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FIELDIANA: GEOLOGY

A Continuation of the

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FIELD MUSEUM OF NATURAL HISTORY

VOLUME 41

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TABLE OF CONTENTS

The Morphology and Relationships of the Cretaceous Teleost Apsopelix. By
Susan Teller-Marshall and David Bardack 1

The Deseadan, Early Oligocene, Mt supialia of South America. By Bryan Patter-
son and Larry G. Marshall 37

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FIELDIANA
Geology

Published by Field Museum of Natural History
Volume 41, No. 1 September 29, 1978

The Morphology and Relationships
of the Cretaceous Teleost Apsopelix

Susan Teller-Marshall

Department of Biological Sciences

University of Illinois at Chicago Circle

Chicago, Illinois

and

David Bardack

Department of Biological Sciences

University of Illinois at Chicago Circle

Chicago, Illinois

and

Research Associate

Field Museum of Natural History

INTRODUCTION

The fossil fishes described in this paper were first reported over a
hundred years ago and have been assigned to systematic positions
in different teleostean cohorts at one time or another since their
discovery. Often, specimens from new localities or those preserved
in an unusual manner were given new generic and specific names,
adding to the confused taxonomy of these fishes. This work began
as an investigation of specimens from a new locality in Texas. These
specimens were preserved three dimensionally and were particularly
well suited for acid preparation. Later it became evident that a com-
plete description required examination of additional specimens and
that the nomenclature of these specimens was in need of extensive
revision.

Apsopelix was described by Cope (1871) who assigned the name to
a single, fragmentary specimen (AMNH 1602) from the "Benton"

Library of Congress Catalog Card No.: 78-57801
ISSN 0096-2651

Publication 1288 1

6E010SY LH

2 FIELDIANA: GEOLOGY, VOLUME 41

formation (Upper Cretaceous) of Kansas. Later Cope (1875, 1877)
described two other genera which he believed were similar to Ap-
sopelix: Syllaemus and Pelycorapis. The latter genus, which con-
tained the species P. varius and P. berycinus, was later (Dunkle,
1958) divided. Pelycorapis varius was assigned to Thrissopater,
which is a synonym of Pachyrhizodus (Forey, 1977).

Woodward (1901, 1903, 1907) stressed the similarities among
Pelycorapis, Syllaemus, Apsopelix, and a fourth genus, Leptichthys
Stewart (1899). Jordan (1924) placed Leptichthys and Pelycorapis
within the genus Apsopelix and assigned this genus to the
Syllaemidae. Finally, Dunkle (1958) argued that Helmintholepis
Cockerell (1919) and Paleoclupea Dante (1942) were synonyms of
Pelycorapis berycinus, that the berycinus species and the
Apsopelix-Syllaemus-Leptichthys group share "distinctive as well
as general" characters. Dunkle (1958) then tentatively assigned P.
berycinus to Apsopelix, the oldest available name.

Most recently, Patterson and Rosen (1977) reported that they
could detect no differences between Syllaemus, Pelycorapis
berycinus, Apsopelix, Leptichthys, Helmintholepis, and
Paleoclupea, and treated Apsopelix anglicus (Dixon) as the valid
name for this material. Our investigation included examination of
specimens referred to Paleoclupea, Leptichthys, Syllaemus,
Pelycorapis, and Apsopelix, as well as new material and supports
the argument that all of these fossils represent the same fish,
Apsopelix anglicus.

The present investigation centers on the morphology of Apsopelix
which until now has received only cursory description. This account
includes features previously undescribed and pursues in further
detail features which have been inadequately considered. An at-
tempt is made to focus on those derived characters, present in
Apsopelix, which will permit comparison of this genus with major
teleostean groups. In the past, Apsopelix has been assigned to the
Percesoces1 (Cope, 1875), Mugilidae (Stewart, 1900),
Crossognathidae (Woodward, 1901; Patterson and Rosen, 1977),
Syllaemidae (Cragin, 1901; Green, 1957), Pelycorapidae (Cragin,
1901), Clupeidae (Stewart, 1900; Woodward, 1903, 1907; Jordan,
1923; Berg, 1940), and Apsopelicidae (Romer, 1966).

Apsopelix is known from North America (Colorado, South
Dakota, Kansas, Texas), England, and France. Part of the European
material is Albian, but otherwise Apsopelix is restricted to the
geologic interval between the Cenomanian and Santonian, possibly

TELLER-MARSHALL & BARDACK: APSOPELIX 3

Campanian (but see p. 4) stages of the Upper Cretaceous. It is a uni-
que fish. The antorbitals, scales, and pelvic bones are larger than
those in other teleosts of comparable size. The cranial roofing bones
are distinctive, and the maxilla comprises nearly all of the dermal
upper jaw. Thus, specimens of Apsopelix are easily recognized. The
combined advantages of three-dimensional preservation of some
fossil material and of acid preparation techniques have facilitated a
complete account of the skull. Remaining specimens elucidate most
of the post-cranial skeleton, but the caudal skeleton is not complete
in any specimen examined. This incomplete preservation of the
caudal skeleton is characteristic of Apsopelix, but enough informa-
tion is available from these specimens to permit some conclusions
about the caudal morphology.

The morphological adaptations of Apsopelix include features
associated with microphagous feeding, particularly the long gill
rakers. The gut must have been very long, judging from the remote
position of the anal fin. The body was more robust than laterally
compressed. These clues indicate that the diet was probably in large
part comprised of material difficult to digest, such as plankton.

ACKNOWLEDGEMENTS

For information concerning Apsopelix we thank Peter L. Forey
and Colin Patterson, British Museum of Natural History; and Donn
E. Rosen, American Museum of Natural History. The drawings were
prepared by Karen Baker Al Lerio and the manuscript typed by
Mrs. Beverly Woodard.

SPECIMENS EXAMINED

Material from several museums has been prepared and studied.
Abbreviations include: AMNH, American Museum of Natural
History; FMNH, Field Museum of Natural History; KU, University
of Kansas Museum of Natural History; SMM, Sternberg Memorial
Museum; USNM, United States National Museum; UT, University
of Texas Vertebrate Paleontological Collections.

1The suborder Percesoces was once used to unite the Crossognathidae, Am-
modytidae, Scombresocidae, Atherinidae, Mugilidae, and Sphyraenidae. See Wood-
ward, 1901, Part IV, p. 347 for diagnosis.

4 FIELDIANA: GEOLOGY, VOLUME 41

AMNH 1602, fish body

FMNH PF7463, three-dimensional head and anterior of body, Eagle Ford Forma-
tion, Dallas County, Texas, Texas Industries Quarry, southwest of intersection
of Chalk Hill Road and Dallas-Ft. Worth Turnpike.

KU 309, whole fish; KU 310, fish without tail; KU 318, head and pectoral girdle;
KU 519, whole fish, Smoky Hill Chalk Member, Niobrara Formation, western
Kansas.

KU 18, fish without tail, Fencepost Limestone Bed at top of Greenhorn Formation,
western Kansas.

KU 882, three-dimensional head and anterior of body, Jetmore or Lincoln limestone
levels of Greenhorn Formation, Mitchell County, Kansas, 1 mile northeast of
Scotsville.

