The
origin, affinity and paleoecology of macrofossils of soft-bodied
organisms of the terminal Ediacaran Period have been highly debated.
Previous discoveries in South America are restricted to small shelly
metazoans of the Nama Assemblage. Here we report for the first time the
occurrence of discoidal structures from the Upper Ediacaran Cerro Negro
Formation, La Providencia Group, Argentina. Specimens are preserved in
tabular sandstones with microbially-induced sedimentary structures.
Flute marks and linear scours at the base of the sandstone layers
indicate deposition under high energy, episodic flows. Stratigraphic,
sedimentologic, petrographic and taphonomic analyses indicate that the
origin of these structures is not related to abiotic process.
Preservational and morphological features, as invagination and the
presence of radial grooves, indicate that they resemble typical morphs
of the Aspidella plexus. The large number of small-sized
individuals and the wide range of size classes with skewed distribution
suggest that they lived in high-density communities. The presence of Aspidella
in the Cerro Negro Formation would represent the first reliable record
of Ediacaran soft-bodied organisms in South America. It also supports
the paleogeographic scenario of the Clymene Ocean, in which a shallow
sea covered part of the southwest Gondwana at the end of the Ediacaran.
Introduction
Macroscopic fossils ascribed to soft-bodied organisms1,2
found in terminal Neoproterozoic rocks (Ediacaran, 635–541 Ma) are
among the earliest records of morphologically complex life forms3,4. These fossils may represent a mixture of stem- and crown-group metazoans, as well as extinct kingdom of eukaryotes5
or higher order clades with no modern representatives. They are
preserved as impressions with distinct taphonomic modes or styles, and
are grouped into the Avalon, White Sea and Nama assemblages6.
Fossils assigned to the Avalon assemblage (575–560 Ma) are best known
from various localities in Eastern Canada and from the Charnwood Forest,
England, and may represent an early evolutionary stage of the
morphologically complex macroscopic organisms. Despite their low
taxonomic richness, the Avalon organisms represent forms preserved in situ that thrived in deep-water marine settings (but see7 and references therein for distinct interpretations), nearly 5 Ma after the 580 Ma Gaskiers glaciation4.
The younger White Sea assemblage (560–550 Ma) holds the highest
taxonomic diversity, with the best-preserved and most-diverse
occurrences recorded in deposits of Australia (Flinders Ranges) and
Europe (White Sea coast of Russia), typically in marine settings above
storm wave base with seafloors covered by microbial mats8.
The Nama assemblage, although Ediacaran (550–541 Ma), is distinct from
the younger assemblages as it records the earliest known members of
calcified metazoans (e.g., Cloudina, Corumbella) instead of soft bodied organisms and with an apparent decline in taxonomic richness5,6.
To
date few dozens of species assigned to soft-bodied, macroscopic
discoidal organisms ascribed to typical Ediacaran holdfast structures
have been described from several localities in major continents2. The taxonomic and evolutionary affinities of those discs have been highly debated and assigned to microbial colonies8, individual2 and frondose organisms9, and even convergent styles of preservation of distinct organisms10.
Except for rare examples in which the disc-shaped forms were found
attached to their corresponding fronds, the majority of specimens
reported are solely discs; the difference in number of discs and fronds
has been tied to taphonomic and biologic (i.e., onthogenetic) reasons
(e.g., refs 9, 10, 11,
and references herein). Here we describe soft-bodied discoidal
specimens from the La Providencia Group, Buenos Aires Province,
Argentina, with several typical features of macrofossils of the
Ediacaran Aspidella plexus9.
The new finding adds information on the distribution and preservational
style of Ediacaran fossils worldwide. Also, it helps to resolve the
paleogeographic scenario of the southwestern Gondwana during the
terminal Neoproterozoic, in which the Río de la Plata Craton reached the
west coast of the Clymene Ocean as part of the southeastern Gondwana.
The South American record of Ediacaran macrofossils
Pioneer works12 and subsequent advancing reports in the 80’s13,14,15 have revealed the presence of remains of probable biological origin in South American Neoproterozoic successions7,16.
Those, however, are limited to calcified metazoan remains, trace
fossils, algae, acritarchs and vendotaenids and are scarce and poorly
documented when compared with typical Ediacaran assemblages recorded in
Africa, Australia, Canada, England and Russia.
