New fossil assemblages from the Early Ordovician Fezouata Biota | Scientific Reports – Nature.com

0
129

Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles and JavaScript.
Advertisement
Scientific Reports volume 12, Article number: 20773 (2022)
250 Altmetric
Metrics details
The Fezouata Biota (Morocco) is a unique Early Ordovician fossil assemblage. The discovery of this biota revolutionized our understanding of Earth’s early animal diversifications—the Cambrian Explosion and the Ordovician Radiation—by suggesting an evolutionary continuum between both events. Herein, we describe Taichoute, a new fossil locality from the Fezouata Shale. This locality extends the temporal distribution of fossil preservation from this formation into the upper Floian, while also expanding the range of depositional environments to more distal parts of the shelf. In Taichoute, most animals were transported by density flows, unlike the in-situ preservation of animals recovered in previously investigated Fezouata sites. Taichoute is dominated by three-dimensionally preserved, and heavily sclerotized fragments of large euarthropods—possibly representing nektobenthic/nektic bivalved taxa and/or hurdiid radiodonts. Resolving whether this dominance reflects a legitimate aspect of the original ecosystem or a preservational bias requires an in-depth assessment of the environmental conditions at this site. Nevertheless, Taichoute provides novel preservational and palaeontological insights during a key evolutionary transition in the history of life on Earth.
The Early Ordovician Fezouata Biota of Morocco is an exceptionally-preserved fossil assemblage that contains a combination of non-mineralized extinct organisms that have become synonymous with the Cambrian Explosion, such as radiodonts, lobopodians, nektaspidids, and marrellomorphs, alongside more derived forms that are representative of typical Palaeozoic faunas, such as xiphosurans and machaeridians1,2. To date, most palaeobiological research1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25 has focused on Fezouata fossils that occur in either upper Tremadocian or middle Floian deposits in the Zagora region (Fig. 1a,b)26, covering to some extent, the proximal–distal axis of an ancient marine environment (Fig. 1c)27,28. This environment was dominated by wave/storm processes29,30. The exceptionally well-preserved fossils in these deposits were buried in situ by storm-induced deposits close to the storm wave base (SWB)29,30,31. Lightly biomineralized or sclerotized animals in the Fezouata Biota are most commonly preserved in shales as weathered carbonaceous material (compressed to different degrees) and authigenic minerals32,33. Preservation within concretions has also been reported from this formation (Fig. 1d), but this mode of fossilization is more restricted compared to shale-hosted macrofossils34. Most Fezouata Shale fossil collections are based on discoveries around the Zagora region in Morocco (e.g., Tamegroute, Bou Izargane, and Tinzouline) (Fig. 1b)32; with little effort spent prospecting fossiliferous localities outside this area. Here, we report a new and continuous fossiliferous section from the Fezouata Shale discovered in Taichoute, 80 km away from previously investigated localities (Fig. 1a,c). We discuss the palaeontology, sedimentology, and possible preservational biases operating at this site. The Taichoute locality expands the range of depositional environments yielding non-biomineralized fossils, reveals new modes of preservation for the Fezouata Shale, and expands the occurrence of fossil-bearing strata within this formation.
(a) Stratigraphic column for the Lower Ordovician Fezouata Shale and Zini formations including the Taichoute locality divided into three fossil assemblages. The red arrow in (a) indicates an accumulation level of brachiopods and bryozoans at the top of the Taichoute section. (b) Zoom on the Zagora Region where the Fezouata Shale was discovered. (c) Taichoute is the most distal site in the depositional environment of the Fezouata Shale. (d) Concretion from the Zagora region. (e) A large lobe from the Fezouata Shale in the upper part of the succession (a3) and interpreted as a density-flow deposit.
Euarthropods, brachiopods, echinoderms, and graptolites constitute together most of the preserved biodiversity in the Fezouata Biota32, and this pattern is replicated in the newly described Taichoute locality (Fig. 2). Some animal groups such as sponges, found in some other localities (e.g., Tamegroute and Bou Izargane), remain, so far, absent from Taichoute (Fig. 2).
Faunal composition and specimen abundances for each animal group at different Fezouata Shale localities based on the Marrakech Collections of the Cadi Ayyad University (Morocco). Note that the pie chart for Taichoute excludes the accumulation level of brachiopods and bryozoans (above a3, at the top of the succession), as it is impossible to count fossil specimens on this bed. This figure does not account for all specimens recovered/observed at outcrops. For information on how this data was collected and plotted, kindly refer to the Material and Methods section.
Taichoute can be categorized by three distinct assemblages based on their diversity and preservation (a1, a2, and a3; Fig. 1a). The lowermost assemblage (a1) consists of brachiopods, gastropods (Fig. 3a), echinoderms (Fig. 3b), and graptolites (Fig. 3c). A middle Floian age for assemblage a1 can be inferred by the occurrence of Baltograptus gr. deflexus8 (Fig. 3c). Fossils from this interval are mainly found in concretions that typically contain a single specimen (e.g., Fig. 3b). The preservation of minute details, showing various stages of disarticulation and the in-situ collapse of echinoderms, with no evidence of abrasion (Fig. 3b), indicate that these animals were not transported, and concretions formed while organisms were decaying on the seafloor below the SWB in a similar way to some previously described concretion-based preservation from the Zagora region2. Another type of concretion, preserving unrecognizable bioclasts transported by storm events and formed above the SWB, has also been previously described from the Zagora region29, but has not been found at Taichoute.
