Description: The Cretaceous period (similar to 145-65 m.y. ago) was characterized by intervals of enhanced organic carbon burial associated with increased primary production under greenhouse conditions. The global consequences of these perturbations, oceanic anoxic events (OAEs), lasted up to 1 m.y., but short-term nutrient and climatic controls on widespread anoxia are poorly understood. Here, we present a high-resolution reconstruction of oceanic redox and nutrient cycling as recorded in subtropical shelf sediments from Tarfaya, Morocco, spanning the initiation of OAE2. Iron-sulfur systematics and biomarker evidence demonstrate previously undescribed redox cyclicity on orbital time scales, from sulfidic to anoxic ferruginous (Fe-rich) water-column conditions. Bulk geochemical data and sulfur isotope modeling suggest that ferruginous conditions were not a consequence of nutrient or sulfate limitation, despite overall low sulfate concentrations in the proto-North Atlantic. Instead, fluctuations in the weathering influxes of sulfur and reactive iron, linked to a dynamic hydrological cycle, likely drove the redox cyclicity. Despite the potential for elevated phosphorus burial in association with Fe oxides under ferruginous conditions on the Tarfaya shelf, porewater sulfide generation drove extensive phosphorus recycling back to the water column, thus maintaining widespread open-ocean anoxia.

Description: The occurrence of microbially induced smectite-to-illite (S-I) reaction has challenged both the notions of solely inorganic chemical control for this reaction and the conventional concept of a semiquantitative illite geothermometer for the reconstruction of the thermal and tectonic histories of sedimentary basins. Here, we present evidence for a naturally occurring microbially induced S-I transition, via biotic reduction of phyllosilicate structural Fe(III), in mudstones buried at the Nankai Trough, offshore Japan (International Ocean Discovery Program Site C0023). Biotic S-I reaction is a consequence of a bacterial survival and growth strategy at diagenetic temperatures up to 80 °C within the Nankai Trough mudstones. These results have considerable implications for petroleum exploration, modification of fault behavior, and the understanding of microbial communities in the deep biosphere.

Description: The area around the Antarctic Peninsula is projected to undergo rapid climatic changes affecting seasonal sea ice cover, water column stratification, terrestrial meltwater run-off, and related nutrient input and thus the conditions for primary production and organic carbon export. The impact of such environmental changes on benthic microbial communities is poorly understood. In this study, we investigated the impact of different sea ice cover and redox conditions on microbial community compositions from 7 different stations (330–450 m water depth) along a 400-mile transect from the eastern shelf of the Antarctic Peninsula to the west of the South Orkney Islands. Two deep stations (3000 m depth) were sampled for comparison. Samples were collected from 6 different intervals down to a depth of 16 cm. The diversity and composition of microbial communities were determined by 16S ribosomal RNA (rRNA) gene sequencing. Redox conditions in sediments with long ice-free periods showed that iron and sulfate reduction are dominant anaerobic pathways for carbon mineralization. In contrast, sediments at a heavily ice-covered station were dominated by the aerobic pathway, which accounted for 〉94 % of the total carbon degradation. Our results reveal that the microbial community composition at the station under heavy ice-cover differs significantly from stations under low ice-cover and tends to cluster separately, suggesting that sea ice cover is the main driver for changes in microbial community composition in the shelf sediments. Further, the frequency of marginal sea ice conditions (here defined as 5-35% sea ice cover) is significantly different between stations (p 0.001) and can explain 5 to 13% of the variation between microbial communities. The bacterial communities at stations under low ice-cover co-varied significantly with TOC content and porewater concentrations of ammonia, dissolved iron, and sulfide. This was reflected in the microbial community composition, where stations with low ice-cover were dominated by Desulfuromonadia, a taxon including many iron and sulfate reducers. At the station with heavy ice-cover, this class showed very low abundances. Our findings demonstrate that the benthic microbial composition and mediated-processes at various sites around the eastern Antarctic Peninsula are regulated by sea ice cover.