SMM 7958, whole fish, Smoky Hill Chalk Member, Niobrara Formation, Kansas.

USNM 16725, three-dimensional head and anterior part of body, Pierre Shale,
Chamberlain, South Dakota (as per catalogue, but horizon and location uncer-
tain as there is no evidence of the matrix similar to that containing the fossil
at this location.)

UT 848, posterior part of head and anterior part of body, Upper Cretaceous
(horizon uncertain), Williamson County, Texas, 1 3A miles east of Coupland in
branch of Bushy Creek.

UT 31051-7, whole fish, Austin Group, Ector Member, Fannin County, Texas,
Savoy Pit 4 miles south of Savoy on farm road 1752, then east three-quarters
of a mile on unpaved road.

UT 40092-6, whole fish, basal Austin Chalk, Grayson County, Texas west of farm
road 1417 where it passes radar tower of Perry AFB.

SYSTEMATIC DESCRIPTION

Subdivision Teleostei (sensu ir'atterson, 1975)
Order incertae sedis
Family Crossognathidae Patterson and Rosen, 1977
Genus Apsopelix Cope, 1871

Apsopelix Cope, 1871, p. 424; Jordan, 1924, p. 230, pi. XX; Dunkle, 1958, p. 271.
Type species: A. sauriformis (monotypy).

Syllaemus Cope, 1875, p. 180; Stewart, 1900, p. 384, pi. LXXII fig. 2; Woodward,
1901, p. 350; Cragin, 1901, p. 26, pi. I; Woodward, 1903, p. 88, pi. XX, pi. XXI
figs. 1-2; Chabanaud, 1930, p. 646, pi. LXVIII; Green, 1957, p. 40, figs. 1-2;
Wenz, 1965, p. 13, figs. 3-5, pi. II. Type species: S. latifrons (monotypy).

Pelycorapis Cope (not Cope, 1874), 1877, p. 587. Type species: Thrissopater varius
(monotypy).

Leptichthys Stewart, 1890, p. 78; Stewart, 1900, p. 372, pi. LXXII fig. 1; Jordan,
1924, p. 231, pi. XXI. Type species: L. agilis (monotypy).

TELLER-MARSHALL & BARDACK: APSOPELIX 5

Helmintholepis Cockerell, 1919, p. 176, pi. XXXII, fig. 4. Type species: H.

vermiculatus (monotypy).
Paleoclupea Dante, 1942, p. 340, figs. 1-4. Type species: P. dakotensis (monotypy).

Diagnosis. — Teleost fishes in which the trunk is fusiform, and
head length about equal to greatest depth. Head tapers ventrally.
Orbit diameter 25-30 per cent head length, nearly equal in
length to ethmoid region; sclerotic ring ossified, snout pointed.
Rostral fused with underlying mesethmoid, shield-like anteriorly
with paired splints passing back below frontals. Cranial roof arched
transversely with a median depression where frontals meet
parietals; parietals wider than long, medially united. Roofed post-
temporal fossae confluent above cranial vault, extending forward to
orbitosphenoid; deep dilatator and subtemporal fossae; or-
bitosphenoid forms vertical plate across upper third of orbit;
basisphenoid present; parasphenoid forms angle at ascending wings
and extends posteriorly beyond braincase. Occipital condyle formed
by basioccipital and exoccipitals. Hyomandibular vertical with
posteriorly directed fossa below neurocranial head. Palate with
ossified processes which meet lateral and median ethmoid elements.
Lower jaw articulation lies beneath anterior third of orbit. Premax-
illa about one-tenth of upper jaw; maxilla arcuate, about eight times
longer than maximum depth; two supramaxillae. Coronoid height of
mandible contained 21/2 times in mandible length. Angular and ar-
ticular fused, retroarticular distinct. Parasphenoid toothless.
Basihyal with a pair of tooth plates; gill rakers long and slender. No
bone-enclosed ethmoid commissure; preopercular and infraorbital
sensory canals with short, bone-enclosed branches; lateral line con-
spicuous. Dermosphenotic and supraorbitals large; antorbital near-
ly covers ethmoid region; posterior infraorbitals extend to
preopercular, no suborbitals. Preopercular expanded ven-
troposteriorly with radiating ridges on expanded surface; oper-
culum and suboperculum smooth, about equal in size. Scales
cycloid, 10-12 rows on one side at midbody; height of exposed por-
tion of each scale about twice its length. About 40 preural centra,
about 12 caudal centra; each centrum with a single lateral ridge,
neural arches fused to all but anterior centra; epineural, epipleural,
and epicentral intermusculars present. Pectoral fins with about 15
rays; pelvic fins abdominal with at least 12 rays, pelvic bone broad-
ly expanded. Dorsal fin with at least 13 rays, originating about mid-
way between snout and posterior end of body; anal fin short and
very close to caudal origin; caudal fin deeply forked with narrow

6 FIELDIANA: GEOLOGY, VOLUME 41

base; fin rays cross hypurals at steep angle. Uroneurals modified
posteriorly, anterior uroneurals cover lateral faces of ural and first
two preural centra.

Apsopelix anglicus (Dixon)

Calamopleurusy anglicus Dixon, 1850, p. 375, pi. XXXII, figs. 11-12.

Apsopelix sauriformis Cope, 1871, p. 424; Jordan, 1924, p. 230, pi. XX; Dunkle,
1958, p. 271.

Syllaemus latifrons Cope, 1875, p. 181; Stewart, 1900, p. 384, pi. LXXII, fig. 2;
Woodward, 1901, p. 351; Cragin, 1901, p. 27, pi. I.

Pelycorapis berycinus Cope, 1877, p. 587.

Calamopleurus anglicus Woodward, 1888, p. 324.

Leptichthys agilis Stewart, 1899, p. 78; Stewart, 1900, p. 372, pi. LXXII, fig. 1;
Jordan, 1924, p. 231, pi. XXI.

Syllaemus anglicus Woodward, 1901, p. 351; Woodward, 1903, p. 89, pi. XX, pi. XXI
figs. 1-2; Chabanaud, 1930, p. 646, pi. LXVIII.

Helmintholepis vermiculatus Cockerell, 1919, p. 176, pi. XXXII, fig. 4.

Paleoclupea dakotensis Dante, 1942, p. 340, figs. 1-4.

Syllaemus hanifii Green, 1957, p. 40, figs. 1-2.

Syllaemus albiensis Wenz, 1965, p. 13, figs. 3-5, pi. II.

Diagnosis.— As for genus, only species. Proportions (as a percen-
tage of standard length): head length 23-25, greatest depth 23-25,
prepectoral 28-29, prepelvic 71-75, predorsal 41-42, preanal 81-83.

Description.—

General features: The head is triangular in lateral view with
the posterior border being gently curved. Dorsally the head forms a
relatively broad, flat surface and tapers * entrally. Maximum head
depth behind the lower jaw articulation equals about 65 per cent of
the head length. Diameter of the orbit is slightly less than the preor-
bital distance and represents about 30 per cent of the head length.
The jaw articulation lies beneath and slightly anterior to the middle
of the orbit. Three specimens preserved in three-dimensional form
probably closely retain the original shape of the fish. Examination
of these suggests that the body was deeper than wide, ovoid in
cross-section (at least at mid-body), and somewhat wider ventrally
than dorsally. Scales with their exposed area twice as high as long
cover the body. Both the pectoral and pelvic fins insert ventrally.

