PALAEONTOLOGIA 
AFRICANA 

ANNALS OF THE 

BERNARD PRICE INSTITUTE 

FOR 

PALAEONTOLOGICAL RESEARCH 

UNIVERSITY OF THE WITWATERSRAND 

JOHANNESBURG 

VOLUME XI 1968 



Printed in the Republic of South Africa by THE NATAL WITNESS (PTY) LTD., Pietermaritzburg, Natal. 



BERNARD PRICE INSTITUTE FOR PALAEONTOLOGICAL RESEARCH 

BOARD OF CONTROL 

S. P. JACKSON (Chairman), 1. GL'fN THOMAS, B. I. BALINSKY, R. A. DART, 
T. W. GEVERS, S. H. HAUGHTON, F. G. HILL, B. D. MALAN, B. W. PRICE, 

P. V. TOBIAS, H. C. KOCH 

STAFF 

Honorary Director and Editor : 
S. H. HAUGHTON, B.A. (Cantab), D.Sc., Hon. LL.D. (C.T.), 

Hon. D.Sc. (Rand), Hon. D.Sc. (Nata l), 
F.R.S., F.G.S. , F.R.S.S. Afr. 

Assistant to Director and Editor: 
A. R. I. CRUICKSHANK, B.Sc. (Edin), Ph.D. (Cantab), M. Inst .Biol. 

Supervising Field Officer: 
J. W. KITCHING 

Honorary Research Fellow Palaeo-anthropology: 
R. A. DART, M.Sc. (Q'1 'd), M.B., Ch.M. (Syd.), Hon. D.Sc. (Rand), F.R.S.S.Afr. 

Field Officer Pleistocene: 
B. MAGUIRE, B.Sc. (Rand) 

Honorary Research Fellow Karroo Vertebrates: 
A. S. BRINK, M.Sc. (Stell ), Ph.D. (Lond.) 

Honorary Research Fellow Palaeobotany: 
EDNA P. PWMSTEAD, D.Sc. (Rand), F.R.S.S.Afr. 



C.S.I.R. Research Fellow Invertebrate Palaeontology, Micropalaeontology and 
Microstratigraphy: 

R. J. DAVEY, B.Sc. (Southampton), Ph.D. (Nottingham) 

Research Assistants: 

P. J. RYAN, M.Sc. (Rand), Ecca Stratigraphy. To 29/2/68 
T. STRATTEN, M.Sc. (Potch), Dwyka Stratigraphy. To 31 /8/68 

J. ANDERSON, B.Sc. (Rand), Palynology 
M. L. DE GASPARTS, B.Sc. (Naple~), Micropalaeontology. To 31 / 1/68 

P. B. BEAUMONT, B.A. (C.T.), Archaeology-Swaziland Project 
J. S. McKINNEY, M.Sc. (Oklahoma), Coal Stratigraphy. To 31 /5/68 

Technical Assistant: 
D. WOLFAARDT 

Secretary: 

Miss J. J. KALLENBACH. To 14-/6/68 
Miss E. G. BARRETT 

Non-European Laboratory Assistants: 

REGENT HUMA 
ALLISON MHLONGA 

9 Preparators 



CONTENTS 

REPORT OF THE HONORARY DIRECTOR FOR THE REMAINDER 
OF THE YEAR 1967 .. 

GONYAULACYSTA PARORTHOCERAS, A NEW SPECIES OF DINO­
FLAGELLATE CYST. By R. J. Davey 

TOOTH STRUCTURE IN RHIZODUS HIBBERTI Ag."A RHIPIDISTIAN 
FISH. By A. R. I. Cruickshank . . . . . . . . . . . . . . 3 

ON THE STRUCTURE OF THE SKIN IN URA NOCENTRODO N 
( RHINESUCHUS) SENEKALENSIS VAN HOEPEN. By G. H. Findlay 15 

A COMPARISON OF THE PALATES OF PERMIAN AND TRIASSIC 
DICYNODONTS. By A. R. I. Cruickshank . . 23 

ON THE CLASSIFICATION OF THE GORGONOPSIA. By D. 
Sigogneau. . 33 

ON THE SCALAPOSAURID SKULL OF OLIVIERIA PARRINGTONI 
BRINK. WITH A NOTE ON THE ORIGIN OF HAIR. By G. H. 
Findlay .. 47 

ON THE LYSTROSAURUS ZONE AND ITS FAUNA WITH SPECIAL 
REFERENCE TO SOME IMMATURE LYSTROSAURIDAE. 
By J. W. Kitching .. 61 

THE CONFUSED STATE OF CLASSIFICATION WITHIN THE 
FAMILY PROCYNOSUCHIDAE. By J. M. Anderson.. 77 

THE CULTURAL IMPLICATIONS OF THE RHINOCEROS TEETH 
FROM LIMEWORKS, MAKAPANSGAT. By J. M. Anderson 85 

THE LITHIC INDUSTRY IN THE MAKAPANSGAT LIMEWORKS 
BRECCIAS AND OVERLYING SURFACE SOIL. By B. Maguire .. 99 

SOME MAIN CONCLUSIONS DRAWN FROM A BASINAL ANALYSIS 
OF THE DWYKA SERIES IN THE KARROO BASIN . By T. 
Stratten .. 127 

SOME CONCLUSIONS DRAWN FROM A BASINAL ANALYSIS OF 
THE ECCA SERIES IN THE KARROO BASIN. By P. J. Ryan .. 133 



REPORT OF THE HONORARY DIRECTOR 
FOR THE REMAINDER OF THE YEAR 1967 

This report covers the period from April 1st 1967 to the end of that calendar 
year, in order that its terminal date shall coincide with that of the financial year. 

It should be stressed at the outset that the term' 'palaeontological research" , 
which forms part of the Institute's title, has in modern times a wider significance 
than it had for earlier geologists. While it still entails the collection, preparation, 
and study of fossils with the object of deciding the genera and species to which 
they can be attributed, it is becoming more and more de Ti811ellT to accept that 
they are the remains of once-living animals and plants, and to endeavour to deduce 
from all the available evidence their modes of life. That is why we in the Institute 
welcome as co-workers the scientists who are endeavouring to elucidate, by 
field and laboratory studies, the conditions and the environments in which the 
fossil-bearing sediments were deposited. 

STAFF 

During the period under review the staff was enriched by the coming of 
Dr A. R. I. Cruickshank, who arrived from Edinburgh on October 19th and 
assumed duty on that day as Assistant to the Honorary Director and Scientific 
Officer. Dr Cruickshank's special studies will be concerned with the vertebrates 
of Karroo age, a continuation in a field with which he has been familiar for some 
years. As Assistant to the Honorary Director, a good proportion of the adminis­
trative work of the Institute falls to be done by him; and he has speedily familiar­
ized himself with this aspect of his duties. 

Other welcome additions to the permanent staff are Miss]. Kallenbach , 
who became typist in April 1967, and Mr D. Wolfaardt who assumed duty as a 
technical assistant at the end of the year. 

It is pleasing to report that the longest-serving member of the staff, Mr J. 
W. Kitching, has been accepted by the University as a candidate for the degree 
of M.Sc., for which he will submit a thesis entitled "On the distribution of the 
Karroo vertebrate fauna with special reference to certain genera and the bearing 
of this distribution on the zoning of the Beaufort beds". The preparation of this 
thesis is now in hand. Mr Kitching has had to shoulder most of the day-to-day 
supervisory work during the period under review, a task he has performed with 
his customary efficiency. 

Dr E. P. Plumstead and Dr R. J. Davey, both C.S.I.R. Fellows, have continued 
their valued work at the Institute. The former, as President of the International 
Subcommission on Gondwana stratigraphy, attended a symposium held in the 
Argentine and Brazil. She also attended a symposium on Continental Drift at 
Montevideo, organized under the joint auspices of J.U.G.S. and U.N.E.S.C .O . 



With the consent of the Government of South Africa she issued, at the Argentine 
meeting, an invitation to hold a Gondwana symposium in the Republic in 1970, 
an invitation which was cordially accepted. An organizing committee for this 
symposium has been established by C.S.I.R. Dr Davey has acted, inter alia, as an 
adviser to S.O.E.K.O.R.; this Corporation has agreed to the appointment, as 
from the beginning of 1968, of Mr J. Anderson as a palynologist, working on 
their behalf, on the staff of the Institute and to subsidize the Institute for this 
work. 

Professor Dart's assistants, Messrs. B. Maguire and P. Beaumont, have 
continued to work at the Institute, as have the two subsidized sedimentary 
geologists Messrs P. Ryan and T. Stratten. Mr A. Keyser, of the Geological 
Survey staff, is preparing a thesis on certain anomodont reptiles, and has made 
considerable use of the facilities which we have placed at his disposal. 

PUBLICATIONS 

During the period under review, Volume X of Palaeontologia Africana was 
issued and distributed. The major part of this volume consists of Dr Plumstead's 
description of the fossil plants of the Cape system (Palaeozoic), in the preparation 
of which she examined almost every specimen available in collections in South 
Africa. The paper is illustrated by 25 photographic plates . Financial contributions 
to the cost of this volume made by C.S.I.R. and by the Geological Survey of 
South Africa are gratefully acknowledged. 

The preparation of Volume Xl is in hand. 

RESEARCH WORK 

A. Palaeoanthropolo8Y 
Until his departure for the United States of America in August to occupy a 

chair in Philadelphia, the work of Messrs Maguire and Beaumont was supervised 
by Emeritus Professor R. A. Dart. Mr Maguire had completed, by July, his 
analysis of more than 16,000 suspected chert artefacts found in the surface soil 
overlying the australopithecine pink breccias at the Makapansgat Limeworks site 
and presented his findings on these very primitive worked cherts at the S2 A ~ 
meeting in Pretoria. During two visits to Makapansgat he collected some 200 
artefacts from the Phase 2 breccia. He is continuing with an examination of 
quartzite and vein-quartz artefacts from soils above the breccias and of the stone 
artefacts from the solution cavities which penetrate the surface of these breccias. 
The collection under study consists of approximately 40,000 pieces. 

Mr Beaumont has continued with the investigations into the pre-European 
mining industry in Swaziland which he has been undertaking with the support of 
the Anglo American Corporation. 

Plans have been drawn by Professor P. V. Tobias and a band of co-workers 
for a further detailed attack on the problems posed by the famous site at Sterk­
fontein which is under the control of the Univers ity of the Witwatersrand, 

ii 



whose Council has charg~ the Board of Control of this Institute with its super­
vision. These plans include new excavations within a defined area-now sur­
rounded by a security fence. Preliminary clearing of rubble has begun, and from 
this rubble some 380 artefacts, some with adherent breccia, had been recovered 
by the end of August. From the rubble there have also been extracted bone­
bearing breccia and rodent bones in addition to the artefacts of various cultures 
(early Acheulean, MSA, and LSA); all have been labelled and stored. The direct 
responsibility for the field activities rests on Mr A. R. Hughes, Supervisor of 
Laboratories of the University's Department of Anatomy. The main objects of 
the renewed studies are to ascertain the full extent of the cave deposit, to throw 
further light on the stratigraphy of the breccias, to obtain (if possible) absolute 
radioactive dating of the deposits, and to increase the knowledge of the fauna. 

B. Karroo Fossil Reptiles 

Since his arrival at the Institute Dr Cruickshank has begun a study of the 
diapsid genus Chasmatosaurus and of its relationship to the later form Erythrosuchus. 
He has prepared certain specimens by removal of matrix; among them is an 
almost complete foot thought to belong to the second of these genera. The study 
was, of course, merely in its preparatory stages at the end of 1967. 

Mr A. Keyser, of the Geological Survey staff, has made considerable use of 
the Institute's facilities and collections, including specimens from the Rubidge 
collection, in preparation for a doctoral thesis on the skull characters of certain 
Anomodont genera. Much of the material that he has handled has been further 
developed in order to display features in which he is particularly interested for 
comparative purposes. 

