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Geology

Published by Field Museum of Natural History

Volume 33, No. 2 January 25, 1974

This volume is dedicated to Dr. Rainer Zangerl

Osteology, Function, and Evolution of
The Trematopsid (Amphibia: Labyrinthodontia)

Nasal Region

John R. Bolt

^**K Assistant Curator, Department of Geology and Paleontology

Field Museum of Natural History

INTRODUCTION

The family Trematopsidae, at present known exclusively from
the Lower Permian of North America, departs from the usual laby-
rinthodont pattern in both morphology and presumed habitat. Like
the related dissorophids and doleserpetontids which, with trematop-
sids, constitute the superfamily Dissorophoidea (Bolt, 1969), the
trematopsids are thought to represent an early tetrapod experiment
in terrestriality. This view of trematopsid habits has most recently
been expressed by Olson (1970), on the basis of extensive collecting
experience. Morphologically, trematopsids are probably unique
among labyrinthodonts in their possession of a very elongate external
naris. This character is also one of the main reasons for separation of
trematopsids from the generally similar dissorophids. The various
suggestions which have been made regarding the function of this
peculiar naris are of doubtful validity. We have only the most gen-
eral knowledge regarding the position of the nasal capsule and the
relationship of the capsule to several septa in the nasal region which
were first described by Olson (1941). There has been no attempt to
derive the trematopsid narial region from that of more "normal"
labyrinthodonts, even the dissorophids. Since the Dissorophoidea
may be ancestral to the living Amphibia (Bolt, 1969), information on
dissorophoid relationships and biology should be of considerable in-
terest to both paleontologists and herpetologists.

Library of Congress Catalog Card Number: 73-91880
Publication 1178 11

BEOLOnY

12 FIELDIANA: GEOLOGY, VOLUME 33

The comparative study presented below provides data which are
relevant to questions of both phylogeny and function. As regards
the latter, I will suggest that:

1. The elongate trematopsid external naris reflects the presence
of a nasal salt gland, and

2. The elongation of the external naris, and the consequent nar-
rowing of the antorbital bar, required transfer of forces away from
the bar. This was achieved by the "nasal flange" characteristic of
trematopsids.

As regards phylogeny, I will attempt to show that the characteristic
trematopsid narial morphology can be derived from that of dis-
sorophids or Doleserpeton, by a series of changes involving little more
than posteriad enlargement of the external naris and (perhaps) an
increase in the size of some other already-existing, uniquely-dissoro-
phoid structures in the nasal region. The existence of these struc-
tures strengthens the case for relationship of dissorophids, trematop-
sids, and doleserpetontids. At the same time, a multiple origin
among dissorophoids of the trematopsid condition appears very pos-
sible.

DeMar (1966) described an armored dissorophid, Longiscitula
houghae, with very elongate external nares like those of trematopsids.
Assignment to the Dissorophidae is, I believe, correct. However,
examination of the type specimen (FMNH UR 430), the only known
skull with preserved nasal region, casts doubt on the condition of the
external naris. The region on both sides is severely damaged, and I
am unable to trace most sutures in the area or to determine the
boundaries of the external naris. It is, therefore, possible that Lon-
giscitula did not possess elongate external nares, and is a normal dis-
sorophid in this regard.

Throughout this paper, the term "external naris" refers to the
paired laterally-placed openings lying anterior to the orbits and in-
cluding the external narial openings. Earlier papers describing tre-
matopsids referred to the elongate external naris as a confluent ex-
ternal naris and antorbital vacuity. This terminology doubtless
derived from the (inappropriate) comparison of trematopsids with
archosaurian reptiles, in which an antorbital vacuity completely
separate from the external naris is characteristically present. There
is no evidence that any labyrinthodont, including the ancestors of
trematopsids, possessed such an antorbital vacuity. This was finally

BOLT: TREMATOPSJD NASAL REGION 13

recognized by the disappearance of all reference to an antorbital
vacuity in Romer's (1947) labyrinthodont review.

