the postparietal, of the type which in labyrinthodonts
usually covers the upper part of the occipital aspect of the exoccipital.
The boss is therefore almost certainly directly dorsal to the exoccipi-
tal. Direct contact may have existed between boss and exoccipital;
more likely, a supraoccipital or part of the opisthotic (cf . Bolt, 1969)
intervened.

6. Just lateral to the boss on the postparietal is a process
(partially preserved, and only on the left side) on the tabular. This
process (OP in fig. 3), directed ventro-medially, may have made
contact with the parocipital process of the opisthotic. There is no
other indication on the tabular of a possible opisthotic contact.

7. The otic notch is deep. Its dorsal border is formed by a vertical
flange composed of squamosal, supratemporal, and tabular. Such a
flange will hereinafter be referred to as the supratympanic flange
(SF in figs. 2-4). The squamosal and tabular meet below the supra-
temporal, excluding it from the ventral margin of the flange. Extend-
ing laterally above the flange, the skull table forms what may be
called the supratympanic shelf (SS in fig. 3). The shelf is here defined
as existing only if there is a supratympanic flange, or at least a
semilunar flange on the supratemporal (see below). The shelf is
damaged on the right side. The supratemporal extends into the
supratympanic flange as a rounded projection. Such a projection of
the supratemporal above the otic notch, whether or not associated
with a supratympanic flange, is called a semilunar flange (SLF in figs.
2 and 4). The terminology adopted is based on, but different from,
that of DeMar (1968). DeMar observed that dissorophids generally
have a distinctively-shaped supratympanic flange, which he called a
"half -moon-shaped flange" (see fig. 4). The same condition is re-
ferred to here as a "supratympanic flange of dissorophid shape."
DeMar (1968, p. 1212) noted that ". . . Trematops [milleri] does have
a ventrally directed ridge on the dorsal margin of the otic notch
which narrows it from above," but he did not name the flange in
Trematops.

8. The antero-ventral wall of the otic notch is formed entirely by
the squamosal. This part of the notch is roughly cone-shaped with
the apex of the cone pointing medially.

70

FIELDIANA: GEOLOGY, VOLUME 30
F

1cm

Fig. 1. Dorsal view of partial trematopsid skull, UR 2400. Abbreviations: F,
frontal; M, matrix; P, parietal; PF, postfrontal; PO, postorbital; PP, postparietal;
SQ, squamosal; ST, supratemporal; T, tabular.

SYSTEMATIC POSITION OF UR 2400

There is little doubt that the specimen is a dissorophoid labyrin-
thodont. There are no features inconsistent with this conclusion, and
it is supported by the presence of a supratympanic flange and by the
shape of the squamosal. These features do not indicate a particular
position within the Dissorophoidea, however. The affinities of UR
2400 within the Dissorophoidea are examine J in more detail beiop .
using quantitative and qualitative charact * s.

An attempt to distinguish the three families within the Dissoro-
phoidea on the basis of postorbital skull proportions was unsuccessful.
The three types of measurements in Table 1 were graphically com-
pared as follows: Lpb:Lt, L pb: W, and Lt:W. The three families could
not be distinguished from one another nor from UR 2400 on this
basis. This is interpreted as strengthening the argument for relation-
ship of UR 2400 to the Dissorophoidea. These prop^rt" ~ns are prob-

BOLT: TREMATOPSID SKULL 71

ably not unique to dissorophoids, however, even though apparently
not common among rhachitomes. Text-figures in Moustafa (1955),
for instance, suggest that Parioxys ferricolus (family Parioxyidae)
resembles dissorophoids in the parameters measured for Table 1.
Parioxys can, of course, easily be distinguished from dissorophoids
when other skull proportions are considered.

CHARACTER ANALYSIS

The systematic position of UR 2400 can apparently best be deter-
mined by use of qualitative characters. Comparison with other dis-
sorophoids suggests several characters that might usefully be exam-
ined (table 1). The states defined for each character will be analyzed
below as primitive or derived, as advocated by Hennig (1966).
Hennig's method of phylogenetic reconstruction requires that a
number of characters be so analyzed. There are presently very few
properly analyzed characters available for dissorophoids; thus no
phylogenetic reconstruction is given in this paper. Boy's (1972)
tentative analysis of sister groups within the Dissorophoidea is in-
teresting but premature.

