UNIVERSITY OF
ILLINOIS LIBRARY
AT URBANA-CHAMPAIGN
GEOLOGY

NOTICE: Return or renew an Library Material*! The Minimum Fee for
each Lost Book is $50.00.

The person charging this material is responsible for
its return to the library from which it was withdrawn
on or before the Latest Date stamped below.

Theft, mutilation, and underlining of books are reasons for discipli-
nary action and may result in dismissal from the University.

To renew call Telephone Center, 333-8400

UNIVERSITY OF ILLINOIS LIBRARY AT URBANA-CHAMPAIGN

APR 2 8 |9<3

w

#

UIAN 1^8

£

?no7

LI61— O-1096

GEOLOG ;ARY

FIELDIANA

Geology

NEW SERIES, NO. 17

The Mammalian Fauna
of Madura Cave, Western Australia
Part VII: Macropodidae: Sthenurinae,
Macropodinae, with a Review of the
Marsupial Portion of the Fauna

Ernest L. Lundelius, Jr.
William D. Turnbull

March 31, 1989
Publication 1399

PUBLISHED BY FIELD MUSEUM OF NATURAL HISTORY

Information for Contributors to Fieldiana

General: Fieldiana is primarily a journal for Field Museum staff members and research associates, although
manuscripts from nonaffiliated authors may be considered as space permits. The Journal carries a page charge of
$65 per printed page or fraction thereof. Contributions from staff, research associates, and invited authors will be
considered for publication regardless of ability to pay page charges, but the full charge is mandatory for nonaffiliated
authors of unsolicited manuscripts. Payment of at least 50% of page charges qualifies a paper for expedited processing,
which reduces the publication time.

Manuscripts should be submitted to Scientific Editor, Fieldiana, Field Museum of Natural History, Chicago, Illinois
60605-2496, USA. Three complete copies of the text (including title page and abstract) and of the illustrations should
be submitted (one original copy plus two review copies which may be machine copies). No manuscripts will be
considered for publication or submitted to reviewers before all materials are complete and in the hands of the Scientific
Editor.

Text: Manuscripts must be typewritten double-spaced on standard-weight, 8V2- by 1 1-inch paper with wide margins
on all four sides. For papers longer than 100 manuscript pages, authors are requested to submit a "Table of Contents,"
a "List of Illustrations," and a "List of Tables." In most cases, the text should be preceded by an "Abstract" and
should conclude with "Acknowledgments" (if any) and "Literature Cited." All measurements should be in the metric
system. The format and style of headings should follow those of recent issues of Fieldiana. For more detailed style
information, see The Chicago Manual of Style (13th ed.), published by The University of Chicago Press, and also
recent issues of Fieldiana.

In "Literature Cited," authors are encouraged to give journal and book titles in full. Where abbreviations are
desirable (e.g., in citation of synonymies), authors consistently should follow Botanico-Periodicum-Huntianum and
TL-2 Taxonomic Literature by F. A. Stafleu & R. S. Cowan (1976 et seq.) (botanical papers) or Serial Sources for
the Biosis Data Base (1983) published by the BioSciences Information Service.
References should be typed in the following form:
Croat, T. B. 1978. Flora of Barro Colorado Island. Stanford University Press, Stanford, Calif., 943 pp.
Grubb, P. J., J. R. Lloyd, and T. D. Pennington. 1963. A comparison of montane and lowland rain forest

in Ecuador. I. The forest structure, physiognomy, and floristics. Journal of Ecology, 51: 567-601.
Langdon, E. J. M. 1979. Yage among the Siona: Cultural patterns in visions, pp. 63-80. In Browman, D. L.,

and R. A. Schwarz, eds., Spirits, Shamans, and Stars. Mouton Publishers, The Hague, Netherlands.
Murra, J. 1946. The historic tribes of Ecuador, pp. 785-821. In Steward, J. H., ed., Handbook of South
American Indians. Vol. 2, The Andean Civilizations. Bulletin 143, Bureau of American Ethnology, Smithsonian
Institution, Washington, D.C.

Stolze, R. G. 1981. Ferns and fern allies of Guatemala. Part II. Polypodiaceae. Fieldiana: Botany, n.s., 6: 1-
522.

Illustrations: Illustrations are referred to in the text as "figures" (not as "plates"). Figures must be accompanied
by some indication of scale, normally a reference bar. Statements in figure captions alone, such as "x 0.8," are not
acceptable. Captions should be typed double-spaced and consecutively. See recent issues of Fieldiana for details of
style.

Figures as submitted should, whenever practicable, be 8V2 by 1 1 inches (22 x 28 cm) and may not exceed 1 IV2 by
I6V2 inches (30 x 42 cm). Illustrations should be mounted on boards in the arrangement you wish to obtain in the
printed work. This original set should be suitable for transmission to the printer as follows: Pen and ink drawings
may be originals (preferred) or photostats; shaded drawings should be originals, but within the size limitation; and
photostats should be high-quality, glossy, black and white prints. All illustrations should be marked on the reverse
with author's name, figure number(s), and "top." Original illustrations will be returned to the author upon publication
unless otherwise specified. Authors who wish to publish figures that require costly special paper or color reproduction
must make prior arrangements with the Scientific Editor.

Page Proofs: Fieldiana employs a two-step correction system. Each author will normally receive a copy of the
edited manuscript on which deletions, additions, and changes can be made and queries answered. Only one set of
page proofs will be sent. All desired corrections of type must be made on the single set of page proofs. Changes in
page proofs (as opposed to corrections) are very expensive. Author-generated changes in page proofs can only be
made if the author agrees in advance to pay for them.

THIS PUBLICATION IS PRINTED ON ACID-FREE PAPER.

UNIVERSITY OF

ILLINOIS LIBRARY

AT URBANA-CHAMPAIGN

GEOLOGY

FIELDIANA

Geology

NEW SERIES, NO. 17

The Mammalian Fauna
of Madura Cave, Western Australia
Part VII: Macropodidae: Sthenurinae,
Macropodinae, with a Review of the
Marsupial Portion of the Fauna

Ernest L. Lundelius, Jr.

Professor of Geological Sciences
University of Texas at Austin
Austin, Texas 78713-7909

Research Associate

Department of Geology

Field Museum of Natural History

William D. Turnbull

Curator, Fossil Mammals
Department of Geology
Field Museum of Natural History
Chicago, Illinois 60605-2496

Committee on Evolutionary Biology
University of Chicago
Chicago, Illinois 60637

Research Associate
Texas Memorial Museum
Austin, Texas 78705

Accepted March 11, 1987
Published March 31, 1989
Publication 1399

PUBLISHED BY FIELD MUSEUM OF NATURAL HISTORY

© 1989 Field Museum of Natural History
Library of Congress Catalog Card Number: 88-82134

ISSN 0096-2651
PRINTED IN THE UNITED STATES OF AMERICA

•^ «* ^ ^J
Table of Contents

'i^

'■£

Abstract 1

Introduction 1

Macropodidae
Sthenurinae

Sthenurus (Simosthenurus) sp 1

Macropodinae

Lagorchestes hirsutus 6

Lagostrophns fasciatus 19

Onychogalea lunata 23

Incertae Sedis within the Small Walla-
bies 33

Protemnodon sp 39

Petrogale sp 45

Macropus 46

Macropus fuliginosus 51

Macropus sp. (Probably M. fuligino-
sus) 51

Macropus titan 57

Macropus sp. (Probably M. titan) .... 57

Macropus robustus 62

Incertae Sedis among the Large Macro-

podids 63

Assessment of the Marsupial Segment of

the Fauna 65

Acknowledgments 69

Literature Cited 69

List of Illustrations

1. Sthenurus (Simosthenurus) sp., near S.
oreas DeVis and 5". gilli Merrilees, from
Madura Cave compared with S. atlas
from Wellington Caves, New South
Wales, S. andersoni from Weetalibah,
New South Wales, and S. brownei from
Mammoth Cave, Western Australia . . . 2-3

2. Bivariate graph with length of P4
plotted against posterior width of P4 for
samples of the various species of
Sthenurus 5

3. Drawing of the skull and right mandible
of the modern Lagorchestes hirsutus
from Bernier Island, Western Australia
8-9

4. Lagorchestes hirsutus from the surface

of Madura Cave 10

5. Lagorchestes hirsutus from the surface

of Madura Cave 11

6. Lagorchestes hirsutus from the surface

of Madura Cave 12

7. Lagorchestes hirsutus and Lagostrophus
fasciatus from Madura Cave compared
with a Recent specimen from the sur-
face of Webb's Cave, Mundrabilla Sta-
tion, Western Australia 14-15

8. Lagostrophus fasciatus from Bernier Is-
land, Western Australia 20-2 1

9. Onychogalea frenata from New South
Wales 26-27

10. Onychogalea unguifera from Derby,
Western Australia, and Onychogalea
lunata from Weeke's Cave, South Aus-
tralia 28-29

1 1 . Onychogalea lunata from Snake Pit
Cave, Western Australia, and Weeke's
Cave, South Australia 30-3 1

12. Onychogalea lunata from Madura

Cave 32

13. Onychogalea lunata from Madura

Cave 34

14. Protemnodon sp. from Madura Cave
compared with Protemnodon anak from
Wellington Caves, New South Wales ... 40

15. Protemnodon brehus and P. roechus
from Wellington Caves, New South

Wales 42-43

16. Bivariate graphs showing the Madura
Cave specimens of Protemnodon in
comparison with certain Wellington
Caves specimens and with samples of P.
brehus and P. roechus from the litera-
ture 48^9

17. Petrogale sp. from Madura Cave com-
pared with various modern species of
the genus from Wedge's Cave, Mime-
gara, Western Australia; Oenpelli, East
Alligator River, Northern Territory;
Kimberly District, Western Australia;
and Rockhampton-Atherton area,
Queensland 50

18. Graphs showing teeth of Macropus from
Madura Cave compared with those of
M. titan, M. giganteus, and M. fuligino-
sus from various localities 52-53

19. Macropus fuliginosus from Madura

Cave 54-55

20. Macropus titan from Madura Cave .... 59

2 1 . Macropus titan and M. robustus from
Madura Cave compared with M. robus-
tus antilopinus from Kimberly District,
Western Australia, and modern species,
M. fuliginosus, M. (Megaleia) rufa, and

M. robustus antilopinus 64

ui

List of Tables

1 . Numerical data on upper dentitions of
Lagorchestes hirsutus from Madura

Cave 16

2. Numerical data on upper dentitions of
Holocene samples of Lagorchestes hir-
sutus from Western Australia 17

3. Numerical data on lower dentitions of
Lagorchestes hirsutus from Madura

Cave 18

4. Numerical data on lower dentitions of
Lagorchestes hirsutus from Western
Australia 19

5. Measurements of upper dentitions of
Lagostrophus fasciatus 22

6. Measurements of lower dentitions of
Lagostrophus fasciatus 23

7. Numerical data on upper dentitions of
Onychogalea lunata from Madura

Cave 35

8. Numerical data on lower dentitions of
Onychogalea lunata from Madura

Cave 36

9. Dimensions of upper dentitions of Ony-
chogalea from various sources 37

0. Dimensions of lower dentitions of Ony-
chogalea from various sources 38

1 . Numerical data on mandibles and lower
dentitions of Protemnodon from Lake
Victoria, Wellington Caves, and Madura
Cave 44

12. Numerical data on upper teeth of Pro-

temnodon from Wellington Caves, Lake
Victoria, and Bingara, New South
Wales, and Queensland in comparison
with the broken tooth of Protemnodon
sp. from Madura Cave 46-47

13. Numerical data on upper dentitions of a
Recent sample of Macropus giganteus
from New South Wales 51

14. Numerical data on lower dentitions of a
Recent sample of Macropus giganteus
from New South Wales 51

15. Measurements of upper and lower den-
titions of Macropus fuliginosus from
Madura Cave 56

16. Numerical data on upper dentitions of a
Recent sample of Macropus fuliginosus
from New South Wales 57

17. Numerical data on lower dentitions of a
Recent sample of Macropus fuliginosus
from New South Wales 57

18. Measurements of metatarsals and termi-
nal phalanges of digits IV and V of the

pes of Recent and fossil Macropus 58

19. Measurements of upper dentitions of
Macropus titan from Madura Cave . 60-6 1

20. Measurements of lower dentitions of
Macropus titan from Madura Cave .... 62

2 1 . The marsupial component of the Ma-
dura Cave fauna listed by taxon and
stratigraphic occurrence, compared with
the fauna reported by Milham and
Thompson (1976) and the Recent fauna
of the Nullarbor as reported by Brooker
(1977) and others 66-67

The Mammalian Fauna

of Madura Cave, Western Australia

Part VII: Macropodidae: Sthenurinae, Macropodinae,

with a Review of the Marsupial Portion of the Fauna

Abstract

The Sthenurinae and Macropodinae from Ma-
dura Cave consist of Sthenurus (Simosthenurus)
near 5. oreas and S. gilli, Lagorchestes hirsutus,
Lagostrophus fasciatus, Onychogalea lunata, Pro-
temnodon near P. brehus and P. roechus, Petrogale
sp., Macropus fuliginosus, Macropus titan, and
Macropus robustus. With the exception of Mac-
ropus robustus and M. fuliginosus, which occur
only in Units 2-7, all the extant species are found
in all units of the deposit.

The marsupial fauna from the Pleistocene Units
2-7 is more diverse than that of the Holocene Unit
1, and contains species that are found today in
more mesic areas to the east and west of the Nul-
larbor Plain. These Pleistocene units also contain
numerous disharmonious pairs of species that in-
dicate a more equable climate than that of the
present. The assemblage from Unit 1 more closely
approximates the present fauna of the region, but
retains a few taxa now found to the east and west.

Introduction

This section of the study of the Madura Cave
mammalian fauna covers Sthenurinae and Ma-
cropodinae and concludes the systematic treat-
ment of the marsupials. It also gives a brief anal-
ysis of the marsupial fauna as discussed here and
in the previous sections (Lundelius & Turnbull,
1973, 1975, 1978, 1981, 1982, 1984) and its re-
lationships to other major Pleistocene marsupial
faunas of Australia. Scales for the drawings are
indicated adjacent each object; all are in centi-
meters except for Figures 1 2 and 1 3, where some
are in centimeters, others, in millimeters. Scales
shown along the edges of Figures 1 6 and 1 8 are in
millimeters. Values given in Tables 1-20 are in
millimeters.

Measurements, abbreviations, and statistical and
dental terminology are either those in standard
use, or they have been given in the previous sec-
tions of this report, or they are defined where used.
The study was completed before the dental ter-
minology of Archer (1978) became widely ac-
cepted; hence, the older standard of Thomas (1 888)
was followed.

MACROPODIDAE 1839
Sthenurinae Glauert, 1 926

Sthenurus Owen, 1873 (nomen nudum), 1874
(Simosthenurus) Tedford, 1 966
Sthenurus (Simosthenurus) sp. near S. oreas DeVis,
1895, and S. gilli Merrilees, 1965

Material

Trench 2, Unit 2, 2 '/a ft
PM 4356, right P4 (Sthenurus sp., Lundelius;
1963, S. Igilli, Merrilees, 1965; S. cf. oreas,
Tedford, 1966) (fig. 1A)
Trench 4, Unit 2, Level 1

PM 38998, anterior third, left P4 or P3 (fig. IB)
Trench 4, Unit 2, Level 2
PM 38996, partial crown, right upper molar (fig.

ID)
PM 38997, molar fragment
Trench 4, Units 4-5
TMM 41 106-3500, crown, left upper molar (fig.
IQ

Comparative Material

Sthenurus andersoni

Weetalibah (Binnia Creek), New South Wales
PM 4516, symphysis and rami with left I-M2,
right I-M, (fig. IF)

Sthenurus atlas

Wellington Caves, New South Wales
PM 1571, right maxillary fragment with M1-3
(fig. IE)

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

Fig. 1 . Sthenurus (Simosthenurus) sp., near S. oreas DeVis and S. gilli Merrilees, from Madura Cave compared
with Sthenurus sp. from other localities. Sthenurus sp. from Madura Cave: A, PM 4356, right P4 shown in labial
(right), lingual, and crown views; B, PM 38998, partial left P4 or P3 shown in labial (left), lingual, and crown views;
C, TMM 41 106-3500, left upper molar crown shown in crown view; D, PM 38996, partial right upper molar shown

FIELDIANA: GEOLOGY

in crown view. Sthenurus atlas from Wellington Caves, New South Wales: E, PM 1571, right maxillary fragment
with M1"3 shown in crown view. Sthenurus andersoni from Weetalibah (Binnia Creek), New South Wales: F, PM
45 16, symphysis and part of both rami with left I-M2 and right I-M, shown in crown view. Sthenurus brownei from
Mammoth Cave, Western Australia: G, PM 4414, left maxilla with P*-M4 shown in crown view; H, PM 7981, right
maxillary fragment with P5 and P4 (removed from crypt) shown in crown and labial views.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

PM 39065, left P4
PM 6776, P3 (or P3)
PM 6777, right P4

Sthenurus brownei

Mammoth Cave, Western Australia
PM 4414, left maxillary with P4-M4 (fig. 1G)
PM 7891, right maxillary fragment with P3 and
P4 removed from crypt (fig. 1 H)

Sthenurus tindalei
Lake Menindee, New South Wales
PM 4529 (cast of SAM PI 3820), palatal portion
of skull with adult dentition

Descriptions

The P4 is a two-crested tooth (fig. 1 A). Its main
crest begins near the anterior end of the crown at
the anterior cusp. The crest soon incorporates a
second laterally compressed, in-line cusp before
dividing just anterior to the midpoint of the crown.
From there the main crest is notched and contin-
ues as the lingual crest. It first runs diagonally
posterolingually to within the posterior quarter of
the crown and then turns back toward the midline
and abruptly tapers down to the crown base at the
posterior edge of the tooth. This lingual crest is
comprised of three narrow cusps, the anterior one
(which lies just behind the notch) being the most
distinct. From the dividing point at the notch a
lower but distinct labial crest rapidly descends, at
first running transversely, then turning posteriorly
and reaching its lowest point before beginning a
steady rise as it continues posteriorly. Nearly at
the rear of the tooth, where it is again nearly as
high as the main crest, it arcs lingually across the
labial half of the tooth, descends, and swings slightly
forward as it enters the median valley. This forms
a backward-opening posterior central basin be-
tween the two crests. Anteriorly within the basin,
a low, sharp ridge connects the labial crest to the
anterior end of the lingual portion of the main
crest. This ridge is nearly parallel to the anterior,
curved portion of the labial crest. At least two
other crenulations swing off from the labial crest
into the shallow posterolabial side of the basin.
Measurements in millimeters of the tooth are:
length 14.65, anterior width 6.63, posterior width
8.47, posterior basin length 8.15, and width 3.17.
The fragment of a P4 (or P3) blade (fig. 1 B) cor-
responds roughly to the anterior cusp of the main
crest in the complete tooth, but differs in having
more pronounced relief in its grooves and ridges.

The two upper molars (fig. 1 C-D) are similar in
size and major morphological features, but differ
in detail. Both are brachyodont with lophs that
are slightly convex anteriorly. The anterior cin-
gulum of TMM 41 106-3500 is small, but extends
across the entire anterior face of the tooth. The
posterior cingulum of both molars is very low and
thin. The two teeth differ markedly in the density
and coarseness of the crenulations on the faces of
the lophs. In PM 38996 the crenulations are less
dense and coarser than in TMM 41 106-3500. In
addition, the posterior crest of the paracone of PM
38996 is more prominent than that of TMM
41106-3500, and it closes the median valley la-
bially. Low extensions of the midlink can be seen
on the faces of the lophs in PM 38996, but not in
TMM 41106-3500. In TMM 41106-3500 both
faces of both lophs and the median valley are cov-
ered with fine crenulations that tend to be oriented
at right angles to the crests and lophs. The longer
crenulations are slightly curved, and many bifur-
cate away from the main crests and lophs. TMM
41 106-3500 is less worn than the other tooth and
further wear would undoubtedly simplify the or-
namentation, but probably not to the extent seen
in PM 38996.

Discussion

The dimensions of the Madura Cave specimens
have been compared with measurements for var-
ious species of Sthenurus given by Bartholomai
(1963), Tedford (1966), Merrilees (1965, 1968a),
and Marcus (1962, 1976), and with an additional
specimen of S. andersoni from Weetalibah, N.S.W.
(PM 4516: P4 length 14.65 mm, anterior width
6.40, posterior width 7.50) (fig. 2). This compar-
ison shows that the P4 from Madura Cave is too
short to be assigned to S. occidentalis, S. orientalis,
S. antiquus, S. pales, S. tindalei, S. atlas, or S.
notabilis. It is too wide to be assigned to S. an-
dersoni and slightly too narrow to be readily as-
signed to 5. brownei. Its proportions are closest to
those of S. gilli and S. oreas, which agrees with
the Merrilees (1965) and Tedford (1966) assign-
ments. It is also close to both of these species in
the size of the posterior basin and in the absence
from the basin of a ridge from the anterior cusp
such as is shown by Tedford (1966) in S. pales.

Comparisons of the two molars from Madura
Cave with those from other localities is difficult
because of the uncertainty of their positions in the
tooth row. Their small size (measurements, ob-

FIELDIANA: GEOLOGY

CO

-r-

C\J

o

T"

CO

T

■8

X

Q)

\

|

\

C

\

\«

\

s

g

(0

2

OB

. co

t>+co

in

-r - 9
3-2

z

LU

CO

. CM

a>

co

P/d H1QIM HOIhBJLSOd

3
. </>

M O

d £
6

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

tainable only from TMM 41 106-3500, are: length
1 1.5 mm, anterior width 10.3 mm, posterior width
10.5 mm) excludes them from Sthenurus pales, S.
tindalei, S. atlas, S. andersoni (except for the M1),
probably from S. notabilis and S. antiquus, and
possibly from S. oreas. They are within the size
range of one or more of the upper molars of S.
gilli, S. brownei, and S. occidentalis. The weak
development of the forelink and the presence of a
buccal ridge closing the median valley in PM 38996
are features cited by Merrilees (1968a) as char-
acteristic of S. brownei. Extensive fine crenulations
are also cited by Merrilees ( 1 968a) as characteristic
of S. brownei, but his Figures 4 and 6 are not clear
enough to allow detailed comparisons with TMM
4 1 1 06-3500. Comparison of the upper molars from
Madura Cave with those of S. oreas is uncertain
because of the lack of upper teeth which have been
unequivocally assigned to that species. Material
from Queensland referred to S. oreas by Bartho-
lomai (1963) is reported by him to have coarse
ornamentation. Bartholomai's Figure 5 indicates
coarser ornamentation than is seen in TMM 4 1 1 06-
3500, but is not unlike that of PM 38996.