'Calamopleurus was founded by Agassiz on fragments of an entirely different fish
from the Upper Cretaceous of Brazil. See Woodward, 1903, p. 89.

TELLER-MARSHALL & BARDACK: APSOPELIX

Epo

O

', I

V

n

•;v

Soc

,Asp

Pto

Fig. 1. Apsopelix anglicus, dorsal view of the neurocranium. For abbreviations see
p. 30.

Pelvic fins are abdominal, the dorsal and anal fins are short. The
caudal fin is slender and deeply forked.

NEUROCRANIUM (figs. 1-5): The neurocranium is 2V2 times as long
as deep; its maximum width across the pterotics equals nearly

8 FIELDIANA: GEOLOGY, VOLUME 41

three-fourths the total neurocranial length. The postorbital part of
the braincase is short, accounting for less than one-third of the total
neurocranial length. Maximum neurocranial depth occurs just
behind the orbit.

The posttemporal fossae (fig. 3, ptf), subtemporal fossae (fig. 3,
stf), and dilatator fossae (fig. 3, df) are well developed. The posttem-
poral fossae are confluent above the cranial vault and extend well
forward, probably to the orbitosphenoid. As in megalopids, the ver-
tical depth of these fossae has resulted in a pronounced convexity of
the skull roof in the otic region. In posterior view (fig. 4) the
neurocranium slopes ventrolateral^ from the midline so that its
dorsal surface describes an arc of 130° around an axis at the middle
of the basioccipital.

The frontals (fig. 1, Fr) are flat sheets of bone, narrow anteriorly,
then widening gradually to contact the parietals and pterotics
posteriorly. The frontals are joined by a straight suture and form a
median depression in the cranial roof (fig. 1) just anterior to the
fronto-parietal juncture. Each frontal shows a line of irregularly
shaped ridges and pits marking the path of the supraorbital sensory
canal. These lines diverge anteriorly.

The parietals (figs. 1-2, Pa) meet in the dorsal midline at a wavy
suture. They are wider than long and taper laterally, extending
more than half the distance from their joint suture to the lateral
edge of the cranial roof. They are also marked with ridges and pits,
including a prominent, centrally located pit line (fig. 2, apl).

Each pterotic (figs. 1-4, Pto) forms the dorsolateral corner of the
neurocranium and makes up the lateral wall plus part of the dorsal
and ventral walls of the posttemporal fossa. In dorsal view the der-
mopterotics meet the frontal, parietal, and epioccipital with ir-
regularly shaped sutures. The lateral surface of the autopterotic is
deeply excavated to form, along with the autosphenotic, the
dilatator fossa. This fossa is roofed by the frontal and more
posteriorly by a lateral extension of the dermopterotic. Beneath this
fossa, the hyomandibular facet (fig. 3, fhm) slopes anteroventrally
and continues forward onto the autosphenotic. The facet is slightly
constricted midway along its length. Beneath the hyomandibular
facet is a deep subtemporal fossa (fig. 3, stf), its long axis sloping
anteroventrally. The autopterotic forms the roof of this fossa.

The epioccipitals (figs. 1, 4, Epo) are visible in dorsal and posterior
views. They contact the parietals anteriorly, the supraoccipital

TELLER-MARSHALL & BARDACK: APSOPELIX

Fig. 2. Apsopelix anglicus, dorsal view of the posterior third of the neurocranium.
For abbreviations see p. 30.

medially, and the pterotics laterally. The dorsal surface of each
epioccipital tapers and is produced posteriorly over the dorsomedial
corner of the posttemporal fossa. The epioccipitals are covered dor-
sally by large supratemporals (fig. 2, Stt). A transverse groove
along the anterior margin of the epioccipitals and supraoccipital
marks the line of contact between the supratemporals and
neurocranium. In posterior view the epioccipitals contact the
supraoccipital medially and the exoccipitals ventrally. In this view
they are square-shaped, with the lateral margin and ventrolateral
corner thickened to form a rounded ridge (fig. 4). This ridge con-
tinues onto the exoccipital. The epioccipitals contribute to the dor-
somedial and most of the medial wall of the posttemporal fossa.

The supraoccipital (figs. 1, 4, Soc) is visible in dorsal and posterior
views. Dorsally it is wider than long and exhibits a small, median,
posteriorly directed prong. In posterior view it is pentagonal, and
about as deep as wide. Together with the exoccipitals, the supraoc-
cipital is gently concave in posterior view.

The exoccipitals (figs. 3, 4, Exo) each exhibit a triradiate set of

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TELLER-MARSHALL & BARDACK: APSOPELIX

11

Soc

Pto

Fig. 4. Apsopelix anglicus, posterior view of the neurocranium. For abbreviations
see p. 30.

rounded ridges in posterior view. The dorsally directed ridge is
sutured to a ventrolateral^ thickened arm of the epioccipital. The
laterally directed ridge meets the intercalar and autopterotic where
these bones form the floor of the posttemporal fossa, while the ven-
tromedially directed ridge contacts the basioccipital and con-
tributes to the occipital condyle. Lateral to the foramen magnum is
the foramen for the vagus nerve trunk (fig. 4, X), while the
glossopharyngeal nerve trunk probably emerged through one of the
numerous foramina on the posterolateral surface of the exoccipital
(fig. 3); the remainder of these foramina probably carried blood
vessels and the supratemporal branches of IX and X.

The intercalars (figs. 3, 4, Ic) are small and barely visible in
posterior view. Each does, however, extend forward to meet the
prootic along the margin of the subtemporal fossa.

The basioccipital (figs. 3, 4, Boc) lies beneath the exoccipitals and
is covered laterally by the parasphenoid. In lateral view the surface
of the basioccipital is concave. These depressions may have housed
anterior extensions of the swimbladder.

The prootics (fig. 3, Pro) are deeper than long in lateral view and

12 FIELDIANA: GEOLOGY, VOLUME 41

expanded dorsally to meet the autopterotics, autosphenotics, and
pterosphenoids. Ventrally each prootic forms a thin sheet overlap-
ped laterally by ascending wings of the parasphenoid. There is a
slender, posteriorly directed arm which forms the ventroposterior
wall of the subtemporal fossa and contacts the intercalar, while the
main body of the prootic contributes to the anterior wall of this
fossa. Ventral to the base of this posteriorly directed arm is the
foramen for posterior exit of the lateral head vein (fig. 3, fhv). More
anteriorly on the lateral surface of the prootic are two additional
foramina for the orbitonasal artery and palatine branch of VII (fig.
3, foa; fpal VII) and for the hyomandibular branch of VII (fig. 3, fhm
VII). The anterior surface of the prootic shows a triangular pattern
of foramina of equal size; two lateral foramina mark the exit of the
trigeminal nerve and the anterior exit of the lateral head vein, while
the more medial foramen marks the exit of the oculomotor nerve.

