Heidi S. Aronson, Christian E. Clark, Douglas E. LaRowe, Jan P. Amend, Lubos Polerecky, Jennifer L. Macalady
{"title":"动态微毒硫化物岩溶系统中硫歧化微生物群落","authors":"Heidi S. Aronson, Christian E. Clark, Douglas E. LaRowe, Jan P. Amend, Lubos Polerecky, Jennifer L. Macalady","doi":"10.1111/gbi.12574","DOIUrl":null,"url":null,"abstract":"<p>Biogeochemical sulfur cycling in sulfidic karst systems is largely driven by abiotic and biological sulfide oxidation, but the fate of elemental sulfur (S<sup>0</sup>) that accumulates in these systems is not well understood. The Frasassi Cave system (Italy) is intersected by a sulfidic aquifer that mixes with small quantities of oxygen-rich meteoric water, creating Proterozoic-like conditions and supporting a prolific ecosystem driven by sulfur-based chemolithoautotrophy. To better understand the cycling of S<sup>0</sup> in this environment, we examined the geochemistry and microbiology of sediments underlying widespread sulfide-oxidizing mats dominated by <i>Beggiatoa</i>. Sediment populations were dominated by uncultivated relatives of sulfur cycling chemolithoautotrophs related to <i>Sulfurovum</i>, <i>Halothiobacillus</i>, <i>Thiofaba</i>, <i>Thiovirga</i>, <i>Thiobacillus</i>, and <i>Desulfocapsa</i>, as well as diverse uncultivated anaerobic heterotrophs affiliated with <i>Bacteroidota</i>, Anaerolineaceae, Lentimicrobiaceae, and Prolixibacteraceae. <i>Desulfocapsa</i> and <i>Sulfurovum</i> populations accounted for 12%–26% of sediment 16S rRNA amplicon sequences and were closely related to isolates which carry out autotrophic S<sup>0</sup> disproportionation in pure culture. Gibbs energy (∆<i>G</i><sub><i>r</i></sub>) calculations revealed that S<sup>0</sup> disproportionation under in situ conditions is energy yielding. Microsensor profiles through the mat-sediment interface showed that <i>Beggiatoa</i> mats consume dissolved sulfide and oxygen, but a net increase in acidity was only observed in the sediments below. Together, these findings suggest that disproportionation is an important sink for S<sup>0</sup> generated by microbial sulfide oxidation in this oxygen-limited system and may contribute to the weathering of carbonate rocks and sediments in sulfur-rich environments.</p>","PeriodicalId":173,"journal":{"name":"Geobiology","volume":"21 6","pages":"791-803"},"PeriodicalIF":2.7000,"publicationDate":"2023-09-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/gbi.12574","citationCount":"0","resultStr":"{\"title\":\"Sulfur disproportionating microbial communities in a dynamic, microoxic-sulfidic karst system\",\"authors\":\"Heidi S. Aronson, Christian E. Clark, Douglas E. LaRowe, Jan P. Amend, Lubos Polerecky, Jennifer L. Macalady\",\"doi\":\"10.1111/gbi.12574\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Biogeochemical sulfur cycling in sulfidic karst systems is largely driven by abiotic and biological sulfide oxidation, but the fate of elemental sulfur (S<sup>0</sup>) that accumulates in these systems is not well understood. The Frasassi Cave system (Italy) is intersected by a sulfidic aquifer that mixes with small quantities of oxygen-rich meteoric water, creating Proterozoic-like conditions and supporting a prolific ecosystem driven by sulfur-based chemolithoautotrophy. To better understand the cycling of S<sup>0</sup> in this environment, we examined the geochemistry and microbiology of sediments underlying widespread sulfide-oxidizing mats dominated by <i>Beggiatoa</i>. Sediment populations were dominated by uncultivated relatives of sulfur cycling chemolithoautotrophs related to <i>Sulfurovum</i>, <i>Halothiobacillus</i>, <i>Thiofaba</i>, <i>Thiovirga</i>, <i>Thiobacillus</i>, and <i>Desulfocapsa</i>, as well as diverse uncultivated anaerobic heterotrophs affiliated with <i>Bacteroidota</i>, Anaerolineaceae, Lentimicrobiaceae, and Prolixibacteraceae. <i>Desulfocapsa</i> and <i>Sulfurovum</i> populations accounted for 12%–26% of sediment 16S rRNA amplicon sequences and were closely related to isolates which carry out autotrophic S<sup>0</sup> disproportionation in pure culture. Gibbs energy (∆<i>G</i><sub><i>r</i></sub>) calculations revealed that S<sup>0</sup> disproportionation under in situ conditions is energy yielding. Microsensor profiles through the mat-sediment interface showed that <i>Beggiatoa</i> mats consume dissolved sulfide and oxygen, but a net increase in acidity was only observed in the sediments below. 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Sulfur disproportionating microbial communities in a dynamic, microoxic-sulfidic karst system
Biogeochemical sulfur cycling in sulfidic karst systems is largely driven by abiotic and biological sulfide oxidation, but the fate of elemental sulfur (S0) that accumulates in these systems is not well understood. The Frasassi Cave system (Italy) is intersected by a sulfidic aquifer that mixes with small quantities of oxygen-rich meteoric water, creating Proterozoic-like conditions and supporting a prolific ecosystem driven by sulfur-based chemolithoautotrophy. To better understand the cycling of S0 in this environment, we examined the geochemistry and microbiology of sediments underlying widespread sulfide-oxidizing mats dominated by Beggiatoa. Sediment populations were dominated by uncultivated relatives of sulfur cycling chemolithoautotrophs related to Sulfurovum, Halothiobacillus, Thiofaba, Thiovirga, Thiobacillus, and Desulfocapsa, as well as diverse uncultivated anaerobic heterotrophs affiliated with Bacteroidota, Anaerolineaceae, Lentimicrobiaceae, and Prolixibacteraceae. Desulfocapsa and Sulfurovum populations accounted for 12%–26% of sediment 16S rRNA amplicon sequences and were closely related to isolates which carry out autotrophic S0 disproportionation in pure culture. Gibbs energy (∆Gr) calculations revealed that S0 disproportionation under in situ conditions is energy yielding. Microsensor profiles through the mat-sediment interface showed that Beggiatoa mats consume dissolved sulfide and oxygen, but a net increase in acidity was only observed in the sediments below. Together, these findings suggest that disproportionation is an important sink for S0 generated by microbial sulfide oxidation in this oxygen-limited system and may contribute to the weathering of carbonate rocks and sediments in sulfur-rich environments.
期刊介绍:
The field of geobiology explores the relationship between life and the Earth''s physical and chemical environment. Geobiology, launched in 2003, aims to provide a natural home for geobiological research, allowing the cross-fertilization of critical ideas, and promoting cooperation and advancement in this emerging field. We also aim to provide you with a forum for the rapid publication of your results in an international journal of high standing. We are particularly interested in papers crossing disciplines and containing both geological and biological elements, emphasizing the co-evolutionary interactions between life and its physical environment over geological time.
Geobiology invites submission of high-quality articles in the following areas:
Origins and evolution of life
Co-evolution of the atmosphere, hydrosphere and biosphere
The sedimentary rock record and geobiology of critical intervals
Paleobiology and evolutionary ecology
Biogeochemistry and global elemental cycles
Microbe-mineral interactions
Biomarkers
Molecular ecology and phylogenetics.