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FIELDIANA
Geology

Published by Field Museum of Natural History

Volume 37, No. 5 February 24, 1978

Ordovician Receptaculites camacho n. sp.
from Argentina

Matthew H. Nitecki

Curator, Fossil Invertebrates
Field Museum of Natural History

and

Gerald G. Forney

Amerada Hess Corp.

WlLLISTON, N.D.

ABSTRACT

An Early Ordovician green alga. Receptaculites camacho n. sp., from the San Juan
Formation in Talacasto Gorge, San Juan Province, Argentina is a probable ancestor
of Receptaculites oweni of the Galena- Kimmswick (Caradocian?) of North America.
Analogy with recent calcareous green algae suggests that R. camacho inhabited
warm, shallow, marine water. A paleomagnetic reconstruction of mid-Ordovician
continental configurations places the North and South American localities of R.
oweni and R. camacho in tropical latitudes. The major global oceanic currents for
Middle Ordovician are inferred.

INTRODUCTION
Receptaculitids are an order of Paleozoic green algae related to
Siphonales, Siphonocladales, and Dasycladales. Receptaculitids
are common in North America, but are poorly known from South
America. Ahlfeld and Branisa (1960) and Branisa (1965) illustrated
a Devonian Receptaculites bolivianus from Bolivia, where it is an
index fossil and a zone marker. The Ordovician specimen described
in this paper was illustrated by Camacho (1966) as Receptaculites
sp. Silurian receptaculitids have been found by geologists working
in the Argentine Precordillera (Camacho, pers. comm.).

Distribution of Argentine and Bolivian receptaculitids has been
discussed by Byrnes (1968), Holland (1971), and Nitecki (1972).
Byrnes and Holland suggested that Devonian receptaculitids were

Library of Congress Catalog Card Number: 77-20539

US ISSN 0096-2651 _

The Library of the

Publication 1277 93

JUN 2 3 1978

n/Mfcilv nt mil

94 FIELDIANA: GEOLOGY, VOLUME 37

restricted to a zone of 15 degrees north and south of the paleo-
equator, but did not include the South American taxa on their map.
Nitecki (1972) included the South American occurrences on a map
of receptaculitid distribution.

The apparent scarcity of South American receptaculitids may be
due to the lack of paleontological exploration. In the 19th century,
European and North American receptaculitids were described by
students of fossil sponges, but no South American occurrences were
known. There has been no active search for receptaculitids in South
America, although with an increased number of field studies, more
will certainly be found.

The fossil described here adds new information on the paleogeo-
graphic distribution of Ordovician receptaculitids and on the possi-
ble ancestry of the well-known North American Receptaculites
oweni.

LOCATION AND STRATIGRAPHY

Early Ordovician carbonate rocks are found throughout the east-
ern Precordillera of Argentina. Narrow bands of limestone extend
southward for almost 500 km. from Cerro Totora (LaRioja Province)
to west of Mendoza City, with their greatest thickness between
Jachal-Huaco and the city of San Juan (Cuerda, 1973).

Harrington (1957) found abundant fossils in the upper part of the
San Juan Formation, and lists over 25 species of crinoids, bryo-
zoans, corals, brachiopods, gastropods, cephalopods, and the trilo-
bite Proetiella tellecheai. Harrington (1957) considers the zone ofP.
tellecheai to be Upper Llanvirnian, since the San Juan Formation at
Huaco is conformably overlain by shales with supposed Llandeilian
graptolites. More recent graptolite collections (including Paraglos-
sograptus etheridgei and Glyptograptus austrodentatus) known
from Llanvirnian of Australia suggest a Lower Llanvirnian age for
the San Juan Formation (Cuerda, 1973). The revised and correct
name of Paraglossograptus etheridgei is P. tentaculatus . It was
originally described from Levis Shale of Quebec from beds appar-
ently corresponding to the European!), hirundo Zone, that is, late
Arenigian. This is in good agreement with Serpagli's strong cono-
dont evidence of the age of San Juan. Conodonts from the San Juan
Formation 50 km. north of Huaco include North Atlantic Lower
Ordovician forms such as Oistodus, Scandodus, and Cordylodus
(Hiinicken, 1971). Serpagli (1974) considers the upper 200 m. of the

/^...Huaco

- Cambrian-Silurian

H'^1 Pre-Cambrian-Devonian

Mendoza City 100 km

rivers •/ roads

JjClocality with R.camacho

50 km

i i i i i i

Fig. 1. Central Argentine Precordillera showing outcrop pattern of undif-
ferentiated rocks of Lower Paleozoic age. The Quebrada de Talacasto locality with
Receptaculites camacho is indicated by an asterisk in a circle (modified from
Padula et al., 1967, fig. 4).