The autosphenotics (fig. 1, 3, Asp) are triangular in dorsal view,
rectangular in orbital view, and produced laterally to a prominent
spine. The dorsal and posterior surfaces are concave, while the or-
bital surface is nearly flat and vertical. This latter face is pierced by
a foramen for the otic branch of the facial nerve. Behind the spine a
pocket on the posterior face of the autosphenotic (fig. 3, flap),
oriented more ventrally than horizontally, probably marks the
origin of part of the levator arcus palatini (cf. Forey, 1973a, p.
1,308). The dorsal surface of the autosphenotic contributes to the
dilatator fossa (fig. 3, df).

The pterosphenoids (fig. 3, Pts) are anteriorly facing sheets which
form the margin of the optic foramen with their medial edges.
Lateral and dorsal to the optic foramen is a small opening within
each pterosphenoid probably for the trochlear.

The orbitosphenoid (fig. 3, Ors) extends forward in front of the
pterosphenoids. It is a vertical sheet of bone longer than deep and
extending more than half the distance to the anterior margin of the
orbit. The dorsal part of this sheet is enlarged where the olfactory
tract lay, and a foramen at the anterior end of the bone marks the
exit of this tract.

The basisphenoid is Y-shaped in orbital view; the upper arms of
the Y form a gentle yolk shaped edge, and the vertical stem of the Y
is longer than the arms. The stem contacts the parasphenoid below,
while the arms touch the prootics and pterosphenoids above.

The parasphenoid (fig. 3, Par) forms an obtuse angle beneath its

TELLER-MARSHALL & BARDACK: APSOPELIX

13

Fig. 5. Apsopetix anglicus, dorsal view of the ethmoid region showing the rela-
tionships of the median ethmoid (Me), palatine process (pme), and maxilla (Mx).
For abbreviations, see p. 30.

junction with the prootic. Anteriorly it is a slender, triangular strut
deeply cleft for receipt of the vomer. Behind the point where the
ascending wings of the parasphenoid meet the prootics, the
parasphenoid deepens, increasing the size of the posterior
myodome, and extends ventrally as an elongated process which
passes beneath and posterior to the basioccipital. The parasphenoid
appears to be toothless.

The ethmoid region is well ossified. It consists of a single dorsal
median ethmoid (figs. 1, 5, Me), probably the result of fusion be-
tween a smooth dermal rostral and the underlying peri and en-
dochondral ossifications (see Patterson, 1970 for a discussion of the
ethmoid region and Nelson, 1969, p. 8 regarding use of the word
"fusion"). There is a narrow ventral vomer and a pair of stout lateral
ethmoids (fig. 3, Le) which form the anterior boundary of the orbit.

The posterior extent of the vomer could not be determined direct-
ly; however, KU 882 shows a ventral cleft between anterior arms of
the parasphenoid presumably occupied by the vomer. This cleft
disappears beneath the middle of the orbit, but it was filled by
matrix posteriorly so that it is likely that the ossified vomer extend-
ed only as far as the posterior edge of the ethmoid region. Patterson

14 FIELDIANA: GEOLOGY, VOLUME 41

and Rosen (1977) cite a partially paired vomerine tooth patch in
Apsopelix, but none of the specimens examined in this study show
evidence of vomerine teeth.

The median ethmoid bifurcates posteriorly, each half tapering
beneath the frontals. Anterior to the bifurcation the ethmoid
widens, extending anteroventrally to abut on either side against a
dorsally directed process from the palatine (figs. 5-6, pme). The most
anterior part of the ethmoid is narrow and biconcave to receive the
anterior ends of the maxillae. There is no evidence of a bone enclosed
ethmoid commissure.

The lateral ethmoids are set back some distance from the median
ethmoid since the ethmoid region at least equals the orbit in length.
Anteriorly, the lateral ethmoid forms the posterior wall of the nasal
capsule, then increases in depth toward the orbit, spanning the
distance between the frontal above and the parasphenoid below. A
small depression on the posterior surface of the lateral ethmoid, at
the ventrolateral corner, receives a dorsal process from the palate
(fig. 6, pie).

HYOPALATINE SERIES (figs. 5-7): Elements of the hyopalatine
series are similar in their relationships to those of other lower
teleosts, but some of the bones have distinct characteristics. Each
hyomandibular (fig. 6, Hm) is vertical with an expanded
neurocranial head. The narrow shaft has a groove along its anterior
edge. The medial side of this groove extends forward as a thin sheet
of bone. Just below the neurocranial head is a large posterior fossa
which contained the origin of the dilatator operculi. In front of this
fossa are numerous small foramina.

Forey (1975, pp. 170-172, fig. 12) has contrasted the hyoman-
dibular architecture and muscle origins in Elops and two
clupemorphs. As far as the levator arcus palatini and the dilatator
operculi are concerned, the skeletal features of Apsopelix indicate
that the muscle arrangements probably differed from that in Elops
and other early teleosts. But the arrangement of these muscles in
Apsopelix was not as in clupeomorphs either, since in Apsopelix the
dermosphenotic is large, there is no ridge on the frontal, and no
anterodorsal process on the hyomandibular (cf. Forey, 1975, fig.
12b).

In Apsopelix there appears to have been a shift of at least part of
the dilatator operculi to an origin on the hyomandibular, freeing the
posterior edge of the autosphenotic for origin of levator arcus

TELLER-MARSHALL & BARDACK: APSOPELIX

15

Fig. 6. Apsopetix anglicus, right hyopalatine series in lateral view. For abbrevia-
tions see p. 30.

palatini fibers in order to meet the demands of a microphagous
feeding mode that requires complex movements and increased effi-
ciency of the palate abductors. So, while both Apsopelix and
clupeomorphs exhibit morphological adaptations associated with
the microphagous feeding mode, the adaptations of Apsopelix differ
from those of clupeomorphs and are not indicative of a close rela-
tionship.

Between the shaft and the anterior bony sheet of the hyoman-
dibular are two foramina, one of which probably marks the exit of
the mandibular and preopercular branches of the facial nerve (fig. 6,
fmp VII).

The metapterygoid (fig. 6, Mpt) is an elongate bone, saddle-
shaped where its anterior edge overlaps the endopterygoid (fig. 6,
Enpt). Posteriorly the metapterygoid joins the lower portion of the
hyomandibular, but the suture is difficult to follow. The ventral
edge of the metapterygoid lies along the dorsal border of the
quadrate. Each ectopterygoid (fig. 6, Ecpt) is boomerang-shaped
and lies along the anterior edge of the quadrate. It then curves
anteriorly, continuing along the lateral edge of the endopterygoid
(fig. 6, Enpt). None of the pterygoid elements appear to bear denti-
tion.

16

FIELDIANA: GEOLOGY, VOLUME 41

The anterior part of the palate shows no sutures on the specimens
examined and there is some difficulty determining whether the
lateral ethmoid process of the palate (fig. 6, pie) stems from the
posterior part of the palatine as in Albula vulpes (Forey, 1973b, fig.
79) or from the anterior part of the ectopterygoid as in Clupea
harengus (Kirchoff, 1958, figs. 11, 15, 16).

The palatine (fig. 6, Pal) is well ossified throughout its length and
bears an anterior process (figs. 5-6, pme) which extends between the
median ethmoid and the maxilla. This process is fused to the
palatine in FMNH PF7463. It appears to be a separate ossification
in USNM 16725, but it is intimately associated with the der-
mopalatine and is not an ethmoid element (cf. Wenz, 1965, fig. 3).
This same process is an ossification of the autopalatine in Albula
vulpes. SMM 7958 shows a number of conical teeth on the palatine;
these teeth are larger than the similarly shaped teeth on the jaw
elements.