I am grateful to H. Barghusen, R. DeMar, and J. Hopson for
helpful discussion and criticism. I also wish to thank the Museum
of Comparative Zoology of Harvard University and the University
of Texas Memorial Museum for the loan of specimens. D. Cohn and
R. Roesener deserve thanks for preparing illustrations.

The following abbreviations refer to specimen depositories:

FMNH, Field Museum of Natural History, Chicago, Illinois
MCZ, Museum of Comparative Zoology, Harvard University,
Cambridge, Massachusetts

UT, University of Texas Memorial Museum, Austin, Texas.
A list of abbreviations used in figures is given on p. 28.

SYSTEMATICS AND MATERIALS

The family Trematopsidae presently consists of four genera:
Trematops, Acheloma, Trematopsis, and Ecolsonia. The latter two
are monotypic and represented by very incomplete material. Trema-
tops and Acheloma each include three species; all but the type species
were erected by Olson (1941, 1970). Despite an abundance of speci-
mens of Trematops and Acheloma, difficulties of preparation and
interpretation have combined to keep even these genera relatively
poorly known. It seems certain, however, that among the materials
already collected there are specimens which cannot easily be fitted
into the named species as presently understood. This is pointed out
in a previous study (Bolt, MS) dealing with the morphology and
function of the labyrinthodont palatine and anterior orbital wall.
It is not necessary to repeat here the observations which support that
conclusion; others will be given below. Until available material has
been more completely prepared, erection of new taxa is justified only
for the most obviously different specimens.

These remarks stem from the fact that the description of the
trematopsid nasal region given below is (unavoidably) based on a
specimen which may represent a new taxon. The specimen (MCZ
1485) is provisionally referred to Acheloma sp. ; comparison with the
types of both A. whitei and A. pricei shows at least a specific dif-
ference, and this seems true also of A. cumminsi based mostly on
Olson's (1941) description (Bolt, MS). Throughout this paper, the
term "A. sp." refers only to MCZ 1485.

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BOLT: TREMATOPSID NASAL REGION 15

MCZ 1485 was collected in 1936, but is not mentioned in Olson's
(1941) review. The specimen was filled with a purplish, friable, fine-
grained sandstone. Sutures are generally easily determined. Most
of the skull is virtually undistorted, although the dorsal roofing bones
behind the level of the anterior orbital walls are missing. All dermal
bones of the palate are present, but the pterygoids are slightly dis-
placed mediad; the parasphenoid and attached basisphenoid have
been displaced posteriad and rotated. Only the (damaged) right
quadrate is present. Part of the braincase is present, but has not
yet been completely prepared. No sphenethenoid has been found
despite preparation of the interorbital area. The need for support
of the fragile bone has precluded complete removal of matrix from
the nasal region.

Horizon — Lower Permian; Admiral Formation

Locality. — Archer County, Texas; "Copper Hill School," South
of Little Wichita River near Mankins-Archer City Highway.

MORPHOLOGY

External naris and internarial foramen (figs. 1, 2). — The external
naris is surrounded by the bones usually seen here in labyrinthodonts
(premaxilla, maxilla, lacrimal, and nasal), with the addition of the
prefrontal. In typical trematopsid fashion, the opening is partly sub-
divided into anterior (shorter) and posterior (longer) portions, by a
constriction. This characteristic is noted by Olson (1941). Olson
figures specimens (for instance, the holotype of A. pricei, MCZ 1419)
in which constriction is due to the maxilla alone and others (for in-
stance, the holotype of Trematops milleri, FMNH UC 640) in which
constriction is due only to a ventrolateral projection from the nasal.
Examination of the two specimens mentioned, confirms Olson's in-
terpretation. The difference is apparently not generically diagnostic
(see Olson's (1941) Figure 2 showing a specimen of A. cumminsi
with a pronounced projection from the nasal). In A. sp. both nasal
and maxilla contribute to the constriction, although the nasal pro-
jection is little developed.

An internarial foramen (fig. lA, B) is developed in A. sp. much
as in other trematopsids. The boundaries shown may or may not
exactly correspond to those present in life. Carroll's (1964) study
of the dissorophid Tersomius texensis demonstrates a small bone in
this position; postmortem loss of such a bone would produce a
trematopsid-like internarial foramen, and in any given trematopsid

16

FIELDIANA: GEOLOGY, VOLUME 33

Fig. 2.