As an initial step in the preparation of his thesis Mr J. W. Kitching has 
compiled a record on cards of the exact locality of each of the known and 
identified reptiles from the Karroo beds in South Africa and has pictorially 
represented this information on an extensive wall-map formed of sheets of the 
Topocadastral maps on the scale of 1 :250,000. He has begun the compilation of a 
detailed chart which will show the zonal distribution of the known genera. There 
can be no doubt that this study will lead to a revised zonification of the Beaufort 
series. 

We have received a typescript copy (in two volumes, one consisting of 
photographs) of the thesis submitted in Paris by Dr D. Sigogneau. The thesis 
deals with the classification and anatomy of the Gorgonopsia and is based almost 
entirely on studies which she undertook in the Institute over a period of nearly 
two years. The contents of the thesis, which is in French, are very detailed; but 
the conclusions are of such importance that we hope to be able to publish an 
extended summary in Palaeonto]oBia Ajricana. 

C. Micropa]aeontoloBY 

Dr R. J. Davey has undertaken work on Cretaceous microplankton oc­
curring in borehole core material from Zululand. He has paid particular attention 

iii 



to three genera of hystricospheres and their genetic relationships and has shown 
that by the systematic change of certain variables an evolutionary series has been 
produced, possibly as a result of the adaptation of the organisms to environment. 
He considers that the evolutionary stages can be correlated with positions in the 
Upper Cretaceous sedimentary seguence. In this work the Institute's Zeiss 
photomicroscope has proved of great value. Dr Davey has spent some time in 
revising his Ph. D. thesis on non-calcareous microplankton from the Cenomanian 
of England, France and orth America, which will be published by the British 
Museum (Natural History) in 1968. He has also supervised the preparation of 
palynological material from borehole cores submitted by S.O.E.K.O.R. 

D. Palaeobotany 

Dr Plumstead has continued her studies of fossil plants from various 
parts of Africa and has examined material from a new area of Antarctica sent to 
her by the British Antarctic Survey. Borehole cores from Somkele, Zululand, 
sent by the Geological Survey, yielded excellent samples of two plants, one of 
which is new to South Africa, while specimens from the deepened Sambokkraal 
borehole near Merweville, C.P., sent by S.O.E.K.O.R. , yielded a new species. 
Two visits to the Orange Free State yielded specimens from a new shaft on St 
Helena G.M. and from a number of borehole cores. Collections of plant fossils 
were recorded from the Ulco Limeworks and from the area of the Verwoerd dam. 

For publication, Dr Plumstead prepared" A Review of Contributions to the 
Knowledge of Gondwana mega-plant fossils in Africa published since 1950" 
which was presented at the Gondwana Symposium in Argentina in October 1967, 
of which she was President, and' 'Fossil Floras and Latitudes" which was presented 
at the Continental Drift Symposium in Uruguay in the same month. 

Mr J. Anderson, an M.Sc. student, worked on Triassic fossil plants which he 
had collected from the Oliviershoek Pass area in Natal. 

E. SedimentoloBY 

Throughout the period under review Mr T. Stratten and Mr P. J . Ryan 
continued work at the Institute. The former is making a detailed study of the 
Dwyka series of the Karroo basin; the latter almost completed his description of 
the sedimentology of the Ecca series of the same basin, which he has presented as 
a Ph.D. thesis to the University of the Witwatersrand. The detailed work of 
both investigators has an important bearing on the understanding of the ecological 
conditions under which plant and animal life flourished in the region in Lower 
Karroo times. 

TEACHING 

The institution by the University of an Honours B.Sc. course in Palaeontology 
necessitates the regularization of formal instruction and the extension, in a 
limited degree, of the assistance that, for some years past, has been given by 
members of the Institute. 

iv 



As a part-time lecturer attached to the Department of Geology, Dr Plum­
stead has given courses in Palaeobotany and in the Geology and Petrology of 
Coal to 2nd, 3rd and 4th year students, while Mr Kitching has been called upon 
to give talks on Karroo vertebrates and Karroo stratigraphy to undergraduates. 

For the year 1968, Regulations bearing upon the Honours B.Sc. in Palaeon­
tology have been drawn up and submitted to the University for approval. If 
adopted, they will necessitate close liaison between the Institute's staff and the 
Professor of Anatomy and his staff. 

v 



GONYAULACYSTA PARORTHOCERAS 

A New Species if DINOFLAGELLA TE CYST 

by Roger J. Davey 

INTRODUCTION 

Da vey (1968 in press) emends the species Gonyaulacysta orthoceras Eisenack 
and also transfers it to the genus Cribroperidinium Neale and Sarjeant. By emending 
Eisenack's species the specimens described by Sarjeant (1966) as G. orthoceras, 
from the Lower Cretaceous of England, must now be excluded from this species. 
Hence, a new species is here erected to accommodate them. 

SYSTEMATIC DESCRIPTION 

Gonyaulacysta parorthoceras sp. nov. 
1966 Gonyaulacysta orthoceras (Eisenack); Sarjeant: 121, pI. 14, figs. 5, 6; 

text-fig. 29 

DIAGNOSIS: 

HOLOTYPE: 

Shell ovoidal with strong, tapering apical horn accounting for 
about one-fifth to one-quarter of overall length. Shell wall of 
moderate thickness, granular to tuberculate. Tabulation 4', 1 a, 
6", ?6c, 7"', Ip, 1""; crests low bearing small spinelets. 
Cingulum strongly spiral, of moderate breadth: sulcus broad 
and extending to antapex. 
B.M. (N.H.) slide V.51730, specimen 3. Speeton Clay, Shell 
West Heslerton Borehole No.1, West Heslerton, Yorks, at 
19.25 metres depth. Lower Cretaceous (Upper Barremian). 

REFERENCES 

DA VEY, R. J., 1968. Non-Calcareous Microplankton from the Cenomanian of 
England, Northern France and North America. Bull. Br. Mus. nat. Hist., 
London. Vol. 17, no. 3 (Part 1) (in press). 

EISENACK, A., 1958. Microplankton aus dem norddeutschen Apt nebst einigen 
Bemerkungen tiber fossile Dinoflagellaten. Neues Jb. Geo]. Palaont, Abh., 
106, 3: 383-422, pIs. 21-27. 

NEALE, J. W. & SAR]EANT, W. A. S., 1962. Microplankton from the Speeton 
Clay of Yorkshire. Geol. Mag ., 99, 5: 439-458, pIs. 19, 20 . 

SAR]EANT, W. A. S., 1966. Dinoflagellate Cysts with a Gonyaulax-type tabulation, 
in Studies of Mesozoic and Cainozoic Dinoflagellate Cysts. Bull. Br. Mus. nat. 
Hist., London. Suppl. 3: 107-156. 



TOOTH STRUCTURE IN Rhizodus hibberti 
AG., A RHIPIDISTIAN FISH 

by A. R. J. Cruickshank 

Department of Zoology, Edinburgh University, 
West Mains Road, Edinburgh, 9, Scotland 

Present address: 
Bernard Price Institute for Palaeontological Research, 

University of the Witwatersrand, 
Jan Smuts A venue, 

Johannesburg, 
South Africa 

ABSTRACT 

The structure of the large laniary teeth of the Lower Carboniferous rhipidistian fish Rhizodu 
hibberti Ag. is interpreted in terms of a new theory of tooth development. The structure of these 
teeth is found to correspond almost exactly to that of the synchronomorial scale as defined by 
Orvig (195 1) and Stensio (1961 ; 1962). These labyrinthodont teeth are thus shown to be composed 
of many tooth primordia, and are not a single unit of dentine. Some isolated Rhizodus teeth are 
described in which the entire labyrinthodont structure is missing, leaving an empty space inside 
the tooth. From this, a non-mechanical tooth remova l mechanism is postulated. 

I TRODUCTION 

New interpretations of vertebrate hard tissues (bone, dentine and enamel) 
have been made by Orvig (1951) and Stensio ( 1961; 1962). The former reviewed 
the characteristics of the various types of dentine and introduced into his discussion 
a new theory on which to base descriptions of teeth and scales. This is termed 
the" Lepidol11orial Theory". The lepidol11orial theory proposes that each tooth 
or scale in any vertebrate is composed in general of severallepidol11oria or units 
of dentine. Lepidol11oria can be combined in two basic ways, to give what are 
known as e ither adesmic or monodesmic teeth or scales. Stensio (1961 ; 1962) 
elaborated the lepidomorial theory and introduced the terms' cyclomorial' and 
'synchronomorial' to describe the state of affairs if more than one generation of 
lepidol11oria were involved in tooth or scale formation. In the adesmic or cyclo­
morial state the lepidomoria lay down hard ti ssue before the papillae have time 
to fuse and in the monodesmic or synchronomorial scale the opposite holds good 
(figs. 1 & 2). 

3 



Synchronomorial scales thus contain at an early stage one large compound 
pulp cavity. It is surrounded by a thin layer of mantle dentine which bulges 
outward into vertical ridges, marking the position of the individuallepidomorial 
crowns. Between these ridges, the mantle dentine projects inwards into the 
pulp cavity as comparatively low intrapulpar crests. These crests represent the 
vestiges of the mantle dentine in the lepidomorial crowns where the latter fused 
together. During further development they grow inward and join, thus forming 
several partition walls which divide the embryonic monodesmic pulp cavity 
into secondary lepidomorial units. Circumvascular dentine is gradually developed 
on the partition walls so that the interior of the crown is almost completely 
filled with hard tissue (fig. 2c). 

Running through the simple pulp cavities of the lepidomoria of Palaeozoic 
elasmobranchs was a vascular loop. It entered the scale by means of a neck canal 
and left through a basal canal (fig. 1). These canals persist in considerable numbers 
in the composite scales of these fish and must be correlated with the vascular 
canals of Williamson as seen in ganoid scales (fig. 4). Dentinal tubules in each 
lepidomorial unit or crown issue from the upper part of each ascending vascular 
canal of Williamson. 

Orvig (1951) concludes that all hard tissues in the vertebrates are related 
and laid down by cells which, although differing in anyone animal, have a common 
ancestry. Thus bone, dentine and enamel are closely related tissues. Enamel is 
further differentiated into that belonging to the lower vertebrates and that 
belonging to the mammals. In the former it is of mesodermal origin and in the 
latter it is of ectodermal origin (Kvam 1946; Poole 1956a & b; Scott & Symons 
1964). As opposed to many earlier authors (e.g. Widdowson 1928) Orvig 
recognises only three types of dentine in the lower vertebrates. These he calls 
osteodentine, tubular dentine and orthodentine. 

Osteodentine is composed of dentinal osteons (modified primary osteons as 
opposed to Haversian systems proper) and an interstitial bony substance which 
mayor may not contain bone cells. The bony substance arises first as trabeculae 
in the pulp tissue and the dentinal osteons are then deposited on the trabeculae 
without any resorption of the hard tissue. Before the formation of the dentinal 
osteons the intervascular trabeculae are lined with cells, frequently osteocyte-like, 
which during the process of deposition of the dentinal osteons modify into true 
odontoblasts. 

Tubular dentine, as defined by Moy-Thomas (1939b), is composed of dentinal 
osteons with an interstitial enamel-like substance. However, Poole (1956a & b) 
regards this sort of enamel as being similar to dentine and thus tubular dentine 
may be only a variety of orthodentine. 

Orthodentine consists of an outer layer of pallial (mantle) dentine and an 
inner layer of circumvascular (circumpulpar) dentine. The latter consists of 
large dentiml osteons, either lining vascular cavities in the teeth or the whole 
pulp cavity. The mantic dentine is pierced by odontoblast processes and may be 
very thin. Vasodentine (Tomes) is regarded as a variety of orthodentine showing 



secondary loss of odontoblasts and the incorporation of blood capillaries in the 
dentine. 

It is not known which type of dentine is the oldest. Orvig (1951) considers 
that teeth originally consisted of an outer layer of mantle dentine with an inner 
mass of osteodentine. In the majority of cases the osteodentine has been lost and 
the teeth are thus formed from orthodentine. Tarlo (1963; 1964) and Orvig 
(1965) discuss the nature of "aspidin", an acellular bone-like tissue found in 
Ordovician ostracoderms. In support of his earlier work, Orvig considers it to 
be secondarily acellular, whereas Tarlo concludes that the condition is primitive, 
seeing that it is the oldest vertebrate hard tissue known. 

