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lOOLOGY

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FIELDIANA
Geology

Published by Field Museum of Natural History

Volume 33, No. 15 November 28, 1975

This volume is dedicated to Dr. Rainer Zangerl

Permo-Carboniferous Fresh Water Burrows

Everett C. Olson

Department of Biology

University of California, Los Angeles, California

and

Research associate

Field Museum OF Natural History

and

Kathryn Bolles

Department of Biology

University of California, Los Angeles, California

ABSTRACT

Burrow-casts from fresh-water deposits of the Late Paleozoic have given concrete
evidence of the aestivation of the lungfish, Gnathorhiza, and the amphibian,
Lysorophus. The structure of these burrows and inferences concerning the life habits
of their occupants are analyzed, with special attention to Lysorophus. A previously
unknown type of burrow, found in association with those of lung fish is described. It
is a large, complex structure, ovoid in cross-section and oriented vertically in the
surrounding sediments. By elimination it seems most probable that it was formed by
some type of large crustacean, but the precise origin remains uncertain.

INTRODUCTION

Casts of burrows of animals are frequently encountered in the
fresh-water deposits of Permo-Carboniferous age. The smaller ones
generally result from the activities of various kinds of "worm-like"
animals and the larger are generally considered to be burrows of the
lungfish Gnathorhiza. It is with the larger types of burrows that
this paper is concerned. Oddly, it was not until 1954 that any
formal note was made of these burrows, although surely they must
have been seen before. In that year, Romer and Olson (1954)
published a short account of the evidence for aestivation of
Gnathorhiza based on its burrows from two localities. Since that
time many additional Permian sites in the Arroyo, Vale, and Choza

Library of Congress Catalog Card Number: 75-25182 The Library of the

Publication 1219 271 MAY 0 7 1976

University ot iniiiuig
at Urbana-Chamoaign

272 FIELDIANA: GEOLOGY, VOLUME 33

Formations of the Texas Clear Fork Group and in the Wellington
Formation and Hennessey Group of Oklahoma have been dis-
covered. Vaughn (1964) described burrows from the Sangre de
Cristo Formation of New Mexico and Carroll (1965) noted burrows
in the Pennsylvanian of Michigan. Informal reports carry these
sorts of burrows into the Mississippian and tentatively into the
Triassic. Carlson (1966) made a thorough study of the burrows at
three sites in the Wellington of Oklahoma, giving details of both the
burrows and the contained lungfishes.

Ovoid nodules containing coiled specimens of the amphibian
Lysorophus have long been known from the Arroyo Formation of
Texas. In more recent years their range has been extended into the
Vale and Choza Formation of Texas (Olson, 1956) and into the
Fairmont Shale of the Hennessey Group of Oklahoma (Olson, 1970,
1971). Somewhat cylindrical burrow -casts occur in the Choza and
the Fairmont Shale and these too contain skeletons of Lysorophus.
Although it is quite clear, and has been somewhat casually noted in
various publications, that Lysorophus was an aestivating amphibi-
an, little attention has been paid to its burrows.

During the field seasons of 1972 and 1973 additional studies
were made at several localities which have produced either
Lysorophus or Gnathorhiza. From one site in the Vale Formation of
Texas an odd type of burrow which cannot be assigned to either
one, or currently to any known Permian animals, has been found.
These structures occur in association with "normal" lungfish
burrows and will be discussed in the final section of this paper.

LYSOROPHUS

This aquatic-aestivating amphibian is abundant in the forma-
tions of the Clear Fork Group, Early Permian, of Texas and
equivalent formations in Oklahoma. It was first named from
Pennsylvanian deposits in Illinois and has been found at various
sites in the Dunkard Series, Early Permian of Ohio, West Virginia,
and Pennsylvania. It has been mentioned and described many times
in the literature on the Permian. A detailed account of the
morphology of the skull was published by Sollas (1920) and recently
John Bolt and Richard Wassersug (1975) have published a new
study of the skull of Lysorophus. A general summary of the habits
and probable habitats of Lysorophus was given by Olson (1956,
1970) and in 1971 much of the postcranial anatomy was described
on the basis of a nearly complete specimen from the Fairmont

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274 FIELDIANA: GEOLOGY, VOLUME 33

Shale of the Hennessey Group of Oklahoma (Olson, 1971). This,
then, is a well-known amphibian.

