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Atlas of Paleocene
Planktonic Foraminifera

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I. Michael Heyman

Secretary

Smithsonian Institution

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

NUMBER 85

Atlas of Paleocene
Planktonic Foraminifera

Richard K. Olsson, Christoph Hemleben, William A. Berggren,

and Brian T. Huber

EDITORS

ISSUED

MAR 3 1999

SMITHSONIAN INSTITUTION

SMITHSONIAN INSTITUTION PRESS

Washington, D.C.
1999

ABSTRACT

Olsson, Richard K., Christoph Hemleben, William A. Berggren, and Brian T. Huber,
editors. Atlas of Paleocene Planktonic Foraminifera. Smithsonian Contributions to Paleobiol¬
ogy, number 85, 252 pages, 37 figures, 71 plates, 1999.—Sixty-seven species of Paleocene
planktonic foraminifera are described and illustrated, including three species of Eoglobigerina,
four species of Parasubbotina, five species of Subbotina, two species of Hedbergella, 10 species
of Globanomalina, six species of Acarinina, 12 species of Morozovella, three species oilgorina,
four species of Praemurica, one species of Guembelitria, one species of Globoconusa, three
species of Parvulamgoglobigerina, two species of Woodringina, six species of Chiloguembe-
lina, one species of Rectoguembelina, and four species of Zeauvigerina. Taxonomic
classification of normal perforate taxa are organized according to wall texture. Spinose
cancellate genera include Eoglobigerina, Parasubbotina, and Subbotina ; cancellate nonspinose
genera include Igorinina and Praemurica ; smooth-walled genera include Hedbergella and
Globanomalina', and muricate genera include Acarinina and Morozovella. Taxonomic
classification of microperforate taxa (including Guembelitria, Globoconusa, Parvularugoglo-
bigerina, Woodringina, Chiloguembelina, Rectoguembelina, and Zeauvigerina ) are organized
according to test morphology.

Scanning electron microscope (SEM) images of type species described by Morozova in the
collections of the Geological Institute, Academy of Sciences (GAN), Moscow, and the type
material described by Subbotina in the collections of the All Union Petroleum Scientific
Research Geological Prospecting Institute (VNIGRI), St. Petersburg, are shown on Plates 8-12.
Twelve species described by Morozova, nine species described by Subbotina, and one species
described by Bykova are illustrated. In addition, SEM images of 28 holotypes and two paratypes
from the Smithsonian Institution collections are shown on Plates 13-17, and the lectotype for
Globigerina compressa Plummer, 1926, and the neotype for Globorotalia monmouthensis
Olsson, 1961, are designated and illustrated with SEM images.

Paleobiogeographic maps showing the global distribution of 29 commonly occurring
Paleocene taxa are included in the atlas, as well as figures showing the stratigraphic ranges of
species by genus and stratigraphic first and last appearances. The biostratigraphic framework
used in the atlas is the revised biostratigraphy given in Berggren et al., 1995, which is
summarized in the atlas. Wall texture and morphological relationships between species and
genera form the basis of phylogenetic interpretations. This is discussed in the section “Wall
Texture, Classification, and Phytogeny” and is referenced to Plates 1-7.

Official publication date is handstamped in a limited number of initial copies and is
recorded in the Institution’s annual report, Annals of the Smithsonian Institution. Series cover
design: The trilobite Phacops rana Green.

Library of Congress Cataloging-in-Publication Data

Atlas of Paleocene planktonic foraminifera / Richard K. Olsson ... [et al.], editors,
p. cm. — (Smithsonian contributions to paleobiology ; no. 85)

Includes bibliographic references and index.

1. Foraminifera, Fossil. 2. Paleontology—Paleocene. I. Olsson, Richard K. II. Series.
QE701.S56no.85 [QE772] 560 s-dc21 [56T.994] 98-3474

® The paper used in this publication meets the minimum requirements of the American
National Standard for Permanence of Paper for Printed Library Materials Z39.48—1984.

Contents

Page

Introduction (by R.K. Olsson, W.A. Berggren, and Ch. Hemleben). 1

Acknowledgments. 4

Abbreviations . 8

Biostratigraphy (by W.A. Berggren and R.D. Norris). 8

Wall Texture, Classification, and Phylogeny (by Ch. Hemleben, R.K. Olsson,

W.A. Berggren, and R.D. Norris). 10

Globorotaliid Wall Texture. 11

Muricate Wall Textures. 12

Neogloboquadrinid Wall Texture (Praemuricate). 12

Spinose Wall Texture. 12

Preservation and Diagenesis. 13

Phylogeny. 13

Spinose Lineages. 13

Cancellate Lineages. 13

Eoglobigerina . 13

Parasubbotina . 17

Subbotina . 17

Nonspinose Lineages. 17

Praemuricate Lineages. 17

Praemurica . 17

Igorina . 17

Smooth-Walled Lineage. 17

Globanomalina . 17

Muricate Lineages. 18

Acarinina . 18

Morozovella . 18

Taxonomy . 19

Family GLOBIGERINIDAE Carpenter, Parker, and Jones, 1862 (by R.K Olsson,

Ch. Hemleben, C. Liu, W.A. Berggren, and R.D. Norris). 19

Genus Eoglobigerina Morozova, 1959 . 19

Eoglobigerina edita (Subbotina, 1953). 19

Eoglobigerina eobulloides (Morozova, 1959). 20

Eoglobigerina spiralis (Bolli, 1957). 22

Genus Parasubbotina Olsson, Hemleben, Berggren, and Liu, 1992 . 24

Parasubbotina pseudobulloides (Plummer, 1926). 24

Parasubbotina aff. pseudobulloides (Plummer, 1926). 25

Parasubbotina varianta (Subbotina, 1953). 26

Parasubbotina variospira (Belford, 1984). 28

Genus Subbotina Brotzen and Pozaryska, 1961. 28

Subbotina cancellata Blow, 1979 . 29

Subbotina triangularis (White, 1928). 30

Subbotina triloculinoides (Plummer, 1926). 31

Subbotina trivialis (Subbotina, 1953). 32

Subbotina velascoensis (Cushman, 1925). 33

Family HEDBERGELLIDAE Loeblich and Tappan, 1961 (by R.K. Olsson,

Ch. Hemleben, and C. Liu). 34

in

IV

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Genus Hedbergella Bronnimann and Brown, 1958 . 34

Hedbergella holmdelensis Olsson, 1964 . 35

Hedbergella monmouthensis (Olsson, 1960). 35

Genus Globanomalina Haque, 1956, emended. 37

Globanomalina archeocompressa (Blow, 1979). 37

Globanomalina australiformis (Jenkins, 1965). 38

Globanomalina chapmani (Parr, 1938). 39

Globanomalina compressa (Plummer, 1926). 40

Globanomalina ehrenbergi (Bolli, 1957). 42

Globanomalina imitata (Subbotina, 1953). 42

Globanomalina ovalis Haque, 1956 . 43

Globanomalina planocompressa (Shutskaya, 1965). 44

Globanomalina planoconica (Subbotina, 1953). 44

Globanomalina pseudomenardii (Bolli, 1957). 45

Family Truncorotaloididae Loeblich and Tappan, 1961 (by W.A. Berggren,

Ch. Hemleben, R.D. Norris, and R.K. Olsson). 45

Genus Acarinina Subbotina, 1953 . 46

Acarinina coalingensis (Cushman and Hanna, 1927). 47

Acarinina mckannai (White, 1928). 48

Acarinina nitida (Martin, 1943). 48

Acarinina soldadoensis (Bronnimann, 1952). 50

Acarinina strabocella (Loeblich and Tappan, 1957). 50

Acarinina subsphaerica (Subbotina, 1947). 52

Genus Morozovella McGowran in Luterbacher, 1964 . 54

Morozovella acuta (Toulmin, 1941). 55

Morozovella acutispira (Bolli and Cita, 1960). 56

Morozovella aequa (Cushman and Renz, 1942). 57

Morozovella angulata (White, 1928). 58

Morozovella apanthesma (Loeblich and Tappan, 1957). 59

Morozovella conicotruncata (Subbotina, 1947). 60

Morozovella gracilis (Bolli, 1957). 61

Morozovella occlusa (Loeblich and Tappan, 1957). 62

Morozovella pasionensis (Bermudez, 1961). 63

Morozovella praeangulata (Blow, 1979). 64

Morozovella subbotinae (Morozova, 1939). 65

Morozovella velascoensis (Cushman, 1925). 66

Genus Igorina Davidzon, 1976 . 68

Igorina albeari (Cushman and Bermudez, 1949). 69

Igorina pusilla (Bolli, 1957). 70

Igorina tadjikistanensis (Bykova, 1953). 71

Genus Praemurica Olsson, Hemleben, Berggren, and Liu, 1992 . 72

Praemurica inconstans (Subbotina, 1953). 73

Praemurica pseudoinconstans (Blow, 1979). 74

Praemurica taurica (Morozova, 1961). 75

Praemurica uncinata (Bolli, 1957). 76

Family Guembelitriidae Montanaro Gallitelli, 1957 (by S. D’Hondt, C. Liu,

and R.K. Olsson). 77

Genus Guembelitria Cushman, 1933 . 79

Guembelitria cretacea Cushman, 1933 . 79

Genus Globoconusa Khalilov, 1956 . 80

Globoconusa daubjergensis (Bronnimann, 1953). 81

Genus Parvularugoglobigerina (Hofker, 1978), emended. 82

Parvularugoglobigerina alabamensis (Liu and Olsson, 1992). 83

Parvularugoglobigerina eugubina (Luterbacher and Premoli Silva, 1964)
. 83

Parvularugoglobigerina extensa (Blow, 1979). 85

Genus Woodringina Loeblich and Tappan, 1957 . 86

Woodringina claytonensis Loeblich and Tappan, 1957 . 86

Woodringina hornerstownensis Olsson, 1960 . 87

Family CHILOGUEMBELINIDAE Reiss, 1963 (by S. D’Hondt and B.T. Huber)... 88

Genus Chiloguembelina Loeblich and Tappan, 1956 . 89

Chiloguembelina crinita (Glaessner, 1937). 90

Chiloguembelina midwayensis (Cushman, 1940). 90

Chiloguembelina morsei (Kline, 1943). 91

Chiloguembelina subtriangularis Beckmann, 1957 . 92

Chiloguembelina trinitatensis (Cushman and Renz, 1942). 92

Chiloguembelina wilcoxensis (Cushman and Ponton, 1932). 92

Family Heterohelicidae Cushman, 1927 (by B.T Huber). 93

Genus Rectoguembelina Cushman, 1932 . 93

Rectoguembelina cretacea Cushman, 1932 . 94

Genus Zeauvigerina Finlay, 1939 . 94

Zeauvigerina aegyptiaca Said and Kenawy, 1956 . 95

Zeauvigerina teuria Finlay, 1947 . 96

Zeauvigerina waiparaensis (Jenkins, 1965). 97

“ Zeauvigerina ” virgata (Khalilov, 1967). 98

Literature Cited.100

Plates.107

Index.250

Members of the Paleogene Planktonic Foraminifera

Working Group

William A. Berggren (Chairman), Department of Geology and Geophysics, Woods Hole
Oceanographic Institute, Woods Hole, Massachusetts, 02543, United States.

Steven D’Hondt, Graduate School of Oceanography, University of Rhode Island,
Kingston, Rhode Island, 02881, United States.

Christoph Hemleben, Institute und Museum fur Geologie und Palaontologie, Universitat
Tubingen, D-72076 Tubingen, Germany.

Brian T. Huber, Department of Paleobiology, MRC NHB 121, National Museum of
Natural History, Smithsonian Institution, Washington, D.C. 20560, United States.

D. Graham Jenkins (deceased), Department of Geology, National Museum of Wales,
Cathays Park, Cardiff CF1 3NP, United Kingdom.

Chengjie Liu, Department of Geological Sciences, Rutgers University, New Brunswick,
New Jersey 08903, United States.

Richard D. Norris, Woods Hole Oceanographic Institute, Woods Hole, Massachusetts
02543, United States.

Richard K. Olsson (Secretary), Department of Geological Sciences, Rutgers University,
New Brunswick, New Jersey 08903, United States.

Paul N. Pearson, Department of Geology, University of Bristol, Queens Road, Bristol BS8
1RJ, United Kingdom.

Fred Rogl, Naturhistorisches Museum, Paleontologisches Abt., Burggring 7, A1014
Vienna, Austria.

Atlas of Paleocene
Planktonic Foraminifera

Richard K. Olsson, Christoph Hemleben, William A. Berggren ,

and Brian T. Huber

Editors

Introduction

(by R.K. Olsson, W.A. Berggren, and Ch. Hemleben)

The Paleogene Planktonic Foraminifera Working Group of
the International Subcommission on Paleogene Stratigraphy,
International Union of Geological Sciences, was formed in
1987 following a meeting (organized by W.A. Berggren) at the
British Petroleum Research Centre in Sunbury on Thames,
U.K., of researchers interested in improving the understanding
of Paleogene planktonic foraminiferal taxonomy and lineage
phylogenies. The consensus of the meeting was that a concerted
effort among workers was needed to unravel conflicting
taxonomic usages of Paleogene taxa due to misunderstanding
and lack of access to type collections, particularly in the former
Soviet Union. The origins of many of the important biostrati-
graphic lineages was obscure so that the radiation of Paleogene
planktonic foraminifera was poorly understood, and, in fact,
some long-held concepts proved to be erroneous. Some of the
important questions included the origin of the basal Cenozoic
radiation, the taxa involved and how to distinguish them, the
origin of the genus Acarinina, and the phylogeny of the
morozovellids. In the following years, important breakthroughs
in research led to the evolution of the working group’s
understanding of the taxonomy and phylogeny of Paleogene
planktonic foraminifera.

Richard K. Olsson, Department of Geological Sciences, Rutgers
University, New Brunswick, New Jersey 08903. Christoph Hemleben,
Institute und Museum fur Geologie und Palaontologie, Universitat
Tubingen, D-72076 Tubingen, Germany. William A. Berggren,
Department of Geology and Geophysics, Woods Hole Oceanographic
Institute, Woods Hole, Massachusetts 02543. Brian T. Huber,
Department of Paleobiology, MRC NHB 121, National Museum of
Natural History, Smithsonian Institution, Washington, D.C. 20560.

Reviewer: William V Sliter {deceased), U.S. Geological Survey,
Menlo Park, California.

The first official meeting of the Paleogene Planktonic
Foraminifera Working Group was held at the Institute of
Geology and Paleontology at the University of Tubingen,
Tubingen, Germany. In order to achieve a meaningful
reconstruction of the taxonomy and phylogeny of Paleogene
planktonic foraminifera the working group decided to focus on
unraveling the origins and evolution of the earliest Paleocene
(Danian) taxa so as to identify lineages of species that could be
traced into the later Paleocene and ultimately through the
Paleogene.

An important step in the understanding of Danian taxonomy
came about with the visit by W.A. Berggren and F. Rogl to
study type collections of V.G. Morozova housed in Moscow
and with the study of Russian species in the collections of W.A.
Berggren and H.P. Luterbacher. The work of Ch. Hemleben
provided a preliminary understanding of a classification of
living species, which was based on whether or not spines were
used in their biological behavior, a division that Parker (1962)
clearly showed could be applied to living plankonic foraminif¬
era based on the presence or absence of spines. His work
focused on the identification in fossilized specimens of the
spinose condition, because spines are used only when the
individual is alive and are shed during gametogenesis. The
presence of spine holes and spine bases in and on the chamber
walls of fossil specimens indicated a spinose condition. The
importance of wall structure was emphasized by Steineck and
Fleisher (1978) in their seminal paper on a phylogenetically
based classification of planktonic foraminifera. An important
breakthrough in using wall texture and structure in the
taxonomic classification of Paleocene planktonic foraminifera
was announced at the 1989 meeting of the working group in
Tubingen. This was the discovery by Ch. Hemleben and R.K.
Olsson of spinose wall texture in specimens of Eoglobigerina
eobulloides (Morozova) from Zone Pa in the Danian section at

1

2

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Millers Ferry, Alabama. This discovery showed that the
spinose condition had developed in planktonic foraminifera
following the terminal Cretaceous mass extinction. It was an
innovation not present in Cretaceous planktonic foraminifera,
and it meant that a phylogenetic classification based on wall
texture might be applied to Danian planktonic foraminifera. In
addition to E. eubulloides, Parasubbotina pseudobulloides
(Plummer) was subsequently shown to have a spinose wall
texture. This discovery abmptly uprooted long-held notions
about Paleocene planktonic foraminiferal phylogenies (Bolli,
1957a; Blow, 1979) in which P. pseudobulloides was consid¬
ered the ancestor of the nonspinose post-Danian muricate
morozovellid radiation. The study by F.T. Banner (1989) of the
planktonic foraminiferal genus Globanomalina clarified the
taxonomy of the smooth-walled group of Paleocene planktonic
foraminifera and showed that wall texture was highly important
in tracing phylogeny and in identifmg lineages. His work
identified the earliest Danian species, Globanomalina archeo-
compressa (Blow), as the first species of a smooth-walled
nonspinose lineage. By the next meeting in 1990 in Tubingen
the first Danian cancellate nonspinose species, Praemurica
taurica (Morozova), was identified. It was now clear that
Danian planktonic foraminifera consisted of four groups based
on wall texture. These four groups had the same kind of wall
texture as did the four groups of living planktonic foraminifera
(Hemleben et al., 1991). The wall textures are microperforate,
normal perforate smooth-walled nonspinose, normal perforate
cancellate nonspinose, and normal perforate cancellate spinose.
Using this classification (Olsson et al., 1992), the new genera
Parasubbotina and Praemurica were erected to represent two
distinct Danian lineages.

During the 1991 and 1992 meetings in Tubingen and the
1993 meeting of the working group at the Cushman Labora¬
tory, National Museum of Natural History (NMNH), Smith¬
sonian Institution, Washington, D.C., details of the Danian
phylogeny had been worked out (Pearson, 1993), and the origin
of the smooth-walled, cancellate nonspinose, and cancellate
spinose groups from Hedbergella was demonstrated (Liu and
Olsson, 1994); however, two opposing interpretations of the
origin of the morozovellids remain unresolved as this atlas goes
to press. At issue is the derivation of this group from either
Praemurica, the traditional view, or from Globanomalina,
which is a newly developed view. The traditional view, based
on the original hypothesis of Bolli (1957a), is emphasized in
the recent work of Norris (1996) and Kelly et al. (1996). The
alternate view, which is based on the studies of Olsson and
Hemleben (1996), emphasizes the development of the charac¬
teristic heavy pustulose wall texture of these groups from a
smooth-walled Globanomalina ancestor. These views and their
alternate phylogenetic interpretations are presented in “Wall
Texture, Classification, and Phylogeny,” below.

During the first meeting of the working group it was
recognized that the microperforate wall texture separated a
distinct group of planktonic foraminifera that dominate the

lowest Danian assemblages. This group was viewed as
opportunistic following the terminal Cretaceous mass extinc¬
tion of planktonic foraminifera. It included Chiloguembelina,
Globoconusa, Guembelitria, Parvularugoglobigerina, and
Woodringina. Confusion over the difference between the
normal perforate and microperforate species had led Brinkhuis
and Zachariasse (1988) and Keller (1988) to erroneously
identify microperforate specimens from the lower Danian at El
Kef as normal perforate species (cancellate spinose and
cancellate nonspinose). Thus, clarification and phylogeny of
the microperforate group became an objective of our working
group. By 1992 the phylogeny of the microperforates from the
Cretaceous survivor species Guembelitria cretacea (Cushman)
had been constructed (D’Hondt, 1991; Liu and Olsson, 1992).
Confusion with regard to the possible Cretaceous origin of
Chiloguembelina, however, prompted a careful morphologic
comparison of Danian Chiloguembelina with the species
Chiloguembelina waiparaenis Jenkins, which, although de¬
scribed from the Danian of New Zealand, occurs in the
uppermost Cretaceous at Ocean Drilling Program (ODP) Site
758 in the Southern Ocean. At the 1993 meeting in
Washington, D.C., it was shown that waiparaensis has a
distinctive morphology separating it from Chiloguembelina
and that it is properly placed in the genus Zeauvigerina, which
has a Cretaceous to Paleocene range. Zeauvigerina, which is
restricted to the southern latitudes, is tentatively placed in the
Heterohelicidae as it does not have a phylogenetic relationship
with the Guembelitriidae (Huber and Boersma, 1994).

Work on the origin and phylogeny of Acarinina by W.A.
Berggren and R.D. Norris led to an important revision of
Paleocene Zone P4. They showed that the consecutive
appearances of A. subsphaerica Subbotina and A. soldadoensis
(Bronnimann) allow Zone P4 to be divided into three subzones.
This plus other refinements has resulted in an updated version
of the Berggren and Miller (1988) zonation of the Paleocene
(Berggren and Norris, 1993; Berggren et al., 1995), which is
summarized in this volume (Figure 1).

An important development in the clarification of Russian
species appears on Plates 8-12, where many holotypes are
illustrated by SEM for the first time. F Rogl was able to borrow
the type material described by Morozova in the collections of
the Geological Institute, Academy of Sciences (GAN) in
Moscow and the type material described by Subbotina in the
collections of VNIGRI in St. Petersburg and was able to obtain
low KV SEM images of these species. One big surprise is that
the widely used but poorly understood species, Globigerina
fringa Subbotina, has a coarsely cancellate wall and thus is not
closely related to any of the earliest Danian taxa. In fact, this
species appears to be described from an upper Danian
stratigraphic level and has affinities with Subbotina cancellata.
This illustrates the pitfalls for workers who use poorly
illustrated drawings of Russian species in identifying taxa for
biostratigraphic studies. These SEM images of Russian types
and the personal observations of Russian taxa by W.A.

NUMBER 85

3

Epoch

Paleocene

Biozone

Datum Marker and
Chronologic Age (Ma)

Other Bioevents and
Chronologic Age (Ma)

Eocene

QJ

c

QJ

O

©

QJ

13

PM

©

03

©

©

©

o

o

13

PM

©

Zone P6

Zone P5

Oh

D

G

o

N

CO

Ph

<d

g

o

N

a

a

Zone P2

a>

G

O

N

Zone Pa

Zone PO

•* —LA: M. velascoensis (54.7)

-LA: G. pseudomenardii (55.9)
- FO: A. soldadoensis (56.5)
-LA: A. subsphaerica (57.1)
-FO: G. pseudomenardii (59.2)
-FO: I. albeari (60.0)

-FO: M. angulata (61.0)

Upper Cretaceous

LA: M. acuta (54.7)

FO: M. gracilis (54.9)

FO: G. australiformis (55.5)

FO: M. subbotinae (55.9)

LA: A. nitida & mckannai (56.3)

FO: M. aequa & A. coalingensis (56.5)

FO: A. mckannai (59.1)

FO: A. nitida & subsphaerica (59.2)
LA: Ps. varianta & variospira (59.2)

FO: A. strabocella (60.5)

FO: M. conicotruncata (60.9)

FO : I. pusilla (61.0)

-FO: Pr. uncinata (61.2)

■FO: G. compressa (63.0)

-FO: Ps. triloculinoides (64.5)
-LA: Par. eugubina (64.9)

-FO: Par. eugubina (64.97)

B=

FO: M. praeangulata (61.2)
FO: G. imitata (61.3)

FO: Ps. varianta (63.0)

U — LA: Par. extensa (64.9)

-LA: most Late Cretaceous
taxa (65.0)

FO: Gc. daubjergensis & W. claytonensis (64.97)

FO: G. archeocompressa & Par. extensa ;

LA: hedbergellids

FIGURE 1.—Paleocene biostratigraphic zonation showing the first occurrence (FO) and last appearance (LA) of
zonal species and other important bioevents.

Berggren and F Rogl have greatly improved the understanding
of these species, their taxonomy, and their synonymy. In
addition to the SEM images of Russian types (Plates 8-12),
low KV SEM images taken by B.T. Huber of types in the
Cushman collections are also shown (Plates 13-17). The atlas
also includes SEM images of topotypes of Globanomalina
australiformis (Jenkins), Hedbergella holmdelensis Olsson,
Hedbergella monmouthensis (Olsson), Morozovella acutispira
(Bolli and Cita), Woodringina hornerstownensis Olsson, and
specimens of Parvularugoglobigerina eugubina (Luterbacher
and Premoli Silva) from the type level at Gubbio, Italy.

The atlas includes a section on the newly revised zonation
for the Paleocene (Figure 1), with range charts showing the

maximum known range of each species organized according to
generic classification, which, in turn, is organized by wall-
texture groups (Figure 2). Other range charts show the order of
the first appearances of taxa (Figure 3) and the last appearances
of taxa (Figure 4). The section on wall texture and classification
describes the basis for the classification used in this atlas and
illustrates in Plates 1-6 the comparison of the types of wall
texture in living species and Paleocene species of planktonic
foraminifera. The section on taxonomy includes the species
considered valid by the working group and includes a
synonymy of species considered to be junior synonyms by
personal observation of working group members. Most of the
species are illustrated by a plate of figures in order to illustrate

4

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

the range of morphologic variability of the species. Species that
are obscure or are poorly known are not included because their
validity is unproven. These species names are mentioned in the
taxonomic discussion under the species considered to be the
probable senior synonym. Paleobiogeographic maps showing
the known distribution of nominate species representative of
each genus is included under that species. Reconstruction of
paleobiogeographic maps was generated using the PGIS/Mac™
software package. Land-sea distributions are modified from
Barron (1987). Occurrences are plotted only for well-
documented identifications either by SEM showing unequivo¬
cal images, by unequivocal drawings, or by personal observa¬
tion of a working group member. Lists of identified species
without illustrations were not used. Interested workers can
update these maps through their own research. A database for
each figure on the plates is archived at the Cushman
Laboratory, at Rutgers University, and at the University of
Tubingen.

The working group was saddened by the sudden death of
Graham Jenkins in August 1995. He played an active role at the
meetings of the working group in his capacity as secretary of
the International Subcommission on Paleogene Stratigraphy
and was valued for his expert knowledge of Paleocene
Southern Ocean planktonic foraminifera.

Acknowledgments

The Paleogene Planktonic Foraminiferal Working Group
(PPFWG) is indebted to Hans Bolli (Zurich), Walter Blow
(deceased), and Nina Subbotina (deceased) whose pioneering
contributions to the study of Paleogene planktonic foraminifera
spanned nearly a half-century from the mid-1930s to the
mid-1980s and laid the groundwork and provided the inspira¬
tion for the taxonomic revision presented in this Atlas. The
Paleogene Planktonic Foraminifera Working Group was
organized in 1987 at a meeting at the British Petroleum (BP)
Research Centre in Sunbury on Thames, U.K. We thank J.
Athersuch of BP for hosting this important first meeting. The
next five meetings of the working group were held at the
Institute und Museum fur Geologie und Palaontologie, Univer¬
sitat Tubingen, Tubingen, Germany, where Ch. Hemleben
graciously hosted those meetings. The invaluable logistical
assistance of J. Breitinger and D. Miihlen at those meetings is
deeply appreciated. We thank H. Htitteman for his assistance in
examining specimens using a scanning electron microscope
and H.P. Luterbacher, Universitat Tubingen, for access to his
collections of Russian species and samples from the type level
of the “Globigerina ” eugubina Zone. Brian T. Huber hosted
the seventh meeting of the working group at the National
Museum of Natural History, Smithsonian Institution, Washing¬
ton, D.C., and R.K. Olsson hosted the final meeting at Rutgers
University, Piscataway, New Jersey.

Discussions with Nina Subbotina (St. Petersburg, deceased),
Valery Krasheninnikov (Moscow), and Khalil Alliyula (Baku,
deceased) were helpful in elucidating problems of taxonomy

among species housed in the collections of VNIGRI (St.
Petersburg), AN (GI) (Moscow), and AN (GI) (Baku),
respectively, during various visits (1958-1988) by W.A.
Berggren. We appreciate the assistance of S.P. Jakovleva,
VNIGRI, St. Petersburg, and N. Muzylov, Geological Institute,
Russian Academy of Sciences, Moscow, to F. Rogl in
obtaining a loan of Russian type material. These specimens are
shown on Plates 8-12 of the atlas. Scanning electron
micrographs (SEM) of primary types at the National Museum
of Natural History (collections of the former United States
National Museum (USNM)) shown on Plates 13-17 were
taken and mounted by B.T. Huber. Scanning electron micros¬
copy by S. D’Hondt at the University of Rhode Island was
assisted by P. Johnson.

Material used in preparing scanning electron micrographs of
Paleocene species were supplied by members of the working
group. Specimens were selected from personal collections and
from Deep Sea Drilling Project (DSDP) and ODP sites. These
are illustrated on Plates 17-71. Micrographs for wall texture
and preservation illustrated on Plates 1-7 are from the
collections of Ch. Hemleben. We deeply appreciate the
indefatigable work of H. Hiittemann, Universitat Tubingen, in
taking of the thousands of micrographs needed for composing
the plates for the atlas. These plates were prepared in the
laboratory of Ch. Hemleben. We thank J. Breitinger, D.
Miihlen, and B. Rodiger for their assistance. We acknowledge
the opportunity to investigate specimens collected by W.
Weiss.

The following research support is acknowledged: W.A.
Berggren (Marine Geology and Geophysics Branch, Ocean
Sciences Division of NSF), Ch. Hemleben (Deutsche
Forschungsgemeinschaft (DFG) He 697/15), S. D’Hondt
(supported in part by the Earth Sciences Division of NSF), and
R.D. Norris (Earth Sciences Division of NSF). We thank the
Ocean Drilling Program for supplying samples used in this
study.

A number of scientists with interest in Paleogene planktonic
foraminifera attended some of the meetings and participated in
the discussions of the working group. They include A.J.
Arnold, Florida State University, Tallahassee, Florida, U.S.A.;
F.T. Banner, University College of London, London, U.K.; C.
Benjamini, Ben Gurion University of the Negev, Beer Sheva,
Israel; A. Boersma, Microclimates Research Consultants,
Stony Point, New York, U.S.A.; R. Corfield, University of
Oxford, Oxford, U.K.; R.L. Fleisher, Chevron U.S.A. Inc.,
Houston, Texas, U.S.A.; S. Gaboarrdi, University of Milano,
Milan, Italy; A. v. Hillebrandt, Technical University of Berlin,
Berlin, Germany; C. Kelly, University of North Carolina, North
Carolina, U.S.A.; E. Kitchell, University of Michigan, Michi¬
gan, U.S.A.; Q. Li, Imperial School of Science and Technol¬
ogy* London, U.K.; H. Luterbacher, Universitat Tubingen,
Tubingen, Germany; E. Molina Martinez, University of
Zaragoza, Zaragoza, Spain; N. MacLeod, University of
Michigan, Ann Arbor, Michigan, U.S.A.; I. Premoli Silva,
University of Milano, Milan, Italy; S. Radford, Imperial School

NUMBER 85

5

Cretaceous

Maastrichtian

early Paleocene

PO

Pa

PI

P2

late Paleocene

P3

a i b

P4

a|b^c

P5

Taxon

Species Genus

H-h

cretacea

Guembelitria

alabamensis

extensa Parvularugoglobigerina
eugubina

daubjergensis

claytonensis
homerstownensis

Globoconusa

Woodringina

morsel

midwayensis

subtriangularis

crinita

wilcoxensis

trinitatensis

Chiloguembelina

holmdelensis

monmouthensis

Hedbergella

archeocompressa

planocompressa

compressa

imitata

ehrenbergi

chapmani

pseudomenardii

ovalis

planoconica

australiformis

Globanomalina

eobulloides

edita

spiralis

Eoglobigerina

aff. pseudobulloides
pseudobulloides .

varianta Pcircisiibbotinci

variospira

trivialis

triloculinoides

cancellata

triangularis

velascoensis

Subbotina

taunca

pseudoinconstans

inconstans

uncinata

Praemurica

H- b

pusilla

albeari

tadjikistanensis

Igorina

strabocella

nitida

subsphaerica *
mckannai
coalingensis
soldadoensis

Acarinina

praeangulata

angulata

conicotruncata

apanthesma

velascoensis

pasionensis

acutispira

occlusa

acuta

aequa

subbotinae

gracilis

Morozovella

waiparaensis
"Z." virgata
teuria
aegyptiaca

Zeauvigerina

cretacea

Rectoguembelina

FIGURE 2.—Stratigraphic ranges of Paleocene planktonic foraminiferal species by genus. (* dashed line
represents range extension at southern high latitude sites.)

6

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Cretaceous

Maastrichtian

early Paleocene

PO

Pa

PI

aib^

P2

late Paleocene

P3

P4

a~i b | c

P5

Taxon

- 1—4

I I

-+-h-

-4_I_

-I.I~

Hedbergella holmdelensis
Guembelitria cretacea
Rectoguembelina cretacea
Zeauvigerina waiparaensis
Hedbergella monmouthensis

Parvularugoglobigerina alabamensis
Parvularugoglobigerina extensa
Globanomalina archeocompressa
Eoglobigerina eobulloides
Praemurica taurica

Parasubbotina aff. pseudobulloides
Parvularugoglobigerina eugubina
Globoconusa daubjergensis
Woodringina claytonensis
Woodringina hornerstownensis

Chiloguembelina morsei
Subbotina trivialis
Eoglobigerina edita
Globanomalina planocompressa
Praemurica pseudoinconstans

Parasubbotina pseudobulloides
Chiloguembelina midwayensis
Subbotina triloculinoides
"Zeauvigerina" virgata
Globanomalina compressa

Praemurica inconstans
Parasubbotina varianta
Chiloguembelina subtriangularis
Zeauvigerina teuria
Globanomalina imitata

Subbotina cancellata
Eoglobigerina spiralis
Praemurica uncinata
Morozovella praeangulata
Globanomalina ehrenbergi

Subbotina triangularis
Parasubbotina variospira
Morozovella angulata
Igorina pusilla
Morozovella conicotruncata

Acarinina strabocella
Igorina albeari
Morozovella apanthesma
Subbotina velascoensis
Igorina tadjikistanensis

Morozovella velascoensis
Globanomalina chapmani
Morozovella pasionensis
Morozovella acutispira
Morozovella occlusa

Globanomalina pseudomenardii
Acarinina subsphaerica*

Acarinina nitida
Chiloguembelina crinita
Acarinina mckannai

Morozovella acuta
Zeauvigerina aegyptiaca
Chiloguembelina wilcoxensis
Globanomalina oval is
Acarinina coalingensis

Acarinina soldadoensis
Morozovella aequa
Globanomalina planoconica
Morozovella subbotinae
Chiloguembelina trinitatensis
Globanomalina austral iformis
Morozovella gracilis

FIGURE 3.—Stratigraphic ranges of Paleocene planktonic foraminiferal species by first occurrence. (* dashed line
represents range extension at southern high latitude sites.)

NUMBER 85

7

Cretaceous

Maastrichtian

early Paleocene

PO

Pa

PI

P2

late Paleocene

P3

a I b

P4

a i b

Taxon

P5

Hedbergella holmdelensis
Hedbergella monmouthensis
Parasubbotina aff. pseudobulloides
Parvularugoglobigerina extensa
Parvularugoglobigerina eugubina

Praemurica taurica
Guembelitria cretacea
Woodringina claytonensis
Eoglobigerina eobulloides
Globanomalina archeocompressa

Chiloguembelina morsei
Globoconusa daubjergensis
Globanomalina planocompressa
Eoglobigerina edita
Praemurica pseudoinconstans

Subbotina trivialis
Eoglobigerina spiralis
Rectoguembelina cretacea
Praemurica inconstans
Globanomalina compressa

Praemurica uncinata
Parasubbotina pseudobulloides
Morozovella praeangulata
Parvularugoglobigerina alabamensis
Chiloguembelina subtriangularis

Igorina pusilla

Woodringina hornerstownensis
Globanomalina ehrenbergi
Acarinina strabocella
Parasubbotina variospira

Subbotina triloculinoides
Morozovella conicotruncata
Morozovella angulata
Acarinina subsphaerica*
Zeauvigerina teuria

Subbotina cancellata
Morozovella acutispira
Acarinina nitida
Acarinina mckannai
Morozovella apanthesma
Igorina albeari

Globanomalina pseudomenardii
Globanomalina imitata
Chiloguembelina midwayensis
"Zeauvigerina" virgata

Parasubbotina varianta
Subbotina triangularis
Morozovella velascoensis
Globanomalina chapmani
Morozovella pasionensis

Morozovella occlusa
Morozovella acuta
Zeauvigerina waiparaensis
Subbotina velascoensis
Igorina tadjikistanensis

Chiloguembelina crinita
Zeauvigerina aegyptiaca
Globanomalina ovalis
Acarinina coalingensis
Acarinina soldadoensis
Morozovella aequa
Globanomalina planoconica
Chiloguembelina wilcoxensis
Morozovella subbotinae
Chiloguembelina trinitatensis

Globanomalina australiformis
Morozovella gracilis

FIGURE 4.—Stratigraphic ranges of Paleocene planktonic foraminiferal species by last occurrence. (* dashed line
represents range extension at southern high latitude sites.)

8

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

of Science and Technology, London, U.K.; S. Spezzaferri,
University of Milano, Milan, Italy; and S. Sturrock, British
Petroleum Ltd., Sunbury, U.K. We thank J.V. Browning,
Rutgers University, for his assistance in the preparation of
figures.

ABBREVIATIONS. —Index of abbreviations used in the atlas
for foraminifer collections and collection examiners is as
follows.

Foraminifer Collections:

BP

British Petroleum, London, England

CC

Cushman Collection Catalog (USNM)

CPC

Commonwealth Paleontological Collection,
Canberra, Australia

GAN

Geological Institute, Academy of Sciences,
Moscow, Russia

P

Protozoa Catalog (USNM)

UC

Collections of the University of Chicago
Walker Museum in the Field Museum,
Chicago, Illinois

USNM

Collections of the former United States
National Museum now in the National
Museum of Natural History, Smithsonian
Institution, Washington, D.C.

UWA

University of Western Australia, Perth, Aus¬
tralia

VNIGNI

Vsesoyuznogo Neftyanogo Nauchno-
Issledovatel’skogo Geologo Instituta (All
Union Petroleum Scientific Research Geo¬
logical Institute), St. Petersburg, Russia

VNIGRI

Vsesoyuznogo Neftyanogo Nauchno-
Issledovatel’skogo Geologo-Razvedo-
chnogo Instituta (All Union Petroleum
Scientific Research Geological Prospecting
Institute), St. Petersburg, Russia

Examiners:

BTH

Brian T. Huber

CL

Chengjie Liu

FR

Fred Rogl

GJ

Graham Jenkins

RDN

Richard D. Norris

RKO

Richard K. Olsson

SD

Steven D’Hondt

WAB

William A. Berggren

Biostratigraphy
(by W.A. Berggren and R.D. Norris)

The use of planktonic foraminifera in biostratigraphy may be
said to be an essentially post-World War II phenomenon
(although there were several pre-war contributions of less than
lasting value) that resulted from the recognition of their
usefulness in local and regional biostratigraphic zonation and
correlation. These studies were often, but not exclusively,

connected with the exploration for petroleum, particularly in
the North Caucasus, Crimea, Tadzhik Depression, and other
southwestern portions of the former Soviet Union (Subbotina,
1947, 1953; Morozova, 1959, 1961; Leonov and Alimarina,
1960; Alimarina, 1962, 1963), in the Caribbean region
(Bronnimann, 1952; Bolli, 1957a, 1957b), and in the Gulf of
Mexico and Atlantic Coastal Plain regions (Loeblich and
Tappan, 1957a). Various biostratigraphic zonal schemes were
developed by the authors cited above and by others, and these
have been rapidly ensconced in the classic biostratigraphic
hagiography of the past half century. Since the advent of the
DSDP (1968) and its successor program the ODP (1985-
present) the various zonal schemes have found widespread
application in regional and global biostratigraphic studies. In
the following section we present a brief review of the major
Paleocene biostratigraphic zonal schemes developed over the
past 50 years. It should be remembered that some of these
schemes were developed as part of a larger zonal scheme—the
Paleogene or the Cenozoic—so that reference to the larger
framework is unavoidable in certain instances.

A detailed zonal biostratigraphy of the Danian and Montian
stages (as recognized) in the Crimea, North Caucasus, and
“Boreal” areas (Russian Platform and Precaspian Basin) was
developed by Morozova (1959, 1960). In these and subsequent
studies (Morozova, 1961), she recognized several taxa that
have become important in lower Paleocene (lower Danian
Stage) biostratigraphy, such as Eoglobigerina eobulloides and
Globigerina taurica.

Coarsely muricate acarininids have figured prominently in
middle to late Paleocene zonal biostratigraphies, particularly
that of the “official” Paleogene zonation of the former Soviet
Union (Permanent Interdepartmental Stratigraphic Commis¬
sion for the Paleogene of the USSR, 1963). This is because of
the general paucity of keeled morozovellids (M. acuta, M.
velascoensis) and of globanomalinids ( G. pseudomenardii) in
the formation(s) above the strata bearing Morozovella angu-
lata-M. conicotruncata in the northern foothills of the
Caucasus Mountains (Subbotina, 1953; Alimarina, 1963) and
in southwestern Crimea (Morozova, 1959, 1960). This latter
scheme would appear to have drawn heavily upon the detailed
studies by the authors cited above as well as those of Shutskaya
(1956, Precaucasus; 1962, Crimea, Precaucasus, and Transcas¬
pian Region; 1965, Turkmenistan). (The taxonomic treatment
of taxa is not up-to-date, and the identification of some taxa
shouldn’t be attempted when preservation is so poor.)
Shutskaya subsequently presented a detailed synthesis of her
decade-long studies in the southwestern Soviet Union, includ¬
ing a detailed zonal scheme for the Paleocene to lower Eocene
in her doctoral thesis (1965) and then concluded with an
exhaustive historical overview of the Paleogene
(bio)stratigraphic succession and zonal characteristics of the
Crimea, northern Precaucasus, and western part of Central Asia
(1970a). In the latter work she included 40 plates containing
detailed illustrations of the faunal content (planktonic and

NUMBER 85

9

benthic taxa) of each Paleocene and lower Eocene zone from
each region, making it possible to better understand the basis
for biostratigraphic subdivision of the Paleogene of the
southwestern Soviet Union. It also allows for correlation of her
zonal scheme with that subsequently proposed in the West over
the past 35 years. Krasheninnikov (1965, 1969) also made
significant contributions to Paleocene biostratigraphy of the
southwestern area of the former Soviet Union as well as other
(sub)tropical areas of the world.

Paleocene planktonic foraminiferal biostratigraphy in the
West was essentially baptized in the form of a detailed zonation
developed for the Paleocene and lower Eocene of Trinidad by
Bolli (1957a; modified in 1966), which was followed soon after
by a zonal scheme developed for (sub)tropical regions by
Berggren (1969a, 1971a; modified and (re)defined by Berggren
and Miller, 1988) and Blow (1979). Premoli Silva and Bolli
(1973) made minor changes to the earlier zonation of Bolli
(1957a) with the insertion of the Globorotalia edgari Zone
between the Globorotalia velascoensis Zone (below) and the
Globorotalia rex (= G. subbotinae) Zone (above; see Toumark-
ine and Luterbacher, 1985). Jenkins (1971) formulated a
relatively broad zonal biostratigraphic scheme for the Paleo¬
cene (as part of a larger Cenozoic study) of New Zealand. With
the recognition that Paleocene low latitude, (sub)tropical
zonation(s) are not fully applicable at high latitudes, Stott and
Kennett (1990) developed a zonal biostratigraphy for high
(austral) latitudes of the Antarctic.

We have adopted the following seven-fold (sub)tropical
biostratigraphic zonation of the Paleocene (Figure 1), which is
based on the studies of Berggren and Norris (1993) who
redefined the zonal boundary definitions of Zones P3a/b, P4/5,
and proposed a threefold subdivision of Zone P4. This zonal
biostratigraphy has been more fully defined and elaborated
upon in Berggren et al. (1995). The definition of the seven
Paleocene zones (and their subdivisions), magnetochronologic
calibration, and estimated age is presented below. Additional
information on the characterization of these zones may be
found in Berggren et al. (1995). Modifications to this scheme
have been proposed by Lu and Keller (1995) based on their
study of DSDP Site 577. Additional information on the history
of Paleogene/Paleocene planktonic foraminiferal biostratigra¬
phy may be found in Berggren and Miller (1988).

P0. Guembelitria cretacea Partial Range Zone (P0, Keller,
1988; emendation of Smit, 1982).

Definition: Biostratigraphic interval characterized by the
partial range of the nominate taxon between the Last
Appearance Datum (LAD) of Cretaceous taxa ( Glo-
botruncana, Rugoglobigerina, Globigerinelloides,
among others) at the K/P boundary as delineated by the
essentially global iridium spike and the First Appearance
Datum (FAD) of Parvularugoglobigerina eugubina.

Magnetochronologic calibration: Chron C29r (late).

Estimated age: 65.0-64.97 mya; earliest Paleocene (Da-
nian).

Pa. Parvularugoglobigerina eugubina Total Range Zone
(Liu, 1993; emendation of Pa of Blow, 1979; Luterbacher
and Premoli Silva, 1964).

Definition: Biostratigraphic interval characterized by the
total range of the nominate taxon, Parvularugoglobiger¬
ina eugubina.

Magnetochronologic calibration: Chron C29r (late).

Estimated age: 64.97-64.9 mya; earliest Paleocene (Da-
nian).

PL Parvularugoglobigerina eugubina-Praemurica uncinata
Interval Zone (PI, defined in Berggren et al., 1995;
emendation of Berggren and Miller, 1988).

Definition: Biostratigraphic interval between the LAD of
Parvularugoglobigerina eugubina and the FAD of
Praemurica uncinata.

Magnetochronologic calibration: Chron C29r (late)-Chron
C27n(0).

Estimated age: 64.9-61.2 mya; early Paleocene (Danian).

PI a. Parvularugoglobigerina eugubina-Subbotina triloc-
ulinoides Interval Subzone (PIa, defined in Berggren et
al., 1995; emendation of Parasubbotina pseudobulloi-
des Subzone (Pla) in Berggren and Miller, 1988).
Definition: Biostratigraphic interval between the LAD of
Parvularugoglobigerina eugubina and the FAD of
Subbotina triloculinoides.

Magnetochronologic calibration: Chron C29r (late)-
Chron C29n (middle).

Estimated age: 64.9-64.5 mya; early Paleocene (early
Danian).

Plb. Subbotina triloculinoides-Globanomalina com-
pressa/Praemurica inconstans Interval Subzone (Plb,
defined in Berggren et al., 1995; emendation of, but
equivalent to. Subzone Plb in Berggren and Miller,
1988).

Definition: Biostratigraphic interval between the FAD of
Subbotina triloculinoides and the FADs of Globa-
nomalina compressa and/or Praemurica inconstans.
Magnetochronologic calibration: Chron C29n (middle)-
Chron C28n (middle).

Estimated age: 64.5-63.0 mya; early Paleocene (Da¬
nian).

Pic. Globanomalina compressa/Praemurica inconstans-
Praemurica uncinata Interval Subzone (Pic, defined in
Berggren et al., 1995; emendation of, but equivalent to,
Subzone Pic in Berggren and Miller, 1988).

Definition: Biostratigraphic interval between the FAD of
Globanomalina compressa and/or Praemurica incon¬
stans and the FAD of Praemurica uncinata.
Magnetochronologic calibration: Chron C28n (middle)-
Chron C27n(o).

Estimated age: 63.0-61.2 mya; early Paleocene (Da¬
nian).

10

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

P2. Praemurica uncinata-Morozovella angulata Interval
Zone (P2, defined in Berggren et al., 1995; emendation of,
but biostratigraphically equivalent to, Zone P2 in Berg¬
gren and Miller, 1988).

Definition: Biostratigraphic interval between the FAD of
Praemurica uncinata and the FAD of Morozovella
angulata.

Magnetochronologic calibration: Chron C27n(o)-Chron
C27n(y).

Estimated age: 61.2-61.0 mya; late early Paleocene (late
Danian).

P3. Morozovella angulata-Globanomalina pseudomenardii
Interval Zone (P3, defined in Berggren et al., 1995;
emendation of Zone P3 in Berggren and Miller, 1988).

Definition: Biostratigraphic interval between the FAD of
Praemurica angulata and the FAD of Globanomalina
pseudomenardii.

Magnetochronologic calibration: Chron C27n(y)-Chron
C26r (middle).

Estimated age: 61.0-59.2 mya; late Paleocene (Selandian).

P3a. Morozovella angulata-Igorina albeari Interval Sub¬
zone (P3a, defined in Berggren et al., 1995).

Definition: Biostratigraphic interval between FAD of
Morozovella angulata and FAD of Igorina albeari.
Magnetochronologic calibration: Chron C27n(y)-Chron
C26r (early).

Estimated age: 61.0-60.0 mya; early late Paleocene
(Selandian).

P3b. Igorina albeari-Globanomalina pseudomenardii In¬
terval Subzone (P3b, defined in Berggren et al., 1995).
Definition: Biostratigraphic interval between FAD of
Igorina albeari and the FAD of Globanomalina
pseudomenardii.

Magnetochronologic calibration: Chron C26r (early)-
Chron C26r (middle).

Estimated age: 60.0-59.2 mya; late Paleocene (Selan¬
dian).

P4. Globanomalina pseudomenardii Total Range Zone (P4,
Bolli, 1957a).

Definition: Biostratigraphic interval characterized by the
total range of the nominate taxon, Globanomalina
pseudomenardii.

Magnetochronologic calibration: Chron C26r (middle)-
Chron C25n(y).

Estimated age: 59.2-55.9 mya; middle part of late Paleo¬
cene (late Selandian-Thanetian).

P4a. Globanomalina pseudomenardii/Acarinina sub-
sphaerica Concurrent Range Subzone (P4a, defined in
Berggren et al., 1995).

Definition: Biostratigraphic interval characterized by the
concurrent range of the nominate taxa between the
FAD of Globanomalina pseudomenardii and the LAD
of Acarinina subsphaerica.

Magnetochronologic calibration: Chron C26r (middle)-
Chron C25r (early).

Estimated age: 59.2-57.1 mya; late Paleocene (latest
Selandian-early Thanetian).

P4b. Acarinina subsphaerica-Acarinina soldadoensis In¬
terval Subzone (P4b, herein defined).

Definition: Biostratigraphic interval between the LAD of
Acarinina subsphaerica and the FAD of Acarinina
soldadoensis.

Magnetochronologic calibration: Chron C25r (early)-
Chron C25r (late).

Estimated age: 57.1-56.5 mya; late Paleocene (Than¬
etian).

P4c. Acarinina soldadoensis/Globanomalina pseudome¬
nardii Concurrent Range Subzone (P4c, defined in
Berggren et al., 1995).

Definition: Biostratigraphic interval characterized by the
concurrent range of the nominate taxa between the
FAD of Acarinina soldadoensis and the LAD of
Globanomalina pseudomenardii.

Magnetochronologic calibration: Chron C25r (late)-
Chron C25n(y).

Estimated age: 56.5-55.9 mya; late Paleocene (late
Thanetian).

P5. Morozovella velascoensis Interval Zone (P5, Bolli, 1957a;

P5 and P6a of Berggren and Miller, 1988).

Definition: Biostratigraphic interval between the LAD of

Globanomalina pseudomenardii and the LAD of Mo¬
rozovella velascoensis.

Magnetochronologic calibration: Chron C25n(y)-Chron

C24r (middle).

Estimated age: 55.9-54.7 mya; latest Paleocene-earliest

Eocene (latest Thanetian-earliest Ypresian).

Wall Texture, Classification, and Phylogeny

(by Ch. Hemleben, R.K. Olsson, W.A. Berggren,
and R.D. Norris)

The recovery of early Paleocene planktonic foraminifera
following the end of the Cretaceous mass extinctions led to
fundamental changes in the wall structure of the test, changes
linked to the way in which the earliest Paleocene species
adapted to the water-mass environment. These changes in wall
structure, consequently, reflect biological activity. Five species
are known to have survived into the Paleocene. We believe that
the planktonic foraminiferal species that came to occupy the
Paleocene oceans were derived from three survivors, which
rapidly gave rise to distinct lineages. The structural differences
in the test wall allow basic groups to be recognized. Two
groups are separated by pore size, one being microperforate
(pore diameter < 1 pm) and the other normal perforate (pore
diameter 2-7 pm). The microperforate species, which evolved
from the survivor-species Guembelitria cretacea, have been

NUMBER 85

11

dealt with in various studies (D’Hondt, 1991; Liu and Olsson,
1992). In the earliest Paleocene (Danian), trochospiral and
biserial microperforate taxa evolved from a triserial taxon.
Although there are fundamental changes that occurred in the
shape of the test, the wall structural changes are moderate (a
thin wall pierced by micropores, and pustule growth in rounded
mounds or short, sharp protuberances).

Wall structure changes in normal perforate planktonic
foraminifera were often quite dramatic. Most notable is the
development of a cancellate wall that is a distinctive and
diagnostic feature of the Cenozoic. This feature, which
developed in two groups, one with spines and the other without
spines, indicates that the biological activities of planktonic
species that possessed this structure were significantly different
from the biological activities in Cretaceous species where this
structure is absent. Another dramatic wall structural change
was the development of the “pseudospinose” (Benjamini and
Reiss, 1979) or “muricate” wall (Blow, 1979), identified by a
heavy pustulose growth. All the taxa in this group can be
separated phylogenetically on the basis of their distinctive
pustulose wall texture. Perhaps the most dramatic change in
wall structure was the development of spines, which was
accompanied by growth of a cancellate wall. Wall growth in
species using spines is different from wall growth in
nonspinose pustule bearing species. Pustules are layered
structures, which form during ontogeny as part of the wall, in
contrast to spines, which are elongated single crystals planted
in the shell wall (Hemleben, 1969; Hemleben, et al., 1991).
Pustulose growth is rare in spinose species. Due to the
development of these distinctive wall structures Paleocene
normal perforate planktonic foraminifera can be classified and
organized in phylogenetic lineages.

A classification based on functional morphology is some¬
what more complex than one based on simple test morphology
as it presumes that one can correctly interpret the function of a
structure in an extinct species. In the Paleocene this is made
easier because direct comparison can be made to living
planktonic species in which there is much data on the function
of test morphology and biological activity (Hemleben et al.,
1977, 1985, 1989, 1991). The basic underlying bilamellar wall
concept of Reiss (1957) can be applied to all known Paleocene
planktonic foraminiferal species. The introduction of spines in
the earliest Danian allowed planktonic foraminifera to develop
a different habit of food gathering and to invade different
habitats. It is possible that some species may have collected
symbionts as is suggested by the carbon isotopic studies of
D’Hondt and Zachos (1993) on Eoglobigerina eobulloides.
Thus, photosymbiosis may have developed along with the
evolution of some of the first spinose planktonic species of the
Cenozoic. Species having symbionts would have been bound to
the photic zone.

The nonspinose planktonic foraminifera are distinguished by
two basic types of wall texture, smooth-walled and cancellate-
walled. In the smooth-walled type, pustules may be absent,

sparsely developed, or heavily developed as is observed in
modem Globorotalia. Heavy pustule development in the
Paleocene led to the “muricate structure,” which characterizes
the genera Acarinina and Morozovella. The cancellate texture
develops by lateral growth of small pustules into smooth ridges
upon which additional pustules may grow. This texture is
observed in the modem Neogloboquadrina dutertrei.

It would appear, then, that some adaptations that evolved in
Paleocene species of planktonic foraminifera are similar, if not
identical in some cases, to the adaptations that are shown by
living species of planktonic foraminifera. Because wall texture
reflects the adaptive strategies exhibited in the biological
activity of living species, it may be an important guide to
phylogenetic study. We regard this relationship as a unifying
concept in the classification and phylogenetic study of
Cenozoic planktonic foraminifera. Although more work needs
to be done on wall texture and morphologic change in the
evolution of Paleogene planktonic species, it seems clear from
the results of the Paleogene Planktonic Foraminifera Working
Group that wall texture provides a guide to understanding the
evolution and phylogeny of Paleocene planktonic foraminiferal
species and for their classification (Plates 1-6).

Globorotaliid Wall Texture

The globorotaliid type, which includes the juvenile up to the
neanic stage (Brummer et al., 1986), is characterized by a
smooth nonspinose wall with more or less scattered pustules.
Pustules increase in number during ontogeny, serving as anchor
points forrhizopods (Plate 1: Figures 1,2, 5, 6; Plate 3). During
continued growth, more pustules form on the center of the
spiral side, around the aperture, and, if a keel is present, on the
keel. The last growth stage may be characterized by a coarse
crystal growth or the pustules may coalesce to form a coarse
crystalline outer layer (Plate 3: Figures 10, 11, 14). The
abundance of pustules varies from species to species. The
interpustule area is usually smooth with no or very low relief.
Some typical living representatives of this type are Globoro¬
talia hirsuta, G. menardii, G. truncatulinoides and others
(Hemleben et al., 1977, 1985, 1991), and their ancestors. The
Paleocene genus Globanomalina has this type of wall texture
(Plate 4: Figures 4-13, 16). The smooth-walled genus
Globanomalina was derived from the late Maastrichtian
hedbergellid, Hedbergella holmdelensis, with the first species
being G. archeocompressa (Plate 4: Figures 4, 5). In this
transition, the morphologic characters of the descendant
species (compressed test with an imperforate peripheral band
and with an extraumbilical aperture bordered by a narrow lip)
are derived from the ancestral species. The wall of H.
holmdelensis is smooth with scattered small pustules on the
chamber walls (Plate 4: Figures 1-3). In G. archeocompressa
the pustules become confined to the umbilical area rather than
being scattered over the entire test. A change to somewhat more
angular-shaped chambers accompanies the transition. Although
the change in overall morphology is small, the wall becomes

12

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

distinctly smooth, a character that identifies species of
Globanomalina and its possible descendant, Pseudohastiger-
ina.

Muricate Wall Textures

In the Paleocene, a heavily pustulose wall texture occurs in
the genera Acarinina and Morozovella (Plates 39-55). The test
wall is characterized by large very coarse pustules that may
cover the entire test, be concentrated on the umbilical
shoulders, or be confined to the periphery of the test and
forming a keel (Plate 4: Figures 14, 15; Plate 5: Figures 1-4).
The pustules grow on a smooth globorotaliid surface. In the
first species of Acarinina, A. strabocella, the early ontogenetic
stage has a rather smooth wall resembling that of modem
globorotaliid species, but later in ontogeny (or chamber
calcification) the typical pustule pattern appears, which is
similar to that in modem Globorotalia inflata (Plate 3: Figures
3, 4, 7). The pustules are spread over the entire test; however,
they are arranged in lines leading towards the aperture and are
especially large and thick in front of the aperture (see Plate 43:
Figure 4). This development is a short step to the more typical
heavily pustulose acarininids in which the pustules become
broad and elongate (Plates 39-42, 44). The wall texture
develops by the growth of conical to blade-like pustules at
triple points between the pores. As these pustules grow larger
they coalesce into larger structures, which give the muricate
wall a somewhat cancellate appearance. Pustule enlargement is
greatest around the umbilicus and often completely closes off
the pores.

In the evolution of Morozovella two groups of species are
separated by different types of muricate wall texture. The
muricate wall texture in the Morozovella aequa line of species
develops by growth of conical pustules of various sizes at triple
points between pores on rather smooth chamber walls (Plates
47-49, 54). Heavier pustule growth occurs on the umbilical
shoulders of the chambers and along the test periphery forming
an imperforate muricate keel in some species. In the Morozov¬
ella velascoensis line of species the surface of the chambers are
smooth (Plates 45, 46, 50-52, 55). Very heavy conical pustule
growth occurs on the umbilical shoulders of the chambers and
along the axial periphery of the test forming a strong,
imperforate muricate keel. Scattered small pustules also may
occur on the chamber surfaces. Extensions of the muricate keel
occur on the spiral side of the test along the chamber sutures
and the spiral suture. The genus Morozovella is further
characterized by the development of conical-shaped chambers.

Neogloboquadrinid Wall Texture (Praemuricate)

This type of wall texture is seen in the living species
Neogloboquadrina dutertrei (Plate 5: Figures 5-11). The
growth pattern during ontogeny consists of the development of
longer or shorter subparallel low ridges of plate-like crystals,
often oriented towards the aperture (Plate 5: Figures 9, 10).

They become more and more prominent as short ridges
connecting the subparallel ones start to grow and, eventually,
form a honeycomb cancellate wall structure (Hemleben et al.,
1991). The short ridges are less developed and may extend only
part way from one elongate ridge to the other (Plate 5: Figures
9, 10). It is a very common structure in Paleogene and Neogene
planktonic foraminifera. This type of wall texture occurs in the
Paleocene genera Igorina and Praemurica (Plates 56-62). A
calcite crust (Plate 5: Figures 8, 11), which is a normal feature
in Neogloboquadrina, has not yet been observed in Paleocene
species. This is probably due to the warmer Paleocene surface
waters as this crust is a feature usually developed in the cold
waters of the modem ocean. In the modem N. dutertrei,
however, as pustule growth becomes more and more prominent
the test wall becomes thicker and encrusted, a feature that also
is observed in Igorina (Plates 56-58). In Zone P0 the transition
from the ancestral Maastrichtian Hedbergella monmouthensis
to Praemurica involves the buildup of subparallel pustulose
ridges and short connective ridges, thus producing the
cancellate texture (Plate 5: Figures 12, 18; Plate 6: Figures

1- 4). In Praemurica taurica (Plate 61), the first Praemurica
species, the test remains a very low trochospiral with an
extraumbilical aperture, but selection is to a H. monmouthensis
morphotype with a lower rate of chamber expansion in the
ultimate whorl (six-chambered test). In order to avoid
confusion with the term neogloboquadrinid we propose the use
of praemuricate for Paleocene taxa with this wall texture.

Spinose Wall Texture

The spinose habit indicates that a group of new planktonic
foraminifera intruded into the carnivorous food niche. The food
catching process is supported by long calcitic spines along
which flows the rhizopodial cytoplasm. Actively swim min g
zooplankton are snared and held without losing control of a
struggling zooplankton organism. The spines are separated
from the wall and are planted like telephone poles (Plate 1:
Figures 3, 4, 7-20). During the reproductive process (gameto-
genesis) the spines are dissolved, leaving a vacated spine hole
as an indication of the spinose condition, and gametogenetic
calcite is deposited along the interpore ridges (Plate 2: Figures

2- 16). More fundamental changes in wall texture and test
morphology took place in the transition from Hedbergella
monmouthensis to the spinose genera Eoglobigerina and
Parasubbotina (Plates 18-23). The fundamental morphologic
characters (trochospiral test with an extraumbilical aperture
bordered by a narrow lip) are maintained in the descendent
species, but the evolution of wall texture involves the
innovation of a cancellate spinose wall. In H. monmouthensis
the wall is lightly pustulose throughout the test, and low
depressions or primitive pore pits occur in the chamber walls
especially surrounding the umbilicus (Plate 31). The test is a
very low trochospiral with rapidly inflating chambers in the
ultimate whorl, but as noted in Liu and Olsson (1994), there is
a range of morphotypes that show (1) a reduced rate of

NUMBER 85

13

chamber-size increase with generally six chambers in the
ultimate whorl, and (2) a moderately elevated trochospiral test
with five chambers in the ultimate whorl. In the transition to the
first spinose species, Eoglobigerina eobulloides, the moder¬
ately elevated trochospiral test becomes weakly cancellate and
spinose (Plate 19). The cancellate texture is enhanced by
gametogenetic calcification. Due to the moderately elevated
trochospiral test the aperture shifts to a more umbilical position
and is only slightly extraumbilical. In the derivation of
Parasubbotina (Plates 21, 22) the rate of chamber increase is
much more rapid than in Eoglobigerina, which produces a very
low trochospiral test with large globular chambers in the
ultimate whorl. The wall becomes weakly cancellate and
spinose. The aperture remains extraumbilical. Subbotina (Plate
2: Figures 3-6, 15, 16; Plates 24-29) evolves from Eoglobig¬
erina by a reduction in the number of chambers in the final
whorl, a shifting of the aperture towards an umbilical position,
and the development of a stronger cancellate-wall texture.

Preservation and Diagenesis

Preservation of fossil planktonic foraminifera plays an
important role in taxonomic and phylogenetic studies. The
effect of the lysocline and the carbonate compensation depth
controls the preservation or partial preservation of an assem¬
blage of planktonic foraminifera. Absence of a species could be
due to its greater susceptibility to dissolution than other
species, thereby leading directly to loss of information.
Preservation of planktonic foraminifera can be loosely meas¬
ured by visual inspection under the light microscope and more
recently by the SEM. It is especially important to assess the
degree of preservation of foraminifera tests in isotopic
analyses, but it is also important in various other studies
utilizing planktonic foraminifera. For instance, in taxonomic
and phylogenetic studies, the degree of preservation may
appear to be excellent (pristine) preservation under the light
microscope but may actually be rather poor when examined
using the SEM under high magnification. In working out
phylogenetic lineages it is important to be able to recognize the
original wall texture in order to assess whether an ancestor-
descendant relationship exists. Preservation is an important
factor in census work where many individuals of a species have
to be accurately identified for the data to be meaningful. Census
work should not be attempted where the tests of foraminifera
are heavily recrystallized and overgrown, thus making identifi¬
cation very subjective due to similar morphology of different
species. Plate 7 illustrates common types of diagenetic
alteration of a planktonic foraminiferal test.

Recrystallization can vary from slight to heavy (Plate 7:
Figures 1, 2, 5-8, 10-15). If the degree of recrystallization is
substantial, subhedral and euhedral calcite crystals form and
obscure the original wall (Plate 7: Figure 12). Overgrowth of
calcite (Plate 7: Figures 4, 8, 10) further obscures the original
wall. Corrosion of a test removes the outer wall layers (Plate 7:
Figures 3, 5, 6) thereby destroying the original wall texture.

Dissolution (Plate 7: Figures 3, 9) may destroy parts of the test
wall leaving holes or may strip away outer wall layers, altering
the appearance of the specimen. Accurate identification is
precluded under such circumstances. Plates 1-6 illustrate
well-preserved original wall texture that can be used as a guide
in assessing the effects of diagenesis on samples of fossil
planktonic foraminifera.

Phylogeny

The phylogeny of the normal perforate Paleocene planktonic
foraminifera is shown in Figure 5a, b and that of the
microperforate Paleocene planktonic foraminifera is shown in
Figure 6. Comments on the phylogeny of the microperforates
are given under each species in the Taxonomy section (also see
D’Hondt, 1991; Liu and Olsson, 1992). The lineages of the
normal perforates based on the study of wall texture is given
below along with comments on the major morphologic changes
that occurred in the evolution of the species in each lineage.

Spinose Lineages

Cancellate Lineages

Eoglobigerina
(Plates 18-20)

E. eobulloides-E. edita-E. spiralis lineage is characterized by

(1) a cancellate spinose test;

(2) development of a higher trochospiral test in E. edita and
E. spiralis ;

(3) a reduced rate of chamber expansion in E. edita
compared to E. eobulloides ;

(4) a more strongly developed cancellate wall that is
enhanced by gametogenetic calcification in E. edita and
E. spiralis.

E. eobulloides-Subbotina lineage is characterized in the
transition to Subbotina by

(1) a more strongly developed spinose cancellate wall;

(2) a reduced number of chambers in the ultimate whorl;

(3) development of a tripartite test due to a more rapid rate
of chamber-size increase;

(4) a more umbilically directed aperture in Subbotina.

Note. —In E. eobulloides the aperture has an umbilical to

slightly extraumbilical position due to the moderately
elevated trochospire. In Subbotina the increase in the rate of
expansion of chambers causes the aperture to shift to a more
umbilical position. This trend culminates in S. triloculinoi-
des by producing a large ultimate chamber with an
umbilically directed aperture. The lip maintains its position
relative to the apertural opening. With a greater expansion
rate of chambers, the initial moderately elevated coil is
enveloped by the expanding chambers thus producing a test
with an apparent low trochospire.

14

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Cretac.

Maastr.

early Paleocene

PO

Pa

PI

P2

late Paleocene

P3

a i b

P4

a

P5

Eocene

P6

Morphologic

Radiation

O

o>

3

e

CZ>

ovalis

imitata

L planocompressa

i compressa j>

ehrenbergi

australiformis
pseudomenardii

a rcheocom p ressa

chapmani

planoconica

nonspinose,
smooth wall, keel
in advanced forms

d

o'

o-

a

■Ni

3

->•

3

O

■ Hedbergella holmdelensis
• H. monmouthensis

nonspinose
K/T survivors

a:

o

Ss

o-

tauric a

■ pseudoinconstans
inconstans
m uncinata

nonspinose,
cancellate wall,
no keel

-o

2

o

a

o

a

i:

i i

■ pusilla

tadjiki-

stanensis

albeari

nonspinose, thick
& crusted wall,
keel in

advanced form

o

s

!!

::

S!

II

■ ■
■ f

4 praeangulata

\

gracilis

subbotinae

aequa

■ angulata

■ conicotruncata

apanthesma

racutispira

acuta

velascoensis

occlusa

pasionensis

nonspinose, conical
chambers,
muricate wall,
two lineages:

1. heavy muricate
keel;

2. weak keel

o

o

ni

o

<

ns

strabocella

aff. pseudobulloides

•

■

1

t

•

edit a
>eobulloides

—minckannai

•nitida

.. pseudobulloides

spiralis

trivialis

■h

■H

■ variospira

T

j cancellata
‘triloculinoides

soldadoensis
\subsphaerica *
coalingensis

varianta

triangularis

velascoensis

nonspinose,
cancellate wall,
no keel,

strongly muricate

spinose,
cancellate wall,
low trochospiral

spinose,
cancellate wall,
elevated coil

spinose,
cancellate wall,
reduction in
chamber number

o

a

2

S’

“o

a

2

Co

r—

•*».

o-

O'

o

C S-

o'

O'

.

On

o-

o-

o

FIGURE 5 a .—Phylogenetic reconstruction of normal perforate planktonic foraminifera showing the origin of
Morozovella from Praemurica uncinata following the hypothesis of Bolli (1957a). See text for explanation.
(* dashed line represents range extension at southern high latitude sites.)

NUMBER 85

15

Cretac.

Maastr.

early Paleocene

PO

Pa

PI

a ib I c

P2

late Paleocene

P3

a i b

P4

P5

a

b ! c

i

tida

•

_L—i_I

.t.r.

mcKannai

\ - l - ►!

Eocene

P6

Morphologic

Radiation

O

0>

3

3

<73

strabocella

coalingensis
subsphaerica *
soldadoensis

nonspinose,
cancellate wall,
no keel,

strongly muricate

a

a

+acutispira

s.

pasionensis

occlusa

velascoensis

acuta

. conicotruncata
■ angulata

i :

4 praeangulata

apanthesma
\aequa
subbotinae
I gracilis

nonspinose, conical
chambers,
muricate wall,
two lineages:

1. heavy muricate
keel;

2. weak keel

a

a

a

a

L planocompressa

m ovalis

i compressa »

l ' i

ehrenbergi
i i'

■ imitata

^austral iformis
pseudomenardii

archeocompressa

chapmani

planoconica

nonspinose,
smooth wall, keel
in advanced forms

O

a~

< 3 -

a

a

a

$

a

/I liil

L Hedbergella holmdelensis
r H. monmouthensis

nonspinose
K/T survivors

\\

■

■

■

■

■

■

«

■4—1-

Jm taurica

•pseudoinconstans
inconstans
- uncinata

nonspinose,
cancellate wall,
no keel.

4 -

1 1

■aff. pseudobulloides

• 1

•

4

*

«

*

■ edita

pusilla

tadjiki-

stanensis

^■■aa

spiralis

■ eobulloides

i—h

—I—r

■ trivialis

albeari

> i

pseudobulloides

■r

f

>variospira

\ cancellata
• triloculinoides

nonspinose, thick
& crusted wall,
keel in

advanced form

varianta

spinose,
cancellate wall,
low trochospiral

spinose,
cancellate wall,
elevated coil

triangularis

velascoensis

spinose,
cancellate wall,
reduction in
chamber number

“a

Cs

a

3

a

a

C*5

a

a

3 s

2

a-

a-

a

a

g 3

c*

a*

a-

65’

Co

a

a-

a-

a

FIGURE 5b. —Phylogenetic reconstruction of normal perforate planktonic foraminifera showing the origin of
Morozovella from Globanomalina imitata following the interpretation of Olsson and Hemleben (1996). See text
for explanation. (* dashed line represents range extension at southern high latitude sites.)

16

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Cretac.

Paleocene

Eocene

1 Genus

Morphologic

Radiation

Maastr.

PO

Pa

P3

P4

P5

P6

QH3

a

El

El

1

eu

exi

t

l

i

i

gubina

i

i

i

i

i

i

i

f ensa

Parvularugoglobigerina

low-high trochospiral,
blunt pustules, high,
slit-like areal aperture

\

i

I

m

■1

■

_ die

iban

iensi

5

high trochospiral,
pustules & pore-mounds,
high arch aperture

m

m

«

m

■

1

1

1

triserial, pore mound,
K/T survivor

111

■

3E

B

HI

- 1—

Globoc

onus

a dai

ibjer

gens

is

low trochospiral, sharp
pustules, basal &
supplementary apertures

t 1

1 '.'VVc-'V,.'';:*.: 1

•

•

»

- /-Wynn

tonens

\s

hor

nersi

r own

ensis

Woodringina

triserial to biserial,
weakly pustulose wall

•

•

•

•

•

■

•

•

•

■

■

■■

■

■

m

■

__ rtf id

wayensis

crinita

Chiloguembelina

biserial throughout,
pustulose wall !

X

■

■i

V

V

1

«

■

M
*
ii
it
i «

11
i •

■ ■

■ t
i •
i «

\

•

•

wild

- Cl/

■

II L L li

lY/pyt

•

•

•

ri C l.J

!

trinitaten

i

i

ntrinn mil

•

•

sis 1

firi c

i

i

i

1

1

\aj ninnr

i

s

1

1

t

Jtiac

i

i

i

Zeauvigerina }

biserial to uniserial,
pustulose to smooth
wall surface

i

u ;—
/

a

f

i

i

i

"7 "

? i

i

i

i

i

i

i

V 1/ £ UM
1 1

i

i

i

i

i

!

FIGURE 6.—Phylogenetic reconstruction of microperforate planktonic foraminifera and Zeauvigerina.

NUMBER 85

17

Parasubbotina
(Plates 21-23)

P. aff. pseudobulloides-P. pseudobulloides-P. varianta line¬
age is characterized by

(1) a weakly developed cancellate spinose wall in P. aff.
pseudobulloides ;

(2) development of a pronounced cancellate spinose wall
that is enhanced by gametogenetic calcification in P.
pseudobulloides;

(3) an increase in test size in P. pseudobulloides;

(4) a decreased number of chambers in the ultimate whorl in
P. varianta;

P. varianta-P. variospira lineage is characterized by

(1) an increased expansion of the chamber coil and a shift to
a moderately elevated trochospire in P. variospira;

(2) a decreased rate of expansion of chambers in P.
variospira;

(3) a test-size increase in P. variospira;

(4) development of tooth-like apertural lips in P. variospira.
Note. — Parasubbotina is distinguished from Subbotina

by its very low trochospire, the greater number of chambers

in the ultimate whorl, and high-arched umbilical-

extraumbilical aperture.

Subbotina
(Plates 24-29)

S. trivialis-S. aff. cancellata-S. cancellata-S. velascoensis
lineage is characterized by

(1) development of a coarsely cancellate spinose wall in S.
cancellata;

(2) a more rapid rate of chamber-size increase that ultimately
closes the umbilicus in S. velascoensis;

(3) a test-size increase in the lineage;

(4) development of flattened, oval-shaped chambers in S.
velascoensis.

S. trivialis-S. triloculinoides lineage is characterized by

(1) a more strongly developed cancellate spinose wall in S.
triloculinoides;

(2) a more rapid rate of chamber-size increase that ultimately
closes the umbilicus in S. triloculinoides;

(3) a test-size increase in S. triloculinoides.

S. trivialis-S. triangularis lineage is characterized by

(1) development of an asymmetric cancellate spinose pore
pattern with well-developed coalescing spine collars in S.
triangularis;

(2) development of wider than high oval-shaped chambers
in S. triangularis;

(3) increased test size in S. triangularis.

NOTE.—The widening of the chambers in S. triangularis

causes the umbilicus to open more than in S. trivialis and

also lengthens the lip so that it becomes long and narrow.

Nonspinose Lineages

Praemuricate Lineages

Praemurica
(Plates 59-62)

P. taurica-P. pseudoinconstans-P. inconstans-P. uncinata
lineage is characterized by

(1) development of a praemuricate cancellate nonspinose
wall texture in P. taurica in the transition from
Hedbergella monmouthensis;

(2) increased number of chambers in the final whorl in P.
taurica;

(3) development of subconical-shaped chambers in the
transition from P. inconstans to P. uncinata.

Igorina
(Plates 56-58)

Praemurica uncinata-Igorina lineage is characterized by

(1) development of a thick, encrusted pustule layering over
the praemuricate wall in the transition from Praemurica
to Igorina;

(2) development of slightly conical to elongate oval-shaped
chambers in Igorina;

(3) development of a somewhat elevated trochospire in
Igorina.

I. pusilla-I. albeari lineage is characterized by

(1) low conical chambers in the lineage;

(2) development of a peripheral keel in I. albeari.

I. pusilla-I. tadjikistanensis lineage is characterized by

(1) development of inflated ovoid-conical chambers in I.
tadjikistanensis.

Smooth-Walled Lineage

Globanomalina
(Plates 32-38)

G. archeocompressa-G. compressa-G. ehrenbergi-G. pseu-
domenardii lineage is characterized by

(1) a compressed test with an imperforate peripheral margin
that becomes keeled in G. pseudomenardii;

(2) increased size and rate of expansion of chambers in the
lineage;

(3) a change in chamber shape from compressed ovoid in G.
archeocompressa-G. ehrenbergi to low conical in G.
pseudomenardii.

18

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

G. compressa-G. chapmani-G. planoconica lineage is charac¬
terized by

(1) a compressed, nearly planispiral test with an imperforate
peripheral margin that becomes thickened into a blunt
keel in G. planoconica;

(2) increased size and rate of expansion of chambers in G.
chapmani;

(3) decreased rate of expansion of chambers, increased
number of chambers in the ultimate whorl, and reduced
test size in G. planoconica.

G. archeocompressa-G. planocompressa-G. imitata-G.
ovalis lineage is characterized by

(1) a low trochospiral, nearly planispiral test with rapidly
inflating globular chambers in G. planocompressa-G.
imitata;

(2) a largely perforate peripheral margin in the lineage;

(3) a large extraumbilical aperture that extends slightly onto
the spiral side in G. ovalis.

G. imitata-G. australiformis lineage is characterized by

(1) development of low conical chambers in G. australi¬
formis;

(2) development of fine pustules covering the test walls;

(3) increased test size in G. australiformis.

Muricate Lineages

Acarinina
(Plates 39-44)

A subtle but significant coiling change, which is first
observed in the ancestral species Acarinina strabocella, occurs
in the development of Acarinina. In A. strabocella, the coil
becomes slightly elevated, thereby shifting the aperture from an
extraumbilical to a more umbilical position (Plate 43). This
evolved character is maintained in all subsequent species of
Acarinina.

Morozovella praeangulata-Acarinina strabocella lineage is
characterized by

(1) development of a muricate wall texture in M. praeangu-
lata;

(2) development of oval-elongate chambers in A. strab¬
ocella;

(3) development of a slightly elevated trochospire in A.
strabocella;

(4) a more umbilically directed aperture in A. strabocella.
NOTE. —The muricate wall is developed by growth of

pustules on a smooth surface at triple points between the
pores; moderate to strong pustule growth occurs on the
umbilical shoulders surrounding the aperture. The elevated
trochospire in A. strabocella causes the aperture to take a
more umbilical position and tends to close off the umbilicus.

A. strabocella-A. nitida lineage is characterized by

(1) development of muricate wall texture;

(2) development of a more elongate chamber shape than in
A. strabocella.

A. nitida-A. subsphaerica lineage is characterized by

(1) development of a higher trochospire and a more tightly
coiled test in A. subsphaerica.

A. subsphaerica-A. mckannai lineage is characterized by

(1) development of muricate wall texture;

(2) oval-elongate chambers that are derived from A.
strabocella.

A. mckannai-A. soldadoensis lineage is characterized by

(1) a change in chamber shape to less elongate-oval in edge
view in A. soldadoensis.

A. nitida-A. coalingensis lineage is characterized by

(1) a change to more elongate-oval chambers in spiral view
and less elongate-oval chambers in edge view in A.
coalingensis;

(2) increased rate of chamber-size leading to a more tightly
coiled test in A. coalingensis.

Morozovella
(Plates 45-55)

As noted in the introduction, two opposing hypotheses of the
phylogeny of the morozovellid lineage remain unresolved. The
traditional view, based on the original hypothesis of Bolli
(1957a), was adopted by Blow (1979), Toumarkine and
Luterbacher (1985), and others. It derives Morozovella through
the enhancement of the anguloconical chambers in the ultimate
and penultimate whorls of Praemurica uncinata and further
peripheral compression of the test, along with the development
of a muricate test in Morozovella (see Plates 53 and 62). Other
morphological features shared by the two genera relate to the
interpretation of pore shape, development of muricae, umbili¬
cal morphology, and apertural morphology. In addition to these
criteria, carbon and oxygen isotopic data are interpreted as
supporting this phylogenetic hypothesis (Norris, 1996; Berg-
gren and Norris, 1997). The alternate view (Olsson and
Hemleben, 1996) emphasizes the development of the character¬
istic heavy pustulose wall texture of Morozovella from a
smooth-walled Globanomalina ancestor, i.e., G. imitata. It is
based on the observation that the wall texture of Morozovella
develops through the growth of pustules on a smooth wall
surface, thus linking this genus to Globanomalina. Angulo¬
conical chambers and a lightly pustulose wall are observed in
the inner whorl of G. imitata (see Plate 12: Figures 10-12;
Plate 36). In contrast, the Praemurica wall texture develops as
elongate subparallel ridges with short connective ridges, giving
the wall a cancellate texture similar to the modem species

NUMBER 85

19

Neogloboquadrina dutertrei. The two phylogenetic hypotheses
are shown in Figure 5a,b.

M. praeangulata is characterized by

(1) development of a pustulose wall surface;

(2) development of conical chambers;

(3) maintenance of 5 chambers in ultimate whorl.

M. praeangulata-M. apanthesma-M. aequa-M. subbotinae
lineage is characterized by

(1) development of high to moderately high conical
chambers in the transition to Morozovella from Globa-
nomalina ;

(2) increased rate of chamber expansion in M. aequa and M.
subbotinae.

M. apanthesma-M. gracilis lineage is characterized by

(1) development of moderately high conical chambers in M.
gracilis ;

(2) a change to a higher rate of expansion of chambers in M.
gracilis.

M. praeangulata-M. angulata-M. conicotruncata-M. velas-
coensis-M. pasionensis lineage is characterized by

(1) development of high conical chambers in M. conicotrun-
cata\

(2) development of a strong muricate keel in M. conicotrun-
cata;

(3) development of strongly muricate umbilical shoulders in
M. conicotruncata.

M. pasionensis-M. occlusa lineage is characterized by

(1) development of low conical chambers in M. occlusa ;

(2) development of a more tightly coiled test that narrows
the umbilicus in M. occlusa.

M. pasionensis-M. acutispira lineage is characterized by

(1) development of low conical chambers in M. acutispira ;

(2) increased rate of chamber expansion in M. acutispira.

Taxonomy

Family Globigerinidae Carpenter, Parker,
and Jones, 1862

(by R.K. Olsson, Ch. Hemleben, C. Liu, W.A. Berggren,
and R.D. Norris)

Original Description.— “Under the general designation
Globigerinida we bring together, for the reasons already stated,
all those hyaline or vitreous Foraminifera which have their
shell-substance coarsely perforated for the exit of pseudopodia,
so as to resemble that of Globigerina-, a character by which they
are differentiated from the Lagenida on the one hand, and from
the Nummulinida on the other. They are further differentiated

from the former of these families by the form and character of
their aperture; for although there are instances in which the
chambers communicate with each other, and the last chamber
with the exterior, by circular pores, yet this is only in aberrant
forms of the group; and the typical aperture is a crescent, which
may either be contracted to a narrow fissure, or which may
open-out so as to have the proportions of a gateway. There is
not a like difference in the form of the aperture between
Globigerinida and Nummulinida ; but generally speaking, it is
of much larger size, so as to permit a much freer communica¬
tion between the segments of the body in the former group than
in the latter.” (Carpenter, Parker, and Jones, 1862:171.)

Diagnostic Characters. —Test lobulate, trochospiral or
planispiral, usually with 3 '/ 2 —6 globular chambers in final
whorl; wall spinose, cancellate, or noncancellate; aperture
interiomarginal, umbilical, a low to high arch, with or without
a lip, may have supplementary apertures.

DISCUSSION.—A great variety of species and genera with
diverse morphologies evolved from the simple trochospiral
globigerine forms in the Paleocene. Only the genera Eoglobig-
erina, Parasubbotina, and Subbotina are represented in the
Paleocene.

