Megaspores and a Palynomorph
from the Lower Potomac Group

in Virginia

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SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY • NUMBER 49

Megaspores and a Palynomorph
from the Lower Potomac Group

in Virginia

Francis M. Hueber

SMITHSONIAN INSTITUTION PRESS
City of Washington
1982

ABSTRACT

Hueber, Francis M. Megaspores and a Palynomorph from the Lower Potomac
Group in Virginia. Smithsonian Contributions to Paleobiology , number 49, 69 pages,
1 figure, 24 plates, 1982.—A plant microfossil assemblage comprising seven
species of megaspores; Verrutriletes carbunculus (Dijkstra) Potonie, Echitnletes cf.
E. lanatus (Dijkstra) Potonie, Erlansomsporites erlansonii (Miner) Potonie, Thyla-
kosporites retiarius (Hughes) Potonie, Arcellites disciformis (Miner) Ellis and
Tschudy, Arcellites cf. A. pyriformis (Dijkstra) Potter, and Paxillitnletes species
Hall and Nicolson; two species of the microspore Crybelospontes Dettmann, C.
stnatus (Cookson and Dettmann) Dettmann adherent to specimens of Arcellites
disciformis , and Crybelosporites species adherent to specimens of Echitnletes cf. E.
lanatus ; and the palynomorph Dictyothylakos pesslerae Horst; is recorded from
the Patuxent Formation, Potomac Group, Lower Cretaceous (Barremian-
Aptian) in Virginia, USA. A preliminary analysis of the enclosing matrix for
microspores and pollen has related the collection site closely to lowermost
Zone I of the Potomac Group as described by Hickey and Doyle (1977). The
megaspore assemblage supported by acceptance of the oldest possible date
derived from the microspore and pollen analysis suggests correlation with the
Barremian-Aptian horizons in the English Wealden, Lower Cretaceous, and
specifically with the “Arcellites Flora” of Hughes. Megafossils comprising two
seed cones belonging to the Pinaceae, Pityostrobus hueberi Robison and Miller
and Pityostrobus virginiana Robison and Miller have been reported from the site.
A fruit or cupule of Caytonia has been found along with numerous seeds, fern
fragments, coniferous woods, and cycadopsid cuticles. This array of megafossils
is not described or illustrated herein. A backswamp area of sedimentation and
type of habitat is suggested on the basis of the lithofacies and generalized
composition of the flora. The writer fully agrees with Tschudy (1976) as to the
importance of searching for megaspores in continental Mesozoic rocks to aid
in correlating and subdividing the deposits more effectively.

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

Library of Congress Cataloging in Publication Data
Hueber, Francis M.

Megaspores and a Palynomorph from the Lower Potomac Group in Virginia
Smithsonian contributions to paleobiology ; no. 49
Bibliography: p.

L Spores (Botany), Fossil. 2. Palynology. 3. Paleobotany—Cretaceous. 4. Paleobotany—
Virginia. I. Title. II. Series.

QE701.S56 no. 49 [QE996] 560s [561'.13] 81-607852 AACR2

Contents

Page

Introduction . 1

Locality . 1

Materials and Methods . 2

Acknowledgments . 4

Systematics . 4

Verrutriletes Potonie, 1956 . 4

Verrutnletes carbunculus (Dijkstra) Potonie . 4

Echitriletes Potonie, 1956 . 5

Echitnletes cf. E. lanatus (Dijkstra) Potonie . 5

Erlansonisporites Potonie, 1956 . 6

Erlansonisporites erlansonii (Miner) Potonie . 6

Thylakosporites Potonie, 1956 . 7

Thylakosporites retiarius (Hughes) Potonie. 7

Crybelosporites Dettmann, 1963 . 10

Crybelosporites striatus (Cookson and Dettmann) Dettmann . 10

Crybelosporites species . 11

Arcellites Miner, 1935 . 11

Arcellites disciformis (Miner) Ellis and Tschudy . 11

Arcellites cf. A. pyriformis (Dijkstra) Potter . 13

Paxillitriletes Hall and Nicolson, 1973 . 15

Paxillitriletes species . 15

Dictyothylakos Horst, 1954 . 15

Dictyothylakos pesslerae Horst, 1954 . 15

Conclusions . 17

Literature Cited . 19

Plates . 21

Megaspores and a Palynomorph
from the Lower Potomac Group

in Virginia

Francis M. Hueber

Introduction

The present study grew out of finding speci¬
mens of the megaspore species Arcellites disciformis
(Miner) Ellis and Tschudy 1964 during a routine
examination of a collection of fossil plants I made
in 1973. My original interest in the collection
centered on the woods and gymnosperm cones;
however, the beauty of the megaspore diverted
my attention and led me to research the literature
for any records of its occurrence in the Cretaceous
Potomac Group. The search was a very brief one.
I found the summary paper for the genus by Ellis
and Tschudy (1964), in which there is citation of
the occurrence of the species in the Patuxent
Formation based on a written communication
from W. G. Chaloner. The occurrence repre¬
sented stratigraphically the earliest for the genus,
but no subsequent photographic documentation
was published.

I had obtained only three specimens from my
original preparation of the matrix. I mounted the
best one for viewing by means of the scanning
electron microscope. The results were excellent;
however, the additional details of anatomy and
morphology needed to fully substantiate the iden¬
tification of the species required more specimens.

Francis M. Hueber, Department of Paleobiology, National Museum
of National History, Smithsonian Institution, Washington, D. C.
20560.

Preparation of three more samples of the matrix
and careful search yielded 84 well-preserved spec¬
imens and 15 badly distorted ones. The even
more significant results of those preparations was
the accumulation of other species of megaspores
in adequate numbers to form the basis for this
expanded and hopefully more useful report.

Tschudy in 1976 and in later conversation gave
added inspiration regarding the significance of
this small assemblage of megaspores. In addition,
an analysis of a sample of the matrix for micro¬
spore and pollen content was made by J. A.
Doyle, whose findings served as the key to the
stratigraphic correlations discussed later herein.

Tschudy (1976) was correct when he wrote:

I am convinced that once megaspores have been routinely
searched for in continental Mesozoic rocks they, and the
smaller palynomorphs accompanying them, will provide for
the stratigraphic subdivision of non-marine rocks as effec¬
tively as ammonites and baculites now serve to subdivide
marine rock sequences.

Locality.— Stratum 2 to feet (60-76 cm)
thick and undetermined areal extent, comprising
lignitized logs and other plant debris enclosed in
a medium gray clay, with irregularly distributed
pockets of silt and medium to coarse sand grains.
Exposed in 1973 during construction of new sec¬
tions of the road bed of Henry Shirley Memorial
Highway, Alexandria City, Virginia, on the slope
between Seminary Road and Richenbacher Av-

1

2

enue at Lat. 38°49'46" N, Long 77°07'07" W,
7.5' Alexandria Quadrangle.

The locality is given USNM Locality No.
14252.

Age is Lower Cretaceous (Barremian-Aptian),
Potomac Group, Patuxent Formation, Lower
Zone I of Hickey and Doyle (1977).

Materials and Methods.— The collection
comprises lumps of clay and sandy clay matrix
containing lignitized woods, cones, leaf fragments
and a large array of seeds. Preparation of a small
sample was made, immediately after the collec¬
tion was obtained, in order to evaluate the quality
of the fossil material before the matrix became
dry. Most of the larger plant fragments disinte¬
grate after drying, even if the matrix is allowed
to dry slowly within its protective paper wrap¬
pings. The first specimens of the spore genus
Arcellites were observed and notes made indicating
the importance of documenting photographically
the presence of the spores in the Potomac Group.
The collection was stored until time for additional
preparations was available.

The matrix when fresh and moist was a me¬
dium gray color; however, on drying a noticeable
change to dusky yellow took place. I suspect that
the change was due to oxidation of finely divided
pyrite that contributes significantly to the origi¬
nal gray color. An efflorescence of melanterite is
present on most of the samples, which are now
quite dry, and its presence as an oxidation by¬
product lends credence to the probable explana¬
tion of the color change of the matrix.

The sand and silt grains, distributed in irregu¬
lar pockets throughout the clay, primarily are
angular, transparent to translucent quartz. A
small fraction of the silt grains are euhederal
zircon, along with mineral fragments tentatively
identified as ilmenite and garnet. No attempt was
made to carry out a complete qualitative and
quantitative analysis of the matrix.

The matrix will gradually disintegrate when
soaked in water for at least one week. Unfortu¬
nately, however, the plant fossils remain coated
with clay particles and sand grains. Complete
maceration of the matrix with subsequent free

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

and clean release of the plant material was best
accomplished with concentrated (48%) hydro¬
fluoric acid.

Transparent, polystyrene, lidded containers,
the type used for food storage, were used to hold
the acid and matrix samples during maceration.
A platform to support the matrix was constructed
from plastic containers of the type used in mar¬
keting fruits such as strawberries. Polyester screen
of standard 0.5 mm mesh was placed on top of
the supporting platform and then the specimen
of matrix. The container was filled with concen¬
trated (48%) hydrofluoric acid in sufficient quan¬
tity to cover the matrix sample. The chemical
reaction was exothermic and it was necessary to
keep the containers in a cold water bath during
the early part of the maceration. The macerations
and first washings were done in a chemical fume
hood.

After 18 to 24 hours the maceration was com¬
plete. The larger fragments of plant remains were
left lying on the screen while the smaller particles
settled through to the bottom of the container.
The screen was slowly lifted from the container
by holding opposing edges with large, long for¬
ceps. Particular care was taken to avoid disturb¬
ing the fossil plant fragments more than neces¬
sary. A one gallon polyethylene cylinder, filled
with tap water and fitted with a plastic supportive
platform positioned about one inch below the
water surface, was close at hand. The screen and
plant fragments were carefully lowered into the
water and placed on the platform. After one hour
the water in the container was siphoned off and
discarded. The container was immediately re¬
filled with fresh tap water. This washing was
repeated four times. Sediment at the bottom of
the container was not removed during the siphon¬
ing process but saved to be combined later with
the sediment that had settled through the screen
during maceration. Additional washing of the
larger plant fragments was accomplished by in¬
verting the supportive screen into a 0.5 mm mesh
plastic sieve that was partially submerged in a
constant-flow water bath set up in the laboratory
sink. The plant fragments generally settled in a

NUMBER 49

3

single area in the sieve but by sweeping the piece
of supportive screen forcefully through the water
and near the specimens they were eventually well
separated from one another. Washing continued
for five hours. The washed material was then
distributed among large (14 cm) petri plates for
sorting and picking of the specimens.

The sediment in the maceration containers was
treated differently from the coarse fraction. First
the supernatant liquid was carefully decanted
into another plastic container for subsequent dis¬
posal. The container holding the sediment was
then filled with tap water, the filling being done
forcefully in order to lift the sediment and dis¬
perse it. The sediment was allowed to settle com¬
pletely, until the wash water was clear. The water
was decanted and forcefully replaced again. This
process was repeated ten times. The washed ma¬
terial was distributed among several small, shal¬
low, white glass containers for sorting and picking
the specimens.

Sorting was done at X 20 magnification, using
a binocular dissecting microscope. Picking was
facilitated by using a dropper pipette or a small
scoop-shaped piece of 0.25 mm mesh copper
screen. Significant large fragments of plant ma¬
terial were sorted into storage vials filled with
distilled water and the megaspores were placed
in small petri plates. No further chemical treat¬
ment was given to the sorted materials except to
include granules of thymol in order to prevent
growth of bacteria and fungi. This measure is
important because the fossil remains are attacked
by bacteria within 24 hours and only a short
while later by aquatic fungi.

It should be noted that at least 40% of the
Arcellites were found floating along the margin of
the meniscus in the sieve frame or plastic wash
containers. The spores were held in place by
surface tension and capillary action of the water.
Several specimens of Thylakospontes were also
found under the same circumstances, including
the tetrahedral tetrads of the species as described
herein. I recommend that future workers pay
particular attention to this peculiarity, otherwise

many megaspores will be lost during the washing
and decanting processes.

