“4

Neate
Atel A
eh ha RB

PN
Sh A ay
natet cts Pte

y
iE)

He ‘
“Loy Dy Ack
arnt

4
a

i

WAea

2h Ph ae ee

7

etrigtpin needs se
BN TR
ae

MY
PHA

ae Pat vbr
Ws ae Rb
fe eA)
hee Rote

ae
:

ye

ne
br
RA

+48

ft

ey
eyo

Ly ¢

FAN Hen aZ Bs tts
it Baia
eG! ea Bad it +> i

Bike
8

eof
fl

aa a
heats

cea.
ees
*y ofthe Greets
ae achat
% 4

es
Perr
Vv

MUS. COMP. ZOOL,
LIBRARY

DEC 17 1971

POSTILLA

PEABODY MUSEUM
YALE UNIVERSITY

NUMBER 153 30 AUGUST 1971

ON THE SYSTEMATIC POSITION
OF MACELOGNATHUS VAGANS

JOHN H. OSTROM

POSTILLA

Published by the Peabody Museum of Natural History, Yale University

Postilla includes results of original research on systematic, evolution-
ary, morphological, and ecological biology, including paleontology.
Syntheses and other theoretical papers based on research are also
welcomed. Postilla is intended primarily for papers by the staff of
the Peabody Museum or on research using material in this Museum.

Editors: Zelda Edelson, Elizabeth G. Weinman, Elise K. Kenney.

Postilla is published at frequent but irregular intervals. Manuscripts,
orders for publications, and all correspondence concerning publications
should be directed to:

Publications Office
Peabody Museum of Natural History
New Haven, Conn., 06520, U.S.A.

Lists of the publications of the Museum are available from the above
office. These include Postilla, Bulletin, Discovery, and special publica-
tions. Postilla and the Bulletin are available in exchange for relevant
publications of other scientific institutions anywhere in the world.

Inquiries regarding back numbers of the discontinued journal, Bulletin
of the Bingham Oceanographic Collection, should be directed to:

Walter J. Johnson, Inc.
111 Fifth Avenue
New York, N.Y. 10003.

}
4

ON THE SYSTEMATIC POSITION OF MACELOGNATHUS VAGANS

JOHN H. OSTROM

Peabody Museum of Natural History and Department of Geology and
Geophysics, Yale University, New Haven, Connecticut 06520

(Received March 30, 1971)

ABSTRACT

The holotype and only known specimen of Macelognathus vagans was placed
in a separate reptilian order (Macelognatha) by O. C. Marsh in 1884. Restudy
of the specimen and of other extensive collections from the Macelognathus
site (Quarry Nine, Como Bluff, Wyoming) and a careful check of Peabody
Museum records suggest that Macelognathus probably belongs to the Order
Crocodilia.

POSTILLA 153: 10p. 30 AUGUST 1971

2 POSTILLA
INTRODUCTION

The peculiar specimen described here (see Figure 1) was, and still is, the sole
basis for a “new” order of reptiles proposed by O. C. Marsh in 1884. Marsh
suggested that his new Order Macelognatha was most closely “allied to the
Chelonia” (1884, p. 341), but the few authors who have cited Macelognathus
subsequently have usually referred it to one or another of the dinosaurian
suborders. Uncertainty about its proper systematic position stems from the
unique combination of a normal series of tooth sockets along the rear por-
tions of the dentaries coupled with a strange, spatula-shaped, toothless anterior
extremity of the lower jaws. The principal paleontologic references at the turn
of the century (Nicholson and Lydekker, 1889 and von Zittel’s text, various
editions from 1890 on) cited Macelognathus, but subsequently it has been
omitted (presumably because of its uncertain identity) from all modern texts
and references! with the exception of von Huene’s (1956) Paldontologie und
Phylogenie der Niederen Tetrapoden. At present, Macelognathus is still of
uncertain affinity.

Considering the extremely rich and diverse collections of Jurassic fossil
vertebrates obtained from Quarry Nine, Como Bluff, Wyoming—the site of
Macelognathus—as well as the extensive exploration and collecting from the
Morrison Formation since 1884, it seems most improbable that no other fossil
remains pertaining to this taxon exist. The present paper summarizes a recent
search for such evidence and suggests a new systematic position for this
enigmatic specimen.