Genus Eoglobigerina Morozova, 1959

Type Species. —Globigerina (Eoglobigerina) eobulloides
Morozova, 1959, emended.

Original Description. —“Test trochoid. Chambers sub-
sphaerical. Wall thin, smooth. Aperture small, opening into the
umbilicus or into the circumumbilical part of the marginal
suture. From representatives of the subgenus Globigerina this
one differs by its thin and smooth or not clearly microreticulate
test wall and by the small size of the aperture. Family
Globigerinidae. Senonian to Danian.” (Morozova, 1959:1115;
translated from Russian.)

Diagnostic Characters. —Low, trochospiral test with
10-16 chambers, 4-6 ] /2 globular chambers in ultimate whorl.
Trochospire moderately to highly elevated; aperture interio¬
marginal, umbilical to slightly extraumbilical, a low, rounded
arch bordered by a thin, narrow lip; umbilicus small and open
to the apertures of surrounding chambers. Cancellate and
spinose wall with spine holes situated along cancellate ridges.

Discussion. —Hemleben et al. (1991) demonstrated that
Eoglobigerina had a spinose morphology, which separates it
from other cancellate forms in the Danian that are nonspinose.
The concept of Eoglobigerina followed herein is similar to that
of previous workers except that it is emended to include the
spinose character.

Eoglobigerina edita (Subbotina, 1953)

Figure 7; Plate 8: figures 13-18; Plate 9: figures 1-6;

Plate 18: figures 1-16

Globigerina edita Subbotina, 1953:62, pi. 2: fig. la-c [Zone of rotaliform

Globorotalia (Danian Stage), Kuban River section, northern Caucasus].—

20

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Fox andOlsson, 1969:1398, pi. 168: figs. 1-4 [lower Paleocene, Cannonball
Fm., North Dakota],—Shutskaya, 1970b, pi. 18: fig. 14a-c [middle subzone
of Globigerina trivialis-Globoconusa conusa-Globorotalia compressa
Zone, Malyi Balkhan Ridge, western Turkmenia] [in part, not pi. 18: fig.
12a-c],

Globigerina edita Subbotina var. polycamera Khalilov, 1956:235, pi. 1: fig.
la-c [Danian Stage, Akhchakuima, northeastern Azerbaizhan],—Shutskaya,
1970a: 119, pi. 18: fig. lla-c [middle subzone of Globogerina trivialis-
Globoconusa daubjergensis-Globorotalia compressa Zone, Khazin-Don
River section, northern Caucasus],

Globigerina ( Eoglobigerina ) hemisphaerica Morozova, 1961:11, pi. 1: fig. 4
[Zone Dnl II, lower substage of Danian Stage, Tarkhankut Peninsula,
Crimea],

Globigerina ( Eoglobigerina) pentagona Morozova, 1961:13, pi. 1: fig. 3 [Zone
Dnl I, lower substage of Danian Stage, Tarkhankut Peninsula, Crimea],
Globigerina ( Eoglobigerina ) tetragona Morozova, 1961:13, pi. 1: fig. 2 [Zone
Dnl I, lower substage of Danian Stage, pre-Caspian Basin, Novouzensk].
Globigerina (Eoglobigerina) theodosica Morozova, 1961:11, pi. 1: fig. 6 [Zone
Dnl I, lower substage of Danian Stage, Tarkhankut Peninsula, Crimea],
Globorotalia ( Globorotalia) edita (Subbotina).—Hillebrandt, 1962:130, pi. 11:
figs. 14, 15 [Zone A, lower Paleocene, Reichenhall-Salzburg Basin,
Austro-German border].

Eoglobigerina edita edita (Subbotina).—Blow, 1979:1210, pi. 61: figs. 2, 3, pi.
66: fig. 1 [Zone Pa, DSDP Hole 47.2/11/3: 148-150 cm], pi. 69: fig. 6 [Zone
PI, DSDP Hole 47.2/11/3: 0-5 cm], pi. 72: figs. 6, 8 [Zone Pi, DSDP Hole
47.2/11/3: fig. 6, 148-150 cm; fig. 8, top section; Shatsky Rise, northwestern
Pacific Ocean], pi. 79: fig. 3 [Zone P2, DSDP Hole 20C/6/4: 72-74 cm;
Brazil Basin, South Atlantic Ocean].

Eoglobigerina edita (Subbotina).—Hemleben, Miihlen, Olsson, and Berggren,
1991:126, pi. 7: fig. 4-6 [Zone Pa, Clayton Basal Sands, Millers Ferry,
Alabama].—Berggren, 1992:562, pi. 1: figs. 5, 6 [Zone Plb, ODP Hole
747A/19H/CC; Kerguelen Plateau, southern Indian Ocean],—Olsson,
Hemleben, Berggren, and Liu, 1992:197, pi. 2: figs. 1-5, 7 [figs. 1-4, Zone
Pa, Clayton Basal Sands; figs. 5, 7, Zone Pla, Pine Barren Mbr., Clayton
Fm., Alabama],

Eoglobigerina edita polycamera Khalilov.—Olsson, Hemleben, Berggren, and
Liu, 1992:197, pi. 2: fig. 6 [Zone Pla, Pine Barren Mbr., Clayton Fm.,
Millers Ferry, Alabama].

Original Description. —“Shell small, rounded, with tall
spiral consisting of 2 V 2 —3 whorls. The last whorl is made up of
4 '/ 2 —5 spherical chambers, usually of almost equal size.
Peripheral margin rounded, scalloped. The most characteristic
feature of this species is the turret-like dorsal surface which is
associated with the large size of the chambers in the earlier
whorls.

“The ventral side is feebly convex compared with the dorsal.
The umbilicus is small and shallow but distinct. The chambers
of the early whorls are compactly arranged and closely packed
together, those of the last whorl are arranged much more freely
giving a scalloped appearance to the peripheral margin. Sutures
deep, slightly curved. The orifice has the form of a small slit
which extends along the marginal suture. Walls smooth, with
small pores. Mean dimensions: diameter 0.25 mm, thickness
0.15 mm.” (Subbotina, 1953:62; translated from Russian.)

Diagnostic Characters. —Species characterized by mod¬
erately high trochospiral test with 4'/2—5 (occasionally up to 7)
globular chambers increasing gradually in size in ultimate
whorl, and a strongly lobulate peripheral margin. Rounded
umbilical to slightly extraumbilical aperture bordered by
narrow lip. Umbilicus small but open to previous chambers.

Cancellate wall weakly developed and spinose with numerous
spine holes along cancellate ridges. Overall size of test
generally < 250 pm.

Discussion.—A considerable variation in the height of the
initial coil and the position of the aperture from an umbilical
toward an extraumbilical position occurs in this species. Blow
(1979) discussed the high degree of variability among early
eoglobigerinids and the apparent fact that few morphotypes
exhibit a consistent expression of morphologic characters.
Thus, he cautioned that strict morphologic limits cannot be as
rigidly applied to early eoglobigerinids as to the later, more
stable morphospecies of globigerinacean genera. Blow also
distinguished as a subspecies of edita the morphospecies
praeedita, which can be viewed as intermediate between
eobulloides and edita. Eoglobigerina edita is an intermediate
member of the eobulloides-edita-spiralis lineage, which
terminated in Zone P2 (see also Pearson, 1993).

Examinations of the holotypes (Plate 8: Figures 13-18, Plate
9: Figures 1-6) of Eoglobigerina hemisphaerica Morozova, E.
theodosica Morozova, E. tetragona Morozova, and E. pen¬
tagona Morozova suggest that these are junior synonyms of
edita Subbotina. These Morozova species are all characterized
by having a weakly cancellate test and an elevated initial whorl,
which places them within the edita plexus. The difference
between these morphotypes is the elevation of the spire (high in
hemisphaerica and pentagona, lower in theodosica and
tetragona) and the number of chambers in the ultimate whorl
(5 l /2 in hemisphaerica, 5 in theodosica, 4'/2 in pentagona, 4 in
tetragona ). The 5'/2-chambered, finely cancellate holotype of
hemisphaerica has a distinctly elevated spiral side; Morozova
(1961) drew attention to the “stepped nature” of the antepenul¬
timate and penultimate whorls, which was said to serve to
distinguish hemisphaerica from edita. We regard this as being
within the range of variation of E. edita.

Stable Isotopes.—N o data.

Stratigraphic Range. —Zone Pa to Zone Pic; ? P2.

Global Distribution. —Worldwide in high and low
latitudes (Figure 7).

Origin of Species. —This species evolved from Eoglobig¬
erina eobulloides near the base of Zone Pa by an increase in the
number of chambers in the last whorl and a slowing of the rate
of growth of these chambers. In addition, there is a trend
towards an elevated initial spire. An increase in the degree of
spinosity is also evident in the evolution of E. edita.

Repository. —Holotype (No. 3975) deposited in the mi-
cropaleontological collections at VNIGRI, St. Petersburg,
Russia. Examined by WAB.

Eoglobigerina eobulloides (Morozova, 1959)

Figure 8; Plate 8: figures 10-12; Plate 19: figures 1-15

Globigerina ( Eoglobigerina ) eobulloides Morozova, 1959:1115, text-fig. la-c

[Zone I, zone of smooth-walled globigerinids (eoglobigerinids), lower

Danian Stage (Uylinian Stage), Tarkhankut Peninsula, Crimea],

NUMBER 85

21

1 80°W

135°W

90°W

45°W

45°E

90°E

135°E

FIGURE 7.—Paleogeographic map showing distribution of Eoglobigerina edita (Subbotina) in Zone PI.
Paleogeographic base map for this and following figures based on reconstruction by Barron (1987) for the
Maastrichtian, with adjustments for the 60 mya continental distributions of Scotese and Denham (1988) and
land-sea distributions in western Europe by Ziegler (1982). Abbreviations used in this and following figures given
in Table 1.

Globigerina fringa Subbotina.—Premoli Silva and Bolli, 1973:541, pi. 7: figs.
6, 9 [Zone Pa, DSDP Site 152/10/1: 127-130 cm; eastern Caribbean Sea],
[Not Subbotina, 1953.]

Eoglobigerina eobulloides eobulloides (Morozova).—Blow, 1979:1214, pi. 60:
fig. 9, pi. 61: fig. 1 [Zone Pa, DSDP Hole 47.2/11/4: 148-150 cm], pi. 65:
figs. 8, 9, pi. 66: figs. 6, 9 [Zone Pa, DSDP Hole 47.2/11/3: 148-150 cm],
pi. 70: figs. 3, 4 [Zone PI, DSDP Hole 47.2/11/3: 0-5 cm], pi. 73: fig. 6
[Zone PI, DSDP Hole 47.2/11/1: 148-150 cm; Shatsky Rise, northwestern
Pacific Ocean],

Eoglobigerina fringa (Subbotina).—Smit, 1982:329, pi. 2: fig. lla-c [base of
Zone Pa, Gredero section, southeastern Spain].—Stott and Kennett,
1990:559, pi. 1: figs. 5, 6 [Zone APa, ODP Hole 690C/15X/4: 28-30 cm;
Maud Rise, Weddell Sea, Southern Ocean], [Not Subbotina, 1953.]
Eoglobigerina eobulloides (Morozova).—Huber, 1991c:461, pi. 2: figs. 9-11
[Zone APIA, ODP Hole 738C/20R/5: 376.54 mbsf; Kerguelen Plateau,
southern Indian Ocean],—Hemleben, Miihlen, Olsson, and Berggren,
1991:126, pi. 7: figs. 1-3 [Zone Pa, Clayton Basal Sands, Millers Ferry,
Alabama],—Olsson, Hemleben, Berggren, and Liu, 1992:197, pi. 1: figs.
1-7 [Zone Pa, Clayton Basal Sands, Millers Ferry, Alabama],

Original Description. —“Test with a flattish spiral; 4-4V2
chambers per whorl. Diameter 0.225 mm., height 0.13 mm.
Differentiated from G. ( Globigerina ) bulloides d’Orbigny and
G. (G.) pseudobulloid.es Plummer by its small aperture and
smooth or definitely micro-cellular test wall.” (Morozova,
1959:1115; translated from Russian.)

Diagnostic Characters.— Spinose species with moder¬
ately elevated trochospire, globular chambers, an umbilical to
slightly extraumbilical rounded aperture bordered by narrow,
slightly flaring lip. Four to 4*/2 chambers in final whorl
increase moderately in size. Umbilicus small but open to
previous chambers. Cancellate wall texture very weakly
developed and difficult to view with the light microscope,
especially where wall preservation is poor. Pores average about
1 pm in diameter at narrowest point and occur at base of
shallow pit surrounded by cancellate ridges. Wall ranges from
4-7 pm in thickness; overall size of test generally < 250 pm.

DISCUSSION.— Considerable uncertainty and confusion sur¬
rounds the identification of this species and Globigerina fringa
Subbotina, 1953, due to the very small size and generalized
drawing of the holotype of G. fringa. Examination of the
holotype (WAB and FR) under a light microscope shows it to
be similar to E. eobulloides in general morphology and, thus, a
possible senior synonynm. Scanning electron micrographs
(SEM) taken by FR (Plate 8: Figures 10-12, Plate 9: Figures
7-9) of the two holotypes, however, show that they are
distinctly different species. “ Globigerina” fringa has a
coarsely cancellate wall similar to that of Subbotina cancellata
Blow, 1979 (Plate 24: Figures 1-14). This type of cancellate

22

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

TABLE 1.—Abbreviations used in the paleobiogeographic maps.

AL Alabama

Au Austria

Az Azerbaijan

BA Bikini Atoll

BB Bulgarian Black Sea

BG Bongerooda Greensand, Australia

Bo Bottacione, Italy

Br Braggs River, Alabama

BR Brazos River, Texas

CB Cannonball Fm.

Cc Northern Caucusus

Cr Crimea

Cu Cuba

Cv Caravaca, Spain

Eg Egypt

EK El Kef, Tunisia

Eu Eureka Core

FR Flaxburne River, New Zealand

Gb Gubbio, Italy

Gu Guatemala

Ir Iran

Ka Kamchatka

Li Lindi, Tanzania

Lo Lodo Fm.

Md Maryland

MF Millers Ferry, Alabama

Mo Morocco

Mw Midway Fm., Texas

MW Mid Waipara River, New Zealand

NE Northeast Atlantic Ocean

Nf Nanafalia Fm., Alabama

NF Northwest Florida

Ng Nugssuaq, Greenland

Ni Nigeria

NJ New Jersey

NK Nye Klov, Denmark

Nv Navarro Fm., Texas

Pa Papua New Guinea

PA Paterno d’Adda, Italy

Pd Pondicherry, India

Pk Pakistan

PP Pebble Point, Australia

RS Reichehall-Salzburg

SB Salzburg Basin

Se Senegal

SF South France

SI Seymour Island, Antartica

SM Salt Mountain Fm., Alabama

Tk Turkey

Tr Trinidad

Tu Turkmenia

TU Te Uri Stream, New Zealand

Va Virginia

Vc Veracruz, Mexico

Vo Velasco Fm., Mexico

WC Woodside Creek, New Zealand

Zu Zumaya, Spain

wall texture is more advanced than that seen in Zone Pa
globigerinids, which suggests that fringa was described from a
higher Danian stratigraphic level. See “Discussion” under
Subbotina cancellata for additional data on this species.

Four-chambered forms of E. eobulloides were named by
Blow (1979) as the subspecies E. eobulloides simplicissima.
This form seems to be the same as Globigerina moskvini
Shutskaya, 1953, a name that could be used for E. eobulloides
except that some of the Shutskaya collections were destroyed
during the 1960s, and, thus, the usage of this name is not
advisable. Blow’s (1979) illustrations of E. eobulloides agree
well with the holotype (Plate 8: Figures 10-12). The small size
of E. eobulloides and its very thin pore-filled walls make this
species very susceptible to dissolution, which is common in
lowermost Danian sections.

STABLE Isotopes. — Eoglobigerina eobulloides has a 5 13 C
and 8 18 0 signature similar to Parasubbotina and Globanomal-
ina but typically with heavier 8 18 0 and more negative 8 I3 C than
coexisting Praemurica and Woodringina (D’Hondt and
Zachos, 1993; Berggren and Norris, 1997). The species shows
little change in 8 18 0 or 8 13 C over a large size range (Berggren
and Norris, 1997), although a positive size/8 13 C relationship
has been reported for the species at small shell sizes from the
early Danian (D’Hondt and Zachos, 1993).

Stratigraphic Range. —Upper Zone P0 to Zone Plb.

Global Distribution. —Worldwide in high to low lati¬
tudes (Figure 8).

Origin of Species .—Eoglobigerina eobulloides evolved
from Hedbergella monmouthensis (Olsson) in late Biochron P0
by the development of a spinose cancellate wall texture (Liu
and Olsson, 1994). It is the earliest spinose taxon of the
Cenozoic, and, as such, it represents a completely new adaptive
innovation (camivory?) following the terminal Cretaceous
event(s). Olsson et al. (1992) suggested that the spinose E.
eobulloides lies at the base of an early Paleocene (Danian)
radiation of normal perforate, cancellate spinose forms refera¬
ble to Eoglobigerina and Subbotina (see also Pearson, 1993).

Repository. —Holotype No. 3508/1, Moscow, GAN. Ex¬
amined by WAB and FR.

Eoglobigerina spiralis (Bolli, 1957)

Figure 9; Plate 16: figures 10-12; Plate 20: figures 1-11

Globigerina spiralis Bolli, 1957a:70, pi. 16: figs. 16-18 [ Globorotalia
uncinata Zone, lower Lizard Springs Fm., Trinidad].—Bolli and Cita,
1960:12, pi. 32: fig. 2a-c [Globorotalia trinidadensis-Globigerina daubjer-
gensis Zone, Pademo d’Adda section, northern Italy].—Hillebrandt,
1962:130, pi. 11: figs. 14, 15 [Zone E, lower Paleocene, Reichenhall-
Salzburg Basin, Austro-German border],

Eoglobigerina spiralis (Bolli).—Blow, 1979:1222, pi. 79: figs. 5-9 [Zone P2,
DSDP Hole 20C/6/4: 72-74 cm; Brazil Basin, South Atlantic Ocean],
Igorina spiralis (Bolli).—Huber, 1991c:461, pi. 3: figs. 13-15 [Zone AP2,
ODP Hole 738C/16R: 338.50 mbsf; southern Kerguelen Plateau, southern
Indian Ocean],

Original Description.— “Shape of test medium to high
trochospiral, biconvex, spiral side distinctly convex, umbilical
side less so; equatorial periphery lobate; axial periphery
rounded. Wall calcareous, perforate, surface smooth. Chambers
inflated, globular or slightly compressed laterally; about 15,

NUMBER 85

23

180°W

135°W

90°W

45°W

90°E

FIGURE 8. —Paleogeographic map showing distribution of Eoglobigerina eobulloides Morozova in Zone PI.

arranged in 3 whorls; the 5-6 chambers of the last whorl
increase moderately in size. Sutures on spiral side radial or
slightly curved, depressed; on umbilical side radial, depressed.
Umbilicus narrow, open. Apertures distinct arches with faint
lips, interiomarginal, umbilical; that of last chamber in some
specimens tends to an extraumbilical-umbilical position.
Coiling random. Largest diameter of holotype 0.28 mm.”
(Bolli, 1957a:70.)

Diagnostic Characters. —Spinose species with distinct
elevated spire and 4 V 2 - 5 V 2 chambers in ultimate whorl.
Chambers closely appressed with an umbilically directed
aperture. Radially directed intercameral sutures on umbilical
side appear as distinct valleys when surrounded by gameto-
genetic calcification. Aperture bordered by thin discontinuous
lip. Wall texture more strongly developed than in ancestral
species, E. edita. Umbilicus very small and often overlapped by
ultimate chamber. Spine holes set along cancellate ridges
appear not as numerous as in E. edita.

DISCUSSION. —Bolli (1957a) regarded E. spiralis as the
immediate ancestor of Igorina pusilla (Bolli). Although Blow
(1979) agreed with Bolli, he noted that the transition from
spiralis to pusilla involved the loss of a porticus as well as the
extraumbilical extension of the aperture. Blow placed great
emphasis on the importance of the porticus as distinct from an
apertural lip. The study of Olsson et al. (1992) on the wall
texture of Danian globigerinids and globorotaliids, however,

showed that the separation of these two kinds of apertural
apparatuses is erroneous, as the apparent differences noted by
Blow are due to ontogenetic and gametogenetic calcification.
The fact that Blow (1979:1223) regarded the spiralis-pusilla-
albeari lineage as “so remarkably taxonomically and stratigra-
phically isolated” indicates that he considered the morphologi¬
cal change involved in the origin of pusilla (i.e., Igorina) as
quite distinct from the mainstream globigerinacean evolution¬
ary history. His belief holds true to some degree in regards to
the origin of the Igorina lineage (see “Discussion” under this
genus). The ancestral relationship of spiralis to pusilla must be
ruled out, however, because the former species has a spinose
wall texture whereas the latter has a nonspinose, praemuricate
wall texture. Eoglobigerina spiralis is the end member of the
eobulloides-edita-spiralis lineage, which terminated in Zone
P2 (see also Pearson, 1993).

Our work has revealed a spinose wall texture in E. spiralis
and suggests that these spinose forms are unrelated to the
nonspinose igorinids; however, we have recognized an appar¬
ently nonspinose wall texture in some specimens that we have
initially attributed to E. spiralis. Indeed, the holotype of E.
spiralis is too poorly preserved to verify the original presence or
absence of spines. Consequentially, we are not completely sure
of the generic designation of this species. Should the paratypes
of E. spiralis prove to have a nonspinose wall texture, we
would be forced to consider this taxon as a possible ancestor to

24

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

180“W

135°W

90°W

45°W

45°E

90°E

135°E

FIGURE 9. —Paleogeographic map showing distribution of Eoglobigerina spiralis (Bolli) in Zone P2.

I. pusilla as originally suggested by Bolli (1957a) and to regard
the spinose homeomorphs as derivatives of Eoglobigerina
edita.

Stable Isotopes.—-N o data available.

Stratigraphic Range. —Zone P2; ? uppermost Zone Pic.

Global Distribution. —Apparently worldwide in high to
low latitudes (Figure 9).

ORIGIN OF Species. —This species evolved from E. edita
near the base of Zone P2 by the development of a tighter coil,
a distinct elevated early coil of chambers, and a more strongly
cancellate test wall.

Repository— Holotype (USNM P5030) deposited in the
Cushman Collection, National Museum of Natural History.
Examined by WAB, BTH, and RKO.

Genus Parasubbotina Olsson, Hemleben, Berggren,
and Liu, 1992

TYPE Species.— Globigerina pseudobulloides Plummer,
1926.

Original Description. —“Test very low trochospiral with
10-12 chambers, and with 4 to 5 chambers in the ultimate
whorl. The chambers which are inflated globular and slightly
ovoid in shape increase rapidly in size. The aperture is
interiomarginal, umbilical to extraumbilical, a high rounded
arch which is bordered by a narrow lip. The umbilicus is

narrow, deep and open to the previous chambers. The wall is
weakly to strongly cancellate and spinose. Spine holes are
numerous and located at the juncture of and along the
cancellate ridges. They may be obscured by gametogenetic
and/or diagenetic calcification.” (Olsson, Hemleben, Berggren,
and Liu, 1992:197.)

Diagnostic Characters. —Genus distinguished by very
low trochospiral test, chambers increasing rapidly in size in
ultimate whorl, and high-arched umbilical-extraumbilical
aperture. Number of chambers never exceeds 5 in ultimate
whorl. Last two chambers may be offset toward umbilicus (P.
variospira) giving test the appearance of a higher spire.

DISCUSSION. —In the lower Danian, low trochospiral, cancel-
late-walled, planktonic foraminiferal species are common and
were thought to be phylogenetically linked together. Olsson et
al. (1992) showed that two groups can be separated on the basis
of a spinose or a nonspinose test morphology. In the earliest
Danian, Parasubbotina and Eoglobigerina represent the spi¬
nose group and Praemurica represents the nonspinose group.

Parasubbotina pseudobulloides (Plummer, 1926)

Figure 10; Plate 21: figures 1-15

Globigerina pseudo-bulloides Plummer, 1926:133, pi. 8: fig. 9a-c [Zone P2,

Wills Point Fm., Midway Group (upper Danian), Navarro Co., Texas].

NUMBER 85

25

Globigerina pseudobulloides Plummer.—Subbotina, 1950:106, pi. 4: figs.
8-10 [Danian Stage, northern Caucasus].—Troelsen, 1957:128, pi. 30: fig.
6a-c [ Tylocidaris oedumi Zone, Hojerup, Stevns Klint], fig. 7a-c [basal
Danian, Bogelund], fig. 8a-c [? Tylocidaris oedumi Zone, Hjerm] [all
Danian Stage, Denmark],—Bolli and Cita, 1960:385, pi. 33: fig. 4a-c
[Globorotalia trinidadensis-Globorotalia pseudobulloides Zone, Pademo
d’Adda section, northern Italy],—Gohrbandt, 1963:44, pi. 1: figs. 7-9
[lower Paleocene, north of Salzburg, Austria],

Globorotalia pseudobulloides (Plummer).—Bolli, 1957a:73, pi. 17: figs.
19-21 [ Globorotalia pusilla pusilla Zone, lower Lizard Springs Fm.,
Trinidad].—Loeblich and Tappan, 1957a: 192, pi. 40: fig. 3a-c [ Tylocidaris
oedumi Zone, Danskekalk Fm., Stevns Klint, Denmark, type Danian Stage],
pi. 41: fig. la-c [Zone PI, McBryde Fm., Maryland], pi. 42: fig. 3a-c [Zone
PI, Brightseat Fm., Maryland], pi. 43: fig. 3a-c [Zone PI, Kincaid Fm.,
Midway Group, northeastern Texas], pi. 44: fig. 6a-c [Wills Point Fm.,
Midway Group, northeastern Texas], pi. 45: figs. la-2c [Zone P3, Matthews
Landing Marl Mbr., Porters Creek Clay, Wilcox Co., Alabama], pi. 46: fig.
6a-c [Coal Bluff Marl Mbr., Naheola Fm., Wilcox Co., Alabama] [in part,
not pi. 40: fig. 9a-c (= Praemurica pseudoinconstans (Blow)), pi. 43: fig.
4a-c (= indeterminate abortive individual), pi. 44: figs. 4, 5 (= indeterminate
abortive individuals)].—Olsson, 1960:46, pi. 9: figs. 19-21 [Zone PI,
Homerstown Fm., New Jersey],

Globorotalia ( Globorotalia) pseudobulloides (Plummer).—Hillebrandt,
1962:124, pi. 12: fig. 2a-c [lower Paleocene, Reichenhall-Salzburg Basin,
Austro-German border],

Globorotalia ( Turborotalia) pseudobulloides (Plummer).—Blow, 1979:1096,
pi. 69: figs. 2, 3 [Zone PI, DSDP Hole 47.2/11/3: 0-5 cm], pi. 71: figs. 4, 5
[Zone PI, DSDP Hole 47.2/11/1: top section; Shatsky Rise, northwestern
Pacific Ocean], pi. 75: figs. 2, 3 [Zone PI, Lindi area, Tanzania], pi. 248:
figs. 6-8 [Zone P2, topotypes from Plummer locality 23, Navarro Co.,
Texas], pi. 255: figs. 1-6 [Zone Pic?, Karlstrup, Denmark; upper Danian],
Subbotina pseudobulloides (Plummer).—Berggren, 1992:563, pi. 1: figs. 7, 8
[Zone Plb, ODP Hole 747A/19H/CC; Kerguelen Plateau, southern Indian
Ocean],

Parasubbotina pseudobulloides (Plummer).—Olsson, Hemleben, Berggren,
and Liu, 1992:197, pi. 3: figs. 1-7 [figs. 1-5: Zone PI a, Pine Barren Mbr.,
Clayton Fm., Alabama; figs. 6, 7: Zone P2, upper Midway Fm., Texas].

Original Description. —“Test rotaliform, very obtusely
trochoid to plane dorsally, composed of about two and one-half
convolutions, of which the last consists most generally of 5
(rarely 6) highly ventricose chambers increasing rapidly in size;
periphery broadly rounded and lobate; shell wall thin and
distinctly punctate but finely reticulate; superior face bearing a
spire of small chambers only very slightly elevated, if at all,
above the circumambient chambers of the final whorl; inferior
face less convex and with a very distinct, though not large,
umbilical depression; aperture a single, moderately large,
lunate opening on the last chamber extending from the margin
to the umbilicus and edged with a narrow, delicate, flaring lip.
Diameter up to .4 mm.” (Plummer, 1926:133.)

Diagnostic Characters. —Test very low trochospiral
with 10-12 chambers, and with 5 chambers in ultimate whorl.
Inflated, globular chambers slightly ovoid in shape and
increase rapidly in size. Aperture interiomarginal, umbilical-
extraumbilical, with high rounded arch bordered by narrow lip.
Umbilicus narrow, deep, and open to previous chambers.
Cancellate spinose wall weakly developed in early forms of
species but become stronger in later forms. Spine holes
numerous, located at the juncture of and along cancellate

ridges, possibly obscured by gametogenetic and/or diagenetic
calcification. Overall test size generally > 250 pm.

DISCUSSION. —The demonstration that P. pseudobulloides
has a cancellate, spinose wall texture (Olsson et al., 1992) and
that it is a member of a relatively minor offshoot of the early
eoglobigerinid radiation, has given pause to long-held notions
about early Paleocene planktonic foraminiferal phylogenies
(see also Pearson, 1993). This is because it has been commonly
accepted for nearly 40 years that P. pseudobulloides was the
ancestor of the post-Danian muricate morozovellid radiation
(Bolli, 1957a; Blow, 1979). Parasubbotina pseudobulloides is
a member of a lineage that includes P. varianta and apparently
P. variospira.

The identification of P. pseudobulloides must be made with
care because of the general, superficial similarity with
Praemurica pseudoinconstans (see also Blow, 1979). The
fundamental difference in wall texture between Parasubbotina
and Praemurica may not be evident in poorly preserved
specimens.

Stable Isotopes. — Parasubbotina pseudobulloides has a
positive 5 18 0 and negative 5 I3 C similar to Subbotina, Eoglo-
bigerina, and Globanomalina. Both 8 18 0 and 5 13 C display little
size-related variability (D’Hondt and Zachos, 1993; Berggren
and Norris, 1997).

Stratigraphic Range.—U ppermost Zone Pa to Zone P3a;

? P3b.

Global Distribution. —Worldwide in low to high lati¬
tudes (Figure 10).

Origin of Species. —This species evolved from 4*/2—5-
chambered, weakly cancellate, spinose morphotypes identified
as Parasubbotina sp. aff. pseudobulloides (Olsson et al., 1992,
pi. 4: figs. 1-4) that occur at the top of Zone P0 and in Zone Pa.
They are not the same as the 5-6-chambered forms identified
as G. (T.) aff. pseudobulloides by Blow (1979), which he
regarded as having a phylogenetic relationship with pseudoin¬
constans.

Repository. —Cotypes: Walker Museum Collection 33076,
Station 23. Examined by BTH and RKO.

Parasubbotina aff. pseudobulloides (Plummer, 1926)

Plate 22: figures 1-5

Parasubbotina aff. pseudobulloides (Plummer).—Olsson, Hemleben, Berg¬
gren, and Liu, 1992:197, pi. 4: figs. 1-4 [upper Zone P0 and Zone Pa,

Millers Ferry, Alabama].

Diagnostic Characters. —Small, very low trochospiral
test with 4'/2-5 chambers in ultimate whorl, globular chambers
increase rapidly in size, high arched umbilical-extraumbilical
aperture with a thin lip, weakly developed cancellate wall,
spinose. Maximum diameter < 225 pm.

DISCUSSION.— This small morphotype apparently has often
been identified as Globigerina fringa Subbotina, 1953. This
species, however, has a coarsely cancellate wall and morphol-

26

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

FIGURE 10.—Paleogeographic map showing distribution of Parasubbotina pseudobulloides (Plummer) in Zone
PL

ogic characters belonging to Subbotina. Parasubbotina aff.
pseudobulloides is smaller than P pseudobulloides, and it has
a very weakly developed cancellate wall in contrast to the
strongly developed cancellate wall of pseudobulloides. The
spinose condition is already present. As the cancellate wall
becomes more strongly developed, along with an increase in
size, this morphotype grades into P. pseudobulloides. Because
of this fact, it is often difficult to consistantly identify the first
occurrence of P. pseudobulloides and hence the base of Zone
PI a. A more useful criterion for the base of Zone Pla is the last
occurrence of Parvularugoglobigerina eugubina (Luterbacher
and Premoli Silva).

Stable Isotopes. —There are no existing isotope data that
are unambiguously attributed to this taxon. Data for P.
pseudobulloides from the early Danian show that this taxon has
5 18 0 and 8 13 C similar to Eoglobigerina and distinctly heavier
5 18 0 than Woodringina (D’Hondt and Zachos, 1993).

Stratigraphic Range. —Upper Zone P0 to Zone Pa.

Global Distribution. —Probably widespread, but few
reliable identifications have been made.

ORIGIN of Species. — Parasubbotina aff. pseudobulloides
evolved from Hedbergella monmouthensis in Biochron P0 by
achieving a more rapid increase in chamber size, by the
development of a primitive cancellate wall texture, and by
becoming spinose.

Repository. —Micropaleontology collections, University
of Tubingen, trager 9120-27; 9121-10. Examined by ChH and
RKO.

Parasubbotina varianta (Subbotina, 1953)

Figure 11; Plate 9: figures 16-18; Plate 22: figures 6-16

Globigerina varianta Subbotina, 1953:63, holotype: pi. 3: fig. 5a-c; paratypes:
pi. 3: figs. 6a-7c, 10a-1 lc [zone of rotaliform Globorotalia, Elburgan Fm„
Kuban River section, northern Caucasus], pi. 3: fig. 12a-c [zone of
compressed Globorotalia, base of lower White Series, Murzai-Tai,
Mangyshlak Peninsula, southwestern Russia], pi. 4: figs. la-3c [zone of
rotaliform Globorotalia, base Foraminiferal Layer FI, Khieu River section,
near Nal’chik, northern Caucasus] [in part, not pi. 3: figs. 7a-c, 8a-c, pi. 15:
figs, la-c, 2a-c, 3a-c],

Globorotalia ( Globorotalia ) varianta (Subbotina).—Hillebrandt, 1962:125, pi.
12: figs. lOa-c, lla,b [Zone D, Reichenhall-Salzburg Basin, Austro-
German border],

Globorotalia (Turborotalia) quadrilocula Blow, 1979:1109, holotype: pi. 87:
fig. 7 [Zone P3, DSDP Hole 47.2/10/1: 72-74 cm], paratypes: pi. 75: fig. 8
[Zone PI, Lindi, Tanzania], pi. 78: figs. 2-4 [Zone P2, DSDP Hole 20C/6/4:
72-74 cm; Brazil Basin, South Atlantic Ocean], pi. 83: fig. 3 [Zone P2,
DSDP Hole 47.2/10/3: 78-80 cm; Shatsky Rise, northwestern Pacific
Ocean], pi. 87: fig. 8 [Zone PI, Lindi, Tanzania].

Subbotina varianta (Subbotina).—Berggren, 1992:563, pi. 1: fig. 3 [ODP Hole
747A/19H/CC; southern Kerguelen Plateau, southern Indian Ocean].

Original Description. —“Shell globigerinelliform plano¬
convex, oval outline, consisting of 2 whorls with 4 chambers to

NUMBER 85

27

1 80°W

135°W

90°W

45°W

FIGURE 11 .—Paleogeographic map showing distribution of Parasubbotina varianta (Subbotina) in Zones PI and
P2.

the last whorl, rapidly increasing in size and closely packed
together. The chambers to the last whorl, as is usual in the
genus, are strongly inflated.

“Dorsal side compressed, ventral convex. The chambers on
the dorsal side are clearly defined and compressed whereas on
the ventral side they are inflated and hemispherical. The last
chamber is particularly large and is almost spherical. Sutures
short, very slightly curved almost straight. On the dorsal side
they are not deeply incised, on the central side they are strongly
incised. Peripheral margin broadly rounded and coarsely
scalloped. Umbilicus always distinct though small and having
the form of a shallow depression in the middle of the ventral
surface. Orifice slit-like, usually with small, indistinct lips
forming a lamelliform border to the slit. Orifice along marginal
suture. Dimensions: diameter 0.28-0.50 mm, thickness 0.12-
0.24 mm.” (Subbotina, 1953:63; translated from Russian.)

Diagnostic Characters. —Test a very low trochospiral,
generally with four rapidly expanding chambers in ultimate
whorl. Wall cancellate spinose with spine holes on interpore
ridges. Umbilical-extraumbilical aperture a rounded high arch
bordered by fairly broad continuous lip. Small, rounded
umbilicus deep and open to surrounding chambers.

DISCUSSION. —The species is smaller and has fewer cham¬
bers in the ultimate whorl than does the closely related
Parasubbotina pseudobulloides. Blow (1979) regarded P.

varianta as an ecophenotypic variant of P. pseudobulloides
comprising a rather specialized side branch of the pseudob¬
ulloides plexus. At the same time he erected the species
Globorotalia ( Turborotalia) quadrilocula, which he consid¬
ered to have originated from a “four-chambered last-whorl
variant” (Blow, 1979:1110) of pseudobulloides. The holotype
of P. varianta (Plate 9: Figures 16-18) is a 4-chambered form
with an ultimate chamber somewhat more inflated than Blow’s
concept of quadrilocula. We regard G. (T.) quadrilocula as
falling within the morphologic range of variability of P.
varianta.

STABLE Isotopes. — Parasubbotina varianta has a S 13 C and
8 18 0 signature similar to that of P. pseudobulloides, Subbotina
triloculinoides, and Globanomalina compressa but typically
with heavier 5 18 0 and more negative 8 13 C than coexisting
Praemurica and Morozovella. The species shows little change
in 8 18 0 or S 13 C over a large size range.

Stratigraphic Range. —Zone Pic to Zone P5.

Global Distribution. —Worldwide in high and low
latitudes (Figure 11).

Origin of Species.—B low’s (1979) observations on the
close relationship of this species with P. pseudobulloides is
supported by our observations. The species evolved in Zone
Pic from P. pseudobulloides by a reduction in the number of
chambers in the ultimate whorl and a tightening of the whorl.

28

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Repository. —Holotype (No. 3994) and paratypes (Nos.
3995-4003, 4215), deposited in the micropaleontological
collections, VNIGRI (378/20), St. Petersburg, Russia. Exam¬
ined by FR.

Parasubbotina variospira (Belford, 1984)

Plate 23: figures 1-16

Globorotalia ( Turborotalia) variospira Belford 1984:18, pi. 24: figs. 15-17,

pi. 25: figs. 1-7 [WABAG Sheet area, Papua, New Guinea],

Morozovella variospira (Belford).—Van Eijden and Smit, 1992:113, text-fig.

26a-D, pi. 5: figs. 1-8 [Zone P3, ODP Hole 758A/30X/CC; eastern Indian

Ocean].

Original Description. —“Test large, trochoid, consisting
of about 12 chambers arranged in three whorls, usually 5 but
sometimes 4 chambers visible from ventral side. Equatorial
periphery lobate, axial periphery rounded. Chambers increas¬
ing only slowly in size, four chambers in penultimate whorl,
coiling in most specimens then becoming looser and more
open, generally with five chambers in final whorl, umbilicus
wide, open, shallow. Occasional specimens with final chamber
directed towards umbilicus, coiling also becoming tighter,
4-4V 2 chambers visible from ventral side. Sutures on both
dorsal and ventral sides narrow, deeply depressed, radial. Test
wall perforate, with small pustules at umbilical margin of early
chambers of last whorl, otherwise finely pitted. Aperture
interiomarginal, umbilical-extraumbilical, low elongate, not
clearly observed.” (Belford, 1984:18.)

Diagnostic Characters. —Large (~0.4 to > 0.7 mm in
diameter), low to (less frequent) moderately high, loosely
coiled trochospiral test with strongly lobulate outline; any or all
of last 3-4 chambers with inwardly projecting umbilical
“teeth,” aperture an interiomarginal, umbilical-extraumbilical
arch; loose coiling between chambers in final whorl occasion¬
ally produce secondary spiral apertures with apertural lips, wall
texture spinose and distinctly cancellate with large pore pits.

DISCUSSION.— Although described a decade ago, this species
has been overlooked in studies of Paleocene planktonic
foraminiferal faunas. This absence of attention is surprising
because P. variospira is large and homeomorphic with the
Neogene species Neogloboquardina dutertrei (d’Orbigny).
Van Eijden and Smith (1992) drew attention to the distinct
features of this large mid-Paleocene taxon and noted its
globoquadrinid-like umbilical “teeth” that are unique among
Paleocene species. Parasubbotina variospira overlaps for a
short stratigraphic interval with Globanomalina pseudomenar-
dii and early members of the acarininid radiation ( nitida,
mckannai, subsphaerica) within the lowermost part of Zone
P4.

STABLE Isotopes. — Parasubbotina variospira has a 5 13 C
and 5 18 0 signature similar to P. pseudobulloides, P. varianta,
Subbotina triloculinoides, and Globanomalina compressa, but
it typically has a heavier 5 I8 0 and more negative 8 13 C than
coexisting Morozovella.

Stratigraphic Range. —Zone P3a to Zone P4 (lower part).

Global distribution. —This species has been observed at
(sub)tropical sites in the Atlantic, Indian, and Pacific oceans.

Origin of Species. —This species evolved from P. varianta
by the development of a more loosely coiled test and inflated
chambers. Both P. varianta and P. variospira share enlarged
apertural flaps. These structures are restricted to the final
chamber of P. varianta but are found on the last 3-4 chambers
in the final whorl of P. variospira.

REPOSITORY. —Holotype (CPC 21919) and paratypes (CPC
21920-21922) deposited in Commonwealth Paleontological
Collection, Bureau of Mineral Resources, Canberra, Australia.

Genus Subbotina Brotzen and Pozaryska, 1961

TYPE Species. — Globigerina triloculinoides Plummer,
1926, emended.

Original Description. —“Le genotype est la Globigerina
triloculinoides Plummer. La figure 3 [4] (1961, op. cit., pi. 4)
montre aussi la surface de Tholotype. Le diametre des pores est
de 1 a 2 microns et ils debouchent a la surface dans un double
entonnoir entoure d’une couronne de rayons. Le diametre de
l’entonnoir varie entre huit a douze microns. Entre les
differents entonnoirs et leurs courrones radiales, la surface est
divisee en petites papilles, prismes, qui ont pent-etre porte de
fines epines calcaires. La meme construction de surface est
representee chez Brady (1884, Rept. Challenger Expedition,
Zool., pt. 22, vol. 9, pi. 77, fig. 1). On y voit une Globigerina
representee comme Globigerina bulloides d’Orbigny, mais elle
doit, selon toute certitude, representer un tout autre type. La
aussi, le mince canal du pore debouche dans un grand entonnoir
et d’apres le dessin, la couronne radiale elle-meme porte les
longues et fines epines calcaire. Toute V image montre une
espece typique de Globigerina a surfaces reticulee qui, a notre
point de vue, s’oppose a la Globigerina s. str. et doir etre traite
comme une Subbotina. Si Ton prend de telles etrudes de details
comme point de depart, 1’observation du diametre des pores et
de leur repartition devient sans valeur si elles ne tiennent pas
compte des details de structure.” (Brotzen and Pozaryska,
1961:160.)

Diagnostic Characters. —Low trochospiral, tripartite
test with 10-12 chambers, with 3-4 rapidly inflating, globular
chambers in ultimate whorl. Aperture interiomarginal, umbili¬
cal to slightly extraumbilical in some species, a low arch.
Apertural lip varies from narrow to fairly broad and distinct
apparatus extending over umbilicus. Umbilicus small and
nearly closed by tight coiling. Wall cancellate and spinose;
spines set at juncture of the cancellate ridges with or without
spine collars. Cancellate texture varies from weak to very
strong and from moderate to very coarse or distinctly
honeycombed.

Discussion. —Olsson et al. (1992) showed that Subbotina
was spinose. The concept of the genus followed herein is
similar to that of previous workers except that it is emended to
include the spinose character.

NUMBER 85

29

Subbotina cancellata Blow, 1979

Plate 9: figures 7-9; Plate 24: figures 1-14;

Plate 25: figures 1-15

?Globigerina fringa Subbotina, 1953:62, pi. 3: fig. 3 [Danian, Pecten horizon,
Azov-Black Sea flysch, Anapa, Caucasus],

Subbotina triangularis cancellata Blow, 1979:1284, holotype: pi. 80: fig. 7
[Zone P2, DSDP Hole 20C/6/4: 72-74 cm], paratypes: pi. 80: figs. 2-6, 8,
9 [Zone P2, DSDP Hole 20C/6/4: 72-74 cm; Brazil Basin, South Atlantic
Ocean], pi. 238: fig. 6 [enlargement of pi. 80: fig. 4],

Original Description. —“The test is coiled in a low
trochospire with about 10-12 chambers comprising the spire
and with four chambers visible in the last convulution of the
test. The chambers of the last whorl are inflated and
subglobular but are moderately appressed and embracing. The
dorsal intercameral sutures are depressed but not incised and
are radially or subradially disposed. The ventral intercameral
sutures are also depressed, slightly incised and are disposed.
The equatorial profile is lobulate and oval in outline whilst the
axial profile is smoothly rounded. The umbilicus is small, but
open and deep, and the umbilical depression is fairly sharply
delimited by the umbilical shoulders of the last whorl of
chambers. The aperture is virtually limited in lateral extent to
the limits of the umbilical depression although it extends a little
further towards the anterior side of the last chamber than it does
towards the posterior side of this chamber. Thus, the aperture is
a low arched opening slightly asymmetrically placed with
respect to the centre of the umbilicus. The aperture is bordered
by a strongly developed porticus which can be seen clearly
cutting across the surface structures of the primary wall of the
last chamber; from this, the porticus can be seen to be a
structure additional to the primary wall of the last chamber and
is not a simple, direct, reflexed continuation of the chamber
wall. The porticus is not significantly thickened. The primary
walls of the test bear large mural-pores which open into very
large, sharply defined pore-pits with massively developed
inter-pore ridges. Maximum diameter of holotype 0.29 mm.”
(Blow, 1979:1285.)

Diagnostic Characters. —Tightly coiled test with 3'/2-4
chambers in ultimate whorl; an umbilically directed aperture
bordered by broad, somewhat irregular lip; and coarse
cancellate wall on all chambers of the test. Test compact,
rounded in outline, and slightly lobulate.

DISCUSSION. —Blow (1979) recognized the significance of
the coarsely cancellate wall as a primary taxonomic character.
The coarsely cancellate wall is a diagnostic feature of the
cancellata-velascoensis lineage. Blow’s figures only showed
umbilical views of his new taxon. Spiral views (Plate 24) show
a rounded, somewhat lobulate outline, with the ultimate
chamber varying in size from slightly smaller to distinctly
larger than the penultimate chamber, and the coarse cancellate
wall of the earlier chambers. The axial periphery is broadly
rounded.

In his discussion of this species, Blow (1979) emphasized
the apertural lip, which he identified as a porticus. He believed

that the porticus was a feature that was added as a later
ontogenetic structure to the test. He based his belief on his
study of the structure, which in a SEM (1979, pi. 238: fig. 6) he
interpreted as an infilling of pore-pits. At that time little was
known about the ontogeny and gametogenesis of planktonic
foraminifera. It is quite clear now that the lip forms as an
extension of the primary chamber wall and that the cancellate
texture develops throughout ontogeny and is enhanced during
gametogenesis. The cancellate texture does not develop on the
apertural lip, which, apparently, led Blow to interpret it as a
separate, late-stage structure.

Blow named cancellata as a subspecies of Subbotina
triangularis (White); however, triangularis has a distinctly
different wall texture (Plate 2: Figures 15, 16, Plate 26) than
cancellata. The recognition of a coarsely cancellate Subbotina
lineage separates cancellata from triangularis and elevates it to
species level.

Considerable confusion exists on the correct identification of
Globigerina fringa Subbotina, 1950. The species is mostly
identified in the lower Danian in Cretaceous/Paleogene
boundary sections and is regarded as one of the earliest Danian
species. The small size of the original figures of the holotype
and its morphologic similarity to Eoglobigerina eobulloides
Morozova, 1959, suggested that these species are synonymous
(see Toumarkine and Luterbacher, 1985). SEMs taken by FR of
the holotypes of the two species, however, shows this not to be
the case (Plate 8: Figures 10-12, Plate 9: Figures 7-9). The
distinguishing characteristic of G. fringa is a coarsely
cancellate wall texture, which is similar to that in Subbotina
cancellata Blow (1979). Furthermore, the coarsely cancellate
wall texture observed in G. fringa is an advanced development
in the evolution of wall texture in the Danian and is not present
in Zone Pa stratigraphic levels. In fact, G. fringa was described
from the “Pecten Horizon,” which is apparently an upper
Danian horizon in the Elburgan Formation in the northwest
Caucasus.

Coarsely cancellate Subbotina cancellata morphotypes
(Plate 25: Figures 1-15) occur in Zone Pic at DSDP Site 356
in the Southern Atlantic Ocean. They appear to be quite similar
to the SEM of the holotype of Globigerina fringa Subbotina,
1953, shown on Plate 9: Figures 7-9. These morphotypes are
smaller than typical S. cancellata and have 4-4 V 2 chambers in
the ultimate whorl. Although Subbotina described this species
as having 4 chambers in the ultimate whorl, she chose a
4'/2-chambered specimen as the holotype. Most of the
specimens in a suite of adults from DSDP Site 356 are
4-chambered (Plate 25). Small immature specimens often have
4 V 2 chambers in the ultimate whorl, and these specimens have
an umbilical to a slightly extraumbilical aperture (Plate 25:
Figures 4, 10). In the adult specimens, the inner whorl is
composed of 4 V 2 chambers. This ontogenetic progression
proceeds from an Eoglobigerina morphotype to a Subbotina
morphotype and suggests that S. cancellata may have evolved
from E. eobulloides ; however, the strong cancellate wall
texture is a distinctive characteristic of Subbotina. In general

30

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

test morphology the cancellata morphotypes at DSDP Site 356
are similar to Subbotina trivialis Subbotina, 1953, suggesting
that cancellata evolved from this species by enhancement of
the cancellate wall.

The development of a coarsely cancellate wall begins a
lineage that extends through S. cancellata to Subbotina
velascoensis (Cushman, 1925). Although it is tempting to
apply the name fringa to the DSDP Site 356 cancellata
morphotypes, we recommend that this not be done pending
further study on the morphologic characteristics of this taxon
and on the stratigraphy and phylogeny of the coarsely
cancellate Subbotinas in Zone PI.

Thus, it is clear that identification of fringa and its taxonomy
should be considered carefully when using literature data in
interpretative studies. For example, Brinkhuis and Zachariasse
(1988) included fringa (together with edita) in the mono-
phyletic genus Parvularugoglobigerina Hofker, 1978,
emended, which is characterized by having a microperforate,
nonspinose wall texture. Similarly, specimens identified by
Keller (1988) as fringa (and indeed, other forms as cf. edita,
hemisphaerica, and taurica) from the basal Paleocene of El Kef
(Tunisia) are microperforate, nonspinose forms referable to
Parvularugoglobigerina.

Stable Isotopes.—N o data available.

Stratigraphic Range. —Zone Pic to Zone P4, currently
known range.

Global Distribution. —The full geographic extent of this
species at this time is unknown. The species has been identified
from North Atlantic (Site 549) and South Atlantic (Sites 20C,
356) DSDP drill sites.

ORIGIN OF Species. — Subbotina cancellata is believed to
have evolved from S. trivialis in the middle part of Zone P1,
possible Plb. It is the first species of the coarsely cancellate
Subbotina lineage. A reduction in the number of chambers in
the ultimate whorl to 3*/2 and an increase in test size
characterizes Zones P2 to P4 morphotypes.

Repository. —Holotype (BP Cat. No. 41/31) and paratypes
(BP Cat. Nos. 41/9, 41/13-41/15, 41/18, 41/20, 41/22)
deposited in The Natural History Museum, London.

Subbotina triangularis (White, 1928)

Plate 26: figures 1-13

Globigerina triangularis White, 1928:195, pi. 28: fig. la-c [Paleocene,
Velasco Fm., Mexico].—Bolli, 1957a:71, pi. 15: figs. 12-14 [Globorotalia
pseudomenardii Zone, lower Lizard Springs Fm., Trinidad],—Shutskaya,
1970a: 104, pi. 3: fig. 5a-c [lower part Acarinina tadjikistanensis djanensis
Zone, Khieu River section, Nal ’ckik, northern Caucasus]; 1970b: 118, pi. 20:
fig. 7a-c [ Globorotalia angulata Zone, Chaaldzhin Group, Malyi Balkhan
Ridge, western Turkmenia], p. 220, pi. 23: fig. la-c [lower part of Acarinina
tadjikistanensis djanensis Zone, Khieu River section, Nal’ckik, northern
Caucasus], p. 224, pi. 25: fig. la-c [upper part of Acarinina tadjikistanensis
djanensis Zone, Khieu River section, Nal’chik, northern Caucasus] [in part,
not pi. 17: fig. 14a-c (= Subbotina triloculinoides)].

Globigerina inaequispira Subbotina.—Loeblich and Tappan, 1957a. 181, pi.
52: figs. la-2c [Zone P4, Vincentown Fm., New Jersey] [in part, not pi. 49:
fig. 2a-c, pi. 56: fig. 7a-c, pi. 61: fig. 3a-c (= Acarinina coalingensis), pi.
62: fig. 2a-c].

Globigerina triloculinoides Plummer.—Loeblich and Tappan, 1957a. 183, pi.
62: fig. 3a-c [Zone P4, Velasco Fm., Mexico] [in part, not pi. 62: fig. 4a-c
and other illustrations of Subbotina triloculinoides ]. [Not Plummer, 1926.]
Globigerina gerpegensis Shutskaya, 1970a: 104, pi. 3: fig. 3a-c [holotype;
upper part of Acarinina tadjikistanensis djanensis Zone, Kachan Stage,
lower Danatin Subgroup, Malyi Balkhan Ridge, western Turkmenia],
Globigerina pseudotriloba Shutskaya, 1970a:85, pi. 2: fig. 7a-c [ Acarinina
conicotruncana Zone, Urukh River section, N. Ossetiya, northern Caucasus],
[Not White, 1928.]

Globigerina uruchaensis Shutskaya, 1970a:87, pi. 2: fig. 6a-c [holotype;
Acarinina conicotruncana Zone, Urukh River section, N. Ossetiya, northern
Caucasus],

Subbotina patagonicaltriangularis group Tjalsma, 1977:510, pi. 4: fig. 2 [Zone
P5, DSDP Site 329/32/4: 67-68 cm], figs. 3-6 [Zone P6, DSDP Site
329/32/4: 139-141 cm; flank of Falkland Plateau, southwestern Atlantic
Ocean],

Subbotina triangularis triangularis (White).—Blow, 1979:1281, pi. 91: figs. 7,
9 [Zone P4, DSDP Hole 21 A/3/6: 74-76 cm; South Atlantic Ocean], pi. 98:
fig. 6 [Zone P4, given as P5, Lindi area, Tanzania], pi. 107: figs. 8, 9 [Zone
P4, given as P6, DSDP Hole 20C/6/3: 76-78 cm; Brazil Basin, South
Atlantic Ocean],

Original Description. —“Test triangular, composed of
about two coils arranged in a low trochoid spire; chambers
inflated, somewhat appressed, three sub-equal chambers
comprising the last whorl; sutures deep; aperture must be in the
small umbilicus.

“Diameter of type specimen, 0.4 mm.; thickness, 0.2 mm.”
(White, 1928:195.)

Diagnostic Characters. —Test a somewhat loose coil of
3'/2 chambers in ultimate whorl, with narrow, deep umbilicus
sometimes obscured by an overlapping ultimate chamber.
Shape of test triangular in umbilical view, ultimate chamber
often smaller than penultimate one, low oval in shape. Axial
periphery broadly rounded. Aperture umbilical to slightly
extraumbilical, bordered by thin, sometimes irregular lip. Wall
cancellate, spinose with an asymmetrically developed pore
pattern and well-developed coalescing spine collars.

Discussion. —Shutskaya’s (1970a, 1970b) references to
pseudotriloba, triangularis, uruchaensis, and gerpegensis are
all considered synonymous with Subbotina triangularis. The
criteria she provided to distinguish between these forms and her
text-illustrations are insufficient for consistent discrimination.
Moreover, she (1970a: 104) included Bolli’s illustration of G.
triangularis (1957a, pi. 15: figs. 12-14) in the synonym of her
new taxon, G. gerpegensis.

The distinctive spinose wall texture of Subbotina triangu¬
laris sets it apart from the trivialis-triloculinoides lineage and
the cancellata-velascoensis lineage. Subbotina triangidaris
may be a stem form for a separate lineage that links .with
Eocene species, but this possibility has not been investigated. It
may be linked with Globigerina praebulloides, which has a
similar wall texture (compare Plate 2: Figures 14-16).

NUMBER 85

31

STABLE Isotopes.— Subbotina triangularis displays a more
positive 8 18 0 and more negative 5 13 C than coexisting
Morozovella and Acarinina (D’Hondt et al., 1994). The species
shows little change in 8 18 0 or 8 13 C over a large size range
(D’Hondt et al., 1994).

Stratigraphic Range. —Zone P2 to Zone P5, ? P6.
Global Distribution. —Apparently this species has a
global distribution in the low to middle latitudes.

Origin of Species. —This species probably evolved from S.
triloculinoides in Zone P3 by developing a more evolute coil,
by increasing its test size, and by achieving a more asymmetical
pore pattern with well-developed coalescing spine collars.

Repository. —Columbia University Paleontology Collec¬
tion (No. 19881, locality No. 11); collection now at the
American Museum of Natural History, New York.

Subbotina triloculinoides (Plummer, 1926)

Figure 12; Plate 9: figures 13-15; Plate 14: figures 15, 16;

Plate 27: figures 1-13

Globigerina triloculinoides Plummer, 1926:134, pi. 8: fig. lOa-b [Zone P2,
Wills Point Fm., Midway Group, Navarro Co., Texas, Station 23].—Bolli,
1957a:70, pi. 15: figs. 18-20 [Globorotalia pusilla pusilla Zone, Lizard
Springs Fm., Trinidad] [in part, not pi. 17: figs. 25, 26].—Loeblich and
Tappan, 1957a: 183, pi. 40: fig. 4a-c [ Tylocidaris oedumi Zone, Danian
Stage, western Denmark], pi. 41: fig. 2a-c [Zone Pic, McBryde Limestone
of Clayton Fm., Wilcox Co., Alabama], pi. 42: fig. 2a-c [Zone Pic,
Brightseat Fm., Maryland], pi. 43: fig. 5a-c [Zone PI, Kincaid Fm., Travis
Co., Texas], pl. 43: figs. 8a,b, 9a-c [Zone P2, Wills Point Fm., Midway
Group, Navarro Co., Texas], pl. 45: fig. 3a-c [Zone P3, Matthews Landing
Marl, Naheola Landing, Tombigbee River, Alabama] [in part, not pl. 46: fig.
la-c, pl. 47: fig. 2a-c, pl. 52: figs. 3-7, pl. 56: fig. 8a-c, pl. 62: figs. 3,
4],—Bolli and Cita, 1960:13, pl. 31: fig. la-c [ Globorotalia trinidadensis-
Globigerina daubjergensis Zone, Pademo d’Adda section, northern Italy].—
Berggren, 1962:86, pl. 14: figs. la-2b [Zone Plb, type Danian, Stevns Klint,
Denmark],—Hillebrandt, 1962:119, pl. 11: fig. la-c [Danian Stage,
Richenhall-Salzburg Basin, Austro-German border],—Shutskaya,
1970b: 118, pl. 18: fig. la-c [upper subzone of Globigerina trivialis-
Globoconusa daubjergensis-Globorotalia compressa Zone, Malyi Balkhan
Ridge, western Turkmenia], pl. 19: fig. 3a-c [Acarinina inconstans Zone,
Malyi Balkhan Ridge, western Turkmenia], pl. 21: fig. 5a-c [Acarinina
praepentacamerata Zone, Urukh River section, northern Caucasus], pl. 23:
fig. 12a-c [lower subzone of Acarinina tadjikistanensis djanensis Zone,
Malyi Balkhan Ridge, western Turkmenia].

Globigerina pseudotriloba White, 1928:194, pl. 27: fig. 17a,b [Velasco Fm.,
Mexico].

Globigerina stainforthi Bronnimann, 1952:23, pl. 3: figs. 10-12 [Paleocene,
Trinidad],

Globigerina ( Globigerina ) microcellulosa Morozova, 1961:14, pl. 1: fig. 11
[Danian, Tarkhankut, Crimea].

Subbotina triloculinoides (Plummer).—Brotzen and Pozaryska, 1961:160,
text-fig. 2, pl. 4: fig. 4 [lower Paleocene, Midway Group, Texas],—Belford,
1967:7, pl. 1: figs. 1-5 [Paleocene, Australia].—Stott and Kennett,
1990:559, pl. 2: fig. 12 [Zone APla, ODP Hole 690C/15X/2: 46-50 cm;
Maud Rise, Weddell Sea, Southern Ocean].

Subbotina triloculinoides triloculinoides (Plummer).—Blow, 1979:1287, pl.
74: fig. 6 [Zone Pl, DSDP Hole 47.2/11/1: 148-150 cm; Shatsky Rise,
northwestern Pacific Ocean], pl. 80: fig. 1 [Zone P2, DSDP Hole 20C/6/4:
72-74 cm; Brazil Basin, South Atlantic Ocean], pl. 98: fig. 7 [Zone P4, given
as P5, Lindi area, Tanzania], pl. 238: fig. 5 [same specimen as pl. 98: fig. 5],

pl. 248: figs. 9, 10 [topotypes, Zone P2, Navarro Co., Texas], pl. 255: fig. 9
[Zone D2 of Bang, 1969, probably Zone Pic, Karlstrup, Denmark], pl. 257:
fig. 9 [Zone Pic, upper Danian, Klagshamn, Sweden],

Original Description. —“Test spiral, trochoid, composed
of about 2 convolutions, the last of which is composed of 3 V 2
very rapidly increasing and highly globose chambers; periph¬
ery very broadly rounded and distinctly lobate; shell surface
strongly reticulate; superior face rounded with a very low spire
of neatly coiled tiny chambers of the preceding whorl; inferior
face rounded with a very shallow umbilical depression;
aperture a small arched slit on the last chamber and edged with
a more or less prominent, delicately notched flap that extends
from a point near the periphery to the umbilical depression.

“Greatest diameter up to .35 mm.; usually less.” (Plummer,
1926:134.)

Diagnostic Characters. —Medium sized, lobulate, trilo¬
bate test with 3—3 V 2 chambers in ultimate whorl increasing
moderately in size, ultimate chamber occupies up to V 2 of test
size. Intercameral sutures depressed, straight to slightly curved
on umbilical and spiral sides of test. Umbilicus narrow, deep,
often covered by well-developed apertural lip. Aperture
umbilical, slightly asymmetrical towards an extraumbilical
direction. Test walls strongly cancellate, spinose, with spines
occurring at the juncture of and along cancellate ridges.

DISCUSSION. —Together with Parasubbotina pseudobulloi-
des (Plummer), this taxon is probably one of the most cited, yet
most frequently misidentified, taxa of the Paleocene. The
detailed analysis of Blow (1979) may serve as a guide to a
reasonably consistent delineation of the main characteristics of
this species. Although S. triloculinoides has a strongly
cancellate wall texture, its does not possess the symmetrical,
coarsely cancellate wall of the cancellata-velascoensis line¬
age. The ancestral S. trivialis is more weakly cancellate, and S.
triangularis has an asymmetrical cancellate surface with
distinct spine collars. Unlike Blow (1979), we do not recognize
the two subgroups (aside from S. triloculinoides sensu stricto)
to which some sort of formal nomenclature may be applied: S.
triloculinoides stainforthi Blow and S. triloculinoides nana
Blow. The former is interpreted as a junior synonym of S.
triloculinoides, as has been more or less suggested by Bolli
(1957a), and the “taxon” nana Khalilov is a squat, subquadrate
form with a linaperta-hke aperture referable to S. velascoensis
(Cushman) and not to 5. triloculinoides (verified by examina¬
tion of the holotype by WAB). Khalilov (1967) indicated that
the range of nana is upper Paleocene to lower Eocene in the
Malyi Caucasus (Azerbaizhan) and Malyi Balkhan (Turkme¬
nia); the morphology of velascoensis (= nana), however,
already appears in Zone P3. The SEMs of the holotype (Plate 9:
Figures 13-15) of S. microcellulosa (Morozova) show this
taxon to be a junior synonym of triloculinoides.

STABLE Isotopes. — Subbotina triloculinoides has a S 13 C
and 8 18 0 signature similar to P. pseudobulloides, P. varianta,
G. compressa, and G. planocompressa, but it typically has a
heavier 8 18 0 and more negative 8 13 C than coexisting Praemu-

32

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

180°W

135°W

90°W

45°W

45°E

90°E

135°E

FIGURE 12.—Paleogeographic map showing distribution of Subbotina triloculinoides (Plummer) in Zones PI to
P3.

rica and Morozovella. The species shows little change in 5 18 0
or 5 13 C over a large size range (Berggren and Norris, 1997).

Stratigraphic Range. —Zones Plb to P4. Although its
upper stratigraphic limit remains somewhat equivocal, we have
not observed it above Zone P4 and believe it is restricted to the
Paleocene.

Global Distribution. —Essentially a worldwide distribu¬
tion in the low to high latitudes (Figure 12).

Origin of Species. —Although Blow (1979) was of the
opinion that the origin of S. triloculinoides lay in the plexus of
forms that radiate from Eoglobigerina eobulloides sensu lato
toward E. trivialis and S. triloculinoides, and, more specifi¬
cally, with F eobulloides simplicissima, we view its evolution
from S. trivialis to be more likely (see also Olsson et al., 1992).

Repository. —Holotype: Walker Museum Collection
33076, Station 23, now in the Field Museum, Chicago.
Paratype (USNM 370088) deposited in the Cushman Collec¬
tion, National Museum of Natural History. Holotype examined
by WAB; paratype examined by BTH.

Subbotina trivialis (Subbotina, 1953)

Plate 9: figures 10-12; Plate 28: figures 1-13

Globigerina trivialis Subbotina, 1953:64, holotype: pi. 4: fig. 4a-c; paratypes:

pi. 4: figs. 5a-7c [zone of rotaliform Globorotalia (= PI), basal Elburgan

Fm., Kuban River section, northern Caucasus] [in part, not pi. 4: fig. 8a-c
(same horizon; = S. triloculinoides )].—Shutskaya, 1970b: 118, pi. 18: fig.
2a-c [upper subzone of Globigerina trivialis-Globoconusa daubjergensis-
Globorotalia compressa Zone, Malyi Balkhan Ridge, western Turkmenia],
pi. 18: fig. 16a-c [middle subzone of Globigerina trivialis-Globoconusa
daubjergensis-Globorotalia compressa Zone, Malyi Balkhan Ridge, west¬
ern Turkmenia] [in part, not pi. 21: fig. 3a-c, pi. 23: fig. 6a-c],
Eoglobigerina trivialis (Subbotina).—Blow, 1979:1224, pi. 65: figs. 1-3, pi.
66: figs. 4, 7 [Zone Pa, DSDP Hole 47.2/11/3: 148-150 cm], pi. 69: fig. 9,
pi. 70: fig. 8 [Zone PI, DSDP Hole 47.2/11/3: 0-5 cm; Shatsky Rise,
northwestern Pacific Ocean], pi. 70: figs. 1, 2 [Zone P2, DSDP Hole
20C/6/4: 72-74 cm; Brazil Basin, South Atlantic Ocean].—Stott and
Kennett, 1990:559, pi. 2: fig. 11 [Zone API, ODP Hole 690C/15X/2: 46-50
cm; Maud Rise, Weddell Sea, Southern Ocean],—Berggren, 1992:563, pi. 1:
fig. 1 [ODP Hole 747C/19H/CC; Kerguelen Plateau, southern Indian Ocean],
Eoglobigerina aff. trivialis (Subbotina).—Blow, 1979:1228, pi. 61: fig. 8
[Zone Pa, DSDP Hole 47.2/11/4: 148-150 cm], pi. 69: fig. 8 [Zone PI,
DSDP Hole 47.2/11/3: 0-5 cm], pi. 74: figs. 7, 8 [Zone PI, DSDP Hole
47.2/11/1: 148-150 cm; Shatsky Rise, northwestern Pacific Ocean],
Eoglobigerina cf. trivialis (Subbotina).—Blow, 1979:1229, pi. 55: fig. 9 [Zone
Pa, DSDP Hole 47.2/11/5: 148-150 cm; Shatsky Rise, northwestern Pacific
Ocean].

Subbotina trivialis (Subbotina).—Huber, 1991 c:461, pi. 3: figs. 16, 17 [Zone
API, ODP Hole 738C/17R: 350.45 mbsf; Kerguelen Plateau, southern
Indian Ocean],—Olsson, Hemleben, Berggren, and Liu, 1992:202, pi. 4: figs.
5-8 [Zone PI a, Pine Barren Mbr., Clayton Fm., Millers Ferry, Alabama].

Original Description. —“Shell inflated with tall first
whorls which are 2 in number and large in size. The last whorl
consists of 4-4 '/2 almost regular, spherical chambers which

NUMBER 85

33

differ very slightly in size. The chambers are closely packed
together and partially overlap each other. Because of this the
shell is very compact. Peripheral margin broadly undulate;
septal sutures curved, deeply incised as is characteristic of
species with strongly inflated shells. Orifice small, and forming
a slightly curved or straight slit which is situated along the
marginal suture and near to, or more rarely above, the
umbilicus. Walls with relatively large pores and a cellular
pattern. Mean dimensions: diameter 0.40 mm, thickness 0.23
mm.” (Subbotina, 1953:64; translated from Russian.)

Diagnostic Characters. —Low trochospiral, tightly
coiled test with 3 */2 chambers in ultimate whorl, umbilical
aperture with thin lip. Ultimate chamber equal to, or slightly
smaller than, penultimate one. Wall weakly cancellate and
spinose. Spines set at junctures of cancellate ridges (Plate 28:
Figures 12, 13). Umbilicus small and nearly closed by tight
coiling. Overall size of test generally < 250 pm.

DISCUSSION. —Although Subbotina’s original description
refers to 4-4'/2 chambers in the final whorl, her illustrations of
the holotype and paratypes show only 3 V 2 chambers. Blow
(1979) presented a thorough analysis of this morphospecies
with which we in large part agree. Like Blow, we have not
observed individuals as large as 0.4 mm in diameter as noted by
Subbotina (1953) for her holotype from the northern Caucasus.
In fact, remeasurement of her holotype (Plate 9: Figures
10-12) shows a diameter of 0.35 mm. Blow (1979) also
described forms with more closely appressed chambers and
abortively developed final chambers (as Eoglobigerina cf.
trivialis ) and forms with a turreted, high-spired umbilical side
(as Eoglobigerina aff. trivialis). We include these morphotypes
here in the concept of trivialis, as they do not appear to have
any significant numerical representation or stratigraphic conti¬
nuity in occurrence.

Stable Isotopes.—-N o data available.

Stratigraphic Range. —Zone Pa to Zone P2.

Global Distribution. —Essentially a worldwide distribu¬
tion in the low to high latitudes.

Origin of Species. —Although we agree with Blow (1979)
that the distinction between the wall texture of eoglobigerinids
and subbotinids is one of degree rather than kind, we view
trivialis as the earliest representative of Subbotina (in contrast
to Blow, 1979, who retained it in Eoglobigerina) and the main
lineage that ultimately gave rise to the late Paleogene-Neogene
spinose globigerinid radiation (see also Pearson, 1993; Liu and
Olsson, 1994).

Repository. —Holotype (No. 4004) and paratypes (Nos.
4005-4007) deposited in the micropaleontological collections,
VNIGRI, St. Petersburg, Russia. Examined by FR.

Subbotina velascoensis (Cushman, 1925)

Figure 13; Plate 29: figures 1-12

Globigerina velascoensis Cushman, 1925:19, pi. 3: fig. 6a-c [Paleocene,
Velasco Fm., Tamalte Arroyo, Hacienda el Limon, San Luis Potosi,

Mexico],—White, 1928:196, pi. 28: fig. 2a,b [Paleocene, Velasco Shale,
Tampico Embayment, eastern Mexico],—Bolli, 1957a:71, pi. 15: figs. 9-11
[Zone P4, Lizard Springs Fm., Trinidad],—Bolli and Cita, 1960:374, pi. 34:
fig. 8a-c [Globorotali pseudomenardii Zone, Pademo d’Adda section,
northern Italy].—Hillebrandt, 1962:120, pi. 11: fig. 4a,b [Paleocene,
Reichenhall-Salzburg Basin, Austro-German border].—Gohrbandt,
1963:47, pi. 2: figs. 1-3 [upper Paleocene, north of Salzburg, Austria].—
Shutskaya, 1970a:94, pi. 4: figs. 3a-4c, 6a-c [figs. 3, 6: Acarinina
subsphaerica Zone, Kambileevka River, Black Mountains, northern Cau¬
casus; fig. 4: Acarinina subsphaerica Zone, Tarkhankut Peninsula, Crimea],
Globigerina velascoensis Cushman var. compressa White, 1928:196, pi. 28:

fig. 3a,b [Velasco Fm., Tampico Embayment, eastern Mexico].

Globigerina quadritriloculinoides Khalilov, 1956:237, pi. 1: fig. 5a-c
[holotype, upper Paleocene, Akhchakuima, NE foothills of Malyi Caucasus,
Nakhichevan Autonomous Republic, Azerbaizhan],

Globigerina triloculinoides Plummer nana Khalilov, 1956:236, pi. 1: fig. 4a-c
[holotype, upper Paleocene, from Akhchakuima, NE foothills of Malyi
Caucasus, Nakhichevan Autonomous Republic, Azerbaizhan],

Original Description. —“Test much compressed, the
dorsal side with all the chambers visible, ventral side only those
of the last-formed coil, sides nearly parallel, periphery broadly
rounded; chambers distinct, three or four making up the
last-formed coil, early chambers subglobular, later ones
becoming more compressed, and the inner margin fairly
straight; wall finely and evenly reticulate; aperture on the
ventral side, elongate.

“Diameter 0.45 mm.; thickness 0.25 mm.” (Cushman,
1925:19.)

Diagnostic Characters. —Tightly coiled test with com¬
pressed chambers and subquadrate test shape with umbilical
aperture. Ultimate chamber much compressed, elongate oval¬
shaped, about one-half test size, and typically overhanging
earlier chambers. Aperture bordered by thin elongate lip; lip
extending less than full length of aperture and squared off at
termination. Test wall coarsely and symmetrically cancellate,
spinose.

Discussion. —Although the holotype specimen is deformed,
Bolli (1957a) defined the concept of this species, which is
followed herein. The species was described from the Velasco
Shale from which White (1928) illustrated better preserved
specimens that he identified with Cushman’s species. White’s
concept was followed by Bolli. White’s figures, although
drawings, illustrate a quadrate-shaped test with much com¬
pressed chambers. Furthermore, his drawings clearly indicate a
symmetrical, coarsely cancellate test wall. Cushman (1925) in
his description referred to an evenly reticulate wall, which
suggests that he observed the wall texture that characterizes this
species.

Bolli (1957a) and Blow (1979) considered that S. velascoen¬
sis evolved from S. triangularis at, or near, the Zone P3/P4
boundary and believed that S. velascoensis represented a
dead-end lineage. Subbotina velascoensis has a much different
wall texture than does S. triangularis. The latter species has a
finer asymmetrical cancellate wall with coalescing spine
collars, whereas S. velascoensis has a symmetrical, coarsely
cancellate wall texture. In S. velascoensis, the spines are set at
the intersection of the cancellate ridges and are not supported

34

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

1 80°W

L35°W

90°W

45°W

45°E

90°E

135°E

FIGURE 13.—Paleogeographic map showing distribution of Subbotina velascoensis (Cushman) in the upper
Paleocene.

by spine collars (Plate 29: Figure 11) as in S. triangularis (Plate
26: Figures 12, 13). We consider S. velascoensis as the end
member of the symmetrical coarsely cancellate lineage that
begins with S. cancellata. Subbotina cancellata, gives rise to S.
velascoensis at, or near, the Zone P3/P4 boundary. We agree
with Bolli and Blow that S. velascoensis represents a dead-end
lineage. Globigerina quadritriloculinoides Khalilov (1956)
from the upper Paleocene of Azerbaizhan exhibits the
characteristic quadrate-shaped morphology of S. velascoensis.
The holotype figures show a coarsely cancellate wall, also
typical of S. velascoensis.

Stable Isotopes. — Subbotina velascoensis has a 5 I3 C and
5 18 0 signature similar to P. varianta, G. compressa, and G.
pseudomenardii, but it typically has a heavier 5 18 0 and more
negative 8 13 C than coexisting Acarinina and Morozovella
(Berggren and Norris, 1997).

Stratigraphic Range. —Zone P3b to Zone P6a.

Global Distribution. —Essentially a worldwide distribu¬
tion in the low to middle latitudes, with preferential develop¬
ment in the middle to higher latitudes as is common with the
subbotinids (Figure 13).

Origin of Species. —This species evolved from S. cancel¬
lata by the development of a more tightly coiled, quadrate test
and compressed chambers.

Repository. —Holotype (USNM CC4348) deposited in the

Cushman Collection, National Museum of Natural History.
Examined by WAB and RKO.

Family Hedbergellidae Loeblich and Tappan, 1961

(by R.K. Olsson, Ch. Hemleben, and C. Liu)

Original Description. —“Primary aperture only, com¬
monly with prominent aperture lip, those of previous chambers
remaining as projections into the umbilical region.” (Loeblich
and Tappan, 1961:309.)

Diagnostic Characters. —Test trochospiral with um-
bilical-extraumbilical aperture with a prominent lip. Apertures
of earlier formed chambers remain visible around the umbili¬
cus.

Discussion. —The vast majority of hedbergellids are repre¬
sented by Cretaceous genera. Only one genus, Hedbergella, a
very common form throughout the Cretaceous, survived into
the Cenozoic where it gave rise to Globanomalina in the early
Danian.

Genus Hedbergella Bronnimann and Brown, 1958

Type Species. — Anomalina lorneiana d’Orbigny var. tro-
choidea Gandolfi, 1942.

NUMBER 85

35

Original Description. —“The smooth- to rough-walled,
calcareous hyaline test is trochospirally coiled. Its small early
chambers are globular, inflated, and globigerine-like. The last
few chambers are elongated and extend into a relatively small
umbilicus. The aperture is rounded, interiomarginal, and opens
into the umbilicus. Short apertural flaps extend into the
umbilicus but do not form an umbilical cover-plate. Family
Globotruncanidae.” (Bronnimann and Brown, 1958:16.)

Diagnostic Characters. —Test low to very low trochos-
piral with 18 or more globular chambers. Number of chambers
in ultimate whorl varing from 5 to 8. Aperture interiomarginal,
umbilical-extraumbilical, a low to high arch, bordered by a
narrow lip. Umbilicus small, deep, and open to apertures of
previous chambers. Normal perforate wall, smooth to heavily
pustulose, nonspinose.

DISCUSSION. —Late Cretaceous species of Hedbergella are
generally typified by more numerous chambers in the ultimate
whorl and by more pustulose chambers. The late Maastrichtian
species Hedbergella holmdelensis and H. monmouthensis,
however, show a reduced number of chambers in the ultimate
whorl and less pustulose chambers.

Hedbergella holmdelensis Olsson, 1964

Plate 30: figures 1-17

Hedbergella holmdelensis Olsson, 1964:160, holotype: pi. 1: fig. 2a-c;

paratype: pi. 1: fig. la-c [upper Maastrichtian, Navesink Fm., New

Jersey],—Huber, 1994:18, pi. 2: figs. 1-8 [upper Maastrichtian, Navesink

Fm., New Jersey],

Original Description. —“Test very low trochospiral,
nearly planispiral in appearance, much compressed; equatorial
periphery strongly lobate; axial periphery rounded. Wall finely
perforate, delicately hispid. Chambers five, occasionally six, in
final whorl, increasing rather rapidly in size, moderately
inflated, ovate, elongate in direction of coiling compressed
ovate in axial view. Sutures depressed and gently curved on
spiral side, depressed and radial on umbilical side. Aperture a
low arch, interiomarginal, umbilical-extraumbilical, bordered
by a thin lip; apertures of previously formed chambers open
into the umbilicus.

“Greatest diameter of holotype 0.20 mm., greatest thickness
0.10 mm. Unfigured paratypes range from 0.15 to 0.24 mm. in
maximum diameter, from 0.07 to 0.12 mm. in maximum
thickness. Greatest diameter of figured paratype 0.26 mm.,
greatest thickness 0.10 mm.” (Olsson, 1964:160.)

Diagnostic Characters. —Characterized by small, nearly
planispiral test with 5, occasionally 6 chambers in ultimate
whorl. Six to 7 chambers in penultimate whorl. Ovate,
elongated, compressed chambers typify species. Axial periph¬
ery imperforate for most part, only sparsely penetrated by
pores. Wall surface smooth but lightly covered by small
pustules. Aperture, a high arch extending from umbilicus to
axial periphery, bordered by a thin, narrow, uniformly wide lip.

DISCUSSION. — Hedbergella holmdelensis is the ancestral
species of the genus Globanomalina that first appears in Zone
P0 of the basal Danian. Morphologically, H. holmdelensis is
very similar to the first species of Globanomalina, G.
archeocompressa. The key morphologic characters that phylo-
genetically link the two species are the small, compressed,
smooth-walled test, the imperforate axial periphery, and the
umbilical-extraumbilical aperture with its narrow lip. Hedber¬
gella holmdelensis retains two typical hedbergellid characters:
the numerous, spherical-shaped chambers in the inner whorl,
which is an adult character of the majority of hedbergellid
species in the Cretaceous, and the pustulose surface of the test,
which is distributed rather uniformly over the chambers, in
contrast to the more restricted occurrence of pustules in
Paleogene species of Globanomalina. Pustule growth, particu¬
larly in the umbilical area, is related to gametogenetic
calcification in smooth-walled species in the Cenozoic. Pustule
growth in Hedbergella is largely unexplored, and its relation¬
ship to gametogenesis is unknown. Nevertheless, the difference
in its distribution on the test suggests a different biological
function for this genus than for Globanomalina. Globanomal¬
ina, however, is placed in the Hedbergellidae to reflect its
phylogenetic linkage with this important Cretaceous group of
planktonic foraminifera.

Stable Isotopes. —No data available
Stratigraphic Range. —Lower Maastrichtian to lower
Zone P0.

Global Distribution. —Apparently worldwide in the high
to low latitudes.

Origin of Species. —This species evolved in the Maas¬
trichtian from a multichambered ancestor.

Repository. —Holotype (USNM 640917) and paratype
(USNM 640919) deposited in the Cushman Collection,
National Museum of Natural History. Examined by BTH and
RKO.

Hedbergella monmouthensis (Olsson, 1960)

Figures 14, 15; Plate 31: figures 1-15

Globorotalia monmouthensis Olsson, 1960:47, pi. 9: figs. 22-24 [upper
Maastrichtian, Redbank Fm., New Jersey],

Hedbergella monmouthensis (Olsson).—Olsson, 1964:160, pi. 1: fig. 3a-c
[upper Maastrichtian, Redbank Fm., New Jersey],—Sliter, 1976:542, pi. 3:
figs. 1-3 [Maastrichtian, DSDP Hole 327A/12/1: 69-72 cm; eastern
Falkland Plateau, South Atlantic Ocean],—Huber, 1990:503, pi. 2: figs. 6-8,
pi. 6: fig. 2 [Maastrichtian, ODP Hole 690C/20X/5: 108-110 cm; Maud
Rise, Southern Ocean]; 1991a:292, pi. 1: figs. 2, 3 [Abathomphalus
mayaroensis Zone, ODP Hole 698A/16R/2: 67-71 cm; northeast Georgia
Rise, South Atlantic Ocean]; 1994:22, pi. 2: figs. 9-16 [upper Maastrichtian,
Redbank Fm., New Jersey],

Original Description. — "Test. —very low trochospiral,
nearly planispiral in appearance. Equatorial periphery strongly
lobate. Axial periphery rounded. Wall. —calcareous, finely
perforate, covered with short minute spines. Chambers. —

36

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

inflated, globular; about 15 arranged in 2 x h whorls. The 5,
occasionally 6, chambers of the final whorl increase rather
rapidly in size; the last two make up over x h of the test.
Sutures .—spiral side: oblique in early stages to straight in adult
stages, depressed, Umbilical side: radial, depressed. Umbil¬
icus. —narrow, deep. Aperture .—a low arch with a distinct lip;
interiomarginal, extraumbilical-umbilical. Coiling. —random.
Diameter 0.20 to 0.25 mm.” (Olsson, 1960:47.)