Bystrow (1938; 1939; 1942) has described the structure of teeth and dermal 
bones of osteolepid and dipnoan fish and labyrinthodont amphibia. This present 
publication is the first to describe the well-known labyrinthine tooth structure 
of Rhipidistians in terms of the lepidomorial theory. The similarity of the 
labyrinthodont tooth to the synchronomorial scale is notable (figs. 2 & 3). In 
addition, tooth replacement phenomena are described here which agree with 
those illustrated by Bystrow, but which do not agree with the usually accepted 
patterns. 

MATERIAL AND METHOD 

The specimens used in the descriptions are from the unregistered collection 
of the Royal Scottish Museum, except for the tooth sectioned longitudinally 
(figs. 5 & 6). This latter specimen is from the Hugh Miller collection and has 
the number E. (Nat. Hist.) 352. 

The techniques used in preparing the teeth for study were small variations 
of standard rock-section cutting. An attempt to make serial transverse sections 
of one tooth was only partially successful. The apparatus used for this attempt 
was a screw slot-cutter with a reinforcing washer. However it tended to shatter 
both the tooth and itself if the specimen was not held absolutely rigid. 

DESCRIPTION OF MATERIAL 

The fish from which the teeth came is classified by Romer (1966, p. 361) 
as follows: order Crossopterygii, sub-order Rhipidistia and family Rhizodontidae. 
Rhizodus is common in the Lower Carboniferous of both Europe and orth 
America. In general the fish of this family have slender bodies, paired fins with 
short obtuse lobes and cycloid scales. In some forms there is a heterocercal tail 
and the backbone has ring-like centra (Rhizodopsis), while in others the tail is 
diphycercal and the notochord is unconstricted (Moy-Thomas 1939a). Hugh 
Miller, quoted by Barkas (1875), estimated that some individuals of Rhizodus must 
have measured at least 40 feet overall although the only complete specimen 
recorded was 9 feet long (Stock 1880). 

5 



Two sorts of tooth occur on the mandibl es of Rhizo dus : a fringe of denticles 
1.5-2.0 cms . high on the dentary and a shorter series of very much larger teeth 
on shelves of bone (coronoids) inside the dentary (fig. 5). Each shelf of bone 
supporting Jan iary teeth has room for two, only one of which is normally fully 
erupted (Pander 1860, Tab. 10 & II) . The external appearance of both types of 
teeth is identical, except for their size. The height of the large laniary teeth on a 
mandible 25 cm. long diminishes from 6 cm. at the fro nt to just over 2 cm . at 
the back. There were four functional laniary teeth on this mandibl e, one laniary 
tooth in the process of being shed, and seven denticl es . In other specimens the 
number of denticles is very much greater, and it is thought that this low number 
is aberrant. 

The lan iary teeth are slender cones which curve backwards and inwards. 
They are oval in cross section with the long axis roughly parall e l to the jaw and 
the oval may be drawn out into one or two fine cutting edges. The basal third of 
the crown is cut by deep grooves and the whole c rown is covered in fine striae. 

The lan iary teeth of Rhizodus have the same macrostructure as the synchro­
nomorial scale described by Orvig ( 195] ). Distally there are no intrapulpar 
crests dividing the pulp cavi ty and on the ex terior there is a moderately thi ck 
layer of enamel. Towards the root intrapulpar crests develop and finally a rather 
compl icated infolding of the dentine is seen (the' Plicidentine' of Tomes) (f ig. 
3c-d). The ename l layer thins off towards the neck of the tooth. Also, in the 
grooves, it is th inner than normal. 

Smart (personal communication) suggests that the pack ing together of the 
lepidomorial units typical of 'Plicidentine' would l1'lake an ext reme ly strong, 
yet light structure designed to withstand heavy shocks. It is known that the 
majority of fish and aquat ic arthropods of thc Ca rbonifero us were heavily 
armoured and a strong piercing tooth would be essenti?1 to thcse predacious 
Rhipidistians. 

In longitudi nal sect ion the ascending vascu lar ca nals of Will iamso n are 
c learly seen. These gradual ly fuse to form the single monodesmic pulp cavity 
(fig. 6). No neck canals of Williamson are present. The ascendi ng vascu lar canals 
0 1 Williamson connect directly w ith the vascular spaces in the jaw and the ce ll 
spaces become visible as the dentine becomes more bone-like. Eventuall y the 
cell spaces take the fo rm of true osteocytes, in a simi lar manner to those of bone 
of attachment. 

Typically, odontob last spaces are not found in orthodentine. However, in 
the teeth of this spec imen of R. hibberti they occurred frequently in the dentine 
lining the pu lp cav ity . They measure about 7fL by 2fL. The dentinal tubes are about 
lfL in width, and the "growth lines" of the circumpulpar dent ine coincide with 
the point where they branch. (In fact it is not a branching, but a fusion of the 
inwardly migrat ing odontob lasts whi ch causes these rings to appear (fi g. 7).) 

No other ce ll spaces are present in the dentine, but near the exter ior of 
the tooth a granular layer containing many cell-li ke spaces is seen. This may be 
sim ilar to the 'G ranu lar layer of Tomes' as found in mammals, but in position is 

6 



more akin to the regions of globular dentine described by Bystrow in Osteolepis and 
other labyrin thodonts. It is however not near! y so ext ensi ve as in these other ani mals. 

The teeth of Rhizodus are thecodont and are held in the jaw with a well 
developed bone of attachment. Basally and radially this bone of attachment passes 
into true bone with cell spaces, and is distinct from the dentine at all levels 
except the lowest. Bone of attachment is seen in the crevices on the exterior of 
the tooth. As the grooves widen towards the base of the crown, this bone of 
attachment tends to cover more and more of the outer surface until at the level 
of the jaw it surrounds the entire crown. Where enamel is present, bone of 
attachment always overlies it. In the lower basal sections there are some spaces 
between the trabeculae of bone of attachment rather bigger than normal. These 
spaces may mark regions where bone has not been formed, or, having been formed, 
is in the process of being resorbed prior to the tooth being shed (fig. 3d) (see 
also under Discussion). 

Cell spaces do not occur in the bone of attachment except near the base of 
the tooth and where it merges into the bone of the jaw. At first these cell spaces 
are compact with few processes and measure approximately 30fL by 8fL. Their long 
axes are parallel to the trabeculae. Towards the jaw their shape gradually changes 
and more processes are seen. The cells here measure 40fL by 5fL (Roux 1942). 

Bone of attachment presents rather higher birefringence in polarised light 
than does dentine and a more even colour than ordinary bone. This is possibly 
due to the presence of smaller crystallites more constantly orientated and 
coincides with the idea that bone of attachment was being constantly removed 
and relaid while the tooth erupted. 

Resorption of tooth tissue is known to occur in most vertebrates from the 
outside initiated through mechanical stimulus . Whereas this probably occurred 
in Rhizodus, there is also evidence that dentine was resorbed through the pulp 
cavity. Transverse sections of an isolated tooth found in rock, and especially those 
sections from the base of this tooth, show a marked difference from the cor­
responding sections of teeth still attached to jaws (fig. 9a & b). In the latter all 
structures associated with the labyrinthodont pattern are seen, but in the former 
most of the dentine has been removed and all that remains is the outem10st layer. 
Bone of attachment shows signs of erosion, but enamel seems to be untouched. 
The complete jaw referred to on page 6 has a pair of laniary teeth with their 
roots contiguous. If, as is most likely, one of these teeth is replacing the other, 
then signs of dentine removal are to be expected on the side of the older tooth, 
nearest the replacing one. No evidence of this can be seen. 

In figure 3d it will be noticed that alongside the fully functional tooth there 
lies remnants of another. The matter is discussed below. 

DISCUSSION 

.. The interpretation of the labyrinthodont tooth given in this paper, using 
Orvig's descriptions of the synchronomorial scale as a basis, gives an entirely new 

7 



orientation to one of the best known features of the Palaeozoic fish and amphibia. 
A consideration of the generalised synchronomorial scale shows that the equi valent 
of many generations of tooth material fuse to form a single tooth. This is the state 
of affairs seen in the labyrinthodont tooth of Rhizodus hibberti of the Lower 
Carboniferous. 

Under Tomes' classification the dentine in labyrinthodont teeth was known 
as 'Plicidentine'. It can now be interpreted more accurately as a variety of 
orthodentine, with an outer layer of mantle dentine and an inner layer of circum­
vascular dentine (Orvig 1951, pp . 347-359) . Mantle dentine is characterised by 
the presence of odontoblast processes; it is of even structure and does not have 
the concentric lines similar to growth rings that circumvascular dentine has 
(figs. 7 & 8). Therefore it would appear to represent an initial rapid deposition 
of hard tissue and would be expected to predominate in the tip of the tooth. 
As far as can be ascertained this is so. 

A granular layer similar to that in the dentine is seen in the enamel, becoming 
more marked towards the tip. At the same time the layer in the dentine becomes 
reduced (fig. 8). The presence of this layer in the enamel can be explained if this 
enamel is formed by the dentine organ and is subjected to similar influences as 
the dentine during development. Therefore the enamel is probably mesodermal 
in origin. 

In postulating that the dentine of these teeth was removed under control of 
a non-mechanical system, rather than in the more normal way, the following 
facts must be examined. Firstly, each shelf of bone supporting the laniary teeth 
has room for only two, and, of which, it seems normal that only one was functional 
at anyone time. On the lower jaw of Rhizodus referred to on page 6, a pair of 
teeth lie side by side. There is no evidence of erosion where they are in contact, 
which would be expected if mechanical stimulus was the normal method of 
removing the older tooth. Secondly, transverse sections of adjacent tooth sockets 
show remnants of dentine with labyrinthodont structure lying round the edge of 
the empty socket and other sections of isolated (presumably shed) teeth identified 
as belonging to Rhizodus, reveal that all internal dentine is absent. These observa­
tions suggest that the dentine is removed from the interior before the tooth is 
.shed. Any mechanism responsible for dentine resorption could also trigger off 
the eruption of the other tooth of the pair. 

It could be postulated that the isolated teeth with no labyrinthodont struc­
tures present were in fact newly erupted teeth broken away from the pair as a 
natural hazard of life. However in figure 9b it will be seen that the remnants of 
dentine and enamel are in general only slightly thinner than the walls of the tooth 
in figure 9a. The dissociated nature of the fragments can be explained only if the 
supporting structures in the centre of the tooth had been eroded from the inside. 

ewly erupted teeth figured by Bystrow (1938) for Benthosuchus always have the 
labyrinthodont structures thinly developed, as are the tooth walls themselves. 
They are much thinner than the tooth wall in figure 9b. 

Bystrow (1942) discusses the pattern of dermal bone growth in Dipterus 

8 



with reference to Westoll-lines. In sections of dermal bones he shows resorption 
spaces occurring within the hard tissues and, in other publications (1938; 1939), 
he shows similar resorption spaces in the bases of teeth of Benthosuchus, Glyptolepis, 
Ho10ptychius and Eusthenopteron. Regarding the Westoll-lines, Jarvik (194-8) agrees 
that they must represent growth stages, an0 Bystrow's analysis of their nature 
must lead to the conclusion that some cyclical mechanism of dentine resorption 
from within the tooth must have operated in these vertebrates. 

In some mammals milk teeth are shed even if the permanent tooth-germ is 
excised (Oberstzyn 1963). Therefore it seems possible that replacement teeth 
do not need to erupt from directly below the functional tooth and that the basal 
dentine can be removed by some process other than mechanici'.l stimulus. 

