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SA NALS OF THE SOUTH AFRICAN MUSEUM
NALE VAN DIE SUID-AFRIKAANSE MUSEUM

Volume 56 Band
September 1970 September
Partie qu ) Deel

THE PALATE AND MANDIBLE IN SOME
SPECIMENS OF DICYNODON TESTUDIROSTRIS
BROOM & HAUGHTON (REPTILIA, THERAPSIDA)

By

Wi A CU VER:

Cape Town Kaapstad
a Helos

j#o 111970
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THE PALATE AND MANDIBLE IN SOME SPECIMENS OF
DICYNODON TESTUDIROSTRIS BROOM & HAUGHTON
(REPTILIA, THERAPSIDA)

By
M. A. CLUVER
South African Museum, Cape Town
(With r2 figures)
[MS. accepted 30 July 1970]

CONTENTS

PAGE
Introduction : oll BIG)
Some features in the canal aon of Dinner TS MuToss ail aya,
Extent of the horny beak in Dicynodon testudirostris . . 140
Jaw musculature and masticatory cycle in Dicynodon vetudiratiis a) ZIG)
Comparison with other forms : 5 : ‘ : . 144
Discussion . ‘ 0 : : ; ; : : . 150
Summary . : ‘ : : : ‘ : 52
Acknow Hedpement: . : : : F : : ST 52
References . : A : : ; ; ‘ ; BUTI, 2
Abbreviations : 4 : : 3 : : 3 SH GS}

INTRODUCTION

During the course of a study on the functional anatomy of the mandible
and palate in the advanced dicynodont genus Lystrosaurus (Cluver, in press)
several Cistecephalus and Endothiodon zone dicynodont specimens were examined
and freed of matrix. It became apparent that both mandible and palate in
these specimens were subject to considerable structural variation, and that the
variations could be of functional significance in that they were probably
associated with differences in the masticatory cycle.

Crompton & Hotton (1967) have given a comprehensive account of the
different stages in the masticatory cycle of the dicynodonts Emydops and
Lystrosaurus, and pointed out the main differences between the two genera in
this respect. Important points in Crompton & Hotton’s work are the following:

(i) the temporalis and pterygoideus musculature in dicynodonts would have
permitted a retractive power stroke only during mastication,

(ii) in an endothiodontid such as Emydops use was made of an anterior ‘beak
bite’ between the upper and lower jaws, distinct from a cutting action
between the upper and lower teeth and the expanded palatal portion of
the palatine.

(in) Lystrosaurus, on the other hand, utilized a slicing action between the lower
beak and the close-fitting palatal rim in front of the tusks.

These authors state that crushing did not take place in the Lystrosaurus

135
Ann. S. Afr. Mus. 56 (4), 1970: 133-153, 12 figs.

134 ANNALS OF THE SOUTH AFRICAN MUSEUM

masticatory cycle, which was adapted solely for slicing action. However,
examination of several well-preserved and undistorted skulls and lower jaws
of Lystrosaurus (Cluver, in press) has shown that crushing between the lower
jaw and the expanded palatal portion of the palatines took place at the end of
the retractive stroke, where the dorsal surface of the dentary closely approaches
the palatal roof.

Important in the reconstruction of this mechanism are the probable areas
of insertion of the jaw adductor muscles. Crompton & Hotton (1967) based
their calculations on the strong likelihood of the external adductor muscles
having inserted on a lateral dentary shelf and in a deep sulcus on the dorsal
edge of the dentary. These features appeared to be common among the majority
of dicynodonts.

It is therefore of considerable interest that several dicynodontid specimens
in the South African Museum collection differ from such diverse genera as
Emydops, Pristerodon, Dicynodon and Lystrosaurus in the absence of both a dorsal
dentary sulcus and a lateral dentary shelf. Correlated with this was the extremely
unusual nature of the palate in these forms, which were identified as specimens
of Dicynodon testudirostris Broom & Haughton, all, including the type specimen,
from the Cistecephalus zone of the Beaufort Series.

The new features uncovered during the preparation of the palate of the
type specimen of Dicynodon testudirostris, and the unusual structure of the palatal
rim and mandible in the referred specimens, warrant an additional description
of the species, which in several important respects differs sharply from other
species of Dicynodon.

In the following, the term dicynodont has reference to members of the
infraorder Dicynodontia (sensu Romer, 1966), while the terms dicynodontid,
endothiodontid and lystrosaurid refer respectively to members of the families
Dicynodontidae, Endothiodontidae and Lystrosauridae.

SOME FEATURES IN THE CRANIAL ANATOMY Of Dicynodon testudirostris
1. Type specimen, S.A.M. Cat. No. 2354 (Fig. 1).
Locality: Dunedin, Beaufort West.

The type skull has been described and illustrated by Broom & Haughton
(1913) and Broom (1932). On the skull roof (Fig. 1b) the intertemporal region
is narrow and the postorbitals meet over the parietals. The preparietal is
broad anteriorly but narrows posteriorly to form only a small part of the border
of the pineal foramen. There is a fairly long, very narrow postfrontal. The
maxilla extends far upwards on the side of the snout to meet the nasal, and
separates the short lacrimal from the septomaxilla. The prefrontal has only a
limited extent on the skull roof.

