Two radical-dependent mechanisms for anaerobic degradation of the globally abundant organosulfur compound dihydroxypropanesulfonate

2(S)-dihydroxypropanesulfonate (DHPS) is a microbial degradation product of 6-deoxy-6-sulfo-d-glucopyranose (sulfoquinovose), a component of plant sulfolipid with an estimated annual production of 1010tons. DHPS is also at millimolar levels in highly abundant marine phytoplankton. Its degradation and sulfur recycling by microbes, thus, play important roles in the biogeochemical sulfur cycle. However, DHPS degradative pathways in the anaerobic biosphere are not well understood. Here, we report the discovery and characterization of two O2-sensitive glycyl radical enzymes that use distinct mechanisms for DHPS degradation. DHPS-sulfolyase (HpsG) in sulfate- and sulfite-reducing bacteria catalyzes C–S cleavage to release sulfite for use as a terminal electron acceptor in respiration, producing H2S. DHPS-dehydratase (HpfG), in fermenting bacteria, catalyzes C–O cleavage to generate 3-sulfopropionaldehyde, subsequently reduced by the NADH-dependent sulfopropionaldehyde reductase (HpfD). Both enzymes are present in bacteria from diverse environments including human gut, suggesting the contribution of enzymatic radical chemistry to sulfur flux in various anaerobic niches.

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A gene cluster for taurine sulfur assimilation in an anaerobic human gut bacterium

Biochemical Journal ◽

10.1042/bcj20190486 ◽

2019 ◽

Vol 476 (15) ◽

pp. 2271-2279 ◽

Cited By ~ 1

Author(s):

Meining Xing ◽

Yifeng Wei ◽

Gaoqun Hua ◽

Mengya Li ◽

Ankanahalli N. Nanjaraj Urs ◽

...

Keyword(s):

Biochemical Characterization ◽

Anaerobic Bacteria ◽

Aerobic Bacteria ◽

Sulfur Source ◽

Sulfur Assimilation ◽

Human Gut ◽

Fermenting Bacteria ◽

Facultative Anaerobic Bacteria ◽

Reducing Bacteria

Abstract Aminoethylsulfonate (taurine) is widespread in the environment and highly abundant in the human body. Taurine and other aliphatic sulfonates serve as sulfur sources for diverse aerobic bacteria, which carry out cleavage of the inert sulfonate C–S bond through various O2-dependent mechanisms. Taurine also serves as a sulfur source for certain strict anaerobic fermenting bacteria. However, the mechanism of C–S cleavage by these bacteria has long been a mystery. Here we report the biochemical characterization of an anaerobic pathway for taurine sulfur assimilation in a strain of Clostridium butyricum from the human gut. In this pathway, taurine is first converted to hydroxyethylsulfonate (isethionate), followed by C–S cleavage by the O2-sensitive isethionate sulfo-lyase IseG, recently identified in sulfate- and sulfite-reducing bacteria. Homologs of the enzymes described in this study have a sporadic distribution in diverse strict and facultative anaerobic bacteria, from both the environment and the taurine-rich human gut, and may enable sulfonate sulfur acquisition in certain nutrient limiting conditions.

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The organosulfur compound dimethylsulfoniopropionate (DMSP) is utilized as an osmoprotectant by Vibrio species

Applied and Environmental Microbiology ◽

10.1128/aem.02235-20 ◽

2020 ◽

pp. AEM.02235-20

Author(s):

Gwendolyn J. Gregory ◽

Katherine E. Boas ◽

E. Fidelma Boyd

Keyword(s):

