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THE CRANIAL MORPHOLOGY OF THE
DICYNODONT GENUS LYSTROSAURUS

By
M. A. CLUVER GANTHSONT
\
AUG 181971 |

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Cape Town Kaapstad

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THE CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS
LYSTROSAURUS
By
M. A. CLUVER
South African Museum, Cape Town

(With 77 figures)

[MS. accepted 12 November 1970]

CONTENTS
PAGE
Introduction ° . 2 : : : ° Zee 0
Material and techniques : : : : ¢ - 158
Section I. The cranial anatomy of Lystrosaurus
Neurocranium
Braincase and occiput - . : ; : LOD
Sphenethmoid complex - : . . . : 175
Visceral arch skeleton
Palatoquadrate - : : 5 . BY Po siee3ye
Stapes and hyoid apparatus - . 2 . 2 G3
Dermocranium
Snout region: < . : : : . e184!
Palatal region : . ; : : : * 199
Skull roof - : : : - c : 2 ON
Squamosal and quadraLojugal: . : : TE 203
Sclerotic plates” - : : 3 e 202:
Mandible : : : : : . : : 205
Section II. The jaw musculature and masticatory cycle in
Lystrosaurus
The jaw musculature 2 ° 6 : G a2 Of
The masticatory cycle c c : ° : 2) GO)
Section III. The atlas-axis complex and cervical and
occipital musculature in Lystrosaurus
Morphology of the atlas-axis complex - . : Oo ONT
Musculature of the atlas-axis complex and occiput e210)
Section IV. Evolutionary sequence leading to the Lystro-
saurus grade of dicynodont development
Comparison of the skulls of Lystrosaurus and typical Permian
dicynodonts
Depth of skull < e : 2 . : ean 2 20
Shortening within the skull - : a 3 22
Relationships of the brain 2 ° . . 0° BIX6)
Adductor musculature - . . : : : 227
Derivation of the Lystrosaurus skull proportions - R23 i
Section V. Variation in the skull of Lystrosaurus and the
taxonomy of the genus
Skull variation within the genus - 6 : . 236
The sexual dimorphism problem- : Q cn 230
Effects of age and distortion on the skull at : > +240

155

Ann. S. Afr. Mus. 56 (5), 1971: 155-274, 77 figs

I 56 ANNALS OF THE SOUTH AFRICAN MUSEUM

PAGE
The species of Lystrosaurus - : : c : 42
Speciation in Lystrosaurus - : C 2 ; STA:
Lystrosaurus from India, China and Russia - : 2) 256
Section VI. The origin of Lystrosaurus from a Permian
ancestor and its relationships with some other Triassic
dicynodont genera - : : < : : 257
Conclusions
The basicranial axis : : < : ° - 261
The soft structures of the snout 2 : p 2S
The jaw and neck musculature - : : : op) FOR
Adaptive changes in the skull - : : . - 264
Division of the species : : : : : > 265
Relationships with other dicynodont genera - . = 265;
Summary - i : 3 : 4 , : Be of as
Acknowledgements O s : : ; ¢ OF
References - . C c . : : : - 268
Abbreviations - C é c . ° : 77 2

INTRODUCTION

Numerically, the major part of the therapsid fauna of the Karoo system is
made up by the infraorder Dicynodontia, herbivores which are represented
abundantly throughout the entire succession. The Dicynodontia form part
of the suborder Anomodontia (sensu Watson & Romer, 1956; Romer, 1966)
and are believed to have diverged from the suborder Theriodontia early in the
history of the Therapsida. In the following descriptions the term dicynoc + |
refers to therapsids within the infraorder Dicynodontia, while dicynodontid,
endothiodontid and lystrosaurid refer respectively to members of the families
Dicynodontidae, Endothiodontidae and Lystrosauridae. This terminological
procedure is in accordance with Romer’s (1966) classification.

It is generally accepted that the success of the Dicynodontia is at least in
part due to their unique masticatory apparatus, involving horny upper and
lower beaks, extremely long and powerful temporal muscles, and an antero-
posterior sliding action between the quadrate and articular. While modifi-
cations in the cranial anatomy have taken place during the course of dicynodont
evolution, and have resulted in rich diversity, the basic masticatory cycle has
been retained and improved throughout.

Thanks to the abundance of specimens available for study, the gross
anatomy of most dicynodont groups is reasonably well known, although poor
preservation, crushing and distortion remain obstacles in any study of Karoo
fossils. Again, the numerous duplicate specimens now available in most dicyno-
dont collections make serial grinding and sectioning of selected specimens
possible, and these techniques have provided a wealth of additional information
regarding the finer anatomy of several species.

Although far removed from the direct line of evolution leading to the first
mammals, the dicynodonts make up the bulk of the therapsids, and this

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 157

abundance makes them very useful to any investigation involving evolutionary
trends among therapsids. Knowledge of such trends in a group whose evo-
lutionary history spans a long, uninterrupted period of time through the
Permian and Triassic periods, is essential to organization of Karoo therapsids
into faunistic entities. Again, as the finer anatomy of the Dicynodontia becomes
more fully understood, and more accurately related to stratigraphical occur-
rence, it should become possible to establish a detailed dicynodont phylogeny
which, when correlated with geographical distribution, will provide useful
information regarding continental connections and therapsid migrations during
the Permian and Triassic.

At the close of the South African Permian the period of dicynodont diversity
so characteristic of the Tapinocephalus, Endothiodon and Cistecephalus zone times
came to an end. In the first zone of the Lower Triassic, the Lystrosaurus zone,
only one dicynodont, Lystrosaurus itself, is common, the only other member of
the infraorder being the very poorly represented Myosaurus. Lystrosaurus, taken
with the associated Prolystrosaurus, therefore comprises a distinct, well-defined
stage in dicynodont development, and is well represented in the shales of the
Lystrosaurus zone. As even a superficial study will show, the genus had soon
become successfully adapted to a new environment of fresh-water lakes and
streams, and had radiated into several morphologically distinct groups of
species.

The following have been the main objectives of this study.

Firstly, an in-depth survey of the cranial anatomy of Lystrosaurus, seen
purely as a therapsid genus, should add to our knowledge of the therapsids as
a whole. Since an abundance of specimens in a good state of preservation was
available for this study, and since the majority of these could be extensively
prepared, it has been possible to describe the morphology in considerable
detail. In this way evidence bearing on several problems of therapsid evolution
has come to light.

Secondly, since the Lystrosauridae are a widespread, successfully adapted
group with a clearly defined temporal occurrence, a comparative study of the
morphology illustrates the manner in which evolutionary processes have acted
to produce a skull form adapted to fulfil certain new needs without prejudicing
the effectiveness of other essential functional qualities. Lystrosaurus is therefore
considered first purely in terms of comparative anatomy, and then in terms of
functional anatomy, the two aspects being subsequently correlated in an
attempt at determining both the most likely Permian ancestor of Lystrosaurus
and the evolutionary pathway followed to produce Lystrosaurus from such
an. ancestor.

Thirdly, an attempt has been made to assess the relationships which
Lystrosaurus as a faunal entity bears to preceding and succeeding dicynodont
groups. Anatomically, the lystrosaurids represent a departure from the standard
pattern found in Permian dicynodonts, themselves a diverse assemblage.
Moreover, they are at first glance manifestly distinct from any of the later

158 ANNALS OF THE SOUTH AFRICAN MUSEUM

Triassic genera, and thus represent an intermediate faunal stage within the
Karoo succession, in which the Dicynodontia were represented by one obvi-
ously highly specialized genus only (if we disregard the rare and poorly known
Myosaurus). However, the present investigation indicates several points of
structural agreement between the cranial morphology of Lystrosaurus and that
of the later dicynodonts.

Finally, although any taxonomic division depending entirely on cranial
morphology must of necessity be far from conclusive, several anatomical
features uncovered during the course of this investigation appear to bear on
the taxonomy of the genus. These points are discussed and a tentative division
of the various species of the genus 1s set out.

In 1859 the first specimen of Lystrosaurus, from the Beaufort Beds of Coles-
burg, Cape Province, was described by T. H. Huxley as Dicynodon murrayi. In
1860, however, Richard Owen realized that forms allied to Huxley’s D. murrayi
should be placed in a separate genus, for which he proposed the name Ptychogna-
thus. By 1890, when Lydekker pointed out that Ptychognathus was preoccupied
and therefore invalid, six species of Ptychognathus had been described by Owen,
in 1860, 1862 and 1876. Lydekker introduced the name Ptychosiagum for the
group, but in 1898 Seeley showed that the specimen described by Cope in
1870 as Lystrosaurus frontosus was in fact a species of Ptychognathus, and that,
should the latter name be invalid, all the species should be placed under the
generic name Lystrosaurus.

At present 24 South African species of Lystrosaurus have been described,
as well as a supposedly ancestral genus, Prolystrosaurus, with two species.

MATERIAL AND TECHNIQUES

Although a large number of specimens of Lystrosaurus in the collections of
the South African Museum and the National Museum, Bloemfontein, provided
the information needed for the section on the comparative anatomy of the
group, the descriptions are based mainly on the following specimens, chosen
for their fine preservation, undistorted state, or suitability for sectioning:

Lystrosaurus murrayt

Nat. Mus. No. C.282 . . Skull & mandible
C.6457 . . Skull, mandible & neck
Gear . . Skull & mandible
C.228 - . . Skull & mandible
S.A.M. No. 1336. . . . Sectioned skull & mandible
K.1495 . . . Skull & mandible

Lystrosaurus declivis

Nat. Mus. No. G.150 . . Skull, mandible & postcranial scraps
C.403. . .. Skull & mandible

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 159

Nat. Mus. No. G.g91 . ~. Skull lacking mandible
G.171 . ~~. Skull lacking mandible

S.A.M. No. K.1284 . . . Sectioned skull & mandible
Lystrosaurus curvatus

Nat. Mus. No. CG.299 =~. =. Skull lacking mandible

S.A.M. No. K.go . . . Sectioned skull & mandible
Lystrosaurus mcCaigt

S.A.M. No. K.116 . . . Skull lacking mandible
Lystrosaurus sp. indet.

S-AUM: NoKe1496 5.) | Snout

LLCO We ie | Braimcase

In addition to these specimens of Lystrosaurus, the following Permian
dicynodonts were frequently referred to as comparative material:

B.P1I. No. 2642 . . . . Emydops skull & mandible
S.A.M. No. 10137. . . . Palemydops skull lacking mandible
OOO och) )c lu) braincase
ULOW 5, Ga kl os we bGaincase
6550. . . . Tuskless dicynodont, with mandible, lack-
ing skull roof
10081 . . . Sectioned tuskless dicynodont, lacking
mandible
6043. . . . Dicynodont, comprising posterior skull
roof, occiput & mandible
8784 . . . Ducynodon, skull & mandible

Three specimens of Lystrosaurus were serially sectioned for the purposes
of this investigation, i.e. S.:A.M. Nos 1336, K.go and K.1284. Specimen No.
K.1284 proved to be the best preserved and least distorted of the three, and
provided more reliable information than the other two specimens, which were
used mainly for comparative and verification purposes.

For sectioning, a mounted diamond saw with a constant mechanical feed
was used, and satisfactory transverse sections were obtained in all three cases.
A constant thickness of the specimen, representing the thickness of the blade, is
lost for each section cut, but it was found that, the specimen being of sufficient
size, no information was lost since the skull, in practice, can never be sectioned
at a perfect right angle to the median plane. Consequently, what fine structures
are missing or incomplete on one side of each section face are usually present
in complementary fashion on the other side.

In two cases it was necessary to embed the specimen prior to sectioning.
Two embedding materials were used, Alabastone plaster and Epoxy resin, it
being found that the plaster was too friable for easy handling of the sections

160 ANNALS OF THE SOUTH AFRICAN MUSEUM

and that the resin tended to cause clogging of the blade during sectioning.

In addition to these three specimens of Lystrosaurus, a tuskless dicynodont,
S.A.M. No. 10081, was embedded in polyester resin and serially sectioned.
This series was of value in comparisons between Lystrosaurus and earlier
dicynodonts.

Mechanical preparation of the specimens was in many cases facilitated by
the relatively soft nature of the rock matrix, and its clean separation from the
often well-preserved bone. In addition, the high percentage of carbonate in
the matrix of several specimens permitted the successful use of 10% acetic acid
in the final stages of preparation. The acid technique was especially effective
in making areas such as the interior of the braincase and snout available for
examination.

Reconstructions of the sectioned specimens were obtained by plotting
points directly from the section faces on to a grid, constructed so as to make
provision for the section thickness and the loss through sectioning. As in con-
vertional reconstructions, making use of the method introduced by Pusey
(1939), lateral and parasagittal views presented no difficulty. However,
orientation of the skull for comparable dorsal and ventral views is complicated
by the peculiar proportions of Lystrosaurus, and by the tremendous variation
expressed in the number of recognizable species of the genus. For example,
an orientation that provides a useful dorsal view in one species may result in
an anterodorsal view in another species.

Theoretically, the most suitable horizontal reference plane is the ventral
inner surface of the braincase, formed by the basioccipital, since this can be
regarded as a conservative region, but this plane proved unsuitable for the
alignment of complete skulls. A number of other planes, based upon structures
within the skull which appear to be constant in shape and position within the
genus, were investigated. The one selected as most practical extends from the
most ventral, median point of the foramen magnum to the ventral, median
surface within the external naris. These points can be determined accurately
and easily in both sectioned and entire skulls, and, since the position of the
nostril is apparently not affected by the deepening and shortening of the skull
in Lystrosaurus, and since the reference plane has a more or less constant rela-
tionship with the basioccipital surface within the braincase, the plane could be
used in comparisons between Lystrosaurus and its Permian predecessors.

All dorsal and ventral views illustrated in this work are orthoprojections
on to this plane, reproduced either from graphic reconstructions of sectioned
specimens, or from pantograph drawings of total specimens. In the case of the
graphic reconstructions, the two basic points of the reference plane were
determined in the lateral reconstructed view of the specimen and then con-
nected to form the reference line in the skull. A second grid, having the reference
plane as a base, was then constructed with a section thickness similar to that
of the first grid. A line, representing the sagittal median line of the skull, is then
drawn across the second grid, parallel to the reference line. In order to recon-

CRANIAL MORPHOLOGY OF THE DIGCYNODONT GENUS LYSTROSAURUS 161

struct a dorsal projection, for instance, any point seen in a transverse section
is plotted on to the first grid, as though to produce a lateral projection, and its
position determined in relation to the second grid. The distance of the point
from the midline of the section face is then determined, and the point is plotted
an equal distance from the line representing the skull midline on the second
grid. The procedure in plotting such a point is illustrated in Figure 1.

In a case such as in Figure 1, where the midline of the skull is not vertical
to the base line, compensation can be made by constructing a new base line
at right angles to the skull midline.

Fig. 1. Method for construction of a dorsal projection onto a hypothetical reference plane from
serial sections.

162 ANNALS OF THE SOUTH AFRICAN MUSEUM

The advantage of this method lies in the ease with which uniformly aligned
skulls can be compared. Although essential in an animal such as Lystrosaurus,
similar methods can be used to advantage in other groups.

SecTION I. THE CRANIAL ANATOMY OF LyYsTROSAURUS

In spite of the wide range of variation in the skull proportions within the
group, all the specimens of Lystrosaurus at my disposal appear to have retained
a set of certain basic, common morphological characters, making a subdivision
of the genus into its various species unnecessary for the purposes of this section.
The following morphological description therefore holds good for the genus
as a whole.

It has proved possible, by making use of sectioned and incomplete speci-
mens, to determine the precise relationships between the neurocranium and
the dermal bones of the skull. Consequently, the descriptions have been divided
into sections dealing with the neurocranium, the visceral arch derivatives and
the dermocranium. In all cases, however, the relationships between these three
developmentally distinct osteological systems have been indicated, in order to
illustrate the concept of their functional unity. For this reason the skull has
been described regionally, again in an attempt at illustrating how several
elements are integrated to produce a single major feature in the skull. It was
felt that in the case of Lystrosaurus, where the skull has undergone several major
changes in proportion and structure during its evolution from a Permian
ancestor, this approach was especially pertinent.

THE NEUROCRANIUM

The neurocranium is represented by the braincase-occiput complex and
the anterior sphenethmoid ossifications. In the snout region a few impressions
on the inner surfaces of the dermal bones provide some indication of the extent
of the unpreserved cartilaginous nasal capsule.

The braincase and occiput

The study of this region in both conventionally prepared and sectioned
specimens has been greatly facilitated by the fact that the various elements of
the Lystrosaurus braincase do not fuse with one another as is the case in most
other dicynodonts, and there is consequently very little doubt as to the exact
relationships they bear to one another. Thus the periotic in Olson’s (1944)
sectioned specimens is in Lystrosaurus clearly divisible into prootic and opisthotic.

As in other dicynodonts, the braincase is formed by the exoccipitals
posteriorly and ventrally, the basioccipital and basisphenoid ventrally, the
opisthotics and prootics laterally and the supraoccipital dorsally (Figs 2, 3, 4, 5).

The posterior portion of the braincase floor is formed by the broad con-
cave dorsal surface of the exoccipital condyles, which meet over the condylar
portion of the basioccipital (Figs 3, 12).

GRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 163

i

Fig. 2. Lystrosaurus declivis. S.A.M. No. K.1284. Parasagittal view of the skull, reconstructed
rom serial sections.

From this floor each exoccipital extends dorsally for a short way to form
a lateral border for the foramen magnum. Dorsally it terminates on the occi-
pital surface as a process for articulation with the proatlas (Fig. ga) and dorso-
medially to the condyle it is pierced by two foramina for the hypoglossal nerve.

The exoccipital-opisthotic meeting is one of the few obscure lines of con-
tact in the skull. In one specimen (S.A.M. No. 11180), however, faint indica-
tions of a line of fusion on the occiput near the foramen magnum (Fig. 10b)
make it clear that the exoccipital did not extend as far laterally as in Pristerodon
(Barry, 1967). The large jugular canal lies between the exoccipital and opis-
thotic, and dorsally to this foramen and just within the cranial cavity the
opisthotic-exoccipital suture is distinct (Fig. ga). Posteriorly each exoccipital
forms a prominent exoccipital condyle, which projects beyond the basioccipital

164 ANNALS OF THE SOUTH AFRICAN MUSEUM

PIL. ANT.
PAE Ie

OP.

BO.

Fig. 3. Lystrosaurus declivis. S.:A.M. No. K.1284. Neurocranium in dorsal view,
reconstructed from serial sections.

condyle, so that functionally a system exists which in some ways resembles
the mammalian double condyle. Van Hoepen (1913) and Von Huene (1931)
mentioned this feature in Lystrosaurus, while Jaekel (1904) found that in Oude-
_ nodon pusillus the basioccipital tends to become reduced. Olson (1944) states
that the dicynodonts parallel the cynodonts in their tendency to form a double
occipital condyle.

Anteriorly the floor of the braincase is formed by the dorsal surface of the
saddle-shaped basioccipital (Figs 10a, 12). This surface has a raised median
crest, low posteriorly and rising up anteriorly to form the posterior lip of a
cup-like depression, the basicranial pit, lying between the basioccipital and
basisphenoid (Fig. 12: BC.P.). Laterally the basioccipital meets the opisthotic
and prootic, and between these three bones the long, ventrally directed auditory
canal is contained (Figs ga, 10a: A.C.). This canal widens as it opens on the
basioccipital-basisphenoid tuber as the fenestra ovalis (Figs 4, ga, 10a). Inter-
nally, the dorsal opening of the auditory canal is enlarged to form an auditory
vestibule (Figs ga, 10a, 12). Behind the vestibule a groove in the basioccipital
leads into the jugular foramen. The direction of the groove seems to indicate
that the jugular vein did not enter the vestibule, as it did in Olson’s (1944)
serially sectioned dicynodonts, but passed medially to it. The jugular foramen
itself is separated from the posterior portion of the vestibule by a bony wall
(Fig. 10a).

CRANIAL MORPHOLOGY OF THE DIGYNODONT GENUS LYSTROSAURUS 165

lcm. BO.

Fig. 4. Lystrosaurus declivis. S.A.M. No. K.1284. Neurocranium in ventral
view, reconstructed from serial sections.

In front of the vestibule the basioccipital comes into broad lateral contact
with the prootic, the suture between the two bones being visible on the anterior
wall of the vestibule and auditory canal (Fig. 9). High up on the wall of the
vestibule the two bones divide over a short distance to form a small pocket
(Fig. 12: P.). It is not known whether this recess housed any specific structure.

Anteriorly, as mentioned above, the basicranial pit lies between basi-
occipital and basisphenoid. This pit lies in the same area of the braincase floor
as the unossified zone described by Olson (1944) and Boonstra (1968) in other
therapsids. In sections (Fig. 2) it can be seen that the pit in Lystrosaurus is con-
tinued ventrally for some distance as a similar unossified zone between the
basioccipital and basisphenoid. Olson (1944) states that the unossified zone is
a rudimentary basicranial fenestra, and therefore a primitive character. Barry
(1967) has found a depression in the floor of the braincase of Pristerodon, which
may be homologous with the unossified zone, and which, Barry states, could
represent a filled-in fenestra basicranialis posterior. These views regarding the
homology of the unossified zone are supported by the fact that in the adult
Cordylus (Van Pletzen, 1946) a fenestra is present in the base of the braincase,
in the position of the fenestra basicranialis posterior of Lacerta (Gaupp, 1898).

The basioccipital is deepest in the region of the auditory canal. Ventrally,
between the two lateral tubera, a transverse intertuberal ridge is formed
(Figs 2, 4, 24). This condition is unusual, as in all other dicynodonts (with the

166 ANNALS OF THE SOUTH AFRICAN MUSEUM

exception of Dicynodon gilli, S.A.M. No. 4008, where the basioccipital is
deepened as in Lystrosaurus) the area between the ventral edge of the basi-
occipital condyle and the foramina of the internal carotid arteries is flat.

Immediately in front of the intertuberal ridge in Lystrosaurus the basi-
occipital meets the parabasisphenoid complex. Posteriorly it forms the median
part of the occipital condyle, and is dorsally overlapped by the exoccipital
condyles.

The auditory capsule is formed by the frootic anteriorly and the opisthotic
posteriorly, while the supraoccipital completes the structure dorsally (Figs 5,
ga, 10a). Both prootic and opisthotic extend laterally to form the paroccipital
process and make contact with the squamosal. The opisthotic (=paroccipital
of some authors) abuts against the quadrate laterally and, on the occipital
surface, forms the medial border of the posttemporal fenestra (Fig. rob).
Dorsally it meets the supraoccipital in a straight suture, and its dorsolateral
corner, above the posttemporal fenestra, is overlapped posteriorly by the
squamosal. The entire anterior face is covered by the prootic. Medially the
opisthotic forms the lateral wall of the jugular canal, separating the canal from
the vestibule, and descends alongside the basioccipital to form the posterolateral
wall of the fenestra ovalis.

The prootic is in the main a flat bone, lying against the anterior surface
of the opisthotic and occipital plate. Laterally it extends to meet the ventral
flange of the squamosal, and forms the anterior half of the paroccipital process

PIL. ANT

PTF

Bos PAS R

BO
Vil EPT. FIP

Fig. 5. Lystrosaurus declivis. S.:A.M. No. K.1284. Neurocranium in lateral
view, reconstructed from serial sections.

CRANIAL MORPHOLOGY OF THE DIGCYNODONT GENUS LYSTROSAURUS 167

and the medial border of the posttemporal fenestra. Medially it forms the
anterior portion of the braincase and terminates anteromedially as the upright
pila antotica. The prootics do not meet in the midline (Figs 2, 55b) and a
dorsum sellae, overlooking a sella turcica, as was found in the pelycosaurs and
therapsids described by Romer & Price (1940) and Olson (1944) respectively,
is not present. Boonstra (1968) finds that the prootics meet in the dinocepha-
lians and therocephalians, but not in the Tapinocephalus zone dicynodonts.

The hypophyseal region in Lystrosaurus will be discussed more fully at a
later stage.

Anteriorly the prootic meets the basisphenoid, and the suture between
these two bones runs down from the base of the pila antotica to the lateral rim
of the fenestra ovalis (Figs 4, 5). Halfway down the prootic-basisphenoid suture
a ledge is formed, covering a distinct recess into which the canal of the facial
nerve opens (Figs 5, 11). The ledge is in the same position as the otic ledge of
lizards (Romer, 1956), and Boonstra (1934a) has described a similar pocket
surrounding the facial foramen in the Gorgonopsia, suggesting that it housed
the geniculate ganglion.

A dorsomedial process of the prootic projects up against the anterior face
of the supraoccipital, and between them the two bones form a shallow notch
in the side-wall of the braincase (Figs ga, 10a: V.N.). A similar, usually deeper
notch has been described in dicynodonts by various authors, and probably
stood in connection with the vascular system of the head (see below).

No true floccular fossa (sub-arcuate fossa of Cox, 1959) is found in Lystro-
saurus, but a shallow depression is present on the inner face of the prootic in
some specimens. Sollas & Sollas (1913) and Olson (1944) described deep
pockets for the flocculus in various dicynodonts, but Boonstra (1968) found

FR

PO ORB PO

Fig. 6. Lystrosaurus declivis. S.A.M. No. K.1284. Frontotransverse
section through frontal region and braincase.

168 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 7. Lystrosaurus declivis. S.A.M. No. K.1284. Frontotrans-
verse section through basicranial axis and skull roof.

only a shallow fossa in the Dinocephalia, while Camp & Welles (1956) state
that the fossa is absent in the Triassic Kannemeyeria, Placerias and Stahlekerva.
This lends support to Olson’s (1944) view that the fossa decreased in depth and
importance during the course of therapsid evolution.

The vestibule, lying between the opisthotic, prootic and basioccipital,
opens into the sacculo-cochlear recess, which in turn communicates widely with
the cranial cavity through the internal auditory meatus. Olson (1944) states

Fig. 8. Lystrosaurus declivis. S.A.M. No. K.1284.
Frontotransverse section through skull base and nasal
region.

GRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 169

that the fenestra rotunda in his sectioned specimens opened into the jugular
foramen, and, although the canal for the jugular vein is posteriorly separated
from the vestibule, this is probably the case in Lystrosaurus too. No division of
the recess into a saccular and cochlear part is apparent in Lystrosaurus, although
a ledge (Figs ga, 10a: L.) at the level of the ampulla of the anterior ascending
semicircular canal might possibly indicate the junction of the sacculus with the
utriculus. The utriculus extends dorsally into the supraoccipital to meet the
crus communis canalium. Three distinct recesses (Fig. 9a: A.AMP.REC.,
P.AMP.REC.) at the internal openings of the semicircular canals indicate the
positions of the ampullae. The anterior two ampullary recesses are contained
within a large, common depression (Figs 9a, 10a: AAAMP.REC.). The anterior
and posterior vertical canals run dorsally through the prootic and opisthotic
respectively, meeting in the supraoccipital to form the crus communis canalium,
which in turn leads into the utriculus.

The supraoccipital provides a roof for the braincase and otic capsules, and
forms the dorsal margin of the foramen magnum and most of the dorsal half
of the occiput. It meets the opisthotic in a straight suture and dorsally to the
foramen magnum is overlaid by the interparietal. Laterally it lies beneath the
tabular and squamosal and anteriorly it is covered by the dorsal part of the

PRO.

liom.

Fig. 9. Lystrosaurus sp. S.:A.M. No. 11180.

(a) Inner view of left otic capsule.

(6) Detail of left anterior ampullary
recess.

170 ANNALS OF THE SOUTH AFRICAN MUSEUM

(a)

PA. FAC.EO

PTF

OP

(b)

LAT. H.V. CH

BO

Fig. 10. Lystrosaurus sp. S.A.M. No. 11180. (a) Inner
view of right otic capsule and basioccipital and
(6) braincase in occipital view.

prootic. Above the notch formed between it and the prootic, the supraoccipital
provides a partial side-wall to the braincase behind the pineal foramen, this
side-wall being covered laterally by the ventrally descending wing of the
parietal. The supraoccipital terminates dorsally as an abruptly truncated dorsal
process, similar to that of the pelycosaurs (Romer & Price, 1940). The
unfinished surface of the anterior edge of this process suggests that the supra-
occipital was continued forward as cartilage beneath the inner parietal surface.

The dorsal edge of the supraoccipital forms the base of two tunnels running
out laterally onto the occiput, from each side of the interior of the braincase
(Fig. 13). Each tunnel lies under the parietal anteriorly, and under the inter-
parietal, tabular and squamosal posteriorly and laterally, and opens out onto
the posterior occipital face laterally to the tabular of its side. Watson (1960)
and Cox (1959) have described similar channels in Diictodon and Kingoria
respectively, ascribing a nutrient function to them.

This canal and a system of grooves on the prootic and supraoccipital

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 171

SOc.

PRO.

Fig. 11. Lystrosaurus sp. S.A.M. No. 11180. Braincase in
anterior view.

(Fig. 11) indicate the probable course of veins which drained the deep struc-
tures of the head. The exact nature and extent of these blood-vessels is neces-
sarily vague, but the following inferences can be made.

The ventral surface of the paroccipital process is characteristically exca-
vated between the fenestra ovalis and the distal end of the process. The dorsal
surface of the stapes is similarly excavated and a clear-cut tunnel (Figs 14,
15: LAT.H.V.CH.) is thus formed, continuing forwards as a groove running
anterodorsally over the ventral and anterior face of the prootic, in the direction
of the facial foramen. The tunnel and groove are in the position of the lateral
head vein of living reptiles (Goodrich, 1930; Dendy, 1909).