The advantages and theoretical basis of Hennig's system have been
treated in many recent publications (e.g., Brundin, 1966; Nelson,
1970; Cracraft, 1972; SchaefFer et al., 1973), and the arguments pro
and con will not be repeated here. However, a note on methodology
is necessary: This paper basically follows the practical procedure
outlined by Marx and Rabb (1970, 1972). Criteria for determining
primitive and derived character states are modified from those pre-
sented by Marx and Rabb. Criterion 1 is uniqueness: character states
occuring in the "descendent" group (in this case, dissorophoids), but
not in the "ancestral" group (see below) are derived. Criterion 2 is
relative abundance: character states found in both the "ancestral"
and "descendent" groups are primitive.

The superfamily Edopoidea is generally considered ancestral to
the Eryopoidea, which in turn appears the most likely group of
origin for the Dissorophoidea. Accordingly, the edopoids and eryo-
poids have been taken as the "primitive" reference groups. In prac-
tice, due to the lack of good descriptions of the region under consider-
ation, three reasonably well-described genera will represent the two
superfamilies. The Edopoidea are represented by Edops (Romer and
Witter, 1942) and Dendrepeton (Carroll, 1967); the Eryopoidea, by
Eryops (Sawin, 1941). Addition of a number of less completely de-
scribed genera would strengthen the analyses only in appearance.

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FIELDIANA: GEOLOGY, VOLUME 30

1cm

Fig. 2. Lateral view of partial trematopsid skull, UR 2400. Vertical shading in-
dicates broken surfaces. Abbreviations: J?, possible fragment of jugal; SF, supra-
tympanic flange, including part of squamosal, supratemporal, and tabular; SLF,
semilunar flange of supratemporal. Other abbreviations as for Figure 1.

The tabulation below includes most North American dissorophoid
genera and species. Missing are Ecolsonia (Trematopsidae) and
Amphibamus (Dissorophidae) . Amphibamus has recently been re-
viewed by Carroll (1964), but the nature of the material severely
limits interpretation of the region around the otic notch. This is
unfortunate in view of Amphibamus' position as the oldest and
generally most primitive dissorophid (Carroll, 1964).

Particularly in the case of Doleserpeton, which is small and is also
represented by more or less immature specimens, the effects of abso-
lute size and of degree of maturity may be important. This is simply
a cautionary note; nothing can be said about these problems at
present due to the absence of proven growth series. All specimens are
here treated as mature for purposes of analysis.

Character 1: supratympanic flange— Four states: (a) absent; (b)
intermediate; (c) present and trematopsid shape; (d) present and
dissorophid shape. It must be emphasized that the difference in shape
between the flanges of (c) and (d) is due to the presence (fig. 4) or
absence (fig. 2) of a semilunar curvature of the squamosal along the
ventral border of the supratympanic flange. In UR 2400 (fig. 2), the

BOLT: TREMATOPSID SKULL

75

Fig. 3. Ventral view of partial trematopsid skull, UR 2400. Vertical shading in-
dicates broken surfaces. Abbreviations: B, boss on postparietal; FSQ, flange on
squamosal; LA, lamina ascendens; MB, markings associated with contact between
braincase and skull roof; OP, process from tabular, presumably for contact with
opisthotic; SF, supratympanic flange, composed of parts of squamosal, supra-
temporal, and tabular; SS, supratympanic shelf. Other abbreviations as in Figure 1.

flange ends posterior to the squamosal-tabular suture by rising to
merge with the undersurface of the tabular. Particularly if the skull
table were bent downward, this inflection could be mistaken for a
semilunar curvature of dissorophid type. None of the three reference
genera shows any sign of developing a supratympanic flange, nor
indeed is there any known development of the flange in any other
labyrinthodont, as noted also by DeMar (1968). Absence of the
flange (a) is therefore primitive; the intermediate condition (b), seen
only in the early dissorophid Tersomius, is reasonably interpreted as
derived. Still more derived are states (c) and (d), but it is presently
impossible to determine whether one was derived from the other.
The apparently straight ventral edge of the weak flange in Tersomius
provides some evidence that state (c) may be more primitive than
(d), but this is inconclusive. Tentative phylogeny of these states is

76 FIELDIANA: GEOLOGY, VOLUME 30

thus:

(a) ►(b):