After isolation, the megaspores were transferred
to distilled water and then further cleaned by
being transferred rapidly from the distilled water
to 100% ethyl alcohol and back to distilled water.
The micro-convection currents caused by the im¬
mersion of the spore in the water after immersion
in the alcohol swept away all of the minute debris
that still may have clung to the spore body. This
process was repeated four times, ending with
transfer of the spore into the alcohol bath. The
transfers were facilitated by supporting the spore
or several spores at a time on a scoop-shaped,
0.25 mm mesh, copper screen. This technique
also works extremely well for cleaning larger plant
fragments. The spores were individually removed
from the alcohol bath, air dried and gently
dropped into a depression slide for storage. They
were generically and specifically sorted at that
time.

Manipulation of the spores for mounting on
cover slips was facilitated by using a single eyelash
attached with acetate glue to a round toothpick.
The tip of the hair is extremely finely pointed
and when moistened with distilled water can be
used to pick, move, and position spores at will.
Circular coverslips were coated on one surface
with a thin film of white glue (Elmer’s brand)
that was allowed to dry. The individual spore
was picked up with the moistened hair. The
moisture absorbed by the spore from the hair in
turn served to moisten the surface of the glue
when the spore was touched to it. Drying was
rapid and the spore remained firmly attached. By
this means spores and spore fragments can be
oriented for scanning electron microscopy as il¬
lustrated in the specimens of Arcellites.

Dissections of Arcellites illustrated herein were
accomplished by sharpening the point of an insect
pin into the form of a microknife blade. The spore
was moistened slightly with distilled water and
then cut open in order to reveal the Y-mark. The
dissected specimens were air dried and mounted
in the same manner as the whole spores.

The coverslips with the spores were mounted

4

on aluminum stubs. The spores were sputter
coated first with carbon and then with gold-pal¬
ladium. They were viewed and photographed
using Cambridge Mark—IIA, Cambridge S4-10,
and Coates and Welter 106B scanning electron
microscopes.

Acknowledgments.— I am grateful to the
work crew of the Shirley Highway project for
alerting me to their discovery of the fossil plant
horizon that resulted in saving a small portion of
it for the national collections, to Mary-Jacque
Mann and Susann Braden for their enthusiastic
and skillful operation of the scanning electron
microscopes and processing of the photographic
negatives, to James P. Ferrigno for the photo¬
graphic prints used to illustrate this paper, to Dr.
James A. Doyle for his analysis of the matrix for
associated palynomorphs and his comments con¬
cerning the stratigraphic correlations, to Garland
R. Upchurch, Jr., for a preparation containing a
specimen of Arcellites disciformis from Lower Zone
I at Dutch Gap Canal, Virginia, to William G.
Chaloner for locality data concerning the occur¬
rence of Arcellites reported by Ellis and Tschudy
from the Patuxent Formation, to Lawrence B.
Isham for drawing the diagram in Figure 1, and
to Robert H. Tschudy and Roberta Townsend
for comments and critical reading of the manu¬
script.

Systematics

The descriptions of the seven megaspores and
two microspore species presented herein are ar¬
ranged according to the morphologic system of
classification proposed by Potonie (1956). The
single specimen of Dictyothylakos pesslerae Horst,
1954 is treated as a species of uncertain affinities
because its position within Potonie’s orderly ar¬
rangement remains obscure.

Anteturma Sporites Potonie, H., 1893

Turma Triletes (Reinsch, 1881) Dettmann, 1963
Subturma Azonotriletes Luber, 1935

Infraturma Apiculati (Bennie and Kidston, 1886)
Potonie, 1956

Genus Verrutnietes Potonie, 1956

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Verrutriletes carbunculus (Dijkstra, 1949)

Genus Echitriletes Potonie, 1956

Echitriletes cf. E. lanatus (Dijkstra, 1951)
Infraturma Muronati Potonie and Kremp, 1954
Genus Erlansonispontes Potonie, 1956
Erlansonispontes erlansomi (Miner, 1932)
Infraturma Perinotriletes Erdtman, 1947
Genus Thylakospontes Potonie, 1956
Thylakosporites retiarius (Hughes, 1955)

Genus Crybelosponles Dettmann, 1963

Crybelosporites stnatus (Cookson and Dettmann,
1958)

Crybelosporites species

Subturma Pyrobolosporites Potonie, 1956
Genus Arcellites Miner, 1935

Arcellites disciformis (Miner, 1935)

Arcellites cf. A. pynformis (Dijkstra, 1951)
Turma Barbates Madler, 1954

Genus Paxillitriletes Hall and Nicolson, 1973
Paxillitriletes species
Uncertain Affinities

Genus Dictyothylakos Horst, 1954
Dictyothylakos pesslerae Horst, 1954

Verrutriletes Potonie, 1956
Verrutriletes carbunculus (Dijkstra) Potonie

Plates 1-3

Triletes carbunculus Dijkstra, 1949:10, pi. I: fig. 12.

Triletes cf. carbunculus Dijkstra, 1951:10, pi. 2: fig. 11.
Verrutriletes carbunculus (Dijkstra).—Potonie, 1956:28, pi. 3:
fig. 26.

Description (from Dijkstra, 1949:22).—

Shape spherical. Diameter 600-1000 ju, (the mean being 820
ju., 4 spores measured). Tri-radiate ridge conspicuous, 50 p
broad, 40 p high, its length being ca. 0.6 of the radius of the
spore. Arcuate ridges lacking or scarcely visible. Spore wall,
inclusive of the tri-radiate ridges and with exception of the
contact faces, covered with hemispherical, red translucent 5-
30 p broad objects. Some specimens have but a few of such
objects, which lie single or are joined to small groups; on
other specimens they have been united to great complexes.
Spore wall 30-36 p thick, dark brown.

The description given by Dijkstra in 1951 for
another specimen, but from the English Wealden,
varies little from the original one as presented
above.

Potonie’s description (1956:28), when he estab¬
lished the new combination, translates as follows:

NUMBER 49

5

The type, ca. 940 /i, has been shown to me. Equator more or
less round to slight triangular. The ‘‘carbuncles” adhere
irregularly distributed on the dull exine like solidified, glob¬
ular, glassy, transluscent, red, liquid droplets. They look like
outflowed resin, which becomes more conspicuous by the
fact that they occur in groups, leave asymmetrical spaces
and are of very variable sizes. The form may be only
provisionally placed in the series here. Similar ones in
Hughes’ collection.

Remarks.— The two complete, although dis¬
torted, specimens and the fragment illustrated
herein conform to the descriptions given by Dijk-
stra and Potonie with exceptions of the breadth
and height of the tri-radiate ridge and the thick¬
ness of the spore coat. The tri-radiate ridge, as
clearly evident in Plate 1 (figures 1, 2, and 4), is
28 /im broad and ~ 21 jim high, just over one-
half the dimensions given for the type specimen.
The thickness of the spore coats illustrated in
vertical section in Plate 2 (figures 1 and 3) and
Plate 3 (figure 2) is 15 jum and 32 jum respectively.
These exceptions cannot be attributed totally to
shrinkage of the spores during dehydration by
reason that the dimensions of the spore bodies are
well within the range of size given in the descrip¬
tion of the type. The dimensions of the tri-radiate
ridge, I feel, do not have so much significance as
to be critical in species determination. The thin¬
ness of the spore coat of the fragment shown in
Plate 1 (figure 6), which serves as the source for
the photographs in Plate 2 (figures 1-3), is prob¬
ably attributable to corrosion and degradation of
the wall following fragmentation of the spore. Its
more porous structure is in obvious contrast to
the dense structure of the spore coats of the
complete but distorted spores shown in Plate 1
(figures 1-5) and Plate 3 (figures 1 and 2).

The specific epithet, carbunculus, is exceptionally
appropriate. Viewed through a binocular micro¬
scope at magnifications of 40 to 60 diameters, the
spores seem encrusted over most of their surfaces
with minute, lustrous, ruby cabochons. The or¬
namentations, best defined morphologically as
gemmae (Plate 1: figure 3), are not present on the
contact areas (Plate 1: figures 1 and 2; Plate 2:
figure 4; Plate 3: figure 1). They are greatly
reduced in size and number or are altogether

absent on the distal surface of the spore body
(Plate 2: figure 5). Potonie’s allusion to them as
resin that had flowed out onto the spore surface
is appropriate. The gemmae appear to have been
exuded from within the spore as a resinous sub¬
stance, retaining its glossy surface and viscous
appearance after solidifying (Plate 1: figures 3
and particularly 5; Plate 2: figures 1 and 2).
Structurally there is a smooth, thin film covering
a foam-like inner layer (Plate 3: figures 2 and 4),
the whole of which is subtended by a papilla of
the outer exoexine (Plate 2: figure 2, papilla at
arrow; Plate 3: figure 2). Viewed from the interior
of the spore, in this instance the partially de¬
graded spore wall fragment (Plate 2: figure 3), a
depression marks the position of a gemma on the
outer surface. This characteristic cannot be seen
when the endexine is intact (Plate 2: figure 6).
Circular holes in the thin film covering the foam¬
like inner layer of the gemmae is a common
feature seen on the spores that have been partially
eroded (Plate 2: figure 7).

Occurrences.— Boring Sm. Maurits No. 554,
South Limburg, Netherlands; Upper Cretaceous
(Aachenian (Senonian)); Dijkstra, 1949.

Epen and Vaals, South Limburg, Netherlands;
Upper Cretaceous (Aachenian (Senonian)); Dijk¬
stra, 1949.

Bore, D’Arcy Expl. Co. Kingsclere No. 1, 466:
Weald, southern England; Lower Cretaceous
(Barremian-Aptian); Dijkstra, 1951.

This report, USNM Locality No. 14252, Pa¬
tuxent Formation, Potomac Group; Lower Cre¬
taceous (Barremian-Aptian).

Specimens.— GG-7A, USNM 304311; GG-7B,
USNM 304312; GG-7C, USNM 304313.

Echitriletes Potonie, 1956

Echitriletes cf. E. lanatus (Dijkstra) Potonie

Plates 4, 5

Triletes lanatus Dijkstra, 1951:11, pi. 2: fig. 22.

Echitriletes lanatus (Dijkstra).—Potonie 1956:36, pi. 4: fig. 36.

Description (from Dijkstra, 1951:11).—

6

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Spore hemispherical, top area flattened. Diameter 600-800
p (the mean being 700 p, 4 specimens measured). Tri-radiate
ridges nearly as long as the spore radius, 20-30 p broad, 50-
100 /u. high. Arcuate ridge not clearly distinguishable. Spore
coat covered with 10 p large papillae bearing hair-like wooly
appendages, 150 p long, 3-5 j u thick. Spore coat brown, 25
p thick.

Potonie (1956:36) described the species as fol¬
lows:

Genotype around 780 p (from the illustration); trilete, simple
megaspores, equator subtriangular to circular, trilete rays
not always present, exine ornamented on all sides with capilli
to spinae, in the genotype provided with rounded verrucae,
which subtend more or less long, hair-like, contorted capilli,
otherwise with simple or hook-like spinae (translated by
author).

Remarks. —Morphologically the two speci¬
mens illustrated herein conform to the descrip¬
tions given for the species, with the exceptions of
the density of the capilli on the specimens (Plate
4: figures 1,2; Plate 5: figures 1, 3) and the low
or poorly developed tri-radiate ridges. Accurate
measurements of the spore body are precluded by
the density of the capilli. Measurements exclud¬
ing the capilli can be estimated as low as 800 fim
or, including the capilli, can be obtained as high
as 1066 jtim. These dimensions exceed the range
given for the type specimen. I am assuming that
the measurements of the type specimen did not
include the capilli, that is, the dimension was of
the spore body alone. If, however, one were to
add the given length of the capilli, 150 fim, to the
diameter of the spore body, 780 jiim, the total of
930 jam would then fall within the measurable
size given for the two specimens at hand. The
specimens in this report are larger, but not so
much so as to be excluded from the species.

