Sulfate-reducing prokaryotic communities in two deep hypersaline anoxic basins in the Eastern Mediterranean deep sea

Sulfur cycling is primarily driven by sulfate reduction mediated by sulfate-reducing bacteria (SRB) in marine sediments. The dissimilatory sulfate reduction drives the production of enormous quantities of reduced sulfide and thereby the formation of highly insoluble metal sulfides in marine sediments. Here, a novel sulfate-reducing bacterium designated Pseudodesulfovibrio cashew SRB007 was isolated and purified from the deep-sea cold seep and proposed to represent a novel species in the genus of Pseudodesulfovibrio. A detailed description of the phenotypic traits, phylogenetic status and central metabolisms of strain SRB007 allowed the reconstruction of the metabolic potential and lifestyle of a novel member of deep-sea SRB. Notably, P. cashew SRB007 showed a strong ability to resist and remove different heavy metal ions including Co2+, Ni2+, Cd2+ and Hg2+. The dissimilatory sulfate reduction was demonstrated to contribute to the prominent removal capability of P. cashew SRB007 against different heavy metals via the formation of insoluble metal sulfides.

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The volcanological significance of deep-sea ash layers associated with ignimbrites

Geological Magazine ◽

10.1017/s0016756800028533 ◽

1980 ◽

Vol 117 (5) ◽

pp. 425-436 ◽

Cited By ~ 66

Author(s):

R. S. J. Sparks ◽

T. C. Huang

Keyword(s):

Deep Sea ◽

Eastern Mediterranean ◽

Eruption Column ◽

Size Distributions ◽

Ash Fall ◽

Column Collapse ◽

Median Diameter ◽

Grain Size Distributions ◽

Bimodal Grain Size ◽

Fall Deposits

SummaryMany volcanic ash layers preserved in deep-sea sediments are the products of large magnitude ignimbrite eruptions. The characteristics of such co-ignimbrite ash-fall deposits are illustrated by two layers from the Eastern Mediterranean: the Minoan ash, Santorini, and the Campanian ash, Italy. These layers are divisible into a coarse lower unit and a fine upper unit in proximal cores. Both layers also show striking bimodal grain size distributions in more distal cores. The coarser mode decreases in median diameter with distance from source whereas the finer mode shows no lateral variation. These features are interpreted in terms of a model for ignimbrite formation by eruption column collapse. Comparable volumes of ignimbrite and associated air-fall ejecta are produced.

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The geometry and rates of microplate motions in the Eastern Mediterranean Sea — Quantitative constraints by using anoxic basins as piercing points

Marine Geology ◽

10.1016/0025-3227(87)90094-6 ◽

1987 ◽

Vol 75 (1-4) ◽

pp. 1-29 ◽

Cited By ~ 10

Author(s):

Derk Jongsma

Keyword(s):

Mediterranean Sea ◽

Eastern Mediterranean ◽

Eastern Mediterranean Sea ◽

Anoxic Basins

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A deep-sea sulfate reducing bacterium directs the formation of zero-valent sulfur via sulfide oxidation

10.1101/2021.03.23.436689 ◽

2021 ◽

Author(s):

Rui Liu ◽

Yeqi Shan ◽

Shichuan Xi ◽

Xin Zhang ◽

Chaomin Sun

Keyword(s):

Deep Sea ◽

Sulfide Oxidation ◽

Sulfur Cycle ◽

Cold Seep ◽

Cold Seeps ◽

Protein Activity ◽

Quinone Oxidoreductase ◽

Sulfate Reducing ◽

Thiosulfate Reductase ◽

Reducing Bacteria

Zero-valent sulfur (ZVS) is a critical intermediate in the biogeochemical sulfur cycle. Up to date, sulfur oxidizing bacteria have been demonstrated to dominate the formation of ZVS. In contrast, formation of ZVS mediated by sulfate reducing bacteria (SRB) has been rarely reported. Here, we report for the first time that a typical sulfate reducing bacterium Desulfovibrio marinus CS1 directs the formation of ZVS via sulfide oxidation. In combination with proteomic analysis and protein activity assays, thiosulfate reductase (PhsA) and sulfide: quinone oxidoreductase (SQR) were demonstrated to play key roles in driving ZVS formation. In this process, PhsA catalyzed thiosulfate to form sulfide, which was then oxidized by SQR to form ZVS. Consistently, the expressions of PhsA and SQR were significantly up-regulated in strain CS1 when cultured in the deep-sea cold seep, strongly indicating strain CS1 might form ZVS in its real inhabiting niches. Notably, homologs of phsA and sqr widely distributed in the metagenomes of deep-sea SRB. Given the high abundance of SRB in cold seeps, it is reasonable to propose that SRB might greatly contribute to the formation of ZVS in the deep-sea environments. Our findings add a new aspect to the current understanding of the source of ZVS.

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