ACKNOWLEDGMENTS 

The descriptions of the laniary teeth of Rhizodus hibberti in this paper were 
carried out as part of the requirem.ents for the degree of B.Sc. (Hons.) in Zoology 
in Edinburgh University. I am very grateful to Dr C. D. Waterson of the Royal 
Scottish Museum for the loan of the material, to Mr G. F. Friend for supervising 
the work, and the technical staff of both the Geology and Zoology Departments 
for the time and trouble taken helping to cut the sections and take the photographs. 
The Cambridgeshire Education Authority supplied a very generous grant during 
the course of the year. Dr R. Sprinz and Dr Alun Maddy kindly read this paper in 
manuscript and made many valuable suggestions for its improvement. Mr G. M. 
Burnett undertook the onerous task of translating the German texts, for which I 
am very grateful. 

REFERENCES 

BARKAS, W. J., 1875. On the microscopical structure of fossil teeth from the 
Northumberland Coal Measures. Mon. rev. dent. sura., 4, 393- 394-. 

BYSTROW, A. P., 1938. Zahnstruktur der Labyrinthodonten. Acta zool. Stockh., 
19, 357-4-25. 

BYSTROW, A. P., 1939. Zahnstruktur der Crossopterygier. Acta zool. Stockh., 20, 
283-338. 

BYSTROW, A. P., 194-2. Deckknochen und Zahne der Osteolepis und Dipterlls. 
Acta zool. Stockh., 23, 263-289. 

JARVIK, E., 194-8. On the morphology and taxonomy of the Middle Devonian 
osteolepid fishes of Scotland. K. Svenska Vetensk-Akad. Handl., 25, 1- 301. 

KVAM, T., 194-6. Comparative study of the ontogenetic and phylogenetic 
development of dental enamel. Norske Tandelaeaiforen. Tid. (supplement). 
56, 1-198. 

Moy-THOMAS, J. A., 1939a. Palaeozoic fishes. London, Methuen. 
Moy-THOMAS, J. A., 1939b. Evolution of the elasmobranchs. Biol. Rev., 14, 1-26. 

9 



OBERSZTYN, A., 1963. Experimental investigations of factors causing resorption 
of deciduous teeth. J. dent. Res., 42, 660-674. 

ORVIG, T., 1951. Histologic studies of placoderms and fossil elasmobranchs. 
I. The endoskeleton. Ark. Zo01., 2, 321-456. 

ORVIG, T., 1965. Palaeohistological notes. 2. Ark. Zool., 16,551-556. 
PANDER, C. H., 1860. Uber die Saurodipterinen, DendrodOriten, Glypto1epiden und 

Cheirolepiden des devonischen Systems. St Petersburg. 
POOLE, D. F. G., 1956a. Fine structure of scales and teeth of Raia clavata. 

Q.)I. microsc. Sci., 97, 99-107. 
POOLE, D. F. G., 1956b. Structure of teeth in mammal-like reptiles. Q. )1. 

microsc. Sci., 97, 303-312. 
ROMER, A. S., 1966. Vertebrate palaeontology. 3rd edition. UniverSity of Chicago 

Press. 
Roux, G. H., 1942. Minute structures in the scales of Latimeria. S. Afr. J. med. 

Sci., 7, 1-18. 
SCOTT, J. H. & SYMONS, N. B., 1964. Introduction to dental anatomy. Edinburgh 

and London, E. & S. Livingston. 
STENSIO, E. A., 1961. Permian vertebrates in Geology ?Jthe Arctic. Ed. G. O. Raasch. 

Toronto University Press. pp. 231-247. 
STENSIO, E. A., 1962. Origin et natur des ecailles placoids et des dents. Colloq. 

into Cent. naw. Rech. scient., 104, 75-85. 
STOCK, T., 1880. Note on the discovery of an entire specimen of Rhizodus sp. 

in the Wardie Shales. Trans. Edinb. geol. Soc., 4, 38. 
TARLO, L. B. H., 1963. Aspidin: the precursor of bone. Nature, London, 199, 

46-48. 
TARLO, L. B. H., 1964. The origin ?Jbone in Proceedings ?J the first bone and tooth 

symposium, Oiford. 1963. Oxford, Pergamon Press. 
WlDDOWSON, T. W., 1928. Dental anatomy and physiology and dental histology. 

London, Bale, Sons & Danielson Ltd. 

10 



Fig. 1. 

Fig. 2. 

Fig. 3. 

Fig. 4. 

Fig. 5 

Fig. 6. 

Fig. 7. 

Fig. 8. 

Fig. 9. 

EXPLANATION OF TEXT FIGURES 
The mode of formation of Cyclomorial scales. From brvig, 1951. 
(a) Vertical section of the primordial lepidomorium, consisting of a dentine crown and 
a bony base. 
(b) A more advanced stage of development. The hard tissues of the second lepidomorium 
have begun to form. 
(c) Two lepidomoria in the final stages of development. 
lpca-lepidomorial pulp cavity; cr-crown of primordial lepidomorium; ve-vessels 
entering the pulp cavity through both the neck and basal canals of Williamson; bp-basal 
plate of the primordiallepidomorium; can. W. n. - neck canal of Williamson; p. Idu' ­
papilla of soft tissue of the first areal zone of growth; ldup-ldu'-crowns of the primordial 
and second lepidomorium respectively; bpa-basal plate of the Cyclomorial scale; can. 
W. b-basal canal of Williamson; bp'- basal plate of the second lepidomorium. 
The mode of formation of a Synchronomorial scale. From brvig, 1951. 
(a) Horizontal section of the crown at early stage of development. A thin layer of mantle 
dentine has formed round the embryonic synchronomorial pulp cavity. 
(b) More mantle dentine has formed, and the intrapulpar crests have grown out to form 
partition walls. 
(c) Formation of dentinal osteons within the secondary lepidomorial pulp cavities formed 
in stage two. 
pd-pallial (mantle) dentine; ipcr- intrapulpar crests; v. sp.-secondary lepidomorial 
pulp cavities; v. can-vascular canals; osd-dentinal osteons; empca-embryonic 
monodesmic pulp cavity. 
Transverse sections of laniary tooth of Rhizodus hibberti Ag. 
Unregistered collection Royal Scottish Museum. See also Fig. 5. 
(a) 2 cm. from apex. 
(b) 2.26 cm. from apex. 
(c) 2.46 cm. from apex. 
(d) 4.11 cm. from apex . 
Pc-main pulp cavity; ipcr- intrapulpar crests; ce-cutting edge of tooth; Sp-large 
spaces between tooth and jaw-bone; Od-dentine of functional tooth; Od' -dentine of 
alternate tooth; Ba-bone of attachment; Bj-bone of jaw. lines represent 1 cm. 
Vertical section of ganoid scale to show ascending canals of Williamson (can. W), but no 
neck canals. From brvig, 1951. 
Tooth of Rhizodus hibberri Ag. prior to being sectioned transversely . See also Fig. 3. 
Unregistered collection, Royal Scottish Museum. Bj- bone of jaw; Sh-shale in which 
tooth and jaw remnant is embedded. Line represents 1 cm . 
Longitudinal section of incomplete laniary tooth of R. hibberri. Registered number E 
(nat. hist.) 352. Hugh Miller collection, Royal Scottish Museum. 
Pc-main pulp cavity; Ba-bone of attachment; Bb- basal bony region of tooth; Bj- bone 
of jaw; can. W-ascending canal of Williamson; V. can . J-vascular canals of the jaw. 
Line is 1 cm. long. 
Orthodentine in laniary tooth of R. hibberti, showing mantle dentine (pd) and circum­
vascular dentine (Cpd). The latter with "growth rings" caused by synchronous fusion of 
inwardly migrating odontoblasts (Gr). Ba- bone of attachment. Line is 1 mm. long. 
High power view of figure 3b. to show granular layer in both dentine and enamel. 
e-enamel; gr. e-granular layer in enamel; gr. d-granular layer in dentine; pd-mantle 
dentine. Line is 50fL long. 
Transverse sections of Rhizodus teeth at equivalent levels. 
(a) Section of tooth immediately above level of jaw-bone. c.f. fig. 3c. 
(b) Basal section of isolated tooth with dentine missing from interior of tooth. Distortion 
of tooth caused by pressure of overlying sediment. 
Od-dentine. 

11 



Fig. 1 

i-.'·,X:·_ ... ::/ 

b'p 

FiJ.3 

~,.,,:-':~~~t:.,,:.~:~::;.~-.~.:,; . );' \. 
con·""n 

1. 

12 

1b 

3c 



Fig.6 

13 



ON THE STRUCTURE OF THE SKIN IN 
URANOCENTRODON (RHINESUCHUS) SENEKALENSIS, VAN HOEPEN 

By G. H. Findlay 

In the famous collection of fossil remains of the labyrinthodont Urano­

centrodon, housed since 1911 in the Transvaal Museum, the bony skin armour from 
the ventral surface of the body of at least six individuals has been preserved. In 
spite of this lavish quantity of material only a few notes on the osseous skin 
structure were included in van Hoepen' s (1915) description, and all later papers 
have passed it by almost completely. 

The two most recent contributions with full bibliographies on the skeleton 
of Uranocentrodon are those of Romer (194-7) and Watson (1962). 

Most of the sandstone slabs from the L)'Strosaurus (basal Triassic) zone of 
Senekal which contain this skin material have been grouped together for many 
years in a large closed display case. Three slabs apparently unconnected with 
each other had not been cemented into the display and were separately available 
at the Museum for detailed study. They proved to belong together, and fitted to 
yield a strip of armour some 25 inches long down the ventral midline and in 
places up to 4- inches broad on one or other side of the midi ine. On these portions 
the present study is mainly based. They had been presented to the museum by the 
Municipality of Senekal after the main collection had been purchased. 

The complete skeleton of Uranocentrodon in the ational Museum, Bloem­
fontein, has a length between the limb girdles of some 4-0 inches, clearly covered 
by ventral armour which extends laterally to a maximum of 5-6 inches from the 
midline. From these measurements, it may be concluded that the study material 
available which comprised this 25 inch strip gave a fairly extensive view of the 
skin structure, pending opportunities to compare it in detail with the rest of the 
collection. 

ORIENTATION OF SPEC/ME S 

The dermal ossicles in Uranocentrodon form an inverted-V or chevron 
pattern, with the point of the chevron lying in the ventral midline directed like an 
arrowpoint towards the head end of the animal. In the specimen studied the 
bilaterally diverging lines of bones meet at an angle of 60° at the anterior end of 
the specimen falling to 50° over the slenderer parts farther back. The angles of 
divergence from the midline itself decline therefore from 30° to 25 ° respectively. 

Mostly it was the internal aspect of the skin armour which showed uppermost 
on the stone slabs from Senekal. In some cases the skin had obviously slipped out 
of line with the vertebral column and was clearly indented from above by dis­
placed parts of the axial skeleton. 

15 



Because the ossicles overlap one another, it is their medial ends which are 
seen on the internal surface of the armour, and their lateral ends on the external 
surface. Therefore if the free ends of the ossicles point towards the midline, it is 
the internal surface which is being examined. By establishing the midline, the 
direction of divergence and the pointing directions of the free ends of the ossicles, 
one can orientate the specimen in all planes. Confirmation may be obtained from 
the position and orientation of the vertebral column where present. 

When the midline is not visible on the specimen, as is the case in some of 
the slabs collected at Senekal, the morphology of the individual bony ossicles 
must be used to determine the facing of the specimen. 

ANATOMY OF THE TYPICAL DERMAL OSSICLE 

The dermal ossicles may be considered as belonging to two regional types: 
those which lie away from the ventral midline, comprising up to 8 clear rows in 
our material, and those which abut on the midline itself, limited naturally to a 
single row contributed from either side. 

The laterally placed ossicle (Fig. 1), seen from the internal or dorsal aspect, 
has a smoothly pointed flame-shaped medial end (G). Its lateral end (C) after 
narrowing somewhat, exhibits a thin saucer-like expansion with a slight anterior 
deflection. These ends are frequently broken off in the specimens. Such an ossicle 
measures about 35 mm. from end to end. Although both ends taper, the ossicles 
measure about 5-6 mm. across at the centre where they are broadest. The most 
conspicuous feature of the ossicles, and indeed the only feature to work from if 
the ends are missing, is a conical buttress (F) running along the posterior edge 
of the ossicle. This cone (Fig. 1 F) has its apex near the posterior edge of the 
spoon or saucer-like lateral end of the ossicle where it is about 1 mm. broad, 
and it swells evenly in thickness to a breadth of 2-3 mm. just medial to the 
midpoint of the ossicle. Here the buttress flattens out over the posterior part of 
the flame-shaped medial end of the ossicle. 

