Distribution of extensive nifH gene diversity across physical soil microenvironments.

TitleDistribution of extensive nifH gene diversity across physical soil microenvironments.
Publication TypeJournal Article
Year of Publication2006
AuthorsIzquierdo JA, Nüsslein K
JournalMicrob Ecol
Volume51
Issue4
Pagination441-52
Date Published2006 May
ISSN0095-3628
KeywordsBacteria, Base Sequence, DNA Primers, Genes, Bacterial, Multigene Family, Oxidoreductases, Phylogeny, Polymerase Chain Reaction, Soil Microbiology
Abstract

The diversity of nitrogen-fixing bacteria is well described for aquatic environments; however, terrestrial analyses remain mostly biased to rhizobial plant-microbe associations. We maximized the level of resolution for this study through the use of nucleotide sequence information extracted from a series of soil microenvironments, ranging from macroaggregates at 2000 microm to the clay fraction at < 75 microm in diameter. In addition, we attempted to create an overview of the distribution of terrestrial nitrogen fixers across such microenvironments by combining culture-independent techniques with a suite of natural soil environments from uniquely different origins. Soil diazotroph diversity was analyzed phylogenetically for 600 terrestrial nifH sequences from 12 midsized clone libraries based on microenvironments of three separate soils across a global scale. Statistical analyses of nifH gene clone libraries were used to estimate coverage, establish degrees of sequence overlap, and compare cluster distributions. These analyses revealed an extensive diversity in a tropical (19 phylotypes) and an arctic soil (17 phylotypes), and moderate diversity in a temperate soil (11 phylotypes). Within each soil, comparisons across aggregate size fractions delineated nifH gene cluster shifts within populations and degrees of sequence overlap that ranged from significantly different (arctic, tropical) to significantly similar (temperate). We suggest that this is due to population separation across aggregates of different size classes, which results from differences in the temporal stability of aggregates as niches for microbial communities. This study not only provides new knowledge of the arrangement of diazotrophic communities at the soil microscale, but it also contributes to the underrepresented knowledge of soil nifH sequences in the public databases.

DOI10.1007/s00248-006-9044-x
Alternate JournalMicrob. Ecol.
PubMed ID16645928