The quadrate (fig. 6, Qu) is broadly expanded dorsally to meet the
pterygoids. Posteriorly it bears a deep, broad notch for the symplec-
tic (fig. 6, Sy). The quadrate condyle lies beneath the orbit. Behind
the condyle a notch in the quadrate receives the postarticular pro-
cess of the angular (fig. 7).

Upper jaw (figs. 5, 8): The upper jaw consists of a premaxilla,
maxilla, and two supramaxillae. A premaxilla has never been
described in Apsopelix. Of the specimens examined in this study on-
ly one, KU 18, retains a fragment of it. A small, laminar bone, it
bears minute acuminate teeth. The premaxilla probably fits into a
notch at the anterior end of the maxilla (fig. 5), but its true extent
and shape remain unknown.

Rart?

Fig. 7. Apsopelix anglicus lateral (left) and medial (right) views of the lower jaw
articulation. For abbreviations see p. 30.

TELLER-MARSHALL & BARDACK: APSOPELIX 17

The maxilla (figs. 5, 8, Mx) extends from beneath the anterior end
of the orbit forward to articulate with the median ethmoid. It is a
sabre-shaped bone, nearly uniform in depth throughout its length,
and about 12 times longer than deep. Dentition consists of a single
row of minute marginal teeth similar to those on the premaxilla, 0.5
mm. from base to tip in FMNH PF 7463.

The anterior supramaxilla (fig. 8, Smx 1) is the longer of the two.
Neither of these bones bears an anterior projection as in many other
lower teleosts, but rather the posterior supramaxilla barely overlies
its anterior partner. UT 31051-7 is preserved with the mouth open
and shows that the supramaxillae do not separate as much as in
clupeoids, but tend to function as a unit. Both supramaxillae exhibit
rugose ornamentation along their entire length and are as deep as
the maxilla at their deepest point.

Lower jaw (figs. 7-8): The lower jaw is short and deep. Maximum
depth is between one-third and one-half total length and occurs
about midway along this length. The ventral margins of both the
dentary (figs. 7-8, Den) and angular (figs. 7-8, Ang) curve medially to
form a narrow shelf marked with pores for the mandibular sensory
canal. The number of these pores is uncertain, but there appear to be
at least two on the posterior part of the dentary and one on the
angular. Mandibular dentition consists of a single row of minute
teeth, like those on the maxilla, along the dentary margin.

The dentaries meet in a short anterior symphysis without curving
much inward. Each dentary receives the angular in a deep posterior
notch and extends back above and below it (fig. 7). A postarticular
process of the angular extends behind the facet for the quadrate
condyle, although this structure is broken off easily and is missing
in all but one of the specimens examined, KU 318.

There is a small, distinct retroarticular visible in KU 318, USNM
16725, and UT 40092-26. Whether this element takes part in or is
excluded from the articular facet could not be determined from
these specimens. The medial surface of the angular shows a pocket
filled by what appears to be an articular in KU 318 (fig. 7, Art). Pat-
terson and Rosen (1977) state that in BMNH 47302 the mandibular
sensory canal opening is in the medial position, the angular and ar-
ticular are fused, and the retroarticular is free except on the surface
of the facet for the quadrate where all three bones appear to be
fused.

18 FIELDIANA: GEOLOGY, VOLUME 41

Hyoid and branchial ARCHES: Some elements of the hyoid and
branchial arches are preserved in FMNH PF 7463, including one
anterior ceratohyal, hypohyals, basihyal, the anterior epibranchials
and ceratobranchials, one hypobranchial, and one basibranchial.
The anterior ceratohyal is rectangular with a gently concave ventral
edge and a centrally located foramen. Two equally developed
hypohyals meet the anterior edge of the ceratohyal.

The basihyal ossified only posteriorly. A pair of tooth plates lies
on its oral surface and extends forward beyond the ossified element.
Each tooth plate is about one-fifth as wide as long and covers the
lateral third of the basihyal, leaving the center of that bone without
teeth. There are 10 longitudinal rows of small, posteriorly directed
tooth bases per tooth plate. The basihyal is the only element of the
hyoid series with dentition preserved. Along the oral edge of the
epibranchials and ceratobranchials are a series of gently curved gill
rakers, about 8 mm. in length. There are no tooth plates present on
any of the branchial arches.

Impressions of 12 branchiostegal rays are present in UT 31051-7,
but the irregular nature of the spaces between these grooves in-
dicates that there were more rays.

Dermal bones of the cheek (fig. 8): The infraorbitals are
preserved in FMNH PF 7463 and USNM 16725. There is a large an-
torbital followed by at least three distinct infraorbitals plus a der-
mosphenotic. The postorbital components of this series extend back
as far as the preoperculum.

The antorbital (fig. 8, Ao) is wedge shaped, expanded posteriorly,
and tapering to a blunt anterior edge. There are two
anteroposteriorly oriented grooves on the antorbital, the lower
probably associated with the infraorbital sensory canal as it entered
the antorbital, while the more dorsal probably housed the antorbital
branch of that canal. The dorsal edge of the antorbital overlaps the
first supraorbital.

The infraorbitals are so fragmented that it is difficult to deter-
mine their exact number. The primitive condition of the teleostean
infraorbital series probably included seven separate bones from the
antorbital to the dermosphenotic (Nelson, 1969). There appears to
have been a reduction in the number of infraorbital bones in Ap-
sopelix. However, there is some question as to where the implied fu-
sion has occurred. Wenz (1965, fig. 5, p. 18) figured Apsopelix with
an antorbital plus five infraorbitals, including the dermosphenotic.

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19

20 FIELDIANA: GEOLOGY, VOLUME 41

There is a large infraorbital covering the posteroventral region of
the cheek and marked by several branches of the infraorbital sen-
sory canal. Above this largest bone in the series are figured two
more bones plus the dermosphenotic, implying that the large bone is
a fusion of the infraorbitals 2 + 3.

In USNM 16725 and FMNH PF 7463, the large infraorbital
covering the posteroventral area of the cheek and marked by
branches of the infraorbital sensory canal is easily recognized, but
there appears to be only one additional bone (fig. 8, Io5) between the
large infraorbital and the dermosphenotic, implying that the large
element is a fusion of Io 2 + 3+4. If Wenz's (1965) interpretation is
correct, then it is possible that the element referred to in our paper
as Io5 is actually a fusion of Io 4+5.

The dermosphenotic is an elongate, triangular bone overlying the
autosphenotic and covering the dilatator fossa. It is smooth where
it meets the infraorbitals, but ornamented with ridges and pits
where it contacts the frontal. This ornamentation marks the
meeting of the temporal and infraorbital canal. The infraorbital sen-
sory canal traverses a path through the center of the infraorbital
bones.

There is at least one long, anteriorly expanded supraorbital (fig. 8,
SO 1) and possibly a second, smaller supraorbital evident only in
USNM 16725. The first supraorbital covers the anterior margin of
the orbit posteriorly and extends forward medial to the antorbital.
The second supraorbital (fig. 8, SO 2) spans the distance between
the posterior edge of the first supraorbital and the anterior edge of
the dermosphenotic.