It is not possible to make a positive assignment
to species on the basis of the available material.
The Madura Cave specimens are not necessarily
all from the same taxon, but not enough is known
about intraspecific variation of minor morpholog-
ical features to rule out their assignment to the
same taxon. Flannery (pers. comm., 1983) states
that the difference in ornamentation between the
two molars is greater than the range of variation
in known samples of Sthenurus. Milham and
Thompson (1976) reported Sthenurus teeth from
the south passage of Madura Cave, referring them
to two species, S. gilli and an unnamed larger form,
but no figures or descriptions of the specimens are
given. More material is needed from Madura Cave
to determine the number and identity of the species
of Sthenurus from this locality.

Macropodinae Thomas, 1888
Lagorchestes hirsutus Gould, 1 844

Material

Surface
TMM 4 1 1 06-679, skull and left ramus (figs. 4A-
D, 5A)
Trench 1, top 1 ft
PM 4784, left ramus fragment with M,.3, alveoli
for P4 and M4

PM 25540, right ramus fragment with M3, al-
veoli of M2 and M4
Trench 2, 2lh ft below surface

PM 25221, left ramus with dP4, M„ part of M2,
part of crypt for P4 (fig. 7B).
Trench 3, Unit 2, Level ?

PM 39038, right P4

PM 39039, left P4
Trench 4, Unit 1 , Level 1

PM 39047, right I1
Trench 4, Unit 1 , top 1 ft

TMM 41106-5130, left P4

PM 39003, skull and mandible (figs. 5B, 6A-C)
Trench 4, Unit 2, Level 1

TMM 41 106-5087, right I1

PM 38916, P3
Trench ? (probably 4), Unit 2, Level ?

PM 38914, left maxillary fragment with P3 (fig.
7C)
Trench 4, Unit 2, Level 2

PM 38947, right M4
Trench 4, Unit 2, Level 4

TMM 41106-150, left P4

cf. Lagorchestes hirsutus

Trench 3, Unit 2, Level 1

TMM 41 106-5044, left M3 (or M2 or M4)

TMM 41 106-5045, right M4 or M3

TMM 41 106-5049, left M,

PM 38922, left M3 or M2

PM 39035, left M4 or M3

PM 39041, right M,
Trench 3, Unit 2, Level 2

TMM 41106-140, left ramus fragment with
M3^
Trench 4, Unit 1, top 1 ft

TMM 41 106-5059, left M4 or M3

TMM 41 106-5082, right M2 or M3

PM 38892, left M3 or M4

PM 38893, left M4

PM 38898, left P4

PM 38901, right M3 or M4
Trench 4, Unit 2, Level 1

PM 38942-38944, three left M4s
Trench 4, Units 4-5

PM 36981, right I3

Comparative Material

Bernier Island, Western Australia

AMNH 155106 (fig. 3)
Webb's Cave (surface), Mundrabilla Station,
Western Australia

TMM 41209-528

FIELDIANA: GEOLOGY

TMM 41209-891

TMM 41209-892 (fig. 7A)

Descriptions

Skull— The skull has the normal macropodid
shape with the braincase relatively more inflated
and the rostrum relatively narrower than in the
large species of Macropus. The muzzle is wider
than that of most Lagostrophus or Onychogalea
of comparable size (O. unguifera being one excep-
tion). In dorsal view the rostrum narrows abruptly
immediately anterior to the orbits. The sides of
the zygomatic arches and the interorbital area are
straight and parallel.

The nasals taper anteriorly and extend only
slightly anterior to the dorsal ends of the premax-
illae. They extend posteriorly as far as the lacri-
mals and are square or gently rounded posteriorly.
The frontals extend approximately one-half the
distance from the posterior end of the nasals to
the nuchal crest. The posterior end of each is gently
rounded. The frontals expand anterolaterally to
contact the maxillary and lacrimal bones. Between
the orbits, where the lateral edges of the frontals
are parallel to each other, they are sharply angled
at the junction of the median wall of the orbit and
the dorsal surface of the skull. In contrast, the
modern comparative specimens of Lagostrophus
and Onychogalea exhibit several different frontal
shapes. The frontals of Lagostrophus fasciatus are
narrower and taper posteriorly nearly to a point,
those of Onychogalea frenata bow outward from
a narrowest point just behind the flange for the
lacrimal and then taper roundly posteriorly, and
those of O. unguifera are wide and more closely
resemble those of Lagorchestes than those of O.
frenata.

The parietals make up approximately two-thirds
of the dorsal part of the braincase. They extend
anteriorly, lateral to the frontals, as far as the pos-
terior end of the interorbital constriction. A small
triangular interparietal is present in front of the
supraoccipital, at the junction of the sagittal and
occipital crests. The modern comparative speci-
men also has the interparietal, as do specimens of
Onychogalea frenata and O. unguifera; specimens
of Lagostrophus fasciatus lack it. The dorsal bor-
der of the temporal fossa is marked by a weak
ridge which extends from the posterior end of the
interorbital constriction diagonally across the dor-
sal surface of the braincase to join its mate, form-
ing a short sagittal crest just anterior to the inter-

parietal. In a modern specimen from Bernier Island
(AMNH 155106, fig. 3), the ridges converge but
do not join to form a sagittal crest. Each lacrimal
has a small flange that projects into the antero-
dorsal part of the orbit.

In lateral view the premaxilla with its incisors
projects below the plane of the molars. The dorsal
profile of the skull is straight from just ahead of
the frontoparietal suture to the anterior end of the
nasal. This profile resembles that of the modern
Lagostrophus fasciatus, but differs from Onycho-
galea frenata and O. unguifera, which have a more
rounded and undulating profile. The muzzle is
deep, with sides that are almost flat. This is also
true of the modern specimen and of specimens of
Lagostrophus fasciatus. There is no prominent
depression on the lower part of the lateral surface
of the maxilla ahead of P4, such as is seen in mod-
ern Onychogalea. The anterior opening of the in-
fraorbital foramen is small (~ 1 mm), as in the
modern specimen and in Lagostrophus fasciatus
and Onychogalea unguifera; in O. frenata it varies
between ~ 1 mm and ~ 3 mm. In the Madura Cave
specimens the foramen is located immediately
ahead of the orbit, about halfway between the tooth
row and the dorsal surface of the skull. In Lagos-
trophus and Onychogalea the anterior opening of
the infraorbital foramen is located nearer the tooth
row.

The descending process of the zygomatic arch
extends to the level of the occlusal surface of the
molars, as in Lagostrophus. In Onychogalea the
descending process is smaller and shorter.

In ventral view the tooth rows are bowed out-
ward slightly, with the maximum width at the po-
sition of the descending process of the zygomatic
arch.

The palate shows little narrowing anterior to P4;
this differs from both Onychogalea and Lagostro-
phus. The modern specimen from Bernier Island
(AMNH 1 55 106) shows more taper than the Ma-
dura Cave specimens (figs. 3A,C, 4A,C, 6A,C).
The incisive foramina are elongate ovals which
extend from the level of the midpoint of I3 to the
suture between the premaxilla and maxilla. They
are larger than those of modern Lagostrophus, ap-
proaching the size of those of modern Onycho-
galea.

The palatal fenestrae are irregularly oval and lie
across the maxillary-palatine suture, opposite
M3^* or M2-3. Additional fenestration of the pal-
atines is not extensive. The fenestrae of the Ma-
dura Cave specimens are smaller than those of the
modern specimen, and much smaller than those

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

*

■

^»

B

FIELDIANA: GEOLOGY

Fig. 3. Drawing of the skull and right mandible of the modern Lagorchestes hirsutus, AMNH 155106, from
Bernier Island, Western Australia. Views of skull: A, dorsal; B, right lateral; C, ventral. Views of jaw: D, lateral; E,
dorsal; F, mesial.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

■

Fig. 4. Four views of a skull of Lagorchestes hirsutus, TMM 41 106-679, from the surface of Madura Cave: A,
dorsal; B, left lateral; C, ventral; D, posterior.

10

FIELDIANA: GEOLOGY

Fig. 5. Medial, dorsal, and lateral views of the left mandibles of two specimens of Lagorchestes hirsutus from
the surface of Madura Cave: A, TMM 41 106-679 Oaw belongs to skull shown in fig. 4); B, PM 39003 Oaw belongs
to skull shown in fig. 6).

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

11

s:

T

B

<

■x'

Fig. 6. Three views of a skull of Lagorchestes hirsutus, PM 39003, from the surface of Madura Cave: A, dorsal;
B, left lateral; C, ventral. (Jaw of this specimen is shown in fig. 5B.)

12

FIELDIANA: GEOLOGY

of modern Lagostrophus fasciatus and Onycho-
galea frenata, where they extend farther forward
into the maxilla. The very young modern O. un-
guifera specimen has no true palatal fenestrae; in-
stead, a small perforation pierces each maxilla at
or near the suture with the palatine, and both max-
illa and palatine are riddled with a dozen similar
perforations, plus so many minute perforations
that the bone resembles lacework.

The auditory bullae are inflated to a greater de-
gree than in Lagostrophus or Petrogale and to about
the same degree as in Onychogalea, but not to the
extent seen in Bettongia. The bullae of Lagor-
chestes are more elongate than those of Onycho-
galea. The mastoid process protrudes farther ven-
trally and laterally, but is not bent forward to lap
around the side of the tympanic as it is in Ony-
chogalea. The tympanic in each of these taxa is
expanded laterally to form a considerable meatal
tube.

Upper Dentition— The upper incisors are ar-
ranged in a smooth, broadly U-shaped arch in the
fossil and modern Lagorchestes, like modern On-
ychogalea (ROM 91.11.1.190; USNM 122614,
237643), and in contrast to the V-shape of this
arch in Lagostrophus (AMNH 155104). The I1 is
the largest incisor. It is almost oval in cross section,
with a flat area on the medial side and a shallow
indentation posteriorly for the I2. In Lagostrophus
the I' is smaller than I2 and I3 and is triangular in
cross section. In Onychogalea the I1 is larger than
I2 or I3 and has a more flattened oval cross section
than that of Lagorchestes.

The I2 and I3 are approximately equal in size,
but are different in shape. The I2 is oval in cross
section except for a flattening on the outside and
a broad, shallow depression posteriorly for the an-
terior edge of I3. A small posterior lobe is present
but is not seen in worn teeth. The I2 of Onycho-
galea is slightly larger and has a better developed
posterior lobe. The I2 of Lagostrophus is much
larger and more elongate than that of either La-
gorchestes or Onychogalea, and is divided into two
lobes by a diagonal anterior-interior groove along
the occlusal surface.

The I3 is an elongate tooth that is divided into
two lobes, a rounded antero-external (labial) one
and a sigmoidal lingual one that extends to the
posterior end of the tooth. The two lobes are joined
at the anterior end of the tooth. The I3 of Ony-
chogalea is somewhat wider anteriorly and has a
less continuous lingual sigmoidal ridge. The I3 of
Lagostrophus has a straight lingual lobe that is not
connected to the labial lobe anteriorly.

A small (1 mm diameter) canine is located at
the anterior end of the maxilla, separated from the
I3 and the P4 by diastemas.

Two bladelike teeth (PM 389 1 4, 389 1 6) are ten-
tatively identified as P3 of this species. Their struc-
ture is similar to that of the P4, but they are slightly
smaller and their main ridges have only three cusps;
those of the P4 have four. The lingual shelf of each
is weaker than that of the P4 and the posterolingual
cusp is continuous with the posterior cusp of the
main ridge. Marshall (1973a) found that the basic
cusp number in Lagorchestes leporides was the
same for P3 as for P4, but in L. hirsutus, if these
identifications are correct, these two teeth differ.
Their dimensions are similar to those of two mod-
ern specimens (WAM 685 from Dorre Island,
Ml 471 from Canning Stock Route, tables 1-2). A
positively identified dP4 is not present in the Ma-
dura Cave sample.

The P4 is an elongate blade with four cusps
aligned along its ridge. There is a low lingual ledge
that varies somewhat in its development from
specimen to specimen. It may be represented by
one or more separate cuspules, or there may be a
low ridge incorporating them. Wear on these struc-
tures is also variable; in PM 39003, in which the
left M, has been shed, the P4 has worn a distinct
abrasion facet on the central cuspule of the lingual
ledge of P4. The main ridge bends sharply lingually
at its posterior end to join a large posterolingual
cusp which lies in line with the lingual ledge. This
last cusp is usually separated from the lingual ledge
by an open valley, but they may be connected. The
anterior cusp of the main ridge is the same size as
the posterior one. It forms a continuation of the
main longitudinal crest of the blade. The anterior
cusp lacks a distinct labial ridge. A weak labial
cingulum is present.

The upper molars are slightly longer than wide.
In the specimens from Madura Cave and in the
modern specimens, mesial drift has pushed the M'
against the posterior end of P4 and interdental wear
has removed most of the procingulum. Remnants
of the procingulum of the M1 of PM 39003 indicate
that it was about as extensive originally as those
on M2^*. The molars increase in size from M1 to
M4. In M' the protoloph is slightly shorter than
the metaloph, in M2 the two lophs are nearly equal,
and in M3 and M4 the metalophs are progressively
shorter than the protolophs. Unworn lophs are
thin and bowed forward in the middle. Worn lophs
are straight. Low crests on the paracone and meta-
cone become exaggerated by wear to give the ap-
pearance of a labial link. The midlinks are formed

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

13

9

Fig. 7. Lagorchestes hirsutus and Lagostrophusfasciatus from Madura Cave compared with Lagorchestes hirsutus
from Webb's Cave, Mundrabilla Station, Western Australia. Lagorchestes hirsutus: A, TMM 41209-892, Recent
specimen from the surface of Webb's Cave, left ramus with P3 and dP4-M2 in lateral (left), dorsal, and medial views;
B, PM 25221, from Madura Cave, left ramus with dP4, M„ part of M2, and a part of the crypt for P4 in lateral (left),
dorsal, and medial views; C, PM 38914, from Madura Cave, left maxillary fragment with P3 shown in lateral (left),
dorsal, and medial views. Lagostrophus fasciatus from Madura Cave: D, PM 38979, left M1 shown in labial (top),

14

FIELDIANA: GEOLOGY

crown, and lingual views; E, PM 38909, left upper molar shown in labial (top), crown, and lingual views; F, PM
39054, right P4 shown in labial (right), crown, and lingual views; G, TMM 41106-580, right M, shown in lingual
(left), crown, and labial views; H, TMM 41 106-5067, partial left M, or M2 shown in labial (left), crown, and lingual
views; I, TMM 41 106-5084, right M2 or M3 shown in lingual (left), crown, and labial views.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

15

Table 1 . Numerical data on upper dentitions of Lag-
orchestes hirsutus from Madura Cave.

N

OR

Mean

,>.

M1

M2

M'

M'

M'~2
M2-3
M'-3
M1^

L

AW

PW

L

AW

PW

L

AW

PW

L

AW

PW

L

AW

PW

L

AW

PW

L
L
L
L

3.94-^.08
1.72-1.82
2.32-2.34

4.81-5.30
1.68-1.80
2.10-2.25

3.80-4.07
3.40-3.55
3.82-3.83

5.12-5.22
4.09^.17
3.93-3.95

5.65-5.96
4.09^.36
3.55-3.67

5.54-6.05
3.97-4.04
3.45-3.65

8.34-8.76
10.25-10.49
13.72-14.37
19.29-19.45

4.01
1.77
2.33

5.06
1.74
2.18

3.94
3.48
3.83

5.17
4.13
3.94

5.81

4.23
3.61

5.80
4.01
3.55

8.55
10.37
14.05
19.37

by spurs of unequal size that join in the central
valley. The protolophs make up the larger part of
the midlinks, in the form of a posterior crest of
the protocone that turns sharply to meet the spur
from the metaloph.

Mandible— The mandible has the normal ma-
cro podid form. The horizontal ramus has about
the same depth from M, through M4. The pro-
portions of the horizontal ramus are similar for
Lagorchestes hirsutus from Madura Cave, Webb's
Cave (TMM 41209-891), the modern specimen
from Bernier Island, a modern specimen of La-
gostrophus fasciatus, and material of Onychogalea
lunata from Webb's Cave on the Nullarbor Plain.
However, modern specimens of Onychogalea
frenata from Queensland and New South Wales
and of O. unguifera from Western Australia have
a more slender and elongate ramus, possibly be-
cause of their immaturity (each has the P3 and dP4
in place). The profile of the tooth row in the mod-
ern specimens is slightly arched in the region oc-
cupied by P4 and M,, apparently as the result of
some forward molar progression. The P4 in both
Madura Cave specimens and in the modern spec-
imens from Bernier Island is rotated forward and
downward. The diastema is relatively shorter than
in Onychogalea and about the same length as in

Lagostrophus. A mental foramen is located just
anterior to the P4 and about halfway between the
upper and lower edges of the mandible.

The ascending ramus and masseteric fossa show
few distinctive features. The ventral border of the
masseteric fossa is located higher above the ventral
margin of the jaw and the postero ventral margin
of the masseteric fossa is more rounded than in
Lagostrophus. The foramen into the dental canal
is located lower than in Onychogalea.

The condyle of the jaw is oval in Lagorchestes
and the articular surface is gently convex antero-
posteriorly. In Lagostrophus the condyle is more
elongate transversely and in Onychogalea it is al-
most round and smaller than in Lagorchestes. In
the modern Lagostrophus and all three species of
Onychogalea a small bony spur projects forward
from the medial side of the condyle; this has not
been seen in Lagorchestes.

Lower Dentition— The lower incisors are slen-
der, procumbent, lancelike teeth. Enamel is pres-
ent all along the ventrolateral surface. In the Ma-
dura Cave specimens the anterior ends are
truncated by a prominent wear surface oriented at
an angle of about 45° to the long axis of the tooth.
Onychogalea frenata has a similarly oriented wear
surface, but in Lagostrophus fasciatus the wear
surface is almost parallel to the long axis of the
tooth, giving the tooth a sharply pointed end. This
difference in the wear of the lower incisors is re-
lated to the difference in the upper incisors in these
taxa. The I1 and I2 of Lagorchestes and Onycho-
galea are large and occlude primarily with the ends
of the lower incisors, producing wear surfaces only
at the ends of the lower incisors. In Lagostrophus
the I1 is small relative to the I2 and P, which are
elongate teeth that occlude with a considerable
length of the upper edge of the lower incisors, pro-
ducing wear surfaces along the upper edges of the
lower incisors. The ventromedial edge of the lower
incisors shows a wear facet produced by wear be-
tween the two lower incisors. This facet is better
developed in Lagostrophus than in Lagorchestes.

The P3s have not been identified in the Madura
Cave material. The dP4 of Lagorchestes is known
from only one specimen, PM 2522 1 . It is assigned
to Lagorchestes on the basis of its association in
a mandible with an M, and M2 which lack the
complex procingula characteristic of Lagostro-
phus, and of the presence under the dP4 of a crypt
for an unerupted P4 larger than that of Onycho-
galea. The dP4 is an elongate molariform tooth
that is wider across the hypolophid than across the

16

FIELDIANA: GEOLOGY

Table 2.
tralia.

Numerical data on upper dentitions of Holocene samples of Lagorchestes hirsutus from Western Aus-

Canning Stock

Route*

Dorre Islandf

Be

AN

rnier Island

N

OR

Mean

N

OR

Mean

IMI 155106

P3

L

1

3.7

3.7

3.9

3.9

AW

1

1.5

1.5

1.8

1.8

PW

1

2.1

2.1

2.0

2.0

dP4

L

1

3.7

3.7

4.1

4.1

AW

1

3.1

3.1

3.0

3.0

PW

1

3.4

3.4

3.2

3.2

P

L

2

5.0-5.3

5.15

4

4.8-5.1

4.95

1

4.7

AW

2

1.8-2.2

2.00

4

1.9-2.0

1.93

1

1.8

PW

2

2.1-2.3

2.20

4

1.9-2.3

2.18

1

2.1

M1

L

3

3.5-4.0

3.73

5

3.5^.7

4.22

1

3.2

AW

3

3.6-3.8

3.73

5

3.7-3.9

3.86

1

3.4

PW

3

3.5^.1

3.80

5

3.7^.1

4.00

1

3.9

M2

L

3

5.0-5.4

5.17

5

5.0-5.6

5.42

1

5.0

AW

3

4.2-4.5

4.40

5

4.0-4.8

4.38

1

4.3

PW

3

4.0-4.6

4.37

5

3.9^».8

4.30

1

4.2

M'

L

2

5.9-6.0

5.95

4

6.0-6.2

6.08

1

5.2

AW

2

4.9-5.0

4.95

4

4.2^.6

4.33

1

4.4

PW

2

4.0-4.5

4.25

4

3.7^.1

3.88

1

4.1

M4

L

1

6.3

6.3

1

5.8

AW

1

4.6

4.6

1

4.3

4.3

1

3.8

PW

1

3.8

3.8

1

3.5

M'-2

L

1

7.5

M2~3

L

1

10.2

M'-3

L

1

13.2

M'-»

L

1

20.5

20.5

1

18.1

* Sample from Canning Stock Route in The Western Australian Museum (Ml 464, Ml 465, Ml 471).

t Sample from Dorre Island in The Western Australian Museum (WAM 685, 10565, 10567, 10624, 10625).

protolophid. The procingulum projects forward
and is narrower than in any of the molars. The
metaconid and entoconid have anterior and pos-
terior crests. The anterior crest of the metaconid
does not join the procingulum as it does in the
molars, but instead turns into the cingular basin.
The forelink extends in a sigmoid curve to the
anterior point of the tooth. Labial to the forelink,
the cingulum is very weak. The P4 is a simple blade
made up of a long, compressed cusp on either end
and two lower and smaller, indistinct cusps be-
tween. The anterior cusp is smooth labially and
has a variably developed ridge on its lingual side.
The posterior cusp is bent lingually. There is no
external cingulum and only a hint of an internal
cingulum. The Madura Cave specimens agree with
the descriptions of P4 of Lagorchestes leporides
from Lake Victoria (Marshall, 1973a).

The lower molars increase in size posteriorly
(table 3). The hypolophid is wider than the pro-

tolophid in M,, about equal in M2, and narrower
in M3 and M4. There are no accessory ridges in
the midlink area. The forelink tends to have a
lingual bow, as is pointed out by Marshall (1973a)
for Lagorchestes leporides from Lake Victoria.

