UNIVLRSITV C1

ILLINOIS l ^RARY

AT URBANA-CHAMPAIGN

L 10LOGY

CO

1 1/ * <-»

I

'fieldiana

Geology

Published by Field Museum of Natural History

JJU^^^^u

Volume 39, No. 2 May 26, 1978

Morphology and Arrangement of Meromes

in
Ischadites dixonensis, an Ordovician Receptaculitid

Daniel C. Fisher

Assistant Professor, Department of Geological Sciences

and Center For Evolution and Paleobiology

University of Rochester, Rochester, New York

and

Research Associate, Field Museum of Natural History

and

Matthew H. Nitecki

Curator, Fossil Invertebrates
Field Museum of Natural History

ABSTRACT

Ischadites dixonensis (Miller and Gurley, 1896), from the Ordovician Galena
Group of Illinois, is the oldest described North American ischaditid. The holotype is
exceptionally well preserved and provides information on merome head morphology,
articulation, and arrangement on the surface of the thallus. Meromes occur in whorls
and form an equal number of dextral and sinistral parastichies. Each parastichy
begins either at one of the heads surrounding the basal pole or at a triangulum, and
extends to the margin of a clearly demarcated apical lacuna. The unusually complete
morphological characterization that is now available for /. dixonensis will play an
important role in discussions of receptaculitid morphogenesis and orientation.

INTRODUCTION

It has become increasingly clear, through the work of Rietschel
(1969), Campbell et al. (1974), and Gould and Katz (1975), that an
accurate description of the shape and arrangement of the elements
making up the surface of the thallus of receptaculitids is a prerequi-
site for any definitive analysis of their morphogenesis and taxonom-

Library of Congress Catalog Card No.: 78-50557 6 L,5rarv of the

ISSN 0096-2651 « , , n n

AUG 25 1978

Publication 1283 17 o

Kfliflfit UMAEI

18 FIELDIANA: GEOLOGY, VOLUME 39

ic affinities. These aspects of morphology have been particularly
difficult to observe due to preservational problems and incomplete
calcification of original structures. Ischadites dixonensis offers an
unusual opportunity to provide this information because calcified
meromes were present over nearly the entire surface of the thallus,
and because the holotype (and only available specimen) is unusually
well preserved (fig. 1). Since its original description and illustration
do not adequately represent its detailed morphology, we believe the
present redescription is necessary. Our treatment of /. dixonensis
differs from that of Miller and Gurley in: 1) concentrating on the
morphology and arrangement of merome heads; 2) providing new
information on internal structure; 3) reversing the life orientation of
the thallus; and 4) interpreting receptaculitids as algae rather than
sponges.

/. dixonensis is the oldest North American species thus far de-
scribed that can be unequivocally assigned to the genus Ischadites.
Initial study of "Ischadites" iowensis, a common receptaculitid
from the Galena Group in the tri-state area of Illinois, Iowa, and
Wisconsin, indicates that it should not be considered a member of
this genus. /. dixonensis, on the other hand, is a "good" ischaditid,
and in many respects is similar to the genotype, /. koenigii, from the
Silurian of North America and Europe.

MATERIAL

The specimen described here was collected in Middle Ordovician,
dolomitized, crinoidal biosparites of the basal Galena Group, near
Dixon, Illinois, U.S.A. It is preserved as a dolomitized mold of the
calcified portions of the thallus. It consists of an incomplete (either
partially lost or never entirely collected), "external," concave por-
tion bearing an impression of the abaxial surfaces of merome plates,
and an "internal," convex portion formed of material deposited be-
tween the meromes (preserving an impression of the merome shafts
and of the adaxial surfaces of merome heads) and within the central
axis.

Opposite:

Fig. 1. Ischadites dixonensis (Miller and Gurley, 1896), FMNH UC 6053, Gurley
Collection, University of Chicago Collection, housed in Field Museum of Natural
History. A, apical view; B, lateral view; height of thallus: 4.3 cm.; maximum
diameter of thallus: 3.1 cm.; C, basal view.

19

20 FIELDIANA: GEOLOGY, VOLUME 39

MORPHOLOGY

Our use of terminology assumes that receptaculitids were algae.
We will not, at present, argue this assignment; rather, we will rely
upon present consensus on this point (Byrnes, 1968; Nitecki, 1969,
1970, 1972; Rietschel, 1969; and Campbell et al., 1974). Likewise, we
will defer discussion of the orientation and morphogenetic interpre-
tation of the thallus. It suffices for now to state that our orientation
coincides with that made by Nitecki (1969, in part), Rietschel (1969),
and in the main body of the text of Gould and Katz (1975). It is op-
posite, however, to that made in the "note added in proof" of Gould
and Katz and by Byrnes (1968) and Nitecki (1969, in part; 1971;
1972).