95

96 FIELDIANA: GEOLOGY, VOLUME 37

San Juan Formation to be of Arenigian age. Serpagli's locality is 50
km. northwest of San Juan.

Talacasto Gorge (Quebrada de Talacasto), where Receptaculites
camacho is found, is one of the best-studied Lower Paleozoic sections
in the Argentine Precordillera (Padula et al., 1967; Marchese,
1972). The gorge is located in San Juan Province about 55 km.
north-northwest of the city of San Juan (fig. 1). The section of
Ordovician to Middle Devonian strata extends from east to west
along the highway from Talacasto to Rodeo, and between the
Matagusanos and Gualilan valleys. Our locality (fig. 1) is about 2
km. east of locality 2 of Padula and others (1967, fig. 4).

The total thickness of the San Juan Formation at Talacasto Gorge
is unknown because the base of the Paleozoic section is bounded by a
fault. The formation (fig. 2) is divisible into a lower, 300 m. thick
member, consisting of 0.5 to 3 m. thick beds, and an upper, 50 m.
thick member, with beds ranging from 0.2 to 1 m. in thickness
(Marchese, 1972). The textures and sedimentary structures of the
upper member suggest deposition in shallower water than the lower
member (Marchese, 1972).

The fauna associated with R. camacho includes the trilobite
Proetiella tellecheai , the gastropod Maclurites avellanedae , the nau-
tiloid cephalopod Lituites sp., the brachiopod Orthis sp., and other,
unidentified, fossils (Baldis, pers. comm.).

According to Baldis (pers. comm.), the San Juan Formation at
Talacasto Gorge is unconformably overlain by the Silurian
(Wenlock-Ludlow) Los Espejos Formation (fig. 2) which consists of
350 m. of fossiliferous green sandstones interbedded with shales.

Receptaculites oweni Hall, 1861

Receptaculites oweni is a very common, conspicuous North
American Ordovician fossil. Although it is well-known to American -i
geologists, it has received little study. R. oweni is the largest recep-i
taculitid known; specimens over 30 cm. in diameter are common. In,
the midwestern United States, R. oweni is restricted to the Galena'
and Kimmswick Formations where it is an excellent horizon
marker. Outside this region, its distribution is less precisely known,
and work in progress indicates that fragmentary material is often
misidentified. While other species have been assigned to jR. oweni,
the reverse is also true, and at least 10 different names have been

DC

LU

700m

cog

350 m

300m

o

Si

lUdc
_j<
Q
Q

0m

vvA

/-

TALACASTO FORMATION

LOS ESPEJOS FORMATION

Upper Member with R. camacho

SAN JUAN FORMATION

Lower Member

FAULT

Fig. 2. Stratigraphic section of the lower part of the Quebrada de Talacasto
succession (Baldis, pers. comm.).

97

98 FIELDIANA: GEOLOGY, VOLUME 37

given to this taxon. Preliminary examination reveals that speci-
mens from Colorado, Nevada, New Mexico, Texas, Wyoming, Mani-
toba, Northwest Territories, Ontario, Saskatchewan, and the
Canadian Arctic appear similar toR. oweni. However, the identifi-
cation of R. oweni in Kentucky, Maryland, New Jersey, Pennsyl-
vania, Alberta, and Quebec, is in question. These fossils appear to be
R. occidentalis , which differs fromi?. oweni in the size of thallus,
length of branches, and in the complexities of lateral heads. If the
fossils reported from these localities arei?. oweni, then the species
ranges into the Ashgillian. Until more information is available, we
consider R. oweni to be restricted to the Galena- Kimmswick of
Caradocian (?) age. However, the topmost part of the Galena Group
may be Ashgillian in age.