The most diverse
South American assemblage of Neoproterozoic body fossils was described
from the late Ediacaran Corumbá Group, Mato Grosso do Sul, Brazil, and
includes acritarchs1, the calcified or organic-walled macroscopic Cloudina lucianoi14, Corumbella werneri13 and extremely rare conulariids17.
Recent discoveries of skeletal organisms of the Nama Assemblage
considerably encouraged the study on taxonomy, taphonomy and
paleoecology of Ediacaran assemblages in South America18,19,20,21.
Apart of skeletal records of acritarchs16,18, calcified or organic-walled macroscopic Cloudina lucianoi14, Corumbella werneri13 and extremely rare conulariids17
recorded in the Ediacaran Corumbá Group, Mato Grosso do Sul, Brazil,
impressions of macroscopically complex, soft-bodied organisms are scarce
in South American deposits of this age22,23,24.
Siliciclastic sedimentary strata preserved in the Neoproterozoic Itajaí
Basin, southern Brazil, record poorly preserved impressions assigned to
Parvancorina sp., Charniodiscus? sp. and Cyclomedusa sp23.
On the other hand, supposed impressions of soft-bodied specimens were
reported from a fluvio-marine succession in the probably Cambrian
Jaibaras Basin, northeastern Brazil24.
However, the nature of those “impressions” is still controversial,
mainly due to: (a) their extremely poor preservation, (b) the deep
weathering of structures and rock matrix, (c) their preservation within a
fluvio-marine succession, (d) the low number of structures in the same
bedding plane (except for the Jaibaras Basin), in clear contrast with
their large abundance in the best known Ediacaran occurrences4,
(e) their much larger sizes when compared with other well-accepted
records, and (f) unreliable depositional ages of the units containing
the dubious structures or fossils (especially in the case of the
Jaibaras Basin). In other circumstances, such as the Santa Barbara
Formation, Camaquã Basin, southern Brazil, the exclusively continental
depositional environment of the successions25
inhibits the occurrence of fossilized marine organisms. In fact, in
these examples many discoidal structures may correspond to sedimentary
structures, such as tool marks, overload structures, wrinkle marks,
pseudofossils and even ring-shaped microbial colonies8.
Geologic setting
The
Tandilia System is a 350 km long northwest-to-southeast orographic belt
located in the southern of the Buenos Aires Province (Fig. 1A).
The unit encompasses igneous and metamorphic rocks of the
Paleoproterozoic basement covered by Neoproterozoic sedimentary
successions. In the Olavarría area, the stratigraphic column shows
~250 m thickness (Fig. 1B) and is composed of the lower Sierras Bayas Group26 and the La Providencia Group27,
which is subdivided in the Avellaneda, Alicia and Cerro Negro
Formations. The Sierras Bayas Group is separated from the overlying La
Providencia Group by an erosional unconformity related to eustatic
sea-level drop. However, the poor age constraint of the unit precludes a
precise estimation on the time range of this hiatus. The Cerro Negro
Formation exceeds 100 m in thickness and consists of
centimeter-to-decimeter tabular and lenticular beds of terrigenous
rocks, arranged as cyclic intercalation of massive and trough
cross-bedding fine-grained sandstones, massive red mudstones and
heterolithic facies (Fig. 1C).
This association indicates traction currents/waves alternating with
periods of slack water. The base of the unit shows several levels
recording microbially induced sedimentary structures (MISS) and rare mud
cracks, which suggests that the sedimentation in this part of the
succession occurred under shallow water conditions with sporadic
subaerial exposure, typical of a deposition in subtidal environment.
Figure 1
(A)
Location of the Tandilia System, Buenos Aires Province, Argentina, and
geologic map of the Olavarría area (map made by MJ Arrouy in Corel Draw
X7 software). (B) Lithostratigraphic section of Sierras Bayas and La Providencia Groups. (C)
Stratigraphic section of the shallow marine and tidally influenced
facies of the Cerro Negro Formation. Fm.–Formation, S–Siltstone, Fs–Fine
sand, Mf–Medium sand, MISS-Microbially Induced Sedimentary Structure.