Thallus shape: The thallus of /. dixonensis is ovoid, with its great-
est transverse diameter located closer to the summit than to the
base (figs. IB, 2 insert). Its surface is more regular than that of other
members of this genus, and could almost be described as that of a
solid of revolution (generated by the revolution of an oval about its
major axis). It nevertheless shows subtle indication, especially near
the summit of the thallus, of the helical surface topography which is
so typical of /. koenigii. The sense of this helix is dextral if it is
followed in lateral view upward from the oldest to the youngest por-
tions of the plant. Since the shape of the central axis is poorly
known, it is not clear whether this is simply a surficial reflection of a
topographically similar central axis, or whether it is superimposed
on a regular axis through systematic variation in the length or ori-
entation of meromes. Associated with this twist is a displacement of
the apical and basal poles relative to each other and to the longitudi-
nal topographic axis of the thallus. If the apical and basal poles are
defined as passing through the center of merome plate whorls that
are very near their respective ends of the thallus, and as perpendicu-
lar to planes described by those whorls, then each pole is inclined at
about 20° to the longitudinal topographic axis.

The basal portion of the thallus (fig. 1C) is not as well preserved as
the rest of the surface, but it seems that it was almost completely
covered by merome plates. The preserved impressions of plates indi-
cate that if a pedicle-like structure existed here, it must have had a
diameter less than 2 mm. In all probability, a pedicle with holdfast
was present at least in very young individuals. During growth of the
thallus, this pedicle either remained small and was closely sur-

FISHER & NITECKI: MEROMES IN ISCHADITES 21

rounded by the developing heads of the first (oldest) meromes, or
else was eventually completely occluded by the growth of these
heads. The former alternative certainly involves the more conven-
tional conception of algal anatomy, and has an analog in the extant
dasyclad Bornetella sphaerica. However, the latter alternative is
descriptive of the condition of well-preserved /. barrandei (generally
similar to /. dixonensis), in which neither a pedicle nor any opening
for it is observed. In any case, there is no evidence for the presence
of an opening such as Miller and Gurley (1896) described and identi-
fied as an osculum. The only hole in this part of the thallus has an
irregular outline (fig. 1C), is not centered on the basal pole, and is
evidently the result of fracturing either during the weathering out
of the specimen or during collection.

The other end of the thallus is more completely preserved and
presents fewer problems of interpretation. Articulated, calcified
meromes extend to within 2.1 mm. of the apical pole. Adapically of
this well-defined circle, composed of a single whorl of meromes,
there are no impressions preserved. In this region the matrix form-
ing the "internal" mold is continuous with that of the "external"
mold, producing a narrow isthmus (diameter: 4.2 mm.) that was
broken when the molds were separated. We interpret these observa-
tions as indicative of an apical lacuna in the original calcified cortex
of the thallus. The existence of such an "opening" has been both
postulated (e.g., Gould and Katz, 1975) and denied (e.g., Rietschel,
1969), but preservation of other taxa has not been adequate to settle
the point.

In our present interpretation, the margin of the apical lacuna is
formed by the most recently calcified meromes that were sufficient-
ly well articulated with their neighbors to remain in place after the
death of the alga and during the infilling of its "skeleton." Adapi-
cally from this margin, on the living plant, we would expect mer-
omes that were either incompletely articulated, incompletely calci-
fied, or both. These meromes probably surrounded an apical tuft of
photosynthetic filaments protruding beyond the general surface of
the thallus. A distinctive feature of /. dixonensis is that the zone on
the thallus surface represented by well-calcified and articulated
meromes comprises such a large portion of its total surface, or, in
other words, that the apical lacuna is relatively small. As a contrast,
/. barrandei is frequently preserved as a rather shallow "hemi-
sphere," representing only the basal portion of the thallus. This con-

22 FIELDIANA: GEOLOGY, VOLUME 39

dition of preservation probably indicates a more limited surficial
extent of well-calcified and articulated meromes. In this respect, /.
koenigii is intermediate between these two species, although it is
closer to /. dixonensis.