Fossils from the Taichoute locality (a1: A–C, a2: D–F, a3: G–J). (a) The gastropod Lesueurilla prima. (b) The solutan echinoderm Plasiacystis mobilis. (c) The graptolite Baltograptus gr. deflexus. (de) Giant euarthropod carapaces indicated with white arrows. (d) Carapace likely belonging to previously documented bivalved arthropods from the Fezouata Biota59. (e) Two incomplete but tapering carapaces (left and center) adjacent to a structure that bears possible resemblance to a block of radiodont setal blades (right), consisting of a series of parallel elongated blades a few millimetres wide separated by slight changes in sediment level and/or by intervening sediment, with an overall tapering outline, similar to the setal blade blocks of hurdiids such as Hurdia from the Burgess Shale60. (f) The multiramous graptolite Holograptus sp. (g) The calymenid trilobite Colpocoryphe cf. thorali. (h) The illaenid trilobite Ectillaenus? sp. (i) The calymenid trilobite Neseuretus cf. attenuatus (blue arrow) and Lichidae gen. indet. (to the left of the blue arrow). (j) A dalmanitid trilobite, subfamily Zeliszkellinae. (k) Accumulations of specimens of a new genus of orthidine brachiopod and bryozoans (white arrow) on top of a3. Scale bars = 5 mm in a, f, g, h, i, j; 10 mm in b, c and k; 25 mm in d; 50 mm in e. By order from a to j: AA.TAI2.OI.9; ML20-259,357; AA.TAI3.OI.2; AA.TAI6.OI.1; AA.TAI6.OI.2; AA.TAI6.OI.6; AA.TAI13.OI.1; AA.TAI13.OI.2; AA.TAI13.OI.3; AA.TAI13.OI.4; AA.TAI14.OI.1. All specimens are housed in the Marrakech Collections of the Cadi Ayyad University.
The intermediate interval a2 (Fig. 1a) yields concretions with low taxonomic diversity consisting mainly of nautiloid cephalopods, euarthropod fragments (Figs. 3d,e and 4), and graptolites (Fig. 3f), Although there is some variability in their morphology and appearance, the euarthropod carapaces are typically oval-shaped to elongate, and they are preserved with substantial convexity and/or artefacts of previous relief that suggests a heavily sclerotized original constitution (Figs. 3d,e and 4). Coupled with their large size, ranging from ca. 5 to 15 cm in length (Figs. 3d,e and 4), and the presence of thickened marginal rims, we tentatively interpret them as corresponding to bivalved euarthropods and possibly elements of radiodonts (Figs. 3d,e and 4). Whilst preliminary, we argue that radiodont affinities are the most plausible for the fragments considering the known diversity of euarthropods during the Early Ordovician, and the fact that giant hurdiid radiodonts are well known from the Fezouata Shale5,6. The observed euarthropod carapaces (Figs. 3d,e and 4) from Taichoute are considerably larger than those described from early- and mid-Cambrian sites [e.g., Balhuticaris35; Isoxys36,37; Tuzoia37,38; Branchiocaris39,40, and Tokummia41], and are more comparable in size to stratigraphically younger euarthropods (e.g., phyllocarids) discovered in Silurian and Devonian strata42,43.
Euarthropod fossils from Taichoute interval a2. (a) Large carapace with central carina (white arrow), similar to that seen in Aegirocassis dorsal carapace elements6. Note the presence of a brachiopod on the right side under the Carina. (b) Carapace with an asymmetrically rounded outline with an anterior protrusion similar to that seen in lateral carapace elements of hurdiids60. (c) Carapace with an asymmetrically rounded outline with one side bearing a structure similar to the upturned projection (white arrow) described for Aegirocassis lateral carapace elements6. (d) Assemblage with at least three carapaces together, some of which are elongated and tapering at one end, with a partial outline possibly resembling that of lateral carapace elements of hurdiids6. Scale bars are 4 cm in a, and 3 cm in b, c, d. By order from a to d: MCZ.IP.198899, MCZ.IP.19890, MCZ.IP.198902, and MCZ.IP.198901. All four specimens are housed at the Museum of Comparative Zoology, Harvard University, USA.