This buttress converts the dorsal aspect of the ossicle into a grooved or 
gutter-like channel (E). In the gutter-like part of the ossicle, two structures are 
clearly housed. One is the next most lateral ossicle of the same row, whose 
flame-shaped medial end lies about 8 111m. away from the inner tip of the ossicle 
in which it lies (Fig. 1). The posterior edge of the overlying ossicle impinges on 
the anterior faCing of the conical buttress, while its anterior edge abuts on or 
overrides the buttresses in the next head ward row of ossicles (Fig. 1). The second 
group of structures which lie in the guttered surface of the internal aspect of the 
scale are the grooves and foramina presumably for nerves and vessels. These lie 
tucked in the angle formed where the ossicle rises up to form the buttress. Here 
they would be sheltered from and protected by the overlying ossicle (Fig. 5). 

The medial or flame-shaped end of the ossicle shows on its inner aspect a 
number of grooves suggesting muscular, ligamentous or tendinous attachments 
passing horizontally forward, interspersed with vascular grooves and foramina. 

16 



'the external aspect of the dermal armour could not be directly studied in 
plan view, but sections cut through one of the slabs at right angles to the line 
of th~ laterally placed ossicles showed the following features. The outer surface 
was s<tw-toothed in cross-section (Fig. 2), the ossicles having roughly the shape 
of anRle irons with the angle pointing to the outer surface of the animal. The 
patter:n was occasionally ratchet-like, with the short slope of the ratchet formed 
by th~ posterior buttress of the scale. 

'fhe midline ossicles differ in having broadly expanded medial ends (Fig. 3) 
by COntrast with the tapering flame-shaped medial ends of the laterally placed 
ossicles. These ends lie along the midline, each overlapping alternately with the 
one fr·om the opposite side. The expanded end of each ossicle can be divided into 
two areas: an anterior portion which points forward and dorsally, and exhibits 
the markings of vessels and ligaments, and a posterior portion, which continues 
laterally into the end of the ossicle buttress, and is flattened or hollowed out 
dorsally over the midline to receive the ventral surface of the next most caudal 
ossicle from the opposite side . 

The ossicles whose medial ends form the midline differ somewhat in shape 
according to their position. Those placed farthest forward are squarish with a 
straight anterior edge at right angles to the midline. They also give the impression 
of being tilted from the horizontal, so that their posterior edges would point 
backwards and downwards on the outside of the body along the midline. Farther 
back the midline scales are flatter and less massive, and have the shape of miniature 
mutton chops which lie without tilting on a level with the rest of the scales (Fig. 4). 

CONSTRUCTION OF THE ARMOUR 

As the ossicles in succeeding rows are of roughly equal length, their lateral 
ends lie in a straight line which is more or less parallel to the ventral midline. 
In any particular row of ossicles the next most lateral ossicle reaches the exterior 
aspect of the armour in the following manner. The anterior edge of any ossicle 
touches the buttress of the more head ward ossicle but diverges from this edge of 
contact at point A, Fig. 1, as it tapers laterally. An angle of divergence of some 
10°_15 ° is formed (Fig. 1), and through this cleft along the anterior free margin 
of th ~ ossicle t:le body of the next ossicle escapes laterally, being partly held 
behind in the cavity of the outer end of the more medial ossicle . This supporting 
cavity lies roughly in line with the 10°_15 ° point of divergence at the front edge 
of the ossicle so supported . A double imprint is therefore sometimes seen on the 
matrix here-that of the oblique divergence of the more medial scale, and the 
groove formed by the ridged outer surface of the escaping lateral scale. 

The arrangement described ensures that no external portion of the armour 
could be displaced in any direction on its own without hinging on another part 
of the armour for movement and support. 

17 



SIGf'IFICANCE OF 1HE VENTRAL ARMOUR 

The armour which clothes the entire ventral surface of Uranocentrodon 

between the limbs would probably function as a protector of the internal organs 
from even and uneven pressures on the ground, and at the same time be of some 
mechanical use when the animal was either lying at rest or walking. The special 
structure of the armour suggests that it may well have served several such functions. 

For example, the posterior buttress of the ossicle structure would counteract 
denting from the outside. It would also resist and transmit forward and backward 
pressures in the rows of ossicles. The inverted V-shaped arrangement of the 
ossicle rows, the backward and downward projections of the midline ossicles and 
the tougher posterior edge of the external aspect of the lateral ossicles are all 
features which make one think of the gripping tread of a motor tyre. Such a 
tread would principally prevent a backwardly slipping movement, and the 
slanting rows of scales would check a sideways slip in either direction. This 
arrangement would be useful for crawling up or lying on a sloping bank. Further­
more, it is perhaps worth pointing out that in walking on its widely separated 
limbs, the Uranocentrodon probably also exhibited fish-like undulations of the 
spine for which the inverted V-pattern would be useful. In a forward swerve to 
the right, the left hand ossicle rows would slide the longest distance with their 
ridges lying in line with the direction of movement. This would minimise friction. 
The right hand rows would at the same time move a comparatively short distance 
obliquely to the line of movement. The friction on the right side would actually 
be greater, but would be offset by the shortest sliding distance and the possibility 
that the simultaneous stride on the foot of this side would raise this part of the 
body somewhat off the ground. 

NATURE OF THE EPIDERMAL COVERING 

It seems rather unlikely that the bony armour just described was either 
naked or projected even partly through the epidermal surface. A tough overlying 
dermis with a thick epidermal covering would adequately transmit the surface 
distortions to the underlying bony shield-and this is the arrangement seen over 
other sculptured and ossicular dermal bones in living amphibia. 

There is an interesting possibility that the epidermis over the bony ridges 
was capped by a horny layer just as is the case in certain fresh-water fish. Van 
Hoepen was able to follow the ventral armour in some of his Uranocentrodon 

specimens round to the dorsum of the fossilised remains, where he found the 
ossicles gradually replaced by reddish brown non-bony rings which he took to be 
horny scales. This seems indeed to be the most likely interpretation. 

Having found small bright red powdery patches near the outer surface of 
the scales while cleaning the present specimen, it seemed worth considering if 
this could also represent keratin. Because of the high sulphur content of keratin 
Dr S. H. Haughton suggested the following mechanism to me-conversion of 
ferruginous mud to ferrous sulphide at the sites of decomposing keratin with 

18 



subsequent conversion of the ferrous sulphide to haematite. This would give the 
site of keratin deposits a reddish tint after all traces of keratin had disappeared. 

The perforated centres of the horny rings described by van Hoepen, which 
are still clearly seen in his mounted exhibit, would possibly have been the sites 
of glandular openings on the surface. 

Bloodvessels and nerves to the ventral body surface could reach it from the 
dorsum and sides of the body, and also to a small extent from channels which 
perforate the ossicles or escape between the outer free ends of the ossicles. 

COMPARISON WITH OTHER SOUTH AFRICAN LABYRINTHODONTS 

Of the South African stereospondylous labyrinthodonts, skin scutes have 
been described only by Kitching (1957) for Laidleria. Mr Kitching had nevertheless 
observed their presence in Ly dekkerina as well, and lent me a specimen for study. 
The ossicles in this specimen were scanty and disarranged, but the best developed 
examples were about 6 mm. long and 1 mm. broad-a length to width ratio 0 f 
1 :6 exactly as in Uranocentrodon, and there was a slight suggestion of the finer 
structural features such as the posterior buttress, the flame-shaped medial and 
the rocker-like lateral end. The ossicles of Lydekkerina were one-sixth the length 
of those in Uranocentrodon (6 mm. as compared with 35 mm.). This size difference 
was about equal to the ratios in total body length between Lydekkerina and 
Uranocentrodon, respectively (15 inches and 6-7 feet). 

Reports from elsewhere allow limited comparisons. The closest resemblances 
are towards Onchiodon (Sclerocephalus) la~vrinthica as described by Credner in 
1893. In this case the scales are of somewhat similar construction with a length of 
15 mm. for an animal 1.3 metres long. 

SUMMARY 

The structural and functional features of the dermal armour of the ventral 
body surface of Uranocentrodon are discussed, chiefly based on one specimen 
acquired by the Transvaal Museum after the first examples had been described. 

ACKNOWLEDGMENTS 

My thanks are due to Dr C. K. Brain, Dept. of Palaeontology, Transvaal 
Museum, for loan of the specimens, and to the C.S.I.R. Photobiology Group, 
whose facilities were used in making this study. 

REFERENCES 

CREDNER, H., 1893. Die Stegocephalen und Saurier aus dem Rothliegenden 
des Plauen' schen Grundes bei Dresden. Part X. Ztschr. Dtsch. Ceoi. Ces., 45, 

639- 704. 
KITCHING, ]. W., 1957. A new small stereospondylous labyrinthodont from the 

Triassic beds of South Africa. Palaeontologia AJricana, 5, 67-82. 

19 



ROMER, A. S., 1947. Review of the Labyrinthodontia. Bull. Mus . Camp. Zool., 
Harvard. 99, (1), 1-368 . 

VAN HOEPEN, E. C. ., 1915. Stegocephalia of Senekal, O.F.S. Ann. Transvaal 
Mus., 5, 124-149 . 

WATSON, D. M. S. , 1962. The evolution of the labyrinthodonts. Phil. Trans. ROJ. 
Soc. B, 245 , 219-265. 

EXPLANATION OF TEXT FIGURES 

Fig. 1. Semi-diagrammatic reconStruction of four dermal ossicles on ventral body surface of 
Uranocentrodon. Dorsal facing (i.e. internal surface). A-point of lateral d ivergence from 
buttress of next most headward scale. B-point of medial divergence of next most tail ward 
scale. C--kidney-shaped lateral end of scale. E-neuro-vascular groove. F-posterior 
buttress, enlarging medially. G- flame-shaped medial end. 8-point of escape to the out­
side from the most lateral ossicle in each row. Total length from tip of C to tip of G 
about 37 mm. 

Fig. 2. Section through five complete ossicle rows, middle row defective. Ventral surface below, 
embedded in sandstone matrix. Anterior end to left. Photograph shows angle-iron-like 
or ratchet-like construction of ossicles, with posterior buttress showing as a thickening 
making up the right-hand portion of the ossicle. Section also shows manner by which 
anterior (left) border of scale approaches posterior border of buttress by means of a sharp 
edge at the middle of the buttress. 

Fig. 3. Midline portion of midline ossicle seen from dorsal aspect. Dish-like area of bone with 
extension to posterior buttress on the left. Straight anterior edge defective. Overlying 
distal scale belonging to right-hand scale removed. 

Fig. 4. Midline view farther back than figure 3. Flame-shaped medial ends of left-hand ossicle 
rows running obliquely up from left. Emerging from beneath them the dilated midline 
ossicle row (damaged), resembling inner end of mutton chop in shape. Overlapping 
ossicles alternately from right side not shown. 

Fig. 5. Dorsal view of left-side ossicle row showing in centre the lateral end (to the left) of one 
ossicle rising up from C to point A (as in figure 1) with the posterior conical buttress 
(with small gap in it) on its lower or posterior edge. The buttrelses of other ossicles show 
the tendency to broaden towards the right (midline). 

20 



Fig. 1 

Fig.3 Fig. 5 

Fig. 2 

c 

21 

--- ... 

