Intracellular calcite and sulfur dynamics of Achromatium cells observed in a lab-based enrichment and aerobic incubation experiment

We investigated the intracellular dynamics of calcite and sulfur in the large sulfur-oxidizing, calcite-accumulating bacterium Achromatium , with an emphasis on oxygen exposure as a physiological control. For this purpose, morphological changes and possible accretion mechanisms of calcite granules i...

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Bibliographic Details
Published in:Antonie van Leeuwenhoek 2019-02, Vol.112 (2), p.263-274
Main Authors: Yang, Tingting, Teske, Andreas, Ambrose, Wallace, Salman-Carvalho, Verena, Bagnell, Robert, Nielsen, Lars Peter
Format: Article
Language:English
Subjects:
Biomedical and Life Sciences
Buffers
Calcite
Deposition
Dynamics
Exposure
Granular materials
Granule cells
Intracellular
Life Sciences
Medical Microbiology
Microbiology
Morphology
Original Paper
Oxidation
Oxygen
Physiology
Plant Sciences
Protons
Soil Science & Conservation
Sulfates
Sulfides
Sulfur
Sulfur oxidation
Surface layers
Variation
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Summary:We investigated the intracellular dynamics of calcite and sulfur in the large sulfur-oxidizing, calcite-accumulating bacterium Achromatium , with an emphasis on oxygen exposure as a physiological control. For this purpose, morphological changes and possible accretion mechanisms of calcite granules in cells that were freshly collected from natural Achromatium -containing sediment were compared to cells from the same source after prolonged exposure to atmospheric oxygen. Intracellular sulfur is oxidized and removed in response to oxygen exposure. Calcite granules also undergo distinct oxygen-related dynamics; they alternate between tightly packaged, smooth granules with narrow but sharply defined interstitial spaces in atmospheric oxygen-exposed cells, and more loosely packaged granules with irregular, bumpy surface texture and larger interstitial spaces in cells that were not artificially exposed to oxygen. These results suggest that morphological changes of the calcite granules reflect their changing physiological role inside the cell. Sulfur oxidation and calcite dissolution appear to be linked in that proton generation during sulfur oxidation is buffered by gradual calcite erosion, visible in the smooth, rounded surface morphology observed after oxygen exposure. Our results support the hypothesis that calcite dynamics buffer the intracellular pH fluctuations linked to electron acceptor limitation during proton-consuming sulfide oxidation to sulfur, and electron acceptor abundance during proton-generating sulfur oxidation to sulfate.
ISSN:0003-6072
1572-9699
DOI:10.1007/s10482-018-1153-2