Diagnostic Characters. —Small species with 5-5 V2
inflated chambers in ultimate whorl rapidly increasing in size.
Penultimate whorl with 7 or more spherical chambers
increasing slowly in size. Periphery distinctly lobulate; test
surface relatively smooth and evenly covered with small
pustules. Axial periphery imperforate but pierced by occasional
pores. Aperture a high rounded umbilical-extraumbilical arch
bordered by a thin, narrow lip.

Discussion. —Liu and Olsson (1994) showed that a variety
of morphotypes existed within an assemblage of H. mon-
mouthensis. This species is regarded as ancestral to the normal
perforate cancellate species of the earliest Danian, which also
have the general shape of these morphotypes. Thus, it is
believed that these variations may have established trends that
resulted in the separation of the Paleocene globigerinids and
globorotaliids. Very primitive pore pits can be observed in the

chamber walls of H. monmouthensis. In the earliest Danian this
character was strongly developed, resulting in the cancellate
wall texture that is the most important distinguishing feature of
Cenozoic planktonic foraminifera. Two important cancellate
groups of planktonic foraminifera are derived from H.
monmouthensis, cancellate spinose and cancellate nonspinose.
Eoglobigerina and Parasubbotina represent the first of the
cancellate spinose genera, and Praemurica represents the first
of the cancellate nonspinose genera. A discussion of these
transitions is given in Liu and Olsson (1994).

STABLE Isotopes. —Hedbergella monmouthensis has
among the most positive 5 18 0 of any Cretaceous trochospiral
planktic foraminifer (Boersma et al., 1979). The 5 I8 0 of H.
monmouthensis is similar to Abathamphalus mayaroensis and
is distinctly more positive than Rugoglobigerina rotundata, R.
rugosa, Globotruncanella petaloidea, and Globotruncana area
(Berggren and Norris, 1997). The 5 13 C of H. monmouthensis is
lighter than coexisitng Rugoglobigerina.

Stratigraphic Range. —Upper Maastrichtian to lower
Zone P0.

Global Distribution. —Worldwide in the high and lower
latitudes (Figure 14).

Origin of Species. —The species originates in the upper
Maastrichtian from H. holmdelensis.

90'

[Late Maasrichtian-Early Danian (PO)l

180°W

135°W

90°W

45°W

45°E

90°E

135°E

FIGURE 14.—Paleogeographic map showing distribution of Hedbergella monmouthensis (Olsson) in the upper
Maastrichtian.

NUMBER 85

37

FIGURE 15. —Neotype of Hedbergella monmouthensis (Olsson), USNM 488562: a, umbilical view; b, edge view;
c, spiral view. (Scale bar = 100 pm.)

Repository. —Holotype (USNM 626471, lost), topotype
(USNM 640920), and neotype (USNM 488562, herein desig¬
nated and illustrated in Figure 15) deposited in the Cushman
Collection, National Museum of Natural History. Examined by
BTH and RKO.

Genus Globanomalina Haque, 1956, emended

TYPE Species. —Globanomalina ovalis Haque, 1956.

Original Description. —“Test oval to nearly circular in
outline, periphery lobate, composed of somewhat globular
chambers arranged in a trochoid spiral, usually very low. All
chambers are visible from the dorsal side, which may be
flattened or convex. Ventral side completely involute, umbili-
cate. Surface smooth, shiny. Wall calcareous, finely perforate,
built of radially arranged crystals of calcite. Aperture periph¬
eral, sometimes extending to the umbilicus on the ventral side,
usually with a short lip. Lower Eocene.” (Haque, 1956:147.)

Diagnostic Characters. —Test very low trochospiral
with 12-15 chambers, with 5-6 chambers in ultimate whorl;
chambers vary from globular to ovoid to low conical in shape.
Aperture interiomarginal, umbilical-extraumbilical, a moder¬
ately high arch bordered by narrow lip that may broaden
slightly towards umbilicus; aperture may extend slightly onto
spiral side. Umbilicus small, generally deep. Wall normal
perforate, smooth, but may be covered with pustule growth in
some species, particularly in umbilical area. Peripheral margin
either perforate, an imperforate band, or keeled.

DISCUSSION. —Banner’s 1989 study of Globanomalina
clarified its taxonomic status, clearly distinguishing the genus
from the planispiral Pseudohastigerina, which Loeblich and
Tappan (1988) regarded as a junior synonym of this genus.
Banner emended the genus to clearly separate it from
Pseudohastigerina and discussed its evolutionary relationship

with this genus. He, however, regarded Globanomalina as
having a microperforate wall with low, bluntly margined
perforation pits. His observations appear to be based on poorly
preserved specimens with corroded and recrystallized walls.
All of the species of Globanomalina included in this atlas are
normal perforate. Banner’s observation of perforation pits is,
however, correct, but as he pointed out, they are not to be
confused with a cancellate wall. Globanomalina is herein
emended to include the smooth-walled species of the Paleo-
cene, which are members of two distinct lineages, one with an
imperforate margin that leads to the carinate species G.
pseudomenardii and one with a perforate margin that leads to
the planispiral genus Pseudohastigerina.

Globanomalina archeocompressa (Blow, 1979)

Plate 32: figures 1-10

Globorotalia (Turborotalia) archeocompressa Blow, 1979:1049, holotype: pi.
58: figs. 8, 9 [Zone Pa, DSDP Hole 47.2/11/5: 148-150 cm], paratypes: pi.
56: figs. 1, 2 [Zone Pa, DSDP Hole 47.2/11/6: 148-150 cm], pi. 58: figs. 2,
6, 7 [Zone Pa, DSDP Hole 47.2/11/5: 148-150 cm], pi. 64: figs. 5, 9 [Zone
Pa, DSDP Hole 47.2/11/3: 148-150 cm], pi. 68: figs. 5, 6 [Zone PI, DSDP
Hole 47.2/11/3: 0-5 cm; Shatsky Rise, northwestern Pacific Ocean].

Original Description.— “The very small test consists of
about 11-12 chambers coiled in a low, lax trochospire with 5'/2
chambers visible in the final convolution of the test. In dorsal
aspect, the chambers are almost hemispherical with inflated
dorsal surfaces and depressed, sensibly radially disposed,
intercameral sutures; the chambers are almost equidimensional
with the tangential length only very slightly greater than the
radial breadth. The inflation of the dorsal surfaces of the last
convolution of chambers is such that the initial spire of
chambers is depressed below the level of the later chamber

38

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

surfaces. In equatorial profile, the test is moderately lobulate
but is almost circular in overall outline. In axial-apertural
profile, the test appears biconcave because of the depression of
the initial spire below the level of the dorsal surfaces of the later
chambers. The test is also seen in the axial-apertural view to
have a rounded peripheral marginal outline and the later
chambers, at least, appear subglobular with little or no
differentiation in the degree of inflation for the ventral and
dorsal surfaces of the chambers. In ventral aspect, the chambers
appear subglobular but with quite deeply depressed, but not
sharply incised, intercameral sutures which are radially
disposed. The umbilicus is open but is shallow with no clearly
marked umbilical shoulders to the surrounding convolution of
chambers. The aperture is interiomarginal and extends from the
shallow umbilicus to very nearly to the peripheral margin. The
aperture is bordered by a well-marked flange-like lip and is a
low, only slightly arched, opening. The wall is very finely
perforate and the mural-pores do not open into distinct
pore-pits, neither are they densely arranged. In optical
appearance, the finely and sparsely perforate wall combined
with the absence of pore-pits and inter-pore ridges gives the test
a smooth, almost polished appearance which is characteristic of
the G. (T) compressa (si) lineage. Maximum diameter of
holotype: 0.139 mm as measured by electron-beam sensor.”
(Blow, 1979:1049.)

Diagnostic Characters. —Very small-sized species,
< 130 pm in greatest diameter. Test flattened and compressed
with spiral side nearly plane. Axial periphery rounded with
slightly conical chambers; chambers nearly flat on spiral side
and project at high angle towards umbilicus. Ultimate whorl
with 5-6 compressed, oval-shaped chambers; chambers very
gradually increasing in size. Umbilicus shallow and broad,
open to previous chambers, with sparse pustules on umbilical
shoulders of surrounding chambers. Umbilical-extraumbilical
aperture a broad, low arch entirely bordered by narrow lip. Wall
of 4-7 pm thickness, smooth and perforate. Pores average 1
pm at narrowest point and mostly confined to chamber
surfaces away from largely imperforate periphery.

DISCUSSION —This is the first species of the genus Globa-
nomalina to appear in the earliest Danian. In morphology it is
very similar to its ancestral species, Hedbergella holmdelensis
Olsson, 1964. It differs, however, in that fine pustules are
confined to the umbilical and inner spiral areas of the test rather
than being sparsely distributed over the entire wall of the test as
in H. holmdelensis. In early species of Globanomalina the
chamber walls are smoother and generally free of numerous
pustules. Pustules are more numerous on the chamber walls of
G. pseudomenardii, but these are enhanced by gametogenesis.
The possibility that the “pustules” in G. archeocompressa are
of similar origin needs further investigation. The chambers are
somewhat more inflated and the equatorial peripheral margin is
more lobulate in H. holmdelensis. Another difference lies in the
ontogeny of each species. Six to 7 chambers make up the

penultimate whorl in H. holmdelensis, a chamber arrangement
typical of ancestral species of Hedbergella in the Cretaceous. In
G. archeocompressa, the penultimate whorl is reduced to 5
chambers, which is typical of Globanomalina. The imperforate
peripheral margin is a primary derived taxonomic character
from H. holmdelensis and is present throughout the archeocom¬
pressa lineage.

Stable Isotopes.—N o data available.

Stratigraphic Range. —Upper Zone P0 to Zone Plb. Due
to the very small size and rare occurrence of this species the
upper range is not yet reliably established.

Global Distribution. —Western equatorial Pacific Ocean,
coastal Gulf of Mexico, and South Atlantic Ocean (DSDP Site
356).

Origin of Species. —This species evolved from Hedber¬
gella holmdelensis in late Biochron P0.

Repository. —Holotype (BP 37/38) and paratypes (BP
37/7, 37/21, 37/39, 37/49, 37/58, 37/118, 40/12, 40/44, 40/55)
deposited in The Natural History Museum, London.

Globanomalina australiformis (Jenkins, 1965)

Figure 16; Plate 33: figures 1-13

Globorotalia australiformis Jenkins, 1965:1112, fig. 11:92-96 [lower Eocene,
Waipawan Stage, Middle Waipawan River section, New Zealand].—
Ludbrook and Lindsay, 1969:367, pi. 1: figs. 4, 5 [middle Eocene, South
Australia].

Planorotalites australiformis (Jenkins).—Tjalsma, 1977:495, pi. 2: figs. 10-12
[lower Eocene, DSDP Site 329/32/1: 141-143 cm], fig. 13, [upper
Paleocene, DSDP Site 329/33/1: 125-127 cm; Maurice Ewing Bank, South
Atlantic Ocean],—Jenkins, 1985:279, fig. 6.8 [holotype refigured].—Huber,
1991b:440, pi. 6: figs. 17, 18 [Zone AP5, uppermost Paleocene, ODP Hole
738B/23X: 196.93 msbf; Kerguelen Plateau, southern Indian Ocean],
Globorotalia (Planorotalites ) australiformis Jenkins in Homibrook, Brazier,
and Strong, 1989:128: fig. 24:15a-c [holotype refigured].

Original Description. —“Test free, sinistrally coiled,
small, low trochospiral, biconvex, equatorial periphery quad-
rilobate; axial periphery rounded in the first 3 chambers of the
final whorl, but angled with an incipient keel in the final
chamber. Wall calcareous, finely perforate, surface smooth.
Chambers compressed, 13 chambers in about 2'/2 whorls, with
5 chambers in the first whorl and 4 in the last, increasing fairly
rapidly in size; proloculus diameter approximately 0.01-0.02
mm. Sutures recurved on spiral side and nearly radial on the
umbilical side; slightly depressed on both sides. Umbilicus
small, open. Aperture a low arch interiomarginal, extraumbili-
cal-umbilical. Maximum diameter: 0.26 mm.” (Jenkins,
1965:1112.)

Diagnostic Characters. —Small species distinguished by
4 low, conical-shaped chambers in ultimate whorl and acute
axial periphery. Earlier chamber walls covered by fine, dense
pustules becoming more sparsely distributed on penultimate
and ultimate chambers. Axial periphery mostly imperforate,
becoming thickened on last one or two chambers.

NUMBER 85

39

1 80°W

135°W

90°W

45°W

45°E

90°E

135°E

FIGURE 16.—Paleobiogeographic map showing distribution of Globanomalina australiformis (Jenkins) in the
upper Paleocene.

DISCUSSION. —The original description of this species by
light microscope indicated a smooth, finely perforate wall, but
SEM micrographs show a fine coating of pustule-like calcite
covering the original wall. It is possible that this coating is of
gametogenetic origin, but this possibility needs more study.
The species has been reported only in southern latitude sites
and may be biogeographically restricted. Blow (1979) sug¬
gested that G. australiformis may be a cool-water endemic
form of the tropical Globorotalia troelseni Loeblich and
Tappan morphotype due to its general morphologic similarity.
Globorotalia troelseni (= G. chapmani Parr, 1938) is a
5-chambered species and does not possess the dense pustulose
wall surface of G. australiformis. It would appear that G.
australiformis arose independently as an endemic species in the
southern high latitudes. Blow also placed specimens identified
as Globorotalia elongata Glaessner, 1937a, by Loeblich and
Tappan (1957a) from the Vincentown Formation of New Jersey
and from the Velasco Shale of Mexico in synonymy with G.
australiformis. Those specimens belong to G. chapmani.

Stable Isotopes.—-N o data available.

Stratigraphic Range. —Lower part of Waipawan Stage to
the Porangan Stage; upper Subbotina triloculinoides Zone to
the P. primitiva Zone (upper Paleocene to lower Eocene).

Global Distribution. —Southern middle to high latitudes
(Figure 16).

Origin of Species. —The origin of this species has not been
traced. Jenkins (1965) notes that australiformis is closely
related to many Paleocene smooth-walled species (of Globa¬
nomalina) and that it replaces G. pseudomenardii Bolli, 1957a,
in the lower part of the Waipawan Stage. It would appear more
closely related to G. imitata in having 4-4 V 2 (mostly 4)
chambers in the final whorl and in the dense pustulose wall
surface observed in early chambers of this species (see Plate 4:
Figures 12, 13, 16; Plate 36: Figures 8, 12).

REPOSITORY. —New Zealand Geological Survey Register
No. TF 1503: holotype and two paratypes. Examined by G.J.

Globanomalina chapmani (Parr, 1938)

Plate 34: figures 1-7

Globorotalia chapmani Parr, 1938:87, holotype: pi. 3: fig. 9a,b; topotype: pi. 3:
fig. 8 [upper Paleocene (probably Zone P4), Kings Park Shale, Kings Park
Bore 1, 1,755 ft, Perth Basin, Western Australia],—McGowran, 1964:85,
text-figs. 1-9 [upper Paleocene, Carnarvon Basin, northwestern Aus¬
tralia].—Berggren, Olsson, and Reyment, 1967:277, text-figs. 1, 3:la-c,
4:la-c, pi. 1: figs. 1-6 [Zone P4, Vincentown Fm., New Jersey;
Boongerooda Greensand, northwestern Australia, text-fig. 1],—Pujol,
1983:657, pi. 3: fig. 3 [upper Paleocene, DSDP Hole 516F/85/1: 40-42 cm;
Rio Grande Rise, South Atlantic Ocean],—Haig, Griffin, and Ujetz,
1993:275, pi. 1: figs. 1-3 [holotype ESEM], figs. 4-6 [Parr topotype ESEM,
from same level as holotype], pi. 2: figs. 1-23 [topotypes, from same level
as holotype].

40

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Anomalina luxorensis Nakkady, 1951:691, pi. 90: figs. 39-41 [upper
Paleocene, Egypt].

Globorotalia membranacea (Ehrenberg).—Subbotina, 1953:205, pi. 16: fig.
12a-c [upper Paleocene, Tarkhankut Peninsula, Crimea] [in part, not pi. 16:
figs. 7a-1 lb, 13]. [Not Planulina membranacea Ehrenberg, 1854.]
Globanomalina ovalis var. lakiensis Haque, 1956:149, pi. 14: fig. 2a-c [upper
Paleocene, Pakistan].

Globorotalia elongata Glaessner.—Bolli, 1957a:77, pi. 20: figs. 11-13 [Zone
P4, Lizard Springs Fm., Trinidad]. [Not Globorotalia pseudoscitula var.
elongata Glaessner, 1937.]

Globorotalia troelseni Loeblich and Tappan, 1957a: 196, pi. 60: fig. 4a-c
[Zone P4, Nanafalia Fm., Alabama], pi. 63: fig. 5a-c [Zone P4, Velasco
Shale, Mexico].

Globorotalia ( Globorotalia) ehrenbergi Bolli.—Hillebrandt, 1962:126, pi. 12:
fig. 3a-c [Zone D, Paleocene, Reichenhall-Salzburg Basin, Austro-
German border], [Not Globorotalia ehrenbergi Bolli, 1957a.]

Planorotalites chapmani (Parr).—Nederbragt and Van Hinte, 1987:586, pi. 2:
figs. 3-10, pi. 3: figs. 4-6 [Zone P4, DSDP Site 605/46/4: 85-89 cm; fig. 3,
DSDP Site 605/47/3: 60-62 cm; New Jersey margin] [in part, not pi. 2: figs.
1, 2, 11-16, pi. 3: figs. 1-3, 10-15].—Huber, 1991b:440, pi. 6: figs. 19, 20
[upper Paleocene, ODP Hole 738C/9R: 265.01 msbf; Kerguelen Plateau,
Southern Indian Ocean].

Original Description. —“Test biconvex, oval, the dorsal
surface more convex than the ventral, which is umbilicate;
periphery lobulated, peripheral margin rounded; chambers
comparatively few, not more than five in the last-formed whorl,
each much larger than its predecessor; sutures depressed, not
limbate, gently recurved on both sides of the test; wall smooth
and punctate, with a silvery lustre; aperture an elongate slit with
a slight lip, opening at the base of the last-formed chamber into
the umbilical depression. Length up to 0.65 mm. This species
belongs to the group of G. hirsuta (d’Orbigny) and is perhaps
nearest to G. hirsuta, which typically has only four chambers to
a whorl and with the sutures on the ventral side radial.” (Parr,
1938:87.)

Diagnostic Characters. —Species identified by com¬
pressed test, pinched periphery with a thickened imperforate
band, and rapidly enlarging chambers. Typically 5, but up to 6,
chambers in ultimate whorl. Test walls smooth with occasional
small pustule buildups in umbilical area and on inner spiral
area.

DISCUSSION.— Haig et al.’s (1993) illustrations of the
holotype, paratypes, and topotypes taken by SEM has clarified
the morphologic characters of this species. It is clear from these
illustrations that Anomalina luxorensis Nakkady (1951),
Globanomalina ovalis var. lakiensis Haque (1956), the form
identified by Subbotina (1953, pi. 16: fig. 12a-c) as Globoro¬
talia membranacea (Ehrenberg, 1854), and the form identified
by Bolli (1957a, pi. 20: figs. 11-13) as Globorotalia elongata
(Glaessner, 1937a) should be placed in the synonomy of G.
chapmani. In addition, Globorotalia troelseni Loeblich and
Tappan (1957a) and the form identified by Hillebrandt (1962,
pi. 12: fig. 3a-c) as Globorotalia ehrenbergi Bolli (1957a) are
5-chambered, compressed, smooth-walled forms that can be
placed in G. chapmani. Globanomalina chapmani is a common
species in upper Paleocene assemblages.

STABLE Isotopes. — Globanomalina chapmani has 6 18 0 and
8 13 C similar to Parasubbotina varianta, S. triloculinoid.es, and
G. pseudomenardii. The species has distinctly more positive
8 18 0 and more negative 8 I3 C than Morozovella, Acarinina, and
Igorina.

Stratigraphic Range. —Within Zone P3 to Zone P6.
Global Distribution. —Worldwide in the middle and high
latitudes.

Origin of Species. — Globanomalina chapmani is a mem¬
ber of the smooth-walled imperforate periphery lineage and
evolved from G. ehrenbergi (Bolli) in the lower part of Zone
P4.

Repository. —Museum collections of the Department of
Geology, University of Western Australia, UWA18897. Exam¬
ined by GJ.

Globanomalina compressa (Plummer, 1926)

Figure 17; Plate 14: figures 1-3; Plate 32: figures 11-16;

Plate 35: figures 1-13,17

Globigerina compressa Plummer, 1926:135, pi. 8: fig. 1 la-c [Zone P2, Wills
Point Fm., Midway Group (upper Danian), Navarro Co., Texas].

Globigerina compressa var. compressa Plummer.—Subbotina, 1953:63, pi. 2:
figs. 2a-6c [Danian, zone of rotaliform globorotaliids, Elburganian horizon,
northern Caucasus].

Globorotalia compressa (Plummer).—Bolli, 1957a:77, pi. 20: figs. 21-23
[lower Paleocene, Lizard Springs Fm., Trinidad],—Bolli and Cita, 1960:20,
pi. 32: fig. 3a-c [ Globorotalia trinidadensis-Globigerina daubjergensis
Zone, Pademo d’Adda section, northern Italy].—Pujol, 1983:656, pi. 2: figs.
3, 4 [lower Paleocene, DSDP Hole 516F/89/2: 119-121 cm; Rio Grande
Rise, South Atlantic Ocean] [in part, not pi. 2: fig. 2].

Globorotalia ( Globorotalia ) compressa (Plummer).—Hillebrandt, 1962:125,
pi. 12: fig. la-c [Zone B, lower Paleocene, Reichenhall-Salzburg Basin,
Austro-German border].

Globorotalia ( Turborotalia ) compressa compressa (Plummer).—Blow,
1979:1062, pi. 75: figs. 10, 11 [Zone PI, Lindi area, Tanzania], pi. 78: figs.
5-10 [Zone P2, DSDP Hole 20C/6/4: 72-74 cm; Brazil Basin, South
Atlantic Ocean], pi. 248: figs. 1-3 [topotype illustrations], pi. 254: figs. 1-3
[Danian, Denmark], pi. 257: figs. 5-7 [upper Danian, Sweden].
Planorotalites compressus (Plummer).—Huber, 1991 c:461, pi. 3: figs. 1, 2
[Zone AP2, ODP Hole 738C/16: 340.93 mbsf; southern Kerguelen Plateau,
southern Indian Ocean],

Globanomalina compressa (Plummer).—Berggren, 1992:563, pi. 1: figs.
14-16 [ODP Hole 747A/19H/CC; Kerguelen Plateau, southern Indian
Ocean],

Original Description. —“Test small, rotaliform, closely
coiled, somewhat compressed, equally bioconvex; peripheral
margin bluntly angular, lobate; chambers increasing gradually,
5 in last-formed whorl, moderately inflated, overlapping on
dorsal face; sutures distinctly depressed and strongly curved on
the dorsal side; shell wall thin, smooth, finely punctate;
aperture a single moderately arched slit protected by a definite
flaring flap at base of septal face and extending into the small
but distinct umbilical depression.

“Diameter up to .4 mm.; average .3 mm.” (Plummer,
1926:135.)

Diagnostic Characters.— Small, 5-chambered smooth-

NUMBER 85

41

'+~r+ +- + 4 + + fT+ + + + +.+'4. + + + + + + + + + +
-h + + + + <+. + + ++ + -v + r<- •'+■•+ + +.* V> VY * + ^

180°W

135°W

90°W

45°W

45°E

90°E

I 35°E

FIGURE 17.—Paleobiogeographic map showing distribution of Globanomalina compressa (Plummer) in Zones
PI and P2.

walled test, with moderately angular axial periphery, and
moderately to strongly developed imperforate peripheral
margin. Aperture a low, umbilical-extraumbilical arch, bor¬
dered along entirety by narrow, well-defined lip.

DISCUSSION. —Plummer (1926) designated three cotypes to
represent her new species and illustrated one view of each
(dorsal, edge, and ventral). We have selected one of these
cotypes (Plummer, 1926: fig. 11c) as the lectotype for this
species (Plate 14: Figures 1-3). The axial view of the lectotype
is the view illustrated by Plummer to show the degree of
compression of the test and the bluntly angular peripheral
margin of the chambers of her new species. The chambers of
the two paralectotypes are somewhat more inflated and the
axial periphery of the test is somewhat less compressed than in
the lectotype. Blow (1979) restricted his identification of G.
compressa to morphotypes with compressed ogival chambers
in axial view in contrast to morphotypes with an inflated
rounded axial periphery, which he identified as G. cf.
compressa or, if the chambers were more fully inflated, as G.
planocompressa Shutskaya. Our studies separate compressa
and planocompressa on the degree of compression/inflation of
the chambers and the presence or absence of an imperforate
peripheral margin. In the compressa-ehrenbergi-chapmani
lineage an imperforate peripheral margin is a distinguishing
characteristic, and the degree of compression of chambers in

the ultimate whorl may vary from slightly compressed to the
compressed ogival shape. In contrast, in the planocompressa-
imitata-ovalis lineage the chambers in the ultimate whorl are
fully inflated and the axial periphery is perforate.

STABLE Isotopes. — Globanomalina compressa has 5 I8 0
and 5 13 C similar to Parasubbotina varianta, S. triloculinoides,
and G. ehrenbergi. The species has distinctly more positive
5 18 0 and more negative 5 I3 C than Morozovella and Praemu-
rica.

Stratigraphic Range.—Z one Pic to Zone P3.

Global Distribution. —Worldwide in low to high lati¬
tudes (Figure 17).

Origin of Species. —This species shares morphologic
similarities with G. archeocompressa in the compressed test
and in the bluntly angular imperforate peripheral margin. The
upper range of G. archeocompressa has not been firmly
established and, consequently, its linkage with G. compressa is,
at present, uncertain. We link the two species on the basis of
their shared morphologic similarities (Plate 32).

REPOSITORY. —The three cotypes, Walker Museum Collec¬
tion 33078, Station 23, are designated as follows: lectotype
(UC 55091) and paralectotype (UC 33078), Chicago Field
Museum; paralectotype (USNM 488563), Cushman Collec¬
tion, National Museum of Natural History. Examined by BTH
and RKO.

42

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Globanomalina ehrenbergi (Bolli, 1957)

Plate 14: figures 4, 8, 12; Plate 35: figures 14-16

Globorotalia membranacea (Ehrenberg).—Cushman and Bermudez, 1949:34,
pi. 6: figs. 16-18 [Paleocene, Cuba]. [Not Planulina membranacea
Ehrenberg, 1854.]

Globorotalia ehrenbergi Bolli, 1957a:77, pi. 20: figs. 18-20 [upper Paleocene,
Lizard Springs Fm., Trinidad].

Globorotalia haunsbergensis Gohrbandt, 1963:53, pi. 6: figs. 10-12 [Paleo¬
cene, north of Salzburg, Austria].

Globorotalia ( Turborotalia ) haunsbergensis Gohrbandt.—Blow, 1979:1075,
pi. 88: figs. 6, 8 [Zone P3, DSDP Hole 47.2/10/1: 72-74 cm; Shatsky Rise,
northwestern Pacific Ocean], fig. 9 [Zone P3, Lindi area, Tanzania],

Original Description. —“Shape of test low trochospiral,
compressed; equatorial periphery strongly lobate; axial periph¬
ery acute, last chamber often with a faint keel. Wall calcareous,
perforate, surface smooth. Chambers compressed; about 12-
15, arranged in 2-3 whorls, the 5 chambers of the last whorl
increasing fairly rapidly in size. Sutures on spiral side slightly
curved, distinctly depressed; on umbilical side radial, de¬
pressed. Umbilicus shallow, open. Aperture a low arch, with a
lip; interiomarginal, extraumbilical-umbilical. Coiling ran¬
dom. Largest diameter of holotype 0.28 mm.” (Bolli,
1957a:77.)

Diagnostic Characters. —Compressed, smooth-walled
test, with chambers moderately increasing in size, often with
ultimate chamber smaller than the penultimate one, pinched
periphery with thickened imperforate margin (faint keel of
Bolli), 5—5 '/2 chambers in ultimate whorl.

DISCUSSION. —Bolli (1957a) erected this species for Paleo¬
cene morphotypes that had been referred to Ehrenberg’s
species. The basis for distinguishing this species from G.
compressa is the pinched periphery and the thickened imperfo¬
rate margin, which is more strongly developed than in G.
compressa. Although Blow (1979) separated G. ehrenbergi
from G. haunsbergensis, we include morphotypes with a more
sharply acute periphery within the range of variation of G.
ehrenbergi. Blow (1979) drew attention to the more lax coiling
of G. haunsbergensis morphotypes, which results in a wide,
shallow umbilicus. The trend towards a more strongly
developed imperforate margin was recognized by Bolli and
Blow as a trend towards a true keel, which resulted in the
evolution of G. pseudomenardii. Globanomalina chapmani is
also allied to G. ehrenbergi in having a pinched periphery and
a thickened imperforate margin. As in G. pseudomenardii, the
rate of chamber-size increase is greater than in G. ehrenbergi.

STABLE Isotopes. — Globanomalina ehrenbergi has 5 I8 0
and 5 13 C similar to Parasubbotina varianta, S. triloculinoides,
and G. compressa. The species has distinctly more positive
8 18 0 and more negative 8 13 C than Morozovella and Igorina.
Stratigraphic Range. —Zone P2 to Zone P4.

Global Distribution. —Apparently a worldwide distribu¬
tion in the low to middle latitudes.

Origin of Species. —As pointed out by Bolli (1957a) and

Blow (1979), this species is transitional to G. pseudomenardii.
It evolved from G. compressa by developing a more highly
developed imperforate margin and a more sharply angular axial
margin.

Repository. —Holotype (USNM P5060) deposited in the
Cushman Collection, National Museum of Natural History.
Examined by RKO.

Globanomalina imitata (Subbotina, 1953)

Plate 10: figures 12-14; Plate 12: figures 10-12;

Plate 36: FIGURES 7-12, 16

Globorotalia imitata Subbotina, 1953:206, holotype: pi. 16: fig. 14a-c;
paratype: pi. 16: figs. 15a-16c [zone of rotaliform globorotaliids (Danian
Stage), Kuban River, northern Caucasus].—Loeblich and Tappan,
1957a: 190, pi. 54: fig. 8a-c [Zone P4, Vincentown Fm., New Jersey], pi. 59:
fig. 5a-c [Zone P4, Aquia Fm., Maryland], pi. 63: fig. 3a-c [Zone P4,
Velasco Fm., Mexico] [in part, not pi. 44: fig. 3a-c, pi. 45: fig. 6a-c, pi. 54:
fig. 9a-c],—Olsson, 1960:46, pi. 9: figs. 7-9 [Zone P3b, Homerstown Fm.,
New Jersey],

Original Description. —“Shell small, rotaliform, strongly
convoluted with a broadly oval outline. Whorls 2 V 2 —3. The
first 2 whorls are considerably smaller than the last. Their
diameter comprises on average only one third the diameter of
the whole shell. Dorsal side flattened, ventral side convex,
subconical. In the centre of the central side there is a very small,
hardly discernible umbilicus. The umbilical ends of the
chambers are disposed above the rest of the surface of the
ventral side, thus forming the apex of a short cone. The
peripheral margin is rounded and scalloped. The chambers on
the dorsal side are oval and drawn out in the direction of the
spiral whereas on the ventral side they are broadly triangular.
There are 4 chambers to the last whorl and these show a rapid
increase in dimensions. The sutures are recessed, almost
straight or slightly curved, on both the dorsal and the ventral
sides. Attention should be paid to the shortness of the sutures
on the dorsal side as compared with the rather long sutures on
the ventral side. The orifice is represented by a straight slit
covered by well-defined slender lips. It has the form of an even
rectangular cavity extending along the whole length of the
marginal suture. The wall is thin, smooth, and in well-preserved
specimens lustrous; it is perforated by many small pores.
Dimensions: diameter 0.15-0.25 mm, thickness 0.08-0.11
mm.” (Subbotina, 1953:206; translated from Russian.)

Diagnostic Characters. —Small smooth-walled test with
4-4 V 2 , occasionally 5, inflated chambers in ultimate whorl.
Chambers ovoid shaped with long axis directed towards
umbilicus. In spiral and umbilical views, chambers ovoid
shaped, with long axis parallel to coiling spire. Test walls
perforate throughout; aperture a high umbilical-extraumbilical
arch bordered by thin continuous lip. Adult chambers smooth-
walled, but wall covered with fine scattered to dense pustules in
early ontogenetic stages possessing anguloconical chambers
(Plate 4: Figures 12, 13, 16, Plate 36: Figures 8, 12).

NUMBER 85

43

DISCUSSION. —This is a distinctive species that is often
overlooked because of its small size. It belongs to the perforate
walled, inflated chamber lineage of planocompressa-imitata-
ovalis. It also appears to have a phylogenetic link to G.
australiformis (see “Discussion” under this species). The
specimens illustrated as imitata by Blow (1979, pi. 81: figs. 8,
9, pi. 83: figs. 1,2, pi. 88: fig. 5) are distinctly cancellate walled
and do not belong to this species but probably belong to
Praemurica.

Stable Isotopes—No data available.

Stratigraphic Range. —Zone Pic to Zone P4.

Global Distribution. —Known from the northern Cau¬
casus, southeast India, and the Atlantic and Gulf of Mexico
coastal plains.

Origin of Species. —This species probably evolved from
Globanomalinaplanocompressa in Zone Pic.

REPOSITORY. —Holotype (No. 4073) and paratypes (Nos.
4074, 4075) deposited in the micropaleontological collections
at VNIGRI (378/112), St. Petersburg. Examined by FR.

Globanomalina ovalis Haque, 1956

Plate 37: figures 1-15

Globanomalina ovalis Haque, 1956:147, pi. 14: fig. 3a-c [upper Paleocene,
Bed B2, Laki Fm., Pakistan],—Banner, 1989, emended: 177, pi. 1: fig. la-c
[original drawings of holotype], pi. 1: fig. 2a-c [original drawings of
holotype of Globanomalina simplex Haque, 1956], pi. 1: fig. 3a-c [SEM of
paratype of G. ovalis ], pi. 1: fig. 4a-c [original drawings of holotype of
Globigerina pseudoiota Homibrook, 1958], pi. 2: fig. la-c [paratype of G.
ovalis ], pi. 2: fig. 2a-e [upper Paleocene, Dannevirke Series, New Zealand],
pi. 3: figs. la-2d [upper Paleocene, Dannevirke Series, New Zealand],
Globigerina pseudoiota Homibrook, 1958:34, pi. 1: figs. 16-18 [upper
Paleocene, New Zealand]. Banner, 1989, pi. 1: figs. 4a-c, pi. 2: figs. 2a-e,
pi. 3, figs, la-d, 2a-d.

Globorotalia ( Turborotalia ) sp. ex interc G. (T.) chapmani Parr and
Pseudohastigerina wilcoxensis (Cushman and Ponton).—Blow, 1979:1060,
pi. Ill: fig. 5 [Moogli Mudstones, Papua, given as Zone P7 = Zone P6a this
paper].

Original Description. —“Test small, oval, longer than
broad, biconvex, nearly bilaterally symmetrical. Periphery
sub-acute, broadly rounded, lobate. Dorsal side flat or slightly
convex, showing all the chambers. Ventral side completely
involute, umbilicate. Chambers distinct, inflated, globose,
somewhat overlapping, about 6 in the adult whorl, rather
rapidly increasing in size as added; last 2 chambers occupy
more that half of the test. Sutures distinct, depressed, somewhat
curved on the dorsal side, radial on the ventral. Surface smooth,
shiny. Wall calcareous, very finally perforate, built of radially
arranged crystals of calcite. Aperture an elongate slit at the base
of the last chamber of the outer whorl extending from the
periphery to the umbilicus with a narrow lip. Length of figured
specimen 0.26 mm; breadth 0.21 mm; thickness 0.14 mm.”
(Haque, 1956:147.)

Diagnostic Characters.—E mended description: u Globa-
nomalina as here defined, with six chambers per whorl initially,
sometimes retaining this number in the last-formed whorl but

sometimes reducing it to five; the rate of chamber volume
increase with chamber addition is approximately the same in
each form, so that (a) when the chamber number is reduced
(e.g., to five in the last whorl) the spiral side of the test remains
completely evolute and flat or slightly convex in shape, or (b)
when the final chamber number is not reduced (e.g., is retained
at about six in the last whorl) the final chambers overlap
slightly onto the spiral side, so that that side becomes
incompletely evolute and slightly concave in shape; wall is
microperforate, with perforation canaliculi about 1 pm in
diameter, opening into broadly and bluntly rounded perforation
pits about 10 pm in diameter (the perforation pits are deeper on
the earlier chambers which have had their walls thickened by
test growth); maximum diameter achieved is about 0.34 mm.”
(Banner, 1989:177.)

DISCUSSION. —Banner’s (1989) study clarified the taxo¬
nomic positon of the genus Globanomalina and the type
species ovalis. Banner correctly pointed out that as the number
of chambers increase from 5 to 6 in the ultimate whorl the test
becomes asymmetrically planispirally arranged. In addition,
the aperture, which is a fairly high arch, bordered by a
continuous, thin lip, migrates slightly onto the spiral side. The
test walls are perforate throughout, and, although Banner
described the wall as microperforate, we include G. ovalis in
the normal perforate category, which contrasts with microper¬
forate taxa (test walls with pore diameters 0.3-0.45 pm in
diameter) of the Guembelitridae. As Banner (1989) pointed out
in his study, Globigerina pseudoiota Homibrook (1958) should
be regarded as a junior synonym of G. ovalis. The form
illustrated by Blow (1979, pi. Ill: fig. 5) as an intermediate
between G. chapmani (Parr) and Pseudohastigerina wilcoxen¬
sis (Cushman and Ponton) is a smooth-walled, 6-chambered,
nearly planispiral form that has an extraumbilical aperture
extending slightly onto the dorsal side. We agree with Blow
that this morphology is transitional to Pseudohastigerina, but
that it is represented in the species G. ovalis.

Stable Isotopes.—N o data available.

Stratigraphic Range. —Upper Zone P4 to Zone P6.

Global Distribution.—N orthern and southern mid¬
latitudes.

Origin of Species. —This species is a member of the
inflated chamber, perforate walled lineage in Globanomalina.
Globanomalina ovalis evolved from G. imitata in the upper
part of Zone P4 by an increase in the number of chambers in the
ultimate whorl from 5 to 6, a greater degree of inflation of the
chambers, and the trend towards planispirality (see Plate 36:
Figures 13-15). Although Berggren et al., 1967, and Banner,

1989, stated that G. ovalis derived from G. chapmani, there is
a distinct difference in the wall texture between the two species
that would appear to preclude a phylogenetic linkage. In the
Pondicherry section of southeast India G. ovalis and G. imitata
overlap morphologically (Plates 36, 37).

Repository. —Geological Survey of Pakistan at Quetta,
Pakistan. Paratypes (P.42400) at The Natural History Museum,
London.

44

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Globanomalina planocompressa (Shutskaya, 1965)

Plate 36: figures 1-6

Globorotalia compressa (Plummer).—Loeblich and Tappan, 1957a: 188, pi. 40:
fig. 5a-c [paratypic by synonymy, type Danian, Ostratorp], pi. 41: fig. 5a-c
[Zone Plb, McBryde Fm., Alabama] [in part, not pi. 42: fig. 5a-c, pi. 44:
figs. 9, 10],

Globorotalia planocompressa planocompressa Shutskaya, 1965:179, pi. 1: fig.

6a-c [lower Paleocene, northern Caucasus],

Globorotalia ( Turborotalia ) compressa planocompressa Shutskaya.—Blow,
1979:1067, pi. 68: figs. 4, 8-10 [Zone Pla, DSDP Hole 47.2/11/3: 0-5 cm],
pi. 71: figs. 8-10 [Zone PI, DSDP Hole 47.2/1/1: 0-1 cm; Shatsky Rise,
northwestern Pacific Ocean],

Globanomalina planocompressa Shutskaya.—Olsson, Hemleben, Berggren,
and Liu, 1992:207, pi. 7: figs. 6-8 [Zone Pla, Clayton Basal Sands, Millers
Ferry, Alabama].

Original Description. —“Test with a subpolygonal lateral
outline, strongly compressed along the growth axis. Spire
consists of three whorls. Early whorls lie on one level with the
surface of the last whorl or rise up slightly above it. In each
whorl there are five to six inflated subspherical chambers,
rapidly and uniformly increasing in size and arranged freely.
Peripherally on the chambers a small papillate projection,
directed toward the subsequent chamber, is frequently ob¬
served. Last chamber asymmetrical, flattened at the apertural
face and slightly shifted toward the umbilical surface.
Equatorial outer margin scalloped. Axial outer margin weakly
asymmetric, broadly rounded. Sutures deep, straight. Umbili¬
cus narrow. Aperture a semicircular slit located between the
umbilicus and the outer margin. Sometimes it is surrounded by
a very narrow lip, the width of which is uniform over its whole
length. Wall smooth, finely perforate. Surface lustrous or
matte. Dimensions of holotype (fig. 5a-x): greatest diameter
0.45, least diameter 0.32, height 0.21 mm.” (Shutskaya,
1965:179; translated from Russian.)

Diagnostic Characters. —Ultimate whorl with 5 cham¬
bers increasing moderately in size. Chambers globular to ovoid
shaped, more inflated than G. archeocompressa. Pores average
1 pm at narrowest point, evenly distributed in chamber walls,
but some areas imperforate, especially on parts of wall
periphery. Wall thickness 4-7 pm.

Discussion. —Although the original types are presumably
lost, the meaning of this taxon seems clear from study of the
Russian collections, and Blow’s (1979) analysis of the species
is followed herein. He based his analysis on the specimen
figured by Loeblich and Tappan (1957a, pi. 40: fig. 5a-c),
which became a paratype of this species when Shutskaya
included this specimen in synonymy with her new species.
Globanomalina planocompressa is the first member of the
planocompressa-imitata-ovalis lineage, a lineage character¬
ized by inflated, perforate-walled chambers.

Stable Isotopes.— Globanomalina planocompressa has
5 18 0 and 5 I3 C similar to Parasubbotina pseudobulloides, S.
triloculinoides, and E. eobulloides. The species has distinctly
more positive 5 18 0 and more negative 5 13 C than Praemurica
and Woodringina.

Stratigraphic Range.—U pper Zone Pa to Zone Pic.

Global Distribution.—K nown distribution in the north¬
ern hemisphere middle and low latitudes.

Origin of Species. —This species originates in Zone Pa
from G. archeocompressa by the inflation of chambers and the
loss of an imperforate peripheral margin. It, in turn, gives rise
to G. imitata in Zone Pic.

Repository. —Holotype No. 3510/1, Moscow, GAN. Ex¬
amined by FR.

Globanomalina planoconica (Subbotina, 1953)

Plate 10: figures 15-17; Plate 34: figures 8-17

Globorotalia planoconica Subbotina, 1953:210, holotype: pi. 17: fig. 4a-c;

paratypes: pi. 17: figs. 5a-6c [zone of conical globorotaliids, lower to middle

Eocene (probably lower Eocene), ser. FI, Khieu River, Caucasus].

Original Description. —“Shell oval, planoconvex, with
flattened dorsal and convex ventral sides. Whorls, 2. The first
whorl is poorly distinguished because of its very small size.
The second whorl is obvious and consists of 5 or 6 chambers
which gradually increase in size. The last chamber is
considerably larger than the penultimate one. The peripheral
margin is scalloped, acute, and sometimes possesses a narrow
keel.

“On the dorsal side the chambers have a semicircular outline,
on the ventral side it is triangular. The umbilical ends of the
chambers are closely joined together so that there is an open
and deep umbilicus.

“The septal sutures are slightly curved and recessed. The
orifice is furnished with a slender and narrow lip. In some
specimens the orifice appears to extend along the whole of the
marginal suture from the umbilicus to the periperal margin and
may even extend on to the peripheral margin itself. The wall is
thin, smooth, transparent and perforated by fine pores.
Dimensions: 0.23-0.26 mm, thickness 0.06-0.08 mm.” (Sub¬
botina, 1953:210; translated from Russian.)

Diagnostic Characters. —Small highly compressed spe¬
cies with well-developed, thickened, imperforate peripheral
margin. Five to 6, occasionally 7, chambers in ultimate whorl.
Aperture a high umbilical-extraumbilical arch bordered by
thin continuous lip. Equatorial periphery rounded in early
portions of ultimate whorl, becoming more lobulate with final
few chambers.

Discussion. —The specimens identified as this species by
Tjalsma (1977) and Huber (1991b) from the South Atlantic and
southern Indian oceans, respectively, differ from the holotype
(Plate 10: Figures 15-17) by having only five chambers in the
ultimate whorl and by the more sharply curved sutures on the
spiral side. Tjalsma reported that transitional forms between
“ planoconica ” and G. australiformis occurred at DSDP Site
329 in the upper Paleocene and lower Eocene, suggesting that
the former species was derived from the latter. It would appear
that these “ planoconica ” morphotypes may be a different

NUMBER 85

45

species. This possibility needs further investigation. Blow
(1979) figured specimens from Zone P10 in a North Atlantic
piston core that he identified as G. planoconica. These
specimens have 7 to 8 chambers in the ultimate whorl and a
high arched aperture that extends slightly over the axial
periphery onto the spiral side. He considered these forms
ancestral to Pseudohastigerina danvillensis (Howe and Wal¬
lace, 1932). Except for the greater number of chambers, Blow’s
specimens are similar to G. planoconica in that they possess a
well-developed imperforate peripheral margin, but they differ
in the apertural lip, which widens as a tooth-like projection into
the umbilical area. It would appear that these morphotypes may
be related to G. planoconica. The morphologic range of this
species and its relationship to other species in the Eocene needs
further study.

Stable Isotopes.—-N o data available.

Stratigraphic Range.—U pper Zone P4 to lower Eocene.

Global Distribution. —As discussed above, the taxon¬
omy of this species needs further clarification before its
distribution can be reliably plotted. At present, a middle to low
latitude distribution is probable.

ORIGIN of Species. —The strong imperforate peripheral
margin allies this species with the chapmani lineage and
suggests that it was derived from this species in upper Zone P4.

REPOSITORY. —Holotype (No. 4081) and paratypes (No.
4082, 4083) deposited in the micropaleontological collections
at VNIGRI (378/118), St. Petersburg. Holotype examined by
FR.

Globanomalina pseudomenardii (Bolli, 1957)

Figure 18; Plate 14: figures 5-7; Plate 38: figures 1-16

Globorotalia membranacea (Ehrenberg).—Subbotina, 1953:205, pi. 16: fig.
13a-c [Paleocene, Tarkhankut Peninsula, Crimea] [in part, not pi. 16: figs.
7a-12c], [Not Planulina membranacea Ehrenberg, 1854.]

Globorotalia pseudomenardii Bolli, 1957a:77, holotype: pi. 20: figs. 14-16;
paratype: pi. 20: fig. 17 [ Globorotalia pseudomenardii Zone, Lizard Springs
Fm., Trinidad],—Loeblich and Tappan, 1957a: 193, pi. 47: fig. 4a-c [Zone
P4, Salt Mountain Limestone, Alabama], pi. 49: fig. 6a-c [lower Zone P4,
Homerstown Fm., New Jersey], pi. 54: figs. 10a-13c [Zone P4, Vincentown
Fm., New Jersey], pi. 59: fig. 3a-c [Zone P4, Aquia Fm., Maryland], pi. 60:
fig. 8a-c [Zone P4, Nanafalia Fm., Alabama], pi. 63: fig. la-c [Zone P4,
Velasco Fm., Mexico] [in part, not pi. 45: fig. 10a-c].—Bolli and Cita,
1960:26, pi. 33: fig. 2a-c [ Globorotalia pseudomenardii Zone, Pademo
d’Adda section, northern Italy],

Globorotalia ( Globorotalia ) pseudomenardii Bolli.—Hillebrandt, 1962:126,
pi. 12: figs. 5a-6b [upper Paleocene beds of Reichhall-Salzburg Basin,
Austria].—Blow, 1979:892, pi. 89: figs. 1-5 [Zone P4, DSDP Hole 21 A/3/5:
74-76 cm; Rio Grande Rise, South Atlantic Ocean], pi. 94: figs. 1-5 [Zone
P4, Lindi area, Tanzania], pi. 108: figs. 4-7 [Zone P4, DSDP Hole 20C/6/3:
76-78 cm; Brazil Basin, South Atlantic Ocean], pi. Ill: figs. 1-4, pi. 112:
figs. 2, 3, 9, 10 [Zone P4, Moogli Mudstones, Papua] [in part, not pi. 105:
figs. 3, 7-10].

Planorotalites pseudomenardii Bolli.—Nederbragt and Van Hinte, 1987:587,
pi. 1: figs. 1-16 [Zone P4, DSDP Site 605/46/4,46/6, 46/3, 52/2; New Jersey
margin, western North Atlantic Ocean].—Nocchi et al., 1991:269, pi. 1: figs.
7-9 [Zone P4, ODP Hole 698A/11R/CC; northeast Georgia Rise, South
Atlantic Ocean],

Original Description. —“Shape of test very low trochos-
piral, biconvex; equatorial periphery elongate, lobate, espe¬
cially so in large specimens; axial periphery angular with
distinct keel. Wall calcareous, perforate, surface smooth.
Chambers strongly compressed; about 15, arranged in 3
whorls, the 5 chambers of the last whorl increasing rapidly in
size. Sutures on spiral side strongly curved, especially so
between last chambers of large specimens, depressed; on
umbilical side radial, depressed. Umbilicus shallow, open.
Aperture a low arch with a lip; interiomarginal, extraumbili-
cal-umbilical. Largest diameter of holotype 0.34 mm., of
figured paratype 0.66 mm.” (Bolli, 1957a:77.)

Diagnostic Characters. —Distinct keel, sharply angled
axial periphery, spiroconvex test, and narrow umbilicus
distinguish species. Number of chambers in the ultimate whorl
consistently 5, but 6-chambered form rarely observed (Plate 38:
Figure 4).

DISCUSSION. —There is considerable variation in the shape
of the equatorial periphery, which varies from fairly smooth to
strongly lobulate, depending on the rate of size increase or
decrease of the final few chambers in the ultimate whorl.

STABLE Isotopes. — Globanomalina pseudomenardii has
5 I8 0 and 5 13 C similar to Parasubbotina varianta and S.
velascoensis. The species has distinctly more positive 5 ls O and
more negative S 13 C than Morozovella, Acarinina, and Igorina.

Stratigraphic Range. —Zone P4.

Global Distribution. —Widely reported in the low to
middle latitudes (Figure 18).

ORIGIN OF Species. —There is general agreement among
workers that G. pseudomenardii originated from G. ehrenbergi
(= G. haunsbergensis Gohrbandt) by an increase in the test size
and the development of a peripheral keel. The species becomes
extinct at the top of Zone P4.

Repository. —Holotype (USNM P5061) and paratype
(USNM P5062) deposited in the Cushman Collection, National
Museum of Natural History. Examined by BTH and RKO.

Family Truncorotaloididae Loeblich and Tappan, 1961

(by W.A. Berggren, Ch. Hemleben, R.D. Norris,
and R.K. Olsson)

Original Description. —“Primary aperture on the umbili¬
cal side, and secondary apertures on spiral side.” (Loeblich and
Tappan, 1961:309.)

Diagnostic Characters. —Test, a low to moderately
elevated trochospire, with or without peripheral keel; chambers
globular to conical shaped; wall cancellate to muricate, pustule
growth moderate to heavy, usually around umbilical area or
along a peripheral keel; aperture interiomarginal, umbilical-
extraumbilical, with or without lip, may have supplementary
apertures.

DISCUSSION. —This family tentatively includes Acarinina,
Igorina, Morozovella, and Praemurica. As discussed in
“Phylogeny,” there are two views among the working group

46

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

/ G. pseudotnenardii

180°W

135°W

90°W

45 °W

45°E

90°E

135°E

FIGURE 18.—Paleobiogeographic map showing distribution of Globanomalina pseudomenardii (Bolli) in Zone
P4.

members on the relationships between these genera (see Figure
5a,b). The use of this family appears appropriate, for the time
being, until these differences are resolved.

Genus Acarinina Subbotina, 1953

TYPE Species. — Acarinina acarinata Subbotina, 1953 (=
junior subjective synonym of Globigerina nitida Martin,
1943).

Original Description. —“Test always strongly inflated,
with chambers of the Globigerina type. Dorsal side slightly
flattened, strongly convex ventrally. There is always an
umbilicus; it may be small and barely discernible or large and
very distinct. Peripheral margin without a keel, most frequently
rounded. Chambers sometimes closely adjacent to one another,
but in many species the chambers are loosely arranged.
Aperture slitlike, along the marginal suture, often without a lip.
Wall coarsely spinose; on the ventral side, near the umbilicus,
the spines are longer than on the remainder of the test.”
(Subbotina, 1953:219; translated from Russian.)

Diagnostic Characters. —Test, a moderate to low tro-
chospire; chambers ovoid shaped, generally with 4-6 cham¬
bers in final whorl, occasionally 7 or more; wall moderately to
strongly muricate with moderate to strong pustule growth on

umbilical shoulders surrounding aperture; aperture interio-
marginal, umbilical-extraumbilical, with or without thin lip.

Discussion. —The genus Acarinina was erected by Subbot¬
ina (1953) to include Paleogene taxa exhibiting morphologic
features intermediate between Globigerina and Globorotalia ,
such as species with rounded chambers, spinose (muricate) test,
and an umbilical-extraumbilical aperture. Three groups were
originally distinguished:

1. Acarininids with angular chambers (e.g., A. crassa-

formis );

2. Acarininids with rounded chambers (e.g., A. acarinata)',

3. Intermediate acarininids (e.g., A. conicotruncata).

Subsequent authors have questioned the inherent morphologi¬
cal homogeneity of this group by considering Acarinina to be
a synonym for taxa as phylogenetically distinct as Turborotalia
and Globorotalia. As conceived herein, Acarinina is character¬
ized by rounded to subangular, unkeeled chambers that are
covered with coarse pustules (muricae), which become dense,
enlarged, and spike-like on the umbilical surface around the
aperture. The heavy growth of pustules form deep funnel-
shaped entrances to the pores and may also partially or
completely close the pores. In Paleocene forms, the aperture
has a very thin lip or none at all.

NUMBER 85

47

Acarinina coalingensis (Cushman and Hanna, 1927)

Plate 39: figures 1-16

Globigerina coalingensis Cushman and Hanna, 1927:205, pi. 14: fig. 4 [lower
Eocene, California],—Mallory, 1959:46, pi. 34: fig. 6 [lower Eocene,
California],

Globoquadrina primitiva Finlay, 1947:291, pi. 8: figs. 129-134.—Homibrook,
1953:437 [middle Eocene, New Zealand],—Jenkins, 1965:1124, fig. 9
[outline drawing of Finlay’s holotype],

Globigerina primitiva (Finlay).—Bronniman, 1952:11, pi. 1: figs. 10-12
[Soldado and Lizard Springs Fms., Trinidad],—Belli, 1957a:71, pi. 15: figs.
6-8 [Globorotalia rex Zone, Trinidad],

Acarinina triplex Subbotina, 1953:230, pi. 23: figs. 1-5 [holotype from
Globorotalia marginodentata Subzone of Globorotalia subbotinae Zone,
lower Eocene, Khieu River, Nal’chik, northern Caucasus].—Blow,
1979:963, pi. 97: figs. 8, 9 [Zone P5, Linde area, Tanzania],—Pearson et al.,
1993:125, pi. 1: figs. 11, 12 [Zone PI 1, middle Eocene, DSDP Hole 523,
South Atlantic Ocean],—Lu and Keller, 1995:102, pi. 2: figs. 4, 5 [Zone AP
6A, lowermost Eocene; ODP Hole 738C/9R/1: 15-17 cm; Kerguelen
Plateau, southern Indian Ocean].

Globigerina inaequispira Subbotina.—Loeblich and Tappan, 1957a: 181, pi.
61: fig. 3 [Zone P4, upper Paleocene, Nanafalia Fm., Alabama] [in part, not
pi. 49: fig. 2a-c, pi. 52: figs. la-2c, pi. 56: fig. 7a-c, pi. 62: fig. 2a-c], [Not
Subbotina, 1953.]

Globorotalia (Acarinina ) primitiva (Finlay).—Hillebrandt, 1962:141, pi. 14:
figs. 2, 4 [Zone G, lower Eocene, Austria].—Blow, 1979:949, pi. 143: figs.
6-9 [Zone P8, lower Eocene, DSDP Hole 20C/5/4: 77-79 cm; Brazil Basin,
South Atlantic Ocean], pi. 249: figs. 1-4 [lower Bortonian, middle Eocene,
New Zealand],

Pseudogloboquadrina primitiva (Finlay).—Jenkins, 1965:1124, fig. 9 [nos.

81-83 (holotype) and 84-86; Bortonian, middle Eocene, New Zealand].
Acarinina coalingensis (Cushman and Hanna).—Berggren, 1969b: 152, pi. 1:
figs. 27-29 [Zone NP 11/12, stratigraphically equivalent to Zone P6/7; lower
Eocene 3, Katharinenhof, Fehmam, northern Germany],—Huber, 199 lb:439,
pi. 3: fig. 2 [Zone AP6b/AP7, lower Eocene, ODP Hole 738C/6R: 247.83 msbf;
Kerguelen Plateau, southern Indian Ocean].—Berggren, 1992:563, pi. 2: fig. 3
[AcarininawilcoxensisZone,\ovjexEocene,OD?S\te 749C/10R/l:40-44cm;
Kerguelen Plateau, southern Indian Ocean],

Globorotalia ( Acarinina ) triplex (Subbotina).—Blow, 1979:963, pi. 97: figs. 8,
9 [Zone P5, Lindi area, Tanzania],

Acarinina primitiva (Finlay).—Stott and Kennett, 1990:559, pi. 6: figs. 11, 12
[Zone AP8, lower Eocene, ODP Hole 689B/21H/1: 110-114 cm; Maud
Rise, Weddell Sea, Southern Ocean].-—Huber, 1991 b:439, pi. 3: fig. 1 [Zone
AP10, middle Eocene, ODP Site 738B/15X: 126.70 msbf; Kerguelen
Plateau, southern Indian Ocean].—Berggren, 1992:563, pi. 2: figs. 4, 5 [Zone
P6-7, ODP Hole 748B/18H/3: 80-84 cm; Kerguelen Plateau, southern
Indian Ocean],—Lu and Keller, 1993:120, pi. 3: figs. 1,2 [Zone AP7, lower
Eocene, ODP Hole 738C/5R/2: 57-59 cm; Kerguelen Plateau, southern
Indian Ocean].—Pearson et al., 1993:125, pi. 1: fig. 19 [Zone P11, middle
Eocene, DSDP Hole 523, South Atlantic Ocean].

Original Description. —“Test subglobular, the last three
chambers making up nearly the whole periphery of the test,
early chambers largely concealed by the ornamentation which
is greatest over the early chambers; consisting of large
projection bosses with a spinose surface, the succeeding
chambers covered with a progressively decreasing ornamenta¬
tion, the last-formed chamber with only a few short slender
spines; aperture small, in the slightly open umbilicus of the
ventral side. Diameter 0.60 mm.” (Cushman and Hanna,
1927:205.)

Diagnostic Characters.—R obust test, 3-4 chambered
final whorl, compact, subquadrate {primitiva morphotype) to
subtriangular ( coalingensis morphotype), strongly and bluntly
muricate test; peripheral margin broadly rounded, less com¬
monly subangular in edge view; chambers arranged at distinct
right angles to each other and usually separated by deep,
incised sutures (particularly between preantepenultimate and
antepenultimate chambers) on umbilical side, and increase
rapidly in size; aperture interiomarginal, umbilical-
extraumbilical.

DISCUSSION. —There are two basic morphotypes that charac¬
terize this robust and strongly muricate species: a form with a
triangular-subquadrate appearance characterized by (predomi¬
nantly) globular chambers (typified by Globigerina coalingen¬
sis Cushman and Hanna, 1927, and its junior synonym
Acarinina triplex Subbotina, 1953), and a form with a
subquadrate to quadrate appearance characterized by straight
and circumumbilically pointed, smooth (nonmuricate) glo-
boquadrinid-like chambers (typified by Globoquadrina primi¬
tiva Finlay, 1947). These two morphotypes have been
synonymized by some workers (Berggren, 1977) and distin¬
guished by others (Pearson et al., 1993; Pearson, 1993). After
having considered these forms synonymous, Berggren (1977)
distinguished them at Kerguelen Plateau sites based on the
perception of their morphologic differences and different
stratigraphic ranges (Berggren, 1992). Our work described
herein suggests that the earlier interpretation may be more
correct. One of us (WAB) has examined topotypic material of
A. coalingensis (including the reillustrated holotype, Berggren,
1977, pi. 10), A. primitiva, and the holotype and topotypes of A.
triplex and now believes that these forms belong to a single
taxon that exibits a gradual replacement through time of the
coalingensis morphotype by the primitiva morphotype. Inas¬
much as consistent distinction between these two morphotypes
appears impossible, we believe it more appropriate to use a
single name for this “taxon” and suggest that authors provide
careful descriptions to denote the presence/development of one
morphotype relative to the other should this prove useful for
biostratigraphic purposes.

Stable Isotopes.—N o data available.

Stratigraphic Range. —Zone P4c to Zone P14; coalin¬
gensis morphotype dominant over interval of P5-P7/8.

Global Distribution. — Acarinina coalingensis has a
^cosmopolitan distribution from the tropics to the Southern
Ocean and from the open ocean into epicontinental seaways.

ORIGIN of Species. —We believe that Acarinina coalingen¬
sis has its closest affinities with (and is probably a direct
descendant of) A. nitida from which it differs primarily in its
larger and more strongly muricate test, reduced number of
chambers, and more pronounced involute coiling. It is also
possible thatzl. coalingensis originated from the A. subsphaer-
ica-A. mckannai group because these taxa are also character¬
ized by well-developed large muricae on the umbilical surface,

48

SMITHSONIAN CONTRIBUTIONS TO PALL j BIOLOGY

a feature that would have evolved twice if A. coalingensis
evolved independently from A. nitida.

REPOSITORY.— Museum of the California Academy of
Sciences, San Francisco (No. 2548).

Acarinina mckannai (White, 1928)

Figure 19; Plate 40: figures 1-16

Globigerina mckannai White, 1928:194, pi. 27: fig. 16a-c [Velasco Fm.,
Mexico].—Loeblich and Tappan, 1957a: 181, pi. 47: fig. 7a-c [Zone P4, Salt
Mountain Fm., Alabama], pi. 53: figs. la-2c [Zone P4, Vincentown Fm.,
New Jersey], pi. 57: fig. 8a-c [Zone P4, Aquia Fm., Virginia], pi. 62: figs.
5a-6c [Zone P4, Velasco Fm., Tamaulipas, Mexico], pi. 62: fig. 7a-c
[designated lectotype, Columbia University No. 19878, Velasco Fm.,
Mexico],

Globorotalia mckannai (White).—Bolli, 1957a:79, pi. 19: figs. 16-18
[Globorotalia pseudomenardii Zone, lower Lizard Springs Fm., Tri¬
nidad],—Bolli and Cita, 1960:383, pi. 33: fig. 6a-c [ Globorotalia
velascoensis Zone, Pademo d’Adda, northern Italy].

Globorotalia (Acarinina) mckannai (White).—Hillebrandt, 1962:140, pi. 14:
figs. 8a-10c [Zone F = Globorotalia velascoensis Zone, Reichenhall-
Salzburg Basin, Austro-German border],—Jenkins, 1971:82, pi. 3: figs.
89-93 [Waipawan Stage, Middle Waipara River section. New Zealand],
Acarinina mckannai (White).—Krasheninnikov and Hoskins, 1973:116, pi. 2:
figs. 6-8 [ Globorotalia velascoensis Zone, DSDP Site 199/8; Caroline
Abyssal Plain, eastern Equatorial Pacific Ocean],—Toumarkine and Luter-
bacher, 1985:116, text-fig. 18 [3a-c, reillustration of Bolli, 1957a, pi. 19:
figs. 16-18; 5a-c, reillustration of holotype from White, 1928; 6a-c,
specimen from northern Caucasus illustrated by Shutskaya, 1958] [in part,
not 4a-c, reillustration of holotype of Globogerina subsphaerica Sub-
botina].—Lu and Keller, 1993:118, pi. 2: figs. 14-16 [Zone AP4, upper
Paleocene, ODP Hole 738C/11R/CC; Kerguelen Plateau, southern Indian
Ocean],

Muricoglobigerina mckannai (White).—Belford, 1984:13, pi. 22: fig. 408
[upper Paleocene, WABAG Sheet area, Papua, New Guinea].—Stott and
Kennett, 1990:559, pi. 3: figs. 7, 8 [Zone AP6, ODP Hole 690B/17H/5:
36-40 cm; Maud Rise, Wedell Sea, Southern Ocean].

Acarinina praecursoria Morozova.—Huber, 1991 b:439, pi. 1: figs. 3-5 [Zone
AP5, ODP Hole 738C/16R: 332.15 mbsf; Kerguelen Plateau, southern
Indian Ocean], [Not Morozova, 1957.]

Original Description. —“Test rotaliform, dorsal side
slightly convex, ventral side very convex, umbilicate, periphery
rounded; chambers usually six in the last whorl, gradually
increasing in size, closely appressed; sutures distinct, deep, not
limbate; wall granular or subspinose, very finely perforate;
aperture an elongate opening extending from the umbilicus
about half way to the peripheral margin. Diameter of type
specimen, 0.4 mm; height, 0.3 mm.” (White, 1928:194.)

Diagnostic Characters. —Test large, 4 V 2-6 chambers in
final whorl, moderate to low spired, final chamber often
curving partly over umbilicus in high-spired variants; strongly
muricate on umbilical surface with deep, funnel-shaped
entrances to pores over the rest of test; chambers slowly
increasing in size in final whorl; peripheral margin rounded,
with chambers elongate parallel to coiling axis as well as
elongate in direction of coiling; sutures deep, straight, and
incised on umbilical surface, gently depressed on spiral side
and slightly curved; umbilicus deep and large; aperture
interiomarginal, umbilical-extraumbilical without a lip.

DISCUSSION. — Acarinina mckannai is one of the most
common and broadly distributed upper Paleocene acarininids
and is easily recognized by its large, globular, muricate test
with generally 5 to 6 chambers in the final whorl. This species
is closely allied with A. subsphaerica, and, indeed, complete
intergradation exists between them in spire height, umbilical
size, and the number of chambers in the final whorl. Shutskaya
(1958, 1970a) figured a large number of specimens as A.
subsphaerica, some of which are clearly referable to A.
mckannai due to their low spire height.

Stable Isotopes.— Acarinina mckannai has 5 18 0 slightly
more negative than coexisting morozovellids, such as M.
velascoensis, and shows no size related trends in 5 18 0
(Shackleton et al., 1985). The 5 13 C of A. mckannai is much
more positive than that of Subbotina and is similar to, or
slightly more negative than, that of Morozovella and Igorina
(Shackleton et ah, 1985).

Stratigraphic Range. —Zone P4a to lower Zone P4c.
GLOBAL Distribution. — Acarinina mckannai is a broadly
distributed species in the tropical to subtropical oceans.
Specimens have been reported from the high southern latitudes
(Huber, 1991b), although these are neither as coarsely muricate
nor as inflated as typical low-latitude representatives of the
species (Figure 19).

ORIGIN OF Species. — Acarinina mckannai evolved from A.
subsphaerica by a reduction in spire height and an increase in
whorl expansion rate. These taxa are the first acarininds to
acquire a coarsely pustulose (muricate) ornamentation on the
umbilical surface. Acarinina subsphaerica appears before A.
mckannai in our material and retains the slightly anguloconic
test shape of A. nitida, suggesting that A. subsphaerica is more
primitive than A. mckannai.

Repository. —Columbia University Paleontology Collec¬
tion (No. 19878); collection now at the American Museum of
Natural History, New York. Examined by WAB.

Acarinina nitida (Martin, 1943)

Plate 12: figures 1-3; Plate 41: figures 1-16

Globigerina nitida Martin, 1943:115, pi. 7: fig. la-c [Morozovella subbotinae
Zone, Lodo Fm., California].

Acarinina acarinata Subbotina, 1953:229, pi. 22: figs. 4, 5, 8, 10 [? figs. 6, 7,
9] [zone of compressed globorotaliids; Globorotalia crassata Subzone =
Zone P5 this paper, Khieu River section, Nal’chik, northern Caucasus].—
Shutskaya, 1970b: 118, 228, pi. 27: fig. 13a-c [ Acarinina acarinata Zone,
Tarkhankut Peninsula, Crimea],—Krasheninnikov and Hoskins, 1973:116,
pi. 1: figs. 1-3 [ Globorotalia velascoensis Zone, DSDP Site 199/8; Caroline
Abyssal Plain, western Pacific Ocean],

Globigerina stonei Weiss, 1955:18, pi. 5: figs. 16-18 [holotype; middle
Paleocene, Peru] [in part, not pi. 5: figs. 19-21],

Globorotalia whitei Weiss.—Bolli, 1957a:79, pi. 19: figs. 10-12 [ Globorotalia
pseudomenardii Zone, lower Lizard Springs Fm., Trinidad], [Not Weiss,
1955.]

Globigerina cf. G. soldadoensis Bronnimann.—Loeblich and Tappan,
1957a: 182, pi. 53: fig. 4a-c [Zone P4, Vincentown Fm., New Jersey]. [Not
Bronnimann, 1952.]

Globorotalia ( Acarinina ) acarinata acarinata (Subbotina)._Blow, 1979:904,

fig. 7 [Zone P5 of Blow, 1979 = Subzone P4c this paper; Tanzania],

NUMBER 85

49

90°E

135°E

FIGURE 19. — Paleobiogeographic map showing distribution of Acarinina mckannai (White) in Zones P4 and P5.

Original Description. —“Test subglobular, more convex
ventrally than dorsally; wall calcareous, finely perforate,
completely covered with numerous fine papillae giving a
granular appearance; periphery broadly rounded, slightly
lobulate; all chambers exposed on dorsal side, only last whorl
of five visible on ventral side; chambers inflated, increasing
rapidly in size as added, last chamber extending slightly
beyond previous ones, overhanging on ventral side to form a
depressed umbilical area; dorsal sutures more or less distinct,
nearly straight, slightly depressed; apertural face of last
chamber flat, aperture a narrow slit extending from umbilicus
about halfway along base of chamber toward periphery
bordered on outer edge by a slight lip. Maximum diameter 0.29
mm; minimum diameter 0.28 mm; maximum thickness 0.28
mm.” (Martin, 1943:115.)

Diagnostic Characters. —Compact, small, trochospiral,
subcircular to subquadrate test with 4 (rarely 5) rounded, tightly
packed, radially compressd and axially elongate chambers;
early whorls raised above surface of last whorl; surface
moderately muricate, particularly on umbilical side, with deep,
funnel-shaped entrances to pores.

Discussion. —This form is generally recognized to be a
senior synonym of Acarinina acarinata (Subbotina), type
species of the genus Acarinina (Stainforth et al., 1975;
Luterbacher, 1975b; Berggren, 1977, who compared the
holotype of nitida with topotypes of acarinata ; Toumarkine

and Luterbacher, 1985). It is one of the earliest acarininids
appearing together with A. subsphaerica at the base of Zone P4.
Acarinina nitida represents an intermediate stage between the
weakly muricate A. strabocella and the more strongly muricate
upper Paleocene acarininids. Subbotina (1953) considered that
acarinata ranged up to the base of her zone of conical
globorotaliids (= P6a/b boundary of this work). Our observa¬
tions agree more closely with Blow (1979), who indicated its
LAD occurs in his Zone P5 or possibly lower P6.

The holotype of Acarinina intermedia Subbotina, 1953
(Plate 12: Figures 4-6), is a poorly preserved specimen with a
missing ultimate chamber and an obscured umbilicus. The
general morphology of this specimen shows four chambers in
the ultimate whorl and heavily muricate umbilical shoulders
suggesting a linkage to nitida. Acarinina nitida has also been
previously identified under different names (see synonomy) by
Weiss (1955), Bolli (1957a), and Loeblich and Tappan (1957a).

Stable Isotopes. — Acarinina nitida has S 18 0 values
similar to co-existing morozovellids, such as M. velascoensis
and M. subbotinae, and shows a slight negative size-trend in
5 I8 0 (D’Hondt et al., 1994). The 8 13 C of A. nitida is much more
positive than that of Subbotina and is similar to that of
Morozovella (D’Hondt et al., 1994).

Stratigraphic Range. —Zone P4a to lower Zone P4c.

Global Distribution. —This form is geographically wide¬
spread in (sub)tropical regions and has been reported from high
southern latitudes on the Kerguelen Plateau (Huber, 1991b) and

50

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Maud Rise, Weddell Sea (Stott and Kennett, 1990) at 62° S and
65° S, respectively.

Origin OF Species. — Acarinina nitida is related to unkeeled
morozovellids with which the acarininids share a similar
ornamentation consisting of deep funnel-shaped entrances to
the pores, short, weakly developed muricae at the interpore
ridges, deeply incised sutures, and a tendency toward slightly
anguloconical chambers in the final whorl. Acarinina nitida is
derived from A. strabocella from which it differs in having only
four chambers in the final whorl, more involute coiling, and a
more coarsely muricate surface texture. Bolli (1957a) and Blow
(1979) suggested that Globorotalia whitei/A. acarinata, re¬
spectively, was the ancestor of A. wilcoxensis and we concur.

Repository. —Holotype (No. 7400) in Stanford University
Paleontological Type Collection. Paratypes deposited in the
National Museum of Natural History (USNM 559454); the
University of California, Berkeley (No. 35066); the American
Museum of Natural History (No. MT-1015); the California
Academy of Sciences, San Francisco (No. 7877); and the
Paleontological Research Institution, Ithaca, N.Y. Paratypes
examined by WAB.

Acarinina soldadoensis (Bronnimann, 1952)

Figure 20; Plate 15: figures 4, 7, 8; Plate 42: figures 1-16

Globigerina soldadoensis Bronnimann, 1952:7, 9, pi. 1: figs. 1-9 [Lizard
Springs Fm., Trinidad; type locality of Globigerina velascoensis Zone of
Bolli, 1957a:64 = Zone P5 this paper],—Bolli, 1957a:71, pi. 16: figs. 7-9
[? figs. 10-12] [ Globorotalia formosa Zone, upper Lizard Springs Fm.,
Trinidad]; 1957b: 162, pi. 35: fig. 9a-c [Globorotaliapalmerae Zone, Navet
Fm., Trinidad].

Acarinina clara Khalilov, 1956:250, pi. 5: fig. 4 [upper Paleocene, Akhcha-
kumia, northeastern Azerbaizhan],

Globorotalia ( Acarinina ) soldadoensis (Bronnimann).—Hillebrandt,
1962:142, pi. 14: figs. 5, 6 [Zone G = Zone P6 this paper; Reichenhall-
Salzburg Basin, Austro-German border],—Jenkins, 1971:73, pi. 4, figs.
94-98 [ Globigerina triloculinoides Zone, Waipawan Stage, Middle Waipara
River section, New Zealand],

Acarinina soldadoensis (Bronnimann).—Berggren, 1971 b:76, pi. 5: figs. 1-3
[Morozovella velascoensis Zone, DSDP Hole 20C/6/4: 5-7 cm; South
Atlantic Ocean].—Huber, 1991 b:439, pi. 2: fig. 16 [Zone AP6a, lower
Eocene, ODP Hole 738C/10R: 275.25 msbf; Kerguelen Plateau, southern
Indian Ocean],

Muricoglobigerina soldadoensis soldadoensis (Bronnimann).—Blow,
1979:1120, pi. 98: figs. 1-3 [sample FORM 1670, Zone P5 of Blow, 1979 =
Zone P4c this paper; Lindi area, Tanzania], pi. 107: figs. 1-5 [Zone P6 of
Blow, 1979; DSDP Hole 20C/6/3: 76-78 cm; South Atlantic Ocean], pi.
109: fig. 8 [Zone P6, DSDP Hole 47.2/8/4: 78-81 cm], pi. 110: fig. 1 [Zone
P6, DSDP Hole 47.2/8/4: 78-81 cm], pi. 124: figs. 1, 3, 5 [Zone P7, DSDP
Hole 47.2/8/3: 83-85 cm], pi. 131: figs. 1-3, 6 [Zone P8, DSDP Hole
47.2/8/2: 71-73 cm; Shatsky Rise, northwestern Pacific Ocean],—Stott and
Kennett, 1990:559, pi. 3: figs. 1, 4 [Zone AP5, ODP Hole 689B/22X/5:

110-114 cm; Maud Rise, Weddell Sea, Southern Ocean],

Original Description. —“The low trochoid test is com¬
posed of about two volutions. The four-chambered, occasion¬
ally five-chambered adult is lobulate in typical specimens. The
spiral side is centrally more or less elevated, the umbilical side
is convex. The umbilicus is large and deep showing the arcuate

apertures of the latter formed chambers. The subglobular
chambers increase gradually in size. They are rounded to
slightly flattened peripherally and distinctly elongate in the
direction of the axis of the test. At the umbilical side the
chambers tend to be somewhat pointed. The end chamber can
be smaller than the penultimate one or even rudimentary.
Except for the indistinct sutures of the early ontogenetic stage,
those of the spiral side are deep and curved in the direction of
coiling, or they are oblique giving the impression of an
overlapping arrangement of the chambers. The sutures of the
umbilical side are straight throughout. The large arcuate
apertures of the last formed chambers are provided with minute
liplike boarders. The wall are perforate and rather thick. The
surface is covered with irregularly distributed papillae which
are stronger and more prominent on the early chambers of the
adult whorl; they are absent or weakly developed near the
aperture of the end chamber. The species is predominantly
coiled sinistrally.” (Bronnimann, 1952:7.)

Diagnostic Characters. —Low trochoid, moderately ev-
olute test of 4-5 moderately to strongly muricate, rounded
chambers distinctly elongated in the axis of coiling; final
chamber often reduced in size; lobulate periphery; deep and
relatively wide umbilicus revealing (in some individuals)
earlier chambers and their arcuate foramina; sutures on spiral
side deep and curved and/or tangential in direction of coiling,
chambers often overlapping.

Discussion. —This taxon is characterized by a test com¬
posed of 4 to 5 chambers arranged in a relatively loose (lax)
coil, resulting in a relatively open and deep umbilicus and
moderate to strong lateral chamber compression (giving an
angulate appearance to the peripheral margin of some
chambers), which culminates in the descendant angulate
species angulosa. Acarinina clara Khalilov (1956) from the
upper Paleocene of Azerbaizhan exhibits the typical lobulate
test and elongated chamber morphology of A soldadoensis and
is herein regarded as a junior synonym of this species.

Stable Isotopes.—-N o data available.

Stratigraphic Range. —Zone P4c to Zone P9.

Global Distribution. —This species has a widespread
geographic distribution from equatorial to subantarctic regions
(Figure 20).

ORIGIN OF Species. — Acarinina soldadoensis is a sister
taxon to A. mckannai from which it differs in being somewhat
more evolute and in having more umbilically elongate
chambers.

Repository.— Holotype (USNM 370085) deposited in the
Cushman Collection, National Museum of Natural History.
Examined by WAB.

Acarinina strabocella (Loeblich and Tappan, 1957)

Figure 21; Plate 15: figures 1-3; Plate 43: figures 1-16

Globorotalia angulata (White) var. praepentacamerata Shutskaya, 1956:94,
95, pi. 3: fig. 3 [Acarinina praepentacamarata Zone, Elburgan Fm., Khieu
River section, northern Caucasus].

NUMBER 85

51

180°W

135°W

90°W

45°W

45°E

90“E

135°E

FIGURE 20. —Paleobiogeographic map showing distribution of Acarinina soldadoensis (Bronnimann) in Zones
P5 and P6.

Globorotalia strabocella Loeblich and Tappan, 1957a: 195, pi. 61: fig. 6a-c
[Nanafalia Fm., Alabama].

Globorotalia praepentacamerata Shutskaya.—Luterbacher, 1964:665, pi. 40:
fig. 45 [Acarinina tadjikistanensis djanensis Zone, Elburgan Fm., Khieu
River, northern Caucasus; topotype determined by Shutskaya],

Acarinina praepentacamerata (Shutskaya).—Shutskaya, 1970b: 118-120, pi.
21: figs. 8, 10 [Acarinina praepentacamerata Zone, Chaldzhin Fm., Malyi
Balkhan, western Turkmenia], pi. 22: fig. 2 [lower subzone of Acarinina
tadjikistanensis djanensis Zone, Lower Danatin Mbr., Malyi Balkhan Ridge,
western Turkmenia].—Stott and Kennett, 1990:558, pi. 4: figs. 9, 10 [Zone
A4, ODP Hole 689B/23X/1: 108-112 cm; Maud Rise, Weddell Sea,
Southern Ocean].—Huber, 1991 b:439, pi. 2: figs. 1,2 [Zone AP5, ODP Hole
738C/11R: 286.04 msbf; Kerguelen Plateau, southern Indian Ocean],
Globorotalia ( Acarinina ) strabocella Loeblich and Tappan.—Jenkins,
1971:84, pi. 4: figs. 102-104 [Globigerina triloculinoides Zone, lower
Waipawan Stage, New Zealand].

Acarinina praeangulata (Blow).—Huber, 1991a:439, pi. 1, figs. 6, 7 [Zone
AP4, ODP Hole 738C/16R: 332.15 mbsf; Kerguelen Plateau, southern
Indian Ocean], [Not Blow, 1979.]

Original Description. —“Test free, of medium size,
trochospiral, sides moderately convex, umbilical shoulder
rounded, umbilicus broad and open, periphery broadly
rounded, peripheral outline lobulate; chambers increasing
gradually in size as added, of greater breadth than height, 4 per
whorl in the early stages, increasing to 5 or 6 per whorl in the
adult, early whorls somewhat elevated above the level of the
final whorl, each successive chamber on the spiral side added
somewhat below the level of that preceding, resulting in an

imbricated appearance; sutures distinct, depressed, curved and
oblique on the spiral side, radial and nearly straight on the
umbilical side; wall calcareous, finely perforate, surface finely
spinose, especially on the umbilical side; aperture an interio-
marginal, extraumbilical-umbilical opening extending to the
periphery.

“Holotype is 0.33 mm in greatest diameter.” (Loeblich and
Tappan, 1957a: 195.)

Diagnostic Characters. —Five to 6 chambered, nearly
circular test with weakly lobulate outline; axial periphery
broadly rounded to subangular, chambers on umbilical side
moderately convex, early whorls on spiral side elevated above
later whorl(s); umbilicus usually broad and open exposing
earlier whorls; test weakly pustulose (muricate) over entire
surface, aperture an interiomarginal, umbilical-extraumbilical
slit.

DISCUSSION. —Shutskaya (1956; see also 1970a, 1970b)
described Globorotalia angulata var. praepentacamerata from
the lower Paleocene of the northern Caucasus and showed that
it had a wide distribution in the southwestern part of the former
Soviet Union. Luterbacher (1964:665) suggested that Globoro¬
talia strabocella Loeblich and Tappan may be a junior
synonym. We agree with this assessment particularly inasmuch
as comparison of our material with the holotype of G.
strabocella at the NMNH shows them to be morphologically

52

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

A. strabocella

180°w

135°W

90°W

45°W

45°E

90°E

135°E

FIGURE 21. —Paleobiogeographic map showing distribution of Acarinina strabocella (Loeblich and Tappan) in
Zone P3.

similar. In view of the fact that there is no original (type)
material remaining of Shutskaya’s taxon (nor of any other taxa
that she described, for that matter, with rare exception), we
prefer to use the name strabocella for this taxon because of the
fact that there is well-preserved type material at a readily
accessible museum (the NMNH in Washington), which aids in
stabilizing the nomenclature.

Shutskaya (1970b: 118, 120, fig. 13) showed that A.
praepentacamerata is restricted to the A. praepentacamerata
Zone and the lower subzone of the overlying A. tadjikistanensis
djanensis Zone in the southwestern part of the former Soviet
Union [= Zone P3 (middle part) to ? P4 [lower part)]. This is
similar to our observations. The forms referred to A. wilcoxen-
sis strabocella from Zones P6-P8b by Blow (1979:970, pis.
114, 129, 132, 251) are considered unrelated to strabocella ;
they differ in their more evolute coiling, flatter spiral coil, and
strongly muricate ornament. They represent a younger, more
advanced acarininid morphology than that seen in A. strab¬
ocella. In fact, we view A strabocella as representing the stem
form of the acarininid radiation that occurred at the P3-P4
zonal transition.

Stable Isotopes.—N o data available.

Stratigraphic Range. —Zone P3 (lower part) to Zone P4
(lower part).

Global Distribution. —Northern middle latitudes to the
Southern Ocean (Figure 21).

Origin of Species. —The origin of the first Acarinina
species is somewhat obscure. The wall surface of A. strabocella
is smooth with simple and coalescent pustules (Plate 5: Figure
1) that become more heavily developed on the older part of the
test. The origin of this species may be linked with the
moderately pustulose Morozovella praeangulata in the lower
part of Zone P3 and may have diverged from early forms of this
species. Alternatively, A. strabocella may have evolved from
Praemurica inconstans by developing a tighter coil and a lower
rate of chamber enlargement. In any case, A. strabocella
represents the stem form of the acarininid radiation. Reduction
of the number of chambers in the final whorl and the increased
development of muricae are seen in the derivation of A. nitida
from A strabocella.

