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1. Ecological impact of the OAE1a (Early Aptian) on Urgonian ecosystems from Vercors, southern France

   Godet, Alexis; Byerly, Jacob; Bourdon, Matthew; Suarez, Marina; Arnaud-Vanneau, Annie; Adatte, Thierry (May 2024, SEPPM)

   Climate and environmental instability during the Early Aptian culminate with the unfolding of the Oceanic Anoxic Event (OAE) 1a, which consists of the deposition of black shales in deep marine settings and a typical negative spike in δ13C values followed by a positive excursion. In the Vercors, southern France, the Urgonian platform developed coeval to the OAE1a, but the impact of this paleoenvironmental crisis on the ecology of benthic ecosystem is yet to be quantified. First, field and petrographic data allow to identify sequence boundaries and maximum flooding surfaces; these are biostratigraphically dated and correlated within the study area. Second, a composite δ13C curve permits to identify the C3 to C7 isotope segments from the literature, thus pinpointing the onset of the OAE1a above the Urgonian Limestone, in the Upper Orbitolina Beds. Third, thin section point counting data permit to quantify the proportion of allochems, thus illuminating the ecology of ecosystems. Principal component analysis helps define three ecological tiers: diversified, photozoan associations with rudists, green algae, and benthic foraminifera dominate ecosystems prior to the OAE1a and up to the C7 segment, while a less diversified heterozoan association with bryozoan and crinoid developed in the aftermaths of the OAE1a. Fourth, elemental geochemical data identify an increased nutrient and detrital input (C7 segment) as the major triggering mechanisms for ecological adjustments and changes in the biodiversity of ecosystems. Our research indicate that these changes are initiated in the aftermaths of the OAE1a but culminate after it. 

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2. The response of Corbières carbonate platform to Early Cretaceous super greenhouse conditions

   Sharpe, Justin; Sansing, Alexis; Suarez, Marina; Godet, Alexis (May 2024, SEPM)

   Shallow marine reef systems are the most diversified ecosystems of modern oceans but face a severe threat from climate change: 91% of ecosystems in the Great Barrier Reef suffer from coral bleaching. To better understand how such ecosystems cope with environmental stress, a carbonate platform from the Corbières region of southern France serves as ancient analog as it developed during the Early Aptian OAE1a, a period marked by significant climate and volcanic activity. The study sought to uncover how benthic carbonate-producing ecosystems adapted during this challenging period. The OAE1a is typically identified by distinctive shifts in carbon isotope composition (δ13C) values and increased organic matter preservation in deep marine settings. Identifying these shifts can shed light on factors favoring carbonate production. The research proposes that warm, arid climates promoted reduced continental weathering and limited transfer of siliciclastic particles and dissolved nutrients that might enhance carbonate platform resilience. We identified seven out of eight segments of the OAE1a and specific microfacies in the Corbières region. Prior to the OAE1a, carbonate production was sustained by a photozoan assemblage with rudists and [insert main biota], with no changes in fauna and flora. A significant shift occurred at the interface between the Urgonian Marl that consists of siliciclastic-rich deposits with bryozoan and crinoid, indicating platform drowning and altered carbonate production. In the aftermaths of the OAE1a, carbonate production not only rebounded but thrived in the upper Urgonian Marl and Urgonian 2 with the return of a photozoan assemblage. This research provides an understanding into the adaptability of carbonate ecosystems to environmental stress, potentially offering lessons for mitigating similar crisis in the future. 

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3. Sea level, carbonate mineralogy, and early diagenesis controlled δ13C records in Upper Ordovician carbonates

   https://doi.org/10.1130/G46861.1  

   Jones, David S.; Brothers, R. William; Crüger Ahm, Anne-Sofie; Slater, Nicholas; Higgins, John A.; Fike, David A. (December 2019, Geology)