The paleontological content of the Neoproterozoic units of the Tandilla System is poorly known. The supposed presence of Cloudina28
is based on specimens recorded in thin sections of micritic limestones
of the Loma Negra Formation. However, because those remains are poorly
preserved, their biogenic origin is controversial, and additional
specimens are necessary to confirm or refute their taxonomic
identification. Acritarchs described in the Cerro Largo and Cerro Negro
formations consist of simple sphaeromorphs, such as Synsphaeridium sp., Trachysphaeridium sp. and Leiosphaeridia sp., compatible with an Ediacaran age for both units5.
Specimens from the Cerro Negro Formation (La Providencia Group)
The
newly recorded assemblage from the Cerro Negro Formation includes
macroscopic discoidal forms, rare ichnofossils and sedimentary
structures ascribed to MISS structures29,30.
The discoidal forms are preserved in at least four stratigraphic levels
within a 15 m thick interval at the middle portion of the Cerro Negro
Formation (Fig. 1C). The discs occur as dozens to more than a hundred (Fig. 2A,B)
forming discrete pavements in the underside of tabular fine-grained
sandstone beds interbedded with micaceous red siltstones and mudstones.
Flute marks and linear scours (Fig. 2C)
occurring in the base of sandstone layers suggest deposition by
episodic flows (as tempestites under shallow water conditions).
Figure 2: Size variation and morphology of Aspidella plexus from the Cerro Negro Formation, La Providencia Group.
(A,B) Samples showing several specimens with great variation in size. (C)
Medium sized (around 35 mm) discoidal convex specimen with a small boss
in the center and very low creases, preserved as negative epirelief
(upper) and full relief (lower). (D) Pavement showing several specimens with puckered features. (E) Detail of negative epirelief specimen with radial folds (puckered features) and invaginated center. (F,G) Specimens with invaginated centers preserved in negative epirelief, with a full relief specimen counterpart. Scales: (A), 10 cm, (C,E,F), 1 cm, (B) the hammer is 27,9 cm long.
The
discoid- to ovoid-shaped forms occur as low positive epirelief of
distinct sizes and show an apparent convex surface with a concentric
depression surrounding a central rounded projection (Fig. 2A,B). Some specimens, especially the large ones, are strongly ornamented with radial grooves (Fig. 2E). The convex specimens are isolated individuals or are grouped in small localized clusters (Fig. 2A,B).
The individuals have diameters ranging from 6 mm to 140 mm, with the
majority of the specimens reaching 10 mm to 26 mm. The smallest
individuals (>30 mm in diameter) are the most frequent. They are
conspicuously rounded and completely smooth (Fig. 2A,B). The specimens ranging from 30 mm to 65 mm have a small boss in the center reaching maximum height of 3 mm (Fig. 2C).
When detached from the fine sandstone bed, each specimen comprising
full relief shows a somewhat lenticular transverse section with a lower
surface bearing irregular radial folds and grooves and a central rounded
pit, leaving its corresponding impression as negative epirelief (Fig. 2D–G). They commonly show an invaginated center, creases and strong radial grooves extending from the center to margin of the disc (Fig. 2E). The medium-sized discs are enclosed by a single circular ridge and preserve typical puckered features in their counterparts (Fig. 2F,G).
The largest discs comprise convex forms (positive epirelief) with
diameters varying from 65 mm to 100 mm. Their morphology resembles that
of the medium-sized discoidal forms.
Apart of the abundant discs, some extremely rare forms (<1 a="" analyzed="" data-track-dest="link:Fig. 3A,B" data-track-source="figure-anchor" data-track="click" href="http://www.nature.com/articles/srep30590#f3" of="" specimens="" the="">Fig. 3A,B
)
show a somewhat straight structure close to the central part of the
disc that resembles frond-like structures. These putative fronds are
preserved in positive epirelief as attached to their corresponding
holdfasts by a single stem that emerges from the central portion of the
discs (Fig. 3A).
The slightly curved frond-like structures range from 50 mm to 70 mm and
apparently have a delicate and thin central stem that divide
symmetrically the supposed petal. The possible petalodium emerges few
millimeters above the frond-like structure and holdfast junction (Fig. 3B) and resembles the charnid morphology31.
However, the absence of any visible ornamentation (as internal features
and rays) makes it impossible to assign the few available specimens
with one specific rangeomorph taxa.
Figure 3: Macro and microscopic diagnostic features of Argentinian discoidal fossils.