Repository. —Holotype (USNM P5879) and paratypes
(USNM CC38526) deposited in the Cushman Collection,
National Museum of Natural History. Examined by WAB and
RDN.

Acarinina subsphaerica (Subbotina, 1947)

Figure 22; Plate 15: figures 9, 10; Plate 44: figures 1-16

Globigerina subsphaerica Subbotina, 1947:108, pi. 5: figs. 26-28 [holotype:

Globigerina ex gr. canariensis Zone, Assu River section, northern

Caucasus], pi. 5: figs. 23-25 [zone of compressed globorotaliids, Osetiya,

NUMBER 85

53

Assu River section, northern Caucasus]; 1953:59, pi. 2: fig. 15a-c [holotype
refigured].—Shutskaya, 1956:91, pi. 3: fig. 1 [holotype from Foraminiferal
Bed (FI), zone of compressed globorotaliids, Assu River section, northern
Caucasus, also recorded from equivalent levels in Assu River section,
Osetiya, northern Caucasus].

Globoconusa quadripartitaformis Khalilov, 1956:249, pi. 5: fig. 3a-c
[holotype No. 238, sample 35 (1946), foothills of Malyi Caucasus,
Azerbaizhan],

Globigerina chascanona Loeblich and Tappan, 1957a: 180, pi. 49: fig. 5a-c
[holotype, lower Zone P4, uppermost Homerstown Fm., New Jersey] [in
part, not pi. 49: fig. 4a-c, pi. 61: fig. 8a-c],

Globigerina spiralis Bolli.—Loeblich and Tappan, 1957a: 182, pi. 47: fig. 3a-c
[Zone P4, Salt Mountain Limestone, Alabama], pi. 49: fig. 3a-c [Zone P4,
Homerstown Fm., New Jersey], pi. 51: figs. 6a-9c [Zone P4, Vincentown
Fm., New Jersey], pi. 53: fig. 3a-c [Zone P4, Vincentown Fm., New Jersey],
[Not Bolli, 1957a.]

Acarinina subsphaerica (Subbotina).—Shutskaya, 1958:89, pi. 2: figs. 12-14,
pi. 3: figs. 1-3 [all figured specimens from Nal’chik Horizon, Sunzha River
section, Groznensk Oblast, northern Caucasus] [in part, not pi. 2: figs. 6-11,
pi. 3: figs. 4-21 = Acarinina mckannai]-, 1960:249, pi. 2: fig. 8;
1970b: 118—120, pi. 2: fig. 8a-c [Acarinina acarinata Zone, Kachan Stage,
Belbek River, Bakhchisaray Region, southwestern Crimea], pi. 6: fig. 3a-c
[Globorotalia aequa Zone, Bakhchisarayan Stage, Belbek River, Bakhchis¬
aray Region, southwestern Crimea], pi. 26: fig. 3a-c [Acarinina subsphaer¬
ica Zone, Nal’chik Region, Khieu River, northern Caucasus].

Acarinina falsospiralis Davidzon and Morozova, 1964:26, 28, pi. 1: fig. 5a-c
[upper Paleocene, upper Bukhara Beds, lower Karatag Horizon, Tutkaul
Village, Sanglak Range, Tadzhik Depression, Tadzhikistan],

Acarinina microsphaerica Morozova in Morozova, Kozhevnikova, and
Kuryleva, 1967:195, pi. 6: figs. 3, 4 [Thanetian Stage, upper Paleocene,
Kacha River, Crimea].

Globorotalia ( Acarinina ) subsphaerica (Subbotina).—Blow, 1979:960, pi. 91:
figs. 4-6 [Zone P4, DSDP Hole 21 A/3/6: 74-76 cm; South Atlantic Ocean],
pi. 92: figs. 1-3 [Zone P4, DSDP Hole 47.2/9/5: 74-76 cm; Shatsky Rise,
northwestern Pacific Ocean],

Muricoglobigerina chascanona (Loeblich and Tappan).—Blow, 1979:1126, pi.
91: figs. 1, 2 [lower Zone P4, DSDP Hole 21 A/3/6: 74-76 cm; South
Atlantic Ocean], pi. 92: fig. 3 [Zone P4, DSDP Hole 47.2/9/5: 70-72 cm], pi.
93: figs. 7-9, pi. 235: figs. 1-3 [Zone P4, DSDP Hole 47.2/9/3: 70-72 cm],
pi. 101: figs. 5, 6 [Zone P5, DSDP Hole 47.2/9/1: 64-66 cm; Shatsky Rise,
northwestern Pacific Ocean].

Acarinina chascanona (Loeblich and Tappan).—Huber, 1991 b:439, pi. 2: fig.
3 [Zone AP4, ODP Hole 738C/15R: 322.07 msbf; Kerguelen Plateau,
southern Indian Ocean] [in part, not pi. 2: fig. 4], [Not Loeblich and Tappan,
1957a.]

Original Description. —“Test small, nearly spherical;
viewed from the ventral side, it very often resembles a slightly
bursting chestnut. Test consists of three or three and one-half
whorls, of which the first two are disproportionately small as
compared with the final whorl. In the final whorl there are five
to six chambers gradually increasing in size. In the middle of
the ventral side there is a small umbilicus. The chambers are
trapezoidal on the dorsal side, and triangular on the ventral
side; they have a smooth outer surface and adhere closely to
one another. Septal sutures depressed, slightly curved in the
direction of coiling. Aperture semi-rounded, occupying ap¬
proximately one-third of the distance between the umbilicus
and the periphery. Wall reticulate, finely porous. Average
dimensions: greatest diameter 0.27 mm.; height 0.25 mm.”
(Subbotina, 1947:108; translated from Russian.)

Diagnostic Characters. —Characterized by strongly ele¬
vated spire and tightly coiled, small test giving species a

sphaerical, globular shape. Umbilicus narrow, deep, and
surrounded by coarse pustules (muricae). Usually with a
diminutive final chamber with an arched aperture.

DISCUSSION. —The strongly conical spire and small, tightly
coiled muricate test makes this one of the most distinctive taxa
of the middle Paleocene. Yet it remains one of the least
understood taxa among the acarininids. Although Subbotina
described subsphaerica as resembling “a slightly bursting
chestnut” (1947:108), she also indicated that the test is
“reticulate, finely porous,” but she made no mention of its most
distinctive character: its high conical spire. In fact, Subbotina
(1953:53) retained subsphaerica among her “polythalamous
species of Globigerina ” characterized by possessing five or
more closely packed chambers in the last whorl (together with
such taxa as edita Subbotina, compressa Plummer, pseudob-
ulloides Plummer, postcretacea Mjatliuk, and tarchanensis
Subbotina and Chutzieva). This oversight is difficult to
comprehend and may be partly ascribed to the poor state of
preservation (recrystallized tests) of most northern Caucasus
Paleocene material. It remained for Shutskaya (1958) to
provide the first adequate characterization of this taxon, to
clearly illustrate the high degree of variability in this taxon
(Shutskaya, 1958, 1970a), in particular, its distinctive high
spire, and to transfer it to its appropriate home in the genus
Acarinina. In fact, Morozova (1958, fig. 5), in a paper dealing
with the morphologic characters important in the classification
of Paleogene taxa of the Globigerinidea, observed that the
microspheric generation among “globigerinids” typically pos¬
sess a higher spire and more whorls of chambers than
megalospheric forms, and she cited Globigerina subsphaerica
Subbotina as a good illustration of this feature.

This taxon has been considered a junior synonym of
Acarinina mckannai (White) by some workers (Hillebrandt,
1962; Krasheninnikov and Ponikarov, 1965; Stainforth et al.,
1975; Berggren, 1977) because of their supposed similarity.
The latter is distinguished by its significantly larger test,
relatively low spire, and more evolute coiling pattern resulting
in a wide and open umbilicus. In our material, A. mckannai
stratigraphically appears somewhat higher/later than A. sub¬
sphaerica from which we suggest it is descended (cf. Stainforth
etal., 1975).

We note that moderately to high-spired morphotypes with
surficial morphology/omament comparable to A. subsphaerica
occur in upper lower to lower middle Eocene; these may
represent a continuation of the late Paleocene acarininid
radiation or an independent early Eocene radiation. This issue,
however, is beyond the scope of this study. Similar high-spired
acarinids, which we regard as synonymous with A. subsphaer¬
ica, have been described from middle Paleocene deposits in
Azerbaizhan, Tadzhikistan, and the Crimea. These include
Globoconusa quadripartitaformis Khalilov (1956), Acarinina
falsospiralis Davidzon and Morozova (1964), and Acarinina
microsphaerica Morozova (1967). Globigerina chascanona
Loeblich and Tappan (1957a) is a small, very high-spired
pustulose form, which we regard as an immature stage of A.

54

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

45°E

90°E

1 35°E

FIGURE 22. —Paleobiogeographic map showing distribution of Acarinina subsphaerica (Subbotina) in Zone P4a.

subsphaerica. Both Blow (1979) and Huber (1991b) noted
these small forms, which they placed in chascanona. Larger
(adult) forms of A. subsphaerica have been identified in middle
Paleocene coastal plain deposits from Alabama and New Jersey
by Loeblich and Tappan as Globigerina spiralis Bolli.

Stable Isotopes.—-N o data available.

Stratigraphic Range. —Subzone P4a. We have not found
A. subsphaerica associated with P3b faunas in any of our
material nor have we found it to occur above the middle part of
Zone P4 at low latitudes. Indeed, it is the short and distinct
stratigraphic range of this taxon that renders it so useful for
subdivision of Zone P4. We recognize high-spired acarininids
from the upper Paleocene at the high southern latitude ODP
Site 690. (This taxon was recently recorded by Lu and Keller
(1995) in younger stratigraphic levels at DSDP Site 577
(Shatsky Rise), northwestern Pacific Ocean and by Huber
(1991b) at ODP Site 738, southwestern Kerguelen Plateau
(southern Indian Ocean) near the Paleocene/Eocene boundary.)

Global Distribution.— This species appears global in
distribution in spite of an apparent bias to a Tethyan
distribution, which is probably related to numerous citations in
the Russian literature (Figure 22).

ORIGIN of Species. — Acarinina subsphaerica evolved from
A. nitida by an increase in spire height and the development of
a coarsely muricate umbilical surface, which is a feature
characteristic of all subsequent acarininids. Both A. sub¬

sphaerica and A. nitida share an anguloconic, umbilically
inflated test as juveniles and, in many of the geologically older
examples, a flat or gently domed spiral surface. Acarinina
subsphaerica gave rise to A. mckannai by an increase in whorl
expansion rate.

Repository. —Holotype in the collections of VNIGRI, St.
Petersburg, Russia.

Genus Morozovella McGowran in Luterbacher, 1964

TYPE Species. —Pulvinulina velascoensis Cushman, 1925.

Original Description. —“Test trochoid, coiling random to
strongly preferential; chambers becoming laterally com¬
pressed, then more or less conical, during ontogeny, developing
an angular margin and sometimes a strongly and irregularly
thickened marginal keel, umbilical shoulders may become
thickened; surface more or less roughened primilarly, espe¬
cially at margins; secondarily accentuated so that the test may
become coarsely spinose or nodular at margins and on
umbilical shoulders. Pores rather coarse and tending to funnel
outwards, especially secondarily. Test umbilicate; aperture
basal and umbilical, a low rimmed arch surrounded by a
poreless area. Paleogene.” (McGowran in Luterbacher,
1964:641.)

Diagnostic Characters.—S trongly anguloconical cham¬
bers throughout ontogeny. Surface texture strongly pustulose

NUMBER 85

55

(muricate) on parts of spire and umbilicus. Most species with
muricocarina.

DISCUSSION. —The morozovellids split into two lineages
early in their evolution: (1) the M. angulata-M. velascoensis
group characterized by the development of muricate adumbili-
cal ridges, a strong muricocarina, and the absence of muricae
on parts of the chamber surfaces; and (2) the M. apanthesma-
M. subbotinae group whose members are initially unkeeled and
entirely covered with fine, thin muricae.

Morozovella acuta (Toulmin, 1941)

Plate 45: figures 1-14

Globorotalia wilcoxensis Cushman and Ponton var. acuta Toulmin, 1941:608,
pi. 82: figs. 6-8 [Zone P4, Salt Mountain Limestone, Wilcox Group,
Alabama].—Cushman and Renz, 1942:12, pi. 3: fig. 2a-c [Zone P4, Soldado
Fm., Trinidad].—Cushman, 1944a:48,49, pi. 8: fig. 5a,b [Zone P3b, Naheola
Fm., Alabama]; 1944b: 15, pi. 2: fig. 16a,b [Zone P5, Bashi Fm., Wilcox
Group, Alabama],—Shifflett, 1948:73, pi. 4: fig. 23a-c [Zone P4, Aquia Fm.
Maryland].

Globorotalia velascoensis (Cushman) var. parva Rey, 1954:209, pi. 12: fig.
la,b [Zone P4, Sample TB 450, Well No. 11, Koudiat Bou-Khelif, near
Ouezzane, northern Morocco],

Globorotalia acuta Toulmin.—Loeblich and Tappan, 1957a: 185, pi. 47: fig.
5a-c [Zone P4, Salt Mountain Limestone, Wilcox Group, Alabama], pi. 55:
figs. 4a-5c [Zone P4, Vincentown Fm., New Jersey], pi. 58: fig. 5a-c [Zone
P4, Aquia Fm., Virginia],—Aubert, 1962:54, pi. 1: fig. 3a-c [Zone P4,
Koudiat Bou Khelif, Morocco].—Luterbacher, 1964:686-689, text-fig.
lOla-c [Zone P4, El Quss Abu Said, Farafrah Oasis, Egypt], text-figs.
102a-104c [Zone P5, Velasco Fm., Ebano, eastern Mexico].

Globorotalia velascoensis parva Rey.—Bolli and Cita, 1960:392-393, pi. 35:
fig. 5a-c [Zone P4, Pademo d’Adda, northern Italy].—Aubert, 1963:54, pi.
1: fig. 2a-c [Zone P4, N. Morocco],

Globorotalia velascoensis acuta (Toulmin).—Shutskaya, 1970a: 119-120, pi.
27: fig. lla-c [Acarinina acarinata Zone, Kachan Stage, Tarkhankut
Peninsula, Crimea], pi. 28: fig. 4a-c, pi. 29: fig. 9a-c [ Globorotalia aequa
Zone, Bakhchisarayan Stage, Tarkhankut Peninsula, Crimea],

Globorotalia ( Morozovella) acuta Toulmin.—Jenkins, 1971:106, pi. 9: figs.
205-207 [Globigerina triloculinoides Zone = Zone P4 this paper, Waipawan
D Stage, Middle Waipara River section, New Zealand].

Globorotalia (Morozovella) velascoensis parva Rey.—Jenkins, 1971:106, 107,
pi. 9: figs. 211-213 [ Globigerina triloculinoides Zone = Zone P4 this paper,
Waipawan Stage, Middle Waipara River section. New Zealand].—Blow,
1979:1030, 1031, pi. 95: figs. 3-6 [Zone P5, Sample FRCM 1670, Lindi
area, Tanzania],

Morozovella acuta (Toulmin).—Toumarkine and Luterbacher, 1985:111,
text-fig. 14 (7, reillustration of holotype; 8, reillustration of Loeblich and
Tappan, 1957a, pi. 55: fig. 4a-c, from the Vincentown Fm., New Jersey;
incorrectly ascribed to the Salt Mountain Fm., Alabama],

Original Description. —“Test trochiform, plano-convex,
dorsal side flat, ventral side strongly convex, deeply umbili-
cate, periphery strongly lobate, acute, and bounded by a thick
flange; chambers distinct, about 4’/2 in the last whorl,
increasing regularly in size as added; sutures distinct, on the
dorsal side slightly curved, limbate, slightly if at all depressed,
on the ventral side radiate, depressed; wall roughened with
minute, low spinose processes, especially along the peripheral
border; aperture an arched opening on the ventral side of the
final chamber extending from the peripheral flange to the

umbilicus. Length 0.46 mm.; width 0.37 mm.; thickness 0.24
mm.” (Toulmin, 1941:608).

Diagnostic Characters.—C onicotruncate, distinctly
muricocarinate test with (typically) 5 chambers in last whorl;
intercameral sutures radial, depressed on umbilical side and
strongly recurved and tangential, distinctly ornamented on, and
flush with, spiral side; periumbilical collar weakly to moder¬
ately well-ornamented with muricae; umbilicus (typically)
wide and open but narrow in more tightly coiled individuals;
aperture interiomarginal, umbilical-extraumbilical with (typi¬
cally) well-developed, triangular, circumumbilical “teeth.”

DISCUSSION. —Considerable controversy surrounds the char¬
acterization and recognition of this, and closely related, forms
of the velascoensis group. The “typical” M. acuta is generally
believed to be distinguishable from M. velascoensis in its
average smaller size, more rapid increase in chamber growth,
proportionately larger final chamber, more subdued periumbili¬
cal ornamentation, and reduced number of chambers in the final
whorl (Loeblich and Tappan, 1957a; Luterbacher, 1964; Blow,
1979). Other authors (Bolli, 1957a; Hillebrandt, 1962; Proto
Decima and Zorzi, 1965, among others) believe these (and
other) forms are linked by continuous gradations and consider
them synonymous.

At the same time, another commonly cited form is
Globorotalia velascoensis parva (auct. non) that we believe
shares a close morphologic relationship with M. acuta.
Whether the forms illustrated by various authors as parva are,
indeed, referable to Rey’s taxon is a moot point, however.
Luterbacher (1964) showed that the typical parva from the type
sample from Morocco has four large, nearly equal-sized
chambers in the final whorl, slightly raised and beaded sutures
on the spiral side, and a relatively narrow umbilicus lacking the
periumbilical ornament characteristic of the velascoensis-
acuta forms. We concur with his analysis that forms identified
as parva by Bolli and Cita (1960), Gartner and Hay (1962), and
Gohrbandt (1963) differ from the type-level specimens of
parva by possessing a heavy keel and a flat spiral side. The
individuals illustrated by Aubert (1962) as velascoensis parva
(pi. 1: fig. 2a-c) and acuta (pi. 1: fig. 3a-c), respectively, from
Koudiat Bou Khelif, Morocco, are virtually identical, and the
individual illustrated as acuta by Blow (1979, pi. 104: fig. 2) is
virtually indistinguishable from the one he figured on pi. 95:
fig. 6 as parva. We believe that the two morphotypes parva
(auct) and acuta are virtually indistinguishable in late Paleo-
cene assemblages.

STABLE Isotopes. — Morozovella acuta has 5 18 0 and 5 13 C
similar to other species of Morozovella (M. occlusa, M.
velascoensis ). Morozovella acuta has more positive 5 13 C and
more negative 8 18 0 than Subbotina spp. (Shackleton et al.,
1985).

Stratigraphic Range. —Zone P4b to Zone P5 (top).
Several authors suggest that M. acuta occurs somewhat higher
than M. velascoensis. We record its lowest occurence in Zone
P4b and have not found it to extend above M. velascoensis at

56

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

DSDP Site 213 (Indian Ocean). Shutskaya (1970a) gave the
range of M. acuta as extending from the A. acarinata Zone (=
Subzone P4b this paper) to the top of the G. aequa Zone (= top
of Zone P5 this paper), which is, essentially, the same as
observed herein.

Global Distribution.— Morozovella acuta is an essen¬
tially subtropical to tropical form with somewhat narrower
biogeographic distribution than velascoensis (see also Loeblich
and Tappan, 1957a).

ORIGIN of Species. —This species evolved from M. velasco¬
ensis through a reduction in umbilical size and ornament and
chamber number.

Repository. —Three paratypes (USNM CC38526) depos¬
ited in the Cushman Collection, National Museum of Natural
History. Examined by WAB and RDN.

Morozovella acutispira (Bolli and Cita, 1960)

Plate 46: figures 1-15

Globorotalia califomica Smith, 1957:190, pi. 28: figs. 22a-23c [homonym].

[Not Globorotalia califomica Cushman and Todd, 1946.]

Globorotalia acutispira Bolli and Cita, 1960:15, pi. 33: fig. 3a-c [Zone P4,
Pademo d’Adda, northern Italy],

Globorotalia kolchidica Morozova, 1961:17, pi. 2: fig. 2a-c [Zone Msl IV(?)
(Cibicides lectus Zone = Zone P3 this paper, upper part), Khokodz’ River
section, Crimea].

Globorotalia sp. aff. G. kolchidica Morozova.—Luterbacher, 1964:668,
text-figs. 61, 62 [ Globorotalia pusilla Zone, Gubbio section, central
Apennines, Italy].

Globorotalia sp. aff. G. acutispira Bolli and Cita.—Shutskaya, 1970b: 118—
120, pi. 25: fig. 7a-c [upper subzone of Acarinina tadjikistanensis djanensis
Zone, Olen Platform, boring 210, 517-527 m, Kachan Stage, Tarkhankut
Peninsula, Crimea].

Globorotalia ( Morozovella ) occlusa acutispira (Bolli and Cita).—Belford,
1984:9, pi. 17: figs. 14-21 [upper Paleocene, WABAG Sheet, Papua, New
Guinea].

Original Description. —“Test trochospirally coiled, the
dimensions medium for the genus, constituted of 11-12
regularly and rapidly increasing chambers, with 4 in number in
the last whorl. Chambers petaloid, bordered by a very large and
projecting banded keel; spiral suture arcuate and retroversed;
umbilical sutures depressed and radial; umbilical cavity very
small and tight. Aperture slender, interiomarginal, extraumbili-
cal-umbilical. Wall finely punctate. The peculiar characteristic
of this species, from which is derived the specific name we
intentionally selected, stems from the exceptional height of the
spire corresponding to the initial whorl; this confers a biconvex
profile to Globorotalia acutispira, characterized by a particu¬
larly sharp rise, quite angular, from the opposite side to that of
the ultimate chamber. The spire thus rises to occupy an
eccentric position with respect to the center of the fossil figure,
which causes the noticeable increase in height of the chambers
constituting the ultimate whorl.” (Bolli and Cita, 1960:15;
translated from Italian.)

Diagnostic Characters.—L enticular to subcircular,
plano-convex to biconvex test with apiculate early whorls and

lobulate outline, 4-6 chambers in last whorl; umbilical sutures
radial, slightly curved, depressed; spiral sutures curved, raised
and ornamented by the extension of the strongly muricate keel;
chambers tend to be flattened along the peripheral margin;
aperture a low, interiomarginal, umbilical-extraumbilical arch
extending from a narrow, deep umbilicus.

Discussion. —This species has been little used in the
literature on Paleocene morozovellids. The distinctive charac¬
ter of this form is the raised early part of the test containing the
neanic chambers; this feature can vary considerably among
individuals in a given sample. Our studies support the
diagnosis of Blow (1979) of a biconvex test with a very narrow
umbilicus linking it with M. occlusa. If Globorotalia califor-
nica Smith, 1957, is indeed a homonym of Globorotalia
califomica Cushman and Todd, 1946 (according to Blow,
1979), and a senior synonym of Globorotalia acutispira Bolli
and Cita, 1960, it should be renamed, although we can agree
(provisonally) with Blow that this may be unnecessary.

A closely related, if not identical, morphospecies is M.
kolchidica (Morozova). Morozova (1961) referred to the flat or
weakly convex central part of the spiral side of the test, which
we have confirmed by examinaton of the holotype (3510/12 in
the micropaleontological collections of GAN, Moscow).
Comparison with the refigured holotype of M. acutispira Bolli
and Cita (in Luterbacher, 1964, text-fig. 72a-c) reveals two
virtually identical forms. Blow’s (1979) interpretation of M.
kolchidica as a junior synonym of G. (M.) formosa gracilis
Bolli is considered anomalous and incorrect (although the two
forms are clearly homeomorphic in the same manner as are M.
velascoensis and M. caucasica). Morozovella kolchidica was
described from (and is characteristic of) Zone P3 (as well as
Zone P4); M. gracilis was described from (and is characteristic
of) Zone P6 (as well as Zone P7). Morozovella acutispira is
also homeomorphic with M. marginodentata (Subbotina), but
the latter bears a consistently more massive muricocarina and
lacks the apiculate early portion of the test (see also Berggren,
1977).

Illustrated on Plate 11: Figures 13-15 is a specimen from the
collections of Shutskaya (no. 645) in VNIGRI (St. Petersburg),
which is probably referable to M. acutispira. Although the slide
containing this specimen is labeled as Globorotalia angulata
var. kubanensis Shutskaya, the illustration of the holotype
resembles M. conicotruncata (Subbotina); however, because
the holotype in Moscow is lost, the identity of this taxon cannot
be determined. Further confusing the taxonomic status of
Shutskaya’s taxon is the other specimen from the same slide
(no. 645) illustrated on Plate 11: Figures 10-12. This specimen
is probably referable to M. apanthesma.

STABLE Isotopes. —The 5 13 C of Morozovella acutispira is
similar to that of coexisting morozovellids but is more positive
than that of Subbotina and Globanomalina. The 5 18 0 of M.
acutispira is lighter than that of Globanomalina and Subbotina
(Berggren and Norris, 1997).

NUMBER 85

57

Stratigraphic Range. —Near the Zone P3/P4 boundary to
the top of Zone P4b.

Global Distribution. —The geographic distribution of
this morphospecies appears characteristic of subtropical to
tropical regions as does that of occlusa.

ORIGIN OF Species.—T his morphospecies is closely related
to, and probably evolved from, M. pasionensis by an increase
in spire height, development of a biconvex test, a decrease in
the number of chambers in the final whorl, and a decrease in the
size of the umbilicus. Morozovella acutispira is closely related
to M. occlusa as herein described.

Repository. —Holotype (No. 1278) in the micropaleontol-
ogical collections of the Laboratory of Micropaleontology,
Institute of Paleontology, University of Milan.

Morozovella aequa (Cushman and Renz, 1942)

Plate 15: figures 11, 12, 15; Plate 47: figures 1-16

Globorotalia crassata (Cushman) var. aequa Cushman and Renz, 1942:12, pi.
3: fig. 3a-c [near base Globorotalia subbotinae Zone, Soldado Fm.,
Trinidad].

Globorotalia lacerti Cushman and Renz, 1946:47, pi. 8: figs. 11, 12 [lower
zone of Lizard Springs Fm., Ravine Ampelu, Lizard Springs area,
southeastern Trinidad],

Globorotalia ( Truncorotalia) crassata (Cushman) var. aequa Cushman and
Renz.—Cushman and Bermudez, 1949:37, pi. 7: figs. 7-9 [near San Ramon,
about 900 m SW of Carretera San Ramon, Pinar del Rio Province, Cuba;
Bermudez Sta. 536].

Globorotalia praenartanensis Shutskaya, 1956:98, pi. 3: fig. 5a-c [ Acarinina
acarinata Zone, Nal’chik Horizon, lower part of Abazin Formation, Kuban
River Basin, central pre-Caucasus].—Luterbacher, 1964:671, text-fig. 73a-c
[topotypes from Acarainina acarinata Zone, Kuban River section, northern
Caucasus].

Globorotalia aequa Cushman and Renz.—Bolli, 1957a:74, pi. 17: figs. 1-3, pi.
18: figs. 13-15 [ Globorotalia velascoensis Zone = Zone P5 this paper; upper
Lizard Springs Fm., Trinidad].—Loeblich and Tappan, 1957a: 186, pi. 59:
fig. 6a-c [Zone P4, Aquia Fm., Virginia], pi. 64: fig. 4a-c [Zone P4, Velasco
Fm., Tamaulipas, Mexico] [in part, not pi. 46: figs. 7a-8c (? = M. angulata),
pi. 50: fig. 6a-c, pi. 55: fig. 8a-c].—Bolli and Cita, 1960:377, 378, pi. 33:
fig. 5a-c [Zone P4, Pademo dAdda section, northern Italy].—Luterbacher,
1975b:64, pi. 2: figs. 22-24 [ Globorotalia subbotinae Zone], pi. 2: figs.
28-30 [ Globorotalia pseudomenardii Zone, Possagno section, Treviso
Province, northern Italy].

Globorotalia angulata (White).—Loeblich and Tappan, 1957a: 187, pi. 48: fig.
2a-c [Zone P4, Salt Mountain Limestone, Alabama], pi. 58: fig. 2a-c
[Aquia Formation, Virginia] [in part, not pi. 45: fig. 7a-c, pi. 50: fig. 4a-c,
pi. 55: figs. 2a-c, 6a-7c, pi. 64: fig. 5a-c]. [Not White, 1928.]

Globorotalia ( Truncorotalia ) aequa aequa (Cushman and Renz).—
Hillebrandt, 1962:133, 134, pi. 13: fig. la-c [Zone F = Zone P5 this paper,
Bad Reichenhall-Salzburg Basin, Austro-German border].

Globorotalia ( Morozovella ) aequa bullata Jenkins, 1965:1110, fig. 10, no.
87-91 [Globigerina triloculinoides Zone, lower Waipawan Stage, Middle
Waipara River section, New Zealand]; 1971:100, pi. 7: figs. 172-176
[reillustration of holotype and paratype specimens].

Globorotalia loeblichi El-Naggar, 1966:218-220, pi. 23: fig. la-c [Globiger¬
ina wilcoxensis Zone = Zone P6 this paper, sample S 68, Thebes Calcareous
Shale, Thebes Fm., Gebel Owaina section],

Truncorotaloides ( Morozovella ) aequus (Cushman and Renz).—McGowran,
1968:190, pi. 1: figs. 3-7 [Planorotalites simplex Zonule, Boongerooda
Greensand, Cape Range, Australia], figs. 8-12 [ Truncorotaloides (A.)
mckannai Zonule, Boongerooda Greensand, Cape Range, Australia],

Globorotalia (Morozovella ) aequa aequa Cushman and Renz.—Jenkins,
1971:100, pi. 7: figs. 167-169 [ Globigerina triloculinoides Zone, Middle
Waipara River section. New Zealand], figs. 170, 171 [ Globigerina
triloculinoides Zone, lower part of type Waipawan Stage, Te Uri Stream
section, New Zealand],—Blow, 1979:975-977, pi. 96: figs. 4-9, pi. 218:
figs. 1-6 [Zone P5 of Blow, 1979; Sample FCRM 1670, Lindi area,
Tanzania], pi. 99: fig. 5 [Zone P5 of Blow, 1979; DSDP Hole 47.2/9/1:
64-66 cm; Shatsky Rise, northwestern Pacific Ocean], pi. 102: figs. 6, 9, 10,
pi. 103: fig. 1, pi. 211: figs. 3-5 [Zone P6 of Blow, 1979; DSDP Hole
20C/6/3: 76-78 cm; Brazil Basin, South Atlantic Ocean], pi. 118: figs. 8-10,
pi. 211: figs. 1, 2 [Zone P7 of Blow, 1979; DSDP Hole 47.2/8/3: 83-85 cm;
Shatsky Rise, northwestern Pacific Ocean],

Morozovella aequa (Cushman and Renz).—Berggren, 197lb:76, pi. 5: fig. 6
[Morozovella velascoensis Zone = Zone P5 this paper, DSDP Hole 20C/6/4:
5-7 cm; Brazil Basin, South Atlantic Ocean],—Snyder and Waters,
1985:446, pi. 7: figs. 5-7 [Zone P4/5, DSDP Site 549/16/5: 57-60 cm;
Pendragon Escarpment, Goban Spur, northeastern Atlantic Ocean],—[not Lu
and Keller, 1995:102, pi. 1: fig. 15 (Zone P3, DSDP Site 577/11/3: 19-21
cm; Shatsky Rise, northwestern Pacific Ocean)].—[not Stott and Kennett,
1990:560, pi. 6: figs. 13-15 (Zone AP 6, ODP Hole 690B/16H/7: 36-40 cm;
Maud Rise, Weddell Sea, Southern Ocean (? = Acarinina wilcoxensis))].
Acarinina aequa (Cushman and Renz).—Tjalsma, 1977:508, pi. 3: fig. 13
[Morozovella velascoensis Zone, DSDP Site 329/32/4: 107-109 cm;
Maurice Ewing Bank, South Atlantic Ocean],

Globorotalia ( Morozovella) aequa lacerti (Cushman and Renz).—Blow,
1979:977-979, pi. 138: figs. 1-3 [Zone P8b of Blow, 1979 = Zone P7 this
paper; DSDP Hole 20C/5/5: 72-74 cm; Brazil Basin, South Atlantic Ocean],
pi. 115: fig. 6 [Zone P7 of Blow, 1979 = Zone P6b this paper; Sample RS 80,
Kilwa area, Tanzania, as ex interc G. (M.) aequa lacerti-G. (M.)
subbotinae ].

Globorotalia (Morozovella) aequa tholiformis Blow, 1979:979-981, pi. 102:
figs. 7, 8 [Zone P6 of Blow, 1979; DSDP Hole 20C/6/3: 76-78 cm; Brazil
Basin, South Atlantic Ocean], pi. 119: figs. 1, 2 [holotype], fig. 3 [Zone P7
of Blow, 1979; DSDP Hole 47.2/8/3: 82-85 cm], pi. 125: figs. 1, 2, pi. 127:
figs. 8, 9, pi. 129: fig. 6 [Zone P8a of Blow, 1979; DSDP Hole 47.2/8/2:
71-73 cm], pi. 133: fig. 9 [Zone P8b of Blow, 1979; DSDP Hole 47.2/8/1:
77-79 cm; Shatsky Rise, northwestern Pacific Ocean].

Original Description. —“Variety differing from the typi¬
cal in the much smoother surface, and the chambers especially
in the later ones, broader and more arcuate.

“Holotype of variety (Cushman Coll. No. 38210) from the
Midway Eocene, Soldado Formation, Soldado Rock, Trinidad,
B.W.I. Coll. Dr. H.G. Kugler (sample K. 2950).” (Cushman
and Renz, 1942:12.)

Diagnostic Characters. —Subquadrate, plano-convex,
muricocarinate test with moderately lobulate peripheral outline
and 4 (less commonly 5) chambers in last whorl; intercameral
sutures on umbilical side straight, radial; raised, curved on
spiral side; umbilicus narrow, bordered by low apertural slit
extending nearly to periphery; test surface generally covered
with muricae, particularly on umbilical shoulder and along
peripheral margin.

DISCUSSION. —This taxon has a complicated and intricate
taxonomic history due, in no small part, to the (minor)
morphologic variability (and resulting complex nomenclature)
ascribed to this species (see discussion by Blow, 1979:975—
982). Cushman and Renz (1942) described a subquadrate,
planoconvex, carinate morozovellid from the terminal Paleo-
cene of Trinidad, which has come to serve as the central type of

58

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

a plexus of late Paleocene to early Eocene forms generally
linked by the features listed in the diagnosis above; however,
we see little justification, or utility, in using these minor
morphologic differences in distinguishing the forms listed in
the synonymic list above.

Stable Isotopes. — Morozovella aequa has more positive
5 13 C and more negative 5 ls O than Subbotina and Globanomal-
ina and a similar isotopic signature to coexisting morozovel-
lids, such as M. velascoensis (Lu and Keller, 1996; Berggren
and Norris, 1997).

Stratigraphic Range. —Zone P4c to Zone P7.

Global Distribution. — Morozovella aequa is a geograph¬
ically widespread species, having been recorded from areas
circumscribed by latitudes 50°N (Goban Spur, northeastern
Atlantic Ocean; Snyder and Waters, 1985) and 50°S (Falkland
Plateau; Tjalsma, 1977); it occurs as far south as nearly 60°
(Kerguelen Plateau; Berggren, 1992) during the brief early
Eocene (Zone P6) temporal excursion of (sub)tropical mo-
rozovellids.

ORIGIN OF Species. — Morozovella aequa evolved from M.
apanthesma through concomitant reduction in the number of
chambers and the development of both more involute coiling
(resulting in a more closed umbilicus) and a peripheral
muricocarina. We have observed this transition both in our
material and particularly at DSDP Site 384, where it occurs at
the base of Zone P4c together with the appearance of various
acarininid taxa of the soldadoensis and primitiva/coalingensis
plexus in the younger part of Chron C25r. We have not found
this form in lower parts of the stratigraphic record (cf. Blow,
1979; Lu and Keller, 1995).

Repository. —Holotype (USNM CC38210) deposited in
the Cushman Collection, National Museum of Natural History.
Examined by WAB and RDN.

Morozovella angulata (White, 1928)

Figure 23; Plate 48: figures I-16

Globigerina angulata White, 1928:191, pi. 27: fig. 13 [Zone P4, Velasco Fm.,
Mexico].

Globorotalia angulata (White).—Glaessner, 1937b:383, pi. 4: figs. 35a-c;
? 36a-c (? = M. aequa), fig. 37a-c (A/, conicotruncala) [upper Paleocene,
Anapa section, Goryachi Kliutch Fm. and Il’sk, northwestern Caucasus;
lower part of Sumgait Group, southeastern Caucasus, lower Foraminiferal
Beds of Dagestan].—Bykova, 1953:82-86, text-figs. 7a— 11 c [“Montian
Stage,” western Turkmenia].—Shutskaya, 1956:92, 93, text-fig. 1, pi. 3: fig.
2a-c [Elburgan Fm., Khieu River section, central Caucasus],—Bolli,
1957a:74, pi. 17: figs. 7-9 [Globorotaliapusilla Zone, lower Lizard Springs
Fm., Trinidad].—Loeblich and Tappan, 1957a: 187, pi. 50: fig. 4a-c [Zone
P3b, Homerstown Fm., New Jersey, cf. Blow, 1979:985], pi. 64: fig. 5a-c
[Zone P4, Velasco Fm., Mexico, cf. Blow, 1979:986] [in part, not pi. 45: fig.
7a-c, pi. 48: fig. 2a-c (= M. aequa (Cushman and Renz)), pi. 55: figs. 2a-c,
6a-7c (probably transitional to M. apanthesma (Loeblich and Tappan)), pi.
58: fig. 2a-c (= M. aequa (Cushman and Renz))].—Bolli and Cita,
1960:376, 377, pi. 35: fig. 8a-c [Globorotaliapusilla Zone, Pademo d’Adda
section, northern Italy].—Olsson, 1960:44, pi. 8: figs. 14-16 [Zone P3b,
Homerstown Fm., New Jersey].—Toumarkine and Luterbacher, 1985:111,
text-fig. 14: 5a-c [holotype reillustrated], text-fig. 14: 6a-c [reillustration of

Bolli, 1957a, pi. 17: figs. 10-12 “transitional form between Globorotalia
uncinata Bolli, new species and Globorotalia angulata (White)”].
Globorotalia (Truncorotalia) angulata (White).—Hillebrandt, 1962:131, 132,
pi. 13: figs. 14a-15c [Zone D = G. pusilla Zone, Richenhall-Salzburg
Basin, Austro-German border],

Truncorotaloides ( Morozovella) angulatus (White).—McGowran, 1968:190,
pi. 1: figs. 13-18 [middle Paleocene, Boongerooda Greensand, Australia],
Globorotalia ( Morozovella) angulata (White).—Blow, 1979:984, pi. 86: figs.
7-9 [figs. 1, 8, given as G. (M) cf. angulata ], pi. 87: fig. 1 [Zone P3, DSDP
Hole 47.2/10/1: 72-74 cm; Shatsky Rise, northwestern Pacific Ocean],
Morozovella protocarina Corfield, 1989:98, pi. 1: figs. 1-12 [Zone P3, DSDP
Site 577/11/6: 30-31 cm; Shatsky Rise, northwestern Pacific Ocean],

Original Description. —“Test rotaliform, dorsal side flat,
ventral side convex, umbilicate, periphery sharply angled;
chambers few, usually four or five in the last whorl, inflated,
rapidly increasing in size; sutures distinct, curved, deep, not
limbate; wall granular or subspinose, very finely perforate;
aperture an elongate opening extending from the umbilicus
almost to the peripheral margin and sometimes provided with a
narrow lip. Diameter of type specimen, 0.35 mm.; height, 0.25
mm.” (White, 1928:191.)

Diagnostic Characters. —Muricate, nonspinose angulo-
conical test, spiral side flat, early chambers slightly elevated,
10-12 chambers arranged in 2 V 2 whorls, 4-6 chambers in final
whorl, periphery lobulate, (sub)acute, imperforate band (muric¬
ocarina) developed along peripheral margin; weak circumum-
bilical collar formed around narrow, deep umbilicus by
elevated chambers, particularly last chamber; sutures de¬
pressed, straight, radial on umbilical side, strongly recurved on
spiral side; aperture, low, interiomarginal, umbilical-
extraumbilical low arch with weakly developed lip.

DISCUSSION. —Blow (1979:984) drew a distinction between
peripherally muricocarinate ( angulata ) and (putatively ances¬
tral) non-carinate {praeangulata ) morphotypes of the early
angulata lineage. Following Blow (1979) in this distinction,
we maintain both morphotaxa in the genus Morozovella (contra
Pearson, 1993).

Considerable confusion and misidentification has sur¬
rounded this taxon, not the least because of the long (about 50
year) sequestration of the White collection at Columbia
University, which ended with its rediscovery by T. Saito and its
subsequent transfer to the American Museum of Natural
History in the early 1980s. We have followed Blow (1979) in
adopting the concept of angulata sensu Bolli (1957a) in
identifying this form. We regard Morozovella protocarina
Corfield (1989) as falling within this concept of M. angulata.
Our studies, however, support the range of M. angulata given
by Bolli (1957a) (Zone P3 to middle part of Zone P4) rather
than that of Blow (1979) (Zone P3 to basal Zone P5).

Stable Isotopes. — Morozovella angulata has more nega¬
tive 8 18 0 and more positive 5 13 C than Parasubbotina and
Subbotina (Douglas and Savin, 1978; Boersma and Premoli
Silva, 1983; Shackleton et al., 1985). The species displays a
distinct trend toward increased 8 13 C with increased test size and
little or no trend in 5 I8 0 with size (Shackleton et ah, 1985).

NUMBER 85

59

180°W

135°W

90°W

45°W

45°E

90°E

135°E

FIGURE 23. —Paleobiogeographic map showing distribution of Morozovella angulata (White) in Zones P3 and
P4.

Stratigraphic Range.— Zone P3 to lower Zone P4.
Global Distribution.— This form is essentially restricted
to (sub)tropical to temperate regions (circumscribed by 50°N
and S latitudes); it has not been reliably reported from high
northern or southern (subantarctic) regions (Figure 23).

ORIGIN OF SPECIES.— This species evolved from Morozov¬
ella praeangulata (Blow) at or near the Zone P2/3 transition by
elaboration of the muricae, development of a peripheral
muricocarina, and establishment of anguloconical chambers
throughout the last whorl.

Repository.— Columbia University Paleontology Collec¬
tion (No. 19876), collection now at the American Museum of
Natural History, New York.

Morozovella apanthesma (Loeblich and Tappan, 1957)

Plate 17: figures 1-3; Plate 49: figures 1-15

Globorotalia apanthesma Loeblich and Tappan 1957a: 187, pi. 48: fig. la-c
[Zone P4, Salt Mountain Limestone, Clarke Co., Alabama], pi. 55: fig. la-c
[Zone P4, Vincentown Fm., New Jersey], pi. 58: fig. 4a-c (paratype), pi. 59:
fig. la-c (holotype) [Zone P4, Aquia Fm., Virginia],

Globorotalia {Morozovella) apanthesma Loeblich and Tappan.—Jenkins,
1971:102, pi. 8: figs. 186-188 [Globigerina triloculinoides Zone, Waipawan
Stage, Middle Waipara River section, New Zealand].—Belford, 1984:9, pi.
16: figs. 1-8 [Zone P4, Papua, New Guinea].

? Globorotalia {Morozovella) apanthesma Loeblich and Tappan.—Blow,

1979:988, pi. 251: fig. 2 [Zone P7 of Blow, 1979 = Zone P6 this paper;
Sample HK 1831, type level of G. rex Zone, “Carmen Jones Ravine,”
tributary of Cascas River, southern Trinidad],

Acarinina apanthesma (Loeblich and Tappan).—Huber, 1991b:446, pi. 4: figs.
1, 2 [Zone AP4, ODP Hole 738C/16R: 332.15 mbsf; Kerguelen Plateau,
southern Indian Ocean].

Not Morozovella apenthesma [sic] Lu and Keller, 1995:102, pi. 1: figs. 18, 19
[Zone P3b/P4x of Lu and Keller; DSDP Site 577/11/2: 52-54 cm; Shatsky
Rise, northwestern Pacific Ocean].

Original Description.—“T est free, trochospiral, plano¬
convex, umbilicoconvex, with rather wide, deep and open
umbilicus, periphery subacute, peripheral outline lobulate;
chambers hemispherical, flattened to gently convex and
appearing lunate in side view from the spiral side, strongly
inflated to subangular on the umbilical side, 4 to 5 in the final
whorl, commonly somewhat obliquely overlapping earlier
chambers, the forward margin of each chamber protruding
slightly above the general level of the spiral side, the posterior
margin of the succeeding chamber beginning at a slightly lower
level; sutures distinct, strongly curved and slightly depressed
on the spiral side, radial and strongly depressed on the
umbilical side, wall calcareous, rather coarsely perforate,
surface spinose, most strongly on the umbilical side; aperture
interiomarginal, extraumbilical-umbilical, a broad arched
opening, with a narrow bordering lip present in well-preserved
specimens.

60

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

“Hypotypes range from 0.23 to 0.45 mm. in diameter and
from 0.15 to 0.33 mm. in thickness.” (Loeblich and Tappan,
1957a:187—188.)

Diagnostic Characters. —Planoconvex, umbilicocon-
vex, test with lobulate, weakly muricocarinate periphery; 4-5
chambers in last whorl, inflated to subangular on umbilical
side, moderately convex, triangular (lunate) in edge view;
intercameral sutures on umbilical side depressed, radially
curved and slightly depressed on spiral side; umbilical side
distinctly muricate, coarsely perforate on spiral side; umbilicus
relatively narrow, deep; aperture an interiomarginal, umbili-
cal-extraumbilical arch with narrow, continuous
intraperiumbilical lip.

DISCUSSION. —Blow (1979) drew attention to an important
distinction within this plexus: apanthesma exhibits the essen¬
tially quadrate chamber pattern of the related (and descendant)
aequa in the early whorls, whereas angulata (and related
forms) retains the more “vorticiform,” strongly recurved, early
whorl pattern. In view of these, and other pertinent observa¬
tions based on personal observations of type material (Blow,
1979), it is strange that he presented, almost as an afterthought,
only a single, spiral view of a form assigned to apanthesma
from (his) Zone P7 (= Zone P6 this paper) whose affinities are
somewhat hard to evaluate. Earlier this species was considered
a junior synonym of M. conicotruncata (Subbotina) by
Luterbacher (1964) and of M. angulata (White) by Berggren
(1977).

Illustrated on Plate 11: Figures 10-12 is a specimen from the
collections of Shutskaya (no. 645) in VNIGRI (St. Petersburg)
that is probably referable to M. apanthesma. Although the slide
containing this specimen is labeled as Globorotalia angulata
var. kubanensis Shutskaya, the illustration of the holotype
resembles M. conicotruncata (Subbotina). Because the holo¬
type in Moscow is lost, the identity of this taxon cannot be
determined. Further confusing the taxonomic status of Shut-
skaya’s taxon is the other specimen from the same slide (no.
645) illustrated on Plate 11: Figures 13-15. This specimen is
probably referable to M. acutispira.

Stable Isotopes. —Limited isotopic data suggest M.
apanthesma is similar in 5 I8 0 and 8 13 C to other morozovellids
and has a more positive 8 I3 C and more negative 5 I8 0 than
coexisiting Globanomalina and Subbotina (Lu and Keller,
1996; Berggren and Norris, 1997).

Stratigraphic Range. —Zone P3b to Zone P4c.

Global Distribution. —Northern middle latitudes to the
Southern Ocean.

Origin of Species. — Morozovella apanthesma and its
descendants, M. aequa and M. subbotinae, differ from the M
angulata-M. velascoensis group in possessing a relatively
even distribution of fine muricae (pustules) over the surface of
the test in contrast to the development of muricae-free surfaces
between the murcorcarina and adumbilical ridges in the M.
velascoensis plexus. Morozovella apanthesma shares charac¬

teristics intermediate between M. praeangulata (its antecedent)
and M. aequa (its descendant). The former is generally
somewhat smaller (contra Loeblich and Tappan, 1957a; see
also Jenkins, 1971), with more subdued muricate wall texture
and more strongly recurved chambers when seen from the
spiral surface. Compared to its ancestor, M. aequa exhibits a
reduced number of chambers and a more anguloconical test.

Repository. —Holotype (USNM P5860) and paratypes
(USNM P5868, P5861, P5862) deposited in the Cushman
Collection, National Museum of Natural History. Examined by
WAB, RDN, and RKO.

Morozovella conicotruncata (Subbotina, 1947)

Plate 11: figures 10-15; Plate 50: figures 1-15

Globorotalia conicotruncata Subbotina, 1947:115, pi. 4: figs. 11-13 [ho¬
lotype, zone of “Danian Foraminifera,” Assu River section, northern
Caucasus], pi. 9: figs. 9-11 [zone of “Danian Foraminifera,” Khieu River
section, Nal’chik, northern Caucasus].—Luterbacher, 1964:660, text-fig. 40
[zone of rotalid globorotaliids, Khieu River section, northern Caucasus],
text-figs. 41, 42 [as G. angulata abundocamerata'. topotypes from
Globorotalia pusilla pusilla Zone, lower Lizard Springs Fm., Trinidad],
text-figs. 46-49 [Globorotalia pseudomenardii Zone], text-fig. 51 [ Glo¬
borotalia pusilla pusilla Zone, Gubbio section, central Apennines, Italy];
1975a:726, pi. 1: figs. 6, 7 [ Globorotalia pusilla pusilla Zone, DSDP Site
305/14/CC; Shatsky Rise, northwestern Pacific Ocean].—Pujol, 1983:645,
pi. 2: fig. 8 [Zone P3 (mid-part), DSDP Hole 516F/87/4: 43-44 cm; Rio
Grande Rise, South Atlantic Ocean],

Acarinina conicotruncata (Subbotina).—Subbotina, 1953:220. pi. 20: fig. 5a,b
[zone of rotalid globorotaliids, Foraminiferal Beds, Suite FI (lower part),
Khieu River, Nal’chik, northern Caucasus], pi. 20: fig. 6a-c [holotype
reillustrated], pi. 20: fig. 7a-c [specimen reillustrated from Subbotina, 1947,
pi. 9: figs. 9-11, same sample as holotype], pi. 20: fig. 8a-c [same sample
as fig. 7a-c] [in part, not pi. 20: figs. 10a-12c].

Globorotalia angulata (White) var. kubanensis Shutskaya, 1956:93, pi. 3: fig.
4a-c [holotype No. 3525/19, GAN, Bed 6, Marl, Elburgan Fm., Kuban River
Section, northern Caucasus].

Globorotalia angulata abundocamerata Bolli, 1957a:74, pi. 17: figs. 4-6
[Globorotalia pusilla pusilla Zone, lower Lizard Springs Fm., Trinidad].—
Bolli and Cita, 1960:379, pi. 35: figs. 6a-c [Globorotalia pusilla pusilla
Zone, Pademo d'Adda section, northern Italy].

Globorotalia ( Truncorotalia ) angulata Hillebrandt, 1962:131, pi. 13: figs.
14a-15c [Zone D = correlative with upper part of Globorotalia pusilla
pusilla Zone, Reichenhall-Salzburg Basin, Austro-German border], [Not
White, 1928.]

Globorotalia kubanensis (Shutskaya).—Shutskaya, 1970b: 118-120, pi. 21:
fig. la-c [Acarinina praepentacamerata Zone, Malyi Balkhan Ridge,
Chaal’dzhin Group, western Turkmenia],

Morozovella conicotruncata (White).—Berggren, 1971 b:74, pi. 4: figs. 8, 9
[Zone P4, DSDP Hole 20C/6/5: 8-10 cm], figs. 10-14 [Zone P4, DSDP
Hole 20C/6/4: 100-102 cm; Brazil Basin, South Atlantic Ocean].—Snyder
and Waters, 1985:446, pi. 8: figs. 4, 5 [Zone P4/5, DSDP Site 549/16/4:
57-60 cm], fig. 6 [DSDP Site 549/16/5: 57-60 cm; northeast Atlantic
Ocean],

Globorotalia ( Morozovella ) angulata conicotruncata (White).—Blow,
1979:986, pi. 87: fig. 3 [Zone P3, DSDP Hole 47.2/10/1: 72-74 cm; Shatsky
Rise, northwestern Pacific Ocean],

ORIGINAL Description. —“Test a truncated cone. There are
two whorls. Dorsal side flat except in the slightly raised central
portion occupied by the first whorl; ventral side strongly

NUMBER 85

61

convex, sloping toward the dorsal side at an angle of about 50°
to 60°. Umbilicus open, deep, not very broad for Globorotalia.
Periphery broadly lobate, acute, not keeled. The final whorl
usually consists of five chambers which are alate on the dorsal
side and triangular on the ventral side. Each chamber of the first
whorl is approximately one-half the size of the corresponding
chamber of the second whorl. The chambers increase very
slowly in size within each whorl, so that each pair of adjacent
chambers seems to be equal. One of the characteristic features
is the uniform thickness (the dorsoventral elongation), due to
which their umbilical ends are almost in the same plane. The
chambers adhere closely to one another. Septal sutures on the
dorsal side simple, arcuately curved, depressed; on the ventral
side, they diverge radially from the umbilicus to the periphery,
in the form of straight, strongly depressed furrows. Spiral
sutures weakly lobate, nearly smooth, depressed, most often
indistinct. Aperture slitlike, very weakly curved to nearly
straight, extending from the umbilicus to approximately
half-way between the umbilicus and the periphery on the
ventral side. Wall densely covered with short and relatively
thick spines, usually larger on the ventral side than on the
dorsal side. Final chamber usually smoother. Spines most
distinct at the periphery.” (Subbotina, 1947:115; translated
from Russian.)

Diagnostic Characters. —Subcircular, moderately lobu-
late, low trochospiral test with 5-7 subangular, inflated,
essentially equidimensional chambers in last whorl, spiral side
flat to slightly convex in early whorls; umbilical sutures
straight to weakly curved, radial, incised; spiral sutures
distinctly curved, incised; axial periphery (sub)acute, periph¬
eral muricocarina variable, generally fused on early chambers
of last whorl whereas later chambers generally subrounded
(although muricocarinae fuse consistently along peripheral
margin on individuals of this form as it transforms into M.
velascoensis in Zone P3b); umbilicus narrow, deep; aperture a
low interiomarginal, umbilical-extraumbilical slit.

DISCUSSION. —This is a distinct middle Paleocene plano¬
convex morozovellid species characterized by 5-7 equidimen¬
sional chambers in the last whorl. Our studies support Blow’s
(1979) observation that this form appears virtually simultane¬
ously with typical angulata- types (cf. Bolli, 1957a); however,
we do not agree with the extended range given this taxon by
Blow (1979) of mid-Zone P3 through Zone P4, extending
possibly into Zone P5. Our studies support, rather, the range
given by Bolli (1957a) of its extension into the lower part of the
Globorotalia pseudomenardii Zone.

Stable Isotopes. — Morozovella conicotruncata has 5 13 C
similar to M. angulata and more positive than Subbotina and
Globanomalina (Boersma and Premoli Silva, 1983; Berggren
and Norris, 1997). The 5 18 0 of M. conicotruncata is slightly
lighter than M. angulata in samples from DSDP Site 384
(Berggren and Norris, 1997) and is distinctly lighter than
coexisting Globanomalina and Subbotina (Boersma and
Premoli Silva, 1983; Berggren and Norris, 1997).

Stratigraphic Range. —Zone P3 to lower Zone P4.
Global Distribution. —As with its closely related sister
taxon angulata, this form has a predominantly tropical to
temperate distribution (< 45° N and S) and has not been reliably
reported from high northern or southern (subantarctic) lati¬
tudes. It is a common and distinct form in our material and is
observed to grade into M. velascoensis in Subzone P3b.

Origin of Species. —This morphospecies evolved from
Morozovella angulata (White) in the lower part of Zone P3 by
the development of a distinctly planoconvex test, a more open
umbilicus than M. angulata, and a characteristic low rate of
chamber enlargement, which results in equidimensional cham¬
bers throughout the final whorl.

Repository. —Holotype (No. 3085) and paratypes (Nos.
2178, 4085, 4086, 4087, 4099) deposited in the micropaleon-
tological collections at VNIGRI, St. Petersburg, Russia.
Examined by WAB.

Morozovella gracilis (Bolli, 1957)

Plate 54: figures 13-15

Globorotalia formosa gracilis Bolli, 1957a:75, pi. 18: figs. 4-6 [ Globorotalia
rex Zone, Trinidad Leasholds, Ltd., well Guayaguayare 159, core 3,707-13',
upper Lizard Springs Fm., Trinidad],—Luterbacher, 1964:692, text-fig.
115a-c [topotypes, Globorotalia rex Zone, Trinidad], text-fig. 117a-c
[Globorotalia formosa formosa! Globorotalia subbotinae Zone, sample level
G-58, Gubbio section, central Apennines, Italy], text-fig. 105a-c [Globoro¬
talia velascoensis Zone, Ebano, eastern Mexico, as G. sp. aff. formosa
gracilis ], text-figs. 106a-107c [Globorotalia velascoensis Zone, sample
level G-74, Gubbio section, central Apennines, Italy].—Shutskaya,
1970b:l 18—120, pi. 14: fig. 8a-c [Globorotalia subbotinae Zone, Churuk-
Su, Kacha River section, Bakhchissaray region, Bakhchissarayan Stage,
southwestern Crimea],—Luterbacher, 1975a:727, pi. 2: fig. 7a-c [DSDP
Site 313/13/4: 71-73 cm; Mid-Pacific Mountains, North Pacific Ocean];
1975b:65, pi. 4: figs. 10-12 [Globorotalia subbotinae Zone, Possagno
section, Trevisiano Province, Italy].

Globorotalia bollii El-Naggar, 1966:202-203, pi. 22: fig. 6a-d [Globigerina
wilcoxensis Zone, Thebes Calcareous Shale, Gebel Aweina, Egypt] [in part,
not pi. 22: fig. 5a-d (holotype = M. subbotinae (Morozova))].

Globorotalia ( Morozovella ) gracilis Bolli.—Jenkins, 1971:105, pi. 9: figs.
202-204 [Globigerina wilcoxensis Zone, Middle Waipara River section,
Waipawan Stage, New Zealand],

Morozovella gracilis (Bolli).—Berggren, 1971b:76, pi. 5: figs. 7, 8 [Morozov¬
ella subbotinae Zone, DSDP Hole 20C/5/6: 100-102 cm; South Atlantic
Ocean],—Huber, 1991 b:440, pi. 4: fig. 8 [Zone AP6A, ODP Hole
738C/10R, 277.78 mbsf; Kerguelen Plateau, southern Indian Ocean].—Lu
and Keller, 1995:102, pi. 1: fig. 9 [Zone P6bx ofLuand Keller = Zone P6a
this paper; DSDP Site 577/9/6: 53-55 cm; Shatsky Rise, northwestern
Pacific Ocean],

Globorotalia (Morozovella) subbotinae gracilis Bolli.—Blow, 1979:1021-
1024, pi. Ill: figs. 9, 10, pi. 112: fig. 1 [Zone P7 of Blow, 1979; sample KRE
83F, Moogli Mudstone, Kagua Inlier, Kagua, Papua, New Guinea], pi. 115:
figs. 7-10, pi. 223: figs. 3, 4 [Zone P7 of Blow, 1979; sample RS 80, Kilwa
area, Tanzania], pi. 120: figs. 1-9, pi. 121: figs. 1-8 [Zone P7 of Blow,
1979; DSDP Hole 47.2/8/3: 83-85 cm; Shatsky Rise, northwestern Pacific
Ocean], ? pi. 249: figs. 8, 9 [Globorotalia pseudomenardii Zone, sample/
specimens collected by L.W. LeRoy as topotypic Discorbina simulatilis
Schwager, 1883, and presented to R. Wright Barker; Maqfi section, Farafrah
Oasis, Egypt],

62

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Morozovella formosa gracilis (Bolli).—Snyder and Waters, 1985:446-447, pi.

8: figs. 7-9 [Zone P7, DSDP Site 549/12/4: 47-50 cm; Pendragon

Escarpment, Goban Spur, northeastern Atlantic Ocean],—Toumarkine and

Luterbacher, 1985:12, text-fig. 15: 12a-c [reillustration of holotype of Bolli,

1957a],

Original Description. —“Shape of test very low trochos-
piral, spiral side almost flat or slightly convex, umbilical side
distinctly convex; equatorial periphery lobate; axial periphery
angular with a faint keel ornamented with spines. Wall
calcareous, perforate, surface distinctly spinose. Chambers
angular, inflated; about 12, arranged in 2 '/ 2 —3 whorls, the 5 or
6 chambers of the last whorl increasing rapidly in size. Sutures
on the dorsal side slightly curved to oblique, slightly depressed;
on umbilical side radial, distinctly depressed. Umbilicus fairly
narrow, deep, open. Aperture a low arch; interiomarginal,
extraumbilical-umbilical. Coiling between 90 and 100 percent
dextral. Largest diameter of holotype 0.50 mm.” (Bolli,
1957a:75.)

Diagnostic Characters. —Planoconvex to moderately
biconvex test, with lobulate peripheral margin ornamented with
well-developed muricocarina; 5-6 essentially equidimensional
chambers in last whorl; umbilical intercameral sutures radial,
straight, depressed; on spiral side, sutures strongly curved,
distinctly muricate except for penultimate/ultimate chamber
suture, which is straight giving cuneiform shape to final
chamber (not unlike the shape in Acarinina triplex)-, umbilical
surface covered with muricae, spiral side weakly muricate
except for concentration of muricae along intercameral sutures
and peripheral margin of ultimate whorl; small sutural
openings along margin/junction of ultimate/penultimate whorl
resulting from chamber addition along topographically sepa¬
rated/elevated muricate edges; umbilicus narrow, deep; aper¬
ture a low interiomarginal, umbilical-extraumbilical arch
extending towards, but not to, the peripheral margin.

DISCUSSION. — Morozovella gracilis occupies a morphol¬
ogic/phylogenetic position intermediate between M. subboti-
nae and M. formosa (see also Pearson, 1993). It differs from the
former in the increased number of chambers (5-6) in the final
whorl, which is associated with a looser (more evolute) coiling
mode, and in the elevated spiral intercameral sutures. Morozov¬
ella formosa is characterized by a further increase in size and
number of chambers (6-8) in the last whorl and concomitant
increase in the width of the umbilicus. Like most other
morozovellids, particularly those morphotypes closely associ¬
ated with the aequa-subbotinae-gracilis-marginodentata-
formosa plexus, it has a complicated taxonomic history, which
is discussed in Berggren (1977) and Blow (1979). Globorotalia
bolli El-Naggar (1966), it appears, includes morphotypes of
this plexas. We regard his pi. 22: fig. 6a-d as a morphotype of
M. gracilis, in contrast to the holotype (pi. 22: fig. 5a-d),
which is a morphotype of M. subbotinae.

Stable Isotopes.—-N o data available.

Stratigraphic Range. —Zone P5 to Zone P6b.

Global Distribution. —This is a geographically wide¬
spread morphospecies recorded from (predominantly)
(sub)tropical biogeographies. It occurs as far south as nearly
60° at ODP Sites 738 (Huber, 1991b) and 747 (Berggren, 1992)
on the Kerguelen Plateau, southern Indian Ocean, as part of the
earliest Eocene extra-tropical excursion of morozovellids.

ORIGIN of Species. —This species evolved from M. subboti¬
nae through a reduction in spire height and an increase in the
number of chambers.

Repository. —Holotype (USNM P5055) deposited in the
Cushman Collection, National Museum of Natural History.
Examined by WAB and RDN.

Morozovella occlusa (Loeblich and Tappan, 1957)

Plate 17: figures 4-6; Plate 51: figures 1-15

? Discorbina simulatilis Schwager, 1883:120, pi. 29: fig. 15a-d [? Zone P4,
Farafra Oasis, Egypt].

Globorotalia occlusa Loeblich and Tappan, 1957a: 191, pi. 55: fig. 3a-c [Zone
P4, Vincentown Fm., New Jersey], pi. 64: fig. 3a-c [holotype. Zone P4,
Velasco Shale, Tamaulipas, Mexico],—Luterbacher, 1964:690, text-figs.

112a— 113c [ Globorotalia velascoensis Zone, Velasco Fm., Ebano, eastern
Mexico], text-fig. 114a-c [ Globorotalia velacoensis Zone, Gubbio section,
central Apennines, Italy].

Globorotalia crosswicksensis Olsson, 1960:47, pi. 10: figs. 7-9 [Zone P3b,
Homerstown Fm., New Jersey].

Globorotalia ( Truncorotalia ) velascoensis occlusa Loeblich and Tappan.—
Hillebrandt, 1962:139, pi. 13: figs. 22, 24, 25 [Zone F = Zone P4/5 this
paper], pi. 13: figs. 23, 26 [Zone D = Globorotalia pusilla pusilla Zone
(upper part), Reichenhall-Salzburg Basin, Austro-German border].
Globorotalia (Morozovella) occlusa Loeblich and Tappan.—Jenkins,
1971:106, pi. 9: figs. 208-210 [Subbotina triloculinoides Zone, Waipawan
Stage, Middle Waipara River section, New Zealand],—Blow, 1979:1007, pi.
90: figs. 7, 10 [lower part of Zone P4, DSDP Hole 21 A/3/6: 74-76 cm; South
Atlantic Ocean], pi. 95: figs. 7-10, pi. 96: figs. 1-3 [Zone P5, sample
FCRM. 1670, Lindi area, Tanzania], pi. 213: fig. 6, pi. 214: figs. 1-6, pi.
215: figs. 5, 6, pi. 103: figs. 4-6, pi. 108: figs. 9, 10 [Zone P6, lower part,
DSDP Hole 20C/6/3: 76-78 cm; Brazil Basin, South Atlantic Ocean], pi.
118: figs. 1-7 [Zone P7, DSDP Hole 47.2/8/3: 83-85 cm; Shatsky Rise,
northwestern Pacific Ocean],—Belford, 1984:9, pi. 17: figs. 6-14 [upper
Paleocene, WABAG Sheet area, Papua, New Guinea],

Globorotalia ( Morozovella) occlusa cf. occlusa Loeblich and Tappan.—Blow,
1979:1007, pi. 92: figs. 5, 6 [Zone P4, DSDP Hole 47.2/8/3: 83-85 cm;
Shatsky Rise, northwestern Pacific Ocean].

Globorotalia (Morozovella) occlusa crosswickensis Olsson.—Blow,

1979:1011, pi. 88: figs. 1,2, pi. 213: figs. 1,2 [upper part of Zone P3, DSDP
Hole 47.2/10/1: 72-74 cm; Shatsky Rise, northwestern Pacific Ocean], pi.
90: figs. 3-6, 8, 9, pi. 213: figs. 3-5, pi. 215: figs. 1-4 [lower part of Zone
P4, DSDP Hole 21 A/3/6: 74-76 cm; South Atlantic Ocean],

Morozovella simulatilis (Schwager).—Snyder and Waters, 1985:470, pi. 9:
figs. 7-9 [Zone P4/5, DSDP Site 549/16/4: 57-60 cm; northeastern Atlantic
Ocean].

Original Description. —“Test free, of medium size,
trochospiral, spiral side flat, umbilical side convex with a very
small and deep umbilicus, periphery keeled, peripheral outline
entire to slightly lobulate; chambers gradually increasing in
size, 4 to 5, rarely 6, in the final whorl, of greatest thickness at
the umbilical shoulder immediately adjacent to the narrow
umbilicus, umbilical shoulder subacutely rounded; sutures

NUMBER 85

63

distinct, curved and oblique, thickened and flush to slightly
elevated on the spiral side; radial and moderately depressed on
the umbilical side; wall calcareous, finely perforate, surface
smooth except for the thickened sutures on the spiral side and
the peripheral keel which may be marginally nodose to hirsute,
umbilical side with a somewhat granular appearance, particu¬
larly in the early region of the final whorl; aperture an
interiomarginal, umbilical-extraumbilcal arch with a distinct
lip above.

“Greatest diameter of holotype 0.45 mm.” (Loeblich and
Tappan, 1957a: 191.)

Diagnostic Characters. —Plano-convex to low bicon¬
vex, nearly circular test, 4-6 (rarely up to 8) chambers in last
whorl, coalescing in a circular, subacute, weakly to moderately
muricate umbilical shoulder and forming a narrow, deep
umbilicus; umbilical sutures depressed, radial; elevated and
beaded, tangentially curved on spiral side; sutures between
final and penultimate whorl coarsely muricate; periphery
distinctly muricocarinate; aperture an interiomarginal, umbili-
cal-extraumbilical arch.

Discussion. —The enhanced, expanded concept of M.
occlusa applied by Hillebrandt (1962) to include biconvex
forms with 5-8 chambers is followed herein (see also
Gohrbandt, 1963; Luterbacher, 1964; Samanta, 1970). Blow
(1979) interpreted this form as a morphologically and
phylogenetically advanced (descendant) form of M. crosswick-
sensis Olsson, which was said to generally lack the circumum-
bilical muricate coronet present in M. occlusa. The former was
described from Zone P3b (Homerstown Fm., New Jersey); the
latter was described from the Velasco Fm. (Zone P4) and is
characteristic of Zones P4 and P5. We include crosswicksensis
in the concept of the taxon occlusa ; it bears a similar
relationship to that observed in the Acarinina coalingensisl
triplex (earlier rounded periphery )-primitiva (later angular
periphery) morphotypic series.

Stable Isotopes. — Morozovella occlusa has 5 13 C and 8 I8 0
similar to coexisting M. velascoensis and Acarinina mckannai
and more positive 8 13 C and more negative 5 18 0 than Subbotina
spp. (Shackleton et al., 1985; Lu and Keller, 1996).

Stratigraphic Range. —Top of Zone P3b (typical cross¬
wicksensis); Zone P4-P5 (typical occlusa).

Global Distribution. —This species is widespread in the
low to middle latitudes.

Origin of Species. —This species probably evolved from
M. pasionenesis by a decrease in umbilical size, development
of a biconvex test, and reduction of the muricate, sharp
adumbilical ridges to lightly muricate, gently rounded surfaces
around the umbilicus. Morozovella occlusa is a sister species to
M. acutispira, with which it shares the biconvex test shape and
relatively constricted umbilicus.

Repository. —Holotype (USNM P5874) and paratypes
(USNM P5866) deposited in the Cushman Collection, National
Museum of Natural History. Examined by WAB, RDN, and
RKO.

Morozovella pasionensis (Bermudez, 1961)

Plate 17: figures 7-9; Plate 52: figures 1-15

Pseudogloborotalia pasionensis Bermudez, 1961:1346, pi. 16: figs. 8a,b
[sample G-58, Rio de Pasion, El Peten, Guatemala],

Globorotalia pasionensis (Bermudez).—Luterbacher, 1964:690, text-fig.
108a-c [topotype, Rio de la Pasion, El Peten, Guatemala], text-figs.
109a-110c [Globorotalia aequa Zone, Gubbio section, central Apennines,
Italy], text-fig. 11 la—c [ Globorotalia velascoensis Zone, Velasco Fm.,
Ebano, eastern Mexico; as G. sp. aff. pasionensis]. —Samanta, 1970:629,
figs. 11, 12 [Zone P4/5, upper Marlstone unit, Pondicherry Formation,
India],

Globorotalia velascoensis caucasica Glaessner.—El-Naggar, 1966:242, pi. 19:
fig. 6a-c [ Globorotalia velascoensis Zone, Gebel Aweina, Egypt]. [Not
Glaessner, 1937a.]

Original Description. —“Test trochoid, planoconvex, dor¬
sal side plane or slightly convex and ventral side strongly
convex, peripheral border lobulate and keeled but not sharp;
chambers in two spiral whorls; all visible on the dorsal side and
on the ventral side only the six or seven of the last whorl which
gradually increase in size, sutures of the chambers depressed,
slightly oblique on the dorsal side and radial on the ventral side;
umbilicus large where one can see some of the chambers of the
primary portion of the test; wall thin, completely covered by
short spines; aperture as a narrow groove at the base of the
septal face of the last chamber. Diameter 0.50mm.; height 0.25
mm.” (Bermudez, 1961:1346; translated from Spanish.)

Diagnostic Characters: Relatively large, low umbilico-
convex test with flat spiral side, distinctly lobulate, heavily
keeled periphery; generally 5-7 (but up to 10, particularly in
younger, Zone P4c-P5 horizons) relatively equidimensional
chambers in final whorl, but with insertion of smaller chambers
between larger chambers in some individuals; intercameral
sutures depressed, radial on umbilical side; curved, moderately
retorse, raised and beaded on spiral side; umbilicus wide but
shallow, periumbilical collar only weakly developed; aperture
a low slit extending along peri-intraumbilical margin to
peripheral margin of last chamber.

DISCUSSION. —This highly variable taxon differs from the
closely related M. velascoensis in having a more loosely coiled,
less vaulted angulo-conical test and a widely varying number of
chambers. The chambers may be either essentially equidimen¬
sional, or there may be smaller, kummeform-like chambers
inserted in the normal chamber progression of the last whorl.
Morozovella pasionensis also has a relatively wider and
shallower umbilicus and a more weakly ornamented perium-
bilcial collar.

Basic analyses of this taxon were made by Luterbacher
(1964) and Blow (1979). The latter observed that the
“holotype” individual of Pseudogloborotalia pasionensis Ber¬
mudez at the National Museum of Natural History is coiled in
a direction (sinistral) opposite to that of the photograph
(dextral) of the “holotype” (Bermudez, 1961, pi. 16: fig. 8a,b);
however, it is the specimen (identified as Pseudogloborotalia
velascoensis (Cushman)) illustrated on pi. 16: fig. lla,b (and

64

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

not that illustrated as fig. 8a,b), which is the holotype of
pasionensis and which was examined by Blow and ourselves in
the Cushman Collection (USNM 639063). The holotype of P
pasionensis shows characters similar to P. velascoensis, which
indicate its close relationship with that taxon, but it has a low
conical test as opposed to the high conical test typical of P.
velascoensis. Luterbacher (1964) provided a revised and
amplified description of this species based on topotypes
supplied by Bermudez. The analyses of Blow and Luterbacher
are essentially compatible, with the exception that Luterbacher
(1964) recorded 5-7 chambers as typical of this form, whereas
Blow (1979) noted 9-10 (and occasionally up to 12) chambers
in the final whorl.

Stable Isotopes. — Morozovella pasionensis has 5 13 C and
8 18 0 similar to coexisting M. velascoensis and Acarinina
mckannai and more positive 8 13 C and more negative 5 18 0 than
Subbotina spp. (Shackleton et al., 1985; Lu and Keller, 1996).

Stratigraphic Range. —Zone P3b to Zone P5. Luter¬
bacher (1964) considered “ pasionensis ” restricted to the
Globorotalia aequa Zone (= Zone P6a this paper), whereas
Blow (1979) considered it restricted to (his) Zone P5 (i.e., prior
to the appearance of M. subbotinae) with questionable or
sporadic occurrences in (his) Zones P4 and P6. In our studies,
we have found that M. pasionensis appears slightly higher or
later than the initial appearance of M. velascoensis in Zone P3b,
and that it ranges throughout Zones P4 and P5. We have not
observed it ranging into post-M velascoensis (Zone P5) levels.
It was ancestral to M. acutispira and M. occlusa, which appear
in the terminal part of Zone P3b.

Global Distribution. —Our observations agree with those
of Blow (1979) that M. pasionensis had an essentially tropical
(but not necessarily solely equatorial Pacific Ocean) distribu¬
tion.

Origin of Species. —This species probably evolved from
M. velascoensis through a reduction in spire height, a decrease
in the ornament around the umbilicus, and an increase in the
number of chambers.

REPOSITORY.— Holotype (USNM 639063) deposited in the
Cushman Collection, National Museum of Natural History.
Examined by WAB, RDN, and BTH.

Morozovella praeangulata (Blow, 1979)

Plate 53: figures 1-13

Transitional form between Globorotalia uncinata Bolli and Globorotalia
angulata (White).—Bolli, 1957a:74, pi. 17: figs. 10-12 [Zone P3, lower
Lizard Springs Fm., Trinidad],

? Acarinina quadratoseptata Davidzon and Morozova, 1964:28, 30, pi. 2: fig.
la-c [holotype], figs. 2a-3c [Zone P2/3 equivalent, upper part of the
Chaaldzha Fm. (“transitional beds”), Kizilcheshme well,, Kyurendag,
Turkmenia] [in part, not text-fig. la-c (= Acarinina mckannai (White))].
Globorotalia (Acarinina) praeangulata Blow, 1979:942-944, pi. 82: figs. 5, 6
[Zone P2, Sample DB 176, type locality of Globorotalia uncinata Zone, near
Pointe a Pierre, southern Trinidad], pi. 83: fig. 6 [Zone P2, DSDP Hole
47.2/10/3: 18-20 cm], pi. 84: figs. 1, 7, pi. 212: figs. 1, 2 [holotype], fig. 8

[Zone P3, DSDP Hole 47.2/10/2: 80-82 cm; Shatsky Rise, northwestern

Pacific Ocean].

Original Description. —“The test is comprised of about
11-12 chambers coiled in a low, but comparatively lax,
trochospire with 5'/2 chambers visible in the last convolution of
the test. In dorsal aspect, the chambers are longer tangentially
than radially broad with the dorsal intercameral sutures
strongly recurved to vorticiform in the earlier parts of the last
convolution; the dorsal intercameral sutures are distinctly
incised and are not pseudolimbate but are weakly muricate (see
Plate 212: fig. 1). The equatorial profile is lobulate and the
peripheral margin does not bear a continuous muricocarina.
However, the peripheral margin is strongly muricate (cf. Plate
212 : figs. 1 and 2) but the muricae are not fused or coalesced
together. In axial-aperture profile, the test is piano-conic (cf.
paratype in Plate 84: fig. 8) with the dorsal side nearly flat and
the ventral side strongly vaulted; the peripheral margin is seen
to be subacute in this axial-apertural aspect. In ventral aspect,
the umbilicus is open and deep and the ventral intercameral
sutures are radially disposed and quite deeply incised. The
primary aperture opens from the umbilicus to about two-thirds
of the way towards the periphery. The wall is muricate with a
peripheral concentration of muricae. Maximum diameter of
holotype 0.32 mm.” (Blow, 1979:942.)

Diagnostic Characters. —Planoconvex, moderately lob¬
ulate test with 5-6 tangentially elongate chambers in last
whorl; umbilical sutures straight to weakly curved, depressed/
incised; spiral intercameral sutures incised, weakly muricate,
strongly recurved; peripheral margin strongly muricate but not
muricocarinate; umbilicus narrow, deep with aperture an
interiomarginal, umbilical-extraumbilical slit (bordered by a
distinct intraperiumbilical lip in well-preseved specimens)
extending nearly to the peripheral margin.

DISCUSSION.— Examination of the holotype (3514/6) and
several paratypes of Acarinina quadratoseptata Davidzon and
Morozova, 1964, in the micropaleontological collections of
GAN in Moscow suggests that this form may be a senior
synonym of M. praeangulata Blow. We retain the name
praeangulata in this work, however, for the reasons given
below. The holotype and one of the paratypes (3514/7) of
quadratoseptata are characterized by 5 chambers in the last
whorl and slightly (but distinctly) curved sutures sloping to a
rounded to subangular, lobulate, noncarinate periphery. In both
specimens, the early whorls are obscured, the tests are poorly
preserved (strongly recrystallized), and the last chamber for
each is missing. Paratype 3514/8 has a quadrate test and flat
early whorls, and the chambers of its last whorl slope toward a
distinctly subangular periphery. The test of this paratype is
homeomorphic with the Pliocene noncarinate Globorotalia
crassaformis. The remaining paratype (3514/9) is distinctly
different, as it comes from a different locality and stratigraphic
level, and it is referable to Acarinina mckannai. The drawing of
this specimen is misleading and gives the impression of a

NUMBER 85

65

morozovellid. A farther problem lies in the fact that the
specimens coil in the opposite direction to what is shown in the
illustrations. The negatives were apparently retouched and
printed backwards.

The Russian authors compared their new species with
Acarinina pentacamerata Morozova, 1961, and A. praecurso-
ria Morozova, 1961. Although believing that quadratoseptata
may indeed be a senior synonym of praeangulata by 15 years,
the fact that the type material of quadratoseptata is very poorly
preserved and has been virtually ignored in Soviet/Russian
literature (it was not mentioned by Shutskaya, 1970a, 1970b, in
her comprehensive review of Paleocene-lower Eocene plank¬
tonic foraminifera) leads us to retain the name praeangulata for
this morphospecies.

STABLE Isotopes. — Morozovella praeangulata has 5 13 C
and 8 I8 0 values similar to M. angulata and more positive 8 13 C
and more negative 8 ls O values than Subbotina spp. (Shackle-
ton et al., 1985).

Stratigraphic Range. —Zone P2 to Zone P3a.

Global Distribution. —The few localities where this
species has been identified suggests a low to middle latitude
distribution.

Origin of Species. —Bolli (1957a) proposed that Globoro-
talia (= Morozovella) angulata was derived from Globorotalia
(= Praemurica) uncinata. He illustrated a form (pi. 17: figs.
10-12) that he considered transitional between M. uncinata
and M. angulata. Blow (1979) accepted Bolli’s proposed
phylogeny and selected this specimen as a paratype to support
his documentation of M. praeangulata as the stem form of the
morozovellid lineage. The transition to M. praeangulata would
have involved the development of a more pronounced
conicotruncate test and concomitant change toward equidimen-
sional (as opposed to tangentially elongate) chambers, as well
as formation of a thicker (and ultimately) muricocarinate
peripheral margin. This has been the traditional view of the
origin of Morozovella. An alternate view, as noted in “Wall
Texture, Classification, and Phylogeny,” is that the wall texture
of M. praeangulata developed with pustule buildup on a
smooth “globorotaliid” surface in contrast to the praemuricate
wall texture of uncinata. In this view M. praeangulata
originated from a smooth-walled Globanomalina, such as G.
imitata, which has pustules covering the walls of early formed
anguloconical chambers (Plate 4: Figures 11-13, 16, Plate 36:
Figures 8-12). These chambers are similar to those observed in
the modem Globorotalia scitula (Plate 3: Figure 8), which was
a stem form for several globorotaliid lineages in the Neogene.
Thus, the initial step in the evolution of M. praeangulata would
have involved the suppression of the later stages of ontogeny
by speeding up the rate of maturation and the development of
a more pustulose, conicotruncate adult test. This change in the
timing of maturation would account for the small size of the
early forms of M. praeangulata.

Repository. —Holotype (BP Cat. No. 38/15) andparatypes
(BP Cat. Nos. 33/3, 33/9, 38/6, 38/14, 38/16, 41/54) deposited
in the micropalentological collections at The Natural History

Museum, London. Paratype (USNM P5074) deposited in the
Cushman Collection, National Museum of Natural History.
Paratype (USNM P5074) examined by WAB and RDN.

Morozovella subbotinae (Morozova, 1939)

Figure 24; Plate 54: figures 1-12

Globorotalia subbotinae Morozova, 1939:80, pi. 2: figs. 16, 17 [upper
Paleocene, base of section at cemetary at Asankozha, left bank of Emba
River, S part of Emba oil field, Kazakh S.S.R. (= Kazakhstan)].—Shutskaya,
1956:98, 99, pi. 4: fig. 4 [ Globorotalia subbotinae Zone, Cherkessk
Formation, Nal’chik, northern Caucasus] [in part, not pi. 4: fig. 3a,b; ? =
Acarinina wilcoxensis]. —Luterbacher, 1964:676, text-figs. 85a-86c, 89a-
90c [ Globorotalia aequa Zone, Gubbio section, central Apennines, Italy],
text-fig. 88a-c [ Globorotalia formosa formosa!Globorotalia subbotinae
Zone, Gubbio section, central Apennines, Italy],—Shutskaya, 1970a: 119, pi.
13: fig. 6a-c, pi. 14: fig. 6a-c [Globorotalia subbotinae Zone, Churuk-Su,
Kacha River section, Bakchissarayan Stage, Bakhchissaray area, southwest¬
ern Crimea], pi. 38: fig. 9a-c [Globorotalia subbotinae Zone, Malyi Balkhan
Ridge, middle Danian Fm., western Turkmenia].—Luterbacher, 1975a:732,
pi. 2: fig. 2a,b [Globorotalia formosa formosa Zone, DSDP Site 305/12/CC;
Shatsky Rise, northwestern Pacific Ocean]; 1975b:65, pi. 2: figs. 31-33
[Globorotalia subbotinae Zone, Possagno section, Trevisiano Province,
Italy],

Globorotalia rex Martin, 1943:117, pi. 8: fig. 2a-c [Zone P6, Lodo Fm., Lodo
Gulch, Fresno Co., California].—Bolli, 1957a:75, pi. 18: figs. 10-12
[Globorotalia rex Zone, upper Lizard Springs Fm., Trinidad].