-' 

. . 
F " 

Fig. 4 



A COMPARISON OF THE PALATES OF PERMIAN AND TRIASSIC 
DICYNODONTS 

By A. R. I. Cruickshank 

ABSTRACT 

Whilst comparing the skulls of some Triassic dicynodonts with Permian members of the 
family, it was noted that the interpterygoid space in the former is consistently smaller than in the 
latter (Cruickshank 1965: 1967). In analysing this difference further, the palates of a series of 
Permian and Triassic dicynodonts were examined, either directly or from published diagrams. From 
graphs drawn using the various measurements taken from the palates, the geological age of the 
specimens can be deduced as can their estimated lengths, if fragmentary. 

THE DICYNODONT PALATE-GENERAL MEASUREMENTS 

It is possible to divide the dicynodont palate into four main regions, here 
d " h" ". I "". ·d" d "b· " terme mout , mterna nares , mterpterygOl space an ram-case 

(fig. 1). The lengths of these regions, measured on the mid-line of the palate 
were plotted on two series of graphs (figs. 2-6). The table of measurements can 
be seen in Cruickshank (1962) . 

From figure 2 it can be seen that when the lengths of the internal nares and 
the interpterygoid spaces are compared, then in general, the interpterygoid space 
of the Permian forms is greater than 60% of the length of its internal nares, 
whereas the value for the Triassic forms is always less than 60%. It is considered 
that this is significant because dicynodonts are the dominant fossil group in the 
terrestrial deposits of "Gondwanaland" and they thus might be used as strati­
graphic markers where the more commonly used macrofossils are missing. 

Other measurements were also plotted to see if there were other similar 
relationships between the parts of the palate and these are described below. 

The length of the "mouth" when plotted against the total length of the 
specimen shows in general a linear relationship between the two parameters 
and no distinction between Permian and Triassic forms is seen. The "mouth" 
being about 30% of the total length of the specimen, except in the case of those 
over 400 mm, where the value drops below this (fig. 3a). Where the length of 
the "mouth" is expressed as a percentage of the total median basal length of the 
skull, no distinction can be drawn between Permian and Triassic forms once 
more (fig. 3b). In general this conclusion holds good for all the graphs where 
the parts of the palate are expressed as percentages of the whole skull length. 
However with increased knowledge of the dicynodonts and using proper statistical 
techniques, perhaps some points of interest may emerge from these graphs 
(figs. 3b, 4b, 5b, 6b). 

23 



When the length of the "internal nares" is plotted against total median 
basal length of the skull, a tendency can be seen for the Permian and Triassic 
forms to separate out (fig. 4a) . The lengths of the "internal nares" of the Triassic 
dicynodonts ranges between 20-23% of the whole, whereas those of the Permian 
dicynodonts range between 13-150/0 of the whole. However, no conclusions 
can be drawn from this graph for skulls of less than 150 mm overall length. 

A measure which might be of value is to compare the length of the interptery­
goid space with the whole skull (fig. Sa). The interpterygoid space of Permian 
dicynodonts in the 0-150 nml range is always more than 12% of the whole skull 
length. Even above 300 mm overall length the interpterygoid space is never less 
than 8% of the whole. On the other hand the majority of Triassic dicynodonts 
seem to have an interpterygoid space less than 80/0 of the whole length of the 
skull, and only one has a value greater than 12%. 

The length of the "braincase" (fig. 6a) seems to bear a linear relationship 
to the rest of the skull in much the same way as the mouth does, except that 
there seems to be less deviation from the straight line. This measure may be of 
use in estimating the overall length of fragmentary specimens. 

DISCUSSION 

This type of analysis is best done with many more specimens than were 
available in this instance. Thus no attempt has been made to apply other than the 
most empirical of interpretations to the graphs. 

In addition, no account has been taken here of the Upper Permian genus 
Cistecephallls. This genus has no interpterygoid space, the area being filled with a 
part of the parasphenoid rostrum (Keyser, in press). Thus no place could be 
found for it in this or similar analyses. However Cistecephalus is already a most 
important zone-fossil of the South African Karroo beds, even if it is aberrant in 
the palatal region. 

Cruickshank (J 967, p. 201) has already discussed the evolutionary mechanisms 
which may have caused the noticeable difference between the length of the 
interpterygoid spaces in Permian and Triassic dicynodonts. As far as this paper 
is concerned it should be noted (fig. 2) that there seems to be a correlation 
between the horizons of the specimens measured and their position on that 
graph. For instance a group of three larger dicynodonts (Daptocephalus leoniceps 
(Owen» straddles the 60% line and towards the lower end of the size range a 
number of Lystrosaurus specimens are close to, but still on the "Triassic" side 
of the line. Daptocephalus (Ewer 1961) is a form characteristic of the uppermost 
Permian in South Africa and Lystrosaurus is the zone-fossil of the succeeding beds, 
which are of Lower Triassic age. The other forms marked on the graph range 
through the Lower to Middle Triassic, and end on the far right with Stahleckeria 
(von Huene 1942) an upper Middle Triassic form. 

Thus it seems possible to separate Permian and Triassic dicynodonts on the 

24 



one palatal character with confidence, but whether these can be assigned to a 
distinct horizon within the era on these grounds is uncertain at present. 

I would like to express my thanks to Dr F. R. Parrington, F.R.S., of the 
University Museum of Zoology, Cambridge for his help and encouragement 
while I was his research student. Dr K. A. Joysey helped considerably with the 
interpretation of the graphs. Financial assistance was given by the University of 
Edinburgh and the D.S.I.R. 

REFERENCES 

CRUICKSHANK, A. R. I., 1962. East African Triassic dicynodonts. Ph.D. Thesis. 
Univ. Camb. 

CRUICKSHANK, A. R. I., 1965. On a specimen of the anomodont reptile 
Kannemeyeria 1atifrons (Broom) from the Manda Formation of Tanzania, 
Tanganyika. hoc. Linn. Soc. Lond. 176, 149-157. 

CRUICKSHANK, A. R. I., 1967. A new dicynodont genus from the Manda 
Formation of Tanzania (Tanganyika). J. Zool. Lond. 153, 163-208. 

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

HUENE, F. VON, 1942. Die Jossi1en Repti1ien des siidamerikanischen Gondwanalandes 
an der Zeitenwende. Munich: C. H. Beck. 

KEYSER, A. W. (in press). On the morphology of the anomodont genus Cistece­
pha1us Owen 1876. 

25 



EXPLANATION OF TEXT FIGURES 

Fig. 1. A. Diagrammatic representation of dicynodont palate to show the regions discussed in this 
paper. 

Fig. 2. 

Fig. 3. 

Fig. 4. 

B. Generalised diagram to show the region around the interpterygoid space in Triassic 
dicynodonts. 

C. The same for Permian dicynodonts. 
ECT -Ectopterygoid; PAL-Palatine; PM X-Premaxilla ; PSP-Parasphenoid; PT­

Pterygoid; V-Vomer. 
ipt.sp.-interpterygoid space; ipt. vac.-interpterygoid vacuity; lab.fos.-labial fossa. 
a-"mouth"; b-"internal nares"; c-" interpterygoid space"; d-"braincase". 

A. 

B. 

A. 

B. 

Graph to show the relationship between the internal nares (b) and the interpterygoid 
space (c). All measurements in mm. 

Graph to show the relationship between the mouth (a) and the total (median basal) 
length. All measurements in mm. 
Graph to show the relationship between the mouth expressed as a percentage of the 
total (median basal) length, and the total (median basal) length. 

Graph ,to show the relationship between the internal nares (b) and the total (median 
basal) length. All measurements in mm. 
Graph to show the relationship between the internal nares expressed as a percentage of 
the total (median basal) length, and the total (median basal) length. 

Fig. 5. A. Graph to show the relationship between the interpterygoid space (c) and the total 
(median basal) length. All measurements in mm. 

B. Graph to show the relationship between the interpterygoid space expressed as a 
percentage of the total (median basal) length, and the total (median basal) length. 

Fig. 6. A. Graph to show the relationship between the braincase (d) and the total (median basal) 
length. All measurements in mm. 

B. Graph to show the relationship between the braincase expressed as a percentage of the 
total (median basal) length, and the total (median basal) length. 

26 



EXPLANATION OF TEXT FIGURES 

Fig. 1. A. Diagrammatic representation of dicynodont palate to show the regions discussed in this 
paper. 

Fig. 2. 

Fig. 3. 

Fig. 4. 

B. Generalised diagram to show the region around the interpterygoid space in Triassic 
dicynodonts. 

C. The same for Permian dicynodonts. 
ECT -Ectopterygoid; PAL-Palatine; PMX-Premaxilla; PSP-Parasphenoid; PT­

Pterygoid ; V-Vomer. 
ipt.sp.-interpterygoid space; ipt. vac.-interpterygoid vacuity; labJos.-labial fossa. 
a-"mouth"; b-"internal nares" ; c-"interpterygoid space"; d-"braincase". 

A. 

B. 

A. 

B. 

Graph to show the relationship between the internal nares (b) and the interpterygoid 
space (c). All measurements in mm. 

Graph to show the relationship between the mouth (a) and the total (median basal) 
length. All measurements in mm. 
Graph to show the relationship between the mouth expressed as a percentage of the 
total (median basal) length, and the total (median basal) length. 

Graph .to show the relationship between the internal nares (b) and the total (median 
basal) length. All measurements in mm. 
Graph to show the relationship between the internal nares expressed as a percentage of 
the total (median basal) length, and the total (median basal) length. 

Fig. 5. A. Graph to show the relationship between the interpterygoid space (c) and the total 
(median basal) length. All measurements in mm. 

B. Graph to show the relationship between the interpterygoid space expressed as a 
percentage of the total (median basal) length, and the total (median basal) length. 

Fig. 6. A. Graph to show the relationship between the braincase (d) and the total (median basal) 
length. All measurements in mm. 

E. Graph to show the relationship between the braincase expressed as a percentage of the 
total (median basal) length, and the total (median basal) length. 

26 



B 

50 + Permian 

o Triassic 

4 + 

3 
+ 

~ t t 
+ 

+ ~ 0 
0 + 

++ 0 

+ 
10 + it 

+ 0 

40 

A 

60Y' 
t + + 

+ + 

0 
0 

0 

o 0 

60 80 
.b. 

27 

0 
0 

0 

c 

& p 

v AL 
- CT 

PT 

/ ipt.vac. 

7~AL 
'-(j I tr-PT 

ipt.sP· 

Fig. 1 

0 

Fig. 2 



• 

+ 
0 

0 

30% 

210 

0 

° 180 
• Permian ++ + 

° Triassic 0 

a + 

° + 

• 0 

• 

. /. Fig.3a 

ti· 
.+ 

/~ 

I 

6 • • 

° + 
+ ° ... • 0 

• ° + ... • + + 
+ .0 

+ 
++.,j 

• 0 

+ + ;. . 
.... + 

+ 

Fig.3b 

o 

28 



210 

180 

150 

120 

b 
90 

60 

30 

40 
bxlOO 
total 

30 

2 

o 

+ Permian 
o Triassic 

+ 0 

Q;) 

T + 

+ 

o 

+ + 
.... + 
~ 

+++ 

0: 00:) 

0 

o 
+ 

o .... 

0 

0 

o 

29 

0 

0 

o 

o 0 
o 

++ 
+ + + 

23% 

2070 

Fig.4a 

700800 

o 

Fig.4b 



50 
+ Permian 

40 o Triassic 

30 
~ t 

20 
t . t t 

"* ++ 

0 
+:; 

10 p' t 0 

0 

40 

30 
c x/OO 
total 

2 

o 

+ 

+ 
+ I + 

++ 
o + 

+ + 
+ 

o 

o 

+ 
00 

0 

12~ 

+ 
+ o 

0 

0 

o + + 
o 

o 

30 

• ~'k 
+ t 

0 

0 

Fig. Sa 

o Fig. Sb 

o o 



300 

270 

240 

210 
• t 

180 

d 150 + Permian + 

o Triassic 

120 + ·0 

+ 

90 . 
0 

0 

60 t 

0 .. Fig.6a 

30 + \" 0+ 

800 

$0 
+ 

+ t 

40 0 
0 

d xlOO +tt..t. 
GO 

+ 00 .. 0 

* + 
0 + total 0 

30 + a-
t + 0 

0 

+ + 0 

2 
0 

0 

Fig.6b 

o 
totalle!2gth 

31 



ON THE CLASSIFICATION OF THE GORGONOPSIA 

by D. Sigogneau 1 

The work here summarized represents an attempt to review the South 
African Gorgonopsians, an attempt based on a re-examination of the cranial 
anatomy of the type material and a comparison of all the specimens available 2. 