The capilli, which range from 65 to 135 jam
long, are proximally broadened, in which case it
could be interpreted that they are subtended by
verrucae (Plate 4: figures 3, 4). Their apices are
either pointed or simply to several times divided
(Plate 5: figure 4). This latter character is not
described for the type-species; however, most of
the forked apices, because of their fragility, can
be easily broken off during processing and thus
are not readily observed (Plate 5: figure 3).

A finely reticulate pattern can be seen as char¬
acteristic of the outer exoexine between the bases
of the capilli (Plate 4: figure 4; Plate 5: figure 2).

I have only two specimens of this megaspore
and although their morphological differences
from the type-species are probably significant
enough to establish a new species, I prefer to
designate them as E. cf. E. lanatus. Acquisition of
additional specimens will permit more significant
analysis of the similarities and differences than is
possible at this time. Commonly, in both speci¬
mens, microspores, herein assumed to be related
to this species, are found among the matted cap¬
illi. They are all of the same morphology and
dimensions (Plate 4: figures 5, 6; Plate 5: figures
5, 6). Description of these microspores appears
later, where they are assigned to Crybelospontes
Dettmann, 1963 as Crybelospontes species.

Occurrences.— Boring B; Bore, D’Arcy Expl.
Co. Kingsclere No. 1 at 706 feet and (?) 466 feet,
Weald, southern England; Lower Cretaceous
(Barremian-Aptian); Dijkstra, 1951.

This report, USNM Locality No. 14252, Pa¬
tuxent Formation, Potomac Group, Lower Cre¬
taceous (Barremian-Aptian).

Specimens.— HH-1 A, USNM 304314; HH-1B,
USNM 304315.

Erlansonisporites Potonie, 1956

Erlansonisporites erlansonii (Miner) Potonie

Plate 6

Selaginellites erlansonii Miner, 1932:500, fig. 1.

Erlansonisporites erlansonii (Miner).—Potonie, 1956:46, pi. 5:

fig. 53.

Description (from Miner, 1932:500).—

Body of exine round, 465-1000 p in diameter the mean
being 690 p; exine reticulate with irregular diaphanous
appendages, 17-122 p in width, giving the spore a total
diameter of 500-1,155 p with the mean at 790 p\ no com-
misural ridges or clefts visible.

Potonie (1956:47) describes the species as fol¬
lows:

Genotype apart from the membranes of the muri 899 p

NUMBER 49

7

(from the photograph); equator circular, trilete mark not or
poorly discernible probably because of the heavy reticula¬
tion. The muri of the reticulum merge into filmy lamellae
that may be uniformly developed on the entire exine, how¬
ever, in the photograph of the genotype they become visible
chiefly on the periphery of the spore (translated by the
author).

Remarks.— One spore from among five speci¬
mens that were obtained from the prepared sam¬
ples is shown in Plate 6 (figures 1-6). It is 800 fim
in diameter and is representative in form and
structure of all of the specimens. The size range
of the five specimens is 695 to 840 jam in diameter.
The location and general size of the trilete mark
is visible (Plate 6: figure 1), probably because of
increased height of the muri of the reticulum
along the leasurae instead of an extension of lips
along the laesurate margins. Support for this
observation requires microtome preparations and
such are not within the scope of this report. The
muri range from 14 to 45 jam in height between
the bastion prongs, the prongs reaching as much
as 78 jam in height.

The outer exoexine is psilate (Plate 6; figure 4).
Bastion prongs and the diaphanous muri con¬
necting them are quite obvious in Plate 6 (figures
1-3, 5). Sculpture of the muri is reticulate with
minute, ~ 1.5 jam, clavae rising from the intersec¬
tions of the muri of the reticulum (Plate 6: figure

6) -

A precious opal-like iridescence of the spore
coat is a notable characteristic of the species.
Structural details of the spore coat relevant to
this phenomenon were not obtained; however, I
shall presume that they are identical to those
described and discussed for Thylakospontes retiarius
(Hughes) Potonie, the next species in this report.
In that discussion it will be noted that the spore
coat structure of this species and T. retiarius is
compared to that of the two modern species of
Selaginella. This evidence strongly suggests that it
would be appropriate to return E. erlansonn to the
original taxon Selaginellites, as proposed by Miner
in 1932. However, the transfer will not be made
herein because neither isotype material from
Miner’s collection nor additional specimens from

the site described herein have been obtained for
direct comparison and confirmation.

Occurrences.— Skansen, east of Disko Island,
Greenland; Upper Cretaceous (?Campanian);
Miner, 1932.

This report, USNM Locality No. 14252, Pa¬
tuxent Formation, Potomac Group; Lower Cre¬
taceous (Barremian-Aptian).

Specimens. —GG-10B, USNM 304316; depres¬
sion slide with four unmounted specimens,
USNM 304317.

Thylakosporites Potonie, 1956
Thylakosporites retiarius (Hughes) Potonie

Plates 7-10

Triletes retiarius Hughes, 1955:213, pi. 11: figs. 3, 4.
Thylakosporites retiarius (Hughes).—Potonie, 1956:49, figs. 55-
57 [not 57 in text. Type-specimen not designated. Lecto-
type designated by Jansonius and Hills, 1976, fig. 3 of
Hughes.]

Description (from Hughes, 1955:213).—

Trilete megaspore probably spherical but the whole upper
(apical) surface may be preserved infolded [figure citation].
Diameter 520-700 p (mean 620 jli, 6 specimens). Tri-radiate
ridges 200 p long, 10 p broad, and 30 p high; contact faces
smooth except in one specimen where the perispore covers
the whole spore surface. Distal hemisphere entirely covered
[figure citation] with a mesh-like (net) perispore sometimes
in different layers of different mesh size. The chief mesh
strands are 15-35 p wide and 10 p thick [figure citation] but
may also be circular in cross-section exactly as described and
figured by Horst (1954) and figured by Michael (1936).
Spore coat is brown but shows a red luminous effect in
places; thickness of exoexine 15 p, intexine very thin 2-3 p
and continuous with tri-radiate lips.

Potonie (1956:49) gives an abbreviated descrip¬
tion that translates as follows:

Genotype ca. 650 p (from the illustration), trilete mega¬
spore, probably spherical, however the entire proximal hem¬
isphere can be strongly folded, Y-radii extending nearly to
the equator; exine smooth, however always surrounded on
the whole distal side, in one specimen of the genotype also
on the proximal side, by a perispore. The latter consists of
an often multilayered reticulum [figure citation] similar to
that which is described by Horst 1954, page 610, as Dictyo-

8

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

thylakos pesslerae. Diciyothylakos is found in the German Weal-
den coals of southern Mecklenburg and Odenwald.

It was correct not to equate Dictyothylakos and Thylakos-
porites because there could be other spore genera that have
a similarly constructed perispore. (In Cystosporites no peris-
pore is present, but at the same time the exine shows a felt¬
like and densely matted, many layered reticulum; compare
Potonie and Kremp, 1955, Plate 10, figure 79.) Detached
fragments of perispores belonging to Thylakosporites are found
(translation by the author).

Remarks. —Thirty-four specimens of this spe¬
cies were obtained from the samples prepared for
this report. This number afforded the opportunity
to observe a wide range of structural details as
well as various degrees of mechanical and chem¬
ical degradation of the spore body and its orna¬
mentation.

Three specimens were recovered in which the
spores are still united in the form of tetrahedral
tetrads; a typical one is illustrated in Plate 7
(figures 1, 2). A very thin, amorphous layer of
organic material covers the whole tetrad and
nearly completely masks the reticulum of the
outer exoexine on the distal portions of the spores.
The layer is thickened along the margins of the
contact areas and becomes more evident when a
single spore is broken away from the tetrad (Plate
7: figures 3, 4). When the thin, amorphous, outer
layer is degraded or eroded the reticulum be¬
comes more prominent (compare Plate 7: figures
5 and 6). The reticulum on some specimens is
partially lost to degradation or erosion (Plate 8:
figures 2-4), or completely missing except for
individual points of attachment to the spore body
(Plate 9: figures 1,3).

The diameter of the spore body, excluding the
reticulum, ranges from 600 to 785 jim, or, includ¬
ing the reticulum, ranges from 640 to 950 jum. No
meaningful measurements of the height of the
extension of the reticulum above the spore body
can be given because the variation is a function
of the amount of compression that the layer has
undergone. The specimens at hand tend to exceed
the size range given for the type material; how¬
ever, I do not consider the difference so great as
to suggest establishing a new species.

A tri-radiate ridge is prominent on the spores.

It varies from 185 to 210 jiim long, 12 to 23 ^.m
wide, and 24 to 32 jttm high. The variation ap¬
pears to be due to the degree of compression, the
more convex, less compressed specimens have
narrower and higher ridges than those that have
been distorted by compression.

Three layers from the spore coat (Plate 8:
figures 1, 5-8; Plate 9: figures 2, 4-6; Plate 10:
figure 3). The reticulate, outer exoexine layer on
the spore body varies from 1.5 to 4 jam thick, the
outer exoexine layer extends into and forms the
coarse reticulum that covers the equatorial and
distal portions of the spore body (Plate 8: figure
4; Plate 10: figure 4). The fine reticulate structure
of the individual elements of the reticulum is
shown in Plate 10 (figures 5, 6). The next layer,
inner exoexine, with an opal-like structure, aver¬
ages 16.75 jam in thickness. The reticulate endex-
ine varies from 1 to 2 jam in thickness; the average
being 1.4 jam. The contact areas are free of the
ornamental reticulum (Plate 9: figures 1, 3; Plate
10: figure 1).

The opal-like quality of the spore wall is, be¬
yond question, the most striking characteristic of
the species. I feel that the characteristic is briefly
alluded to in Hughes’ comment: “ . . . spore coat
. . . shows red luminous effects in some places.”
The spore stands out, sparkling with the colors of
a fine, precious opal, against the blackness of the
surrounding carbonized plant debris. I regret that
it is not possible to reproduce a color photograph
to illustrate this phenomenon. The structure of
the inner exoexine (Plate 8: figures 5, 7; Plate 9:
figures 4, 6) is precisely that which has been
shown by Sanders and Darragh (1971) for the
structure of precious opal. Rows of contiguous
spherules, each spherule averaging 0.25 jum in
diameter, are uniformly and alternately aligned,
giving the appearance of stacked lead shot, or on
a grander scale, stacked cannon balls. The align¬
ment can be seen to change direction (Plate 9:
figure 4) through an angle approximating 60°
This alignment of spherular bodies produces a
diffraction grating effect by separating and re¬
flecting incident light into the spectrum colors.
The various alignments of the spherules produce

NUMBER 49

9

the various colors seen as the spore body is ro¬
tated. At first it was thought that the spore had
been preserved through permineralization of the
spore wall by opal. However, only this species
and Erlansonispontes erlansonii from among all of
the other species found at this site exhibit the
precious opal effect and it would be quite unusual
for such selective preservation to take place. I
made the assumption that the organic layers of
the outer exoexine and the endexine had pro¬
tected what I thought was the siliceous inner
exoexine from attack by the hydrofluoric acid
solution. This assumption was encouraged by the
specimen illustrated in Plate 10 (figures 1-3),
which exhibits a peculiar corrosion of the inner
exoexine layer of the spore wall.

Electron dispersive x-ray (EDX) analysis of the
inner exoexine layer produced the results shown
in the spectograph reproduced in Figure 1. Silicon
should be the primary element recorded if the
inner exoexine layer were composed of opal. In¬
stead, only a minor amount of silicon is indicated.
Analyses of five different specimens of the spore
yielded essentially the same results as shown here.
The analyses clearly indicated that the inner
exoexine layer in Thylakosporites retiarius is not
composed of opal, even though its microstructure
and light refractive qualities parallel those of
precious opal. All of the elements indicated in the

s

ci

0 UFS = 8192 10.240

Figure 1. — Electron dispersive x-ray spectrograph showing
analysis of inner exoexine layer in spore coat of Thylakosporites
retiarius (Hughes) Potonie (specimen KK-1B, USNM
304318).

analyses can be anticipated as components of the
structure of the spore coat, with the exception of
the copper (Cu), aluminum (Al), and tin (Sn),
which are interpreted herein as contaminants
derived from the metal screening used in the
isolation, cleaning, and drying of the individual
spores. Taylor, et al. (1976) present analysis of
the spore walls of the liverwort species, Conoce-
phalum conicum , and discuss the significance of the
various elements found there. Their bibliography
contains several additionally useful references for
the intepretation of the results of spore wall anal¬
yses. I recommend that the interested reader con¬
sult Taylor, et al. Further discussion of the subject
is beyond the scope of this report.

