Iron biomineralization by anaerobic neutrophilic iron-oxidizing bacteria | INSTITUT DE PHYSIQUE DU GLOBE DE PARIS

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  Iron biomineralization by anaerobic neutrophilic iron-oxidizing bacteria

Publication Type:

Journal Article

Source:

Geochimica Et Cosmochimica Acta, Volume 73, Issue 3, p.696-711 (2009)

ISBN:

0016-7037

Accession Number:

WOS:000262877000006

URL:

http://www.sciencedirect.com.biblioplanets.gate.inist.fr/science/article/pii/S0016703708006376

Keywords:

UMR 7154 ; Minéralogie ; N° Contribution : 2441

Abstract:

Minerals formed by bio-oxidation of ferrous iron (Fe(II)) at neutral pH, their association with bacterial ultrastructures as well as their impact on the metabolism of iron-oxidizing bacteria remain poorly understood. Here, we investigated iron biomineralization by the anaerobic nitrate-dependent iron-oxidizing bacterium Acidovorax sp. strain BoFeNI in the presence of dissolved Fe(II) using electron microscopy and scanning Transmission X-ray Microscopy (STXM). All detected minerals consisted mainly of amorphous iron phosphates, but based on their morphology and localization, three types of precipitates could be discriminated: (1) mineralized filaments at distance from the cells, (2) globules of 100 25 run in diameter, at the cell surface and (3) a 40-nm thick mineralized layer within the periplasm. All of those phases were shown to be intimately associated with organic molecules. Periplasmic encrustation was accompanied by an accumulation of protein moieties. In the same way, exopolysaccharides were associated with the extracellular mineralized filaments. The evolution of cell encrustation was followed by TFM over the time Course of a culture: cell encrustation proceeded progressively, with rapid precipitation in the periplasm (in a few tens of Minutes). followed by the formation of surface-bound globules. Moreover, we frequently observed an asymmetric mineral thickening at the cell poles. In parallel, the evolution of iron oxidation was quantified by STXM: iron both contained in the bacteria and in the extracellular precipitates reached complete oxidation within 6 days. While a progressive oxidation of Fe in the bacteria and in the medium could be observed, spatial redox (oxido-reduction state) heterogeneities were detected at the cell poles and in the extracellular precipitates after I day. All these findings provide new information to further the understanding of molecular processes involved in iron biomineralization by anaerobic iron-oxidizing bacteria and offer potential signatures of those metabolisms that can be looked for in the geological record. (C) 2008 Elsevier Ltd. All rights reserved.