Mesial Drift

Mesial (anterior) drift of the cheek teeth of La-
gorchestes is apparent in the crowding of the M1
against the P4 in the upper dentition and in the
rotation of P4 forward and downward in the man-
dible. Other indications are the tendency of the
lower tooth row to be arched and for the anterior
molars to show heavy wear while the posterior
ones show little or none. Sanson (1983) has point-
ed out that mesial drift is at a maximum in those
taxa in which the premolars are either reduced in
size or are quickly shed; Peradorcas is the most
extreme example.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

17

Table 3. Numerical data on lower dentitions ofLag-
orchestes hirsutus from Madura Cave.

N

OR

Mean

dP4
P4

M,
M2
M,
M4

M,_2
M2.3
M,_3

L

AW

PW

L

AW

PW

L

AW

PW

L

AW

PW

L

AW

PW

L

AW

PW

L
L
L
L

3.72
2.04
2.14

4.4-4.8
1.5-1.8
1.5-1.9

3.8-4.1
2.7-3.0
2.8-3.4

4.5-4.7
3.2-3.6
3.3-3.7

5.0-6.0
3.1^.3
3.3^.3

5.5-5.6
3.6^4.7
3.1-3.8

8.5-8.7

9.7-10.8

13.6-14.3

19.3-19.6

3.72
2.04
2.14

4.60
1.65
1.78

3.90
2.82
3.10

4.62
3.33
3.56

5.47
3.82
3.75

5.54
4.05
3.37

8.60
10.13
13.94
19.46

In Lagorchestes, P4 appears to drift more readily
than P4. After drifting over the hump in the jaw,
the P4 becomes the most steeply inclined of all the
teeth. The P4 appears to have a firmer anchorage
to the bone than P4, and its lesser drift results in
a slightly different mechanism of accommodation
in the upper molar dentition. Here the drift is
accomplished by extreme interdental wear so that
M1 soon loses the lingual two thirds of its procin-
gulum and a very appreciable portion of the pro-
toconal and hypoconal areas of the crown itself.
The result is that the tooth occupies a space only
about one half that of its original length, and comes
to overlap the labial side of P4. The P4 erupts
progressively, so that the level of its occlusal sur-
face remains below that of M1, causing a break in
the curved surface of the functional occlusal plane.
This helps it to maintain its occlusal relationship
with P4 and M,.

Another striking indication of mesial drift is the
remarkable way that the most heavily stressed of
the upper molar roots are eroded and resorbed,
and apparently remodeled in the area between the
crown base and the alveolar surface. This results
in molar roots that curve posteriorly toward their
tips. This phenomenon is best seen in the hypo-
conal region of the anterior molars (TMM 41 106-
679, PM 39003, AMNH 155106). As far as we

can tell it is most pronounced in Lagorchestes,
intermediate in Onychogalea, and absent in La-
gostrophus, which shows less medial drift.. The rea-
sons for these differences are not known, but one
could speculate that in Onychogalea, in which me-
sial drift is fully comparable to that in Lagor-
chestes, P4 is a very reduced tooth which offers
very little resistance to drift. Perhaps without much
resistance the alveoli have never had time to be-
come as extensively ossified and alveolar remod-
eling is all that is necessary to permit drift to occur.
Conversely, in Lagorchestes, where a larger blade
resists the drift more effectively, a more complete
ossification may result; in this case the remodeling,
which involves both the alveolar bone and the
tooth base and roots, may depend to a greater
extent on tooth root changes.

Discussion

Mean values of dental measures of the Madura
Cave sample of Lagorchestes hirsutus average
slightly larger than those of Recent samples given
by Tedford (1967) and Marshall (1973a), but in
most cases there is extensive overlap. There also
is extensive overlap in dental dimensions between
the Madura Cave sample and Recent samples from
the Canning Stock Route and Dorre and Bernier
Islands, Western Australia (tables 1-4). The lengths
of P5 are greater in the Madura Cave sample than
in Tedford's and Marshall's samples, and there is
no overlap in the lengths of the P4. The lengths of
Mj are lower in the Madura Cave sample, with no
overlap, probably because the Madura Cave sam-
ple is made up of older individuals in which both
occlusal and interdental wear would act to reduce
the length. As pointed out by Marshall (1973a),
measures of L. hirsutus and L. leporides overlap.
Tedford (1967, fig. 2) separated L. leporides and
L. hirsutus by plotting length of P4 against maxi-
mum width of M1. This separation is actually the
result of the non-overlapping values of the length
of P4, which is shown in Tedford's Table 30. The
Madura Cave sample extends the range of lengths
of P4 upward to 5.30 mm (table 1), which is below
the lowest value (5.4 mm) for the combined Re-
cent samples of L. leporides of Tedford (1967) and
Marshall (1973a). On the basis of their smaller
size all Madura Cave P4s are assigned to L. hir-
sutus.

Lagorchestes hirsutus is known from a wide area
in the interior of Western Australia and from Ber-
nier and Dorre islands, in Shark Bay, northwestern
Australia (Ride & Tyndale-Biscoe, 1959; Finlay-

18

FIELDIANA: GEOLOGY

Table 4. Numerical data on lower dentitions of Lagorchestes hirsutus from Western Australia.

Canning Stock Route*

Dorre Island

Rprnipr IvI-.inH

N

OR

Mean

N

OR

Mean AMNH 155106

p,

L

3.5

3.5

3.0

3.0

AW

1.4

1.4

1.6

1.6

PW

1.7

1.7

1.9

1.9

dP4

L

3.5

3.5

3.8

3.8

AW

2.3

2.3

1.8

1.8

PW

2.7

2.7

2.6

2.6

P4

L

4.6

4.6

4

4.4-4.6

4.48

I 3.8

AW

1.8

1.8

4

1.6-1.9

1.75

1 1.6

PW

1.8

1.8

4

1.7-1.9

1.83

1 1.6

M,

L

3

3.5^1.0

3.70

4

4.0-4.5

4.28

1 3.5

AW

2

2.9

2.9

4

2.7-2.9

2.80

I 2.5

PW

3

2.9-3.2

3.10

4

2.9-3.2

3.03

2.8

M2

L

3

4.0-5.4

4.70

5

4.3-5.0

4.86

I 4.2

AW

3

3.4-3.5

3.43

5

3.3-3.6

3.46

I 3.0

PW

2

3.0-3.4

3.20

5

3.4-3.7

3.50

I 3.2

M,

L

2

5.7-5.9

5.80

4

5.7-6.0

5.83

I 4.8

AW

2

3.7-3.9

3.80

4

3.7^.0

3.83

I 3.7

PW

2

3.6-3.9

3.75

4

3.4-3.8

3.53

I 3.6

M,

L

2

5.9-6.0

5.95

2

5.7-6.3

6.00

5.5

AW

2

3.7-3.9

3.80

2

3.9-4.0

3.95

1 3.2

PW

1

3.3

3.3

2.9

M„

L

1

19.5

19.5

7.2

M2_,

L

I 9.6

M,_,

L

...

...

1 12.9

Mw

L

16.5

* Sample from Canning Stock Route in The Western Australian Museum (Ml 464, Ml 465, Ml 471).

t Sample from Dorre Island in The Western Australian Museum (WAM 685, 10565, 10567, 10624, 10625).

son, 1936; Glauert, 1933). Since it has previously
been reported from Horseshoe Cave on the Nul-
larbor Plain (although without stratigraphic con-
text; Archer, 1972, 1974), its presence in the Ma-
dura Cave fauna is not unexpected. Like many
other species, it had a wider distribution in the
past. It has been reported from deposits dated be-
tween 30,000 and 35,000 b.p. in Devil's Lair, in
the southwestern corner of Western Australia
(Dortch & Merrilees, 1972; Baynes et al., 1975;
Balme et al., 1978; Merrilees, 1979). Tedford
(1967) reported a specimen, probably of Holocene
age, from the lower Cooper's Creek 40 mi (6 1 km)
east of Lake Eyre in South Australia. Lagorchestes
hirsutus is said to have been an inhabitant of the
open plains.

Lagostrophus Thomas, 1887

Lagostrophus fasciatus (Peron & Lesueur), 1807

Material

Trench 4, Unit 1 , Level 1

TMM 41 106-5067, left M, or M2 (fig. 7H)

TMM 41 106-5068, right M2 or M3

PM 38909, left upper molar (fig. 7E)

PM 38911, left M2
Trench 4, Unit 1, top 1 ft

TMM 41 106-580, right M, (fig. 7G)

TMM 41 106-5084, right M2 or M3 (fig. 71)

PM 39054, right P4 (fig. 7F)
Trench 4, Unit 2, Level 4

PM 38979, left M1 (fig. 7D)

Comparative Material

Lagostrophus f. fasciatus
Bernier Island, Western Australia

AMNH 155104 (fig. 8)
Dorre Island, Western Australia

USNM 218467

Descriptions

Upper Dentition— The P4 is represented by the
anterior half of an unrooted tooth, which preserves

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

19

•

Fig. 8. Skull and left mandible of Lagostrophus f. fasciatus, AMNH 155104, from Bernier Island, Western
Australia. Views of skull: A, dorsal; B, right lateral; C, ventral. Views of mandible: D, lateral; E, dorsal; F, medial.

20

FIELDIANA: GEOLOGY

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

21

Table 5. Measurements of upper dentitions of Lag-
ostrophus fasciatus.

Madura Cave

Recent

PM

PM

AMNH

USNM

38979

38909

155104

218467

P3

L

AW

PW

4.5
2.6
2.6

dP4

L

AW

PW

4.1
3.6
3.3e

P4

L

AW

PW

5.4
2.6
2.8

M1

L

4.2

4.2

4.2

AW

3.4

3.8

3.8

PW

3.6

4.1

3.7

M2

L

4.7

4.6

AW

4.5

4.0

PW

4.3

3.8

M3

L

5.1

4.9

AW

4.5

4.5e

PW

4.5

3.9e

M4

L

AW
PW

5.7e

Molariform

L

tooth

AW
PW

3.3

e = Estimate.

the anterior three of the usual 5 + cusps (fig. 7F).
The tooth is bladelike, with the axial ridge con-
tinuing onto the front of the anteriormost cusp.
That cusp also has labial and lingual ridges that
ascend posteriorly toward the tooth base. The lin-
gual ridge joins a weak lingual cingulum; the labial
ridge joins the outward-bulged side of the tooth
about halfway toward the base of the crown.

The M1 is an unworn, unrooted tooth (fig. 7D).
The crown is rectangular, nearly as wide as long,
and has only a weak constriction between its two
parts. There is a distinct but unexpanded procin-
gulum across the front of the tooth from the an-
terior crest of the paracone to the anteromedial
corner of the base of the protocone. A weak fore-
link connects the base of the protoloph with the
midpoint of the cingulum. Both lophs are bowed
forward slightly, and the paracone and metacone
have longitudinal anterior and posterior crests
along their labial borders, which lie nearly in line.
The midlink is a thin, simple, arcuate ridge that
curves off" from the protocone to join the anterior
side of the metaloph at about midheight. The pos-

terior basin is open, and its medial and lateral
margins are symmetrical. The distinctive second
"postlink" is thin but pronounced. This structure
is not the true postlink of Tedford (1966), which
is also present. We call the tooth an M1 because
it compares well in size with the M ' of the Amer-
ican Museum specimen (fig. 8; table 5). In that
specimen the other molars have a very similar
morphology but are each successively slightly larg-
er, suggesting that size is the best means of distin-
guishing one tooth from another.

The other upper molar is a partial tooth lacking
the anterior side of the protoloph and the postero-
labial corner (fig. 7E). It also appears to have been
unerupted and unrooted. It has a well developed
"postlink." Its only unusual feature is an anterior
double wrinkle in the metaloph which is the meta-
loph contribution to the midlink. Otherwise it
agrees with the description of the M1.

Lower Dentition— The lower molars conform
to a standard pattern (fig. 7G-I). In the modern
specimen used for comparison (fig. 8), all are elon-
gate and rectangular with simple posteriorly bowed
cross lophs, and there is a uniform gradual increase
in size from M, to M4 (table 6). All lower molars
of L. fasciatus have a distinctive forelink-procin-
gulum pattern in which the link stands off from
the cingulum, rather than merging with it as it does
in most other wallabies. The hypolophid makes
the greatest contribution to the midlink. The con-
tribution of the protolophid to the link is variable,
and sometimes absent. Other variable features are
low, rounded bulges that sometimes occur on the
anterior faces of the lophids medial to their mid-
points. The Madura Cave teeth all conform to this
pattern, and one or more exhibit each of the minor
variables seen in the modern specimen. Estimates
of their positions in the series are based on size.

In spite of the small number of specimens of
this taxon, the close agreement of morphological
detail between the Madura Cave specimens and
the modern comparative materials permits con-
fident assignment of the Madura Cave material to
Lagostroph us fasciatus.

Discussion

Lagostrophus fasciatus was found over much of
southwestern Australia during the early period of
European settlement (Shortridge, 1909; Calaby,
1 97 1 ). It may be extinct now on the mainland, but
it survives on Bernier and Dorre islands in Shark
Bay (Ride & Tyndale-Biscoe, 1959). It has been

22

FIELDIANA: GEOLOGY

Table 6. Measurements of lower dentitions of Lagostrophus fasciatus.

Madura Cave

Recent

TMM

TMM

TMM

TMM

AMNH

USNM

41106-5067

41106-5068

41106-580

41106-5084

155104

218467

p,

L

...

4.0

AW

• •

••

1.8

PW

••

••

2.1

dP4

L

AW

PW

••

••

4.0
3.2
3.4

P4

L

AW

PW

••

••

4.7
2.0
2.3

M,

L
AW

4.<

\

••

4.3
3.1

4.2
3.2

4.5
3.4

PW

■•

••

3.3

3.4

3.4

M2

L

• •

• •

5.2

4.5

4.8

AW

••

3.;

>

3.7

3.6

3.6

PW

••

••

3.3

3.7

3.5

M,

L

• •

..

4.9

AW

• •

• •

3.8

PW

••

••

3.8

M4

L
AW

••

••

5.2e
4.9e

PW

e =

Estimate.

reported previously with no stratigraphic context
from Horseshoe Cave on the Nullarbor Plain
(Archer, 1972, 1974). The Nullarbor Plain rec-
ords, some of which are of Holocene age (including
most of the Madura Cave materials), together with
its presence in archaeological sites of Holocene age
along the lower Murray River in South Australia
(Wakefield, 1 964), indicate a former distribution
throughout South Australia. It has not been re-
ported from Pleistocene faunas at Lake Menindee
(Tedford, 1 967) or Lake Victoria (Marshall, 1973a).

Onychogalea Gray, 1 84 1
Onychogalea lunata (Gould), 1 840

Material

Trench 1 , Unit 1 , top 1 ft
PM 4783, left maxilla with P4-M4 (fig. 12B)
PM 4785, left ramus with I,-M4 (fig. 12A)
PM 25538, right maxillary fragment with P3,

dP4, P4 removed from crypt (fig. 1 2Q
PM 25539, right ramus fragment with P4 re-
moved from crypt, M„ alveoli for P3 and
dP4, M2_3 in crypt (fig. 12D)
PM 25541, left ramus with M2^,, alveoli for P4-
M,

Trench 2, 2'/2 ft below surface

PM 25222, right ramus with part of M4
Trench 3, Unit 2, Level ? (presumably 1)
TMM 41 106-183, right ramus with M,_2, P4 re-
moved from crypt, M3 in crypt, alveoli for

P3anddP4(fig. 13 A)
TMM 41 106-184, right maxilla with P3, dP4, P4

removed from crypt, M1 2 (fig. 13B)
TMM 4 1 106-506 1 , left maxillary fragment with

P3, dP4, P4 removed from crypt, alveoli for

M1 (fig. 13Q
TMM 41 106-5088, right ramus fragment with

dP4, P4 removed from crypt, alveoli for M,,

crypt for M2_3 (fig. 13D)
PM 34469, left maxillary fragment with P4
PM 38918, left ramus fragment with M, or dP4
PM 38926, left M, or dP4
PM 38927, trigonid, left M2 or M3
PM 39005, right maxillary fragment with P4-

M1 (fig. 13E)
PM 39007, right premaxillary fragment with I1

(fig. 13F)
PM 39049, right maxilla with M'-\ alveoli for

dP4, crypt for P4
PM 39050, left maxilla with M'"2
PM 39052, right maxillary fragment with M3-4

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

23

Trench 3, Unit 2, Level 2
TMM 41106-141, left maxilla with unworn dP4,

alveoli for P3 and M1, crypt for P4 (opened

but tooth lost) (fig. 13G)
TMM 41 106-142, left maxillary fragment with

dP4, alveoli for P3, P4 removed from crypt

(in two pieces)
Trench 3, Unit 2, Level 4

PM 38919, left P4
Trench 4, Unit 1 , top 1 ft
TMM 41 106-494, left maxillary fragment with

M1"2, crypt for P4
TMM 4 1 1 06-495, right maxillary fragment with

M1"2
TMM 41 106-5063, edentulous right premaxilla

(fig. 13H)
PM 38884, left premaxilla with I2 (fig. 131)
PM 38894, right P4
PM 38899, left M1
PM 38900, right M3 or M2
PM 38902, left P4
PM 38915, left dP4 or M,
PM 39046, left maxillary fragment with P3
Trench 4, Unit 2, Level 1
TMM 41106-315, left ramus with M3, alveoli

for P4-M2 and M4
TMM 4 1 1 06-3 1 6, right maxillary fragment with

dP4, P4 removed from crypt, alveoli for P3,

M1
PM 38775, right dP4
PM 38940, left P4 or P3
PM 38941, left dP4
PM 38995, left M4

cf. Onychogalea lunata

Trench 3, Unit 2, Level 1

TMM 41 106-5039, right M4 or M3

TMM 41 106-5040, right M3 or M4

TMM 41 106-5047, right M3 or M2

PM 39033, right M4 or M3
Trench 3, Unit 2, Level 4

PM 39016, left M1

PM 39017, left dP4
Trench 4, Unit 1, top 1 ft

TMM 41 106-492, left ramus fragment with M2
or M3

TMM 41 106-493, right M3 or M2

TMM 4 1 106-542, left ramus fragment with M^

TMM 41 106-543, left ramus fragment with MM

TMM 41 106-579, left dP4 or M,

TMM 41 106-581, left M3

TMM 41 106-594, broken right M1

TMM 41 106-625, right dP4

TMM 41 106-627, right M, or M2

TMM 41 106-2833, right M,

TMM 41 106-2834, right dP4

TMM 41106-5069, left upper molar, probably
M1 or M2

TMM 41 106-5072, right upper molar, probably
M2 or M3, possibly M4

TMM 41 106-5075, worn left dP4

TMM 41 106-5076, right M, or dP4

TMM 41 106-5078, right M4

TMM 41 106-5079, left M3 or M4

TMM 41 106-5080, left M3

TMM 41 106-5151, left dP4

PM 38903, left M4
Trench 4, Unit 2, Level 1

PM 38925, right ramus fragment with M2_3

PM 38980, right M2 or M3 or M4

PM 38982, right M,

PM 38984, right M3 or M4

PM 38986, right M1

PM 38987, left M3 or M2

PM 38988, left M3 or M2

PM 38989, left M2 or M3

PM 38991, right M4

PM 38993, left M,
Trench 4, Unit 2, Level 2

PM 38931, right dP4

PM 38932, left M1

Comparative Material

Onychogalea frenata
Warwick, Queensland

ROM 91.11.1.190 (fig. 9C)
New South Wales via National Zoological Park

USNM 122614, male (fig. 9A-B)
National Zoological Park

USNM 219299, male (diseased and abnormal)

Onychogalea unguifera
Derby, Western Australia
USNM 237643 (fig. 10A-B)

Onychogalea lunata

Weeke's Cave (surface), South Australia

PM 38776, subadult (fig. 10C)

PM 38777, subadult (fig. 11Q
Weebubbie Cave (surface), Western Australia

TMM 41 107-334, juvenile

TMM 41 107-335, juvenile
Jenning's Cave (surface), Western Australia

TMM 42121-1, juvenile
Snake Pit Cave (surface), Western Australia

TMM M-937 (fig. 1 1A-B)

Descriptions

Upper Dentition— An I1 and an I2, both in pre-
maxillary fragments, are the only upper incisors

24

FIELDIANA: GEOLOGY

from Madura Cave assigned to Onychogalea. The
I1 (fig. 13F) is curved along its long axis and has
a flattened oval cross section. The occlusal surface
makes an acute angle with the mesial surface of
the tooth. The morphology is like that of modern
O.frenata, but the size is smaller. The I2 (fig. 131)
is almost square in cross section. It too is slightly
smaller than the I2 of modern O. frenata, and is
more deeply worn than the I2 of the modern
Queensland specimen, as a result lacking the pos-
terior lobe seen in that specimen. The occlusal
surface is oriented at an angle of about 45° to the
long axis of the tooth. The morphology of the in-
cisors clearly marks them as Onychogalea. Their
assignment to O. lunata is based on their small
size (Marshall, 1973a) and the presence of other
specimens clearly assignable to that species.

The P3 is a variable tooth (figs. 12C, 13B-C,G).
Most specimens are triangular, with two large
crested cusps on the labial edge separated by a
valley. A third smaller cusp is located lingual to
the main posterior one and is connected to it by
a weak ridge. One specimen (PM 25538; fig. 12C)
has an elongate molariform P3 with four cusps and
incipient transverse lophs. This tooth is narrower
across the anterior loph than across the posterior
loph. None of the P3s has a lingual cingulum.

The dP4 is a molariform tooth that differs from
M ' in its slightly smaller size, more elongate rect-
angular form, and greater development of the par-
astylar crest (figs. 1 2C, 1 3B-C,G). The protoloph
is variably developed. Most specimens, such as
TMM 41 106-5061 (fig. 13C), have a well-defined
protoloph, but one (TMM 4 1 1 06-3 1 6) lacks a pro-
toloph, the protocone and paracone being sepa-
rated by a V-shaped valley. The procingulum is
more asymmetrical than it is in the molars because
of the strong development of the parastylar area.
The midlink is low and extends straight from the
protocone to the center of the metaloph. There is
only a hint of a forelink.

The P4 is smaller than the P3. Its morphology
is variable (figs. 1 2B-C, 1 3B-C,E), but less so than
that of the P3. All available specimens are trian-
gular with three cusps, two large ones on the labial
side of the tooth separated by a deep valley, and
a smaller cusp lingual to the large posterior cusp
and connected to it by a ridge. One specimen (PM
38919) has a small cuspule in the valley between
the two labial cusps, and an incipient lingual cin-
gulum.