In spite of this the taxonomy remains unsettled. The genus and
species, Lysorophus tricarinatus, were named on the basis of
fragmentary vertebrae from an Upper Pennsylvanian site near
Oakwood, Illinois (see Olson, 1946). The name was carried over to
the Texas specimens and also to those from the Dunkard. It is not
at all certain that the Texas specimens belong to the named species
and there is considerable question even about the validity of the
name Lysorophus. The taxonomy, although badly in need of a
thorough review, is not germane to the purposes of this paper, and
we will use the name Lysorophus to refer to the Texas and
Oklahoma materials, without a species name, but with the
conviction that all of our materials do pertain to but a single
species.

The remains of Lysorophus reflect two aspects of its living
habits — a free-swimming phase and as aestivating phase. The great
majority of specimens have come from the latter and it is with
these that we will be principally concerned.

Three aspects of the aestivating phase are of particular interest.
First, as has been noted briefly in earlier papers, the fossils
characteristically occur in local concentrations, each occupying at
most an area of a few square meters. Second, each such
concentration tends to yield specimens of about the same size (fig.
1). Based upon measurements along the base of the centra of the
dorso-lumbar vertebrae (in which variation along the column as
measured by the coefficient of variation "V" in individuals ranges
from about 1.5 - 3.0) pooled means from various samples of 2.5, 4.5,
7.2, and 10.0 mm. have been obtained. Even smaller animals are
known with centra no longer than 1 mm., but not in sufficient
quantity or well enough preserved for reliable estimations of means.
As shown in Figure 1, for some representative samples, there is
considerable variation around the mean at each of the sites, but for
the most part different sample groups, subjected to a standard t-
test of means, prove to be significantly different at the P = .05
level.

In these samples the animals are tightly coiled and the nodules
which they form are ovoid (pi. IE). Most have only one individual
but some have two or three. There is no distinct, regular boundary
between the nodules and the surrounding sediment, but there is a

OLSON & BOLLES: PALEOZOIC BURROWS

275

Plate I. A, A cross-section of a burrow-cast of undetermined origin from the
Vale Site 1919. x about V2. B, An acid etched cross-section of a burrow-casts from
the same site at A; x about 1. C, Segments of burrow-casts from the Vale site 1919:
segments on right are from lungfish burrows; on left is from the undetermined casts
also shown in A and B. x about Va. D, Cross-section of a Lysorophus burrow-cast
with part of the animal shown in place. From a burrow of the type shown in Plate
IIB. x about lA. (For explanation of letters see Figure 3.) E, A partial nodule of
Lysorophus from the Arroyo Formation showing curved outline of nodule controlled
by coiling of individual specimen: X about 3/a.

marked difference in composition, with nodules being very high in
dolomite, with a small admixture of quartz and feldspar and the
surrounding sediments being predominantly quartz. The nodules
weather cleanly from the sediments, being much more resistant to
chemical actions of the ground water and mechanical weathering.

276 FIELDIANA: GEOLOGY, VOLUME 33

From the Choza Formation of Texas and the Fairmont Shale of
the Hennessey Group in Oklahoma, has come a series of samples
with larger individuals of Lysorophus in which the mean, pooled,
vertebral length is 11.8 mm. Some of the individuals have lengths as
great as 13.5 mm. approaching the large Dunkard lysorophid
Molgophis in size. In these same formations there are also smaller
individuals, but these do not exhibit the clumping pattern found in
the Arroyo and Vale, are not coiled, and are not encased in
dolomitic nodules. They appear to have been preserved from the
free-swimming stage of life.