The hitherto undescribed palate (Fig. 1c) of the type skull was completely
cleared of matrix and several unusual features were uncovered. Although there

PALATE AND MANDIBLE IN SOME SPECIMENS OF DICYNODON TESTUDIROSTRIS 135

(a)

(b)

tub.

pm

ant.pm.r

ipt.vac.

(c)

Fic. 1. Skull of Dicynodon testudirostris. Type specimen, S.A.M. Cat. No. 2354. (a) lateral (b) dorsal
(c) ventral view. xX 1. Scale = 1 cm.

136 ANNALS OF THE SOUTH AFRICAN MUSEUM

is no indication of a canine tusk, the relationships between palatine, premaxilla
and maxilla place the species in the genus Dicynodon as defined by Toerien (1953).
The palatine has a small palatal surface and does not reach the premaxilla
anteriorly. The maxilla therefore forms the lateral border of the anterior palatal
notch.

The palatal surface of the premaxilla bears a pair of anterior palatal
ridges, as is found in many dicynodonts, as well as the typical median ridge
which extends back to meet the vomer.

The maxilla is produced ventrally as an enlarged caniniform process,
which is incomplete on both sides of the specimen (Fig. 1c, can. fl.). Initially
broad-based, this flange tapers rapidly to form a blade which was obviously
continued further ventrally during life. The preserved portion of the blade is
rounded posteriorly but carries a sharp anterior cutting edge. This sharp edge
of the flange is carried medially to the equally sharp palatal rim, and between
the two edges a recess is formed. In ventral view it can be seen that the maxillary
flange is turned quite sharply inwards.

In contrast to dicynodonts in which the roof of the palate is smoothly and
evenly excavated, the premaxilla and maxilla in this species are built up
medially to the maxillary flange to form a raised shelf (Fig. 1c, pal. sh.), equal
in height to the median premaxillary ridge. A deep trench is thus formed
between the lateral shelf and the median ridge.

Anterior to the caniniform flanges the palate is broad and bounded laterally
by a shallow palatal rim. Anteriorly the rim, formed by the premaxilla, is
deeper and terminates as two laterally placed processes, continuations of the
anterior palatal ridges. Between them the two processes separate a shallow
median cleft.

The reduced palatal surface of the palatine lies slightly recessed above
the level of the raised anterior maxillary and premaxillary shelf. A thin median
process of the palatal portion of the palatine extends in towards the median
vomerine septum, tending to separate off the anterior palatal notch of the
internal nares.

At the posterior limit of the raised premaxillary-maxillary shelf, and
medially to the posterior limit of the maxillary caniniform flange, the maxilla
is drawn out into a rounded, pointed tubercle (Fig. 1c, tub.).

2. Referred specimen, $.A.M. Cat. No. 10086 (Figs 2, 3).
Locality: Dunedin, Beaufort West.

This specimen is an almost complete skull and mandible, only part of the
right zygomatic arch being missing. The skull is only slightly dorso-ventrally
compressed. It was possible to remove the mandible entirely without damage
to the specimen, and the relationships between palate and mandible could be
accurately determined.

Basically, the skull differs from that of the type specimen only in its

PALATE AND MANDIBLE IN SOME SPECIMENS OF DICYNODON TESTUDIROSTRIS 137

completeness and slightly larger size. On the skull roof the postorbitals meet
over the parietals, the preparietal is inflated anteriorly, the postfrontal is a
narrow strip of bone, and the prefrontal has a limited extent on the outer skull
roof. The maxilla rises up high behind the nostril to separate the lacrimal from
the septomaxilla.

The palate is identical to that of the type specimen, but the caniniform
flanges of both sides are preserved in their entirety. It can now be seen that
each flange terminates ventrally as a sharp, curved edge (Fig. 2).

In the mandible (Fig. 3) the post-dentary bones, which appear to be of
the normal dicynodont pattern, have undergone a slight downward shift in
relation to the dentary, which has several unusual characteristics. There is no

Fic. 2. Skull of Dicynodon testudirostris. S.:A.M. Cat. No. 10086. (a) lateral (b) ventral view. x 1.
Scale = 1 cm.

138 ANNALS OF THE SOUTH AFRICAN MUSEUM

(b)

Fic. 3. Mandible of Dicynodon testudirostris. S:A.M. Cat. No. 10086. (a) dorsal (b) lateral view.
x, 1. p9calei— Tem:

lateral dentary shelf such as is found in Emydops, Pristerodon, Lystrosaurus,
Daptocephalus and Kingoria, and which is supposed to have provided an effective
insertion area for the lateral division of the external adductor muscle mass.
Similarly, the dorsal edge of the dentary is smoothly rounded, and shows no
trace of the deeply incised trench found in other dicynodonts, which is thought
by some authors to have provided attachment for an inner division of the
external adductor muscle mass. In the symphyseal region the dentary is not
as deep as in the mandible of other edentulous dicynodonts. Medially the
dorsal surface of each dentary is built up on either side of a deep median
trough as a pair of sharp-edged longitudinal ridges (Fig. 3, den. r.). Each ridge
terminates as a sharp process on the anterior surface of the mandible, and is
produced backwards past the main body of the jaw ramus. These ridges lie in
true parasagittal planes, and separate the deep median trough from two lateral,
dorsally excavated, dentary ledges (Fig. 3, den. 1.)