The upper molars increase in size posteriorly
(table 7; figs. 12B, 13B,E). The protoloph is nar-
rower than the metaloph in M1, about the same
width in M2, and wider in M3 and M4. The para-
cone and metacone are crested when unworn. The

protoloph and metaloph are strongly bowed an-
teriorly, particularly in unworn teeth. The mid-
links consist of an anterior part that extends from
the protocone to the center of the interloph valley,
and a posterior part that extends from the center
of the metaloph. Small accessory ridges are present
on the midlink at the point where the two halves
meet; these ridges are particularly noticeable on
unworn teeth. There usually are other accessory
ridges in the interloph valleys, those on the lingual
side developed from the base of the tooth between
the protocone and the hypocone. The procingulum
is prominent, and reaches almost all the way across
the front of the tooth. The anterior edge of the
procingulum is joined to the paracone by a ridge.
There is no forelink, but a swelling is present on
the cingulum in the position usually occupied by
the forelink. The postlink isolates a small pit at
the back of each tooth.

Mandible— The mandible of Onychogalea lun-
ata from Madura Cave is similar to that of La-
gorchestes hirsutus, but is slightly smaller and more
delicate (figs. 12A,D, 13A,D). It also is slightly
smaller than the modern comparative mandible
of O.frenata. The horizontal ramus has upper and
lower borders which are parallel in adults, but in
one juvenile (PM 25539; fig. 12D) the horizontal
ramus is deeper under the alveolus for the dP4. In
profile, the tooth row is arched, with the apex of
the arch located at dP4 in PM 25539, at P4-M, in
PM 4785 (fig. 12A), and at M2 in PM 25541. This
change in the position of the teeth with respect to
the apex of the arch, together with the more an-
terior position of the M4 relative to the ascending
ramus in older individuals, indicates the existence
of mesial drift in Onychogalea lunata, as in La-
gorchestes hirsutus. A prominent rugosity is lo-
cated on the side of the jaw below the ventral
margin of the temporal fossa. This is not present
in Lagorchestes or Lagostrophus, but is present in
the modern specimens of Onychogalea frenata. A
mental foramen is located just anterior to P4.

Lower Dentition— Only one of the specimens
(PM 4785; fig. 12A) that can be reliably assigned
to Onychogalea has a lower incisor. The end is
broken, but the small part of the wear surface that
remains is oriented at an angle of about 45° to the
long axis of the tooth. This is similar to the ori-
entation of the wear surface in Lagorchestes (see
the section on that taxon) and different from the
wear surface on the lower incisor of Lagostrophus,
in which it is oriented at a very low angle to the
long axis of the tooth.

No P3 has been recognized from the Madura
Cave material.

Only TMM 41 106-5088 (fig. 13D) has a dP4 in

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

25

26

FIELDIANA: GEOLOGY

Fig. 9. Onychogalea frenata, USNM 122614, from New South Wales (via National Zoological Park): A, skull
shown in dorsal, left lateral, and ventral views; B, left mandible shown in lateral (left), dorsal, and medial views.
Onychogalea frenata, ROM 9 1 . 1 1 . 1 . 1 90, from Warwick, Queensland: C, right maxilla and mandibular dentitions
shown in occlusal views.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

27

Fig. 10. Onychogalea unguifera, USNM 237643, from Derby, Western Australia: A, skull shown in top dorsal,
left lateral, and ventral views; B, right mandible shown in lateral (left), dorsal, and medial views. Onychogalea lunata,
PM 38776, from Weeke's Cave, South Australia: C, partial skull shown in right lateral and ventral views.

28

FIELDIANA: GEOLOGY

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

29

Fig. 1 1 . Onychogalea lunata, TMM M-937, from Snake Pit Cave, Western Australia: A, skull shown in dorsal,
left lateral, and ventral views; B, lower jaws shown in dorsal view, with medial view of left ramus and lateral view
of right ramus. Onychogalea lunata, PM 38777, from Weeke's Cave, South Australia: C, partial skull shown in right
lateral and ventral views.

30

FIELDIANA: GEOLOGY

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

31

* t#

32

FIELDIANA: GEOLOGY

place. This tooth is elongate and molariform, dif-
fering from the molars in being slightly smaller
and relatively narrower across the protolophid.
The protolophid and hypolophid are slightly bowed
posteriorly. The midlink extends in a straight line
from the hypoconid to a point labial to the center
of the protolophid. There are no accessory ridges
in the interloph valley. The procingulum is an ar-
cuate ridge that connects the forelink with a crest
on the anterior side of the metaconid to enclose
an almost circular cingular basin. Two of the iso-
lated teeth have the morphology of dP4s. However,
they are slightly wider across the protolophids than
is the dP4 of the one specimen which has that tooth
in place (TMM 41106-5088), so it is uncertain
whether they are dP4s or M,s with narrower than
normal protolophids.

The P4 apparently is highly variable. Two spec-
imens show its well-developed form— a two-cusped
tooth which is widest posteriorly. The cusps are
in line with the long axis of the tooth. The anterior
cusp is the smaller of the two, and may be either
a simple cone (as in PM 4785; fig. 1 2A) or flattened
from side to side and thus more bladelike (as in
TMM 41 106-183; fig. 13A); in PM 4785, this cusp
has another much smaller cusplet adhering to its
labial side. The posterior cusp has a posterolingual
bladelike crest, and may have other weaker crests
or bulges. In two other specimens (TMM 41 106-
5088, fig. 13D; PM 25539), this tooth is only a
single cusp in a crypt, at a very early develop-
mental stage. Each is a minute cone, about 1 mm
high and less than 1 mm in diameter, and one
shows a small posterior crest. A modern young
adult specimen from the surface of another Nul-
larbor cave, Snake Pit Cave (TMM M-937; fig.
1 1 B), has the tooth fully erupted and shows
that it may sometimes be much smaller and have
a far simpler morphology, consisting of a single
high cusp and a low talonid bulge. The crown of
this tooth is supported by two in-line fused roots.

The lower molars differ from each other only in
minor details (figs. 1 2A,D, 1 3A). The size gradient
is M, < M2 < M3 = M4 (table 8). The protolophids
and hypolophids are slightly bowed posteriorly. In
M, to M3 the widths of both lophs are very nearly
the same, but in M4 the protolophid is noticeably
wider than the hypolophid. The anterior crest of
the hypoconid makes a smooth, slightly sigmoid
sweep, first medially, then anteriorly, to join the
protolophid just labiad to its midpoint. At this
junction the link reaches to midheight on the near-
ly vertical posterior side of the protolophid. The
protolophid contribution to the midlink is very

weak. There tends to be a bulge or cusplet on the
lingual side of the procingulum. This feature is
distinct from the bulge of the edge of the cingulum
itself and varies in its expression. It is commonest
on M3, often found on M4, and rarely present on
the anterior molars.

Discussion

Onychogalea lunata has been recorded as a liv-
ing species from southwestern Western Australia,
inland across southern Australia to the region of
the junction of the Murray and Darling rivers in
western New South Wales or Victoria, and within
the southern part of the Northern Territory. The
Elder Expedition reported it in the Everard Range
of South Australia, and the Horn Expedition col-
lected it at Alice Springs (Shortridge, 1 909; Glauert,
1933; Jones, 1923-1925). Tedford (1967) gives
measures for a juvenile from Rawlinna, on the
Nullarbor Plain in Western Australia. This record
supports the belief of Shortridge (1909) that this
animal was distributed across the Nullarbor Plain
in the recent past. The easternmost record from
the junction of the Murray and Darling rivers is
based on specimens collected by the Blandowski
Expedition (Wakefield, 1 966). In eastern Australia
it is known from Holocene deposits in an archae-
ological site at Fromm's Landing on the lower
Murray River (Wakefield, 1 964), and from Pleis-
tocene deposits at Lake Menindee and Lake Vic-
toria in western New South Wales (Tedford, 1 967;
Marshall, 1 973a). In Western Australia it is known
from undated deposits in Horseshoe Cave (Archer,
1972, 1974). It is present in both Holocene and
Pleistocene deposits in Madura Cave.

Comparison of dental measurements of speci-
mens from different stratigraphic levels in Madura
Cave (tables 7-8), from Lake Menindee (Tedford,
1967, tables 33-34), and from Lake Victoria (ta-
bles 9-10) shows extensive overlap in all cases. To
test for differences between the samples from Unit
2 and Unit 1, Mann- Whitney tests were run on
lengths, anterior widths, and posterior widths of
dP4, P4, M\ dP4, and M,. No significant differences
(P > .05) were found. All samples currently avail-
able are too small to demonstrate any significant
geographic or chronological differences.

Incertae Sedis within the Small Wallabies

Material

Probably Onychogalea lunata

Trench 3, Unit 2, Level ?

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

33

B

b 3

g. a a

i

m^

^K^

\

34

FIELDIANA: GEOLOGY

Table 7. Numerical data on upper dentitions of Onychogalea lunata from Madura Cave.

Unitl

Unit 2

N

OR

Mean

N

OR

Mean

P3

L

2

2.6-2.9

2.75

2

2.7-3.0

2.85

AW

2

1.3-1.4

1.35

2

1.3-1.4

1.35

PW

2

2.0

2.0

2

2.0

2.0

dP4

L

1

3.5

3.5

7

3.7^.3

3.93

AW

1

2.7

2.7

7

2.6-3.1

2.89

PW

1

2.8

2.8

7

2.9-3.5

3.15

P4

L

3

2.7-3.1

2.86

5

2.9-3.3

3.02

AW

3

1.2-1.4

1.31

5

1.2-1.7

1.45

PW

4

1.6-2.3

1.84

5

1.9-2.4

2.05

M'

L

4

3.7-4.2

3.87

4

3.4^t.O

3.76

AW

4

3.2-3.4

3.25

4

3.0-3.2

3.12

PW

4

3.3-3.5

3.38

4

3.1-3.3

3.20

M2

L

3

4.5^.6

4.54

2

4.0-^.5

4.25

AW

3

3.6-3.7

3.62

2

3.4-3.7

3.55

PW

3

3.5-3.6

3.55

2

3.3-3.6

3.45

M3

L

5.1

5.1

1

4.7

4.7

AW

3.8

3.8

1

3.6

3.6

PW

3.5

3.5

1

3.3

3.3

M4

L

5.3

5.3

1

4.8

4.8

AW

3.9

3.9

1

3.6

3.6

PW

3.0e

3.0e

1

2.8

2.8

M'-2

L

8.3

8.3

2

7.8-8.5

8.15

M2"3

L

9.5

9.5

M'-3

L

13.1

13.1

...

...

M'^

L

18.1

18.1

e =

Estimate.

TMM 41 106-55, left M,
TMM 41 106-5041, right M'
PM 39034, left M3 or M2

Trench 4, Unit 1, top 1 ft
TMM 41 106-544, left M2 or M3
TMM 41 106-2835, right M1
TMM 41 106-2836, left M,
TMM 41 106-5073, right M1 or M2
TMM 41 106-5074, right M'orM2
TMM 41 106-5083, right M4 or M3

Trench 4, Unit 2, Level 1
PM 38901, right M3 or M4

PM 38977, left M1 or dP4
PM 38978, right M3 or M2

Trench 5, Unit 6
PM 38885, right M2

Probably Lagorchestes hirsutus

Trench 4, Unit 1, top 1 ft
TMM 41 106-5081, left M2 or M3
PM 38891, right M2

Probably Lagorchestes hirsutus or Onychogalea
lunata

Opposite Page:

Fig. 13. Onychogalea lunata from Madura Cave. A, TMM 41 106-183, right ramus fragment with P4 removed
from crypt, M,_2, M3 in crypt, and alveoli of P3 and dP« shown in dorsal and lateral views. B, TMM 41 106-184,
right maxilla with P3-M2 shown in lateral (left), occlusal, and medial views. C, TMM 41 106-5061, left maxillary
fragment with P3, dP, P* (removed from its crypt), and alveoli of M1 shown in medial (left), crown, and lateral views.
D, TMM 41 106-5088, right ramus fragment with dP4, P„ (only partly formed and removed from its crypt), alveoli
of M,, and crypts for M2_3 shown in lateral (left), dorsal, and medial views. E, PM 39005, right maxillary fragment
with P*-M' shown in lateral (left), crown, and medial views. F, PM 39007, right premaxillary fragment with I1 shown
in lateral (left) and medial views. G, TMM 41 106-141, left maxilla with dP4 and alveoli of P3 and M1 shown in
medial (left), crown, and lateral views. H, TMM 41106-5063, edentulous right premaxilla shown in lateral (left),
ventral, and medial views. I, PM 38884, left premaxilla with I2 shown in lateral (left), ventral, and medial views.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

35

Table 8. Numerical data on lower dentitions of Onychogalea lunata from Madura Cave.

Unitl

Unit 2

N

OR

Mean

N

OR

Mean

dP4

L

1

3.5

3.5

AW

2.2

2.2

1

2.0

2.0

PW

2.4

2.4

1

2.4

2.4

P.

L

2.6

2.6

1

2.7

2.7

AW

1.1

1.1

1

1.0

1.0

PW

1.3

1.3

1

1.6

1.6

M,

L

2

3.7-3.9

3.80

2

3.6-3.7

3.65

AW

2.6

2.6

2

2.2-2.4

2.30

PW

2.8

2.8

3

2.4-2.8

2.57

M2

L

4.2

4.2

1

4.5

4.5

AW

...

1

3.1

3.1

PW

3.1

3.1

2

2.9-3.1

3.00

M3

L

4.9

4.9

1

4.9

4.9

AW

...

...

1

3.2

3.2

PW

3.4

3.4

1

3.2

3.2

M4

L
AW

2

4.8-5.0
3.3

4.90
3.3

PW

2

2.7

2.7

1

2.8

2.8

M,_2

L

7.8

7.8

M2_3

L

9.1

9.1

M,_3

L

12.7

12.7

MM

L

17.2

17.2

Trench 3, Unit 2, Level ?

TMM 41 106-5043, left dP4

TMM 41 106-5046, right M3

TMM 41106-5086, right ramus fragment with
M,_3 or M2^,
Trench 4, Unit 1, top 1 ft

TMM 41 106-5058, right M2 or M3

TMM 41 106-5077, left dP4 or M,

Undetermined

Trench 3, Unit 2, Level ?, probably level 1
TMM 41 106-2838, right P4
TMM 41 106-5029, left I,
TMM 41 106-5030, right I,
TMM 41 106-5031, right I,
TMM 41 106-5032, left I,
TMM 41 106-5033, incisor or canine
TMM 41 106-5034, badly eroded left lower mo-
lar
TMM 41 106-5035, left M, or M2
TMM 41 106-5036, broken right M4
TMM 41 106-5037, broken left M3 or M4
TMM 41 106-5042, broken left M4
TMM 41 106-5048, broken left M3 or M4
TMM 41 106-5050, right M, or M2

TMM 41 106-5051, worn out upper molar

TMM 41 106-5052, right M2 or M3

TMM 41 106-5053, broken right M3 or M4

TMM 41 106-5054, worn out upper molar

TMM 41 106-5055, broken right M3 or M4

TMM 41 106-5056, broken left M2 or M3

PM 38923, right I,

PM 39008, right ramus with alveolus for dP4-
M„ crypts for P4 and M2_3

PM 39009, right ramus fragment with alveolus
for one molar, crypt for one molar

PM 39010, maxillary fragment with two worn
and broken molars

PM 39036, broken right M3 or M4

PM 39037, worn out molar fragment

PM 39042-39044, three right I,s

PM 39045, left I,

PM 39051, left M,

PM 39053, right maxillary fragment with al-
veolus for two molars
Trench 3, Unit 2, Level 2

TMM 41 106-5121, broken left M2 or M3
Trench 3, Unit 2, Level 4

PM 38920, broken and eroded right M, or dP4

PM 39011, worn left I,

PM 39012, right I,

36

FIELDIANA: GEOLOGY

Table 9. Dimensions of upper dentitions of Onychogalea from various sources.

O. lunata

o. mm-
guifera
Derby,

Lake Victoria,

N.S.W.*

Weeke's

Cave, S.A

., and

NMV
P

NMV
P

Snake Pit Cave, w.a.
PM PM

, surface
TMM

W.A.
USNM

O. frenata

USNM

USNM

ROM

28573

28830

38777

38776

M-937

237643

219299

122614

91.11.1.190

P3

L

3.5

3.7

3.5

AW

2.0

2.0

1.8

PW

2.7

2.5

2.8

dP4

L

AW

PW

3.7
2.8
3.0

4.8
3.6
4.0

3.9
3.2

3.5

4.0w

3.7

3.8

P4

L

AW

PW

3.3
1.6
2.1

2.5
1.4
1.8

3.3
1.2
2.1

3.8
2.3

2.8

M1

L

4.0

3.7

3.6

4.3

5.6

4.8

4.5

4.7

AW

3.2

3.1

3.1

3.5

4.3

4.1

3.8

4.1

PW

3.3

3.1

3.2

3.5

4.4

4.2

3.8

4.2

M2

L

4.2

4.3

4.9

5.7

5.3

5.6

AW

3.5

3.6

3.8

4.5

4.2

4.4

PW

3.5

3.4

3.7

3.6

4.5

4.2

4.4

M3

L

5.0

4.9

5.0

5.6

6.7

5.8e

6.4

AW

3.8

3.7

4.0

4.9

4.6

4.8

PW

3.6

3.6

3.4

3.7

4.6

4.3e

M4

L

AW

PW

4.9
3.9

3.4

:::

M'-2

L

7.9

7.7

8.9

10.4

9.9

M2"3

L

9.3

9.1

10.4

12.5

11.9

M'-3

L

12.7

12.4

14.2

16.8

16.3

* Data from Marshall (1973a, table 45). w = Worn; e = estimate.

PM 39015, broken right upper molar
PM 39019, broken left upper molar

Trench 3, Unit 3, Level ?
TMM 41106-37, left ramus fragment with al-
veolus for M2^»

Trench 4, Unit 1, Level ?, probably level 1
TMM 41 106-2837, broken premolar fragment
PM 39137, right upper I1
PM 39142, terminal phalange

Trench 4, Unit 1, Level 1
TMM 41 106-552, broken right lower molar
TMM 41 106-5064, maxillary fragment with al-
veolus for two molars
TMM 41 106-5065, left upper molar
TMM 41106-5066, eroded and broken M, or

dP4
TMM 41 106-5148, broken left I,
PM 38896, broken molar fragment

PM 38908, incompletely formed left I1

PM 39109, anterior half, upper molar
Trench 4, Unit 1 , top 1 ft

TMM 41 106-624, broken lower molar

TMM 41 106-626, broken upper molar

TMM 41 106-5070-5071, two broken right up-
per molars

PM 38897, ramus fragment

PM 38904, worn out M,

PM 38905, worn right I,

PM 38910, broken left M4

PM 38913, right ramus fragment

PM 39132, right upper I

PM 39133, right upper molar
Trench 4, Unit 2, Level 1

PM 7986-7987, right lower I and left M„ re-
spectively

PM 38936, left premaxilla with I2

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

37

Table 10. Dimensions of lower dentitions of Onychogalea from various sources.

O. frenata

O.

lunata

O. un-

New South
Wales (via

Weebubbie Cave,

Jen-

viirt-i'*"

ning's

Snake Pit

guifera

National

National

Cave,

Cave,

Derby,

Zoologi-

Zoological

Warwick,

TMM

TMM

surface

surface

W.A.

cal Park

Park)

Queensland

41107-

41107-

TMM

TMM

USNM

USNM

USNM

ROM

335

334

42141-1

M-937

237643

219299

122614

91.11.1.190

P3

L

2.5

2.4

3.5

3.7

3.5

AW

1.3

1.

3

1

7

2.0

1.8

PW

1.4

1.

4

2

2

2.5

2.8

dP4

L

3.5

3.

5

3.2

4

7

3.9

4.0w

AW

2.1

2.

3

2.0

2

7

3.2

3.7

PW

2.5

2.

4

2.3

3

1

3.5

3.8

P4

L

AW

PW

1.8
1.1

3.8
2.3
2.8

M,

L

3.8

3.

7

3.6

4.1

5

7

4.8

4.5

4.7

AW

2.6

2.

7

2.4

2.6

3

4

4.1

3.8

4.1

PW

2.6

2.

7

2.6

2.9

3

8

4.2

3.8

4.2

M2

L

5.0

5.9

5.3

5.6

AW

3.1

4.5

4.2

4.4

PW

3.3

4.5

4.2

4.4

M3

L

AW

PW

5.5
3.3
3.3

6.7
4.9

4.7

5.8e
4.6

6.4
4.8
4.3e

M4

L

AW

PW

5.2e

3.3

2.6e

M,_2

L

8.9

10.4

9.7

9.9

M2_3

L

10.2

12.5

11.0

11.9

M..3

L

14.0

16.8

15.4

16.3

MM

L

19.2e

w = Worn; e = estimate.

PM 38975, worn out lower molar

PM 38976, right M2 or M3

PM 38981, right M, or M2

PM 38983, broken upper molar

PM 38985, broken lower molar

PM 38990, broken left M2 or M3

PM 38992, broken left M2 or M3

PM 38994, broken right lower molar

PM 391 19-39121, three terminal phalanges

PM 39122-39123, two subterminal phalanges

PM 39146, 39148, two anterior halves, upper

molars
PM 39150, posterior half, left upper molar
PM 39151, posterior half, left lower molar
Trench 4, Unit 2, Level 2
PM 38933, left M2
PM 38934, left M3

PM 38948, right I,

PM 38954, broken left upper molar

PM 39072, anterior half, left upper molar

PM 39077, partial upper incisor
Trench 4, Unit 2, Level 3

TMM 41 106-4A-B, right I,s
Trench 4, Units 4-5

PM 38876, left I,

PM 38877-38878, two maxillary fragments

PM 39080, partial left upper molar

PM 39090, half, molar

PM 39096, anterior half, left lower molar
Trench 4, Unit 7, Level ?

PM 38928, right ramus fragment with alveolus
for M2_3, crypt for M4

PM 38929, right ramus fragment with alveolus
for M,_3, crypt for M4

38

FIELDIANA: GEOLOGY

Trench 4, Unit 7, Level 2

PM 38882, left maxillary fragment with broken
P4, alveolus for M1

PM 38930, broken left M'
Trench 5, Unit 5

PM 38887, left I2 or I3
Trench 5, Unit 5 or 6(?)

PM 39126, molar fragment
Trench 5, Unit 6

TMM 41 106-641, broken left lower molar

PM 38886A-B, two upper incisors

PM 39125, left I1

Protemnodon Owen, 1873 (nomen nudum), 1874
Protemnodon sp. near P. brehus (Owen) and P.
roechus Owen

Material

Trench 2, 2Vi ft

PM 53920, ventral side, left I,
Trench 4, Unit 2, Level 1

PM 39063, left ramus with broken P4, M,_3,
roots of M4 (fig. 14 A)
Trench 4, Unit 2, Level 2

PM 39089, posterior one-third, left P4 (fig. 14B)
TMM 41 106-2832, anterior half, left upper M3
or M4 (fig- 14C)

Comparative Material

Protemnodon anak
Wellington Caves, New South Wales
PM 1553, left ramus with broken I, P4-M4 (fig.
14D)

cf. Protemnodon brehus

Wellington Caves, New South Wales

PM 1 534, left ramus with I, dP4, P4 in crypt (fig.