Although R. oweni is found chiefly in limestone, it is also common
in dolostone. In the field, it is easily recognized by its large size,
short but relatively thick branches, and disc-like preservation. Al-
though complete specimens have never been illustrated, we have
such entire individuals in our collections. These show that R. oweni
was globose, rather than disc-like, without holdfast, and suggest
that this form rested directly on the substrate.

Receptaculites camacho n. sp.

The fossil from Talacasto Gorge is a very large Receptaculites 22
cm. in diameter (fig. 3). Although its large size and flat shape could
easily cause it to be mistaken fori?, oweni and although not all the
skeletal elements are well-preserved, it represents a distinct new
species. The single specimen consists of a complete upper part of the
thallus and portions of its sides. The thallus is circular in outline
with the central area and margin of the fossil somewhat elevated.
This is a distorted form of preservation frequently found in North
American Receptaculites oweni. The central nucleus, representing
the growing, distinctly mamillary tip is very pronounced and
somewhat elevated. The branches are very short, with irregular
bases, relatively thin shafts, and heads consisting of thin, small
stellate structures just below relatively thin plates. The heads and
shafts are poorly preserved and the head elements appear fused and
heavily calcified. Small knobs are found on the outer surface of
individual plates. Horizontal and vertical elements of the stellate
structures are distinct on portions of the surface. These structures
are not observed together, indicating that the elements of the stel-
late structures were in two planes.

NITECKI & FORNEY: ORDOVICIAN RECEPTACULITIDS

99

FlG. 3. Receptaculites camacho from Quebrada de Talacasto, Holotype, Field
Museum of Natural History, PP 19881.

The following characters are shared by/?, camacho and /?. oweni:
very large thallus; preserved part has a circular, disc-like outline;
somewhat elevated nucleus is centrally located; branches are
characteristically very short; calcification of bases and heads of
laterals forms a double wall structure; and a thin outer plate is
present.

R. camacho differs from/2, oweni as follows: lateral shaft is much
thinner (the shaft of/?, camacho is five times thinner than the shaft
of/?, oweni); stellate structure of camacho consists of four small
ribs, apparently not fused together; and a small central protuber-
ance is present on the plate.

This comparison shows that R. oweni and R. camacho are
morphologically very similar taxa. The characters generally used to

100 FIELDIANA: GEOLOGY, VOLUME 37

differentiate receptaculitid species, such as calcification, formation
of walls, and length of branches, indicate that these are very closely
related forms that could be placed in the same subgenus. Since R.
camacho is stratigraphically older thani?. oweni, the conclusion
that R. camacho is an ancestral stock of R. oweni seems very
reasonable.

PHYTOGEOGRAPHY OF RECENT DASYCLADACEAN ALGAE

Data on the distribution of extant algae are based either upon the
study of small planktonic forms, or upon attached near-shore forms.
The pattern of distribution of planktonic algae gives us information
about oceanic currents, and about the physical conditions of the
near and surface waters from which the plankton was transported.
The pattern of distribution of near-shore benthonic algae, however,
indicates the distribution of conditions suitable for their establish-
ment and growth. This is particularly true for long-lived organisms
which spend all of their lives (including reproductive phases) in one
place. On a global scale, recent marine algal floras are differenti-
ated into northern and southern, and tropical and non-tropical
realms. Like the terrestrial plants, species of benthonic algae are
geographically restricted.

While the vertical and horizontal distribution of living red algae
is now being studied (Adey and Macintyre, 1973; Adey and Vassar,
1975), the distribution of calcareous green algae, particularly
Dasycladales, has received little attention. Both intensity and color
of light are important in the bathymetric distribution of green
calcareous algae. Chlorophyta cannot tolerate deep or muddy water
because they require light frequencies that cannot penetrate deep
or muddy water. Calcified algae have a greater ability to tolerate
exposure to light than uncalcified forms. Green "naked" uncalcified
Acetabularia cannot tolerate an intensity of light as high as heavily
calcified forms, and when exposed to strong light it bleaches and
loses much of its chlorophyll. Therefore, calcified individuals can
inhabit shallower and more intensely illuminated waters. The use-
fulness of benthonic calcareous algae as depth indicators in
paleoenvironmental studies is discussed by Riding (1975).