An exciting and completely unexpected body
of information relevant to the structure of the
inner exoexine of T. retiarius was found in a paper
by Tryon and Lugardon (1978). The writers dis¬
cuss the structure and mineral content of the
spore coats of the megaspores of two species of
Selaginella. They illustrate their paper with SEM
and TEM photographs as well as EDX spectro¬
graphs. The SEM photographs in their pi. IV
(fig. 1) and pi. V (fig. 1) are so similar in appear¬
ance to those in my Plate 8 (figure 5) and Plate
9 (figure 4) as to appear to be the same specimens.
However, their photographs are of the megaspore
wall of Selaginella galeottii Spring, a modern, trop¬
ical, American species. Their EDX analyses of
the opal-like inner exoexine of the spores indicate,
as did my analyses, the presence of only a minor
amount of silicon. Their analyses are more de¬
tailed than mine and include spectrographic
mapping whereby they are able to demonstrate
that the silicon is concentrated in the outer limits
of the inner exoexine layer. The silicon, presum¬
ably as the oxide mineral quartz, is randomly
distributed among the interstices of the rows of
spherular bodies that form the layer. The opal¬
like iridescence of the spore coat of the mega¬
spore of S. galeottii is not mentioned by Tryon and
Lugardon; however, I have observed the phenom¬
enon in specimens from Veracruz, Mexico filed
in the United States National Herbarium.

Pierre Martens (1960a) illustrates, by means of

10

TEM photographs, the same opal-like wall struc¬
ture in the megaspores of another modern species
of Selaginella, S. myosurus (Swartz) Alston. In a
second paper on the same species (1960b) he
describes the iridescent quality of the spore wall
when observed microscopically in reflected light.
This is the only reference to the phenomenon that
I have been able to find in the literature. Selagi¬
nella myosurus is native to the region of Zaire,
Africa.

Frangoise Stanier (1965, 1967) presents addi¬
tional details regarding the structure of the me¬
gaspore wall of S. myosurus and quotes the obser¬
vation made by Martens on the iridescent quality
of the spore wall. The TEM photographs in her
pi. 1: figs. 3, 4 (1967) lend supportive evidence
for the interpretation of the structure of the spore
wall of the fossil T. retiarius , illustrated herein with
SEM photographs.

Additional, refined EDX analyses and prepa¬
rations, such as sections for transmission electron
microscopy of the spore coat of T. retiarius , are
required. Certainly, precisely the same study of
the spore coat structure of Erlansonisporites erlan-
sonii is also required when one considers the sig¬
nificance of the iridescent quality of the spore
coats of the two fossil species. Nevertheless, de¬
spite lack of elaborative details, the evidence at
hand strongly indicates that the spore species, T.
retiarius and E. erlansonii, are fossil evidence for the
existence of ancestral forms of some of the modern
species of Selaginella during the Lower Cretaceous
of eastern North America.

As a final note, I agree completely with Po-
tonie’s opinion (1956) that Dictyothylakos and Thy-
lakosporites are not to be combined. I illustrate a
specimen of Dictyothylakos late in this report to
show that structurally there is some similarity
between the reticulum of the outer exoexine of
Thylakosporites and the morphology of Dictyothyla¬
kos. I present a conjectural analysis of Dictyothy¬
lakos in the discussion of the specimen.

Occurrences.— Hughes’ locality S 7; Cliffs of
Compton Bay, Isle of Wight: Wealden Marls,
Bed 11; Lower Cretaceous (Barremian-Aptian);
Hughes, 1955.

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

This report, USNM Locality No. 14252, Pa¬
tuxent Formation, Potomac Group; Lower Cre¬
taceous (Barremian-Aptian).

Specimens.— BB-12A, USNM 304319; GG-8A,
USNM 304320; GG-10A, USNM 304321; GG-
10C, USNM 304322; GG-10D, USNM 304323;
HH-2B, USNM 304324; KK-1B, USNM 304318;
KK-2A, USNM 304325; KK-2B, USNM 304326;
and 26 specimens stored in a depression slide,
USNM 304327 for use in further study.

Crybelosporites Dettmann, 1963

Crybelosporites striatus (Cookson and Dett¬
mann) Dettmann

Plate 11

Perotrilites striatus Cookson and Dettmann, 1958, 4(1) :43, pi.

1: figs. 8-12.

Description (from Dettmann, 1963:80).—

Microspores trilete, spheroidal. Sclerine stratified, cavate
proximally, 4-5 j u thick (inclusive of sculptural/structural
elements), consisting of a smooth, homogeneous, inner layer
(1-1.5 ju. thick) and a ruffled, proximally cavate, two-layered
sculptine, the outer of which forms a conical gula-like pro¬
jection over the proximal pole. Sculptine 3 ju thick in optical
section, striated proximally, reticulate distally and equato-
rially; reticulum composed of membranous muri (1.5-3 ju
high) which enclose circular to polygonal lumina 1—3 /i. in
diameter. Laesurae developed on two inner wall layers only;
straight, length 3/4 spore radius with weakly thickened lips.

Dimensions: equatorial diameter 28(37)45 [i; polar di¬
ameter 34(45)56 ju; diameter of inner layer 20(29)29 fx.

Remarks.— Scanning electron microscope ob¬
servations preclude complete comparison of the
spores illustrated herein to those observed by
means of optical light microscopy. The two-lay-
ered, proximally cavate sculptine is quite obvious
in Plate 11 (figures 3, 4). The reticulate sculpture
is rather faintly discernible on the distal and
equatorial portions of the spore body. The size
range of the specimens among the folds of the
acrolamellae on specimens of Arcellites disciformis
in Plate 11 (figures 1, 3) and Plate 14 (Figure 3)
is 30 to 42 jam in equatorial diameter, which is

NUMBER 49

11

within the size range given for the type of the
species.

Significantly this microspore has been found
adhering to the type specimen of the megaspore
species Arcellites disciformis and on subsequent
specimens illustrated by Ellis and Tschudy
(1964). Also, the specimen of A. disciformis sent by
Garland Unchurch, Jr., mentioned later herein,
has two of these same microspores adhering to
the base of the acrolamellae. This repeated asso¬
ciation clearly indicates that these megaspores
and microspores will eventually be identified with
a single sporophyte species. However, the sporo-
phyte is certain to be a delicate aquatic fern of
which the remains will be found only as a result
of ideal conditions of burial and preservation.

I am not convinced that the natural position of
occurrence of these microspores is within the neck
formed by the acrolamellae of the megaspore as
described by Ellis and Tschudy (1964). Instead,
their position appears to have been one of adhe¬
sion to the smooth outer surface of the folds of
the acrolamellae. Additional discussion of this
question is presented later in the remarks on
Arcellites disciformis.

Occurrences.— Aptian through Albian in
Australia and New Guinea; Dettmann, 1963.

No. 1 Mann well, 4686 feet, Fall River Sand¬
stone; Upper Cretaceous (Albian); Ellis and
Tschudy, 1964.

This report, USNM Locality No. 14252, Pa¬
tuxent Formation, Potomac Group; Lower Cre¬
taceous (Barremian-Aptian).

Specimens.— BB-11C, USNM 304328; GG-6A,
USNM 304329.

Crybelosporites species

Plates 4, 5

Description (incomplete).—Trilete micro¬
spores; equatorial outline of spore body circular;
structure of the spore coat requiring thin sections
for transmission electron microscopy or exami¬
nation by optical, light microscopy for complete
description; however, sculptine of two layers is

suggested by folded, cavate, outer layer (Plate 4:
figure 5) that covers and masks the sculpture of
the inner layer; sculpture of inner layer may be
granular as described for C. punctatus Dettmann,
1963 (Plate 4: figure 6); Y-mark small (Plate 5;
figure 6), rays approximately one-half of spore
radius; diameter of the spore 23 to 25 jum (14
measured).

This microspore was found lodged among the
capilli on Echitriletes cf. E. lanatus, described
herein, in relatively large numbers and to the
apparent exclusion of other species. I suggest that
these spores, the megaspore as well as micro¬
spores, were produced by the same sporophyte,
which, unfortunately, is yet to be identified.

Occurrence.— This report, USNM Locality
No. 14252, Patuxent Formation, Potomac Group;
Lower Cretaceous (Barremian-Aptian).

Specimens.— HH-1 A, USNM 304314 and HH-
1B, USNM 304315.

Arcellites Miner, 1935

Arcellites disciformis Miner emend. Ellis
and Tschudy

Plates 12-19

Arcellites disciformis Miner, 1935:600, pi. 20: figs. 61, 64-66.
Arcellites disciformis Miner, emend. Ellis and Tschudy, 1964:

75.

Description (emendation by Ellis and
Tschudy, 1964:75).—

Nearly spherical spore body having an equatorial diameter
of 185-350 /i (mean 259 ju); neck consisting of six leaf-like
folded appendages forming a long flamelike organ; length
of neck 261-477 /x (mean 357 /x). Each “leaf” folded length¬
wise and inward, characteristically crenulate or fimbriate on
its margin. “Leaves” commonly exhibit torsion of about
180°. Spore body bearing a variable number (11 to 26, mean
16) of blunt tubelike appendages, which are usually con¬
stricted at their bases. Appendages possess a thick, probably
originally spherical, reticulate bladder on their extremities.
Spore coat of three layers; exoexine about 11 fi thick, thin¬
ning at neck and appendages and divisible into two layers,
outer about 8 ju. thick and inner about 3 jli thick, sometimes
seen detached from the exoexine. The inner layer of the
exoexine and the intexine are continuous across the floor of
the neck. A tri-radiate scar is present on the floor of the neck.

12

Exoexine penetrated by characteristic pits which are some¬
what elliptical in cross section; intexine smooth.

Remarks.— Nearly all specimens examined for
this report are preserved in three-dimensional,
undistorted form. The equatorial diameter of the
spore bodies varies from 188 to 245 jtim, which
places the variation below the mean given in the
original description. The measurements I have
taken are from dry spores. I did not measure
specimens in wet mounts wherein I am sure the
measurements would be higher due to swelling of
the spore walls as a result of absorption of water.
Movement can be observed as the spores dry or
as they are remoistened during the mounting
processes, suggesting that a certain amount of
shrinkage does take place during dehydration.
The flame-like organ varies in length and width,
as can be seen in the equatorial and proximal
views of the examples in Plates 11-13 and Plate
19 (figures 1, 3). Again the variation falls below
the mean given in the original description, and
the reason for that is probably the same as for the
spore body variation.

Morphologically and anatomically the speci¬
mens are identical to those described and illus¬
trated by Ellis and Tschudy (1964). Three layers
form the spore coat and are clearly demonstrated
in Plate 17 (figure 2). Pits in the outer exoexine
layer, illustrated in surface view in Plate 16 (fig¬
ures 1-4), penetrate the outer exoexine layer, as
can be seen in Plate 17 (figures 2-4). The inner
exoexine layer has a reticulate structure while the
endexine (intexine) is compact and almost amor¬
phous. The tubular appendages (Plate 18; figure
1) are formed by extension of the outer exoexine
layer (Plate 18: figure 3). In some instances for¬
mation of the appendages was not complete as
indicated by protuberances on the spore surface
(Plate 16: figure 4). The inner exoexine extends
very slightly into the base of each appendage
(Plate 17: figures 3, 4; Plate 18: figures 3, 5). The
apices of the appendages are reticulate (Plate 18:
figures 1, 2, 4) and I agree that they probably
were formerly slightly expanded in bladder-like
form (Plate 18: figure 2). The reticulation is
similar to that of the margins of the acrolamellae.