Globorotalia ( Truncorotalia) aequa simulatilis (Schwager).—Hillebrandt,
1962:134, 135, pi. 13: figs. 6a-c, 7, 8a-c [Zone G, Reichenhall-Salzburg
Basin, Austro-German border]. [Not Schwager, 1883.]

Globorotalia bollii El-Naggar, 1966:202, pi. 22: fig. 5a-d [Globorotalia
wilcoxensis Zone, Thebes Calcareous Shale, Gebel Aweina, Egypt] [in part,
not pi. 22: fig. 6a-d (= M. gracilis (Bolli))].

Globorotalia nartanensis Shutskaya, 1970b: 118-120, pi. 15: figs. 2a-c, 8a-c
[Globorotalia subbotinae Zone, Churuk-Su, Kacha River section, Bakhchi-
ssarag region, Bakhchissarayan Stage, southwestern Crimea], [Not Globoro¬
talia nartanensis Shutskaya, 1956:96-98, pi. 54: fig. 2a-c (= M. lensiformis
Subbotina, 1953).]

Globorotalia {Morozovella) aequa rex Martin.—Jenkins, 1971:101, 102, pi. 7:
figs. 180-182 [Globigerina wilcoxensis Zone, Waipawan Stage, Middle
Waipara River section, New Zealand].

Morozovella subbotinae (Morozova).—Berggren, 1971 b:76, pi. 5: figs. 10, 11
[Globorotalia subbotinae Zone, DSDP Hole 20C/5/6: 100-102 cm; Brazil
Basin, South Atlantic Ocean],—Snyder and Waters, 1985:442, 443, pi. 9:
figs. 10-12 [DSDP Hole 548A/28/3: 70-74 cm; Goban Spur, northeastern
Atlantic Ocean].—Toumarkine and Luterbacher, 1985:112, text-fig. 15:9a-c
[reillustration of holotype of Globorotalia rex Martin, 1943], text-fig.
15:10a-c [reillustration of holotype of Globorotalia subbotinae Morozova,
1939], text-fig. 15:1 la-c [reillustration of specimen from northwestern
Crimea identified by Subbotina, 1953, pi. 17: fig. 13a-c as Globorotalia
crassata Cushman],—Huber, 1991b:440, pi. 4: fig. 9 [Zone AP6A, ODP
Hole 738C/10R: 277.78 mbsf; Kerguelen Plateau, southern Indian Ocean],—
Lu and Keller, 1993:123, pi. 4: fig. 19 [their Morozovella subbotinae
Subzone of Zone AP5A JPlanorotalites australiformis Zone of Stott and
Kennett, 1990; ODP Hole 738C/11/1R: 15-17 cm; Kerguelen Plateau,
southern Indian Ocean]; 1995:102, pi. 1: figs. 11-13 [their Subzone P6bx,
DSDP Site 577/9/6: 53-55 cm; Shatsky Rise, northwestern Pacific Ocean],

Globorotalia ( Morozovella ) subbotinae subbotinae (Morozova).—Blow,
1979:1018-1021, pi. 102: figs. 1-5, pi. 219: figs. 1-4 [Zone P6 of Blow,
1979; DSDP Hole 20C/6/3: 76-78 cm; Brazil Basin, South Atlantic Ocean],
pi. Ill: figs. 6-8 [Zone P7 of Blow, 1979, Sample KRE 83F, Moogli
Mudstones, Kagua, Papua, New Guinea], pi. 115: figs. 3-5 [Zone P7 of
Blow, 1979, Sample RS 80, Kilwa area, Tanzania; also pi. 115: fig. 6 as

66

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Globorotalia ( Morozovella) sp. specimen ex interc G. (M.) aequa lacerti
Cushman and Renz and G. (M) subbotinae subbotinae Morozova], pi. 119:
figs. 4-10, pi. 219: figs. 5, 6, pi. 220: figs. 1-6, pi. 222: figs. 1-7 [Zone P7
of Blow, 1979, DSDP Hole 47.2/8/3: 82-85 cm], pi. 127: figs. 6, 7 [Zone
P8a of Blow, 1979, DSDP Hole 47.2/8/2: 71-73 cm], pi. 123: fig. 8 [Zone
P8b of Blow, 1979, DSDP Hole 47.2/8/1: 77-79 cm; Shatsky Rise,
northwestern Pacific Ocean], pi. 103: figs. 2, 7, 9, pi. 223: figs. 1, 2 [Zone P6
of Blow, 1979, DSDP Hole 20C/6/3: 76-78 cm; Brazil Basin, South Atlantic
Ocean],

Original Description. —“Test lenticular, composed of
2—2'/2 spiral whorls. Peripheral margin acute, lobulate, with a
keel and fine, irregular denticulations. Dorsal side slightly
convex, ventral side conical, the side inclined at an angle of
25-30° to the dorsal side. Umbilicus narrow but deep. In the
last whorl, there are 4-5 chambers rapidly increasing in size.
Sutures deep near the umbilicus, becoming shallower toward
the periphery. Wall thin, spinose. Aperture in the form of a
narrow slit, extending from the umbilicus to the peripheral
margin.

“Dimensions.—Diameter, 0.36 mm; thickness, 0.20 mm.”
(Morozova, 1939:80; translated from Russian.)

Diagnostic Characters. —Relatively large (to 0.5 mm
maximum diameter), planoconvex to weakly biconvex test
with moderately lobulate, strongly/thickly keeled periphery;
4-472 chambers in last whorl, generally covered with muricae
on umbilical side, spiral side relatively smooth; umbilical and
spiral intercameral sutures weakly curved, tangential on spiral
side yielding trapezoidal-shaped chambers; circumumbilical
chamber tips weakly ornamented by muricae and surrounding
deep, narrowly open umbilicus; aperture a low, umbilical-
extraumbilical slit extending almost to periphery and bordered
by weak lip.

DISCUSSION. —This robust species is a characteristic element
of latest Paleocene and early Eocene planktonic assemblages.
Morozovella subbotinae has had a convoluted taxonomic
history. It is generally agreed by specialists that Globorotalia
subbotinae Morozova, 1939, is a senior synonym of Globoro¬
talia rex Martin, 1943 (see Berggren, 1977; Blow, 1979, for
discussions). In the (former) Soviet Union this taxon was
identified with (the middle Eocene) Globorotalia crassata,
Cushman, 1925 (nomen non conservandum, fide Blow, 1979 =
Morozovella spinulosa (Cushman, 1927b)) (see Subbotina,
1947, 1953).

Blow (1979) drew attention to the close similarities between
M. subbotinae (Morozova), M. marginodentata (Subbotina),
and M. gracilis (Bolli). In fact, he separated M. gracilis from M.
subbotinae at the subspecies level based on the increase in
chamber number (from 472 in subbotinae to 572-6 in gracilis ),
which is associated with the development of a somewhat more
evolute coiling mode and more vorticiform spiral intercameral
sutures in M. gracilis, and on the slightly different (shorter)
stratigraphic range of M. gracilis. The development of a
strongly dentate (fimbriate) muricocarina ( marginodentata ) on
some morphotypes was regarded as an ecophenotypic variation
within the subbotinae plexus of morphotypes. He considered

this indicative of high productivity, and M. marginodentata
was, accordingly, identified only as a variant of M. subbotinae
(cf. Berggren, 1971b, who had suggested earlier that M.
marginodentata might be synonymous, an ecophenotypic
variant of M. gracilis).

STABLE Isotopes. — Morozovella subbotinae has 8 I3 C and
5 I8 0 similar to M. velascoensis and Acarinina nitida and has
more positive 8 13 C and more negative 5 ls O than Subbotina
triangularis (D’Hondt et al., 1994). Morozovella subbotinae
displays a pronounced increase in 5 13 C with increased test size
but little corresponding change in 5 18 0 (D’Hondt et al., 1994).
Stratigraphic Range. —Zone P5 to Zone P6b.

Global Distribution. — Morozovella subbotinae is a geo¬
graphically widespread morphospecies. It is recorded in
(sub)tropical assemblages in Atlantic, Indo-Pacific, and typical
Tethyan biogeographies and as far south as 60° in association
with the early Eocene (Zone P6) extra-tropical excursion of
carinate morozovellids on the Kerguelen Plateau (Huber,
1991b, ODP Site 738; Berggren, 1992, ODP Site 747) (Figure
24).

Origin of Species. — Morozovella subbotinae evolved from
M. aequa through the enhanced development of peripheral
muricocarina, a heightened anguloconical umbilical side, and
an increase in test size.

Repository. —Holotype (Slide No. 700) deposited in the
micropaleontological collections at VNIGRI, St. Petersburg,
Russia.

Morozovella velascoensis (Cushman, 1925)

Figure 25; Plate 17: figures 10-12; Plate 55: figures 1-15

Pulvinulina velascoensis Cushman, 1925:19, pi. 3: fig. 5a-c [Velasco Fm., San
Luis Potosi, Tampico Embayment, eastern Mexico].

Globorotalia velascoensis (Cushman).—White, 1928:281, pi. 38: fig. 2a-c
[Velasco Shale Fm., eastern Mexico].—Cushman and Renz, 1946:47, pi. 8:
figs. 13, 14 [lower Lizard Springs Fm., Trinidad],—Subbotina, 1947:123, pi.
7: figs. 9-11 [Globortalia velascoensis Zone, Sunzha River section, northern
Caucasus], pi. 9: figs. 21-23 [Globorotalia velascoensis Zone, Kuban River
section, northern Caucasus].—Le Roy, 1953:33, pi. 3: figs. 1-3 [Maqfi
section, Egypt].—Haque, 1956:181, pi. 24: fig. 2a-c [upper Paleocene,
Nammal Gorge, Salt Range, Pakistan],—Bolli, 1957a:76, pi. 20: figs. 1-4
[Globorotalia pseudomenardii Zone, lower Lizard Springs Fm., Tri¬
nidad],—Loeblich and Tappan, 1957a: 196, pi. 64: figs. la-2c [Zone P4,
Velasco Fm., Tamaulipas, Mexico].—Bolli and Cita, 1960:391, pi. 35: fig.
7a-c [Globorotalia pseudomenardii Zone, Pademo d’Adda section, northern
Italy],—Said and Kerdany, 1961:330, pi. 1: fig. lOa-c [lower Esna Shale
Fm., Western Desert, Egypt].—Shufskaya, 1970b: 118-120, pi. 23: fig.
3a-c, pi. 24: fig. 5a-c [Acarinina tadjikistanensis djanensis Subzone,
Kachan Stage, Tarkhankut Peninsula, Crimea, Olenev Platform, Boring 210,
517-527 m], pi. 25: fig. 5a-c [same zone as above, but from boring 229,
637-641 m], pi. 27: fig. 12a-c [Acarnina acarinata Zone, Kachan Stage,
Tarkhankut Peninsula, Crimea], pi. 29: fig. 8a-c [Globorotalia aequa Zone,
Bakhchissarayan Stage, Tarkhankut Peninsula, Crimea],—Luterbacher,
1975a:726, pi. 1: fig. 8a,b [Globorotalia pseudomenardii Zone, DSDP Site
305/14/1: 135-138 cm; Shatsky Rise, northwestern Pacific Ocean],—Pujol,
1983:644, pi. 3: fig. 9 [Zone P5, DSDP Hole 516F/84/5: 13-15 cm; Rio
Grande Rise, southwestern Atlantic Ocean].

NUMBER 85

67

180°W

135°W

90°W

45°W

45°E

90°E

135°E

FIGURE 24. —Paleobiogeographic map showing distribution of Morozovella subbotinae (Morozova) in Zones P5
and P6.

Pseudogloborotalia velascoensis (Cushman).—Bermudez, 1961:1349, pi. 16:

fig. 1 la,b [Velasco Station, Tampico-San Luis Potosi Railway, Mexico],
Globorotalia (Truncorotalia) velascoensis velascoensis (Cushman).—
Hillebrandt, 1962:169, pi. 13: figs. 16-21 [Zone D = Globorotalia pusilla
pusilla Zone (upper part), Reichenhall-Salzburg Basin, Austro-German
border].

Truncorotaloides (Morozovella) velascoensis (Cushman).—McGowran,
1968:190, pi. 2: fig. 1 [Velasco Fm., Ebano, Mexico],

Globorotalia ( Morozovella) velascoensis velascoensis (Cushman).—Jenkins,
1971:107, pi. 9: figs. 214-216 [Globigerina triloculinoides Zone, Waipawan
Stage, Middle Waipara River section, New Zealand].—Blow, 1979:1029, pi.
92: fig. 7 [Zone P4, DSDP Hole 47.2/9/3: 70-72 cm; Shatsky Rise,
northwestern Pacific Ocean], pi. 94: figs. 6-9, pi. 95: figs. 1, 2, pi. 216: figs.
1-8, pi. 217: figs. 1-6 [Zone P5, Samples FCRM. 1670, Lindi area,
Tanzania], pi. 99: figs. 3, 4 [Zone P5, DSDP Hole 47.2/9/1: 64-66 cm;
Shatsky Rise, northwestern Pacific Ocean].—Belford, 1984:10, pi. 1: fig. 2,
pi. 19: figs. 1-12 [upper Paleocene, Wabag Sheet area, Papua, New Guinea].
Morozovella velascoensis (Cushman).—Toumarkine and Luterbacher,
1985:109, text-figs. 11, 12 [fig. 11: reillustration of Bolli, 1957a, pi. 20: figs.
1-3; fig. 12: reillustration of holotype from Cushman, 1925, pi. 3, fig. 5a-c],

Original Description. —“Test plano-convex, the dorsal
side flat or even slightly concave, ventral side very much
produced, periphery carinate, subacute, the series of which
surround a depressed umbilical area; about seven chambers in
the last-formed coil; sutures distinct, on the dorsal side curved,
marked by a series of small, bead-like processes, the periphery
of each with a slightly raised carina which marks also the line
of coiling in the central portion, ventral side with the sutures

nearly radiate, straight, much depressed, surface roughened
with very minute, low spinose processes which rather
uniformly cover the entire test; aperture elongate, narrow, on
the ventral side [of] the last-formed chamber extending from
near the periphery almost to the umbilical area.” (Cushman,
1925:19.)

Diagnostic Characters. —Relatively large (maximum
diameter >0.5 mm), robust, plano-convex, nearly circular,
moderately lobulate test composed of about 15-16 chambers
arranged in 2'/2—3 whorls; last whorl with 6-7 (rarely 8)
anguloconical chambers whose tips surround moderately open
umbilicus; umbilicus surmounted by an “adumbilical” or
circum-umbilical rim (“collar”) of fused muricae; umbilical
sutures radial, depressed, moderately to strongly curved, raised
and beaded on spiral side; wall finely perforate, distinctly
muricocarinate periphery, but spiral chamber surfaces often
nearly free of muricae; aperture a low, interiomarginal,
umbilical-extraumbilical arch.

DISCUSSION. —This is the type species of the genus
Morozovella McGowran (in Luterbacher, 1964) and one of the
most characteristic and easily recognized Paleocene morozov-
ellids. It has been assigned to various genera and subgenera
over the past half century but would appear to have found a
suitable home in the genus Morozovella as defined by
McGowran in Luterbacher (1964; see also McGowran, 1968).

68

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

--^=p^-r-f=^+~^+ + +•.+ +•

* + + t * + + + + +

4 4 4 4 + + + 4 + 4.4 + + + .+ + 4
+ + 1+ 4 4 + 4 + + + [+ + + + + 4 + + 4, 4 + 4 4

180°W

135°W

90°W

45°W

FIGURE 25.— Paleobiogeographic map showing distribution of Morozovella velascoensis (Cushman) in Zones P4
and P5.

This species has been confused with the heterochronously
isomorphic form M. caucasica (Glaessner) (see Subbotina,
1953, pi. 19: figs. la-2c, who identified strongly muricocari-
nate and circumumbilically muricate forms from the lower
Eocene zone of conical globorotaliids of the northern Caucasus
as G. velascoensis ; see also El-Naggar, 1966, who was equally
confused by the distinctions between these two taxa, and Blow,
1979, for clarification of the problems associated with
separation and recognition of these two forms).

Stable Isotopes. — Morozovella velascoensis has 5 ,3 C
similar to coexisting species of Morozovella and Acarinina and
more positive 6 I3 C and more negative 5 18 0 than Subbotina
(Boersma and Premoli Silva, 1983; Shackleton et al., 1985;
D’Hondt et al., 1994). Morozovella velascoensis displays a
pronounced increase in 5 I3 C with increased test size but little
corresponding change in 8 I8 0 (D’Hondt et al., 1994). This
species typically has more negative 5 18 0 than all other
analyzed species of Morozovella (Berggren and Norris, 1997).

Stratigraphic Range. —Zone P3b to Zone P5 (top).

Global Distribution. — Morozovella velascoensis has a
wide geographic distribution but is a predominantly
(sub)tropical to temperate form; it has not been recorded from
high northern or southern (subantarctic) latitudes (> 45° N or
S). The disappearance of this taxon is a distinct biostratigraphic
event that is used to define the boundary between Zones P5 and

P6, which occurs in mid-Chron C24r, and is closely correlative
with the Paleocene/Eocene boundary as denoted in the Belgian
and/or London-Hampshire Basin(s) of northwestern Europe
(Berggren and Aubry, 1996) (Figure 25).

Origin of Species. —This species evolved from Morozov¬
ella conicotruncata (Subbotina) within Subzone P3b by the
acquisition of coarsely muricate adumbilical ridges, the
complete loss of muricae on the spiral chamber surfaces and
between the murcrocarina and umbilical collar, as well as the
formation of a thick, coarsely muricate mucrocarina.

Repository. —Holotype (USNM CC4347) deposited in the
Cushman Collection, National Museum of Natural History.
Examined by WAB and RDN.

Genus Igorina Davidzon, 1976

TYPE Species. — Igorina tadjikistanensis (Bykova, 1953).

Original Description. —“Test free, bilaterally convex.
Equatorial outline round, slightly undulate. Axial outline takes
the form of a bilateral cone with variable vertex angles.
Chambers on spiral side alate, on umbilical side triangular.
Umbilicus small or absent. Aperture a slit at the base of the
septal surface of the last chamber. Surface of chambers smooth
or almost uniformly covered with small spines.” (Davidzon,
1976:197; translated from Russian.)

NUMBER 85

69

Diagnostic Characters. —Test small, biconvex, may
have a peripheral keel; chambers, ovoid or low conical in
shape, 5-6 in final whorl; wall, coarsely cancellate, praemuri-
cate, often with a thick, encrusted pustulose layer covering the
praemuricate wall; aperture, interiomarginal, umbilical-
extraumbilical, a low arch bordered by a thin lip.

Discussion. —As Pearson (1993:212) observed, the group
of “biconvex, muricate morozovellids” (see Boersma and
Premoli Silva, 1983; Premoli Silva and Boersma, 1989)—
including the pusilla-laevigata, convexa, and broedermanni
plexus of forms—is probably distinct from Acarinina and
mainstream morozovellids. He considered these forms inappro¬
priately placed in Igorina Davidzon (Loeblich and Tappan,
1988), inasmuch as the type species of the latter, Globorotalia
tadjikistanensis Bykova, was considered an enigmatic, bicon¬
vex morozovellid from the upper part of Zone P3a, and
probably is related to conicotruncata. Recent examination and
SEM reillustration of the holotypes of Globorotalia tadjikista¬
nensis Bykova (pi. 11: figs. 4-6) and Globorotalia convexa
Subbotina (pi. 11: figs. 1-3), however, have shown these forms
to be synonymous, with tadjikistanensis having priority.

Igorinids are characterized by their small, coarsely cancellate
tests, evolute coiling, and distinctive blunt, praemuricate
surface texture. We believe that the Igorinids evolved from
Praemurica about the time of appearance of the first
morozovellids (M. praeangulata, M. angulata). Like many
globigerininid groups, the igorinids show a trend toward
chamber compression and development of a peripheral keel,
but this trend is reversed in the Eocene with the evolution of the
I. broedermanni group.

Igorina albeari (Cushman and Bermudez, 1949)

Figure 26; Plate 16: figures 1-6; Plate 56: figures 1-16

Globorotalia albeari Cushman and Bermudez, 1949:33, pi. 6: figs. 13-15
[holotype from stratigraphic level within subsequently described (1957)
Globorotalia pseudomenardii Zone, Madruga Fm., Cuba].—Cifelli and
Belford, 1977:100, pi. 1: figs. 4-6 [holotype reillustrated].

Globorotalia pusilla laevigata Bolli, 1957a:78, pi. 20: figs. 5-7 [ Globorotalia
pseudomenardii Zone, Lizard Springs Fm., Trinidad].—Bolli and Cita,
1960:27, pi. 32: fig. 6a-c [ Globorotalia pseudomenardii Zone, Pademo
d’Adda, northern Italy].—Hillebrandt, 1962:128, 129, pi. 11: fig. 17a-c
[Globorotalia pseudomenardii Zone, Reichenhall-Salzburg Basin, Austro-
German border].—McGowran, 1965:63, pi. 6: fig. 4 [upper Paleocene,
stratigraphically equivalent to Globorotalia pseudomenardii Zone, Dilwyn
Clay, Rivemook Mbr., Pebble Point, Australia],

Globorotalia pseudoscitula Glaessner.—Loeblich and Tappan, 1957a: 193, pi.
46: fig. 4a-c [Zone P3, Coal Bluff Fm., Midway Group, Gulf Coast,
Alabama], pi. 53: fig. 5a-c [Zone P4, Vincentown Fm., New Jersey], pi. 59:
fig. 2a-c [Zone P4, Aquia Fm., Aquia Creek, Maryland/Virginia], pi. 63: fig.
6a-c [Zone P4, Velasco Fm., Tamaulipas, Mexico] [in part, not pi. 48: fig.
3a-c (= Igorina pusilla (Bolli))]. [Not Glaessner, 1937.]

Globorotalia ( Globorotalia ) albeari Cushman and Bermudez.—Blow,
1979:883, pi. 92: figs. 4, 8, 9, pi. 93: figs. 1-4 [Zone P4, DSDP Hole
47.2/9/3: 70-72 cm; Shatsky Rise, northwestern Pacific Ocean].

Original Description. —“Test very small for the genus,
strongly biconvex, dorsal side showing all the coils and ventral

side only the last-formed whorl, periphery somewhat rounded;
chambers not very distinct, 9 to 10 in the last-formed whorl,
only slightly inflated ventrally, increasing very gradually in
size as added; sutures fairly distinct but only slightly depressed
except in the last whorl on the ventral side, rather strongly
recurved on the dorsal side; wall slightly spinose, coarsely
perforate; aperture an elongate opening on the ventral side of
the last-formed chamber extending from nearly the inner end to
the periphery and with a distinct thin lip. Diameter 0.30-0.32
mm; thickness 0.20 mm.” (Cushman and Bermudez, 1949:33.)

Diagnostic Characters. —Moderately to strongly bicon¬
vex, essentially circular, cancellate, pustulose test with 6-8
chambers in final whorl; intercameral sutures on umbilical side
radial to weakly recurved yielding triangular-shaped chambers;
strongly recurved and exhibiting distinct limbation on the spiral
side, particularly between the last 3-4 chambers, yielding
trapezoidal-shaped chambers; peripheral margin distinctly
carinate, particularly on last chambers of final whorl; aperture
a low interiomarginal, umbilical-extraumbilical arch extend¬
ing towards, but not to, the peripheral margin.

Discussion. —Comparison of the type specimens (Plate 16:
Figures 1-6) of Globorotalia albeari Cushman and Renz,
1946, and G. pusilla laevigata Bolli, 1957a, by Blow (1979)
and Berggren (1960, 1965, 1968, 1969a, 1977) have confirmed
the suspicions previously raised by Postuma (1971) of the
synonymy of these two forms. Most notable is the presence of
a distinct peripheral carina in this taxon that was not shown in
the holotype illustration by Cushman and Renz (1946) nor,
surprisingly, in the refiguration of the holotype by Cifelli and
Belford (1977). We have observed a wide range of variation in
the degree of convexity of the spiral side in this taxon and have
tried to convey this variation in Plate 56: Figures 1-16. The
umbilical side is generally less convex than the spiral side, and
the final chamber is often flattened and smoother (less
pustulose) than the remainder of the test.

Stable Isotopes. — Igorina albeari has 5 13 C more negative
than Acarinina and Morozovella but more positive than
Subbotina and Globanomalina. The 8 18 0 of I. albeari is more
negative than Subbotina and Globanomalina but is more
positive than Morozovella (Berggren and Norris, 1997).

Stratigraphic Range. —Zone P3a/P3b boundary to Zone
P4.

GLOBAL Distribution. — Igorina albeari is predominantly
tropical to subtropical, low latitude, in distribution. It has not
been recorded from high southern latitudes at appropriate
stratigraphic levels (Stott and Kennett, 1990), although Huber
(1991b) recorded/illustrated a form (pi. 3: figs. 18, 19) similar
to albeari (as pusilla ) from a biostratigraphic level (Zone AP5
near the Paleocene/Eocene boundary) in ODP Hole 73 8C
(Kerguelen Plateau, southern Indian Ocean). From our experi¬
ence with Russian literature and the comparative material in the
collection at WHOI, it would appear that this taxon has not
been recorded or is not present in the Caucasus-Crimean
Paleocene (Figure 26).

70

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

180°W

135°W

90°W

45 °W

45°E

90°E

135°E

FIGURE 26.—Paleobiogeographic map showing distribution of Igorina albeari (Cushman and Bermudez) in
Zones P3 and P4.

ORIGIN of Species. —Igorina albeari is derived from I.
pusilla by the development of compressed chambers and a keel
on one or more chambers in the final whorl.

REPOSITORY. —Holotype (USNM CC47413) deposited in
the Cushman Collection, National Museum of Natural History.
Examined by WAB, RDN, and BTH.

Igorina pusilla (Bolli, 1957)

Figure 27; Plate 16: figures 7-9; Plate 57: figures 1-16

Globorotalia pusilla pusilla Bolli, 1957a:78, pi. 20: figs. 8-10 [Globorotalia
pusilla pusilla Zone, Guayaguayare Well 159, Trinidad Leasholds, Ltd.,
Lizard Springs Fm., Trinidad].—Bolli and Cita, 1960:388, 389, pi. 34: fig.
4a-c [ Globorotalia pusilla pusilla Zone, Pademo d’Adda, northern Italy].
Planorotalites tauricus Morozova, 1961:16, pi. 2: fig. 3 [ Acarinina indolensis
Subzone (Dn 2 III 1 ), Michurino Substage, Urukh River, northern Caucasus],
Globorotalia (Globorotalia ?) pusilla pusilla Bolli.—Hillebrandt, 1962:128,
pi. 11: fig. 18a,b [Globorotalia pusilla pusilla Zone, Reichenhall-Salzburg
Basin, Austro-German border].

Globorotalia pusilla pusilla (?) Bolli.—Shutskaya, 1970b:218, pi. 22: fig. 3a-c
[lower subzone of Acarinina tadjikistanensis djanensis Zone, lower Danatin
Formation, Malyi Balkhan Ridge, western Turkmenia],

Globorotalia pusilla Bolli.—Pujol, 1983:652, pi. 2: figs. 12, 13 [ Globorotalia
pusilla Zone, DSDP Hole 516F/86/4: 6-9 cm; Rio Grande Rise, South
Atlantic Ocean],

Morozovella pusilla pusilla (Bolli).—Snyder and Waters, 1985:446, 449, 460,
pi. 8: figs. 15-17 [ Morovozella pusilla pusilla Zone, DSDP Site 549/20/5:
18-20 cm; northeastern Atlantic Ocean].

Planorotalites pusilla pusilla (Bolli).—Toumarkine and Luterbacher,

1985:108, fig. 12:13a-c [holoype reillustrated], fig. 12:14a-c [Zone P3,

DSDP Hole 144A/3/4: 120-122 cm; South Atlantic Ocean],

Original Description. —“Shape of test low trochospiral,
biconvex, compressed; equatorial periphery nearly circular,
slightly lobate; axial periphery acute to subacute. Wall
calcareous, perforate, surface smooth. Chambers compressed;
12-16, arranged in 2 ! /2-3 whorls, the 5-6 chambers of the last
whorl increasing moderately in size. Sutures on spiral side
strongly curved, slightly depressed; on umbilical side radial,
depressed. Umbilicus narrow, open. Aperture a low arch, with
narrow lip; interiomarginal, extraumbilical-umbilical. Coiling
random. Largest diameter of holotype 0.24 mm.” (Bolli,
1957a:78.)

Diagnostic Characters. —Relatively small (generally
< 0.25 mm in diameter), essentially circular, biconvex, cancel-
late, pustulose test with 5-6 chambers in last whorl;
intercameral sutures on umbilical side radial, depressed, on
spiral side moderately to strongly curved, depressed/weakly
incised; axial periphery subacute and non-carinate; umbilicus
narrow, shallow, aperture an interiomarginal, umbilical-
extraumbilical arch extending towards, but not reaching, the
periphery.

DISCUSSION. —Igorina pusilla is the earliest representative
of the biconvex, praemuricate igorinids. The small, biconvex

NUMBER 85

71

FIGURE 27. —Paleobiogeographic map showing distribution of lgorina pusilla (Bolli) in Zones P3 and P4.

test, deep funnel-shaped entrances to the pores, and distinctly
praemuricate surface serves to differentiate this form (and its
descendants) from the mainline morozovellids and suggests
that I. pusilla represents the founding species of a separate
lineage among early Paleogene planktonic foraminifera. There
appears to be little confusion in the identification of this
species. We note, however, that Planorotalites tauricus
Morozova (1961) is a middle Paleocene igorinid species from
the northern Caucacus that we regard as synonymous with I.
pusilla.

Stable Isotopes.—N o data available.

Stratigraphic Range. —Zone P3a to Zone P3b (lower
part).

Global Distribution. — lgorina pusilla has been recorded
from predominantly low latitude (sub)tropical locations (Figure
27).

Origin of Species. —We believe that the igorinids are
derived from the nonkeeled, praemuricate forms of the
inconstans-uncinata plexus as previously suggested by Pear¬
son (1993). Although the exact pattern of ancestry has not been
worked out, lgorina pusilla is probably derived from forms
similar to P. inconstans or P. uncinata by development of more
involute coiling. This transformation may have occurred
through the suppression of the later stages of ontogeny by
speeding up the rate of maturation. This change in the timing of

maturation would account for the small size of mature
igorinids.

Repository. —Holotype (USNM P5064) deposited in the
Cushman Collection, National Museum of Natural History.
Examined by WAB, RDN, and BTH.

lgorina tadjikistanensis (Bykova, 1953)

Plate II: figures 1-9; Plate 58: FIGURES 1-12

Globorolalia tadjikistanensis Bykova, 1953:86, pi. 3: fig. 5a-c [Globorotalia
tadjikistanensis Zone, Suzakian Stage, southern part of Tadzhik Basin,
Ak-Tau, Kazakhstan; given as Eocene].—Leonov and Alimarina, 1960:53,
pi. 7: figs. 1, 2, 7 [upper part Globorotalia tadjikistanensis Subzone, eastern
facies, Khieu River section, northern Caucasus], figs. 3, 4, 7 [lower part
Globorotalia tadjikistanensis Subzone, eastern facies, Khieu River section,
northern Caucasus].—Luterbacher, 1964:52, text-fig. 52a-c [ Globorotalia
pusilla pusilla Zone, Gubbio section, central Apennines, Italy],

Globorotalia convexa Subbotina, 1953:209, pi. 17: fig. 2a-c [holotype], fig.
3a-c [zone of conical globorotaliids, Foraminiferal Layer, Series FI, Khieu
River, Nal’chik, northern Caucasus].—Loeblich and Tappan, 1957a: 188, pi.
48: fig. 4a-c [Zone P4, Vincentown Fm., New Jersey], pi. 50: fig. 7a-c
[Zone P4, Homerstown Fm., New Jersey], pi. 53: figs. 6a-8c [Zone P4,
Aquia Fm., Maryland], pi. 57: figs. 5a-6c [Zone P4, Salt Mountain
Limestone, Alabama], pi. 63: fig. 4a-c [Zone P4, Velasco Fm., Tamaulipas,
Mexico],—Pujol, 1983:644, pi. 3: figs. 1, 2 [Zone P3, DSDP Hole
516F/88/2: 102-103 cm; Rio Grande Rise, South Atlantic Ocean],
Truncorotaloides ( Morozovella ) convexus (Subbotina).—McGowran,
1968:192, pi. 2: figs. 11-14 [ Truncorotaloides (Acarinina) mckannai
zonule, Boongerooda Greensand, Australia].

72

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Globorotalia ( Acarinina) convexa Subbotina.—Jenkins, 1971:81, pi. 3: figs.
79-83 [ Globigerina ( Subbotina) triloculinoides Zone, type Teurian, Te Uri
Stream section, New Zealand].—Blow, 1979:920, pi. 85: figs. 2-7 [Zone P3,
DSDP Hole 47.2/10/2: 80-82 cm], pi. 88: figs. 3, 4 [upper part of Zone P3,
DSDP Hole 47.2/10/1: 72-74 cm], pi. 100: figs. 3, 5-9 [Zone P5, DSDP
Hole 47.2/9/1: 64-66 cm; Shatsky Rise, northwestern Pacific Ocean],
Globorotalia ( Acarinina ) convexa cf. convexa Subbotina.—Blow, 1979:921,
pi. 100: figs. 1, 2, 4 [Zone P5, DSDP Hole 47.2/9/1: 64-66 cm; Shatsky
Rise, northwestern Pacific Ocean],

Globorotalia ( Morozovella ) tadjikistanensis Bykova.—Belford, 1984:10, pi.

18: figs. 18-23 [upper Paleocene, Wabag Sheet, Papua, New Guinea].
Morozovella convexa (Subbotina).—Stott and Kennett, 1990:560, pi. 3: figs. 5,
6 [Zone AP3, near AP3/4 boundary, ODP Hole 690B/19H/4: 36-40 cm;
Maud Rise, Weddell Sea, Southern Ocean].

Original Description. —“Test rounded in outline, bicon¬
vex, with a weakly sloping, convex evolute side, and an arched,
cone-shaped, strongly convex ventral side. Peripheral margin
weakly lobate. The spiral consists of about three whorls with
six to eight chambers per whorl. On the ventral side, the
umbilical ends of the chambers converge, usually forming a
small, shallow umbilicus. The chambers on the dorsal side in
the first one and one-half whorls are barely discernible; in the
last one to one-half whorls they are rather low, flat, and curved.
On the ventral side the chambers are triangularly curved, rather
distinctly convex, and increase slightly in size as they are
added. The septal sutures on the dorsal side are tapered. In the
final one and one-half whorls they are slightly depressed. On
the ventral side the sutures are depressed and curved. Apertural
face not distinct. The aperture is not distinguishable. The wall
is rough, covered with short, thin spines. Dimensions of
holotype: large diameter 0.32 mm; small diameter 0.28 mm;
thickness 0.20 mm.” (Bykova, 1953:86; translated from
Russian.)

Diagnostic Characters. —Relatively small (< 0.25 mm
in diameter), nonspinose, biconvex, ovate to subcircular,
moderately lobulate, densely and finely praemuricate test with
5-7 (rarely up to 9-10) chambers in last whorl; axial periphery
subrounded to subacute, noncarinate; umbilical intercameral
sutures curved, depressed, spiral sutures depressed, strongly
recurved, tangential to inner whorl, often obscured by dense
murical network; umbilicus small, shallow as a result of tight
coiling mode, surrounded by an irregularly wavy umbilical
shoulder formed by undulating periumbilical chamber apices;
aperture a low, narrow interiomarginal, umbilical-
extraumbilical slit bordered by a distinct lip and extending
towards, but not reaching, the peripheral margin.

Discussion. —This taxon is a distinct component of late
Paleocene and earliest Eocene assemblages. Recent examina¬
tion and SEM reillustration of the holotype specimen of the
taxon tadjikistanensis (Plate 11: Figures 4-6) and convexa
(Plate 11: Figures 1-3), described originally from the upper
Paleocene of Kazakhstan (Bykova, 1953) and from the zone of
conical globorotaliids (= Zones P6-P8) in the Kuban River
section near Nal’chik, in the northern Caucasus (Subbotina,
1953), respectively, has shown the two forms to be conspecific,

with the former having priority. We essentially follow the
interpretation of Blow (1979), although unlike Blow we
include certain forms illustrated by Loeblich and Tappan
(1957a) from the synonymy of this species. We also include the
multichambered variety identified as cf. convexa in this taxon,
which presages its descendant I. broedermanni Cushman and
Bermudez.

STABLE Isotopes. — Igorina tajikistanensis has 5 I8 0
slightly lighter than coexisting M. velascoensis at equivalent
sizes and has distinctly more negative 5 I8 0 than Subbotina
(Shackleton et al., 1985; Berggren and Norris, 1997). The 5 13 C
of I. tajikistanensis displays a strong increase in 5 13 C with
increased size, which is similar to Acarinina and Morozovella
(Berggren and Norris, 1997).

Stratigraphic Range. —Zone P3b to Zone P7.

Global Distribution. — Igorina tadjikistanensis was
broadly distributed in tropical and subtropical latitudes.

Origin of Species. —This species probably evolved from /.
pusilla in middle to upper Zone P3 by developing a more
involute coiling mode, increasing the number of chambers in
the final whorl, and developing a dense, finely praemuricate
ornament. Igorina tadjikistanensis differs from I. albeari in
being generally smaller, lower spired, and without a peripheral
keel.

Repository. —Holotype (Flo. 2794-a) and paratype (No.
2794-a) deposited the micropaleontological collections at
VNIGRI, St. Petersburg, Russia. Examined by FR.

Genus Praemurica Olsson, Hemleben, Berggren,
and Liu, 1992

TYPE Species. — Globigerina ( Eoglobigerina ) taurica Mo¬
rozova, 1961.

Original Description. —“Test very low trochospiral with
10-15 chambers, and with 5-6, but occasionally more in the
ultimate whorl. The chambers which are globular to slightly
ovoid in shape increase very gradually in size. The arrangement
of chambers in the coil is nearly planispiral although the last
one or two chambers may be shifted slightly towards the
umbilicus. The aperture is interiomarginal, umbilical to
extraumbilical, a low to high arch which is bordered by a
narrow lip that often is somewhat wider in the umbilical area.
The umbilicus can vary from narrow and deep to fairly broad
and wide but is open to the previous chambers. The wall is
weakly to strongly cancellate and nonspinose.” (Olsson,
Hemleben, Berggren, and Liu, 1992:202.)

Diagnostic Characters. —Test very low trochospiral,
5-6, up to 8 in some species, globular to oval chambers in last
whorl that increase slowly to moderately in size; periphery
moderately to distinctly lobulate; nonspinose, cancellate wall
texture weakly developed; aperture an interiomarginal, umbili-
cal-extraumbilical low to high rounded arch, bordered by a
thin lip.

NUMBER 85

73

DISCUSSION. —The wall texture of Praemurica (Plate 6:
Figures 2-4) is similar to that observed in the modem
Neogloboquadrina dutertrei (d’Orbigny) (Plate 5: Figures 9,
10). Elongate subparallel ridges, often with an orientation
towards the aperture, are connected by shorter less well-
developed ridges that are thicker and broader on one side. This
gives the test a cancellate wall texture, which is herein termed
praemuricate. It is the first distinctive nonspinose, pustulose
wall texture to evolve in the phylogeny of the early Paleocene
planktonic foraminifera.

Praemurica inconstans (Subbotina, 1953)

Figure 28; Plate 10: figures 4-8; Plate 14: figures 13, 14;

Plate 59: figures 1-16

Globigerina inconstans Subbotina, 1953:58, pi. 3: figs. 1, 2 [holotype, fig. 1;
both specimens from zone of rotaliform globorotaliids, Elburgan Fm., Kuban
River, northern Caucasus = middle part of Acarinina inconstans Zone of
Leonova and Alimarina, I960].—Berggren, 1965:291, text-fig. 9:3, 4 [Zone
P2, Mexia Clay member. Wills Point Fm., Midway Group, Mexia, Texas].
Globigerina schachdagica Khalilov, 1956:246, pi. 1: fig. 3 [holotype: Danian
Stage, Zeid, northwestern Azerbaidzhan],

Acarinina praecursoria Morozova, 1957:1111, text-fig. 1 [Danian, Khokodze
River, northern Caucasus].

Globorotalia trinidadensis Bolli, 1957a:73, pi. 16: figs. 19-21 [holotype], figs.
22, 23 [Globorotalia trinidadensis Zone, lower Lizard Springs Fm.,
Trinidad],

Transitional form between Globorotalia pseudobulloides (Plummer) and
Globorotalia uncinata Bolli.—Bolli, 1957a:74, pi. 17: figs. 16-18 [ Glo¬
borotalia uncinata Zone, lower Lizard Springs Fm., Trinidad],

Globorotalia ( Acarinina ) inconstans (Subbotina).—Leonov and Alimarina,
1960, pi. 3: figs. 1-3, 5-8 [ Globorotalia inconstans Subzone: figs. 1, 7,
Podkhoomok River section; figs. 2-6, Khieu River; fig. 8, Urukh River,
northern Caucasus].

Globorotalia scabrosa Bermudez, 1961:1196, 1197, pi. 5: fig. 5 [Petromex
Well, 200 m, La Palma 56, Panuco, Veracruz, Mexico].

Globigerina scobinata Bermudez 1961:1197, pi. 5: fig. 6 [Madruga Fm.,
Madruga, Havana Province, Cuba].

Globorotalia ( Globorotalia) inconstans (Subbotina).—Hillebrandt, 1962:130,
pi. 12: figs. 7, 8 [Zone B, Reichenhall-Salzburg Basin, Austro-German
border],

Globorotalia inconstans (Subbotina).—Luterbacher, 1964:650: figs. 19-23
[figs. 19, 23, topotypes from zone of rotaliform globorotaliids, upper part of
Elburgan Fm., Kuban River, northern Caucasus; figs. 20, 22, Globorotalia
trinidadensis Zone, Gubbio section, central Apennines, Italy].

Globigerina arabica El-Naggar, 1966:157, 158, pi. 18: fig. 6 [holotype from
Sample 30, Gebel Owaina, Globorotalia compressalGlobigerina daubjer-
gensis Zone, upper Danian, Nile Valley, Egypt],

Acarinina inconstans inconstans (Subbotina).—Shutskaya, 1970b: 108, pi. 6:
figs. 4, 5 [middle part Acarinina inconstans Zone: fig. 4, western Turkmenia,
Malyi Balkhan; fig. 5, Elburgan Fm., northern Caucasus].

Globorotalia ( Turborotalia ) inconstans (Subbotina).—Blow, 1979:1080, pi.
71: figs. 6, 7 [Zone PI, DSDP Hole47.2/1/1: top], pi. 75: figs. 4-7 [ZonePI,
Lindi area, Tanzania], pi. 76: figs. 3, 6, 7 [Zone P2, DSDP Hole 47.2/10/6:
69-71 cm], fig. 10 [Zone P2, Hole 47.2/10/5: 70-72 cm], pi. 77: fig. 1 [Zone
P2, DSDP Hole 20C/6/4: 72-74 cm; Brazil Basin, South Atlantic Ocean], pi.
81: figs. 1, 2 [Zone P2, DSDP Hole 47.2/10/4: 83-85 cm; Shatsky Rise,
northwestern Pacific Ocean], pi. 233: figs. 4, 5 [Zone PI, Lindi area,
Tanzania],

Subbotina inconstans (Subbotina).—Stott and Kennett, 1990:559, pi. 2: figs. 5,
6 [Subzone APlb, upper Danian, ODP Hole 690C/14X/2: 36-40 cm; Maud
Rise, Weddell Sea, Southern Ocean],

Morozovella inconstans (Subbotina).—Berggren, 1992:564, pi. I: figs. 12, 13

[Subzone Pic, ODP Hole 747A/19H/CC: Kerguelen Plateau, southern

Indian Ocean],

Original Description. —“Test with round or broadly oval
outline consisting of 2-2 */2 whorls to the spiral. Peripheral
margin rounded, weakly lobulate. The early whorls are
disproportionately small relative to the last whorl. They (the
whorls) are situated either on the same plane as the last whorl
or even below it. The last whorl contains 5-6 chambers which
increase gradually in size; the last chamber is often considera¬
bly larger than the others. However, there are some individuals
in which the last three chambers are of equal size.

“Dorsal side very strongly compressed, ventral side convex,
in certain forms conical. There is a well-defined, shallow
umbilicus in the middle of the ventral side. Chambers spherical,
closely packed together. The outline of the dorsal side of the
chambers is rounded and that of the ventral side is either
rounded or triangular.

“Sutures simple, curved in the form of an arc. On the ventral
side they radiate from the umbilicus. Aperture slit-like, situated
along the marginal suture. Walls smooth, often finely cancel-
late. Dimensions: diameter 0.35-0.45 mm, thickness 0.12-
0.20 mm.” (Subbotina, 1953:58; translated from Russian.)

Diagnostic Characters. —Nonspinose, subcircular to
broadly elongate-oval, moderately lobulate, 5-7 chambered,
cancellate test; peripheral margin rounded to weakly subangu-
lar, chambers in early whorls tightly coiled, rapidly expanding
in final whorl; sutures radial, straight to weakly curved in early
forms, more strongly curved and weakly incised in more
advanced forms; aperture an interiomarginal, umbilical-
extraumbilical slit with distinct, lipped rim.

DISCUSSION. —The extensive synonymy above reflects our
current understanding and interpretation of this taxon. A
variety of morphotypes have been ascribed to inconstans-
trinidadensis-praecursoria over the past 40 years and assigned
to the genera Globigerina, Globorotalia, Acarinina, Subbotina,
and Turborotalia. We include this form in the genus
Praemurica following the demonstration by Olsson et al.
(1992) of a phylogenetically distinct and homogenous lower
Paleocene cancellate, nonspinose lineage. One of us (WAB)
has examined the type specimens of inconstans, praecursoria,
trinidadensis, and schachdagica and the synonymic listing
above is based to a large extent on those studies. The wide
range of variation ascribed herein to this morphospecies unifies
forms sharing the characteristics of a cancellate, nonspinose
test intermediate between the pseudoinconstans-taurica mor¬
phology and the typically anguloconical, nonkeeled uncinata
morphology.

STABLE Isotopes. — Praemurica inconstans has more posi¬
tive 8 13 C and more negative 5 18 0 than Subbotina and
Globanomalina but has a similar isotopic signature to P.
taurica (Boersma and Premoli Silva, 1983; Berggren and
Norris, 1997). There is a pronounced increase in 8 13 C with
increased size in P. inconstans (Kelley et al., 1996).

74

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

180°W

135°W

90°W

45°W

45°E

90°E

1 35°E

FIGURE 28.—Paleobiogeographic map showing distribution of Praemurica inconstans (Subbotina) in Zone P2.

Stratigraphic Range. —Zone Pic to lower Zone P3.
Global Distribution. —A cosmopolitan species in north¬
ern and southern hemisphere sections (Figure 28).

Origin of Species. —This morphospecies evolved from
Praemurica pseudoinconstans by the development of umbili¬
cal-conical chambers in morphologically advanced forms,
development of incised umbilical sutures, and an increase in
the number of chambers in the final whorl.

Repository. —Holotype (No. 3992) and paratype (No.
3993) deposited in the micropaleontological collections at
VNIGRI, St. Petersburg, Russia. Examined by WAB.

Praemurica pseudoinconstans (Blow, 1979)

Plate 60: figures 1-13

Globorotalia pseudobulloides (Plummer).—Loeblich and Tappan, 1957a: 192,
pi. 40: fig. 9a-c [paratype. Pine Barren Mbr., Clayton Fm., Alabama] [in
part], [Not Plummer, 1926.]

Globorotalia ( Turborotalia) pseudoinconstans Blow, 1979:1105, pi. 67: fig. 4
[holotype: Zone Pa, DSDP Hole 47.2/11/3: 148-150 cm], pi. 67: fig. 3
[paratypes: Zone Pa, DSDP Hole 47.2/11/3: 148-150 cm], pi. 69: fig. 4
[paratypes: Zone PI, DSDP Hole 47.2/11/3: 0-5 cm; Shatsky Rise,
northwestern Pacific Ocean],

“Morozovella” inconstans (Subbotina).—Huber, 1991 c:461, pi. 3: figs. 11, 12
[Zone APlb, ODP Hole 738C/19R: 365.22 mbsf; Kerguelen Plateau,
southern Indian Ocean]. [Not Subbotina, 1953.]

Praemurica pseudoinconstans (Blow).—Olsson, Hemleben, Berggren, and
Liu, 1992:202, pi. 6: figs. 1,4 [Zone Pa, Clayton Basal Sands, Millers Ferry,
Alabama]: figs. 2, 3, 5-8 [Zone Pla, Pine Barren Mbr., Clayton Fm., Millers
Ferry, Alabama].

Original Description. —“The comparatively small test is
coiled in a low, fairly lax, trochospire with 6 complete
chambers visible in the last convolution of the test together
with a small part of a seventh chamber and about 12-14
chambers comprising the spire. In dorsal aspect, the chambers
are sensibly equidimensional, inflated and subglobular, with
quite distinctly incised dorsal intercameral sutures; these
intercameral sutures are radially disposed. In ventral aspect, the
chambers are inflated, subglobular, but are slightly more
embracing and appressed than as seen in dorsal aspect. The
chambers increase evenly, but only slowly, in size as added in
the progression of the trochospire. The umbilicus is widely
open, moderately deep and clearly delimited by the umbilical
shoulders of the last convolution of chambers. The primary
aperture is slit-like near the umbilicus but widens to become
highly arched at, or near to, the peripheral margin of the test;
the aperture is bordered by a strongly developed flap-like lip
proximally, which extends into the umbilical depression.
Distally, the lip of the aperture is more rim-like and is less
broad than seen proximally. Within the umbilicus, relict
apertures are present for chambers prior to the last and their

NUMBER 85

75

apertural lips are confluent with the lip of the ultimate chamber.
The equatorial profile is subcircular to slightly elongate in the
direction of the diameter which bisects the final chamber; the
equatorial profile is also moderately lobulate. The axial-
apertural profile shows an equally biconvex test with rounded
peripheral margins. The wall texture of the test is finely and
densely perforate and, over the earlier chambers of the last
whorl, the mural-pores open into small pore-pits. The inter¬
pore ridges show a meandriform pattern which is characteristic.
Maximum diameter of holotype 0.328 mm. as measured by
electron beam sensor.” (Blow, 1979:1105.)

Diagnostic Characters. —Ultimate whorl with 5-5V 2
chambers of which first few increasing in size gradually, final
few increasing in size more rapidly; last chamber slightly offset
toward umbilicus in some specimens. Aperture a high rounded
arch, bordered by a narrow lip broadening toward umbilicus;
aperture not as pronounced as P. taurica. Cancellate wall
texture weakly developed, difficult to view with light micro¬
scope, especially in poorly preserved specimens. Pores about 1
pm in diameter at narrowest point, positioned at bases of
cancellate ridges. Walls about 4 pm thick, overall test size up
to 300 pm across.

DISCUSSION. — Praemurica pseudoinconstans is a fairly
common species that may be confused with the less common
Parasubbotina pseudobulloides (Plummer). Indeed, Blow
(1979) carefully distinguished the two species and selected as
a paratype a specimen from the Clayton Formation, Alabama,
previously identified by Loeblich and Tappan (1957a) as P.
pseudobulloides. The chambers in P. pseudobulloides increase
more rapidly in size and are more inflated than in P.
pseudoinconstans. Parasubbotina pseudobulloides is spinose
in contrast to P. pseudoinconstans, which is nonspinose. The
meandriform pattern of the interpore ridges noted by Blow
(1979) is due to the Neogloboquadrina dutertrei-hke wall
texture observed in this species under SEM. In this type of wall
texture, the pores are often not isolated from one another by
interpore ridges as in P. pseudobulloides. Except for their
general appearance, the two wall textures are fundamentally
different.

Stable Isotopes.—N o data available.

Stratigraphic Range. —Zone Pa to Zone P2.

Global Distribution. —Originally described from DSDP
Site 47, Shatsky Rise, northwestern Pacific Ocean. It also
occurs in Alabama and in the South Atlantic Ocean at DSDP
Site 356.

ORIGIN of Species. —Evolved from Praemurica taurica in
middle Biochron Pa by increasing the rate of expansion of the
last few chambers in the ultimate whorl.

Repository. —Holotype (BP Cat. No. 37/134) and para-
types (BP Cat. No. 37/135, 40/7) deposited in the micropaleon-
tological collections at The Natural History Museum, London.
Paratype (USNM P5724) deposited in the Cushman Collection,
National Museum of Natural History. Paratype (USNM P5724)
examined by WAB and RKO.

Praemurica taurica (Morozova, 1961)

Figure 29; Plate 10: figures 1-3; Plate 61: figures 1-15

Globigerina ( Eoglobigerina) taurica Morozova, 1961:10, pi. 1: fig. 5a-c
[lower Danian Stage (Uylin Substage), Dnl I Zone, Globigerina (Eoglobig¬
erina ) taurica Zone, Tarkhankut Peninsula, Crimea],

Morozovella taurica (Morozova).—Berggren, 1992:564, pi. 1: figs. 9-11
[Danian, ODP Hole 747C/3H/2: 22-24 cm; Kerguelen Plateau, southern
Indian Ocean],

Praemurica taurica (Morozova).—Olsson, Hemleben, Berggren, and Liu,
1992:202, pi. 5: figs. 1-8 [Zone Pla, Pine Barren Mbr., Clayton Fm., Millers
Ferry, Alabama],

Original Description. —“Test with a subpolygonal lateral
outline, strongly compressed along the growth axis. Spire
consists of three whorls. Early whorls lie on one level with the
surface of the last whorl or rise up slightly above it. In each
whorl there are five to six inflated subspherical chambers,
rapidly and uniformly increasing in size and arranged freely.
Peripherally on the chambers a small papillate projection,
directed toward the subsequent chamber, is frequently ob¬
served. Last chamber asymmetrical, flattened at the apertural
face and slightly shifted toward the umbilical surface.
Equatorial outer margin scalloped. Axial outer margin weakly
asymmetric, broadly rounded. Sutures deep, straight. Umbili¬
cus narrow. Aperture a semicircular slit located between the
umbilicus and the outer margin. Sometimes it is surrounded by
a very narrow lip, the width of which is uniform over its whole
length. Wall smooth, finely perforate. Surface lustrous or
matte.

“Dimensions of holotype (fig. 5a-c): greatest diameter 0.45,
least diameter 0.32, height 0.21 mm.

“ Variability: The form of the test, changing from oval to
rounded, and the number of chambers in a whorl are not
constant. Tests are predominant in which the last whorl there
are five to six chambers, but are encountered with four and a
half, seven, or eight chambers to a whorl.

“Comparison : From the near species Globigerina cretacea
d’Orbigny, 1840, and G. edita Subbotina, 1949, this species
differs by its flatter, low test, the often oval outlines, more
flattened spiral side, greater number (5-6) of chambers in the
last whorl, the asymmetrical shape of the last chamber, which
stands above the umbilicus, and the small umbilical aperture.”
(Morozova, 1961:10; translated from Russian.)

Diagnostic Characters. —Characterized by a very low
trochospiral test with 5-6, occasionally more, chambers in
ultimate whorl. Globular to slightly ovoid chambers increase
very gradually in size with last one or two occasionally slightly
shifted towards umbilicus. Umbilical-extraumbilical aperture
a low to high arch bordered by narrow lip broadening towards
umbilicus and becoming somewhat triangular in shape. In
well-preserved specimens, lips from previous chambers project
as small flaps into fairly wide, broad umbilicus having a deep
depression. Cancellate structure weakly developed.

76

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

FIGURE 29. —Paleobiogeographic map showing distribution of Praemurica taurica (Morozova) in Zone P 1 .

DISCUSSION.— This is the first species of Praemurica to
evolve from Hedbergella monmouthensis in the basal Danian.
It is fairly commmon in Zone Pa. Although the cancellate wall
texture is weakly developed, it is distinctive under SEM, being
nearly identical to the living species Neogloboquadrina
dutertrei. Praemurica taurica is a stem form of an important
lineage leading to P. uncinata.

STABLE Isotopes.— Praemurica taurica has more positive
5 13 C and more negative 5 18 0 than Subbotina and Globanomal-
ina in the late Danian, but all these taxa have similar isotopic
signatures in the earliest Danian (Berggren and Norris, 1997).
There is a pronounced increase in 8 I3 C with increased size in P.
taurica among small specimens (up to ~200 pm; D’Hondt and
Zachos, 1993) but a weak trend above this size (Norris, 1996).

Stratigraphic Range.— Upper Zone PO to Zone Plb;
?Plc.

Global Distribution.— Worldwide in the high to low
latitudes (Figure 29).

ORIGIN OF Species.— This species evolved from Hedber¬
gella monmouthensis in late Biochron PO. It is the stem form of
the praemuricate pseudoinconstans-inconstans-uncinata line¬
age of the lower Paleocene (Danian) Zones PI and P2.

Repository.— Holotype (No. 3510/1) deposited at GAN,
Moscow. Examined by FR.

Praemurica uncinata (Bolli, 1957)

Figure 30; Plate 10: figures 9-11; Plate 14: figures 9-11;

Plate 62: figures 1-16

Globorotalia uncinata Bolli, 1957a:74, pi. 17: figs. 13-15 [Globorotalia
uncinata Zone, lower Lizard Springs Fm., Trinidad],—Luterbacher,
1964:655, 657, fig. 30a-c [ Globorotalia uncinata Zone, level G-85, Gubbio
section, central Apennines, Italy], fig. 31a-c [topotype, Trinidad].—Said
and Sabry, 1964:385, 386, pi. 1: fig. 12a-c [Globorotalia uncinata Zone,
Esna Shale, Gebel Aweina, Egypt].—Berggren, 1965:294, text-fig. 9 (5a-c)
[Globorotalia uncinata Zone, Mexia Clay Mbr., Wills Point Fm., Mexia,
Texas].-—Toumarkine, 1978:692, 693, pi. 1: fig. 16 [ Globorotalia uncinata
Zone, DSDP Site 363/17/1: 87-89 cm; Walvis Ridge, South Atlantic
Ocean].—Pujol, 1983:645, 652, pi. 2: fig. 1 [ Globorotalia uncinata Zone,
DSDP Hole 516F/87/7: 39-40 cm; Rio Grande Rise, South Atlantic Ocean].

Acarinina indolensis Morozova, 1959:1116, text-fig. 1 [Danian, Globoconusa
daubjergensislAcarinina indolensis Zone, northwestern Crimea].

Globorotalia uncinata uncinata Bolli.—El-Naggar, 1966:240, pi. 18: fig. la-c,
pi. 19: fig. 2a-c [samples S.34 and S.36, respectively, both Globorotalia
uncinata Zone, lower Esna Shale, Gebel Oweina, Egypt].

Acarinina inconstans uncinata (Bolli).—Shutskaya, 1970a: 110, pi. 6: fig. la-c
[holotype refigured], fig. 2a-c [middle part of Acarinina inconstans Zone,
Elburgan Fm., Kuban River, northern Caucasus], fig. 3a-c [lower part of
Globigerina trivialis-Globoconusa daubjergensis-Globorotalia compressa
Zone, northern Osetiya, Urukh River, northern Caucasus]; 1970b: 118-120,
pi. 19: figs. 7a-c, lOa-c [Acarinina inconstans Zone, Elburgan Fm., Kuban
River, Cherkessk region, northern Caucasus].

Globorotalia ( Acarinina ) praecursoria praecursoria (Morozova).—Blow,
1979:944-947, pi. 76: figs. 4, 8, 9, pi. 81: fig. 3 [Zone P2, DSDP Hole

NUMBER 85

77

47.2/10/5: 70-72 cm], pi. 77: figs. 2-5 [Zone P2, DSDP Hole 20C/6/4:
72-74 cm; Brazil Basin, South Atlantic Ocean], pi. 82: figs. 1-3 [Zone P2,
recollection of Globorotalia uncinata type locality, Trinidad], pi. 84: fig. 2,
pi. 85: fig. 9 [Zone P3, DSDP Hole 47.2/10/2: 80-82 cm; Shatsky Rise,
northwestern Pacific Ocean], [Not Morozova, 1961.]

Morozovella uncinata (Bolli).—Snyder and Waters, 1985:448,449, pi. 10: figs.
1, 2 [Globorotalia uncinata Zone, DSDP Site 550/37/5: 59-61 cm;
Porcupine Abyssal Plain, northeastern Atlantic Ocean],

Original Description. —“Shape of test low trochospiral,
spiral side almost flat or slightly convex, umbilical side
distinctly convex; equatorial periphery distinctly lobate; axial
periphery rounded to subangular. Wall calcareous, perforate,
surface finely spinose. Chambers subangular, inflated, laterally
compressed; 12-15, arranged in about 2'/2 whorls, the 5-6
chambers of last whorl increasing moderately in size. Sutures
on spiral side strongly curved, depressed; on umbilical side
radial, depressed. Umbilicus fairly narrow, deep, open. Aper¬
ture a low arch; interiomarginal, extraumbilical-umbilical.
Coiling random. Largest diameter of holotype 0.35 mm.”
(Bolli, 1957a:74.)

Diagnostic Characters. —Nonspinose, weakly cancel-
late, elongate-oval, plano-convex to moderately high spired,
moderately lobulate test with 5-8 chambers in last whorl;
chambers occasionally so loosely coiled as to form secondary
spiral apertures between them; sutures on umbilical side radial,
depressed, on spiral side incised and strongly recurved yielding
typically trapezoidal-shaped chambers; axial periphery suban¬
gular, noncarinate but with rugose muricae often situated along
peripheral margin of early chambers of last whorl; umbilicus
typically narrow, deep, bordered by weakly developed circu-
mumbilical shoulder formed by raised periumbilical chamber
extensions; aperture a narrow interiomarginal, umbilical-
extraumbilical arch extending to peripheral margin.

Discussion. —Blow (1979) argued the case for including
uncinata Bolli, 1957a, as a junior synonym of praecursoria
Morozova, 1957. Our examination of the holotypes of both of
these forms leads us to reject this interpretation. Rather, we
interpret praecursoria as an advanced, atypically large end-
member of inconstans that is characterized by rounded
chambers and an axial periphery, and we reserve for uncinata
those forms exhibiting the typical anguloconical (but noncari¬
nate) test with distinctly incised and recurved spiral inter-
cameral sutures. Acarinina indolensis Morozova (1959) is a
small form of P. uncinata with five chambers in the final whorl
but, nevertheless, exhibits the characteristic morphology of this
species.

Stable Isotopes. — Praemurica uncinata has more positive
8 13 C and more negative 5 18 0 than Subbotina and Globanomal-
ina and has an isotopic signature similar to that of Morozovella
praeangulata (Shackleton et al., 1985; Berggren and Norris,
1997). There is a pronounced increase in 8 13 C with increased
size in P. uncinata (Kelly et ah, 1996; Norris, 1996).
Stratigraphic Range. —Zone P2 to lower Zone P3.
Global Distribution. —This taxon has been widely

reported in the literature from predominantly low latitude
(sub)tropical localities. Shutskaya (1970a, 1970b) recorded it
from several localities in the northern Caucasus. This species
does not appear to occur in high southern latitudes (Stott and
Kennett, 1990; Huber, 1991b), and we have not found it in our
examination of material from the southern part of the Indian
Ocean (Figure 30).

ORIGIN OF Species. —This species evolved from Praemurica
inconstans at the base of Zone P2 by extension of the
umbilically conical chambers into most of the final whorl, and
by the formation of blunt pustules around the umbilicus and on
the initial chambers of the final whorl.

Repository. —Holotype (USNM P5048) deposited in the
Cushman Collection, National Museum of Natural History.
Examined by WAB and RDN.

Family Guembelitriidae Montanaro Gallitelli, 1957

(by S. D’Hondt, C. Liu, and R.K. Olsson)

Guembelitriinae Montanaro Gallitelli, 1957:136 [subfamily],

Guembelitriidae El-Naggar, 1971:431 [nomen translatum ex subfamily].

Original Description. —“Test triserial; chambers globu¬
lar; aperture basal, arched, simple.” (Montanaro Gallitelli,
1957:136.)

Diagnostic Characters. —Original description of fo-
raminiferal tests assignable to subfamily Guembelitriinae does
not apply to all members of family Guembelitriidae. Tests of
guembelitriid foraminifera either triserial ( Guembelitria spp.),
trochospiral ( Parvularugoglobigerina spp., Globoconusa
spp.), or nearly triserial in initial whorl and approximately
biserial in later whorls ( Woodringina spp.). Chambers usually
globular or subglobular, increasing gradually in size. Aperture
usually a loop-shaped arch, often slightly infolded on one side,
marked by a fine lip. Surface texture microperforate, smooth to
pustulous; when present, pustules or small mounds generally
perforated by one or more pores (“pore-mounds”) ( Guembe¬
litria, Parvularugoglobigerina, Woodringina) or peripherally
associated with pores ( Globoconusa ).

DISCUSSION. —Montanaro Gallitelli (1957) emended the
family Heterohelicidae Cushman, 1927a, by creating the
subfamily Guembelitriinae for the triserial genera Guembelitria
Cushman, 1933, and Guembelitriella Tappan, 1940. Loeblich
and Tappan (1957a) assigned Woodringina Loeblich and
Tappan, 1957, to the Guembelitriinae, implicitly modifying the
definition of the Guembelitriinae to include forms that are
triserial in the first whorl and biserial in later whorls. El-Naggar
(1971) raised the Guembelitriiidae to family status, and Blow
(1979) explicitly broadened its definition to include mor-
photypes with biserial and trochospiral stages.

The assignment of biserial Woodringina species to the
Guembelitriidae rests on the hypothesis that Woodringina
species were derived from Guembelitria cretacea Cushman,
1933. This phylogenetic hypothesis is a subset of the broader

78

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

180°W

135°W

90°W

45°W

45°E

90°E

1 35°E

FIGURE 30. —Paleobiogeographic map showing distribution of Praemurica uncinata (Bolli) in Zone P2.

hypothesis that Chiloguembelina midwayensis (Cushman,
1940), is lineally derived from Guembelitria cretacea Cush¬
man, 1933, via Woodringina claytonensis Loeblich and
Tappan, 1957 (Olsson, 1970, 1982; Premoli Silva, 1977; Li and
Radford, 1991; Olsson etal., 1992; Liu and Olsson, 1992). This
broader hypothesis is supported by cladistic analysis, based on
shared apertural, surface textural, and juvenile characters
(D’Hondt, 1991). Given the apparent phylogenetic relationship
of Chiloguembelina midwayensis to Guembelitria cretacea, the
Guembelitriidae constitutes a paraphyletic family because it
does not include descendent species assigned to the Chi-
loguembelinidae. The relationship of many post-Paleocene
microperforate taxa (i.e., Cassigerinella Pokorny, 1955, Cor-
rosina Thalmann, 1956, and Gallitellia Loeblich and Tappan,
1986) to the Guembelitriidae remains largely unexplored.

Recent studies have documented morphologic intergradation
and shared surface-textural and apertural characteristics be¬
tween Guembelitria cretacea and members of the trochospiral
genera Parvularugoglobigerina Hofker, 1978, and Globocon-
usa Khalilov, 1956 (D’Hondt and Keller, 1991; Liu and Olsson,
1992; Olsson et al., 1992) (Plates 63-68). These demonstrate
the general validity of several recent phylogenetic hypotheses
for the origin of the latter genera (Olsson, 1970, 1982; Premoli
Silva, 1977; Smit, 1982; Olsson et al., 1992). On this basis, we
assign both Parvularugoglobigerina and Globoconusa to the
Guembelitriidae.

Among the primary morphologic characters that unite the
Guembelitriidae is a close surface-textural association of pores
and pustules (Liu and Olsson, 1992; Olsson et al., 1992) (Plates
63-68). Where the pores directly perforate the surface mounds
(or pustules), these perforated mounds are commonly referred
to as “pore-mounds.” Interspecimen and intraspecimen vari¬
ation in surface texture from smooth to pore-mound is
exhibited by Guembelitria cretacea, Woodringina claytonen¬
sis, and Parvularugoglobigerina species (D’Hondt and Keller,
1991; Liu and Olsson, 1992; Olsson et al., 1992) (Plates
63-68). The degree of pore-mound expression within a
specimen appears ontogenetically variable, with the ultimate
chamber often exhibiting more weakly developed pore-mounds
than immediately preceding chambers (Liu and Olsson, 1992)
(Plates 63-68). Furthermore, the pustules (pore-mounds) are
often asymmetrically perforate (Plate 63: Figure 6, Plate 65:
Figure 6, Plate 67: Figure 14).

The phyletic relationship of Parvularugoglobigerina, Glo¬
boconusa, Woodringina, and Chiloguembelina to Guembelitria
cretacea indicates that both trochospiral and biserial chamber
arrangements divergently evolved within the planktonic fo-
raminifera (Olsson, 1982; Smit, 1982; D’Hondt, 1991; Liu and
Olsson, 1992). Such relationships have clearly not been
accounted for by taxonomic schemes, which separate serial and
trochospiral morphotypes at the superfamily level (i.e.,
Loeblich and Tappan, 1988).

NUMBER 85

79

Genus Guembelitria Cushman, 1933

Chiloguembelitria Hofker, 1978:60.

TYPE Species. — Guembelitria cretacea Cushman, 1933.
Original Description. —“Test similar to Gumbelina, but
triserial; wall calcareous, finely perforate; aperture large, at the
inner edge of the last-formed chamber.” (Cushman, 1933:37.)

Diagnostic Characters. —-Test small and triserial. Aper¬
ture bordered by a distinct lip and often slightly asymmetric.
Wall structure microperforate; surface texture of well-
preserved specimens characterized by presence of pore-
mounds.

DISCUSSION. —Confusion remains over the taxonomic status
of Chiloguembelitria, which Loeblich and Tappan (1988)
retained as a valid genus and Kroon and Nederbragt (1990)
suggested is a junior synonym of Guembelitria. This confusion
is exacerbated by the absence of a designated holotype for
Chiloguembelitria or its type species, Chiloguembelitria
danica Hofker, 1978. Nonetheless, it appears that no morpho¬
logical characters consistently distinguish Chiloguembelitria
spp. from Guembelitria spp. The original description and
illustration of C. danica Hofker, 1978, resembles Guembelitria
cretacea Cushman, 1933, in its apertural characteristics and its
consistent triseriality (Plate 63). The absence of distinct
chiloguembelitriid characters indicates that, as suggested by
Kroon and Nederbragt (1990), Chiloguembelitria danica
Hofker, 1978, is a junior synonym of Guembelitria cretacea
Cushman, 1933.

Guembelitria cretacea Cushman, 1933

Figure 31; Plate 8: figures 1-3; Plate 13: figure 3;

Plate 63: figures 1-12

Guembelitria cretacea Cushman, 1933:37, pi. 4: fig. 12a,b [upper Maas-
trichtian, Navarro Fm„ Texas],—Olsson, 1970:601, pi. 91: figs. 4, 5 [upper
Maastrichtian, Redbank Fm., New Jersey],—Smith and Pessagno, 1973:15,
pi. 1: figs. 1-8 [upper Maastrichtian, Corsicana Fm., Texas],—Keller,
1989:319, figs. 1-1, 1-2 [lower Danian, Brazos River, Texas],—D’Hondt,
1991:172, pi. 1: figs. 1, 3, 5, 6 [Zone Pa, DSDP Site 577/12/5: 94-96 cm;
Shatsky Rise, northwestern Pacific Ocean], figs. 2, 4 [lower Danian, Brazos
River, Texas], pi. 2: fig. 2 [Zone Pa, DSDP Site 577/12/5: 94-96 cm;
Shatsky Rise, northwestern Pacific Ocean], fig. 3 [Zone Pa, DSDP Site
528/31/CC: 14-15 cm; Walvis Ridge, South Atlantic Ocean].—D’Hondt
and Keller, 1991:93, pi. 3: fig. 1 [Zone Pa, DSDP Site 577/12/5: 115-117
cm; Shatsky Rise, northwestern Pacific Ocean].—Liu and Olsson, 1992:341,
pi. 1: figs. 1, 2 [Zone Pa, Pine Barren Mbr., Clayton Fm., Millers Ferry,
Alabama].

Guembelitria irregularis Morozova, 1961:17, pi. 1: fig. 9 [Danian, Tarkhankut,
Crimea].—D’Hondt, 1991:172, pi. 1: fig. 7 [Zone Pa, DSDP Site 577/12/5:
94-96 cm; Shatsky Rise, northwestern Pacific Ocean].

Chiloguembelitria danica Hofker, 1978:60, pi. 4: fig. 14 [holotype: Danian,
DSDP Hole 47.2, sample depth unknown; Shatsky Rise, northwestern
Pacific Ocean].—Loeblich and Tappan, 1988:452, pi. 484: figs. 3-6
[holotype], figs. 7, 8 [Danian, DSDP Hole 47.2, sample depth unknown;
Shatsky Rise, northwestern Pacific Ocean],

Guembelitria (?) trifolia (Morozova).—Blow, 1979:1384, pi. 61: fig. 9 [Zone
Pa, DSDP Hole 47.2/11/5: 148-150 cm; Shatsky Rise, northwestern Pacific
Ocean], [Not Globigerina (Eoglobigerina ) trifolia Morozova, 1961.]

Guembelitria azzouzi Salaj, 1986:49, pi. 1: figs. 1-6, pi. 2: fig. 1 [base of
Danian, El Haria, Tunisia].

Guembelitria besbesi Salaj, 1986:50, pi. 1: figs. 7-9 [base of Danian, El Haria,
Tunisia],

Guembelitria trifolia (Morozova).—Keller, 1989:319, figs. 3-3, 3-4 [lower
Danian, Brazos River, Texas],—D’Hondt and Keller, 1991:93, pi. 3: fig. 2
[Zone Pa, DSDP Site 577/12/5: 115-117 cm; Shatsky Rise, northwestern
Pacific Ocean], [Not Globigerina ( Eoglobigerina) trifolia Morozova, 1961.]

Original Description. —“Test small, triserial; chambers
globular, nearly spherical; sutures much depressed; wall
smooth, finely perforate; aperture large, semicircular or
semi-elliptical at the inner margin of the last-formed chamber.
Length of holotype 0.20 mm.; breadth 0.17 mm.” (Cushman,
1933:37.)

Diagnostic Characters. —Test small, triserial, composed
of globular chambers with strongly depressed sutures. Aperture
bordered by distinct lip; aperture often slightly asymmetric due
to infolding of lip along one side of aperture (as in
Woodringina and Chiloguembelina). Wall structure microper¬
forate; surface texture often characterized by blunt pore-
mounds; i.e., mounds marked by one or more pores (Plate 63:
Figure 6).

DISCUSSION. —As discussed previously, Chiloguembelitria
danica Hofker, 1978, appears to be a high-spired form of
Guembelitria cretacea Cushman, 1933. Similarly, the primary
characters of Guembelitria irregularis Morozova, 1961 (Plate
8: Figures 1-3), and Guembelitria azzouzi Salaj, 1986, are
indistinguishable from those of Guembelitria cretacea. In
contrast, Guembelitria dammula Voloshina, 1961 (Plate 12:
Figures 7-9), appears to differ from Guembelitria cretacea
sensu stricto by its three-chamber series being aligned more
strictly parallel to its axis of test coiling. Closer examination of
the type population of G. dammula may be necessary to
determine whether it should be reduced to a junior synonym of
G. cretacea or retained as a separate taxon.

Salaj (1986) designated a short-spired earliest Paleocene
form of Guembelitria as G. besbesi. Other authors have
identified that short-spired form of Guembelitria as Guembe¬
litria (?) trifolia (Morozova) or Guembelitria trifolia (Mo¬
rozova) (Blow, 1979; Keller, 1989; D’Hondt, 1991). The latter
designations are incompatible with our interpretation of
Globigerina (. Eoglobigerina ) trifolia Morozova, 1961, as a
variant of Globoconusa daubjergensis (Bronnimann, 1953)
(Plate 8: Figures 4-6). In any case, the short-spired Guembe¬
litria morphotype intergrades with G. cretacea sensu stricto
(Plate 63). The former differs from the latter only in having a
shorter spire. Along with G. cretacea sensu stricto, the
short-spired morphotype is present in uppermost Maastrichtian
near-shore sequences (D’Hondt, 1991) and is abundant in
lowermost Paleocene planktonic foraminiferal assemblages
(D’Hondt and Keller, 1991). The stratigraphic and biogeogra¬
phic association of these intergrading morphotypes suggests
that the short-spired form (= Guembelitria besbesi Salaj, 1986)
is a morphologic variant of G. cretacea.

80

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

180°W

135°W

90°W

45°W

45°E

90°E

135°E

FIGURE 31 .—Paleobiogeographic map showing distribution of Guembelitria cretacea Cushman in the Daman.

Stable Isotopes. —Biogeographic and oxygen isotopic
data suggest that G. cretacea inhabited a near-surface plank¬
tonic niche (Boersma et al., 1979; Boersma, 1984a; D’Hondt
and Zachos, 1993).

Stratigraphic Range. —Maastrichtian to Zone Plb.

Global Distribution. —During the Maastrichtian, G.
cretacea was generally limited to near-shore environments and
only rarely was present in the open ocean (Davids, 1966;
Olsson, 1970; Smith and Pessagno, 1973). Immediately
following the Cretaceous/Tertiary boundary event, G. cretacea
radiated into the open ocean, where it was abundant at low and
middle latitudes (Olsson, 1970; Smit and van Kempen, 1987;
D’Hondt and Keller, 1991; Liu and Olsson, 1992). In Zone P0
and lower Zone Pa it was a cosmopolitan planktonic
foraminiferal taxon. Biogeographic and oxygen isotopic data
suggest that G. cretacea inhabited a near-surface planktonic
niche (Boersma et al., 1979; Boersma, 1984a; D’Hondt and
Zachos, 1993) (Figure 31).

Origin of Species.—U nknown.

Repository. —Holotype (USNM CC19022) deposited in
the Cushman Collection, National Museum of Natural History.
Examined by SD, CL, and RKO.

Genus Globoconusa Khalilov, 1956

Globastica Blow, 1979:1231.

TYPE Species. — Globoconusa conusa Khalilov, 1956 =
Globigerina daubjergensis Bronmmann, 1953.

Original Description. —“Test high conical, turret-like,
tapering toward the initial end. Dorsal side strongly convex,
with a conical spire, its apex at the initial chamber. The height
of the cone exceeds the diameter of its base or is nearly equal to
it. On the dorsal side all whorls are visible, in general
represented by semispherical chambers; on ventral side
subspherical chambers are observed only in the last whorl.”
(Khalilov, 1956:249; translated from Russian).

Diagnostic Characters. —Test tiny, low to high trochos-
pire of 2—2 '/2 whorls; each whorl comprised of 3-4 inflated,
subglobular chambers. Wall calcareous, microperforate, with
distinctly hispid surface; pustules often peripherally associated
with a small pore (and vice-versa). Aperture a very small, low
arch, with umbilical position. Test sometimes marked by one or
more small supplementary apertures on spiral side.

DISCUSSION. — Globoconusa conusa Khalilov, 1956, is
widely considered to be a junior synonym of Globigerina
daubjergensis Bronnimann, 1953 (Loeblich and Tappan, 1964,
1988; Khalilov, 1967; Morozova et al., 1967, Olsson, 1970;
Premoli Silva, 1977; Hofker, 1978; Smit, 1982; Toumarkine
and Luterbacher, 1985; Brinkhuis and Zachariasse, 1988; Stott
and Kennett, 1990; D’Hondt and Keller, 1991; Huber, 1991b;
Li and Radford, 1991; Liu and Olsson, 1992; Olsson et al.,
1992). A different opinion was held by Blow (1979), who noted

NUMBER 85

81

that Khalilov’s (1956:249) type description of Globoconusa
conusa differs from the holotype of G. daubjergensis in some
respects (i.e., the test of G. conusa was originally described as
“strongly thickened” and “covered with small, dense pits”). On
this basis, Blow (1979) created the generic designation
Globastica for Globigerina daubjergensis and related forms.

Globoconusa daubjergensis (Bronnimann, 1953)

Figure 32; Plate 8: figures 4-6; Plate 15: figures 13, 14;

Plate 64: figures 1-12

Globigerina daubjergensis Bronnimann, 1953:340, text-fig. 1 [Danian,
Daubjerg Quarry, Denmark],

Globoconusa conusa Khalilov, 1956:249, pi. 5: fig. 2a-c [Danian, northeastern
Azerbaidzhan],—Blow, 1979:1386, pi. 257: fig. 10 [Danian, DSDP Hole
20C/6/4: 72-74 cm; Brazil Basin, South Atlantic Ocean], fig. 11 [Thanet
Sands, Reculver, Kent, England],

Globigerinoides daubjergensis (Bronnimann).—Loeblich and Tappan,
1957a: 184, pi. 40: fig. la-c [upper Danian, Sweden], pi. 40: fig. 8a-c [Zone
PI, Pine Barren Mbr., Clayton Fm., Alabama], pi. 41: fig. 9a-c [Zone Pic,
McBryde Mbr., Clayton Fm., Alabama], pi. 42: figs. 6a-7c [Zone Pic,
Brightseat Fm., Maryland], pi. 43: fig. la-c [Zone PI, Kincaid Fm., Texas],
pi. 44: figs. 7, 8a-c [Zone P2, Wills Point Fm., Texas],—Olsson, 1960:43,
pi. 8: figs. 4-6 [Zone PI, basal Homerstown Fm., New Jersey].

Globigerina kozlowskii Brotzen and Pozaryska, 1961:162, pi. 1: figs. 1-14, pi.

2: figs. 1-17, pi. 3: figs. la-2c [Danian, Pamietowo, Poland].

Globigerina (Eoglobigerina ) trifolia Morozova, 1961:12, pi. 1: fig. 1 [Danian,
Tarkhankut, Crimea],

Globoconusa tripartita Morozova et al., 1967:193, pi. 5: figs. 4-6 [Danian,
Kopet-Dagh, Crimea].

Globoconusa daubjergensis gigantea Bang, 1969:65, pi. 4: figs. 1 —3b [type
Danian, Denmark],

Globoconusa daubjergensis (Bronnimann).—Olsson, 1970:601, pi. 92: fig.
2a,b [lower Danian, Pine Barren Mbr., Clayton Fm., Millers Ferry,
Alabama], figs. 5a-6b [Danian, basal Homerstown Fm., New Jersey],—
Keller, 1993:1, pi. 3: figs. 1-3 [Danian, ODP Hole 690C/15/1: 19-21 cm],
pi. 4: figs. 11-13 [Danian, Hole 690C/15/1: 121-123 cm; Weddell Sea,
Southern Ocean],

Globastica daubjergensis (Bronnimann).—Blow, 1979:1235, pi. 74: figs. 7-9
[Zone Pi, DSDP Hole 47.2/11/2: 148-150 cm; Shatsky Rise, northwestern
Pacific Ocean], pi. 256: figs. 1-9 [Zone D2, Danian, Karlstrup, Denmark],
pi. 257: figs. 3, 4 [upper Danian, Ostratorp, Sweden],

Original Description. —“The specimens are very small
for the genus [ Globigerina ]. The outline of the trochoid test is
distinctly lobulate. The spiral side is pointed in the initial
portion. The umbilicus is small and shallow. The final whorl,
the dominant portion of the test, consists of 3 to 4 gradually in
size increasing subglobular chambers. The sutures of the final
whorl are strongly incised, those of the early test are not clearly
visible. The extremely small, subcircular aperture opens into
the shallow umbilical depression. The rough surface is covered
by minute irregularly distributed spines. The thin walls are
finely perforate. The direction of coiling is undetermined, 11
out of 19 specimens are coiling to the right hand side.

“The maximum diameter of the tests varies from 0.125 mm
to 0.2 mm, average 0.15 mm. The height of the test is ±0.12
mm and the aperture has a diameter of ± 0.02 mm. Common in
sample 38.” (Bronnimann, 1953:340.)

Diagnostic Characters. —Test characterized by
microperforate wall structure, with outer surface covered by
abundant small pustules. Wide variation in spire height; some
specimens marked by relatively low trochospire, others display
relatively high spire (similar to short-spired Guembelitria
cretacea). Occasionally exhibits small secondary (intercameral)
apertures; both primary and secondary apertures sometimes
covered by bullae.

DISCUSSION. —The morphology of G. daubjergensis has
been described in detail by several authors (Bronnimann, 1953;
Loeblich and Tappan, 1957a; Troelsen, 1957; Blow, 1979).
Troelsen (1957:120) recognized two forms as end-member
morphologic variants of Globigerina daubjergensis Bronni¬
mann, noting that the two variants “grade imperceptibly into
each other.” One of these contains four chambers in each whorl,
whereas the other is a three-chambered form ( Eoglobigerina
trifolia Morozova, 1961, Globigerina tripartita Morozova et
al., 1967, and Globastica sp. Type 1 of Blow, 1979). Blow
(1979:1244) suggested that the three-chambered form “is one
of three later differentiates from the basic Globastica daubjer-
ge/ww-morphotype.” Close examination of lowermost Paleo-
cene sequences, however, suggests that the first appearance of
the three-chambered morphotype preceded that of the four-
chambered morphotype (D’Hondt and Keller, 1991).