Bivalved euarthropods and radiodonts are generally interpreted as primarily nektic or nektobenthic components of Palaeozoic ecosystems1,2,5,6. The dominance of nektic/nektobenthic euarthropod taxa, nautiloids, and planktonic graptolites in a2 suggests that the seafloor, above which they lived, was not suitable to sustain a diverse and abundant benthic community. However, this environment does not necessarily correspond to Taichoute, mainly because a2 concretions differ from those found in a1 in terms of their quality of fossil preservation. Specimens in a2 are fragmented (Figs. 3d,e and 4). The disarticulated nature of specimens could result from prolonged decay, which may have started in the water column during the bloating and floating stage of initial decomposition, concurrent with processes such as carcass scavenging. Disarticulation may have also resulted from fossil transport, especially given that, unlike a1, a2 concretions are generally not formed of a single specimen, and numerous fragments were often trapped within sediments, that were later consolidated in concretions (e.g., Fig. 3e). Some of these carapaces are covered by meandering traces of varying sizes across their surface, and rare brachiopod epibionts are found on some carapaces (Figs. 3d and 4a) indicating that they could have acted as nutrient sources for the community and/or as a stable substrate for brachiopods to attach to, following their transport to Taichoute, and prior to their consolidation in concretions in a244.
The upper interval a3 (Fig. 1a) consists of a large sedimentary lobe yielding fragmented bryozoans and trilobites (Fig. 3g–j). These large sedimentary bodies in the Fezouata Shale (Fig. 1e) are considered as the stratigraphically distal equivalent to the overlying proximal Zini Formation (Fig. 1a). Due to the degree of fossil disarticulation and fragmentation within this lobe, it is certain that carcasses were transported prior to their preservation. The uppermost interval, above this lobe shows an accumulation level preserving rhynchonelliform brachiopods and bryozoans in minute detail (on planar bedding surfaces, and not within concretions) with very little evidence of physical abrasion (Fig. 3k).
The Fezouata Shale sequence shallows upwards, but this is mainly evident in the Zagora area, where it ends with the deposition of the Zini Formation (Fig. 1a), interpreted as nearshore sandstones30,45. However, the entire environment represents a proximal-to-distal gradient from the southeast (in Algeria) to the northwest30,46. Thus, the shallowing-upwards sequence is not expressed in terms of facies everywhere in the Fezouata Shale. In this formation, the position of large siltstone lobes, similar to the one deposited in a3, reflects an increase in the sediment supply into the basin linked to a lowering of the base level and an increase of erosion in the shallower-water south-eastern area. These large hectometric lobes that are siltstone-dominated (Fig. 5a) with minor very fine sandstone components, and displaying dominantly planar lamination, asymmetrical cross-laminations, and reactivation surfaces (Fig. 5b,c), have been described as storm-induced, density-flow deposits in the most distal setting of the Fezouata Shale30. The interpretation of Taichoute as the most distal section is in accordance with its position in the basin and the previously defined proximal–distal axis30 (Fig. 1c). This study is the first to document fossil preservation in association with such settings in the Fezouata Shale, regardless of the fidelity or quality of this preservation. Considering the deposition continuity between a1, a2, and a3 (Fig. 5a), it is likely that all three intervals represent lateral variations of deposition, from normal sedimentation on the seafloor (a1), passing through lobe fringe (a2) to lobe centre (a3) within the same shelf setting (Fig. 6).
Sedimentary context of Taichoute. (a) Overview of the upper part of the Fezouata Shale displaying a transition between a1, a2, and a3. The large siltstone-lobes of a3 transition upward into the overlying Middle Ordovician Tachilla Formation. The white arrows show the lateral discontinuity, characteristic of the siltstone lobes. (b) The asymmetrical cross-laminations form current ripples displayed in the siltstone lobes. (c) Reactivation surfaces occur frequently in the siltstone lobes, attesting to the turbulence of repeated density flows. These deposits also display planar laminations.
The different modes of preservation within the Fezouata Shale, their distribution, and the sedimentary processes at play for their formation. SWB: Storm Wave Base.
These sedimentological interpretations complement previous studies made on the Fezouata Shale that highlighted a difference in the mechanism of fossil preservation between this Ordovician site and other Cambrian deposits preserving labile anatomies such as the Chengjiang Biota (China) and the Walcott Quarry in the Burgess Shale (Canada). It was suggested that most animals preserved near the Zagora region were preserved in-situ13,29,31 with little to no evidence of transport following death, unlike the aforementioned Cambrian sites where sedimentary flows, particularly turbidity currents, were operational, transporting animals from their living environment to facies favourable for their preservation47,48,49,50. The discovery of Taichoute increases the similarity between the Fezouata Shale and some Cambrian sites by showing that carcasses could be transported within the general context of this formation. However, the Fezouata Shale remains a unique formation with various modes of fossilisation including animal preservation (i) in accumulation levels (above a3 in Taichoute) (Fig. 1a) (ii) as bioclasts in concretions deposited above the SWB (present near Zagora); (iii) in shales around the SWB (dominant near Zagora), and (iv) under the SWB: (a) in-situ, in concretions of different sizes (similar to a1 in Taichoute and some sites near Zagora), (b) transported, in concretions (similar to a2 in Taichoute), and (c) transported, in large hectometric lobes (similar to a3 in Taichoute) (Fig. 6). This taphonomic variability is likely driven by the wide spatial and temporal distribution of the Fezouata Shale, around 850 m of sediments (Fig. 1a) over 900 km2 in the Draa Valley, spanning ~ 11 myr. This suggests that the Fezouata Shale is an ideal candidate to further investigate a possible continuum between shale and concretion preservation, and untangle the possible environmental conditions responsible for the transition between these two modes which preserve most of exceptionally preserved fossils during the Early Palaeozoic.