Character 2: squamosal-tabular contact— Two states: (a) absent and
(b) present. State (a) applies to species which completely lack the
contact. State (b) applies to species in which there is slight contact,
or to species with a well-developed contact such as that in UR 2400
(fig. 2). All dissorophoids in which a squamosal-tabular contact is
definitely present resemble UR 2400. It is uncertain whether or not
contact is present in Tersomius texensis. Longiscitula houghae is de-
scribed by DeMar (1966) as possessing state (a), but re-examination
shows that state (b) is present. There is definitely a slight contact of
squamosal and tabular in Eryops, and possibly in Edops and Dendrer-
peton as well. State (b) is thus presumably primitive, state (a)
derived.

Character 3: semilunar flange of supratemporal— Two states: (a)
absent and (b) present (SLF in figs. 2 and 4). The condition in Edops
is uncertain; in Dendrerpeton and (particularly) Eryops, a more or less
wedge-shaped flange is present. The available evidence thus suggests
that state (b) is primitive, state (a) derived.

Character U' supratympanic shelf— Three states: (a) absent, (b)
intermediate, and (c) present. State (a) applies to specimens with no
projecting shelf or ridge, or very slight development of a ridge. This
state also applies to specimens (Dissorophus multicinctus) in which
dermal sculpturing extends downward over the semilunar flange, with
no development of a shelf. Apparent absence of the shelf may be
secondary and due to breakage. As noted for UR 2400 in Table 1, the
loss of a supratympanic shelf by breakage can significantly affect
measurement of table width (W). Secondary loss of the shelf can also
result in a significant change in shape of the skull table— compare
right and left sides of UR 2400 in Figure 1. Skull- table shape is a
potentially useful character, but must obviously be used carefully.
A specimen lacking the shelf but showing signs of damage in the area
is scored (-?); probably most of these were originally state (b). State
(b) applies to specimens in which there is no shelf as such, but a
distinct ridge of dermally-sculptured bone. State (c) applies to speci-
mens such as UR 2400, where a shelf is present and its undersurface,
where visible, is unsculptured.

The semilunar flange of dissorophoids is presumably homologous
to the more or less wedge-shaped supratemporal flange seen in the
reference genera. Projection of the skull table laterally beyond the

BOLT: TREMATOPSID SKULL
SQ

Fig. 4. Broiliellus olsoni, UT 3189-8. Left lateral view of part of skull of holo-
type, to show dissorophid shape of supratympanic flange. Supratympanic flange, in-
cluding all of tabular portion, is broken off posteriorly; flange is in plane of paper.
Vertical shading indicates broken surfaces. Abbreviations: J, jugal; MX, maxilla;
PO, postorbital; SC, semilunar curvature of squamosal within supratympanic
flange; SF, supratympanic flange, including parts of squamosal, supratemporal,
and tabular (tabular portion is broken off in this specimen) ; SLF, semilunar flange
of supratemporal; SQ, squamosal.

homologue of the semilunar flange would thus constitute a supra-
tympanic shelf. A supratympanic shelf as thus defined apparently
does not occur in the reference genera. Therefore state (a) is primitive;
state (b) is reasonably considered derived, and state (c) more derived.

Systematic results— XJR 2400 is probably a trematopsid, on the
basis of the derived state (c) of character 1: supratympanic flange
present and of trematopsid shape. The specimen cannot be definitely
assigned to any trematopsid genus. However, in view of the general
lack of morphological information on trematopsids, and the small
portion of the skull preserved, a new taxon should not be established
for this specimen.

State (c) of character 1 apparently serves to define the Tre-
matopsidae as a monophyletic group in Hennig's sense, i.e., a group
all members of which share at least one derived character only with
each other. This conclusion leaves out of consideration the possibly
trematopsid shape of the flange in Cacops— the specimen is so poorly
preserved in this area as to make determination of character state

78 FIELDIANA: GEOLOGY, VOLUME 30

very uncertain. DeMar (1968) suggested the presence of the dissoro-
phid shape of supratympanic flange in most dissorophids as a unifying
character of the family. This is correct in a sense; however, the
absence of this character state in Tersomius, and possibly in Am-
phibamus and Cacops, precludes using it to formally demonstrate
monophyly in Hennig's sense. Similarly, none of the other characters
analysed can be used to demonstrate monophyly of the Dissoro-
phoidea or its constituent families. This should not be taken as a
denial of monophyly, but simply as a statement that monophyly has
not yet been demonstrated. Finally, this analysis suggests that it was
incorrect to use the semilunar flange on the supratemporal to show
relationship of Doleserpeton to dissorophids (Bolt, 1969). The semi-
lunar flange is probably a shared primitive character, and as such
should not be employed in phylogenetic analysis.

