Microbial ecology and biogeochemistry of hypersaline sediments in Orca Basin

In deep ocean hypersaline basins, the combination of high salinity, unusual ionic composition and anoxic conditions represents significant challenges for microbial life. We used geochemical porewater characterization and DNA sequencing based taxonomic surveys to enable environmental and microbial ch...

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Bibliographic Details
Main Authors: Nigro, L.M., Elling, F.J., Hinrichs, K.-U., Joye, S.B., Teske, A.
Format: Article in Journal/Newspaper
Language:English
Published: Public Library of Science 2020
Subjects:
Thaumarchaeota
microbiology
Methanohalophilus
Article
nonhuman
salinity
limit of quantitation
archaeon
Archaea
methanogenesis
Ecosystem
sea water
RNA
Ribosomal
16S
DNA sequencing
genetics
limit of detection
chemistry
Sulfates
sediment
biogeochemistry
archaeal DNA
concentration (parameter)
Seawater
hypersaline sediment
Gulf of Mexico
methane
16S rRNA gene
Deltaproteobacteria
controlled study
DNA
Archaeal
river basin
classification
carbon
sulfate
isotope analysis
Geologic Sediments
RNA 16S
Orca
Online Access:https://doi.org/10.17615/qrpm-7281
https://cdr.lib.unc.edu/downloads/k0698k302?file=thumbnail
https://cdr.lib.unc.edu/downloads/k0698k302
Description
Summary:In deep ocean hypersaline basins, the combination of high salinity, unusual ionic composition and anoxic conditions represents significant challenges for microbial life. We used geochemical porewater characterization and DNA sequencing based taxonomic surveys to enable environmental and microbial characterization of anoxic hypersaline sediments and brines in the Orca Basin, the largest brine basin in the Gulf of Mexico. Full-length bacterial 16S rRNA gene clone libraries from hypersaline sediments and the overlying brine were dominated by the uncultured halophilic KB1 lineage, Deltaproteobacteria related to cultured sulfate-reducing halophilic genera, and specific lineages of heterotrophic Bacteroidetes. Archaeal clones were dominated by members of the halophilic methanogen genus Methanohalophilus, and the ammonia-oxidizing Marine Group I (MG-I) within the Thaumarchaeota. Illumina sequencing revealed higher phylum- and subphylum-level complexity, especially in lower-salinity sediments from the Orca Basin slope. Illumina and clone library surveys consistently detected MG-I Thaumarchaeota and halotolerant Deltaproteobacteria in the hypersaline anoxic sediments, but relative abundances of the KB1 lineage differed between the two sequencing methods. The stable isotopic composition of dissolved inorganic carbon and methane in porewater, and sulfate concentrations decreasing downcore indicated methanogenesis and sulfate reduction in the anoxic sediments. While anaerobic microbial processes likely occur at low rates near their maximal salinity thresholds in Orca Basin, long-term accumulation of reaction products leads to high methane concentrations and reducing conditions within the Orca Basin brine and sediments.

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