Non-biomineralized fossils in Taichoute are restricted to large euarthropod carcasses, consisting of heavily sclerotized material, preserved in substantial three-dimensional relief, to the exclusion of more delicate structures such as body cuticles, cellular sheets in contact with the water column, and internal organs (Fig. 3). As such, it is not possible to exclude a taphonomic filter51,52,53,54 at play in Taichoute. This filter could result from a prolonged exposure to decay as both biomineralized and heavily sclerotized structures are more resistant to degradation than other tissue-types51. Furthermore, it was previously shown that big carcasses provide large quantities of decaying organic material favouring concretion growth28,34. This resulted in the in situ preferential preservation of large-bodied remains in concretions in some sites near Zagora28,34. In Taichoute, large animals were transported and trapped within sediments, that were later consolidated in a2. It is possible, that the organic material generated from these carcasses following their transport, facilitated siltstone (i.e., interpreted as lobe-fringe deposits; Fig. 6) consolidation around large carcasses. The mineralogy of the surrounding matrix might have also played a role controlling what got preserved in Taichoute. Particular mineralogical phases are associated with horizons with soft-tissue preservation in the Fezouata Shale55,56 and in other deposits bearing exceptional preservation around the world57,58. These minerals replicate soft tissues, provide resistance to decay, and induce damage to bacterial membranes, facilitating the preservation of labile structures in the fossil record. In this sense, the absence of labile tissues and dominance of heavily sclerotized structures could also point to a lack of these favourable mineralogical phases in Taichoute sediments.
Taichoute is a newly described middle to late Floian fossil site in the Fezouata Shale. This discovery contributes to our understanding of animal preservation in this unique Lower Ordovician formation by showing that some organisms are transported by density flows. Three types of concretion preservation exist in Taichoute, expanding the fossilization modes observed within the Fezouata Shale. The dominant concretion type preserves large euarthropod carcasses, which, based on their morphology and size, might correspond to either bivalved forms and/or possibly radiodonts. Future mineralogical and geochemical investigations on Taichoute have the potential to produce valuable preservational insights allowing us to resolve whether the aforementioned ecological observations represent legitimate aspects of original ecosystems, or are biased by taphonomic filters. Nevertheless, at this stage, and prior to yielding further investigations on Taichoute, this site remains a significant fossil locality providing novel sedimentary, taphonomic, and palaeontological information (Table 1) at a key interval in the history of life on Earth—at the transition between the Cambrian Explosion and the Ordovician Radiation.
In 2017, a field excavation took place in Taichoute (Lower Ordovician, Morocco), 80 km away from more traditional Fezouata localities (Fig. 1c). The 85 m-thick sedimentary succession at Taichoute was logged at a dm-scale, taking into account, sedimentary structures, grain size, and bed geometries. Over 300 fossil samples were studied locally, but only 70 samples were transported to the Marrakech Collections of the Cadi Ayyad University in Morocco owing to the heavy weight of the concretions and are accounted for in Fig. 2. Kindly note that more than 12,000 specimens were transported from Bou Izargane to the Marrakech Collections, but only 660 specimens were identified and inventoried so far; these are as such considered in Fig. 2. We acknowledge that taxonomic abundances are likely to change following the complete curation of specimens from Bou Izargane and new fossil discoveries at Tamegroute, Tinzouline, and Taichoute, and these abundances are also likely to fluctuate between fossil collections of different institutions (e.g., Cadi Ayyad University, Yale Peabody Museum, University of Lausanne, and Harvard University). For these reasons, abundances are not central to this manuscript. However, it is important to emphasize that abundance discrepancies between collections and fossiliferous localities do not influence the Taichoute conclusions made within this paper (i.e., location, age, environment, preservation). Numbered material in Fig. 3 is deposited at the Cadi Ayyad University in Morocco, while fossils in Fig. 4 are deposited in the Invertebrate Paleontology collections at the Museum of Comparative Zoology, Harvard University (MCZ.IP).
All data needed to evaluate the conclusions in the paper are present within the Main Manuscript. Additional data related to this paper may be requested from the corresponding author (F. Saleh: [email protected]).
Van Roy, P. et al. Ordovician faunas of Burgess Shale type. Nature 465(7295), 215–218 (2010).
Article  PubMed  Google Scholar 
Van Roy, P., Briggs, D. E. & Gaines, R. R. The Fezouata fossils of Morocco; an extraordinary record of marine life in the Early Ordovician. J. Geol. Soc. 172(5), 541–549 (2015).
Article  Google Scholar 
Vinther, J., Van Roy, P. & Briggs, D. E. G. Machaeridians are Palaeozoic armoured annelids. Nature 451(7175), 185–188 (2008).