The posttemporal fenestra is excavated in such a way as to form a channel
running anteromedially from the occiput onto the face of the prootic. In one

PAR FOR

JUG. FOR

Fig. 12. Lystrosaurus murrayi. Nat. Mus. No. C.6457. Dissected
braincase in dorsolateral view.

172 ANNALS OF THE SOUTH AFRICAN MUSEUM

specimen a deep groove in the occiput leading into the fenestra provides strong
evidence for a vein passing through the fenestra. A shallow groove runs dorsally
up the face of the prootic from the lateral head vein channel to meet the groove
from the posttemporal fenestra. This groove is then continued dorsally along
the line of contact between the prootic and supraoccipital to the notch between
the two bones in the side-wall of the braincase (Fig. 10a: V.N.). This dorsal
part of the system of grooves is distinct and deeply excavated in some specimens.
Olson (1944) does not believe that the dorsal notch in the braincase, which is
well developed in some therapsids, stood in connection with the venous system,
stating that the notch was formed between supports for the orbitosphenoid
complex. The condition in Lystrosaurus is, however, clearly due to the presence
during life of a blood-vessel. A similar explanation was proposed by Agnew
(1959) in Dicynodon grimbeeki, while Boonstra (19344, 19346) figures a venous
fossa between the supraoccipital and prootic in the Gorgonopsia and Thero-
cephalia, and states that this is a feature of all therapsids.

Using very similar grooves in the skull of the dicynodont Kingoria, Cox
(1959) reconstructed a system of veins which is comparable with that proposed

Fig. 13. Lystrosaurus declivis. S.A.M. No. K.1284. Consecutive sections,
from posterior (a) to anterior (e) of the dorsal braincase and occiput
showing the relationships of the occipital nutrient channels.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 173

by Watson (1911, 1913) for Diademodon. The posttemporal fenestra probably
served as a passage for the v. capitis dorsalis, which in modern reptiles such as
Sphenodon (Dendy, 1909; O’Donoghue, 1920) drains the occipital musculature
and passes forward to enter the braincase in front of the auditory capsule. In
Lystrosaurus the groove leading to the venous notch in the prootic therefore
marks the passage of this blood-vessel into the cranial cavity, as is also thought
to be the case in the Pelycosauria (Romer & Price, 1940).

A different function for the posttemporal fenestra has been proposed by
Ewer (1961) and Barry (1967), namely, that a slip of the adductor musculature
passed through the fenestra and was attached to an adjacent area of the occipital
face. However, available evidence, especially in recent reptiles, weighs against
this theory.

Within the cranial cavity the v. capitis dorsalis probably met the v. cephalica
posterior of its side. This latter vein is the lateral branch of the median longi-
tudinal sinus (Dendy, 1909; Swain, 1968). The v. cephalica posterior would
then have continued down to emerge from the skull through the jugular fora-
men together with cranial nerves IX, X and XI. The size of this foramen
suggests that Lystrosaurus, in common with other dicynodonts, possessed a
fairly large jugular vein.

The v. capitis lateralis passed back above the basipterygoid process,
between the epipterygoid laterally and the pila antotica medially, and through
the pterygo-paroccipital foramen to leave the skull through the channel
between the stapes and the paroccipital process, along with the hyomandibular
branch of the facial nerve. The shallow groove on the prootic below the post-

JUG. FOR

Fig. 14. Lystrosaurus declivis. Nat. Mus. No. C.403,
Ventral occipital region in posterolateral view.
showing stapes and lateral head vein channel.

174 ANNALS OF THE SOUTH AFRICAN MUSEUM

Vil REC.

EPT FIP

lcm

Fig. 15. Lystrosaurus declivis. Nat. Mus. No. C.403.
Anterolateral view of braincase, showing stapes
and lateral head vein channel.

temporal fenestra probably indicates a connecting sinus between the v. capitis
dorsalis and the v. capitis lateralis, providing an alternative route for venous
blood from the occiput.

In Lystrosaurus the gutter in each dorsolateral quarter of the occiput,
between the supraoccipital and tabular and leading into the back of the
cranial cavity, probably stood in connection with drainage of the occipital
musculature, as did the v. capitis dorsalis. A vein leading into the gutter from
each side of the occiput would emerge from between the supraoccipital and
parietal into the cranial cavity and join the v. cephalica posterior of its side.
There are thus altogether four forward groups for blood draining from the
occiput. Most of this blood was carried by the jugular vein, but a portion would
have reached the v. capitis lateralis via the connecting sinus and would have
left the skull dorsally to the stapes.

In Lystrosaurus the anterior part of the braincase floor, between the two
pilae antoticae, is formed by the basisphenoid, which is ventrally indistinguishably
fused to the parasphenoid. The prootica do not meet in the midline and no true
sella turcica, as is found in Dicynodon, is present in Lystrosaurus, where the entire
hypophyseal region has been affected by shortening of the skull base. The
possible relations of the hypophysis and dorsum sellae will be discussed in a
later section.

In ventral view (Figs 4, 24) the basioccipital-parabasisphenoid suture is
characteristically distinct on the anterior slope of the intertuberal ridge. The
paired carotid canals enter the basisphenoid ventrally, immediately behind the

GRANIAL MORPHOLOGY OF THE DIGYNODONT GENUS LYSTROSAURUS 175

interpterygoidal plate, and dorsally emerge together in the small fossa posterior
to the vertical presphenoidal plate.

Common to all species of Lystrosaurus is a shortening of the skull base
anterior to the basioccipital. Thus the presphenoid ossification, usually far
forward in dicynodonts, lies immediately in front of the internal opening of
the internal carotid arteries in Lystrosaurus, obscuring some of the relations
between parasphenoid and basisphenoid (Figs 2, 12). However, it is clear that
a well developed basipterygoid process makes contact with the footplate of the
epipterygoid laterally (Figs 3, 4: BPT.PROC.), and that a broad parabasi-
sphenoid sheet extends forward to just behind the interpterygoidal vacuity.
This sheet is in close contact with the interpterygoidal plate below. The lateral
wing-like portions of the sheet are homologous with the parasphenoidal wings
described and figured by Barry (1967) in Pristerodon and by Olson (1944).
The palatine branch of the facial nerve is contained between the parabasi-
sphenoid sheet and the interpterygoidal plate (Figs 22a, 24). This canal has
been found in therapsids by Boonstra (1934a), Parrington & Westoll (1940),
Olson (1944), Gamp & Welles (1956) and Cox (1959). The nerve entered the
ventral surface of the skull laterally to, and in advance of, the internal carotid
foramina, and, passing between parasphenoid and pterygoid, emerged anterior
to the interpterygoidal fossa and footplate of the epipterygoid.

Dorsally the parabasisphenoidal plate supports a median, septal ossifica-
tion, the presphenoid. This latter bone is ventrally and laterally supported by
the cultriform process of the parasphenoid, which extends up dorsally from the
interpterygoidal vacuity and terminates anteriorly as a process clasped between
the posterior, diverging wings of the vomer (Figs 2, 28). In acid-prepared and
sectioned specimens it can be seen that the presphenoid is covered laterally
for some way by the parasphenoid. In typical dicynodonts (such as the speci-
men illustrated in Figure 34a) the parasphenoid, while also supporting the
presphenoid, is only slightly grooved along the dorsal surface. The high, thin
dorsally extended wings on either side of the presphenoid in Lystrosaurus repre-
sent a different condition altogether, and is the result of the skull-deepening
process undergone by the genus.

The sphenethmoid complex

There is considerable uncertainty regarding the homology of the various
elements of the sphenethmoid complex, and the terminology used by different
morphologists has confused the issue to an even greater extent. For this reason
the structure of the complex in Lystrosaurus will be dealt with before entering
into a discussion on the most suitable terminology.

In Lystrosaurus there are three median ossifications of the braincase anterior |
to the basisphenoid (Figs 2, 28). The most posterior of these is the postero-
ventrally situated presphenoid (mentioned previously), which is a vertical
plate clasped ventrally and laterally by the cultriform process of the para-
sphenoid (Figs 12, 17), and which meets the basisphenoid posteriorly. Its

I 76 ANNALS OF THE SOUTH AFRICAN MUSEUM

MES.

ORB. ! cm.

Fig. 16. Lystrosaurus murrayi. Nat. Mus.
No. C.6457. Sphenethmoid complex in
right lateral view.

surface displays a coarser histological texture than the surrounding and clearly
distinguishable parasphenoid. Its posterior edge, above and in front of the
hypophyseal region, is excavated to form a trough, while its dorsal edge is
grooved in a manner suggesting that the ossification was continued dorsally
as cartilage. Anteriorly the wings of the parasphenoid project dorsally past
this groove (Fig. 17).

The anterodorsal structure situated beneath the frontals (Figs 2, 28:
MES., ORB.), is more complicated and consists of two separate ossifications.
The posterior ossification is a median keel which bears two lateral wings
extending upwards to make contact with the longitudinal ridges on the inner
surface of the frontals. (Figs 16, 28: ORB.). The median keel is of irregular
thickness and is fenestrated. The trough formed by the lateral wings in all
probability corresponds to the embryonic planum supraseptale (Romer &
Price, 1940) and housed part of the olfactory lobes of the brain. On the. posterior
edge of each wing is a notch, representing the anterior border of the optic
foramen (Figs 16, 28: II). The remainder of the posterior margin is excavated
to form a groove, suggesting that the ossification was continued posteriorly in

PAS

Fig. 17. Lystrosaurus murrayi. Nat. Mus. No.
C.6457. Presphenoid in right lateral view.

GRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 177

cartilage. In this way a complete optic foramen was probably formed. The
ventral edge of the bone, similarly excavated, was probably connected by a
sheet of cartilage to the anterodorsal edge of the presphenoid, to form a possibly
complete interorbital septum. Cox (1959) has suggested a comparable condition
in Aingoria.

Anteriorly the trough-shaped ossification makes close contact with a third
structure, a median sheet of bone (Figs 2, 16: MES.) extending up to the inner
surface of the frontals. This septum is of constant thickness over the greater
part of its extent, but dorsally it is laterally expanded beneath the surface of
the frontals, forming a roof for, and a partition between, the olfactory nerve
bundles.

The two anterodorsal ossifications, lying up against the skull roof, can be
clearly distinguished from each other in acid-prepared and sectioned speci-
mens. Basically the complex resembles that of other dicynodonts, but there is
wide disagreement in the terminology used by different authors. Seeley (1898)
called the entire anterodorsal structure, beneath the frontals, the orbito-
sphenoid, Broom (1904) called it the ethmoid and Sollas & Sollas (1913) used
the terms ethmoid or mesethmoid. The latter supposed the bone to be the fore-
runner of the mammalian cribriform plate and pointed out that its relations
with the olfactory nerve and the rest of the basicranial axis make it very similar
to the mammalian mesethmoid. They regard a ventral ossification, anterior to
the fossa hypophyseos of their sectioned Dicynodon and in the same position as
the posteroventral ossification in Lystrosaurus, as an anterior extension of the
basisphenoid. Broom (1926, 1927) agreed with Sollas & Sollas (1913) on this
latter point, and regarded the entire anterodorsal structure as being homo-
logous with the mammalian presphenoid. He concluded that there were three
elements in the basicranial axis of all therapsids, Dicynodon being representative
of the group. These elements were basioccipital, basisphenoid and presphenoid.
In 1927 he pointed out that certain mammal groups had only three elements
in the basicranial axis, and other groups four. The first groups he collectively
called Palaeotherida, which he supposed had inherited the therapsid condition
directly. The second group, the Neotherida, he regarded as having secondarily
obtained a new element, the mesethmoid, anteriorly in the basicranial axis.

However, Olson (1944), studying sectioned specimens of all four therapsid
infraorders, concluded that there were four elements in the basicranial axis,
these being basioccipital, basisphenoid, a presphenoid lying in the central
stem anterior to the fossa hypophyseos, and an anterodorsal element beneath
the frontals which he tentatively identified as a mesethmoid. The dorsolateral
wings, which enclose the forebrain, he called the orbitosphenoid, showing that
this was not part of the basicranial axis. He also showed that the presphenoid
in dicynodonts may lie relatively far back and make contact with the basi-
sphenoid. In cases where the presphenoid made contact with the mesethmoid
in gorgonopsians and therocephalians there was no fusion between the ele-
ments. He concludes that the presphenoid ossified from the fused trabeculae,

178 ANNALS OF THE SOUTH AFRICAN MUSEUM

the mesethmoid from the internasal septum of the trabeculae, and the orbito-
sphenoid from the preoptic pillar and planum supraseptale. The primitive
mammalian condition, Olson states, is one where all four elements are present,
while some groups of mammals secondarily lost the mesethmoid early in their
evolution.

In his work on the cranial development of certain primitive mammals
Roux (1947) followed Broom’s (1926, 1927) interpretation of the therapsid
basicranial axis. He concluded that in those Chrysochloridae which he investi-
gated three basicranial elements were present, i.e. basioccipital, basisphenoid
(which extended far forward), and, as Broom (1927) showed, a median element
which arose far forward in the skull. This latter element, which lay in the
position of the mammalian mesethmoid and in the same position as in Broom’s
(1926) Dicynodon, Roux called the presphenoid. Roux points out that the
Palaeotherida are not a natural group and that two or three elements assist
in the formation of the anterior ossification. Furthermore, the new median
element in the Neotherida does not arise anterior to the presphenoid as would
be expected, but in fact between the presphenoid and basisphenoid. The latter
bone is now restricted to the lamina hypophyseos posteriorly. Roux, having
found that the new element arises from paired centres in the orbitosphenoid,
concludes that there are only three unpaired median ossifications in the basi-
cranial axis of all vertebrates.

Camp & Welles (1956) follow the terminology of Camp (1942) in their
description of certain Triassic dicynodonts. They call the dorsal trough-shaped
ossification, in contact with the ventral frontal surface, the frontosphenoid,
while they term the ventral median keel the septosphenoid. The postero-
ventral element, in contact with the basisphenoid, they call presphenoid. They
state that the septosphenoid may be equivalent to the mammalian mesethmoid,
but Camp (1956) rejects this on the grounds that it lies below the cerebrum
and forms an interorbital septum. He disagrees with the term orbitosphenoid
on the grounds that this bone must ossify from the metoptic root and should
therefore enclose an optic foramen. This is not the case in any dicynodont.

Agnew (1959) reviews the question of the sphenethmoid homology, and
points out that Camp’s (1956) argument is not necessarily valid since the
orbitosphenoid ossification in the amphisbaenid Monopeltis (Malan, 1946)
invades the planum supraseptale, the dorsal part of the interorbital septum
and the posterodorsal part of the nasal septum. Agnew agrees with the inter-
pretation of the basicranial axis as set out by Roux (1947) and calls the entire
median portion of the sphenethmoid complex in Dicynodon grimbeeki the pre-
sphenoid, with a possible rudimentary mesethmoid between the anterior
portions of the lateral orbitosphenoid wings. However, the posterior portion of
Agnew’s presphenoid is in the same position as the anterior basisphenoidal
extension of Broom (1926) and Roux (1947).

Cox (1959) calls the entire anterodorsal complex in Kingoria a spheneth-
moid, and states that it is not divided into orbitosphenoid and mesethmoid

CRANIAL MORPHOLOGY OF THE DIGYNODONT GENUS LYSTROSAURUS 179

ossifications. He maintains that a structure in Azngoria, similar to the pre-
sphenoid of Olson’s (1944) sectioned specimens, is merely an anterior ossification
of the basisphenoid, lying in the cultriform process of the parasphenoid. Ewer
(1961) agrees with this view, but Barry (1967) finds a division in the antero-
dorsal structure in Pristerodon, and calls the posterior portion, including the
lateral wings, the orbitosphenoid. For the anterior, clearly independent ossi-
fication, he uses the term septosphenoid of Camp (1942). He states that the
wings of the orbitosphenoid should be regarded as the ossified planum
supraseptale.

For an interpretation of the elements in Lystrosaurus it must be decided
whether the posteroventral element is indeed independent of the basisphenoid.
In Lystrosaurus this element fuses with the basisphenoid in the region of the
internal carotid canal as a result of shortening of the skull-base in this region.
Camp & Welles (1956) find the same phenomenon in Placerias, but state
categorically that macerated specimens show that the posteroventral element
is independent of the basisphenoid. In his sectioned therapsid specimens
Olson (1944) found that the posteroventral ossification may be completely free
of the basisphenoid or only partly fused to it. Agnew (1959) found the element
to be independent in his sectioned Dicynodon. Against this evidence the inter-
pretations of Sollas & Sollas (1914), Broom (1926) and Cox (1959) must fall
away. The instances they cite could, it seems, be due to apparent fusion between
the posterior element and the basisphenoid.

The second point is the nature of the anterodorsal structure, below the
frontals. Sollas & Sollas (1914), Cox (1959) and Ewer (1961) regard it as a
single ossification. However Olson (1944) found in his sectioned specimens that
it consists of a posterior orbitosphenoid and an anterior, sometimes ventral,
mesethmoid. Camp & Welles (1956), Agnew (1959) and Barry (1967) all
divide it into two elements, but use different terminologies. Moreover, in the
present investigation it was found that in both acid-prepared and sectioned
specimens of Lystrosaurus a clear-cut line of fusion divides the complex into an
anterior plate-like septum and a posterior trough-shaped portion.

There are thus three median elements in the Lystrosaurus basicranial axis
anterior to the hypophyseal region: the posteroventral one, immediately in
advance of the basisphenoid, the anterodorsal one enclosing the forebrain
and extending ventrally as a short, fenestrated interorbital septum, and,
anterior to this, the anterodorsal plate-like septum extending up to the inner
frontal surface and dividing the olfactory tracts.

For the posteroventral element the term presphenoid seems the most accept-
able, as it ossifies from the fused trabeculae and from the interorbital septum
arising from the trabeculae. Furthermore, it is in the position of the rudimentary
interorbital septum found in the developing Ornithorhynchus (De Beer, 1937).
This conclusion is supported by the definition of Bellairs (1949: 492), viz.
*, . . the term presphenoid may be restricted to the trabecular ossifications in
contact with the basisphenoid behind’, and by Haines (1950) who regards the

180 ANNALS OF THE SOUTH AFRICAN MUSEUM

term presphenoid as denoting the bone usually ossified from presphenoid and
orbitosphenoid centres.

The trough-shaped, anterodorsal element, lying beneath the frontals,
seems equivalent to the planum supraseptale of reptiles (Barry, 1967) and the
broad preoptic root and adjacent orbital cartilages of mammals (De Beer,
1937). There can be little doubt that the optic nerve emerged through the
notch in the posterior border of the bone (Sollas & Sollas, 1914; Olson, 1944).
This being so, the ossification is anterior to the optic foramen and must there-
for include the preoptic root. Camp & Welles (1956) object to the term orbito-
sphenoid for this bone on the grounds that the orbitosphenoid ossifies from the
metoptic root. However, Boonstra (1934a) has described and figured a sphen-
ethmoid with a complete posterior foramen in the gorgonopsian Arctognathus,
this foramen being in the position of the notch in Lystrosaurus and other dicyno-
donts. Moreover, Malan (1946) has shown that the orbitosphenoid in Monopeltis
invades the planum supraseptale and the dorsal part of the interorbital septum.
The term orbitosphenoid would therefore seem to be suitable for the ossification
in Lystrosaurus. It is important to note that this bone in Lystrosaurus descends
ventrally as a septum. This must be regarded as a secondary invasion by the
preoptic roots into the basicranial axis, such as was observed by Roux (1947)
in the orbitosphenoid of developing embryos of primitive mammals. In croco-
diles and lizards (Bellairs, 1949) the orbital cartilages, from which the orbito-
sphenoid ossifies, also meet in the midline. It is interesting to note that no
metoptic root is developed in the marsupials, and no true foramen opticum is
formed (De Beer, 1937).

The anterior, septal portion of the anterodorsal structure is more difficult
to identify. Olson in his (1944) investigation into the therapsid infraorders
tentatively calls it mesethmoid, but Camp (1956) rejects this possibility in the
dicynodonts because the bone does not form part of the nasal septum, does not
carry the olfactory lobes in its posterior extension and lies between the cerebral
hemispheres and forms the interorbital septum. In Lystrosaurus, however, these
are not the relations of the anterior element, which lies entirely anterior to the
cerebrum, forms no part of the interorbital septum and appears to have been
intimately associated with the olfactory nerve bundles. Its nearest counterpart
appears to be the mesethmoid of mammals and it deserves to be referred to as
such. Agnew (1959) finds a small median ossification in Dicynodon grimbeeki
which he calls the mesethmoid.

If the above argument is valid, Roux’s (1947) statement that there are
never more than three centres of ossification in the basicranial axis of all verte-
brates is unacceptable, since he bases his assumption on Broom’s (1926, 1927)
interpretation of Dicynodon. Roux did find that the new median basicranial
element in those primitive mammals which he investigated is not a true
median ossification but a fusion in the midline of centres arising in the orbito-
sphenoid. However, the findings of De Beer & Woodger (1930) regarding the
strictly median, trabecular origin of the interorbital septum of the rabbit

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 181

suggests that some mammals have in fact retained a posterior part of the
reptilian median septum, equivalent to the therapsid presphenoid. Haines
(1950) has described the ossified interorbital septum in a variety of mammals,
showing that this bone is in contact with the mammalian presphenoid, which
he defines (p. 585) as ‘. . . the bone in the adult skull, separate in most mammals,
which is usually ossified from presphenoid and orbitosphenoid centres. It
corresponds to the “‘presphenoid part” of the sphenoid bone of man.’

The basicranial axis of Lystrosaurus therefore comprises four separate
elements, viz. the basioccipital, basisphenoid, presphenoid, and mesethmoid
as primary median ossifications. The preoptic roots of the orbitosphenoid have
secondarily invaded the basicranial axis.

In some mammal groups, such as the insectivores described by Roux (1947)
it seems that both presphenoid and interorbital septum are absent, and that
only the orbitosphenoids may secondarily invade this region.

THE VISCERAL ARCH SKELETON

Palatoquadrate

The epipterygoid (Figs 2, 22a, 28) is a long, narrow rod lying between the
quadrate ramus of the pterygoid and the descending lateral wing of the parietal.
Dorsally the slightly broadened upper tip makes contact with the inside of the
descending lateral parietal flange in an interdigitating suture. Ventrally the
shaft curves down and back to merge with the footplate. The footplate lies on
the lateral edge of the quadrate ramus of the pterygoid, is flattened anteriorly
to its junction with the dorsal shaft, and makes medial contact with the para-
basisphenoid complex (Figs 3, 4). Its anterior extent varies within the genus.
In the larger forms it extends well forward as a pterygoid process (Fig. 5) while
in the smaller forms it is generally limited. Anteosaurus (Boonstra, 1968) and
Kannemeyeria (Barry, 1965) have long anterior processes. Ewer (1961) dis-
cussed a strip of bone lying anterior to the footplate of the epipterygoid in
Daptocephalus, and in view of the condition in Lystrosaurus, appears to be correct
in her interpretation of its being an anterior prolongation of the epipterygoid.

Posteriorly the footplate is sharply truncated and the posterior edge,
excavated in the form of a groove, faces backwards along the quadrate ramus
of the pterygoid towards the quadrate (Fig. 18). The footplate does not reach
as far back as in Dicynodon grimbeeki (Agnew, 1959) or Pristerodon (Barry, 1967).

The quadrate (Fig. 19) is clasped between the paroccipital process medi-
ally and the quadratojugal laterally. It consists of a broad, anteriorly convex,
medial plate, which curves down ventrally to form the medial condyle, and a
wide sheet extending laterally from the plate to provide a base for the quadrato-
jugal and to form the lateral condyle.

The lateral condylar surface is only slightly coanded and lies mainly in the
horizontal plane. The ventral surface of the inner condyle is more rounded
and is separated from the outer condyle by a vertical articular surface. A deep

182 ANNALS OF THE SOUTH AFRICAN MUSEUM

PTGR
Q.

fom

Fig. 18. Lystrosaurus murrayi. Nat. Mus. No.
C.6457. Left quadrate region in lateral view.

notch is thus formed between the two condyles, into which the articular fits.
The anteroposteriorly directed quadrate foramen (Figs 18, 22a), which possibly
transmitted a nerve to the lower jaw, as Romer (1956) suggested for Sey-
mouria, lies between the quadrate and quadratojugal. The inner surface of the
quadrate bears a smooth facet for the reception of the posterior end of the
quadrate ramus of the pterygoid (Figs 1ga, 19b). Dorsally to the pterygoid
facet the groove widens into a notch, facing forwards along the quadrate
ramus (Figs 8, 1ga, 19b), while the anterior surface of the inner arc-like edge
of the quadrate bears a groove, unfinished in periosteum, above its inner
condylar portion. These two features of the quadrate strongly suggest the
existence during life of a connecting strip of cartilage between the quadrate
and the sharply truncated footplate of the epipterygoid, to form a single
palatoquadrate complex. Support for this view is provided by a recessed facet
on the lateral side of the quadrate ramus of the pterygoid (Figs 15, 18), between

PQ.C.NO

LAT.CON

Q.R. FAC.

MED.CON.
(a) (b)

Fig. 19. Lystrosaurus sp. S.A.M. No. K.1495. Right quadrate
in (a) anterior and (4) medial view.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 183

the footplate and quadrate, presumably indicating that the palatoquadrate
cartilage was closely apposed to the pterygoid. The well-defined hollow,
unfinished in periosteum and lying above the facet for the quadrate ramus on
the medial surface of the quadrate, probably received a medial projection of
this cartilage.

White (1939) has found evidence for a palatoquadrate cartilage in Sey-
mouria, while Barry (1965, 1967) showed that a similar cartilaginous con-
nection between quadrate and epipterygoid existed in Pristerodon, where the
quadrate is notched in a fashion very similar to Lystrosaurus. In both Pristerodon
and Dicynodon grimbeeki the footplate of the epipterygoid extends far back,
almost reaching the quadrate.

Stapes and hyoid apparatus

The stapes (Figs 14, 15, 20) is short and squat. It is deeply excavated
dorsally, and a large, clear-cut channel is closed off between it and the parocci-
pital process. The stapedial footplate has a short dorsal process extending up
the fenestra ovalis. Ventrally the medial half of the stapes is cut away into a
distinct facet, which appears to be unique among dicynodonts. Barry (1968)
suggests that the facet provided attachment for a portion of the hypobranchial
skeleton.

Laterally the stapes is dorsoventrally flattened and bears two articular
facets. The ventral facet makes contact with the ventromedial surface of the
quadrate, and the dorsal facet meets the ventrolateral extremity of the parocci-
pital process. This latter stapes—opisthotic contact has previously been found

(b)

MED. FAC

(c) (d)

Fig. 20. Lystrosaurus declivis. Nat. Mus. No. C.403. Lett stapes
in (a) dorsal (b) posteroventral (c) ventral and (d) lateral
views.

184 ANNALS OF THE SOUTH AFRICAN MUSEUM

by Boonstra (1965) in the dinocephalian Struthiocephalus and by Cox (1959)
in Kingoria. A well-defined anteroposteriorly directed groove separates the two
facets and possibly transmitted a blood-vessel or nerve. There are no indica-
tions of an extrastapedial process such as found by Ewer (1961) in Dapto-
cephalus or of a sharp ‘tympanic’ opisthotic process such as is found in Kingoria
(Cox, 1959), and it seems unlikely that a tympanum was present in life.

In several specimens of Lystrosaurus a pair of short, curved rods (Fig. 21)
was found, usually in the pterygoid region of the skull. Barry (1968) considers
that they are ossified ceratohyals. They are often found in association with the
stapes, and a strong possibility exists that in life they articulated with the
median, ventral facets of the stapes (Barry, 1968). Other records of preserved
portions of the hypobranchial skeleton in dicynodonts are a basihyal in Pris-
terodon (Barry, 1967) and a pair of rods in Aingoria and Daptocephalus (Cox,
1959; Ewer, 1961).

Fig. 21. Lystrosaurus declivis. Nat. Mus.
No. C.403. Stapes and ceratohyals in
articulation, ventral view.

THE DERMOCRANIUM

The snout region

The snout and adjacent skull roof are the most variable portions of the
Lystrosaurus skull, but several characteristics of the region are common to all
variants and can thus be used for diagnosis of the genus. The snout is always
strongly developed and ventrally extended, but the nasal apertures have not
accompanied this ventral growth and remain relatively high in the skull. In
some forms the snout curves down smoothly from the frontal surface, while in
others the anterior surface of the snout is a remarkable flat plane, separated
from the frontal plane by a transverse frontonasal ridge.

The premaxilla has an extensive facial portion, more extensive than in any
Dicynodon, and forms a large part of the snout (Figs 22a, 27). The variation in
degree of development of the snout is caused directly by increase or decrease
in the extent of the premaxilla and maxilla. Besides this quantitative variation,
there are also marked differences in the shape and form of the premaxilla
within the genus. Thus in species with moderately developed, smoothly down-
turned snouts, and with no transverse nasal ridge, the outer surface of the pre-

CRANIAL MORPHOLOGY OF THE DIGYNODONT GENUS LYSTROSAURUS

FR

Vil PAL

LAB. FOS
cm : MAX

(a)

Fig. 22. Lystrosaurus declivis. Nat. Mus. No.
C.403. (a) Skull in lateral view. (b) Right
external nasal aperture.

