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
The deep intraterrestrial biosphere
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
INTRODUCTION
Exploration of the microbial world started slowly about 350 years ago, when van Leeuwenhoek and his contemporaries first focused their microscopes on extremely small living things. It is only during the last 20 years, however, that exploration of the world of intraterrestrial microbes has gathered momentum. Previously, it had generally been assumed that persistent life could not exist deep underground, out of reach of the sun and a photosynthetic ecosystem base. In the mid-1980s, scientists started to drill deep holes, from hundreds to a thousand metres deep, in both hard and sedimentary bedrock, and up came microbes in numbers equivalent to those found in many surface ecosystems. The world of intraterrestrial microbes had been discovered.
Intraterrestrial ecosystems have been reviewed elsewhere and the content of those reports need not be repeated here (Ghiorse & Wilson, 1988; Pedersen, 1993a, 2000; Bachofen, 1997; Bachofen et al., 1998; Fredrickson & Fletcher, 2001; Amend & Teske, 2005). Instead, this chapter will focus on characteristics that distinguish the intraterrestrial from the terrestrial world.
Most ecosystem environments have specific, distinguishing characteristics. The environments of intraterrestrial microbial ecosystems occupy a special position, differing substantially in many respects from those of most surface-based ecosystems. In many ways, underground ecosystems must be approached quite differently from the way in which those on the surface would be approached.
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- Micro-organisms and Earth Systems , pp. 233 - 246Publisher: Cambridge University PressPrint publication year: 2005