15 A)
PM 1541, right ramus with P3, dP4, and P4 and

M3 in crypts (fig. 1 5B)
PM 1543, right ramus with dP4-M,, broken P4

in crypt (fig. 1 5C)
PM 1544, left ramus with M,_3 (fig. 15D)
PM 1551, right ramus with P3, dP4, P4 in crypt
PM 1557, left ramus with P3, dP4-M2
PM 1560, right mandible with P4 exposed in

crypt, M,_3, M4 in crypt (fig. 15E)

cf. Protemnodon roechus
Wellington Caves, New South Wales
PM 1570, right maxilla with P3, dP»-M2, P4 in
crypt (fig. 15F)

PM 1583-1584, left maxilla in two fragments
with P3, dP»-M2, P4 and M3 in crypt (fig.
15G)

PM 39064, right P3 (fig. 15H)

PM 39066, right P4

Descriptions

The horizontal ramus (fig. 14A) is moderately
shallow and thick (depth at M,-M2 = 34.2 mm,
thickness = 16.35 mm; depth at M2-M3 = 33.2
mm, thickness ■ 17.9 mm). From P4 to M3, it
shows little change in depth, but thickens appre-
ciably. The base of the symphysis rises at a low
angle from the plane of the ventral edge of the
horizontal ramus. Only the posterior part of the
symphysis is preserved, so its shape and length
cannot be determined. The shape of the preserved
portion suggests that it was shallow, but it is deeper
than that of a specimen of Protemnodon anak from
Wellington (PM 1553; fig. 14D). The symphysis
is rugose, but not ankylosed. The geniohyal pit is
shallow and located at the posterior end of the
symphysis. The mental foramen is located about
1 1 mm anterior to P4 and about 4 mm below the
dorsal edge of the diastema. The lateral groove is
shallow and is located 7 mm below the edge of the
alveolus; it extends from the premolar at least to
the posterior root of M2.

The posterior part of the P4 is broken away. The
outline of this tooth is an elongate oval. The labial
surface bears an irregular wear facet for most of
its length, which covers from one-third (in rear)
to one-half (in front) of the crown below the crest
of the occlusal surface. The anterior part of this
wear surface has a broad groove across it, setting
off a triangular ridge. The anterior part of the un-
worn lingual surface is gently convex.

The lower molars are rectangular in occlusal view
with a slight constriction at the interloph valley,
which is mostly confined to the labial side of the
teeth. The relative sizes of the molars are: M, <
M2 < M3. The protolophid is slightly narrower
than the hypolophid in M, and about equal to it
in M2 and M3 (table 1 1). The lophids are weakly
convex posteriorly when unworn but are straight
when worn. Forelinks are moderately well devel-
oped, extending from the protoconid anterolin-
gually and then anteriorly to join the procingulum
just labiad the center line of the tooth. The pro-
cingulum is prominent but narrow. It descends
labially from its junction with the forelink to the

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

39

Fig. 14. Protemnodon sp. from Madura Cave: A, PM 39063, left ramus with P4-M3 shown in lateral (left), occlusal,
and medial views; B, PM 39089, partial left P4 shown in labial (left), crown, and posterior views; C, TMM 41 106-
2832, anterior half of left M3 or M4 shown in crown view. Protemnodon anak from Wellington Caves, New South
Wales: D, PM 1553, left ramus with I (broken)-M4 shown in lateral (left), dorsal, and medial views.

40

FIELDIANA: GEOLOGY

base of the protoconid, forming an anterolabial
pit. The anterolingual area of the procingulum is
nearly flat. The midlink descends anterolingually
from the hypoconid and then turns anteriorly to
join the protolophid near its base at the midline
of the tooth. The labial side of the interloph valley
slopes away from the midlink more steeply than
does the lingual side. Low, indistinct lingual ridges
descend from the metaconid and entoconid to-
ward the interloph valley. The postcingulum is
very small or absent. There is no bulge at the base
of the crown.

The P4 is represented by the posterior third of
the crown and most of the posterior root (fig. 14B).
The outer blade is missing, but the posterior basin
formed by the posterior cingulum, the posterolin-
gual cusp, and the rear of the labial crest is well
preserved, as is the posterior part of the lingual
trough. The ridgelike posterolingual cusp is joined
to the main crest and to the lingual crest. There is
a vertical groove on the lingual surface where it
joins the lingual crest. The Madura Cave specimen
is similar in size and morphology to a specimen
from Lake Menindee figured by Tedford (1967,
fig. 25C), which he referred to Protemnodon bre-
hus.

Because of its large size (width across protoloph
= 15.1 mm), the anterior half of the upper molar
(TMM 41 106-2832) probably is an M3 or M4. Its
anterior width falls within the limits of the ranges
of M2, M3, and M4 of Bartholomai's (1973) Darling
Downs, Queensland, sample of Protemnodon roe-
chus, and just within the range of M3 of his
Queensland sample of P. brehus, and of M4 of his
Bingara, New South Wales sample. It also falls
within the range of M3 of Marshall's (1973a) Lake
Victoria, New South Wales, sample. There is no
forelink, and the stout procingulum has a low angle
of inclination. The protoloph is bowed anteriorly
in its middle. There is a delicate but distinct pro-
toconal spur. A similarly developed labial crest
and spur extend from the posterolabial edge of the
paracone. Both of these spurs lead into the inter-
loph valley. The tooth is slightly larger than that
recorded by Stirton (1963, pp. 152-153) for the
type and most of the other specimens of P. brehus,
as well as any of the specimens of other species
measured by him.

Discussion

Six species of Protemnodon were named by Owen
(1874, 1877) on the basis of material from Pleis-

tocene deposits in Australia: P. anak, P. og, P.
minutus, P. brehus, P. antaeus, and P. roechus.
Stirton's review of the genus (1963) made a start
at determining the relationships of these species
by unraveling several taxonomic problems, but
presented no definitive discussion of the validity
of each species. Bartholomai's review of the genus
(1973) synonymized P. og into P. anak, P. mimas
into P. brehus, and P. antaeus into P. roechus, and
split off P. chinchillaensis and P. devisi, both Plio-
cene in age, from P. anak.

The characters which have been used to differ-
entiate these species show considerable intrasam-
ple variability, the extent of which has been poorly
understood until recently. This has made specific
identification of Protemnodon specimens difficult,
especially in the case of isolated specimens. Bar-
tholomai (1973) analyzed large samples of Pro-
temnodon from Queensland, which provided some
information on intraspecific variation for material
from that area. Marcus (1976) has done the same
for material from Bingara.

We have doubts about the usefulness of the
qualitative characters suggested by Bartholomai
( 1 973) as distinguishing Protemnodon brehus from
P. roechus. The tuberculation on the lingual side
of the interloph valley of the upper molars is vari-
able in the two comparative specimens from Wel-
lington Cave. Furthermore, one of Bartholomai's
figures (1973, pi. 1 3) shows a specimen of P. brehus
(which is supposed to lack this feature) to have a
weakly developed tuberculation on M1 and M3.
The degree of labial concavity of the labial crest
of P4 in P. roechus, as shown in Bartholomai's
figures (1973, fig. 7, nos. 5-8), appears to be vari-
able. The extent of the expansion of the bases of
the lower molars also is variable. In view of these
doubts and of the extensive overlap in the size
ranges of virtually all metric characters (see Bar-
tholomai, 1973, tables 6, 1 0, fig. 9), we have doubts,
as did Flower (1884), Lydekker (1887), and Mar-
shall (1973a), that the two species are distinct.
Nonetheless, since we lack the comparative ma-
terial to investigate this question, we will consider
these to be two separate species in the following
discussion.

The width of the protoloph of the upper molar
fragment from Madura Cave exceeds the upper
limit of the observed range for all upper molars
of Protemnodon anak given by Bartholomai (1973),
but is within the observed range for M3 and M4
of P. brehus and M2^* of P. roechus (table 12). No
qualitative character, such as the tuberculation seen
by Bartholomai (1973) on the labial side of the

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

41

Fig. 15. Protemnodon sp. from Wellington Caves, New South Wales, for comparison. Protemnodon brehus: A,
PM 1534, left ramus with I, dP4, and P4 in crypt shown in lateral (left), dorsal, and medial views; B, PM 1541, right
ramus with P3 and dP4 shown in lingual (left), crown, and labial views; C, PM 1543, right ramus with posterior roots
of P3, broken P4, and dP4-M, shown in medial (left), dorsal, lateral, and anterior views; D, PM 1544, left ramus with

42

FIELDIANA: GEOLOGY

H

M|_, shown in lateral and crown views; E, PM 1560, right mandible with P4-M4 shown in dorsal and lateral views.
Protemnodon roechus: F, PM 1570, right maxilla with P3-M2 shown in lateral and ventral views, and P4 exposed in
crypt shown in lateral, ventral, and lingual views; G, PM 1583-1584, adjoining maxillary fragments with P3-M3
shown in crown view; H, PM 39064, right P3 shown in labial (left), crown, and lingual views.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

43

Table 1 1 . Numerical data on mandibles and lower dentitions of Protemnodon from Lake Victoria, Wellington
Caves, and Madura Cave.

Protemnodon cf. brehus

Protemnodon brehus
Lake Victoria*

N

OR

Mean

Ma-
dura
Cave
PM

39063

Wellington Caves

N

OR

Mean

Protem-
nodon
anak
Welling-
ton
Caves
PM
1553

p3

L

AW

PW

dP4

L

AW

PW

P4

L

AW

PW

M,

L

AW

PW

M2

L

AW

PW

M,

L

AW

PW

M4

L

AW

PW

Mandible

below M|_2
Mandible

below M2_3

Depth
Depth

Mandible
at M,_2

Mandible
at M2.3

Thickness
Thickness

12.2

10.0

9.7

15.0-15.2

11.6-12.3

17.4-18.0
12.8-13.9
12.7-13.6

18.8-19.5
13.1

11.6-12.7

12.2

10.0

9.7

15.07

11.95

17.68
13.43
13.10

19.10

13.1

12.15

16.4
6.3

11.9
8.9
9.3

13.0
10.4
10.5

16.2
11.9

12.0

34.2
33.2

16.3
17.9

11.7-12.3
5.5-6.5
6.3-6.9

10.3-12.5
5.9-7.5

7.1-8.7

17.5

12.1-13.9
8.7-10.2
8.9-9.9

15.8-16.7

11.1-11.5

11.2

18.1-19.9
12.6-12.7
12.4-12.9

12.05
5.90
6.60

11.55
6.85
8.04

17.5

13.20
9.45
9.55

16.23
11.30
11.2

19.00
12.65
12.65

32.0-32.2 32.10

30.9-31.2 31.05

13.7-14.4 14.05

15.4-16.2 15.80

17.4
5.1

7.3

10.9
6.5
7.6

12.7

10.0

9.3

15.4

17.0

11.1

9.7

32.3
32.8

10.9
11.3

* Data from Marshall (1973a, table 61).

interloph valley in P. roechus is preserved. It is
not clear whether this molar and the ramus rep-
resent the same species. However, since they are
similar in size and lack features which might sug-
gest a difference, the most parsimonious assump-
tion is that they do represent the same taxon.

The ramus from Madura Cave differs from oth-
ers assigned to Protemnodon anak in a number of
characters which have been cited as diagnostic by
Bartholomai (1973) and Marcus (1976). The angle
between the base of the symphysis and the ventral
margin of the horizontal ramus rises at a steeper
angle (10°-20°), and the symphysis is deeper. The
geniohyal pit is prominent just behind the sym-

physis. The horizontal ramus is deeper and thick-
er, as is the ramus of our comparative specimen
from Wellington Cave (PM 1553; table 11, fig.
1 6 A), but matches the dimensions given by Bar-
tholomai for P. brehus and P. roechus and by Mar-
cus for P. brehus.

The dental dimensions of the Madura Cave
specimen are larger than those given for Protem-
nodon anak, but within the ranges given for P.
brehus and P. roechus by Bartholomai (1973),
Marshall (1973a), and Marcus (1976) (tables 1 1-
1 2, fig. 1 6). A comparison of the Madura Cave
specimen with the qualitative dental characters
given by Bartholomai is less easily made. The an-

44

FIELDIANA: GEOLOGY

tenor cingular areas of the lower molars of the
Madura Cave specimen are not as wide relative
to the widths of the lophids as is shown in Bar-
tholomai's figures of P. brehus, but are wider than
is shown for P. anak. The Madura Cave specimens
also differ from P. anak and are similar to P. brehus
and P. roechus in most other characters, but be-
cause of the doubts mentioned above it is difficult
to be certain to which of these two species they
belong. All measurements which could be taken
on the Madura Cave specimens fall within the
broad area of overlap of the size ranges of these
two species (table 1 1 , fig. 1 6). The qualitative char-
acter that suggests the most unequivocal assign-
ment is the degree of expansion of the base of the
crown in the lower molars. In P. roechus the base
of the crown is expanded (Bartholomai, 1973); in
P. brehus and the Madura Cave specimens the base
of the crown is not expanded.

Protemnodon has been reported from other lo-
calities on the Nullarbor Plain. Glauert (1912) re-
ported P. anak from Balladonia, but Merrilees
(1968a) subsequently referred this material to
Sthenurus. Protemnodon cf. brehus has been re-
ported by Milham and Thompson ( 1 976) from the
south passage of Madura Cave, but they did not
figure the material or give the basis for their as-
signment; P. brehus has also been reported from
the Mammoth Cave deposits in southwestern
Australia (Tedford, 1967).

Petrogale Gray, 1837
Petrogale Species Indeterminate

Material

Trench 3, Unit 2

PM 39006, left I1 in a fragment of the premaxilla
(fig. 17 A)
Trench ? (probably 4), Unit 1, top 1 ft

PM 39130, left I1 (fig. 17B)
Trench 4, Unit 2, Level 2

PM 39068, left M4 (fig. 17C)

Comparative Material

Petrogale brachyotis

Kimberly District, Western Australia

FM 119823 (fig. 17F)

FM 120577

Petrogale cf. lateralis

Northwest Cape, Western Australia (Late Pleis-
tocene or Holocene)
PM 26694

PM 26701
PM 36718
Wedge's Cave, Mimegara (north of Perth), West-
em Australia (Late Pleistocene or Holocene)
PM 5749 (fig. 17D)
PM5771
PM 5772
PM 5773

Petrogale inornata
Rockhampton-Atherton area, Queensland

FM 64360

FM 64430 (fig. 17G)

Petrogale venustula

Oenpelli, East Alligator River, Northern Territory

USNM 284068

Petrogale pearsoni

Oenpelli, East Alligator River, Northern Territory
RCS London A.348.51 (fig. 17E)

Descriptions

The left M4 (PM 39068; fig. 1 7C) compares well
with that of a Holocene specimen of Petrogale
from Wedge's Cave, Western Australia (PM 5749;
fig. 17D) in most morphological characters, al-
though it is slightly smaller. The protoloph and
metaloph are convex anteriorly, while the proto-
loph is noticeably longer than the metaloph. Both
lophs contribute to the midlink. A cleft divides
the midlink in the median valley. Ridges from the
paracone and metacone almost meet on the labial
side of the median valley to form a median basin.
The procingulum occupies the entire anterior bor-
der of the tooth. It is connected to the paracone
by a prominent ridge, but is not connected to the
metacone, leaving the procingular basin open on
the lingual side. The postcingulum is connected to
the hypocone by a ridge, forming a posterior cin-
gular basin. According to Merrilees (1979), this is
characteristic of M2^*; this agrees with our obser-
vations on recent specimens of Petrogale from
Queensland, Western Australia, and the Northern
Territory. This character distinguishes the M2~* of
Petrogale from those of macropodids such as Mac-
ropus irma and M. eugenii that have dentitions
similar to those of Petrogale. The Madura Cave
specimen differs from the Wedge's Cave specimen
principally in its small size and in the form of the
procingulum, which does not slope lingually to-
ward the base of the tooth.

The dimensions of PM 39068 are: length 7.50
mm, anterior width 5.00 mm, and posterior width

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

45

Table 1 2. Numerical data on upper teeth of Protemnodon from Wellington Caves, Lake Victoria, and Bingara,
New South Wales, and Queensland in comparison with the broken tooth of Protemnodon sp. from Madura Cave.

Protem-

nodon sp.

P. roechus

Madura
Cave,
W.A.

P. brehus

Wellington Caves, N.S.W.*

PM PM PM

1570 1583-84 39066 Mean

Darling Downs, Qld.f
N OR Mean

TMM
41 m*-

Bingara, N.S.W4

2832 N OR

Mean

P4

L

22.4

20.4

21.40

7

18.3-20.7

19.4

AW

10.3

10.4

10.35

7

9.2-10.4

9.7

PW

11.3

10.5

10.90

M1

L

13.5

13.7

13.60

4

12.9-14.0

13.4

AW

11.9

12.1

12.00

9

12.2-13.9

12.8

PW

12.0

12.2

12.10

M2

L

15.2

15.5

15.35

12

15.7-17.7

16.7

4

15.4-16.6

16.00

AW

13.5

12.9

13.20

10

13.7-15.4

14.6

15.1 4

13.3-13.9

13.60

PW

13.0

12.7

12.85

M3

L

18

17.2-19.9

18.6

1

16.7

16.70

AW

(13.6)

12

14.9-16.2

15.6

15.1

PW

M4

L

13

17.7-20.0

19.0

2

18.7

18.70

AW

11

14.7-16.5

15.7

15.1 2

14.4-15.2

14.80

PW

2

* FMNH specimens not previously reported, f Data from Bartholomai (1973, table 10). % Data from Bartholomai
(1973, table 6). § Data from Marshall (1973a, table 61).

4.35 mm. A comparison of these dimensions with
those given by Merrilees (1979) for a series of
Pleistocene, Holocene, and modern samples of Pe-
trogale from southwestern Western Australia shows
that the length of the Madura Cave specimen is
within the observed range but the widths, espe-
cially the posterior width, are below the observed
ranges.

The I's (PM 39006, 39130; fig. 17A-B) are
strongly curved, with a wear surface developed on
the lingual face. There is a shallow groove near the
posterior edge of the labial surface of PM 39006,
which produces a notch on the cutting edge of the
tooth; no trace of this groove can be found on the
other specimen. A vertical buttress is present on
the posterior part of the lingual surface of the tooth.
None of the Madura Cave specimens shows a dis-
crete cuspule arising from this lobe, as reported
by Merrilees (1979) for some specimens from
southwestern Western Australia.

Discussion

The taxonomy of this genus is confused. Tate
( 1 948) recognizes three species with eight subspe-

cies. Marlow (1962) shows distributions of seven
species divided into 17 subspecies, while Ride
(1970) recognizes six species. Calaby (1971) has
suggested that this is the result of the highly frag-
mented distribution of the genus today, which has
caused a large amount of local variation. The Ma-
dura Cave material is inadequate for a specific
assignment.

Rock wallabies of the genus Petrogale inhabit
cliffs, rock piles, and rocky outcrops in most parts
of Australia (Calaby, 1971). The genus has not
been reported from the Nullarbor Plain. The only
parts of this area that appear to provide suitable
habitat are the scarp that separates the Roe Plain
from the Hampton Tableland, and possibly some
of the karst features such as the larger dolines.

Macropus Shaw, 1790

The taxonomy of the genus Macropus has long
been a problem. There is no general agreement on
the boundaries of the genus, although most stu-
dents now place the red kangaroo in a separate
genus, Megaleia (Sharman, 1961; Calaby, 1966;
Frith & Calaby, 1969; Bartholomai, 1975). More

46

FIELDIANA: GEOLOGY

Table 12. Extended.

P. brehus

Queensland Sample^

Lake Victoria§

N

OR

Mean

N

OR

Mean

9
10

18.1-19.8
9.3-10.6

19.2
10.0

6
4

12.7-14.6
12.0-12.7

13.6
12.3

1
1
1

14.4
12.2
12.6

14.4
12.2
12.6

14
6

14.8-17.0
13.4-14.6

16.3

14.0

1

1
1

16.4
14.8
14.8

16.4
14.8
14.8

18
15

16.2-18.1
13.7-15.1

17.5
14.5

2
2
1

18.2-18.4

15.0-15.2

15.2

18.30
15.10
15.2

12
11

17.3-19.1
13.7-15.0

18.2
14.3

2
2

17.7-17.8
14.6-14.7

17.75
14.65

recently, Peacock et al. (1981) have suggested that
there is little justification for this separation be-
yond the chromosome number difference. Even
with Megaleia removed, the genus is particularly
troublesome for the paleontologist because so many
species have been named on the basis of minor
dental characters whose significance is unknown.
Although it has now become possible to separate
many of the large-sized species of Macropus and
to separate Macropus from Megaleia on the basis
of dental characters which are usable on paleon-
tological materials (Tedford, 1967; Frith & Cala-
by, 1969; Bartholomai, 1975; Marcus, 1976),
problems remain.

It has been shown by Kirsch and Poole (1967,
1972) on the basis of serological studies and by
Peacock et al. (1981) on the basis of DNA se-
quence studies that the living gray kangaroos are
in fact two species, Macropus giganteus and M.
fuliginosus. Macropus giganteus is distributed over
the eastern part of Queensland, much of New South
Wales and Victoria, and northern Tasmania, while
M. fuliginosus is found in western Victoria, south-
western New South Wales, and the southern parts
of South Australia and Western Australia (Shep-
herd, 1982). The two species overlap without in-
terbreeding in western Victoria and southwestern

New South Wales (Shepherd, 1982). In spite of
rigorous attempts by Poole et al. (1980) to do so,
no dental or skeletal criteria are known that will
consistently separate these two species. A third
fossil species, M. titan, which is morphologically
similar to the living species, has been recognized
on the basis of significantly larger size (Owen, 1 874;
Marshall, 1973a; Marshall & Corruccini, 1978).