Central axis: An irregular fracture obliquely truncates the basal
portion of the "internal" mold of the thallus. Removal of this basal
fragment reveals a cross-section of the thallus from about the sev-
enth to the seventeenth merome whorl. A maximum value for the
width of the central axis at this level can be estimated from the
inward extent of the molds of merome shafts outcropping on the
surface of the fracture. The axis is certainly not wider than 6 mm.
(one-fourth the total width of the thallus at this level) and is prob-
ably not wider than 5 mm. The uncertainty of this estimate is due
primarily to the fact that the central portion of the "internal" mold
is more open-textured than the periphery. Therefore, the molds of
merome shafts simply become indistinguishable proximally, with-
out clearly exposing their contact with the central axis. The merome
shafts exposed by the fracture described above are straight and
extend perpendicularly to the surface of the thallus. They are cylin-
drical and relatively thin throughout their observable length, show-
ing no evidence of either distal or proximal expansions. At the distal
end of the merome shaft, just where it joins its plate, its adapical
surface is marked by a small pit (which may be drawn out as a
trough on the adaxial surface of the plate) for the reception of the tip
of the abapical rib (fig. 3) of the stellate structure of another merome
(see below). It is important to note that this relationship is distinct
from what Rietschel (1969) describes as a pit and rib insertion in-
volving the abapical surface of the merome shaft and an adapical
rib.

Merome heads: The merome heads of I. dixonensis are extremely
similar to those of the Silurian /. tenuis (Nitecki and Dapples, 1975).
They consist of a thin, marginally tapering plate whose abaxial sur-
face is somewhat convex, closely associated with a four-ribbed stel-
late structure (fig. 3). The two latitudinal ribs have their bases at the
distal end of the merome shaft and are in contact with the adaxial
surface of the plate until shortly before reaching the plate margin.
They are oriented 80-85° from the merome shaft and extend beyond
the margins of the plate by approximately one-third of their length.
The abapical meridional rib is similar to the latitudinal ribs in all
respects, except that it is more nearly perpendicular to the merome

FISHER & NITECKI: MEROMES IN ISCHADITES 23

shaft and extends beyond the margin of its plate for nearly one-half
its length. The adapical meridional rib is also nearly perpendicular
to the merome shaft, and its base is located proximally on the shaft
about one rib diameter from its mates. Its length relative to the
plate margin (determined where the "internal" mold appears incom-
plete or abraded) is similar to that of the latitudinal ribs.

The most common type of merome plate is rhombic in outline (fig.
2), with the vertices pointing latitudinally and longitudinally. The
largest rhombic plates (width: 4.4 mm.) occur at about the level of
the fourteenth whorl, well below the topographic equator. Size of
plates decreases toward both poles, with the smallest plates located
nearest the apical pole. Accompanying this size gradient is a gradi-
ent in the shape of the rhombic plates. Near the apical pole they are
relatively narrow longitudinally, while nearer the equator they
become broader and then maintain a relatively constant shape. The
surface of the "external" mold is too coarse to discern whether any
growth lines were present on the plates.

The two other types of merome plates, interposita and triangula (a
term introduced here for the plate situated directly adapically of an
interpositum), are of the usual ischaditid form (Rietschel, 1969;
Gould and Katz, 1975). The interposita are broader longitudinally
than the rhombic plates of their own whorl, while the triangula are
usually narrower than their rhombic neighbors.

Articulation of merome heads: In order to discuss the articulation
of adjacent merome heads, it is useful to extend the analogy be-
tween the thallus and a terrestrial globe, by use of the cardinal direc-
tions. If we consider an array of rhombic plates only, the plates of
one whorl can be conceived of as a series of eastern or western neigh-
bors. Near the apical pole these neighbors touch each other only at
their eastern and western vertices. However, in the equatorial and
basal regions of the thallus, the plates are positioned slightly en
eschelon, so that a given plate contacts its western neighbor only on
a very short stretch of its northwestern edge, and its eastern neigh-
bor on a very short stretch of its southeastern edge. There is no
evidence of imbrication of plates within a whorl. Each plate also has
neighbors to the southwest, southeast (members of the whorl
formed immediately before), northwest, and northeast (members of
the whorl formed immediately after), with each of which it shares
large stretches of its respective edges (fig. 2). These plates of consec-
utive whorls imbricate in such a way that the plates of later-formed

24

FIELDIANA: GEOLOGY, VOLUME 39

*<*:~^

5mm

Fig. 2. Camera lucida drawing of a portion of the surface of Ischadites dixonensis
(see fig. 4 for precise location). Insert: lateral view of I. dixonensis.