Article  CAS  PubMed  Google Scholar 
Vinther, J., Parry, L., Briggs, D. E. G. & Van Roy, P. Ancestral morphology of crown-group molluscs revealed by a new Ordovician stem aculiferan. Nature 542(7642), 471–474 (2017).
Article  CAS  PubMed  Google Scholar 
Van Roy, P. & Briggs, D. E. G. A giant Ordovician anomalocaridid. Nature 473(7348), 510–513 (2011).
Article  PubMed  Google Scholar 
Van Roy, P., Daley, A. C. & Briggs, D. E. Anomalocaridid trunk limb homology revealed by a giant filter-feeder with paired flaps. Nature 522(7554), 77–80 (2015).
Article  PubMed  Google Scholar 
Botting, J. P. Diversity and ecology of sponges in the Early Ordovician Fezouata Biota, Morocco. Palaeogeogr. Palaeoclimatol. Palaeoecol. 460, 75–86 (2016).
Article  Google Scholar 
Gutiérrez-Marco, J. C. & Martin, E. L. O. Biostratigraphy and palaeoecology of Lower Ordovician graptolites from the Fezouata Shale (Moroccan Anti-Atlas). Palaeogeogr. Palaeoclimatol. Palaeoecol. 460, 35–49 (2016).
Article  Google Scholar 
Lehnert, O. et al. Conodonts from the Lower Ordovician of Morocco—Contributions to age and faunal diversity of the Fezouata Lagerstätte and peri-Gondwana biogeography. Palaeogeogr. Palaeoclimatol. Palaeoecol. 460, 50–61 (2016).
Article  Google Scholar 
Lefebvre, B. et al. Palaeoecological aspects of the diversification of echinoderms in the Lower Ordovician of central Anti-Atlas, Morocco. Palaeogeogr. Palaeoclimatol. Palaeoecol. 460, 97–121 (2016).
Article  Google Scholar 
Lefebvre, B. et al. Exceptionally preserved soft parts in fossils from the Lower Ordovician of Morocco clarify stylophoran affinities within basal deuterostomes. Geobios 52, 27–36 (2019).
Article  Google Scholar 
Martí Mus, M. A hyolithid with preserved soft parts from the Ordovician Fezouata Konservat-Lagerstätte of Morocco. Palaeogeogr. Palaeoclimatol. Palaeoecol. 460, 122–129 (2016).
Article  Google Scholar 
Martin, E. L. et al. The lower Ordovician Fezouata Konservat-Lagerstätte from Morocco: Age, environment and evolutionary perspectives. Gondwana Res. 34, 274–283 (2016).
Article  Google Scholar 
Martin, E. L. et al. Biostratigraphic and palaeoenvironmental controls on the trilobite associations from the Lower Ordovician Fezouata Shale of the central Anti-Atlas, Morocco. Palaeogeogr. Palaeoclimatol. Palaeoecol. 460, 142–154 (2016).
Article  Google Scholar 
Nowak, H. et al. Palynomorphs of the Fezouata Shale (Lower Ordovician, Morocco): Age and environmental constraints of the Fezouata Biota. Palaeogeogr. Palaeoclimatol. Palaeoecol. 460, 62–74 (2016).
Article  Google Scholar 
Pérez-Peris, F., Laibl, L., Vidal, M. & Daley, A. Systematics, morphology, and appendages of an Early Ordovician pilekiine trilobite Anacheirurus from Fezouata Shale and the early diversification of Cheiruridae. Acta Palaeontol. Pol. 66(4), 857–877 (2021).
Google Scholar 
Pérez-Peris, F. et al. A new nektaspid euarthropod from the Lower Ordovician strata of Morocco. Geol. Mag. 158(3), 509–517 (2016).
Article  Google Scholar 
Polechová, M. The bivalve fauna from the Fezouata Formation (Lower Ordovician) of Morocco and its significance for palaeobiogeography, palaeoecology and early diversification of bivalves. Palaeogeogr. Palaeoclimatol. Palaeoecol. 460, 155–169 (2016).
Article  Google Scholar 
Van Iten, H. et al. Palaeobiogeography, palaeoecology and evolution of Lower Ordovician conulariids and Sphenothallus (Medusozoa, Cnidaria), with emphasis on the Fezouata Shale of southeastern Morocco. Palaeogeogr. Palaeoclimatol. Palaeoecol. 460, 170–178 (2016).
Article  Google Scholar 
Saleh, F., Lefebvre, B., Hunter, A. W. & Nohejlová, M. Fossil weathering and preparation mimic soft tissues in eocrinoid and somasteroid echinoderms from the Lower Ordovician of Morocco. Microsc. Today 28(1), 24–28 (2020).
Article  Google Scholar 
Saleh, F. et al. Contrasting Early Ordovician assembly patterns highlight the complex initial stages of the Ordovician Radiation. Sci. Rep. 12(1), 1–8 (2022).
