Book contents
- Frontmatter
- Contents
- Contributors
- Editors' Preface
- Isotopic-labelling methods for deciphering the function of uncultured micro-organisms
- Biofilms and metal geochemistry: the relevance of micro-organism-induced geochemical transformations
- Minerals, mats, pearls and veils: themes and variations in giant sulfur bacteria
- Soil micro-organisms in Antarctic dry valleys: resource supply and utilization
- New insights into bacterial cell-wall structure and physico-chemistry: implications for interactions with metal ions and minerals
- Horizontal gene transfer of metal homeostasis genes and its role in microbial communities of the deep terrestrial subsurface
- Biosilicification: the role of cyanobacteria in silica sinter deposition
- Metabolic diversity in the microbial world: relevance to exobiology
- Biogeochemical cycling in polar, temperate and tropical coastal zones: similarities and differences
- Fungal roles and function in rock, mineral and soil transformations
- The deep intraterrestrial biosphere
- Iron, nitrogen, phosphorus and zinc cycling and consequences for primary productivity in the oceans
- Mechanisms and environmental impact of microbial metal reduction
- New insights into the physiology and regulation of the anaerobic oxidation of methane
- Biogeochemical roles of fungi in marine and estuarine habitats
- Role of micro-organisms in karstification
- Index
Minerals, mats, pearls and veils: themes and variations in giant sulfur bacteria
Published online by Cambridge University Press: 06 July 2010
- Frontmatter
- Contents
- Contributors
- Editors' Preface
- Isotopic-labelling methods for deciphering the function of uncultured micro-organisms
- Biofilms and metal geochemistry: the relevance of micro-organism-induced geochemical transformations
- Minerals, mats, pearls and veils: themes and variations in giant sulfur bacteria
- Soil micro-organisms in Antarctic dry valleys: resource supply and utilization
- New insights into bacterial cell-wall structure and physico-chemistry: implications for interactions with metal ions and minerals
- Horizontal gene transfer of metal homeostasis genes and its role in microbial communities of the deep terrestrial subsurface
- Biosilicification: the role of cyanobacteria in silica sinter deposition
- Metabolic diversity in the microbial world: relevance to exobiology
- Biogeochemical cycling in polar, temperate and tropical coastal zones: similarities and differences
- Fungal roles and function in rock, mineral and soil transformations
- The deep intraterrestrial biosphere
- Iron, nitrogen, phosphorus and zinc cycling and consequences for primary productivity in the oceans
- Mechanisms and environmental impact of microbial metal reduction
- New insights into the physiology and regulation of the anaerobic oxidation of methane
- Biogeochemical roles of fungi in marine and estuarine habitats
- Role of micro-organisms in karstification
- Index
Summary
MINERALS, MATS, PEARLS AND VEILS: A PANOPLY OF GIANT SULFUR BACTERIA
The biogeochemical cycling of sulfur has been at the heart of microbial ecology since the mid-19th century. This is due, at least in part, to the striking forms of many of the organisms involved in the transformation of reduced sulfur species. Giant sulfur bacteria were among the earliest micro-organisms to capture the interest of microbiologists exploring the links between geochemical cycling of the elements and the microbiota responsible. Consequently, giant sulfur bacteria were among the first bacteria described. Organisms resembling Beggiatoa (‘ Oscillatoria alba’) were described as early as 1803 (Vaucher, 1803), but were included in the genus Beggiatoa some time later (Trevisan, 1842). Thiothrix (Rabenhorst, 1865; Winogradsky, 1888), Achromatium (Schewiakoff, 1893) and Thioploca (Lauterborn, 1907) were all described by the early 20th century and Winogradsky (1887, 1888) had already formulated the principles of lithotrophic growth based on sulfide oxidation, from his work on Beggiatoa species. Surprisingly for such conspicuous organisms, novel giant sulfur bacteria are still being described (Guerrero et al., 1999; Schulz et al., 1999).
Achromatium
Bacteria of the genus Achromatium are remarkable. Cells of up to 125 μm in length have been reported (Babenzien et al., 2005; Head et al., 2000a) and, in addition to characteristic sulfur globules that become visible on treatment of the cells with dilute acid, their large oval cells are typically filled with enormous inclusions of calcium carbonate (Fig. 1).
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- Micro-organisms and Earth Systems , pp. 35 - 70Publisher: Cambridge University PressPrint publication year: 2005
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