The possible origin of the group from the Russian eotheriodonts is discussed in 
conclusion. 

When one realizes what a tremendous amount of material Broom had to 
deal with, one cannot help but be impressed by the synthesis at which he was 
able to arrive and which remains to-day largely valid. He masterfully recognized 
the major taxonomic boundaries and their significance, perceiving within each 
group the affinities uniting the different constituents. 

However, his inner feeling that it was his duty to make known each and 
every specimen examined by him led him to neglect somewhat their preparation 
and to establish types insufficiently described or justified. Quite apart from that, 
the number of specimens accumulated for over a hundred years naturally de­
manded a re-organization of the different infra-orders; I was offered by Dr. A. S. 
Brink, fonner Assistant Director of the Bernard Price Institute for Palaeontological 
Research of Johannesburg, the opportunity to disentangle the Gorgonopsians. 
After four years of reflection I emerged in 1967 with a provisional classification, 
the sole pretention of which being to present some new morphological data. 
The material consists of about 150 specimens, formerly distributed in 67 genera 
and 108 species. Except for the North American material, every specimen has 
been re-examined, often further prepared, and drawn and photographed. 

This activity was made possible firstly by the Bernard Price Institute for 
Palaeontological Research, which offered me the counsel of Dr. A. S. Brink and 
the multifarious aid of Mr. J. W. Kitching, by the collaboration of many other 
institutions both in South Africa and in Europe, as well as by the co-operation 
of Dr. S. H. Rubidge and his family. It was also made possible by the aid of the 
Centre National de la Recherche Scientifique, and the direction of Professors]. 
Piveteau and J.-P. Lehman. 

My first idea was to sort out a few principal structural types and to re­
arrange the m.ain bulk around them. But I soon discovered what an astonishing 
homogeneity reigned within the infra-order; this, combined with the fact that 
many of the nomenclatorial types-being among the first mammal-like reptiles 
discovered-were in a rather poor state of preservation, hindered the achievement 
of this idea. 

However, out of the mass of nearly identical forms I soon noticed, as had 
Broom and others, that a few specimens emerged rather sharply. For these I 

33 



maintained the family Ictidorhinidae created by Broom, even though I have 
lately come to doubt the familial status of the group; this will be discussed later. 

In this view, the rest of the Gorgonopsians had to be united in a single 
family, the Gorgonopsidae, and any subdivision within them had to be infra­
familial since the anatomic divergences that could be picked out among them 
were always less in degree than those between them and the Ictidorhinidae. I 
have therefore been led to distinguish two subfamilies, the Gorgonopsinae and 
the Rubidgeinae. 

Haughton and Brink were the first authors to give generic diagnoses which 
took into account, in the Gorgonopsidae, the shape of the skull, the particularities 
of the frontal and the preparietal, the morphology of the palate and the number 
of post-canines. In a previous article I have already stated the necessity for more 
criteria, but a few complementary remarks are needed here. It is obvious that, as 
far as shape is concerned, post-mortem deformation has to be considered, but it 
is possible that the present shape is more indicative than previously thought; 
indeed, one may presume that a skull will not generally be deformed in just any 
manner, but that a narrow skull will be compressed laterally while a wider one 
will see its width accentuated. Still on the subject of shape, we do not know for 
sure what modifications are to be expected between juveniles and adults; no 
more do we know the amplitude of individual variation in this and other 
characters. 

I eventually accorded a generic value to the following ensemble of characters; 
the general shape of the skull, the size and shape of the temporal fossae, the ratios 
of the inter-orbital and inter-temporal widths, the shape of the post-orbital, 
sub-orbital and zygomatic arches, the relation of the frontal to the supra-orbital 
rim, the presence of the preparietal, the dimensions of the post-frontal and 
lacrymal, details of the occiput, the degree of ossification of the braincase wall, 
and the relative position of the pterygoid transverse apophyses. In spite of the 
number of criteria utilized, it was often difficult to decide to which genus a 
specimen should be referred, and some of them even did not fit at all into tfUs 
scheme. One of the reasons for this difficulty is, of course, the fact that as yet 
very rarely are post-cranial elements known, and this accentuates the artificial 
character of this classification. 

Nevertheless, I arrived, for the family Gorgonopsidae, at a total of 22 genera; 
these shall be quickly reviewed. 

Three of them-Broomisaurus Joleaud, Galesuchus Haughton and Eoarctops 
Haughton, all monotypic and represented by a single specimen-are among the 
oldest South African gorgonopsids known, since they come from the bottom of 
the Tapinocephalus zone of the Beaufort series 3 . Unfortunately, they all are in a 
rather bad state of preservation (one of them is even reduced to a weathered 
snout), but they show rather clearly that the gorgonopsid structural type was 
already fully established at this time. Moreover, they do not appear as the most 
primitive members of the family, if one takes as a point of reference their 
sphenacodont ancestors. From the same zone, Dr. L. D. Boonstra has collected, 

34 



and generously lent to me, other specimens which possess with the above genera 
a number of common characters, thus making the" TapinocephaJus assemblage" 
a rather homogeneous one. It was therefore tempting to group these specimens 
in a subfamily, the Galesuchinae. But, for one thing, its definition would not 
have been really in opposition to that of the two other subfamilies; furthermore 
there remains the question of what to do with the genera which begin in this 
zone as "Galesuchinae" (AeJurosaurus Jelinus 4, for example) and continue into 
the following zone as Gorgonopsinae (AeJurosaurus wilmanae (Broom), for example). 
From these considerations came my decision to maintain this assemblage within 
the Gorgonopsinae. 

Indeed, the genus Aelurosaurus Owen, in the form of its type-species, 
A. Jelinus, would fit perfectly well in the "Tapinocephalus assemblage". There 
is even a good similarity between this species (known only by snouts) and the 
only species of Galesuchus, both in proportions and in details of the bones, and it is 
not impossible that the two species belong to the same genus; but there remain 
uncertainties in the palate of G. 8racilis and in the posterior part of the skull of 
AeJurosaurus Jelinus; moreover I have now extended the genus Aelurosaurus to a 
number of later species. Thus conceived, it appears as a rather primitive form of 
small size, as the first representatives of the infra-order might be expected to be; 
the skull is lightly built, the skull roof relatively narrow, but the snout is already 
short. The preparietal, anteriorly situated in the type-species, underwent some 
backward displacement in the two latest species; the facial part of the lacrymal is 
short and the cheek dentition has begun a reduction, but the transverse apophyses 
are still found rather posteriorly. Besides the species individualized by Broom, 
and which I have for the most part maintained, the genus comprises now two 
other species: Aelurosaurus (" Aelurosauropsis' ') wi1manae (Broom) and A. (" GaJe­

rhinus") polyodon (Broom), as well as an uncertain third, A.? (" Scylacocephalus") 

watermeyeri (Broom), whose affinities tend also toward Cyonosaurus. 

Morphologically very close to the preceding comes the genus Arcto8nathus 

Broom. The differences noted between the two genera are often due to a simple 
progression: the small forms of the beginning would have increased in size, their 
snout shortened even more; the frontals would have reduced their participation 
in the supra-orbital rim, and the preparietal would have become smaller; at the 
same time the transverse apophyses would have become edentulous. However, 
one would not have expected, of forms so late, a braincase so little ossified, no 
more than one would expect, in the course of evolution, the accentuation of the 
sinuosity in the maxillary alveolar border and the retreat of the pterygoid trans­
verse apophyses. The existence of a specimen attributed to Arcto8nathus in the 
Tapinocephalus zone would seem to confirm my hypothesis that a separation of the 
two genera has taken place early. "Lycaenodontoides bathyrhinus" Haughton is 
definitely a synonym of the type-species, Arcto8nathus curvimoJa. It is less sure 
that" Arcto8nathoides" breviceps (Boonstra) finds its place here. As for the inclusion 
in the genus Arcto8nathus of "Dixeya" nasuta (von Huene), this remains somewhat 

35 



p 

open to discussion, all the more since the details of the cranial roof of this species 
are not known. 

It is not impossible that the small" Galerhinus" rubidgei of Broom should be, 
like the type-species" Galerhinus" polyodon, incorporated in the genus Aelurosaurus. 
But in order to decide it would be necessary to know the modalities of differential 
growth, for it is perhaps a juvenile form. This uncertainty obliged me-since I 
had suppressed the type-species-to create for this small skull a new generic 
name, according to a rule of nomenclature which does not always appear defensible. 

The affinity which unites Aelurosaurus to S9'laco8nathus Broom (another 
genus beginning in the Tapinocephalus zone) is not less probable, but it occurs on 
another plane than for Arcto8nathus: it is a question here of two contemporaneous 
forms not long detached from a common stock. One finds again the short snout 
and the preparietal anteriorly situated, but a beginning of specialization would 
appear in the frontal tending to become isolated from the supra-orbital rim, in 
the inter-orbital roof enlarging, and the post-canines reducing even more in 
number. Beside synonymizing the two species of Broom , Sc. parvusand Sc. "major", 
I introduced into the genus the stocky "Cynariops" robustus (Broom) and the 
three species "Cynarioides" gracilis (Broom), grimbeeki (Broom) and laticeps 
(Broom). 

It seems that S9'lacops Broom is to S9'laco8nathus what Arcto8nathus was to 
Aelurosaurus. In the course of evolution there would have been an increase in 
size, an attenuation of the ventral sinuosity of the skull, complete elimination of 
the frontal from the supra-orbital rim, and forward displacement of the transverse 
apophyses. These modifications make of S9'lacops a somewhat evolved genus, even 
though its prootic remains apparently little ossified. The incorporation of 
"Sycocephalus" bi8endens (Brink and Kitching) into S9'lacops has the merit of 
w1derlining the resemblance that exists between this genus and Gor8onops, a 
resemblance which does not however, in my opinion, correspond to a close 
relationship . 

Gor8onops tOTVUS, the first Gorgonopsian species to be described, by Owen in 
1876, was based on a rather poorly preserved skull. At present the species is 
represented by four specimens (a fifth one has been serially sectioned), of which 
only one comes from the Cistecephalus zone. Like S9'lacops, it is a middle-sized 
form (the type was thought to be juvenile, but further studies and comparisons 
do not confirm this hypothesis) and, contrary to what was supposed until now, 
does not appear very primitive. It is true that the snout is still long, the preparietal 
and the lacryn1al well developed, the frontal largely open on to the orbit, the 
palate provided with an abundance of teeth, and the transverse apophyses remain 
posterior. But the shape of the skull, the inter-orbital width, the number of 
post-canines and above all the degree of ossification of the prootic (of which the 
dorsal and ventral processes close in front of the fifth nerve) testify already to a 
certain degree of evolution. Furthermore, the most recent specimen of the species 
is distinguished by a reinforcement of the divers arches, an inter-temporal 
enlargement, and a reduction of the preparietal and the supra-orbital frontal, 

36 



all of which are advances tending to fill in the space between Gorgonops torvus and 
G. whaitsi. 