(A)
Positive epirelief view showing a structure similar to an attached
stalk and frond. A white arrow points the putative connection between
the holdfast and the stem. (B) Detail of a complete specimen,
including a structure interpreted as a possible set of holdfast and
frond. Note that the structure that supposedly corresponds to a
recumbent frond overlaps at least four small discs. (C–F) Two full-relieves of discs in cross section ascribed to Aspidella (C–F) are parts and counterparts of the section). Scales: (B), the coin has 2.5 cm in diameter; (C–F), 1 cm.
Thin
perpendicular sections show various preservational features that are
similar to those also observed in the material from the Fermeuse
Formation9 (Fig. 3C–F).
These include a prominent “V” shaped invagination at the central
portion of the disc that in some cases deform the underlying laminae (Fig. 3F), as well as slumping and complex filling by sand (Fig. 3C–F). Some specimens (Fig. 3D–F) show a particular convex-up laminated sandy filling pattern.
The
MISS structures developed on fine-grained sandstone substrates are
common in the intermediate portion of the Cerro Negro Formation (Fig. 4).
Basically, the biogenicity of those structures can be attested by (a)
their occurrence in depositional facies indicating clear water, moderate
wave energy and quartz sand bottoms32, (b) variable morphologies reflecting local hydrodynamic conditions32, and (c) particular textures characterized by crinkly carbonaceous laminae with trapped clastic grains33.
The presence of elongate and bifurcated forms with flat-topped crests
separated by parallel shallow depressions (Fig. A), which rarely form
honey-comb configuration suggests that these can be ascribed to Kinneyia wrinkle structures. The structure show in Fig. 4B
is characterized by slightly curved subparallel flat-topped ridges
(locally bifurcated) with height less than 0.2 mm and separated by
linear grooves. The morphological complexity of these forms allows us to
associate them with the problematic fossil Arumberia (especially the Arumberia banski30,
interpreted as a structure formed by very complex and non-actualistic
type of microbial community that colonized very shallow waters30).
Other wrinkle marks show irregular reticulate pattern formed by
coalescent nodules and asymmetrical polygons, which are typical of
“elephant skin” structures (Fig. 4C).
The recurring MISS associated with the fine-grained sandstone beds are
mat deformation structures strongly folded and curved (Fig. 4A).
The presence of MISS in fine-grained sandstone beds suggests that the
substrates were continuously sheltered by microbial mats, reinforcing
the intrinsic association between biomats and the preservation of the Aspidella discoidal holdfast31.
Ediacaran terrigenous sediments typically show low degree of
bioturbation, which also contributes to the preservation of the basal
protuberance of Aspidella34.
Despite of this, recent studies indicate that those organisms may
tolerate moderate levels of organic activity in the substrate35.
Figure 4: Wrinkle structures of the Cerro Negro Formation, La Providencia Group.
(A) Several small and simple traces on a wave rippled surface. (B) Low relief Arumberia type structure with aligned crests developed on the upper surface of a ripple marks. (C) Elephant skin structure showing typical reticulate and wrinkly pattern. (D) Detail of bed-parallel bilobed trace fossil assigned to cf. Archaeonassa. Scales: (A), the hammer is 27,9 cm long (C), 2 cm; (D), 1 cm.
The
ichnofossils are very rare and occasionally occur associated with mat
deformation wrinkles. Bilobed structures preserved in positive epirelief
are characterized by unbranched and slightly curved horizontal traces
with two longitudinal transverse ridges separated by a central
depression (Fig. 4D). They usually are found below the MISS and are similar to the ichnogenus Archaeonassa.
This type of trace fossil was previously interpreted as an undermat
tunnel made by a bilaterian organism near the sediment-water interface36.
Affinity of Cerro Negro discoidal fossils
Discoidal
structures in sedimentary rocks can be formed by distinct abiotic and
biotic processes. Various sedimentary discoidal structures may derive
from concretions, molds and casts of nodules, gas and fluid escape
conduits, mounds and craters37.
The stratigraphic interval where the discoidal structures were recorded
is mainly characterized by sandstones deposited in shallow water
conditions with no evidence of methane or other hydrocarbon seeping.
Indeed, the shape (in plan- and cross-section views) and dimensions of
discoidal structures are incompatible with those observed in mud
volcanos, mounds, conduits, and domes associated to seeping. Not
surprisingly, gas and fluid scape microstructures are missing in the
polished slabs (Fig. 3). Evidences of concretions or nodules are also absent (Fig. 3).