The nasal is a small, rod-shaped bone (fig. 8, Na) above and
anterior to the first supraorbital in USNM 16725. It is in line with
the anterior part of the supraorbital sensory canal on the frontal and
shows evidence of a bone enclosed canal. The nasals appear to taper
anteriorly, but this could be an artifact of preservation.

Opercular series (fig. 8): The preoperculum (fig. 8, Pop) ex-
pands ventraliy from a relatively narrow dorsal end. The surface of
the expanded portion is marked by radiating ridges which end
posteriorly as fine lines, each ridge giving rise to about four lines.
Pores of the preopercular sensory canal are evident along the
anterior margin of these radiating ridges. The sensory canal does
not run along the anterior margin of the bone, but rather through its
center, particularly at the angle (cf. Forey, 1973b, Elops, fig. 6, p.
19).

TELLER-MARSHALL & BARDACK: APSOPELIX 21

The operculum (fig. 8, Op) is smooth and without ornamentation.
Its width is contained in its length 1 Vb times. It has a gently curved
posterior border, and is barely overlapped anteriorly by the preoper-
culum. The suboperculum (fig. 8, Sop) is also smooth and about the
same size and shape as the operculum. Most of its surface is covered
by the expanded ventral portion of the preoperculum. The interoper-
culum is covered by the preoperculum except for its ventral edge. It
is about as long as the suboperculum.

Scales (fig. 10): The scales are large and cycloid. Faint
anteroposteriorly oriented folds and closely spaced circuli are visi-
ble on the exposed surface. A complete scale is longer than deep, the
deepest portion being posterior to the center. There are 10-12
longitudinal rows of scales present on each side. The sixth
transverse row from the dorsal fin carries the lateral line, which con-
sists of a series of simple tube-like openings. Dunkle (1958, pp.
269-270) discussed the scales of Apsopelix in detail.

Paired fins and their supports (figs. 2, 9, 10): The paired fins
are in the primitive position for teleosts, the pectorals inserting low
on the flank and the pelvics set back in the abdominal region. There
are at least 15 rays on the broad-based pectoral fins and at least 12
rays on the pelvic fins (fig. 10).

The supratemporals (fig. 2, Stt) are scale-like sheets of bone which
overlap the supraoccipital, epioccipitals, and pterotics in dorsal
view. Their anterior surface has coarse rugae which follow the path
of the supratemporal commissure and its posteriorly directed
branches. The supratemporals meet only at their anterior edges on
the dorsal midline.

The posttemporals (fig. 2, Ptt) and supracleithra are rod-shaped
bones. The supracleithrum is longer than the posttemporal. The
lateral line traverses the posttemporal near its posterodorsal
margin along the anterior half of its length. The supracleithrum
overlaps a considerable portion of the cleithrum, and reaches the
level of the ventral margin of the orbit ventrally.

Each cleithrum curves anteroventrally and medially around the
gill chamber and meets its complement in the ventral midline just
anterior to this chamber. The lateral surface of the cleithrum is ex-
panded above the pectoral fin and there appears to be at least one
scale-like postcleithrum just above the pectoral fin base.

Only the posterior end of the scapula has been observed; it has a
rounded ridge which forms a point of attachment for the first pec-

22

FIELDIANA: GEOLOGY, VOLUME 41

Fig. 9. Apsopelix anglicus, ventral
view of right pelvic plate. A = anterior;
M= medial.

M

toral ray and the first radial. The coracoid contacts the medial edge
of the scapula posteriorly and the inner face of the cleithrum more
anteriorly. Where the coracoid meets the scapula it forms a ridge
continuous with the scapular ridge and supports the majority of the
fin rays via the remaining radials.

The coracoids meet in the ventral midline to form a median ven-
tral keel. This keel extends forward, but does not reach the cleithral
symphysis. Posteriorly the keel extends back beyond the scapula-
coracoid ridge. The mesocoracoid extends dorsally from its basal
contact with the scapula and coracoid, forming an arch. Its dorsal
end touches the medial surface of the cleithrum. There are four
radials, the most medial being longest. They are simple struts,
slightly expanded at their distal ends.

The prepelvic distance is about three-fourths of the standard
length. Each pelvic fin is attached to a long, broad triangular pelvic
bone (fig. 9) which extends anteriorly from the origin of the fin for a
distance of about four abdominal vertebrae. There is a thickened
ridge along the posterior edge of each pelvic bone. The two bones
meet in a median symphysis along the ventral midline. This
massive, broad pelvic bone is charactertistic of Apsopelix.

TELLER-MARSHALL & BARDACK: APSOPELIX 23

Median fins (fig. 10): Of those specimens studied in which the
whole fish is preserved, the ventral surface is exposed and the body
twisted. The preservation of the median and caudal fins is poor. KU
309, KU 519, and SMM 7958, in which the dorsal fin is preserved,
and UT 31051-7, in which the anal fin is preserved, show the best
median fin preservation of the specimens examined in this study.

The dorsal fin is short, with about 11-12 rays, the longest being
most anterior. The predorsal length is about 40 per cent of the stan-
dard length. The first dorsal ray is the longest and most robust.

The anal fin of Apsopelix is short and the preanal length is about
four-fifths of the standard length. UT 31051-7 shows a few anal
rays, but otherwise this fin is not known in Apsopelix apart from
Cope's (1871) original description of AMNH 1602. Only the first
anal ray is preserved in UT 31051-7, but examination of photos of
AMNH 1602 show the anal fin with 10-12 rays.

The caudal fin is deeply forked, with a narrow base. The number of
branched principal rays appears to be nine above and eight below,
but such counts are difficult to obtain in the specimens examined
and may be in error.

Vertebral column and caudal skeleton (fig. 10): There are
about 40 preural centra; nearly 30 are abdominal. The centra are
longer than deep, somewhat constricted at their centers, and pierced
for passage of the notochord. Each centrum is marked by a single
lateral ridge.

The neural arches of the anteriormost centra are autogenous, but
otherwise they appear to be fused with the centra as are the haemal
arches. Pleural ribs are associated with at least 20 centra, being ab-
sent from the first few vertebrae, but the nature of the rib articula-
tions has not been preserved in the specimens examined. KU 18
shows numerous intermuscular bones. Above the pleural ribs are
epipleural intermusculars which are forked anteriorly. Epipleurals
also appear to be associated with haemal arches as far back as the
36th centrum. There appear to be short, straight epicentral inter-
musculars associated with the more anterior abdominal centra.
Anteriorly forked epineural intermusculars are associated with the
neural arches as far back as the 36th centrum.

The quality of caudal preservation in Apsopelix specimens is
generally poor. It is fragmentary at best in the North American
specimens, but Patterson and Rosen (1977) state that enough of it is
visible in AMNH 8330 and in several British Museum specimens to

0

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24

TELLER-MARSHALL & BARDACK: APSOPELIX 25

show that it is almost identical with that of Crossognathus (cf. Pat-
terson and Rosen, 1977, fig. 21, p. 114), differing only in having the
neural and haemal spines more strongly inclined and pressed
together plus increased hypurostegy so that the proximal ends of
the upper and lower principal rays almost meet. When compared
with Patterson and Rosen's figure of the caudal skeleton of
Crossognathus, the fragmentary caudal material from KU 309, KU
519, SMM 7958, and UT 31051-7 supports their conclusions.