Acheloma sp., MCZ 1485. Snout in right lateral view.

specimen it is likely to be difficult to prove that this did not happen.
Thus the internarial foramen can usually not be confidently used as a
diagnostic character.

Internal naris and anterior palate (figs. 1, 3). — The internal naris
is of normal labyrinthodont appearance, and is surrounded by the
usual labyrinthodont bones — maxilla, premaxilla, vomer, and pala-
tine. It is not so elongate as the external naris, although it extends
slightly farther posteriorly. The constrictions in the external naris
approximately coincide with the anterior border of the internal naris.

As in most dissorophoids, the vomers form a large anterior and
medial internarial pit. The internarial foramen opens into the an-
terior portion of this pit. The anterior vomerine borders could not
be completely determined, but the figured condition must be very
nearly correct. The medial margins of the vomers are reflected up-
ward within the internarial pit (fig. 3A) ; Olson (1941) referred to the
two reflected areas jointly as the "internasal septum." This termi-
nology may be retained, although the two halves of the "septum"
approach one another only dorsally. The internasal septum closely
approaches the underside of the skull roof, but it cannot be deter-
mined whether there was actual contact. Posterior and lateral to
the internarial pit, the vomer (anteriorly) and palatine (posteriorly)
bend up along the border of the internal naris at about a 20° angle
to the horizontal (fig. 3B, C). This lateral, reflected area of the

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Fig. 3. Acheloma sp., MCZ 1485. Schematic cross-sections through snout, at
levels indicated in Figure 2. In Figure 3A, the dorsally-reflected portions of the
vomers together form the 'internasal septum' (see text). Figure 3B is taken just
posterior to the internarial pit. In Figure 3C, SU is present but unlabelled.

17

18 FIELDIANA: GEOLOGY, VOLUME 33

vomer and palatine was thought by Olson (1941) to consist of vomer
only; Olson considered this area as forming another (unnamed) sep-
tum (SU in fig. 3B). This septum disappears at the antero-medial
corner of the internal naris, opposite the maxillary constriction of
the external naris. In lateral view (figs. IC, 2) the upturned medial
border of the choana is thus masked by the maxillary border of the
external naris.

Several additional features of A. sp. pertinent to classification
may be noted here. The primitive contact of pterygoids with vomers
is retained. Although the contact is a narrow one in this instance,
trematopsids are the only dissorophoids known to possess it. (Car-
roll's (1964) Figure 4 shows a close approach to a pterygoid -vomer
contact in the primitive dissorophid Tersomius texensis. Examina-
tion of the specimen (MCZ 1912) on which Carrol based his figure,
suggests that the anterior portion of his suture line is a crack. The
pterygoid may not even reach the palatine in T. texensis, ending in-
stead at or posterior to the ectopterygoid tooth) . The interpterygoid
vacuities in A. sp. are large for a trematopsid, but this is also the
case mEcolsonia (Vaughn, 1969). There are three sets of fang-teeth,
of varying sizes. Compared to the diameter of an average marginal
tooth, the palatine fangs are considerably larger; the ectopterygoid
fangs are the same or slightly greater, and the vomerine fangs are
apparently the same or smaller. The left vomerine tooth illustrated
in Figure IB may or may not be a small fang. The vomerine fangs
might have been removed in preparation. A posterior extension
(VOE in fig. IB) is present on each vomer. Each extension runs
forward an undetermined distance into the unprepared area behind
the internarial pit. The extensions are not part of the sphenethmoid :
on both sides no suture with the vomer is visible. So far as I can
determine, this peculiar extension is unique to A. sp. among laby-
rinthodonts. The extension falls well short of the skull roof. The
parasphenoidal rostrum could conceivably have lain either dorsal
(usual condition in labyrinthodonts) or ventral to the vomerine ex-
tensions. Measurement of the preserved portion of the parasphenoi-
dal rostrum shows that it certainly reached as far forward as the vom-
erine extensions, and perhaps the main portions of the vomers. It
is uncertain whether the rostrum made contact with the vomers.
There is a vomerine contact in Ecolsonia (Vaughn, 1969), with the
anterior tip of the parasphenoidal rostrum apparently ventral to the
vomers.