We also exclude other inorganic processes, such as scratch circles made
by wave-induced rotation of anchored objects or even that they may
represent giant foraminifers38,39.
Hence, based on the evidences below, we think that an exclusively
organic origin is the most plausible explanation for the origin of the
discoidal structures of the Cerro Negro Formation, mainly due to: (a)
lack of tool marks and incomplete, simple, or double rings produced by
partial rotation of stalked objects in the same bedding planes where
they are abundant (or organisms); (b) radial circles are rare and, when
observed, they are not concentric as in the fake Kullingia of Newfoundland38; (c) absence of micro and thin radiate pattern as found in false discoidal fossils (e.g., Ediacaria samples from Russia8);
(d) the boss or tubercle of each specimen is not perfectly centered,
which points to some morphological variation more common of structures
of biologic origin (Fig. 2C–G);
(e) absence of tube-like or channelized features or conduits in the
internal part of the discs linking to the central boss, that could be
interpreted as fluid or gas scape structures (Fig. 3C–F); (f) the discs are developed tridimentionally inside and above the substrate level in several size classes (Fig. 5); (g) presence of distinct forms (morphs9) represented by hundreds of specimens (Figs 2 and 3)
and rare, but diagnostic, frond-like projections; (h) specimens that
are closely preserved are deformed only at the touching margins,
indicating that they are not coalescent and, thus, each individual is an
independent entity (Fig. 5B–i); the lack of overlapped specimens rules out that they could be traces, or even scratch circles (Fig. 5B).
Figure 5: Aspidella specimens from the Cerro Negro Formation, La Providencia Group.
(A)
A hundred specimens of discs preserved in a pavement. Note the
predominance of specimens smaller than 20 mm and some “giant” specimens
with maximum size of 150 mm. (B) Pavement showing a large number
of discs with different sizes. Note the lack of overlapped specimens and
the slightly deformation in the tangent discs indicated by white
arrows. (C) Size distribution of all Aspidella in the pavement sample showed in (A). Scale (A,B) the hammer is 27, 9 mm.
Preservation,
general morphology, number of specimens, and their shape and size
classes are all similar to that observed in typical Aspidella specimens. In particular, the invagination at center, the presence of a central boss (Fig. 2C) as well as the marginal grooves that can form puckered features (Fig. 2D–G) are all structures typically observed in Aspidella. Convex-up laminations in some specimens (Fig. 3D–F) can be associated with the collapse of the organism during sandy infilling events, in a typical pattern previously described9. In some specimens, the projected central structure could be interpreted as the insertion of a stem-like structure9.
The
absence of specimens with concentrically ornamented central disc,
irregular radial structures and concentric ridges and grooves precludes
classifying them as Ediacaria or Spriggia2. Also, the absence of branching radial segments rules out their assignment to Hiemalora2;
similarly, their puckered pattern is very distinctive from the
concentrically increasing lobes or tentacle-like delicate spokes of the
genus Mawsonites40, or even other concentric-bearing discoidal fossils8,41.
It
is important to note that, despite several efforts to understand the
taxonomy, taphonomy and paleoecology of the early discoidal fossils, no
formal taxonomic revision was so far proposed for the Aspidella species and other possible synonymous taxa and related forms2,9,42,43. Considering this, we include the Cerro Negro specimens as belonging to the Aspidella group, or “plexus”8.
Paleoecology and Taphonomy: implications for the Age of the La Providencia Grouph
The large density of individuals (~500 specimens per m2) observed in various pavements (Fig. 5A–B) suggests that the Cerro Negro discs lived in high-density populations, as previously observed in other Ediacaran occurrences9. This pattern of preservation is commonly found in other worldwide Aspidella records and is also noted in modern sessile benthic communities with high juvenile mortality9,43. The size class distribution of the Cerro Negro specimens (Fig. 5C)
also suggests no size-selection prior to the final burial. Yet, they
were preserved in sandstones generated by high energy sedimentary
processes, indicating that the community was smothered by episodes of
rapid sedimentation. The predominance of small individuals indicates
that the original living population was mainly composed of minute
specimens. The size variation in individuals from the same bedding plane
also indicates that the specimens with different dimensions (or even
distinct morphologies) are not restricted to a particular bedding plane
or strata. Consequently, they are not limited to a specific environment
or depositional setting within the examined sedimentary succession.