186 ANNALS OF THE SOUTH AFRICAN MUSEUM

_ 2

Fig. 23. Lystrosaurus declivis. Nat. Mus. No. C.403. Skull in dorsal view.

maxilla is smooth and gently rounded from side to side to merge into the
lateral maxillary surface of the snout (Figs 27, 36). On the other hand, those
forms with more strongly developed snouts and with frontonasal ridges, have
a characteristic longitudinal ridge running medially down the anterior surface
of the premaxilla (Fig. 26). This ridge may be knife-edged in some specimens
and is of variable extent. It may occur high up on the nasal process of the
premaxilla only, or it may run the entire length of the bone. Furthermore, the
anterior surface of the premaxilla in these forms is, with the exception of the
longitudinal ridge, perfectly flat and straight. This plane, unique among
dicynodonts, meets the lateral surface of the snout at a sharp angle. The snout
as a whole may be relatively narrow in these species, with a correspondingly
narrower and more compact palatal region of the premaxilla.

The nasal process of the premaxilla extends dorsally between the nasals
and almost up to the frontonasal ridge, where present. It forms the anterior
border of the nasal aperture, and meets the septomaxilla in the floor of the
aperture. Ventrally to this it meets the maxilla in a straight suture which runs
down to the rim of the palate.

The ventral rim of the palate is sharp and extended relatively far ven-
trally, and reflects the nature and extent of the unpreserved horny beak. The
deeply recessed, dome-shaped palatal portion of the premaxilla bears three
prominent longitudinal ridges (Figs. 24, 25). The median ridge is the largest
and extends from the anterior portion of the choana, where it meets the vomer

CRANIAL MORPHOLOGY OF THE DIGYNODONT GENUS LYSTROSAURUS 187

JAC. DUCT NO

FEN.OV aa

Fig. 24. Lystrosaurus declivis. Nat. Mus. No. C.403. Skull in ventral view.

in a complex suture, to a point just behind the descending palatal rim. Pos-
teriorly the ridge is high and sharp, but flattens out anteriorly. On each side
of the ridge is a narrow, deeply incised channel, opening out on to the palatal
surface at the tip of the ridge.

The lateral palatal ridges lie on the anterior descending rim of the palate,
each arising laterally to the anterior tip of the median ridge and terminating
as a ventral projection beyond the level of the rest of the premaxillary rim.
Each ridge is cut down the middle by a single channel, similar to those along-
side the median ridge. It seems probable that these grooves housed nutrient
blood-vessels running between the bony ridges and a layer of horn. The pre-
sence of horn on the ridges is further suggested by the porous, roughened
surface of the bone. The extent of the horny beak on the palate will be more
fully discussed in a later section.

Posteriorly the premaxilla divides the nasal passages as a median septum,
and terminates as a sharp blade enclosed by the diverging anterior wings of
the vomer (Figs 2, 28, 35). Wan Hoepen (1913) mentioned this suture in
Lystrosaurus latirostris, and Barry (1967) found a similar interdigitating con-
tact in Pristerodon. The increase in size of the premaxilla in Lystrosaurus as
compared with other dicynodonts, is reflected in the great dorsoventral extent
of this posterior sheet. The ventral half of the premaxilla-vomer suture is more
complicated, there being a median septum of the vomer extending between
two diverging internal premaxillary processes. Furthermore, a lateral fold of

188 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 25. Lystrosaurus curvatus. Nat. Mus. No. C.299. Premaxillary
portion of palate in ventral view.

the premaxilla overlaps the anteroventral corner of the diverging vomerine
wing. In this way a very firm, interlocking suture is formed between the
premaxilla and vomer (Figs 28, 35).

The relative extent of the maxilla varies with the size of the premaxilla. It
meets the latter bone anteriorly, the septomaxilla and lacrimal dorsally, and
overlaps the jugal posterodorsally. Ventrally it is extended as a strong canini-
form process which carries the single canine tusk, while a posterior process
extends as part of the zygomatic arch to below the middle of the orbit. The
line of the zygomatic arch is prolonged downwards to the caniniform process
as a pronounced lateral thickening of the snout, the tusk and surrounding
portions of the palate being thus powerfully buttressed by the entire zygoma.
The lateral thickening of the snout has a rough, pitted surface, suggesting a
covering of horn extending up from above the tusk. The posterior part of the
sharp palatal rim is formed by the ventral edge of the maxilla in front of the
tusk (Figs 24, 26). This, the sharpest part of the palatal rim, slopes down and
back to lie flush against the inner surface of the tusk, and is always well deve-
loped, regardless of tusk size.

In the palate the maxilla separates the premaxilla from the palatine and
forms the lateral border of an anterior notch in the choana. Laterally to this
it covers the palatine and the anterior palatal process of the pterygoid by its
posterior pterygoid process, the anterior part of which forms the ventral
border of the labial fossa (Figs 24, 31).

In the region of the maxillo-palatine contact in the palate, at the base of
the caniniform process, the surface of the maxilla is pitted and scored by
grooves similar to those found on the premaxillary palatal surface. This appears
to be a continuation of a similar pitted surface on the anterior expanded end
of the palatine, and indications are that the palatine and adjoining maxilla

CRANIAL MORPHOLOGY OF THE DIGYNODONT GENUS LYSTROSAURUS 189

FR.TUB

NAS SMX. CAN.

JUG. LAC.

SMX.FOR

Fig. 26. Lystrosaurus declivis. Nat. Mus. No. C.403. Skull in anterior view.

were covered by a layer of horn. That the dicynodont palatine was provided
with such a covering has long been recognized (Watson, 1948). It is interesting
to note that the area of the maxilla next to the palatine in Lystrosaurus is in the
same relative position as the postcanine tooth-bearing region in endothiodonts,
so that in Lystrosaurus the functions of a row of teeth have apparently been
taken over by a horny pad. Watson (1960) has found nutrient foramina and a
boss around the canine tusk in several dicynodonts, and Cox (1959) has
described similar roughened areas on the maxilla of Kingoria.

The relative tusk size in Lystrosaurus varies considerably. Generally it
can be said that those species with frontonasal ridges and more strongly deve-
loped snouts possess relatively larger tusks than those species with smoothly
rounded, weaker snouts. Wear facets are found in most cases, and are especially
marked in forms with large tusks. These facets are confined to the inner surface
of the tusk and are clearly the result of wear against the mandibular beak.
Absence of other facets and wear marks makes it unlikely that the tusks were
used for regular digging or scratching purposes. This conclusion is in agree-
ment with Sollas & Sollas (1914) and Watson (1960). The possibility does
nevertheless exist that the tusks, especially of larger individuals, were used as
offensive or defensive weapons. No traces of replacement teeth were found,
and the presence of concentric growth rings, visible in sections, suggest con-

190 ANNALS OF THE SOUTH AFRICAN MUSEUM

tinued tusk growth throughout life, such as described by Camp & Welles
(1956) in Placerias.

The nasal forms the dorsal border of the nasal aperture, meets the septo-
maxilla, lacrimal and prefrontal laterally, and makes contact with the frontal
dorsally. In forms with smoothly rounded snouts the nasals diverge posteriorly,
whereas in species with transverse frontonasal ridges this is not the case, and
the suture between nasals and frontals is straight and transverse. This difference
is obviously associated with the presence or absence of the ridge. Along half of
their extent the nasals meet in the midline, but ventrally they are separated by
the nasal process of the premaxilla. The outer surface of the nasal is smooth
but perforated by several large nutrient foramina, and forms a low, rounded
boss over the nasal aperture. Together the nasals form the middle portion of
the frontonasal ridge when this is present.

The nasal apertures are situated relatively high in the skull, and close in
front of the orbits. The nasal provides a roof for each aperture and the pre-
maxilla forms the anterior wall and anterior part of the floor. The septomaxilla
closes the opening from behind. A depression in the side of the snout below the
nasal opening contains several pits and ridges, and its ventral boundary is a
strong ledge of the maxilla (Figs 22a, 22b). Ewer (1961) found a comparable
condition in Daptocephalus, where the septomaxilla displays a complex of

Fig. 27. Lystrosaurus curvatus. Nat. Mus. No. C.29g. Skull in anterior view.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS IOI

rugosities and depressions, and she speculates on the possibility of this bone
forming the base of a muscular mechanism whereby the fleshy nostril could be
closed when the animal was feeding off submerged plant matter. There is a
very strong likelihood that a similar mechanism was present in the semi-aquatic
Lystrosaurus, a possibility first mentioned by Watson (1912). In this connection
it is interesting to note that whereas in Daptocephalus the roughened, pitted area
is confined to the septomaxilla, in Lystrosaurus the adjoining premaxilla and
maxilla contribute towards the formation of ledges and tuberosities. It thus
seems that whatever the nostril-closing device present in Daptocephalus was, it
was enlarged and probably more important in the aquatic Lystrosaurus.

Brink (1951) thought it likely that Lystrosaurus amphibius possessed a fleshy
nostril which extended dorsally along the snout up to the prefrontal boss.
Although no deep groove in the nasal, such as described by Brink, was found
in any of the skulls examined during the course of this study, it is interesting

MES
SQ

PIL. ANT.

Fig. 28. Lystrosaurus declivis. S.A.M. No. K.1284. Lateral view of median septum of the skull,
reconstructed from serial sections.

192 ANNALS OF THE SOUTH AFRICAN MUSEUM

to note that in all specimens the nasal is pierced by numerous large nutrient
foramina.

The septomaxilla is distinct on the outer surface of the skull behind the
nasal opening. The septomaxillary foramen is contained between the maxilla
and the ventral edge of the septomaxilla. Posteriorly the septomaxilla meets
the lacrimal over a short distance. Van Hoepen (1913) stated that a thin sheet-
like portion of the maxilla separated the septomaxilla from the lacrimal in
Lystrosaurus latirostris, but that beneath this the two bones met. It seems likely
that this character is variable and of little significance. A short, wide canal
(Figs 26, 29, 32: SMX.CAN.) traverses the body of the septomaxilla and runs
medially to open out on the median edge of the bone. The possible function
of this canal is discussed below.

The lacrimal is an extensive bone and bears complicated relations to the
surrounding bones of the snout. Between the jugal and prefrontal it forms the
anteroventral border of the orbit and the lateral border of the large fenestra
leading from the orbit into the nasal cavity. It terminates anteriorly as a process
enclosed by the maxilla and on the outer surface of the snout meets the septo-
maxilla in a short suture. A short lacrimal duct pierces the lacrimal at the
anteroventral corner of the orbit and opens into the nasal cavity close behind
the septomaxilla-lacrimal suture (Figs 29, 32).

Serially sectioned and acid-prepared specimens made possible a detailed
study of the inner nasal cavities, usually inaccessible in conventionally prepared
specimens. The inner surface of the nasal is smooth but pierced by several large
foramina. However, the surface of the frontals just behind is unfinished in
periosteum, and two distinct ridges are formed, one on each side of the midline.
Each ridge has a flat ventral surface and is continued forward on to the nasal
of its side (Fig. 30: FR.R.). Both Van Hoepen (1913) and Barry (1967) have
found similar ridges in Lystrosaurus and Pristerodon respectively. Barry (1967)
supposes that the ridges supported cartilaginous or membraneous structures of
the nasal capsule, and tentatively identifies that part of the mesethmoid
(Barry’s septosphenoid) which expands laterally beneath the frontals with the
sphenethmoidal commissures of recent reptiles. However, it seems more likely
that the ridges on the frontals and nasals were associated with a pair of carti-
laginous sphenethmoidal commissures, as suggested by Romer & Price (1940)
in the Pelycosauria. In recent reptiles (Malan, 1946) and mammals (Roux,
1947) these bars of cartilage are closely applied to similarly ridged frontals.

Alternatively, the pair of frontonasal ridges in Lystrosaurus may have
supported a pair of turbinals, within a posterior extension of the nasal cavity.
Kemp (19692) has suggested that this was the case in the Gorgonopsia, Thero-
cephalia and Cynodontia, where a more extensive system of ridges is found”
within the nasal cavity. Kemp further maintains that the above-mentioned
ridges in the pelycosaurs are evidence of the presence of turbinals in primitive
synapsids.

As shown earlier, the premaxilla terminates posteriorly as a deep septum

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 193

PM. NAS.

PFR.

SMX. CAN

LAC. FOR.

ML, :

LLL

GR. JAC.ORG.

Fig. 29. Lystrosaurus sp. S.A.M. No. K.1495. Inner surface of the
snout cavity in anterior view.

dividing the nasal cavity and meeting the vomer behind. The dorsal edge of
this septum is flat anteriorly, but posteriorly, where it is clasped by the anterior
vomerine flanges, it is excavated to form a sulcus. Kemp (1969a) has described
a similar sulcus in the dorsal edge of the gorgonopsian vomerine median
septum, and suggests that it received the ventral edge of the cartilaginous
nasal septum. He goes on to demonstrate that, this being the case, the nasal
capsule in gorgonopsids was probably situated high in the snout, and com-
municated with the internal choanae by means of a choanal tube. .

In Lystrosaurus the deepened snout has resulted in the internal choanae
lying relatively far ventrally to the external nares and the level of the dorsal
edge of the premaxillary septum. If the nasal capsule of Lystrosaurus resembled
that of gorgonopsians, as seems likely, any choanal tube passing down to the
choana would have been of considerable length, and would have been sup-
ported posteriorly by the median processes of the palatines, as Kemp thought
was the case in the Gorgonopsia.

Within the nasal cavity the premaxilla is longitudinally grooved on either
side of the median septum, so that a furrow is formed leading from a point
near the nasal aperture to the anterior notch of the choana (Figs 29, 35). The

194 ANNALS OF THE SOUTH AFRICAN MUSEUM

posterior part of the furrow is especially deep and clear-cut. It seems very
probable that the furrow served to transmit the duct of Jacobson’s organ.
Camp & Wells (1956) found a similar groove leading from a depression in the
snout of Placerias and mentioned the possibility of this being evidence for the
presence of Jacobson’s organ. Pearson (1924) also found indications of the
organ in Kannemeyeria. In a sectioned dicynodont (S.A.M. 10081) a similar
groove opening into the anterior choanal notch was found alongside the pre-
maxillary septum.

In recent reptiles the duct of Jacobson’s organ opens into the anterior
part of the choana, and in mammals, where the primitive choana has been
eliminated by the secondary palate, it passes into the oral cavity through the
naso-palatine foramen (foramen incisivum) which lies between the premaxilla
and maxilla (Goodrich, 1930; Stadtmiiller, 1936).

This reconstruction of the duct of Jacobson’s organ in Lystrosaurus is at
variance with Brink’s (1960) deductions regarding the septomaxillary region
of a sectioned therocephalian, Akzdnognathus parvus. Brink, in the first place,
maintained that the morphology of this region in therocephalians is different
from that of the same region in dicynodonts, but comparison of Figures 29
and 32 with Brink’s (1960) Figure 36 shows that the two regions are essentially
similar in Akidnognathus and Lystrosaurus.

Fig. 30. Lystrosaurus sp. S.A.M. No. K.1495. Ventral view of inner
frontal and nasal surfaces.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 195

Examination of the grooves and foramina in Akidnognathus led Brink to
conclude that the duct of Jacobson’s organ had departed from its primitive
reptilian orientation and now opened in a new position near the external
aperture of the nasal passage, through the canal in the septomaxilla. This,
Brink supposed, was a result of the developing secondary palate, which had
cut off the duct’s opening into the oral cavity and thus prevented the organ
from functioning as a ‘taste’ organ. With its new opening at the entrance of
the nasal passage the organ could perform the functions of a primitive taste
and olfactory organ.

However, as stated above, in typical mammals the organ of Jacobson
still opens into the oral cavity through the naso-palatine foramen, and has no
direct relations with the nasal chambers. Broom (1895, 18964, 18966) has
described Jacobson’s organ in a variety of mammals and has shown that in
groups as diverse as the rodents, the horse, camel and giraffe, as also in the
marsupial Aepyprynus, the organ does in fact open into the nasal capsule, but
in these cases the new disposition of the duct is due to aberrations in the palatal
structure, such as, for instance, enlargement of the premaxilla in the horse,
whereby the ventral portion of the naso-palatine duct is obliterated. Further-
more, the internal opening of the duct in these forms is close to the organ
itself, and never in the vicinity of the external naris.

ORB. NAS. FEN

Fig. 31. Lystrosaurus murrayi. Nat. Mus. No. C.6457. Posterodorsal view of
labial fossa region.

196 ANNALS OF THE SOUTH AFRICAN MUSEUM ‘

The direct connection of Jacobson’s organ with the interior of the nasal
capsule in certain mammals must, it seems, be regarded as secondary and
uncharacteristic of the class as a whole, since in all other marsupial and pla-
cental mammals investigated by Broom, Jacobson’s organ opens into the oral
cavity via the naso-palatine duct. With all factors taken into consideration,
it seems most likely that the organ was present in therapsids, and that its duct
opened into the choana. In a recent (1969@) publication, Kemp has come to a
similar conclusion regarding Jacobson’s organ in the Gorgonopsia he investi-
gated. In the dicynodonts the development of the extensive palatal portion of
the premaxilla resulted in a backwards displacement of the duct which, how-
ever, still opened into the choana. The difference in the position of the duct’s
opening into the oral cavity in the two therapsid groups in which a functional
secondary palate was developed, namely the cynodonts and dicynodonts, is
illustrative of the different means whereby a backwards displacement of the
internal nares was accomplished in the two groups. While in the cynodonts the
bony secondary palate was formed by medial extensions of the maxillae and
palatines, enclosing an anterior naso-palatine foramen, in the dicynodonts
simple posterior enlargement of the premaxilla took place.

Laterally to the groove for the duct of Jacobson’s organ in Lystrosaurus the
surface of the maxilla is smooth and concave to form a floor and anterior wall
for the nasal cavity. The deepening of the snout has resulted in this portion
of the maxilla lying at a steep angle, instead of more or less horizontally as in
dicynodonts such as Aingoria (Fig. 54). A deep recess, such as found by Watson
(1960) in a dicynodont snout, in the anterolateral corner of the nasal chamber
at the junction of the septomaxilla and maxilla, opens out on to the outer sur-
face of the snout through the septomaxillary foramen (Figs 22a, 32: SMX.
FOR.).

Cox (1959) found three foramina in this region in Aingoria. Two of these
hold the same morphological relationships with the maxilla and septomaxilla
as does the septomaxillary foramen in Lystrosaurus. The third pierces the septo-
maxilla and is equivalent to the septomaxillary canal in Lystrosaurus. Cox
mentions the possibility of one of these foramina serving the duct of Jacobson’s
organ, but in the light of the above evidence for a different pathway for this
duct, his alternative interpretation, that the ducts of the lateral nasal and
lacrimal glands were transmitted to the outer snout surface through the
foramina, is more acceptable. In Lystrosaurus the canal traversing the septo-
maxilla is large enough to carry a lacrimal duct the size of which is indicated
by the bony lacrimal canal. This latter canal enters the nasal cavity at the same
level and close behind the septomaxillary canal. A distinct sulcus runs between
the two openings (Figs 29, 32: LAC.DUCT), making it virtually certain that
the lacrimal duct left the skull through the septomaxillary canal.

Kemp (1969a@) has concluded that in the Gorgonopsia the lacrimal duct,
after entering the nasal cavity, passed into the maxillary sinus and then opened
into the choana, as in typical recent reptiles. In Lystrosaurus and other dicyno-

CGRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 197

SMX. CAN.
L, DUCT

MAX. ANT.

MAX

SMX. FOR

PAL.

j

”/) WWy

Fig. 32. Lystrosaurus declivis. S.A.M. No. K.1284. Interior of
snout in medial view. Reconstructed from serial sections.

donts, however, the duct enters the nasal cavity dorsally and anteriorly to the
maxillary antrum, making it unlikely that the course postulated by Kemp was
followed in these animals. Moreover, the close association between the naso-
lacrimal duct and septomaxilla in Dasypus (Fuchs, 1911) suggests that the
duct in therapsids other than Lystrosaurus passed through, or close to, the
septomaxilla.

The smaller septomaxillary foramen, between the septomaxilla and
maxilla, in this case probably served to transmit the duct of the lateral nasal
gland, which in recent reptiles opens into the vestibule at this point (Pratt,
1948) and serves to moisten the nostril. The septomaxillary foramen is a feature
of the Gorgonopsia, Therocephalia and Dinocephalia (Boonstra, 19344, 19346,
1968). In the Squamata, the septomaxilla has abandoned its primary position
as a surface bone of the snout and migrated medially to form a roof for Jacob-
son’s organ, and loses its association with the duct of the lateral nasal gland.

Laterally the nasal cavity leads to an extensive maxillary antrum, which
surrounds the root of the tusk in the base of the zygomatic arch (Figs 29, 32,
33, 35: MAX. ANT.). Anteriorly the antrum is bounded by the maxilla and
lacrimal, and laterally and posteriorly by the jugal. Dorsally the antrum leads
into two blind pouches, one reaching forward to near the lacrimal canal, and

198 ANNALS OF THE SOUTH AFRICAN MUSEUM

A MAX

Fig. 33. Lystrosaurus declivis. S.A.M. No.
K.1284. Frontotransverse section through
posterior part of nasal cavity.

one running posteriorly a short way into the zygomatic arch. The posterior
wall of the maxillary antrum, consisting of jugal, lacrimal and palatine, is
excavated to form the labial fossa.

The function of the maxillary antrum is not one associated with the
presence of a large canine tusk, as is shown by the condition in two dicynodonts,
S.A.M. 10081 and 6550 (Figs 34a, 54a), which are tuskless and yet possess
well-developed antra. In three sectioned dicynodont specimens examined by
Agnew (1959) the antrum was absent in two and present in the other. This
variable occurrence in closely related animals makes it unlikely that the antrum
contained important glandular tissue, and it seems probable that Watson
(1960) was correct in his supposition that the space was filled by a diverticulum
of the respiratory passage. Such a diverticulum, containing a pair of turbinals,

EPT,

Fig. 34. (a) Dicynodont sp. S.A.M. 6550. Partial snout and basicranial axis in posterolateral
view. (6) Dicynodont sp. S.A.M. 10377. Snout in posterolateral view.

GRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 199

has been proposed by Kemp (1969) in the maxillary sinus of the Gorgonopsia.

Ewer (1961) showed that the labial fossa occurs in Lystrosaurus, Dapto-
cephalus, Kannemeyerta and Aulacephalodon, but not in Dicynodon or the endothio-
dontids. It appears that the labial fossa is not a new structure in these genera,
as a foramen in a position homologous to the Triassic Lystrosaurus and Kanne-
meyeria labial fossa is present in the snouts of two tuskless Cistecephalus zone
dicynodonts, $.A.M. 6550 and 10377 (Figs 34a, 34b). The foramen very likely
served to transmit nutrient blood-vessels into the snout, and the enlargement
of the foramen into the labial fossa is probably related to the increase in size
of the snout in Triassic dicynodonts and the advanced Aulacephalodon and
Daptocephalus.

The palatal region

There is no ectopterygoid in Lystrosaurus. Morphologically the position of
the ectopterygoid is taken up by the pterygoid process of the maxilla. Whereas
in Daptocephalus the ectopterygoid forms part of the ventral margin of the labial
fossa, in Lystrosaurus this portion of the labial fossa border is formed by the
maxilla only. The possibility exists that the pterygoid process of the maxilla
represents an ectopterygoid.

The palatine is in the main a curved vertical sheet of bone. It forms the
lateral and posterior wall of the choana, and its anterodorsal border separates
the maxillary antrum from the nasal cavity. It meets the median vomerine
septum medially and extends up as a transverse sheet to form the ventral
border of the large fenestra leading forward from the orbit into the nasal
cavity (Fig. 31: ORB. NAS. FEN.). Above the labial fossa it is clasped between
the jugal and lacrimal.

The vomer (Figs 2, 28, 33, 35) is a median sheet of bone, bifurcated ante-
riorly and posteriorly, and extending upward from ventrally in the choana
to make a brief contact with the mesethmoid. Anteriorly it is firmly interlocked
with the premaxilla, as described above, while the posterior bifurcation clasps
the parasphenoidal rostrum dorsally and forms the anterior border of the
interpterygoidal fossa ventrally. The dorsal tip of the posterior bifurcation
loosely surrounds the ventral edge of the mesethmoid.

The parasphenoid, intimately fused to the basisphenoid, has already been
referred to in the description of the neurocranium. Deepening and shortening
of the skull has transformed the cultriform process of this element from the long
low bar of typical dicynodonts to a narrow trough with high, thin sides (Fig.
17). The essential relationships between parasphenoid and presphenoid are
retained, however, and the latter is tightly clasped between the high ascending
wings of the parasphenoidal rostrum. In dicynodonts such as Dicynodon grimbeekt
and Pristerodon the rostrum is grooved for the reception of the sphenethmoid
complex or a cartilaginous extension of it; in Lystrosaurus there is a deep trench
in the parasphenoid anterior to the presphenoid, which in all likelihood received
a similar cartilaginous extension of the sphenethmoid.

200 ANNALS OF THE SOUTH AFRICAN MUSEUM

Z
Z
Z
AAA
FL

(a) (b)

Fig. 35. Lystrosaurus declivis. S.A.M. No. K.1284. (a) Frontotransverse section through external
nasal aperture and nasal cavity. (4) Frontotransverse section through ventral part of snout and
nasal cavity.

The pterygoid can be reduced to three processes: an anterior palatine
process, a broad median plate-like process which meets its fellow of the other
side behind the interpterygoidal fossa (vacuity), and a posterior quadrate
ramus (Fig. 24). The anterior palatine process is inserted between the palatine
medially and the posterior pterygoid process of the maxilla laterally. Between
the palatine and pterygoid is a canal running from the palate to close behind
the labial fossa (Fig. 24: LAT.PAL.FOR.). Cox (1959) found a similar canal
between the palatine and ectopterygoid of Aingoria, and supposes that it is the
reduced equivalent of the large lateral palatal fenestra of reptiles (Versluys,
1936). In this connection it can. be mentioned that a large suborbital fenestra
lies between the ectopterygoid, pterygoid and palatine of the Therocephalia,
but it is not found in the Gorgonopsia (Boonstra, 1936a, 1936). Versluys
(1936) states that a broad lateral palatal fenestra occurs in cotylosaurs and
pelycosaurs, and that it probably transmitted a branch of the trigeminal nerve.

The median pterygoid processes meet to form a strong pterygoidal plate
which is closely applied to the ventral surface of the parabasisphenoid, enclosing
a canal for the palatine branch of the facial nerve (Figs 22a, 24). The quadrate
ramus is a flat bar extending laterally to insert between the quadrate and the
paroccipital process (Fig. 8). A smooth facet is developed on the medial surface
of the quadrate for this contact. Along its anterior dorsal surface the process
carries a section of the epipterygoid footplate. Between the epipterygoid foot-
plate and the quadrate, the lateral surface of the pterygoid is grooved (Figs
15, 18), suggesting that a sheet of cartilage connecting the epipterygoid and
quadrate (see section on the visceral arch skeleton) lay closely applied to the
pterygoid in this region.

Between the quadrate ramus of the pterygoid and the prootic-opisthotic
portion of the braincase a large opening, the pterygo-paroccipital foramen of
Watson (1911) and Cox (1959) is formed (Fig. 24: PT.PAR.FOR.). Romer &

GRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 201

Price (1940) state that this passage in pelycosaurs is equivalent to the cranio-
quadrate foramen of Goodrich (1930). Technically this would also be correct
in a therapsid such as Lystrosaurus, since, if the posterior portion of the footplate
of the epipterygoid and the quadrate were connected by a band of cartilage,
as seems likely, the passage would have been situated between the braincase
and palatoquadrate.

The skull roof

Lystrosaurus species may be grouped into two categories on the basis of
variation in the shape of the skull roof, which is here considered to include
nasals, frontals, prefrontals, preparietal and parietals. In one group the skull roof is
smooth and flat (Figs 27, 36), and gently rounded anteriorly to merge into the
anterior surface of the snout. In these forms, as previously mentioned, the flat
anterior surface of the snout is rounded off at each side and longitudinal ridges
are absent. In the second group the frontals are thickened to form a pair of raised
bosses from which a system of grooves and ridges radiate (Figs 23, 26). These
latter are especially well exposed in acid-prepared specimens. In such speci-
mens it is also clear that a large number of nutrient foramina, not found in the
smooth-skull types, penetrate the frontal bosses. The nature of the bone struc-
ture here is remarkably similar to that of the anterior expanded portion of the
palatine.

The presence of these bosses, ridges and foramina, which are reminiscent
of those found on the horn-forming bony tissue of recent mammals, points to
the possible existence during life of a fairly thick horny pad covering the
frontals, and which perhaps formed a pair of knob-like projections over the
bosses. Less well-developed tuberosities are also found on the anterior portions
of the parietals and preparietal. There is no such roughening of the skull
surface on the nasals or prefrontals, but a curved, transverse frontonasal ridge,
referred to above, is present over these bones, separating the dorsal skull roof
from the snout, which in these forms slopes down abruptly from the dorsal
fronto-parietal portion of the skull roof. The anterior surface of the snout is
perfectly straight and flat, but bears a longitudinal median ridge. In contrast
to the smoothly rounded skull types, the snout falls away laterally at a sharp
angle, so that it presents a square-cut anterior appearance (Fig. 26). Smooth
bosses may sometimes be formed by the prefrontals on the anterodorsal borders
of the orbits. These are never large in the group with smoothly rounded skull
surfaces, but may become prominent in specimens with nasal ridges and sculp-
tured frontal surfaces.