whorls underlie (or are situated adaxially to) the plates of earlier
formed whorls. Finally, each rhombic plate has neighbors directly to
the south and north, members of the second previous and second
subsequent whorls. Where en eschelon and imbricate relationships
are clearly developed, these plates do not come into direct contact at

FISHER & NITECKI: MEROMES IN ISCHADITES

25

Fig. 3. Reconstruction of distal portion of meromes of Ischadites dixonensis, seen
in oblique view (orientation shown by the arrows).

all; nearer the apical pole they may contact one another at a point.
All of these relationships seem to involve only abutment and supra-
position. There is no evidence of marginal sutures or fusion. In fact,
as long as the plates were growing (by marginal accretion, if they
were similar to the plates of/, barrandei; Rietschel, 1969; Gould and
Katz, 1975), they could not have been fused.

The articulation of merome plates is maintained by a uniform pat-
tern of interlocking of the ribs of stellate structures of neighboring
heads (fig. 3). The abapical meridional rib extends all the way to the
merome shaft of its southern neighbor, where its distal end inserts
in the small pit located at the junction of the merome shaft and
plate. The western latitudinal rib, with its distally adaxial orienta-
tion, passes adaxially of the abapical rib of its northwestern merome
neighbor. Similarly, the eastern latitudinal rib passes adaxially of
its northeastern neighbor's abapical rib. Furthermore, the eastern
rib of one merome consistently lies adapically of the western rib of
its eastern neighbor. These ribs overlap considerably, but at most
extend only about three-fourths of the way to their neighbor's shaft.
Finally, the adapical meridional rib extends adaxially of the
abapical rib of its northern neighbor (also adaxially of the juxta-
posed latitudinal ribs), to some point near the merome shaft of that
neighbor. The relative position of the ribs of stellate structures is ac-
tually much more consistent throughout the thallus than the plate
edge relationships originally used to define neighbors. It is in light
of these interlocking relationships that the various details of
merome head morphology find at least part of their explanation.

26 FIELDIANA: GEOLOGY, VOLUME 39

A similar pattern of merome head relationships is developed in
the vicinity of interposita and triangula. The difference is that the
northern neighbor of the interpositum, the triangulum, is a member
of the first subsequent whorl rather than the second, and contacts it
along an edge rather than not at all. Since the interpositum and
triangulum each have only one stellate structure (not a universal
feature of receptaculitids), similar 10 that of rhombic plates, the nor-
mal pattern of rib interlocking is preserved. However, the north-
western and northeastern neighbors of the triangulum (the first
rhombic plates of the intercalated parastichies— see below) have no
immediate southern neighbors. Therefore, their abapical ribs do not
contact any merome shaft, but rather, terminate before crossing the
latitudinal ribs of the associated interpositum.

Arrangement of meromes: Because of the limited exposure of mer-
ome shafts, the arrangement of meromes can only be studied in
terms of the arrangement of their heads. For this specimen, it is
possible to count and describe the position of heads over virtually
the entire thallus. As shown by Gould and Katz (1975) for /. bar-
randei, the meromes of /. dixonensis are arranged in whorls (49,
from basal pole to apical lacuna). At any latitude of the thallus a
series of plates obtained by following consecutive western (or east-
ern) neighbors around the thallus always returns to the plate at
which it began. This is an important distinction from other recepta-
culitids (e.g., certain specimens referred to /. koenigii in Nitecki,
1969) where, in the region of the apical hemisphere, other arrange-
ments occur.

One of the most salient features of merome head arrangement is
the pattern of sinistral and dextral spirals. These spirals apparently
represent only conspicuous alignments of elements in a uniform pat-
tern, rather than real morphogenetic units (Gould and Katz, 1975).
In order to avoid confusion with the term for a series of sequentially
produced elements ("genetic spiral" or "fundamental spiral"), we
introduce the term "parastichy." This term is commonly used in
literature on phyllotaxis and denotes a series of elements, within a
uniform array, in which consecutive members can be recognized in-
ductively by some regular spatial transposition (Williams, 1974).
We will be dealing primarily with series of plates that are juxta-
posed along a considerable length of their edges. Although these ac-
tually are only a subset of all possible parastichies, and technically
should be called "contact parastichies," the less precise term can be
used, in this case, without confusion. For example, the dextral para-