Apart from water depth, the geographic distribution of algae is
mainly controlled by water temperature. The algal floras of the
tropical Atlantic and Indian Oceans are very similar. These floras
are not continuous around the southern, non-tropical projections of

NITECKI & FORNEY: ORDOVICIAN RECEPTACULITIDS 101

South Africa and South America. Such a distribution may be a
result of extinction, migration, and currents. The most common
view today is that Pleistocene climatic variations caused this
distribution. However, Pleistocene climatic changes cannot explain
the distribution of the living dasycladaceous genera Bornetella,
Helicoryne, Dasycladus, and Acetabularia. Bornetella and
Helicoryne are cosmopolitan in the tropics, but are absent from the
Caribbean; Dasyclad us is found in the Mediterranean, Caribbean,
and Australia; Acetabularia is found on both sides of Panama,
across the equator (including Australia), and in the Mediterranean.
Neither the closing or opening of the Isthmus of Panama, nor the
movement of cold or warm Pleistocene currents alone can explain
this distribution. Even more difficult to explain is the distribution
of the dasycladaceous alga Batophora oerstedii found not only in the
warm, quiet marine waters of lagoons in the Gulf of Mexico and in
the Caribbean, but also in lakes in New Mexico 500 miles from the
nearest marine locality! Although modern Dasycladales are gener-
ally restricted to the marine tropics, they are also found outside the
tropical sea belt. This pattern suggests that the importance of Pleis-
tocene changes upon the distribution of marine algae may have
been exaggerated.

PALEOECOLOGY OF ORDOVICIAN RECEPTACULITIDS

The ecology of Ordovician receptaculitids is known from 1)
calathids of the southwestern United States, 2) receptaculitids from
the southern Appalachians, and 3) Receptaculites oweni from the
Upper Mississippi Valley.

1. Calathids, best known in the Lower Ordovician mounds of
western Texas, are definite reef builders, with long thalli and thick
holdfasts. They are a major component of algal bioherms that range
in size from small mounds one-half meter long, to structures more
than 15 m. long. The bioherms are calcitic mudstones bound by
possible blue-green algae, by archaeoscyphian sponges, and by
calathid receptaculitids. In the reefs, calathids are beautifully pre-
served in growth position. The size of calathids in each mound is
related to the size and rate of growth of the mound, indicating that
these algae were long-lived with a life span probably measured in
decades.

2. The receptaculitids of the Appalachian region occur either in
association with organic reefs or are found in the inter-reef facies.

102 FIELDIANA: GEOLOGY, VOLUME 37

Those in reefs have bulky thalli, often with holdfasts, and were
unquestionably sessile. Like the long-lived Texas calathids,
Appalachian reef receptaculitids formed "thickets" and acted as
frame builders to produce boundstone (Alberstadt et al., 1974).

3. Although holdfast is not known in Receptaculites oweni, the
heavy calcification and large size suggest that it was a benthonic
form. Even in incomplete specimens, the individual branches are
articulated, and there is only rare evidence of abrasion or extensive
transport.

R. oweni is an abundant fossil and it is usually found in rocks of a
consistent lithology. The lithology and faunal associations of recep-
taculitid localities in Illinois, Wisconsin, Iowa, and Missouri indi-
cate moderate to high energy, shallow bioturbated subtidal and
shoal environments. These shallow environments were, however,
probably many miles from the nearest shorelines of the widespread
epeiric seas. However, the facts controlling the dispersal of the
genus remain still poorly understood.

PALEOGEOGRAPHY OF ORDOVICIAN RECEPTACULITIDS

Reconstruction of Ordovician continental positions is helpful in
our understanding of the latitudinal distribution of the Ordovician
members of the genus Receptaculites.

For post- Permian time the continental reconstructions are based
on data derived from the magnetic anomalies of the oceanic crust,
geographic fits, and paleomagnetic determinations; for pre-
Permian time the information on the relative positions of continen-
tal plates is much more difficult to obtain. Apparent polar wander-
ing paths for well-defined plates can be used, but other sources are
required to fix absolute positions on the globe and the relative
positions of the various plates to one another.