Article  Google Scholar 
Allaire, N., Lefebvre, B., Martin, E., Nardin, E. & Vaucher, R. Taphonomy of new Rhopalocystis assemblages in the Lower Ordovician of the Zagora area (central Anti-Atlas, Morocco). Prog. Echinoderm Palaeobiology: Cuadernos del Museo Geominero 19, 21–26 (2015).
Google Scholar 
Martin, E., Lefebvre, B. & Vaucher, R. Taphonomy of a stylophoran-dominated assemblage in the Lower Ordovician of Zagora area (central Anti-Atlas, Morocco). Prog. Echinoderm Palaeobiology: Cuadernos del Museo Geominero 19, 95–100 (2015).
Google Scholar 
Allaire, N. et al. Morphological disparity and systematic revision of the eocrinoid genus Rhopalocystis (Echinodermata, Blastozoa) from the Lower Ordovician of the central Anti-Atlas (Morocco). J. Paleontol. 91(4), 685–714 (2017).
Article  Google Scholar 
Hunter, A. W. & Ortega-Hernández, J. A new somasteroid from the Fezouata Lagerstätte in Morocco and the Early Ordovician origin of Asterozoa. Biol. Let. 17(1), 20200809 (2021).
Article  Google Scholar 
Lefebvre, B. et al. Age calibration of the Lower Ordovician Fezouata Lagerstätte, Morocco. Lethaia 51(2), 296–311 (2018).
Article  Google Scholar 
Saleh, F. et al. Storm-induced community dynamics in the Fezouata Biota (Lower Ordovician, Morocco). Palaios 33(12), 535–541 (2018).
Article  Google Scholar 
Saleh, F. et al. Large trilobites in a stress-free Early Ordovician environment. Geol. Mag. 158(2), 261–270 (2021).
Article  Google Scholar 
Vaucher, R., Martin, E. L. O., Hormière, H. & Pittet, B. A genetic link between Konzentrat-and Konservat-Lagerstätten in the Fezouata Shale (lower Ordovician, Morocco). Palaeogeogr. Palaeoclimatol. Palaeoecol. 460, 24–34 (2016).
Article  Google Scholar 
Vaucher, R., Pittet, B., Hormière, H., Martin, E. L. O. & Lefebvre, B. A wave-dominated, tide-modulated model for the Lower Ordovician of the Anti-Atlas, Morocco. Sedimentology 64(3), 777–807 (2017).
Article  Google Scholar 
Saleh, F. et al. Taphonomic pathway of exceptionally preserved fossils in the Lower Ordovician of Morocco. Geobios 60, 99–115 (2020).
Article  Google Scholar 
Saleh, F. et al. Insights into soft-part preservation from the Early Ordovician Fezouata Biota. Earth Sci. Rev. 213(103464), 1–12 (2021).
Google Scholar 
Saleh, F., Daley, A. C., Lefebvre, B., Pittet, B. & Perrillat, J. P. Biogenic iron preserves structures during fossilization: A hypothesis. BioEssays 42(6), 1900243 (2020).
Article  CAS  Google Scholar 
Gaines, R. R., Briggs, D. E. G., Orr, P. J. & Van Roy, P. Preservation of giant anomalocaridids in silica-chlorite concretions from the Early Ordovician of Morocco. Palaios 27(5), 317–325 (2012).
Article  Google Scholar 
Izquierdo-López, A. & Caron, J. B. Extreme multisegmentation in a giant bivalved arthropod from the Cambrian Burgess Shale. iScience 25, 104675 (2022).
Article  PubMed  PubMed Central  Google Scholar 
Fu, D. J., Zhang, X. L., Budd, G. E., Liu, W. & Pan, X. Ontogeny and dimorphism of Isoxys auritus (Arthropoda) from the early Cambrian Chengjiang biota, South China. Gondwana Res. 25(3), 975–982 (2014).
Article  Google Scholar 
García-Bellido, D. C. et al. The bivalved arthropods Isoxys and Tuzoia with soft-part preservation from the Lower Cambrian Emu Bay Shale Lagerstätte (Kangaroo Island, Australia). Palaeontology 52(6), 1221–1241 (2009).
Article  Google Scholar 
Vannier, J. et al. Tuzoia: Morphology and lifestyle of a large bivalved arthropod of the Cambrian seas. J. Paleontol. 81(3), 445–471 (2007).
Article  Google Scholar 
Wu, Y., Fu, D. J., Zhang, X. L., Daley, A. C. & Shu, D. Dimorphism of Bivalved Arthropod Branchiocaris? yunnanensis from the Early Cambrian Chengjiang Biota, South China. Acta Geol. Sin. 90(3), 818–826 (2016).
Article  Google Scholar 
Legg, D. A. & Caron, J. B. New Middle Cambrian bivalved arthropods from the Burgess Shale (British Columbia, Canada). Palaeontology 57(4), 691–711 (2014).
Article  Google Scholar 
Aria, C. & Caron, J. B. Burgess Shale fossils illustrate the origin of the mandibulate body plan. Nature 545(7652), 89–92 (2017).