BOLT: TREMATOPSID NASAL REGION

PMX

19

Fig. 4. Doleserpeton annectens. Skull in dorsal view,
numerous specimens. Skull length approximately 15 mm.

Composite, based on

Nasal flange and nasal capsule (figs. 1, 2, 3). — Olson (1941) de-
scribes a total of three "septa" in the nasal region. Two of these
have been described above; the third, Olson's "descending septum
of the nasal," is also well-preserved in A. sp. As seen in Figures 2
and 3C, the septum is an extension of the nasal anteriorly, and of the
prefrontal posteriorly. The septum will hereafter be referred to as
the nasal flange, for convenience. The term "nasal septum" is pre-
empted by a braincase structure. Besides the nasal and prefrontal,
the nasal flange is also formed by an extension from the lacrimal.
The lacrimal contribution is small, being restricted to the postero-

20 FIELDIANA: GEOLOGY, VOLUME 33

ventral portion of the flange. The lacrimal portion of the flange is
oriented in a transverse plane, just behind the posterior border of the
external naris. The area is thus not visible in lateral view. Here as
elsewhere in its course, the nasal flange is oriented approximately
vertically. From its posterior end, the nasal flange runs forward and
medially at about a 45° angle to the midline. It thus increasingly
diverges from the lateral edge of the (unnamed) septum (SU in fig.
3B) formed by the medial margin of the internal naris. Posteriorly,
the nasal flange is close to the dorsal surface of the palate (fig. 3C),
although apparently nowhere does it make contact with the palate.
The separation increases anteriad, largely due to the decreasing
height of the nasal flange. Except for suture lines, the lateral sur-
face of the nasal flange is featureless. Thickness of the flange pos-
teriorly appears less than that of the frontal and nasal, where those
bones are broken above the orbits. Over most of its extent, how-
ever, thickness of the nasal flange is unknown.

A minimum estimate for the antero-posterior extent of the nasal
capsule, is the distance between the anterior border of the external
naris and the posterior border of the internal naris. Its posterior
extent may be further indicated by a distinct fossa developed in the
dorsal surface of the palatine (FONC in fig. lA) . The posterior bor-
der of the fossa is formed by a ridge whose posterior face rises gradu-
ally from the palatine. The ridge is not as pronounced medially, and
disappears at the dorsal suture line between palatine and vomer.
The dorsal suture line lies some distance medial to the ventral
suture line between these bones; as in Doleserpeton, the palatine
overlaps the vomer for a considerable distance medial to the inter-
nal naris. That face of the palatine ridge which borders the fossa,
meets the surface of the palatine at a sharp angle (about 90°). This
fact suggests that some soft structure lay against the anterior face
of the ridge. The fossa might indicate the posterior limit of the nasal
capsule, which as expected would thus be only a short distance be-
hind the posterior border of the internal naris. Although the fossa
is limited laterally by the medial margin of the internal naris, this
should obviously not be interpreted to mean that the nasal capsule
did not extend around the internal naris. The ridges which border
the fossa may serve to stiffen the edges of the thin bone. In any case,
the fossa and its bordering ridges are not necessarily very accurate
indicators of nasal capsule position, especially as regards the medial
extent of the capsule. If the fossa is accepted as indicative of nasal

BOLT: TREMATOPSID NASAL REGION 21

capsule position, the nasal flange must be seen as probably dividing
the cavity of the nasal sac into medial and lateral portions. There
is another possibility, however, which will be adopted here. The
nasal capsule might have been confined to the area lateral to the
dermal bone of the nasal flange. Such an arrangement is admittedly
unusual among tetrapods, in which the medial walls of the nasal
capsules are generally replaced by the midline chondrocranial nasal
septum (de Beer, 1937, p. 395). However, according to Jurgens
(1971) the primitive condition in both urodeles and anurans is one
in which the nasal capsules are separated by an extension of the
cavum cranii. This observation is consistent with the suggestion
(Bolt, 1969) of a dissorophoid origin for the Lissamphibia although
such separated and laterally-placed nasal capsules may have been
widespread among labyrinthodonts. The fossa, particularly its
posterior part, may indeed have contained cartilage, but this car-
tilage was not necessarily part of the nasal capsule. The fossa may,
for instance, mark the position of a processus maxillaris posterior
which was here connected to the pterygoid process of the palato-
quadrate cartilage.