The third point of special interest is that the large individuals
from the Choza and Fairmont occur in a different sort of a burrow,
being found in elongated burrow casts with elliptical cross-sections
(pi. ID; IIB). The specimens from these kinds of burrows, like those
in the nodular burrows from different sites, fall into a limited size
range, but in this case only one size group, with a mean of 11.8 and
a range from about 10.5 - 13.5 mm. has been found. The relative
amounts of quartz, feldspar, and dolomite in the matric and in the
burrow-cast are shown in Figure 3. A regression of the mean sizes
on ontogenetic time, in which it is assumed that the different size
groups represent periodic, perhaps annual aestivation stages, shows
a rather typical growth curve (fig. 2). The final stage indicates a
continuation of a slight reduction in the relative growth rate
established between the two succeeding stages. The most logical
interpretation is that the large forms represent an additional
growth stage, not recorded in earlier formations and that they also
assumed a somewhat different mode of burrowing.

Three features then characterize the aestivation habits of
Lysorophus: (1) clumping of individuals; (2) size segregation in the
clumps; and (3) different habits of burrowing in the largest size
group as compared to those of the small animals. Various studies of
living amphibians and fishes, and even invertebrates, suggest
reasons why these characteristics may exist. If we assume, as we
have, that the basic motivation for burrowing was aestivation, then
the difference in behavior between size groups may relate to
differences in:

1. Physiology;

2. The substrate;

3. Water depth;

4. Climate at different times;

5. Function and morphology.

OLSON & BOLLES: PALEOZOIC BURROWS

277

Plate II. A, Lungfish burrow-casts in place at site #3 of Carlson (1968) (Perry
5, Olson, 1970). B, Two burrow-casts of Lysorophus in place at site in the Choza
Formation of Foard County, Texas. C, The Vale outcrop of burrow-casts at Vale site
1919. D, Closeup of burrow-casts at site shown in C.

These are not exclusive and are somewhat difficult to
differentiate even among living animals, becoming evident only
after careful experimental work and field observations. The
problems with fossils are, of course, much more acute.

It has been shown in salamanders that water loss is
substantially less in large than in small animals under similar
circumstances (Ray, 1958, Spight, 1968), and that aggregation and
coiling reduce both the rate of water loss and oxygen consumption.
This has been demonstrated for the tiger salamander, Ambystoma,
as well by Gehlbach et al. (1969). Siren and plethodontids occur in
burrows in both coiled and straight positions, but when occupying

278

FIELDIANA: GEOLOGY, VOLUME 33

VERTICAL
BURROWS

OVOID
BURROWS

TIME -AESTIVATION PERIODS

Fig. 2. A regression of the mean length of vertebral centra, pooled for several
samples at each point, on aestivation periods. It is assumed that aestivation periods
mark equal time units, perhaps annual.

burrows which they have made themselves they are usually coiled.
Where there is periodic aridity, plethodontids assume a coiled
position (Heatwole, 1960). On the other hand, Ray (1958) has shown
that animals obtained from moist areas do not coil under
experimental conditions even when drying is artificially induced.
Coiling habits differ between species relative to body structure.
Ambystoma, for example, is only able to form a tight S-curve,
whereas plethodontids are able to form full coils. A change in form
and size in ontogeny might bring about similar behavioral
differences between growth stages within a species and perhaps this
may have resulted in the differences in burrowing behavior between
the small and large specimens of Lysorophus.

OLSON & BOLLES: PALEOZOIC BURROWS

279

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Fig. 3. The results of X-ray analyses of the matrix and burrow-cast of a large
Lysorophus from the Choza. The burrow-case is of the type shown in Plate II B.
Relative proportions of quartz, feldspar, and dolomite are shown. Note the relatively
high proportion of dolomite in the burrow cast as compared with the matrix. Letters
A and B refer to the positions of the samples as shown in Plate ID.

The hardness of the substrate and its capacity to hold water
also are important to the nature of the burrowing amphibians.
Many burrowers penetrate, where possible, to the moist zone of the
substrate. Shallow burrows are formed where the substrate tends to
remain moist close to the surface. Substrates that lose water rapidly
are less suitable for burrowers than those which retain water and
thus both compositon and the texture of the substrate are
important. Heatwole (1960), on the basis of experiments with
different substrates, concluded that "probably coiling in burrows
indicates an inability to penetrate the substrate farther to reach
favorable conditions." He noted also that animals tended to move
about in search for suitable sites for burrowing. If the most
favorable sites differed somewhat for different size groups, then a
segregating site selection might take place.