PALATE AND MANDIBLE IN SOME SPECIMENS OF DICYNODON TESTUDIROSTRIS 139

3. Referred specimen 8.A.M. Cat. No. 10078 (Fig. 4).
Locality: Dunedin, Beaufort West.

This is a slightly distorted skull with mandible, lacking part of the occiput
and right zygomatic arch, and the posterior part of the right jaw ramus.

The relationships of the bones of the skull roof are as in the type specimen,
and a pair of caniniform flanges is present. The palate is identical to that of
the previous two specimens, but preparation has revealed the presence of a
small, partially erupted tooth lying flat against the medial surface of each
caniniform flange. The teeth are in the position of the large canine tusks
common in dicynodonts, but each tooth is contained in a recess in the caniniform
flange, suggesting that it lay under the horny beak and was not functional.

In the North American dicynodont genus Placerias, Camp & Welles
(1956) have described ‘male’ specimens with enlarged caniniform processes
which almost completely enclose a non-functional tooth. In these skulls,
however, the tooth is directed into the buccal cavity, and the tip has been worn
down by the action of the dentary during mastication.

The mandible of this specimen was removed and cleared of matrix. In all
respects it is identical to the mandible of specimen no. 10086.

4. Referred specimen $S.A.M. Cat. No. 10377.
Locality: Noblesfontein, Victoria West.

This specimen is a skull lacking both zygomatic arches and the inter-
temporal part of the skull roof. While the caniniform processes themselves have
been sheared off close to the base on both sides, the characteristic notch between
the base of the medial, anterior edge of the caniniform flange and the lateral

(b)

Fic. 4. Skull of Dicynodon testudirostris. S.:A.M. Cat. No. 10078. (a) palatal (b) anteroventral
view. X 1. Scale = 1 cm.

140 ANNALS OF THE SOUTH AFRICAN MUSEUM

palatal rim is preserved on both sides. On the right side the section through
the process has revealed a broken-off tooth in the same position, and of the
same size, as the teeth in specimen no. 10078.

In addition to these described specimens, a superficial survey of the South
African Museum dicynodont collection showed that additional specimens of
D. testudirostris appear to be widespread in several Cistecephalus zone localities.
Specimens showing the characteristic caniniform flange, mandible and skull
roof of D. testudirostris have been collected at Kuilspoort, Beaufort West (e.g.
S.A.M. 6550, 7401), Roosplaats, Beaufort West (e.g. S.A.M. 10204), Leeu-
kloof, Beaufort West (e.g. S.A.M. 11084) and Loskop, Victoria West (e.g.
S.A.M. roo60).

EXTENT OF THE Horny BEAK IN Dicynodon testudirostris

Several inferences can be made regarding the extent of the horny beak
in the above specimens. The lateral palatal rim, which tapers to a sharp
knife-edge, was apparently covered by a correspondingly sharp and probably
thin layer of horn, produced anteriorly as two spiky processes over the bony
projections of the premaxilla. To the rear the horny layer would have covered
the caniniform flanges, extending as a sharp leading edge anteriorly. Several
sizeable nutrient foramina in the notch between the leading edge and the
lateral palatal rim suggest that a thickening of horn lay in this recess. Medially
to the caniniform flange the presence of a horny pad is again indicated by
nutrient foramina on the raised area of premaxilla and maxilla. The horn
cover very likely extended beneath the roof of the secondary palate to form a
cutting edge over the median palatal ridge.

A posterior extension of the beak appears to have capped the expanded
palatal portion of the palatine.

On the mandible the beak appears to have terminated in a pair of sharp
points similar to those of the upper jaw. Behind these spikes the horny layer
must have continued as a pair of cutting edges, while laterally to each edge the
lateral dentary depression would have contained a thicker horny pad. This pad
probably terminated laterally as a clearly defined edge on the side of the
mandible. The median trough between the two cutting edges was very likely
also covered with at least a thin layer of horn.

JAw MuscuLaTuRE AND MAsTICATORY CYCLE IN Dicynodon testudirostris

The rounded dorsal edge and flat lateral surface of the dentary in Dicynodon
testudirostris suggest that the jaw adductor musculature was not inserted onto
the mandible in the same way as in, for instance, Emydops or Daptocephalus.
However, since the anatomy of the articular and quadrate in Dicynodon testudi-
rostris has remained typically dicynodont and indicates the usual anteroposterior
sliding action between the two bones, and since the areas of origin of the external
adductor musculature on the rear of the skull have remained unchanged, it is
safe to assume that the masticatory cycle was close to the usual dicynodont

PALATE AND MANDIBLE IN SOME SPECIMENS OF DICYNODON TESTUDIROSTRIS I41I

pattern and that the external adductor muscles inserted on approximately the
same portions of the dentary as in other dicynodonts. Thus the lateral division
of the external adductor muscle probably arose from the quadratojugal and
lateral parts of the squamosal and inserted over the lateral surface of the dentary,
in the position of the dentary shelf in other dicynodonts. The medial division
of the external adductor muscle would have had its origin inside the temporal
fossa on the squamosal, parietal and postorbital, and probably inserted partly
on the dorsal edge and partly on the inner or outer surface of the dentary, in
the position of the dentary groove of other dicynodonts.