FUNCTION AND EVOLUTION OF THE NASAL FLANGE

Function of the nasal flange. — Posteriorly, the nasal flange lies
very close to the dorsum of the palate. A small portion of the flange
is thus in position to prevent large upward movements of the ad-
jacent palate. However, aside from the lack of bony contact be-
tween flange and palate, the orientation and height of the rest of
the flange is not such as to indicate that direct palatal support was
one of its functions. As indicated above, the flange might have been
pushed into the nasal capsule and sac, thus subdividing the latter into
medial and lateral components. This was suggested by Olson (1941),
who thought that the medial subdivision might house Jacobson's or-
gan. In general, the possible function for such subdivision would be to
increase the area of epithelium within the nasal sac, or to physically
separate functionally different areas. Ordinarily in lower tetrapods,
however, the skeletal support for flanges and ridges within the nasal
sac is provided mostly by the cartilaginous nasal capsule. There is no
obvious reason why the support of a long extension from the dermal
roofing bones should have been required in this case. Similarly,
there is no reason to suppose that a gland in the nasal region re-
quired support from the flange. The apparent rigidity of the nasal
flange renders it unsuitable for participation in movements which

22 FIELDIANA: GEOLOGY, VOLUME 33

might change the volume of any part of the nasal sac. The flange
might have served for the origin of muscles — but there is no other
indication of the presence and function of such musculature.

A clue to the possible function of the nasal flange is provided by
the extensive fenestration of the trematopsid skull. Between the
posterior margin of the orbit and the anterior margin of the external
naris, the tooth-bearing maxilla appears to be attached to the skull
roof only by the antero-posteriorly narrow antorbital bar composed
of lacrimal and prefrontal. Forces acting on the tooth row would be
transmitted to the skull roof via the antorbital bar, across the frontal-
prefrontal and nasal-prefrontal sutures. For convenience, these
sutures may be referred to jointly as the frontonasal-prefrontal su-
ture, although the frontal and nasal are actually separate bones in all
labyrinthodonts. The trematopsid skull is actually less extensively
fenestrated than it appears, however. In A. sp., starting from a
point near the ventral end of the antorbital bar, the nasal flange
unites the lacrimal and prefrontal to the nasal. The flange in effect
forms an extension of the antorbital bar, greatly increasing the bar's
anteroposterior extent.

The nasal flange was perhaps useful in shifting some compressive
stress from the antorbital bar. At the same time, it seems reasonable
to suppose that forces acting on the tooth row sometimes produced
dangerously large turning moments about the frontonasal-prefrontal
and the prefrontal-lacrimal sutures. The sutures themselves might
be endangered, or sufficient rotation about the suture (s) might occur
to endanger some bone(s) which could not deform to the extent per-
mitted by the sutures. Possibly such forces could produce danger-
ous deformation in the narrow suborbital bar and adjacent bone even
in the absence of significant rotation around sutures. No decision
as to the relative significance of these alternatives is possible in the
absence of detailed information on the bending strengths of the
sutures and adjacent bones. In either case, failure could be pre-
vented by strengthening the sutures and /or transferring part of the
bending stress away from the antorbital bar. The nasal flange ap-
pears situated so as to be capable of doing both. A suture-strength-
ening function of the nasal flange might explain the apparently non-
bevelled nature of the frontonasal-prefrontal suture in A. sp.

Evolution of the nasal flange. — Even if one accepts the functional
suggestions above, the question remains as to why this structure
(the nasal flange) was used to meet certain functional requirements.
At least part of the explanation may lie in the presumably ante-

BOLT: TREMATOPSID NASAL REGION

23

Fig. 5. Doleserpeton annedens. Right nasal in ventral view.

cendent conditions seen in other dissorophoids. These may be repre-
sented by Doleserpeton annedens (figs. 4, 5), for which the best ma-
terial is available.

