Microbial thiosulphate reaction arrays: the interactive roles of Fe(III), O₂ and microbial strain on disproportionation and oxidation pathways

In this work, we experimentally evaluate pH and [graphic removed] dynamics associated with abiotic and microbial [graphic removed] oxidation under varying [O₂], [Fe(III)] and microbial strain/consortia (two pure strains, Acidithiobacillus ferrooxidans, Acidithiobacillus thiooxidans, their consortia,...

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Veröffentlicht in:	Geobiology 2008-12, Vol.6 (5), p.461-470
Hauptverfasser:	WARREN, L.A, NORLUND, K.L.I, BERNIER, L
Format:	Artikel
Sprache:	eng
Schlagworte:	Acidithiobacillus - metabolism Ferric Compounds - metabolism Hydrogen-Ion Concentration Oxidation-Reduction Oxygen - metabolism Thiosulfates - metabolism Water Microbiology
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container_title	Geobiology
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creator	WARREN, L.A NORLUND, K.L.I BERNIER, L
description	In this work, we experimentally evaluate pH and [graphic removed] dynamics associated with abiotic and microbial [graphic removed] oxidation under varying [O₂], [Fe(III)] and microbial strain/consortia (two pure strains, Acidithiobacillus ferrooxidans, Acidithiobacillus thiooxidans, their consortia, and two enrichments from an acidic environmental system, Moose Lake 2002 and Moose Lake 2003). Results of the batch experiments demonstrate highly active microbial processing of [graphic removed] while abiotic controls under identical experimental conditions remain static with no pH decrease. When abiotic controls were manually titrated with acid to achieve similar pH decreases to those occurring in the microbial treatments, different S pathways were involved. In particular, disproportionation is a substantial component of initial microbial [graphic removed] processing, and is accelerated by the presence of Fe(III), indicating that recycling of S through intermediate oxidation states is likely to be widespread in acidic mine environments where high [Fe(III)] is common. Furthermore, the microbially mediated S reaction pathways were dependent on both environmental conditions and microbial strain/consortia, indicating that microbial community structure also plays a key role. Collectively, these results highlight the importance of microbial activity, their poor representation by abiotic S models, the likelihood that Fe(III), rather than O₂, is a key control on microbial S processing in acid environments and the need to identify the microbial community/strain involved.
doi_str_mv	10.1111/j.1472-4669.2008.00173.x
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Results of the batch experiments demonstrate highly active microbial processing of [graphic removed] while abiotic controls under identical experimental conditions remain static with no pH decrease. When abiotic controls were manually titrated with acid to achieve similar pH decreases to those occurring in the microbial treatments, different S pathways were involved. In particular, disproportionation is a substantial component of initial microbial [graphic removed] processing, and is accelerated by the presence of Fe(III), indicating that recycling of S through intermediate oxidation states is likely to be widespread in acidic mine environments where high [Fe(III)] is common. Furthermore, the microbially mediated S reaction pathways were dependent on both environmental conditions and microbial strain/consortia, indicating that microbial community structure also plays a key role. 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Results of the batch experiments demonstrate highly active microbial processing of [graphic removed] while abiotic controls under identical experimental conditions remain static with no pH decrease. When abiotic controls were manually titrated with acid to achieve similar pH decreases to those occurring in the microbial treatments, different S pathways were involved. In particular, disproportionation is a substantial component of initial microbial [graphic removed] processing, and is accelerated by the presence of Fe(III), indicating that recycling of S through intermediate oxidation states is likely to be widespread in acidic mine environments where high [Fe(III)] is common. Furthermore, the microbially mediated S reaction pathways were dependent on both environmental conditions and microbial strain/consortia, indicating that microbial community structure also plays a key role. 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Results of the batch experiments demonstrate highly active microbial processing of [graphic removed] while abiotic controls under identical experimental conditions remain static with no pH decrease. When abiotic controls were manually titrated with acid to achieve similar pH decreases to those occurring in the microbial treatments, different S pathways were involved. In particular, disproportionation is a substantial component of initial microbial [graphic removed] processing, and is accelerated by the presence of Fe(III), indicating that recycling of S through intermediate oxidation states is likely to be widespread in acidic mine environments where high [Fe(III)] is common. Furthermore, the microbially mediated S reaction pathways were dependent on both environmental conditions and microbial strain/consortia, indicating that microbial community structure also plays a key role. 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subjects	Acidithiobacillus - metabolism Ferric Compounds - metabolism Hydrogen-Ion Concentration Oxidation-Reduction Oxygen - metabolism Thiosulfates - metabolism Water Microbiology
title	Microbial thiosulphate reaction arrays: the interactive roles of Fe(III), O₂ and microbial strain on disproportionation and oxidation pathways
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