   Abstract Stratigraphic variability in the geochemistry of sedimentary rocks provides critical data for interpreting paleoenvironmental change throughout Earth history. However, the vast majority of pre-Jurassic geochemical records derive from shallow-water carbonate platforms that may not reflect global ocean chemistry. Here, we used calcium isotope ratios (δ44Ca) in conjunction with minor-element geochemistry (Sr/Ca) and field observations to explore the links among sea-level change, carbonate mineralogy, and marine diagenesis and the expression of a globally documented interval of elevated carbon isotope ratios (δ13C; Hirnantian isotopic carbon excursion [HICE]) associated with glaciation in Upper Ordovician shallow-water carbonate strata from Anticosti Island, Canada, and the Great Basin, Nevada and Utah, USA. The HICE on Anticosti is preserved in limestones with low δ44Ca and high Sr/Ca, consistent with aragonite as a major component of primary mineralogy. Great Basin strata are characterized by lateral gradients in δ44Ca and δ13C that reflect variations in the extent of early marine diagenesis across the platform. In deep-ramp settings, deposition during synglacial sea-level lowstand and subsequent postglacial flooding increased the preservation of an aragonitic signature with elevated δ13C produced in shallow-water environments. In contrast, on the mid- and inner ramp, extensive early marine diagenesis under seawater-buffered conditions muted the magnitude of the shift in δ13C. The processes documented here provide an alternative explanation for variability in a range of geochemical proxies preserved in shallow-water carbonates at other times in Earth history, and challenge the notion that these proxies necessarily record changes in the global ocean. 

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4. Shifting stoichiometry: Long‐term trends in stream‐dissolved organic matter reveal altered C:N ratios due to history of atmospheric acid deposition

   https://doi.org/10.1111/gcb.15965  

   Rodríguez‐Cardona, Bianca M.; Wymore, Adam S.; Argerich, Alba; Barnes, Rebecca T.; Bernal, Susana; Brookshire, E. N. Jack; Coble, Ashley A.; Dodds, Walter K.; Fazekas, Hannah M.; Helton, Ashley M.; et al (November 2021, Global Change Biology)

   Abstract Dissolved organic carbon (DOC) and nitrogen (DON) are important energy and nutrient sources for aquatic ecosystems. In many northern temperate, freshwater systems DOC has increased in the past 50 years. Less is known about how changes in DOC may vary across latitudes, and whether changes in DON track those of DOC. Here, we present long‐term DOC and DON data from 74 streams distributed across seven sites in biomes ranging from the tropics to northern boreal forests with varying histories of atmospheric acid deposition. For each stream, we examined the temporal trends of DOC and DON concentrations and DOC:DON molar ratios. While some sites displayed consistent positive or negative trends in stream DOC and DON concentrations, changes in direction or magnitude were inconsistent at regional or local scales. DON trends did not always track those of DOC, though DOC:DON ratios increased over time for ~30% of streams. Our results indicate that the dissolved organic matter (DOM) pool is experiencing fundamental changes due to the recovery from atmospheric acid deposition. Changes in DOC:DON stoichiometry point to a shifting energy‐nutrient balance in many aquatic ecosystems. Sustained changes in the character of DOM can have major implications for stream metabolism, biogeochemical processes, food webs, and drinking water quality (including disinfection by‐products). Understanding regional and global variation in DOC and DON concentrations is important for developing realistic models and watershed management protocols to effectively target mitigation efforts aimed at bringing DOM flux and nutrient enrichment under control. 

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5. Exploring Saccharomycotina Yeast Ecology Through an Ecological Ontology Framework

   https://doi.org/10.1002/yea.3981  

   Harrison, Marie‐Claire; Opulente, Dana A; Wolters, John F; Shen, Xing‐Xing; Zhou, Xiaofan; Groenewald, Marizeth; Hittinger, Chris Todd; Rokas, Antonis; LaBella, Abigail Leavitt (October 2024, Yeast)

   ABSTRACT Yeasts in the subphylum Saccharomycotina are found across the globe in disparate ecosystems. A major aim of yeast research is to understand the diversity and evolution of ecological traits, such as carbon metabolic breadth, insect association, and cactophily. This includes studying aspects of ecological traits like genetic architecture or association with other phenotypic traits. Genomic resources in the Saccharomycotina have grown rapidly. Ecological data, however, are still limited for many species, especially those only known from species descriptions where usually only a limited number of strains are studied. Moreover, ecological information is recorded in natural language format limiting high throughput computational analysis. To address these limitations, we developed an ontological framework for the analysis of yeast ecology. A total of 1,088 yeast strains were added to the Ontology of Yeast Environments (OYE) and analyzed in a machine‐learning framework to connect genotype to ecology. This framework is flexible and can be extended to additional isolates, species, or environmental sequencing data. Widespread adoption of OYE would greatly aid the study of macroecology in the Saccharomycotina subphylum. 

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