In Apsopelix uroneurals 1 and 2 extend forward to the second
preural centrum and the third uroneural extends forward to the first
preural centrum. There are, in addition to these elongate uroneurals,
a posterior set of shorter uroneurals, although the exact number
cannot be determined in the specimens examined. There are more
than six hypurals, but the exact number is uncertain. (There are
nine hypurals in Crossognathus.). The first and second hypurals are
fused or partly fused in all of the specimens examined for this study.
The parhypural is fused to the first preural centrum. It and the
haemal spines of PU^ and PU3 are broadly expanded. According to
Patterson and Rosen (1977), there are caudal scutes present in
Crossognathus. There is no evidence of caudal scutes in the North
American specimens of Apsopelix examined in this study.

DISCUSSION

A number of distinctive morphological features in Apsopelix (the
large scales, antorbitals and pelvic bones, the form and proportion
of the dermal upper jaw elements, the arrangement and ornamenta-
tion of the cranial roof bones) have facilitated identification and the
proper assignment of specimens previously described as Syllaemus,
Pelycorapis, Leptichthys, Helmintholepis, and Paleoclupea.
However, these features along with nearly all others known in Ap-
sopelix have little value as clues to the position of this genus among
the teleostean fishes. It exhibits a host of characters primitive for
teleosts, a few characters which seem to be unique to the genus Ap-
sopelix (posteriorly directed fossa on the hyomandibular, premaxilla
so reduced as to be nearly lost, basihyal with a pair of tooth plates
along its lateral margins only, antorbital which nearly covers the
ethmoid region, broadly expanded pelvic bone), and no suite of
characters that unequivocally indicate to which major teleost group
it is most closely related.

Of the major teleost groups, it is least likely that Apsopelix 's rela-
tionships are to be sought among the euteleosts. It was placed

26 FIELDIANA: GEOLOGY, VOLUME 41

within the Percesoces1 (Woodward, 1901) and Mugilidae (Stewart,
1900) on the mistaken assumption that the major element of the up-
per jaw was a premaxilla. Apsopelix shares none of the specializa-
tions unique to euteleosts (Patterson, 1970; Nelson, 1973a; Patter-
son and Rosen, 1977).

Certain features present in Apsopelix were thought by previous
investigators (Stewart, 1900; Woodward, 1903, 1907; Jordan, 1923;
Chabanaud, 1930; Berg, 1940) to be indicative of a relationship with
clupeomorphs. These include: 1) laterally compressed body, 2) form
and position of fins, 3) features associated with microphagous
feeding (reduced dentition on the dermal jaws; short, deep lower
jaw; curved maxilla with a flat articular head; large, mobile
supramaxillae; long gill rakers).

Character 1 has proved to be either an artifact of preservation or
an error of interpretation. Three-dimensionally preserved specimens
of Apsopelix indicate that the body of this fish was ovoid or even
pear-shaped in cross-section. This hypothesis is reinforced by the
fact that the flattened specimens have been dorsoventrally com-
pressed. A laterally compressed fish would be more likely to come to
rest on its side and be preserved laterally compressed rather than
dorsoventrally compressed as is the case in Apsopelix.

Character 2, the form and position of the fins, is present in Ap-
sopelix, clupeids, and engraulids. It is also present in elopids,
albulids, and (with the addition of the adipose fin) salmonids,
osmerids, and other lower teleosts. Thus, the form and position of
the fins is an adaptation to mode of life and found in several
primitive teleost groups.

The third group of characters, those associated with
microphagous feeding, form a functional complex to facilitate a
feeding mode that developed a number of times in the course of
teleost evolution. Among living teleosts the epibranchial organ, a
structural adaptation to the microphagous feeding mode, has
developed independently in at least four lineages of teleosts (Nelson,
1967). So it is reasonable to assume that the occurrence of this
whole complex of characters, while valuable in reinforcing other
evidence of a relationship, is not by itself sufficient to prove a con-
nection between Apsopelix and clupeomorphs.

Until recently two characters previously unknown in Apsopelix,
the presence of epipleural intermusculars and a ventral keel on the

1See footnote, p. 3

TELLER-MARSHALL & BARDACK: APSOPELIX 27

parasphenoid coupled with the extension of this bone posterior to
the braincase, were also associated with clupeomorphs. Epipleural
intermuscular bones are found at least in some osteoglossomorphs
(Patterson, 1975) and the keeled parasphenoid is characteristic of
North American specimens of Pachyrhizodus, a genus which Forey
(1973b, 1977) associates with salmoniform euteleosts. Since these
characters are not exclusive to clupeomorphs, it is unlikely that
their presence in Apsopelix indicates clupeomorph affinities.

In summary, Apsopelix has been associated previously with
clupeomorphs on the basis of characters which can be shown to have
been erroneously described, plesiomorphic for teleosts, or con-
vergent. Derived characters shared by clupeomorphs include a
swim-bladder-ear connection involving penetration of the exoc-
cipital and prootic, a temporal foramen between the frontal and
parietal in the apex of the posttemporal fossa (Greenwood et al.,
1966), supratemporal commissure associated with the supraoc-
cipital (Patterson, 1970), a pleurostylar caudal skeleton (Green-
wood, 1968; Gosline, 1971; but see Forey, 1975), fusion of the
angular and articular with the exclusion of the retroarticular from
the articular facet (Nelson, 1973b), and fusion of tooth plates lb 1-3
and Cb 5 (Nelson, 1967). Apsopelix exhibits none of these characters
so its relationships lie elsewhere.

Wenz (1965) and Romer (1966) assigned Apsopelix to the
Elopoidei. Apsopelix shares a large number of primitive features
with living members of the elopiform fishes (see Forey, 1973b, pp.
187-189), but these characters are found in members of all major
teleost groups and are of no use in determining relationships. Pat-
terson and Rosen (1977) cite four shared, derived characters for the
cohort Elopomorpha: a leptocepholus larva, angular and retroar-
ticular bones fused, rostral and prenasal ossicles, and a compound
neural arch formed in cartilage over PU1 and Ul. The first character
is of no help in determining relationships of fossil fishes; the retroar-
ticular is not fused with the angular in Apsopelix, and no rostral or
prenasal ossicles are present in Apsopelix. The neural arches of the
first ural and first preural centra are not preserved in the North
American specimens of Apsopelix examined for this study, but in
the similar Crossognathus there are separate neural arches over Ul
and PU1.

Patterson and Rosen (1977) cite some resemblances between the
posttemporal fossae of Apsopelix and those of megalopids, but
state that in Apsopelix the condition is not precisely the same as in

28 FIELDIANA: GEOLOGY, VOLUME 41

recent megalopids. Other braincase similarities noted by Patterson
and Rosen include the large myodome, shape of the intercalar,
strongly ossified ethmoid region, and a deep pit in the lateral sur-
face of the posterior part of the basioccipital suggesting the
possibility of a simple otophysic connection.