Unlike previously reports43
our data suggest some relationship between size distribution and
morphology of the discs. For example, the small individuals (<14 70="" are="" could="" denote="" different="" in="" individuals="" large="" mm="" of="" ones="" ontogenetic="" preservation="" puckered.="" smooth="" stages="" sup="" the="" this="" to="" up="" usually="" whereas="">9,43
, bearing distinct morphological characters.The preservation of specimens from the Cerro Negro Formation is typical of “death mask” style1 reported for Aspidella specimens by previous authors9
being compatible with the three hyporelief morph types. As commented
above, some are also characterized by creases and folds, and may
correspond to external molds of the upper surface of holdfasts (i.e.,
puckered morphology43). Various features found in the Cerro Negro assemblagemm are typical of the “Fermeuse-style” of Ediacaran fossil preservation44, such as: (a) the density and abundance of disc-shape fossils (Aspidella)
in various distinct bedding planes at the base of sandstones,
representing event beds; (b) the skewed size distribution of the
specimens occurring in the same bedding plane with predominance of
smaller ones; c) the presence of rare trace fossils; and (d) the rarity
of fronds and other rangeomorphs.
However, despite the
similarities of both assemblages is noteworthy that the Cerro Negro
Formation was deposited in very shallow water conditions (subtidal to
tidal setting) whereas the Fermeuse Formation was deposited below fair
weather wave base by storm- or turbidite-induced events. In addition,
due to the strong association with microbial mats and shallow water
settings, the preservation of the probable Aspidella from South America also resembles that of the “Flinders-style”43. The three dimensional preservation of the studied specimens, including both flat to convex forms9 as well as the puckered ones2,43 may represent one of the most complete spectrum of preservation of members of the Aspidella group.
The discoidal fossils are more commonly found in Ediacaran deposits, but there are also scattered occurrences in Cryogenian2 to Early Paleozoic successions45. However, as commented above, diagnostic features indicative of older (Cryogenian) or younger organisms (Early Cambrian, as Nimbia or Tirasiana46) are lacking, which reinforces the assignment of the Argentinian discs to Ediacaran Aspidella group9. Despite some uncertainties about the precise age of the studied Neoproterozoic discoidal fossils2,42, the occurrence of Aspidella constrains the age of the La Providencia Group to the terminal Ediacaran5,9. Additionally, the presence of ichnofossils in the same assemblage reinforces an age no older than 565 Ma47.
Paleobiogeographic distribution: implication for Gondwana reconstruction
The
Argentinian geotectonic province of Tandilia was located in the
southwestern portion of the Río de La Plata Craton and corresponds to a
narrow strip composed of Paleoproterozoic basement units covered by a
slightly deformed Neoproterozoic succession. Available paleomagnetic
reconstructions for the Río de La Plata Craton during the Upper
Ediacaran (575 Ma) indicate that this plate was separated from Laurentia
and probably it was linked with the São Francisco craton in
intermediate to low latitudes48.
It is probable that at 550 Ma these cratonic masses were already part
of the proto-Gondwana supercontinent being isolated from the
Amazonia/Río Apa microcontinents by the short-lived Clymene Ocean49 (Fig. 6).
During the Upper Ediacaran, the paleogeographic scenario of the
proto-Gondwana indicates a prominent open passive margin to the east49 in which several carbonate platforms and shallow marine successions were deposited. The position of the Río de La Plata48,50
in the context of the proto-Gondwana reinforces the hypothesis of
oceanic opening to the east and deposition of the upper portion of the
La Providencia Group under fully marine conditions (Fig. 6).
Evidences of marine deposition in the upper portion of the La
Providencia Group is attested by the presence of acritarchs, tidally
influenciated sedimentary facies27 and the Ediacaran discoidal fossils described here.
Figure
6: Schematic reconstruction of the Southeastern Gondwana paleogeography
during the end of Ediacaran with fossil occurrences.
1-Australia,
2- India, 3-Antarctica, 4-West Africa, 5-Congo–São Francisco, 6-
Kalahari, 7-Paraná, 8-Río de la Plata, 9-Amazônia, 10-Río Apa,
11-Laurentia (map made by L.V. Warren in Corel Draw X7 software).