The nasal region of A. sp. can be transformed to closely resemble
that of Doleserpeton annectens. As discussed below, this is a reversal
of the probable direction of change. D. annectens represents the
primitive dissorophoid condition, A. sp. the derived; but since the
nasal region of A. sp. has just been described, the reversed trans-
formation sequence may be easier to follow. The order in which
changes are listed below has no particular significance, as they must
have taken place more or less simultaneously. With A. sp. as the
starting-point then, and D. annectens as the goal, the necessary
changes are:

1. The snout becomes broader and more rounded.

2. The nasal bones become shorter and broader.

3. The posterior border of each external naris, still formed by the
lacrimal, migrates forward. The result of this change, together with
(2), is a subcircular, slightly elongate external naris; there is a short

24 FIELDIANA: GEOLOGY, VOLUME 33

contact of nasal and lacrimal, and the prefrontal is thus excluded
from the external naris.

4. The nasal flange decreases in height, i.e., it projects a smaller
distance below the skull roof and does not approach the palate so
closely.

5. The lacrimal portion of the nasal flange expands anteriad and
dorsad, remaining lateral to the prefrontal portion. The end-point
is reached when the lacrimal portion of the nasal flange is approx-
imately coextensive with the prefrontal portion. The two-layered
flange thus formed retains contact with a strong, low flange, or pro-
cess, from the nasal bone to complete the "nasal flange" of Doleser-
peton.

Some minor alterations in the palate, which need not be detailed,
accompanied the listed changes. The picture can be rounded out by
the Doleserpeton nasal (fig. 5). A strong process projects from the
undersurface of the nasal, somewhat posterior to the border of the
external naris. A small depression (CPRF in fig. 5) is incised into
the antero-lateral terminus of the process; this depression probably
marks the contact with the prefrontal portion of the nasal flange.

In D. annectens the nasal flange is clearly in a position to brace
the prefrontal-lacrimal suture against turning moments. Contact
between the flange and the nasal bone indicates a probable role in
bracing the nasal-prefrontal and nasal-lacrimal sutures also. The
arrangement seen in D. annectens might have reduced stress on the
frontal-prefrontal suture due to turning moments, but probably not
to the extent seen in A. sp. Such bracing was not needed in Doleser-
peton, because of the bevelled nature of that suture and the existence
of a larger antorbital bar. The condition of the nasal flange in A.
sp. (and presumably other trematopsids) then may reflect primarily
a change in emphasis, rather than assumption of a new functional
role. Considering both the function and morphology of the Doleser-
peton-type and trematopsid-type nasal flanges, it seems that the
latter most likely was derived from the former. (This conclusion
does not imply that trematopsids are derived from either Doleserpe-
ton or dissorophids — this is quite unlikely on other evidence.)

The nasal flange in dissorophids. — At present, the nasal flange can
be demonstrated in only two dissorophid genera. However, with the
evidence from trematopsids and Doleserpeton this distribution seems
sufficient to strongly suggest that the flange is a primitive dissoro-
phoid character. A nasal flange is present in Broiliellus olsoni, UT
3189-8; this specimen has the same catalog number as the holotype,

BOLT: TREMATOPSID NASAL REGION 25

but is actually a referred specimen (DeMar, 1967). It is a frag-
mentary left half of the snout, consisting essentially of the area which
in trematopsids I have called the antorbital bar. The specimen is
figured in lateral and posterior view in Bolt (MS). It has been pre-
pared to show a well-developed nasal flange. The sutures between
contributing bones cannot be made out. The flange is broken off
anteriorly, the break passing through the broad-based nasal portion.