FISHER & NITECKI: MEROMES IN ISCHADITES

27

Fig. 4. Schematic map of relative plate positions on the basal hemisphere of
Ischadites dixonensis. Plates whose outlines are clearly preserved on the specimen
are shown as dots. Less clearly determinable outlines are indicated by small circles.
Concentric circles define the basal 25 whorls of the thallus, within which all inter-
posita and triangula are located. The irregular region enclosed by the solid line sur-
rounding the basal pole is the area that is incompletely preserved. The similarly cir-
cumscribed region extending from the twelfth to the twenty-second whorl is shown
in Figure 2. Broken lines indicate several arbitrarily chosen parastichies. Or-
thostichies are numbered around the circumference of the map, and, for ease of
reference, actual plate positions have been shifted to align the orthostichies along
radii. This makes the parastichies and the spacing between meromes appear less
regular than on the actual specimen.

stichy to which a given plate belongs would be composed of 1) that
plate, itself; 2) the plate, if it exists, that is a southwestern neighbor
of 1, and all succeeding southwestern neighbors; and 3) the plate, if
it exists, that is a northeastern neighbor of 1, and all succeeding

28 FIELDIANA: GEOLOGY, VOLUME 39

northeastern neighbors. Defined in this way, all parastichies on /.
dixonensis begin (i.e., have their oldest element) either with one of
the meromes immediately surrounding the basal pole or with one
bearing a triangulum. All triangula on this specimen occur in the
basal hemisphere of the thallus (precise positions are given in fig. 4).
Since each merome can be seen as an element of both a dextral and a
sinistral parastichy, each of these points of inception is the begin-
ning of both a dextral and a sinistral parastichy. Furthermore, each
parastichy anywhere on the thallus continues all the way to the mar-
gin of the apical lacuna. A consequence of this is that an equal num-
ber of dextral and sinistral parastichies pass through any given
whorl of the thallus.

An alternate characterization of the surficial pattern of /. dixon-
ensis is as a group of orthostichies, which in this case are series of
northern or southern neighbors (meridional series). Each plate is a
member of only one orthostichy, and, except for interposita and
their associated triangula, any orthostichy includes only plates
belonging to alternate whorls. Each orthostichy extends to the mar-
gin of the apical lacuna and begins either with one of the plates
immediately surrounding the basal pole, with the northwestern
neighbor of a triangulum, or with the northeastern neighbor of a tri-
angulum. The number of orthostichies is equal to the sum of the
dextral and sinistral parastichies. Whether the surficial pattern is
perceived as a system of orthostichies or parastichies depends on
the extent of calcification and manner of preservation. When plate
boundaries are evident, parastichies are usually most conspicuous.
When only the pattern of stellate structures is clearly exposed or-
thostichies are more pronounced. Thus, although these two expres-
sions of pattern are redundant, each is useful in a different setting.
Both were necessary for the complete interpretation of the present
specimen (see fig. IB).

Another significant aspect of merome arrangement is the number
of plates surrounding the basal pole. We estimate this from the
number of interposita on the thallus and the maximum number of
meromes per whorl (or alternately, from the number of meromes in
any whorl and the number of interposita situated abapically of that
whorl). Since: 1) for each interpositum, an additional merome occurs
in subsequent whorls; 2) there are clearly 31 meromes per whorl in
the apical portion of the thallus; and 3) we have located 21 interpos-
ita on the thallus, there can be no more than 10 meromes immedi-
ately surrounding the basal pole. Given the extent of the inade-

FISHER & NITECKI: MEROMES IN ISCHADITES 29

quately preserved area, we may well have missed two interposita,
but probably not more than four. Therefore, it is unlikely that there
are fewer than six meromes around the basal pole, and there are cer-
tainly no more than 10.

DISCUSSION

In most respects, the description we have presented of /. dixonen-
sis is consistent with that offered by Rietschel (1969) for forms sim-
ilar to Receptaculites neptunu Conspicuous differences involve our
demonstration of: 1) an apical lacuna that seems to be too clearly
demarcated to presume that it occurs only because of breakage or
inadequate preservation; and 2) a uniform pattern of penetration of
merome shafts by the abapical rib of their northern neighbor. Of the
features of the two descriptions that are more similar, several seem
to be characteristic of an even broader range of receptaculitid taxa.
These include the order of juxtaposition and overlap between the
latitudinal and meridional ribs of stellate structures, the direction of
imbrication between consecutive merome whorls, the arrangement
of interposita and triangula, and the geometry of origin of new
parastichies. We must emphasize, however, that there are recepta-
culitids that depart significantly from certain aspects of this general
pattern. These will be considered in detail elsewhere.