Depth of water in which different size groups live and in which
they burrow for aestivation may also be a consideration. Protop-
terus, for example, tends to be distributed with the larger animals in
deeper water and smaller animals in shallower water. As conditions

280 FIELDIANA: GEOLOGY, VOLUME 33

Fig. 4. The pattern of coiling of Lysorophus in large, vertical burrows of the type
shown in Plate IIB. The reconstruction is based on analysis of several burrows both
from the Choza Formation of Texas and the Fairmont Shale of Oklahoma.

leading to aestivation set in, burrowing tends to occur in the main
areas of habitation, resulting in some size segregation.

Climate is a controlling factor in aestivation, determining not
only where the phenomenon will occur but also strongly influencing
the form it will take. In the case of aestivation of extinct animals
over a period of geological time, the factor of climatic change may
be very important. Clearly the climate changed somewhat from the
Arroyo to the Choza times in Texas and similar changes seem to
have occurred in Oklahoma. There was a tendency for increased
aridity, but also, it appears, there tended to be an increase in the
number of relatively small, but permanent lakes near the coast
lines. It is in such deposits, formed in small lakes, that Lysorophus
is found in the Choza and in the Fairmont Shale of Oklahoma. The
smaller animals, with central lengths of less than 10 mm. do not
appear to have aestivated under these circumstances. Samples
contain a wide range of size groups and specimens are not found
tightly coiled in nodules (see fig. 1, column 9). A few such sites have
been found in the Vale, but they are rare. The larger animals,
however, did aestivate, occurring in elongated, elliptical burrows, in
loose, open, spiral coils (fig. 4, pi. ID, IIB).

It may be that the differences in coiling patterns between these
large forms and those of the tightly coiled smaller ones from the
Arroyo and Vale Formations arose merely because the large
individuals mechanically could not coil tightly. Being less subject to
dessication because of their size, these large individuals probably
could tolerate the conditions of a single burrow even though they

OLSON & BOLLES: PALEOZOIC BURROWS 281

were loosely coiled. This does not explain the fact that the smaller
ones did not aestivate at all. It also does not explain why the very
large individuals have been found only in the Choza and Hennessey
and not in any of the many samples from earlier formations.
Perhaps only during the Choza and Hennessey times were the
climatic conditions favorable for continued growth, or perhaps the
substrates of earlier sites were not suitable for larger forms which
could not coil tightly and aggregate.

Any solution is necessarily speculative. What seems to be the
most likely explanation, however, relates to the special conditions of
the small permanent lakes. Lysorophus does not appear to have
lived in large, open bodies of water. The permanent small lakes may
have provided optimal conditions for growth, but if, as seems likely,
they were subject to periodic partial, but not complete, drying, then
it could have been that only the largest animals would have found
it necessary to aestivate, whereas the smaller could continue their
free existence in shallow waters under somewhat restricted, but
favorable conditions.

The large animals probably were unable to cope with limited,
shallow water and reduced food supplies, but could survive in
burrows in which they were loosely coiled. This interpretation fits
the evidence from both sites at which the large burrows occur. The
distribution by size of a sample of the free-swimming forms from
the Choza site is shown in the last column in the histograms in
Figure 1. There is no clustering of size groups and, as noted earlier,
the specimens do not occur coiled in dolomitized nodules.

This is at least a logical explanation for the differences in
burrow types and the occurrence of large animals only in the Choza
and Fairmont Shale of the Hennessey. It does not explain why
groups of similar sizes occur in isolation in earlier formations.
Perhaps there was some sort of schooling behavior, such as various
fishes show, or some control by depth of water. The non-segregated
distribution of individuals from the free-swimming samples suggests,
however, that this was not the case. Rather, it appears more likely
that the grouping was based on modest substrate differences which
had advantages for one or another size group with respect to easy
penetration and moisture retention. Site selection may have been
the most important factor in producing the size groupings. This is
subject to testing in the field, but currently at least, access to the
critical sites is not permitted by the land owners.