The inner surface of the frontal is extended down as a ventral ledge which
makes contact with one of the two dorsally diverging wings of the orbitosphen-
oid. Anteriorly the ledge becomes a ridge which is continued on to the inner
surface of the nasal (Fig. 30), and which, as stated above, appears to have |
supported a sphenethmoidal commissure. Between the diverging wings of the
orbitosphenoid the inner frontal surface is recessed to accommodate the cere-

202 ANNALS OF THE SOUTH AFRICAN MUSEUM

bral hemispheres. In parasagittal view (Fig. 2) of the sectioned specimen
(S.A.M. K.1284) it can be seen that the frontals are continued forward in the
‘median line between the nasals to emerge briefly on the anterior surface of
the snout in front of the frontonasal ridge. This unusual condition was not
observed in any other specimen.

The preparietal (Figs 23, 36) is large and broad, and extends to behind the
frontal bosses, where these are present. There is considerable variation in the
shape of this element, and while in some specimens it is wide and blunt anteriorly,
in others it terminates as a sharp process between the frontals. In those
specimens with frontal tuberosities a low boss on the preparietal surrounds the
anterior border of the pineal foramen.

The fostfrontal lies in the posterodorsal corner of the orbit, and extends
back between the frontal and postorbital to reach the parietal. In dorsal view
(Figs 23, 36) it is a thin splint of bone, but on the ventral surface of the skull
roof it is a broad sheet underlying the postorbital.

The parietals surround the posterior half of the pineal foramen and each
extends forward as a wedge of bone between the preparietal and frontal. In
sections (Figs 2, 13) it can be seen that the parietal lies partly in the occiput
and meets the dorsal edge of the supraoccipital. These two bones contain
between them the canal and gutter described earlier. On the occiput the
parietal is completely covered by the thin interparietal. Laterally a sheet of the

Fig. 36. Lystrosaurus curvatus. Nat. Mus. No. C.29g. Skull in dorsal
view.

GRANIAL MORPHOLOGY OF THE DIGCYNODONT GENUS LYSTROSAURUS 203

parietal descends medially to the postorbital as a lateral wall for the dorsal
portions of the brain (Figs 13, 22a). Ventrally this sheet meets the dorsal tip
of the epipterygoid.

On the occiput (Figs 13, 37) the znterparietal covers the parietal, the dorsal
half of the supraoccipital and appears briefly in the medial wall of the temporal
fossa between the parietal and squamosal (Fig. 13). Laterally it meets the thin
tabular of each side (Figs 13, 37). The tabular covers the posterior extension of
the parietal and posteriorly lies apposed to the squamosal.

Lystrosaurus is characterized by its extremely short temporal fossa, the fossa
and orbit being roughly the same size. The zygomatic arch is consequently
short and stout relative to skull depth. The jugal extends backwards and up
from the anteroveniral border of the orbit, and lies medially to the squamosal
and dorsally to the maxilla in the zygoma. Posteriorly it terminates as a dorsal
process which supports the ventral portion of the postorbital.

The fostorbital curves back posteriorly to form the dorsomedial border of
the temporal fossa. Here it overlies the parietal and squamosal and is excavated
ventrally to form a deep notch between the skull roof and the descending
wing of the parietal. This notch probably served as an attachment point for
part of the inner adductor muscle mass. In some of the larger forms of Lystro-
saurus the postorbital carries a pronounced boss behind the orbit.

Fig. 37. Lystrosaurus curvatus. Nat. Mus. No. C.299. Skull in occipital
view.

The squamosal and quadratojugal

The large, triradiate squamosal provides attachment areas for the jaw
adductor musculature and portions of the neck musculature, and is conse-
quently strongly developed. A ventral flange forms the lateral border of the
occiput, lying alongside the supraoccipital and opisthotic and enclosing the

204 ANNALS OF THE SOUTH AFRICAN MUSEUM

posttemporal fenestra. Ventrally this flange buttresses the quadrate from
behind and, above the quadrate, forms the area of origin of a lateral division
of the adductor muscle mass (see p. 207). The anterior, zygomatic ramus forms
the lateral border of the temporal fossa and terminates below the orbit between
the jugal and maxilla. The dorsomedial ramus constitutes the posterior boun-
dary of the temporal fossa and provides attachment for the inner portion of the
jaw adductor muscle mass. Within the temporal fossa the squamosal overlaps
the supraoccipital and prootic over a small area.

The guadratojugal is a fan-shaped bone applied to the anterior face of the
lateral squamosal flange (Figs 6, 7, 22a). Ventrally the quadrate is clasped
between the squamosal and quadratojugal. The quadratojugal meets the
quadrate above the lateral articular condyle, closing off the quadrate foramen.

Sclerotic plates

Although numerous specimens of Lystrosaurus were examined in the course
of this study, and a great many well-preserved skulls extensively prepared, in
only one case were traces of sclerotic plates encountered. In the course of
clearing the orbits of S.A.M. K.1402, a series of three sclerotic plates was
uncovered in the left orbit, and a similar series of two plates in the right orbit

(Fig. 38).

Fig. 38. Lystrosaurus sp. S.A.M.
No. K.1402. Anterodorsal view
of skull showing sclerotic plates.

Huxley (1859) found impressions of sclerotic plates in the type specimen
of Lystrosaurus murrayi, and believed that not more than four or five plates were
present. Among other dicynodonts sclerotic plates have been found in Dicynodon
by Sollas & Sollas (1916) and Agnew (1959). Among therocephalians these
plates are preserved in Scaloporhinus and Zorillodontops (Cluver, 1969) and in
Ictidosuchops intermedius (Crompton, 1955).

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 205

THE MANDIBLE

The mandible of Lystrosaurus conforms closely to the standard dicynodont
pattern as described by many authors, including Watson (1948) and Ewer
(1961).

The dentary is powerfully constructed and, as in the case of several other
edentulous dicynodonts, is built up dorsally to the height of the tips of the
mandibular teeth of endothiodontids such as Emydops. In dorsal view the
symphyseal region is square and bounded laterally by two ledges, each ledge
being an anterior continuation of the jaw ramus of its side (Fig. 39b). The two
ledges, termed dentary tables by Crompton & Hotton (1967), are separated by
a rounded, median channel. Each lateral ledge has a slightly concave dorsal
surface and is continued forward as a spiny process on the anterior edge of the
mentum. On the lateral surface of the symphyseal region are two well-defined
grooves (Fig. 39a), leading down and back from the anterior tip of the jaw,
and each being bounded anteriorly by a sharp, narrow ridge.

The curved anterior surface of the symphysis, the lateral symphyseal
surface, as well as the dorsally situated lateral ledges, are perforated by numer-
ous nutrient foramina, such as are found in bone underlying a layer of horn

SA.

LAT DENR.

REF. LAM

IP

LAT DEN.L

LAT. DEN. SH

(b)

Fig. 39. Lystrosaurus declivis. Nat. Mus. No. C.403. Mandible in
(a) lateral and (6) dorsal view.

206 ANNALS OF THE SOUTH AFRICAN MUSEUM

in recent reptiles, and it is safe to conclude that a horny beak covered most of
the symphyseal block, with possible pad-like thickenings on the lateral surfaces
and the dorsal dentary tables. Anteriorly the beak probably terminated as two
sharp lateral processes, separated by a median cleft.

Behind the symphysis each lateral ledge is continued on to the ramus of its
side, and the slightly concave dorsal surface of each ledge becomes a deep,
thin-walled groove in the dorsal edge of the dentary. This part of the dentary
is not perforated by nutrient foramina. Below the groove the dentary is expan-
ded laterally to form a shelf (Fig. 39) lying above the mandibular fenestra.

The articular is divided into two condyles, a large lateral condyle and a
smailer, thin median condylar shelf, projecting from below the level of the
lateral condyle. The lateral condyle is divided into an anterior, concave
section and a posterior, convex portion. Below the posterior condylar facet
the articular is continued ventrally as a broad retroarticular process (Figs 39a,
40). A lateral recessed area (Fig. 39a) lies between the lateral rim of the arti-
cular condyle and the reflected lamina of the angular. This recess is continued
forward some distance beneath the reflected lamina itself. The articular is
similarly undercut beneath the median condyle (Fig. 40). There seems little
doubt that both these areas served for attachments of the jaw musculature.

SPL.

Fig. 40. Lystrosaurus murrayt. Nat. Mus.
No. C.6457. Inner surface of left ramus
of mandible in posterolateral view.

Medially the articular is abruptly truncated, and was clearly continued
forward as cartilage into the Meckelian fossa as Meckel’s cartilage. A similar
condition has been described by Barry (1967) in Pristerodon, and Watson (1948)
in Dimetrodon. The medial border of the Meckelian fossa is formed by the
prearticular, which posteriorly lies closely apposed to the medial surface of the
articular. Anteriorly the prearticular meets the splenial (operculum of Van
Hoepen, 1913). The surangular is of normal dicynodont pattern. As is the case
in all other dicynodonts, the coronoid bone is lacking.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 207

SecTIon IJ. THE JAW MUSCULATURE AND MASTICATORY
CYCLE IN LysTROSAURUS

THE JAW MUSCULATURE

There is no indication that the changes in skull proportions undergone by
Lystrosaurus have resulted in a departure from the general composition of the
jaw musculature as reconstructed in other dicynodonts by various morpho-
logists. Cox (1959) and Ewer (1961) have discussed the cranial muscles of
RKingoria and Daptocephalus respectively, Watson (1948) has reconstructed those
of Dicynodon, and Crompton & Hotton (1967) have discussed these muscles
and their function in Emydops and Lystrosaurus.

It is generally accepted that two main groups of jaw muscles found in
living reptiles were present in dicynodonts, namely the capiti-mandibularis
and pterygoideus groups. In Lystrosaurus it is clear that the capiti-mandibularis
group was divided into two large adductor muscles, one arising inside the
temporal arcade and the other on the lateral flange of the squamosal and
posterior part of the zygomatic arch. Crompton & Hotton (1967) call these
two muscle masses the medial and lateral external adductor muscles, terms used by
Brock (1938) and equivalent to the capiti-mandibularis superficialis medialis
and lateralis of Adams (1919).

In Crompton & Hotton’s (1967) reconstruction, the medial adductor
arose from the posterior and median borders of the temporal fossa and inserted
in the dorsal dentary groove (Fig. 41a). The lateral adductor, which arose
from the lateral flange of the squamosal and ventrolateral surface of the
zygomatic arch behind the level of the postorbital, inserted on the lateral ledge
of the dentary above the mandibular fenestra (Fig. 41b).

Ewer recognized the presence of a temporalis and masseter muscle attach-
ing to the dentary in Daptocephalus. In her reconstruction, the temporalis
muscle inserted on the lateral shelf and on the rear of the dentary, while the
masseter muscle, recognized also by Parrington (1955), inserted on the reflected

‘AE. MED A.E.LAT.

(a) (b)

Fig. 41. Lystrosaurus declivis. Nat. Mus. No. C.403. Skull in lateral view with
(a) adductor externus medialis and pterygoideus anterior and (b) adductor
externus lateralis and depressor mandibulae muscles restored.

208 ANNALS OF THE SOUTH AFRICAN MUSEUM

lamina of the angular. Ewer (1961) supposed that the groove in the dorsal
edge of the dentary indicates a posterior extension of the horny beak, and that
the two blade-like projections of the beak thus formed would slice food in the
mouth against horn-covered tubercles on the palate during the masticatory
stroke.

Although such a dentary groove is present in Lystrosaurus, no position of
the lower jaw exists in which more than only the very anterior portion of the
groove is in the vicinity of any horn-covered region of the palate. With the
mandible in the most protracted position possible, the deepest portion of the
dentary groove lies far posterior to the caniniform process and laterally to the
pterygoid. A posterior, double-bladed extension of the horny beak would
therefore be useless during the masticatory cycle, and it is far more likely that
the inner portion of the adductor mass inserted in the sulcus.

Of interest in this connection is the unusual condition of the dentary in an
incompletely preserved Cistecephalus zone dicynodont, S.A.M. 6043 (Fig. 42)
(Cluver, 1970). This specimen includes an incomplete mandible, which in
some respects resembles that of Aingoria (Cox, 1959). There is no separate
groove in the dorsal edge of the dentary, but the lateral dentary ledge, normally
found in dicynodonts, is flared out far laterally and forms the lateral border of
a deep fossa, which extends forwards for a short way as a pocket in the dentary.
It seems likely that the insertion areas of the entire adductor muscle mass lay
in this excavation. The fossa most probably arose by loss of the outer sharp rim
of the dentary groove of typical dicynodonts, with consequent merging of the
dentary groove with the lateral mandibular shelf. Thus the dorsal edge of the
dentary, above the fossa, is a thin sharp plate, similar in all respects to the inner
wall of the dentary groove in typical dicynodonts.

The fact that disappearance of the typical dentary groove in this specimen
was accompanied by extension of the lateral dentary shelf suggests that the
insertion area of the lateral adductor muscle was displaced laterally, so that

Fig. 42. Dicynodont
sp. S.A.M. No. 6043.
Left ramus of man-
dible in dorsal view.

CRANIAL MORPHOLOGY OF THE DIGYNODONT GENUS LYSTROSAURUS 209

accommodation of the inner division of the muscle mass was possible. The
condition in this specimen thus indirectly lends weight to the theory that an
inner division of the adductor muscle inserted on the dorsal edge of the dentary
in typical dicynodonts.

Furthermore, the dentary fossa in S.A.M. 6043 has two main surfaces, a
median outward-sloping surface, and a lateral inward-sloping surface. It is
conceivable that the lateral external adductor muscle was attached to the
lateral surface, and the medial external adductor to the inner surface.

It seems unlikely that a masseter muscle was present in therapsids other
than possibly the cynodonts. Barghusen (1968) has maintained that, for
functional reasons, a masseter was not present in Dvzmetrodon or primitive
therapsids, and possibly arose for the first time in cynodonts. Using data derived
from studies by Haines (1934) and Zierler (1961) on muscular extension and
contraction, he has shown that in Dimetrodon a masseter muscle with the origin
and insertion proposed by Watson (1948) and Fox (1964) would be capable of
only limited stretch, insufficient to meet the requirements of a reasonable,
effective jaw gape. Crompton & Hotton (1967) have similarly maintained that
the postulated areas of attachment of such a muscle in dicynodonts are not
convincing, and show that the action which would be produced by such a
muscle does not conform with the general nature of the dicynodont masticatory
cycle.

In this section the external adductor musculature proposed by Crompton
& Hotton (1967) has been followed.

In Lystrosaurus the anterior pterygoideus muscle of the pterygoideus group
arose from the lateral surface of the pterygoid and, in the absence of the
ectopterygoid, probably also from the posterior pterygoid process of the maxilla,
which has taken the position of the ectopterygoid. The direction of the muscle
fibres was posterior and ventral, and they passed around the ventral edge of
the articular to reach their attachment area in the lateral recess in front of the
articular condyle and beneath the reflected lamina (Figs 41a, 43).

In addition to the anterior pterygoideus muscle, a second member of the
adductor internus musculature, namely the posterior pterygoideus muscle of
Parrington (1955) was probably present in Lystrosaurus. Arising from the
moulded ventral surface of the interpterygoidal plate, and quadrate ramus of
the pterygoid, this muscle would have inserted in the excavated area under the
median condyle of the mandible (Fig. 43).

Watson (1948) considered that the retroarticular process of therapsids
served as an attachment for the pterygoideus musculature and that a depressor
mandibulae muscle was absent, the jaw being lowered by other muscles,
perhaps the sublingual group. However, Parrington (1955) has convincingly
shown that a depressor mandibulae was very likely present in therapsids, and
that the retroarticular process of pelycosaurs was retained in later synapsids.
Subsequent morphologists have followed Parrington’s view, and Barry (1967)
showed that in certain Chelonia, where the retroarticular process is very poorly

210 ANNALS OF THE SOUTH AFRICAN MUSEUM

PT. POST.

Fig. 43. Lystrosaurus declivis. Nat.
Mus. No. C.403. Ventral view of
skull with pterygoideus anterior
and posterior muscles restored.

developed, a strong depressor mandibulae muscle was nevertheless present,
so that the small size of the process in dicynodonts need not necessarily be
indicative of a weak or non-existent depressor mandibulae muscle. Moreover,
it appears that in some endothiodontids, such as a well preserved Emydops sp.
(S.A.M. 10153) a well-developed, ventrally directed retroarticular process is
present.

It may therefore be accepted that the depressor mandibulae muscle in
Lystrosaurus inserted around the ventral edge of the retroarticular process and
found its origin on the lateral squamosal surface of the occiput (Fig. 41b). Cox
(1959) and Ewer (1961) have given contrasting areas of origin for this muscle,
Ewer suggesting that the origin was low down on the lateral squamosal flange,
as in recent reptiles, rather than on the dorsolateral, posteriorly projecting
corner of the squamosal, as in Cox’s reconstruction of Kingoria. The posterior,
lateral surface of the lateral squamosal flange above the quadrate does not seem
to have served as an attachment area for any of the occipital muscles, and in
Lystrosaurus the depressor mandibulae very likely originated here, as suggested
by Ewer. Thus reconstructed (Figs 41b, 51), the muscle is of considerable
length and capable of accommodating fore-and-aft movement of the mandible.

THE MASTICATORY CYCLE

In his study of the Dicynodontia Watson (1948) concluded that the lower
jaw of these animals was capable of extensive anterior-posterior displacement,
so that from a forward, protracted position where the posterior articular
condyle surface lies up against the quadrate, the mandible can be pulled back
into a retracted position in which the quadrate lies in the anterior concave
facet of the articular condyle. Watson supposed that a back-and-forth propalinal
movement of the lower jaw when in the drawn-up position would serve to
crush food in the mouth. However, Crompton & Hotton (1967) have shown
that only a retractive power stroke could have been useful in mastication of
food already in the mouth. Thus the mandibular teeth of Empdops are posteriorly

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS PIII

serrated and anteriorly rounded. Furthermore, they show fairly conclusively
that the force provided by the anterior pterygoideus muscle, and exerted by
the mandibular teeth on the palate during a forward stroke, would have been
infinitely smaller than the dislocatory forces at work on the jaw joint. In con-
trast to this, a very powerful and extremely effective masticatory force was
exerted by the external adductor muscles during a retractive stroke.

Crompton & Hotton (1967) have also given an exhaustive functional
analysis of the various components of the muscle forces potentially present
within the masticatory apparatus of both Emydops and Lystrosaurus during a
typical masticatory cycle. The following description of such a cycle has been
largely drawn from their account.

The lower jaw, when drawn up against the palate and retracted so that
the quadrate rests in the anterior articular facet, could be lowered by contrac-
tion of the depressor mandibulae muscle and, perhaps simultaneously, drawn
forwards (protracted) by the pterygoideus muscles. The articular would then
eventually come to lie with its posterior articular facet up against the anterior
condylar surface of the quadrate (Fig. 44a). At this stage the median condyle
of the articular is separated from the inner condyle of the quadrate.

With the mouth now opened to give the greatest possible gape (see p. 232),
the external adductor muscles are able to draw the mandible up and back,
i.e. they effect both elevation and retraction (Figs 44b, 44c). If the pterygoideus
muscles maintained their pull on the posterior part of the mandible, elevation
alone would have taken place, and retraction would have started only when
these muscles relaxed. As Crompton & Hotton (1967) have pointed out, the
anterior tips of the upper and lower beaks in Lystrosaurus can approach each
other only after a certain amount of retraction has taken place, and it is likely
that in Lystrosaurus jaw elevation and retraction took place as a single move-
ment. In the first stages of retraction the inner condyle of the lower jaw comes
into contact with the median quadratic condyle, but as the jaw moves back,
the two surfaces part once more. Retraction ceases when the quadrate slips
into the anterior recess of the articular.

Of interest here is that in Emydops, where so-called ‘beak bite’ could take

(a) (b) (c)

Fig. 44. Lystrosaurus declivis. Nat. Mus. No. C.403. Skull in lateral view with mandi-
ble in (a) depressed and protracted (b) adducted and (c) retracted positions.

22 ANNALS OF THE SOUTH AFRICAN MUSEUM

place when the mandible was in the fully protracted position, a third facet on
the articular condyle, above the retroarticular process, permitted the quadrate
to buttress the mandible while only the vertical component of the external
adductors drew the jaw up to give a nip between the upper and lower beaks
at the front of the mouth (Crompton & Hotton, 1967). In Lystrosaurus, where
anterior contact between the upper and lower beaks was not possible, no such
facet on the articular is present.

The following account of the relationships between the occlusal surfaces
of the upper and lower jaws during jaw elevation and retraction differs in
several respects from that given by Crompton & Hotton (1967).

Figures 45, 46 and 47 illustrate a restoration of the upper and lower horny
beaks of Lystrosaurus, to show the relationships between various pad-like
thickenings and cutting edges during the masticatory cycle. As the mandible is
drawn up from the protracted, depressed position, the horny pads on the
lateral surface of the symphysis move past the sharp, blade-like edge of the
palatal rim in front of the caniniform process (Figs 26, 46, 47) in a slicing
action. The extensive development of this portion of the palatal rim in all
specimens, irrespective of tusk size, indicates the importance of this slicing
stage of the masticatory cycle. The pads on the lateral symphyseal surface
move up deeper into the recessed palatal dome as retraction begins, with the
dorsal edge of the dentary riding against the maxilla in the notch between the
caniniform process and the anterior tip of the pterygoid. The degree of inter-
meshing which takes place between the anterior edges of the mandible and
premaxilla as they approach each other at the beginning of retraction depends
on the thickness of horn covering the two edges. In the case of Lystrosaurus the
anterior biting edges on the premaxilla and dentary would have to be extended
fairly considerably in horn to be able to meet effectively. The two laterally
placed terminal projections of the dentary beak would move back along the
palate laterally to the two anterior palatal ridges of the premaxillary palatal
rim, drawing food back into the mouth.

Fig. 45. Lystrosaurus declivis. Nat. Mus. No. C. 403. Mandible with
restored horny beak in (a) dorsal and (6) lateral view.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 213

Fig. 46. Lystrosaurus declivis. Nat. Mus.
No. C.403. Ventral view of skull with
horn-covered area on palate restored.

Crompton & Hotton (1967) state that the lower jaw does not approach
the dorsal palatal roof during the masticatory cycle, and that the cycle is
adapted for slicing only. However, examination of several well-preserved skulls
and mandibles (see also Cluver, 1970) has shown that as retraction continues,
the lateral horny pads on the lateral symphyseal surface pass behind the
caniniform process, and that the pads on the dorsal dentary tables, on each
side of the dorsal symphyseal surface (Fig. 45a), move up against the horn-
covered areas on the palatines and surrounding portions of the maxilla (Fig. 46).
The median palatal ridge of the premaxilla (Fig. 46) now fits neatly into the

Fig. 47. Lystrosaurus declivis. Nat. Mus.
No. C.403. Lateral view of skull with
horn-covered areas on snout restored.

214 ANNALS OF THE SOUTH AFRICAN MUSEUM

median groove in the anterior edge of the mentum. At this stage grinding and
crushing of the food within the mouth would have taken place, until such time
as retraction ceases with the quadrate resting in the anterior recess of the
articular condyle. It is interesting to note that in Lystrosaurus the horny exten-
sion from the palatine on to the maxilla is in the same relative position as the
postcanine maxillary teeth of Emydops.

The masticatory cycle of Lystrosaurus is thus a combination of slicing, which
_ takes place in front of the caniniform processes, and crushing, which takes
place in the mouth at the level of the palatal horn layers on the palatine and
adjoining maxilla.

Section III. THE ATLAS-AXIS COMPLEX AND THE CERVICAL AND
OCCIPITAL MUSCULATURE IN LrsTROSAURUS

MORPHOLOGY OF THE ATLAS-AXIS COMPLEX

The atlas of Lystrosaurus is of the normal therapsid tripartite type, con-
sisting of an intercentrum and two neural arches.

The intercentrum (Fig. 50) is a semicircular, wedge-shaped element,
with an anterior concave facet for articulation with the basioccipital, and a
posterior facet which meets the odontoid process of the axis. The neural arches
(Fig. 48) are well separated in the midline. Each is a complex structure, with
the main body of the bone bearing anteromedial and posteromedial articular
facets for the exoccipital and odontoid respectively. The body of the bone is
extended far laterally and posteriorly as a broad, vertical, wing-like transverse
process. Dorsally to this process the bone is narrowed down to a short neck, as
is the case in the typical neural arch. Dorsally the arch broadens to provide a
proatlantal facet in front and a rudimentary postzygapophysis behind. Laterally
to the postzygapophysis the atlas is produced laterally and slightly dorsally

LAT. PROC

PAFAG ATC: PA.FAC.AT

TR. PROC

Fig. 48. Lystrosaurus murrayi. Nat. Mus. No. C.6457. Atlas neural
arch in (a) left lateral (b) dorsal and (c) medial views.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 215

as a short process above the atlantal wing. Between this process (Fig. 48:
LAT.PROC.) and the dorsomedial edge of the neural arch a flat shelf is
formed.

The Lystrosaurus atlas compares well with those which Cox (1959) and
Ewer (1961) have described in Kingoria and Daptocephalus respectively. Cox
(1959) has attempted to show that the dorsolateral process on the atlantal
arch is homologous with the neural spine of typical vertebrae, and that the
neural spine present on the atlas of Seymourta (White, 1939) is equivalent to
the backwardly-directed spiny process lying laterally to the atlantal post-
zygapophysis of Ophiacodon and Dimetrodon (Romer & Price, 1940). Cox also
points out that Brink & Kitching (1954) have figured a similar process in
Prorubidgea, while Brink (1955) has restored a similar spine in Diademodon,
although Jenkins (1968) states that the neural arch of cynodonts is spineless.

Against Cox’s theory it can be pointed out that the new process, lying
laterally to the postzygapophysis, is morphologically in a totally different
position to that of the neural spine in Seymourta, and that there is no spine of
any sort in Captorhinus, so that there are no known connecting stages illustrating
the migration of the spine to its new position. Furthermore, in the primitive
pelycosaur Petrolacosaurus (Peabody, 1952) again no atlantal spine is found,
and Peabody states that the arch is very like that of Ophiacodon and Dimetrodon,
except that there is no process lateral to the postzygapophysis, but ‘. . . a longi-
tudinal ridge occurs in the demi-arch . . . which suggests incipient development
of such a spine’ (p. 19). Moreover, certain inferences regarding attachments
of the atlas-axis musculature make it unlikely that the process is homologous
with the neural spine of Seymouria. These inferences will be discussed later.

A pair of curved proatlas elements is present in Lystrosaurus, each proatlas
extending from the facet on the atlantal neural arch to an articular tubercle
on the exoccipital alongside the foramen magnum.

The axis in Lystrosaurus (Fig. 49) is of fairly typical dicynodont pattern.
The prezygapophysis is reduced to the same extent as the postzygapophysis

POSTZ.

PREZ.

AT. FAC:

OD.

(a) (b)

Fig. 49. Lystrosaurus murrayi. Nat. Mus. No. C.6457. Axis and odontoid in
(a) left lateral and (b) dorsal views.

216 ANNALS OF THE SOUTH AFRICAN MUSEUM

of the atlantal arch. The odontoid portion of the axis, representing the atlas
centrum, is clearly demarcated from the axial centrum by a distinct suture.

THE MUSCULATURE OF THE ATLAS-AXIS COMPLEX
AND THE OCCIPUT

Literature dealing with the probable nature of the muscles arising from
the atlas-axis complex and inserting on the rear of the skull comprises several
sometimes conflicting accounts. Muscle scars are few and indistinct, and
uncertainty regarding the proportion of reptilian as opposed to mammalian
qualities in the occipito-cervical region makes the problem a vexed one.

Evans (1939) has given a comprehensive review of the occipital and neck
muscles in living reptiles and mammals, and has attempted to restore this
musculature in fossil reptiles and amphibians. Briefly, three major groups of
muscles are present in the cervical region of reptiles and mammals. These are
the Iliocostalis system, the Longissimus system and the Transversospinalis
system. In mammals the first group loses its insertion on the skull, and is
confined to the cervical vertebral series.

The lon. issimus capitis muscle of the longissimus system originates from the
prezygapophyses of the cervical vertebrae and inserts on the squamosal and
parietal in reptiles and on the mastoid process in mammais. In Lystrosaurus this
muscle probably inserted on the dorsolateral part of the occiput, beneath the
posterior flange of the squamosal (Fig. 51).

The semispinalis capitis muscle probably inserted on the occiput below the
longissimus capitis muscle. The semispinalis capitis is part of the transverso-
spinalis system, and arises from the transverse processes of the anterior thoracic
vertebrae and the postzygapophyses of the cervical vertebrae.