The deposits in Madura Cave have produced
remains that are referable to Macropus titan and
M. fuliginosus. All material that can be confidently
assigned to M. titan on the basis of both mor-
phology and size comes from Units 2-7, which
have radiocarbon dates ranging from 15,600 ±
250 to 37,800 ± 3520 b.p. (Lundelius & Turnbull,
1973). All material that can be assigned to M.
fuliginosus is from the present surface of the cave
or from Unit 1. This unit, which is 2 ft (~ 60 cm)
thick, has an eroded top surface. The top 1 ft (30
cm) of the unit has been radiocarbon-dated at 7470
± 120 b.p. (Lundelius & Turnbull, 1973). Thus,
all of the confidently referred M. titan material is
of Pleistocene age and the M. fuliginosus material
is of modern or Holocene age. The tentatively as-
signed specimens of these taxa seem to follow this
same pattern, but those which lack definitive fea-
tures or are of intermediate size have been as-
signed to Macropus sp.

This stratigraphic and chronological distribu-
tion of these two species in the Madura Cave de-
posits is consistent with their chronological dis-
tribution in other parts of Australia as reviewed
by Marshall (1973a).

The close morphological resemblance of M. gi-
ganteus-M. fuliginosus to M. titan has been noted
by many investigators (Owen, 1874; Lydekker,
1887; Tedford, 1967; Marshall, 1973a; Marshall
& Corruccini, 1 978) and has been cited by the last
two authors as an example of dwarfing in a single
lineage at the end of the Pleistocene. The discovery
that M. fuliginosus and M. giganteus are separate
species raises questions about the details of the
relationship of these three taxa. Furthermore,
Marshall (1973a) points out that M. titan as it is
currently recognized also may have been hetero-
geneous.

Regardless of the exact phylogenetic relation-
ship between M. titan and M. fuliginosus, the re-
cord at Madura Cave shows that a larger Macropus
was replaced by a smaller one with similar mor-
phology after 16,000 b.p., about the same time as
in other parts of Australia and at the same time
as the disappearance of the extinct mammals and
the disharmonious assemblages.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

47

aa

1 1

MANDIBLE

i

T 1

T

J—

©

•

i

co 34

■

CM

2

©

O

z

PM 1560

X

•

< 33

-

<N

x M/2-3

^»

PM 1553

M/1-2

2

»-

XM/1-2

PM 1544

< 32

X

-

X

M/2-3

©

Q.

LU

Q

PM 1544

31

i i

©

»

©

X

X

1

PM 1560

•

'

10

11

12

13 14 15 16 17

WIDTH BENEATH M/1-2 AND M/2-3

18

35

■ 34

■ 33

32

• 31

19

11

10 -

9

X

g

cc 8
O

DC

LU

I-

z

< 7

PM 1560

X PM 1544
© x

**

P. roechus^-

P. brehus

>*

-i 111

10

P. anak

PM 1553

Key to symbols

x PM # = FM specimens from Wellington Caves
~if= Madura Cave Specimens

Bingara Specimens
© = P. brehus -Marcus
• = P. brehus -Bartholomai
□ = P. roechus -Bartholomai

1 — f— i Darling Downs Specimens

. ©

PM 1543

PM1557

M/1

10

11

12 13

LENGTH

14

15

48

FIELDIANA: GEOLOGY

Id

1 1

-i 1 1 1

M/2

12

0 0

I ,

©

P. brehus

11

PM 1560
P. roechus

Ox 0

PM 1544

0

* 0 •

10

PM 1553

9

P. anak

_i

_i 1_ i .

12

13

14

15 16

LENGTH

17

18

13

- 12

10

19

13 ■

cr
O
cr

10

M/3

14

e *

P. anak

P. brehus
PM1560

T 0

. 0

P. roechus

PM 1553

15

16

19

20

-13

PM 1544

-12

■10

21

17 18

LENGTH

Fig. 1 6. Bivariate graphs showing the Madura Cave specimens of Protemnodon (stars) in comparison with certain

Wellington Caves specimens and with samples of P. brehus and P. roechus from the literature. Upper left, mandibular

proportions at M,_2 and M2_3; lower left, length x anterior width of M,; upper right, length x anterior width of M2;

lower right, length x anterior width of M3.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

49

B

D

Fig. 1 7. Petrogale sp. from Madura Cave compared with various modern species of the genus. Petrogale sp. from
Madura Cave: A, PM 39006, left I1 in premaxillary fragment shown in lingual (left) and labial views; B, PM 39130,
left I1 shown in lingual (left) and labial views; C, PM 39068, left M4 shown in lingual (left), crown, and labial views.
Petrogale sp. from Wedge's Cave, Mimegara, Western Australia: D, PM 5749, right maxilla shown in ventral view.
Petrogale pearsoni from Oenpelli, East Alligator River, Northern Territory: E, RCS A.348.51, right side of palate
shown in ventral view. Petrogale brachyotis from Kimberly District, Western Australia: F, FM 1 19823, right side of
palate shown in ventral view. Petrogale inornata from Rockhampton-Atherton area, Queensland: G, FM 64430, right
side of palate shown in ventral view.

50

FIELDIANA: GEOLOGY

Table 13. Numerical data on upper dentitions of a
Recent sample of Macropus giganteus from New South
Wales.

Table 14. Numerical data on lower dentitions of a
Recent sample of Macropus giganteus from New South
Wales.

N

OR

Mean

N

OR

Mean

P3

L

2

6.4-6.8

6.60

P,

L

2

5.6-6.0

5.8

AW

2

3.2-3.3

3.25

AW

2

2.6

2.6

PW

2

4.5-4.6

4.55

PW

2

3.4-3.6

3.5

dP

L

2

7.9-8.0

7.95

dP4

L

2

7.8-8.3

8.05

AW

2

6.1-6.5

6.30

AW

2

4.4-5.2

4.80

PW

2

6.5-6.9

6.70

PW

2

5.3-5.8

5.55

M1

L

5

6.9-10.2

9.02

M,

L

4

7.8-9.7

9.04

AW

5

7.2-8.6

7.88

AW

4

5.6-6.1

5.98

PW

5

7.5-8.7

8.14

PW

4

6.1-7.4

6.80

M2

L

4

9.9-11.2

10.63

M2

L

5

10.0-11.7

10.86

AW

4

8.5-9.5

8.93

AW

5

6.4-8.0

7.20

PW

4

8.2-9.5

8.90

PW

5

6.5-8.1

7.24

M3

L

3

12.0-13.0

12.47

M,

L

3

11.5-12.7

12.20

AW

3

9.4-10.2

9.77

AW

3

8.2-8.6

8.43

PW

3

8.8-10.0

9.33

PW

3

7.6-8.4

8.03

M4

L

3

12.8-14.1

13.30

M4

L

3

12.8-13.4

13.07

AW

3

9.9-10.8

10.23

AW

3

8.3-9.2

8.67

PW

3

8.9-10.3

9.47

PW

3

7.7-8.6

8.03

Diastema

L

5

53.0-63.5

58.38

Diastema

L

5

43.6-51.0

46.66

M1^

L

3

42.2^»6.2

43.53

MM

L

3

36.2-43.0

40.13

Macropus fuliginosus Shaw and Nodder, 1790,
part; (Desmarest, 1817) part

Material

Surface
TMM 41106-23-24, pair of rami (same indi-
vidual) with left and right I,, P3-dP4, M, in
crypt (fig. 19D)
Trench 2, Unit 1, top 1 ft

PM 6246, right ramus with I, P4-M3, M4 in crypt
(fig. 19C)
Trench 4, Surface and Unit 1, top 6 inches
TMM 41 106-510, right maxilla with M1^ (fig.

19 A)
TMM 41 106-547, posterior one-third, left dP
Trench 4, Unit 1 , top 1 ft (presumably level 2)
PM 39128, left upper molar (fig. 19B)
PM 39134, right upper molar
TMM 41106-501, distal half, right metatarsal
V(fig. 19F)

Macropus sp. (Probably Macropus fuliginosus)

Trench 1, Unit 1, top 1 ft

TMM 41 106-499, right I2 or I1
Trench 4, Surface and Unit 1 , top 6 inches

TMM 41 106-551, tooth fragment

PM 7983, terminal phalanx from one of the
syndactylous toes

PM 7984, terminal phalanx from manus
PM 391 10, anterior half, left dP4 or M,
PM 391 13, anterior half, lower molar or dP4
Trench 4, Unit 1 , top 1 ft (presumably level 2)
TMM 41 106-500, left metacarpal II (fig. 19E)
TMM 41 106-502, first phalanx, manus
TMM 41 106-503, terminal phalanx, pes
TMM 41 106-504, terminal phalanx, pes
PM 39129, left P
PM 39138, right I3
PM 39143, terminal phalanx, manus

Comparative Material

Macropus sp. (Probably Macropus fuliginosus)

Murraelellevan Cave (surface red clay), Western
Australia
PM 24334, left ramus with M,^,, alveolus of P4
Hasting's Cave (surface), Western Australia
PM 50847, skull and mandible with P in crypt,
erupted P\ dP4, M1 in crypt; I„ P3, dP4,
erupting M,

Macropus fuliginosus

Jurien Bay, Western Australia

TMM M-925
West coast north of Perth, Western Australia

TMMM-927(fig. 211)

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

51

10

12 14

-+-

** 8

^— H 15

12 i

Sh 2

P/3 Length

P/4 Length

16

T

18

Key to symbols

M = Madura Cave Specimens

• = M. fuliginosus

© = M. titan
T Q = Macropus titan from Queensland
T LV = M. titan from Lake Victoria
T C = M. titan from Camperdown
GV = M giganteus from Victoria
G NSW = M. giganteus from New South Wales
F Kl = M. fuliginosus fuliginosus from Kangaroo Isl.
FM = M fuliginosus melanops
F NSW = M. fuliginosus from New South Wales

Numbers indicate sample size, bar graphs show
range and mean. Scale is shown top and bottom.

6 8 10 12 14 16 18

Fig. 18. Graphs showing Madura Cave specimens (M) of Macropus sp. in comparison with comparable teeth of
M. titan (T), M. giganteus (G), and M. fuliginosus (F) from various localities. Left, comparison of lower teeth; right,
comparison of upper teeth.

Descriptions

Upper Molars— The lophs of the upper molars
(fig. 1 9 A-B) are convex anteriorly when unworn,
straight when worn. The anterior cingulum ex-
tends across the full width of the tooth, and is tied

by a low ridge to the base of the paracone. Lin-
gually, it extends upward to join the protocone
close to its base. A low, straight forelink connects
the anterior cingulum to the protoloph and divides
the cingular basin. In the unworn state, the mid-
link is lower than the lophs. Both lophs contribute

52

FIELDIANA: GEOLOGY

10

M

TQ
TLV
TC
GV

GNSW
FKI
F.M.
FNSW

M

TQ

TLV

TC

GV

GNSW

FKI

F.M.

FNSW

M

TQ

TLV

TC

GV

GNSW

FKI

F.M.

FNSW

M

TQ

TLV

TC

GV

GNSW

FKI

F.M.

FNSW

M

TQ

TLV

TC

GV

GNSW

FKI

F.M.

FNSW

M

TQ

TLV

TC

GV

GNSW

FKI

F.M.

FNSW

M

TQ

TLV

TC

GV

GNSW

FKI

F.M.

FNSW

12 14 16 18

Key to symbols

M = Madura Cave Specimens

• = M. tuliginosus

© = M. titan
T Q = Macropus titan from Queensland
T LV = M. titan from Lake Victoria
T C = M. titan from Camperdown
GV = M. giganteus from Victoria
G NSW = M. giganteus from New South Wales
F Kl = M. tuliginosus tuliginosus from Kangaroo Isl.
FM = M. tuliginosus melanops
F NSW = M. tuliginosus from New South Wales

Numbers indicate sample size, bar graphs show
range and mean. Scale is shown top and bottom.

M1/ Length

sr

^i

■MO

M2/ Length

-M7

H4
—•28

^13

■•5

-M1

10

12

14

16

18

to the midlink, with their junction point being
marked by a cleft. A labially directed spur extends
from the metaloph portion at this point. The ac-
cessory cuspule on the anterolabial side of the mid-
link reported by Stirton (1963, p. 121) and Mar-
shall (1973a) in Macropus titan is incipient in this
specimen. The posterior cingulum is formed by a

prominent ridge on the posterior face of the hy-
pocone and a much smaller ridge on the base of
the posterior face of the metacone.

Comparison with the upper molars of modern
Megaleia rufa shows that the Madura Cave spec-
imen differs in having a well-developed forelink
and a procingulum which is tied to the paracone.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

53

54

FIELDIANA: GEOLOGY

J

Fig. 19. Macropus fuliginosus from Madura Cave. A, TMM 41 106-510, right maxilla with M1-4 shown in lateral
(left), ventral, and medial views. B, PM 39128, left upper molar shown in crown view. C, PM 6246, right jaw ramus
with I, P4-M3, and M4 in its crypt shown in lateral (left), dorsal, and medial views. D, TMM 41 106-24, right jaw
ramus with I, P,-dP4, and M, in crypt shown in lateral (left), dorsal, and medial views. E, TMM 41 106-500, left
metacarpal II, a tentatively referred specimen, shown in left dorsal and ventral views. F, TMM 41 106-501, distal
half of right metatarsal V shown in left ventromedial, lateral, and dorsal views.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

55

Table 15. Measurements of upper and lower den-
titions of Macropus fuliginosus from Madura Cave.

TMM TMM

41106- 41106-

PM

PM

510

547

39128

39134

dP4

L

AW

PW

5.3

M1

L

AW

PW

10.6
8.5b
8.8b

M2

L

AW

PW

11.9
9.6
9.5

M3

L

AW

PW

13.6
10.5
10.1

M4

L
AW

12.7
9.7

PW

8.2b

Molar

L

10.1

>9.8

AW

7.6

7.8

PW

7.8

PM

TMM

TMM

6246

41106-23

41106-24

P3

L

6.7

6.7

6.6

AW

3.1

3.1

3.1

PW

4.4

3.8

3.7

dP4

L

9.3

8.0

7.9

AW

5.5

4.9

4.5

PW

6.7

5.6

5.3

M,

L

10.8

AW

6.8

PW

7.4

M2

L

AW

PW

11.5
7.5
6.9?

M3

L
AW

14.2

PW

b =

broken.

In both of these characters it is similar to modern
Macropus fuliginosus. The posterior cingular pit
is somewhat larger than is seen in specimens of
M. fuliginosus available for comparison.

Lower Dentition— The P3 (fig. 19D) is elon-
gate with three main cusps and an anterior cuspule.
The anterior cusp is laterally compressed, with a
low vertical ridge on each side and a sharper ridge
connecting its apex with an anterior cuspule and
the posterior labial cusp. The two posterior cusps
are joined to form a transverse loph.

The dP4 (fig. 19D) is molariform. The proto-

lophid is distinctly narrower than the hypolophid.
The midlink is like that of the molars, but the
forelink is incomplete even though the procingul-
um is large. A shallow vertical groove is present
on the posterior face of the hypolophid, as in the
molars.

The P4 of PM 6246 (fig. 19C) is similar to the
P3 in morphology. It is triangular with the large
anterior cusp joined to an anterior cuspule by a
ridge. It differs from the P3 in that the posterior
ridge of the anterior cusp bifurcates, joining both
the posterior cusps to form a posterior basin. The
two posterior cusps join to form a posterior lophid.
A small ridge extends anteriorly from the middle
of the posterior transverse lophid into the poste-
rior basin.

The lower molars are bilophodont and brachy-
hypsodont. The protolophid and hypolophid are
slightly concave anteriorly when unworn and
straight when worn. The procingulum projects for-
ward and upward, and where it is joined by the
forelink it is almost as high as the protolophid in
an unworn tooth.

The forelink arises from the protoconid and turns
sharply linguad and then anteriad to join the pro-
cingulum. The large midlink is made up of con-
tributions from the protolophid and hypolophid.
Their junction is marked by a cleft and some over-
lap in an unworn tooth. The lophids are parallel,
in contrast to Megaleia rufa in which the ento-
conid is located posterior to the hypoconid and
the protolophid and hypolophid are not parallel.
A vertical groove is present on the posterior face
of the hypolophid.

Postcranial Skeleton— The distal one-third
of one right fifth metatarsal (TMM 4 1 1 06-50 1 ; fig.
19F) is present. The distal part of the shaft is
strongly curved laterally. The distal articular sur-
face is asymmetrical with the lateral border pro-
jecting outward and backward. A median ridge is
present ventrally on the posterior part of the ar-
ticular surface. The transverse diameter of the dis-
tal end is 13.0 mm, which is within the size range
of two modern specimens of M. fuliginosus (TMM
M-927, 13.9 mm; TMM M-925, 12.9 mm). The
corresponding measurements of two modern spec-
imens of Megaleia rufa from Western Australia
are 8.7 mm (TMM M-939) and 7.6 mm (TMM
M-928). In addition, the distal articular surface in
M. rufa lacks the median ridge.

A terminal phalanx of digit IV of the pes (TMM
41 106-504) is tentatively referred to M. fuligino-
sus. It has the high triangular shape of the artic-

56

FIELDIANA: GEOLOGY

Table 16. Numerical data on upper dentitions of a
Recent sample of Macropus fuliginosus from New South
Wales.

Table 1 7. Numerical data on lower dentitions of a
Recent sample of Macropus fuliginosus from New South
Wales.

N

OR

Mean

N

OR

Mean

P3

L

15

5.6-7.2

6.42

P,

L

15

5.5-6.8

6.05

AW

15

3.5-4.2

3.87

AW

15

2.6-3.3

2.95

PW

15

4.7-5.7

5.08

PW

15

3.3-4.3

3.87

dP4

L

18

7.1-9.0

8.16

dP<

L

18

7.1-9.0

8.22

AW

18

6.2-7.2

6.59

AW

18

4.6-5.5

4.91

PW

18

6.6-7.7

6.94

PW

18

5.4-6.3

5.70

P4

L

10

6.5-8.3

7.23

P<

L

10

5.2-6.7

6.06

AW

10

2.8-4.9

3.26

AW

10

2.1-3.6

2.67

PW

10

3.4-5.0

4.25

PW

10

2.6-3.9

3.26

M'

L

31

8.5-11.0

9.68

M,

L

29

8.4-10.8

9.73

AW

31

7.2-9.0

7.86

AW

30

5.4-7.6

6.20

PW

31

7.3-9.7

8.18

PW

28

5.6-7.3

6.46

M2

L

30

7.8-12.3

10.87

M2

L

31

9.5-13.1

11.20

AW

31

7.4-10.4

8.75

AW

32

6.8-8.4

7.38

PW

27

8.0-10.6

8.95

PW

28

6.2-8.2

7.21

M3

L

18

11.5-13.5

12.32

M3

L

17

10.2-13.1

12.08

AW

19

7.4-11.1

9.42

AW

17

7.5-9.1

8.13

PW

18

8.4-10.8

9.48

PW

17

7.0-8.7

7.70

M4

L

12

12.5-13.6

12.98

M4

L

11

8.2-14.5

12.22

AW

13

7.7-11.4

9.61

AW

11

7.4-9.7

8.21

PW

10

8.6-10.9

9.39

PW

9

7.0-8.5

7.56

Diastema

L

31

51.0-68.3

57.20

Diastema

L

36

31.6-53.9

44.81

M'^

L

13

34.3-51.5

42.15

MM

L

6

32.^46.5

40.27

ulation facet and the short, broad protruding ven-
tral base typical of macropodids. It is slightly
smaller than modern specimens of M. fuliginosus
and Megaleia rufa (table 1 8).

Discussion

All of the Macropus material that can be con-
fidently assigned to M. fuliginosus comes from Unit
1 or from the present surface of the deposits, and
thus is either modern or Holocene in age. M. fu-
liginosus is a member of the modern fauna of this
region and apparently has been present throughout
most of the Holocene.

Macropus titan Owen, 1838

Material

Trench 2, Unit 2, Level 2% ft

PM 6247, right ramus with posterior half, M3,
M4 (fig. 20A)
Trench 3, Unit 2, Level ?

TMM 41 106-5057, labial side, left P3

Trench 3, Unit 2, Level 4

PM 39021, right dP4
Trench 4, Unit 2, Level 1

PM 38974, dP4
Trench 4, Unit 2, Level 2

PM 7993, right maxillary fragment with M1-3
(fig. 20B)

PM 39070, left dP4

PM 39071, left P3
Trench 4, Units 4-5

PM 7994, right P4

PM 7995, left M4

PM 7998, left ramus with dP4-M3, P4 in crypt
(fig. 20E)

PM 39000, left ramus with M4 (fig. 20D)
Trench 4, Unit 7, Level 4

PM 7992, right maxillary fragment with P3, an-
terior half of dP4 (fig. 20C)

Macropus sp. (Probably Macropus titan)

Trench 2, Unit 2, Level 2% ft

PM 26 1 64, tip, lower incisor

PM 39102, phalanx
Trench 3, Unit 2, Level ? (probably 1) and
Level 1

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

57

Table 1 8. Measurements of metatarsals and terminal phalanges of digits IV and V of the pes <

af Recent and fossil

Macropus.

Meta-

Terminal

Terminal

Metatarsal 4

tarsal

phalanx,

phalanx,

5

D4, articular

D5, articular

Ant.-post.
diam. distal

Proximal

Distal

facet

Distal

facet

end

Length

width

width

width

Width

Height

Width Height

Macropus fuliginosus

TMM M-925

23.7

171.7

28.7

23.7

TMM M-927

20.2

166.8

27.2

23.9

16.3

16.7

TMM 41 106-501

12.9

TMM 41 106-503

9.2 6.2

TMM 41 106-504

12.0

10.8

Macropus titan

PM 39002 A

>17.8

173.0

>27.2

>19.7

PM 39002 B

17.9

25.9

23.0

M. (Megaleia) rufa

FM 98914

19.0

165.0

29.0

23.6

13.8

13.3

FM 44274

19.7

158.0

27.5

25.0

8.7

14.7

14.2

TMM M-928

16.5

160.0

24.6

21.2

7.6

14.0

12.7

5.9 6.2

TMM M-939

8.6

12.7

13.3

Macropus robustus

FM 104674

15.5

125.0

22.7

20.7

FM 104813

22.8

FM 119818

15.7

112.0

21.3

20.0

10.7

FM 120574

16.5

134.3

24.5

22.1

11.1

TMM 41 106-105

25.6

TMM 41106-103, proximal end, left humerus
(fig. 2 ID)

PM 39060, left upper molar, probably M4

PM 39061, left upper molar, probably M4

PM 39062, right I2 or I1

PM 39067, left I1

PM 39083, left upper molar

PM 39084, anterior one-third, lower molar

PM 39085, molar fragment

PM 39086, metaloph, right molar

PM 39149, anterior half, left dP4 or M,
Trench 3, Unit 2, Level 4

TMM 41 106-144, left upper incisor

TMM 41 106-146, thoracic vertebrae, about T-
6-9

TMM 41 106-147, second phalanx, digit IV, pes
Trench 3, Unit 3, Level ? (probably 1)

TMM 41 106-45, tip, left lower incisor
Trench 4, Unit 2, Level 1

PM 7982, fragment, upper incisor

PM 7985, anterior half, right lower molar

PM 7988, terminal phalanx, digit III, manus

PM 7989, terminal phalanx

PM 39124, second phalanx, digit V, pes

PM 39145, molar fragment

Trench 4, Unit 2, Level 2

PM 39055, left P

PM 39056, right I1

PM 39073, broken left upper molar

PM 39074, broken left lower molar

PM 39075, broken molar

PM 39076, molar fragment

PM 39088, terminal phalanx, manus (or pos-
sibly of pes of a smaller form)
Trench 4, Unit 2, Level 3

PM 39093, anterior one-fourth, right lower mo-
lar
Trench 4, Units 4-5

PM 39001, portion of midshaft, right tibia

PM 39002A-B, two right fourth metatarsals (fig.
21A-C)

PM 39092, anterior half, left lower molar

PM 39097, posterior half, right lower molar

Descriptions

Upper Dentition— The P3 is a triangular tooth
with the labial blade interrupted by a shallow notch
(fig. 20C). A posterior lingual cusp is joined to the

58

FIELDIANA: GEOLOGY

)

w

H>

Fig. 20. Macropus titan from Madura Cave. A, PM 6247, right ramus fragment with part of M3 and M4 shown
in lateral (left), dorsal, and medial views; B, PM 7993, right maxillary fragment with M'-3 shown in lateral (left),
ventral, and medial views; C, PM 7992, right maxillary fragment with P3 and part of dP1 shown in ventral view; D,
PM 39000, left ramus with M4 shown in dorsal and lateral views; E, PM 7998, left ramus with dP„-M3 and P4 in
crypt shown in dorsal and medial views.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

59

Table 19. Measurements of upper dentitions of Macropus titan from Madura Cave.