282 FIELDIANA: GEOLOGY, VOLUME 33

GNATHORHIZA

The descriptions of the burrows of Gnathorhiza in Romer and
Olson (1954) and the detailed study by Carlson (1968) make it
necessary to touch only on some points which serve to differentiate
lungfish burrows from other types. Some burrows in outcrop, where
the sediment has been partly cleared away, are shown in Plate IIA.
The general shape is fairly distinctive, but the primary criterion for
recognition of lungfish burrows, of course, is the presence of well-
preserved remains of fishes in aestivating position. In the site
shown, site #3 of Carlson, fish are abundant, but in some other
sites the burrows are largely barren.

From the occupied burrows it is possible to obtain information
upon the general morphology of the burrow-cast and to carry this
over for interpretation of barren burrows elsewhere. In these latter
cases, of course, there must remain some doubt, for other burrowing
animals can make structures which are quite similar. Several
localities of the Early Permian in Oklahoma and Texas have well-
preserved remains of lungfishes. The best are at Romer's Reed
Ranch locality in Wilbarger County, Texas and at Carlson's site #3
in Oklahoma, near the town of Perry. This is Perry site 5 as
designated by Olson in 1967. Also lungfish are abundant but badly
macerated at Carlson's site # 1, which is Perry site 1 in Olson, 1967.

Beyond the presence of preserved fishes, some morphological
features of the burrow-casts are more or less diagnostic. When well
preserved and not severely weathered, the cast consists of an outer
shell and an inner core, with a more or less circular cross-section. As
described by Carlson (1968) at his site #1, the outer shell contains
packed scales and small bones, indicating some compacting action
by the fish during construction of the burrow. This outer shell is
usually lost during weathering leaving only the inner core, in which
the fish is preserved, if present at all. This core consists of a long
cast of the inner chamber and ranges from about 1.5 - 10 cm. in
diameter, in different casts, and may be as much as 50 cm. in
length. The diameter of individual burrows changes very little from
top to bottom, but some tend to narrow slightly in the lower
portions. The casts are always nearly vertical in the enclosing
sediments, not departing more than some 5 - 8 degrees from
verticality. Plates IC and II A, C, D, show some of the "burrows" in
place and others removed from the matrix.

When the outer shell is present, the outer surface may be quite
irregular, although still roughly circular in cross-section. The inner

OLSON & BOLLES: PALEOZOIC BURROWS 283

chamber has a very regular outer surface and under some
circumstances shows strong slickensides oriented nearly vertically.
The chemical composition of the core differs somewhat, depending
upon whether or not large amounts of organic material were
present. Those which have well-preserved fish remains are highly
dolomitic as compared with the surrounding matrix. Carlson (1968)
pointed out this dolomitic character and it has been confirmed at
several other sites as well (fig. 5). Casts from two sites in the Vale,
however, in which fish remains are absent, or nearly so, have a
much lower increment of dolomite, being composed mostly of
quartz with only small amounts of dolomite and feldspar.

Burrow-casts that are well preserved and show most of the
structures noted above can be referred to the lungfish Gnathorhiza
with considerable confidence. Problems arise when there are
deviations from this pattern, and this is what happened in the case
of a new burrow site in the Vale, as discussed in the following
section.

BURROWS OF THE VALE SITE 1919

This locality lies on Texas Farm Road 1919 near the boundary
between Baylor and Foard Counties. It is quite near one of the sites
from which lungfish burrows were first described by Romer and
Olson in 1954. The outcrop along the roadcut is shown in Plate IIC,
D. Typical burrow-casts of Gnathorhiza are present. These range in
cross-section dimension from 1.5 - 6.0 cm., all are long and have a
cup-shaped base. These structures, of course, were immediately
identified as lungfish burrows and some of them carry scattered
remains of Gnathorhiza bones and scales. Along with them are
some rather large, vertical structures with more elliptical cross-
sections, these are enclosed in an irregular shell which contains
darker, irregular fragments of rock which give the appearance of
being brecciated. These also were at first thought to be lungfish
burrows which had retained an outer shell, as had those at site # 1
of Carlson. After cross-sections had been made (fig. 6; pi. IA),
problems in reconciling the two types of burrows were encountered
as discussed below.