The latter constituted previously the type of the genus "Scymnognathus" 

Broom. This form was represented by five specimens, unhappily very fragmentary 
and poorly preserved, of which three are at present in the collections of the 
American Museum of Natural History, New York, and were, in consequence, 
not examined. When Broom created the species, he said that he hesitated to 
distinguish it generically from Gorgonops torvus, and he did not in fact justify his 
ultimate distinction. However, according to Boonstra, it is a form clearly more 
evolved than G. torVllS. A detailed analysis led me back to the first opinion of 
Broom. For example, going back to the arguments given by Boonstra, one sees 
that the snout is in fact equally rounded in both cases, the temporal fossae are 
scarcely more developed in G. whaitsi, while the orbits are relatively a little 
smaller; the tooth row was probably convex in both species, and the ossification 
of the prootic has progressed equally in the two forms; lastly, the supra-orbital 
frontal appears a little narrower in G. whaitsi, but, as noted above, it is tending 
toward reduction in the last specimen of G. torvus. It is true that there are real 
differences, such as a great disparity in size and perhaps in the position of the 
transverse apophyses, but these differences do not, in my view, exceed a generic 
level. As a matter of fact, the two species appear to be very close to each other, 
with G. torvus remaining slightly retarded. I have considered it possible to include 
as well in this genus the large "GoTgonognathus" longijrons (Haughton), whose 
differences with respect to G. whaitsi are only of degree and which, according to 
its author himself, would only be an advanced form of the latter. I have also 
adopted Boonstra's opinion according to which" Leptotrachelus" Watson would be 
close to "Scymnognathus". The inclusion of "Chiwetasaurus" dixo/i Haughton in 
this genus is perhaps more disputable. On the other hand, "Pachyrhinos" kaiseri 

(Broili and Schroeder), from the top of the Tapinocephallls zone, seems rather 
clearly related to G. IVhaitsi, even though its type and only specimen is too 
incomplete for certainty, and though a resemblance between it and Aloposaurus? 

("Aloposauroides") tenllis (Brink and Kitching) has been noted: they both show 
the same particularities of the snout, of the orbits and of the post-orbital arches. 
But the amplitude of the posterior widening and the position of the transverse 
apophyses are not known in G. kaiseri where, moreover, the post-canines are 
much larger. 

The genus Aloposaurus Broom itself remains rather poorly defined, the type­
specimen, which I have not seen, being apparently very badly preserved. Its 
affinities appear to be divided between Gorgonops and Scylacops. 

It is not impossible that there exists also a relationship between the same 
genus Gorgonops and Leontocephalus Broom, at least as regards the type-species, 
L. cadlei Broom. But for the time being the affinities of this snout, and the reference 
of the two other species to this genus, L. ? (Aelurognathus) haughtoni (von 
Huene), remain doubtful. 

37 

o 



Situated more or less at the heart of the Gorgonopsians is the genus C),ono­
saurus Olson 5 • This essentially replaces the genus C)'niscops, established three 
months later by Broom on a different number of incisors; this number having 
since been shown to be identical 6 in the two cases there is no longer any reason 
to separate C)'onosaurus lonBiceps and C)'niscops lonBiceps. We are dealing here with 
one of the best represented species of all the Gorgonopsians, as well as one of the 
most primitive. This middle-sized animal has retained, cranially, a long snout; 
the temporal fossae are also elongated, but not extended posteriorly by ample 
squamosal wings; the gracility of the arches, like the proportions of the cranial 
roof, are certainly original, confirmation of which can be seen in the large size of 
the frontal, preparietal and lacrymal; the same thing applies to the posterior 
position of the toothed transverse apophyses and the feeble degree of ossification 
in the prootic; lastly, it is the species which, after "Galerhinus" rubidBei, has 
retained the greatest number of small post-canines. Only the downward extension 
of the lateral postorbital appears evolved in this species, along with the elongated 
temporal fossae. Two of the other species formerly included in this genus, 
C),onosaurus rubidBei (Broom) and C. kitchinBi (Broom) (with which" Alopecorh),nchus 
rubidBei" Brink and Kitching has been synonymized), are somewhat more 
specialised. Of the two others, "C)'niscops" cookei (Broom) and "C)'niscops" 
broomianus (von Huene), the first is now referred to ArctoBnathus, the second 
synonymized with" Sc;ylacocephalus" watermeyeri and therefore included with it in 
AelurosauTUs. As has been noted above, the distinction between this genus and 
C)'onosauTUs remains, with respect to the latter species, a little vague. 

L)'caenops ornatus Broom is almost as primitive as C),onosaurus; in fact, the 
general shape of the skull appears more sphenacodont-like than that of C)'onosauTUs 
lonBiceps, but the palate is undoubtedly more evolved and the cheek dentition 
already somewhat reduced. The two other species, L)'caenops (" L),caenoides") 
anBusticeps (Broom) and L. (" Tigricephalus") kinBwi lli (Broom), form with the 
type-species something of a morphological succession by a progressive increase 
in size, in general massiveness, and a reduction of the preparietal. On the contrary, 
the three other species remain as primitive as the type. But all three are questioned, 
L.? (" TanBaBorBon") tenuirostris (Boonstra) because of its affinities with C),ono­
saUTUS, L.? (AeluTOBnathus) minor (Brink and Kitching) and L.? (AeluroBnathus) 
microdon (Boonstra) because of their affinities with AeluroBnathus (Broom and 
Haughton). 

This last genus retains, like Lycaenops, a convex dorsal profile and temporal 
fossae lacking a posterior extension; the prootic is scarcely more evolved and the 
details of the bones differ little in the two cases. Only a greater massiveness, both 
general and local, can be noted in AeluroBnathus, but the basic affinity is indisput­
able. Besides the synonymization of A. nyassaensis Haughton with A. tiBriceps 
Broom and Haughton and the suggested exclusion of A. microdon and A. minor, the 
principal innovation concerning this genus resides in the incorporation of 
"Dixeya" quadrata (Haughton). This species is now well represented and responds 
in a satisfactory manner to the definition of the genus AeluroBnathus. 

38 



One finds in Arctops Watson the general massiveness of Aelurognathus, 

together with the primitive characters of L),caenops. In addition, the cranial roof 
proportions of Arctops seem to me directly inherited from the sphenacodonts, 
the prootic remains very short anteriorly, and the palate itself has evolved but 
little: one of the most primitive genera of the Gorgonopsidae is the result. I 
have thought it possible to include in the type-species, based on the posterior 
part of the skull, A. "watsoni" Brink and Kitching, as well as another skull, 
undescribed. "Gorgonorhinus" minor (Broom) follows most of the definition of 
Arctops. This genus contains the only new species here proposed of the Gorgon­
opsidae; the specimen upon which it is based was previously classed in Ae1urog­

nathus minor, but it seems more comfortably situated in the genus Arctops, mostly 
because of the morphology of the ventral surface of the skull. The above discussion 
stresses the affinity which unites Arctops and Aelurognathus. 

The species Arctops? (" Smilesaurus' ') jerox (Broom) (=' 'Pardocephalus" 

Broom) offers another testimony to this affinity; indeed it allies not only Arctops 

to Aelurognathus but both of them to L)'caenops, morphologically extending just 
beyond L. kingwilli in the sequence already mentioned (L. ornatus, L. angusticeps, 

L. kingwilli). At the same time Arctops? jerox considerably evokes A. willistoni, by 
its form, its massiveness (increased here), its posterior width, the proportions of 
the cranial roof, and the large size of the post-canines (fewer in number); the 
palate, on the contrary, is like that of Ae1urognathus. The choice of Arctops for 
this species derives from the fact that the only difference between this genus and 
"Smilesaurus" is one of an order of evolution (advancement of the pterygoid 
transverse apophyses), whereas in order to go from Aelurognathus or L)'caenops to 
"Smilesaurus", one must imagine a "regression" (inter-orbital shrinking for the 
first, inter-temporal widening for both). But it would perhaps have been pre­
ferable to simply retain the genus "Smilesaurus", all the more since the Russian 
Inostrancevia Amalitzki seems to have affinities with this form. 

Within this ensemble, restricted to a narrow evolutionary framework, 
was however born another survival attempt in the form of the Rubidgeinae. This 
attempt consisted essentially in an increase of the power of aggressivity, manifested 
by larger size, the reinforcement of the snout and the development of the anterior 
dentition at the expense of the post-canines. The widening of the cranial roof and 
of the diverse arches must have corresponded to more extensive muscle insertions, 
as did, presumably, the hollowing of the occiput. Perhaps the tendency toward 
closure of the cerebral wall by the coming together of the prootic and the 
orbitosphenoid could be interpreted in the same sense (it should be noted that the 
epipterygoid not only remains always exterior to the wall, but that it never 
manifests any tendency to widen). At the same time and as in all the large forms, 
one is confronted with a reduction of the preparietal and a retreat of the frontal 
from the supra-orbital rim. 

This attempt appears timidly in S)'cosaurus Haughton, is expressed more or 
less clearly in Prorubidgea Broom and Clelandina Broom, and attains its full 

39 



development in Dinogorgon Broom and Rubidgea Broom j the succession thus 
evoked remains for the most part purely morphological. 

Sycosaurus somewhat brings to mind Scylaeops, with its snout scarcely as high 
as wide and narrowed anteriorly, and with the posterior broadening of the skull. 
But the large size of the post-canines and the posterior situation of the transverse 
apophyses also remind one of Aretops. Be that as it may, the specialization of the 
cranial roof has already advanced and one can note an incipient zygomatic widening 
in Sycosaurus latieeps and S. ("Leontosaurus") vanderhorsti (Broom), but less clearly 
in S.? (Ly eaenops) kingoriensis (von Huene). As for the species "Sycosaurus" 
brodiei Broom, it seems to me to participate more directly in the following genus. 

Prorubidgea Broom appears derived more or less directly from a form close 
to Aelurognathus: one finds again the elevated shape of the skull with its rounded 
snout, the small orbits and the transverse apophyses anteriorly situated (with one 
exception). The zygomatic arches and the cranial roof, while more evolved than 
in Aelurognathus, are less so than in Syeosaurus, which might explain the exclusion 
of Prorubid8ea from the Rubidgeidae by Haughton and Brink (but not Watson 
and Romer). The various species of this genus have diversely developed the 
generic plan, but their affinities with each other seem to me difficult to question. 

From a strictly morphological point of view, Dinogorgon Broom prolongs 
in a very satisfactory fashion Prorubidgea. Not only is the shape the same and the 
orbits of similar proportions, but the only differences that one can find constitute 
evolutionary advances with respect to Prorubidgea: the cranial roof is barely 
enlarged and there are still five post-canines, but neither a preparietal nor a 
supra-orbital frontal exist any longer j the ventral zygomatic apophyses are 
strongly developed, and the pterygoid transverse apophyses are placed even more 
anteriorly. Lastly, an elongate swelling is formed, increasing the thickness of the 
supra-orbital rim, which extends onto the post-orbital arch in the form of an 
oblique ridge. 

It seems to me that there is an identity between the three species previously 
attributed to this genus. I would go even further and consider this single species as 
referable to the genus Rubid8ea Broom. But DinogoTgon was created first and on a 
snout in rather poor condition j the synonymy of the two genera would lead me 
to base all this assemblage on an incomplete specimen, a deed that would always 
be open to suspicion. Consequently, Rubidgea is maintained. 

This genus Rubidgea prolongs in turn (especially in the form of R. atrox) the 
Dinogorgon "stage" j the maximum of force developed in the Gorgonopsians is 
attained here. The development of the cranial roof is such that the small orbits are 
practically invisible dorsally, and the zygomatic projection is so developed that it 
<constitutes the most ventral point of the skull j the post-canines are reduced to 
one or two and the palatine teeth tend to disappear. The divergences that are 
visible between the three principal specimens do not seem easily attributable to 
individual variation. As for the skull of "TigTisaurus" prieei Broom, this appears 
to me too incomplete to permit its attribution to any of the three recognized 
species. 



It remains to discuss, in this subfamily, two forms which are rather exceptional 
by the width of their skull: this width is only extreme in the small Clelandina 
rubidgei Broom and C. (" Dracocephalus") scheepersi (Brink and Kitching) j it 
becomes extraordinary in Broomicephalus laticeps Brink and Kitching (= Rubidgea 
laticeps Broom) since here it exceeds the skull length. The last-named species 
has attained a level of specialization identical to that of the other Rubidgea and 
was previously classified in the same genus. However, I have tried to maintain a 
consistency with the rest of this classification by following Brink's suggestion 
and by placing it in a parallel genus. 

It does appear that this specialization of the Rubidgeinae was fatal j there, 
where suppleness and invention were needed in order to adapt to ecologic change, 
they reacted with a dep