Several reconstructions of continental positions are available for
the Ordovician. Smith et al. (1973, text-fig. 13) present a Cambrian
to Lower Ordovician map; Whittington and Hughes (1973, text-fig.
2) offer a modification of it; Barnes and Fahraeus (1975, figs. 4 and
5) published an Early and Late Ordovician continental reconstruc-
tion based in part on the map of Smith et al.

Our reconstruction and sutures are based upon McKerrow and
Ziegler, 1972, and upon Smith and Hallam, 1970, and the shape of
the Siberian plate is from McKerrow (pers. comm.). Unlike Barnes

NITECKI & FORNEY: ORDOVICIAN RECEPTACULITIDS

103

TABLE 1. SELECTED ORDOVICIAN PALEOMAGNETIC POLE

POSITIONS FROM EUROPE AND NORTH AMERICA

(Van der Voo, pers. comm.).

Reference

Pole

Location

Age

Position

EUROPE:

Aberdeenshire,

MO 470

11°N 189°E

Scotland

Girvan,

LO 510?

11°N 168°E

Scotland

Lake District,

UO 445

9°N 176°E

England

Lake District,

UO 445

28°N 188°E

England

Wales

UO 435

2°N 182°E

Wales

MO 470

16°N 179°E

Norway

UO 440

14°N 180°E

Sallomy and Piper, 1973
Nesbitt, 1967, p. 49

Briden and Morris, 1973,

p. 38
Briden and Morris, 1973,

p. 41
McElhinny, 1973, no.

WE 3.5
McElhinny, 1973, no.

WE 3.2
Piper, 1974, p. 383

Mean

13°N 180°E

Pole

•JORTH AMERICA:

New York, USA

MO

36°N 114°E

McElhinny and Opdyke,
1973, p. 3,697

New Jersey, USA

UO-LS

35°N 126°E

Proko and Hargraves,

435

1973, p. 185

Mean
Pole

36°N 120°E

and Fahraeus, we have omitted New Zealand from our map because
evidence is not available on its position.

No paleomagnetic data are available to place China and Mexico
on an Ordovician map. Smith et al. attach China to Siberia while
Barnes and Fahraeus attach it to Australia. China is not relevant to
our interpretation, therefore it is left out of our Figure 4.

Our reconstruction of Middle Ordovician continental positions
(fig. 4) is based on newer European, North American, and Austra-

104 FIELDIANA: GEOLOGY, VOLUME 37

lian paleomagnetic studies and on older studies from Siberia.
McElhinny and Embleton (1974) based a new path of apparent polar
wander for the southern continents on the Gondwana reconstruc-
tion of Smith and Hallam (1970). When their southern continents
are reassembled, the individual polar tracks converge for much of
the Paleozoic. For Gondwana, the Cambrian and Ordovician south
pole centers (with respect to Africa) in the Mediterranean just east
of Tunisia. This pole is used to position Gondwanaland in our Figure
4. A new pole for the Ordovician Gondwana (McElhinny and Emble-
ton, 1974) places Argentina in a latitude lower than any of the other
maps.

The new Ordovician mean poles for North America and Europe
(table 1) are based on a re-evaluation by Van der Voo (pers. comm.)
using reliability criteria of Van der Voo and French, 1974. The
mean pole position for Europe differs only slightly from previous
values of 7°N 180°E (Smith et al., 1973, p. 10), or 10°N 176°E
(McElhinny, 1973), but the North American mean pole differs
considerably from previous determinations. The position of North
America in the reconstruction of Smith et al. (1973, fig. 14) is based
on a Cambrian pole at 7°N 140°E. McElhinny (1973) stated that this
North American Ordovician pole (28°N 192°E) was questionable.
The pole used to position North America in Figure 4 is the mean of
values obtained by Proko and Hargraves (1973) and McElhinny and
Opdyke (1973).

All these values are based on samples from rocks that can be
proved to have been heated at least 300° C which makes them
questionable (Bergstrom, pers. comm.). Bergstrom's (unpublished)
data from thermally unaffected Arenigian and Llanvirnian lime-
stones from the Baltic Shield give a pole position for the Baltic
Shield during Arenigian time of 34°N 47°E. This, according to
Bergstrom, fits well with sedimentological and faunal data, and
suggests that the Baltic limestones in Early and Middle Ordovician
time were cold water sediments, not tropical.