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Minute, pleat-like folds along the margins of the
acrolamellae end in finger-like extensions that
appear to be entangled but not fused with those
of the neighboring margin (Plate 15: figures 2-
4). Pores and fissures are present between the
folds and among the elements of the fimbriate
margins. They probably gave access to the neck
cavity (Plate 15: figure 1) formed by the acrola¬
mellae. Occasionally the acrolamellae are sepa¬
rated from one another (Plate 13: figure 4; Plate
14: figures 1, 2). They, like the appendages, are
formed by extension of the outer exoexine (Plate
19: figure 3) as a single layer (Plate 15: figure 2).
The Y-mark can be clearly observed only by
removal of the flame-like organ or by cutting the
spore body in half along its equator. The best
results were obtained by cutting the spore body
in half (Plate 19: figure 1) and examining the
inner surface of the proximal polar area. The Y-
mark is clearly visible in the spore coat that forms
the floor of the neck cavity (Plate 19: figure 2).
The endexine and the inner exoexine are contin¬
uous across the floor of the neck cavity (Plate 19:
figures 3, 4) but are split by the trilete suture.

Microspores were found adhering to the outer,
smooth surfaces of the folds in the acrolamellae
(Plate 14: figure 3; Plate 11: figures 1-4). I agree
with Ellis and Tschudy (1964:76) that the flame¬
like organ, the neck, may have had a gelatinous
material associated with it that served to trap
microspores. The outer layer of the sculptine of
the microspore may also have had a sticking
quality that would cause it to adhere to the
surface of the megaspore after the gelatinous
exudate of the megaspore had disintegrated. Ger¬
mination of the microspore could have occurred
outside of the neck cavity and the sperm could
have swam through the fissures and pores along
the margins of the acrolamellae, into the cavity
and to the female gametophyte at the base of the
neck.

I have illustrated these megaspores in the po¬
sition suggested by Ellis and Tschudy as the life
position when the spores were released from the
sporophyte. This is the position that they assume
when found floating in the wash waters during

NUMBER 49

13

preparation of the matrix. Note that many can
be lost if wash waters are discarded without first
being examined for “floaters.”

Ellis and Tschudy (1964) place Arcellites crillen-
sis Schemel, 1950 and Arcellites cf. A. hexapartitus
(Dijkstra) Potter, 1963 in synonymy with A. dis-
cifnrmis. I agree with this decision. I must admit
that I am uneasy with Arcellites hexapartitus as
illustrated by Hughes, 1955 (pi. 10: fig. 4). How¬
ever, without seeing specimens of the species at
first hand I must accept the identification of the
specimen.

Occurrences (from Ellis and Tschudy, 1964,
table 1).—In descending order of age:

Skansen, Disko Island, Greenland; Upper Cre¬
taceous (Cenomanian); Miner, 1935.

Crill coal, Dakota Group, Iowa, USA; Upper
Cretaceous (Albian); Schemel, 1950.

“D” sandstone, 4480 feet, Plains Exploration
Company Parker 1; C NW SE Sec. 19, T. 3N., R.
51 W., Washington County, Colorado, USA;
Upper Cretaceous (Cenomanian); Ellis and
Tschudy, 1964.

“Huntsman” shale, samples 4531 and 4580
feet, Marathon Oil Company Holt 2; SE SE SE
Sec. 7, T. 17N., R. 49W., Morrill County, Ne¬
braska, USA; Upper Cretaceous (Albian); Ellis
and Tschudy, 1964.

Newcastle Sandstone (type section); NW NW
NW Sec. 28, T. 45N., R. 61W., Weston County,
Wyoming, USA; Upper Cretaceous (Albian); El¬
lis and Tschudy, 1964.

“J” sandstone, 4865 feet, Marathon Oil Com¬
pany Gurschke 1; SW NE SE Sec. 3, T. 14N., R.
50W., Cheyenne County, Nebraska, USA; Upper
Cretaceous (Albian); Ellis and Tschudy, 1964.

Glencairn Shale Member of the Purgatoire
Formation, Beaver Creek surface section; NW
Sec. 10, T. 18S., R. 68W., Fremont County,
Colorado, USA; Upper Cretaceous (Albian); Ellis
and Tschudy, 1964.

Skull Creek Shale, South Platte Formation,
4698 feet, Marathon Oil Company, Knievel 1;
NE SE SE Sec. 2, 15N., R. 49W., Cheyenne
County, Nebraska, USA; Upper Cretaceous (Al¬
bian); Ellis and Tschudy, 1964.

Fall River Sandstone, 4686 feet, California
Company Mann 1; SE NE NW Sec. 27, T. 30N.,
R. 56W., Sioux County, Nebraska, USA; Upper
Cretaceous (Albian); Ellis and Tschudy, 1964.

Patuxent Formation, Potomac Group, Dre-
wry’s Bluff, James River, near Richmond, Vir¬
ginia; Lower Cretaceous (Barremian-Aptian); W.
G. Chaloner, pers. comm. 22 Sep 1980.

Dutch Gap Canal, Virginia; Lower Zone I,
Potomac Group, Lower Cretaceous (Barremian-
Aptian); specimen sent for examination by Gar¬
land Upchurch, Jr.

This report, USNM Locality No. 14252, Pa¬
tuxent Formation, Potomac Group; Lower Cre¬
taceous (Barremian-Aptian).

Specimens. —BB-11A, USNM 304330; BB-
1 IB, USNM 304331; BB-11C USNM 304328;
BB-1 IF, USNM 304332; GG-3A, USNM 304333;
GG-4A, USNM 304334; GG-4B, USNM 304335;
GG-4C, USNM 304336; GG-5A, USNM 304337;
GG-5C, USNM 304338; GG-6A, USNM 304329;
GG-6B, USNM 304339; II-2, USNM 304340;
depression slide with 70 specimens unmounted,
USNM 304341.

Arcellites cf. A. pyriformis (Dijkstra) Potter

Plates 20, 21

Triletes pyriformis Dijkstra, 1951:14, pi. II: fig. 9
Pyrobolosporapyriformis (Dijkstra).—Hughes, 1955:209, pi. XI:
figs. 1, 2.

Arcellites pyriformis (Dijkstra).—Potter, 1963:228.

Description (from Dijkstra, 1951:14).—

Spore pyriform, mostly flattened in lateral direction. Length
of spore, including neck-like projection, 375-700 p (the mean
being 591 p, 17 specimens measured), breadth about 300-
700 p. Neck-like projection to 250 p long, 300 p bioad. Tri-
radiate ridges 250-300 p long, 50 p broad, about 60 p high.
Arcuate ridge not distinguishable. Between the tri-radiate
ridges some plications running in lateral direction, 100-200
p long, 30 p broad, 10 p high. Spore body covered with
numerous bluntly ended appendages, 30 p long, 20 p broad.
Spore coat black.

Hughes’ emendation (1955:209) is as follows:

Spore-body originally nearly spherical but usually equatorial
diameter exceeds the axial. Equatorial diameter 290-920 p

14

(mean 651 ju, 35 specimens or mean 631 ju. including Dijkstra’s
specimens). The axial measurement with or without the neck
is meaningless, as the majority of specimens are asymmetri¬
cally laterally flattened; this suggests that the top of the
spore below the neck is the most rigid part. Only the
maximum neck dimensions are given as the neck is so
frequently incomplete; length up to 350 \i, width 350-400
(i at extremity, narrowing to the base. The neck arises from
the spore body as three prominent folds and consists basically
of three bulging lobes between these folds; the specimen in
Plate XI, fig. 2, is a small one with somewhat irregular
appendages but it shows at the neck attachement a fold
centrally, flanked by two downward bulging lobes, with the
two other folds at the margins in this view. In most cases the
main part of the neck is opaque and ochreous in colour, and
lacking in precise form; broken surfaces reveal the upper
part to be composed of a solid mass of sponge-like tissue
without any central canal. Certain complete specimens seem
to show a six-fold symmetry of leaves of the neck on the top
surface, and others in which the neck is reduced to translu-
cency by maceration show the same number. Spore-body
covered evenly with blunt simple or compound appendages
30-40 /x broad, and seldom less than 15 jtt apart in an average
specimen; slight decrease in size of appendages towards the
neck.

Spore-coat brown to black, consisting of opague exoexine
layer 25-30 /x thick and intexine 5 /x thick and transluscent;
exoexine layer is likely to be divided as in P. vectis but good
confirmatory sections have not been prepared because of the
brittleness of specimens. Tri-radiate mark (laesurae 200 /x
long) seen on inner side of apex of intexine and inner part of
exoexine in broken specimen. Ideally a neck-chamber is
present in the base of the neck but it has not been explored;
the swollen lobes mentioned above were seen in some good
specimens to be hollow.

Remarks.— Three specimens were obtained
but only one of them is complete (Plate 21: figures
1-3). Its diameter is 647 [im and the range of sizes
of the appendages is in agreement with that given
in the type-description. However, I cannot be
certain of the morphology of the neck. Hughes
begins his morphological description saying that
“the neck arises from the spore-body as three
prominent folds and consists basically of three
bulging lobes between these folds.” My specimen
shows three folds arising from the spore body but
no bulges are present between the folds; the neck
remains three-parted (Plate 21: figures 3, 4). I
shall withhold judging whether there are only
three acrolamellae on my specimen or six that are
distorted by preservation. Hughes placed empha-

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

sis on the presence of six acrolamellae. I cannot
prove which number is correct for my specimen.
I shall therefore suggest that it be designated
Arcellites cf. A. pyriformis in light of the strong
agreement of the other structural details with the
type-specimen.

The two fragmentary specimens (Plate 20: fig¬
ures 1-7, and Plate 21: figures 6-9) exhibit iden¬
tical morphological characteristics to the intact
spore and provide excellent anatomical details.
The spore coat comprises three layers (Plate 20:
figure 4, and Plate 21: figure 7); the inner exoex¬
ine, which is coarsely reticulate, and the endexine,
which is very thin (~ 1 /tm). The outer exoexine
forms the appendages. All of the layers tend to
separate from one another (Plate 20: figures 4-6)
and, in the case of the fragment in Plate 21 (figure
6), the endexine is missing from most of the inner
wall. When preserved, the endexine structure is
more finely reticulate (Plate 20: figure 8) than
that of the other layers. Evidence for a neck
chamber at the base of the neck is illustrated in
Plate 20 (figure 3) and Plate 21 (figure 6). Details
of the Y-mark were not obtained from the speci¬
mens at hand.

I have illustrated this species with the neck
pointing downward, suggesting the position of
the spore when it was free floating after release
from the sporophyte. Unfortunately, no micro¬
spores have been found attached to the neck as
has been the case with A. disciformis. My feeling is
that the microspores would most likely adhere to
the apex of the neck rather than to the sides. The
texture of the apex, in the fossil condition, sug¬
gests that it was spongy and thus porous and the
probable site of any gelatinous exudate that
might have entrapped microspores.

Occurrences.— Lower part Bore B, Nether¬
lands; Lower Cretaceous (Wealden); Dijkstra,
1951.

Cliffs in middle Fairlight Clay below Coast
Guard Station, halfmile NE of Fairlight Glen
Foot, England; Hughes’ Locality 80A; Lower
Cretaceous (Berriasian); Batten, 1969.

Wealden Marls of the Isle of Wight, England;
Lower Cretaceous (Barremian); Hughes, 1955.

NUMBER 49

15

This report, USNM Locality No. 14252, Pa¬
tuxent Formation, Potomac Group; Lower Cre¬
taceous (Barremian-Aptian).

Specimens.— BB-12, USNM 304342; HH-2A,
USNM 304343; HH-2C, USNM 304344.

Paxillitriletes Hall and Nicolson, 1973
Paxillitriletes species

Plates 22, 23

Paxillitriletes Hall and Nicolson, 1973:319 [type-species P.

reticulatus (Madler) Hall and Nicolson],

Diagnosis (from Madler, 1954:150).—“Mac¬
rospores with pilose sculpture along the tetrad
rays or only in their immediate region; equatorial
flange narrow, rays of Y-mark extending to or
slightly beyond it.”