The main internal adductor muscles, i.e. the anterior and posterior ptery-
goideus muscles, probably had the same relationships as those reconstructed in
Emydops by Crompton & Hotton (1967). The pterygoideus anterior muscle
arose from the palatal ramus of the pterygoid and the lateral surface of the
ectopterygoid, and wrapped around the lower edge of the articular and pre-
articular to insert on the outside surface of the prearticular beneath the
reflected lamina.

The posterior pterygoideus muscle arose from its side of the characteristi-
cally moulded ventral surface of the interpterygoidal plate, and inserted
beneath the internal condyle of the articular.

A depressor mandibulae muscle, now accepted as having been present in
dicynodonts (Barry, 1967; Crompton & Hotton, 1967), would have originated
on the occipital flange of the squamosal, and inserted on the ventrally directed
retro-articular process of the articular.

Given these areas of origin and insertion, the jaw musculature would have
been capable of the typical dicynodont masticatory cycle proposed by Crompton
& Hotton (1967). However, the singular nature of the palate and anterior
portions of the dentaries, results in occlusal relationships between upper and
lower jaws which represent a departure from the condition in, for instance,
Daptocephalus or Lystrosaurus.

1. Jaw from protracted, fully depressed position to protracted adducted position
(Fig. 5a, b, c).

When the jaw is drawn up from the fully protracted position the sides of
the dentary are able to move only a short way up past the caniniform flanges
before the dorsal edge of the dentary touches the ectopterygoid (Fig. 5b, c).
With the jaw slightly retracted before adduction, the overlap between canini-
form flange and the dentary is increased, but actual contact between the
flange and lateral dentary surface would be possible only if a considerable
layer of horn were present on the dentary, and then the contact would be
limited to one between the dentary and the inwardly directed leading edge of
the flange. Lateral displacement of the mandible during mastication was
probably possible during life, but the nature of the quadrate-articular contact
in Dicynodon testudirostris seems to have kept such movement down to a
minimum.

142 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fic. 5. Masticatory cycle of Dicynodon testudirostris. Lateral (a, b, d, f) and ventral (c, e, g) views.

PALATE AND MANDIBLE IN SOME SPECIMENS OF DICYNODON TESTUDIROSTRIS 143

2. Jaw fully protracted, fully adducted (Fig. 5b, c).

The anterior tips of mandible and premaxilla approach, but would have
to be considerably produced as horn to make contact. The lateral palatal and
mandibular rims are well separated, laterally as well as dorsoventrally, while
the lateral dentary surface approaches the maxillary flange. The side of the
mouth is still well open.

3. Jaw after beginning of retraction (Fig. 5d, e).

The dorsal, buccal surface of the fused dentaries moves up towards the
palate, tending to close the side of the mouth in front of the caniniform flanges.
However, the palatal and mandibular rims are still well separated laterally.
The lateral dentary surface has passed the caniniform flange and the lateral
excavation on the buccal surface of the dentary approaches the built-up area
of the palate median to the flange.

4. Jaw fully retracted (Fig. 5f, g).

The anterior tip of the jaw lies in line with the front edges of the caniniform
flanges, while the lateral dentary troughs appose the raised premaxilla-maxilla
region. The median premaxillary palatal blade lies inside the median trench
of the dentary symphyseal region.

Nowhere in the cycle does the lateral palatal rim, in front of the maxillary
caniniform flanges, perform any prominent function. With the jaw in the
adducted protracted position the anterior tips of the dentary and premaxilla
approach each other, and the maxillary caniniform flanges overlap the lateral
dentary surface, but the lateral palatal rim is well separated from the lateral
dentary surface, both in ventral and in lateral view. As retraction proceeds,
the anterior tip of the jaw moves upward, closing the gap in lateral view, but
in ventral view it can be seen that the rounded dentary moves away from the
lateral rim.

The caniniform flanges appear to have been functional mainly during the
adduction of the lower jaw, and during the very first stages of retraction. After
a short period of retraction the flat, lateral surface of the dentary has moved
past the anterior cutting edge of the flange, which thereafter lies well separated
from the rounded anterior portion of the dentary. A modest pad of horn on the
side of the dentary, behind the rounded tip, would have been sufficient to
give a working surface for the presumably sharp-edged, thin layer of horn on
the caniniform flange.

During retraction, the lateral excavated area on the dorsal surface of the
dentary approaches and apposes the built-up area of the maxilla and premaxilla,
median to the maxillary caniniform flange. At the rear of each of the built-up
areas is a short bony tubercle which projects towards the trough of the dentary
table of its side, while the inner edge of each raised area bears less prominent
tubercles. The horn pad housed in each dentary trough would have worked
up against the horn-covered surface of the palate in a grinding, crushing action.
The bony tubercles on the maxilla, if they were reflected in the covering horn

144 ANNALS OF THE SOUTH AFRICAN MUSEUM

layer, would have assisted in stabilizing food during this crushing process.

At the end of retraction, the lateral dentary troughs move further upward,
opposite the inflated palatal portions of the palatines.