Some specimens assigned to the three-chambered mor¬
photype appear morphologically intermediate between Guem¬
belitria cretacea and Globoconusa daubjergensis (Plate 63:
Figures 7-9). The existence of such intermediate forms in
lowermost Paleocene sediments has often been interpreted to
demonstrate the evolution of G. daubjergensis from G.
cretacea (Olsson, 1970, 1982; Premoli Silva, 1977; Smit, 1977,
1982; Li and Radford, 1991; Liu and Olsson, 1992).

Blow (1979:1235) suggested that G. daubjergensis, G.
daubjergensis gigantea, and G. kozlowskii should probably be
considered as only subspecifically related. Bang (1969)
proposed the subspecies designation Globoconusa daubjergen¬
sis gigantea for morphotypes of G. daubjergensis that are
marked by an umbilical bulla and secondary bullae in
intercameral sutures. The holotype illustration of Globigerina
kozlowskii Brotzen and Pozaryska (1961) has a higher initial
spire and tighter coiling mode than the holotype of G.
daubjergensis. Nonetheless, the former falls within the range of
morphologic variability of the latter. Hence, G. kozlowskii is a
junior synonym of G. daubjergensis.

Recrystallization renders the holotype of Postrugoglobiger¬
ina praedaubjergensis Salaj difficult to unambiguously iden¬
tify (Salaj, 1986, pi. 3: fig. 7); however, Salaj (1986)
considered Postrugoglobigerina praedaubjergensis immedi¬
ately ancestral to G. daubjergensis, and the only other
illustrated specimen assigned to P. praedaubjergensis is a
Globoconusa daubjergensis specimen (Salaj, 1986, pi. 3: figs.
8, 9).

STABLE Isotopes. —Although its abundance in near-shore
sequences indicates a near-surface planktic habitat (Troelsen,

82

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

FIGURE 32. —Paleobiogeographic map showing distribution of Globoconusa daubjergensis (Bronnimann) in
Zones Pa and PL

1957; Keller, 1989; Liu and Olsson, 1992), its oxygen isotopic
signature and open-marine abundance patterns suggest a
preference for relatively cool water masses (Premoli Silva and
Boersma, 1989; D’Hondt and Keller, 1991; Liu and Olsson,
1992; D’Hondt and Zachos, 1993).

Stratigraphic Range.—B asal Zone Pa to Zone Pic.

Global Distribution. — Globoconusa daubjergensis was
abundant in high-latitude and near-shore planktonic foraminif-
eral assemblages (Troelsen, 1957; Keller, 1989; Premoli Silva
and Boersma, 1989; Liu and Olsson, 1992). It was rare in
low-latitude open-marine environments (Premoli Silva and
Boersma, 1989; D’Hondt and Keller, 1991; Liu and Olsson,
1992) (Figure 32).

ORIGIN OF Species. — Globoconusa daubjergensis is consid¬
ered to be a direct descendent of Guembelitria cretacea (Bang,
1969; Olsson, 1970, 1982; Premoli Silva, 1977; Smit, 1977,
1982; Li and Radford, 1991; Liu and Olsson, 1992).

Repository. —Holotype (USNM CC64879) deposited in
the Cushman Collection, National Museum of Natural History.
Examined by SD, CL, and RKO.

Genus Parvularugoglobigerina (Hofker, 1978), emended

Postrugoglobigerina Salaj, 1986:52.

TYPE Species. — Globigerina eugubina Luterbacher and
Premoli Silva, 1964.

Original Description. —“Very small species with 3-6
chambers in the last-formed whorl; at the dorsal side all
chambers visible; at the ventral side only those of the
last-formed coil; chambers globular, with sutures depressed on
both sides; umbilical cavity very small; walls thin, consisting of
one lamella, with small pustules in between the pores; often the
pustules are found in rows, as in Rugoglobigerina. Pores fine,
pipelike, at the surface ending in a funnel, as in some species
they end in pits of the wall. Aperture an umbilical-
extraumbilical, crescent-like opening, with slightly thickened
border, or a narrow poreless lip.” (Hofker, 1978:60.)

Diagnostic Characters. —Original description inaccu¬
rate, especially with respect to surface texture. Test typically
small, with moderate to flat trochospire consisting of 2'/2
whorls of globular or subglobular chambers. Chambers
gradually increase in size; 3 */2—7 chambers in each whorl,
separated by radial and depressed sutures on both spiral and
umbilical sides. Umbilicus closed. Aperture umbilical to
extraumbilical, ranging from comma-shaped arch to long
narrow opening extending up apertural face in nearly equatorial
position. Aperture bordered by a slight lip. Surface texture
microperforate, pustulous or smooth; when pustulous, well-
preserved parvularugoglobigerinids exhibit pore-mound sur¬
face texture characteristic of guembelitriid taxa. Pores do not
end in pits; pustules not aligned.

NUMBER 85

83

DISCUSSION. —As noted by several previous authors, Hof-
ker’s (1978) description of Parvularugoglobigerina eugubina
(Luterbacher and Premoli Silva) does not accurately describe
Globigerina eugubina Luterbacher and Premoli Silva, 1964
(Bang, 1979; Brinkhuis and Zachariasse, 1988; Loeblich and
Tappan, 1988; Liu and Olsson, 1992; Olsson et al., 1992).
Nonetheless, the genus Parvularugoglobigerina was erected
with Globigerina eugubina Luterbacher and Premoli Silva,
1964, as the type species, and it remains the generic label for
that species and related forms (Hofker, 1978; Brinkhuis and
Zachariasse, 1988; Loeblich and Tappan, 1988; Olsson et al.,
1992).

The type species of Postrugoglobigerina is Postrugoglobig-
erina hariana Salaj, 1986. Because Postrugoglobigerina
hariana Salaj, 1986, is a junior synonym of Globigerina
eugubina Luterbacher and Premoli Silva, 1964, Postrugoglo¬
bigerina Salaj, 1986, is a junior synonym of Parvu¬
larugoglobigerina Hofker, 1978.

Parvularugoglobigerinids generally resemble woodringinids
in their surface texture and apertural characteristics.

Parvularugoglobigerina alabamensis (Liu and Olsson, 1992)

Plate 65: figures 1-6

Guembelitrial alabamensis Liu and Olsson, 1992:341, pi. 2: figs. 1-7 [Zone

Pla, Pine Barren Mbr., Clayton Fm., Millers Ferry, Alabama].

Original Description. —“Test small, 110-160 pm in
height and 90-135 pm in largest diameter, height-width ratio
1.0-1.2; 10-13 globular or spherical chambers arranged in a
high trochospire, triserial in the early and trochospiral in the
later ontogenetic stage, with 3 to 4, mostly 3 V 2 to 4 chambers
in the last formed whorls; sutures deeply incised; umbilicus
open, narrow and shallow; aperture semicircular, high, with a
distinct narrow but thick lip, umbilical, symmetrically situated
at the base of the last formed chamber. Wall microperforate,
early chambers have intensive small pore mounds, later
chambers are covered with dense blunt pustules and less
frequent pore-mounds.” (Liu and Olsson, 1992:341.)

Diagnostic Characters. —Typically characterized by 2 V 2
whorls, each composed of 3-4 inflated subglobular chambers,
increasing slowly in size. Aperture low, centrally located,
umbilical, marked by a distinct lip. Sometimes characterized by
presence of pore-mounds (Plate 65: Figure 6).

DISCUSSION. — Parvularugoglobigerina alabamensis differs
from Guembelitria cretacea by possessing 3 V 2 —4 (rather than
3) chambers in the outer whorl. It resembles G. cretacea in its
apertural characteristics and presence of pore-mounds. Parvu¬
larugoglobigerina alabamensis sensu stricto differs from
Parvularugoglobigerina extensa in having a less elongate
aperture that does not extend extraumbilically.

Stable Isotopes.—-N o data available.

Stratigraphic Range. —Zone Pa to Zone P3b.

Global Distribution.—S imilar to Parvularugoglobiger¬
ina eugubina.

ORIGIN OF Species.— This species evolved from Guembe¬
litria cretacea. Parvularugoglobigerina alabamensis appears
as a morphologically intermediate form between G. cretacea
and Parvularugoglobigerina extensa Blow. For example, the
apertural characteristics of P. alabamensis more closely
resemble those of G. cretacea than do those of typical P.
extensa (compare Plates 63 and 65); however, the exact
phylogenetic relationship of Parvularugoglobigerina ala¬
bamensis to Parvularugoglobigerina extensa is unclear, in part
because the first known occurrence of P. extensa is stratigraph-
ically lower than the first known occurrence of P. alabamensis.
It appears likely that either P. alabamensis evolved from G.
cretacea independently of P. extensa (Liu and Olsson, 1992) or
P. alabamensis was ancestral to P. extensa, but the known
stratigraphic record of P. alabamensis is incomplete. The first
hypothesis is stratigraphically simpler, but evolutionarily more
complex, than the second because the former necessarily entails
iterative evolution of four-chambered parvularugoglobigerine
morphotypes from G. cretacea.

TYPE Locality. —Forty feet above the base of the Clayton
Fm. at Millers Ferry, Alabama.

Repository. —Holotype (USNM 460338) and paratypes
(USNM 460339-460342) deposited in the Cushman Collec¬
tion, National Museum of Natural History. Examined by SD,
CL, and RKO.

Parvularugoglobigerina eugubina (Luterbacher
and Premoli Silva, 1964)

Figure 33; Plate 66: figures 1-12; Plate 67: figures 1-14

Globigerina anconitana Luterbacher and Premoli Silva, 1964:107, pi. 2: fig.

3a-c [ Globigerina eugubina Zone, Gubbio, central Appenines, Italy],
Globigerina eugubina Luterbacher and Premoli Silva, 1964:105, pi. 2: fig.
8a-c [Globigerina eugubina Zone, Gubbio, central Appenines, Italy],—
Premoli Silva and Bolli, 1973:526, pi. 7: figs. 2-5 [Globigerina eugubina
Zone: figs. 2-4, DSDP Site 152/10/1: 127-130 cm; fig. 5, DSDP Site
152/10/CC; Nicaragua Rise, Caribbean Sea],—Smit, 1982:339, pi. 1: figs.
1-20, pi. 2: figs. 1-8 [Zone Pa, Gredero, southeastern Spain].—Keller,
1988:257, pi. 3: figs. 8-10 [Zone Pa, El Kef, Tunisia]; 1989:321, pi. 6: figs.
3, 6 [Zone Pa, Brazos River, Texas].

Globigerina sabina Luterbacher and Premoli Silva, 1964:108, pi. 2: fig. 6a-c
[Globigerina eugubina Zone, Gubbio, central Appenines, Italy].

Globigerina umbrica Luterbacher and Premoli Silva, 1964:106, pi. 2: fig. 2a-c
[Globigerina eugubina Zone, Gubbio, central Appenines, Italy].
Globorotalia (Turborotalia ) cf. hemisphaerica (Morozova).—Blow,
1979:1077, pi. 64: fig. 8 [Zone Pa, DSDP Hole 47.2/11/3: 148-150 cm;
Shatsky Rise, northwestern Pacific Ocean],

Globorotalia ( Turborotalia) longiapertura Blow, 1979:1085, pi. 56: figs. 3, 4
[Zone Pa, DSDP Hole 47.2/11/6: 148-150 cm], pi. 58: figs. 3-5 [Zone Pa,
DSDP Hole 47.2/11/5: 148-150 cm], pi. 63: figs. 1-9 [Zone Pa, DSDP Hole
47.2/11/4: 148-150 cm], pi. 68: fig. 3 [Zone Pa, DSDP Hole 47.2/11/3:
148-150 cm], pi. 72: fig. 1 [given as Zone PI, DSDP Hole 47.2/11/1:
148-150 cm; Shatsky Rise, northwestern Pacific Ocean],

Globorotalia ( Turborotalia )? cf. pentagona (Morozova).—Blow, 1979:1088,
pi. 64: fig. 1 [Zone Pa, DSDP Hole 47.2/11/4: 148-150 cm; Shatsky Rise,
northwestern Pacific Ocean].

Globorotalia (Turborotalia) cf. tetragona (Morozova).—Blow, 1979:1113, pi.
64: fig. 7 [Zone Pa, DSDP Hole 47.2/11/3: 148-150 cm; Shatsky Rise,
northwestern Pacific Ocean] [in part, not pi. 67: fig. 5],

84

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Postrugoglobigerina hariana Salaj, 1986:53, pi. 3: figs. 1-3, 5 [base of
Danian, El Haria, Tunisia].

Globigerina cf. edita (Subbotina).—Keller, 1988:257, pi. 3: fig. 18 [Zone Pa,
El Kef, Tunisia],

Globigerina {Eoglobigerina) hemisphaerica Morozova.—Keller, 1988:257 pi.
3: figs. 6, 7 11 [Zone Pa, El Kef, Tunisia], [Not Globigerina {Eoglobiger¬
ina) hemisphaerica Morozova, 1961.]

Globigerina {Eoglobigerina) taurica Morozova.—Keller, 1988:257, pi. 3: figs.
4, 5 [Zone Pa, El Kef, Tunisia]. [Not Globigerina {Eoglobigerina) taurica
Morozova, 1957.]

Parvularugoglobigerina eugubina (Luterbacherand Premoli Silva).—D’Hondt
and Keller, 1991:96, pi. 4: figs. 4-6 [Zone Pa, DSDP Site 577/12/5:
115-117 cm; Shatsky Rise, northwestern Pacific Ocean],—Liu and Olsson,
1992:345, pi. 3: figs. 1-11 [Zone Pa, Pine Barren Mbr., Clayton Fm.,
Millers Ferry, Alabama], [Not Hofker, 1978:60, pi. 2: figs. 6-10, pi. 3: figs.
1 , 2 .]

Parvularugoglobigerina longiapertura (Blow).—D’Hondt and Keller,
1991:96, pi. 4: figs. 7 8 [Zone Pa, DSDP Site 577/12/5: 115-117 cm;
Shatsky Rise, northwestern Pacific Ocean],

Parvularugoglobigerina morphotype 3, D’Hondt and Keller, 1991:93, pi. 3:
figs. 10, 11 [Zone Pa, DSDP Site 577/12/5: 115-1 17 cm; Shatsky Rise,
northwestern Pacific Ocean].

Parvularugoglobigerina cf. eugubina (Luterbacher and Premoli Silva).—Liu
and Olsson, 1992:345, pi. 3: fig. 12 [Zone Pa, Pine Barren Mbr., Clayton
Fm., Millers Ferry, Alabama],

ORIGINAL Description. —“Test very small, trochospiral;
umbilical side flat, spiral side almost flat; the initial part of the
spire is slightly raised relative to the final whorl. Composed of
12 to 14 globular chambers, disposed in 2 x h whorls; the final
whorl contains 6 chambers that increase gradually in size. The
final chamber occupies about ‘/4 to Vs of the test’s surface. The
periphery is lobate. Sutures depressed and radial on the
umbilical side, depressed and slightly arcuate on the spiral side.
Umbilicus quite large. Aperture at the base of the final chamber
in an umbilical position. Surface slightly rugose.

Dimensions:

holotype

length

0.13 mm

width

0.095 mm

depth

0.06 mm.

paratypes

A

B

length

0.11 mm

0.13 mm

width

0.105 mm

0.11 mm

depth

0.045 mm

0.055 mm.

(Luterbacher and Premoli Silva, 1964:105; translated from
Italian.)

Diagnostic Characters. —Test a small trochospire with
2 '/2 whorls, each whorl with 4'/2—8 inflated subglobular
chambers; chambers increasing slowly in size; first and last
whorls usually with same number of chambers. Spire height
low to moderate. Test wall microperforate, well-preserved
specimens sometimes exhibit surficial pore-mounds (Plate 67:
Figure 14). Aperture elongate, marked by thickened rim;
apertural position ranges from umbilical to nearly peripheral
(Plates 66, 67). Individual specimens sometimes exhibit dorsal
aperture (Plate 66: Figure 6) or both dorsal and umbilical
apertures on final chamber (Plate 66: Figure 9); some showing
more than one dorsal aperture.

Discussion. —Premoli Silva and Bolli (1973) declared
Globigerina umbrica Luterbacher and Premoli Silva, 1964, and
Globigerina sabina Luterbacher and Premoli Silva, 1964, to be
junior synonyms of Globigerina eugubina Luterbacher and
Premoli Silva, 1964. This broadened the concept of eugubina
to include moderately spired forms with 4'/2 chambers in the
final whorl (Globigerina sabina ) and forms with 7 chambers in
the final whorl (Globigerina umbrica). We also include in this
broadened concept Globigerina anconitana Luterbacher and
Premoli Silva (1964), a species that was described from the
same assemblage as these species. Smit (1982) first noted that
Globorotalia longiapertura Blow, 1979, is a junior synonym of
Globigerina eugubina Luterbacher and Premoli Silva.

Following Premoli Silva and Bolli (1973) and Smit (1982),
we treat several intergrading morphotypes as variants of P.
eugubina (Plates 66, 67). These include a moderately spired
form with 4'/2-5 chambers (Plate 66: Figures 1, 2, Plate 67:
Figures 13, 14) in each whorl (= Globigerina sabina
Luterbacher and Premoli Silva, 1964; Globorotalia (Turboro-
talia) longiapertura paratypes of Blow, 1979, Plate 63: Figures
1-3; Parvularugoglobigerina morphotype 3 of D’Hondt and
Keller, 1991; Parvularugoglobigerina cf. eugubina of Liu and
Olsson, 1992) and a relatively low-spired form characterized by
5-8 chambers per whorl (Plate 66: Figures 7, 8, 10-12, Plate
67: Figures 1,3, 10, 12) that has an apertural extension from the
umbilicus to a near peripheral location and slightly more
embracing chambers with less deeply incised sutures (the
longiapertura morphotype of Blow, 1979).

Globigerina minutula Luterbacher and Premoli Silva, 1964,
was described along with Globigerina eugubina from the
Gubbio section. The holotype drawing of G. minutula
illustrates a very low trochospiral, 3-chambered form, which
closely resembles Plate 65: Figure 13 that was selected from the
type level. The specimen is completely recrystallized so that it
is uncertain whether it is a microperforate or normal perforate
taxon. Consequently, given its generalized morphology, we
cannot accurately identify this taxon.

Although badly preserved, the type specimen of Postrugog¬
lobigerina hariana Salaj, 1986, is indistinguishable from
Parvularugoglobigerina eugubina. The holotype of P. hariana
is a low trochospiral form with a pore-mound surface texture,
five globular chambers in each of two whorls, a low rate of
chamber expansion, and a “narrow slot-like interiomarginal
umbilical aperture at the base of the last chamber” (Salaj,
1986:53). Consequently, Postrugoglobigerina hariana Salaj,
1986, is regarded as a junior synonym of Parvularugoglobiger¬
ina eugubina (Luterbacher and Premoli Silva, 1964). In
addition, we include in P. eugubina a number of forms
identified by Blow (1979) and Keller (1988) to various species
of cancellate Danian species (see synonomy). The illustrations
of Blow and Keller clearly show a microperforate wall
structure; therefore, these identifications are incorrect. The
general morphology of their illustrated forms falls within the
broadened concept of P. eugubina.

NUMBER 85

85

FIGURE 33. —Paleobiogeographic map showing distribution of Parvularugoglobigerina eugubina (Luterbacher
and Premoli Silva) in Zone Pa.

Stable Isotopes. —Oxygen isotopic data suggest that P.
eugubina occupied a slightly deeper or cooler-season planktic
niche than co-occurring G. cretacea and Woodringina spp.
(Boersma et al., 1979; Boersma, 1984a; D’Hondt and Zachos,
1993).

Stratigraphic Range. —Zone Pa.

Global Distribution. —Biogeographic data indicate that
P. eugubina was a low to middle latitude taxon with an
open-ocean affinity (Premoli Silva and Bolli, 1973; Premoli
Silva and Boersma, 1989; D’Hondt, 1991; D’Hondt and Keller,
1991; Liu and Olsson, 1992) (Figure 33).

Origin of Species. —This species evolved from Guembe-
litria cretacea via Parvularugoglobigerina extensa at the base
of Zone Pa.

Repository. —Holotype (No. C20532) and paratype (Nos.
C20554, C20555) are deposited in the Basel Museum of
Natural History, Switzerland.

Parvularugoglobigerina extensa (Blow, 1979)

Plate 65: figures 7-13

Woodringina hornerstownensis group, Premoli Silva and Bolli, 1973:538, 540,
pi. 6: fig. 10, pi. 7: fig. 1 [Globigerina eugubina Zone, DSDP Site 150/10/2:
78-50 cm; Caribbean Sea], [Not Olsson, I960.]

Eoglobigerinal extensa Blow, 1979:1220, pi. 69: fig. 7 [Zone PI, DSDP Hole
47.2/11/3: 0-5 cm], pi. 74: figs. 1, 2 [Zone PI, DSDP Hole 47.2/11/3:
148-150 cm; Shatsky Rise, northwestern Pacific Ocean].

Eoglobigerinal fodina Blow, 1979:1221, pi. 57: figs. 5, 6 [Zone Pa, DSDP
Hole 47.2/11/5: 148-150 cm; Shatsky Rise, northwestern Pacific Ocean].
Globigerina minutula Luterbacher and Premoli Silva.—Smit, 1982:338, pi. 3:
figs. 3-6 [Zone Pa, Gredero, southeastern Spain], [Not Luterbacher and
Premoli Silva, 1964.]

Globoconusa conusa (Khalilov).—Keller, 1988:257, pi. 3: figs. 12-14 [Zone
POb, El Kef, Tunisia]; 1989:319: figs. 3, 9-11 [Zone Pa, Brazos River,
Texas]. [Not Khalilov, 1956.]

Parvularugoglobigerina morphotype 1, D’Hondt and Keller, 1991:93, pi. 3:
figs. 3-5, 7-10 [figs. 3, 4, 7-10, Zone Pa, DSDP Site 577/12/5: 115-117
cm; Shatsky Rise, northwestern Pacific Ocean; fig. 5, lower Danian, Brazos
River, Texas],

Parvularugoglobigerina morphotype 2, D’Hondt and Keller, 1991:96, pi. 41:
figs. 1, 2 [Zone Pa, DSDP Site 577/12/5: 115-117 cm; Shatsky Rise,
northwetem Pacific Ocean].

Parvularugoglobigerina aff. eugubina (Luterbacher and Premoli Silva).—Liu
and Olsson, 1992:345, pi. 2: figs. 8-11 [Zone Pa, Pine Barren Mbr., Clayton
Fm., Millers Ferry, Alabama].

Original Description. —“The small test is coiled in a
distinct, tightly expressed, trochospire with 9-10 chambers
comprising the spire and four chambers in the last whorl. In
dorsal aspect, the chambers are inflated, closely appressed,
closely-set and quite strongly embracing and the dorsal
intercameral sutures are subradially to sinuously disposed. The
dorsal and ventral intercameral sutures are depressed to
moderately incised. In ventral aspect, the chambers are inflated,
subglobular, but embracing. The umbilicus is closed and the
aperture extends from the umbilicus extensively towards the

86

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

anterior side of the last chamber and is a widely open, almost
rectangular, opening bordered by a weakly developed but
thickened porticus. The equatorial profile is strongly lobulate
but almost circular in outline whilst the axial profile shows the
distinct early trochospire and subglobular nature of the later
chambers. The wall is very finely perforate and the mural-pits
are very widely and sparsely developed; the mural pores do not
open into pore pits but the wall bears fine pustules which may
be the bases of normal spines. Maximum diameter of holotype
0.198 mm. as measured electronically. The name extensa
derives adjectively from the extensive nature of the aperture.”
(Blow, 1979:1220.)

Diagnostic Characters. —Characterized by 2‘/2 whorls,
each composed of 3 V 2 —4 inflated subglobular chambers,
increasing slowly in size. Aperture centrally located, umbili-
cal-extraumbilical, marked by distinct lip, often elongate, and
often asymmetrically oriented. Test wall microperforate.
Despite original description, pustules are not bases of normal
spines but guembelitriid pustules typically either perforated by
pores (pore-mounds) or peripherally associated with pores.

DISCUSSION. — Parvularugoglobigerina extensa is a moder¬
ately high-spired form and is morphologically intermediate
between Guembelitria cretacea and Parvularugoglobigerina
eugubina. Parvularugoglobigerina extensa primarily differs
from G. cretacea sensu stricto by possessing 3 V 2 —4 (rather
than 3) chambers in the outer whorl and by typically having an
elongate aperture that extends extraumbilically.

Eoglobigerina^ fodina Blow, 1979, was originally described
as characterized by a small but open umbilicus and a circular
aperture “extending from the opening in a slightly oblique
manner, into the terminal face of the last chamber” (Blow,
1979:1221). The name fodina was derived from the Latin word
for pit or tunnel and applied to the apertural shape, which was
described as looking like the entrance to a London Under¬
ground Railway tunnel (Blow, 1979:1221). The slight differ¬
ences between the holotypes of extensa and fodina result from
elongation of the former’s aperture toward the umbilicus.
Given the extreme plasticity of apertural morphology and
location in related taxa (i.e., Parvularugoglobigerina eugubina
and Woodringina species), such minor differences appear
insufficient to maintain extensa and fodina as separate taxa.
Consequently, we have reduced Eoglobigerina! fodina Blow,
1979, to a junior synonym of Parvularugoglobigerina extensa
(Blow, 1979). In addition, the 3'/2-4 chambered inflated
subglobular, microperforate forms described by Premoli Silva
and Bolli (1973), Smit (1982), Keller (1988), D’Hondt and
Keller (1991), and Liu and Olsson (1992) under various names
(see synonomy) are placed in P. extensa.

Although Blow (1979:1220) provisionally placed extensa
and fodina in the genus Eoglobigerina, he recognized their
microperforate structure as quite “distinct from the normal
perforate, cancellate or reticulate, wall of the eobulloides-
trivialis-edita group.” On that basis, he expressed doubt that
assignment of those forms to Eoglobigerina would be

maintained in future studies. On the basis of wall structure and
texture, Blow (1979) suggested that extensa and fodina (=
extensa ) were more closely related to Globastica (= Globocon-
usa ) daubjergensis than to any other species assigned to
Eoglobigerina. He further hypothesized that “either fodina or
extensa might be ancestral to daubjergensis or, alternatively the
various forms only share a common ancestor” (Blow,
1979:1221). The latter interpretation is consistent with the
present hypothesis that Globoconusa daubjergensis and Parvu¬
larugoglobigerina extensa both evolved directly from Guem¬
belitria cretacea (Olsson, 1970, 1982; Premoli Silva, 1977;
Smit, 1982; Liu and Olsson, 1992; Olsson et al., 1992).
Stable Isotopes. —No data available.

Stratigraphic Range. —Upper Zone P0 through Zone Pa.
GLOBAL Distribution. —Similar to Parvularugoglobiger¬
ina eugubina.

ORIGIN OF Species. —This species evolved from Guembe¬
litria cretacea.

Repository. —Holotype (BP Cat. No. 39/60) and paratype
(BP Cat. No. 40/24) are deposited at The Natural History
Museum, London. Examined by GJ.

Genus Woodringina Loeblich and Tappan, 1957

Type Species. — Woodringina claytonensis Loeblich and
Tappan, 1957b.

Original Description. —“Test free, early stage with a
single whorl of three chambers, followed by a biserial stage;
chambers inflated; wall calcareous, radial in structure, finely
perforate; aperture a low arched slit, bordered above by a slight
lip. Family Heterohelicidae. Paleocene. Monotypic.” (Loeblich
and Tappan, 1957b:39.)

Diagnostic Characters. —Tests contain an initial whorl
of 3 chambers, later whorls of 2 chambers each. Test wall
microperforate, marked by a guembelitriid surface texture
(smooth walled or bearing perforate pustules). Aperture usually
asymmetrically positioned and thin apertural lip infolded on
one side.

Discussion. —Although Woodringina remains limited to
the Paleocene, it is no longer monotypic. It was assigned to the
subfamily Guembelitriinae by Loeblich and Tappan (1957b).
Elevation of the subfamily Guembelitriinae to the family
Guembelitriidae (El-Naggar, 1971; Blow, 1979; Loeblich and
Tappan, 1988) removed it from the family Heterohelicidae.

Woodringina claytonensis Loeblich and Tappan, 1957

Plate 13: figures 6-8; Plate 68: figures 1-6

Woodringina claytonensis Loeblich and Tappan, 1957b:39: fig. la-d [lower
Danian, Pine Barren Mbr., Clayton Fm., Alabama]; 1957a: 178, pi. 40: fig. 6
[holotype reillustrated].—D’Hondt, 1991:172, pi. 1: figs. 8, 11, 12 [figs. 8,
12, DSDP Site 577/12/5: 94-96 cm; fig. 11, lower Danian, Brazos River,
Texas], pi. 2: figs. 4, 12 [DSDP Site 577/12/5: 94-96 cm; Shatsky Rise,
northwestern Pacific Ocean],—Liu and Olsson, 1992:341, pi. 1: figs. 4-6

NUMBER 85

87

[Zone Pa, Pine Barren Mbr., Clayton Fm., Millers Ferry, Alabama],—
MacLeod, 1993:61, pi. 3: figs. 8-14 [ODP Hole 690C/15X/2: 28-30 cm;
Maud Rise, Southern Ocean],

Woodringina hornerstownensis Olsson.—Keller, 1988:257, pi. 3: fig. 15 [Zone
Pa, El Kef, Tunisia]; 1989:319: figs. 3-6 [lower Danian, Brazos River,
Texas]. [Not Woodringina hornerstownensis Olsson, I960.]

Woodringina kelleri MacLeod, 1993:63, pi. 4: figs. 1-3 [Danian, DSDP Site
577A/12/2: 44-46 cm; Shatsky Rise, northwestern Pacific Ocean],
Woodringina cf. kelleri MacLeod, 1993:63, pi. 3: figs. 4, 5, 12 [Zone Pa, El
Kef, Tunisia],

Original Description. —“Test free, tiny, flaring rapidly;
early stage with a single whorl of three chambers (reduced
‘triserial’), commonly followed by three or more, rarely up to
five, pairs of biserial chambers, the plane of biseriality slightly
twisted in development; chambers few in number, subglobular,
increasing rapidly in size; sutures distinct, constricted; wall
calcareous, finely perforate and very finely hispid; aperture a
low arched slit bordered above by a slight lip, somewhat
asymmetrical in position.

“Length of holotype 0.15 mm.; greatest breadth 0.12 mm.
Other specimens range from 0.12 to 0.22 mm. in length.”
(Loeblich and Tappan, 1957b:39.)

Diagnostic Characters. —In general, original description
accurately describes diagnostic features of W. claytonensis,
except for description of microperforate wall as hispid. Some
specimens smooth-walled (Loeblich and Tappan, 1988), others
characterized by presence of scattered pore-mounds (Plate 68:
Figure 6). In other respects, species highly variable
morphologically, with apertural height varing from high to low.
Twisted plane of biseriality, apertural asymmetry, and triserial-
ity of the first whorl more strongly pronounced in some
specimens than in others within same assemblages.

DISCUSSION. —MacLeod (1993:92) described Woodringina
kelleri as distinguished from Woodringina claytonensis by the
former’s “laterally compressed adult chambers, and ... its large
elongate aperture that is surrounded by a well-developed
discontinuous apertural rim;” however, the final chambers of
both holotypes are similarly subglobular in edge and plan view
(compare MacLeod, 1993, pi. IV: figs. 1-3 to Loeblich and
Tappan, 1957b, pi. 39: fig. 1; see also Plate 13: Figures 6, 7).
The only other figured specimen identified by MacLeod (1993)
as W. kelleri also lacks laterally compressed chambers and
closely resembles the W claytonensis holotype in the shape of
its final chambers (compare D’Hondt, 1991, pi. 2: fig. 4 to
Loeblich and Tappan, 1957b, pi. 39: fig. 1). Comparison of the
respective apertural characteristics of W claytonensis and W
kelleri is complicated by the absence of W claytonensis
paratype specimens and the physical obstruction of the W
claytonensis holotype aperture. Nonetheless, the W claytonen¬
sis holotype also appears to have a large elongate aperture
surrounded by a well-developed, discontinuous apertural rim
(Plate 13: Figure 7). The aperture of the W. kelleri holotype
(Plate 13: Figure 8) does appear to be more centrally located
than that of the W. claytonensis holotype. This difference
appears insufficient to warrant maintenance of W kelleri as a

separate taxon, given the pronounced variability in position,
height, and number of apertures exhibited by otherwise similar
specimens in populations of Woodringina and other guembe-
litriid genera (i.e., Guembelitria and Parvularugoglobigerina).
Hence, we consider Woodringina kelleri MacLeod, 1993, a
junior synonym of Woodringina claytonensis Loeblich and
Tappan, 1957.

Stable Isotopes. —The stable isotopic signature of this
species suggests an affinity for relatively warm near-surface
water masses (D’Hondt and Zachos, 1993).

Stratigraphic Range. —Basal Zone Pa to Zone Plb.
GLOBAL Distribution. — Woodringina claytonensis was
most abundant in low-latitude open-ocean assemblages
(D’Hondt and Keller, 1991; Liu and Olsson, 1992). It was rare
in high-latitude open-marine environments (Liu and Olsson,
1992).

Origin of Species. —This species is considered to have
descended from Guembelitria cretacea (Olsson, 1970, 1982;
Smit, 1977, 1982; D’Hondt, 1991; Li and Radford, 1991;
Olsson etal., 1992; Liu and Olsson, 1992). D’Hondt (1991) and
Liu and Olsson (1992) illustrated forms that are morphologi¬
cally intermediate between Guembelitria cretacea Cushman,
1933, and Woodringina claytonensis Loeblich and Tappan,
1957. Such morphotypes are triserial in early whorls and
biserial in later whorls ( Guembelitria irregularis Morozova,
1961, of D’Hondt, 1991) (Plate 63: Figure 12; Plate 68: Figure
5).

Repository. —Holotype (USNM P5685) deposited in the
Cushman Collection, National Museum of Natural History.
Examined by SD, CL, and RKO.

Woodringina hornerstownensis Olsson, 1960

Figure 34; Plate 13: figures 4, 5; Plate 68: figures 7-14

Woodringina hornerstownensis Olsson, 1960:29, pi. 4: figs. 18, 19 [Zone P3b,
Homerstown Fm., New Jersey],—D’Hondt, 1991:172, pi. 2: figs. 5-8 [figs.
5, 8, Zone Pla, DSDP Site 577/12/4: 34-36 cm; Shatsky Rise, northwestern
Pacific Ocean; figs. 6, 7, Zone P3b, Homerstown Fm., New Jersey].—Liu
and Olsson, 1992:341, pi. 1: fig. 8 [Midway Group, Plummer Stop 14,
Kaufman Co., Texas].—MacLeod, 1993:63, pi. 4: figs. 6, 7, 11, 13 [lower
Danian, El Kef, Tunisia],

Chiloguembelitria taurica Morozova.—Keller, 1988:257, pi. 3: fig. 3 [Zone
Pa, El Kef, Tunisia]. [Not Chiloguembelitria taurica Morozova, 1961.]

Original Description. —“Test small, elongate, slightly
twisted, rather rapidly tapering, about twice as long as broad.
Initial end consists of whorl of three chambers, rest of test
consists of biserial arrangement of chambers. Wall smooth,
surface of last two chambers may be finely spinose, especially
near the aperture. Chambers numerous, somewhat inflated,
wider than high, increasing more rapidly in width than height as
added. Sutures distinctly depressed, nearly at right angles to
axis of test. Aperture a low arch at one side of final chamber,
directed inward, with a small lateral flange along the periphery.
Length 0.15 mm. Width 0.10 to 0.15 mm.” (Olsson, 1960:29.)

88

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Diagnostic Characters. —Test wall microperforate; aper¬
ture marked by a thin lip. Apertural position and height
somewhat variable. Biserial portion of test distinctly twisted,
although less so than W claytonensis. Woodringina horner-
stownensis distinguished from W. claytonensis by “the elon¬
gate tapering test and the almost straight sutures” (Olsson,
1960:29). Woodringina hornerstownensis often with six or
more pairs of biserial chambers, whereas W claytonensis
usually limited to five or fewer.

DISCUSSION. —The holotype illustration and description of
Chiloguembelina taurica Morozova, 1961, closely resembles
W hornerstownsis Olsson, 1960. Chiloguembelina taurica was
originally described as being characterized by a “high narrow
test, weakly compressed bilaterally, its height two to three
times the width. Lateral outlines at first subtriangular, later
almost parallel” (Morozova, 1961:18). The test of C. taurica is
formed of 10-12 spheroidal chambers, and its intercameral
sutures are almost straight. Although not visible in the holotype
illustrations, the aperture of C. taurica was described as
semicircular and basal (Morozova, 1961). Based on its type
illustration and description, Chiloguembelina taurica Mo¬
rozova, 1961, should be considered a possible junior synonym
of Woodringina hornerstownensis Olsson, 1960. The holotype
illustrations and descriptions of Heterohelix gradata Khalilov,
1967, and Heterohelix gradata normalis Khalilov, 1967, also
closely resemble Woodringina hornerstownensis Olsson, 1961.
Heterohelix gradata normalis was originally described as
being characterized by an elongate “wedge-shaped [test],
gradually broadening toward the obliquely trimmed-off apertu¬
ral end ... chambers biserially arranged, in each offset row there
are 6-8 spherical chambers. ... Aperture semilunate, much
shifted from the median frontal position and shielded on one
side by a moderately protruding lip” (Khalilov, 1967:173).
From this description H. gradata normalis is indistinguishable
from W. hornerstownensis in general test morphology. Further¬
more, it appears to share the asymmetry of apertural shape and
position that is diagnostic of Woodringina and related taxa.
Heterohelix gradata sensu stricto was distinguished from H.
gradata normalis by its last 4-10 chambers being much larger
than the preceding chambers (Khalilov, 1967). It also appears
to share the chamber shape, adult chamber arrangement, and
apertural asymmetry of W. hornerstownensis. Given the
general congruence of their original illustrations and descrip¬
tions with W. hornerstownensis, Heterohelix gradata Khalilov
and H. gradata normalis Khalilov should be considered
possible junior synonyms of W. hornerstownensis Olsson,
1960. The original descriptions of H. gradata and H. gradata
normalis stated that the tests of these taxa are covered with
large pores (Khalilov, 1967). If so, these taxa are distinguish¬
able from W. hornerstownensis on the basis of wall structure.
Close examination of wall structure and other relevant
characters (i.e., the presence or absence of initial triseriality) in
type populations of H. gradata and H. gradata normalis are
necessary to conclusively define the taxonomic status of these
taxa relative to W. hornerstownensis.

Stable Isotopes. —Biogeographic and stable isotopic data
suggest an open-ocean, warm shallow-water habitat for W.
hornerstownensis, similar to that of W. claytonensis (D’Hondt
and Keller, 1991; Liu and Olsson, 1992; D’Hondt and Zachos,

1993) .

Stratigraphic Range. —Zone Pa to Zone P3b.

Global Distribution. —Widespread in high and low
latitudes (Figure 34).

Origin of Species. —This species is generally considered to
have descended from Guembelitria cretacea via W. claytonen¬
sis (Olsson, 1970, 1982; Smit, 1977, 1982; D’Hondt, 1991; Li
and Radford, 1991; Olsson et al., 1992; Liu and Olsson, 1992).

Repository. —Holotype (USNM 626457) deposited in the
Cushman Collection, National Museum of Natural History.
Unfigured paratypes deposited at Princeton University (No.
81038) and Rutgers University (No. 5026). All specimens
examined by SD, CL, and RKO.

Family Chiloguembelinidae Reiss, 1963
(by S. D’Hondt and B.T. Huber)

Original Description. —“Trochospirally coiled with two
chambers per coil arranged around an elongated axis. Test
usually twisted. Aperture single, an interiomarginal asymmetri¬
cal low to high arch, bordered by an asymmetrically situated
flap which is often protruding and platelike, or terminal,
situated on a short neck. No distinct toothplates. Ornamentation
if present consisting of inflational papillae or short spines.”
(Ruess, 1963:55.)

Diagnostic Characters. —Small test comprised of biseri¬
ally arranged chambers, often with a slightly twisted coiling
axis. Intercameral sutures distinct, depressed, and often
somewhat oblique. Wall calcareous and microperforate with
smooth to pustulous surface texture. Aperture arched, rimmed
by narrow lip, and generally infolded on one side of ultimate
chamber. Many Chiloguembelina species with well-developed
flap or flange bordering aperture along infolded side.

Discussion. —As noted in the discussion of the Guembe-
litriidae, the Chiloguembelinidae appears to be a monophyletic
or paraphyletic family descended from Guembelitria cretacea
via Woodringina claytonensis (Olsson, 1970, 1982; Premoli
Silva, 1977; Smit, 1982; D’Hondt, 1991; Li and Radford, 1991;
Liu and Olsson, 1992; Olsson et al., 1992). It is generally
believed that this family was monophyletic throughout the
Paleocene. It’s post-Paleocene status is less clear, as the
relationships of Chiloguembelina to such late Paleogene and
Neogene taxa as Streptochilus Bronnimann and Resig, 1971,
and Cassigerinella Pokorny, 1955, is presently uncertain.

Reiss (1963) originally assigned both Chiloguembelina and
Zeauvigerina to the Chiloguembelinidae. Given the Late
Cretaceous occurrence of Zeauvigerina (Huber and Boersma,

1994) and the earliest Paleocene derivation of Chiloguembelina
from a guembelitriid ancestor, retention of this assignment

NUMBER 85

89

180°W

135°W

90°W

45°W

45°E

90°E

FIGURE 34.—Paleobiogeographic map showing distribution of Woodringina hornerstownensis Olsson in Zones
PI to P3.

would render the Chiloguembelinidae a polyphyletic group. On
these grounds, Zeauvigerina should no longer be assigned to
the Chiloguembelinidae.

Genus Chiloguembelina Loeblich and Tappan, 1956

TYPE Species. —Chiloguembelina midwayensis (Cushman,
1940).

Original Description. —“Test free, flaring; inflated cham¬
bers biserially arranged, with a tendency to become somewhat
twisted; sutures distinct, depressed; wall calcareous, finely
perforate, radial in structure, surface smooth to hispid; aperture
a broad low arch bordered with a pronounced neck-like
extension of the chamber; commonly this forms a more
strongly developed flap at one side, so that the aperture appears
to be directed toward one of the flat sides of the test.” (Loeblich
and Tappan, 1956:340.)

Diagnostic Characters. —The original description is
diagnostic of many Chiloguembelina species (i.e., Chiloguem¬
belina midwayensis (Cushman, 1940), C. crinita (Glaessner,
1937b), and C. morsei (Kline, 1943)). The diagnostic charac¬
ters of Chiloguembelina species include the microperforate
surface texture, slight twisting of the coiling axis, and infolding
of the apertural lip on one side. The apertural flap noted by
Loeblich and Tappan (1956) and Reiss (1963) characterizes C.

midwayensis and closely related taxa (C. morsei and C. crinita).
This flap is located on the apertural side that is not infolded and
results from extension of the apertural lip (and its trailing
chamber wall) over the preceding chamber. The apertural
infolding and opposing flap render the chiloguembelinid
aperture distinctly asymmetric with respect to the plane of
biserial symmetry. This apertural asymmetry and twisting of
the coiling axis are much reduced in the late Paleocene taxa
Chiloguembelina trinitatensis (Cushman and Renz, 1942) and
Chiloguembelina wilcoxensis (Cushman and Ponton, 1932).
Apertural asymmetry is variably expressed in C. wilcoxensis;
although apertural asymmetry occurs in early ontogeny, the
apertures of terminal chambers appear to be symmetric in some
C. wilcoxensis specimens and asymmetric in others (Plate 70:
Figures 11, 12, 16, 17).

DISCUSSION. —The microperforate surface texture, apertural
asymmetry, and twisted coiling axis are the primary features
that unite Chiloguembelina species with woodringinids and
other Paleocene descendants of Guembelitria cretacea. The
biserial first whorl of Chiloguembelina species distinguishes
them from Woodringina species.

Beckmann (1957) proposed that Giimbelina trinitatensis
Cushman and Renz and Giimbelina wilcoxensis Cushman and
Ponton descended from Chiloguembelina crinita (Glaessner).
On this basis, Beckmann (1957) assigned trinitatensis and
wilcoxensis to the genus Chiloguembelina.

90

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Chiloguembelina crinita (Glaessner, 1937)

Plate 69: figures 1-8

Giimbelina crinita Glaessner, 1937b:383, pi. 4: fig. 34a,b [Paleocene, beds
from Goijatschij Kljutsch].

Chiloguembelina crinita (Glaessner).—Beckmann, 1957:89, text-figs. 14
(1-4), pi. 21: fig. 4a,b [ Globorotalia pseudomenardii and Globorotalia
velascoensis Zones (Zones P4 and P5), lower Lizard Springs Fm.,
Trinidad].—Loeblich and Tappan, 1957a: 178, pi. 49: fig. 1 [upper
Paleocene, Homerstown Fm., New Jersey], pi. 51: figs, la-3 [Vincentown
Fm., New Jersey], pi. 56: fig. la,b [Aquia Fm., Maryland], pi. 60: fig. 6
[Nanafalia Fm., Alabama], pi. 62: fig. 1 [Velasco Fm., Mexico],—MacLeod,
1993:66, pi. 6: figs. 1,2, 5, 6 [lower Zone P6, ODP Hole 738C/10R/4: 34-36
cm; Kerguelen Plateau, southern Indian Ocean], [Not Huber, 1991 b:448, pi.
6: figs. 2, 3; 1991c:461, pi. 2: figs. 3, 4.]

Original Description. —“Test small, built up with about
10-15 spherical or oval-shaped, distinct, separated chambers.
The spire of the initial chambers in existing specimens is not
distinctly recognizable. The ratio of chamber width to the
length varies strongly. The largest diameter of the last chamber
is offset from the biserial plane. Consequently, the last chamber
diagonally overlies the previous one, the median suture on both
sides are not opposite each other and the test appears thereby
somewhat distorted. The aperture opens not in the usual case
towards the edge of the test, but in a direction which lies
between the edge and the side of the test. In extreme cases, it is
directed even along the suture of the last chamber in side view.
The aperture is moderate in width, but high, half rounded and
enclosed along the margin. The test surface in many specimens
is covered by fine granulations, but in spite of their minuteness
especially on the periphery, [there are] distinctly visible sharp
tiny protuberances.

“Measurements.—length 0.17-0.22 mm.; width 0.10-0.15
mm.; thickness 0.05-0.1 mm.” (Glaessner, 1937b:383; trans¬
lated from German.)

Diagnostic Characters. —Test biserial throughout,
exhibiting characteristic chiloguembelinid apertural asymme¬
try; aperture marked by narrow lip, infolded on one side, and
expanded into distinct apertural flange on opposite side. As
noted by Beckmann (1957) and Loeblich and Tappan (1957a),
later chambers subglobular. Sutures distinct and depressed.
Test microperforate and last chambers finely hispid.

DISCUSSION. —The later chambers of Chiloguembelina crin¬
ita specimens are much higher and more inflated than those of
C. midwayensis and C. morsei. These differences are readily
observable, as late-stage chambers of C. crinita appear
subglobular in edge and plan views.

Stable Isotopes.—-N o data available.

Stratigraphic Range. —Lower Zone P4 to lower Zone P6.
Global Distribution. —Cosmopolitan.

ORIGIN OF Species.— Chiloguembelina crinita is believed to
have evolved from C. midwayensis (Beckmann, 1957).

Repository. —Holotype deposited in the Collections of the
Institute for Fuel-Research of the Academy of the Sciences of
Russia (Paleontology Division), Moscow.

Chiloguembelina midwayensis (Cushman, 1940)

Figure 35; Plate 13: figures 9, 10, 12, 13; Plate 69: figures 16-22

Giimbelina midwayensis Cushman, 1940:65, pi. 11: fig- 15 [Paleocene, Sumter
Co., Alabama].—Cushman and Todd, 1946:58, pi. 10: fig. 15 [Paleocene,
Arkansas],—Cushman, 1951:37, pi. 11: figs. 7, 8 [Paleocene, Alabama,
Arkansas, and Texas],

Chiloguembelina midwayensis (Cushman).—Loeblich and Tappan, 1957a: 179,
pi. 41: fig. 3 [Danian, Clayton Fm., Alabama], pi. 43: fig. 7a,b [Wills Point
Fm., Texas], pi. 45: fig. 9a,b [Porters Creek Clay, Alabama].—D’Hondt,
1991:173, pi. 2: fig. 13 [Zone Pa, DSDP Site 528/31/CC: 14-15 cm; Walvis
Ridge, South Atlantic Ocean], fig. 14 [Zone Pa, DSDP Site 577/12/5: 34-36
cm; Shatsky Rise, northwestern Pacific Ocean], [Not Olsson, 1970:601, pi.
91: fig. 8.—MacLeod, 1993:66, pi. 6: figs. 3, 4, 7-10.—Huber and Boersma,
1994:282, pi. 3: fig. 3a-d.]

Chiloguembelina midwayensis midwayensis (Cushman).—Beckmann,
1957:90, text-fig. 14 (24-27), pi. 21: fig. la,b [ Globorotalia trinidadensis
through Globorotalia velascoensis Zones, lower Lizard Springs Fm.,
Trinidad].

Chiloguembelina midwayensis strombiformis Beckmann, 1957:90, text-fig. 14
(28-31), pi. 21: fig. 6a-c [Globorotalia pseudomenardii and Globorotalia
velascoensis Zones, lower Lizard Springs Fm., Trinidad].

Original Description. —“Test small, compressed, usually
twice as long as broad, rapidly tapering, with the greatest
breadth formed by the last pair of chambers, periphery rounded
throughout, lobulate; chambers with breadth and height about
equal, slightly overlapping, inflated, increasing rapidly in
height as added; sutures distinct, depressed, very slightly
curved, wall finely spinose; aperture high, arched, with distinct
lateral flanges [sic]. Length 0.18-0.22 mm.; breadth 0.10-0.12
mm.; thickness 0.05 mm.” (Cushman, 1940:65.)

Diagnostic Characters. —Test small, compressed in
thickness (depth), and rapidly tapering. Early chambers
subspherical, successive chambers increase more rapidly in
breadth than in height. Late-stage chambers cross the coiling
axis and overlap immediately preceding chamber. In holotype,
overlap so pronounced that maximum breadth of final chamber
nearly equal to maximum breadth of test (Plate 13: Figures 9,
10). Holotype’s surface covered with numerous small pustules;
however, last two chambers contain few pustules. Contrary to
the original description, aperture of each chamber with only
one distinct lateral flange (the chiloguembelinid “flap” of
Loeblich and Tappan, 1956) (Plate 69: Figures 16-22).

DISCUSSION. — Chiloguembelina midwayensis strombi¬
formis Beckman, 1957, was erected as a Paleocene subspecies
of Chiloguembelina midwayensis (Cushman, 1940). The
chambers of the C. midwayensis strombiformis holotype (Plate
13: Figures 12, 13) expand much more rapidly in depth
(thickness) than do those of C. midwayensis sensu stricto; in
late-stage chambers of C. midwayensis sensu stricto, chamber
breadth consistently exceeds chamber depth.

Stable Isotopes. —The stable isotopic signature of C.
midwayensis suggests that this species inhabited a deeper-
water or cooler-season habitat than most co-occurring taxa
(Boersma and Premoli Silva, 1983; D’Hondt and Zachos,
1993).

NUMBER 85

91

FIGURE 35.—Paleobiogeographic map showing distribution of Chiloguembelina midwayensis (Cushman) in the
Danian. “s.l.” refers to sensu lato forms found at high latitude sites.

Stratigraphic Range. —Zone Pa (D’Hondt, 1991) to
Zone P5 (Beckman, 1957; Boersma, 1984b).

GLOBAL Distribution. —Chiloguembelina midwayensis
occurred at low and middle latitudes (Beckmann, 1957;
Boersma, 1984b; D’Hondt and Keller, 1991; Liu and Olsson,
1992) (Figure 35).

ORIGIN of Species. —Chiloguembelina midwayensis
evolved from C. morsei (Kline) (D’Hondt, 1991).

Repository. —Holotype (USNM CC35715) deposited in
the Cushman Collection, National Museum of Natural History.
Examined by SD, BTH, CL, and RKO.

Chiloguembelina morsei (Kline, 1943)

Plate 13: figures 14, 15; Plate 69: figures 9-15

Gumbelina morsei Kline, 1943:44, pi. 7: fig. 12 [Danian, Porters Creek Clay,
Clay Co., Mississippi].

Chiloguembelina morsei (Kline).—Loeblich and Tappan, 1957a: 179, pi. 40:
fig. 2a,b [Danian, Erslev, Mors, Denmark], pi. 41: fig. 4 [Clayton Fm.,
Alabama], pi. 42: fig. la,b [Brightseat Fm., Maryland], pi. 43: fig. 2 [Kincaid
Fm., Texas], pi. 43: fig. 6a,b [Wills Point Fm., Texas]. [Not Huber,
1991a:448, pi. 6: figs. 6, 7.]

Chiloguembelina midwayensis (Cushman).—MacLeod, 1993:66, pi. 6: figs. 3,
4 [Danian, DSDP Hole 577A/12/2: 44-46 cm; Shatsky Rise, northwestern
Pacific Ocean],

Original Description. —“Test small, about twice as long

as broad, regularly tapering, with greatest breadth at apertural
end, periphery rounded and lobulate; chambers with breadth
greater than height, inflated, increasing rapidly in size,
especially in breadth; sutures distinct, depressed; wall finely
but distinctly spinose; aperture high, arched, with distinct
lateral flanges [sic].” (Kline, 1943:44.)

Diagnostic Characters. —Test biserial throughout. Su¬
tures distinct and depressed; basal sutures separating earliest
chambers subhorizontal, those separating later chambers
oblique. Successive chambers overlap, particularly in late
ontogeny. Initial chambers subspherical. Chamber breadth
increases more rapidly than chamber depth, with successive
chambers exhibiting a greater breadth to depth ratio than
predecessor, consequently, maximum breadth of each late-
stage chamber greater than its maximum depth. Surface of
holotype test marked by numerous small pustules; pustules less
abundant on final chambers. Aperture of each chamber
exhibiting only one distinct lateral flange.

DISCUSSION. —The gross morphology of Chiloguembelina
morsei is very similar to that of Chiloguembelina midwayensis.
Loeblich and Tappan (1957a) suggested that C. morsei can be
distinguished from C. midwayensis sensu stricto by the
former’s narrower test, more globular chambers, and more
deeply constricted sutures. The two taxa are most readily
distinguished by the narrowness of their tests; the chambers of

92

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

C. morsei expand less rapidly in breadth than those of C.
midwayensis. Consequently, the periphery of the former
defines a more acute angle (~50°) than that of the latter (~60°).
Forms intermediate between C. morsei and C. midwayensis
have been illustrated as C. midwayensis by D’Hondt
(1991:173, pi. 2: figs. 13, 15).

Stable Isotopes. —-No data available.

Stratigraphic Range. —Zone Pa (D’Hondt, 1991) to
Subzone Pic (Boersma, 1984b).

Global Distribution. —Low and middle latitudes
(Boersma, 1984b; D’Hondt and Keller, 1991).

ORIGIN of Species.— Chiloguembelian morsei evolved from
a Woodringina species in Zone Pa (D’Hondt, 1991; Liu and
Olsson, 1992).

Repository. —Holotype (USNM 487301) deposited in the
Cushman Collection, National Museum of Natural History.
Examined by SD, BTH, and RKO.

Chiloguembelina subtriangularis Beckmann, 1957

Plate 13: figures 17, 18; Plate 70: figures 1-7

Chiloguembelina subtriangularis Beckmann, 1957:91, text-fig. 15 (39-42), pi.

21: fig. 5a,b [Paleocene, Globorotalia pusilla pusilla Zone, lower Lizard

Springs Fm., Trinidad].—Said and Kerdany, 1961:331, pi. 2: fig. 6

[Paleocene, lower part of Esna Shale, Farafra Oasis, Egypt],

Original Description. —“Test small, subtriangular,
pointed at the base, compressed, with a subangular periphery.
Chambers biserial, very slightly inflated. Sutures nearly
horizontal, slightly depressed, at least in the later stages. Wall
smooth. Aperture commonly slightly eccentric, semicircular to
subquadrangular, may have a slight collar.” (Beckmann,
1957:91.)

Diagnostic Characters. —Test small, biserial with a
subangular periphery, subtriangular in side view. Chambers
increasing nearly twice as rapidly in breadth than in height,
slightly inflated, successive chambers slightly overlapping
previous chambers, sutures somewhat depressed and nearly
straight, forming a low angle with the growth axis. Aperture a
low, asymmetrically positioned, interiomarginal arch sur¬
rounded by a lip that narrows toward center of chamber. Length
140-220 pm.

DISCUSSION. —This species is easily distinguished from
other chiloguembelinids by its subtriangular test with a
subangular periphery.

Stable Isotopes.—N o data available.

Stratigraphic Range. —Zone Pic to Zone P3.

Global Distribution. —Reported from the low to middle
latitudes worldwide.

ORIGIN of Species. —Beckmann (1957) suggested that C.
subtriangularis descended from C. midwayensis during the
Paleocene.

REPOSITORY. —Holotype (USNM P5783), figured paratypes
(USNM P5784A-D), and unfigured paratypes (USNM P5785)

deposited in the Cushman Collection, National Museum of
Natural History. Examined by SD and BTH.

Chiloguembelina trinitatensis (Cushman and Renz, 1942)

Plate 13: figures 11, 16; Plate 70: figures 8-10, 14

Gumbelina trinitatensis Cushman and Renz, 1942:8, pi. 2: fig. 8 [Paleocene,
Soldado Fm., Trinidad].

Chiloguembelina trinitatensis (Cushman and Renz).—Beckmann, 1957:91,
text-fig. 15 (43-45), pi. 21: fig. 7a,b [ Globorotalia velascoensis Zone,
Lizard Springs Fm., Trinidad].

Original Description. —“Test slightly longer than broad,
moderately compressed, rapidly tapering, greatest breadth
formed by the last-formed pair of chambers, periphery rounded,
lobulate; chambers with breadth and height about equal, the
last-formed pair in the adult usually much larger than the
remainder of the test; sutures distinct, depressed, straight,
nearly at right angles to the elongate axis; wall smooth or
slightly hispid, aperture high, arched. Length of holotype 0.27
mm; breadth 0.20 mm; thickness 0.15 mm.” (Cushman and
Renz, 1942:8.)

Diagnostic Characters. —Distinguished by biserial test
with chambers increasing uniformly in breadth and height, and
symmetrically centered, low-arched aperture surrounded by
narrow, equidimensional lip.

Discussion. —The holotype of this species differs from C.
crinita by having an aperture that is symmetrically positioned
on the chamber face, and it differs from C. wilcoxensis by its
smaller size and slower, more continuous chamber-size
increase. The holotype has been extensively recrystallized so
the primary wall texture is difficult to discern.

Stable Isotopes.—N o data available.

Stratigraphic Range. —Zone P5 to lower Zone P6a. In
Trinidad, Beckman (1957) recorded C. trinitatensis only in the
Morozovella velascoensis Zone (= Zone P5), but observations
by BTH suggest it ranges from Zone P5 to Zone P6a at DSDP
Site 152.

Global Distribution. —Reported primarily from low-
latitude, near-shore marine sections.

Origin of Species. —Beckmann (1957) suggested that C.
trinitatensis descended from C. crinita during the Paleocene,
but see discussion under C. wilcoxensis.

Repository. —Holotype (USNM CC38198) deposited in
the Cushman Collection, National Museum of Natural History.
Examined by BTH.

Chiloguembelina wilcoxensis (Cushman and Ponton, 1932)

Plate 13: figures 19, 20; Plate 70: figures 11-13,15-18

Giimbelina wilcoxensis Cushman and Ponton, 1932:66, pi. 8: figs. 16, 17
[lower Eocene, Wilcox Fm., Ozark, Alabama],

Chiloguembelina wilcoxensis (Cushman and Ponton).—Beckmann, 1957:92,
text-fig. 15 (49-58), pi. 21: figs. 10, 12, 13 [upper Paleocene to lower
Eocene, Lizard Springs Fm., Trinidad].—Huber, 1991 b:440, pi. 6: figs. 4, 5

NUMBER 85

93

[Zone AP6a, early Eocene, ODP Hole 738C/8R: 264.35 mbsf; Kerguelen

Plateau, southern Indian Ocean].

Original Description. —“Test biserial, periphery broadly
rounded; chambers distinct, much inflated, increasing very
rapidly in the adult so that the last four chambers make up a
very considerable amount of the entire test; sutures distinct,
depressed; wall distinctly papillate throughout; aperture a low
opening at the base of the last-formed chamber in the median
line. Length 0.45 mm; breadth 0.35 mm; thickness 0.25 mm.”
(Cushman and Ponton, 1932:66.)

Diagnostic Characters. —Distinguished by large test
size, broadly rounded periphery, rapid chamber-size increase in
initial portion of test, and symmetrically centered, low-arched
to semicircular aperture surrounded by an equidimensional lip.

DISCUSSION. —The final chamber in adult Chiloguembelina
wilcoxensis may be normalform to strongly kummerform. The
aperture on the final chamber may be a symmetrical low to
moderately high semicircular arch, centered on the chamber
face, and bordered by an equidimensional lip (Plate 70: Figures
11, 12), or they may be slightly asymmetrical, off-centered on
the final chamber face, and bordered by an inequidimensional
lip that is slightly infolded on one side (Plate 70: Figure 16).

The symmetrical shape and positioning of the aperture and
equidimensional bordering lip on adult specimens of C.
wilcoxensis are reminiscent of the Cretaceous Heterohelicidae.
Dissection of adult tests with symmetrical apertures in the
center of the final chamber, however, reveal that the apertures
on pre-adult chambers are asymmetrical in position and shape
and the bordering lip is infolded on one side (Plate 70: Figure
12). Apertural asymmetry in early ontogeny is taken to
represent a primitive feature shared with the chiloguembelinid
stock, whereas apertural symmetry in adult specimens is
considered a derived character that first appeared in C.
trinitatensis. Chiloguembelina wilcoxensis differs from this
species by its larger, less tapering test.

Stable Isotopes.—-N o data available.

Stratigraphic Range. —Zone P4 to Zone P6a. The FAD
of C. wilcoxensis is not well-constrained in published deep-sea
records because many authors have not differentiated the
chiloguembelind species. In Trinidad, Beckmann (1957)
recorded the FAD of C. wilcoxensis in the Globorotalia
pseudomenardii Zone (= Zone P4), with an uncertain occur¬
rence within the lower part of this zone, and the LAD at the top
of the Globorotalia velascoensis Zone (= Zone P5). Observa¬
tions by BTH of high-latitude samples from ODP Sites 698,
700, and 738 indicate that the FAD of this species is in the
middle of Zone AP4 (~Zone P4) and its LAD in Zone AP6a
(~Zone P6a).

Global Distribution. —Reported from low to high lati¬
tudes worldwide.

Origin of Species. —Although Beckmann (1957) suggested
that C. wilcoxensis descended from C. crinita during the late
Paleocene, it is more likely that C. wilcoxensis was derived

from C. trinitatensis during the late Paleocene because C.
wilcoxensis and C. trinitatensis are more similar morphologi¬
cally, and the study of Caribbean DSDP Site 152 indicates that
the first occurrence of C. trinitatensis is older than that of C.
wilcoxensis (B. Huber, pers. observ., 1995). Both species have
a similar pustulose wall texture suggesting that they are
phylogenetically related (Plate 70, compare Figures 14 and 18).

REPOSITORY. —Holotype (USNM 16218) deposited in the
Cushman Collection, National Museum of Natural History.
Examined by BTH.

Family Heterohelicidae Cushman, 1927
(by B.T. Huber)

Original Description. —“Test in the more primitive forms
planospiral in the young, later becoming biserial, in the more
specialized genera the spiral stage and even the biserial stage
may be wanting and the relationships shown by other
characters; wall calcareous, perforate, ornamentation in higher
genera bilaterally symmetrical; aperture when simple, usually
large for the size of the test, without teeth, in some forms with
apertural neck and phialine lip.” (Cushman, 1927:59.)

Diagnostic Characters. —Test with biserial arrangement
of alternating chambers, final arrangement either multiple or
uniserial; chambers, globular to ovoid in shape; wall smooth or
striated with fine to coarse parallel ridges; aperture, a low,
symmetrical arch, usually at base of ultimate chamber, may be
terminal, may have accessory sutural apertures.

DISCUSSION. —Only simple, biserial forms survived into the
Cenozoic. The latter portion of the test often becomes uniserial.

Genus Rectoguembelina Cushman, 1932

Type Species. — Rectoguembelina cretacea Cushman, 1932.

Original Description. —“Test with the early chambers
arranged in a biserial manner similar to Guembelina, later
chambers uniserial and rounded in transverse section; cham¬
bers all inflated, distinct; sutures distinct, depressed; wall
calcareous, thin, very finely perforate; aperture in the early
stages similar to Guembelina in the adult terminal, rounded,
with a distinct neck.” (Cushman, 1932:6.)

Diagnostic Characters. —Transition from biserial to
uniserial portion of test very abrupt, occurring after first four or
more pairs of biserial chambers, without an intervening interval
of gradually increasing chamber overlap. Apertures on biserial
portion interiomarginal with a small, narrow arch; apertures on
uniserial chambers terminal, circular, and aligned in rectilinear
fashion, without lip or toothplate. Wall calcareous, microperfo-
rate; surface smooth to finely pustulose.

Discussion. —Glaessner (1936) and Montanaro Gallitelli
(1957) considered Rectoguembelina to be a junior synonym of
Tubitextularia Sulc (type species = Pseudotextularia bohemica
Sulc, 1929), whereas Loeblich and Tappan (1964, 1988)

94

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

synonymized both of these genera under Bifarina Parker and
Jones (type species = Dimorphina saxipara Ehrenberg, 1854).
Comparison of the type species of Rectoguembelina with the
type species of Bifarina and Tubitextularia, however, reveals
significant differences. The holotype illustration of Dimor¬
phina saxipara, which is a cross-sectional view, shows a
tubular extension between the apertures of successive uniserial
chambers (Loeblich and Tappan, 1988, pi. 491: fig. 4), and the
apertures on the uniserial chambers of Pseudotextularia
bohemica are described and illustrated as alternating from one
side of the chamber to the other (Sulc, 1929, pi. 1: figs. 6-16);
however, the uniserial apertures of R. cretacea lack any tubular
extensions and are terminal in position. Rectoguembelina
cretacea also differs from P. bohemica and D. saxipara by
having a greater number of chambers, which are less globular
and more distinctly biserial prior to the onset of the uniserial
growth stage. Based on comparison of the type species,
Tubitextularia is retained as a junior synonym of Bifarina,
whereas Rectoguembelina is resurrected to accomodate the
distinctly different R. cretacea.

The holotype and paratypes of Rectoguembelina texana
Cushman and R. trinitatensis Cushman and Renz are more
appropriately assigned to Bifarina because the biserial stage is
only represented by two to four very globular chambers, the
wall texture is hispid rather than smooth, and the apertures on
the uniserial chambers alternate from one side to the other prior
to the final chamber. Presently, R. cretacea is the only species
placed in Rectoguembelina.

Rectoguembelina differs from Zeauvigerina by having
several, rather than one, fully uniserial chambers following the
biserial stage. The early ontogeny of both taxa are similar
though, as the biserial chambers have an asymmetrically
positioned aperture surrounded by a narrow, equidimensional
lip.

Stratigraphic Range. —Maastrichtian through Zone P2.
Global Distribution. —Low to middle latitudes.

Origin of Genus. —Probably derived from the same
Laeviheterohelix stock that gave rise to the Zeauvigerina
plexus.

Rectoguembelina cretacea Cushman, 1932

Plate 13: figures 1, 2; Plate 71: figures 24-26

Rectogiimbelina cretacea Cushman 1932:6, pi. 1: figs. 11, 12 [upper

Maastrichtian, Arkadelphia Clay, Hope, Arkansas],

Tubitextularia laevigata Loeblich and Tappan, 1957a: 180, pi. 41: fig. 6 [lower

Paleocene, McBryde Limestone Mbr., Clayton Fm., Wilcox Co., Alabama],

Original Description. —“Test consisting of two unequal
portions, the early portion consisting of several pairs of
globular chambers arranged as in Guembelina, the adult stage
uniserial, formed usually by three subglobular or slightly
pyriform chambers, slightly overlapping, the apertural end
extended out into a tapering neck; sutures distinct, depressed;
wall smooth, translucent, very finely perforate; aperture

circular, at the end of the tubular neck. Length 0.25-0.35 mm;
breadth 0.08-0.10 mm; thickness 0.05-0.07 mm.” (Cushman,
1932:6.)

Diagnostic Characters.—D istinguished by small, elon¬
gate biserial to uniserial test, usually with 2-4 uniserial
chambers arranged in rectilinear fashion and bearing simple,
terminal, round to oval-shaped aperture on short neck.

DISCUSSION. —The Paleocene holotype of T. laevigata
Loeblich and Tappan is very similar to the R. cretacea holotype
(Plate 13: Figures 1, 2) except for the presence of more globular
chambers in the uniserial growth stage. Paleocene specimens of
Rectoguembelina from DSDP Site 357, however, bear uniserial
chambers that range in shape from the globular forms of the T.
laevigata holotype to forms identical to the R. cretacea
holotype (Plate 71: Figures 24-26). It is on this basis that T.
laevigata is considered a junior synonym of R. cretacea.

Stable Isotopes. —Stable isotopic evidence that R. creta¬
cea inhabited upper surface waters is presented in Huber and
Boersma (1994, table 1; = T. laevigata). The oxygen isotopic
data reveal that R. cretacea was more than 1.5 %o more
negative than the co-occurring benthic species Nuttalites
truempyi, and it was more than 0.5 %o more negative than three
other planktonic species ( Globoconusa daubjergensis,
Globanomalina compressa, and Globanomalina sp.).

Stratigraphic Range. —Maastrichtian through Zone P2.

Global Distribution. —This species has a very irregular
distribution, occurring only in near-shore sediments during the
Maastrichtian and in offshore sediments at several deep sea
sites during the Paleocene, ranging from the low to middle
latitudes.

ORIGIN OF Species. —The origin of R. cretacea is uncertain,
but test dissections have revealed that apertures in the biserial
growth stage are asymmetrically positioned and partially
surrounded by a narrow lip of equidimensional thickness,
which is identical to the apertures on biserial chambers of
Zeauvigerina waiparaensis. This suggests that Rectoguembe¬
lina and Zeauvigerina shared a common phylogenetic stock,
and Laeviheterohelix is suggested as the most closely related
ancestral taxon based on similarities discussed in Huber and
Boersma (1994).

Repository. —Holotype (USNM CC16308) deposited in
the Cushman Collection, National Museum of Natural History.
Examined by BTH.

Genus Zeauvigerina Finlay, 1939

Type Species. — Zeauvigerina zelandica Finlay, 1939.

Original Description. —“Genus similar to Eouvigerina in
size, biserial arrangement of most chambers and spout-like
uvigerine aperture, but differing in first and last stages. The
early chambers show not the slightest trace, even in the
microspheric form, of spiroplectine coiling; the final chambers
have no tendency to become irregularly triserial, the whole test
being regularly bolivine throughout.

NUMBER 85

95

“The general similarities to Eouvigerina (especially of the
aspera and gracilis type, which have somewhat the same
ornament) are so marked that close relationship must surely
exist. If so, the elision of the theoretical coiled early chambers
and the more settled and compact development throughout is
probably due to the later appearance in time of this genus,
Eouvigerina proper being an Upper Cretaceous form, while the
New Zealand development is Upper Middle Eocene.” (Finley,
1939:541.)

Diagnostic Characters. —Distinguished by biserial
chamber arrangement with tendency in adult specimens toward
development of uniserial final chamber with near terminal or
terminal, oval-shaped aperture, partially or entirely surrounded
by thickened, equidimensional lip. In pre-adult chambers,
aperture a low, interiomarginal arch partially bordered by
narrow, equidimensional lip. Wall calcareous, microperforate;
surface smooth to finely pustulose.

DISCUSSION. —There has been some disagreement about the
suprageneric classification of Zeauvigerina and whether or not
this is a planktonic or benthic taxon. In his original description
of this genus, Finlay (1939) noted similarities in chamber
arrangement and morphology of the necked aperture between
Zeauvigerina and the benthic taxon Eouvigerina and suggested
a strong likelihood that these were closely related. Following
Finlay’s (1939) comments, Loeblich (1951) emended the
definition of Eouvigerina to accomodate Zeauvigerina as a
junior synonym. This classification was later adopted in
Loeblich and Tappan (1964). In their more recent classification
of foraminifera, Loeblich and Tappan (1988) resurrected the
genus Zeauvigerina but placed it in the benthic superfamily
Loxostomatacea without an explanation for this reallocation. In
contrast, Finlay (1947) noted that broken specimens of Z. teuria
resemble Giimbelina (= Chiloguembelina) and suggested that
Zeauvigerina was probably planktonic. Beckmann (1957)
further noted that the necked, terminal aperture occurs only in
the final chamber, and the earlier apertures are interiomarginal,
semicircular, and eccentric in position, similar to Chiloguembe¬
lina, whereas the earlier chambers in Eouvigerina have tubular
projections usually connected by a thin, band-like structure.
Consequently, Beckmann (1957) and Reiss (1963) considered
Zeauvigerina to be closely related to Chiloguembelina. This
classification was followed by Jenkins (1965, 1971) and other
subsequent workers until Huber and Boersma (1994) placed
Zeauvigerina in the Heterohelicidae based on biometric and
stratophenetic evidence. The generic description of Zeauviger¬
ina was modified by the latter authors to accomodate wholly
biserial forms of Z. waiparaensis (Jenkins, 1965) and “Z. ”
virgata (Khalilov, 1967).

Zeauvigerina has been variously interpreted as having
inhabited a plantonic or benthic habitat by various authors. The
only stable isotopic data published for species of this genus
were presented by Huber and Boersma (1994), who favored an
interpretation of a planktic mode of life for Z. aegyptiaca, but
suggested a benthic habitat or a deep-dwelling planktic habitat

for Z. waiparaensis. These authors preferred the latter
interpretation based on relative abundance counts of Z.
waiparaensis that were greater than the relative abundance of
all benthic species combined in pelagic carbonate samples they
studied.

Stratigraphic Range.- — Zeauvigerina waiparaensis, the
oldest species assigned to Zeauvigerina, first occurs just below
the base of the Abathomphalus mayaroensis Zone at ODP Site
750 in the Antarctic Indian Ocean and DSDP Site 208 in the
southwestern Pacific Ocean. This genus has not been recorded
elsewhere until the lower Danian at ODP Site 690 (Maud Rise)
and DSDP Site 528 (Walvis Ridge) in the South Atlantic Ocean
and in New Zealand. Zeauvigerina zelandica, which has the
highest range of the zeauvigerinids, last occurs in the Kaiatan
Stage (upper Eocene) in New Zealand.

Global Distribution. —Worldwide in high to low lati¬
tudes.

ORIGIN OF genus. —Probably derived from Laeviheterohe-
lix (Heterohelicidae) during the late Campanian or early
Maastrichtian.

Zeauvigerina aegyptiaca Said and Kenawy, 1956

FIGURE 36a; Plate 71: figures 19, 20

Zeauvigerina aegyptiaca Said and Kenawy, 1956:141, pi. 4: fig. 1 [Paleocene,
Esna Shale, measured section at Nekhl, 29°50'N, 33°34'E, northern Sinai,
Egypt].—Beckmann, 1957:92, text-fig. 15 (59-62), pi. 21: figs. 9a,b, 11
[upper Paleocene, Lizard Springs Fm„ Trinidad],—Huber and Boersma,
1994:271, pi. 2: figs. 6-8 [upper Paleocene, DSPD Site 98/12/1: 119-120
cm; Blake Plateau, western North Atlantic Ocean].

Original Description.— “Test small, about twice as long
as broad, gradually broadening from the subacute initial end to
the point of greatest breadth, which is slightly above the
middle, after which the sides become parallel; periphery
slightly rounded, in transverse section some what rectangular;
biserial throughout; chambers broader than high, indistinct;
sutures indistinct, slightly depressed; wall smooth; aperture
rounded, at the end of a short but distinct neck, with a
weakly-developed lip. Length 0.3 mm; breadth 0.2 mm.” (Said
and Kenawy, 1956:141.)

Diagnostic Characters. —Test variable in shape and size,
length 150-370 pm, with elliptical to moderately tapering
outline and rounded periphery. Most specimens biserial with
uniserial final chamber and a terminal aperture produced on
short neck with a poorly to well-developed surrounding lip.
Less common forms biserial throughout with off-centered
interiomarginal aperture.

Discussion. —Unlike the late Paleocene higher latitude
zeauvigerinids, Z. aegyptiaca usually produces a final uniserial
chamber with a distinct neck and bordering rim or lip, but,
within the population of Z. aegyptiaca, there are a few uniserial
specimens lacking a neck. These are very similar to Z. teuria
Finlay from New Zealand and may have been derived from that
species during the late Paleocene.

96

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

FIGURE 36.—Primary types of Zeauvigerina : a, Zeauvigerina aegyptiaca Said
and Kenawy, holotype, USNM P4091, side view; b, Zeauvigerina teuria
Finlay, paratype, USNM 689029, side view. (Scale bars = 100 pm.)

Ontogenetic growth patterns of Z. aegyptiaca were charac¬
terized for populations from DSDP Site 98 and for two of
Beckmann’s (1957) USNM hypotypes (Huber and Boersma,
1994: fig. 8). The growth trajectories show two patterns: one
group includes specimens from DSDP Site 98 that are smaller
than 200 pm and the other group, which includes the Trinidad
hypotypes and several DSDP Site 98 specimens, reaches nearly
300 pm in length, has a more rapid chamber growth rate, and
attains cross-sectional chamber areas that are more than twice
the maximum values of the smaller forms. The former group
shows growth patterns that are nearly identical to those of Z
waiparaensis (Jenkins, 1965). Because some intermediate
forms also occur in the DSDP Site 98 populations, all of these
forms are considered the same species.

Whereas the apertural necks and bordering rims are rather
weakly developed in most Z. aegyptiaca specimens, these
features are very pronounced on some forms (e.g., Plate 71:
Figure 20). Some of the latter specimens closely resemble Z.
zelandica Finlay, which was described from the Eocene in New
Zealand. Biometric comparison of Z. aegyptiaca and Z.
zelandica may reveal that these species are synonymous.

STABLE Isotopes. —Stable isotopic data for Zeauvigerina
aegyptiaca were reported in Huber and Boersma (1994, table
1). The S 18 0 values for this species are very close to co-existing
Chiloguembelina strombiformis (= C. midwayensis), inter¬
mediate between the benthic Nuttalites truempyi and the
planktic S. triloculinoides, but considerably more negative
(>l%o) than A. mckannai. The 8 13 C values are much
closer to co-occurring planktonic species than to N. truempyi.

Stratigraphic Range. —Said and Kenawy (1956) identi¬
fied Z. aegyptiaca from the Paleocene Esna Shale of Sinai and

noted two occurrences of this species within the underlying
Maastrichtian chalk. The Cretaceous occurrence of Zeauviger¬
ina, however, was not confirmed in subsequent studies of
Maastrichtian sediments underlying the Esna Shale at other
sites in Egypt (Said and Kerdany, 1961; Said and Sabry, 1964).
In fact, Said and Sabry (1964) stated that Z. aegyptiaca is a
Landenian (upper Paleocene) index species, but they did not
mention a previous occurrence in Maastrichtian sediments
elsewhere. Zeauvigerina aegyptiaca was also reported by
Beckmann (1957) from the lower Lizard Springs Formation in
Trinidad, ranging from the Globorotalia pseudomenardii Zone
through the G. velascoensis Zone (upper Paleocene), and by
McGowran (1964) from the Kings Park Shale (Paleocene) in
Western Australia. This species also occurs in upper Paleocene
sediments from DSDP Sites 95 and 98 on Blake Plateau.

Global Distribution.—W orldwide in the middle to low
latitudes.

Origin of Species. —This species is probably derived from
Z. teuria Finlay during the late Paleocene (Huber and Boersma,
1994).

Repository. —Holotype (USNM P4091) deposited in the
Cushman Collection, National Museum of Natural History
(Figure 36a). Examined by BTH.

Zeauvigerina teuria Finlay, 1947

Figure 366

Zeauvigerina teuria Finlay, 1947:276, pi. 4: figs. 49-54 [Paleocene, type
Teurian Te Uri Stream section, Porangahau Survey District, New Zea¬
land],—Jenkins, 1971:70, pi. 1: Figs. 22, 23 [holotype reillustrated], figs.
24-26 [topotypes].—Webb, 1973:543, pi. 2: figs. 3, 4 [Paleocene, DSDP
Site 208/30/1: 112-114 cm; Lord Howe Rise, Tasman Sea], [Not Huber,

1991 b:461, pi. 2: fig. 2.]

Original Description. —“Large for the genus, U/2 times
length of zelandica, but more than twice its full size, stouter and
thicker. Final chamber with flattish top instead of tapering to
spout aperture, otherwise similar in chamber arrangement,
proportions, and sutures. Very finely and densely roughened all
over by minute papillae instead of actual fine, sharp spines.
Aperture normal, at end of a short thick central tubular neck
with distinct rim. Size, 0.45 mm.

“Broken specimens are easily confused with Gumbelina,
which has more spherical chambers, deeper sutures, and when
unbroken the characteristic quarter-moon-shaped aperture. It is
quite probable, however, that Zeauvigerina was derived from
Gumbelina and was pelagic. In the overlying Waipawan
[Paleocene] superficially similar specimens are all true Gumbe¬
lina, the accompanying Zeauvigerina being the much smaller
zelandica and the smooth parri." (Finlay, 1947:276.)

Diagnostic Characters. —Distinguished from Z. parri
and Z. waiparaensis by larger size and presence of necked
aperture, and from Z. zelandica Finlay by absence of rim
surrounding terminal aperture.

NUMBER 85

97

DISCUSSION. —Although Jenkins (1971) considered Z.
aegyptiaca to be a junior synonym of Z. teuria, comparison of
USNM paratypes indicates that these are distinct species.
Zeauvigerina aegyptiaca has a more spherical final chamber
and a terminal aperture that is produced on a longer neck and is
surrounded by a narrow rim. It is not clear from the scattered
reports of these latter two species whether their stratigraphic
and biogeographic ranges overlap or are separated by signifi¬
cant gaps.

Stable Isotopes. —-No data available.

Stratigraphic Range. —This species occurs in the middle
Teurian Stage (Danian) in New Zealand (Jenkins, 1971) and
was reported in Danian sediments at DSDP Site 208 (Webb,
1973).

Global Distribution. —Reported only from the middle
latitudes in the Southern Hemisphere (New Zealand, DSDP
Sites 208, and 277).

Origin of Species. —This species probably derived from Z.
waiparaensis (Jenkins) during the Danian (Huber and
Boersma, 1994).

REPOSITORY. —Holotype and three paratypes (Register No.
TF 1245) in the collections of the New Zealand Geological
Survey. Paratype (USNM 689029) deposited in the Cushman
Collection, National Museum of Natural History (Figure 3 6b).
Examined by BTH.

Zeauvigerina waiparaensis (Jenkins, 1965)

Figure 37; Plate 71: figures 1-18

Chiloguembelina waiparaensis Jenkins, 1965:1095, pi. 1: figs. 1-6 [Danian,
Teurian Stage, Globigerina ( Globigerina ) pauciloculata Zone, Middle
Waipara River section, New Zealand]; 1971:68, pi. 1: figs. 10-15 [holotype
and paratypes reillustrated].—Huber, 1991c:461, pi. 2: figs. 5, 6 [lower
Paleocene, ODP Hole 738C/20R: 376.00 mbsf; Kerguelen Plateau, southern
Indian Ocean].

Heterohelix glabrans (Cushman).—Webb, 1973:543, pi. 1: fig. 4 [upper
Maastrichtian, DSDP Site 208/33/4: 128-130 cm; Lord Howe Rise, Tasman
Sea], [Not Cushman, 1938.]

Zeauvigerina waiparaensis (Jenkins).—Huber and Boersma, 1994:276, pi. 1:
figs. 1-10 [fig. la,b, topotype; figs. 2-8, 10, Abathomphalus mayaroensis
Zone, ODP Hole 750A/16R/1: 130-131 cm; fig. 9, Globotruncanella
havanensis Zone, ODP Hole 750A/19R/1: 118-120 cm; Kerguelen Plateau,
southern Indian Ocean], pi. 2: figs. 1-5, 10a,b [fig. la,b, late Paleocene,
ODP Hole 738C/13C/CC; figs. 2-5c, ODP Hole 738C/21R/CC; fig. 10a,b,
ODP Hole 750A/17R/1: 52-54 cm; both Abathomphalus mayaroensis Zone,
Kerguelen Plateau, southern Indian Ocean].