Marine Bacteria ◽

Heterotrophic Bacteria ◽

Turgor Pressure ◽

Organosulfur Compound ◽

Marine Species ◽

Sulfur Cycle ◽

Marine Phytoplankton ◽

Growth Defect ◽

Choline Transport ◽

Coral Mucus

Dimethylsulfoniopropionate (DMSP), a key component of the global geochemical sulfur cycle, is a secondary metabolite produced in large quantities by marine phytoplankton and utilized as an osmoprotectant, thermoprotectant and antioxidant. Marine bacteria can use two pathways to degrade and catabolize DMSP, a demethylation pathway and a cleavage pathway that produces the climate active gas dimethylsulfide (DMS). Whether marine bacteria can also accumulate DMSP as an osmoprotectant to maintain the turgor pressure of the cell in response to changes in external osmolarity has received little attention. The marine halophile Vibrio parahaemolyticus, contains at least six osmolyte transporters, four betaine carnitine choline transport (BCCT) carriers BccT1-BccT4 and two ABC-family ProU transporters. In this study, we showed that DMSP is used as an osmoprotectant by V. parahaemolyticus and several other Vibrio species including V. cholerae and V. vulnificus. Using a V. parahaemolyticus proU double mutant, we demonstrated that these ABC transporters are not required for DMSP uptake. However, a bccT null mutant lacking all four BCCTs had a growth defect compared to wild type in high salinity media supplemented with DMSP. Using mutants possessing only one functional BCCT in growth pattern assays, we identified two BCCT-family transporters, BccT1 and BccT2, which are carriers of DMSP. The only V. parahaemolyticus BccT homolog that V. cholerae and V. vulnificus possess is BccT3 and functional complementation in Escherichia coli MKH13 showed V. cholerae VcBccT3 could transport DMSP. In V. vulnificus strains, we identified and characterized an additional BCCT family transporter, which we named BccT5 that was also a carrier for DMSP.Importance DMSP is present in the marine environment, produced in large quantities by marine phytoplankton as an osmoprotectant, and is an important component of the global geochemical sulfur cycle. This algal osmolyte has not been previously investigated for its role in marine heterotrophic bacterial osmotic stress response. Vibrionaceae are marine species, many of which are halophiles exemplified by V. parahaemolyticus, a species that possesses at least six transporters for the uptake of osmolytes. Here, we demonstrated that V. parahaemolyticus and other Vibrio species can accumulate DMSP as an osmoprotectant and show that several BCCT family transporters uptake DMSP. These studies suggest that DMSP is a significant bacterial osmoprotectant, which may be important for understanding the fate of DMSP in the environment. DMSP is produced and present in coral mucus and Vibrio species form part of the microbial communities associated with them. The function of DMSP in these interactions is unclear, but could be an important driver for these associations allowing Vibrio proliferation. This work suggests that DMSP likely has an important role in heterotrophic bacteria ecology than previously appreciated.

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The organosulfur compound dimethylsulfoniopropionate (DMSP) is utilized as an osmoprotectant by Vibrio species

10.1101/2020.09.10.292482 ◽

2020 ◽

Author(s):

Gwendolyn J. Gregory ◽

Katherine E. Boas ◽

E. Fidelma Boyd

Keyword(s):

Metabolic Pathways ◽

Turgor Pressure ◽

Organosulfur Compound ◽

Marine Species ◽

Sulfur Cycle ◽

Marine Phytoplankton ◽

Growth Defect ◽

Wild Type ◽

Choline Transport ◽

Wide Range

AbstractDimethylsulfoniopropionate (DMSP) is a key component of the global geochemical sulfur cycle that is a secondary metabolite produced in large quantities by marine phytoplankton and utilized as an osmoprotectant. Bacterial DMSP lyases convert DMSP to the climate active gas dimethylsulfide (DMS). Whether marine bacteria can also accumulate DMSP as an osmoprotectant to maintain the turgor pressure of the cell in response to changes in external osmolarity remains unknown. The marine halophile Vibrio parahaemolyticus, contains at least six osmolyte transporters, four betaine carnitine choline transport (BCCT) carriers BccT1-BccT4 and two ABC-family ProU transporters. In this study, we showed that DMSP is used as an osmoprotectant by V. parahaemolyticus and several other Vibrio species including V. cholerae and V. vulnificus. Using a V. parahaemolyticus proU double mutant, we demonstrated that these ABC transporters are not required for DMSP uptake. However, a bccT null mutant lacking all four BCCTs had a growth defect compared to wild type in high salt media supplemented with DMSP. Using bccT triple mutants, possessing only one functional BCCT, in growth pattern assays, we identified two BCCT-family transporters, BccT1 and BccT2 are carriers of DMSP. Vibrio cholerae and V. vulnificus, only contain a homolog of BccT3 and functional complementation in Escherichia coli MKH13 showed only V. cholerae BccT3 could transport DMSP. In V. vulnificus strains, we identified and characterized an additional BCCT transporter that was also a carrier for DMSP. Phylogenetic analysis uncovered at least 11 distinct BCCT transporters among members of the Harveyi clade, with some species having up to 9 BCCTs as exemplified by V. jasicida.ImportanceDMSP is present in the marine environment, produced in large quantities by marine phytoplankton as an osmoprotectant, and is an important component of the global geosulfur cycle. The bacterial family Vibrionaceae is comprised of marine species, many of which are halophiles such as V. parahaemolyticus, which can utilize a wide range of osmolytes and possesses at least six transporters for the uptake of these compounds. Here, we demonstrated that V. parahaemolyticus and other Vibrio species can accumulate DMSP as an osmoprotectant and show that the BCCT family transporters were required. DMSP was transported by four different BCCT transporters; BccT1, BccT2, BccT3 and BccT5 depending on the species. Bioinformatics and phylogenetics demonstrated that Vibrio species contain a large number of BCCTs and that many of these are associated with different metabolic pathways.