During retraction, the pair of longitudinal cutting edges on the dorsal,
buccal surface of the fused dentaries, which were covered by a correspondingly
sharp layer of horn, project up into the trench between the raised lateral portion
of the palate and the median premaxillary palatal ridge. These three sharp
blades would have produced between them an effective slicing action. The
terminal dentary spikes do not take an extensive part in this action, and approach
the palatal trenches only at the end of retraction.

COMPARISON WITH OTHER FORMS
Endothiodontidae

Emydops sp. S.A.M. Cat. No. 10153 (Fig. 6).
Locality: Dunedin, Beaufort West.

This is a well-preserved, undistorted skull. Canine tusks are absent, but
there appear to be 4 postcanine teeth in both upper and lower jaw. In a number
of teeth posterior serrations are visible. The palatal portion of the palatine is
large and appears to make contact with the premaxilla. According to Toerien
(1953) a palatine-premaxilla contact is characteristic of Emydops.

The palatal rim is well developed and sharp-edged, but it appears to
become blunter posteriorly. There is a prominent median premaxillary ridge,
but no indication of anterior premaxillary ridges. There is no clearly defined
caniniform process.

The symphyseal region of the jaw is short, and the anterior tip of the

lat. den.sh

lat. den. sh.

(a) \

(b)

Fic. 6. Skull of Emydops sp. S.A.M. Cat. No. 10153. (a) lateral (b) ventral view. x 1. Scale=1 cm.

PALATE AND MANDIBLE IN SOME SPECIMENS OF DICYNODON TESTUDIROSTRIS 145

dentary is produced dorsally as a blunt process. Immediately behind the
symphyseal region the dorsal edge of the dentary is rounded, but further back
there is a deeply incised trench lateral to the tooth row. The lateral surface of
the dentary is drawn out to form a wide ledge above the mandibular fenestra.

Pristerodon (Information taken from Barry, 1967).

Canine tusks are present, as well as three postcanine teeth. The palatal
rim is well developed anterior to the canine tusk. The palatine is not as large
as in Emydops, and does not meet the premaxilla. Toerien (1953) has found
this to be the case in the Pristerodon species he investigated. Anterior premaxillary
ridges are not prominent.

Two functional teeth are present in each jaw ramus. As in Emydops, the
symphyseal region is not extensive, and is produced to form a blunt anterior
process. Both the dorsal dentary groove and the lateral dentary shelf are present.

Endothiodontid (?) sp. S.A.M. Cat. No. 10137 (Fig. 7).
Locality: Dunedin, Beaufort West.

Although tuskless and lacking postcanine teeth, this specimen resembles
Emydops in size, the broad intertemporal region and palatine-premaxillary

contact.
There is a median palatal ridge but no prominent anterior ridges. There

is a weak caniniform thickening. The palatal surface of the palatine is large and
meets the premaxilla anteriorly.

Fic. 7. Skull of endothiodontid (?) sp. S.A.M. Cat. No. 10137. Palatal view. x 1. Scale=1 cm.

Cryptodontidae (sensu Toerien, 1953; Haughton & Brink, 1956)
Oudenodon kolbei, type specimen, S.A.M. Cat. No. 1886 (Fig. 8).

Locality: Rhenosterfontein, Beaufort West.

The palatal rim is drawn out as a modest caniniform process, a ventral
continuation of a pronounced lateral thickening of the side of the snout. The

146 ANNALS OF THE SOUTH AFRICAN MUSEUM

ant. pm.r.

med. pm-r.

7 We
Fic. 8. Skull of Oudenodon kolbei. Type specimen, S.A.M. Cat. No. 1886. Palatal view. x 4.
Scale = 1 cm.

palatal rim is well developed before and behind the caniniform process. All
three premaxillary palatal ridges are present and prominent. Behind the level
of the caniniform process the premaxilla is raised to form a ledge along the
suture with the maxilla. The ledge is furnished with several sharp bony tubercles.
The palatines are greatly expanded and make contact with the premaxilla.

Tuskless dicynodont, $.A.M. Cat. No. 10661 (Fig. 9).
Locality: Welgevonden, Fraserburg.

The mandible of this specimen has muscle scars on the lateral face of the
dentary, which is not expanded to form a ledge. Behind the symphysis the
dentaries are built up to form dentary tables (Fig. ga, den. 1.) (Crompton &
Hotton, 1967). A deep dentary groove is present on the dorsal edge of the jaw
ramus, and is continued forward as a shallow trough onto the dentary table or
ledge. It seems probable that a pad of horn, carried in this anterior trough,
would have acted against the palatine and adjoining premaxillary-maxillary
portion of the palate during retraction of the jaw.

Dicynodontidae
Dicynodon grimbeeki (Information taken from Agnew, 1959).

The palatal rim is well developed in front of the tusks and the palatine
does not reach the premaxilla.

PALATE AND MANDIBLE IN SOME SPECIMENS OF DICYNODON TESTUDIROSTRIS

147

den. gr.

(a)

lat.den ‘sh.

(b)

eH
ang

Fic. 9. Mandible of tuskless dicynodont sp. $.A.M. Cat. No. 10661. (a) dorsal (b) lateral view.
< 45 Scalei— 1 cm:

ant. pm. r.