Original Description. —“Test free, small, elongate, bise-
rial, tapering towards the prolocular end, compressed. Cham¬
bers subglobular, 17, the first 7 increasing slowly in size and
the last 10 increasing more rapidly in size. Wall calcareous,
finely perforate. Sutures subparallel in side view, slightly
depressed, distinct. Aperture terminal, oval-shaped, symmetri¬
cal, with its open end towards the penultimate chamber. Length
of holotype 0.26 mm.” (Jenkins, 1965:1095.)

Diagnostic Characters. —Distinguished by small, irreg¬
ular outline of test, uneven biserial chamber addition, and

terminal, oval-shaped aperture on mature specimens. Equidi-
mensional, narrow lip partially surrounds and folds into
aperture.

Discussion. —Biometric study of this taxon revealed con¬
siderable variability in chamber arrangement and apertural
positioning (Huber and Boersma, 1994). This resulted in the
recognition of a sensu stricto form and four forma, including
forma improcera, forma palmula, forma prolata, and forma
velata, which are considered ecophenotypes or ontogenetic
variants. The sensu stricto phenotype conforms to the original
holotype description. Tracings of x-radiograph images reveal a
relatively uniform growth rate up to the ninth or tenth chamber
(or test length of about ~90 pm). This growth stage is followed
by a series of chambers that have a diminished rate of size
increase and are somewhat erratic in their growth pattern.
Zeauvigerina waiparaensis sensu stricto begins to increase
chamber overlap only in the last one or two chambers, and
some chambers become nearly uniserial in position and have a
nearly terminal aperture (e.g, Plate 71: Figures 1-4). The
ultimate chambers of forms included in Z. waiparaensis sensu
stricto are invariably smaller than the penultimate chambers,
unlike specimens included in Z. waiparaensis forma improcera
and Z. waiparaensis forma prolata. Dissection of the ultimate
and earlier chambers of Z. waiparaensis sensu stricto reveals
apertures that are quite different from the nearly terminal final
chamber aperture; the aperture on the juvenile chambers is a
small, semicircular arch oriented to the front of the test,
off-centered, and interiomarginally positioned (Plate 71:
Figures 11, 12). As with the ultimate chamber, an equidimen-
sional, narrow lip partially borders the apertures of juvenile
chambers. These features clearly distinguish taxa included in
the Zeauvigerina plexus from species included in Chiloguem¬
belina, which has a flange-like lip that is inequally broadened
on one side of a narrow and highly arched aperture and that is
oriented to the side of the test.

The forma improcera (Plate 71: Figures 13-15) and forma
prolata (Plate 71: Figures 7, 8) are biserial throughout and have
interiomarginal, low-arched apertures. These are both consid¬
ered immature growth forms of Z. waiparaensis (Huber and
Boersma, 1994). Forma velata (Plate 71: Figures 17, 18) differs
from the other Z. waiparaensis by having a uniserial final
chamber with a terminally positioned aperture. Dissection of
forma velata (Plate 71: Figure 18) reveals an interiomarginal
aperture identical to the improcera and prolata forma.

STABLE Isotopes. — Zeauvigerina waiparaensis sensu lato
yields stable isotopic values that are close to benthic
foraminifer values and consistently more positive in 8 18 0 and
more negative in 5 13 C than co-occurring planktonic taxa
(Huber and Boersma, 1994). A planktic habitat was inferred by
Huber and Boersma (1994) based on relative abundance counts
of Z. waiparaensis, which were greater than the relative
abundance of all benthic species combined in the pelagic
carbonate samples that they studied.

98

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

FIGURE 37. —Paleobiogeographic map showing distribution of Zeauvigerina waiparaensis (Jenkins) in the
Danian.

STRATIGRAPHIC Range. — Zeauvigerina waiparaensis sensu
stricto was described by Jenkins (1965) from Teurian (Danian)
sediments in New Zealand. On the Kerguelen Plateau (ODP
Sites 738 and 750) and Lord Howe Rise (DSDP Site 208), the
improcera, prolata, velata, and sensu stricto forma first appear
in the middle Maastrichtian, just below the base of the
Abathomphalus mayaroensis Zone. These range into, but not
above, the Danian in New Zealand and at the deep sea sites.
Forma palmula has a separate range, first occurring in the upper
Paleocene and last occurring in the lower Eocene.

Global Distribution. —Restricted to the Pacific and
Indian Ocean sectors of the Southern Ocean during the late
Maastrichtian, but the sensu stricto forma is present at DSDP
Site 528 in the Angola Basin in only two samples: at the top of
the Maastrichtian as contaminants (having the color of the
Paleocene forams), and in the lowest Danian (528/31/CC) at the
K/T boundary. Zeauvigerina waiparaensis does not range
farther into the Paleocene at this location and has not been
found in Cretaceous or Paleocene levels at the adjacent DSDP
Site 527 (Figure 37).

Origin of Species. —The origin of this species is uncertain,
but Huber and Boersma (1994) surmised that Laeviheterohelix
was the most likely ancestor because of the similarities in wall
texture, chamber morphology, and apertural features.

Repository. —Holotype and two paratypes (Register No.
TF 1495) in the collections of the New Zealand Geological
Survey.

“Zeauvigerina” virgata (Khalilov, 1967)

Plate 71: figures 21-23

Heterohelix virgata Khalilov, 1967:174, fig. 9a,b [Village of Zeid, northeastern
Azerbaidzhan].

“Zeauvigerina" virgata (Khalilov).—Huber and Boersma, 1994:279, pi. 2:
figs. 9a-c, lla-c [lower Paleocene, ODP Hole 750A/11R/2: 40-42 cm;
Kerguelen Plateau, southern Indian Ocean].

Original Description. —“Test long, compressed bilater¬
ally, slowly becoming broader toward the apertural end; initial
end bluntly compressed, while the apertural end is obliquely
cut off. At the apertural end the rows of chambers are much
shifted with respect to one another. Chambers spherical,
alternating in two rows, forming moderate zigzags along the
depressed spiral suture. Often the initial end of the test is
planispiral. Chambers gradually increase in size toward the
apertural end. Septal sutures depressed, slightly curved.
Aperture semilunate, placed somewhat further on relative to the
frontal plane of the second row of chambers. Wall calcareous,
rows of pores are observed on the surface. Along the length of
the test the number of pores in each row on the chambers
exceeds 3 to 5.” (Khalilov, 1967:174; translated from Russian.)

Diagnostic Characters. —Test elongate with very uni¬
form chamber addition, biserial throughout; aperture interio-
marginal, bordered by an equidimensional, thickened rim or
lip.

NUMBER 85

99

DISCUSSION. —Examination of the holotypes of Heterohelix
oculis Khalilov (labeled H. ocutus on the holotype slide) and H.
virgata Khalilov (first called Heterohelix parallelus, then
revised on the slide) revealed two species that are similar in
most features. The holotype of H. oculis is smaller in size, is
generally thinner side to side, and has a twisted initial portion,
rounder chambers, finer and fewer chambers, and a less
scalloped outline. The holotype of H. oculis resembles the type
figure, but the aperture is not visible; however, the holotype of
H. virgata shows less similarity to the type figure, as the
strongly slanted sutures and distinctive aperture shown in the
illustration are obscured in the holotype. Nonetheless, the
Southern Ocean forms illustrated herein are most similar to the
holotype of H. virgata.

This species resembles Chiloguembelina by having biserial
chambers with an off-centered, asymmetrical aperture, but it
differs from it in that the aperture is forward facing and the
apertural lip is of uniform thickness throughout. It is tentatively
placed in “Zeauvigerina ” because it resembles the immature
growth forms of Z. waiparaensis (forma prolata) in test
coiling, test elongation, chamber number, absence of overlap of
sequential chambers, and in the rounded aperture oriented to
the front of the test (e.g., compare Plate 71: Figures 6-8 with
Plate 71: Figures 21, 22). Biometric analysis by Huber and
Boersma (1994) revealed that “Z. ” virgata can be distin¬
guished from Z. waiparaensis by its greater rate of chamber

inflation that begins half way up the test. SEM illustrations
show that the lip of “Z. ’’ virgata extends fully around the
aperture (Plate 71: Figure 23) in contrast to the partial lip ofZ.
waiparaensis (Plate 71: Figures 5, 16). Although intermediate
forms were not found, Huber and Boersma (1994) suggested
that “Z. ’’ virgata may have been derived from Z. waiparaensis
sensu lato during the Danian. If this can be proven, then the
species “Z. ” virgata and its relatives belong in the genus
Zeauvigerina.

Stable Isotopes.—-N o data available.

STRATIGRAPHIC Range. —“ Zeauvigerina ” virgata was first
identified from the upper Danian of the lower Caucasus where
it is a rare component of faunas in the Zeid section (Khalilov,
1967). These faunas probably belong to upper Danian Zone
Pld, but the full range of “Z.” virgata in the Caucasus is not
currently known. Southern Ocean populations of “Z.” virgata
range from about Zone Plb into Zone P3a, and rare specimens
are found to the top of the Paleocene.

Global Distribution. —Reported from the Caucasus and
the Southern Ocean.

Origin of Species. —Similarity between mature specimens
of “Z” virgata and immature forms of Z. waiparaensis
suggests the former was derived from the latter during the early
Paleocene (Huber and Boersma, 1994).

Repository. —Holotype no. 638 at the Institute of Geology
of the Academy of Sciences of Azerbaidzhan, Baku.

Literature Cited

Alimarina, V.P.

1962. Nekotorye osobennosti razvitiya planktonnykh foraminifer v rannem
paleogene Severnogo Kavkaza [Observations on the Evolution of
Planktonic Foraminifera in the Early Paleogene of the Northern
Caucasus]. Byulleten Moskovskogo Obshchestva Ispytatelei Prirody,
Otdel Geologicheskii, 37:128-129. [In Russian.]

1963. Nekotorye osobennosti razvitiya planktonnykh foraminifer v svyazi
s zonalny ras’cheleniem nizhnogo paleogene severnogo Kavkaza
[Some Peculiarities in the Development of Planktonic Foraminifera
and the Zonation of the Lower Paleogene of the Northern Caucasus],
Voprosy Mikropaleontologii, Akademiya Nauk SSSR, 7:158-195.
[In Russian.]

Aubert, J.

1962. Les Globorotalia de la region prerifaine (Muroc septentrional).
Notes et Memoires du Service Geologique Maroc, 22:1-156.

Bang, I.

1969. Planktonic Foraminifera and Biostratigraphy of the Type Danian. In
P. Bronnimann and H.H. Renz, editors, Proceedings of the First
International Conference on Planktonic Microfossils, 1:58-65.
Geneva.

1979. Foraminifera from the Type Section of the eugubina Zone Compared
with Those from the Cretaceous/Tertiary Boundary Localities in
Jylland, Denmark. Danmarks Geologiske Undersogelse Arbog,
1979:139-165.

Banner, F.T.

1989. The Nature of Globanomalina Haque, 1956. Journal of Foraminif-
eral Research, 19:171-184.

Barron, E.J.

1987. Global Cretaceous Paleogeography: International Geologic Correla¬
tion Programme Project 191. Palaeogeography, Palaeoclimatology,
Palaeoecology, 59:207-216.

Beckmann, J.P.

1957. Chiloguembelina Loeblich and Tappan and Related Foraminifera
from the Lower Tertiary. In A.R. Loeblich, Jr., and collaborators.
Studies in Foraminifera. Bulletin of the United States National
Museum, 215:83-95.

Belford, D.J.

1967. Paleocene Planktonic Foraminifera from Papua and New Guinea.
Bureau of Mineral Resources, Australia, Bulletin, 92:1-33.

1984. Tertiary Foraminifera and Age of Sediments, Ok Tedi-Wabag,
Papua, New Guinea. Bulletin, Bureau of Mineral Resources,
Geology, and Geophysics, Australia, 216:1-52.

Benjamini, C., and Z. Reiss

1979. Wall-hispidity and -perforation in Eocene Planktonic Foraminifera.
Micropaleontology, 7:141-150.

Berggren, W.A.

1960. Paleogene Biostratigraphy and Planktonic Foraminifera of the SW
Soviet Union: An Analysis of Recent Soviet Investigations.
Stockholm Contributions in Geology, 6:63-125.

1962. Some Planktonic Foraminifera from the Maestrichtian and Type
Danian Stages of Southern Scandinavia. Stockholm Contributions in
Geology, 9(1): 106 pages.

1965. Some Problems of Paleocene-Lower Eocene Planktonic Foraminif-
eral Correlations. Micropaleontology, 11:278-300.

1968. Phylogenetic and Taxonomic Problems of Some Tertiary Planktonic
Foraminiferal Lineages. Tulane Studies in Geology and Paleontol¬
ogy, 6:1-22.

1969a. Rates of Evolution in Some Cenozoic Planktonic Foraminifera.
Micropaleontology, 15:351-365.

1969b. Paleogene Biostratigraphy and Planktonic Foraminifera of North¬
western Europe. In P. Bronnimann and H.H. Renz, editors,
Proceedings of the First International Conference on Planktonic
Microfossils, 1:121-160.

1971a. Multiple Phylogenetic Zonations of the Cenozoic Based on
Planktonic Foraminifera. In A. Farinacci, editor. Proceedings of the
II Planktonic Conference, 1:41-56. Rome: Edizioni Tecnoscienza.

1971b. Paleogene Planktonic Foraminiferal Faunas on Legs I-IV (Atlantic
Ocean), JOIDES Deep Sea Drilling Program—a Synthesis. In A.
Farinacci, editor, Proceedings of the II Planktonic Conference,
1:57-77. Rome: Edizioni Tecnoscienza.

1977. Atlas of Palaeogene Planktonic Foraminifera: Some Species of the
Genera Subbotina, Planorotalites, Morozovella, Acarinina and
Truncorotaloides. In A.T.S. Ramsay, editor, Oceanic Micropaleon¬
tology, pages 205-300. London: Academic Press.

1992. Paleogene Planktonic Foraminifera Magnetobiostratigraphy of the
Southern Kerguelen Plateau (Sites 747-749). In S.W. Wise, Jr., R.
Schlich et al., Proceedings of the Ocean Drilling Program, Scientific
Results, 120:551-569. College Station, Texas: Ocean Drilling
Program.

Berggren, W.A., and M.-P. Aubry

1996. A Late Paleocene-Early Eocene NW European and North Sea
Magnetobiochronologic Correlation Network. In R.W.O’B. Knox,
R.M. Corfield, and R.E. Dunnay, editors, Correlation of the Early
Paleogene in Northwest Europe. Geological Society, Special
Publication, 101:309-352.

Berggren, W.A., D.V. Kent, C.C. Swisher, III, and M.-P. Aubry

1995. A Revised Cenozoic Geochronology and Chronostratigraphy. In
W.A. Berggren, D.V. Kent, M.-P. Aubry, and J. Hardenbol, editors,
Geochronology, Time Scales and Global Stratigraphic Correlations.
Society of Economic Paleontologists and Mineralogists, Special
Publication, 54:129-212.

Berggren, W.A., and K.G. Miller

1988. Paleogene Tropical Planktonic Foraminiferal Biostratigraphy and
Magnetobiochronology. Micropaleontology, 34:362-380.

Berggren, W.A., and R.D. Norris

1993. Origin of the Genus Acarinina and Revisions to Paleocene
Biostratigraphy. [Abstract.] Geological Society of America, Ab¬
stracts with Programs, 24:A359.

1997. Taxonomy and Biostratigraphy of (Sub)tropical Paleocene Plank¬
tonic Foraminifera. Micropaleontology, Supplement I, 43:1-116.

Berggren, W.A., R.K. Olsson, and R.A. Reyment

1967. Origin and Development of the Foraminiferal Genus Pseudohas-
tigerina Banner and Blow, 1959. Micropaleontology, 13:265-288.

Bermudez, P.J.

1961. Contribucion al estudio de las Globigerinidea de la region
Caribe-Antillana (Paleocene-Reciente). Boletin de Geologia ( Ven¬
ezuela ), Publicacion Especial, 3 (Congres Geologia Venezolano, 3d,
Caracas, 1959, Mem. 3):1119-1393.

Blow, W.H.

1979. The Cainozoic Globigerinida. 1413 pages. Leiden, The Netherlands:
E.J. Brill.

Boersma, A.

1984a. Campanian through Paleocene Paleotemperature and Carbon Isotope
Sequence and the Cretaceous-Tertiary Boundary in the Atlantic
Ocean. In W.A. Berggren and J.A. van Couvering, editors,
Catastrophes and Earth History, pages 247-278. Princeton, New
Jersey: Princeton University Press.

100

NUMBER 85

101

1984b. Cretaceous-Tertiary Planktonic Foraminifers from the South-
Eastern Atlantic, Walvis Ridge Area, Deep Sea Drilling Project Leg
74. In T.C. Moore, P.D. Rabinowitz et al., Initial Reports of the Deep
Sea Drilling Project, 74:501-524. Washington, D.C.: U.S. Govern¬
ment Printing Office.

Boersma, A., and I. Premoli Silva

1983. Paleocene Planktonic Foraminiferal Biogeography and Paleocean-
ography of the Atlantic Ocean. Micropaleontology, 29:355-381.

Boersma, A., N.J. Shackleton, M. Hall, and Q. Given

1979. Carbon and Oxygen Isotope Variations at DSDP Site 384 (North
Atlantic) and Some Paleotemperatures and Carbon Isotope Varia¬
tions in the Atlantic Ocean. In B.E. Tycholke, P.R. Vogt et al., Initial
Reports of the Deep Sea Drilling Project, 43:695-717. Washington,
D.C.: U.S. Government Printing Office.

Bolli, H.M.

1957a. The Genera Globigerina and Globorotalia in the Paleocene-Lower
Eocene Lizard Springs Formation of Trinidad, B.W.I. In A.R.
Loeblich, Jr., and collaborators, Studies in Foraminifera. Bulletin of
the United States National Museum, 215:61-82.

1957b. Planktonic Foraminifera from the Eocene Navet and San Fernando
Formations of Trinidad, B.W.I. In A.R. Loeblich, Jr., and col¬
laborators, Studies in Foraminifera. Bulletin of the United States
National Museum, 215:155-172.

1966. Zonation of Cretaceous to Pliocene Marine Sediments Based on
Planktonic Foraminifera. Boletin Informativo Asociacion Venezo-
lana de Geologia, Mineriay Petroleo, 9:3-32.

Bolli, H.M., and M.B. Cita

1960. Globigerine e Globorotalie del Paleocene di Pademo d’Adda
(Italia). Rivista Italiana di Paleontologia e Stratigrafia, 66:361 —
408.

Brinkhuis, H., and W.J. Zachariasse

1988. Dinoflagellate Cysts, Sea Level Changes and Planktonic Foraminif¬
era Across the Cretaceous-Tertiary Boundary at El Haria, North¬
west Tunisia. Marine Micropaleontology, 13:153-191.

Bronnimann, P.

1952. Trinidad Paleocene and Lower Eocene Globigerinidae. Bulletins of
American Paleontology, 34: 34 pages.

1953. Note on Planktonic Foraminifera from Danian Localities of Jutland,
Denmark. Eclogae Geologicae Helvetiae, 45:339-341.

Bronnimann, P., and N.K. Brown, Jr.

1958. Hedbergella, a New Name for a Cretaceous Planktonic Foraminif¬
eral Genus. Journal of the Washington Academy of Sciences,
48:15-17.

Bronnimann, P., and J. Resig

1971. A Neogene Globigerinacean Biochronologic Time-scale of the
Southwestern Pacific. In E.L. Winterer, W.R. Reidel et al., Initial
Reports of the Deep Sea Drilling Project, 7:1235-1409. Washing¬
ton, D.C.: U.S. Government Printing Office.

Brotzen, F., and K. Pozaryska

1961. Foraminiferes du Paleocene et de P Eocene inferieur en Pologne
septentrionale; remarques paleogeographiques. Revue de Mi-
cropaleontologie, 4:155-166.

Brummer, G.J.A., Ch. Hemleben, and M. Spindler

1986. Planktonic Foraminiferal Ontogeny and New Perspectives for
Micropaleontology. Nature, 319:50-52.

Bykova, N.K.

1953. Foraminifery suzakskogo yarusa Tadzhikskoi depressii [Foraminif¬
era of the Suzakh Stage of the Tadzhik Depression]. Trudy
Vsesoyuznogo Neftyanogo Nauchno-Issledovat'skogo Geologo-
Razvedochnogo Instituta ( VNIGR1 ), Mikrofauna SSSR, Sbornik,
6:5-103. [In Russian.]

Carpenter, W.B., W.K. Parker, and T.R. Jones

1862. Introduction to the Study of the Foraminifera. 139 pages. London:
Ray Society Publications.

Cifelli, R„ and D.J. Belford

1977. The Types of Several Species of Tertiary Planktonic Foraminifera in
the Collections of the U.S. National Museum of Natural History.
Journal of Foraminiferal Research, 7:100-105.

Corfield, R.M.

1989. Morozovella protocarina : A New Species of Palaeocene Planktonic
Foraminferida. Journal of Micropaleontology, 8( 1 ):97-102.

Cushman, J.A.

1925. Some New Foraminifera from the Velasco Shale of Mexico.
Contributions from the Cushman Laboratory for Foraminiferal
Research, 1:18-23.

1927a. An Outline of a Re-classification of the Foraminifera. Contributions
from the Cushman Laboratory for Foraminiferal Research, 3:1-
105.

1927b. New and Interesting Foraminifera from Mexico and Texas.
Contributions from the Cushman Laboratory for Foraminiferal
Research, 3:111-119.

1932. Rectogiimbelina, a New Genus from the Cretaceous. Contributions
from the Cushman Laboratory for Foraminiferal Research, 8:4-7.

1933. Some New Foraminiferal Genera. Contributions from the Cushman
Laboratory for Foraminiferal Research, 9:32-38.

1938. Cretaceous Species of Guembelina and Related Genera. Contribu¬
tions from the Cushman Laboratory for Foraminiferal Research,
14:2-28.

1940. Midway Foraminifera from Alabama. Contributions from the
Cushman Laboratory for Foraminiferal Research, 16:51-73.

1944a. A Paleocene Foraminiferal Fauna from the Coal Bluff Marl Member
of the Naheola Formation of Alabama. Contributions from the
Cushman Laboratory for Foraminiferal Research, 20:29-49.

1944b. A Foraminiferal Fauna of the Wilcox Eocene, Bashi Formation,
from near Yellow Bluff, Alabama. American Journal of Science,
242:7-18.

1951. Paleocene Foraminifera of the Gulf Coastal Region of the United
States and Adjacent Areas. United States Geological Survey
Professional Paper, 232: 75 pages.

Cushman, J.A., and P.J. Bermudez

1949. Some Cuban Species of Globorotalia. Contributions from the
Cushman Laboratory for Foraminiferal Research, 25:26-45.

Cushman, J.A., and G.D. Hanna

1927. Foraminifera from the Eocene near San Diego, California. Transac¬
tions of the San Diego Society of Natural History, 5:45-64.

Cushman, J.A., and G.M. Ponton

1932. An Eocene Foraminiferal Fauna of Wilcox Age from Alabama.
Contributions from the Cushman Laboratory for Foraminiferal
Research, 8:51-72.

Cushman, J.A., and H.H. Renz

1942. Eocene, Midway, Foraminifera from Soldado Rock, Trinidad.
Contributions from the Cushman Laboratory for Foraminiferal
Research, 18:1-14.

1946. The Foraminiferal Fauna of the Lizard Springs Formation of
Trinidad, British West Indies. Special Publications of the Cushman
Laboratory for Foraminiferal Research, 18: 48 pages.

Cushman, J.A., and R. Todd

1946. A Foraminiferal Fauna from the Paleocene of Arkansas. Contribu¬
tions from the Cushman Laboratory for Foraminiferal Research,
22:45-65.

Davids, R.

1966. A Paleoecologic and Paleo-biogeographic Study of Maastrichtian
Planktonic Foraminifera. 241 pages. Doctoral dissertation, Rutgers
University, New Brunswick, New Jersey.

Davidzon, R.M.

1976. Novyy paleogenovyy rod planktonnykh foraminifer [A New
Paleogene Planktonic Foraminiferal Genus], Trudy, Vsesoyuznyi
Nauchno-Issledovatel’skii Geologorazvedochnyi Neftyanoi Institut
( VNIGNI ), Tadzhikskoe Otdelenie, 183:197-198. [In Russian.]

102

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Davidzon, R.M., and V.G. Morozova

1964. Planktonnye i bentosnye izvestkovye foraminifery Bucharskikh
sloev (Paleotsen) Tadzhikskoi depressii [Planktonic and Benthonic
Calcareous Foraminifera of the Bukhara Beds (Paleocene) of the
Tadzhik Depression.] Paleontologicheskiy Zhurnal, 3:23-29. [In
Russian.]

D’Hondt, S.

1991. Phylogenetic and Stratigraphic Analysis of Earliest Paleocene
Biserial and Triserial Planktonic Foraminifera. Journal of Foram-
iniferal Research, 21:170-183.

D’Hondt, S., and G. Keller

1991. Some Patterns of Planktic Foraminiferal Assemblage Turnover at the
Cretaceous-Tertiary Boundary. Marine Micropaleontology, 17:77—
118.

D’Hondt, S., and J.C. Zachos

1993. On Stable Isotopic Variation and Earliest Paleocene Planktonic
Foraminifera. Paleoceanography, 8:527-547.

D’Hondt, S., J.C. Zachos, and G. Schultz

1994. Stable Isotopic Signals and Photosymbiosis in Late Paleocene
Planktic Foraminifera. Paleobiology, 20:391-406.

Douglas, R.G., and S.M. Savin

1978. Oxygen Isotopic Evidence for the Depth Stratification of Tertiary
and Cretaceous Planktic Foraminifera. Marine Micropaleontology,
3:175-196.

Ehrenberg, C.G.

1854. Mikrogeologie. 374 pages. Leipzig: L. Voss.

El-Naggar, Z.R.

1966. Stratigraphy and Planktonic Foraminifera of the Upper Cretaceous-
Lower Tertiary. Bulletin of the British Museum (Natural History ),
Geology, supplement 2: 291 pages.

1971. On the Classification, Evolution, and Stratigraphical Distribution of
the Globigerinacea. In A. Farinacci, editor, Proceedings of the II
Planktonic Conference, 1:421-476. Rome: Edizioni Tecnoscienza.

Finlay, H.J.

1939. New Zealand Foraminifera: Key Species in Stratigraphy, No. 2.
Transactions of the Royal Society of New Zealand, 69:309-329.

1947. New Zealand Foraminifera: Key Species in Stratigraphy, No. 5. New
Zealand Journal of Science and Technology, 28:259-292.

Fox, S.K., and R.K. Olsson

1969. Danian Planktonic Foraminifera from the Cannonball Formation,
North Dakota. Journal of Paleontology, 43:1397-1404.

Gandolfi, R.

1942. Ricerche micropaleontologiche e stratigrafiche sulla scaglia e sul
flysch Cretacici dei Dintorni di Balerna (Canton Ticino). Rivista
Italiana di Paleontologia, Memoria, 4: 160 pages.

Gartner, S., Jr., and W.W. Hay

1962. Planktonic Foraminifera from the Type Ilerdian. Eclogae Geologi-
cae Helvetiae, 55:553-575.

Glaessner, M.F.

1936. Die Foraminiferengattungen Pseudotextularia und Amphimorphina.
Problems in Paleontology, Moscow University Laboratory of
Paleontology, 1:116-134.

1937a. Planktonische Foraminiferen aus der Kreide und dem Eozan und ihre
stratigraphische Bedeutung. Studies in Micropaleontology, Publica¬
tions of the Laboratory of Paleontology, Moscow University,
1:27-52.

1937b. Studien iiber Foraminiferen aus der Kreide und dem Tertiar des
Kaukasus. Problems in Paleontology, Moscow University Labora¬
tory of Paleontology, 2-3:349-410.

Gohrbandt, K.H.A.

1963. Zur Gliederung der Palaogen im Helvetikum nordlich Salzburg nach
planktonischen Foraminiferen, I. Teil: Paleozan und tiefstes Unter-
eozan. Mitteilungen der Geologischen Gesellschaft in Wien, 56:1-
116.

Haig, D.W., B.J. Griffin, and B.F. Ujetz

1993. Redescription of Type Specimens of Globorotalia chapmani Parr
from the Upper Paleocene, Western Australia. Journal of Foraminif¬
eral Research, 23:275-280.

Haque, A.F.M.M.

1956. The Foraminifera of the Ranikot and the Laki of the Nammal Gorge,
Salt Range. Memoirs of the Geological Survey of Pakistan,
Palaeontologia Pakistanica, 1:1-300.

Hemleben, Ch.

1969. Zur Morphogenese planktonischer Foraminiferen. Zitteliana, 1:91—
113.

Hemleben, Ch., A.H.W. Be, O.R. Anderson, and S. Tuntivate-Choy

1977. Test Morphology, Organic Layers and Chamber Formation of the
Planktonic Foraminifer Globorotalia menardii (d’Orbigny). Journal
of Foraminiferal Research, 7:1-25.

Hemleben, Ch., I. Breitinger, and W. Deuser

1985. Field and Laboratory Studies on Some Globorotaliid Species from
the Sargasso Sea off Bermuda. Journal of Foraminiferal Research,
15:254-272.

Hemleben, Ch., D. Miihlen, R.K. Olsson, and W.A. Berggren

1991. Surface Texture and the First Occurrence of Spines in Planktonic
Foraminifera from the Early Tertiary. Geologisches Jahrbuch,
128:117-146.

Hemleben, Ch., M. Spindler, and O.R. Anderson

1989. Modern Planktonic Foraminifera. 363 pages. New York: Springer.

Hillebrandt, A. von

1962. Das Paleozan und seine Foraminiferenfauna im Becken von
Reichenhall und Salzburg. Bayerische Akademie der Wissenschaf-
ten, 108: 181 pages.

Hofker, J.

1978. Analysis of a Large Succession of Samples through the Upper
Maastrichtian and the Lower Tertiary of Drill Hole 47.2, Shatsky
Rise, Pacific, Deep Sea Drilling Project. Journal of Foraminiferal
Research, 8:46-75.

Hornibrook, N. de B.

1953. Faunal Migrations to New Zealand, I: Immigration of Foraminifera
to New Zealand during the Upper Cretaceous and Tertiary. New
Zealand Journal of Science and Technology, 34:436-444.

1958. New Zealand Upper Cretaceous and Tertiary Foraminiferal Zones
and Some Overseas Correlations. Micropaleontology, 4:25-38.

Hornibrook, N. de B., R.C. Brazier, and C.P. Strong

1989. Manual of New Zealand Permian to Pleistocene Foraminiferal
Biostratigraphy. New Zealand Geological Survey Paleontological
Bulletin, 56: 175 pages.

Howe, H.V., and W.E. Wallace

1932. Foraminifera of the Jackson Eocene at Danville Landing on the
Ouachita, Catahoula Parish, Louisiana. Geology Bulletin, Depart¬
ment of Conservation, Louisiana Geological Survey, 2:7-118.

Huber, B.T.

1990. Maestrichtian Planktonic Foraminifer Biostratigraphy of the Maud
Rise (Weddell Sea, Antarctica): ODP Leg 113 Holes 689B and
690C. In P.F. Barker, J.P. Kennett et al., Proceedings of the Ocean
Drilling Program, Scientific Results, 113:489-513. College Station,
Texas: Ocean Drilling Program.

1991a. Planktonic Foraminifer Biostratigraphy of Campanian-Maestrich-
tian Sediments from Sites 698 and 700, Southern South Atlantic. In
P.F. Ciesielski, Y. Kristoffersen et al., Proceedings of the Ocean
Drilling Program, Scientific Results, 114:281-298. College Station,
Texas: Ocean Drilling Program.

1991b. Paleocene and Early Neogene Planktonic Foraminifer Biostratigra¬
phy of Sites 738 and 744, Kerguelen Plateau (Southern Indian
Ocean). In J. Barron, B. Larsen et al., Proceedings of the Ocean
Drilling Program, Scientific Results, 119:427-449. College Station,
Texas: Ocean Drilling Program.

NUMBER 85

103

1991c. Maestrichtian Planktonic Foraminifer Biostratigraphy and the
Cretaceous/Tertiary Boundary at Hole 738C (Kerguelen Plateau,
Southern Indian Ocean). In J. Barron, B. Larsen et al., Proceedings
of the Ocean Drilling Program, Scientific Results, 119:451-465.
College Station, Texas: Ocean Drilling Program.

1994. Ontogenetic Morphometries of Some Late Cretaceous Trochospiral
Planktonic Foraminifera from the Austral Realm. Smithsonian
Contributions to Paleobiology, 77: 85 pages.

Huber, B.T., and A. Boersma

1994. Cretaceous Origin of Zeauvigerina and Its Relationship to Paleocene
Biserial Planktonic Foraminifera. Journal of Foraminiferal Re¬
search, 24:268-287.

Jenkins, D.G.

1965. Planktonic Foraminiferal Zones and New Taxa from the Danian to
Lower Miocene of New Zealand. New Zealand Journal of Geology
and Geophysics, 8:1088-1126.

1971. New Zealand Cenozoic Planktonic Foraminifera. Palaeontological
Bulletin, New Zealand Geological Survey, 42: 278 pages.

1985. Southern Mid-Latitude Paleocene to Holocene Planktic Fo¬
raminifera. In H.M. Bolli, J.B. Saunders, and K. Perch-Nielsen,
editors, Plankton Stratigraphy, pages 263-282. Cambridge: Cambr¬
idge University Press.

Keller, G.

1988. Extinction, Survivorship, and Evolution across the Cretaceous/
Tertiary Boundary at El Kef. Marine Micropaleontology, 13:239-
263.

1989. Extended Cretaceous/Tertiary Boundary Extinctions and Delayed
Population Change in Planktonic Foraminifera from Brazos River,
Texas. Paleoceanography, 4:287-332.

1993. The Cretaceous-Tertiary Boundary Transition in the Antarctic
Ocean and Its Global Implications. Marine Micropaleontology,
21:1-45.

Kelly, D.K., A.J. Arnold, and W.C. Parker

1996. Paedomorphosis and the Origin of the Paleocene Planktonic
Foraminiferal Genus Morozovella. Paleobiology, 22:266-281.

Khalilov, D.M.

1956. O pelagicheskoy faune foraminifer Paleogenovykh otlozheniy
Azerbaydzhana [Pelagic Foraminifera of the Paleogene Deposits of
the Azerbaizhan SSR], Trudy Instituta Geologii, Akademiya Nauk
Azerbaidzhanskoi SSR, 17:234-255. [In Russian.]

1967. Mikrofauna i stratigrafiya paleogenovykh otlozheniy Azer¬
baydzhana, chast' II [Microfauna and Stratigraphy of Paleogene
Strata of Azerbaydzhan, Part 2]. 216 pages. Baku, Azerbaydzhan:
Akademiya Nauk Azerbaidzhanskoi SSR Instituta Geologii. [In
Russian.]

Kline, V.H.

1943. Clay County Fossils: Midway Foraminifera and Ostracoda. Missis¬
sippi State Geological Survey Bulletin, 53:1-98.

Krasheninnikov, V.A.

1965. Zonal 'naya stratigrafiya Paleogenovykh otlozhenii [Zonal Stratigra¬
phy of Paleogene Deposits]. International Geological Congress, 21st
Norden, 1960, Doklady Soviet Geologists, Problem 16: Problems of
Cenozoic Stratigraphy, 12D:37-61. Moscow: Akdemiya Nauk
SSSR. [In Russian.]

1969. Geograficheskoe i stratgraficheskoe raspredelenie planktonnykh
foraminifer v otlozheniyakh Paleogena tropicheskoi i subtropich-
eskoi oblastei [Geographical and Stratigraphical Distribution of
Planktonic Foraminifers in Paleogene Deposits of Tropical and
Subtropical Areas]. Izdatelstvo "Nauka," Moscow, Akademiya
Nauka SSSR, 184 pages. [In Russian.]

Krasheninnikov, V.A., and R.H. Hoskins

1973. Late Cretaceous, Paleogene and Neogene Planktonic Foraminifera.
In B.C. Heezen, I.D. McGregor et al., Initial Reports of the Deep Sea
Drilling Project, 20:105-203. Washington, D.C.: U.S. Government
Printing Office.

Krasheninnikov, V.A., and V.P. Ponikarov

1965. Zonal Stratigraphy of Paleogene Deposits in the Nile Valley. Papers,
Geological Survey and Mining Resources Department, United Arab
Republic, Cairo, 132:1-26.

Kroon, D., and A.J. Nederbragt

1990. Ecology and Paleoecology of Triserial Planktic Foraminifera.
Marine Micropaleotology, 16:25-38.

Leonov, G.P., and V.P. Alimarina

1960. Stratigrafiya i planktonnye foraminifery “perekhodnykh” ot mela k
paleogeny sloev tsentral’nogo Predkavkazya [Stratigraphy and
Plantonic Foraminifera of the Cretaceous-Paleogene “Transition”
Beds of the Central Part of the North Caucasus]. In Problema V:
Granitsa melovoi i paleogenovoi sistem. Mezhdunarodnyi Geol-
ogicheskii Kongress, XXI Sessiya, Doklady Sovetskikh Geologov,
Izdatelstvo Akademiya Nauk, pages 29-60. [In Russian.]

Leroy, L.W.

1953. Biostratigraphy of the Maqfi Section, Egypt. Geological Society of
America, Memoir, 54:1-73.

Li, Q., and S.S. Radford

1991. Evolution and Biogeography of Paleogene Microperforate Plank¬
tonic Foraminifera. Palaeogeography, Palaeoclimatology, Palaeoe-
cology, 83:87-1 15.

Liu, C.

1993. Uppermost Cretaceous-Lower Paleocene Stratigraphy and Turno¬
ver of Planktonic Foraminifera Across the Cretaceous/Paleogene
Boundary. 181 pages. Doctoral dissertation, Rutgers University,
New Brunswick, New Jersey.

Liu, C., and R.K. Olsson

1992. Evolutionary Adaptive Radiation of Microperforate Planktonic
Foraminifera Following the K/T Mass Extinction Event. Journal of
Foraminiferal Research, 22:328-346.

1994. On the Origin of Danian Normal Perforate Planktonic Foraminifera
from Hedbergella. Journal of Foraminiferal Research, 24:61-74.

Loeblich, A.R., Jr.

1951. Coiling in the Heterohelicidae. Contributions from the Cushman
Foundation for Foraminiferal Research, 2:106-110.

Loeblich, A.R, Jr., and H. Tappan

1956. Chiloguembelina, a New Tertiary Genus of the Heterohelicidae
(Foraminifera). Journal of the Washington Academy of Sciences,
46:340.

1957a. Planktonic Foraminifera of Paleocene and Early Eocene Age from
the Gulf and Atlantic Coastral Plains. In A.R. Loeblich, Jr., and
collaborators. Studies in Foraminifera. Bulletin of the United States
National Museum, 215:173-198.

1957b. Woodringina, a New Foraminiferal Genus (Heterohelicidae) from
the Paleocene of Alabama. Journal of the Washington Academy of
Sciences, 47:39-40.

1961. Suprageneric Classification of the Rhizopodea. Journal of Paleon¬
tology, 35:245-330.

1964. Sarcodina Chiefly “Thecamoebians” and Foraminiferida. In R.C.
Moore, editor, Treatise on Invertebrate Paleontology, Part C,
Protista (2): 900 pages, 653 text-figures. Lawrence, Kansas:
University of Kansas Press.

1986. Some New and Revised Genera and Families of Hyaline Calcareous
Foraminiferida (Protozoa). Transactions of the American Micro¬
scopical Society, 105:239-265.

1988. Foraminiferal Genera and Their Classification. 2 volumes, 970
pages, 847 plates. New York: Van Nostrand and Reinhold Company.

Lu, G., and G. Keller

1993. The Paleocene-Eocene Transition in the Antarctic Indian Ocean:
Inference from Planktic Foraminifera. Marine Micropaleontology,
21:101-142.

1995. Planktic Foraminiferal Faunal Turnovers in the Subtropical Pacific
during the Late Paleocene to Early Eocene. Journal of Foraminiferal
Research, 25:97-116.

104

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

1996. Separating Ecological Assemblages Using Stable Isotope Signals:
Late Paleocene to Early Eocene Planktic Foraminifera, DSDP Site
577. Journal of Foraminiferal Research, 26:103-112.

Ludbrook, N.H., and J.M. Lindsay

1969. Tertiary Foraminiferal Zones in South Australia. In P. Bronnimann
and H.H. Renz, editors. Proceedings of the First International
Conference on Planktonic Microfossils, 2:366-374.

Luterbacher, H.P.

1964. Studies in Some Globorotalia from the Paleocene and Lower Eocene
of the Central Apennines. Eclogae Geologicae Helvetiae, 57:631-
730.

1975a. Paleocene and Early Eocene Planktonic Foraminifera Leg 32, Deep
Sea Drilling Project. In R.L. Larson, R. Moberly et al.. Initial
Reports of the Deep Sea Drilling Project, 32:725-728. Washington,
D.C.: U.S. Government Printing Office.

1975b. Planktonic Foraminifera of the Paleocene and Early Eocene,
Possagno Section. Schweizerische Palantologische Abhandlungen,
97:57-67, plates 1-4.

Luterbacher, H.P., and I. Premoli Silva

1964. Biostratigrafia del limite Cretaceo-Terziario nell’Appenino cen-
trale. Rivista Italiana di Paleontologia e Stratigrafia, 70:67-128.

MacLeod, N.

1993. The Maastrichtian-Danian Radiation of Triserial and Biserial
Planktic Foraminifera: Testing Phylogenetic and Adaptational
Hypotheses in the (Micro)Fossil Record. Marine Micropaleon¬
tology, 21:47— 100.

Mallory, V.S.

1959. Lower Tertiary Biostratigraphy of the California Coast Ranges. 146
pages. Tulsa, Oklahoma: American Association of Petroleum
Geologists.

Martin, L.T.

1943. Eocene Foraminifera from the Type Lodo Formation, Fresno
County, California. Stanford University Publications, Geological
Sciences, 3:93-125.

McGowran, B.

1964. Foraminiferal Evidence for the Paleocene Age of the King’s Park
Shale (Perth Basin, Western Australia). Journal of the Royal Society
of Western Australia, 47:81-86.

1965. Two Paleocene Foraminiferal Faunas from the Wangerrip Group,
Pebble Point Coastal Section, Western Australia. Proceedings of the
Royal Society of Victoria, 79:9-74.

1968. Reclassificatiion of Early Tertiary Globorotalia. Micropaleontol¬
ogy, 14:179-198.

Montanaro Gallitelli, E.

1957. A Revision of the Foraminiferal Family Heterohelicidae. In A.R.
Loeblich, Jr., and collaborators, Studies in Foraminifera. Bulletin of
the United States National Museum, 215:133-154.

Morozova, V.G.

1939. K stratigraphii verchnego mela i paleogena Embenskoi oblasti po
faune foraminifer [On the Stratigraphy of the Upper Cretaceous and
Paleogene of the Embe Region According to the Foraminiferal
Fauna]. Byulleten Moskovskogo Obshchestva Ispytatelei Prirody,
Otdel Geologicheskii. 17:59-96. [In Russian, includes an English
summary.]

1957. Nadsemeistvo foraminifer Globigerinidea superfam. nova i nekotori
yevo predstaviteli [Foraminiferal Superfamily Globigerinidea, Su¬
perfamily nov., and Some of Its Representatives], Doklady Akade-
miya Nauk SSSR, 114(5): 1109-1111. [In Russian.]

1958. K sistematike i morfologii paleogenovykh predstavitelei nadse-
meistva Globigerinidea [Addition to the Systematics and Morphol¬
ogy of the Paleogene Members of the Superfamily Globigerinidea].
Voprosy Mikropaleontologii, 114:22-52. [In Russian.]

1959. Stratigrafiya Datsko-Montskikh otlozhenii Kryma po foraminif-
eram [Stratigraphy of the Danian-Montian Deposits of the Crimea
According to the Foraminifera], Doklady Akademiya Nauk SSSR,
124:1113-1116. [In Russian.]

1960. Zonal’naya stratigrafiya Datsko-Monstkikh otlozhenii CCCR i
granitsa mela c paleogenom [The Paleocenoses of Danian-Montian
Foraminifera and Their Stratigraphic and Paleogeographic Impor¬
tance], In Problema V: Granitsa melovoi i paleogenovoi sistem.
Mezhdunarodnyi Geologicheskii Kongress, XXI Sessiya, Doklady
Sovetskikh Geologov, Izdatelstvo Akademiya Nauk, pages 83-100.
[In Russian.]

1961. Datsko-Montskie planktonnye foraminifery yuga SSSR [Danian-
Montian Planktonic Foraminifera of the Southern USSR],
Paleontologicheskiy Zhurnal, 2:8-19. [In Russian.]

Morozova, V.G., G.E. Kozhevnikova, and A.M. Kuryleva

1967. Datsko-Paleotsenovye Raznofatsial’nye otlozheniya Kopet-Daga i
metody ikh korrelyatsii po foraminiferam [Danian-Paleocene
Heterofacial Deposits of Kopet-Dag and Methods of Their Correla¬
tion According to the Foraminifers]. Trudy Geologicheskogo
Instituta, Akademiya Nauk SSSR, 157:1 -208. [In Russian.]

Nakkady, S.E.

1951. A New Foraminiferal Fauna from the Esna Shales and Upper
Cretaceous Chalk of Egypt. Journal of Paleontology, 24:675-692.

Nederbragt, A.J., and J.E. Van Hinte

1987. Biometric Analysis of Planorotalites pseudomenardii (Upper Paleo¬
cene) at Deep Sea Drilling Site 605, Northwestern Atlantic. In J.E.
Van Hinte, S.W. Wise et al., Initial Reports of the Deep Sea Drilling
Project, 93:577-592. Washington, D.C.: U.S. Government Printing
Office.

Nocchi, M., E. Amici, and I. Premoli Silva

1991. Planktonic Foraminiferal Biostratigraphy and Paleoenvironmental
Interpretation of Paleocene Faunas from the Subantarctic Transect,
Leg 114. In P.F. Ciesielski, Y. Kristoffersen et al., Proceedings of
the Ocean Drilling Program, Scientific Results, 114:233-279.
College Station, Texas: Ocean Drilling Program.

Norris, R.D.

1996. Symbiosis as an Evolutionary Innovation in the Radiation of
Paleocene Planktic Foraminifera. Paleobiology, 4:461-480.

Olsson, R.K.

1960. Foraminifera of Latest Cretaceous and Earliest Tertiary Age in the
New Jersey Coastal Plain. Journal of Paleontology, 34:1-58.

1964. Late Cretaceous Planktonic Foraminifera from New Jersey and
Delaware. Micropaleontology. 10:157-188.

1970. Planktonic Foraminifera from Base of Tertiary, Millers Ferry,
Alabama. Journal of Paleontology, 44:598-604.

1982. Cenozoic Planktonic Foraminifera: A Paleobiogeographic Sum¬
mary. In T.W. Broadhead, editor, Foraminifera Notes for a Short
Course (organized by M.A. Buzas and B.K. Sen Gupta). University
of Tennessee Department of Geological Sciences Studies in Geology,
6:127-147.

Olsson, R.K., and Ch. Hemleben

1996. Phylogeny of Normal Perforate Paleocene Planktonic Foraminifera
Based on Wall Texture. [Abstract.] North American Paleontology
Conference, Washington, D.C., Abstracts with Program, page 294.

Olsson, R.K., Ch. Hemleben, W.A. Berggren, and C. Liu

1992. Wall Texture Classification of Planktonic Foraminifera Genera in
the Lower Danian. Journal of Foraminiferal Research, 22:195-213.

Parker, F.L.

1962. Planktonic Foraminiferal Species in Pacific Sediments. Micropale¬
ontology, 8:219-254.

Parr, W.J.

1938. Upper Eocene Foraminifera from Deep Borings in King’s Park,
Perth, Western Australia. Journal of the Royal Society of Western
Australia, 24:69-101.

Pearson, P.N.

1993. A Lineage Phylogeny for the Paleogene Planktonic Foraminifera.
Micropaleontology, 39:193-232.

NUMBER 85

105

Pearson, P.N., N.J. Shackleton, and M.A. Hall

1993. The Stable Isotope Paleoecology of Middle Eocene Planktonic
Foraminifera and Multi-species Integrated Isotope Stratigraphy,
DSDP Site 522, South Atlantic. Journal of Foraminiferal Research,
23:123-140.

Plummer, H.J.

1926. Foraminifera of the Midway Formation in Texas. University of Texas
Bulletin, 2644: 206 pages.

Pokorriy, V.

1955. Cassigerinella boudecensis n. gen., n. sp. (Foraminifera, Protozoa) z
Oligocenu zdanickeho flyse [Cassigerinella boudecensis n. gen., n.
sp. (Foraminifera, Protozoa) from the Oligocene of the Zdanice
Flysch]. Vestnik Ustredniho Ustavo Geologickeho, 30:136-140. [In
Czech.]

Postuma, J.A.

1971. Manual of Planktonic Foraminifera. 420 pages. Amsterdam:
Elsevier Publishing Co.

Premoli Silva, I.

1977. The Earliest Tertiary Globigerina eugubina Zone: Paleontological
Significance and Geographical Distribution. Memorias del Segundo
Congreso Latinoamericano de Geologia, 3, Special Publication,
7:1541-1555.

Premoli Silva, I., and A. Boersma

1989. Atlantic Paleogene Planktonic Foraminiferal Bioprovincial Indices.
Marine Micropaleontology, 14:357-371.

Premoli Silva, I., and H.M. Bolli

1973. Late Cretaceous to Eocene Planktonic Foraminifera and Stratigraphy
of Leg 15 Sites in the Caribbean Sea. In N.T. Edgar, J.B. Saunders
et al., Initial Reports of the Deep Sea Drilling Project, 15:499-547.
Washington, D.C.: U.S. Government Printing Office.

Proto Decima, F., and P. Zorzi

1965. Studio micropaleontologico-stratigrafico della serie Cretaceo-
Terziaria del Molinetto di Pederroba (Treviggiano occidentale).
Memorie degli Istituti di Geologia e Mineralogia dell'Universita di
Padova, 25: 44 pages.

Pujol, C.

1983. Cenozoic Planktonic Foraminiferal Biostratigraphy of the South¬
western Atlantic (Rio Grande Rise): Deep Sea Drilling Project Leg
72. In P.F. Barker, D.A. Johnson et al., Initial Reports of the Deep
Sea Drilling Project, 72:623-673. Washington, D.C.: U.S. Govern¬
ment Printing Office.

Reiss, Z.

1957. The Bilamellidae, nov. superfamily, and Remarks on Cretaceous
Globorotaliids. Contributions from the Cushman Foundation for
Foraminiferal Research, 8:127-145.

1963. Reclassification of Perforate Foraminifera. Bulletin of the Geologi¬
cal Survey of Israel, 35:1-111.

Rey, M.

1954. Description de quelques especes nouvelles de Foraminiferes dans le
Nummulitique nord-marocain. Bulletin de la Societe Geologique de
France, series 6, 4:209-211.

Said, R., and A. Kenaway

1956. Upper Cretaceous and Lower Tertiary Foraminifera from Northern
Sinai, Egypt. Micropaleontology, 2:105-173.

Said, R., and M.T. Kerdany

1961. The Geology and Micropaleontology of the Farafra Oasis, Egypt.
Micropaleontology, 7:317-336.

Said, R., and H. Sabry

1964. Planktonic Foraminifera from the Type Locality of the Esna Shale in
Egypt. Micropaleontology, 10:375-395.

Salaj, J.

1986. The New Postrugoglobigerina praedaubjergensis Zone at the Base
of the Stratotype of the Marine Paleocene (El Kef, Tunisia).
Geologicky Zbornik, Geologica Carpathica, 37:35-58.

Samanta, B.K.

1970. Planktonic Foraminifera from the Early Tertiary Pondicherry
Formation of Madras, South India. Journal of Paleontology,
44:605-641.

Schwager, C.

1883. Die Foraminiferen aus den Eocaenablagerungen der libyschen
Wiiste und Aegyptens. Palaeontographica, 30:79-153.

Scotese, C.R., and C.R. Denham

1988. Terra Mobilis: Plate Tectonics for the Macintosh. Austin, Texas:
Earth in Motion Technologies. [Computer program.]

Shackleton, N.J., R.M. Corfield, and M.A. Hall

1985. Stable Isotope Data and the Ontogeny of Paleocene Planktonic
Foraminifera. Journal of Foraminiferal Research, 15:321 -336.

Shifflett, E.

1948. Eocene Stratigraphy and Foraminifera of the Aquia Formation.
Maryland Department of Geology, Mines and Water Resources
Bulletin, 3:1-93.

Shutskaya, E.K.

1953. Raschlenenie kubanskogo i elburganskogo gorizontov Severnogo
Kavkaza po globigerinam [The Subdivision of the Kuban and
Elburgan Horizons of the Northern Caucusus by Means of the
Globigerinids]. Byulleten Moskovskogo Obshchestva Ispytatelei
Prirody, new series, volume 58, Otdel Geologicheskii, 28:71-79. [In
Russian.]

1956. Stratigrafiya nizhnikh gorizontov paleogena Tsentral’nogo Pred-
kavkaz’ya po foraminiferam [Stratigraphy of the Lower Horizons of
the Paleogene in the Central Precaucasus According to the
Foraminifera], Trudy Instituta Geologii, Akademiya Nauk SSSR,

164(70):3— 114. [In Russian.]

1958. Izmenchivosti nekotorikh nizhnepaleogenovikh plannktonikh fo-
raminifer severnogo Kavkaza [Variations of Some Lower Paleogene
Planktonic Foraminifers of the Northern Caucasus]. Voprosyi
Mikropaleontologii, Akademiya Nauk SSSR, 2:84-90. [In Russian.]

1960. Stratigrafiya ifatsii nizhnego paleogena Predkavkazya [Stratigraphy
and Facies of the Lower Paleogene of the Precaucasus]. 104 pages.
Vsesoyuznyi Nauchno-Issledovatel’skii Geologorazvedochnyi
Neftyanoi Institut (VNIGNI). Moscow: Gostoptekhizdat. [In Rus¬
sian.]

1962. Foraminifery datskogo yarusa i paleotsena fatsii otrtogo morya
Kryma, Predkavkazya i Zakaspiya [Foraminifera of the Danian and
Paleocene in Pelagic Facies of Crimea, Precaucasus and Transcas¬
pian Region]. Byulleten Moscovskogi Obshchestva Ispytatelei
Prirody, Otdel Geologicheskii, 37:126-127. [In Russian.]

1965. Filogeneticheskie vzaimootnoscheniya vidov gruppy Globorotalia
compressa Plummer v datskom vekhe i paleotzenovoi epokhe [On
the Phylogenetic Relations of the Species of the Globorotalia
compressa Plummer-group during Danian Time and the Paleocene
Epoch]. Voprosyi Mikropaleontologii, Akademiya Nauk SSSR,
9:173-188. [In Russian.]

1970a. Morfologicheskie grupirovki vidov rodov Globigerina i Acarinina v
nizhnei chasti paleogena Kryma, Predkavkazya i zapada Srednei
Azii i ipisanie vidov [Morphological Groups of Species of the
Genera Globigerina and Acarinina in the Lower Part of the
Paleogene in the Crimea, Precaucasus and Western Part of Central
Asia as Well as Description of Genera]. In E.K. Shutskaya, editor,
Stratigrafiya i paleontologiya Mezozoiskikh i Paleogenovykh ot-
lozhenii Srednei Azii. Trudy, Vsesoyuznyi Nauchno-Issledovatel 'skii
Geologorazvedochnyi Neftyanoi Institut (VNIGNI), 69:79-134. [In
Russian.]

1970b. Stratigrafiya, foraminifery i paleogeografiya nizhnego paleogena
Kryma, predkavkaz’ya i zapadnoi chadsti srednei azii [Stratigraphy,
Foraminifera and Paleogeography of the Lower Paleogene in the
Crimea, Precaucasus and the Western Part of Central Asia]. Trudy,
Vsesoyuznyi Nauchno-Issledovadetel 'skii Geologorazvedochnyi
Neftyanoi Institut (VNIGNI), 70: 256 pages. [In Russian.]

106

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Sliter, W.V.

1976. Cretaceous Foraminifers from the Southwestern Atlantic Ocean, Leg
36, Deep Sea Drilling Project. In P.F. Barker, E.W.D. Dalziel et al..
Initial Reports of the Deep Sea Drilling Project, 36:519-573.
Washington, D.C.: U.S. Government Printing Office.

Smit, J.

1977. Discovery of a Planktonic Foraminiferal Association between the
Abathomphalus mayaroensis Zone and the Globigerina eugubina
Zone at the Cretaceous/Tertiary Boundary in the Barranco del
Gredero (Caravaca, SE Spain): A Preliminary Report, I and II.
Koninklijke Nederlandse Akadamie van Wetenschappen, Proceed¬
ings, section B, 80:280-301.

1982. Extinction and Evolution of Planktonic Foraminifera after a Major
Impact at the Cretaceous/Tertiary Boundary. In L.T. Silver and PH.
Schultz, editors, Geological Implications of Impacts of Large
Asteroids and Comets on the Earth. Geological Society of America,
Special Paper, 190:329-352.

Smit, J., and Th.M.G. van Kempen

1987. Planktonic Foraminifers from the Cretaceous/Tertiary Boundary at
DSDP Sea Drilling Project Site 605, North Atlantic. In J.E. Van
Hinte, S.W. Wise et al.. Initial Reports of the Deep Sea Drilling
Project, 93:549-553. Washington, D.C.: U.S. Government Printing
Office.

Smith, B.Y.

1957. Lower Tertiary Foraminifera from Contra Costa County California.
University of California Publications in Geological Sciences,
32:1-190.

Smith, C.C., and E.A. Pessagno

1973. Planktonic Foraminifera and Stratigraphy of the Corsicana Forma¬
tion (Maestrichtian) North-central Texas. Special Publication of the
Cushman Foundation for Foraminiferal Research, 12: 68 pages.

Snyder, S.W., and V.J. Waters

1985. Cenozoic Planktonic Foraminiferal Biostratigraphy of the Goban
Spur Region, Deep Sea Drilling Project Leg 80. In PC. de
Graciannsky, C.W. Poag et al., Initial Reports of the Deep Sea
Drilling Project, 80:439-472. Washington, D.C.: U.S. Government
Printing Office.

Stainforth, R.M., J.L. Lamb, H. Luterbacher, J.H. Beard, and R.M. Jeffords

1975. Cenozoic Planktonic Foraminiferal Zonation and Characteristics of
Index Forms. University of Kansas Paleontological Contributions,
Article, 62: 425 pages.

Steineck, P.L., and R.L. Fleisher

1978. Towards the Classical Evolutionary Reclassification of Cenozoic
Globigerinacea (Foraminiferida). Journal of Paleontology, 52:618-
635.

Stott, L.D., and J.P. Kennett

1990. Antarctic Paleogene Planktonic Foraminifer Biostratigraphy: ODP
Leg 113, Sites 689 and 690. In P.F. Barker, J.P. Kennett et al..
Proceedings of the Ocean Drilling Program, Scientific Results,

113:549-569. College Station, Texas: Ocean Drilling Program.

Stratigraphic Commission

1963. [Decision of the Permanent Interdepartmental Stratigraphic Com¬
mission on the Paleogene of the USSR.] Sovetskaya Geologiya,
6:145-151. [In Russian.]

Subbotina, N.N.

1947. Foraminifery datskikh i paleogenovykh otlozhenii severnogo Kav-
kaza [Foraminifera of the Danian and Paleogene Deposits of the
Northern Caucasus]. In Mikrofauna neftyanykh mestorozhdenii
Kavkaza, Emby I Srednei Azii. Trudy, Vsesoyuznyi Nauchno-
Issledovatel 'skii Geologorazvedochnyi Neftyanoi Institut ( VNIGNI ),
1:39-160. [In Russian.]

1950. Mikrofauna i stratigrafiya Elburganskogo Gorozonta Goriathego
Klyitcha [Microfauna and Stratigraphy of the Elburgan Horizon and
the Goryatchy Klijutch Horizon], Trudy Vsesoyuznego Neftyanogo
Nauchno-Issledovatel 'skogo Geologo-Razvedochnogo Instituta
( VNIGR1 ), Mikrofauna SSSR, Sbornik, 51:5-112. [In Russian.]

1953. Iskopaemye foraminifery SSSR (Globigerinidy, Khantkenininidy i
Globorotaliidy) [Fossil Foraminifera of the USSR (Globigerinidae,
Hantkeninidae and Globorotaliidae)]. Trudy Vsesoyznogo Neftyan¬
ogo Nauchno-Issledovatel 'skogo Geologo-Razvedochnogo Instituta
(VNIGRI ), 76: 296 pages. [In Russian.]

Sulc, J.

1929. Contributions a connaissance de la morphologie des foraminiferes.
Vestnik Statniho Geologickeho Ustavu Ceskoslovenske Republiky,
5:142-149.

Tappan, H.

1940. Foraminifera from the Grayson Formation of Northern Texas.
Journal of Paleontology, 14:93-126.

Tjalsma, R.C.

1977. Cenozoic Foraminifera from the South Atlantic, DSDP Leg 36. In
P.F. Barker, I.W.D. Dalziel et al., Initial Reports of the Deep Sea
Drilling Project, 36:493-518. Washington, D.C.: U.S. Government
Printing Office.

Thalman, H.E.

1956. Bibliography and Index to New Genera, Species and Varieties of
Foraminifera for the Year 1954. Journal of Paleontology, 30:352-
388.

Toulmin, L.D.

1941. Eocene Smaller Foraminifera from the Salt Mountain Limestone of
Alabama. Journal of Paleontology, 15:567-611.

Toumarkine, M.

1978. Planktonic Foraminiferal Biostratigraphy of the Paleogene of Sites
360 to 364 and the Neogene of Sites 362A, 363, and 364 Leg 40. In
H.M. Bolli, W.B.F. Ryan et al.. Initial Reports of the Deep Sea
Drilling Project, 40:679-721. Washington, D.C.: U.S. Government
Printing Office.

Toumarkine, M., and H.-P. Luterbacher

1985. Paleocene and Eocene Planktic Foraminifera. In H.M. Bolli, J.B.
Saunders, and K. Perch-Nielsen, editors, Plankton Stratigraphy,
pages 87-154. Cambridge: Cambridge University Press.

Troelsen, J.C.

1957. Some Planktonic Foraminifera of the Type Danian and Their
Stratigraphic Importance. In A.R. Loeblich, Jr., and collaborators.
Studies in Foraminifera. Bulletin of the United States National
Museum, 215:125-132.

Van Eijden, A.J.M., and J. Smit

1992. Eastern Indian Ocean Cretaceous and Paleogene Quantitative
Biostratigraphy. In J. Weissel, J. Peirce, E. Taylor, J. Alt et al.,
Proceedings of the Ocean Drilling Program, Scientific Results,
121:77-124. College Station, Texas: Ocean Drilling Program.

Voloshina, A.M.

1961. Nekotorye novye vidy Verkhiemelovykh foraminifer Volyno-
Podol’skoy plity [Some New Species of Upper Cretaceous
Foraminifera from the Volhyn-Podol Platform]. Paleontologicheskii
Sbornik, L’vovskogo Geologicheskogo Obshchestva, 1:71-81. [In
Russian.]

Webb, P.N.

1973. Upper Cretaceous-Paleocene Foraminifera from Site 208 (Lord
Howe Rise, Tasman Sea), DSDP, Leg 21. In R.E. Bums, J.E.
Andrews et al., Initial Reports of the Deep Sea Drilling Project,
21:541-573. Washington, D.C.: U.S. Government Printing Office.

Weiss, L.

1955. Foraminifera from the Paleocene Pale Greda Formation of Peru.
Journal of Paleontology, 29:1-21.

White, M.P.

1928. Some Index Foraminifera of the Tampico Embayment of Mexico,
Part I and Part II. Journal of Paleontology, 2:177-215, 280-317.

Ziegler, P.A.

1982. Geological Atlas of Western and Central Europe. Pages 1-22.
Amsterdam: Elsevier Publishing Co.

Plates

108

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 1

Spinose and Nonspinose Wall Texture

FIGURE 1.— Globorotalia hirsuta (d’Orbigny), nonspinose smooth wall surface with scattered pustules, notice the
size gradient of pustule distribution from the ultimate to the antiprepenultimate chambers (bar = 200 pm).
Recent, plankton net catch, off Bermuda.

FIGURE 2.— Globorotalia menardii (Parker, Jones, and Brady), cross section of bilamellar wall, primary organic
membrane (POM) spans across the pore cross section; during life the pore is closed by this organic layer in
addition to organic pore fillings (bar = 10 pm). Recent, plankton net catch, Indian Ocean.

FIGURE 3.— Globigerinoides ruber (d’Orbigny), overall view of early adult stage showing spines implanted in
test wall (bar = 100 pm). Recent, plankton net catch off Barbados, Caribbean Sea.

FIGURE 4.— Globigerinoides sacculifer (Brady), cross section showing POM and remanents of pore plate, organic
pore lining, and terraced pore structure with plate-like crystals. Rather fine-grained crystals form the wall (bar
= 2 pm). Recent, plankton net catch, Indian Ocean.

FIGURE 5.— Globorotalia menardii (Parker, Jones, and Brady), keel with small and medium-sized pustules
growing on a very smooth surface (bar = 20 pm). Recent, Eltanin cruise 15 sample.

FIGURE 6.— Globorotalia truncatulinoides (d’Orbigny), tangential view and cross section of pustules showing
layering indicating that pustules grow as part of the test wall (bar = 5 pm). Recent, DSDP Site 1/1/1: 1-4 cm.

FIGURE 7.— Globigerinoides ruber (d’Orbigny), cross section of wall showing broken spine that is separated from
the wall. POM with part of the pore plate, inner organic lining (IOL), and organic pore lining (bar = 5 pm).
Recent, plankton net catch, South Pacific Ocean.

Figure 8. — Globigerina praebulloides Blow, cross section of spine hole containing mold of a spine (bar = 2
pm). Upper Eocene, DSDP Hole 362A/7/5: 24-26 cm; Walvis Ridge, eastern South Atlantic Ocean.

FIGURE 9. — Globigerinoides sacculifer (Brady), overall view of surface of test showing regular cancellate
structure with spines and spine holes (bar = 100 pm). Recent, plankton net catch off Barbados, Caribbean Sea.

FIGURE 10.— Subbotina linaperta (Finlay), overall view of surface of test showing same cancellate surface texture
as above with spine holes (bar = 100 pm). Upper Eocene, DSDP Hole 362A/7/5: 24-26 cm; Walvis Ridge,
eastern South Atlantic Ocean.

FIGURE 11.— Globigerinoides ruber (d’Orbigny), showing a less regular cancellate surface texture than G.
sacculifer or S. linaperta. Note spine holes (bar= 100 pm). Recent, plankton net catch off Barbados, Caribbean
Sea.

FIGURE 12.— Globigerina bulloides d’Orbigny, showing a more pitted surface due to rather isolated spine bases.
Note spine holes in spine bases (bar= 100 pm). Recent, sediment trap off Bermuda, North Atlantic.

FIGURE 13.— Globigerina praebulloides Blow, same as Figure 8, above, but showing a rather thick wall (bar =
100 pm). Upper Eocene, DSDP Hole 362A/7/5: 24-26 cm; Walvis Ridge, eastern South Atlantic Ocean.

FIGURE 14.— Globigerinoides sacculifer (Brady), enlarged view of test wall showing spine holes left by the
resorption of spines during gametogenesis (bar= 10 pm). Recent, plankton net catch off Barbados, Caribbean
Sea.

FIGURE 15.— Globigerinoides ruber (d’Orbigny), enlarged view of test wall showing spine holes and some
gametogenic calcification (bar = 10 pm). Recent, plankton net catch off Barbados, Caribbean Sea.

FIGURE 16.— Globigerina bulloides d’Orbigny, enlarged view of test wall showing spine holes (bar = 40 pm).
Recent, plankton net catch, middle North Atlantic Ocean.

FIGURE 17.— Globigerinoides sacculifer (Brady), juvenile specimen showing a globorotaliid test with a smooth
wall and a few spines (bar = 20 pm). Live specimen, Barbados.

FIGURE 18.— Globigerinoides sacculifer (Brady), showing crystal growth in surface view (bar = 20 pm). Live
specimen, Barbados.

FIGURE 19. — Globigerinoides sacculifer (Brady), enlargement of Figure 18 showing the pore resorption (bar = 5
pm).

FIGURE 20.— Globigerinoides sacculifer (Brady), detail of cancellate structure of the pore funnel with plate-like
crystal growth and spines (bar = 10 pm). Recent, Eltanin cruise 15 sample.

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110

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 2

Gametogenetic Calcification (Spinose Wall Texture)

FIGURE 1 .— Globigerinoides ruber (d’Orbigny), view of test wall showing a cancellate structure with spines on
the interpore ridges (bar = 10 pm). Recent, plankton net catch, off Bermuda.

FIGURE 2.— Globigerinoides sacculifer (Brady), view of test wall showing gametogenic calcification covering
the spine holes (bar= 10 pm). Live specimen, off Bermuda.

FIGURE 3.— Subbotina linaperta (Finlay), view of test wall showing spine holes and incipient gametogenic
calcification (bar = 20 pm). Upper Eocene, DSDP Hole 362A/7/5: 24-26 cm; Walvis Ridge, eastern South
Atlantic Ocean.

FIGURE 4.— Subbotina linaperta (Finlay), view of test wall showing different stages of gametogenetic
calcification (bar = 20 pm). Upper Eocene, DSDP Hole 362A/7/5: 24-26 cm; Walvis Ridge, eastern South
Atlantic Ocean.

FIGURE 5.— Subbotina linaperta (Finlay), enlarged view of test wall showing partial gametogenetic overgrowth
of a spine hole (bar = 4 pm). Upper Eocene, DSDP Hole 362A/7/5: 24-26 cm; Walvis Ridge, eastern South
Atlantic Ocean.

FIGURE 6.— Subbotina cancellata Blow, view of test wall showing gametogenic calcification covering the spine
holes (bar = 10 pm). Paleocene, Zone P4, DSDP Site 549/20/5: 20-22 cm; Goban Spur, eastern North
Atlantic.

FIGURES 7-9.— Parasubbotina pseudobulloides (Plummer): 7, view of test wall showing a cancellate surface
texture with spine holes and rather heavy corrosion; 8, spine holes and gametogenic calcification; 9,
well-preserved specimen showing typical gametogenic calcification (bar = 10 pm). Paleocene, Zone P2,
Midway Group, Texas, sample 8030.

FIGURE 10.— Globigerinoides ruber (d’Orbigny), view of test wall showing a less well-developed cancellate
surface texture with gametogenic calcification (bar = 10 pm). Recent, plankton net catch, off Bermuda.

FIGURES 11-13.— Eoglobigerina eobulloides Morozova: 11, view of test wall showing cancellate wall texture,
spine holes, and gametogenic calcification; 12, corroded surface (lower left) and gametogenic calcification; 13,
well-preserved specimen showing rather thick gametogenic calcification (bar = 10 pm). Paleocene, Zone Pa,
Core 226, samples 8, 21, 84, respectively, Millers Ferry, Alabama.

FIGURE 14.— -Globigerina praebulloides Blow, view of test wall showing spine holes and spine bases (bar = 10
pm). Upper Eocene, DSDP Hole 362A/7/5: 24-26 cm; Walvis Ridge, eastern South Atlantic Ocean.

FIGURES 15, 16.— Subbotina triangularis (White), views of test wall showing spine holes, spine bases, and
gametogenic calcification. Compare to Figure 11 (bar = 10 pm). Paleocene, Zone P4, Glendola Well, New
Jersey, sample 286-287 feet.

NUMBER 85

111

112

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 3

Nonspinose (Globorotaliid) Wall Texture

FIGURE 1.— Globorotalia scitula (Brady), overall view of a thin-walled test showing smooth surface and scattered
pustules in umbilical area (bar = 100 pm). Recent, sediment trap, off Barbados.

FIGURE 2.— Globorotalia truncatulinoides (d’Orbigny), overall view of a medium thick-walled test showing
heavier pustule growth on the older chambers (bar = 200 pm). Recent, sediment trap, off Bermuda.

FIGURE 3.— Globorotalia inflata (d’Orbigny), overall view of a medium thick-walled test showing pustules of
various ages on all chambers (bar = 100 pm). Recent, plankton net catch, western South Atlantic Ocean.

Figure 4.— Globorotalia inflata (d’Orbigny), overall view of test showing a final layer of thick pustule growth
(bar = 100 pm). Recent, plankton net catch, off Bermuda.

Figure 5.— Globorotalia truncatulinoides (d’Orbigny), enlarged view of chamber surface with young small
pustules (bar = 10 pm). Recent, North Atlantic Ocean.

Figure 6.— Globorotalia inflata (d’Orbigny), enlarged view of tangential section of a thin-layered wall covering
a previously formed wall, indicating superposition of various calcification events (bar = 4 pm). Recent,
plankton net catch, off Bermuda.

FIGURE 7. — Globorotalia infata (d’Orbigny), enlarged view of tangential section of test wall showing
consecutive pustule growth that leads to a bumpy layered wall (bar = 20 pm). Recent, plankton net catch.
Chain 35, Station 89.

FIGURE 8.— Globorotalia scitula (Brady), enlarged view of 3rd and 4th chambers of Figure 1 showing
distribution of pustules and covering of pores by growth of pustules (bar = 20 pm). Recent, sediment trap, off
Barbados.

FIGURE 9.— Globorotalia truncatulinoides (d’Orbigny), enlarged view of test wall showing several generations
of pustule growth and an increase in wall thickness by pustule growth (bar = 40 pm). Recent, plankton net
catch. South Atlantic Ocean.

FIGURES 10, 11.— Globorotalia inflata (d’Orbigny): 10, enlarged view of test wall showing outermost pustules
and the beginning of calcite crust growth (bar = 20 pm); 11, additional calcification on top of pustules (bar =
4 pm). Recent, plankton net catch, off Bermuda.

FIGURE 12.— Globorotalia truncatulinoides (d’Orbigny), cross section of test wall showing the normal wall and
a layered pustule (bar = 20 pm). Recent, DSDP Site 2/4/2: 149-151 cm; Gulf of Mexico.

FIGURE 13.— Globorotalia truncatulinoides (d’Orbigny), branching pustules (bar = 40 pm). Recent, DSDP Site
2/4/2: 149-151 cm; Gulf of Mexico.

FIGURES 14-16 .—Globorotalia menardii (Parker, Jones, and Brady): 14, cross section of test wall showing the
normal wall and the beginning of the calcite crust (elongated crystals); 15, early stage of keel development
showing the doubling of the wall; at this stage the keel contains a few pores that do not function (bar = 10 pm).
Recent, DSDP Site 2/4/2: 149-151 cm; Gulf of Mexico. 16, medium stage of keel development showing the
layering of the keel (bar = 10 pm). Recent, DSDP Site 1/1/1: 1-4 cm; Gulf of Mexico.

NUMBER 85

113

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114

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 4

Nonspinose (Globorotaliid) Wall Texture, Cretaceous and Paleocene

FIGURES 1-3.— Hedbergella holmdelensis Olsson: 1, overall view of test showing a smooth wall with pustule
distribution resembling Globorotalia scitula (Brady) (bar = 50 pm); 2, enlarged view of 3rd chamber showing
overgrowth of pores by pustules (bar = 5pm); 3, pustule growth covering wall surface on 5th chamber (bar =
5 pm). Topotype, upper Maastrichtian, Navesink Formation, New Jersey.

FIGURES 4, 5.— Globanomalina archeocompressa (Blow): 4, overall view of test showing a smooth surface with
a pustule distribution similar to G. scitula (Brady) and H. holmdelensis Olsson (bar = 20 pm); 5, enlarged view
of wall showing a smooth surface and some small pustules in front of the aperture (bar = 10 pm). Paleocene,
Zone PI a, DSDP Site 356/29/1: 70-72 cm; Sao Paulo Plateau, South Atlantic Ocean.

FIGURES 6, 7. — Globanomalina planocompressa (Shutskaya): 6, overall view of test showing a very smooth
surface and no pustules (bar = 50 pm); 7, closeup view of 3rd chamber (bar = 10 pm). Paleocene, Zone P1 c,
Mexia Clay, Texas.

FIGURE 8.— Globanomalina chapmani (Parr), enlarged view of test wall showing smooth surface and some pores
in the imperforate peripheral band (bar = 10 pm). Paleocene, Zone P4, Glendola Well, New Jersey, sample
286-287 feet.

FIGURES 9, 10. — Globanomalina pseudomenardii (Bolli): 9, cross section of test wall showing the layered wall
and the trace of the POM (primary organic membrane) and pustule exhibiting the same morphology as in
globorotaliid species (bar = 2 pm), Paleocene, Zone P4, Whitesville Well, New Jersey, sample 210-215 feet.
10, view of surface layer on top of keel and of pustules of various generations (bar = 10 pm), Paleocene, Zone
P4, Glendola Well, New Jersey, sample 286-287 feet.

FIGURES 11-13, 16.— Globanomalina imitata (Subbotina): 11, enlarged view of test wall showing typical
globorotaliid pustules (bar = 10 pm); 12, chambers of the inner whorl showing conical inner chambers with
rounded and sharp-tipped pustules (bar = 20 pm); 13, enlarged view of inner chamber of Figure 12 showing
pustules (bar = 10 pm); Paleocene, Zone P4, Whitesville Well, New Jersey, sample 210-215 feet. 16, enlarged
view of inner chamber showing same pustule development as in Figure 12 (bar = 10 pm), Paleocene, Zone P4,
DSDP Site 384/7/CC; southeast Newfoundland Ridge, North Atlantic Ocean.

FIGURE 14.— Morozovella praeangulata (Blow), enlarged view of test wall showing pustules growing on a
smooth “globorotaliid” surface (bar = 20 pm). Paleocene, Zone P3b, DSDP Site 527/28/6: 30-32 cm; Walvis
Ridge, eastern South Atlantic Ocean.

FIGURE 15.— Morozovella velascoensis (Cushman), enlarged view of test wall showing different sized pustules
growing on a smooth “globorotaliid” surface (bar = 20 pm). Paleocene, Zone P5, DSDP Site 213/16/1: 104
cm; Wharton Basin, eastern Indian Ocean.

NUMBER 85

115

116

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 5

Acarinina and Praemurica Wall Texture

FIGURE 1.— Acarinina strabocella (Loeblich and Tappan), enlarged view of test wall showing a smooth
(globorotaliid) surface with simple and coalescent pustules (bar = 10 pm). Paleocene, Zone P2, DSDP Site
356/25/5: 148-150 cm; Sao Paulo Plateau, South Atlantic Ocean.

FIGURE 2. — Acarinina nitida (Martin), enlarged view of test wall showing a smooth (globorotaliid) surface with
simple and coalescent pustules, similar to Figure 1; wall texture, pustule morphology, and distribution is
typical of extant globorotaliids (bar = 20 pm). Paleocene, Zone P4, DSDP Site 384/8/1: 136-138 cm;
southeast Newfoundland Ridge, North Atlantic Ocean.

FIGURE 3.— Acarinina mckannai (White), enlarged view of test wall showing heavy, coalescing pustule growth
on a smooth (globorotaliid) surface; wall texture, pustule morphology, and distribution is typical of extant
globorotaliids (bar = 20 pm). Paleocene, Zone P4, DSDP Site 384/6/CC; southeast Newfoundland Ridge,
North Atlantic Ocean.

FIGURE 4.— Acarinina subsphaerica (Subbotina), enlarged view of test wall showing heavy pustule growth; wall
texture, pustule morphology, and distribution is typical of extant globorotaliids (bar = 20 pm). Paleocene,
Zone P4, DSDP Site 465/5/1: 65-67 cm; Hess Rise, central Pacific Ocean.

FIGURES 5-8.— Neogloboquadrina dutertrei (d’Orbigny), overall view of thin (Figure 5), medium (Figures 6, 7),
and thick (Figure 8) walled specimens showing development of globoquadrinid wall texture by growth and
coalescing of pustules to form a cancellate wall texture. A calcite crust is formed in the final stage (Figure 8).
(Figure 5: bar = 50 pm; Figures 6-8: bar = 100 pm.) Recent, plankton net catch, eastern North Atlantic.

FIGURES 9-11.— Neogloboquadrina dutertrei (d’Orbigny): 9, 10, enlarged views of test wall of same specimen
showing pores separated by elongated, subparallel ridge-like structures, which are connected by short, less
developed ridges, thereby forming the cancellate wall texture. (Figure 9: bar = 20 pm; Figure 10: bar = 10
pm.) Recent, sediment trap, off Barbados. 11, two enlarged views of test wall of single specimen showing
gametogenetic calcification and early formation of a calcite crust. The wall thickens as the individual sinks to
deeper water, e.g., deep chlorophyll maximum. (Bars = 20 pm and 5 pm, respectively.) Recent, plankton net
catch, off Bermuda.

FIGURES 12-15.— -Hedbergella monmouthensis (Olsson), views of test wall showing the development and
distribution of pustules on a smooth surface: 12, overall view of specimen (bar = 40 pm); 13, enlarged view
of ultimate chamber with small scattered pustules; 14, enlarged view of penultimate chamber showing growth
and coalescing of pustules; 15, enlarged view of 4th chamber showing coalescing of pustules around pores,
which is an initial step toward the development of a cancellate wall texture. (Figures 13-15: bars = 10 pm.)
Topotype, upper Maastrichtian. Redbank Formation, New Jersey.

FIGURES 16-18.— Praemurica taurica (Morozova): 16, overall view of test showing the globoquadrinid-type
(praemuricate) wall texture (bar = 40 pm); 17, enlarged view of test wall of another specimen showing the
praemuricate cancellate wall (bar = 10 pm); 18, enlarged view of test wall of another specimen showing
elongate, subparallel ridges connected by short, less developed ridges surrounding the pores (bar = 10 pm).
Paleocene, Zone PI a, Millers Ferry, Alabama, core 225, Figures 16, 17, from sample 216 and Figure 18 from
sample 194.

118

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 6

Praemurica and Microperforates

FIGURES 1-4.— Praemurica pseudoinconstans (Blow): 1, overall view of test showing the globoquadrinid-type
(praemuricate) wall texture (bar = 40 pm); 2, 4, enlarged view of 6th and 3rd chambers, respectively, showing
the typical praemuricate wall texture of elongate, subparallel ridges connected by shorter, less developed ridges
surrounding the pores, and showing light gametogenetic calcification (bar = 10 pm); 3, enlarged view of
another specimen showing the praemuricate wall texture (bar = 10 pm). Paleocene, Zone PI a, Millers Ferry,
Alabama, core 225, sample 194.

FIGURE 5.— Igorina pusilla (Bolli), enlarged view of test wall showing the praemuricate wall texture (bar = 10
pm). Paleocene, Zone P4, Glendola Well, New Jersey, sample 286-287 feet.

FIGURE 6.— Igorina albeari (Cushman and Bermudez), enlarged view of test wall showing the typical
praemuricate wall texture of subparallel ridges connected by shorter, less developed ridges surrounding the
pores (bar = 20 pm). Paleocene, Zone P3b, DSDP Site 356/24/2: 92-94 cm; Sao Paulo Plateau, South Atlantic
Ocean.

FIGURES 7-10. — Globigerinita glutinata (Egger): 7, overall view of early adult form showing microperforate
wall and scattered small pustules (bar = 100 pm); 8, mature adult form showing heavy pustulose wall texture
and bulla with scattered small pustules (bar = 100 pm); 9, enlarged view of test wall of another specimen
showing microperforate wall with multifaceted pustules covering pores (bar = 20 pm); 10, enlarged view of
test wall of another specimen showing microperforate wall with small rounded pustules overgrowing pores
(bar = 5 pm). Recent, plankton net sample. North Atlantic Ocean.

FIGURES 11, 12.— Globoconusa daubjergensis (Bronnimann): 11, overall view of test showing microperforate
wall with scattered pustules (bar = 50 pm); 12, enlarged view of another specimen showing microperforate
wall with sharp-pointed pustules (bar = 10 pm). Paleocene, Zone Pic, Brightseat Formation, Maryland.

FIGURES 13, 14.— Chiloguembelina crinila (Glaessner): 13, overall view of test showing microperforate wall
covered with coarse rounded pustules (bar = 50 pm); 14, enlarged view of 3rd chamber showing
microperforate wall and rounded pustules overgrowing pores (bar = 10 pm). Paleocene, Zone P4, Whitesville
Well, New Jersey, sample 180-185 feet.

FIGURES 15-18.— Chiloguembelina morsei (Kline): 15-17, overall view and enlarged views of test wall showing
microperforate texture with coarse multifaceted pustules overgrowing pores (compare to Figure 9) (Figure 15:
bar = 40 pm; Figures 16, 17: bar = 10 pm). Paleocene, Zone P2, DSDP Site 356/24/2: 92-94 cm; Sao Paulo
Plateau, South Atlantic Ocean. 18, enlarged view of test wall, partially recrystallized, showing multifaceted
pustules (bar = 20 pm). Paleocene, ODP Hole 690B/16/5: 76-80 cm; Maud Rise, Southern Ocean.