Also belonging to the transversospinalis system are the rectus and obliquus
capitis muscles (Fig. 50). In reptiles a m. rectus capitis posterior (dorsalis) major
arises from the axis neural spine and below it a m. rectus capitis posterior (dorsalis)
minor may originate from the axis neural spine or the atlantal neural arch. Both
muscles insert on the dorsal part of the occiput, near the midline. A m. rectus
capitis lateralis originates on the transverse process of the atlas and inserts on the
occiput. Also in reptiles, a m. obliquus capitis magnus originates on the axial
neural spine and the dorsal surface of the atlas neural arch, and inserts on the
opisthotic occipital surface. A m. obliquus capitis minor (Jenkins, 1968), the
equivalent of the m. obliquus capitis inferior of Evans (1939), originates from the
dorsal surface of the axial neural arch and inserts on the atlantal postzygapo-
physis.

In mammals the organization of the musculature in this region has been
considerably altered to accommodate extensive rotation of the now ring-shaped
atlas on the odontoid peg of the axis. The obliquus capitis magnus muscle is
lost, and an obliquus capitis caudalis muscle (Jenkins, 1968) originates on the
axial spine and inserts on the wing of the atlas. An obliquus capitis cranialis
muscle originates on the wing of the atlas and inserts on the occiput. These

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 217

R.C.POST. MAJ.

R.C.POST MIN

Kam

OBL.C.CAUD. 4 1 RC. POST. MAJ.

(b)

Fig. 50. Lystrosaurus murrayi. Nat. Mus. No. C.6457. Atlas-axis complex with restored musculature
in (a) lateral and (6) dorsal views.

muscles, which Evans (1939) calls the obliquus capitis superior and inferior,
serve respectively for rotation of the atlas about the axis, and extension of the
head at the occipito-atlantal joint.

The restoration of the rectus and obliquus capitis muscles in a therapsid
such as Lystrosaurus is complicated by uncertainty as to the number of ‘mamma-
lian’ features evolved in the genus, such as, for example, the amount of rotation
possible at the atlanto-axial joint. Since the Dicynodontia became a distinct
group early in the evolution of the therapsids, and are phylogenetically very
distant from the ancestral mammal stock, any so-called mammalian charac-
teristics most probably evolved independently, and should be regarded as
parallels to similar qualities in, for example, the cynodonts. Of importance in
this connection is the basically reptilian interpretation by Jenkins (1968) of the
cynodont atlas-axis complex and the associated musculature.

Cox (1959) has also chosen an essentially reptilian reconstruction of the
atlas-axis musculature in the dicynodont Kingoria, supposing that the primitive
obliquus capitis magnus muscle was present between the axis and occiput.
However, Ewer (1961) states that the obliquus capitis magnus muscle was
probably not present in any of the therapsids, and that Daptocephalus was capable
of fairly extensive rotatory movements at the atlanto-axial joint. In Lystrosaurus,
judging by the rudimentary condition of the pre- and postzygapophyses of the
axis and atlas respectively, some degree of rotation did take place at this joint,
and since the obliquus capitis magnus muscle would have impeded this motion,
it was probably not present, at least not as an important muscle.

Cox (1959) maintained that if the process on the atlantal arch, lateral to
the postzygapophysis, is homologous with the neural spine, the m. obliquus
Capitis minor (inferior of Cox) would have inserted on it, and the m. obliquus
capitis superior would have originated on it, since these muscles would origin-

218 ANNALS OF THE SOUTH AFRICAN MUSEUM

)RC.POST. MAJ,
RC. POSTMIN.

RC.LAT lcm.

Fig. 51. Lystrosaurus declivis. Nat. Mus. No. C.403.
Occipital view of skull showing areas of occipital
musculature insertion.

ally have been part of the interspinalis muscles running between successive
vertebral spines. Fusion of this atlantal neural spine with the transverse process
of the atlas would, according to Cox, produce the mammalian condition,
where the obliquus capitis caudalis and cranialis muscles insert and originate
on the enlarged atlantal transverse process.

If Cox’s theory were correct, signs of this transition would be expected in
the atlas-axis complex in cynodonts, since these therapsids are accepted as
being closely related to the forms which gave rise to the first mammals. How-
ever, the neural arch of the cynodont atlas bears no process equivalent to the
spine in Lystrosaurus and Kingoria (Jenkins, 1968) and the transverse wing retains
its primitive vertical position, in contrast to the more horizontal orientation of
this process in mammals. Jenkins (1968) has for several reasons preferred to
regard the cynodont atlas-axis complex as reptilian, rather than as closely
foreshadowing the mammalian condition, as Evans (1939) thought was the case.

Cox’s theory is thus further weakened, since as the cynodonts have a
primitive transverse process, the neural spine would be expected to be present
to provide attachment for the two obliquus capitis muscles. It seems more likely
that in the therapsids the m. obliquus capitis caudalis inserted on the dorsal
surface of the atlantal neural arch and ‘spine’, near the postzygapophysis, and
that the m. obliquus capitis cranialis originated on the wing-like transverse
process, as reconstructed by Ewer (1961). If this view is correct, Lystrosaurus
had retained a basically reptilian atlanto-axial musculature, with, however,
the loss of the m. obliquus capitis magnus. To accomplish more effectively the
modest degree of rotation between the atlas and axis, as indicated by the reduced
zygapophyseal articulation between the two bones, the atlas developed a pro-
cess laterally to the postzygapophysis for the insertion of the m. obliquus capitis
caudalis. In this way the muscle gained a larger oblique component of force,
enabling it to function more effectively as a rotator muscle. However, this
mechanism was still much less effective than the mammalian condition, where

GRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 219

the m. obliquus capitis caudalis is inserted on the enlarged and posteriorly
directed atlantal wing, and runs in a dorsoventral direction, rather than the
posterodorsal-anteroventral direction of dicynodonts.

By this analysis the ‘atlas spine’ of Cox may be termed simply the dorsal
process of the atlas, which, together with the necessity for rotating the atlas
about the axis, probably arose in therapsids to accommodate: the lateral
migration of the insertion of the m. obliquus capitis caudalis from its original
position on the postzygapophysis of the atlas (where the equivalent muscle in
recent reptiles is still inserted).

The large, vertically orientated atlantal wing of Lystrosaurus suggests that
it provided a relatively large surface of origin for muscles running anteriorly
and laterally. This surface is directed at the region of the occiput below the
posttemporal fenestra. The m. obliquus capitis cranialis (Figs 50, 51) arose on
the atlantal wing and would very likely have inserted on the opisthotic below
the posttemporal fenestra. This region in Lystrosaurus is depressed over a fairly
large area. The m. rectus capitis lateralis, also arising from the atlantal wing,
would have inserted below the m. obliquus capitis cranialis. These two insertion
areas are similar to those suggested for these muscles by Ewer (1961) in Dafto-
cephalus, and for the m. obliquus capitis magnus by Cox (1959).

The restoration of the rectus capitis muscles (Figs 50, 51) poses fewer
problems. A m. rectus capitis anterior (ventralis) would have arisen from the
ventral surfaces of the centra of the atlas and axis, and inserted on the base of
the skull, in Lystrosaurus probably also on the rear of the intertuberal ridge. The
m. rectus capitis posterior (dorsalis) was probably divided into minor and major
components. The latter arose from the axis neural spine and inserted dorsally
on the occiput near the midline. The former muscle probably found its origin
on the flat dorsal surface of the atlas behind the articulation between atlas and
proatlas, inside the insertion of the m. obliquus capitis caudalis on the dorsal
process of the atlas. This muscle, passing dorsally over the curved proatlas,
inserted on the occiput below the m. rectus capitis posterior major. These areas
of origin and insertion are similar to those proposed by Ewer (1961), although
Ewer found indications of a rectus capitis posterior medius having separated
from the major component on the axis spine.

Thus reconstructed, the occipital and cervical osteology and musculature
of Lystrosaurus represent a modified reptilian pattern rather than a primitive
mammalian one. Departure from the typical reptilian condition is seen in the
loss of the obliquus capitis magnus muscle and the incipient rotation between
atlas and axis, with accompanying reduction in the zygapophyseal articulation.

These changes are probably correlated with the characteristic morphology
of the lystrosaurian occipital condyles, where the basioccipital has receded
below the posteriorly projecting exoccipital condyles. This modification of the
typical reptilian condition, where the condyle is a single rounded process, is
not confined to Lystrosaurus among dicynodonts (Olson, 1944), and suggests
that rotation at the occipito-atlantal joint was reduced. Probably concomitant

220 ANNALS OF THE SOUTH AFRICAN MUSEUM

with the changes taking place at this joint was the reduction of the zygapophy-
seal articulation between atlas and axis, with consequent changes in the atlanto-
axial musculature.

Because of the many uncertain factors involved, the above reconstruction
is naturally far from conclusive, but, as it stands, it does account for all the
individual muscles which are generally supposed to have been present in this
region in therapsids, and provides an explanation for the several osteological
innovations.

SEcTION IV. THE EVOLUTIONARY SEQUENCE LEADING TO
THE LYSTROSAURUS GRADE OF DICYNODONT DEVELOPMENT

In previous sections several references have been made to the way in which
the characteristic skull form of Lystrosaurus differs from that of earlier, Permian
dicynodonts. In this section, differences in morphology between a typical
Lystrosaurus skull and that of typical, earlier dicynodonts will be used as a basis
for an attempted comprehensive explanation, in terms of functional anatomy,
for the changes within the evolutionary sequence which culminated in Lystro-
saurus.

At this point Lystrosaurus is considered purely as a stage in dicynodont
evolution advanced over the typical Permian stage. In a later section the
relationships of Lystrosaurus to other Triassic groups of dicynodonts, and its
origin from a Permian ancestor, will be discussed.

In this section illustrations comparing Lystrosaurus with earlier dicynodonts
are based on the following specimens:

Lystrosaurus declivis

S.A.M. K.1284 . . . . Sectioned skull & mandible
Nat. Mus. 0.403 . . . . Skull & mandible
Emydops sp.
Bibl. 26420 98 ee kml ee omnandible
Dicynodon sp.
S.A.M. 8784... . . . Skull & mandible

Two skull measurements were used as constants in the illustrations.
Generally, skulls were compared with skull lengths over the reference plane
(see Material and techniques) brought to a constant, but in some cases, where
it was thought necessary to use a measurement unlikely to have been affected
by the adaptive changes in the Lystrosaurus skull, the interquadrate length,
being the distance between the outer edges of the lateral quadratic condyles,
was used.

In comparisons involving the jaw adductor musculature, a line representing
the axis of the lower jaw has been selected. This is the line connecting the
anterior tip of the dentary with the point of contact between the articular and
quadrate.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 221

COMPARISON OF THE SKULLS OF LYSTROSAURUS AND TYPICAL PERMIAN
DICYNODONTS

Depth of skull

In both lateral and parasagittal view it is apparent that, when compared
with earlier dicynodonts, the skull in Lystrosaurus has become deeper overall.
When the skulls are brought to the same basic length (Fig. 52) this effect is
accentuated, since Lystrosaurus has also undergone shortening of the basicranial
axis. In Figure 53, however, the skulls of Lystrosaurus and Dicynodon have been
drawn to the same interquadrate length. Here it is clear that the skull roof in
Lystrosaurus is higher than in Dicynodon, and that the Lystrosaurus snout is pro-
duced farther ventrally. The mandible in Lystrosaurus thus lies at a greater
angle to the reference plane of the skull than in other dicynodonts.

i
Ne

\\
y=,

(b)

Wm

<——s/

Ut =

iS WTI

| Mm '
f \y a
CES ay

Wt,

ie

(c) (d)

Fig. 52. Comparison of the skull of Lystrosaurus with those of Permian dicy-

nodonts. (a) Lystrosaurus declivis, S.:A.M. No. K.1284; (b) Dicynodon sp.

S.A.M. No. 10081; (c¢) Dicynodon grimbeeki (after Camp & Welles, 1956);
(d) Dicynodon sp (after Boonstra, 1968).

The deepening of the snout below the level of the basicranial axis is in
effect a lowering of the palate and feeding plane. As can be seen in Figures 52
and 53, this deepening has taken place below the level of the nostril, the position
of which, in both Lystrosaurus and Dicynodon, remains on a more or less constant
level in relation to the basicranial axis. In consequence, the premaxilla in
Lystrosaurus is greatly enlarged and deepened, and the vomer now forms a deep

222 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 53. Comparison of the skull of Lystrosaurus with that of a Permian
dicynodont. (a) Lystrosaurus declivis, Nat. Mus. No. C.403; (6) Dicynodon sp.,
S.A.M. No. 8784.

septum. The deepest part of the skull is at the level of the canine tusks and the
vomer-premaxilla suture.

The very deep snout and enlarged premaxilla have necessitated a new orien-
tation of the nasal passages (Fig. 54). In typical dicynodonts the palatal plate
of the premaxilla is thin and horizontally disposed, and the respiratory passages
lie in an anteroposterior direction, with the choanae only slightly below the
level of the nostril. In Lystrosaurus the premaxilla is enormously thickened below
the nasal aperture, thus displacing the internal nares far ventrally. The direction
of the respiratory passages thus became dorsoventral rather than antero-
posterior. Furthermore, a choanal tube leading from the nasal capsule to the
internal nares, such as was suggested for the Gorgonopsia by Kemp (1969),
would, in comparison with other dicynodonts, have been considerably elongated
in Lystrosaurus.

The remainder of the skull has not followed the deepening of the snout to
the same extent, with the result that the palate of Lystrosaurus is divided into
two planes which meet at an angle at the level of the caniniform processes. The

Fig. 54. Comparison of the snout of Lystrosaurus with that of Permian dicynodonts.
Parasagittal views of (a) Dicynodon sp., S.A.M. No. 10081 (from serial sections) ; (b) Lystro-
saurus declivis, S.A.M. No. K.1284 (from serial sections); (c) Kingoria nowacki (after Cox,

1959).

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 223

anterior plane is formed by the palatal surface of the premaxilla and slopes up
and forwards. The plane of the choana, which is formed by the ventral sur-
faces of the palatines and pterygoids, posteriorly slopes up and backwards
(Figs 2, 52, 54). With the skull held parallel to the reference plane, the choana
faces backwards and down rather than purely ventrally as in more primitive
dicynodonts.

Shortening within the skull

Watson (1912) recognized that the characteristic skull form of Lystrosaurus
was achieved, at least in part, by shortening of the skull, instead of down-
turning of the face on the rest of the skull, and stated that in this way the animal
retained lengthened temporal muscles, enabling it to swing back its shortened
jaw through practically go°.

Again in lateral and parasagittal view, it is immediately seen that con-
siderable shortening of the skull has taken place in Lystrosaurus in comparison
with other, earlier dicynodonts. The postpineal region of the skull roof and the
temporal fossae are much shorter than in other dicynodonts, and sectioning
reveals that the basicranial axis, including basioccipital, basisphenoid and
parasphenoid, is greatly reduced in length. Thus in Figure 52 the presphenoid
in both Dicynodon grimbeeki and the 8.A.M. dicynodont lies well in advance of
the internal openings of the internal carotid arteries in the hypophyseal region.
In Lystrosaurus on the other hand, the presphenoid lies immediately anterior
to the carotid artery canals and hypophyseal region, and above the interptery-
goidal suture. Similarly, the orbitosphenoid in Lystrosaurus lies just anterior to
the parietal foramen and internal carotid canal and directly above the presphe-
noid, whereas in Dicynodon and Emydops this ossification is situated far forward
in the skull.

The shortening of the basicranial axis has brought about changes in the
hypophyseal region. In typical dicynodonts the sella turcica is shallow and
extends some way back from the internal openings of the carotid canals. In two
mechanically prepared braincases of Cistecephalus zone dicynodonts, $.A.M.
5600 and 11075 (Fig. 55a) the sella turcica is relatively deep and there is a
dorsum sellae formed by the basioccipital. In Lystrosaurus (Fig. 556) on the other
hand, there is no impression on the basisphenoidal floor of the braincase behind
the internal carotid canal. Furthermore, shortening of the basicranial axis has
resulted in compression of the hypophyseal region as a whole, so that the
internal carotid canals open into the braincase just anterior to the pilae antoticae
of the prootics. If the hypophysis filled the sella turcica in Dicynodon, as it seems
to have done, and if the relative size of the hypophysis is the same in Lystrosaurus
and Dicynodon, then the hypophysis of Lystrosaurus could not have maintained
the relationships with the braincase which were present in Dicynodon. Either
the hypophysis extended far dorsally and retained a very small area of contact
with the basisphenoid, or it was partially contained in the basicranial pit
(Figs 2, 12, 55) between the basisphenoid and basioccipital. This pocket, which

224 ANNALS OF THE SOUTH AFRICAN MUSEUM

BAS

(b)

Fig. 55. Comparison of the hypophyseal region of Lystrosaurus and
a Permian dicynodont. (a) Dicynodont sp., S.A.M. No. 5600;
(6) Lystrosaurus sp., S.A.M. No. 11180. Anterodorsal views.

is continued ventrally as an unossified zone, is a constant feature in Lystrosaurus,
and its shape strongly suggests that it housed a soft body of some kind. If the
pit did indeed house a portion of the hypophysis, the basioccipital would have
formed a dorsum sellae.

Boonstra (1968), however, suggested that in his sectioned Dicynodon the
sella turcica (and therefore the hypophysis) was small. If this were so in Lystro-
Saurus, and the hypophysis did not reach back to the basicranial pit, then the
basisphenoid would have formed a floor for the body behind the internal
carotid opening. In this case no distinct sella turcica was present in Lystrosaurus.

In ventral view the shortening of the skull has caused the changes in the
pterygoid region illustrated in Figure 56. When the skulls of Emydops and
Lystrosaurus are brought to the same basal length, it can be seen that the choana,
including the interpterygoidal fossa or vacuity of Lystrosaurus is slightly shorter
than in Emydops (Lystrosaurus 32:6°% of basal length, Emydops 36-7°% of basal
length). The chief difference between the two types in this region is, however,
the structure of the interpterygoidal vacuity and the position of the parasphenoid
and vomer. In the endothiodontid genera Emydops and Palemydops the posterior
portion of the relatively broad median plate of the vomer is recessed into the
choana and lies far above the level of the ventral pterygoidal and palatine
border of the choana. The interpterygoidal vacuity is wide and extends far

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 225

Fig. 56. Comparisons of palates of (a) Emydops sp., B.P.I. No. 2642;
(6) Lystrosaurus declivis Nat. Mus. No. C. 403.

forward, terminating between two posteriorly diverging plates of the vomer,
which lie medially to the anterior flanges of the pterygoids. This condition is
similar to that found in Dicynodon grimbeeki (Agnew, 1959). Dorsally to the
interpterygoidal vacuity runs the parasphenoidal rostrum, visible in ventral view
as a broad bar forming an incomplete roof for the interpterygoidal vacuity.

In Lystrosaurus the entire palate has migrated ventrally to accompany to
some extent the downgrowth of the snout. This ventral migration is more
pronounced anteriorly than posteriorly, so that the plane of the choana (see
above) lies at an angle to the premaxillary palatal surface. The vomer, accom-
panying the pterygoids and palatines, has become a thin vertical sheet of
bone, lying approximately in the same plane as the lateral borders of the
internal nares. Furthermore, with reduction in the length of the basicranial
axis, the interpterygoidal vacuity has become a shortened and lanceolate fossa,
clearly demarcated by the vomers in front and the interpterygoidal plate
behind. In ventral view the interpterygoidal fossa has therefore become distinct
and well separated from the internal nares.

According to Cruickshank (1967) the ‘interpterygoidal space’ of Lystro-
saurus is retained as a typical feature in later Triassic dicynodonts such as
Tetragonias and Kannemeyeria, this being one of the factors which led him to
believe that a species of Lystrosaurus might have given rise to these later dicyno-
dont groups. In a further (1968) publication dealing with this region in
dicynodonts, he maintained that Triassic dicynodonts, with the Lystrosaurus
type of interpterygoidal vacuity, can be separated from their Permian predeces-
sors by comparison of the length of the interptergygoidal vacuity relative to
the length of the internal nares. He found that in Permian dicynodonts the
length of the vacuity was always greater than 60% of the internal nares, while
in Triassic forms it was always less than 60%. The possible significance of these

226 ANNALS OF THE SOUTH AFRICAN MUSEUM

points will be more fully discussed at a later stage.

Together with these changes in the Lystrosaurus palate, the parasphenoidal
rostrum has lifted above the dorsal opening of the interpterygoidal fossa to
extend dorsally as a pair of thin vertical sheets of bone closely surrounding the
presphenoid. In lateral view a fenestra is visible between the dorsal border of
the pterygoid and the ventral edge of the parasphenoid.

In spite of the deepening of the parasphenoid and vomer, and the shorten-
ing that has taken place in this region, the basic relationships between the two
bones in Permian dicynodonts are still maintained in Lystrosaurus, and the
parasphenoid rostrum is clasped between the diverging wings of the vomer in
the same way as in Pristerodon (Barry, 1967) and other dicynodonts (Fig. 52).
However, in Lystrosaurus the line of contact in the median plane between vomer
and parasphenoid is at an angle of approximately 40° to the reference plane of
the skull, whereas in typical dicynodonts the line of contact is parallel to the
reference plane.

Relationships of the brain

In Figure 57 the endocranial casts of a Permian dicynodont and of Lystro-
saurus, reconstructed from serial sections, have been compared. Olson (1944)
and Boonstra (1968) have figured similar endocranial casts.

Fig. 57. Comparison of endocranial cast

of (a) Dicynodon sp., S.A.M. No. 10081

(from serial sections); (b) Lystrosaurus

declivis, S.A.M. K1284 (from serial
sections. )

CRANIAL MORPHOLOGY OF THE DIGCYNODONT GENUS LYSTROSAURUS 227

In typical dicynodonts the brain appears to have filled the posterior por-
tions of the braincase and, in front of the prootics, extended up to the pineal
foramen and down to the sella turcica. Anterior to this the cerebral hemispheres
were supported by the lateral flanges of the orbitosphenoid, and the olfactory
tracts extended far forwards on each side of the mesethmoidal septum. In an
endothiodontid such as Emydops the brain lay more or less horizontally from
medulla oblongata to the cerebral hemispheres. In Lystrosaurus the deep,
shortened skull necessitated a dorsoventral expansion of the brain in front of
the prootics, reaching the pineal organ dorsally and the hypophysis ventrally.
Anterior to this the new, relatively dorsal position of the orbitosphenoid and
its proximity to the pineal organ indicates that the cerebral hemispheres were
located far dorsally in relation to the medulla oblongata, and relatively closer
to the hypophysis-pineal organ plane. The brain thus assumed an S-shape, and
was higher than it was long. This S-shape is also apparent in Edinger’s (1955)
illustration of a Lystrosaurus endocranial cast.

The adductor musculature

As a result of the changes in proportion undergone by the skull, the external
adductor musculature in Lystrosaurus underwent changes which produced a
new distribution of forces during the masticatory cycle. Crompton & Hotton
(1967) have stated that there is no difference in the angle of pull of the adductor
muscles on the mandibular axis in Emydops and Lystrosaurus, but all the speci-
mens at my disposal indicate that in Lystrosaurus there was an increased vertical
component of force during the masticatory cycle. In Figure 58 lateral views of
Emydops, Dicynodon and Lystrosaurus are illustrated, in each case with the mandi-
ble in the adducted position. Alongside each skull is a reconstruction of the
external adductor muscle masses as they would have appeared with the mandi-
ble in this position. It is immediately clear that the average angle of pull by the
adductors on the jaw axis becomes progressively more vertical in the series
Emydops — Dicynodon— Lystrosaurus. Comparison between several specimens of
Lystrosaurus shows that within the genus the average angle of pull remains
virtually constant.

The condition in Dicynodon may be explained fairly simply by reference to
Figures 58 and 59. In Figure 58 the skulls of Emydops, Dicynodon and Lystro-
saurus have been brought to the same basal length, and it can be seen that in
comparison with Emydops the Dicynodon skull has been slightly deepened overall
below the reference plane, the mandible being consequently ventrally dis-
placed. Any such displacement would automatically result in an increased
vertical angle of pull by the adductor muscles. Thus in Figure 59 the average
angle at A is 18°, as compared with 25° at Aj.

In Lystrosaurus (Fig. 58) the skull has deepened to an even greater extent
below the reference line. The quadrate is relatively lower than in Emydops or
Dicynodon, and the snout has dropped ventrally to a considerable extent. The
lowering of the anterior palatal region would theoretically increase the oblique

228 ANNALS OF THE SOUTH AFRICAN MUSEUM

(a)

Fig. 58. Comparison of skull and adductor musculatures of (a) Emy-
dops, (b) Dicynodon and (c) Lystrosaurus.

Fig. 59. Schematic repre-

sentation of the effect on

the adductor musculature

of simple lowering of the >
jaw axis.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 229

Fig. 60. Schematic representation of the
effect on the jaw adductor musculature
of snout deepening in Emydops.

component of force on the dentary when the jaw approaches the adducted
position.

In Figure 60 the skull of Emydops is illustrated, with three hypothetical
lines of force exerted by the external adductor muscle on an anterior hypothe-
tical point, A, on the jaw axis BA. If the snout is produced ventrally, rotating
the jaw axis 15° and without any shortening or deepening of the orbitotemporal
region taking place, then the average angle of pull by the adductor muscles at
point A on the axis decreases from 25° to 17°, and the vertical component of
force exerted during jaw elevation is considerably decreased, while the hori-
zontal component, responsible for retraction, is proportionally increased. If it
were necessary for the animal to preserve a minimum vertical component in
the total external adductor force in order to ensure a certain minimum amount
of pressure from the mandible against the palate, then it is conceivable that
shortening of the posterior moiety of the skull could take place to compensate
for the lowering of the palate. In Figure 61 the effect of lowering the palate

Fig. 61. Schematic representation of the effect on the
dicynodont jaw adductor musculature of snout deepen-
ing (A—A,) and skull shortening (B—B,).

230 ANNALS OF THE SOUTH AFRICAN MUSEUM

from A to A, is diagrammatically illustrated, as well as how shortening of the
posterior half of the skull in the sequence B—B, —B, compensates for this effect.
If A is dropped to A,, the average angle (26°) of GA, DA and EA on the jaw
axis BA changes to a value of 23° at A, on the line BA,. There is thus a con-
siderable change in the position of A, but a small change in the average angle
of pull on the jaw axis.

If B migrates to B, the average angle at A, becomes 25°, while if B, moves to
B, the angle becomes 26°. It is therefore clear that a substantial forward migra-
tion of B is necessary to cancel the 3° difference in the angle of pull caused by
dropping A to A,. In terms of skull morphology this means that a substantial
lowering of the snout produces a small increase in the oblique component of
the external adductor musculature, which in turn can be compensated for
only by a fairly substantial forward migration of the posterior areas of adductor
muscle attachment (Fig. 62).

However, if forward migration of the posterior areas of attachment of these
adductor muscles involves a forward displacement of the quadrate (as indicated
in Figure 62), the jaw axis would undergo a series of new orientations, which
could be compensated for only by an increase in the height of the muscle
attachment areas. This skull deepening would assist in producing the original
angle of pull by the adductors on the mandibular axis, but would considerably
increase their length. This lengthening effect is shown in Figure 62, where
simple dropping of the snout results in an average increase of 20% in the
muscle length. If shortening of the temporal region takes place, the average
length of the muscle fibres returns to the original value, but now the distribu-
tion of long and short fibres is changed. Thus, in the primary stage of Figure 62,
before lowering of the palate or skull shortening took place, the posterior, more
oblique fibres were longer than the anterior, more vertical fibres. After lowering
of the palate and skull shortening, precisely the reverse is the case.

The characteristic skull proportions of Lystrosaurus were arrived at by deepen-
ing of the snout, and lowering of the anterior palatal region, and shortening
and deepening of the temporal region. Combinations of the various effects on

Fig. 62. Schematic representation of the effect on the
jaw adductor musculature of snout deepening and
skull shortening in Emydops.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 231

the adductor musculature in the above hypothetical cases of skull shortening,
skull deepening, etc., should therefore be found to apply to Lystrosaurus.

Simple shortening of the skull in Lystrosaurus would help to compensate for
deepening of the snout, and, together with deepening of the posterior part of
the skull, would return the average angle of pull by the adductor muscles on the
dentary to the original value. However, as shown above, additional deepening
of the postorbital region of the skull resulted in an increased vertical component
in the adductor mass.

The distribution of long and short fibres in the external adductor muscles in
Lystrosaurus and Emydops has been illustrated in Figure 63, where the mandibles
have been drawn to the same length. With the jaw in the adducted position,
it is apparent that in Lystrosaurus the more anterior muscle fibres, which exert
a more vertical pull on the mandibular axis, have become lengthened in
comparison with the same fibres in Emydops. Analysis of the adductor muscle
reconstructions in Figure 58 shows that in Lystrosaurus the most oblique fibres,
represented by the line c, are shorter than the most vertical fibres, represented
by line a. In Dicynodon and Emydops these two sets of fibres are of approximately
the same length. In Lystrosaurus, therefore, the longest fibres of the adductor
muscles exert force on the dentary at a greater angle than in Dicynodon or
Emydops.

Using these anatomical and functional comparisons, it should be possible
to arrive at a logical evolutionary sequence of events leading from some ances-
tral Permian dicynodont form to a typical species of Lystrosaurus.

Fig. 63. Comparison of long and short fibres of the jaw adductor muscula-
ture of Emydops and Lystrosaurus with jaws in adducted position.