TAXONOMIC HISTORY

Macelognathus vagans was founded on two incomplete dentaries (YPM 1415)
by Marsh (1884) in a very brief description supplemented by a single illustra-
tion. Marsh described the specimen as:

two dentary bones of the lower jaws. These bones resemble in many
respects the corresponding parts of a turtle, but are broader, and more
nearly horizontal. The jaws were evidently covered with a horny beak
in front, but further back they contained teeth. The edentulous portion
is flat and thin, and nearly horizontal. The two rami meet in nearly the
same plane, and are united at the symphysis by a close suture. . . . The
teeth were implanted in distinct sockets, in front, but further back, the
walls between them become thinner, and a groove appears to gradually
take their place. The form of the teeth cannot be determined from the
present specimen. (1884, p. 341).

1. Romer (1966) lists “?Marcellognathus U. Jur. NA” under Hypsilophodontidae, Sub-
order Ornithopoda, but it is not known whether or not this citation refers to the specimen
under consideration here.

i
]

}

MACELOGNATHUS VAGANS 3

Marsh’s assessment of Macelognathus relationships was that:

These jaws are too solid and massive for Birds or Pterodactyles. With
Serpents and Lizards they have evidently only remote affinities. The close
union of the rami by suture separates them from the Dinosaurs, and the
edentulous beak, from the Crocodiles. They appear to be nearest allied
to the Chelonia, although Turtles without teeth occur in the same strata
with them. (1884, p. 341).

Nicholson and Lydekker (1889) suggested that Macelognathus may pos-
sibly represent a generalized family in the Suborder Athecata—the most gen-
eralized turtles that show approximation to other reptiles. Karl von Zittel, on
the other hand, assigned Macelognathus to the Family Stegosauridae (Sub-
order Predentata, Order Dinosauria) in the 1890 edition of his textbook. In
1891, George Baur, a former student of von Zittel’s and a then recently re-
signed assistant to O. C. Marsh, published an important critique on the
validity of the Order Dinosauria (his conclusion was that it did not represent
a natural group) in which he included a footnote “I think that Macellognathus
[sic] Marsh, which has nothing whatever to do with the Testudinata, belongs
to this family [Coeluridae] and to Coelurus.” (1891, p. 450). Unfortunately
Baur never published his reasons for this conclusion.

Marsh (1897) referred to Macelognathus once more and refigured it, but
did not comment further on its taxonomic position. O. P. Hay (1902) stated
incorrectly that Marsh placed Macelognathus in the Testudinata but then
placed it in the (then debateable) Order Dinosauria with the qualification that
its phylogenetic relationships are problematical. Subsequent authors have
assigned it without explanation as follows: Moodie (1908)—Dinosauria; Gil-
more (1909)—Reptilia; Mook (1916)—Reptilia; Simpson (1926)—Ornith-
ischia; von Huene (1956)—Ornithischia (Hypsilophodontidae). In 1966, Os-
trom and McIntosh referred this specimen questionably to the Crocodilia or
Eosuchia.

HISTORY OF THE SPECIMEN

Peabody Museum records show that the holotype of Macelognathus vagans
was collected by William Reed during the summer of 1880 from Quarry Nine,
the famous mammal quarry at Como Bluff, Wyoming. It, together with
numerous other specimens, was shipped in two boxes (Nos. 75 and 76) to
Yale and was received and accessioned (No. 1394) on Sept. 18, 1880. Acces-
sion number 1394 was applied to all the contents of both boxes. The accession
entry for box 75 reads “Containing one box of cans from Quarry 9, (Box
7514) inside of Box 75, and balance from [Quarry] 13 W. and four packages
from west side of middle gulch.” A series of notebooks in the Peabody
Museum archives gives further details on the collections received from Marsh’s

4 POSTILLA

collectors. One such notebook compiled by Otto Meyer, one of Marsh’s as-
sistants, is dated 1884 and entitled “Notes on Jurassic vertebrates from
Quarry 9, Como, Wyom.” It records in some detail the contents of several
dozen boxes and cans accessioned from Quarry Nine. Accession No. 1394, as
applied to the contents of box 7514, is recorded on five separate pages under
five different entries—numbers 1 to 5. This presumably indicates that the
contents consisted of five separate packages (cans, according to the accession
entry), if other accession entries in this notebook and in other Museum records
are accurate. Only two references to lower jaws are recorded in Meyer’s notes
under accession number 1394, “lower Jaws” (plural), unidentified, listed under
package No. 3 and “lower jaw” (singular), identified as crocodile, listed under
package No. 4. A single crocodilian mandible with accession number 1394
still resides in the Peabody Museum collections and this almost certainly is
the jaw listed under No. 4 in Meyer’s notebook. Accordingly, it appears most
probable that the unidentified lower jaws listed under No. 3 are those now
referred to as Macelognathus vagans (YPM 1415).