TMM

41106- PM PM
5057 7994 7992

PM

38974

PM

39021

PM
39060

PM

39061

PM
7993

PM

39083

P1

L

AW

PW

'

1.1

7.3
3.5
4.9

dP4

L

AW

PW

. . i

>.5

8.0
4.1
5.4

9.6
>6.1

7.1

:::

P

L

AW

PW

9
3

5

.7
.9
.4

...

...

M1

L

AW

PW

11.2

M2

L

AW

PW

12.9
11.6
11.8

M3

L

AW

PW

12.7
9.5
9.6

14.7
11.8
11.6

M4

L

AW

PW

>11.1
>9.0
>7.9

Molar

L

AW

PW

14.7
9.6
8.9

posterolabial cusp just anterior to its apex by a
transverse ridge, and at its posterior end by a low
ridge to form a small posterior basin. A small an-
terior lingual cingular cusp is present, but is not
joined to the posterior one.

The dP4 is a molariform tooth with a prominent
procingulum that is connected to the paracone by
a sharp ridge. Marshall (1973a) states that this
feature, which is not present in the molars, is typ-
ical of the dP4 of Macropus titan of the Lake Vic-
toria sample. The small interloph cuspule on the
lingual side of the tooth observed by Marshall
( 1 973a) in a Lake Victoria specimen is not present
on the Madura Cave specimens.

The upper molars (fig. 20B) are virtually iden-
tical to those of Macropus fuliginosus. The lophs
are high and convex anteriorly when unworn, with
sides that are straight but converge toward the
crown. The procingulum extends across the com-
plete breadth of the tooth. It is joined to the pro-
toloph by the forelink, which is located slightly
lingual to the midline of the tooth, but it is sep-
arated from the paracone and protocone by clefts.
The midlink is large, with its major part from the
protocone and a smaller contribution from the

middle part of the metaloph. The midlink does
not bow labially, and there are no accessory cus-
pules associated with the midlink or the postero-
labial face of the protoloph, both of which were
reported by Marshall (1973a) for some specimens
of M. titan from Lake Victoria, the Camperdown
district of Victoria, and the Darling Downs of
Queensland. The bases of the protocone and hy-
pocone of PM 7993 have small cuspules in the
lingual side of the median valley. The postcingu-
lum is large and is formed primarily by a ridge
from the hypocone. It is joined to the base of the
metacone to form a posterior basin. There is no
vertical groove on its posterior face.

Lower Dentition— The P4 is a compressed
bladelike tooth with two major cusps and a lower
posterolingual cusp joined to the main posterior
cusp by a ridge (fig. 20E). This agrees with the
description of M. titan given by Marshall (1973a).

The lower molars are bilophodont, brachyhyp-
sodont teeth (fig. 20A,E). The lophids are slightly
concave anteriorly when unworn and straight when
worn. The procingulum projects forward and up-
ward from the base of the tooth. The forelink arises
from the protocone, turns sharply linguad, and

60

FIELDIANA: GEOLOGY

Table 19. Extended.

PM

39084

PM

39086

PM

39092

PM

39097

PM

39071

then turns anteriad to join the procingulum. In an
unworn tooth, the central part of the procingulum
where it joins the forelink is as high as the pro-
tolophid.

The protolophid and hypolophid contribute to
the large midlink, and their junction is marked by
a cleft. The protolophid and hypolophid are par-
allel, in contrast to Megaleia rufa, in which the
entoconid is located posterior to the hypoconid
and the hypolophid and protolophid are not par-
allel. A vertical groove is located on the posterior
surface of the hypolophid.

A cuspule is present in the lingual side of the
valley in PM 7998 (fig. 20E), as is reported for
Macropus titan by Marshall (1973a). In PM 6247
(fig. 20A) and PM 39000 (fig. 20D), the median
valley and the lingual part of the procingular valley
contain cement.

Postcranial Skeleton— The proximal part of
a left humerus (TMM 41 106-103; fig. 2 IB) from
Madura Cave is the same size as the comparable
portion of the humeri of modern Macropus fuli-
ginosus (TMM M-925, M-927) and Megaleia rufa
(98914, TMM M-928). The morphology differs
only in the shape of the head; the articular surface

of the head of the Madura Cave specimen is oval
with an extension toward the greater tuberosity,
while the articular surfaces of the modern speci-
mens are almost circular.

The fourth metatarsal is represented by a com-
plete specimen (PM 39002 A; fig. 21 A) and the
proximal half and distal articular surface of another
(PM 39002B; fig. 21B-C); both are from the left
foot. PM 39002A lacks the posterior part of the
proximal articular surface. The anterior part of the
articular surface is smoothly concave. The prox-
imal articular surface of PM 39002B is also smooth,
but is more deeply concave medially. Both spec-
imens have a prominent ridge on the medial side
of the anterior surface of the shaft that extends
from 2 cm below the proximal end to the middle
of the shaft. This feature is present in two modern
specimens of Macropus fuliginosus (TMM M-925,
M-927; fig. 211) but not on our specimens of Me-
galeia rufa (98914, TMM M-928, M-939; fig. 2 1 J),
and is small or absent on specimens of modern
Macropus robustus (FM 1 04674, 1 048 1 3, 1 1 98 1 8
[fig. 2 IK], 120574).

Both of the Madura Cave metatarsals lack the
prominent rugose bulge on the proximal part of
the posterior face that is seen in Megaleia rufa.
Macropus fuliginosus also lacks this bulge. The
condition in Macropus robustus is intermediate.
The Madura Cave specimens are essentially the
same size as modern specimens of Macropus fu-
liginosus (including those from Western Australia)
and Megaleia rufa, and are 25% larger than mod-
ern specimens of Macropus robustus (table 18).

Discussion

All previous studies of Pleistocene Macropus
have concluded that Macropus titan is morpho-
logically indistinguishable from M. giganteus and
M. fuliginosus and differs from them only in its
25°/o-30% larger size (Owen, 1874;Lydekker, 1887;
Tedford, 1967; Marshall, 1973a; Marcus, 1976;
Bartholomai, 1975; Marshall ACorruccini, 1978).
All of the Macropus material from Unit 1 , which
is Holocene in age, can be assigned to M. fuligi-
nosus on the basis of both size and morphology.
The Macropus material from Units 2-7, which is
of Pleistocene age, presents a somewhat confused
picture. With the exception of a dP4 (PM 7998),
all the lower teeth of Macropus from the lower
units whose position in the jaw can be determined
fall within the size range of samples of M. titan
from Lake Victoria, the Eastern Darling Downs,

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

61

Table 20. Measurements of lower dentitions of Macropus titan from Madura Cave.

PM

7998

PM PM

39070 6247

PM
7995

PM

39092

PM

39084

PM

39074

PM

7985

PM

39075

PM PM

39093 39097

dP4

L

AW

PW

9.5 1

>5.8

7.4

5.3

5.7

P4

L

AW

PW

6.9

2.3
3.7

M,

L

AW

PW

>10.0

M2

L

AW

PW

14.0
9.0
8.6

M3

L

AW

PW

16.2

M4

L

AW

PW

16.9

9.7
9.5

18.4

10.5

9.2

Molar

L

AW

PW

>1

>9

9.4

and the Camperdown area of Victoria reported by
Marshall (1973a). The dP4 is slightly below the
size range reported by Marshall (1973a), but is
larger than the dP4s of several samples of M. gi-
ganteus and M. fuliginosus from various parts of
Australia (fig. 1 8 A). The other dental dimensions
are closer to those of M. titan than to those of M.
giganteus and M. fuliginosus. With the exception
of four P3s (TMM 41 106-5057; PM 38974, 39071,
7992) and an M1 (PM 50847), those upper teeth
from Units 2-7 whose positions in the jaw can be
determined fall within, but usually at the lower
ends of, the observed size ranges of samples of M.
titan from Lake Victoria, the Eastern Darling
Downs, and the Camperdown area of Victoria re-
ported by Marshall (1973a) and Bartholomai
(1975) (fig. 18B). The P3s are shorter than those
of M. titan and fall in the upper part of the range
of several samples of M. giganteus and M. fuli-
ginosus (fig. 1 8B). The postcranial material from
Units 2-7 is the same size as that of modern spec-
imens of M. fuliginosus.

Marshall (1973a) pointed out that the size of
Macropus titan increases from Queensland to Vic-
toria parallel to the size change in M. giganteus
and M. fuliginosus. This suggested the possibility
of a Bergmann cline, but Marshall believed the
data to be inadequate to demonstrate this. The

somewhat small size of some of the Madura Cave
specimens might cause one to speculate about a
possible east-west cline for these taxa across the
Nullarbor Plain, which would not be a Bergmann
response. Such speculation is premature in any
case, for there is inadequate data from the Madura
Cave M. titan and M. fuliginosus samples to show
any size trends. In addition, the M. titan sample
from Units 2-7 in Madura Cave spans a significant
period of time and cannot be treated as a single
coherent sample; it is also of inadequate size to
show change through time.

Macropus robustus Gould, 1840

Material

Trench 3, Unit 2, Level ? (probably 1)
PM 39058, left P (fig. 21H, right)
PM 39057, left I2 (fig. 21H, left)
TMM 41106-105, proximal left metatarsal IV
(fig. 2 IE)
Trench 4, Units 4-5
PM 799 1 , proximal one-fourth, right ulna, lack-
ing epiphysis of olecranon process and rim
of articular facets (fig. 2 1 F)

62

FIELDIANA: GEOLOGY

Comparative Material

Discussion

Macropus robustus cervinus
Cape Range, Western Australia

FM 104670

FM 104671

FM 104674

FM 104676

FM 104687

FM 104690

FM 104692

FM 104694

FM 104701

Macropus robustus
National Zoological Park
FM 104813

Macropus robustus antilopinus
Kimberly District, Western Australia

FM 119818 (fig. 21G,K)

FM 120574

Descriptions

Upper DENTmoN-The left I3 (PM 39058; fig.
2 1H) is a long tooth with one groove separating a
stout, narrow, anterior lobe from a posteriorly flar-
ing but thinner posterior lobe. This morphology
is similar to that of Macropus robustus and Me-
galeia rufa, but in the latter the tooth is much
smaller. The P of Macropus fuliginosus differs from
that of the Madura Cave specimen in having two
grooves rather than only one.

The I2 (fig. 21H) resembles that of modern M.
robustus both in size and in having no groove on
its outer face.

Postcranial Skeleton— The fourth metatarsal
fragment (fig. 2 1 D) appears to be referable to Mac-
ropus robustus on the basis of size (table 1 8) and
morphology. Seen from the front, the articular sur-
face is smoothly concave and the concavity is shal-
low as in modern M. robustus.

The ulna (fig. 2 1 F) is slightly smaller and more
delicate than any of our modern comparative spec-
imens (fig. 2 1 G). The frayed edges of the articu-
lation facets make detailed comparison difficult.
The olecranon process is small but robust, and the
facet for articulation with the radius is very small.
The specimen is in the same general size range as
the modern specimens of M. robustus, and the
olecranon process is about 25% shorter than that
of the ulna of Macropus fuliginosus (fig. 21G) and
Megaleia rufa.

Macropus robustus is widely distributed in Aus-
tralia where suitable habitats in the form of rocky
outcrops occur (Frith & Calaby, 1969). The flat
topography of the Nullarbor Plain does not appear
to provide suitable habitats for M. robustus. How-
ever, the scarp that separates the Hampton Ta-
bleland from the Roe Plain may have provided
small areas of rocky outcrops suitable for M. ro-
bustus, as well as for Petrogale.

Incertae Sedis among the Large Macropodids

Specimens which we cannot identify with cer-
tainty, but which probably are referable to one or
another of the large macropods are included.

Trench 3, Unit 2, Level 1
TMM 41106-109-111, one subterminal phal-
ange and two terminal phalanges, probably
from the manus of a large species of Mac-
ropus
TMM 41 106-186, root and labial side, I1 or P,

from a large species of Macropus
PM 39 1 56-39 157, two terminal phalanges, pos-
sibly from the manus of a Macropus species
(had been associated with TMM 41106-
103-111)
Trench 3, Unit 3, Level ?, probably 1

PM 39082, terminal phalange
Trench 4, Unit 1 , Level 1

PM 39108, molar tooth fragment from between

lophs
PM 39131, macropodid right I1 or I2
PM 39140, macropodid partial right I2 or I3
Trench 4, Unit 2, Level 1
TMM 41106-300-303, four macropodine toe

bones
PM 7990, partial vertebra, either a posterior
thoracic or anterior lumbar, consisting of
centrum and neural arch
Trench 4, Unit 2, Level 2

PM 39069, right M4, similar to that of Thylogale

and Macropus irma
PM 39087, terminal phalange
Trench 4, Unit 2, Level 3

PM 7996, distal seven-eighths, large second
phalange, digit IV, pes, probably from a
large species of Macropus
Trench 4, Unit 2, Level 4

PM 38999, proximal epiphysis, tibia, may be
from a large Protemnodon or Macropus, or
possibly a small diprotodont
Trench 4, Units 4-5

PM 39098, partial right upper molar

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

63

64

FIELDIANA: GEOLOGY

Assessment of the Marsupial Segment
of the Fauna

Fossil remains of marsupials from Madura Cave
provide a good picture of Australian marsupial
faunas during the late Pleistocene and the early
Holocene, and the faunal changes that took place
through that span of time.

The late Pleistocene fauna shows a higher taxo-
nomic diversity than either that of the early Ho-
locene or the modern historic fauna of the Nul-
larbor Plain. This diversity is characteristic of
Pleistocene faunas in most parts of the world. A
total of 37 Pleistocene and 24 early Holocene and
modern historic taxa is recorded from the Nul-
larbor Plain (table 21). Of the 37 Pleistocene taxa,
all but one (Megaleia rufa) were recovered from
Madura Cave. It is more difficult to determine how
many species were living on the Nullarbor Plain
in historic times because of inadequate surveys of
the mammalian fauna prior to the habitat changes
brought about by domestic and other introduced
animals. Brooker (1 977) observed only four species
of marsupials during his work in this area, but
listed 10 species known to have occurred there
prior to 1 940. Examination of distribution maps
by Shortridge (1909) and Marlow (1962) suggests
that there may have been as many as 1 5 species
of marsupials on the Nullarbor Plain prior to the
beginning of European influence. The change in
diversity between the Pleistocene and historic times
is the result not only of extinction of some species
(4 completely extinct plus 2 extinct on the main-
land), but also of the extirpation of about 1 6 extant
species.

In addition to the increased diversity, the Pleis-
tocene marsupial assemblage from Madura Cave
contains a number of species that today are allo-
patric and seemingly ecologically incompatible.
These types of associations, first recognized by
Hibbard (1960), and termed "disharmonious" by
Semken (1974), are characteristic of late Pleisto-

cene faunas wherever they have been adequately
studied. The presence of these disharmonious as-
sociations in Australian Pleistocene faunas has been
summarized by Lundelius (1983). Seventy-three
pairs of species that are now allopatric were found
in Units 2-7 of Madura Cave. Examples of such
pairs of formerly sympatric, but now allopatric,
species are: Phascolarctos cinereus and Dasycercus
cristicauda, P. c. and Dasyuroides byrnei, P. c. and
Caloprymnus campestris; Antechinus flavipes and
Dasycercus cristicauda, A. f. and Dasyuroides byr-
nei. Forty pairs of presently allopatric species were
found in Unit 1. It should be pointed out that a
substantial number of the disharmonious pairs in-
volve Sarcophilus harrisi and Thylacinus cyno-
cephalus, whose absence from the historical fauna
of the mainland may have more to do with the
introduction of the dingo than with the general
post-Pleistocene climatic change (Archer, 1974).
If the disharmonious pairs involving these two
taxa are subtracted the numbers fall to 33 for the
older units and 22 for Unit 1 .

There is a major change in the marsupial fauna
from Unit 2 (dated at 15,600 b.p. at its top) to
Unit 1 (dated at 7470 b.p. at its top, but separated
from Unit 2 by an erosion surface). Milham and
Thompson (1976) give dates of present to ~7000
b.p. for the same unit in the South Tunnel. The
faunal changes include the disappearance of most
of the extinct taxa, including Sthenurus, Protem-
nodon, Macropus titan, possibly Thylacoleo, and
the two extant taxa Antechinus flavipes and Phas-
colarctos cinereus.

Milham and Thompson (1976) have reported
the presence of Protemnodon sp., Sthenurus sp.,
and Phascolarctos sp. from the upper unit in the
South Tunnel. The results of nitrogen and fluorine
analyses on dentine of Protemnodon teeth from
this unit reported by them suggest that the material
of this taxon and probably that of Sthenurus and
Phascolarctos is derived from an older deposit. If
this is so, the radiocarbon dates of 3450 to 7880

Opposite Page:

Fig. 21. Various specimens of Macropus, some from Madura Cave, some from the modern species from other
localities: cf. Macropus titan from Madura Cave: A, PM 39002A, right metatarsal IV shown in proximal and
dorsal (anterior) views; B, PM 39002B, proximal half of right metatarsal IV shown in proximal view; C, PM 39002B,
distal end of right metatarsal IV shown in ventral (posterior) view (fragments in B and C are associated parts of the
same bone); D, TMM 41 106-103, proximal end of left humerus shown in proximal view. Macropus robustus from
Madura Cave: E, TMM 41 106-105, portion of metatarsal IV shown in proximal and dorsal (anterior) views; F, PM
7991, proximal end of right ulna lacking olecranon epiphysis shown in medial (left), anterior (dorsal), and lateral
views; H, PM 39057, left I2 shown in labial view and PM 39058, left P shown in labial view. Macropus robustus
antilopinus from Kimberly District, Western Australia: G, FM 1 198 18, right ulna shown in medial and lateral views;
K, FM 119818, left metatarsal IV shown in anterior view. Modern Macropus fuliginosus: I, TMM M-927, right
metatarsal IV shown in anterior view. Modern M. (Megaleia) rufa: J, TMM M-939, right metatarsal IV shown in
anterior view.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

65

SI

2 3

15

^g

<S 8>

1 A 03

all
5 ** «i

as *■ r o,

a -C *h 6 M

«> e «- _. ™

■p B *a s

o. -.
E «
2©

li

*a

e L-

- _ u

— *

o 2
PQ

X X X X X

X x xXX X

xX X

XX X

XXXXX Xx|XX XXx

XxxX x : : x xXX

XXxXxj::xXX:Xx

XXxX XxxxX XXXX x

XXx

XxxXx xx;xxXXxX ::::: xXXX

+ +

+ +

»

+ • +

+ +•&•*»+ o- o- + +

+ +

+ +

-Si •t°

a <o ~

a o .£

-S £ a

*» Si

I 3

fe

o oj ^ X *X

-Si w1 ^
a S «

11 %

3-i

she

till

<3

a 3 -3 ?
-. ^= 5 o -Si

-Si
2 a

Ms -a

si a a

P 3
5

tf£^

a -c -a y o
b c*. ^> S ^j
§ ?-S £.3

£ ,« F ^

2 <5

a t-
S « §■■£
a <a s >-
3 5 a S

Q 5 -c' w> -«:' & ^ -s; >2

3 Q

•5 a

•2 %

■si

s £ v-

& a 3
§ a 5

3 a ^

3 ^ 5o-3

ft, 0 oq eq

2 a

c

a

R

FIELDIANA: GEOLOGY

1

c

a ^ S s ^>

a
E
o
■a

H

fl § *•

6 ._ o
•c 2

ii:

o •

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

67

b.p. from these deposits do not apply to these taxa.
Thylacoleo is present in Unit 1 . If this specimen
was in primary context, then it is the youngest
known specimen of this taxon. However, as dis-
cussed in Part III (Lundelius & Turnbull, 1978, p.
91), the matrix adhering to the specimen suggests
that it may have been eroded from older deposits
near the front of the cave and redeposited farther
in.

Two other groups of taxa that no longer occur
on the Nullarbor Plain are found in Unit 1 . One
group includes Parantechinus apicalis, Sminthop-
sis murina, Phascogale calura, Phascogale tapoa-
tafa, and Potorous platyops, which are found today
in association with Antechinus flavipes and Phas-
colarctos cinereus in areas of eastern and/or south-
western Australia with climates that are more hu-
mid than the present-day climate in the region of
Madura Cave. The other group, which consists of
Dasyuroides byrnei, Myrmecobius fasciatus, and
Caloprymnus campestris, is found today in areas
approximately as arid as that of Madura Cave.
The presence of the first group of taxa indicates a
climate more humid than the present one. This
agrees with information from other parts of Aus-
tralia. Although the general pattern of climatic
change through this period is a shift to drier con-
ditions, the details are not clear. The association
in the Pleistocene and early Holocene faunas of
members of these two groups of species with seem-
ingly disparate environmental requirements forms
the disharmonious associations mentioned above.
Disharmonious faunas in North America have been
interpreted as indicating more equable climates
during the Pleistocene (Hibbard, 1 960). The same
probably is true for Australia (Lundelius, 1983).
The lower number of disharmonious associations
in Unit 1 (~40 vs. ~ 73 in the older units) indicates
a change to less equable conditions after approx-
imately 15,000 b.p.