In addition to simply describing the morphology of /. dixonensis,
we have tried to set up a procedure and terminology for expressing
the arrangement of meromes on the thallus. This has been designed
to allow more precise descriptions of the manner in which the num-
ber of meromes at any particular latitude on the thallus is increased
or decreased. Since even a cursory familiarity with receptaculitids
indicates that there is a great deal of variation in the specific pat-
tern of merome arrangement, a consistent procedure for pattern
description will be a useful tool in comparative work.

The controversy surrounding the issues of life orientation and
morphogenesis of receptaculitids has two principal roots: 1) diverg-
ent interpretations of particular aspects of morphology; and 2)
attention to very different types of evidence, in the context of differ-
ent taxa, by different workers. This second factor might have facili-
tated, rather than confused, efforts to develop a comprehensive
understanding, except for the fact that there has not been an ade-
quate basis for comparing the results of independent investigations.
In other words, there has been abundant disagreement on what

30 FIELDIANA: GEOLOGY, VOLUME 39

features are in fact homologous on various receptaculitid thalli. This
has made it difficult or impossible for workers to agree even on what
would be a consistent orientation for all receptaculitids (e.g., Camp-
bell et al., 1974, p. 68, discussing the work of Rietschel, 1969, and
Nitecki, 1969), not to mention the problem of deciding whether or
not such an orientation actually represented the life position.

It should go without saying that in order to develop a consistent
and broadly applicable theory of homology, we need a detailed
knowledge of the morphology of receptaculitid taxa representing as
much as possible of the morphological spectrum which is actualized
by the group. Yet this has not really been the thrust of most recent
work. Rietschel (1969) makes an important contribution here, with
his relatively complete characterization of the apical and basal re-
gions of R. neptuni-\ike receptaculitids, but he considers a rather
narrow range of body form. Studies of individual taxa are certainly
important (Campbell et al., 1974; Gould and Katz, 1975), for it is on
that level that the basic evidence on orientation and relative mer-
ome age must be gathered. However, these studies need to be syn-
thesized through comparative work.

A key element in the development of the comparative morphology
of receptaculitids will be the description of material that is suffi-
ciently well preserved to provide information both on the surficial
organization of merome plates and on features situated more prox-
imally within the thallus. This will allow the determination of
homology to be based on multiple lines of evidence, and will also
make it possible to incorporate evidence from taxa for which our
morphological understanding is clearly incomplete. We see the
description of /. dixonensis as a contribution to this goal. The actual
formulation of a theory of homology will be treated separately
(Fisher and Nitecki, in prep.); our present aim is only to set forth the
detailed morphology of this particular ischaditid and establish the
basic context within which our research is undertaken.

ACKNOWLEDGEMENTS

We thank Stephen J. Gould and David M. Raup for discussion of
this material or comments on the manuscript, and Tibor Perenyi for
help with illustrations. We gratefully acknowledge financial sup-
port to the junior author from National Science Foundation grant
DEB77-11129.

FISHER & NITECKI: MEROMES IN ISCHADITES 31

REFERENCES

Byrnes, J. G.

1968. Notes on the nature and environmental significance of the Recep-
taculitaceae. Lethaia, 1, pp. 368-381.

Campbell. K. S. W., D. J. Holloway. and W. D. Smith

1974. A new receptaculitid genus, Hexabactron, and the relationships of the
Receptaculitaceae. Palaeontographica, 146, pp. 52-77.

Gould. S. J. and M. Katz

1975. Disruption of ideal geometry in the growth of receptaculitids: a natural
experiment in theoretical morphology. Paleobiology, 1, pp. 1-20.

Miller. S. A. and W. F. E. Gurley
1896. New species of Paleozoic invertebrates from Illinois and other states. 111.
State Mus. Nat. Hist. Bull., 11, pp. 8-50.

Nitecki. M. H.

1969. Redescription of Ischadites koenigii Murchison, 1939. Fieldiana: Geol., 16,
pp. 341-359.

1970. North American cyclorinitid algae. Fieldiana: Geol., 21, pp. 1-182.

1971. Ischadites abbottae, a new North American Silurian species (Dasycladales).
Phycologia, 10, pp. 263-275.

1972. North American Silurian receptaculitid algae. Fieldiana: Geol., 28, pp. 1-108.

Nitecki. M. H. and C. C. Dapples
1975. Silurian Ischadites tenuis n.sp. (receptaculitids) from Indiana. Fieldiana:
Geol., 35, pp. 11-20.

RlETSCHEL. S.

1969. Die Receptaculiten. Senckenbergiana Lethaea, 50, pp. 465-517.

Williams. R. F.

1974. The shoot apex and leaf growth. Cambridge University Press. 256 pp.