Redox Transformations of Arsenic Oxyanions in Periphyton Communities

Overview

Journal Appl Environ Microbiol

Specialties Environmental Health
Microbiology

Date 2004 Nov 6

PMID 15528502

Citations 7

Authors

Thomas R Kulp

Shelley E Hoeft

Ronald S Oremland

Affiliations

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Abstract

Periphyton (Cladophora sp.) samples from a suburban stream lacking detectable dissolved As were able to reduce added As(V) to As(III) when incubated under anoxic conditions and, conversely, oxidized added As(III) to As(V) with aerobic incubation. Both types of activity were abolished in autoclaved controls, thereby demonstrating its biological nature. The reduction of As(V) was inhibited by chloramphenicol, indicating that it required the synthesis of new protein. Nitrate also inhibited As(V) reduction, primarily because it served as a preferred electron acceptor to which the periphyton community was already adapted. However, part of the inhibition was also caused by microbial reoxidation of As(III) linked to nitrate. Addition of [14C]glucose to anoxic samples resulted in the production of 14CO2, suggesting that the observed As(V) reduction was a respiratory process coupled to the oxidation of organic matter. The population density of As(V)-reducing bacteria within the periphyton increased with time and with the amount of As(V) added, reaching values as high as approximately 10(6) cells ml(-1) at the end of the incubation. This indicated that dissimilatory As(V) reduction in these populations was linked to growth. However, As(V)-respiring bacteria were found to be present, albeit at lower numbers (approximately 10(2) ml(-1)), in freshly sampled periphyton. These results demonstrate the presence of a bacterial population within the periphyton communities that is capable of two key arsenic redox transformations that were previously studied in As-contaminated environments, which suggests that these processes are widely distributed in nature. This assumption was reinforced by experiments with estuarine samples of Cladophora sericea in which we detected a similar capacity for anaerobic As(V) reduction and aerobic As(III) oxidation.

Citing Articles

Biotic and Abiotic Factors Influencing Arsenic Biogeochemistry and Toxicity in Fluvial Ecosystems: A Review.

Barral-Fraga L, Barral M, MacNeill K, Martina-Prieto D, Morin S, Rodriguez-Castro M Int J Environ Res Public Health. 2020; 17(7).

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Microbial Interspecies Interactions Affect Arsenic Fate in the Presence of Mn.

Liang J, Bai Y, Qu J Microb Ecol. 2017; 74(4):788-794.

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Regulation of arsenite oxidation by the phosphate two-component system PhoBR in Halomonas sp. HAL1.

Chen F, Cao Y, Wei S, Li Y, Li X, Wang Q Front Microbiol. 2015; 6:923.

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Characterization and transcription of arsenic respiration and resistance genes during in situ uranium bioremediation.

Giloteaux L, Holmes D, Williams K, Wrighton K, Wilkins M, Montgomery A ISME J. 2012; 7(2):370-83.

PMID: 23038171 PMC: 3554400. DOI: 10.1038/ismej.2012.109.

Coupled arsenotrophy in a hot spring photosynthetic biofilm at Mono Lake, California.

Hoeft S, Kulp T, Han S, Lanoil B, Oremland R Appl Environ Microbiol. 2010; 76(14):4633-9.

PMID: 20511421 PMC: 2901740. DOI: 10.1128/AEM.00545-10.

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