y

UWiVEHSn Y CF

ILUNOIS LIBRARY

ATURBANA-CHAMPAIGN

GEaOGY

The person charging this material is re-
sponsible 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which it was withdrawn on or before the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 disciplinary action and may
result in dismissal from the University.

UNIVERSITY OF MMMniS LIBRARY AT URBANA-CHAMPAIGN

OCT f 3

L161 — O-1096

I

FIELDIANA • GEOLOGY

Published by
FIELD MUSEUM OF NATURAL HISTORY

Volume 16 March 22, 1968 No. 8

Cymaprimadontidae

A New Family of Insectivores
John Clark

ASSOCIATE CURATOR, SEDIMENTARY PETROLOGY

I. Introduction

During the summer of 1965, Mr. K. Kietzke of the Field Mu-
seum staff collected a partial right mandible of an animal which is,
even on cursory examination, a new form. The specimen occurred
near the top of the Crazy Johnson Member of the Chadron For-
mation in South Dakota. The matrix is a slightly-cemented ben-
tonitic mudstone with abundant, very fine sand grains. Paleogeo-
graphically, the fossil occurred approximately a mile north of the
northern edge of the zone of channel-fill sediments designated the
Red River Valley (Clark, 1937).

The bone is soft and white, with pale olive enamel on the teeth.
Unfortunately, crystalline calcite fills many of the cracks and cav-
ities, and permeates even the most intimate structure of the bone,
which greatly increased the difficulties of preparation and X-ray
photography.

Subsequent search of the Museum's collection disclosed a left
mandible, UC 349, of a form related to but not congeneric with
the first. This was in the collection recently acquired from the
Walker Museum. Unfortunately this second specimen, collected
by Baur in 1894, has as field data: "Oligocene of South Dakota,
White River Badlands." The matrix is a fine sand, better cemented
and slightly coarser than that of the Chadron specimen. The bone is
hard and dark gray with a limonite incrustation, and the single tooth
preserved is dark brown. X-ray reveals limonite filling the pulp
cavities of the tooth roots. Preservation resembles that of the Lower
Nodular Zone, Scenic Member, Brule Formation; as will be devel-

Library of Congress Catalog Card Number: 68-21 23 4

£OLOGlUBeNa JULUB68

imn

242 FIELDIANA: GEOLOGY, VOLUME 16

oped later, the anatomical characters also suggest that this sec-
ond jaw is younger than the first. However, I have seen bone and
preservation of this sort occasionally in the Peanut Peak Member
the Chadron. The specimen should be regarded as of Oligocene
age, probably Orellan (Brule), but possibly late Chadronian.

In view of the problematical age plus the fact that only the
dental ramus and M3 are preserved, I shall describe this second
specimen without giving it a generic and specific name. It will be
used to aid in delimiting the new family.

Figures 3-6 were drawn by Dr. T. Perenyi; Figures 1 and 2 are
by the author.

II. Description

Order Insectivora

The supra-familial taxonomy of the numerous families, both
fossil and recent, previously grouped within this order, is in such a
state of flux that only a specialist can form significant judgments.

The Early Tertiary and Recent families which seem most closely
related to the new one proposed here have been variously classified,
but have not previously been regarded as closely related to each
other. It seems most practical, therefore, to describe the new family,
indicate its possible relationship to others, and refer it to the Insec-
tivora. This leaves to specialists the evaluation of relationships in
suprafamilial classification.

Family CYMAPRIMATONTIDAE, new family

Known age and geographic distribution:- — Early to ? Middle Oligo-
cene, South Dakota.

Type genus: — Cymaprimadon, new genus.

Family characters: — Large for insectivores, about the size of mod-
ern Lutra or Lynx, mandible low, thick, extremely massive; posterior
mental foramen very large, postero-ventrally directed, beneath
the P4-M1 inter-alveolar partition; a curved, longitudinal groove
on the latero-ventral side of the dental ramus; mandibular sym-
physis small and narrow; symphyseal surfaces unsutured and almost
flat; inferior cheek-tooth row strongly arched into an open sigmoid;
one lower incisor enlarged, procumbent, with enamel distribution
restricted and a prominent median groove; other incisors reduced
or absent; canine reduced; Pi absent; P2 reduced, P3 larger, P4 the

m

CLARK: CYMAPRIMADONTIDAE

A

243

HEAVY EfiAMEL
LI&HT ENAMEL

Fig. 1. Cross-sections of incisor of Cymaprimadon kenni: A, Slightly behind
alveolar rim. B (Hypothetical), near tip of tooth.

longest of the cheek-tooth series ; Mi-Ma progressively smaller; pos-
terior roots of cheek teeth large, round; anterior roots smaller,
flattened antero-posteriorly; molar paraconids reduced but present;
hypoconid large, developing toward a blade; entoconid and hypo-
conulid greatly reduced; root of enlarged incisor extended back to
beneath posterior root of P3; mandibular canal high in jaw.