Remarks.— Only two specimens were found
and this paucity of material precludes assigning
a specific name to these beautifully ornamented
megaspores. The specimen shown in Plate 22
(figures 1-4) and Plate 23 (figures 1,2) is 284 jum
in diameter, excluding the equatorial flange. The
distal surface has a reticulate sculpture. Short
appendages, 5.75 to 17.5 /im long, and truncate
bases of longer ones, extend from the contact
points of the muri. The exine is uniformly pitted
(Plate 23: figure 2). The contact areas on the
proximal surface also have a reticulate sculpture
with appendages extending from the intersections
of the muri. The appendages are 4-6 [im long
near the equatorial flange and gradually increase
in length to form capilli 57-115 jtirrl long at the
border of the laesurae. The Y-mark extends to
the outer margin of the equatorial flange and is
bordered by labra 58-75 /tm high that are formed
by the fused, broadened bases of blunt-ended
appendages. The equatorial flange is formed in
the same way; however, the appendages are much
shorter, 23-40 pm high.

The second specimen (Plate 23: figures 3, 4) is
laterally flattened and is 325 jum in diameter. The
formation, size, and distribution of the append¬
ages is the same as on the other specimen. The

labra seem to be torn or perhaps fimbriate. The
spore is not so well preserved as the other.

These specimens, in their form and distribution
of sculptural elements, most resemble P. alatus
(Batten, 1969) Hall and Nicolson and P. fairligh-
tensis (Batten, 1969) Hall and Nicolson from
among the 12 species listed by Hall and Nicolson
(1973). P. alatus is larger in all dimensions than
the specimens at hand and has capilli over the
whole of the distal surface of the spore. The
broken or truncated bases of appendages on the
distal surface of the first of the two specimens
described herein suggest that there were capilli
present but that they were eroded prior to burial
or subsequent to maceration and processing. P.
fairlightensis is smaller than the spores at hand;
however, in sculptural detail they are very similar.
I tend to favor identification of the spores with P.
alatus but more specimens are required in order
to arrive at a convincing analysis and conclusion.

Occurrence. —The genus Paxillitriletes ranges
from Lower Jurassic, P. mensurus (Harris, 1935),
to Upper Cretaceous, e.g., P. dakotensis (Hall,
1963). A summary of all of the species is given by
Hall and Nicolson, 1973.

This report establishes a record of the genus at
USNM Locality No. 14252, Patuxent Formation,
Potomac Group; Lower Cretaceous (Barremian-
Aptian).

Specimens.— GG-3C, USNM 304345; GG-3D,
USNM 304346.

Dictyothylakos Horst, 1954
Dictyothylakos pesslerae Horst, 1954

Plate 24

Description (translated by the author from
Horst, 1954:610).—

The structures are uniformly orange colored. In oblique
light, dark-field of the ultropak they appear rosin-like and
strongly reflective. They are brittle and break easily.

The photographs [plate citation] clearly show the for¬
mation of the body from a net-like framework. The individ¬
ual meshes are in part three to five cornered, in part polygons
are formed through irregular development of the framework;

16

their inner edges are often rounded. From the thick, 15-35
H m, primary strands depart secondary strands, about 10 jUm
in diameter, which serve as reinforcement to the meshes.

All strands are nearly round in cross-section. They are
hollow, which has been proved during the course of the
research.

The fragment, only briefly mentioned by Michael (1936),
was found in the coal petrographic collection of the
Staatlichen Geologischen Kommission (glycerine-jelly prep¬
aration No. 6 from the Osterwald occurrence). The compar¬
ison demonstrated a conformity in both accounts. Similar
fossils, to my knowledge to this time, have not been de¬
scribed. A classification of the very well-characterized objects
into known fossil species is at present still not possible.

Diagnosis: Oblong hollow body, net-like, orange colored
framework, 4.5 mm maximum length and average 1.7 mm
width. Meshes of net in part three to five cornered, in part
polygonal. All strands are hollow inside. Cross-section round.
Diameter of the primary strands 15-35 jtim, the secondary
strands about 10 fim. Weight of a fully preserved specimen
0.192 mg.

Remarks.— Although only one specimen of this
enigmatic palynomorph was obtained from my
preparations, I felt that the significance of its
occurrence was adequate reason to include illus¬
trations and description of it. The dorsiventral,
discoid form of the specimen (Plate 24: figures 1,
2) causes me to hesitate in associating it taxonom-
ically with Thylakosporites retiarius. However, struc¬
turally the margin of the disc, with its looping
and anastomosing elements (Plate 24: figures 1,
2, 4, 5) does recall to a certain degree the sculp¬
tural detail of the outer exoexine of Thylakosporites.
The remainder of the specimen bears no similar¬
ity. The surface shown in Plate 24 (figure 1) is
interpreted as the outer surface because of the
more pronounced relief in the patterns surround¬
ing the pore-like openings (Plate 24: figure 3).
The surface comprises strands of structural ma¬
terial laid down in much the way coils of clay
would be used to form a decorative ceramic ob¬
ject. The inner surface (Plate 24: figure 2) has less
relief, the surfaces between the pores are relatively
flat. Particular attention is directed toward the
frayed aspect of the margin of the specimen. This
characteristic leads me to suggest that this speci¬
men is operculum-like and may have broken
away from its parent organ as a result of stresses

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

applied to the structurally weaker filaments along
the margin.

Descriptively, for what it is worth, and I give
little value to color in fossil materials, the speci¬
men at hand is orange and quite lustrous. In color
and lustre there is agreement with the description
of the type-specimen. The strands along the mar¬
gin of the specimen are clearly comparable, mor¬
phologically, to the strands forming the frame¬
work of the body of the type-specimen. However,
the remainder of the specimen illustrated herein
is thicker and of heavier construction overall due
to the layering of structural elements around the
pores or meshes. Also, all of the strands are solid
rather than hollow. This latter characteristic is,
unfortunately, not clearly illustrated in the orig¬
inal account of the type-species.

Horst (1954) made every effort to determine
the composition of the material through chemical
analysis, staining reactions, x-ray analysis, and
spectrochemical techniques. None gave a positive
indication of the composition. He remained con¬
vinced that Dictyothylakos was of plant origin and
stressed that it probably was the “framework of
an alga” and not the remains of a seed coat as
suggested by Michael (1936).

Hughes (1955) was strongly of the opinion that
some of Dictyothylakos illustrated by Horst was
identical in form to the perispore he was describ¬
ing as part of his new species, Triletes retiarius , now
Thylakosporites retiarius. The result was that he
placed part of Horst’s material, although he did
not state which part, in synonymy with T. retiar¬
ius. This action has not been accepted by most
palynologists.

I should like to present a conjectural analysis
of Dictyothylakos pesslerae that simply requires the
extension of insufficient evidence into a discus¬
sion. I shall not go so far as to prepare drawings
because they can pass through the veil of reality
and miraculously, in some later time, be repro¬
duced as facts.

Horst, in his figures 2 and 3, illustrates individ¬
ual, apparently hollow, oblong bodies, the walls
of which are coarsely reticulate. In his figure 2,
one end of the body is tapered to a somewhat

NUMBER 49

17

blunt point while the opposite end is truncated,
appearing as though broken. In figure 3, one end
of the body is broken away and very irregular in
outline. The body is split longitudinally for about
one-half of its length and would probably exhibit
a tapered form if reconstructed. Unfortunately,
the end opposite the very roughly broken one is
also incomplete. My reason for describing these
two bodies is to have a basis for the suggestion
that the specimen described in this report repre¬
sents a covering or closure (operculum) on the
broader end of a morphologically similar if not
identical body. A reconstruction would represent
the complete form as a lidded, cylindrical con¬
tainer reminiscent of a pyxis. The net-like struc¬
ture would be represented as strands of material
laid down on the inner surface of the container.
I shall, from here on, refer to the container as a
sporangium. Thin-walled cells forming the outer
layer of the sporangium were lost to decay. I shall
suggest further that, if Dictyothylakos were part of
a sporangium, the sporangium was a megaspor¬
angium.

In summary, Dictyothylakos , because of the sim¬
ilarity between its structural components and
those of the outer exoexine of Thylakosporites, may
represent a part of a megasporangium from which
a spore like Thylakosporites originated. This sug¬
gestion is not wholly original, as Hughes (1955:
214) did casually infer such an interpretation. I
reinforce the interpretation with the specimen
described and illustrated herein. I suggested ear¬
lier that Thylakosporites is probably the megaspore
of an ancient Selaginella. No present-day mega¬
sporangium of Selaginella even approaches the
conjectured appearance of Dictyothylakos.

Occurrences. —Bore W. Ill, 870 m, Wealden
coal (Lower Cretaceous), south Mecklenburg and
Osterwald, Germany; Horst, 1954.

Seven separate but undocumented localities in
the Wealden (Lower Cretaceous) of England;
Hughes, 1955.

This report, USNM Locality No. 14252, Pa¬
tuxent Formation, Potomac Group, Lower Cre¬
taceous (Barremian-Aptian).

Specimens. —II-4B, USNM 304347.

Conclusions

Evidence for correlating a part of the Potomac
Group with a part of the English Wealden section
is a significant contribution of this report. The
megaspores described herein, though significant,
would not be so effective in correlation were it
not for some added precision afforded by the
preliminary palynological analysis of the matrix
prepared by Dr. J. A. Doyle (pers. comm.). In
that analysis he found a large number of ferns,
Eucommidites , Vitreisporites ( =Caytonia), some sac¬
cate conifers, but very few Classopollis, bisaccate
pollen related to Decussosporites, a beautiful suite
of angiospermous monosulcates such as Retimono-
colpites peroreticulatus , Clavatipollemtes , Liliacidites
species B and others, familar to Zone I of the
Potomac Group. Although the listing is only a
preliminary one, Doyle has no doubt that the
Shirley Highway locality is in Zone I, as described
by Hickey and Doyle in 1977. The assemblage,
as he sees it, resembles most closely the 770-765'
level in Delaware Well D12, that is, the lower
part of Zone I, which would place the age in the
Barremian-Aptian level in the section. As a point
of reference I refer the reader to Hickey and
Doyle’s fig. 3, in which the subdivisions of the
Potomac Group and correlations of the fossil
localities are shown. The horizon with which the
material from the Shirley Highway excavation
closely correlates is at the lower right of their
figure.

Turning now to the early Cretaceous Wealden
of England, Hughes (1958:44) suggests certain
megaspore floras as representative of particular
stages within the Wealden section. The “ Verrutri-
letes Flora” represents Berriasian; the “ Thomsonia
Flora” (now, because of nomenclatural change,
“Paxillitriletes Flora”) is Valanginian; the “ Pyro -
bolospora Flora” (now, because of nomenclatural
change, “ Arcellites Flora”) is Barremian-Aptian.

A review of the species indicates the presence
of Verrutriletes carbunculus , which was first reported
from the Upper Cretaceous (Senonian) by Dijk-
stra (1949) and then again by him from the
Barremian-Aptian (1951). The Barremian-Ap-

18

tian occurrence was at 466’ in the Kingsclere Bore
Hole No. 1 in England that directly associates the
species with the “ Arcellites Flora” of Hughes. That
occurrence and association are also true for Echi-
triletes, to which I compare some specimens in this
report. Thylakosporites retiarius, Arcellites disciformis,
A. pyriformis, and Dictyothylakos pesslerae can all be
associated with the “ Arcellites Flora.” Thus most
of the megaspores and the palynomorph discussed
herein are typical to the Barremian-Aptian stages
in the Wealden section. The megaspores, in as¬
sociation with the preliminary analysis of the
microspore and pollen flora by Doyle, suggest
correlation between lowermost Zone I (Patuxent
Formation) of the Potomac Group and the Bar¬
remian-Aptian horizons of the English Wealden.

Of the species recorded herein that are not
directly associated with the “Arcellites Flora,”
Crybelospontes striatus may be added by reason of
its relationship as the microspore belonging with
Arcellites disciformis. Also Paxillitriletes can be antic¬
ipated as a member of the “Flora” because its
range is from Lower Jurassic to Upper Cretaceous
and certainly one or more of the 12 species will
be shown to be of Barremian-Aptian age. On the
other hand, Erlansonisporites erlansonii to this time
is known only from the Upper Cretaceous (PCam-
panian) on Disko Island, Greenland, and this
report extends its range considerably downward
in the section. I am concerned about my identi¬
fications of Echitriletes cf. E. lanatus, Arcellites cf. A.
pyriformis , and Paxillitriletes species because I have
had too few specimens and have relied on SEM
studies alone for the analyses.