120

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 7

Diagenesis

FIGURES 1, 2.— Subbotina cancellata Blow, overall view and enlarged view of recrystallized and corroded
specimen; diagenesis obscures original wall texture, although a spine hole is visible in center of picture (Figure
1: bar = 40 pm; Figure 2: bar= 10 pm). Paleocene, Zone P2, DSDP Hole 398D/39/4: 145-147 cm; western
Iberian continental margin, eastern North Atlantic Ocean.

FIGURE 3.— Eoglobigerina edita (Subbotina), enlarged view of test wall showing corrosion and dissolution (bar
= 4 pm). Paleocene, Zone Pa, Millers Ferry, Alabama, core 226, sample 8.

FIGURE 4.— Subbotina trivialis (Subbotina), enlarged view of heavily recrystallized and overgrown test wall
showing euhedral calcite crystals closing off pores, although a spine hole is still visible in center of picture (bar
= 20 pm). Paleocene, Zone PI, DSDP Hole 390A/11/4; 80-82 cm; Blake-Bahama Basin, North Atlantic
Ocean.

FIGURES 5, 6.— Parasubbotina pseudobulloides (Plummer), enlarged views of corroded and recrystallized test
wall; diagenesis has nearly obliterated original wall texture, but a few spine holes are preserved (Figure 5; bar
= 10 pm; Figure 6: bar = 4 pm). Paleocene, Zone Pla, Millers Ferry, Alabama, core 226, sample 85.

FIGURE 7.— Acarinina strabocella (Loeblich and Tappan), enlarged view of recrystallized wall showing fine
subhedral crystals; recrystallized pustules show euhedral crystal surfaces (bar = 10 pm). Paleocene, Zone P3,
ODP Hole 750A/11/1: 149-150 cm; southern Kerguelen Plateau, Southern Ocean.

FIGURE 8. — Praemurica inconstans (Subbotina), enlarged view of recrystallized and overgrown test wall,
showing closed off pores and obscured original wall texture (bar = 10 pm). Paleocene, Zone Pic, DSDP Site
577/12/1: 49-51 cm; Shatsky Rise, western Pacific Ocean.

FIGURE 9.— Subbotina cf. triangularis (White), enlarged view of partially dissolved wall showing calcitic pore
linings that are visible due to dissolution (bar = 10 pm). Paleocene, Zone P5, DSDP Site 2/3/16; Wharton
Basin, eastern Indian Ocean.

FIGURE 10.— Subbotina cf. velascoensis (Cushman), enlarged view of cross section showing recrystalled wall
with overgrowth on inner wall, but POM is still visible (bar = 10 pm). Paleocene, Zone P2, DSDP Site
398D/39/4: 145-147 cm; western Iberian continental margin, eastern North Atlantic Ocean.

FIGURE 11.— Subbotina sp., enlarged view of heavily recrystallized wall (bar = 4 pm). Paleocene, Zone Pa,
DSDP Site 577/12/5: 113-114 cm; Shatsky Rise, western Pacific Ocean.

FIGURE 12.— Subbotina triangularis (White), enlarged view of cross section showing heavily recrystallized wall
completely obscuring the original wall texture (bar = 10 pm). Paleocene, Zone P4, DSDP Site 549/20/2:
69-71 cm; Goban Spur, eastern North Atlantic Ocean.

FIGURES 13, 14.— Parvularugoglobigerina eugubina (Luterbacherand Premoli Silva), overall view and enlarged
view showing completely recrystallized test wall; original microperforate wall is obscured (Figure 13: bar = 40
pm; Figure 14: bar = 10pm). Paleocene, Zone Pa, DSDP Site 577/12/5: 125-126 cm; Shatsky Rise, western
Pacific Ocean.

FIGURE 15.— Chiloguembelina wilcoxensis (Cushman and Ponton), enlarged view of recrystallized wall showing
recrystallized pustules; microperforate wall is obscured (bar = 10 pm). Paleocene, ODP Hole 690B/16/5:
76-80 cm; Maud Rise, Southern Ocean.

122

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 8

Russian Primary Type Specimens

(bars = 100 pm)

FIGURES 1-3.— Guembelitria irregularis Morozova, 1961:17, pi. 1: fig. 9, holotype no. 3510/13a, Moscow
GAN; Danian, Tarkhankut, Crimea. See “Discussion” for Guembelitria cretacea.

FIGURES 4-6.— Globigerina (Eoglobigerina) trifolia Morozova, 1961:12, pi. 1: fig. 1, holotype no. 3510/4,
Moscow GAN; Danian, Tarkhankut, Crimea. See “Discussion” for Globoconusa daubjergensis.

FIGURES 7-9.— Acarinina multiloculata Morozova, 1961:15, pi. 2: fig. 5, holotype no. 3510/10, Moscow GAN;
Montian, Balka Nasypkoiskaya, Crimea. Probably a reworked specimen of Hedbergella planispira (Tappan,
1940).

FIGURES 10-12.— Globigerina (Eoglobigerina ) eobulloides Morozova, 1959:1115, text-fig. la-c, holotype no.
3508/1, Moscow GAN; Danian, Tarkhankut, Crimea. See Eoglobigerina eobulloides.

FIGURES 13-15.— Globigerina ( Eoglobigerina) hemisphaerica Morozova, 1961:11, pi. 1: fig. 4, holotype no.
3510/3, Moscow GAN; Danian, Tarkhankut, Crimea. See “Discussion” for Eoglobigerina edita.

FIGURES 16-18.— Globigerina ( Eoglobigerina ) theodosica Morozova, 1961:11, pi. 1: fig. 6, holotype no.
3510/2, Moscow GAN; Danian, Tarkhankut, Crimea. See “Discussion” for Eoglobigerina edita.

NUMBER 85

123

. O&W

124

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 9

Russian Primary Type Specimens

(bars = 100 (am)

FIGURES 1-3. — Globigerina ( Eoglobigerina) tetragona Morozova, 1961:13, pi. 1: fig. 2, holotype no. 3510/5,
Moscow GAN; Danian, Pre-Caspian Basin, Novouzensk. See “Discussion” for Eoglobigerina edita.

FIGURES 4-6. — Globigerina ( Eoglobigerina) pentagona Morozova, 1961:13, pi. 1: fig. 3, holotype no. 3510/6,
Moscow GAN; Danian, Tarkhankut, Crimea. See “Discussion” for Eoglobigerina edita.

FIGURES 7-9.— Globigerina fringa Subbotina, 1953:62, pi. 3: fig. 3, holotype no. 2175, St. Petersburg VNIGRI
(323/39); Danian, Pecten horizon, Azov-Black Sea flysch, Anapa, Caucasus. See “Discussion” for Subbotina
cancellata.

FIGURES 10-12.— Globigerina trivialis Subbotina, 1953:64, pi. 4: fig. 4a-c, holotype no. 4004, St. Petersburg
VNIGRI (378/30); Elburgan Fm., Kuban River section, northern Caucasus. See Subbotina trivialis.

FIGURES 13-15.— Globigerina ( Globigerina ) microcellulosa Morozova, 1961:14, pi. 1: fig. 11, holotype no.
3510/7, Moscow GAN; Danian, Tarkhankut, Crimea. See “Discussion” for Subbotina triloculinoides.

FIGURES 16-18.— Globigerina varianta Subbotina, 1953:63, pi. 3: fig. 5a-c, holotype no. 3994, St. Petersburg
VNIGRI (378/20); zone of rotaliform Globorotalia, Elburgan Fm., Kuban River section, northern Caucasus.
See Parasubbotina varianta.

NUMBER 85

125

126

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 10

Russian Primary Type Specimens

(bars = 100 pm)

FIGURES 1-3.— Globigerina ( Eoglobigerina) taurica Morozova, 1961:10, pi. 1: fig. 5, holotype no. 3510/1,
Moscow GAN; Danian, Tarkhankut Peninsula, Crimea. See Praemurica taurica.

FIGURES 4-6.— Globigerina inconstans Subbotina, 1953:58, pi. 3: fig. 1, holotype no. 3992, St. Petersburg
VNIGRI (378/18); zone of rotaliform globorotaliids, Elburgan Fm., Kuban River, northern Caucasus. See
Praemurica inconstans.

FIGURES 7, 8.— Acarinina praecursoria Morozova, 1957:1 1 11, text-fig. 1, holotype no. 3507/1, Moscow GAN;
Danian, Khokhodz’ River, northern Caucasus. See “Discussion” for Praemurica inconstans and for
Praemurica uncinata.

FIGURES 9-11.— Acarinina indolensis Morozova, 1959:1116, text-fig. 1, holotype no. 3508/2, Moscow GAN;
Danian, Tarkhankut Peninsula, Crimea. See “Discussion” for Praemurica uncinata.

FIGURES 12-14.— Globorotalia imitala Subbotina, 1953:206, pi. 16: fig. 14a-c, holotype no. 4073, St.
Petersburg VNIGRI (378/112); zone of rotaliform globorotaliids (Danian?), Elburganian horizon, Kuban
River, northern Caucasus. See Globanomalina imitata.

Figures 15-17.— Globorotalia planoconica Subbotina, 1953:210, pi. 17: fig. 4a-c, holotype no. 4081, St.
Petersburg VNIGRI (378/118); zone of conical globorotaliids, lower to middle Eocene (probably lower
Eocene), Series FI, Khieu River, Caucasus. See Globanomalina planoconica.

NUMBER 85

127

128

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 11

Russian Primary Type Specimens

(bars = 100 pm)

FIGURES 1-3.— Globorotalia convexa Subbotina, 1953:209, pi. 17: fig. 2a-c, holotype no. 4079, St. Petersburg
VNIGRI (378/116); zone of conical globorotaliids, lower to middle Eocene (probably lower Eocene), Series
FI, Khieu River, Caucasus. See “Discussion” for Jgorina tadjikistanensis.

FIGURES 4-6.— Globorotalia tadjikistanensis Bykova, 1953:86, pi. 3: fig. 5a-c, holotype no. 2794-a (upper
specimen), St. Petersburg VNIGRI (350/10); Suzakian Stage (middle Paleocene), Ak-Tau, southern part of
Tadzhik Basin, Kazakhstan. See “Discussion” for Igorina tadjikistanensis.

FIGURES 7-9.— Globorotalia tadjikistanensis Bykova, 1953:86, paratype no. 2794-a (middle specimen), St.
Petersburg VNIGRI (350/10); Suzakian Stage (middle Paleocene), Ak-Tau, southern part of Tadzhik Basin,
Kazakhstan. See Igorina tadjikistanensis.

FIGURES 10-15.— Globorotalia angulata (White) var. kubanensis Shutskaya, 1956, specimens from remaining
collections of Shutskaya (no. 645-32), St. Petersburg VNIGRI; zone of Acarinina conicotruncata, PC 1 (middle
Paleocene), Khieu River, Caucasus. Holotype in Moscow is lost, hence the identity of this taxon
cannot be determined. Further confusing the taxonomic status of this taxon is the specimen represented by
Figures 10-12, which is probably referable to Morozovella apanthesma (Loeblich and Tappan), and the
specimen represented by Figures 13-15, which is probably referable to Morozovella acutispira (Bolli and
Cita). The holotype figure, in contrast, resembles Morozovella conicotruncata (Subbotina).

NUMBER 85

129

130

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 12

Russian Primary Type Specimens

(bars = 100 (am)

FIGURES 1-3.— Acarinina acarinata Subbotina, 1953:229, pi. 22: fig. 5, paratype no. 4129, St. Petersburg
VNIGR1 (378/160); zone of compressed globorotaliids, Paleocene-lower Eocene, Series FI, Khieu River,
Caucasus. See “Discussion” for Acarinina nitida.

FIGURES 4-6.— Acarinina intermedia Subbotina, 1953:227, pi. 20: fig. 15, holotype no. 4095, St. Petersburg
VNIGRI (378/124); zone of compressed globorotaliids, Paleocene?, Goryache Klynch horizon, Kuban River,
Caucasus. See “Discussion” for Acarinina nitida.

FIGURES 7-9.— Guembelitria dammula Voloshina, 1961, hypotype; Paleocene, P0, Bjala (K/T section no. 2b,
1-2 cm above boundary), Bulgaria. See “Discussion” for Guembelitria cretacea.

FIGURES 10-12.— Globanomalina imitata (Subbotina, 1953), hypotype; Paleocene, Plb/c, Bjala (K/T section no.
2b, sample Sum 24/12), Bulgaria. See Globanomalina imitata.

NUMBER 85

131

132

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 13

USNM Primary Type Specimens

(bars = 50 pm)

FIGURE 1.— Rectogiimbelina cretacea Cushman, 1932, holotype, USNM CC16308; upper Maastrichtian,
Arkadelphia Clay, Hope, Arkansas.

FIGURE 2.— Tubitextularia laevigata Loeblich and Tappan, 1957 (= Rectoguembelina cretacea Cushman),
holotype, USNM P5820; lower Paleocene, McBryde Limestone Mbr„ Clayton Fm., Wilcox Co., Alabama.

FIGURE 3.— Guembelitria cretacea Cushman, 1933, holotype, USNM CC 19022; upper Maastrichtian, Navarro
Fm., Texas.

FIGURES 4, 5.— fVoodringina homerstownensis Olsson, 1960, holotype, USNM 626457; Zone P3b, Homerstown
Fm., New Jersey.

FIGURES 6, 7.— Woodringina claytonensis Loeblich and Tappan, 1957, holotype, USNM P5685; lower Danian,
Pine Barren Mbr., Clayton Fm., Alabama.

FIGURE 8.— Woodringina kelleri MacLeod, 1993 (= Woodringina claytonensis Loeblich and Tappan); Zone Pa,
DSDP Site 577A/12/2: 44-46 cm; Shatsky Rise, northwestern Pacific Ocean.

FIGURES 9, 10.— Gumbelina midwayensis Cushman, 1940, holotype, USNM CC35715; basal Midway Fm.,
Sumter Co., Alabama.

FIGURES 11, 16.— Gumbelina trinitatensis Cushman and Renz, 1942, holotype, USNM CC38198; Paleocene,
Soldado Fm., Trinidad.

FIGURES 12, 13.— Chiloguembelina midwayensis strombiformis Beckmann, 1957 (= Chiloguembelina
midwayensis (Cushman)), holotype, USNM P5771; Globorotalia pseudomenardii Zone, Lizard Springs Fm.,
Trinidad.

FIGURES 14, 15.— Giimbelina morsei Kline, 1943, holotype, USNM 487301; Danian, Porters Creek Clay, Clay
Co., Mississippi.

FIGURES 17, 18.— Chiloguembelina subtriangularis Beckmann, 1957, holotype, USNM P5783; Globorotalia
pusilla pusilla Zone, lower Lizard Springs Fm., Trinidad.

Figures 19, 20.— Giimbelina wilcoxensis Cushman and Ponton, 1932, holotype, USNM 16218; Wilcox Fm.,
Ozark, Alabama.

NUMBER 85

133

134

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 14

USNM Primary Type Specimens

(bars = 50 pm)

FIGURES 1-3.— Globigerina compressa Plummer, 1926, lectotype, Chicago Field Museum UC5509I; upper
Danian, Zone P2, Wills Point Fm., Midway Group, Navarro Co., Texas.

FIGURES 4, 8, 12.— Globorotalia ehrenbergi Bolli, 1957, holotype, USNM P5060; upper Paleocene, Lizard
Springs Fm., Trinidad.

FIGURES 5-7.— Globorotalia pseudomenardii Bolli, 1957, holotype, USNM P5061; Globorotalia pseudomenar-
dii Zone, Lizard Springs Fm., Trinidad.

FIGURES 9-11.— Globorotalia uncinata Bolli, 1957, holotype, USNM P5048; Globorotalia uncinata Zone,
lower Lizard Springs Fm., Trinidad.

FIGURES 13, 14.— Globorotalia trinidadensis Bolli, 1957 (= Praemurica inconstans (Subbotina)). holotype,
USNM P5044; Globorotalia trinidadensis Zone, lower Lizard Springs Fm., Trinidad.

FIGURES 15, 16.— Globigerina triloculinoides Plummer, 1926, paratype, USNM 370088; Zone P2, Wills Point
Fm., Midway Group, Navarro Co., Texas, Plummer station 23.

NUMBER 85

135

136

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 15

USNM Primary Type Specimens

(bars = 50 pm)

Figures 1-3.— Globorotalia strabocella Loeblich and Tappan, 1957, holotype, USNM P5879; Nanafalia Fm.,
Alabama.

FIGURES 4, 7, 8.— Globigerina soldadoensis Bronnimann, 1952, holotype, USNM 370085; Lizard Springs Fm.,
Trinidad; type locality of Globorotalia velascoensis Zone of Bolli, 1957a = Zone P5.

FIGURES 5, 6.— Globigerina aquiensis Loeblich and Tappan, holotype, USNM P5839; Aquia Fm., Aquia Creek,
Virginia.

FIGURES 9, 10.— Globigerina chascanona Loeblich and Tappan, 1957 (= Acarinina subsphaerica (Subbotina)),
holotype, USNM P5842; Zone P4, uppermost Homerstown Fm., New Jersey.

FIGURES 11, 12, 15.— Globorotalia crassata (Cushman) var. aequa Cushman and Renz, 1942, holotype, USNM
CC38210; near base of Globorotalia subbotinae Zone, Soldado Fm., Trinidad.

FIGURES 13, 14.— Globigerina daubjergensis Bronnimann, 1953, holotype, USNM CC64879; Danian, Daubjerg
Quarry, Denmark.

NUMBER 85

137

mm

138

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 16

USNM Primary Type Specimens

(bars = 50 pm)

FIGURES 1-3. —Globorotalia albeari Cushman and Bermudez, 1949, holotype, USNM CC47413; Globorotalia
pseudomenardii Zone, Madruga Fm., Cuba.

FIGURES 4-6. — Globorotalia pusilla laevigata Bolli, 1957 (= Igorina albeari (Cushman and Bermudez)),
holotype, USNM P5065; Globorotalia pseudomenardii Zone, Lizard Springs Fm., Trinidad.

FIGURES 7-9.— Globorotalia pusilla pusilla Bolli, 1957, holotype, USNM P5064; Globorotalia pusilla pusilla
Zone, Guayaguayare Well 159, Trinidad Leasholds, Ltd., Lizard Springs Fm., Trinidad.

FIGURES 10-12. —Globigerina spiralis Bolli, 1957, holotype, USNM P5030; Globorotalia uncinata Zone, lower
Lizard Springs Fm., Trinidad.

NUMBER 85

139

140

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 17

USNM Primary Type Specimens

(bars = 50 pm)

FIGURES 1-3.— Globorotalia apanthesma Loeblich and Tappan, 1957, holotype, USNM P5860; Zone P4, Aquia
Fm., Virginia.

FIGURES 4-6.— Globorotalia occlusa Loeblich and Tappan, 1957, holotype, USNM P5874; Zone P4, Velasco
Shale, Tamaulipas, Mexico.

FIGURES 7-9.— Pseudogloborotalia pasionensis Bermudez, 1961, holotype, USNM 639063; sample G-58, Rio
de Pasion, El Peten, Guatemala.

FIGURES 10-12.— Pulvinulina velascoensis Cushman, 1925, holotype, USNM CC4347; Velasco Fm., San Luis
Potosi, Tampico Embayment, eastern Mexico.

85

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142

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 18

Eoglobigerina edita (Subbotina, 1953)

(Figures 1-14: bars = 50 pm; Figure 15: bar = 20 pm; Figure 16: bar = 10 pm)

FIGURE 1.—Zone Pa, Millers Ferry, Alabama, core 226, sample 85.

Figures 2, 3, 5, 6.—Zone Pla, DSDP Site 356/28/2: 144-145 cm; Sao Paulo Plateau, South Atlantic Ocean.

FIGURES 4, 15, 16.—Zone Pla, Millers Ferry, Alabama, core 225, sample 194; Figures 15, 16, views of wall
texture of 3rd chamber of Figure 4.

FIGURE 7. —Zone Pla, Millers Ferry, Alabama, core 225, sample 216.

FIGURES 8-14.—Zone Pic, Brightseat Fm., Maryland.

NUMBER 85

143

144

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 19

Eoglobigerina eobulloides Morozova, 1959

(Figures 1-12: bars = 50 pm; Figures 13, 15: bars = 10 pm; Figure 14: bar = 4 (am)

FIGURES 1, 2, 5, 13-15. —Zone Pa, Millers Ferry, Alabama, core 226, sample 85; Figures 13-15, views of 3rd
chamber of Figure 5 showing spinose cancellate wall texture.

FIGURES 3, 7, 11, 12.—Zone PI a, Millers Ferry, Alabama, core 226, sample 216.

FIGURES 4, 6.—Zone Pla, DSDP Hole 350A/11/4: 80-82 cm; Greenland.

FIGURE 8.—Zone P0, Millers Ferry, Alabama, core 225, sample 349.

FIGURE 9. —Zone Pa, Millers Ferry, Alabama, core 226, sample 84.

Figure 10. —Zone Pic, Brightseat Fm., Maryland.

NUMBER 85

145

146

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 20

Eoglobigerina spiralis (Bolli, 1957)

(Figures 1-9, 11: bars = 50 pm; Figure 10: bar = 4 jam)

FIGURES 1-6, 10.—Zone Pic, Midway Fm., Texas, Plummer station 14; Figure 10, view of 5th chamber of
Figure 5 showing spinose wall texture.

FIGURES 7-9.—Zone P2, DSDP Site 356/25/5: 109-111 cm.

FIGURE 11.—Zone P2, DSDP Site 356/26/4: 30-32 cm; Sao Paulo Plateau, South Atlantic Ocean.

NUMBER 85

147

148

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 21

Parasubbotina pseudobulloides (Plummer, 1926)

(Figures 1-11: bars = 50 (am; Figures 12-15: bars = 5 pm)

FIGURES 1-4, 8, 12.—Zone P2, Midway Group, Texas, sample 8030; Figure 12, view of 2nd chamber of Figure
4 showing cancellate spinose wall texture.

Figures 5, 9. —Zone PI a, Millers Ferry, Alabama, surface sample 30 feet.

FIGURES 6, 10, 11, 13, 14.—Zone Pla, Millers Ferry, Alabama, core 225, sample 216; Figures 13, 14, views of
4th chamber of Figure 6 showing cancellate spinose wall texture.

FIGURES 7, 15.—Zone Pla, Millers Ferry, Alabama, core 226, sample 85; Figure 15, view of 2nd chamber of
Figure 7 showing cancellate spinose wall texture.

NUMBER 85

149

150

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 22

Parasubbotina aff. pseudobulloides (Plummer, 1926)

(Figures 1-3: bars = 50 (am; Figures 4, 5: bars = 10 (am)

FIGURES 1-5.—Zone Pa, Millers Ferry, Alabama, core 226, sample 85; Figures 4, 5, views of 2nd chamber of
Figure 3 showing weakly developed cancellate spinose wall texture, slightly recrystallized.

Parasubbotina varianta (Subbotina, 1953)

(Figures 6-13: bars = 50 pm; Figures 14, 15: bars = 10 pm; Figure 16: bar = 4 pm)

FIGURES 6-8, 10-12, 14-16.—Zone P2, DSDP Site 356/25/5: 148-150 cm; Sao Paulo Plateau, South Atlantic
Ocean; Figure 14 (view of 2nd chamber of Figure 6) and Figure 15 (view of 3rd chamber of Figure 12),
showing cancellate spinose wall texture.

FIGURE 9.—Zone Pic, Mexia Clay Mbr., Midway Group, Texas.

FIGURE 13.—Zone PI a, Millers Ferry, Alabama, core 225, sample 194.

NUMBER 85

151

152

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 23

Parasubbotina variospira (Belford, 1984)

(Figures 1-14, 16: bars = 100 jam; Figure 15: bar= 200 |im)

Figures 1-10, 13, 15, 16.—Zone P3, DSDP Site 384/10/CC.

FIGURES 11, 12, 14.—Zone P3, DSDP Site 384/9/CC; southeast Newfoundland Ridge, North Atlantic Ocean.

b ixj»cr^'!^v*’'v

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154

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 24

Subbotina cancellata Blow, 1979

(bars = 100 pm)

FIGURES 1-12.— Zone Pic, DSDP Site 356/26/3: 90-92 cm; Sao Paulo Plateau, South Atlantic Ocean.
FIGURE 13.—Zone P4, Vincentown Fm., Glendola Well, New Jersey, sample 286-287 feet.

FIGURE 14.—Zone P4, DSDP Site 549/20/5: 20-22 cm; Goban Spur, eastern North Atlantic Ocean.

NUMBER 85

155

156

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 25

Subbotina cancellata Blow, 1979

(Figures 1-14: bars = 50 pm; Figure 15: bar = 10 pm)

FIGURES 1-15.—Morphotypes showing a range of variation in the number of chambers in the final whorl and in
the coarseness of the cancellate wall texture; Figure 7 shows transitional morphology to Subbotina trivialis
(Subbotina, 1953). See “Discussion” under S. cancellata on the relationship with Globigerina fringa
Subbotina, 1950. Zone Pic, DSDP Site 356/27/6: 38-40 cm; Sao Paulo Plateau, South Atlantic Ocean.

NUMBER 85

157

158

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 26

Subbotina triangularis (White, 1928)

(Figures 1-11: bars = 100 jam; Figure 12: bar = 10 (am; Figure 13: bar = 4 (im)

Figures 1, 3, 7, 8, 12, 13.—Zone P4, Vincentown Fm., Glendola Well, New Jersey, sample 286-287 feet; Figure
12 (view of 3rd chamber of Figure 11) and Figure 13 (view of 2nd chamber of Figure 8) showing spinose wall
texture.

Figures 2, 4-6, 9, 11.—Zone P4, Velasco Fm., Tamaulipas, Mexico.

FIGURE 10.—Upper Paleocene, Khieu River, foraminifer beds.

NUMBER 85

159

160

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 27

Subbotina triloculinoides (Plummer, 1926)

(Figures 1-11: bars = 50 pm; Figures 12, 13: bars = 5 pm)

Figure L—Zone P4, DSDP Site 549/20/2: 69-71 cm.

FIGURES 2, 6, 7.—Zone Pic, Mexia Clay Mbr., Midway Group, Texas.

FIGURES 3, 10.—Zone Plb, Eureka Core, Gulf of Mexico, sample 6817-6817.5 feet.

FIGURES 4, 9, 12, 13.—Zone Pic, Wills Point Fm., Milam Co., Texas; Figure 12, view of 2nd chamber of Figure
9 showing cancellate spinose wall texture; Figure 13, view of spine hole on interpore ridge.

FIGURE 5.—Zone Plb, Eureka Core, Gulf of Mexico, sample 6820-6820.5 feet.

FIGURE 8.—Zone PI, DSDP Hole 390A/11/4: 80-82 cm; Blake-Bahama Basin, North Atlantic Ocean.

FIGURE 11.—Zone P4, DSDP Site 549/20/5: 20-22 cm; Goban Spur, eastern North Atlantic Ocean.

NUMBER 85

161

162

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 28

Subbotina trivialis (Subbotina, 1953)

(Figures 1-11: bars = 100 pm; Figure 12: bar = 10 pm; Figure 13: bar = 4 pm)

FIGURE 1.—Zone Pic, upper Midway, Milam Co., Texas, sample 8030.

FIGURES 2, 5, 9.—Zone PI, DSDP Hole 390A/11/4: 80-82 cm; Maud Rise, Southern Ocean.

FIGURES 3, 10, 12, 13.—Zone PI a, Millers Ferry, Alabama, core 225, sample 194; Figures 12, 13, views of wall
of Figure 10 showing cancellate spinose wall texture.

FIGURE 4.—Zone PI a, Eureka Core, Gulf of Mexico, sample 6826.5-6827.0 feet.

FIGURES 6-8, 11.—Zone Pla, DSDP Site 356/28/2: 144-145 cm; Sao Paulo Plateau, South Atlantic Ocean.

NUMBER 85

163

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164

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 29

Subbotina velascoensis (Cushman, 1925)

(Figures 1-10, 12: bars = 100 (am; Figure 11: bar= 10 (am)

FIGURES 1, 3-6, 10. —Zone P4, Velasco Fm., Tamaulipas, Mexico.

FIGURES 2, 8, 9, 11, 12.—Zone P4, Glendola Well, New Jersey, sample 286-287 feet; Figure 11, view of wall
of Figure 8 showing cancellate spinose wall texture.

FIGURE 7.—Zone P4, Nerinea Fm., Pondicherry, South India.

NUMBER 85

165

166

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 30

Hedbergella holmdelensis Olsson, 1964

(bars = 50 pm)

FIGURES 1-16. —Topotypes, upper Maastrichtian, Navesink Fm., New Jersey.
FIGURE 17.— Zone P0, Millers Ferry, Alabama, core 225, sample 346.

NUMBER 85

167

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168

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 31

Hedbergella monmouthensis (Olsson, 1960)

(Figures 1-6, 8-13: bars = 50 pm; Figures 7, 14: bars = 10 pm; Figure 15: bar = 4 pm)

FIGURES 1-11.— Topotypes, upper Maastrichtian, Redbank Fm., New Jersey; Figure 7, enlarged view of
apertural lips of Figure 1.

FIGURES 12-15.—Zone P0, Millers Ferry, Alabama, core 225, sample 346; Figures 14, 15, views of wall of
Figure 13 showing development of primitive pore pits.

NUMBER 85

169

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.

170

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 32

Globanomalina archeocompressa (Blow, 1979)

(bars = 10 pm)

FIGURES 1-9.—Zone P0, Millers Ferry, Alabama, core 225, sample 342.

FIGURE 10.—Zone P0, Millers Ferry, Alabama, core 225, sample 346.

Globanomalina compressa (Plummer, 1926)

(bars = 100 pm)

FIGURES 11-13, 15, 16.—Zone Pic, DSDP Site 356/26/3: 90-92 cm; Sao Paulo Plateau, South Atlantic Ocean.

FIGURE 14.-—Zone P2, DSDP Hole 398D/39/4: 100-102 cm; western Iberian continental margin, eastern North
Atlantic Ocean.

NUMBER 85

171

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172

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 33

Globanomalina australiformis (Jenkins, 1965)

(Figures 7, 10, 11, 13: bars = 100 (am; Figures 1-4, 6: bars = 40 |am; Figures 8, 9: bars = 50 pm;

Figures 5, 12: bars = 10 |um)

Figures 1-6.—Topotypes, Subbotina triloculinoides Zone, N141/910N.2, Waipara, New Zealand; Figure 5,
view of 3rd chamber of Figure 3 showing wall texture.

FIGURES 8, 9.—Lower Paleocene, ODP Hole 738B/23X/CC; Kerguelen Plateau, southern Indian Ocean.

FIGURES 7, 10-13.—Zone Pic, ODP Hole 747C/2R/4: 90-92 cm; Kerguelen Plateau, southern Indian Ocean;
Figure 12, view of 4th chamber of Figure 13 showing wall texture.

NUMBER 85

173

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fV

rv tA.

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 34

Globanomalina chapmani (Parr, 1938)

(bars = 50 (am)

FIGURES 1, 2, 5, 6.—Zone P4, Vincentown Fm., Glendola Well, New Jersey, sample 286-287 feet.
Figure 4.—Zone P4, Vincentown Fm., Whitesville Well, New Jersey, sample 215-220 feet.
FIGURES 3, 7.—Zone P4, Nerinea Fm., Pondicherry, South India, sample PT14.

Globanomalina planoconica (Subbotina, 1953)

(bars = 50 pm)

FIGURES 8-17. —Zone P4, Velasco Fm., Tamaulipas, Mexico, John Cruz Collection, sample 17.

NUMBER 85

175

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111

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176

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 35

Globanomalina compressa (Plummer, 1926)

(Figures 1-3, 5-13, 17: bars = 100 pm; Figure 4: bar = 40 pm)

FIGURES 1, 3, 5, 7, 11.—Zone Pic, Mexia Clay Mbr., Midway Group, Texas.

FIGURE 4.—Zone P2, Wills Point Fm., Texas.

FIGURES 2, 6, 8-10.—Zone Pic, Brightseat Fm., Maryland.

FIGURES 12, 13, 17.—Zone Pic, DSDP Site 356/26/3: 90-92 cm; Sao Paulo Plateau, South Atlantic Ocean.

Globanomalina ehrenbergi (Bolli, 1957)

(bars = 100 pm)

FIGURES 14-16.—Zone Pic, Mexia Clay Mbr., Midway Group, Texas.

NUMBER 85

177

178

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 36

Globanomalina planocompressa (Shutskaya, 1965)

(Figures 1-4: bars = 40 pm; Figures 5, 6: bars = 100 pm)

FIGURE 1. —Zone PI a, Millers Ferry, Alabama, core 225, sample 194.

FIGURES 2, 3, 6. —Zone PI a, Millers Ferry, Alabama, surface sample 30 feet.

FIGURE 4. —Zone Plb, Eureka Core, Gulf of Mexico, sample 6817-6817.5 feet.

Figure 5.—Zone Pic, Brightseat Fm., Maryland.

Globanomalina imitata (Subbotina, 1953)

(Figures 8-13, 15, 16: bars = 40 pm; Figures 7, 14: bars = 100 pm)

FIGURES 7, 16.—Zone Pic, Mexia Clay Mbr., Midway Group, Texas.

FIGURES 8-12.—Zone P4, Vincentown Fm., Whitesville Well, New Jersey, sample 210-215 feet; Figure 12,
view showing inner whorl of conical-shaped chambers with pustulose surface.

FIGURES 13-15 .—Globanomalina aff. imitata transitional to G. ovalis, Zone P4, Nerinea Fm., Pondicherry,
South India, sample PT14.

NUMBER 85

179

(}■ -■/

180

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 37

Globanomalina ovalis Haque, 1956

(bars - 50 pm)

Figures 1-15.—Zone P4, Nerinea Fm., Pondicherry, South India, sample PT14.

NUMBER 85

181

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ms • jj\

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mmm

182

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 38

Globanomalina pseudomenardii (Bolli, 1957)

(bars = 50 pm)

FIGURES 1-7. —Zone P4, Velasco Fm., Tamaulipas, Mexico.

FIGURES 8, 10-16. —Zone P4, Vincentown Fm., Glendola Well, New Jersey, sample 286-287 feet.
FIGURE 9. —Zone P4, Nerinea Fm., Pondicherry, South India, sample PT14.

NUMBER 85

183

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y W*.

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^*”fiitnryi j. >y TiTf

184

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 39

Acarinina coalingensis (Cushman and Hanna, 1927)

(bars = 100 jim)

FIGURES 1, 4, 13-15.—Zone P5, DSDP Site 465/3/1: 59-61 cm; Hess Rise, central North Pacific Ocean.
FIGURES 2, 3, 8, 12, 16.—Zone P5, DSDP Hole 20C/6/4: 17-19 cm; Brazil Basin, South Atlantic Ocean.
FIGURES 5-7, 9-1 1. —Zone P5, ODP Hole 758A/28/1: 50-52 cm; Ninetyeast Ridge, Indian Ocean.

NUMBER 85

185

186

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 40

Acarinina mckannai (White, 1928)

(bars = 100 (am)

FIGURES 1-4.—Zone P4, DSDP Site 465/4/3: 62-64 cm; Hess Rise, central North Pacific Ocean.

FIGURES 5-7.—Zone P4, DSDP Site 384/6/CC; southeast Newfoundland Ridge, North Atlantic Ocean.
FIGURE 8. —Zone P4, DSDP Site 384/7/1: 60-62 cm; southeast Newfoundland Ridge, North Atlantic Ocean.
FIGURES 9-11—Zone P4, DSDP Site 527/27/1: 30-32 cm; Walvis Ridge, South Atlantic Ocean.

FIGURES 12, 16.—Zone P4, ODP Hole 758A/28/5: 50-52 cm; Ninetyeast Ridge, Indian Ocean.

FIGURE 13.—Late Paleocene, ODP Hole 738C/16R/1: 55-60 cm; Kerguelen Plateau, southern Indian Ocean.
FIGURES 14, 15.—Zone P4, Vincentown Fm., Glendola Well, New Jersey, sample 219-221 feet.

NUMBER 85

187

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wiw 1

188

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 41

Acarinina nitida (Martin, 1943)

(Figures 1-4, 7, 10: bars = 40 |im; Figures 13-15: bars = 50 pm; Figures 5, 6, 8, 9, 11, 12, 16: bars = 100 pm)
FIGURES 1-3, 7.—Zone P4, DSDP Site 384/9/2: 136-138 cm.

FIGURES 4, 10.—Zone P4, DSDP Site 384/8/4: 136-138 cm; southeast Newfoundland Ridge, North Atlantic
Ocean.

FIGURES 5, 8, 9, 11, 12.—Zone P4, Vincentown Fm., Glendola Well, New Jersey, sample 219-221 feet.

FIGURE 6.—Zone P5, ODP Hole 758A/28/3: 50-52 cm; Ninetyeast Ridge, Indian Ocean.

FIGURE 13.—Lower Eocene, ODP Hole 738C/10R: 277.78 mbsf.

FIGURES 14, 15.—Lower Eocene, ODP Hole 738C/10R/3: 98-102 cm; Kerguelen Plateau, southern Indian
Ocean.

FIGURE 16.—Upper Paleocene, ODP Hole 690B/25/3: 90-92 cm; Maud Rise, Southern Ocean.

NUMBER 85

189

190

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 42

Acarinina soldadoensis (Bronnimann, 1952)

(bars - 100 ^m)

FIGURES 1-3.—Zone P4, DSDP Site 465/4/4: 62-64 cm.

Figure 4.—Zone P5, ODP Hole 758A/28/3: 50-52 cm.

FIGURES 5-7.—Zone P6a, DSDP Hole 20C/3/1: 1-19 cm; Brazil Basin, South Atlantic Ocean.
FIGURES 8, 12-14.—Zone P5, DSDP Site 465/3/1: 59-61 cm; Hess Rise, central North Pacific Ocean.
Figures 9-11.—Zone P5, DSDP Site 213/16/1: 104-106 cm; eastern Indian Ocean.

FIGURES 15, 16.—Zone P4, ODP Hole 758A/28/5: 50-52 cm; Ninetyeast Ridge, Indian Ocean.

NUMBER 85

191

192

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 43

Acarinina strabocella (Loeblich and Tappan, 1957)

(Figures 1, 2, 5: bars = 40 (im; Figures 3, 4, 6-16: bars = 100 ^m)

FIGURE 1.—Zone P3b, Hornerstown Fm., New Jersey, NJT 12-1 A.

FIGURES 2, 3, 13.—Zone P2, DSDP Site 356/25/5: 148-150 cm; Sao Paulo Plateau, South Atlantic Ocean.
FIGURES 4, 7, 8, 10, 11, 14, 16.—Zone P2, ODP Hole 750A/11/2: 19-21 cm.

FIGURES 5, 6, 9, 12.—Zone P2/3, ODP Hole 750A/11/1: 149-150cm; Kerguelen Plateau, southern Indian Ocean.
FIGURE 15.—Zone P3, DSDP Site 384/9/6: 136-138 cm; southeast Newfoundland Ridge, North Atlantic Ocean.

NUMBER 85

193

wt

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mk

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194

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 44

Acarinina subsphaerica (Subbotina, 1947)

(bars = 100 pm)

FIGURES 1, 5, 16.—Zone P4, DSDP Site 384/7/CC; southeast Newfoundland Ridge, North Atlantic Ocean.
FIGURES 2, 3, 8, 10, 13.—Zone P4, DSDP Site 465/5/1: 65-67 cm.

FIGURE 4.—Upper Paleocene, ODP Hole 738C/15R: 322.07 mbsf; southern Kerguelen Plateau, Southern Ocean.
FIGURES 6, 7.—Zone P4, DSDP Site 527/27/1: 30-32 cm; Walvis Ridge, South Atlantic Ocean.

FIGURES 9, 11.—Zone P5, ODP Hole 758A/28/3: 50-52 cm; Ninetyeast Ridge, Indian Ocean.

Figure 12.—Zone P4, ODP Hole 761B/17/6: 49-51 cm; Wombat Plateau, eastern Indian Ocean.

FIGURES 14, 15.—Zone P4, DSDP Site 465/4/4: 62-64 cm; Hess Rise, central North Pacific Ocean.

NUMBER 85

195

196

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 45

Morozovella acuta (Toulmin, 1941)

(bars = 100 (am)

FIGURES 1, 3, 5, 6, 9-11.—Zone P4, Velasco Fm., Tamaulipas, Mexico.

FIGURES 2, 12-14.—Zone P3, DSDP Site 465/5/4: 63-64 cm; Hess Rise, central North Pacific Ocean.
FIGURES 4, 7, 8. —Zone P4, Vincentown Fm., Glendola Well, New Jersey, sample 230-232 feet.

NUMBER 85

197

198

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 46

Morozovella acutispira (Bolli and Cita, 1960)

(bars = 100 (am)

FIGURES 1-6.—Zone P3b, DSDP Site 527/28/6: 30-32 cm; Walvis Ridge, South Atlantic Ocean.

FIGURES 7, 12.— Zone P4, Vincentown Fm., Whitesville Well, New Jersey, sample 212-220 feet.

FIGURES 8, 9.—Zone P4?, ODP Hole 864C/13/2: 73-75 cm; East Pacific Rise, eastern central Pacific Ocean.
FIGURES 10, 11.—Zone P4, DSDP Site 465/3/4: 62-64 cm; Hess Rise, central North Pacific Ocean.

FIGURES 13-15.—Topotypes, Zone P4, Paderno d’Adda, northern Italy.

NUMBER 85

199

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gX

200

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 47

Morozovella aequa (Cushman and Renz, 1942)

(Figures 1-3, 7-10, 13-16: bars = 100 pm; Figures 4-6, 11, 12: bars = 200 pm)

FIGURES 1-3.—Zone P5, ODP Hole 758A/28/5: 50-52 cm.

FIGURES 4, 6, 7.—Zone P5, ODP Hole 758A/28/1: 50-52 cm, Ninetyeast Ridge, Indian Ocean.
FIGURES 5, 11, 12.—Zone P5, DSDP Site 465/3/1: 59-61 cm.

FIGURES 8-10.—Zone P4, DSDP Site 465/3/3: 98-100 cm; Hess Rise, central North Pacific Ocean.
FIGURES 13, 14, 16.—Zone P4, Vincentown Fm., Glendola Well, New Jersey, sample 230-232 feet.
FIGURE 15.—Zone P4, Velasco Fm., Tamaulipas, Mexico.

NUMBER 85

201

sL*v 3 .^-

202

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 48

Morozovella angulata (White, 1928)

(bars = 100 (am)

FIGURES 1-3, 11.—Zone P3, DSDP Site 356/21/4: 110-112 cm; Sao Paulo Plateau, South Atlantic Ocean;
Figures 1-3, M. aff. M. angulata.

FIGURES 4, 5, 7. —Zone P3, DSDP Site 465/6/5: 66-68 cm; Hess Rise, central North Pacific Ocean.

Figure 6.—Zone P2, DSDP Site 384/11/1: 86-88 cm.

FIGURES 8-10.—Zone P2, DSDP Site 527/30/1; 50-52 cm; Walvis Ridge, South Atlantic Ocean.

FIGURE 12.—Zone P2, DSDP Site 384/1 1/3: 30-32 cm.

Figures 13-16.—Zone P2, DSDP Site 384/10/CC; southeast Newfoundland Ridge, North Atlantic Ocean.

NUMBER 85

203

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204

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 49

Morozovella apanthesma (Loeblich and Tappan, 1957)

(bars = 100 (im)

FIGURES 1-6.—Zone P4, DSDP Site 465/4/1: 62-64 cm.

FIGURES 7-9.—Zone P3, DSDP Site 465/6/5: 66-68 cm.

FIGURES 10, 11.—Zone P3, DSDP Site 384/10/5: 24-26 cm; southeast Newfoundland Ridge, North Atlantic
Ocean.

FIGURES 12-15.—Zone P3a, DSDP Site 465/7/CC; Hess Rise, central North Pacific Ocean.

NUMBER 85

205

km

■j>, P »

?* j/

?Wka

206

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 50

Morozovella conicotruncata (Subbotina, 1947)

(Figures 1, 5, 9-15: bars = 100 ^m; Figures 2-4, 6-8: bars = 200 (am)

FIGURES 1-3.—Zone P3, DSDP Site 384/10/2: 136-138 cm.

Figures 4-6.—Zone P3, DSDP Site 465/6/5: 66-68 cm.

FIGURES 7-9.—Zone P3b, ODP Hole 758A/31/1: 50-52 cm; Ninetyeast Ridge, Indian Ocean.

Figures 10-12.—Zone P3, DSDP Site 465/6/3: 61-63 cm; Hess Rise, central North Pacific Ocean.

FIGURES 13-15.—Zone P3, DSDP Site 384/10/3: 10-12 cm; southeast Newfoundland Ridge, North Atlantic
Ocean.

NUMBER 85

207

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208

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 51

Morozovella occlusa (Loeblich and Tappan, 1957)

(bars = 100 (am)

FIGURES 1-3.—Zone P4, DSDP Site 465/4/1: 62-64 cm.

Figures 4, 8, 9.—Zone P4, Velasco Fm., Tamaulipas, Mexico.

Figures 5, 6.—Zone P4, DSDP Site 384/6/CC; southeast Newfoundland Ridge, North Atlantic Ocean.

FIGURE 7.—Zone P4, ODP Hole 758A/29/4: 50-52 cm; Ninetyeast Ridge, Indian Ocean.

FIGURES 10, 11.—Zone P4, DSDP Site 465/4/4: 62-64 cm.

FIGURES 12, 15.—Zone P4?, ODP Hole 864C/13/2: 73-75 cm; East Pacific Rise, eastern central Pacific Ocean.
Figures 13, 14.—Zone P4, DSDP Site 465/3/3: 98-100 cm; Hess Rise, central North Pacific Ocean.

NUMBER 85

209

210

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 52

Morozovella pasionensis (Bermudez, 1961)

(Figures 4, 5, 7, 8, 12, 14: bars = 100 |im; Figures 1-3, 6, 9-11, 13, 15: bars = 200 jam)

Figures 1-3, 10, 14.—Zone P3, DSDP Site 465/5/2: 62-64 cm.

FIGURES 4, 7, 13.—Zone P4, DSDP Site 465/3/3: 98-100 cm; Hess Rise, central North Pacific Ocean.

FIGURES 5, 8, 12.—Zone P4, ODP Site 865B/14/3: 138-140 cm; Allison Guyot, central equatorial Pacific Ocean.
FIGURE 6.—Zone P4, DSDP Site 384/7/1: 90-92 cm.

Figure 9.—Zone P4, DSDP Site 384/6/CC.

Figure 11.—Zone P4, DSDP Site 384/7/2: 106-108 cm.

FIGURE 15.—Zone P4, DSDP Site 384/6/3: 30-34 cm; southeast Newfoundland Ridge, North Atlantic Ocean.

NUMBER 85

211

X'S'S '•<

212

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 53

Morozovella praeangulata (Blow, 1979)

(bars = 100 |am)

FIGURES 1-3, 11-13.—Zone P3b, DSDP Site 356/24/2: 92-94 cm; Sao Paulo Plateau, South Atlantic Ocean.
Figures 4-6.—Zone P3, DSDP Site 384/10/5: 24-26 cm.

FIGURE 7. —Zone P3b, DSDP Site 465A/1/1: 52-54 cm; Hess Rise, central North Pacific Ocean.

Figure 8.— Zone P3, DSDP Site 384/10/CC.

FIGURES 9, 10.—Zone P2, DSDP Site 384/11/1: 86-90 cm; southeast Newfoundland Ridge, North Atlantic
Ocean.

NUMBER 85

213

214

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 54

Morozovella subbotinae (Morozova, 1939)

(Figures 1-3: bars = 50 (urn; Figures 4-12: bars = 100 (am)

FIGURES 1-3.—Zone AP6a, ODP Hole 738C/10R: 277.78 mbsf; southern Kerguelen Plateau, southern Indian
Ocean.

Figures 4, 5.—Zone P5, ODP Hole 758A/28/1: 50-52 cm; Ninetyeast Ridge, Indian Ocean.

FIGURES 6-9.—Zone P4-P5, DSDP Site 465/3/1: 59-61 cm; Hess Rise, central North Pacific Ocean.

Figures 10-12.—ZoneP5, DSDP Site 213/16/1: 104-106 cm; eastern Indian Ocean.

Morozovella gracilis (Bolli, 1957)

(bars = 100 (am)

FIGURES 13-15.—Zone P5, DSDP Site 213/16/1: 104-106 cm; eastern Indian Ocean.

NUMBER 85

215

216

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 55

Morozovella velascoensis (Cushman, 1925)

(Figures 2, 3, 7, 12: bars = 100 (am; Figures 1, 4-6, 8-11, 13-15: bars = 200 jam)

Figures 1-3.—ZoneP5, DSDP Site 213/16/1: 104-106 cm; eastern Indian Ocean.

FIGURES 4-6.—Zone P4, DSDP Site 465/3/1: 59-61 cm.

FIGURES 7-9.—Zone P4, ODP Hole 758A/28/1: 50-52 cm.

FIGURES 10, 12.—Zone P4, DSDP Site 465/3/4: 62-64 cm; Hess Rise, central Pacific Ocean.

FIGURE 11.-—Zone P5, ODP Hole 758A/28/1: 50-52 cm; Ninetyeast Ridge, Indian Ocean.

FIGURES 13-15.—Zone P4, DSDP Site 384/9/CC; southeast Newfoundland Ridge, North Atlantic Ocean.

NUMBER 85

217

218

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 56

Igorina albeari (Cushman and Bermudez, 1949)

(Figures 1-12, 16: bars = 100 |im; Figures 13, 15: bars = 40 (im; Figure 14: bar= 10 urn)

FIGURES 1-3, 9.—Zone P4, DSDP Site 465/3/3: 98-100 cm; Hess Rise, central North Pacific Ocean.

FIGURES 4, 8, 12.—Zone P4, DSDP Site 384/8/1: 126-128 cm; southeast Newfoundland Ridge, North Atlantic
Ocean.

FIGURES 5-7, 10, 11.—Zone P4, ODP Hole 758A/29/4: 50-52 cm; Ninetyeast Ridge, Indian Ocean.

FIGURES 13, 16.—Zone P4, DSDP Site 356/24/2: 92-94 cm.

FIGURES 14, 15.—Zone P4, DSDP Site 356/24/1: 110-112 cm; Sao Paulo Plateau, South Atlantic Ocean.

NUMBER 85

219

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220

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 57

Igorina pusilla (Bolli, 1957)

(Figures 1, 2, 5, 9-11, 13-16: bars = 100 pm; Figures 3, 4, 6-8, 12: bars = 40 (am)

FIGURES 1, 2.—Zone P4, DSDP Site 384/7/3: 130-132 cm; southeast Newfoundland Ridge, North Atlantic
Ocean.

FIGURES 3, 4.—Zone P3b, DSDP Site 3/21/CC; Gulf of Mexico.

FIGURE 5.—Zone P3, ODP Hole 761B/18X/2: 52-54 cm.

FIGURES 6-8, 12.—Zone P4, Vincentown Fm., Glendola Well, New Jersey, sample 286 feet.

FIGURES 9, 10.—Zone P3, DSDP Site 465/6/5: 66-68 cm.

FIGURE 11.—Zone P3, DSDP Site 465/5/4: 63-64 cm; Hess Rise, central Pacific Ocean.

FIGURES 13-16.—Zone P4, ODP Hole 761B/18X/1: 52-54 cm; Wombat Plateau, Indian Ocean.

NUMBER 85

221

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 58

Igorina tadjikistanensis (Bykova, 1953)

(Figure 1: bar = 40 pm; Figures 2-12: bars = 100 pm)

FIGURES 1, 2, 4, 6, 8, 10, 12.—Zone P4, Velasco Fm., Tamaulipas, Mexico.

FIGURES 3, 5, 7, 9, 11.—Zone P4, Vincentown Fm., Glendola Well, New Jersey, sample 230-232 feet.

NUMBER 85

223

224

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 59

Praemurica inconstans (Subbotina, 1953)

(bars = 100 Jim)

FIGURES 1-3, 13, 15. —Zone P3, DSDP Site 465/7/CC; Hess Rise, central Pacific Ocean.

FIGURES 4-7, 12, 16.—Zone Pic, DSDP Site 356/26/4: 117-118 cm; Sao Paulo Plateau, South Atlantic Ocean.
FIGURES 8-11.—Zone Pic, DSDP Site 527/30/4: 30-32 cm; Walvis Ridge, South Atlantic Ocean.

Figure 14.—Zone P2, DSDP Site 384/11/3: 30-32 cm; southeast Newfoundland Ridge, North Atlantic Ocean.

NUMBER 85

225

226

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 60

Praemurica pseudoinconstans (Blow, 1979)

(Figures 1-11: bars = 50 jam; Figures 12, 13: bars = 10 pm)

FIGURES 1, 3, 6. —Zone Pa, Millers Ferry, Alabama, core 226, sample 85.

FIGURES 2, 10-13.—Zone Pla, Millers Ferry, Alabama, core 225, sample 194; Figure 12 (view of 2nd chamber
of Figure 11) and Figure 13 (view of 4th chamber of Figure 10) showing cancellate nonspinose wall texture.

FIGURE 4.—Zone Pla, DSDP Site 384/13/2: 140-142 cm; southeast Newfoundland Ridge, North Atlantic Ocean.

FIGURE 5.—Zone P2, DSDP Site 356/25/5: 148-150 cm; Sao Paulo Plateau, South Atlantic Ocean.

FIGURES 1 , 9.—Zone Pla, Millers Ferry, Alabama, core 225, sample 216.

FIGURE 8.—Zone Pla, DSDP Hole 465A/3/3: 120-122 cm; Hess Rise, central Pacific Ocean.

/'r;

NUMBER 85

227

228

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 61

Praemurica taurica (Morozova, 1961)

(Figures 2, 4, 7, 9, 11, 12: bars = 100 pm; Figures 1, 3, 5, 6, 8, 10, 15: bars = 40 jam;

Figures 13, 14: bars = 10 pm)

FIGURES 1, 3.—Zone PI a, Millers Ferry, Alabama, core 225, sample 216.

FIGURES 2, 4.—Zone PI a. Millers Ferry, Alabama, core 225, sample 194.

FIGURE 5. —Zone Pa, Millers Ferry, Alabama, core 226, sample 5.

FIGURE 6. —Zone Pla, ODP Hole 750A715/2: 8-12 cm; southern Kerguelen Plateau, southern Indian Ocean.

FIGURES 7, 9, 13, 14.—Zone Pla, Millers Ferry, Alabama, sample 30 feet above Prairie Bluff; Figures 13, 14,
views of wall of Figure 9 showing cancellate nonspinose wall texture.

FIGURE 8.—Zone Pa, Millers Ferry, Alabama, core 225, sample 334.

FIGURE 10. —Zone Pa, Millers Ferry, Alabama, core 226, sample 15.

FIGURES 11, 12, 15.—Zone Pic, DSDP Site 356/26/CC; Sao Paulo Plateau, South Atlantic Ocean.

NUMBER 85

229

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230

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 62

Praemurica uncinata (Bolli, 1957)

(bars = 100 (am)

FIGURES 1-3, 5-7, 16.—Zone P3, DSDP Site 465/7/CC; Hess Rise, central Pacific Ocean.

FIGURES 4, 8, 9, 12-15.—Zone P2, DSDP Site 384/11/3: 30-32 cm.

FIGURES 10, 11.—Zone P2, DSDP Site 384/11/3: 136-138 cm; southeast Newfoundland Ridge, North Atlantic
Ocean.

NUMBER 85

231

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232

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 63

Guembelitria cretacea Cushman, 1933

(Figures 1-5, 7-12: bars = 50 jam; Figure 6: bar = 10 (am)

FIGURES 1-4.—Upper Maastrichtian, Redbank Fm., New Jersey.

FIGURES 5, 6, 10-12.—Zone Pa, Millers Ferry, Alabama, core 226, sample 18; Figure 6, view of wall of Figure
5 showing typical pore mounds of this species; Figure 12, specimen showing transitional morphology to
Woodringina.

FIGURE 7.—Zone Pa, DSDP Hole 390A/11/5: 135-136 cm; Blake-Bahama Basin, North Atlantic Ocean.
FIGURES 8, 9.—Zone Pa, DSDP Site 577/12/5: 115-117 cm; Shatsky Rise, northwestern Pacific Ocean.

NUMBER 85

233

234

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 64

Globoconusa daubjergensis (Bronnimann, 1953)

(Figures 1-7, 10-12: bars = 50 pm; Figures 8, 9: bars = 10 pm)

FIGURES 1-3, 5, 6, 8, 9.—Zone Pic, Brightseat Fm., Maryland; Figure 8 (view of ultimate chamber of Figure 6)
and Figure 9 (view of ultimate chamber of Figure 5) showing microperforate wall texture and poreless sharp
pustules.

FIGURE 4.—Zone P0, Brazos River, Texas.

FIGURE 7.—Zone Pa, Millers Ferry, Alabama, core 225, sample 256.

FIGURES 10-12. —Zone Pic, Midway Fm., Texas, Plummer station 14.

NUMBER 85

235

236

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 65

Parvularugoglobigerina alabamensis (Liu and Olsson, 1992)

(Figures 1-5: bars = 50 pm; Figure 6: bar = 10 jam)

FIGURE 1.—Zone Pla , Millers Ferry, Alabama, core 225, sample 265.

FIGURES 2, 3.—Zone Pla, Millers Ferry, Alabama, core 225, sample 266.

FIGURE 4.—Zone Pla, Millers Ferry, Alabama, core 226, sample 20.

FIGURES 5, 6.—Zone Pla, Millers Ferry, Alabama; Figure 5, holotype, sample 40 feet above Prairie Bluff Chalk;
Figure 6, view of wall of 3rd chamber of holotype showing microperforate pore mound texture.

Parvularugoglobigerina extensa (Blow, 1979)

(bars = 50 pm)

FIGURES 7, 9-12.—Zone Pa, DSDP Site 577/12/5: 94-96 cm; Shatsky Rise, northwestern Pacific Ocean.
FIGURE 8. —Zone Pa, El Kef, Tunisia.

FIGURE 13.—Zone Pa, type level of P. eugubina, Gubbio section, central Appennines, Italy.

NUMBER 85

237

238

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 66

Parvularugoglobigerina eugubina (Luterbacher and Premoli Silva, 1964)

(Figures 1-4, 6-12: bars = 50 |im; Figure 5: bar = 10 |im)

FIGURES 1-5.—Zone Pa, Millers Ferry, Alabama, core 225, sample 328; Figure 5, view of wall of 2nd chamber
of Figure 2 showing microperforate wall texture with a few incipient pore mounds.

FIGURES 6, 8, 9, 12.—Zone Pa, DSDP Site 577/12/5: 115-117 cm.

FIGURES 7, 10.—Zone Pa, El Kef, Tunisia.

FIGURE 11.—Zone Pa, DSDP Site 577/12/5: 134-136 cm; Shatsky Rise, northwestern Pacific Ocean.

NUMBER 85

239

240

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 67

Parvularugoglobigerina eugubina (Luterbacher and Premoli Silva, 1964)

(Figures 1-10, 12, 13: bars = 50 (am; Figures 11, 14: bars = 10 pm)

FIGURES 1 -9. —Zone Pa, type level of P. eugubina, Gubbio section, central Appennines, Italy.

FIGURES 10-12.—Zone Pa, DSDP Site 577/12/5: 125-126 cm; Shatsky Rise, northwestern Pacific Ocean;
Figure 11, view of Figure 10 showing recrystallized wall that obscures microperforate wall texture.

FIGURES 13, 14.—Zone Pa, Millers Ferry, Alabama, core 226, sample 20; Figure 14, view of wall of 4th chamber
of Figure 13 showing microperforate wall texture and scattered pore mounds.

NUMBER 85

241

mm

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242

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 68

Woodringina claytonensis Loeblich and Tappan, 1957

(Figures 1-5: bars = 50 (am; Figure 6: bar = 10 pm)

FIGURE 1.—Zone P0, Brazos River, Texas.

FIGURES 2, 6.—Zone Pla, DSDP Hole 390A/11/5: 135-136 cm; Blake-Bahama Basin, North Atlantic Ocean;
Figure 6, view of 2nd chamber of Figure 2 showing microperforate wall texture and blunt pustules.

FIGURE 3. —Zone Pa, Millers Ferry, Alabama, core 226, sample 18.

FIGURE 4.—Zone Pla, Midway Group, Texas, Plummer station 4.

FIGURE 5.—Zone Pa, DSDP Site 577/12/5: 115-117 cm; Shatsky Rise, northwestern Pacific Ocean, specimen
showing intermediate morphology with Guembelitria cretacea.

Woodringina hornerstownensis Olsson, 1960

(bars = 50 pm)

FIGURES 7, 8.—Topotypes, Zone P3, Hornerstown Fm., New Jersey.

FIGURES 9, 10, 13, 14.—Zone Pa, DSDP Site 577/12/5: 113-114 cm; Shatsky Rise, northwestern Pacific Ocean.
FIGURES 11, 12.—Zone Pic, Midway Fm., Texas, Plummer station 14.

NUMBER 85

243

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244

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 69

Chiloguembelina crinita (Glaessner, 1937)

(Figures 1-7: bars = 50 pm; Figure 8: bar = 10 pm)

FIGURES 1-8.—Zone P4, Glendola Well, New Jersey, sample 230-232 feet; Figure 8, view of 2nd chamber of
Figure 3 showing pustulose wall texture.

Chiloguembelina morsei (Kline, 1943)

(Figures 9-14: bars = 50 pm; Figure 15: bar = 10 pm)

FIGURES 9, 10.—Danian, ODP Hole 690C/14R/1: 76-80 cm; Maud Rise, Southern Ocean.

FIGURES 11-15.—Zone P2, DSDP Site 356/25/5: 148-150 cm; Sao Paulo Plateau, South Atlantic Ocean; Figure
15, view of 3rd chamber of specimen showing pustulose wall texture.

Chiloguembelina midwayensis (Cushman, 1940)

(Figures 16, 18-22: bars = 50 pm; Figure 17: bar = 10 pm)

FIGURES 16-22.—Zone P2, DSDP Site 356/25/5: 148-150 cm; Sao Paulo Plateau, South Atlantic Ocean; Figure
17, view of 3rd chamber of Figure 18 showing pustulose wall texture.

NUMBER 85

245

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246

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 70

Chiloguembelina subtriangularis Beckmann, 1957

(Figures 1-3, 5-7: bars = 50 (am; Figure 4: bar = 10 (am)

FIGURES 1-7.—Zone P2, DSDP Site 356/25/5: 148-150 cm; Sao Paulo Plateau, South Atlantic Ocean; Figure
4, view of 2nd chamber of Figure 7 showing pustulose wall texture.

Chiloguembelina trinitatensis (Cushman and Renz, 1942)

(Figures 8-10: bars = 5 jam; Figure 14: bar = 20 (am)

FIGURES 8, 9.—Zone P5, DSDP Site 152/4/3: 20-24 cm.

FIGURES 10, 14.—Zone P5, DSDP Site 152/4/2: 16-18 cm; Caribbean Sea; Figure 14, view of 3rd chamber of
Figure 10 showing pustulose wall texture.

Chiloguembelina wilcoxensis (Cushman and Ponton, 1932)

(Figures 11-13, 15-17: bars = 50 (am; Figure 18: bar = 20 (am)

FIGURES 11 — 13, 16-18.—Upper Paleocene, ODP Hole 690B/16X/5: 76-80 cm; Maud Rise, Southern Ocean;
Figure 12, dissection of Figure 11 showing the asymmetrical position of apertures in earlier formed chambers;
Figure 18, view of 2nd chamber of Figure 17 showing pustulose wall texture.

FIGURE 15.—Hypotype, specimen illustrated in Beckmann, 1957, pi. 21: fig. 13; lower Eocene, type Globorotalia
rex Zone, Lizard Springs Fm., Trinidad.

NUMBER 85

247

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248

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 71

Zeauvigerina waiparaensis (Jenkins, 1965)

(Figures 1-4, 6-15, 17, 18: bars = 50 pm; Figures 5, 16: bars = 10 pm)

FIGURES 1-5.— Z. waiparaensis sensu stricto: Maastrichtian, ODP Hole 750A/46R/1: 130-131 cm; Figure 5,
apertural view of Figure 4 showing equidimensional lip partially surrounding aperture.

FIGURE 11.— Z. waiparaensis sensu stricto: Maastrichtian, ODP Hole 750A/18X/CC.

FIGURE 12.— Z. waiparaensis sensu stricto: Maastrichtian, ODP Hole 750A/18R/CC.

FIGURES 6-8.— Z. waiparaensis forma prolata: Maastrichtian, ODP Hole 750A/17R/1: 52-54 cm.

FIGURES 9, 10.— -Z waiparaensis forma palmula : Late Paleocene, ODP Hole 738C/13R/CC.

FIGURES 13-16.— Z. waiparaenis forma improcera: Maastrichtian, ODP Hole 750A/16R/1: 130-131 cm;
Kerguelen Plateau, southern Indian Ocean; Figure 16, apertural view of Figure 15 showing equidimensional lip
partially surrounding aperture.

FIGURES 17, 18.— Z. waiparaensis forma velata: Maastrichtian, ODP Hole 738C/21R/CC; Kerguelen Plateau,
southern Indian Ocean.

Zeauvigerina aegyptiaca Said and Kenawy, 1956

(bars = 50 pm)

FIGURES 19, 20.—Upper Paleocene, DSDP Site 98/12/1: 119-120 cm; Bahama Platform, western Atlantic
Ocean.

“Zeauvigerina” virgata (Khalilov, 1967)

(Figures 21, 22: bars = 50 pm; Figure 23: bar = 20 pm)

FIGURES 21-23.—Upper Paleocene, ODP Hole 750A/11R/2: 40-41; Kerguelen Plateau, southern Indian Ocean;
Figure 23, apertural view of Figure 22.

Rectoguembelina cretacea Cushman, 1932

(bars = 50 pm)

FIGURES 24-26.—Upper Paleocene, DSDP Site 357/30/CC; Rio Grande Rise, South Atlantic Ocean.

NUMBER 85

249

Index

abundocamerata, Globorotalia angulata, 60
acarinata, Acarinina, 46, 48
acarinata, Globorotalia ( Acarinina) acarinata, 48
Acarinina, 1, 12, 46
acuta, Globorotalia, 55
acuta, Globorotalia ( Morozovella), 55
acuta, Globorotalia velascoensis, 55
acuta, Morozovella, 55; 196
acuta (var.), Globorotalia wilcoxensis, 55
acutispira, Globorotalia, 56
acutispira, Globorotalia {Morozovella) occlusa,
56

acutispira, Morozovella, 3, 19, 56; 198
acutispira (aff.), Globorotalia sp., 56
aegyptiaca, Zeauvigerina, 95; 248
aequa, Acarinina, 57
aequa, Globorotalia, 57
aequa, Globorotalia {Morozovella) aequa, 57
aequa, Globorotalia {Truncorotalia) aequa, 57
aequa, Morozovella, 12, 19, 57; 200
aequa (var.), Globorotalia crassata, 57
aequa (var.), Globorotalia {Truncorotalia) cras¬
sata, 57

aequus, Truncorotaloides {Morozovella), 57
alabamensis, Guembelitria !, 83
alabamensis, Parvularugoglobigerina, 83; 236
albeari, Globorotalia, 69
albeari, Globorotalia {Globorotalia), 69
albeari, Igorina, 17, 69; 218
anconitana, Globigerina, 83
angulata, Globigerina, 58
angulata, Globorotalia, 58
angulata, Globorotalia {Truncorotalia), 58, 60
angulata, Globorotalia {Morozovella), 58
angulata, Morozovella, 19, 58; 202
angulatus, Truncorotaloides {Morozovella), 58
apanthesma, Acarinina, 59
apanthesma, Globorotalia, 59
apanthesma, Globorotalia {Morozovella), 59
apanthesma, ? Globorotalia {Morozovella), 59
apanthesma, Morozovella, 19, 59; 204
arabica, Globigerina, 73

archeocompressa, Globanomalina, 2, 11, 17, 37;
170

archeocompressa, Globorotalia {Turborotalia), 37

aspera, Eouvigerina, 95

australiformis, Globanomalina, 3, 18, 38; 172

australiformis, Globorotalia, 38

australiformis, Globorotalia {Planorotalites), 38

australiformis, Planorotalites, 38

azzouzi, Guembelitria, 79

besbesi, Guembelitria, 79

bohemica, Pseudotextularia, 94

bollii, Globorotalia, 65

bullata, Globorotalia {Morozovella) aequa, 57
californica, Globorotalia, 56

(Page number of principal account is in italics.)

cancellata, Subbotina, 2, 17, 29; 154, 156
cancellata, Subbotina triangularis, 29
cancellata (aff.), Subbotina, 17
cancellate spinose, 13
cancellate nonspinose, 17
Cassigerinella, 78

caucasica, Globorotalia velascoensis, 63
chapmani, Globanomalina, 18, 39; 174
chapmani, Globorotalia, 39
chapmani, Planorotalites, 40
chascanona, Acarinina, 53
chascanona, Globigerina, 53
chascanona, Muricoglobigerina, 53
Chiloguembelina, 2, 89
Chiloguembelinidae, 88
Chiloguembelitria, 79
claytonensis, Woodringina, 86; 242
coalingensis, Acarinina, 18,47; 184
coalingensis, Globigerina, 47
compressa, Globanomalina, 11,40; 170, 176
compressa, Globorotalia, 40, 44
compressa, Globorotalia {Globorotalia), 40
compressa, Globorotalia {Turborotalia) com¬
pressa, 40

compressa, Globigerina, 40
compressa (var.), Globigerina compressa, 40
compressus, Planorotalites, 40
conicotruncata, Acarinina, 60
conicotruncata, Globorotalia, 60
conicotruncata, Globorotalia {Morozovella) angu¬
lata, 60

conicotruncana, Morozovella, 19, 60; 206
conusa, Globoconusa, 80, 81, 85
convexa, Globorotalia, 71
convexa, Globorotalia {Acarinina), 72
convexa, Morozovella, 12
convexus, Truncorotaloides {Morozovella), 71
convexa (cf.), Globorotalia {Acarinina) convexa,
12

Corrosina, 78

crassaformis, Acarinina, 46
crassaformis, Globorotalia, 64
crassata, Globorotalia, 66
cretacea, Guembelitria, 2, 10, 79; 232
cretacea, Rectoguembelina, 94; 248
crinita, Chiloguembelina, 90; 244
crinita, Giimbelina, 90
crosswickensis, Globorotalia, 62
crosswickensis, Globorotalia {Morozovella) oc¬
clusa, 62

dammula, Guembelitria, 19
danica, Chiloguembelitria, 19
daubjergensis, Globastica, 81
daubjergensis, Globigerina, 80, 81
daubjergensis, Globigerinoides, 81
daubjergensis, Globoconusa, 81; 234

edita, Eoglobigerina, 13, 19, 20; 142

edita, Eoglobigerina edita, 20

edita, Globigerina, 19

edita, Globorotalia {Globorotalia), 20

edita, Parvularugoglobigerina, 30

edita (cf.), Globigerina, 84

ehrenbergi, Globanomalina, 17,42; 176

ehrenbergi, Globorotalia, 40

ehrenbergi, Globorotalia {Globorotalia), 40

elongata, Globorotalia, 40

eobulloides, Eoglobigerina, 1, 11, 13, 20, 21; 144

eobulloides, Eoglobigerina eobulloides, 2 1

eobulloides, Globigerina {Eoglobigerina), 20

Eoglobigerina, 12, 13, 19

Eouvigerina, 95

eugubina, Parvularugoglobigerina, 3, 83; 238,
240

eugubina (aff.), Parvularugoglobigerina, 85
eugubina (cf.), Parvularugoglobigerina, 84
eugubina, Globigerina, 82, 83
extensa, Eoglobigerina !, 85
extensa, Parvularugoglobigerina, 85; 236
falsospiralis, Acarinina, 53
fodina, Eoglobigerina?, 85
fringa, Eoglobigerina, 21
fringa, Globigerina, 2, 21, 29
fringa, Parvularugoglobigerina, 30
gerpegensis, Globigerina, 30
gigantea, Globoconusa daubjergensis, 81
glabrans, Heterohelix, 91
Globanomalina, 2, 11, 17, 18, 37
Globastica, 80
Globigerinidae, 19
Globoconusa, 2, 80
gracilis, Eouvigerina, 95
gracilis, Globorotalia formosa, 61
gracilis, Globorotalia {Morozovella), 61
gracilis, Globorotalia {Morozovella) subbotinae,
61

gracilis, Morozovella, 19, 61; 214

gracilis, Morozovella formosa, 62

gradata, Heterohelix, 88

Guembelitria, 2, 79

Guembelitriella, 11

Guembelitriidae, 77

hariana, Postrugoglobigerina, 84

haunsbergensis, Globorotalia, 42

haunsbergensis, Globorotalia {Turborotalia), 42

Hedbergella, 2, 34

Hedbergellidae, 34

hemisphaerica, Globigerina {Eoglobigerina), 20,
84

hemisphaerica (cf.), Globorotalia {Turborotalia),
83

Heterohelicidae, 93

holmdelensis, Hedbergella, 3, 11, 35; 166

250

NUMBER 85

251

hornerstownensis, Woodringina, 3, 87, 88; 242
hornerstownensis group, Woodringina, 85
Igorina, 12, 17, 68
imitata, Globanomalina, 18, 42; 178
imitata, Globorotalia, 42

improcera (forma), Zeauvigerina waiparaensis, 97

inaequispira, Globigerina, 30, 47

inconstans, Acarinina inconstans, 73

inconstans, Globigerina, 73

inconstans, Globorotalia, 73

inconstans, Globorotalia ( Acarinina ), 73

inconstans, Globorotalia ( Globorotalia ), 73

inconstans, Globorotalia {Turborotalia ), 73

inconstans, Morozovella, 73

inconstans, “ Morozovella 74

inconstans, Praemurica, 17, 73; 224

inconstans, Subbotina, 73

indolensis, Acarinina, 76

intermedia, Acarinina, 49

irregularis, Guembelitria, 79

kelleri, Woodringina, 87

kelleri (cf.), Woodringina, 87

kolchidica, Globorotalia, 56

kolchidica (aff.)» Globorotalia sp., 56

kozlowskii, Globigerina, 81

kubanensis, Globorotalia, 60

kubanensis (var.), Globorotalia angulata, 60

lacerti, Globorotalia, 57

lacerti, Globorotalia ( Morozovella) aequa, 57

laevigata, Globorotalia pusilla, 69

laevigata, Tubitextularia, 94

Laeviheterohelix, 94, 95

lakiensis (var.), Globanomalina ovalis, 40

loeblichi, Globorotalia, 57

longiapertura, Globorotalia ( Turborotalia ), 83

longiapertura, Parvularugoglobigerina, 84

luxorensis, Anomalina, 40

marginodentata, Morozovella, 56

mckannai, Acarinina, 18, 43; 186

mckannai, Globigerina, 48

mckannai, Globorotalia, 48

mckannai, Globorotalia {Acarinina), 48

mckannai, Muricoglobigerina, 48

membranacea, Globorotalia, 40, 42, 45

microcellulosa, Globigerina {Globigerina), 31

microperforate, 10

microsphaerica, Acarinina, 53

midwayensis, Chiloguembelina, 90, 91; 244

midwayensis, Chiloguembelina midwayensis, 90

midwayensis, Giimbelina, 90

minutula, Globigerina, 85

monmouthensis, Globorotalia, 35

monmouthensis, Hedbergella, 3, 12, 17, 35; 168

Morozovella, 12, 18, 54

morsel, Chiloguembelina, 91\ 244

morsei, Giimbelina, 91

muricate, 12, 18

muricate keel, 12

nana, Globigerina triloculinoides, 33
nana, Subbotina triloculinoides, 31
nartanensis, Globorotalia, 65
nitida, Acarinina, 18, 48; 188
nitida, Globigerina, 48
normalis, Heterohelix gradata, 88
occlusa, Globorotalia, 62

occlusa, Globorotalia {Morozovella), 62
occlusa, Globorotalia {Truncorotalia) velasco-
ensis, 62

occlusa, Morozovella, 19, 62; 208
occlusa (cf.), Globorotalia {Morozovella) occlusa,
62

oculis, Heterohelix, 99
ovalis, Globanomalina, 18, 43; 180
palmula (forma), Zeauvigerina waiparaensis, 91
parallelus, Heterohelix, 99
Parasubbotina, 12, 17, 24
parva, Globorotalia {Morozovella) velascoensis,
55

parva, Globorotalia velascoensis, 55
parva (var.), Globorotalia velascoensis, 55
Parvularugoglobigerina, 2, 82
Parvularugoglobigerina morphotype 1, 85
Parvularugoglobigerina morphotype 2, 85
Parvularugoglobigerina morphotype 3, 84
pasionensis, Globorotalia, 63
pasionensis, Morozovella, 19, 63; 210
pasionensis, Pseudogloborotalia, 63
patagonica/triangularis group, Subbotina, 30
pentacamerata, Acarinina, 65
pentagona, Globigerina {Eoglobigerina), 20
pentagona (cf.), Globorotalia {Turborotalia )?, 83
planocompressa, Globanomalina, 18,44; 178
planocompressa, Globorotalia planocompressa,
44

planocompressa, Globorotalia {Turborotalia)
compressa, 44

planoconica, Globanomalina, 18, 44; 174
planoconica, Globorotalia, 44
polycamera, Eoglobigerina edita, 20
poly camera, Globigerina edita var., 20
Postrugoglobigerina, 82
praeangulata, Acarinina, 51
praeangulata, Globorotalia {Acarinina), 64
praeangulata, Morozovella, 18, 19, 64; 212
praecursoria, Acarinina, 48, 73
praecursoria, Globorotalia {Acarinina)praecurso¬
ria, 76

praedaubjergensis, Postrugoglobigerina, 81
praeedita, Eoglobigerina, 20
Praemurica, 12, 72
Praemuricate, 12

praenartanensis, Globorotalia, 57
praepentacamerata, Acarinina, 51
praepentacamerata, Globorotalia, 51
praepentacamerata (var.), Globorotalia angulata,
50

primitiva, Acarinina, 47
primitiva, Globigerina, 47
primitiva, Globoquadrina, 47
primitiva, Globorotalia {Acarinina), 47
primitiva, Pseudogloboquadrina, 47
prolata (forma), Zeauvigerina waiparaensis, 97
protocarina, Morozovella, 58
pseudobulloides, Globigerina, 25
pseudobulloides, Globorotalia, 25, 74
pseudobulloides, Globorotalia {Globorotalia), 25
pseudobulloides, Globorotalia {Turborotalia), 25
pseudobulloides, Parasubbotina, 2, 17, 24; 148
pseudobulloides, Subbotina, 25
pseudobulloides (transitional), Globorotalia, 73

pseudobulloides (aff.), Parasubbotina, 17,25; 150
pseudo-bulloides, Globigerina, 24
Pseudohastigerina, 11

pseudoinconstans, Globorotalia {Turborotalia),
74

pseudoinconstans, Praemurica, 17, 74; 226
pseudoiota, Globigerina, 43
pseudomenardii, Globanomalina, 11,45; 182
pseudomenardii, Globorotalia, 45
pseudomenardii, Globorotalia {Globorotalia), 45
pseudomenardii, Planorotalites, 45
pseudoscitula, Globorotalia, 69
pseudotriloba, Globigerina, 30, 31
pusilla, Globorotalia, 70
pusilla, Globorotalia pusilla, 70
pusilla, Globorotalia {Globorotalia ?) pusilla, 70
pusilla, Igorina, 17, 70; 220
pusilla, Morozovella pusilla, 70
pusilla, Planorotalites pusilla, 70
quadratoseptata, ? Acarinina, 64
quadrilocula, Globorotalia {Turborotalia), 26
quadripartitiformis, Globoconusa, 53
quadritriloculinoides, Globigerina, 33
Rectoguembelina, 93
rex, Globorotalia, 65

rex, Globorotalia {Morozovella) aequa, 65
sabina, Globigerina, 83
scabrosa, Globorotalia, 73
saxipara, Dimorphina, 94
schachdagica, Globigerina, 73
scobinata, Globigerina, 73
simplex, Globanomalina, 43
simplicissima, Eoglobigerina eobulloides, 22
simulatilis, ? Discorbina, 62
simulatilis, Globorotalia {Truncorotalia) aequa,
65

simulatilis, Morozovella, 62
Smooth-walled, 17

soldadoensis, Acarinina, 2, 18, 50; 190

soldadoensis, Globigerina, 50

soldadoensis, Globorotalia {Acarinina), 50

soldadoensis, Muricoglobigerina soldadoensis, 50

soldadoensis (cf.), Globigerina, 48

spinulosa, Morozovella, 66

spiralis, Eoglobigerina, 13 ,22; 146

spiralis, Globigerina, 22, 53

spiralis, Igorina, 22

stainforthi, Globigerina, 31

stainforthi, Subbotina triloculinoides, 31

stonei, Globigerina, 48

strabocella, Acarinina, 12, 18, 50; 192

strabocella, Globorotalia, 51

strabocella, Globorotalia {Acarinina), 51

Streptochilus, 88

strombiformis, Chiloguembelina midwayensis, 90
Subbotina, 13, 17,25
subbotinae, Globorotalia, 65
subbotinae, Globorotalia {Morozovella) subboti¬
nae, 65

subbotinae, Morozovella, 19, 65; 214
subsphaerica, Acarinina, 2, 18, 52; 194
subsphaerica, Globigerina, 52
subsphaerica, Globorotalia {Acarinina), 53
subtriangularis, Chiloguembelina, 92; 246
tadjikistanensis, Globorotalia, 71

252

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

tadjikistanensis, Globorotalia ( Morozovella ), 72

tadjikistanensis, Igorina, 17, 68, 7/; 222

taurica, Chiloguembelina, 88

taurica, Chiloguembelitria, 87

taurica, Globigerina ( Eoglobigerina ), 75, 84

taurica, Morozovella, 75

taurica, Praemurica, 2, 12, 17, 75; 228

tauricus, Planorotalites, 70

tetragona, Globigerina ( Eoglobigerina ), 20

tetragona (cf.), Globorotalia ( Turborotalia ), 83

teuria, Zeauvigerina, 96

texana, Rectoguembelina, 94

theodosica, Globigerina ( Eoglobigerina ), 20

tholiformis, Globorotalia ( Morozovella ) aequa, 51

triangularis, Globigerina, 30

triangularis, Subbotina, 17, 30; 158

triangularis triangularis, Subbotina, 30

trifolia, Globigerina ( Eoglobigerina ), 81

trifolia, Guembelitria, 79

trifolia, Guembelitria (?), 79

triloculinoides, Globigerina, 30, 31

triloculinoides, Subbotina, 13, 17,37; 160

triloculinoides, Subbotina triloculinoides, 31

trinidadensis, Globorotalia, 73

trinitatensis, Chiloguembelina, 92; 246

trinitatensis, Guembelina, 92

trinitatensis, Rectoguembelina, 94

tripartita, Globoconusa, 81

triplex, Acarinina, 47

triplex, Globorotalia ( Acarinina ), 47

trivialis, Eoglobigerina, 32

trivialis, Globigerina, 32

trivialis, Subbotina, 17, 32; 162

trivialis (aff.), Eoglobigerina, 32

trivialis (cf.), Eoglobigerina, 32

trochoidea (var.), Anomalina lorneiana, 34

troelseni, Globorotalia, 40

Truncorotaloididae, 45

Tubitextularia, 94

umbrica, Globigerina, 83

uncinata, Acarinina inconstans, 76

uncinata, Globorotalia, 76

uncinata, Globorotalia uncinata, 76

uncinata, Morozovella, 77

uncinata, Praemurica, 17, 18, 7(5; 230

uncinata (transitional form), Globorotalia, 64, 73

uruchaensis, Globigerina, 30

varianta, Globigerina, 26

varianta, Globorotalia ( Globorotalia ), 26

varianta, Parasubbotina, 17, 2(5; 150

varianta, Subbotina, 26

variospira, Globorotalia (Turborotalia ), 28

variospira, Morozovella, 28

variospira, Parasubbotina, 17, 25; 152

velascoensis, Globigerina, 33
velascoensis, Globigerina var. compressa, 33
velascoensis, Globorotalia, 66
velascoensis, Globorotalia ( Morozovella ) velasco¬
ensis, 67

velascoensis, Globorotalia ( Truncorotalia ) velas¬
coensis. 67

velascoensis, Morozovella, 12, 19, (5(5; 216
velascoensis, Pseudogloborotalia, 67
velascoensis, Pulvinulina, 66
velascoensis, Subbotina, 17, 33; 164
velascoensis, Truncorotaloides ( Morozovella ), 66
velata (forma), Zeauvigerina waiparaensis, 97
virgata, “ Zeauvigerina 95; 248
virgata, Heterohelix, 98
waiparaensis, Chiloguembelina, 2, 97
waiparaensis, Zeauvigerina, 97; 248
waiparaensis s.s., Zeauvigerina, 97
whitei, Globorotalia, 48
wilcoxensis, Acarinina, 50
wilcoxensis, Chiloguembelina, 92; 246
wilcoxensis, Giimbelina, 92
wilcoxensis, Pseudohastigerina, 43
Woodringina, 2, 5(5
Woodringina spp., 77
Zeauvigerina, 2, 94
zelandica, Zeauvigerina, 94

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