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Dissolution of Arsenic Minerals Mediated by Dissimilatory Arsenate Reducing Bacteria: Estimation of the Physiological Potential for Arsenic Mobilization

BioMed Research International ◽

10.1155/2014/841892 ◽

2014 ◽

Vol 2014 ◽

pp. 1-12 ◽

Cited By ~ 24

Author(s):

Drewniak Lukasz ◽

Rajpert Liwia ◽

Mantur Aleksandra ◽

Sklodowska Aleksandra

Keyword(s):

Microbial Mats ◽

Arsenic Removal ◽

Anaerobic Growth ◽

Arsenic Compounds ◽

Copper Ore ◽

Terminal Electron Acceptor ◽

Reducing Bacteria ◽

Dissolution Of Minerals ◽

Arsenate Reducing Bacteria

The aim of this study was characterization of the isolated dissimilatory arsenate reducing bacteria in the context of their potential for arsenic removal from primary arsenic minerals through reductive dissolution. Four strains,Shewanellasp. OM1,Pseudomonassp. OM2,Aeromonassp. OM4, andSerratiasp. OM17, capable of anaerobic growth with As (V) reduction, were isolated from microbial mats from an ancient gold mine. All of the isolated strains: (i) produced siderophores that promote dissolution of minerals, (ii) were resistant to dissolved arsenic compounds, (iii) were able to use the dissolved arsenates as the terminal electron acceptor, and (iii) were able to use copper minerals containing arsenic minerals (e.g., enargite) as a respiratory substrate. Based on the results obtained in this study, we postulate that arsenic can be released from some As-bearing polymetallic minerals (such as copper ore concentrates or middlings) under reductive conditions by dissimilatory arsenate reducers in indirect processes.

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Glycyl Radical Enzymes and Sulfonate Metabolism in the Microbiome

Annual Review of Biochemistry ◽

10.1146/annurev-biochem-080120-024103 ◽

2021 ◽

Vol 90 (1) ◽

Author(s):

Yifeng Wei ◽

Yan Zhang

Keyword(s):

Bond Cleavage ◽

Anaerobic Bacteria ◽

Sulfur Cycle ◽

Annual Review ◽

Publication Date ◽

Strictly Anaerobic ◽

Glycyl Radical ◽

Free Radical Chemistry ◽

Reducing Bacteria ◽

Radical Enzymes

Sulfonates include diverse natural products and anthropogenic chemicals and are widespread in the environment. Many bacteria can degrade sulfonates and obtain sulfur, carbon, and energy for growth, playing important roles in the biogeochemical sulfur cycle. Cleavage of the inert sulfonate C–S bond involves a variety of enzymes, cofactors, and oxygen-dependent and oxygen-independent catalytic mechanisms. Sulfonate degradation by strictly anaerobic bacteria was recently found to involve C–S bond cleavage through O2-sensitive free radical chemistry, catalyzed by glycyl radical enzymes (GREs). The associated discoveries of new enzymes and metabolic pathways for sulfonate metabolism in diverse anaerobic bacteria have enriched our understanding of sulfonate chemistry in the anaerobic biosphere. An anaerobic environment of particular interest is the human gut microbiome, where sulfonate degradation by sulfate- and sulfite-reducing bacteria (SSRB) produces H2S, a process linked to certain chronic diseases and conditions. Expected final online publication date for the Annual Review of Biochemistry, Volume 90 is June 2021. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

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Sulfidogenesis from 2-Aminoethanesulfonate (Taurine) Fermentation by a Morphologically Unusual Sulfate-Reducing Bacterium,Desulforhopalus singaporensis sp. nov

Applied and Environmental Microbiology ◽

10.1128/aem.65.8.3328-3334.1999 ◽

1999 ◽

Vol 65 (8) ◽

pp. 3328-3334 ◽

Cited By ~ 50

Author(s):