DERIVATION OF THE LYSTROSAURUS SKULL PROPORTIONS

It is generally accepted that Lystrosaurus led an aquatic or semi-aquatic mode
of life, and incomplete ossification of the tarsalia and the retention of embryonic
cartilage between the elements of the neurocranium can be regarded as indica-
tions of this. Watson (1912) reconstructed Lystrosaurus as a creature capable of
strong swimming action, on the grounds that the extended ischium provided
attachment for strong and extensive ischio-femoral muscles, and considered
that the shallow lower part of the pelvis indicates that the animal did not

232 ANNALS OF THE SOUTH AFRICAN MUSEUM

require strong adductor muscles to support the weight of its body. Flexibility
of the vertebral column also suggests arching of the back during the stroke of
the hind limb.

Furthermore, it seems most probable that the characteristic skull form of
Lystrosaurus was arrived at primarily in response to a need for lowering the
feeding level of the skull deeper into the aquatic medium. Since the type of
masticatory cycle found in Lystrosaurus is essentially similar to that found in
earlier dicynodonts such as Dicynodon feliceps (Crompton & Hotton, 1967) this
change was probably not related to an entirely new diet, but rather to the
changed accessibility of a semi-submerged food source.

This primary impetus in the evolution of Lystrosaurus resulted in snout
deepening, which took place below the level of the nasal aperture and chiefly
involved the premaxilla, maxilla and vomer. In this way the premaxillary
portion of the palate was produced far ventrally, with the deepest portion of
the skull being at the level of the caniniform process. With the condyle-nostril
plane of the skull horizontally aligned, the portion of the premaxillary palate
anterior to the caniniform process faces antero-ventrally, while the choana,
behind the caniniform process, faces posteroventrally. The nasal capsules
became modified to allow a new orientation for the nasal passages, which in
Lystrosaurus ran vertically from the nasal aperture to the choana.

However, any tendency for such lowering of the feeding plane would have
two immediate results. First, the mandible, when adducted, would lie at an
angle to the reference plane of the skull, in a position equivalent to incomplete
adduction in Emydops. In the second place the angle of pull by the external
adductor muscles on the jaw axis would become smaller, i.e. the direction of
pull would become more oblique. The consequence would be a reduction in
the arc through which the mandible could be rotated during the masticatory
cycle, that is, the mandible would have been capable of providing a very limited
gape only.

This is because there is a maximum possible gape in dicynodonts, reached
when the external adductor muscles start exerting pull through and behind the
quadrate-articular contact (Fig. 64). The extent of the gape is determined by
the origin and insertion of the various fibres of the external adductors. In the
masticatory cycle the jaw could be swung down by the depressor mandibulae
muscle until the extended fibres of the posterior part of the adductor muscles
came close to the quadrate-articular contact, and thus began to lose their effi-
ciency as jaw elevators. If the mandible were dislocated through the adductor
fibres pulling behind the condylar contact, tremendous stresses would be exerted
on the jaw joint and the major part of the muscle mass rendered ineffective. It
is clear that the lateral external adductor muscles would be the delimiting
factors in the gape size, since, with their origins close to the quadrate and their
insertions well below the dorsal edge of the mandible, they would be the first
fibres to approach the quadrate-articular contact during jaw depression.

In Figure 65 Emydops and Lystrosaurus are represented with their jaws depres-

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 233

Fig. 64. Model of hypothetical
dicynodont illustrating factors
which determine maximum gape.

sed to the maximum possible extent, as determined by the lateral external
adductor muscle. The lines CX, DX and EX are hypothetical lines of traction
exerted by fibres of the lateral external adductor muscle on the jaw axis AB.
Angle FGH represents the extent to which the tip of the premaxilla has des-
cended below the reference plane.

As shown above, lowering of the snout in a dicynodont results in a relatively
depressed position of the mandible when adducted. If there were no changes
involving the areas of origin of the adductor externus muscles, a very limited
gape would result. To counteract this effect, deepening and shortening of the
temporal region took place in Lystrosaurus simultaneously with the deepening
of the snout. Deepening of this posterior part of the skull served to provide
higher points of origin for the adductor muscle fibres, and shortening meant
that these points of origin came to lie relatively closer to the ventral insertion -
areas. In this way the adductors became less obliquely inserted on the mandible
when in the adducted position, and could allow the mandible to be swung
relatively further back than in a form such as Emydops, and still retain
sufficient moment on the jaw axis to be able to elevate the jaw rapidly and
effectively.

Figure 65 shows some interesting comparative values for Emydops and
Lystrosaurus when both are seen with the mandible in the maximum depressed
position. In Emydops the antero-ventral tip of the premaxilla lies 6° below the
condyle-nostril reference plane of the skull (i.e. angle FGH = 6°). Lystro-
saurus has lowered its premaxilla to 14° below this. To compensate for the
lowering, the mandible in Lystrosaurus has been allowed to drop 11° below the
jaw of Emydops, to make possible a maximum gape (H—B) of 47°, in which
position the average angle of pull by the lateral external adductors on the
mandible is 39°. In Emydops the maximum gape (H—B) was 48°, and in this

234 ANNALS OF THE SOUTH AFRICAN MUSEUM

position the average angle of pull by the lateral external adductor muscle was
also 39°.

If both skulls are aligned along the same reference plane, both mandibles
can be rotated back to make possible an equally large gape, but because of the
relatively low position of the palate in Lystrosaurus, the mandible had to be
swung relatively farther back, and consequently allowed Lystrosaurus to execute
forward scooping movements with the jaw during the first stages of elevation.

With the jaw in the position of maximum gape, the temporal muscle fibres
are stretched to the greatest possible length required by the masticatory cycle.
This length is well within the maximum to which a muscle fibre can stretch.
Haines (1934) has shown that a human muscle fibre can contract by about 57%
of its extended length, Le. a fibre can stretch by about 132% of its contracted
length. Haines (cited by Parrington, 1955) later confirmed these values by
means of tests on dog muscle fibres. Parrington (1955) has calculated the extent
to which fibres of the jaw adductor muscles would have to stretch to allow suffi-
cient gape in the Gorgonopsia, and by making allowance for the possible
presence of non-contractile tendons in the total muscle length, has assumed
that the muscles could extend by 80°%% of their total contracted length.

Using the value of 80% possible extension, it can be calculated that in
animals such as Lystrosaurus and Emydops, the external adductor muscles, which
inserted far forward on the mandible and were thus of considerable length even
when fully contracted, were theoretically capable of far greater extension than
required for maximum gape, as illustrated in Figure 65. The same is true of
fibres of the anterior pterygoideus muscle.

Ewer (1961) supposes that the increase in height of the posterior part of
the skull in Daptocephalus is an adaptation for increasing the length of the tem-

Fig. 65. Comparison of the skulls of Emydops and Lystrosaurus with mandibles in the
position of maximum gape.

CRANIAL MORPHOLOGY OF THE DIGYNODONT GENUS LYSTROSAURUS 235

poral muscle fibres, to allow the jaw to be opened adequately. However, if the
above values for muscle contraction and extension are accepted, the adductor
muscles in any dicynodont are of sufficient length, due to their anterior insertion
on the dentary, to provide an adequate gape without additional lengthening
being necessary.

The distinctive skull proportions of Lystrosaurus therefore probably arose
as a result of a new aquatic or semi-aquatic mode of life, involving changed
accessibility of the food source. The consequent lowering of the feeding level
in the skull was of necessity accompanied by shortening and deepening of the
temporal region of the skull, to provide the necessary new positions of origin
of the temporal external adductor musculature. The maintenance of a constant
maximum gape was of overriding importance in this regard.

SECTION V. VARIATION IN THE SKULL OF LysTROSAURUS AND
THE TAXONOMY OF THE GENUS

The far-reaching and obviously very successful changes which produced
Lystrosaurus from a dicynodont ancestor have resulted in a skull form remarkably
different to that of other dicynodonts. Moreover, within the broad framework
of cranial features which characterize the genus, are several variations in both
proportion and structure, indicating that the success of the new skull form did
not prevent the genus from radiating into several species in which the skull
pattern is modified. To date 24 South African species of Lystrosaurus have been
described, and a problematical associated genus, Prolystrosaurus, with two
species, has been created.

The first specimen of Lystrosaurus was described in 1859 by Huxley as
Dicynodon murray, but Owen (1860) recognized that new forms similar to
D. murrayi warranted the formation of a new genus, Ptychognathus. This genus
included the new species declivis, latirostris and verticalis. In 1862 he further
described P. alfredi and in 1876 added P. boopis and P. depressus, and described
a new species of Dicynodon, D. curvatus, which Broom in 1932 placed into the
genus Lystrosaurus.

It became apparent, however, that the name Ptychognathus had been pre-
occupied by Stimpson in 1858 for a crustacean, and Lydekker in 1890 intro-
duced a new name, Ptychosiagum, for all the specimens of Ptychognathus. However,
Seeley (1898) maintained that if the name Ptychognathus should be withdrawn,
only Lystrosaurus (Cope, 1870) could take its place since Lystrosaurus frontosus
was clearly a Ptychognathus. Seeley further proposed two subgenera for Ptycho-
gnathus (or Lystrosaurus). These were Rhabdotocephalus (Rhabdocephalus of Broom,
1932, and Brink, 1951), with type species R. mcCaigi, and Mochlorhinus, with
type species M. platyceps.

Broom (1903) used the generic name Lystrosaurus when describing some
specimens in the Albany Museum, and in 1907 he introduced a new species,
L. anderson. L. oviceps (Haughton, 1915) and L. putterilli (Van Hoepen, 1915)

236 ANNALS OF THE SOUTH AFRICAN MUSEUM

were the next new species, and in 1916 Van Hoepen further described L.
breyeri, L. jorissent, L. jepper, L. theileri, L. wagert and L. wagnert.

In 1917 Haughton maintained that Dzcynodon strigops of Broom (1913) was
related, and ancestral, to Lystrosaurus, and placed it, together with a new species,
natalensis, in a separate genus, Prolystrosaurus. Broom in 1940 described L.
rubidgei and in 1941 L. bothai, while Brink (1951) and Toerien (1954) described
L. amphibius and L. primitivus respectively.

There have been several attempts at arranging these species into natural
groups, and various synonomies have been declared among them. In 1907,
Broom suggested the division of the genus into two branches, one to accom-
modate the large forms such as L. mcCaigi, L. platyceps and L. andersoni, and the
other to include the smaller species. In 1932 he again stressed the need for
reorganization of the genus, and pointed out that any collection of Lystrosaurus
specimens can be divided into males and females, according to the presence or
absence of ridges and bosses on the skull roof. He placed nearly all the pre-
viously described species under L. murrayi, but allowed L. curvatus (Dicynodon
curvatus of Owen, 1876), L. platyceps, L. mcCaigi and L. andersoni. He mentioned
the possibility of L. platyceps being the female of L. mcCaigi, but figured another
specimen as the presumed female mcCazgi. He claimed that Haughton (1917) had
based his genus Prolystrosaurus on the crushed skull of a young female, probably
of L. murrayt.

In 1951 Brink enlarged on Broom’s (1907) proposal for the separation of
the larger species from the smaller ones. He added L. putterilli and the new
L. amphibius to the larger forms and stated that these species were characterized
by the extent to which the dorsal orbital borders protruded above the general
level of the skull roof. The smaller species such as L. murrayi, L. declivis and
L. verticalis fell into a separate branch. He regarded L. oviceps as the most primi-
tive species of the genus, connecting Lystrosaurus with Dicynodon. He recognized
12 South African species of Lystrosaurus and suggested that, since Prolystrosaurus
did not represent a natural ancestor of Lystrosaurus, but was in fact probably
allied to L. murrayi, the species strigops and natalensis be referred to Lystrosaurus.
Brink at the same time merged the species alfredi, depressus and boopis with
Lystrosaurus declivis, and the species frontosus, jeppei, jorisseni, theilert, wagert,
wagnert and latirostris with Lystrosaurus murray. He included L. breyeri under
Lystrosaurus oviceps.

SKULL VARIATION WITHIN THE GENUS

The organization of this genus into different species involves the problem
of separation of variations which could be random or due to sex, age or distor-
tion from those which could be regarded as specific differences. The success of
any such attempt*must depend on the number of specimens available for
comparison, and on their state of preservation. Ideally, only perfect, undis-
torted specimens should be considered, but it is unfortunately true that such
specimens are rare in even the best collections. Added to this is the fact that it

GRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 237

is very often impossible to determine whether a skull is distorted in some way
without almost complete preparation of the specimen. However, present infor-
mation, based on the anatomical evidence of the previous section, does permit
some conclusions to be drawn.

The genus Lystrosaurus can be defined as follows:

Small to large dicynoedonts. A single pair of tusks in both sexes.
Snout steeply downturned, with extensive premaxillary development.
Nostril situated relatively high in the skull. Orbit large, temporal
fossa greatly shortened. Post-pineal region of the skull table short.
Exoccipital condyles projecting further posteriorly than basioccipital
condyle. Prominent ventral transverse ridge between the basioccipital
tubers. No floccular fossa. Characteristic pit-shaped unossified zone
between basioccipital and basisphenoid. Trabecular region anterior
to the hypophyseal region short. Presphenoid immediately anterior
to the internal carotid canals. Vomer and premaxilla form deep
median septum. Labial fossa present. Ectopterygoid absent. Pterygoid
meeting maxilla. Sharp cutting edge on the maxilla anterior to the
canine tusk. No notch or break in profile on maxillary margin.
Zygomatic arch steeply inclined. Choanal plane at angle to premaxil-
lary palatal plane. Excavated facet on stapes.

While all specimens share the above characteristics, the following varia-

tions appear to be significant:

Tes

Extent of premaxillary and maxillary snout development.

2. Size of tusk.
3. Presence or absence of transverse frontonasal ridge.
4. Presence or absence of frontal tuberosities and bosses.
5. Presence or absence of prefrontal bosses.
6. Presence or absence of longitudinal ridges on the snout.
7. Nature of frontonasal suture.
8. Nature of transition between frontal and nasal planes.
On the basis of several of these variations two skull types can be distin-
guished:
A B
1. Strongly developed snout Moderately developed snout
2. Large canine tusks Weak canine tusks
3. Frontonasal ridge Frontonasal ridge absent
4. Frontal tuberosities Frontals smooth
5. Prefrontal bosses Prefrontal bosses absent or weak
6. Longitudinal snout ridges Snout smooth
7. Frontal and facial plane meet Frontal and facial planes smoothly
at angle rounded

Species with typical type A skulls include L. declivis and L. murrayi, while

species with the cranial features listed under B include L. curvatus and L. platy-

238 ANNALS OF THE SOUTH AFRICAN MUSEUM

ceps. Basically the skulls in both groups are similar, and the differences are due
to a greater or lesser degree of modification of common structures, without
change in the fundamental and characteristic skull form. As shown in succeeding
pages, no formal systematic status should be conferred on these ‘species groups’.

THE SEXUAL DIMORPHISM PROBLEM

The fact that all specimens of Lystrosaurus examined fall naturally into
either one or the other of the two ‘species groups’ suggests two possibilities,
namely, that either there were two distinct lines of development within the
genus, or that a fairly consistent type of sexual dimorphism was present in most
or all of the species.

The possibility of two phylogenetically distinct groups being present within
the genus has been pointed out by Seeley (1898), Broom (1907) and Brink
(1951). Seeley recognized that the nature of the junction of the facial surface
with the dorsal interorbital surface of the skull permitted a separation to be
made. He stated that whereas in Ptychognathus the facial or snout surface was
separated from the dorsal skull surface by an angular ridge, in Mochlorhinus
the two surfaces were smoothly rounded into each other. Rhabdotocephalus
differed from both of these in that the facial surface of the skull met the skull
roof at an angle, but without a transverse ridge.

Seeley’s (1898) suggestion has merit in that the factors he used to divide the
genus appear to be valid. At that time, however, the taxonomic value of the
groups must have been uncertain, and Seeley’s proposed subgenera did not
meet with much support (Broom, 1903). In the case of Rhabdotocephalus (Lystro-
saurus mcCaigi) lateral compression could have obliterated any transverse ridge,
and have produced instead the singular sharp longitudinal ridges on the anterior
frontal surface.

As shown above, Broom (1907) proposed that the large forms of Lystro-
saurus be separated from the small ones, and Brink (1951) enlarged on this idea.
However, the criteria used by Brink to distinguish groups of species, 1.e. size
and the height of the dorsal border of the orbit above the skull roof, are not
reliable, and may well be explained in terms of age or distortion. Lateral com-
pression of the frontal region of the type skull of L. mcCaigi, for example, has
produced artificially raised supraorbital ridges. Furthermore, Brink did not
separate the ridged skulls from the smooth, and both types are included in each |
of the two groups in his scheme of the interrelationships of the species. He regards
L. oviceps as the most primitive member of the genus, but further preparation
of the type skull of this species has revealed considerable crushing, and the
species is probably allied to L. declivis.

On the other hand, there is also a case for the possibility of the skull
differences being due to a fairly constant sexual dimorphism within the genus.
This has been suggested by Broom (1932) and Tripathi & Satsangi (1963).
The possibility is strengthened by the fact that the characters used to differen-
tiate between the two groups are similar to those which distinguish male and

CGRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 239

female individuals of recent animal species. Thus Cave & Steel (1964) showed
that sexual differences in the skull of the Colobus monkey were differences in
the relative development of existing structures, and that sex could be deter-
mined by comparing the size of the supraorbital ridges, canine tooth, presence
or absence of a sagittal crest and the shape of the palate. Ashton & Zucker-
mann (1950) found that the sexes of the great apes differed in the size of the
canine, and Ashton (1956) showed that sexual dimorphism entered after
puberty, when the new canine appeared and especially rapid growth of the
temporal and nuchal muscles took place in the male. The degree of sexual
dimorphism in the various primate groups varies considerably (Ashton, 1956;
Hooijjer, 1952). Similar dimorphism occurs in the elephant (Perry, 1954, 1955)
and the mountain sheep (Geist, 1966).

The possible effects of sexual dimorphism on the cranial osteology of
dicynodonts were recognized by Owen in 1860 and 1876 when he discussed the
relationships of the tuskless Oudenodon with Dicynodon. Broom (1912) concluded
that the presence or absence of tusks in Dvaelurodon whaitst and Dicynodon
bolorhinus was due to sexual dimorphism, and in 1932 suggested the possibility
of sexual differences in several dicynodont species, among them Diucynodon
vanderbyli and Dicynodon whaitsi and, as shown above, stated that any group of
Lystrosaurus specimens can be divided into males and females on the nature of
the skull roof.

In 1957 Barry gave the problem a new approach and pointed out that on
evidence from recent mammals (Fraser, 1938; Ashton & Zuckermann, 1950;
Ashton, 1956) sexual dimorphism is not characterized by complete suppression
of any factor in one of the sexes, but rather that common characters are empha-
sized and more pronounced in one sex and reduced in the other. He found that
in the specimens of Dicynodon grimbeeki he investigated the males have strong
tusks, while tuskless specimens, previously regarded as females, still retain a
tooth bud in the maxilla. These apparently tuskless specimens may equally
well be immature males. Only individuals with weak snouts and tusks may
with any reasonable certainty be regarded as females. This view is apparently
supported by the specimens of Dicynodon jouberti which Broom (1905) and Boon-
stra (1948) had previously divided into males and females according to the
degree of canine tusk development.

Tripathi & Satsangi (1963) supported Broom’s (1932) division of Lystro-
Saurus into males and females, and in their definition of L. murrayz state:

‘Skull table highly variable, in male individuals fronto-nasal ridge well
developed, frontals ridged either by prominent tubercles or transverse
ridge; female skulls smooth with almost almond-shaped preparietals,
tending to be circular in adult individuals; in males a bony outgrowth
arises from the preparietal to meet the frontal tubercle’ (p. 16).

Neither Broom (1932) or Tripathi & Satsangi (1963) recognized that
there is a variation in tusk size, and that this variation is correlated with the

240 ANNALS OF THE SOUTH AFRICAN MUSEUM

differences in the nature of the skull roof.

There is clearly considerable support for the theory of sexual dimorphism
among dicynodonts and thus for Broom’s (1932) division of Lystrosaurus speci-
mens into males and females. However, essential for the feasibility of the theory
is that collecting at any given locality should reveal specimens of both types of
Lystrosaurus in comparable numbers and in more or less close association with
each other.

The Commonage at Harrismith, Orange Free State, presents a favourable
test locality. Various sites at this locality form part of the same horizon, and
specimens of Lystrosaurus are especially abundant and well preserved. Many
beautiful skulls have been obtained here in the past, mainly by the late Mr.
A. W. Putterill.

In early 1969 a field trip into the Karoo included a short period at Harri-
smith. Some excellent skulls, many with associated postcranial material, were
recovered, and these were subjected to preliminary preparation in order to
ascertain the number of specimens representative of each of the two groups of
Lystrosaurus. It was found that of 20 skulls thus examined, 16 fell into group A
(Broom’s males) and only one into group B (Broom’s females). Of three skulls
of more uncertain affinities, one probably belongs in group A and the other
two in group B.

Furthermore, of 14 good skulls from Harrismith in the collection of the
National Museum, Bloemfontein, only three definitely resort under group B
and would classify as females. Again, subjecting 20 identifiable skulls in the
South African Museum collection from Skerpioenkraal, Middelburg, to the
same process showed that only three specimens fell under group B (Broom’s
females).

Even though other localities in the Lystrosaurus zone should be found to
yield both types of Lystrosaurus in equal or near-equal numbers, the presence
of only a few localities such as Harrismith, where one variety greatly outnum-
bers the other, must cast doubt on Broom’s (1932) conclusions, while the
consistent preponderance of supposedly male over supposedly female specimens
in the areas tested is another factor difficult to explain. Furthermore, Lystro-
saurus has, in previous sections, been shown to be a basically primitive therapsid
genus, having retained a large proportion of reptilian characteristics, and the
presence here of a consistent and morphologically clear-cut sexual dimorphism
would surely be unusual. Therefore, until continued intensive collecting shows
that both types of Lystrosaurus are found in most localities where groups of
contemporaneous individuals occur, it seems safest to assume that the two
groups characterized on p. 237 represent phylogenetically distinct “species
groups’ within the genus.

EFFECTS OF AGE AND DISTORTION ON THE LYSTROSAURUS SKULL FORM

Since size of specimens of Lystrosaurus varies over a fairly wide range, the
question of the influence of age on the nature of the skull morphology arises.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 241

Kitching (1968) has illustrated a convincing growth series of a species of
Lystrosaurus, here considered to be L. curvatus. The smallest specimens in this
series, B.P.I. 407 and 408, have a basal length of 42 mm and 45 mm respectively,
and tusks have not yet erupted. Comparable in size to these rare little skulls
are two specimens, S.A.M. 3531 and K.1396, in which tusks have not yet
erupted. The former appears to be very similar to B.P.I. 408, while the damaged
prefrontal region of the latter makes a diagnosis impossible.

It is impossible to place such small specimens into either of the ‘species
groups on p. 237, since differences such as smooth frontal and prefrontal’
regions or transverse frontonasal ridges and frontal bosses appear to be estab-
lished at a slightly later age, represented by three specimens available for this
study, namely, S.A.M. K.1362, Nat. Mus. C.211 and T.M. R.19 with basal
lengths of respectively 73 mm, 84 mm and approximately 90 mm. Specimen
No. K.1362 has a newly erupted tusk and with its smoothly curved skull roof
is clearly distinguishable from the other two specimens, with larger tusks, clear
frontonasal ridges and frontal bosses. K.1362 (Fig. 67) is here considered to be
L. curvatus, while C.211 (Fig. 75) and R.19 are regarded as specimens of
L. murray and L. declivis respectively. (See also pp. 250 and 247.)

Moreover, individuals with smoothly curved skull roofs are known which
are larger than many individuals with frontonasal ridges and frontal bosses.
Thus, for example, the basal length of the skull of Nat. Mus. C.205, L. curvatus,
is 192 mm, making it well over twice the size of a specimen with frontal bosses
and frontonasal ridge such as Nat. Mus. C.ert.

Minor changes in the skull, such as a change in the relationships of the
nasals, may be attributable to age, and are discussed in the succeeding section,
but it seems unlikely that age is a factor in the determination of the major
differences in skull proportions within the genus.

While determining the skull form in the various species of Lystrosaurus,
special attention was paid to the possible effects of distortion. It was found that
in the majority of apparently well preserved specimens distortion could be
detected in the anteroventral orbital border, the postorbital —jugal—maxilla
contact in the zygomatic arch, the premaxilla—nasal contact and in the relative
positions of the presphenoid and orbitosphenoid. Thus in dorsoventral crushing
there is usually telescoping of the lacrimal, prefrontal and jugal in the region
of the lacrimal canal, together with ventral displacement of the orbitosphenoid
on to or alongside the presphenoid. At the same time it is usually apparent that
the nasals have slipped down behind the nasal process of the premaxilla, this
being reflected in distortion of the nasal aperture.

In another common type of crushing the skull roof has been forced forward
relative to the skull base. This is often difficult to detect, since only careful and
extensive preparation reveals any sign of distortion, these being, in the main,
forward displacement of the ventral tip of the postorbital over the jugal and
maxilla, and the anterior position of the orbitosphenoid relative to the presphe-
noid. Anteroposterior crushing is usually indicated by distortion in the palate,

242 ANNALS OF THE SOUTH AFRICAN MUSEUM

while lateral compression generally results in folding back of the posterior
squamosal flanges.

Analysis of imperfections such as these will usually indicate the nature of
distortion suffered by a particular skull, and allow a tentative reconstruction
of the original shape to be made. However, in this study use was made as far .
as possible only of skulls which were either uncrushed or had undergone easily
interpreted distortion. The sphenethmoid complex was regarded as the main
indicator of distortion, and in all cases of doubt the presphenoid and orbito-
sphenoid were exposed in order to determine their relative positions.

THE SPECIES OF LYSTROSAURUS

Lystrosaurus curvatus (Owen)
(Figs 27, 36, 37, 66, 67)

Dicynodon curvatus Owen, 1876.
Lystrosaurus curvatus Broom, 1932.
Lystrosaurus wageri, jorissent @ theileri Van Hoepen, 1916.

Type specimen: B.M.N.H. R.3792
Locality: Cradock, C.P.

Morphologically, this species appears to be the closest to the Permian
dicynodonts. The snout, while typically lystrosaurian, is not as far ventrally
produced as in some species of Lystrosaurus, and frontonasal and premaxillary
ridges and frontal bosses are absent. Among dicynodonts these latter features
appear to be confined to some of the more specialized species of Lystrosaurus.

The skull roof is smooth and the premaxillary plane curves over in a smooth
arc to meet the frontoparietal plane. Although a transverse frontonasal ridge
as such is absent, slight indications of a fold on the prefrontal may be present.

POF

Fig. 66. Lystrosaurus curvatus, Nat. Mus. No. C.29g. Skull in lateral
view.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 243

Frontal protuberances are absent and, in comparison with other species of
Lystrosaurus, snout and tusk development are not strong. The suture between
frontals and nasals lies on the roof of the skull in the general frontoparietal
plane and in the majority of specimens is irregular (Fig. 36). Each nasal con-
tinues posteriorly as a process between the two anterior diverging processes
of the frontal of its side. In a small percentage of individuals, however, the
frontonasal suture is almost straight and transverse.

Typical in this species is the shape of the ventral ramus of the squamosal,
which in all lystrosaurids is flared out laterally to provide a large area of
origin for the lateral external adductor muscle mass. In Lystrosaurus curvatus
this flange is produced posteriorly as well as laterally so that in a lateral ortho-
projection the occipital condyles are concealed behind the squamosal (Figs 66,
67).

L. wageri, jorissent and theilert have smoothly rounded skull roofs and are
best included under L. curvatus. It was not possible to determine whether these
forms show the posterior projection of the squamosal.

DEN. ANG lcm

Fig. 67. Lystrosaurus curvatus, S.A.M.
No. K.1284. Skull in lateral view.

Lystrosaurus bothai Broom

Lystrosaurus bothai Broom, 1941.

Type specimen: Rubidge Collection.
Locality: Rygerspoort, Cradock District.

This species appears to be related to both Lystrosaurus curvatus and the
next species, L. platyceps. The skull is not ridged and the snout is more strongly
developed than in L. curvatus, but less than in platyceps. Broom (1941) thought
that the species resembled flatyceps in the nature of the frontals, while Brink
(1951) thought that it compared with curvatus. The relatively narrow interor-
bital width in L. bothai is certainly reminiscent of L. curvatus, as is the frontonasal
suture, where the frontal extends down between the posterior process of the
nasals. :

The broad, anteriorly blunt preparietal in L. bothai is found in both L.
curvatus and L. platyceps.

244 ANNALS OF THE SOUTH AFRICAN MUSEUM

Lystrosaurus platyceps Seeley
(Figs 68, 69)

Lystrosaurus (Mochlorhinus) platyceps Seeley, 1898.
Lystrosaurus andersoni Broom, 1907.

Type specimen: Albany Museum.
Locality: Bethulie, Orange Free State.

This species is apparently the most advanced of those species with smooth,
Dicynodon-like skulls. The snout is relatively deeper than in either L. curvatus or
L. bothai. In lateral view the anterior facial surface is only very slightly convex
and the transition between facial and frontal planes is more abrupt than in
curvatus or bothai, although there is no ridge or angular, sharp division between
the two planes.

A feature of Lystrosaurus platyceps, setting it apart from L. curvatus, is the
inclusion of the entire nasal within the premaxillary facial plane, suggesting
that deepening of the snout, which involves the maxilla and premaxilla in
L. curvatus, has proceeded to the extent of involving the nasal in L. platyceps.
That this is probably not an age phenomenon is shown by the fact that the four
specimens of L. platyceps examined (e.g. S.A.M. 706 and T.M. R.27) were
smaller than several specimens of L. curvatus investigated.