The information recorded in Meyer’s notebook takes on special significance
when it is realized that Marsh was most particular in his instructions to all of
his collectors. He required every collector to be meticulous in collecting pro-
cedures and in preserving and recording specimen sources and associations
(see his directions for collecting vertebrate fossils, p. 172-173 in Schuchert
and LeVene’s biography of Marsh). Moreover, Reed was an experienced col-
lector who had worked for Marsh as one of his most trusted field men since
1877. In the light of this information, it seems safe to assume that the material
packaged with the unidentified lower jaws and recorded by Meyer as No. 3
represents fossil remains that were closely associated in the quarry. That these
other materials actually belonged to the same individual as the jaws is beyond
proof, of course, but their relevance to the identity of Macelognathus cannot
be dismissed. In addition to the unidentified jaws, Meyer listed “sorted teeth”
(unidentified) and a scute, caleaneum, cuboid, neurapophysis of an atlas, and a
metatarsal—all identified as crocodile. Opposite these crocodilian items Meyer
wrote “Note. These bones resemble more the corresponding ones in the young
alligator, than in the old one.” Although a variety of turtle, lizard and dino-
saurian remains were also accessioned with Macelognathus, Meyer’s notes
clearly record that only crocodilian remains were packaged (and thus probably
closely associated in the quarry) with this specimen.

A thorough search of the Quarry Nine collections in the Peabody Museum
at Yale turned up a tray with accession number 1394 containing “sorted”
teeth and crocodilian remains that mateh in part Meyer’s description (a neural
arch, a scute and a metatarsal) plus a note in Marsh’s handwriting stating
“Macelognathus jaws taken from here March 22nd, 1884, OCM.” Although
the “cuboid” and “calcaneum” have not been recognized they may be repre-
sented among the several small fragments in the tray. The scute, neural arch,
metatarsal and teeth are clearly crocodilian. These have been catalogued as
YPM 5539.

}

MACELOGNATHAHUS VAGANS 5)
REVISED DESCRIPTION

Macelognathus Marsh
Macelognathus Marsh, 1884.

TYPE SPECIES. Macelognathus vagans Marsh, 1884.

TYPE SPECIMEN. YPM 1415, symphyseal and anterior portions of left and right
dentaries, figured by Marsh (1884, p. 341 and 1897, figs. 65, 66).

TYPE LOCALITY. Quarry Nine, SW 1/4 Sec. 12, T. 22 N., R. 77 W., Como
Bluff, Albany County, Wyoming.

DESCRIPTION. When placed in articulation the two dentary fragments form a
shallow, spatula-like symphyseal extremity, the anterior portion of which was
edentulous. The symphysis is long and shallow and with very low inclination
almost parallel to the mandibular axis. The symphysis itself measures 47 + mm
in length with a maximum depth (perpendicular to length) of 9.0 mm. The
symphysis appears to have been a straight, strongly digitate suture that pro-
vided a strong and relatively immobile union of the two mandibles. There
is, however, no evidence of fusion between the jaw rami. A narrow medial
groove, the rostral extension of the Meckelian canal, marks the long axis of
each symphyseal suture in their posterior halves, quite similar to the condi-
tion in modern crocodilians.

The width across the articulated dentaries at the anteriormost alveoli (ap-
proximately 35 mm behind the anterior extremity) is 41.5 mm. The anterior
margins are no longer intact, but the little that remains indicates a very thin,
sharp-edged, perhaps slightly denticulate rostral margin comparable to the
figures published by Marsh (1884, 1897). The posterior extremities are missing
from both fragments, consequently no accurate estimate is possible for the
original dentary (or mandible) length. Neither fragment preserves any evi-
dence of reduction in either height or thickness along the posterior region, but
judging from the sizes of the tooth sockets, I would estimate that the present
fragments represent less than half of the original dentary length. The greatest
preserved length of the two Macelognathus fragments is slightly more than
10 cm.