Article  CAS  PubMed  Google Scholar 
Briggs, D. E. G., Rolfe, W. I., Butler, P. D., Liston, J. J. & Ingham, J. K. Phyllocarid crustaceans from the Upper Devonian Gogo Formation, Western Australia. J. Syst. Paleontol. 9(3), 399–424 (2011).
Article  Google Scholar 
Jones, W. T., Feldmann, R. M. & Mikulic, D. G. Archaeostracan (Phyllocarida: Archaeostraca) Antennulae and Antennae: Sexual Dimorphism in Early Malacostracans and Ceratiocaris as a Possible Stem Eumalacostracan. J. Crustac. Biol. 35(2), 191–201 (2015).
Article  Google Scholar 
Mángano, M. G. et al. Nonbiomineralized carapaces in Cambrian seafloor landscapes (Sirius Passet, Greenland): Opening a new window into early Phanerozoic benthic ecology. Geology 40(6), 519–522 (2012).
Article  Google Scholar 
Vaucher, R. et al. Bedforms in a tidally modulated ridge and runnel shoreface (Berck-Plage; North France): implications for the geological record. Bull. Soc. Géol. Fr. 189(1), 5 (2018).
Article  Google Scholar 
Álvaro, J. J. et al. Diachronism in the late Neoproterozoic-Cambrian arc-rift transition of North Gondwana: A comparison of Morocco and the Iberian Ossa-Morena Zone. J. Afr. Earth Sc. 98, 113–132 (2014).
Article  Google Scholar 
Gaines, R. R. Burgess Shale-type preservation and its distribution in space and time. Paleontol. Soc. Pap. 20, 123–146 (2014).
Article  Google Scholar 
Hammarlund, E. U. et al. Early Cambrian oxygen minimum zone-like conditions at Chengjiang. Earth Planet. Sci. Lett. 475, 160–168 (2017).
Article  CAS  Google Scholar 
Qi, C. et al. Influence of redox conditions on animal distribution and soft-bodied fossil preservation of the Lower Cambrian Chengjiang Biota. Palaeogeogr. Palaeoclimatol. Palaeoecol. 507, 180–187 (2018).
Article  Google Scholar 
Saleh, F. et al. The Chengjiang Biota inhabited a deltaic environment. Nat. Commun. 13(1), 1–9 (2022).
Article  Google Scholar 
Saleh, F. et al. Taphonomic bias in exceptionally preserved biotas. Earth Planet. Sci. Lett. 529, 115873 (2020).
Article  CAS  Google Scholar 
Saleh, F. et al. A novel tool to untangle the ecology and fossil preservation knot in exceptionally preserved biotas. Earth Planet. Sci. Lett. 569, 117061 (2021).
Article  CAS  Google Scholar 
Whitaker, A. F., Schiffbauer, J. D., Briggs, D. E., Leibach, W. W. & Kimmig, J. Preservation and diagenesis of soft-bodied fossils and the occurrence of phosphate-associated rare earth elements in the Cambrian (Wuliuan) Spence Shale Lagerstätte. Palaeogeogr. Palaeoclimatol. Palaeoecol. 592, 110909 (2022).
Article  Google Scholar 
Saleh, F. et al. Probability-based preservational variations within the early Cambrian Chengjiang biota (China). PeerJ 10, e13869 (2022).
Article  PubMed  PubMed Central  Google Scholar 
Saleh, F., Pittet, B., Perrillat, J. P. & Lefebvre, B. Orbital control on exceptional fossil preservation. Geology 47(2), 103–106 (2019).
Article  CAS  Google Scholar 
Saleh, F. et al. Iron from continental weathering dictated soft-part preservation during the Early Ordovician. Terra Nova 34(3), 163–168 (2022).
Article  CAS  Google Scholar 
Anderson, R. P., Tosca, N. J., Gaines, R. R., Koch, N. M. & Briggs, D. E. G. A mineralogical signature for Burgess Shale–type fossilization. Geology 46(4), 347–350 (2018).
Article  CAS  Google Scholar 
Anderson, R. P., Tosca, N. J., Saupe, E. E., Wade, J. & Briggs, D. E. G. Early formation and taphonomic significance of kaolinite associated with Burgess Shale fossils. Geology 49(4), 355–359 (2021).
Article  CAS  Google Scholar 
Van Roy, P. Non-trilobite arthropods from the Ordovician of Morocco. Unpublished Ph.D. Thesis (2006).
Daley, A. C., Budd, G. E. & Caron, J. B. Morphology and systematics of the anomalocaridid arthropod Hurdia from the Middle Cambrian of British Columbia and Utah. J. Syst. Paleontol. 11(7), 743–787 (2013).