Genus Cymaprimadon,^ new genus

Type species: — Cymaprimadon kenni,- new species.

Type specimen of species: — Field Museum no. PM 9567, a right
mandibular ramus with M3 and the greater portion of an enlarged
incisor.

Since only this one specimen of the genus species is known,
generic and specific characters are not separable.

Geologic horizon: — Top of Crazy Johnson Member, Chadron For-
mation, Lower Oligocene.

Locality:~NW \i of NE 3^, sec. 25, T 3S, R lOE, Pennington
Co., South Dakota. Northeast face of the Finney Breaks.

> From Kvy.a., a wave or furrow; primus, first; o5i,>v, a tooth, in reference to the
groove in the enlarged incisor.

* Named in honor of Mr. Kenneth Kietzke, who found the type specimen.

244 FIELDIANA: GEOLOGY, VOLUME 16

Generic and specific characters:

1. Measurements as in Table 1.

2. Dental formula= ?3 _ i _ 3 _ 3.

3. Ii reduced, probably absent; I2 greatly enlarged, procumbent;
I3 reduced, probably absent.

4. I2 enamel distributed as in Figure 1, and very thin. A complex
pattern of fine, vermiform crenulations developed on the enamel
surface (fig. 2).

5. Alveolus for I2 extending back to beneath the anterior alveolus
for P4.

6. Cheek-tooth series continuous, crowded, without diastemata,
from I2 to M3.

7. M3 trigonid low, less than twice the height of talonid, meas-
ured from the enamel border.

8. Protoconid largest, paraconid medial and smallest; trigonid
cusps slightly compressed at points, to enclose a tiny basin.

9. Talonid a very shallow, flat-bottomed basin, sloping strongly
mesio-anteriorly. The large hypoconid rises but little higher
than this basin, standing almost on the midline of the tooth
with a ridge extending forward to the postero-internal base of
the protoconid. The entoconid and hypoconulid are reduced
to tiny nubbins on the posterior part of the low ridge which
forms the postero-internal rim of the basin.

10. Tiny accessory cuspule on the postero-external side of the hy-
poconid.

11. Tiny accessory cuspule on the mesio-posterior wall of the met-
aconid.

12. Small but definite anterior cingulum at base of protoconid ; ob-
scure cingular prominence at base of paraconid ; internal cingu-
lum at base of metaconid; the three cingula separated from
each other.

13. A prominent shelf around the alveoli of the molars and P4, and
heavy crests at the ends of the premolar interalveolar partitions.

14. Posterior mental foramen large, as a family character; anterior
to this a row of smaller foramina, probably individually vari-
able in detail.

15. Protuberant muscle scars on ventral border of ramus below
M3 and below Pi.

1

DENTINE

ROOT

PULP
CAVITY

Fig, 2. A, Drawing of enamel pattern of incisor, greatly enlarged. B, Photo-
graph of same.

245

246 FIELDIANA: GEOLOGY, VOLUME 16

16. Rugose area on side of chin.

17. Bone surface generally marked by widely spaced, tiny, pos-
teriorly directed pores, from which grooves 1-5 mm. long ex-
tend backward, roughly parallel to the elongation of the bone
on which they occur.

New But Unnamed Genus and Species

Specimen upon which description is based: — Field Museum speci-
men UC 349 (formerly in the collection of the Walker Museum,
University of Chicago) .

The known stratigraphic occurrence is Oligocene; probably the
specimen is from the Scenic Member of the Brule Formation, but
possibly it is from the Peanut Peak Member of the Chadron For-
mation. The locality is "White River Badlands, South Dakota."
Since this expression was used by early collectors to mean "Badlands
of the White River Formation" (now group), rather than "Bad-
lands in the drainage area of the White River," the locality data
should not be interpreted to exclude Cheyenne River and Bad River
drainage basins.