Eleven alveoli are preserved in the left dentary fragment extending over
a distance of 67 mm. Nine alveoli are at least partially preserved in the right
fragment over a length of 59 mm. Not all alveoli are equally distinct, but most
show a concave outer wall and a straight or slightly concave inner wall. Inter-
alveolar bony walls are preserved in the right dentary, but are poorly pre-
served or missing in the left. Alveolar dimensions vary, but most approximate
5 to 6 mm in longitudinal and about 4 mm in transverse dimensions. The
alveoli all appear to be relatively deep sockets. Both dentaries lack teeth en-
tirely and it is this deficiency, together with the peculiar, toothless rostrum,
that has made placement of this specimen so uncertain. Several tooth sockets

6 POSTILLA

FIG. 1. Holotype of Macelognathus vagans (YPM 1415) in dorsal (A) and ventral
(B) aspects. Medial view of the left dentary (C) shows the elongated and shallow
symphyseal suture, and the “splenial facets” on the inner surface.

were excavated for tooth fragments and both dentaries were X-rayed for evi-
dence of replacement teeth. These efforts were to no avail. Both dentary frag-
ments are undistorted and show a pronounced change in alveolus orientation
from the front of the tooth row to the back. The anteriormost alveolus on
each side is inclined at about 45° to the sagittal plane, whereas the most
caudad sockets appear to have had a more nearly vertical orientation. This
condition is not diagnostic of crocodilians, but it is present in Alligator and
Crocodilus.

The lateral and ventral surfaces are not sculptured, but they are marked

MACELOGNATHUS VAGANS 7

by numerous widely spaced foramina of small to moderate size that seem to
radiate away from the symphysis. There are faint grooves or channels as-
sociated with some of these. This surface texture is distributed over the dentary
surfaces immediately adjacent to the tooth row as well as on the anterior tooth-
less region. Marsh (1884) suggested that the anterior portions of these jaws
were covered with a horny beak and such may have been the case, but micro-
scopic examination failed to reveal any evidence of this. The dentaries of
Macelognathus show no conspicuous change in surface texture or in foramina
density between the anterior toothless region and those surfaces adjacent to
the tooth row. By contrast, those parts of turtle mandibles that are covered
by horny beak are much more highly perforated than those parts that are
not so covered. It seems very unlikely to me that both the toothed and tooth-
less regions alike were enclosed in a horny beak. Furthermore, the density of
foramina is considerably greater in turtle mandibles than it is in Macelogna-
thus. In fact, the surface texture and pattern of foramina in Macelognathus
are very different from those of turtle jaws, but they are almost identical to
those found in this region of Recent Alligator and Crocodilus. These facts
indicate that the jaws of Macelognathus were covered by normal epidermal
tissues rather than a horny beak.

The medial dentary surfaces are marked by broad and moderately deep
Meckelian canals that narrow anteriorly and lead into the medial symphyseal
groove mentioned above. In both fragments, the Meckelian canal is bordered
above and below by shallow but distinct grooves or facets. The superior groove
extends to within about 12 to 14 mm of the symphysis, but the inferior grooves
appear to reach all the way to the symphysis. These surfaces are believed to be
the articular surfaces for the splenials and as such indicate that the splenials
probably contributed to the symphyseal junction. This condition may be sig-
nificant for the systematic placement of Macelognathus.

SYSTEMATIC POSITION OF Macelognathus

Chelonian affinities of Macelognathus, sometimes attributed to Marsh, can be
dismissed on several grounds; these include the presence of well-defined alveoli
indicative of a thecodont dentition, the unfused symphysis, the apparent junc-
tion of the splenials at the symphysis, the flat and rounded symphyseal region
rather than a sharp, triangular beak, and the surficial textural evidence of a
closely applied, epidermal covering rather than a horny beak. Ornithischian
affinities appear improbable because there is no evidence whatsoever of a
predentary—the anterior, medial mandibular element that is present in all
adequately known ornithischians. Moreover, the symphysis in all ornithischians
is short and weakly developed, apparently forming a mobile union, and the
splenials terminate far posterior to the symphysis. Baur’s unexplained ref-
erence of Macelognathus to the Coeluridae (Order Saurischia) is not sub-
stantiated by comparison with any known theropod, a group in which the
symphysis is universally short and apparently flexible, and the splenials are

8 POSTILLA

short and fail to meet at the symphysis. Rhynchocephalian remains have been
collected at Quarry Nine, but the thecodont tooth implantation of Macelogna-
thus rules out any close relationship with this order. Squamatan affinities
appear remote on the basis of the relatively large size of Macelognathus and
the firm symphyseal junction involving the splenials.

