Genomic insight of sulfate reducing bacterial genus Desulfofaba reveals their metabolic versatility in biogeochemical cycling

Gao, Ping; Zhang, Xiaoting; Huang, Xiaomei; Chen, Zhiyi; Marietou, Angeliki; Holmkvist, Lars; Qu, Lingyun; Finster, Kai; Gong, Xianzhe

doi:10.1186/s12864-023-09297-2

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2024

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Cited by 5 publications

References 78 publications

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Deciphering metabolic regulatory mechanisms in vital anaerobes for enhanced biogas production from protein-rich waste

Thamanna,

Chellapandi

2024

Syst Microbiol and Biomanuf

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Deciphering metabolic regulatory mechanisms in vital anaerobes for enhanced biogas production from protein-rich waste

Thamanna,

Chellapandi

2024

Syst Microbiol and Biomanuf

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Camellia oil alleviates type 2 diabetes mellitus through modulating gut microbiota and metabolites

Wang,

Li,

Podio

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Food Bioscience

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Photoelectron-Promoted Sulfate Reduction for Heavy Metal Removal without Organic Carbon Addition

Zhong,

Ren,

Guo

et al. 2024

Environ. Sci. Technol.

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Sulfate-reducing microorganisms (SRMs) show promise for heavy metal removal from contaminated environments, but their scalability is limited by reliance on organic carbon, sludge formation, and CO 2 emissions. This study investigates using photoelectrons from biogenic (Bio-ZnS) and abiogenic (Abio-ZnS) sphalerite nanoparticles to enhance the activity of Desulfovibrio desulfuricans G20 (G20) for sulfate reduction and lead removal without organic substrates. Both Abio-ZnS and Bio-ZnS NPs promote sulfate reduction and energy production in G20 cells under illumination without the addition of organic substrates, with Bio-ZnS achieving 1.6 times greater sulfate reduction and 3.1 times higher ATP production compared to Abio-ZnS. This superior performance of Bio-ZnS NPs is due to their wider band gap, higher photoconversion efficiency, lower charge-transfer resistance, and closer proximity to cells, which enable more efficient photoelectron uptake, enhanced intracellular electron transfer, and reduced energy consumption for motion and filamentation. The uptake of photoelectrons also promotes G20s resistance to high Pb 2+ concentrations through enhanced PbS precipitation, biofilm formation, enzymatic detoxification, and Pb 2+ efflux, thus improving long-term and cyclic lead removal by G20 under substrate-depleted conditions. This approach harnesses solar energy, reduces reliance on organic substrates, and lowers costs and CO 2 emissions, offering a sustainable solution for utilizing SRMs in bioremediation.

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Genomic insight of sulfate reducing bacterial genus Desulfofaba reveals their metabolic versatility in biogeochemical cycling

Cited by 5 publications

References 78 publications

Deciphering metabolic regulatory mechanisms in vital anaerobes for enhanced biogas production from protein-rich waste

Deciphering metabolic regulatory mechanisms in vital anaerobes for enhanced biogas production from protein-rich waste

Camellia oil alleviates type 2 diabetes mellitus through modulating gut microbiota and metabolites

Photoelectron-Promoted Sulfate Reduction for Heavy Metal Removal without Organic Carbon Addition

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