Broiliellus is an advanced, armored dissorophid. A primitive,
unarmored dissorophid with a probable nasal flange is Tersomius
texensis. Carroll (1964, p. 172) has described a ridge on the under-
surface of the nasal and prefrontal. The exact course of this ridge
is uncertain from his description. Carroll's Figure 6C, based on
acetate peels of serial sections through MCZ 3236, shows a ridge (un-
labelled) which is probably the nasal portion of a nasal flange. Re-
examination of the peels of MCZ 3236 shows the flange to be present
in sections numbered 21-11. The specimen is too damaged to permit
tracing of the nasal flange in detail. However, there is a fairly clear
transition from a ridge composed of nasal alone anteriorly, to one
composed of prefrontal plus lacrimal posteriorly (section 11). An-
teriorly the flange begins somewhat posterior to the external naris,
as in Doleserpeton. The anterior orbital wall and the adjacent area
of the nasal flange are not present in the other specimens sectioned
by Carroll— MCZ 3234 and 1694.

The nasal flange in labyrinthodonts in general. — It appears that
a nasal flange is not present outside of the Dissorophoidea. This
conclusion rests on a very narrow base, as few sufficiently-detailed
descriptions of the snout are available. Some examples of well-
described labyrinthodonts lacking the flange are: the stereospondyl
Benthosuchus (Bystrov and Efremov, 1940) ; the rhachitome Eryops
(Sawin, 1941); the seymouriamorph Seymouria (White, 1939). Ab-
sence of the flange in Eryops 3ind Benthosuchus is unsurprising: both
have small orbits and extensive antorbital bars. In the case of
Seymouria, the relative length of the antorbital bar is closer to that
of dissorophoids, but is still significantly greater. The point may be
illustrated by a simple comparison: As a rough indicator of head
size, we can use the snout-quadrate length (L), measured parallel
to the midline. The length of the antorbital bar (BL) can be ex-
pressed as the shortest distance between the posterior margin of the
external naris and the anterior margin of the orbit. The orbit of
Seymouria is notched antero-ventrally, and the antorbital bar was
measured from the anterior wall of the notch. Measurements are

L

BL

L/BL

11.2

3.1

3.6

14.2

3.3

4.3

9.5

1.7

5.6

26 FIELD! ANA: GEOLOGY, VOLUME 33

TABLE 1. Length of antorbital bar (cm.) in Seymouria and dissorophids.
See text for explanation.

Seymouria baylorensis (FMNH UC 666)
Dissorophus muUicinctus (MCZ 2122-1)
Broiliellus texensis (holotype) (FMNH UC 684)

given in Table 1. These two dissorophid genera were chosen be-
cause they are represented by relatively complete and undeformed
specimens, presumably adult, which are approximately the same size
as Seymouria.

The comparison with Seymouria is particularly interesting, as
the lacrimal-prefrontal suture is strongly bevelled as in dissoro-
phoids (Bolt, MS). Due to its peculiar palatal construction, how-
ever, the lack of a nasal flange in Seymouria cannot be ascribed solely
to the size of the antorbital bar (cf. Bolt, MS).

FUNCTION AND EVOLUTION OF THE EXTERNAL NARIS

Morphological aspects of the evolution of the trematopsid ex-
ternal naris are fairly clear and straightforward. Functional as-
pects of the evolution of this unusual naris, however, have remained
obscure. The generally-accepted explanation is given by Olson
(1941, p. 161), who suggests that the anterior part of the external
naris ". . . was concerned primarily with the sense of smell, while
the more posterior part functioned principally as an air intake. It
has been suggested previously that the posterior part housed a gland
of some sort. While this is possible, the structure outlined above
makes it seem rather improbable."

The basis for this explanation was the observation that the in-
ternal naris lies beneath only the posterior part of the external naris.
Olson's conclusion does not follow, however. Inspired air does not
necessarily take the shortest possible path between internal and ex-
ternal nares. During its transit of the nasal passages, air may be
filtered, humidified, and otherwise modified, while being exposed to
various sensory cells. As might be expected, the nasal cavities of
living amphibians and reptiles can be quite complicated (cf. Mat-
thes, 1934; Stebbins, 1948; Parsons, 1959, 1970). It is, therefore,
reasonable to suppose that the anterior part of the trematopsid ex-
ternal naris served as an air intake. In support of this possibility

BOLT: TREMATOPSID NASAL REGION 27

is the observation that, by comparison with other labyrinthodonts,
this portion occupies the usual area of the external naris. The same
conclusion was drawn by Williston (1909), on the basis of compar-
ison with Eryops.