Article  Google Scholar 
Download references
The paper is dedicated to the memory of Bernard Pittet, former supervisor of F.S. and R.V. who passed away prior to the writing of this manuscript and who helped us improve our understanding of sedimentary processes associated with exceptionally-preserved fossils in the Fezouata Shale. Jan Ove R. Ebbestad is thanked for providing mollusc identifications and photographs. Mohammed “Ou Said” Ben Moula and his family are acknowledged for their key involvement in fieldwork and collection of the specimens that are now housed at the Museum of Comparative Zoology at Harvard University. Joseph Botting, Peter Van Roy, Christian Klug, and Marika Polechová are thanked for providing comments that helped us improve this work. This paper is supported by Grant no. 2020M683388 from the Chinese Postdoctoral Science Foundation awarded to F.S. F.S. also thanks FGSE funding of the University of Lausanne. This work is also supported by Grant no. 205321_179084 from the Swiss National Science Foundation, awarded to A.C.D. L.L. is supported by the Czech Science Foundation (Project no. 20-23550Y) and by institutional support RVO 67985831 of the Institute of Geology of the Czech Academy of Sciences. Fieldwork of J.C.G.-M. was funded by the Spanish Ministry of Science and Innovation, Grants nr. CGL2017-87631-P and PID2021-125585NB-100. J.O.-H. is supported by the National Science Foundation (CAREER award no. 2047192). D.A.T.H. thanks the Leverhulme Trust for support. This paper is a contribution to the TelluS-Syster project ‘Vers de nouvelles découvertes de gisements à préservation exceptionnelle dans l’Ordovicien du Maroc’ (2017) and the TelluS-INTERRVIE projects ‘Mécanismes de préservation exceptionnelle dans la Formation des Fezouata’ (2018), and ‘Géochimie d’un Lagerstätte de l’Ordovicien inférieur du Maroc’ (2019) all funded by the INSU, CNRS. This paper is also a contribution of the IGCP Projects 653 and 735.
Institute of Earth Sciences (ISTE), University of Lausanne, Geopolis, 1015, Lausanne, Switzerland
Farid Saleh, Romain Vaucher & Allison C. Daley
Yunnan Key Laboratory for Palaeobiology, Institute of Palaeontology, Yunnan University, Kunming, China
Farid Saleh & Xiaoya Ma
MEC International Joint Laboratory for Palaeobiology and Palaeoenvironment, Institute of Palaeontology, Yunnan University, Kunming, China
Farid Saleh & Xiaoya Ma
Univ Brest, CNRS, Ifremer, Geo-Ocean, UMR 6538, Place Nicolas Copernic, F-29280, Plouzané, France
Muriel Vidal
Laboratoire de Géoressources, Géoenvironnement Et Génie Civil ‘L3G’, Faculté Des Sciences Et Techniques, Université Cadi-Ayyad, BP 549, 40000, Marrakesh, Morocco
Khadija El Hariri
Czech Academy of Sciences, Institute of Geology, Rozvojová 269, 165 00, Prague 6, Czech Republic
Lukáš Laibl
Instituto de Geociencias (CSIC, UCM), Departamento GEODESPAL, Facultad de Ciencias Geológicas, Spanish Research Council, José Antonio Novais 12, 28040, Madrid, Spain
Juan Carlos Gutiérrez-Marco
Department of Natural Sciences, National Museums Scotland, Edinburgh, EH1 1JF, UK
Yves Candela
Palaeoecosystems Group, Department of Earth Sciences, Durham University, Durham, DH1 3LE, UK
David A. T. Harper
Museum of Comparative Zoology and Department of Organismic and Evolutionary Biology, Harvard University, Cambridge, MA, 02138, USA
Javier Ortega-Hernández
Centre for Ecology and Conservation, University of Exeter, Penryn, UK
Xiaoya Ma
Université Cadi Ayyad, École Normale Supérieure, Marrakech, Morocco
Ariba Rida
Independent, 7 rue Chardin, Maquens, 11090, Carcassonne, France
Daniel Vizcaïno
Université Claude Bernard Lyon 1, École Normale Supérieure de Lyon, CNRS, UMR5276, LGL-TPE, Université de Lyon, Villeurbanne, France
Bertrand Lefebvre
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
F.S. and B.L. designed the project. F.S., M.V., L.L., J.C. G.-M., Y.C., D.V., and B.L. participated in the fieldwork. J.O.H. photographed materials. F.S., and R.V., did the sedimentary analyses and made the figures. All co-authors helped interpret and discuss the results. F.S. wrote the manuscript with inputs from all co-authors.
Correspondence to Farid Saleh.
The authors declare no competing interests.
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
Reprints and Permissions
Saleh, F., Vaucher, R., Vidal, M. et al. New fossil assemblages from the Early Ordovician Fezouata Biota. Sci Rep 12, 20773 (2022). https://doi.org/10.1038/s41598-022-25000-z
Download citation
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-022-25000-z
Anyone you share the following link with will be able to read this content:
Sorry, a shareable link is not currently available for this article.

Provided by the Springer Nature SharedIt content-sharing initiative
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.
Advertisement
Scientific Reports (Sci Rep) ISSN 2045-2322 (online)
© 2022 Springer Nature Limited
Sign up for the Nature Briefing newsletter — what matters in science, free to your inbox daily.

source