The matrix surrounding the burrows of this exposure contains
remains of Lysorophus, of a small nectridean close to Peronedon of
the Fairmont Shale of Oklahoma (Olson, 1970), and of a small,
undetermined reptile with a skull length of about 1 cm. Fragments
of Gnathorhiza are occasionally encountered. As is usual in

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SMALL BURROW (B)

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Fig. 5. Above: Diagram of a cross-section through the base of a burrow, A and a
"reduction halo" of a second burrow, just below the burrow in shale, B. C represents
a sample from the matrix. Below: An X-ray analyses showing the relative proportions
of quartz, feldspar, and dolomite at A, B, and C. Note the relatively high proportion
of dolomite in the burrow-cast, in which a lungfish was preserved, but its absence at
B and small relative amount at C.

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(A)

ELLIPTICAL CORE
(B)

CRESCENTIC CORE
(C)

Fig. 6. Above: Diagram of the cross-section of two adjacent burrow-casts with
elliptical cross -sections of the type shown in Plate IA, B, and C (left figure). Below:
results of X-ray analyses showing relative proportions of quartz, feldspar, and
dolomite at sample sites A, B, and C (above). A is one of the deep brown
"brecciated" fragments around the burrow cast (see also pi. IA). B is the elliptical
core and C the crescentic core. Note the relatively high proportion of dolomite in the
"brecciated" fragment contrasting with the relatively low proportion at B.

285

286 FIELDIANA: GEOLOGY, VOLUME 33

Permian red-beds remains of invertebrates are almost non-existent.
A few fragments and impressions of very small pelecypods have
been found, but that is all.

It appeared that this outcrop offered a chance for a detailed
study of the internal structure of lungfish burrows and additional
analyses of conditions of deposition. Several blocks of burrows were
taken from the unweathered parts of the deposit and these were
"dissected" and serial cross-sections of the burrows were cut. The
composition of the burrows and matrix were subjected to X-ray
analyses by Dr. Keith Chave. A number of unexpected factors were
discovered.

The burrow-casts with circular outlines, lungfish burrows,
could not be identified more than a few inches back of the outcrop
surface. Etching with strong acid, X-ray analyses, and studies of
cross-sections under light microscopes revealed no trace of them. On
the other hand, the more elliptical structures with "brecciated"
outer shells continued to be present in abundance. First we thought
that the cores of these elliptical structures produced the circular
casts of the lungfish burrows. The composition of both is very
similar, being predominantly quartz, with small amounts of
dolomite and feldspar (fig. 5). The shape of the cores of the
elliptical structures, however, shows that this cannot be so. There
seems to be no way by which these cores could have modified
consistently from their characteristic shapes to form casts with
nearly circular cross-sections.

The structure of the cross-sections of the elliptical burrows is
shown in Figure 6 and Plate IA. The outer shell, with dark
fragments, which give a brecciated appearance, is consistently
present. This encloses the inner parts of the structure for its full
length of about 50 cm. The enclosed area, in cross-section, consists
of two distinct core structures. One is an elliptical core which is
surrounded by a deeper brown zone. The material of this zone is
more soluble in strong acid than in the core and etches as shown in
Plate IB. The second core structure is crescentic and the arms of
the cresent pass into the outer shell, as shown on the etched
specimen. The deeper brown, more soluble zone, separates it from
the elliptical core. The relative composition of the different
components is shown in Figure 6.

The deep brown fragments in the "brecciated" part of the
structure are high in dolomite relative to quartz and compared to

OLSON & BOLLES: PALEOZOIC BURROWS 287

the core and the surrounding matrix. This suggests that a high
content of organic material was present during their formation,
analogous to the situation of lungfish burrows in which fish remains
are well preserved.

The structure of these casts is quite clear. What produced them
is at present uncertain. Unlike many Gnathorhiza and Lysorophus
burrows, they carry almost no recognizable organic remains, either
of complete animals or washed-in fragments. Clearly, they are not
burrows of Lysorophus and no other aestivating amphibians are
known from this time in the Permian. If they are vertebrate
burrows, it would appear that they must be lungfish or some
otherwise unknown animal. In any case, it appears likely that some
remains of the producer would have been found within the
sediments, and none has.