Among the megafossil remains from this local¬
ity Pityostrobus hueberi Robison and Miller and P.
virgimana Robison and Miller (1977), assigned to

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

the Pinaceae, represent the first species of this
genus to be reported from the North American
Atlantic Coastal Plain. The age in Robison and
Miller was given as Albian, which, at the time,
was based on correlations projected from outcrops
of known age. The pollen and spore analysis,
although preliminary, indicates that the site is
within the Barremian-Aptian Patuxent Forma¬
tion of the Potomac Group.

A cupule or fruit belonging to Caytoma, com¬
parable morphologically to C. nathorsti (Thomas)
Harris (1964), was found during the sorting of
the plant remains for megaspores. Seeds compa¬
rable to those found in the cupule were also
isolated from the debris.

The megafossil flora is rich in fern, cycadopsid,
and conifer remains and accordingly deserves
further attention. The collection of the matrix is
available in the paleobotanical collections of the
National Museum of Natural History, Smithson¬
ian Institution, as a study resource for qualified
researchers.

Interpretation of the lithofacies of the site,
along with the general composition of the mega¬
fossil flora, suggests a backswamp deposit as dis¬
cussed by Hickey and Doyle (1977). It is unfor¬
tunate that there was very little time to collect
from the deposit before it was destroyed. The
megafossil flora can only be hinted at on the basis
of the collection at hand. Potentially some of the
sporophytes may have been found that were the
sources of the sporomorphs described herein. It
would have been particularly exciting if sporo¬
phytes of Selaginella, similar to the modern species
S. galeottii and S. myosurus, were found and shown
to be the sources of Erlansonisporites erlansonii and
Thylakosporites retiarius.

Literature Cited

Batten, D. J.

1969. Some British Wealden Megaspores and Their Fa¬
cies Distribution. Palaeontology, 12(2):333-350, 7
plates.

Bennie, J. and R. Kidston

1886. On the Occurrence of Spores in the Carboniferous
Formation of Scotland. Proceedings of the Royal Phys¬
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Cookson, I. C., and M. E. Dettmann

1958. Some Trilete Spores from Upper Mesozoic Depos¬
its in the Eastern Australian Region. Proceedings of
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6 plates.

Dettmann, M.E.

1963. Upper Mesozoic Microfloras from Southeastern
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Dijkstra, S. J.

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Aachenian (Senonian) in South Limburg, Neth¬
erlands. Geologische Stichting Mededelingen, new se¬
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1951. Wealden Megaspores and Their Stratigraphic
Value. Geologische Stichting Mededelingen, new series,
5:7-22, 1 table, 2 plates.

Ellis, C. H., and R. H. Tschudy

1964. The Cretaceous Megaspore Genus Arcellites Miner.
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Erdtman, G.

1947. Suggestions for Classification of Fossil and Recent
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Hall, J. W.

1963. Megaspores and Other Fossils in the Dakota For¬
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Hall, J. W., and D. H. Nicolson

1973. Paxillitriletes, a New Name for Fossil Megaspores
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Harris, T. M.

1935. The Fossil Flora of Scoresby Sound, East Green-
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1964. The Yorkshire Jurassic Flora, IP. Caytoniales , Cycadales
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Hickey, L. J., and J. A. Doyle

1977. Early Cretaceous Fossil Evidence for Angiosperm
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Horst, U.

1954. Merkwiirdige Gebilde in Kohlen aus dem Weal¬
den. Geologie, 3:610-612, 3 plates.

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1955. Wealden Plant Microfossils. Geological Magazine,
92(3):201-217, 2 figures, 3 plates.

1958. Paleontological Evidence for the Age of the Eng¬
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Jansonius, J., and L. V. Hills

1976. Thylakosporites Potonie, 1956. In Genera File of Fossil
Spores. Special publication. Alberta, Canada: De¬
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Luber, A. A.

1935. Les types petrographiques de charbons fossile du
Spitzbergen. Chemie Combustible Solide, 5:186-195.
[Publication not seen.]

Madler, K.

1954. Azolla aus dem Quartar und Tertiar sowie ihre
Bedeutung fur die Taxonomie alterer Sporen. Geo¬
logische Jahrbuch, 70:143-158, 1 figure, 1 plate.

Martens, P.

1960a. Sur une structure microscopique orientee dans la
parois megasporale d’une Selaginelle. Compte Rendu
de I’Academie des Sciences de Paris, 250:1599-1602, 2
plates.

1960b. Nouvelles observations sur la structure des parois
megasporales de Selaginella myosurus (Swartz) Al¬
ston. Compte Rendu de I’Academie des Sciences de Paris,
250:1774-1775.

Michael, F.

1936. Palaobotanische Studien in der Nordwest-
deutschen Wealden Formation. Abhandlungen der
Preussischen Geologischen Landesanstalt, new series,
166:3-79, 4 plates.

Miner, E. L.

1932. Megaspores Ascribed to Selaginellites from the Up¬
per Cretaceous Coals of Western Greenland. Jour¬
nal of the Washington Academy of Sciences, 22(18-19):
497-506, 31 figures.

19

20

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

1935. Paleobotanical Examinations of Cretaceous and
Tertiary Coals. American Midland Naturalist, 16(4):
585-625, 6 figures 7 plates.

Potonie, H.

1893. Die Flora des Rotliegenden von Thuringen. Ab-
handlungen Koniglichen Preussischen Geologischen Lan-
desanstalt, new series, 9(2): 185.

Potonie, R.

1956. Synopsis der Gattung der Sporae dispersae, I:
Sporites. Beihefte zum Geologischen Jahrbuch, 23:1-
103, 11 plates.

Potonie, R., and G. Kremp

1954. Die Gattung der palaeozoischen Sporae dispersae
und ihre Stratigraphie. Geologische Jahrbuch, 69:
111-194, 5 diagrams, 17 plates.

Potter, D. R.

1963. An Emendation of the Sporomorph Arcellites
Miner, 1935. Oklahoma Geology Notes, 23(9):227-
230, 1 plate.

Reinsch, P. F.

1881. Neue Untersuchungen uber die Mikrostruktur der Stein-
kohle des Carbon der Dyas und Trias. 124 pages, 94
plates. Leipzig: T. O. Weigel.

Robison, C. R., and C. N. Miller, Jr.

1977. Anatomically Preserved Seed Cones of the Pina-
ceae from the Early Cretaceous of Virginia. Amer¬
ican Journal of Botany , 64(6):770-779, 16 figures.

Sanders, J. V., and P. J. Darragh

1971. The Microstructure of Precious Opal. Mineralogical
Record, 2 (6): 261-268, 13 figures.

Schemel, M. P.

1950. Cretaceous Plant Microfossils from Iowa. American
Journal of Botany, 3 7 (9): 750-754, 19 figures.

Stainier, F.

1965. Structure et infrastructure des parois sporales chez
deux Selaginelles. La Cellule, 65:219-244, 5 plates.

1967. Morphological Study of the Walls of Mega- and
Micro-Spores of Selaginella myosurus (Sw.) Alston.
Review of Palaeobotany and Palynology, 3:47-50, 1
plate.

Taylor, J., G. LeVee, P. Hollingsworth, and W. Bigelow

1976. Sporopollenin and Major Mineral Constituents of
the Spore, Elators, and Capsule Wall of Conoce-
phalum conicum. Michigan Botanist , 15:167-172, 7
figures.

Tryon, A. F., and B. Lugardon

1978. Wall Structure and Mineral Content in Selaginella
Spores. Pollen et Spores, 22(3):315-340, 10 plates.

Tschudy, R. H.

1976. Stratigraphic Distribution of Species of the Me¬
gaspore Genus Minensporites in North America.
United States Geological Survey Professional Paper,
743E.-E1-E11, 4 plates, 1 figure, 3 tables.

PLATES

22

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 1

Figures 1-6. — Verrutnletes carbunculus (Dijkstra) Potonie: 1, Proximal view, X 100; 2, equatorial
view, X 100; 3, area x in figure 1, X 500; 4, area y in figure 1, X 1000; 5, surface of exine
between gemmae on ornamented portion of spore, X 1000. (Specimen GG-7A, USNM
304311.) "

6, Fragment, source of subsequent views of structure of wall and ornamentations, X 75
(Specimen GG-7C, USNM 304313).

24

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 2

Figures 1-7.— Verrutriletes carbunculus (Dijkstra) Potonie: 1, Vertical section of spore coat with
gemma in place, X 2000; 2, outer exoexine surface with gemma and former site of gemma
attachment (arrow), X 1000; 3, oblique view of inner surface of spore coat showing depression
immediately beneath gemma, X 1000. (Specimen GG-7C, USNM 304313.)

4, Proximal view, X 85; 5, distal view X 85; 6, view at x in figure 4 at 45° tilt, X 500; 7, view
of sculpture at y in figure 5, X 350. (Specimen GG-7B, USNM 304312.)

NUMBER 49

25

26

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 3

Figures 1-4.— Verrutriletes carbunculus (Dijkstra) Potonie: 1, View of broken margin of one of
laesurae and of morphology of gemma, X 200; 2, vertical section of sporoderm (end =
endexine, i-ex = inner exoexine, g = gemmae), X 1000; 3, fused gemmae with rupture
revealing inner structure, X 3500; 4, corroded gemma showing interior structure, X 3000.
(Specimen GG-7B, USNM 304312.)

NUMBER 49

27

28

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 4

Figures 1-4 .—Echitriletes cf. E. lanatus (Dijkstra) Potonie: 1, Assumed proximal view, X 75; 2,
assumed distal view, X 75; 3, view at x in figure 1 showing density and morphology of capilli,
X 150; 4, view at y in figure 1 showing bases of capilli and surface of outer exoexine, X 1000.
(Specimen HH-1A, USNM 304314.)

Figures 5, 6 .—Crybelosporites species: 5, Microspores lodged among capilli at z in figure 2 (note
folds of outer layer of sculpture (perine) on lower-most spore), X 1000; 6, single microspore
showing granulate surface of inner layer of “sculptine” impressed on outer layer of sculptine
(perine), X 3000. (On specimen HH-1A, USNM 304314.)

1

iJL * I

i

30

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 5

Figures 1-4 .—Echitnletes cf. E. lanatus (Dijkstra) Potonie: 1, Assumed proximal view, X 75: 2,
outer exoexine surface at x in figure 1, X 1000; 3, assumed distal view, X 75; 4, divided tips
of capilli at y in figure 3, X 150. (Specimen HH-1B, USNM 304315.)

Figures 5, 6 .—Crybelosponles species: Microspores lodged among capilli at z in figure 3, X 1000;
6, distal view of microspore collapsed, and with Y-mark evident as depression; outer layer of
sculptine (perine) suggested by folds on left and lower right margins of spore, X 3000. (On
specimen HH-1B, USNM 304315.)

32

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 6

Figure 1-6 .—Erlansonispontes erlansonii (Miner) Potonie: 1, Proximal view, X 115; 2, equatorial
view (clockwise rotation), X 115; 3, distal view, X 115; 4, low murus and texture of outer
exoexine at x in figure 1, X 2300; 5, diaphanous muri extending between bastions, apices of
bastions rounded, view at y in figure 1, X 550; 6, reticulate surfaces of muri, X 1500.
(Specimen GG-10B, USNM 304316.)

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34

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 7

Figures 1-6. — Thylakospontes retiarius (Hughes) Potonie: 1, Apical view of tetrahedral tetrad,
X 40; 2, basal view of tetrahedral tetrad of spores, X 40; 5, area at x in figure 2 showing
reticulum of outer exoexine partially free of layer of organic material that coats whole
tetrahedral tetrad, X 125. (Specimen GG-8A, USNM 304320.)