TABLE 1

Dimension PM 9567 UC 349

Depth of mandible below anterior root of Mi 12.6 15.6

Thickness of mandible below anterior root of Mi 8.5 10.5

Anterior rim of temporal fossa to posterior rim of

posterior mental foramen 20.0 23.1

Cheek-tooth series, C-M3 alveoli 41 .4

Cheek-tooth series, P4 - Ms alveoli 30.5 35.4

Ml -Ms alveoli 20.6 24.3

P4 alveolus, antero-posterior 9.5i 10.2

Ml, alveolus, antero-posterior 7.5 7.5

M2 alveolus, antero-posterior ! 6.8 6.9

Ms, length 5.6 7.8

Ms, breadth 4.4 5.8

Ms, height, enamel rim-top of protoconid 4.9 6.4^

Ms, height, enamel rim-top of metaconid 4.0 5.6

Ms, height, enamel rim-top of hypoconid 3.3 4.7

1 Slightly too large, due to breakage and laboratory repair.

2 Estimated, — tip broken.

Table 1 reveals that this specimen represents an animal much
larger than Cymaprimadon kenni. The individual had, apparently,
lived to a very slightly more advanced age than had the type of C.
kenni, because M3 is fully erupted. M3 of C. kenni has the enamel

CLARK: CYMAPRIMADONTIDAE 247

border a little below the alveolar rim. In neither case is there any
trace of wear. Both individuals had apparently attained approx-
imately full size shortly before their death. The similarity of growth
stage makes it probable that, with the exceptions noted below, dif-
ferences between the two specimens are individual or generic rather
than developmental.

Significant characteristics of specimen UC 349:

1. Measurements as in Table 1.

2. Dental formula= i _ o _ 2 — 3

3. Enlarged incisor alveolus extends back to beneath posterior
root of P3; posterior wall consists of spongy bone apparently
formed shortly before the individual's death.

4. Cheek-tooth series crowded, continuous. Little or no room for
Ci, Pi_2, between the enlarged incisor and P3; probably these
teeth were missing.

5. P3 reduced relative to the corresponding tooth in Cymaprima-
don kenni.

6. M2 and M3 of equal size; M4 slightly longer. Pi longest in the
cheek-tooth series but proportionally shorter than in C. kenni.

7. M3 trigonid low; height 62% of the length of the tooth, com-
pared with 83% in C. kenni.

8. M3 protoconid very slightly larger than metaconid. Paraconid
reduced to a sloping prominence connected to the anterior
ridge of the protoconoid; a deep, medio- ventrally trending
groove between the paraconid and metaconid. Protoconid and
metaconid cusps slightly compressed at tips, but form no basin
due to the reduction of the paraconid.

9. M3 talonid consists of a heavy, blunt blade, rising posteriorly
to the hypoconid as its cone-shaped terminus. The remaining
conules form a denticulated posterior portion of a heavy in-
ternal rim which does not enclose a basin because it is not ap-
preciably higher than the area within it. A heavy, low ridge
extends down the linguo-posterior wall of the hypoconid to
a denticle on the rim, but does not directly join it.

10. There is a small accessory cuspule on the mesio-posterior wall
of the metaconid, as in C. kenni, but none on the hypoconid.

11. A very broad, low, heavy cingulum forms a straight wall across
the anterior face of M3. Unlike C. kenni, no other cingula
occur.

248

FIELDIANA: GEOLOGY, VOLUME 16

Fig. 3. Lateral view of jaws: A, C. kenni. B, UC 349.

12. The shelf and crests aroung the alveolar borders are even more
prominent than in C. kenni.

13. The protuberant muscle scars of C. kenni are absent in UC 349;
otherwise the foramina and jaw characters preserved resemble
those of C. kenni.

In most respects, this animal represents a genus evidently more
advanced along the generic trend of the family than is Cymaprim-
adon. The increase in overall size and weight, further reduction
of the paraconid, further alteration of the talonid to a shearing
blade based upon the hypoconid, and apparent further reduction
of the anterior cheek-tooth series may all be regarded as changes
carrying the Cymaprimadontidae further from [whatever was their
ancestral group. The development of a heavy anterior cingulum
and suppression of the other two partial cingula presumably have
the same significance. The degree of specialization suggests, as
does the type of preservation, that UC 349 represents a genus later
in time (probably Orellan) than the middle Chadronian Cyma-
primadon.

Fig, 4. Vertical view of jaws: A, C. kenni. B, UC 349.