The outer shell would appear to be the result of some sort of
action by the occupant. Gnathorhiza seems to have packed its
walls, as described by Carlson (1968). In Protopterus, as shown by
Johnels and Svensson (1955), drying of the sediment and of the
occupant of a burrow results in contraction of both, and a water
resistant cocoon is formed by the lungfish. Such alterations might
leave a fossil record in the form of modifications of the outer
margins of the burrow. Some specimens of Protopterus do have
sediment between the parts of the body folded in the burrow and
conceivably the brown layer between the two chambers might be
some such feature, although very different from that of Protopterus.
The burrows from the Vale, however, are totally different in shape
from those of Protopterus and any analogies seem far-fetched.
Added to this is the fact that the aestivation burrows of
Gnathorhiza, the only known lungfish from this time, while similar
in being elongate and vertical, are very different in internal
structure.

It appears then that the burrows may either be those of some
invertebrate or else are inorganic in origin. They clearly are not tree
roots and any inorganic origin poses many more problems than an
organic one. The absence of remains of a possible invertebrate
producer poses no serious problem in view of the fact that their
remains are very rarely preserved in the red sandstones and clay-
shales of the Early Permian of Texas and Oklahoma. Small
conchostracans, small pelecypods, and, of course, insects are known
from beds of the Lower Permian, but these occur mostly in the
dolomites and only pelecypods are found in the red shales. These

288 FIELDIANA: GEOLOGY, VOLUME 33

are always small and usually preserved as impressions. None of
these known invertebrates can be considered as candidates for the
formation of the elliptical burrows, on a size basis alone. The fact
that these are fresh-water deposits generally limits the kinds of
invertebrate organisms which could have been present to make the
burrows to fresh-water molluscs, pelecypods or gastropods, and to
crustaceans. The fresh-water molluscs do not seem to be good
candidates, in view of the complex nature of the burrows, so that it
seems that these may be the work of some large crustaceans, by
elimination, however, rather than because of any reasonable
analogue among known moderns.

Fossil burrows of a marine decapod, termed Ophiomorpha and
made by animals close to Callianassa, were described in detail by
Hester and Pry or (1972). Shapes are vaguely similar in cross-section
and the burrows are elongated, but they are irregular and curved
and twisted. The most pertinent point in their discussion with
reference to the present case is that the burrows which they
described were in some instances lined with fecal pellets. The red-
brown "brecciated" fragments in the Permian burrow walls have
somewhat the appearance of broken coprolites from beds of this
type and their dolomitic nature suggests a possible organic content
during their formation. They could, conceivably, represent a wall-
lining by fecal material.

The two different structures of the core indicate a complex
occupancy of the burrows, for which no very plausible explanation
has been forthcoming. Was there a "living chamber," the elliptical
core, and a second chamber, say for water circulation or waste
disposal? Was this an elongated animal that somehow folded over
to occupy the two parts of the chamber with, for example, some
sort of siphon to the surface in one or the other? Or are the two
chambers the result of some sort of differential shrinking with
drying and contraction of the sediments which somehow produced
the more soluble external coating of the elliptical cross-section?
Was this burrow some sort of a "brood chamber" either for an
invertebrate or a vertebrate? Is it possible, for example, that
Gnathorhiza, like some modern lungfish, did have brood-burrows
different from aestivation burrows and that is what we have found?

We don't know and currently have no favored explanation. It is
possible that more precise analysis of the composition of the various
parts of the structures will give additional information, and this is
being investigated. Most likely, however, it will be necessary to find

OLSON & BOLLES: PALEOZOIC BURROWS 289

a reasonable modern analogue, which now is either not known or at
least not known to us, or to find circumstances in which the animal
has been preserved in the burrows.

ACKNOWLEDGMENTS

The research leading to this paper was supported by a National
Science Foundation Grant GB 31283X. Field work was done with
the aid of Mr. Gary Johnson of Southern Methodist University and
Mrs. Lila Olson. Laboratory preparations of the materials for study
were carried out by Mr. Richard Lassen, Museum Scientist at the
University of California at Los Angeles. The X-ray analyses were
carried out by Dr. Keith Chave of the University of Hawaii. We are
sincerely grateful to each of these persons and to the National
Science Foundation for their indispensible aid.

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