Fic. 10. Skull of Dicynodon sp. S.A.M. Cat. No. 10681. Palatal view. x $. Scale = 1 cm.

Dicynodon sp. S.A.M. Cat No. 10681 (Fig. 10).
Locality: Leeukloof, Beaufort West.

The palatal surface is deeply recessed, and the palatal rim is strongly
developed in front of the tusk and also to a lesser degree behind the tusk. The

palatine does not reach the premaxilla. Anterior palatal ridges, as well as the
posterior ridge, are present.

148 ANNALS OF THE SOUTH AFRICAN MUSEUM

The jaw in several Dicynodon specimens possesses a dorsal dentary groove
and built-up dentary tables, but no prominent lateral dentary ledge is found.
Muscle scars in the region above the mandibular fenestra are present in some
cases.

Daptocephalus sp. S.A.M. Cat. No. 8784.

Locality: Doornplaats, Graaff-Reinet.

Tusks are present and the palatal rim is strongly developed. Anterior
palatal ridges as well as the posterior one are present. Ewer (1961) has described
bony palatal tubercles on the palatine and adjoining maxilla. The palatine
makes a short contact with the premaxilla.

The anterior part of each jaw ramus is built up to form dorsally grooved
dentary tables, and a posterior dorsal dentary sulcus is present. The lateral
surface of the dentary is moulded to form a weak ledge, and muscle scars are
visible in this region.

Lystrosauridae (Fig. 11)

Several well-preserved skulls with mandibles were available for comparison.
The palate is deeply recessed and bears clear anterior and posterior palatal
ridges, while the surface of the maxilla alongside the palatal portion of the
palatine is rough and pitted. In the lower jaw dentary tables and a dentary
groove are present, and a clear dentary shelf is formed, although the latter is
not as pronounced as in, for instance, the mandible of Emydops.

- (b
tb) lat. den.sh. -

es

Fic. 11. Mandible of Lystrosaurus. Nat. Mus. Bloemfontein Cat. No. C. 403. (a) lateral (b) dorsal
view. X 4. Scale = I cm.

PALATE AND MANDIBLE IN SOME SPECIMENS OF DICYNODON TESTUDIROSTRIS 149

lat den.sh

den. fos
lat.den sh

Fic. 12. Mandible of Kingoria (?). S.A.M. Cat. No. 6043. (a) dorsal (b) lateral view. x 2.
Scale = 1 cm.

Dicynodont (Aingoria?)
S.A.M. Cat. No. 6043 (Fig. 12).
Locality: Heuningnest Krantz, Graaff-Reinet.

This specimen consists of an occipital plate, the intertemporal region of
the skull roof, the left jaw ramus and the symphyseal region of the fused
dentaries.

The nature of the preserved dentary indicates that this dicynodont differed
from all the specimens described above in the nature of the external adductor
muscle insertion. There is a very deeply excavated dentary fossa, leading out
laterally to a wide dentary shelf. There is no groove on the dorsal border of the
dentary, which is reduced to a sharp edge above the lateral dentary shelf.
Anterior to this region the dentary is rounded dorsally.

It appears that in this dicynodont, which in some respects resembles
Kingoria (Cox, 1959), the insertion areas of both the external and internal
adductor muscle masses were coalesced in the deep and wide dentary shelf.

DIscussION

Boonstra (1963) has outlined the main steps involved in the derivation of
a typical dicynodont from a sphenacodont pelycosaur. The two Russian forms
Venjukovia and Otsheria appear to be transitional in this evolutionary sequence.
The main changes which took place in the palate are connected with the
development of a premaxillary secondary palate and the reduction in the
number of teeth.

150 ANNALS OF THE SOUTH AFRICAN MUSEUM

The increase in palatal extent of the premaxilla, already far advanced in
Venjukovia and Otsheria, results in the posterior displacement of the internal
nares, and an associated dorsal vaulting of the palate posterior to the pre-
maxilla. Thus in Venjukovia only a lateral portion of the palatine retains its
original palatal disposition, the median section being strongly arched to form
a posterodorsal roof for the emerging air passage. The maxilla assists in the
posterior displacement of the functional choana by developing a median exten-
sion, which in some dicynodonts separates the premaxilla from the palatine.
The ventral surface of the vomer, flush with the surrounding palatal bones in
pelycosaurs, has been affected by the dorsal arching of the palatines, and in
typical dicynodonts lies recessed in the palatal vault. In typical dicynodonts
teeth anterior to the canine tusks have been lost, and postcanine teeth, where
present, have migrated medially. A true alveolar border is absent.

The relationships between premaxilla, maxilla and palatine would by
this analysis depend on the rate of posterior extension of the premaxilla, the
degree of medial extension of the maxilla, and the degree of dorsal arching of
the palatine. A further determining factor would be the shortening of the
palatal region as a whole, a process which seems to have been active during the
evolution of true dicynodonts from pelycosaur ancestors. Associated with these
changes in the anterior portion of the skull, was the differentiation of the
external adductor muscle into lateral and medial portions, the former division
gaining an area of origin, unique among therapsids, below and lateral to the
base of the zygomatic arch.