B

Fig. 5. Lingual view of jaws: A, C. kenni. B, UC 349,

249

250 FIELDIANA: GEOLOGY, VOLUME 16

III. Soft anatomy and probable way of life
of Cymaprimadontids

The symphysis in C. kenni makes a 30° angle with the axis of
the mandible. The skull must have been approximately 45-50 mm.
wide at the mandibular condyles. Judging from the weight of the
bone and the massive muscle scars, the head was probably a great
deal wider. The general head proportions were probably nearly
those of an otter or lynx, with large temporal and masseter muscles
compensating by their bulk for the undoubtedly narrower calva-
rium of Cymaprimadon.

Strong outward angulation of Mi and the lower premolars sug-
gests than the anterior part of the palate was broad. Some sort of
active, well-muscled labial apparatus is indicated by the rugose area
on the anterior surface of the jaw; adequate blood was supplied
through the large mandibular canal and short, wide-diameter mental
foramina. Whatever the labial apparatus was, it presumably func-
tioned in connection with the use of the unique I2.

I2 poses a real problem. Great enlargement, high specialization
in shape, and the development of a unique enamel decoration all
indicate that the tooth functioned in a distinctive manner extremely
important to the animal. The tooth must have tapered distally to
a long, sharp, triangular point with an internal groove and a rounded
external side. The right and left incisors together probably pro-
duced a sharp, procumbent point with a cross-section as shown in
Figure 1,B, rounded ventrally and marked by a tube with a dorsally
open slot.

Such a dental structure, with thin, discontinous enamel areas,
is obviously designed for only one purpose — piercing a soft, non-
abrasive object. Any normal masticatory function is impossible,
for it. The tube is designed for the passage of liquids, either into
or out of the animal's mouth.

The first alternative, that the tube is part of a suction apparatus,
requires that the animal use it to suck in either vegetable juices or
blood. The only vegetable juices available to teeth so delicate would
be the juice of soft-fleshed fruits. A tube so narrow would be of little
use, and would almost certainly become plugged with fiber. Fur-
thermore, the cheek-tooth dentition and heavy jaw musculature
are not those of an innocently frugivorous animal. Judging from
the size and alignment of the alveoli, P4 functioned as a reasonably

I

B

Fig. 6. Vertical view of M3: A, C. kenni. B, UC 349.

251

252 FIELDIANA: GEOLOGY, VOLUME 16

efficient carnassial tooth, and even M3 is constructed for effective
dissectorial mastication.

Vampirism offers an even less satisfactory alternative utilization
of these teeth. The two together would form a sharp-pointed but
very short half-cone-shaped weapon, with a base at least 20 mm.
broad. No animal could possibly sit quietly unnoticing while such
an object was rammed into its body, and the open tube could not
possibly function during the ensuing struggle.

Since this dental apparatus would not effectively ingest liquid
food, the remaining possibility is that it served to inject something.
Solenodon, the only other known mammal with a similarly grooved
tooth, has been shown to be venomous (Rabb, 1959), and to use
its grooved but heavily-enamelled incisors as fangs for insertion of
its venom. In Cymaprimadon, the particular gland specialized
for venom was probably either the sublingual or the submaxillary,
both of whose ducts discharge appropriately at the base of the
incisors.

Use of the incisor tube to transmit venom to its victims would
be effective. Corollary to this use would be the development of a
heavy maxillary root of the zygomatic arch, probably accompanied
by an eversion of the arch to a feloid position. The masseter would
then occupy an almost fore-and-aft position, and would drive the
mandible forward. Heavy scars along the base of the mandible,
presumably in part for the insertion of the digastric, suggest that
Cymaprimadon was also able to withdraw its weapon with some
vigor. These musculoskeletal adaptations are, of course, conjec-
tural. Confirmation must await discovery of a skull.

If Cymaprimadon was venomous, it must also have been an active
carnivore. Such an apparatus would be entirely wasted on beetles
and grasshoppers. The cheek-tooth dentition also suggests a car-
nivorous habit. Whether Cymaprimadontids preyed chiefly upon
fish and amphibians, or upon forest-dwelling terrestrial mammals,
or on birds and arboreal mammals, is largely conjectural. The paleo-
geographic location of the type of C. kenni, and the matrix of UC
349, suggest that they lived away from the stream channels proper
but close enough that they certainly inhabited forests rather than
savannah plains or prairies. Their rarity as fossils might be a func-
tion of arboreal existence, or might simply indicate that they were
rare elements of the fauna.