3, Probable equatorial view, broken area in lower left representing margin of contact point
in tetrahedral tetrad, X 70; 4, reverse side of specimen, X 70; 6, view of morphology of
reticulum at y in figure 3, X 200. (Specimen HH-2B, USNM 304324.)

NUMBER 49

lOOyUm

lOOjum

36

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 8

Figures 1-8.— Thylakosporites retiarius (Hughes) Potonie: 1, Surface of outer exoexine between
elements of reticulum, X 5000 (specimen HH-2B, USNM 304324).

2, Distal view, X 100; 3, proximal view with area of commissure broken away, X 100; 4,
view at x in figure 3 with specimen tilted toward viewer at about 30° showing points of
attachment of elements of reticulum, both intact and broken, X 325; 5, transverse section of
spore coat (o-ex = outer exoexine, i-ex = inner exoexine, end = endexine), X 2500; 6, finely
reticulate sculpture of the outer exoexine, X 10,000; 7, orderly arrangement of spherular
elements forming inner exoexine, X 10,000; 8, reticulate structure of endexine as seen in
surface view, X 10,000. (Specimen GG-10C, USNM 304322.)

200um

200um

—1 V

38

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 9

Figures 1-6.— Thyiakospontes retiarius (Hughes) Potonie: 1, Proximal view of crushed and eroded
specimen, Y-mark exaggerated due to folding, X 150; 2, transverse section of spore coat at x
in figure 1, (o-ex = outer exoexine) eroded except at points of attachment of reticulum (i-ex
= inner exoexine, end = endexine) loosened and folded, X 600; 3, near-equatorial view
showing remnants of points of attachment of reticulum (Plate 8, figure 4), X 140; 4, orderly
arrangement of spherular elements forming inner exoexine and in turn giving rise to opal¬
like quality of spore coat as seen in reflected light, view at y in figure 2, X 5000; 5, remnants
of surface of outer exoexine particularly at arrow, X 5000; 6, additional view of spherular
elements seen at y in figure 2, X 10,000. (Specimen BB-12A, USNM 304319.)

mama

100pm

40

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 10

Figures 1-6. — Thylakospontes retianus (Hughes) Potonie: 1, Slightly oblique proximal view
showing erosion and corrosion of spore coat, X 150; 2, oblique distal view showing areas of
corrosion and separation of spore coat elements, X 150; 3, area x in figure 2 (end = endexine,
i-ex = inner exoexine, o-ex = outer exoexine), X 500. (Specimen GG-10A, USNM 304321.)

4, Fragment of distal portion of spore with reticulum intact, X 130; 6, transverse section of
strand of reticulum viewed at y in figure 4, X 3000. (Specimen GG-10D, USNM 304323.)

5, Reticulate surface structure of one reticulum strand, X 4500. (Specimen GG-10C, USNM
304322.)

10 U/j m

42

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 11

Figures 1-4. — Crybelosporiles striatus (Cookson and Dettmann) Dettmann: 1, Microspores resting
in folds of acrolamellae of megaspore, X 170; 2, folding of outer exoexine (perine) of spores,
X 750; 4, single spore at x in Figure 2 showing reticulate surface of inner exoexine and outer
cavate exoexine, X 2000. (Specimen of Arcellites disciformis (Miner) Ellis and Tschudy, GG-
6A, USNM 304329 with seven adherent microspores.)

3, Additional examples of this microspore on second specimen of Arcellites disciformis , X 1250.
(Specimen of Arcellites disciformis (Miner) Ellis and Tschudy, BB-11C, USNM 304328, with
adherent microspores.)

44

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 12

Figure 1-4 .—Arcellites disciformis (Miner) Ellis and Tschudy: 1, Equatorial view showing tube¬
like appendages ornamenting body of spore and plicate, crenulate-margined acrolamellae
forming neck and chamber above Y-mark, X 170; 2, proximal view showing torsion of
acrolamellae forming neck, X 240. (Specimen BB-11B, USNM 304331.)

3, Equatorial view of extremely well-preserved specimen except for flattening of tube-like
appendages, X 170; 4, proximal view shows greater expansion of acrolamellae forming neck,
X 240. (Specimen BB-11A, USNM 304330.)

NUMBER 49

45

46

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 13

Figures 1-4 .—Arcellites disciformis (Miner) Ellis and Tschudy: 1, Equatorial view of specimen
mounted by apices of acrolamellae, tubular nature of body appendages clearly demonstrated,
X 170; 2, distal view showing distribution of body appendages and punctate texture of outer
exoexine, X 170. (Specimen GG-5C, USNM 304338.)

3, Equatorial view showing narrow, elongate neck, X 170; 4, proximal view showing
separation of crenulate margins of some of acrolamellae, X 280. (Specimen GG-5A, USNM
304337.)

7

48

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 14

Figures 1-4 .—Arcellites disciformis (Miner) Ellis and Tschudy: 1, Crushed specimen showing
separation of individual acrolamellae, X 170; 2, enlarged view to show detail of morphology
of margins of acrolamellae, X 350. (Specimen GG-4B, USNM 304335.)

3, Equatorial view of obliquely crushed specimen showing microspores (Crybelospontes stnatus)
lodged in plications of acrolamellae, X 170; 4, proximal view showing pronounced torsion of
acrolamellae, X 280. (Specimen BB-11C, USNM 304328.)

lOQ/Um

50

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 15

Figure 1-4 .—Arcellites disciformis (Miner) Ellis and Tschudy: 1, Proximal view showing chamber
or neck cavity formed by acrolamellae, apices of acrolamellae were removed by dissection,
X 340; 2, separation of acrolamellae and demonstration of single-layered construction of
individual acrolamellae, X 1700. (Specimen II-2, USNM 304340.)

3, Marginal contact of two acrolamellae showing intertanglement of fimbrate margins and
pores and interstices between crenae, X 2000 (specimen GG-5A, USNM 304337).

4, Base of acrolamellae at point of origin from body of spore, X 1325 (specimen BB-11A,
USNM 304330).

NUMBER 49

51

52

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 16

Figures 1-4 .—Arcellites disciformis (Miner) Ellis and Tschudy: 1, Pitted structure of outer
exoexine of spore body and continuation of structure into tubular appendage, X 1000; 2,
pitted surface structure of outer exoexine X 5500. (Specimen BB-11A, USNM 304330.)

3, Irregularity in size of pits possibly due to corrosion as shown by thinned areas that transmit
electron beam through specimen, X 4000 (specimen GG-5A, USNM 304337).

4, Pitted surface structure of outer exoexine clearly visible as well as undeveloped body
appendages represented by rounded protuberances from body surface, X 1600 (specimen
BB-11F, USNM 304332).

NUMBER 49

53

54

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 17

Figures 1-4 .—Arcellites disciformis (Miner) Ellis and Tschudy: 1, Spore body sectioned trans¬
versely to demonstrate spore coat structure, X 240; 2, view at x in figure 1 (o-ex = outer
exoexine, i-ex = outer exoexine, end = endexine), X 4000. (Specimen GG-4A, USNM
304334.)

3, Vertical section through base of body appendage and onward through spore wall (note
outer exoexine and inner exoexine rising into base of appendage, endexine layer seen at
lowest level of section), X 3000 (specimen GG-4C, USNM 304336).

4, Transverse section of base of body appendage showing outer exoexine and limit of
extension of inner exoexine into appendage, X 3500 (specimen GG-5C, USNM 304338).

NUMBER 49

55

56

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 18

Figures 1-5 .—Arcellites disciformis (Miner) Ellis and Tschudy: 1, Body appendages, intact and
with broken apex, X 750; 2, appendage with ruptured apex, suggesting partially collapsed
bulbous tip, X 1500; 5, view downward into interior of body appendage showing reticulate
structure of inner exoexine at bottom and characteristic structure of outer exoexine, X 3200.
(Specimen GG-5C, USNM 304338.)

3, Longitudinal section through body appendage showing outer exoexine forming wall of
appendage and inner exoexine extending only slightly into base, endexine clearly discernible,
forming inner layer of spore coat, X 1000 (specimen GG-6A, USNM 304329).

4, Inwardly contracted apex of body appendage with structure similar to fimbrate margins
of acrolamellae, X 7000 (specimen GG-5A, USNM 304337).

NUMBER 49

57

58

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 19

Figures 1-4 .—Arcellites disciformts (Miner) Ellis and Tschudy: 1, Equatorial view of specimen
showing level of section required to reveal position of Y-mark, X 170; 2, view into spore body
cavity with Y-mark in position that corresponds to area directly beneath the cavity formed
by acrolamellae, X 350. (Specimen GG-3A, USNM 304333.)

3, Equatorial view of specimen badly broken during attempt to prepare transverse sections,
chamber formed by acrolamellae imperfectly demonstrated but can be interpreted in this
view, X 230; 4, view into spore body cavity showing Y-mark and layering of spore coat, X
480. (Specimen GG-6B, USNM 304339.)

60

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 20

Figures 1-7 .—Arcellites cf. A. pyriformis (Dijkstra) Potter: 1, Near equatorial view, folds of neck¬
like projection broken away at lower left, X 90; 2, view at x in figure 1 showing texture of
outer exoexine surface and variation in morphology of the body appendages, X 180; 3,
broken side of spore from which some details of spore coat structure were obtained, X 90: 4,
detail at y in figure 3, the o-ex (outer exoexine) quite thick and forming body appendages
seen in section; a thinner, i-ex (inner exoexine) appearing more loosely structured and end
(endexine) seen as extremely thin layer, X 1000; 5, detail at z in figure 3, X 500; 6, detail at
arrow in figure showing sculpture of exoexine and separation between outer exoexine and
inner exoexine (note textural differences), X 5000; 7, detail of outer exoexine surface texture
in figure 5, X 8,500. (Specimen BB-12, USNM 304342.)

NUMBER 49

61

62

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 21

Figures 1-9 .—Arcellites cf. A. pyriformis (Dijkstra) Potter: 1, Equatorial view, X 85; 2, equatorial
view, specimen rotated 90° counter-clockwise, X 85; 3, equatorial view, 180° rotation from
position in figure 1, X 85; 4, proximal view, X 85; 5, area at x in figure 1 after rotation of
specimen few degrees toward viewer, X 300. (Specimen HH-2A, USNM 304343.)

6, Fragment of spore in near-equatorial view, X 85; 7, section of spore coat (o-ex = outer
exoexine, i-ex = inner exoexine), X 4000; 8, structure of inner-most surface of endexine, X
2000; 9, surface texture of outer exoexine, X 950. (Specimen HH-2C, USNM 304344.)

NUMBER 49

200nm

64

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 22

Figures 1-4 .—Paxillitriletes species Hall and Nicolson: 1, Proximal view, X 260; 2, equatorial
view, 90° rotation, counter-clockwise, on equatorial axis, X 260; 3, distal view, X 260; 4,
equatorial view, 90° rotation, counterclockwise on equatorial axis, X 260. (Specimen GG-3D,
USNM 304346.)

50um

66

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 23

Figures 1-4. — Paxillitriletes species Hall and Nicolson: 1, View at x in Plate 22 (figure 4)
showing long capillae along margins of laesurae, shorter capillae arising at connecting points
of muri, part of equatorial flange (lower right) and fused bases of appendages immediately
bordering laesurae, X 600; 2, detail at x in figure 1 showing reticulate sculpture of surface of
outer exoexine, X 2200. (Specimen GG-3D, USNM 304346.)

3, Equatorial view, X 175; 4, proximal view, X 175. (Specimen GG-3C, USNM 304345.)

68

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

PLATE 24

Figures 1-5. —Dictyothylakos pesslerae Horst: 1, View interpreted as upper or outer surface of
specimen (note “frayed” margin), X 90; 2, slightly oblique view interpreted as lower or inner
surface, X 90; 3, detail of surface at x in figure 1, X 375; 4, margin of specimen at y in figure
1, showing broken elements and structural detail, X 200; 5, view at z in figure 2 showing
broken structural elements rounded in cross-section and apparently not hollow, X 350.
(Specimen II-4B, USNM 304347.)

NUMBER 49

69

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