Splenial involvement in the mandibular symphysis is characteristic of a
number of long-snouted reptiles (i.e. Mesosauria, Ichthyosauria, Sauropterygia,
Phytosauria, Eosuchia and some crocodilians including living gavials?) and
is not necessarily consistent among closely related taxa. In all instances
splenial symphyseal articulation is correlated with elongation of the sym-
physeal suture and does not appear to be necessarily related to anterior
elongation of the splenials. Symphysis elongation presumably is related to
snout elongation or immobilization of jaw symphysis. This correlation of
symphysis elongation and splenial junction apparently holds true for Macelog-
nathus.

Of the groups mentioned above, only the eosuchians (and specifically the
champsosaurs) and crocodilians are serious candidates for consideration as
relatives of Macelognathus. Initially, I suspected that YPM 1415 might
represent an early member of the Choristodera, largely because the splenial
symphyseal junction is so extensively developed in all known champsosaurs.
My suspicion appeared to be reinforced by a recent discovery by a Princeton
University expedition of a very similar spatula-mouthed champsosaur from
the Paleocene of the Big Horn Basin in Wyoming (D. Baird, pers. comm.).
However, after further consideration and extensive examination of the Morri-
son fauna, I have come to the conclusion that Macelognathus-champsosaur
affinities are highly improbable and crocodilian relationships are much more
likely.

A very thorough search during the last four years through all of the collec-
tions from Quarry Nine that are housed in the Peabody Museum and in the
United States National Museum failed to turn up a single piece of evidence
to corroborate Macelognathus-champsosaur relationships. Every tooth, jaw
and vertebra from Quarry Nine (of which there are several thousand) was
examined, as was a large number from other quarries at Como Bluff. Despite
the distinctive character of champsosaur teeth and vertebrae, not a single item
was found that even remotely resembled these elements as they are presently
known in the Choristodera. Negative evidence is seldom conclusive, but the
extraordinary abundance of material available from this classic site, and its
great diversity, makes it highly improbable that other remains of Macelogna-
thus are not represented in the collections from Quarry Nine. Failure to dis-
cover recognizable champsosaur remains in the Quarry Nine collections or
in any other Morrison collections can hardly be considered proof of non-
choristoderan relationships. It is quite possible that early choristoderans had
not yet acquired the distinctive vertebral or dental characters of champsosaurs.

2. Langston (1965), reported a supposed Miocene gavialid in which the splenial makes
a large contribution to the symphyseal suture.

MACELOGNATAUS VAGANS 9

But, on the other hand, crocodilian remains are very abundant in the Morrison
Formation, and especially so in the Quarry Nine collections. Moreover, they
constituted the only recognizable remains packaged with the specimen in
question, as well as constituting the most abundant remains accessioned
under 1394.

The evidence is largely circumstantial, but the only anatomical feature
preserved in YPM 1415 that is not presently known in the Crocodilia is the
edentulous, spatulate rostrum. I suggest that the total evidence now available
indicates a crocodilian relationship for Macelognathus.

SUMMARY

Reassessment of Museum records, probable quarry associations, the Quarry
Nine fauna and the morphology of the holotype and only known specimen
of Macelognathus vagans (YPM 1415) indicate that the most probable
affinities are with the Order Crocodilia and not with turtles or any dinosaurian
group. Thecodont dentition, long symphyseal suture, splenial participation
in the symphysis, and the evidence of epidermal rather than horny covering of
the mandibles are consistent with crocodilian relationships.

10 POSTILLA

LITERATURE CITED

Baur, George. 1891. Remarks on the reptiles generally called Dinosauria. Amer.
Nat. 25: 434-454,

Gilmore, Charles W. 1909. A new rhynchocephalian reptile from the Jurassic of
Wyoming, with notes on the fauna of “Quarry 9.” Proc. U.S. Nat. Mus.
37: 35-42.

Hay, Oliver P. 1902. Bibliography and catalogue of the fossil Vertebrata of North
America. Bull. U.S. Geol. Surv. 179: 1-868.

Huene, Friedrich R. F. von. 1956. Paléontologie und Phylogenie der Niederen
Tetrapoden. Gustav Fischer Verlag, Jena. 716 pp.

Langston, Wann, Jr. 1965. Fossil Crocodilians from Colombia and the Cenozoic
history of the Crocodilia in South America. Univ. Calif. Public. Geol. Ser.
52: 1-157.

Marsh, Othniel C. 1884. A new order of extinct Jurassic reptiles (Macelognatha).
Amer. Jour. Sci. (3), 27: 341.

1897. Vertebrate fossils. Jn Samuel F. Emmons, Whitman Cross and George
H. Eldridge, Geology of the Denver Basin in Colorado. Monogr. U.S. Geol.
Surv. 27: 473-527.