In any event, a carnivorous insectivore weighing at least several
pounds, with a head as big as an otter's and a highly effective toxic

I

CLARK: CYMAPRIMADONTIDAE 253

fang, must have been a frightening member of the predatory com-
munity,

IV. Relationships

Determination of the relationships of the Cymaprimadontidae
is attended by the difficulties usual to insectivore classification:
fragmentary materials plus the difficulty of distinguishing geneti-
cally related characters from parallel or convergent characters.

A search for earlier related or ancestral forms leads at once to
the Pantolestidae. Both families are large for insectivores, with
massive mandibles. More significantly, both have cheek teeth
small in proportion to the jaw, molars with reduced paraconids and
relatively short trigonids, P4 the longest tooth in the series, and a
large, short posterior mental foramen. The large canines and small
incisors of the Pantolestidae obviously exclude them from a directly
ancestral position, but the two families might well represent succes-
sive divergences from a common stem.

Possible descendants are unknown as fossils. However, com-
parison with Solenodon, which has been drawn earlier on a purely
functional basis, reveals a fair number of resemblances and no single
conclusive difference.

Both are large for insectivores. In both, the mandibular canal
is large and placed high in the jaw. The symphysis in both extends
back to a position beneath P3. In both, the canine is greatly reduced
and an incisor (I2 in Solenodon and probably in Cymaprimadon) is
grooved and enlarged. In both, apparently, venom was developed
and used for predation.

An equal number of equally impressive differences also becomes
apparent. Solenodon has an exceedingly long, narrow skull rather
than a massive one. I3 is present. P4 is not quite so long as Mi.
The molars do not decrease in length posteriorly. The paraconids
of the molars almost equal the metaconids in height, and lie on the
lingual side of the tooth rather than in the middle. The talonid
consist of a ridge and an open basin, as in Cymaprimadon, but in
Solenodon the ridge connects to the metaconid and the basin is labial
to it, whereas in Cymaprimadon the ridge connects to the protoco-
nid and the basin is lingual to it.

The relationship, if any, is distant. Tentatively, I believe that
there is a relationship, but that the line leading to Solenodon separated

254 FIELDIANA: GEOLOGY, VOLUME 16

from the ancestral stock of the other two before they differentiated
from each other.

It seems improbable that venom, absent from all other mammal-
lian groups, would develop absolutely independently in three fami-
lies of Insectivora (Soricidae — Pearson, 1942; Solenodontidae —
Rabb, 1959; Cymaprimadontidae — this publication). For this rea-
son I tend to regard the three as somewhat more closely related
to each other than they are to some other families of insectivores.

The anatomy of the mandibular canal seems to be a solid line
of evidence linking the Pantolestidae, Cymaprimadontidae, and
Solenodontidae.

The three would all fall, probably, within the suborder Sorico-
morpha of the order Lipotyphla of Butler (1956) . They would occupy
the same position in McDowell's (1958) classification, but the Pan-
tolestidae and Cymaprimadontidae might properly be excluded
from the superfamily Soricoidea. Van Valen's (1966) "group M"
is stated on p. 104 to include the Pantolestidae and on p. 108 to be
ancestral to the primates, which in turn are ancestral to the rodents;
"group M" is also, apparently, ancestral to the lagomorphs. Since
"group M" is not a formal taxonomic designation, it cannot be prop-
erly considered. However, it seems very clear that the Cymapri-
madontidae are related at an ordinal level to the Pantolestidae, and
that they are not ordinally related to primates, rodents, or rabbits.

REFERENCES

Butler, P. M.

1956. The Skull of Ictops and the Classification of the Insectivora. Proc. Zool.
Soc. London, ser. B, 126, pp. 453-481.

Clark, John

1937. The stratigraphy and paleontology of the Chadron Formation in the Big
Badlands of South Dakota. Ann. Carnegie Mus., 25, pp. 261-350.

McDowell, S. B., Jr.

1958. The Greater Antillean insectivores. Bull. Am. Mus. Nat. Hist., 115,
art. 3, pp. 117-214.

Pearson, 0. P.

1942. On the cause and nature of a poisonous action produced by the bite of a
shrew {Blarina brevicandata) . Jour. Mammal., 23, pp. 159-166.

Rabb, G. B.

1959. Toxic salivary glands in the primitive insectivore Solenodon. Chgo.
Acad. Sci., Nat. Hist. Miscellanea, No. 170, pp. 1-3.

Van Valen, Leigh

1966. Deltatheridia, a new order of mammals. Bull. Am. Mus. Nat. Hist.,
132, art. 1, pp. 1-126.

K,