It is therefore not surprising that a variety of palatal types were evolved
during the early phases of dicynodont evolution. The most obvious variation
is the presence or absence of a palatine-premaxilla contact. Thus in two
apparently closely related endothiodontid genera, Emydops and Pristerodon, a
palatine-premaxilla contact is present in the former but absent in the latter.
In the lower jaw of these genera, however, the dentaries appear to be basically
similar, with dorsal dentary grooves and lateral dentary ledges.

Oudenodon resembles Dicynodon in the absence of post-canine teeth and the
similar dorsal grooves and flat lateral surface of the dentaries. In both genera
it seems that the dentaries have been deepened behind the symphysis to form
dentary tables. However, in Dicynodon a palatine-premaxilla contact is con-
sistently lacking, this contact being a feature of Oudenodon.

Dicynodon testudirostris resembles other species of Dicynodon in the presence of
the median palatal process of the maxilla between the premaxilla and palatine.
Departures from the typical dicynodontid condition are the reduced or absent
canine tusks, the transformed and enlarged caniniform processes, the greatly
reduced palatal portion of the palatine, the widely excavated dentary tables
of the lower jaw and the rounded dorsal edge of the dentary.

It seems that these characteristics of Dicynodon testudirostris are specialisa-
tions leading away from the typical Dicynodon stock, rather than primitive
features retained from an ancestral dicynodont group. The reduction of the

PALATE AND MANDIBLE IN SOME SPECIMENS OF DICYNODON TESTUDIROSTRIS I5I

typical Dicynodon canine teeth and concomitant enlargement of the caniniform
process was of adaptive value, connected with a reorganisation of the food
cutting and crushing areas on the palate and buccal surface of the lower jaw.
The anterior edge of the caniniform process appears to have taken over the
slicing function of the more anterior palatal rim, which has no close association
with the sides of the dentary during the masticatory cycle. Similarly, while in
most typical dicynodonts the main food-crushing area in the palate is the
expanded palatal portion of the palatine and a part of the adjoining maxilla,
in Dicynodon testudirostris the food-crushing activity has been moved forward to
the raised premaxillary-maxillary shelf median to the caniniform process. The
palatine has been reduced accordingly.

In the symphyseal region of the lower jaw, the dorsal edge of the dentary,
which in Dicynodon and Daptocephalus appears to have borne a simple thickening
of horn, has become excavated to form a deep trough, which would have
contained a greatly enlarged pad of the horny beak to work up against the
raised maxillary-premaxillary shelf in the palate. Medially the trough is
terminated as a high, sharp blade, which, produced in horn, would have
acted as a sharp knife-edge in the trough alongside the median palatal ridge.

Associated with these changes was a new insertion of the medial division
of the external adductor muscle. The sulcus in the dorsal edge of the dentary
appears to have housed this insertion in forms which have retained post-canine
teeth, such as Emydops and Pristerodon, as well as more advanced genera such
as Dicynodon, Lystrosaurus and Kannemeyeria. There is a possibility that the inser-
tion of this muscle mass in Dicynodon testudirostris migrated outwards onto the
lateral surface of the dentary. That there was considerable variation in this
part of the dentary among the various dicynodont groups has been shown, an
extreme condition being the dentary of the dicynodont, S.A.M. Cat. No.
6043 (Kingoria ? sp.), where a coalescence of the insertions of the inner and
outer division of the adductor muscle appears to have occurred in the wide
and deeply moulded dentary ledge.

The features in the skull and mandible of Dicynodon testudirostris which
represent a departure from the typical Dicynodon cranial pattern are adaptive
modifications, clearly related to an attempt at achieving more effective masti-
cation. Dicynodon testudirostris is in these respects clearly distinguishable from
other species of Dicynodon, and the results of further investigation into the
morphology of the genus Dicynodon itself may later warrant the inclusion of the
species testudirostris in a different but related genus.

SUMMARY

Several specimens of the therapsid Dzucynodon testudirostris have been
described, with special reference to the palate, palatal rim and mandible. The
function of the unusual caniniform flange of the maxilla, and the occlusal
relationships between upper and lower jaws during the masticatory cycle,

152 ANNALS OF THE SOUTH AFRICAN MUSEUM

have been discussed. Comparison of Dicynodon testudirostris with other dicynodont
genera has provided some indication of the steps involved in the evolution of
the various main dicynodont groups.

ACKNOWLEDGEMENTS

Mrs. I. M. Chesselet and Miss S. A. James have, by their meticulous and
painstaking preparation of the majority of the specimens, made an invaluable

contribution to this project.
The Trustees of the South African Museum thank the South African
Council for Scientific and Industrial Research for a grant in aid of publication.

REFERENCES

Acnew, J. D. 1959. Cranio-osteological studies in Dicynodon grimbeeki with special reference to
the sphenethmoid region and cranial kinesis. Palaeont. afr. 6: 77-107.

Barry, T. H. 1967. The cranial morphology of the Permo-Triassic anomodont Pristerodon
buffaloensis with special reference to the neural endocranium and visceral arch skeleton.
Ann. S. Afr. Mus. 50: 131-161.

Boonstra, L. D. 1963. Early dichotomies in the therapsids. S. Afr. F. Sci. 5g: 176-195.

Broom, R. 1932. The mammal-like reptiles of South Africa and the origin of mammals. London:
Witherby.