Recent reconstructions support a marine ingression over continental areas in the eastern proto-Gondwana18,
suggesting that the carbonate platforms represented by the Bambuí
(Brazil), Nama (Namibia) and Arroyo del Soldado Groups (Uruguay) as well
as the Taylor Formation (Antarctica) were developed in the same shallow
eperiric sea. In this context, the marine deposition of the Cerro Negro
Formation extends the scenario of widespread tidal flats opened to the
east to as early at the end of Ediacaran. The complete closure of the
Clymene Ocean along its 3000 km length took place in the early to
mid-Cambrian51.
This geotectonic event was responsible for the deformation of the
short-lived basins in the paleo margins of the proto-Gondwana,
encompassing sedimentary successions in Africa and South America.
The
presence of Ediacaran fossil assemblages in Brazil, Namibia, Antarctica
and now in Argentina reinforces the hypothesis of a vast seaway that
connected to the Clymene Ocean during the terminal Ediacaran18,52,53.
Despite its indisputable paleogeographic significance, the Cerro Negro
biota is the first record of Ediacaran soft-bodied macrofossils in South
America. This opens new avenue to our understating on the composition
and ecology of the Ediacaran life in the shallow water settings
developed in the first marine basins of the Gondwana paleocontinent.
Methods
We
collected specimens from a 15 m thick interval of tabular, fine-grained
sandstones in the Cerro Negro Formation. Numerous meter-sized slabs
were extracted from outcrops and quarry walls. In addition, samples of
fallen rock were also collected in the mining area of the Cementos
Avellaneda S.A, Olavarría, Argentina. In laboratory, samples were
prepared according standard paleontological techniques, and then
specimens were measured with digital calipers. Slabs and specimens were
photographed and analyzed regarding morphology and taphonomy, including
determinations of size classes, thicknesses, modes of preservation
(epirelief, hyporelief, full relief), presence of coalescing specimens
and presence (or absence) of radial or concentric ornamentations. Thin
sections, perpendicularly cutting the discoidal structures, were also
prepared, analyzed and imaged. The studied specimens are deposited in
the Centro de Investigaciones Geológicas – CONICET – Universidad
Nacional de La Plata, La Plata, Argentina.
Additional Information
How to cite this article: Arrouy, M. J. et al. Ediacaran discs from South America: probable soft-bodied macrofossils unlock the paleogeography of the Clymene Ocean. Sci. Rep.6, 30590; doi: 10.1038/srep30590 (2016).
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We
are grateful to two reviewers and the editor for their extensive and
very constructive comments, which greatly helped to improve the
manuscript. The authors also thank the Cementos Avellaneda S.A for
logistic support in the field. Financial support provided by CNPq
(project 444070/2014-1) and FAPESP (project 2015/24608-3).
Author information
Affiliations
Centro de Investigaciones Geológicas – CONICET – FCNyM (UNLP), Diagonal 113 N°275, La Plata, Argentina
María Julia Arrouy
, Daniel G. Poiré
& Lucía E. Gómez Peral
Departamento
de Geologia Aplicada, Instituto de Geociências e Ciências Exatas,
Universidade Estadual Paulista, Avenida 24A, 1515, Rio Claro 13506-900,
Brazil
Lucas V. Warren
, Fernanda Quaglio
& Milena Boselli Rosa
Curso
de Geologia, Instituto de Geografia, Universidade Federal de
Uberlândia, Rodovia LMG 746, Km 1, Monte Carmelo 38500-000, Brazil
Fernanda Quaglio
Departamento
de Zoologia, Instituto de Biociências, Universidade Estadual Paulista,
Distrito de Rubião Júnior, Botucatu 18618-000, Brazil
Marcello Guimarães Simões
Contributions
Fieldwork:
M.J.A., L.V.W., D.G.P. and M.B.R. Conceived and designed the
experiments: M.J.A., L.V.W., F.Q., M.G.S. and M.B.R. Analyzed the data:
M.J.A., L.V.W., F.Q., M.G.S. and L.E.G.P. Contributed materials/analysis
tools: M.J.A., L.V.W. and F.Q. Wrote the paper: M.J.A., L.V.W., F.Q.
and M.G.S. Photography and Figures: M.J.A., L.V.W., L.E.G.P. and M.B.R.
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