Lystrosaurus anderson is included here on account of its smooth skull roof
and the inclusion of the nasals in the facial plane.

Resemblances between L. platyceps, L. curvatus and the apparently inter-
mediate L. bothai include the broad, approximately rectangular preparietal,
the interdigitating frontonasal suture, the lack of a transverse frontonasal ridge
and the absence of longitudinal ridges on the snout. These three species can
also be regarded as primitive in that, while they display the specializations of

Fig. 68. Lystrosaurus platyceps. S.A.M. No. 706. Skull in
lateral view.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 245

Fig. 69. Lystrosaurus platyceps.
S.A.M. No. 706. Skull in dorsal

view.

Lystrosaurus, they have retained the smooth, gently rounded skull roof which is
characteristic of Permian dicynodonts. They comprise group B on p. 237.

In the following species of Lystrosaurus there is a departure from this con-
dition and the skulls are characterized by the presence of certain pronounced
bosses and ridges on the snout and skull roof. These species comprise group A

on p. 237.

Lystrosaurus oviceps Haughton
(Figs 70, 71)
Lystrosaurus oviceps Haughton, 1915.
Lystrosaurus breyeri Van Hoepen, 1916.
Type specimen: S.A.M. 641.
Locality: Tarka River, Cradock District.

L. oviceps may be regarded as the most primitive of those species which
possess transverse frontonasal ridges and frontal bosses. It is the only species in
this group in which the facial surface of the premaxilla is not flat, and the
smoothly curved snout, sloping back to the frontonasal ridge, is reminiscent
of L. curvatus. The snout is, however, very strongly developed and bears a
prominent median longitudinal ridge. Since the snout and skull roof merge
smoothly into each other, the frontonasal ridge does not divide the facial from
the frontal plane. Two frontal tuberosities are present. The frontonasal suture
is mainly transverse, and the frontals do not project forward between the pre-
frontals and nasals, but a short median process formed by both frontals pro-
trudes forward for a short way between the nasals. This type of frontonasal
suture resembles that of some specimens of L. curvatus.

The type skull has undergone considerable crushing, and the occiput 1s

246 ANNALS OF THE SOUTH AFRICAN MUSEUM

PO.

v
Fig. 70. Lystrosaurus oviceps, S.A.M. No. 641. Skull in lateral
view.
displaced forward and up. In the undistorted state, therefore, the postorbital
region of the skull would have been longer than as illustrated by Haughton
(1915). In Figures 68 and 69 the skull is shown in the distorted condition. It
seems likely that L. oviceps is derived from L. curvatus.
Brink (1951) has placed L. breyert of Van Hoepen (1916) under L. oviceps
and, judging by the illustrations of Broom (1932), this is probably correct.

Fig. 71. Lystrosaurus oviceps. S.A.M. No. 641.
Skull in dorsal view.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 247

Lystrosaurus declivis (Owen)

Ptychognathus declivis Owen, 1860.
Ptychognathus latirostris Owen, 1862.
Ptychognathus depressus Owen, 1876.
Ptychognathus alfredi Owen, 1876.
Lystrosaurus wagneri Van Hoepen, 1916.
Lystrosaurus primitivus Toerien, 1954.
Type specimen: B.M.N.H. 36221.
Locality: Rhenosterberg.

The skull in this species resembles that of Lystrosaurus murrayi, described
later, and seems to form a morphological link between it and L. oviceps. As in
oviceps, the snout is directed forward as well as down, but the smoothly curved
snout is lost and the anterior premaxillary facial surface in declivis is a perfectly
flat plane, broken only by a sometimes very prominent longitudinal median
ridge.

There is a strongly developed frontonasal ridge and prominent frontal
tuberosities. The lateral snout surface lies at a sharp angle to the anterior snout
surface, so that in ventral view the premaxillary portion of the palate is rect-
angular.

A feature of this species, as also of L. murrayt, is the division of the skull roof
and snout surfaces into three planes: a parieto-preparietal plane which extends
over the intertemporal region up to the frontal bosses, a frontal plane which
slopes forward and down from the frontal bosses to the frontonasal ridge, and
a premaxillary plane, generally referred to as the facial plane, which drops down
steeply from the frontonasal ridge. The anterior two-thirds of each nasal is
generally included in the plane of the anterior premaxillary surface.

FR. MES.

!
foul
\
VJ

Fig. 72. Lystrosaurus declivis. Nat. Mus. No. C.171.
Skull in lateral view.

248 ANNALS OF THE SOUTH AFRICAN MUSEUM

FR. TUB.—\. eas JUG.

Fig. 73. Lystrosaurus declivis. Nat. Mus. No.
C.171. Skull in dorsal view.

Included in this species are several specimens (e.g. C.403, Figs 22, 23, 24,
26) which resemble L. declivis in all respects excepting the nature of the transi-
tion between the premaxillary and frontal surfaces. In these individuals the
anterior two-thirds of the nasal is not included in the premaxillary plane, but
slopes back to the frontonasal ridge, thus separating the frontal and premaxil-
lary surface planes. These specimens are small and the variation may well be
due to age differences. As shown below, a similar size-correlated variation is
noted in the species L. murrayt.

The frontonasal suture is of the oviceps type, with the frontal extending
down between the nasal and prefrontal. In a few specimens, however, the
frontals protrude forward for a short way between the diverging posterior ends
of the nasals. Unlike species such as L. curvatus, the ventral squamosal flange
faces directly forward, so that in a lateral orthoprojection the occipital condyles
are visible (Fig. 72).

Besides the bosses on the frontals and the longitudinal ridges on the snout,
several specimens of L. declivis display sharp ridges on the skull roof behind the
frontonasal ridge. Thus in S.A.M. K.1392 the interfrontal suture is raised
considerably to form a median, knife-edged crest, while in S.A.M. 3455 the
suture between nasal and prefrontal is similarly elevated. The tusks are strong,
with inner wear facets.

Lydekker (1890) placed L. alfredi and L. depressus under L. latirostris, but
Brink (1951) seems correct in stating that all three of these ‘species’ belong under
L. declivis. All three have frontonasal ridges and strongly developed, longi-
tudinally ridged snouts. Examination of the type skull of L. primitivus shows that
it is probably a badly distorted L. declivis. The specimen has been extensively
dorsoventrally compressed, with consequent obliteration of the nasal apertures
and foramen magnum.

GRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 249

Lystrosaurus mcCaigi Seeley
(Figs 744, 746)
Lystrosaurus (Rhabdotocephalus) mcCaigi Seeley, 1898.
Lystrosaurus mcCaigt Broom, 1903.
Lystrosaurus amphibius Brink, 1951.
Type specimen: Albany Museum.
Locality: Elandsberg, Cradock, C.P.

Although Seeley (1898) referred to this species in the course of a description
of Lystrosaurus platyceps, Broom (1903) was the first to give an account of the
anatomy of the type specimen.

Included in this species are some of the largest specimens of Lystrosaurus.
The snout is very strongly developed with longitudinal ridging, and the nasals
appear to be entirely included in the premaxillary plane. The species resembles
declivis in that the facial surface slopes forward and down from its junction with
the frontal plane. However, the premaxillary plane is much more strongly
developed in mcCaigi than in declivis, the plane in declivis being 86% of the skull
length over the reference plane, while in mcCavgi this figure becomes 103%.

The prefrontals are well developed, although their exact extent is obscured
by the lateral compression which the type skull has undergone. However, it is
clear that mcCazgi differs from all the preceding species in that the prefrontals
protrude forward of the midline of the facial surface. The degree of develop-
ment of these prefrontal bosses and again the lateral compression of the type
skull have obscured the transition between facial and frontal planes. No clear
frontonasal ridge is apparent in the type specimen, but there is an angular
division between the two planes. In three large skulls, namely Nat. Mus. C.228,
S.A.M. K.116 and B.P.I. 380, which appear to be specimens of Lystrosaurus
meCaigi and which have not suffered lateral crushing, there is a clear frontal
ridge, from which the nasals appear to be excluded, across the level of the middle
of the orbits, i.e. relatively farther back than in L. declivis.

Included under this species is Brink’s (1951) L. amphibius, which is founded
on a laterally compressed skull. The considerable distortion has accentuated
the extent of the supraorbital and prefrontal bosses, but it is likely that when
allowance has been made for this the specimen would closely resemble mcCazgz.
Brink (1951) figures two planes in the skull roof of L. amphibius, which appear
to correspond with the parieto-preparietal and frontal planes. In K.116, which
is a well preserved, undistorted skull, these two planes are not differentiated,
and a flat skull table leads forward to the prominent frontal ridge. The pre-
maxillary facial plane commences at this ridge. There is no trace in this skull
of the grooves which Brink noted in the skull of L. amphibius, leading dorsally
from the nostril and which he supposed indicated the presence of fleshy external
nostrils. Examination of the type skull of L. amphibius has shown that these
shallow grooves are the result of the extensive lateral compression which the
skull has undergone.

A resemblance to L. declivis in mcCaigi is seen in the extremely prominent

250 ANNALS OF THE SOUTH AFRICAN MUSEUM

4 cms,

Fig. 74. Lystrosaurus mcCaigi. S.A.M. No. K.116. Skull in (a) lateral and
(6) dorsal view.

longitudinal crests in the frontal region. A median crest is formed at the inter-
frontal suture, while two laterally situated crests, each lying medially to the
prefrontal boss of its side, are probably situated along the nasal-prefrontal
suture.

The possibility of mcCaigi representing a large murrayi or declivis would seem
to exist, but Kitching (1969, and personal communication) has found that
these large forms of Lystrosaurus occur mainly in the lower horizons of the
Lystrosaurus zone, while murrayi and declivis apparently persist throughout the
entire zone. This suggests that L. mcCazgi is a distinct species which had its main
radiation early in Lystrosaurus zone times.

Toerien (1953) appears to be correct when he derives the palate of Lystrosau-
rus from that of Dicynodon, but the contact between the palatine and the posterior
process of the premaxilla which he described in Brink’s (1951) L. amphibius is
certainly due to the lateral compression of the specimen. Premaxillary-palatine
contact was not observed in any other Lystrosaurus specimen.

Lystrosaurus murray (Huxley)
(Figs 75, 76, 77)
Dicynodon murrayi Huxley, 1859.
Lystrosaurus frontosus Cope, 1870.
Ptychognathus boopis Owen, 1876.
Ptychognathus verticalis Owen, 1876.
Lystrosaurus jeppei Van Hoepen, 1916.
Prolystrosaurus strigops Haughton, 1917.
Prolystrosaurus natalensis Haughton, 1917.
Type specimen: B.M.N.H. R.1291.
Locality: Colesburg District, C.P.

The skull in this species is short and deep and in lateral view presents a
square appearance. In contrast to the condition in L. declivis, the flat anterior
surface of the snout lies at right angles to the parieto-preparietal plane. As a
result, the orbit lies relatively far forward in the skull.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS Palsy to

PM

Fig. 75. Lystrosaurus murrayi. Nat. Mus. No. C.211. Skull in (a) lateral and (b) dorsal
view.

The skull roof is characterized by the presence of a frontonasal ridge,
frontal bosses and a radiating system of frontal ridges. In addition, there is a
median, longitudinal ridge on the snout. As is the case in L. declivis, the dorsal
skull roof is divided into a posterior parieto-preparietal plane and an anterior
frontal plane, which slopes forward and down from the level of the frontal bosses.
The anterior, plane surface of the premaxilla lies at right angles to the parieto-
preparietal plane.

A variation, similar to one mentioned in L. declivis, occurs in the region
anterior to the frontonasal ridge. In smaller individuals, such as C.211 with
basal length of 84 mm (Fig. 75), the nasals together form a surface which slopes
down from the ridge to meet the premaxillary plane at an angle, while in larger
individuals such as C.282 with basal length 112 mm (Figs 76, 77), the anterior

Fig. 76. Lystrosaurus murrayi. Nat. Mus. No. C.282.
Skull in dorsal view.

252 ANNALS OF THE SOUTH AFRICAN MUSEUM

two-thirds of the nasals are included in the premaxillary plane, so that the
facial plane commences at the frontonasal ridge.

This variation appears to be correlated with the degree of prefrontal
development and is probably an age phenomenon. Increase in the size of the
prefrontal with increasing age and size appears to result in forward extension
of the anterior orbital border, moving the frontonasal ridge forward and rota-
ting the nasals until they come to he in the premaxillary facial plane. This
apparent straightening out of the snout results in the anterior border of the
orbit lying relatively farther forward in larger specimens.

Brink (1951) is in error when he states that L. murrayi has no transverse
ridge separating the facial from the frontal plane, since this was one of the
features noted by Huxley (1859) in his description of the type skull. Both Broom
(1932) and Brink (1951) have included L. frontosus under L. murrayt.

Transverse frontonasal ridges are present in L. verticalis and L. boopis.
Lydekker (1890) placed the former under L. murrayi, while Brink (1951)
included L. boopis under L. declivis. In 1916 Van Hoepen described six new
species of Lystrosaurus, which Broom (1932) placed under L. murray. Brink
(1951) stated that of these L. jepper, L. jorissent and L. theileri belonged under
L. murrayi, but that L. breyert is comparable to L. oviceps. Examination of these
type specimens has shown that while L. jeppei is probably a dorsoventrally
crushed L. murrayi with a frontonasal ridge, the specimens L. wageri, L. jorissent
and L. theileri probably belong under L. curvatus, and L. wagnert under L.
declivis.

Haughton in 1917 created a separate genus, Prolystrosaurus, for two species,

Fig. 77. Lystrosaurus murrayi. Nat. Mus. No. C.282. Skull in
lateral view.

CRANIAL MORPHOLOGY OF THE DIGYNODONT GENUS LYSTROSAURUS 253

strigops and natalensis, which he claimed were ancestral to Lystrosaurus. Broom
(1932) referred to these species as variants of Lystrosaurus murrayt. Brink (1951)
also maintained that the two species were closely related to L. murrayi. Personal
examination of both the type and co-type specimens of Prolystrosaurus natalensis
and exposure of the median basicranial ossifications of the co-type showed that
both specimens are badly dorsoventrally crushed. This is what Tripathi &
Satsangi (1963) had supposed. The type specimen of P. natalensis is badly
weathered and the nature of the skull roof cannot be determined, but the snout
of the co-type specimen bears longitudinal ridges and there are indications of
frontal tuberosities on the skull roof. The nasal region of the skull roof is not
preserved, making it impossible to determine the presence of a frontonasal
ridge. It does none the less seem justifiable to regard Prolystrosaurus as being
- founded on a crushed specimen of L. murrayi. It is here proposed that the species
described by Haughton (1917) be included under Lystrosaurus murrayt.

Lystrosaurus putterilli Van Hoepen

Lystrosaurus putterilli Van Hoepen, 1915.

Type specimen: T.M. R.44.
Locality: Harrismith, Orange Free State.

This species is equal in size, and apparently closely related, to L. mcCaigi.
Examination of the type skull and a second specimen, T.M. R.47, shows that
there is a single parieto-preparietal-frontal plane on the skull roof, terminated
by a transverse ridge at the level of the middle of the orbits. This transverse
ridge appears to lie posterior to the nasals. The preparietal is large.

This species differs from mcCaigi only in the relationships of the nasals,
which curve back from the premaxillary facial surface towards the transverse
frontal ridge. The prefrontal bosses thus do not protrude forward of the facial
plane as is the case in L. mcCazgi. At this stage it seems safest to regard putterilli
as a distinct species.

Lystrosaurus rubidger Broom

Lystrosaurus rubidgei Broom, 1940.

Type specimen: Rubidge Collection.
Locality: Bethesda Road Station, C.P.

The type skull is considerably crushed (Kitching, personal communication)
but the presence of several unusual features seems to justify its retention, at
least provisionally, as a separate species. The nasals are entirely included in the
premaxillary facial plane. At the same time the frontals and nasals form an
interdigitating suture, with the frontals passing far down between the nasal and
and prefrontal.

Apparently there is no frontonasal ridge and the species may therefore be
allied to L. platyceps. Broom (1940) and Brink (1951) regard the forward frontal

254 ANNALS OF THE SOUTH AFRICAN MUSEUM

extension of the species as unusual for Lystrosaurus, but this feature has been
found to be common in the branch comprising the smooth-skull-roof types.

SPECIATION IN LYSTROSAURUS

Soon after the emergence of the typical Lystrosaurus skull form, speciation
apparently occurred in two main directions within the genus. One group of
species, including L. curvatus and L. platyceps, retained the smoothly rounded
skull roof of its presumably dicynodontid ancestors, while the other group,
including L. declivis, L. murrayi and L. mcCaigi, developed longitudinal ridges
on the snout, a transverse frontonasal ridge between the facial and frontal
planes, and a pair of prominent bosses, with a system of radiating ridges, on the
frontals. This second group comprises more species than the first, and the
majority of Lystrosaurus specimens recovered from the Karoo are included in it.

A certain parallelism exists in the trends shown within the two groups.
Thus in both lines of evolution the tendency is for stronger snout development,
with L. platyceps representing the extreme condition in one group, and L.
McCaigi the extreme in the other.

In both groups, again, increased snout development is accompanied by a
tendency for increased inclusion of the nasal in the facial plane of the premaxilla.
The stage of complete nasal inclusion was achieved by only one species in each
line, platyceps in the one and mcCaigi in the other.

L. curvatus appears to be morphologically the most primitive of all species
of Lystrosaurus, and differs from the typical Dicynodon only in the shortening of
the basicranial axis and deepening of the snout, basic features of all species of
Lystrosaurus. While clearly related to L. bothai and L. platyceps, L. curvatus also
contains individuals with transverse frontonasal sutures and more strongly
developed snouts. These individuals form a morphological link with L. oviceps,
with a frontonasal ridge and strong tusks. The succeeding species, such as
murrayt and declivis, are characterized by the presence of the frontonasal ridge,
frontal bosses and increasingly strong development of the snout, of which the
anterior surface is always a flat plane, broken only by a longitudinal ridge.

These features were used in the construction of the following diagram-
matic scheme of the morphological relationships between the various Lystro-
Saurus species. This scheme very likely does not represent true phylogenetic
relationships, neither do the indicated morphological levels represent horizons
within the Triassic. It appears that the primary radiations of Lystrosaurus into
its various species took place before South African Lystrosaurus zone times. Thus
a species such as L. mcCaigi, which is represented in the scheme as a morpholo-
gically advanced species, apparently flourished in basal Lystrosaurus zone times,
and was poorly represented in later periods. However, on the basis of available
information, it was not possible to ascribe any other species with certainty to a
particular horizon within the Lystrosaurus zone.

In this assessment of the species of Lystrosaurus, nine of Brink’s (1951) South
African species of Lystrosaurus are retained, these being curvatus, bothai, platyceps,

GRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 255

oviceps, declivis, mcCaigi, murrayi, putterilli and rubidgei. The species andersoni and
amphibius of Brink’s scheme have been included under flatyceps, and mcCaigi
respectively, while the species verticalis, natalensis and strigops have been included
under L. murray.

L. putterilli. Facial plane does L. mcCaigi. Facial plane
not include nasal, which slopes includes entire nasal, slopes
back to frontal ridge. down from frontal ridge.

L. murrayi. Facial plane sloping
steeply down from _ ridge,
frontal bosses, facial plane at
right angles to parietal plane.

L. declivis. Flat facial plane,
slopes forward from ridge,
nasal partly in facial plane,
frontal bosses.

L. platyceps. Snout strong, nasal
included in facial plane, snout
and skull roof surfaces smooth.

L. oviceps. Weak frontonasal
ridge, strong, curved, snout,
frontal bosses.

L. bothai. Snout — strong,

smoothly curved into skull

roof, interdigitating fronto-
nasal suture.

L. curvatus. Snout relatively
weak, skull roof and snout
smoothly curved, frontonasal
suture interdigitating or
transverse.

Permian dicynodontid sp.
Snout weak, snout and skull
roof smoothly curved.

256 ANNALS OF THE SOUTH AFRICAN MUSEUM

LYSTROSAURUS FROM INDIA, CHINA AND RUSSIA

Although the Middle Beaufort beds of South Africa have yielded the vast
majority of known Lystrosaurus specimens, representatives of the genus have been
recovered in areas as far afield as Bengal in India, Sinkiang in China and
Luang Prabang in Indo-China (Laos). In addition (Colbert, personal com-
munication; Elliot, et al., 1970) specimens of Lystrosaurus have very recently
been located in Antarctica. Of these three regions, the Panchet series of the
Raniganj coalfields, Bengal, have provided a considerable number of specimens.
The first specimens from this area were described as Dicynodon orientalis by
Huxley (1865), but Lydekker, realizing the true affinities of the form (1879),
placed the species successively under Owen’s Ptychognathus (1887) and his own
Ptychosiagum (1890). Das Gupta (1922) first used the name Lystrosaurus for the
Indian specimens.

Tripathi (1960) and Tripathi & Satsangi (1963) have produced recent
publications dealing with the fauna of the Panchet series, and have given a
comprehensive (1963) account based on a large collection of Lystrosaurus from
the Panchet beds. They maintain that the Panchet sediments are identical
with the Middle Beaufort beds of South Africa, and have identified several
South African species of Lystrosaurus, namely, L. murrayt (sensu Broom, 1932),
L. platyceps and L. mcCaigi. In addition, they distinguish a new species, L.
rajurkari, which they regard as being one of Broom’s ‘female’ specimens, and
which appears to be related to the curvatus-platyceps group.

The Lystrosaurus fauna from Sinkiang province has been described by Yuan
& Young (1934), Young (1935, 1939) and Sun (1964). Four species have been
recognised, namely, L. broomi (Yuan & Young, 1934; Young, 1939), L. hedini
(Young, 1935), L. weidenreicht (Young, 1939) and L. young: (Sun, 1964).

L. broomi was originally described (Yuan & Young, 1934) as L. murray,
but Young later (1939) considered that its wide geographical separation from
the South African Middle Beaufort beds, coupled with the unusual dorsal
process of the lacrimal between nasal and prefrontal, pointed to its being a
distinct species. Young mentions rough crests on the skull, and indications are
that the species has affinities with the murrayi—declivis group of South African
lystrosaurids.

L. hedini differs from all other known lystrosaurids in the remarkable
embayment in the lateral palatal rim. A resemblance to L. putterilli, noted also
by Brink (1951), is the apparent presence of a transverse ridge across the middle
of the orbits. This species is probably also allied to the murrayi—declivis group of
South African lystrosaurids.

L. weidenreicht is known largely from postcranial skeletal remains, and
comparison with other forms is difficult. L. youngi (Sun, 1964) closely resembles
the South African L. curvatus.

Yuan & Young (1934) state that Dicynodon incicivum (Repelin, 1923) from
Luang Prabang, Indo-China, is clearly a Lystrosaurus, but too poorly preserved
for comparisons.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS P47)

Efremov (1938, 1940) has described Lystrosaurus klimovi from the Dongus
River, Orenburg Province, U.S.S.R. Although very incomplete, it can be seen
that the skull possesses an apparently narrow intertemporal region, while the
interorbital region on the other hand appears to be remarkably broad. Efremov
(1951) subsequently placed this specimen in a new genus, Rhadiodromus.

While the presence of Lystrosaurus (including South African species) in
India can be explained in terms of Gondwanian affinities, the occurrence of the
genus in regions such as Luang Prabang, Sinkiang (and Russia?) points to a
geographical distribution which was not confined to within the borders of a
southern Gondwana continental mass. The Sinkiang species broomi and hedini,
while possessing structural peculiarities in the skull, are clearly typically
lystrosaurian, and there is thus a possibility that Lystrosaurus may have arisen
in regions to the north of the South African Karoo basin or the Indian Panchet
successions.

SecTION VI. THE ORIGIN OF LYSTROSAURUS FROM A PERMIAN
ANCESTOR AND ITS RELATIONSHIPS WITH SOME OTHER
TRIASSIC DICYNODONT GENERA

In the past, various authors have made references to the question of the
phylogenetic descent of Lystrosaurus from a Permian ancestor, and several
dicynodont species have in fact been singled out as possible ancestral forms.
Thus Haughton (1917) thought that Dicynodon testudirostris foreshadowed
Lystrosaurus in the lengthening of the premaxilla and maxilla, and the ‘bending
down’ of the snout, and Broom (1932) suggested that since Dicynodon gilli of the
Cistecephalus zone approached Lystrosaurus in so many characters, it could very
well be close to the ancestral form of that genus. Broom did not elaborate on the
lystrosaurian features of D. gilli, but the large orbits and slightly shortened
temporal fossae are certainly reminiscent of Lystrosaurus, and, in addition, the
basicranial region resembles that of Lystrosaurus in the presence of an inter-
tuberal ridge. However, features which preclude this species from the direct
ancestry of Lystrosaurus are the contact between the premaxilla and frontals,
the small prefrontal and the near-contact between the postorbitals in the
intertemporal region.

Toerien (1953, 1955) argued that Dicynodon is the most likely ancestor of
Lystrosaurus, the palate of Lystrosaurus being a modification of that of Dicynodon,
and in 1954 he described a new species of Lystrosaurus, L. primitivus, which he
regarded as being very similar to the Russian Dicynodon annae. Gamp (1956)
similarly suggested that D. annae might be close to the ancestry of Lystrosaurus.

Comparison of Lystrosaurus with other, Permian and Triassic dicynodonts
shows that, firstly, some features of the Lystrosaurus skull are foreshadowed in
various groups of Permian dicynodonts, and secondly, Lystrosaurus has several
characteristics in common with other Triassic dicynodont groups.

Examples of the first instance are the intertuberal ridge and shortened

258 ANNALS OF THE SOUTH AFRICAN MUSEUM

temporal fossa in Dicynodon gilli and short temporal fossa, steeply downturned
snout and overall deepened skull in species such as Dzictodontoides skaios (Watson,
1960). In Daptocephalus the snout is increased in length (as is common in all
descendants of Dicynodon, including Lystrosaurus, cf. Toerien, 1955), and the
pterygoid has gained contact with the premaxilla, as is the case in Lystrosaurus. A
further resemblance to Lystrosaurus is the labial fossa in the Daptocephalus snout.

In terms of functional morphology, the masticatory cycle of Lystrosaurus
represents a modification of an essentially similar cycle in Dicynodon. In con-
trast to forms such as Emydops, the premaxillary and maxillary palatal rim in
both Dizcynodon and Lystrosaurus has been ventrally extended in front of the .
canine tusk as a sharp cutting blade, against which the lateral surface of the
dentary symphysis acts to produce a slicing action during the masticatory cycle.

In the second instance, several points in the cranial anatomy of Lystro-
saurus indicate that the genus is affiliated to other Triassic dicynodont groups.
A review of the exact relationships and evolution of the Triassic dicynodont
groups (Cox, 1965) would be outside the scope of this work, and has not been
attempted here. Neither is such a review necessary for the present purpose,
which is simply to demonstrate various structural similarities between Lystro-
saurus and some later Triassic dicynodonts.

In Kannemeyeria, as shown above, the pterygoid is produced forward to
meet the maxilla, in much the same way as in Lystrosaurus. More striking is the
similarity of structure of the interpterygoidal fossa in Lystrosaurus and other
Triassic dicynodonts (Cox, 1965) such as Aannemeyeria, Tetragonius nyalilus
(Cruickshank, 1967), Stahlekeria potens from South America and Placerias gigas
from North America (Camp & Welles, 1956). In Permian dicynodonts such as
Emydops and Dicynodon the interpterygoidal vacuity is long and extended dor-
sally to the level of the roof of the choana, whereas in a Triassic form such as
Lystrosaurus the vacuity is reduced to a small fossa in the basicranial girder,
bounded posteriorly by the pterygoids and anteriorly by the vomer. As stated
in Section IV, the shortened interpterygoidal vacuity of Lystrosaurus is regarded as
an advance over the condition in Emydops and Dicynodon, and is the result of adap-
tive specializations, principally shortening of the basicranial axis, in the skull.

Camp’s (1956) work is of importance here, since he discusses certain
features which, he considers, indicate a fairly close relationship between Kan-
nemeyerta, Placerias and Stahlekeria, and which led him to include the three
genera in a family, the Kannemeyeriidae. These features include:

pterygoid-maxilla contact;
reduction of ectopterygoid;
reduction of interpterygoidal vacuity.

To these characteristics could be added:

absence of a floccular (sub-arcuate) fossa;
posterior position of presphenoid;
presence of labial fossa.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 259

All six of these features are characteristic of Lystrosaurus, the condition of
the interpterygoidal vacuity and parasphenoid being especially significant,
since it suggests that some shortening of the basicranial axis has taken place
in Kannemeyeria, Placerias and Stahlekeria. That this is so is further indicated by
the relatively posterior position of the sphenethmoid complex in these genera.

Camp’s (1956) illustrations show that in Stahlekeria and Placerias arching
down of the snout on the basicranial axis has taken place. The ventral position
of the feeding plane is arrived at in a manner analogous to that in Lystrosaurus,
since it is the result of simple downwards flexure of the skull axis, which does not
involve deepening of the vomer and premaxilla and which carries the nasal
opening down with it. In contrast, the nasal aperture in Lystrosaurus has retained
its primitive position relative to the foramen magnum.