Broom, R. & HaucutTon, S. H. 1913. On two new species of Dicynodon. Ann. S. Afr. Mus. 12:
36-37.

Camp, C. L. & WELLEs, S. P. 1956. Triassic dicynodont reptiles. Part I. The North American
genus Placerias. Mem. Univ. Calif. 13: 255-304.

Cuiuver, M. A. (In press.) The cranial anatomy of the genus Lystrosaurus. Ann. S. Afr. Mus.

Cox, C. B. 1959. On the anatomy of a new dicynodont genus with evidence of the position of
the tympanum. Proc. zool. Soc. Lond. 132: 231-367.

Crompton, A. W. & Horron, N. 1967. Functional morphology of the masticatory apparatus
of two dicynodonts (Reptilia, Therapsida). Postilla 10g: 1-51.

Ewer, R. F. 1961. The anatomy of the anomodont Daptocephalus leoniceps (Owen). Proc. zool.
Soc. Lond. 136: 375-402.

HaucutTon, S. H. & Bring, A. S. 1954. A bibliographical list of Reptilia from the Karroo beds
of Africa. Palaeont. afr. 2: 1-187.

Romer, A. S. 1966. Vertebrate paleontology. 3rd ed. Chicago: University Press.

TorrIEN, M. J. 1953. The evolution of the palate in South African Anomodontia and its
classificatory significance. Palaeont. afr. 4: 49-117.

PALATE AND MANDIBLE IN SOME SPECIMENS OF DICYNODON TESTUDIROSTRIS

ang.

ant. pm. r.

art.
bas.

bo.

can. fl.
den.
den. fos.
den. gr.
den. |.
den. r.
ect.

eo.

ept.

fr

ipt. vac.
jug.

lac.

lat. den. sh.

max.

med. pm. r.

nas.
orb.

pa.

ABBREVIATIONS
angular pal.
anterior premaxillary ridge pal. sh.
articular pas.
basisphenoid pfr.
basioccipital pil. ant.
caniniform flange pm.
dentary po.
dentary fossa pof.
dentary groove pp.
dentary ledge prs.
dentary ridge pt.
ectopterygoid q.
exoccipital qj.
epipterygoid ref. lam.
frontal Sa.
interpterygoidal vacuity smx.
jugal smx. for.
lacrimal sq.
lateral dentary shelf sta.
maxilla ts
median premaxillary ridge tub.
nasal vo.
orbitosphenoid VII
parietal XII

palatine
palatal shelf
parasphenoid
prefrontal
pila antotica
premaxilla
postorbital
postfrontal
preparietal
presphenoid
pterygoid
quadrate
quadratojugal
reflected lamina
surangular
septomaxilla

septomaxillary foramen

squamosal
stapes
tooth
tubercle
vomer

foramen for facial nerve

8)

foramen for hypoglossal nerve

INSTRUCTIONS TO AUTHORS

Based on

CONFERENCE OF BIOLOGICAL EDITORS, COMMITTEE ON FORM AND STYLE. 1960.

Style manual for biological journals. Washington: American Institute of Biological Sciences.

MANUSCRIPT

To be typewritten, double spaced, with good margins, arranged in the following order:
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tion to plates.

ILLUSTRATIONS
To be reducible to 12cm X 18cm (19cm including caption). A metric scale to appear with
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REFERENCES

Harvard system (name and year) to be used: author’s name and year of publication given
in text; full references at the end of the article, arranged alphabetically by names, chronologi-
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author in that year.

For books give title in italics, edition, volume number, place of publication, publisher.
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World list of scientific periodicals. 4th ed. London: Butterworths, 1963), series in parentheses,

volume number, part number (only if independently paged) in parentheses, pagination.

Examples (note capitalization and punctuation)

BULLOUGH, W. S. 1960. Practical invertebrate anatomy. 2nd ed. London: Macmillan.

FiscHER, P.-H. 1948. Données sur la résistance et de le vitalité des mollusques. 7. Conch., Paris
88: 100-140.

Fiscuer, P.-H., Duvat, M. & Rarry, A. 1933. Etudes sur les échanges respiratoires des littorines.
Archs Zool. exp. gén. 74: 627-634.

Koun, A. J. 1960a. Ecological notes on Conus (Mollusca: Gastropoda) in the Trincomalee region
of Ceylon. Ann. Mag. nat. Hist. (13) 2: 309-320.

Koun, A. J. 19605. Spawning behaviour, egg masses and larval development in Conus from the
Indian Ocean. Bull. Bingham oceanogr. Coll. 17 (4): 1-51.

TuHIELE, J. 1910. Mollusca: B. Polyplacophora, Gastropoda marina, Bivalvia. In ScHULTZE. L,
Koologische und anthropologische Ergebnisse einer Forschungsreise im westlichen und zentralen Stid-
Afrika. 4: 269-270. Jena: Fischer. Denkschr. med.-naturw. Ges. Jena 16: 269-270.

ZOOLOGICAL NOMENCLATURE

To be governed by the rulings of the latest International code of zoological nomenclature issued
by the International Trust for Zoological Nomenclature (particularly articles 22 and 51).
The Harvard system of reference to be used in the synonymy lists, with the full references
incorporated in the list at the end of the article, and not given in contracted form in the synonymy
list.

Example
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TN
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