Continental positions in Figure 4 indicate that R. oweni and
R. camacho, like Devonian receptaculitids (Byrnes, 1968), were
tropical plants. In North America,/?, oweni was restricted to lati-
tudes between 20°N and 20°S, while the South American locality of
R. camacho was at 15°S. The earliest occurrence of R. camacho in
South America suggests that the descendents of this species mi-
grated eastward to North America, where they evolved into R.

105

106 FIELDIANA: GEOLOGY, VOLUME 37

oweni. A single subgenus possibly consisting of these two species
was distributed over a large area and in deep water, just as some
modern genera of Dasycladales are distributed.

Middle Ordovician ocean currents have been drawn (fig. 4), by
analogy with the present day ocean currents. Today, surface ocean
currents usually are broadly aligned along the direction of major
wind belts. If continents were not exposed, zonal ocean currents
would simply circle the globe. This is seen today in latitudes without
exposed land, and the Antarctic Circumpolar Current is such a
zonal current.

However, when north to south land barriers are present, the
circumglobal zonal currents are deflected and produce gyres. Mod-
ern wind belts cause two gyres, one in each hemispheric ocean
basin: an anticyclonic gyre (5 to 45 degrees latitude) and a cyclonic
gyre (45 to 65 degrees latitude). Figure 4 shows zonal currents when
no interfering land masses are present, and gyres when land masses
interfere with and deflect zonal currents. We assume that the Or-
dovician wind belts had approximately the present position. There
is evidence that the length of day was about 10 per cent shorter in
the Devonian than it is today (Mazzullo, 1970). The faster rotation
of the earth during that time would tend to move the dry belts and
wind belts slightly closer to the equator, but this would be unnoticed
on the scale of our map.

SYSTEMATICS
Receptaculites camacho n. sp. Figure 3.

Name. — Named for Professor H. H. Camacho, Buenos Aires Uni-
versity, who provided the specimen described here.

Definition. — Large, flattened globose Receptaculites; branches
very short and small; bases of branches irregular, heavily calcified,
forming an inner wall; shaft of lateral short and thin (in adult rarely
over 5 mm. in length); thin, small, four-ribbed stellate structures in
two planes; plates thin with central knobs.

Holotype. — A single, upper part of thallus, PP 19881 (shown in
fig. 3), deposited in Field Museum of Natural History.

Stratigraphic position and locality. — San Juan Formation,
Talacasto Gorge, Argentine Precordillera.

NITECKI & FORNEY: ORDOVICIAN RECEPTACULITIDS 107

CONCLUSION

We know nothing of the method of dispersal of receptaculitids,
and it is clear that the living relatives (Dasycladales) are not now
inhabiting the ecological niches formerly occupied by receptaculi-
tids. Dasycladales live in wide geographic areas, and their distri-
bution is largely temperature controlled. It appears, however, that
we can infer the receptaculitid environment. R. oweni and R.
camacho are closely related, and because the North American
occurrence ofR. oweni is stratigraphically restricted (Galena and
Kimmswick Formation), and because the lithologic character of
enclosed rock is very similar, we propose that the earlier South
American occurrence represents, nevertheless, a similar environ-
ment. This environmental interpretation indicates environmental
similarities, but no conclusion about the relative positions of the
continents could be based solely on the distribution of receptaculi-
tids. Our conclusions about continental positions are independent of
the distribution of Receptaculites and are based on tectonic and
paleomagnetic data. Thus this new distributional pattern of Recep-
taculites supports but does not explain the posited relative positions
of North and South America in the Ordovician time.

ACKNOWLEDGEMENTS

We are grateful to H. H. Camacho for providing the specimen from
Argentina; B. A. J. Baldis for stratigraphic and geographic informa-
tion; R. Van der Voo for paleomagnetic data; C. S. Scotese for
computer graphics; and C. R. Barnes, S. M. Bergstrom. and our
colleagues at Field Museum for reading the manuscript. Richard
Roesner prepared the drawings. Research has been supported by
National Science Foundation grant DEB 77-11129.

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108 FIELDIANA: GEOLOGY, VOLUME 37

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