Adaptive bidirectional extracellular electron transfer during accelerated microbiologically influenced corrosion of stainless steel

Li, Ziyu; Chang, Weiwei; Cui, Tianyu; Xu, Dake; Zhang, Dawei; Lou, Yuntian; Qian, Hongchang; Song, Hao; Mol, J.M.C.; Cao, Fahe; Gu, Tingyue; Li, Yong

doi:10.1038/s43246-021-00173-8

Cited by 53 publications

(28 citation statements)

References 57 publications

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“…Shewanella oneidensis MR-1 is an attractive model microorganism for the study of corrosion mechanisms because: it is genetically tractable; it grows aerobically and anaerobically; it grows with H 2 as the electron donor; it can oxidize reduced flavins to support respiration; and it is capable of direct electron exchange with minerals and electrodes (Fredrickson et al, 2008;Hernandez-Santana et al, 2022;Jiang et al, 2020;Ross et al, 2011;Rowe et al, 2018;Shi et al, 2016). Anaerobic corrosion via H 2 or flavins as electron shuttles as well as direct electron uptake from Fe 0 have all been proposed as potential mechanisms for corrosion by S. oneidensis and related species (Herrera and Videla, 2009;Jiang et al, 2020;Jin et al, 2019;Kalnaowakul et al, 2020;Li et al, 2021aLi et al, , 2021bLutterbach et al, 2009;Miller et al, 2018;Philips et al, 2018;Schütz et al, 2015;Shi et al, 2006;Turick et al, 2002;Windt et al, 2003;Wurzler et al, 2020). However, none of the suggested mechanisms were rigorously evaluated with construction of the appropriate mutant strains or other strategies to rule out alternative mechanisms.…”

Section: Introductionmentioning

confidence: 99%

Direct microbial electron uptake as a mechanism for stainless steel corrosion in aerobic environments

Zhou

Zhang

et al. 2022

Water Research

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Section: Introductionmentioning

confidence: 99%

Direct microbial electron uptake as a mechanism for stainless steel corrosion in aerobic environments

Zhou

Zhang

et al. 2022

Water Research

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“…oneidensis MR-1 biofilms on stainless steel. Li et al utilized riboflavin, an endogenous redox mediator produced by Shewanella, and polarized the ultramicroelectrode tip of SECM to either riboflavin reducing (−0.6 V vs Ag|AgCl) or oxidizing (−0.2 V vs Ag|AgCl) potentials, while biofilms of the bacterial cells were grown on stainless steel electrodes with or without passive layers . The study provided in situ evidence of the EET process taking place during the corrosion process, and revealed that the bacterial cells can perform bidirectional extracellular electron transfer using the diffusible mediator depending on the state of the steel surface (active or passive).…”

Section: Methods To Study Enzymatic and Microbial Electrodesmentioning

confidence: 99%

Enzymatic and Microbial Electrochemistry: Approaches and Methods

et al. 2022

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The coupling of enzymes and/or intact bacteria with electrodes has been vastly investigated due to the wide range of existing applications. These span from biomedical and biosensing to energy production purposes and bioelectrosynthesis, whether for theoretical research or pure applied industrial processes. Both enzymes and bacteria offer a potential biotechnological alternative to noble/rare metal-dependent catalytic processes. However, when developing these biohybrid electrochemical systems, it is of the utmost importance to investigate how the approaches utilized to couple biocatalysts and electrodes influence the resulting bioelectrocatalytic response. Accordingly, this tutorial review starts by recalling some basic principles and applications of bioelectrochemistry, presenting the electrode and/or biocatalyst modifications that facilitate the interaction between the biotic and abiotic components of bioelectrochemical systems. Focus is then directed toward the methods used to evaluate the effectiveness of enzyme/bacteria−electrode interaction and the insights that they provide. The basic concepts of electrochemical methods widely employed in enzymatic and microbial electrochemistry, such as amperometry and voltammetry, are initially presented to later focus on various complementary methods such as spectroelectrochemistry, fluorescence spectroscopy and microscopy, and surface analytical/characterization techniques such as quartz crystal microbalance and atomic force microscopy. The tutorial review is thus aimed at students and graduate students approaching the field of enzymatic and microbial electrochemistry, while also providing a critical and up-to-date reference for senior researchers working in the field.

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“…In general, dissimilatory metal-reducing bacteria (DMRB) oxidise organic matter, including organic contaminants and hydrogen gas (H 2 ) in anoxic environments, and then transmit the released electrons to solid-phase minerals containing oxidised metal ions, such as manganese (Mn(IV)) and ferric iron (Fe(III)) for anaerobic respiration [38]. These microorganisms are commonly involved in the degradation/corrosion of organic matter [130] and metals [131,132], e.g., Pb, Cd, and As, in surface and sub-surface environments such as sediments of rivers, soils, lakes, and oceans. Additionally, the bacteria involved have the potential to dramatically alter the geochemistry of the surrounding Fe mineral-containing As in groundwater and sediments, resulting in As contamination of drinking water sources, diseases, poisoning, and human health disruption [39,133,134].…”

Section: Effect Of Dissimilatory Iron-reducing Bacteria's Transformat...mentioning

confidence: 99%

Significance of Shewanella Species for the Phytoavailability and Toxicity of Arsenic—A Review

Darma

Yang

Zandi

et al. 2022

Biology

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The distribution of arsenic continues due to natural and anthropogenic activities, with varying degrees of impact on plants, animals, and the entire ecosystem. Interactions between iron (Fe) oxides, bacteria, and arsenic are significantly linked to changes in the mobility, toxicity, and availability of arsenic species in aquatic and terrestrial habitats. As a result of these changes, toxic As species become available, posing a range of threats to the entire ecosystem. This review elaborates on arsenic toxicity, the mechanisms of its bioavailability, and selected remediation strategies. The article further describes how the detoxification and methylation mechanisms used by Shewanella species could serve as a potential tool for decreasing phytoavailable As and lessening its contamination in the environment. If taken into account, this approach will provide a globally sustainable and cost-effective strategy for As remediation and more information to the literature on the unique role of this bacterial species in As remediation as opposed to conventional perception of its role as a mobiliser of As.

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Adaptive bidirectional extracellular electron transfer during accelerated microbiologically influenced corrosion of stainless steel

Cited by 53 publications

References 57 publications

Direct microbial electron uptake as a mechanism for stainless steel corrosion in aerobic environments

Direct microbial electron uptake as a mechanism for stainless steel corrosion in aerobic environments

Enzymatic and Microbial Electrochemistry: Approaches and Methods

Significance of Shewanella Species for the Phytoavailability and Toxicity of Arsenic—A Review

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