Moodie, Roy L. 1908. The relationship of the turtles and plesiosaurs. Kansas Univ.
Sci. Bull. 4: 319-327.

Mook, Charles C. 1916. Study of the Morrison Formation. Ann. New York Acad.
Sci. 27: 39-191.

Nicholson, Henry A. and Richard Lydekker. 1889. A manual of palaeontology.
William Blackwood & Sons, London. 2 vols., 1624 pp.

Ostrom, John H. and John S. McIntosh. 1966. Marsh’s dinosaurs, the collections
from Como Bluff. Yale Univ. Press, New Haven. 388 pp.

Romer, Alfred S. 1966. Vertebrate paleontology. 3rd ed. Univ. Chicago Press,
Chicago. 468 pp.

Schuchert, Charles, and C. M. LeVene. 1940. O. C. Marsh, pioneer in paleontology,
Yale Univ. Press, New Haven. 541 pp.

Simpson, George G. 1926. The fauna of quarry nine. Amer. Jour. Sci. (5), 12: 1-11.

Zittel, Karl von. 1890. Handbuch der Palaeontologie, Bd. 3, Vertebrata. Munich
and Leipzig. 1699 pp.

REVIEW
|

|
| STYLE

FORM

TITLE
ABSTRACT

IMENCLATURE

LUSTRATIONS

FOOTNOTES

TABLES

REFERENCES

2OR'S COPIES

PROOF

COPYRIGHT

INFORMATION FOR AUTHORS

The Publications Committee of the Peabody Museum of Natural
History reviews and approves manuscripts for publication. Papers
will be published in approximately the order in which they are
accepted; delays may result if manuscript or illustrations are not in
proper form. To facilitate review, the original and one carbon or
xerox copy of the typescript and figures should be submitted. The
author should keep a copy.

Authors of biological papers should follow the Style Manual for
Biological Journals, Second Edition (Amer. Inst. Biol. Sci.). Authors
of paleontological manuscripts may choose to follow the Sugges-
tions to Authors of the Reports of the U.S. Geological Survey,
Fifth Edition (U.S. Govt. Printing Office).

Maximum size is 80 printed pages including illustrations (= about
100 manuscript pages including illustrations). Manuscripts must be
typewritten, with wide margins, on one side of good quality 8! x 11”
paper. Double space everything. Do not underline anything except
genera and species. The editors reserve the right to adjust style and
form for conformity.

Should be precise and short. Title should include pertinent key
words which will facilitate computerized listings. Names of new
taxa are not to be given in the title.

The paper must begin with an abstract. Authors must submit com-
pleted BioAbstract forms; these can be obtained from the Postilla
editors in advance of submission of the manuscripts.

Follow the International Codes of Zoological and Botanical Nomen-
clature.

Must be planned for reduction to 4 x 614” (to allow for running
head and two-line caption). If illustration must go sideways on
page, reduction should be to 334 x 634”. All illustrations should be
called “Figures” and numbered in arabic, with letters for parts
within one page. It is the author’s responsibility to see that illustra-
tions are properly lettered and mounted. Captions should be typed
double-spaced on a separate page.

Should not be used, with rare exceptions. If unavoidable, type
double-spaced on a separate page.

Should be numbered in arabic. Each must be typed on a separate
page. Horizontal rules should be drawn lightly in pencil; vertical
rules must not be used. Tables are expensive to set and correct;
cost may be lowered and errors prevented if author submits tables
typed with electric typewriter for photographic reproduction.

The style manuals mentioned above must be followed for form and
for abbreviations of periodicals. Double space.

Each author receives 50 free copies of his Postilla. Additional copies
may be ordered at cost by author when he returns galley proof.
All copies have covers.

Author receives galley proof and manuscript for checking printer’s
errors, but extensive revision cannot be made on the galley proof.
Corrected galley proof and manuscript must be returned to editors
within seven days.

Any issue of Postilla will be copyrighted by Peabody Museum of
Natural History only if its author specifically requests it.

Acme

Bookbinding Co., Inc.
300 Summer Street
* Boston, Mass. 02210

“Hi win 1

4 066 305 I

nae
ie
€

f
Se

ae

Mite,

Ch atene
ie Ve eC aT ee
Lt diaeinteten P;

A

eetihe
Stns

%
Nivea:
Ui SSS

4,
teh By
iybids Usd

Ne
Ib Pend

rn

is
Cae soma ©