Planigale sp. indet. also disappears at the end
of the Pleistocene sequence in Madura Cave. How-
ever, we cannot categorize this species as readily
as the groups discussed above, for too little is known
about its habitat requirements to permit a gener-
alization about its environmental implications.
Archer (1976) lists two other occurrences of Plan-
igale sp. indet. The closest to Madura Cave is a
modern specimen from the eastern edge of the
Nullarbor Plain, in much the same sort of arid
environment. The other occurrence is from the
Hammersly Range in the Pilbara, but habitat data
are not given. Planigale maculata appears to be
limited to wetter climates (Taylor et al., 1982).

Andrews and Settle (1982) report that P. gilesi is
restricted to riverine floodplains and overflows.
Denny (1982) states that most planigales are found
close to water, but that P. tenuirostris can be found
in drier habitats. Read (1982) speculated that the
drifting home ranges of P. tenuirostris are an ad-
aptation to an arid environment.

There are few changes in morphology or size in
those taxa that persist into the Holocene or Recent.
One change which did occur is the small increase
in size of Dasycercus cristicauda from Unit 2 to
Unit 1 . We suggested (Lundelius & Turnbull, 1 978,
p. 64) that this represents an instance of character
release related to the disappearance of the mor-
phologically similar and closely related Dasyu-
roides byrnei after about 16,000 b.p., which may
have allowed Dasycercus cristicauda to broaden
its niche.

The absence ofMegaleia rufa from the Madura
Cave deposits is puzzling, although it is not com-
mon anywhere as a fossil. The species is present
today on the Nullarbor Plain. It is found in the
late Pleistocene fauna from Lake Menindee (Ted-
ford, 1967), where it is associated with many of
the same species that occur in the Madura Cave
fauna. It is not recorded as having been found in
the late Pleistocene fauna of the Lake Victoria
region, which has produced many of the same
species as Lake Menindee and Madura Cave (Mar-
shall, 1973b). It is present in the late Pleistocene
fauna from Unit III of Seton Rock Shelter, Kan-
garoo Island, South Australia (Hope et al., 1977).
Its absence from the Madura Cave fauna may be
the result of a sampling accident, since the larger
animals are poorly represented. This poor repre-
sentation of the larger taxa suggests that most of
the fossils were accumulated by owls, which could
not handle the larger forms. A comparably puz-
zling situation is the absence of the monotreme
Tachyglossus aculeata.

Macropus eugenii, M. irma, and Potorous tri-
dactylus are also absent from the Pleistocene de-
posits. These taxa, along with Vombatus, Phas-
colarctos, and Potorous platyops, if their Pleistocene
records in southwestern and southeastern Austra-
lia are considered (Merrilees, 1968b), have dis-
junct distributions on either side of the Nullarbor
Plain, and at some time in the past these popu-
lations should have been connected across this
area. This expectation has been realized for Phas-
colarctos cinereus (Lundelius & Turnbull, 1982),
whose modern distribution is eastern and south-
eastern Australia, but which is known from Pleis-
tocene deposits in southwestern Australia (Mer-

68

FIELDIANA: GEOLOGY

rilees, 1 968b; Balme et al., 1 978), and for Potorous
platyops, known as a living animal in western Aus-
tralia and as a fossil from eastern Australia (Wake-
field, 1964). There are several possible explana-
tions for the absence of these three taxa: (1) They
may have been connected across an area north of
the Roe Plain, and may not have been present in
the vicinity of Madura Cave; (2) the connection
or dispersal may have taken place at some time
earlier than that represented by the Madura Cave
deposits; or (3) their absence may be a sampling
accident.

Three species of marsupials, Parantechinus ap-
icalis, Tarsipes spencerae, and Setonyx brachyu-
rus, are restricted to southwestern Australia. Only
one of these, Parantechinus apicalis, is known from
Pleistocene or Holocene faunas of the Nullarbor
Plain. If the absence of these taxa from the late
Pleistocene fauna of that area is not a sampling
accident, then the marsupial fauna from the Pleis-
tocene deposits indicates an environment that was
mesic and more equable than the present envi-
ronment, but which lacked the dense swampy areas
preferred by Setonyx brachyurus, the thickets pre-
ferred by Macropus eugenii (Ride, 1970), and the
forests preferred by Vombatus. A savannah or
woodland is indicated.

Acknowledgments

We gratefully acknowledge the encouragement,
support, and collecting assistance given by Judith
Lundelius and Priscilla Turnbull; without their help
the work would not have been accomplished. We
also thank Marlene H. Werner for the fine draw-
ings of both the Madura Cave fossils and the suite
of modern comparative materials; and Zbigniew
T. Jastrzebski, Senior Scientific Illustrator at Field
Museum, who montaged the drawings, prepared
the graphs, and gave advice. The original fieldwork
was supported in part by a grant from the National
Science Foundation (GB975), and others from the
Geological Foundation, University of Texas and
from Field Museum. The Foundation further sup-
ported Lundelius on a study trip to Field Museum.

Literature Cited

Andrews, D. L., and G. L. Settle. 1 982. Observations
on the behavior of species of Planigale (Dasyuridae,
Marsupialia) with particular reference to the narrow-
nosed planigale (Planigale tenuirostris), pp. 31 1-324.
In Archer, M., ed., Carnivorous Marsupials, vol. 1,
chap. 3 1 . Royal Zoological Society of New South Wales,
Sydney, N.S.W., Australia.

Archer, M. 1972. Nullarbor 1970. The Western Cav-
er, 12(1): 21-24.

1 974. New information about the Quaternary

distribution of the thylacine (Marsupialia, Thylacini-
dae) in Australia. J. Roy. Soc. West. Aust., 57(2): 43-
50.

. 1976. Revision of the marsupial genus Plan-

igale Troughton (Dasyuridae). Mem. Queensland Mus.,
17(3): 341-365.

. 1978. The nature of the molar-premolar

boundary in marsupials and a reinterpretation of the
homology of marsupial cheekteeth. Mem. Queensland
Mus., 18(2): 157-164.

Balme, J., D. Merrilees, and J. K. Porter. 1 978. Late
Quaternary mammal remains, spanning about 30,000
years from excavations in Devil's Lair, Western Aus-
tralia. J. Roy. Soc. West. Aust., 61(2): 33-65.

Bartholomai, A. 1963. Revision of the extinct ma-
cropodid genus Sthenurus Owen in Queensland. Mem.
Queensland Mus., 14(3): 51-76.

. 1973. The genus Protemnodon Owen (Mar-
supialia, Macropodidae) in the upper Cainozoic de-
posits of Queensland. Mem. Queensland Mus., 16(3):
309-363.

. 1975. The genus Macropus Shaw (Marsupialia:

Macropodidae) in the upper Cainozoic deposits of
Queensland. Mem. Queensland Mus., 17(2): 195-235.

Baynes, A., D. Merrilees, and J. K. Porter. 1975.
Mammal remains from the upper levels of a late Pleis-
tocene deposit in Devil's Lair, Western Australia. J.
Roy. Soc. West. Aust., 58: 97-126.

Brooker, M. G. 1977. Some notes on the mammalian
fauna of the western Nullarbor Plain, Western Aus-
tralia. West. Aust. Nat., 14(1): 2-15.

Calaby, J. H. 1966. Mammals of the upper Richmond
and Clarence rivers, New South Wales. C.S.I. R.O. Div.
Wildl. Res. Pap., 10: 3-55.

. 1971. The current status of Australian Macro-
podidae. Aust. Zoologist, 16(1): 17-29.

Denny, M. J. S. 1982. Review of Planigale (Dasyu-
ridae, Marsupialia) ecology, pp. 131-138. In Archer,
M., ed., Carnivorous Marsupials, vol. 1, chap. 13.
Royal Zoological Society of New South Wales, Sydney,
N.S.W., Australia.

Desmarest, A. G. 1817. Kanguroo, p. 35, plate 22. In
Nouveau dictionaire d'histoire naturelle, n. ed.. 17.
Chez Deterville, Paris.

DeVis, C. W. 1895. A review of the fossil jaws of the
Macropodidae in the Queensland Museum. Proc. Linn.
Soc. N.S.W., 2nd series, 10: 75-133.

Dortch, C. E., and D. Merrilees. 1972. A salvage
excavation in Devil's Lair, Western Australia. J. Roy.
Soc. West. Aust., 54: 103-1 13.

Finlayson, H. H. 1936. On mammals from the Lake
Eyre Basin. Trans. Roy. Soc. S. Aust., 60: 157-161.

Flower, W. H. 1884. Catalogue of the Specimens Il-
lustrating the Osteology and Dentition of Vertebrated
Animals, Living and Extinct, Contained in the Mu-
seum of the Royal College of Surgeons of England.
Part II, Class Mammalia Other Than Man. Taylor and
Francis, London, 779 pp.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

69

Frith, H. J., and J. H. Calaby. 1969. Kangaroos. F.

W. Cheshire, Melbourne, Victoria, XI + 209 pp.
Glauert, L. 1912. Fossil marsupial remains from Bal-

ladonia in the Eucla Division. Rec. West. Aust. Mus.

Art Gallery, 1: 47-65.
. 1926. A list of Western Australian fossils. Geol.

Surv. West. Aust., Bull. No. 88: 36-71.
. 1933. The distribution of the marsupials in

Western Australia. Part IV. Fieldiana: Geol., n.s., 6:
1-72.

1982. The mammalian fauna of Madura Cave,

Western Australia. J. Roy. Soc. West. Aust., 19: 17-

32.
Gould, J. 1840. On five new species of kangaroos.

Proc. Zool. Soc. London, 1840: 92-94.
. 1 844. Exhibition and character of a number

of animals transmitted from Australia by Mr. Gilbert.

Proc. Zool. Soc. London, 1844: 103-107.
Gray, J. E. 1837. Descriptions of some new or little

known Mammalia, principally in the British Museum

collection. Mag. Nat. Hist. (Charlesworth), n.s., 1: 577-

587.
. 1841. Contributions toward the geographical

distribution of the Mammalia of Australia with notes
on some recently discovered species, pp. 397-414. In
Grey, G., ed., Journals of Two Expeditions of Dis-
covery in Northwest and Western Australia, vol. 2,
appendix C. T. and W. Boone, London.

Hibbard, C. W. 1960. An interpretation of Pliocene
and Pleistocene climates in North America. Annu.
Rep. Mich. Acad. Sci., Arts & Lett., 62: 5-30.

Hope, J. H., R. J. Lampert, E. Edmondson, M. J. Smith,
and G. F. van Tets. 1 977. The late Pleistocene fau-
nal remains from Seton Rock Shelter, Kangaroo Is-
land, South Australia. J. Biogeog., 4: 363-385.

Jones, F. W. 1923-1925. The bandicoots and the her-
bivorous marsupials (the syndactylous Didelphia), pp.
133-270. In The Mammals of South Australia, vol.
2. Handbooks of the Flora and Fauna of South Aus-
tralia. R. E. E. Rogers, Adelaide, S.A., Australia.

Kirsch, J. A. W., and W. E. Poole. 1967. Serological
evidence for speciation in the grey kangaroo Macropus
giganteus Shaw (Marsupialia: Macropodidae). Nature
(Lond.), 215: 1097-1098.

. 1972. Taxonomy and distribution of the grey

kangaroos, Macropus giganteus Shaw and Macropus
fuliginosus (Desmarest), and their subspecies (Mar-
supialia: Macropodidae). Aust. J. Zool., 20: 315-339.

Lundelius, E. L., Jr. 1963. Vertebrate remains from
the Nullarbor Caves, Western Australia. J. Roy. Soc.
West. Aust., 46: 75-80.

— . 1983. Climatic implications of late Pleistocene

and Holocene faunal associations in Australia. Al-
cheringa, 7: 125-149.

Lundelius, E. L., Jr., and W. D. Turnbull. 1973.
The mammalian fauna of Madura Cave, Western Aus-
tralia. Part I. Fieldiana: Geol., 31(1): 1-35.

. 1975. The mammalian fauna of Madura Cave,

Western Australia. Part II. Fieldiana: Geol., 31(2): 37-
117.

. 1978. The mammalian fauna of Madura Cave,

Western Australia. Part V. Fieldiana: Geol., n.s., 11:
1-32.

1 984. The mammalian fauna of Madura Cave,

Western Australia. Part VI. Fieldiana: Geol., n.s., 14:
1-63.

Lydekker, R. 1 887. Catalogue of the Fossil Mammalia
in the British Museum, Part V. London, xxv + 345
pp.

Marcus, L. F. 1 962. A new species of Sthenurus (Mar-
supialia, Macropodidae) from the Pleistocene of New
South Wales. Rec. Aust. Mus., 25: 299-304.

. 1976. The Bingara fauna: A Pleistocene ver-
tebrate fauna from Murchison County, New South
Wales, Australia. Univ. Calif. Publ. Geol. Sci., 114:
1-145.

Marlow, B. 1962. Marsupials of Australia. Jacaranda
Press, Brisbane, Queensland, Australia, 141 pp.

Marshall, L. G. 1973a. The Lake Victoria local fauna:
A late Pleistocene-Holocene fauna from Lake Victo-
ria, southwestern New South Wales, Australia. M.A.
thesis, Monash University, Clayton, Victoria, Austra-
lia.

. 1973b. Fossil vertebrate faunas from the Lake

Victoria region, S.W. New South Wales, Australia.
Mem. Natl. Mus. Victoria, 34: 151-172.

Marshall, L. G., and R. S. Corruccini. 1978. Vari-
ability, evolutionary rates, and allometry in dwarfing
lineages. Paleobiology, 4(2): 101-119.

Merrilees, D. 1965. Two species of the extinct genus
Sthenurus Owen (Marsupialia, Macropodidae) from
south-eastern Australia, including Sthenurus gilli sp.
nov. J. Roy. Soc. West. Aust., 48(1): 22-32.

. 1968a. Southwestern Australian occurrences

of Sthenurus (Marsupialia, Macropodidae), including
Sthenurus brownei, sp. nov. J. Roy. Soc. West. Aust.,
50(3): 65-79.

-. 1968b. Man the destroyer: Late Quaternary

changes in the Australian marsupial fauna. J. Roy. Soc.
West. Aust., 51(1): 1-24.

1979. Prehistoric rock wallabies (Marsupialia,

Western Australia. Part III. Fieldiana: Geol., 38: 1-
120.

. 1981. The mammalian fauna of Madura Cave,

Macropodidae, Petrogale) in the far southwest of
Western Australia. J. Roy. Soc. West. Aust., 61(3): 73-
96.

Milham, P., and P. Thompson. 1976. Relative antiq-
uity of human occupation and extinct fauna at Madura
Cave, southeastern Western Australia. Mankind, 10(3):
175-180.

Owen, R. 1838. Letter, pp. 365-369. In Mitchell, T.
L., ed., Three Expeditions into the Interior of Eastern
Australia, vol. 1 , 2nd ed. T. and W. Boone, London.

. 1 873. On the fossil mammals of Australia. Part

VIII. Macropodidae: Genera: Macropus, Osphranter,
Phascolagus, Sthenurus, Protemnodon [abstract]. Proc.
Roy. Soc. London, 21: 128.

. 1874. On the fossil mammals of Australia. Part

VIII. Macropodidae: Genera: Macropus, Osphranter,
Phascolagus, Sthenurus, Protemnodon. Phil. Trans.
Roy. Soc. London, 164: 245-287, 8 pis.

70

FIELDIANA: GEOLOGY

. 1 877. Researches on the Fossil Remains of the

Extinct Mammals of Australia with a Notice of the
Extinct Marsupials of England, vols. 1 and 2. J. Erx-
leben, London, xv + 522 pp.

Peacock, W. J., E. S. Dennis, A. Elizur, and J. H.
Calaby. 1981. Repeated DNA sequences and kan-
garoo phylogeny. Aust. J. Biol. Sci., 34: 325-340.

Peron, F., and C. A. Lesueur. 1807. Voyage de De-
couvertes aux terres Australes, atlas plate 27. (Fide
Tate, 1948.)

Poole, W. E., S. M. Carpenter, and H. G. Simms. 1 980.
Multivariate analysis of skull morphometries from the
two species of grey kangaroos, Macropus giganteus
Shaw and M.fuliginosus (Desmarest). Austral. J. Zool.,
28:591-605.

Read, D. 1982. Observations on the movements of
two arid zone planigales (Dasyuridae, Marsupialia),
pp. 227-231. In Archer, M., ed., Carnivorous Mar-
supials, vol. 1, chap. 21. Royal Zoological Society of
New South Wales, Sydney, N.S.W., Australia.

Ride, W. D. L. 1970. A Guide to the Native Mammals
of Australia. Oxford University Press, London, 249
pp.

Ride, W.D.L., and C.H.Tyndale-Biscoe. 1959. The
mammals. In Ride et al., The results of an expedition
to Bernier and Dorre islands, Shark Bay, Western Aus-
tralia in July 1959. Fauna Bull. Fisheries Dept. West.
Aust., no. 2: 54-97.

Sanson, G. D. 1983. Evolution of feeding adaptations
in fossil and Recent macropodids, pp. 489-506. In
Rich, P. V., and E. M. Thompson, eds., The Fossil
Vertebrate Record of Australasia. Monash University
Offset Printing Unit, Clayton, Victoria, Australia.

Semken, H. A., Jr. 1974. Micromammal distribution
and migration during the Holocene, p. 25. Abstracts,
Amer. Quat. Assoc. 3rd Bienn. Meeting, University
of Wisconsin, Madison.

Sharman, G. B. 1961. The mitotic chromosomes of
marsupials and their bearing on taxonomy and phy-
logeny. Aust. J. Zool., 9: 38-60.

Shaw, G., and F. P. Nodder. 1 790. The Naturalists'
Miscellany, vol. 1, text for plate 33. Nodder & Co.,
London.

Shepherd, N. C. 1982. Extension of the known range
of western grey kangaroos, Macropus fuliginosus, and
eastern grey kangaroo, M. giganteus, in New South
Wales. Aust. Wildl. Res., 9(3): 389-391.

Shortridge, G. C. 1 909. An account of the geograph-
ical distribution of the marsupials and monotremes of
south-west Australia, having special reference to the
specimens collected during the Balston Expedition of
1904-1907. Proc. Zool. Soc. London, 1909: 803-848.

Stirton, R. A. 1963. A review of the macropodid
genus Protemnodon. Univ. Calif. Publ. Geol. Sci., 44(2):
97-162.

Tate, G. H. H. 1948. Studies on the anatomy and
phylogeny of the Macropodidae (Marsupialia). Bull.
Amer. Mus. Nat. Hist., 91(2): 233-352.

Taylor, M. J., J. H. Calaby, and T. D. Redhead. 1 982.
Breeding in wild populations of the marsupial mouse
Planigale maculata sinualis (Dasyuridae, Marsupi-
alia), pp. 83-87. In Archer, M., ed., Carnivorous Mar-
supials, vol. 1, chap. 9. Royal Zoological Society of
New South Wales, Sydney, N.S.W., Australia.

Tedford, R. H. 1966. A review of the macropodid
genus Sthenurus. Univ. Calif. Publ. Geol. Sci., 57: 1-
72.

. 1967. The fossil Macropodidae from Lake

Menindee, New South Wales. Univ. Calif. Publ. Geol.
Sci., 64: 1-164.

Thomas, O. 1887. On the wallaby commonly known
as Lagorchestes fasciatus. Proc. Zool. Soc. London,
1886: 544-547.

. 1888. Catalogue of the Marsupialia and Mon-

otremata in the collection of the British Museum (Nat.

Hist.), London. Taylor and Francis, London, i-xiii +

401 pp.
Wakefield, N. A. 1964. Mammal remains, appendix

1. In Mulvaney, D. J., G. H. Lawton, and C. R. Twi-

dale, Archaeological excavations of Rock Shelter no.

6, Fromm's Landing, South Australia. Proc. Roy. Soc.

Victoria, 77: 494-498.
. 1966. Mammals of the Blandowski Expedition

to northwestern Victoria, 1856-57. Proc. Roy. Soc.
Victoria, 79(2): 371-391.

LUNDELIUS & TURNBULL: MADURA CAVE. PART VII.

71

Other Fieldiana: Geology Titles Available in This Series

The Mammalian Fauna of Madura Cave, Western Australia. Part I. By E. L. Lundelius, Jr., and W. D.
Turnbull. Fieldiana: Geology, vol. 31, no. 1, 1973. 35 pages, 13 illus.

Publication 1160, $3.25

The Mammalian Fauna of Madura Cave, Western Australia. Part II. By E. L. Lundelius, Jr., and W.
D. Turnbull. Fieldiana: Geology, vol. 31, no. 2, 1975. 81 pages, 21 illus., appendix.

Publication 1209, $7.25

The Mammalian Fauna of Madura Cave, Western Australia. Part III. By E. L. Lundelius, Jr., and W.
D. Turnbull. Fieldiana: Geology, vol. 38, no. 1, 1978. 120 pages, 27 illus., 29 tables.

Publication 1290, $9.50

The Mammalian Fauna of Madura Cave, Western Australia. Part IV. By E. L. Lundelius, Jr., and W.
D. Turnbull. Fieldiana: Geology, n.s., 6, 1981. 72 pages, 21 illus., 8 tables.

Publication 1315, $7.25

The Mammalian Fauna of Madura Cave, Western Australia. Part V: Diprotodonta (Part). By E. L.
Lundelius, Jr., and W. D. Turnbull. Fieldiana: Geology, n.s., 1 1, 1982. 32 pages, 10 illus., 4 plates, 4
tables.

Publication 1332, $4.50

The Mammalian Fauna of Madura Cave, Western Australia. Part VI. By E. L. Lundelius, Jr., and W.
D. Turnbull. Fieldiana: Geology, n.s., 14, 1984. 63 pages, 15 illus., 21 tables.

Publication 1354, $8.25

Order by publication number and/or ask for a free copy of our price list. All orders must be prepaid.
Illinois residents add current tax. All foreign orders are payable in U.S. dollar-checks drawn on any U.S.
bank or the subsidiary of any foreign bank. Prices subject to change without notice. Address all requests
to:

FIELD MUSEUM OF NATURAL HISTORY

Library— Publications Division

Roosevelt Road at Lake Shore Drive

Chicago, Illinois 60605-2498, U.S.A.

Field Museum of Natural History
Roosevelt Road at Lake Shore Drive
Chicago, Illinois 60605-2496
Telephone: (312) 922-9410