Thomas J. Lie ◽

Michael L. Clawson ◽

Walter Godchaux ◽

Edward R. Leadbetter

Keyword(s):

Marine Bacterium ◽

Enrichment Culture ◽

Bond Cleavage ◽

Sole Source ◽

Sulfur Cycle ◽

Terminal Electron Acceptor ◽

Sulfate Reducing ◽

16S Ribosomal Dna ◽

End Products ◽

Reducing Bacteria

ABSTRACT A pure culture of an obligately anaerobic marine bacterium was obtained from an anaerobic enrichment culture in which taurine (2-aminoethanesulfonate) was the sole source of carbon, energy, and nitrogen. Taurine fermentation resulted in acetate, ammonia, and sulfide as end products. Other sulfonates, including 2-hydroxyethanesulfonate (isethionate) and cysteate (alanine-3-sulfonate), were not fermented. When malate was the sole source of carbon and energy, the bacterium reduced sulfate, sulfite, thiosulfate, or nitrate (reduced to ammonia) but did not use fumarate or dimethyl sulfoxide as a terminal electron acceptor for growth. Taurine-grown cells had significantly lower adenylylphosphosulfate reductase activities than sulfate-grown cells had, which was consistent with the notion that sulfate was not released as a result of oxidative C-S bond cleavage and then assimilated. The name Desulforhopalus singaporensis is proposed for this sulfate-reducing bacterium, which is morphologically unusual compared to the previously described sulfate-reducing bacteria by virtue of the spinae present on the rod-shaped, gram-negative, nonmotile cells; endospore formation was not discerned, nor was desulfoviridin detected. Granules of poly-β-hydroxybutyrate were abundant in taurine-grown cells. This organism shares with the other member of the genusDesulforhopalus which has been described a unique 13-base deletion in the 16S ribosomal DNA. It differs in several ways from a recently described endospore-forming anaerobe (K. Denger, H. Laue, and A. M. Cook, Arch. Microbiol. 168:297–301, 1997) that reportedly produces thiosulfate but not sulfide from taurine fermentation.D. singaporensis thus appears to be the first example of an organism which exhibits sulfidogenesis during taurine fermentation. Implications for sulfonate sulfur in the sulfur cycle are discussed.

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Removal of lead by sulfate-reducing bacteria in anaerobic continuous stirred tank reactors

Vietnam Journal of Biotechnology ◽

10.15625/1811-4989/14/3/9873 ◽

2016 ◽

Vol 14 (3) ◽

pp. 557-561

Author(s):

Nguyễn Thị Yên ◽

Kiều Thị Quỳnh Hoa

Keyword(s):

Sulfate Reducing Bacteria ◽

Stirred Tank ◽

Synthetic Wastewater ◽

Terminal Electron Acceptor ◽

Stirred Tank Reactors ◽

Sulfate Reducing ◽

Sulfide Production ◽

Continuous Stirred Tank ◽

Continuous Stirred Tank Reactors ◽

Reducing Bacteria

Lead contaminated wastewater negatively impacts to living organisms as well as humans. In recent years, a highly promising biological process using the anaerobic production of sulfide ions by sulfate-reducing bacteria has presented itself as an alternative option for the removal of lead. This process is based on microbial utilization of electron donors, such as organic compounds (carbon sources), and sulfate as the terminal electron acceptor for sulfide production. The biogenic hydrogen sulfide reacts with dissolved heavy metals to form insoluble metal sulfide precipitates Removal of lead by an enriched consortium of sulfate-reducing bacteria (DM10) was evaluated sulfate reduction, sulfide production and lead precipitation. Four parallel anaerobic continuous stirred tank reactors (CSTR, V = 2L) (referred as R1 - R4) were fed with synthetic wastewater containing Pb2+ in the concentrations of 0, 100, 150 and 200 mg L-1 of lead and operated with a hydraulic retention time of 5 days for 40 days. The loading rates of each metal in R1- R4 were 0, 20, 30 and 40 mg L-1 d-1, respectively. The results showed that there was no inhibition of SRB growth and that lead removal efficiencies of 99-100% for Pb2+ were achieved in R2 (100 mg L-1) and R3 (150 mg L-1) throughout the experiment. For the highest lead concentration of 200 mg L-1, a decrease in efficiency of removal (from 100 to 96%) was observed at the end of the experiment. The obtained result of this study might help for a better control operation and performance improvements of reactors.

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