Spatial ecology of bacteria at the microscale in soil

Despite an exceptional number of bacterial cells and species in soils, bacterial diversity seems to have little effect on soil processes, such as respiration or nitrification, that can be affected by interactions between bacterial cells. The aim of this study is to understand how bacterial cells are...

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Bibliographic Details
Published in:PloS one 2014-01, Vol.9 (1), p.e87217-e87217
Main Authors: Raynaud, Xavier, Nunan, Naoise
Format: Article
Language:English
Subjects:
Agriculture
Analysis
Bacteria
Biodiversity
Biodiversity and Ecology
Biology
Bulk density
Cell interactions
Earth Sciences
Ecology
Environmental science
Environmental Sciences
Gaussian process
Mathematical models
Mathematics
Microbial Interactions
Models, Biological
Mutualism
Nitrification
Normal distribution
Predation
Scaling
Soil analysis
Soil bacteria
Soil Microbiology
Soil microorganisms
Soils
Spatial distribution
Species
Species diversity
Statistical models
Studies
Two dimensional analysis
Two dimensional models
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Summary:Despite an exceptional number of bacterial cells and species in soils, bacterial diversity seems to have little effect on soil processes, such as respiration or nitrification, that can be affected by interactions between bacterial cells. The aim of this study is to understand how bacterial cells are distributed in soil to better understand the scaling between cell-to-cell interactions and what can be measured in a few milligrams, or more, of soil. Based on the analysis of 744 images of observed bacterial distributions in soil thin sections taken at different depths, we found that the inter-cell distance was, on average 12.46 µm and that these inter-cell distances were shorter near the soil surface (10.38 µm) than at depth (>18 µm), due to changes in cell densities. These images were also used to develop a spatial statistical model, based on Log Gaussian Cox Processes, to analyse the 2D distribution of cells and construct realistic 3D bacterial distributions. Our analyses suggest that despite the very high number of cells and species in soil, bacteria only interact with a few other individuals. For example, at bacterial densities commonly found in bulk soil (10(8) cells g(-1) soil), the number of neighbours a single bacterium has within an interaction distance of ca. 20 µm is relatively limited (120 cells on average). Making conservative assumptions about the distribution of species, we show that such neighbourhoods contain less than 100 species. This value did not change appreciably as a function of the overall diversity in soil, suggesting that the diversity of soil bacterial communities may be species-saturated. All in all, this work provides precise data on bacterial distributions, a novel way to model them at the micrometer scale as well as some new insights on the degree of interactions between individual bacterial cells in soils.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0087217