REFERENCES

Bolt J. R.

1969. Lissamphibian origins: possible protolissamphibian from the Lower

Permian of Oklahoma. Science, 166, pp. 888-891.
1974. Osteology, function and evolution of the trematopsid (Amphibia: Laby-
rinthodontia) nasal region. Fieldiana: Geol., 33, no. 2, pp. 11-30.
Boy J. A.

1972. Die Branchiosaurier (Amphibia) des saarpfalzischen Rotliegenden (Perm,
SW-Deutschland). Abh. hess. L.— Amt Bodenforsch., 65, pp. 1-137.
Brundin, L.

1966. Transantarctic relationships and their significance as evidenced by
chironomid midges, with a monograph of the subfamilies Podonominae and
Aphroteniinae and the austral Heptagyiae. K. Svenska Vet. Akad. Handl.,
11, pp. 1-472.

Bystrov, A. P.

1935. Morphologische Untersuchungen der Deckknochen des Schadels der
Wirbeltiere. Acta Zool., 16, pp. 65-141.
Carroll, R. L.

1964. Early evolution of the dissorophid amphibians. Bull. Mus. Comp. Zool.,
131, pp. 161-250.

1967. Labyrinthodonts from the Joggins Formation. Jour. Paleontol., 41,
pp. 111-142.

Cracraft, J.

1972. The relationships of the higher taxa of birds: problems in phylogenetic
reasoning. Condor, 74, pp. 379-392.
DeMar R. E.

1966. Longiscitula houghae, a new genus of dissorophid amphibian from the
Permian of Texas. Fieldiana: Geol, 16, pp. 45-53.

1968. The Permian labyrinthodont amphibian Dissorophus multicinctus, and
adaptations and phylogeny of the family Dissorophidae. Jour. Paleontol., 42,
pp. 1210-1242.

BOLT: TREMATOPSID SKULL 79

Gregory, J. T., F. E. Peabody, and L. I. Price

1956. Revision of the Gymnarthridae, American Permian microsaurs. Bull.
Peabody Mus. Nat. Hist., 10 pp. 1-77.
Hennig, W.

1966. Phylogenetic Systematics. University of Illinois Press, Urbana, 263 pp.
McGinnis, H. J.

1967. The osteology of Phlegethontia, a Carboniferous and Permian aistopod
amphibian. Univ. Calif., Pub. Geol. Sci., 71, pp. 1-49.

Marx, H., and G. B. Rabb

1970. Character analysis: an empirical approach applied to advanced snakes.
J. Zool., London, 161, pp. 525-548.

1972. Phyletic analysis of fifty characters of advanced snakes. Fieldiana: Zool.,
63, 321 pp.

Moustafa, Y. S.

1955. The skeletal structure of Parioxys ferricolus Cope. Bull. Inst. d'Egypte,
36, pp. 41-76.
Nelson, G. J.

1970. Outline of a theory of comparative biology. Syst. Zool., 19, pp. 373-384.
Olson, E. C.

1941. The family Trematopsidae. Jour. Geol., 49, pp. 149-176.

1967. Early Permian vertebrates. Okla. Geol. Survey, Circular 74, 111 pp.
Romer, A. S. and R. V. Witter

1942. Edops, a primitive rhachitomous amphibian from the Texas red beds.
Jour. Geol., 50, pp. 925-960.

Sawin, H. J.

1941. The cranial anatomy of Eryops megacephalus. Bull. Mus. Comp. Zool.,
86, pp. 407-463.
Schaeffer, B., M. K. Hecht, and N. Eldredge

1973. Phylogeny and paleontology, pp. 31-46. In Dobzhansky, T., M. K.
Hecht, and W. C. Steere, eds., Evolut. Biol, 6.

Vaughn, P. P.

1958. A pelycosaur with subsphenoidal teeth from the Lower Permian of
Oklahoma. Jour. Wash. Acad. Sci., 48, pp. 44-47.