The suggestion may then be revived, that the posterior part of
the trematopsid external naris housed a gland. A possible candidate
is the "glandula nasalis externa." This gland, lying lateral to the
nasal sac but opening into it, is widespread in living amphibians
(Matthes, 1934). A similar and apparently homologous glandula
nasalis externa occurs in most living reptiles, although some (second-
arily) lack it (Parsons, 1959). It has recently been discovered that
this gland is an important route for salt excretion in some lizards
both marine and terrestrial (see Dunson, 1969, for recent review of
salt glands in general). According to Dunson (1969, p. 95), "The
animals with the greatest secretory capacity seem to be associated
with environments and food highest in salt and lowest in water, but
this is an impression supported by only limited data."

These characteristics might or might not apply to the environ-
ment of the trematopsids. Trematopsids were likely highly ter-
restrial, and were certainly carnivorous. More detailed description
of trematopsid environment and food would be speculative at this
time. However, it seems plausible to suggest that the posterior
portion of the trematopsid external naris was occupied by a salt
gland, possibly homologous with the glandula nasalis externa. Per-
haps in the ancestral trematopsids enlargement of the gland was
blocked in all directions but laterally. Mediad enlargement, for
instance, might have adversely affected nasal functioning. This
might occur by squeezing the nasal capsule between the gland and
the nasal flange. Laterad expansion could occur by enlarging the
external naris; at the same time, the nasal flange gradually assumed
its trematopsid morphology and function. Dissorophids and Dole-
serpeton did not necessarily lack salt glands; the varied homologies of
reptilian salt glands (Dunson, 1969) indicates the possibility of sim-
ilar differences in labyrinthodonts. In reptiles, the salt glands com-
pensate for the kidney's inability to produce a hypertonic urine
(Schmidt-Nielsen et al., 1963). If the same were true of trematop-
sids, the elongate external naris might be regarded as an indirect re-
sult of this renal characteristic.

The hypothesis outlined above as to the origin of the elongate
external naris of trematopsids has phyletic implications. These im-
plications exist regardless of the homologies, and even the nature

28 FIELDIANA: GEOLOGY, VOLUME 33

(glandular or non-glandular) of the structures involved in posteriad
narial expansion. In any labyrinthodont, we need only grant the
presence of a nasal flange similar to that of dissorophids and Dole-
serpeton in both structure and function. Enlargement of any struc-
ture lateral to the nasal sac is then likely to produce the trematopsid
external naris and nasal flange. Two conclusions follow:

1. Within the Dissorophoidea, similar types of experimentation
would likely occur, and lead to similar modifications of the external
naris and nasal flange.

2. The elongate external naris, even if accompanied by a trema-
topsid-type nasal flange, is not a diagnostic character for the family
Trematopsidae.

ABBREVIATIONS

CPRF — Contact area for prefrontal

CPT — Contact area for pterygoid

EN — External narial opening

FONC — Fossa, possibly for nasal capsule

FR — Frontal

IN — Internal narial opening

INF — Internarial foramen

INP — Internarial pit

JU — Jugal

LAC — Lacrimal

LEE — Laterally-exposed portion of ectopterygoid

LEP — Laterally-exposed portion of palatine

MX -- Maxilla

MXCS — Constriction of external narial opening, due to maxilla

N — Nasal

NCS — Constriction of external narial opening, due to nasal

NEN — Area of nasal bordering the external naris

NF — Nasal flange

PAL — Palatine

PAR — Parietal

PFR — Postfrontal

PMX — Premaxilla

PO — Postorbital

PP — Postparietal

PR — Process on ventral surface of nasal

PRE — Prefrontal

PT — Pterygoid

Q — Quadrate

QJ — Quadratojugal

SQ — Squamosal

BOLT: TREMATOPSID NASAL REGION 29

ST — Supratemporal

SU — Unnamed septum

VO — Vomer

VOE — Vomerine extension

VPP — Ventral prefrontal process

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