None of these similarities is convincing. Differences in the forma-
tion of the posttemporal fossae between megalopids and Apsopelix
(see Patterson and Rosen, 1977 p. 132) suggest convergence of this
character. The enlarged myodome characteristic of Apsopelix and
megalopids generally occurs in conjunction with a deep
neurocranium and is not exclusive to megalopids. The intercalar of
North American specimens of Apsopelix does not resemble that of
Eocene megalopids (cf. figs. 3, 4 with Forey, 1973b, figs. 36, 37, 42,
43) as stated by Patterson and Rosen (1977). It is a proportionately
smaller bone in Apsopelix without the posterior expansion present
in Eocene megalopids. A heavily ossified mesethmoid is primitive
for teleosts (Patterson, 1970). Finally, it seems likely that an
otophysic connection per se must be looked upon as a primitive
teleostean character (Greenwood, 1973).

In summary, there are no derived characters of elopomorphs
shared with Apsopelix. Characters of the braincase shared by
megalopids and Apsopelix can be more reasonably explained as con-
vergent or primitive for teleosts, since the structure of the lower jaw
and caudal skeleton of Apsopelix opposes elopomorph relationships.
Thus, the probability of finding relationships of Apsopelix within
the elopomorphs fades.

Part of the problem in comparing Apsopelix to the
osteoglossomorphs is that this group is so diverse. Among those
derived characters which are known in at least some
osteoglossomorphs (see Greenwood et al., 1966, 1967; Greenwood,
1967, 1970, 1971, 1973; Nelson, 1968, 1969, 1972) there is only one
which appears to be shared with Apsopelix. That character, fusion
of Io 3 + 4 (Nelson, 1969), has yet to be firmly established as present
in Apsopelix. Given that there is a fusion of Io 3 + 4 in Apsopelix,
this character alone (found also in Chanos and cypriniformes) is not
sufficient to indicate a relationship.

One similarity between Apsopelix and at least some fossil
osteoglossomorphs could be the shape and disposition of the
premaxilla. Judging from the relationship of the maxilla to the me-
dian ethmoid in Apsopelix, the premaxilla probably overlapped the
anterior end of the maxilla and extended down over it to form the

TELLER-MARSHALL & BARDACK: APSOPELIX 29

anteriormost border of the upper jaw as in Ichthyodectes ctenodon
and Xiphactinus audax (see Bardack, 1965, fig. 16, p. 58, fig. 9, p.
45). These three fishes also share an ossified malleolar process on
the anterior end of the palatine, but this ossification appears to be a
response to a functional need and is also present in some members of
the elopiforms (Forey, 1973b).

This discussion has reviewed the four major teleost groups and
argued against assigning Apsopelix to any one of these groups. The
original hope of the authors was that more information concerning
the morphology of Apsopelix would facilitate the discovery of its
systematic relationships. The accumulation of this information has
instead precipitated arguments against a systematic assignment of
Apsopelix to any presently well-defined group.

In their analysis of the relationships of fossil and Recent teleosts,
Patterson and Rosen (1977) place Apsopelix with Crossognathus as
a nominal family incertae sedis within the group containing Tharsis
dubius and extant teleosts.

That is, Apsopelix shares with Tharsis dubius the three features it
exhibits which are synapomorphies with Recent teleosts,1 but does
not show any derived characters typical of a Recent teleost group.
We agree with Patterson and Rosen (1977) and feel that it is
preferable that Apsopelix be left incertae sedis rather than er-
roneously associated with a teleost group on the basis of convergent
or plesiomorphous characters.

GEOLOGIC AND GEOGRAPHIC RANGE

The oldest Apsopelix specimen known is a single fish from the Al-
bian of France (Wenz, 1965). By Cenomanian time Apsopelix ranged
throughout the North Temperate Euroamerican Region (Kauffman,
1973). It apparently did not enter other regions. Morphological
features of Apsopelix remain constant throughout its geologic as
well as geographic range. The Late Cretaceous specimens from the
Western Interior do not differ significantly from the English,
French (Patterson and Rosen, 1977), or Gulf Coast specimens. The
morphological stability of Apsopelix in time supports the idea of
punctuated equilibria (Eldridge and Gould, 1972; Gould and
Eldrige, 1977), the concept of speciation as a rare event that punc-

'These three features are: loss of suborbital bones, presence of epipleural inter-
muscular bones, and uroneurals distributed in two series, i.e., the uppermost
uroneurals overlap and he at an angle to the longer anterior ones.

30 FIELDIANA: GEOLOGY, VOLUME 41

tuates a system in homeostatic equilibrium. Essentially, we have
only the stable stage of evolution in this group.

The geographic distribution of Apsopelix coupled with the mor-
phological similarity of individuals throughout its range is
reasonable when viewed from the perspective of the configuration of
continents and oceans in Cretaceous times (see Kauffman, 1973, fig.
2, p. 356). The greater proximity of the European and American con-
tinents during the Jurassic and Early Cretaceous combined with a
similar biologic source area in the continuous north temperate
seaway resulted in a close similarity of Northern European and
North American bivalve faunas (Kauffman, 1973) and would sup-
port the similarity of Northern European and North American Ap-
sopelix.

These fishes appear to have been specifically adapted to interior
marine environments1 of the north temperate realm, to have main-
tained a set of morphological adaptations to this type of environ-
ment through time, and to have become extinct with the disap-
pearance of this type of environment.

ABBREVIATIONS

Ang angular

apl anterior pit line

Ao antorbital

Art articular

Asp autosphenotic

Bsp basisphenoid

Boc basioccipital

Den dentary

df dilatator fossa

Dsp dermosphenotic

Ecpt ectopterygoid

Enpt endopterygoid

Epo epioccipital

Exo exoccipital

fhm hyomandibular facet

fhmVII foramen for hyomandibular trunk of fa-
cial nerve

'Specimens from Texas localities near the Western Interior/Gulf Atlantic Coast
boundary are found with invertebrates and in sediments that are characteristic of
interior marine rather than coastal shelf environments.

TELLER-MARSHALL & BARDACK: APSOPELIX

31

fhv

foramen for head vein

fica

foramen for internal carotid artery

flap

fossa for levator arcus palatini

fmpVII

foramen for mandibular and preopercu-

lar branches of facial nerve

foajfpalVII

foramen for orbitonasal artery; foramen

for palatine branch of facial nerve

Fr

frontal

Hm

hyomandibular

Ic

intercalar

Io

infraorbital

IX

foramen for glossopharyngeal nerve

Le

lateral ethmoid

Me

median ethmoid

Mpt

metapterygoid

Mx

maxilla

Na

nasal

Op

operculum

Ors

orbitosphenoid

Pa

parietal

Pal

palatine

Par

parasphenoid

pie

process to lateral ethmoid

pme

process to median ethmoid

Pop

preoperculum

Pro

prootic

ptf

posttemporal fossa

Pto

pterotic

pts

pterosphenoid

Ptt

posttemporal

Qu

quadrate

Rart

retroarticular

Smx

supramaxilla

So

supraorbital

Soc

supraoccipital

Sop

suboperculum

stf

subtemporal fossa

Stt

supratemporal

Sy

symplectic

Vo

vomer

X

foramen for vagus nerve

32 FIELDIANA: GEOLOGY, VOLUME 41

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