In Placerias and Stahlekerta the high posterior position of the areas of origin
of the adductor musculature is very possibly correlated with the ventral orienta-
tion of the snout, in much the same way as deepening and extreme shortening
of the Lystrosaurus skull has been shown to be the result of ventral displacement
of the palate, so that an effective angle of traction on the mandibular axis is
maintained. The ventral extension of the quadrate process of the squamosal,
effecting a lowering of the suspensorium, may be regarded as a further compensa-
tion in Placerias and Stahlekeria.

In Kannemeyeria, where the basicranial axis is shortened but only slightly
arched, the parietal, supraoccipital and interparietal are greatly thickened and
the areas of external adductor muscle attachment on the squamosal are raised,
but the quadrate is not lowered to the same extent as, for example, in Stahlekeria,
where the skull is least extended above the foramen magnum and the quadrate
is in a more ventral position than in the other two ‘kannemeyeriid’ genera.

There are thus several respects in which Lystrosaurus resembles Camp’s
three kannemeyeriid genera, the most significant of these being shortening of
the basicranial axis, pterygoid-maxilla contact, a tendency for ventral displace-
ment of the palate, reduction of the interpterygoidal vacuity and deepening of
the posterior moiety of the skull. With regard to the postcranial anatomy,
Cruickshank (1964) has noted similarities in the interclavicle of Lystrosaurus
and later Triassic dicynodonts, and states that in this respect Lystrosaurus,
while retaining certain features of Permian dicynodonts, also resembles succeed-
ing Triassic dicynodonts. However, the ulna in Lystrosaurus does not possess a
separately ossified olecranon process, a feature of the later Triassic Dicyno-
dontia (Cox, 1965).

In a later (1967) publication, Cruickshank considers that Tetragonius
njalilus of the East African lower Middle Triassic is a connecting link in an
evolutionary sequence leading from Lystrosaurus to Kannemeyeria. In support of
this view he cites several characters which the genera have in common, namely,
similar palatal regions, square shape of the skull in dorsal view, absence of
the ectopterygoid, similar ilia, ‘W’-shaped naso-frontal suture, large tusks and
expanded maxillary flanges. Furthermore, he demonstrates that Tetragonias

260 ANNALS OF THE SOUTH AFRICAN MUSEUM

resembles Kannemeyeria in the narrow intertemporal bar, abbreviated post-
orbitals, and prespinous fossa in the scapula.

Against this theory is the fact that the main points of similarity between
Lystrosaurus and Tetragonias, i.e. the pterygoid-maxilla contact and the reduced
interpterygoidal vacuity, are characters which appear to be widespread among
Triassic dicynodont genera and need not indicate a special relationship between
Lystrosaurus and Tetragonias. Furthermore, it seems improbable that any species
of Lystrosaurus, highly specialized in the very deep median septum in the snout
region, the correspondingly deepened premaxilla and the extremely shortened
basicranial axis and temporal fenestrae, could give rise to a form like Tetra-
gonias, with a weak snout and long temporal fenestrae. Without any informa-
tion regarding the basicranial axis and the position of the sphenethmoid com-
plex in Tetragonias, it is not possible to determine whether shortening or flexure
has taken place in this region, although the reduced interpterygoidal vacuity
could perhaps be regarded as an indication of such shortening. Certainly, more
definite morphological similarities must be uncovered before the idea of a close
relationship between Lystrosaurus and Tetragonias can be fully accepted.

From a comparison of the above groups of Triassic dicynodonts, it seems
reasonable to accept that genera such as Lystrosaurus, Kannemeyeria, Placerias,
Stahlekeria and most probably also Tetragonias and Dinodontosaurus arose from
a single Permian ancestral group, and that these genera, although geogra-
phically diverse, retained a basic similarity of skull morphology, in characters
such as the presence of a labial fossa, the pterygoid-maxilla contact, shortening
of the basicranial axis and interpterygoidal vacuity and a tendency in some for
ventral displacement of the palate.

Early in the evolution of this group of Triassic dicynodonts Lystrosaurus
diverged from the main line of development to become adapted to an aquatic
existence. Although a highly specialized and distinct group, it retained several
characteristics which were apparent in later survivors of the original basic
Triassic stock.

If Lystrosaurus can in fact be regarded as a specialized representative of a
main line of dicynodont development, the search for its ancestral form can be
narrowed down to Permian groups which provide indications of the changes
undergone by the Triassic genera. In this connection the Upper Permian dicyno-
dontid (sensu Haughton & Brink, 1954; Romer, 1966) genus Daptocephalus is
of significance. Here the interpterygoidal vacuity is in the process of becoming
separated from the choana proper, and is shorter than that of other Permian
dicynodonts.. This character reflects the tendency in Triassic dicynodonts for
reduction of the interpterygoidal vacuity. Furthermore, Daptocephalus has a
well-developed labial fossa, the presphenoid arises fairly far back in the basi-
cranial axis, and the pterygoid makes contact with the maxilla. The narrow
intertemporal bar and long temporal region in Daptocephalus make it an unlikely
direct ancestor for Lystrosaurus at least, but it is very likely that Daptocephalus
stands near the ancestral stock of the Triassic dicynodonts.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 261

In conclusion it can be said that several features in the cranial anatomy of
Lystrosaurus had been established in its Permian predecessors, and since several
of these features are also characteristic of other Triassic genera, it seems likely
that Lystrosaurus arose as an early offshoot of a main line of Triassic dicynodont
development. Although no specific Permian dicynodont can as yet be pointed
out as a direct ancestor of the later dicynodonts, extrapolation back into the
Permian of trends seen in Triassic dicynodonts makes it reasonable to assume
that such an ancestral form had many of the characteristics of Daptocephalus,
but had retained a fairly broad intertemporal region.

Whether this hypothetical ancestral form was present in the South African
Permian, or whether Lystrosaurus and Aannemeyeria represent migratory
descendants of a geographically distant ancestor, must at present remain
uncertain.

CONCLUSIONS
THE BASICRANIAL AXIS

Four elements have been identified in the basicranial axis of Lystrosaurus,
namely, basioccipital, basisphenoid, presphenoid and mesethmoid. Further-
more, it is concluded that a further ossification, the orbitosphenoid, has second-
arily invaded the basicranial axis.

Broom (1927) concluded that the therapsid basicranial axis consisted of
three median ossifications only, and divided the mammals into two groups, the
Palaeotherida (with three basicranial elements) and the Neotherida (with
four basicranial elements). According to Broom, the Neotherida had gained
an extra ossification in the basicranial axis. If Lystrosaurus, on the other hand,
is typical of the therapsids, the premammalian basicranial axis included a
presphenoid and mesethmoid anterior to the basisphenoid.

It seems that the critical factor in these considerations is the nature of the
bone referred to here as presphenoid. Broom (1927), who was in any case not
justified in comparing the Mammalia with a therapsid as aberrant as Dicynodon
(Parrington & Westoll, 1940), was also mistaken, it seems, in assuming that the
presphenoid in Dicynodon was a forward extension of the basisphenoid. An
apparently similar basisphenoidal extension has been described in the insecti-
vore Evemitalpa (Roux, 1947), but the two instances do not appear to be com-
parable. Thus in Lystrosaurus the presphenoid is clearly part of an extensive
interorbitonasal septum and was continued dorsally and anteriorly in cartilage.
Moreover, this septum is clasped ventrally by the clearly distinguishable
cultriform process of the parasphenoid. These two features are clearly reptilian,
and the inference must be that the septum arose ontogenetically from fused
trabeculae. The dicynodont septum, as exemplified in Lystrosaurus, would rather
appear to be homologous with the interorbital septum of mammals such as the
rabbit and Ornithorhynchus (De Beer & Woodger, 1930; Haines, 1950), where
the septum arises from fused trabeculae as in Lacerta.

262 ANNALS OF THE SOUTH AFRICAN MUSEUM

This is in agreement with the findings of Olson (1944) and Camp & Welles
(1956), who demonstrate that in dicynodonts and other therapsid groups the
presphenoid is independent of the basisphenoid and in all likelihood arose in a
cartilage derived from the fused trabeculae. From this same cartilage the
dorsally situated mesethmoid probably arose. Olson assumes that the meseth-
moid of therapsids is lost in some mammal groups (Broom’s Palaeotherida).

It may therefore be concluded that Roux’s (1947) statement that there
are but three centres of ossification in the basicranial axis of all vertebrates is
incorrect, and that the four ossifications which appear to be present in the
therapsid basicranial axis were inherited by certain mammals, such as those
described by De Beer & Woodger (1930) and Haines (1950), where a true
interorbital septum, in the position of the therapsid presphenoid, is present.
Haines (1950) has shown that a bony interorbital septum is present in several
mammals, and defines the mammalian presphenoid as being the bone in the
adult skull which, separate in most mammals, ossifies from presphenoid and
orbitosphenoid centres.

In a therapsid such as Lystrosaurus the orbitosphenoid, arising from the
orbital cartilages, has invaded the basicranial axis in the form of a well-developed
septum, separated from the presphenoid by cartilage. Roux (1947) has shown
that a similar median migration of orbitosphenoid ossification centres occurs
in the primitive mammals he investigated. Although the orbitosphenoid bone
in therapsids does not generally enclose a complete optic foramen, it has been
concluded that (p. 176) the element was continued posteriorly in cartilage,
so that the optic notch, in for instance Lystrosaurus, would have been closed off
from behind to form a complete optic foramen.

Expansion of those portions of the brain supported by the therapsid
orbitosphenoid would result in lateral and ventral displacement of this element,
with subsequent merging with, or obliteration of, the presphenoidal septum.
A fusion between the two elements would result in a compound element with
the relations of the mammalian presphenoid as defined by Haines (1950).
By this analysis, the dicynodont basicranial axis is of a primitive reptilian
pattern.

The validity of this interpretation of the basicranial axis of therapsids as
compared with that of mammals is, basically, dependent on the nature of the
bone in therapsids referred to here as the presphenoid. If the presphenoid is
indeed a discrete element, then the therapsids have four median ossifications
in the basicranial axis, one of which may be suppressed in some mammals. On
the other hand, if the presphenoid is an anterior extension of the basisphenoid,
as Cox (1959) believes, then therapsid structure does not truly foreshadow the
condition in mammals.

At present the evidence appears to favour the view that the therapsid
basicranial axis is of an essentially reptilian type, with an extensive interorbi-
tonasal septum arising from the fused trabeculae and containing two ossifica-
tions anterior to the basisphenoid.

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 263

THE SOFT STRUCTURES OF THE SNOUT

The interior of the snout region of Lystrosaurus has provided evidence of
several of the unpreserved structures of the nasal capsule. It seems likely that
the mesethmoid was continued anteriorly beneath the frontal and nasal sur-
faces as a pair of cartilaginous sphenethmoidal commissures, in a direction
indicated by a pair of ridges on the inside of the skull roof. On the other hand,
Kemp (1969a) has mentioned the possibility of these ridges in therapsids being
evidence for the presence of turbinals.

Furthermore, it seems probable that the ventral edge of the cartilaginous
nasal septum was received by the grooved dorsal edge of the premaxillary
median septum. This being the case, the nasal capsules were located relatively
high in the snout, and a pair of choanal tubes, such as suggested by Kemp
(1969a), must have led from the nasal capsules to the oral cavity through the
choanae.

In addition, the courses of the ducts of Jacobson’s organ, the lacrimal
gland and the lateral nasal gland have been suggested. The duct of Jacobson’s
organ lay in a groove alongside the premaxillary median septum and opened
into the choana through the anterior choanal notch between the premaxilla
and maxilla. The course of the nasolacrimal duct within the nasal cavity appears
to be clearly marked. A deep sulcus leads from the internal opening of the
lacrimal canal to the internal opening of the septomaxillary canal, which
penetrates the body of the septomaxilla, and it seems certain that the nasolac-
rimal duct emerged through this canal and opened into the external nasal
aperture. Moreover, that this was the case among therapsids generally, is
indicated by the close relationship between septomaxilla and nasolacrimal duct
in Dasypus (Fuchs, 1911).

Furthermore, it is concluded that the maxillary antrum, which is of
variable occurrence among dicynodonts, contained a diverticulum of the
nasal chamber.

THE JAW AND NECK MUSCULATURE

In order to clarify the nature of the adaptive changes undergone by the
Lystrosaurus skull, the jaw and neck musculatures were reconstructed and the
possible range of movements at the jaw joint and in the neck region determined.

In the jaw musculature, lateral and medial external adductor muscles,
anterior and posterior pterygoideus muscles and a depressor mandibulae
muscle have been restored. It appears that Crompton & Hotton (1967) are
correct in their view that the external adductor muscle mass was divided into
lateral and medial groups, and that the medial group inserted in the dorsal
dentary groove. There is also the possibility that a portion of the medial group
inserted in the normal way in the Meckelian fossa. The masticatory cycle
permitted by this musculature would have included slicing, such as proposed
by Crompton & Hotton (1967), between the lower and upper beaks in front of
the mouth. In addition to the slicing action, this investigation has indicated that

264 ANNALS OF THE SOUTH AFRICAN MUSEUM

a degree of crushing and grinding between horny pads on the upper and lower
jaws took place farther back in the mouth during a later stage of the cycle.

A similar restoration of the musculature in the neck region suggests that
Lystrosaurus had retained a basically primitive system of occipital and atlanto-
axial muscles. However, this essentially reptilian musculature was modified
to allow a degree of flexure and extension at the atlanto-occipital joint, as
indicated by the posteriorly projecting exoccipital condyles, as well as a certain
amount of rotation at the atlanto-axial joint, as indicated by the reduced
atlas-axis zygapophyseal articulation. Kemp (1969) has shown on purely
mechanical and geometrical grounds that these movements are possible in the
specimen of Lystrosaurus which he examined.

Comparison of the atlas in Seymouria, the pelycosaurs, dicynodonts and
cynodonts has shown that the modest degree of rotation between the atlas and
axis was most probably accomplished by a lateral migration of the insertion
area of the m. obliquus capitis caudalis, resulting in the formation of the
dorsal process of the atlas, which Cox (1959) had regarded as the homologue
of the neural spine. The m. obliquus capitis cranialis arose from the vertical
transverse process of the atlas. Thus, while Lystrosaurus was functionally fore-
shadowing typically mammalian movements in the occipito-cervical region,
the musculature involved remained essentially primitive.

ADAPTIVE CHANGES IN THE SKULL

Comparison of the skull of Lystrosaurus with the skulls of Permian dicyno-
donts indicates that shortening of the basicranial axis and deepening of the
skull, especially in the snout region, are the main modifications in Lystrosaurus.
These two processes have affected the orientation and relative position of the
nasal capsules and respiratory passages, the position of the presphenoid and
orbitosphenoid, the morphology of the hypophyseal region and palate, and the
orientation of the brain.

Most significant, however, are the effects of skull shortening and deepening
on the external adductor musculature. Lowering of the anterior palatal region
in a dicynodont would tend to decrease the arc through which the lower jaw
could be rotated back to its maximum gape. Since the size of the gape is deter-
mined by the direction and position of fibres of the external adductor muscles
relative to the quadrate-articular contact, any disadvantageous reduction
of the gape size due to deepening of the snout would have to be compensated
for by modifications in the external adductor muscles. Comparisons with
Emydops and Dicynodon have shown that, with the jaw in the protracted, adduc-
ted position, the combined retractive forces of the adductor musculature are
exerted at a greater angle to the jaw axis in Lystrosaurus than in other dicyno-
donts.

Furthermore, when the skulls of a Permian dicynodont (such as the
endothiodontid Emydops) and Lystrosaurus are compared with the mandibles
swung back to the point of maximum gape, as determined by the lateral exter-

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 265

nal adductor muscles, it can be seen that the areas of origin of the external
adductor musculature in Lystrosaurus allow the mandible to be rotated back
relatively farther than in Permian dicynodonts. Consequently, although the
palatal surface is relatively lower, the size of the gape in Lystrosaurus remains
comparable to that of typical dicynodonts.

A second effect that simple snout deepening would have on the dicynodont
masticatory cycle would be that, due to the steep angle at which the adducted
mandible would lie in relation to the reference plane of the skull, the jaw
adductor muscles would exert a very oblique tractive force on the jaw axis.
Consequently, the tendency for horizontal retraction of the jaw would be
vastly increased, at the expense of the vertical component of force, which is
especially responsible for the crushing of food against the palate.

These comparisons, taken together with the fact that Lystrosaurus was
almost certainly committed to an aquatic mode of life, suggest that the charac-
teristic skull proportions in Lystrosaurus arose primarily in response to new
feeding requirements, which involved a lowered food-gathering level. As a
result, deepening of the snout below the level of the nostril took place. Con-
comitant changes in the orientation of the adductor musculature were essential
if a suitable gape and an effective masticatory cycle were to be maintained, and
in compensation for snout deepening, shortening of the basicranial axis and
deepening of the temporal region of the skull took place. These two changes,
effecting an anterior displacement of the areas of origin of the adductor muscula-
ture relative to the areas of insertion, ensured that an effective traction force
was maintained on the jaw axis, while they at the same time permitted the
mandible to be rotated farther back.

DIVISION OF THE SPECIES

Investigation into the pronounced cranial variation within the genus
indicates that such variations are due to differences in proportional develop-
ment of various common structures, and do not affect the basic, functionally
integrated skull form. It seems that once the successful adaptive changes had
been brought about, speciation in Lystrosaurus took place in two roughly
parallel directions. While one group of species retained the smooth skull roof
of typical Permian dicynodonts, the second group developed prominent ridges
and bosses on the snout and dorsal skull roof. In each group there is a tendency
for increased deepening of the snout, resulting in eventual inclusion of the
nasal into the general premaxillary facial plane.

RELATIONSHIPS WITH OTHER DICYNODONT GENERA

This investigation has shown that Lystrosaurus closely resembles later genera
of Triassic dicynodonts, which, collectively, are in several respects morpholo-
gically distinct from Permian dicynodonts. Lystrosaurus appears to have diverged
from the main Triassic dicynodont stock very shortly after the emergence of
this stock during the Permo-Triassic transition. Although the genus is highly

266 ANNALS OF THE SOUTH AFRICAN MUSEUM

specialized, features such as the pterygoid—maxilla contact, the presence of the
labial fossa, the shortened basicranial axis and reduced interpterygoidal
vacuity, as well as the absence of the ectopterygoid and floccular fossa, link
Lystrosaurus with other geographically widespread Triassic genera such as
Kannemeyeria, Placertas and Dinodontosaurus. On the other hand, the South
African Upper Permian genus Daptocephalus appears to foreshadow the Triassic
dicynodont assemblage in that it possesses several of the above-mentioned
cranial features, but its narrow intertemporal crest makes it an unlikely ancestor
for Lystrosaurus.

While the position of Lystrosaurus relative to the Permian and Triassic
dicynodont assemblages seems reasonably clear, more exact information
regarding its geographical region of origin and its most likely ancestor is lack-
ing. Since representatives of the genus are also found in India, Indo-China,
northern China and recently Antarctica, it is clear that Lystrosaurus was a
geographically widespread group, and there is no definite indication of its
having arisen in the South African Karoo. Its occurrence in the Panchet rocks
of India, which are lithologically very similar to the South African Middle
Beaufort beds, suggests that the Indian subcontinent was in close proximity to
southern Africa in Eo-Triassic times. However, the presence of Lystrosaurus
in the Chinese Triassic of Sinkiang shows that the distribution of the genus
included areas outside of the Gondwanaland supercontinent. The chances of
Lystrosaurus actually having arisen in these northern regions appear to be remote,
but the fact that in the South African Lystrosaurus zone the apparently morpholo-
gically advanced species occur mainly in the basal layers certainly does point
to a migration into this area. On the other hand, the presence of Daptocephalus
in the South African Upper Permian indicates that trends which could con-
ceivably have culminated in the appearance of typical Triassic dicynodonts were
present in the Cistecephalus zone of the Karoo.

SUMMARY

In this investigation attention was paid mainly to the comparative and
functional anatomy of the skull of Lystrosaurus, a member of the aberrant,
herbivorous mammal-like reptiles comprising the infraorder Dicynodontia.

Specimens of Lystrosaurus yielded much important information regarding
the various braincase and sphenethmoidal ossifications, and allowed a reassess-
ment of the problem of the number of ossifications in the therapsid basicranial
axis. The evidence provided by serially sectioned and acid-prepared specimens
of Lystrosaurus indicates that four such ossifications, namely the basioccipital,
basisphenoid, presphenoid and mesethmoid were probably present in therap-
sids, and that this condition was inherited by the early mammals. In the snout
region the positions of the cartilaginous sphenethmoidal commissures and nasal
septum have been determined, as well as the courses of the ducts of the lateral
nasal gland, Jacobson’s organ and the lacrimal gland. It is concluded that in

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS 267

therapsids the duct of the lacrimal gland penetrated or was closely associated
with the septomaxilla, a condition which persists in primitive mammals.

A restoration of the musculature of the neck and occipital region has indica-
ted the likely range of movements possible between the occipital condyles and
the atlas, and within the atlas-axis complex. It can be shown that rotation of the
atlas on the axis, as well as the dorsoventral flexure of the skull on the atlas, are
movements which were acquired parallel to, and independently of, the same
range of movements present in the more highly advanced mammal-like reptiles.
A similar restoration of the jaw musculature and horn-covered areas of the
upper and lower jaws has shown that the masticatory cycle of Lystrosaurus inclu-
ded highly efficient food slicing and crushing actions.

A consideration of the adaptive importance of several fundamental
morphological characteristics of Lystrosaurus permitted a formulation of the
evolutionary process by which the characteristic skull form of Lystrosaurus was
arrived at. This process was shown to be closely connected with the functional
requirements of the jaw adductor musculature.

Comparison of Lystrosaurus with earlier, Upper Permian dicynodonts, as
well as with succeeding Triassic dicynodont genera, shows that Lystrosaurus
resembles its Triassic successors in several important respects, but retains some
primitive features of the Permian groups. It appears that Lystrosaurus diverged
from the Triassic dicynodont stock at an early stage, and became rapidly
adapted to an aquatic or semi-aquatic way of life.

It has been shown that, while pronounced sexual dimorphism may well
have been present in several Lystrosaurus species, the genus may be more con-
veniently divided into two parallel groups of species. The less common, and
presumably more primitive, of these two groups retained certain characters of
their Permian forebears.

The South African species of Lystrosaurus have been compared with
species from other parts of the world. While the presence of the genus in
India, Indo-China and Antarctica can be explained in terms of continental
drift, the Sinkiang species of Lystrosaurus indicate that the distribution of Lystro-
saurus included areas to the north of the southern Gondwanaland continental
mass.

ACKNOWLEDGEMENTS

I have had most valuable discussions on various aspects of this work with
Drs T. H. Barry, M. E. Malan, L. D. Boonstra, A. W. Crompton, A. R. I.
Cruickshank and Mr. J. W. Kitching. I am, in addition, grateful to Dr. Barry
and Dr. Malan for their critical reading of the manuscript and their numerous
useful suggestions.

I am also greatly indebted to the late Dr. A. C. Hoffman, of the National
Museum, Bloemfontein, and Drs S. H. Haughton and A. R. I. Cruickshank,
of the Bernard Price Institute for Palaeontological Research, Johannesburg,

268 ANNALS OF THE SOUTH AFRICAN MUSEUM

for allowing me access to specimens of Lystrosaurus housed in their respective
institutions.

Mr. C. Gow, then of the South African Museum staff, was responsible for
the preparation of several Lystrosaurus specimens; these revealed much compara-
tive and functional anatomical detail.

Two collecting trips in the Karoo, in 1967 and 1969, were undertaken with
the generous support of the South African Council for Scientific and Industrial
Research. :

This work was submitted as a thesis in partial requirement of the degree of
Doctor of Philosophy at the University of Stellenbosch, August 1970.

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ABBREVIATIONS
A. AMP. REC. — anterior ampullary recess, for ampullae of anterior and horizontal
semicircular canals
A.C. — auditory canal
ADD. FOS. — adductor fossa
INs lols 1Ey5\A E — adductor externus lateralis muscle
A. E. MED. — adductor externus medialis muscle
ANG. — angular
ART. — articular
ANALG LANE facet for atlas on odontoid
BAS. basisphenoid
BC. P basicranial pit
BO. basioccipital
BPT. PROC. basipterygoid process
CH. ceratohyal
DEN. dentary
DEN. GR. dentary groove
DEP. MAND. depressor mandibulae muscle
ECT. ectopterygoid
EO. exoccipital
EO. FAC facet on atlas for exoccipital
EPT. epipterygoid
BPI. EDP epipterygoid footplate
FEN. OV fenestra ovalis
F. M. foramen magnum
FR. frontal
FR.R

ridges on inner frontal surface

CRANIAL MORPHOLOGY OF THE DICYNODONT GENUS LYSTROSAURUS

FR. TUB.
FTP. GR.
GR. JAC. ORG.
H. SG. G.

JAC. DUCT NO.

JUG. FOR.

ORB

ORB. NAS. FEN.

1

PA.

PASYAG Ad:
PA. FAC. EO.
PAL.

PAL. PROC.
P. AMP. REC.
PAR. FOR.
PAS.

PAS. R.

PBS. S.

PFR.

PIL. ANT.
PIN. ORG.
PM.

tuberosities on frontal

groove in epipterygoid footplate
groove for duct of Jacobson’s organ
horizontal semicircular canal
hypophysis

foramen for 12th nerve

internal auditory meatus
intercentrum

internal carotid canal
interparietal

interpterygoidal vacuity
intertuberal ridge

notch in palate for Jacobson’s organ duct
jugal

jugular foramen

ledge in vestibule

labial foramen

labial fossa

lacrimal

lacrimal foramen

lateral articular condyle

lateral dentary ledge

lateral dentary ridge

lateral dentary shelf

lateral head vein channel
lateral palatal foramen

lateral process on atlas neural arch
lacrimal duct

longissimus capitis muscle
maxilla

maxillary antrum

medial condyle of quadrate
facet on medial end of stapes
mesethmoid

nasal

neural spine

nutrient channel

obliquus capitis caudalis muscle
obliquus capitis cranialis muscle
odontoid

facet on atlas for odontoid
opisthotic

orbitosphenoid

fenestra between orbit and nasal cavity
pocket

parietal

proatlas facet on atlas

proatlas facet on exoccipital
palatine

palatine process of pterygoid
ampullary recess for posterior semicircular canal
parietal foramen

parasphenoid

parasphenoid rostrum
parabasisphenoid sheet
prefrontal

pila antotica

pineal organ

premaxilla

273

PT. GR.
PT. PAR. FOR.
PT. POST.

R. C. LAT.

R. C. POST. MAJ.
R. C. POST. MIN.

REF. LAM.

Nat. Mus. No.
S.A.M. No.
T.M. No.

ANNALS OF THE SOUTH AFRICAN MUSEUM

postorbital

postfrontal

postzygapophysis

preparietal

notch for palatoquadrate cartilage
prearticular

prezygapophysis

prootic

presphenoid

pterygoid

pterygoideus anterior muscle

posttemporal fenestra

groove on pterygoid

pterygoparoccipital foramen

pterygoideus posterior muscle

quadrate

quadrate foramen

quadrate groove

quadratojugal

quadrate ramus of pterygoid

facet for quadrate ramus of pterygoid
rectus capitis anterior muscle

rectus capitis lateralis muscle

rectus capitis posterior major muscle
rectus capitis posterior minor muscle
reflected lamina

surangular

septomaxilla

septomaxillary canal

septomaxillary foramen

supraoccipital

splenial

squamosal

semispinalis capitis muscle

stapes

tusk

tabular

transverse process

unossified zone

vestibule

venous notch

vomer

olfactory nerve

notch for optic nerve

foramen for facial nerve

recess for opening of facial nerve

foramen for palatine branch of facial nerve
hypoglossal nerve

Catalogue number of the Bernard Price Institute for Palaeontological
Research, University of the Witwatersrand, Johannesburg
Catalogue number of the National Museum, Bloemfontein
Catalogue number of the South African Museum, Cape Town
Catalogue number of the Transvaal Museum, Pretoria

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:
(1) Heading, consisting of informative but brief title, name(s) of author(s), address(es) of
author(s), number of illustrations (plates, figures, enumerated maps and tables) in the article.
(2) Contents. (3) The main text, divided into principal divisions with major headings; sub-
headings to be used sparingly and enumeration of headings to be avoided. (4) Summary.
(5) Acknowledgements. (6) References, as below. (7) Key to lettering of figures. (8) Explana-
tion to plates.

ILLUSTRATIONS
To be reducible to 12cm Xx 18cm (19cm including caption). A metric scale to appear with
all photographs.

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-
cally within each name, with suffixes a, b, etc. to the year for more than one paper by the same
author in that year.

For books give title in italics, edition, volume number, place of publication, publisher.
For journal articles give title of article, title of journal in italics (abbreviated according to the

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.

FiscHER, 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.

Konn, A. J. 1960). Spawning behaviour, egg masses and larval development in Conus from the
Indian Ocean. Bull. Bingham oceanogr. Coll. 17 (4): 1-51.

THIELE, J. 1910. Mollusca: B. Polyplacophora, Gastropoda marina, Bivalvia. Jn scHULTZE. L,
Koologische und anthropologische Ergebnisse einer Forschungsreise im westlichen und zentralen Siid-
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
Scalaria coronata Lamarck, 1816: pl. 451, figs 5 a, 6; Liste: 11. Turton, 1932: 80.

"Wi 0