Abstract
Two complementary forces shape microbial genomes: vertical inheritance of genes by phylogenetic descent, and acquisition of new genes related to adaptation to particular habitats and lifestyles. Quantification of the relative importance of each driving force proved difficult. We determined the contribution of each factor, and identified particular genes or biochemical/cellular processes linked to environmental preferences (i.e., propensity of a taxon to live in particular habitats). Three types of data were confronted: (i) complete genomes, which provide gene content of different taxa; (ii) phylogenetic information, via alignment of 16S rRNA sequences, which allowed determination of the distance between taxa, and (iii) distribution of species in environments via 16S rRNA sampling experiments, reflecting environmental preferences of different taxa. The combination of these three datasets made it possible to describe and quantify the relationships among them. We found that, although phylogenetic descent was responsible for shaping most genomes, a discernible part of the latter was correlated to environmental adaptations. Particular families of genes were identified as environmental markers, as supported by direct studies such as metagenomic sequencing. These genes are likely important for adaptation of bacteria to particular conditions or habitats, such as carbohydrate or glycan metabolism genes being linked to host-associated environments.
Highlights
Microorganisms inherit a genome from their parent cells that reflects their phylogeny
We showed in a previous work that even though prokaryotic taxa are remarkably cosmopolitan (Tamames et al, 2010), in many instances they show environmental preferences that shape the diversity found in different environments
To obtain a set of genomes annotated with comparable completeness, we analyzed the distribution of the number of Clusters of orthologous groups (COGs) vs. genomic size in the 1384 genomes
Summary
Microorganisms inherit a genome from their parent cells that reflects their phylogeny. The genes within the genome determine the functions the organism can carry out and, the places where it can live. Microbes are confronted with a variety of habitats that impose particular constraints on them. Environments can be classified on this basis (Tamames et al, 2010). Particular genes are required by bacteria in order to overcome the hurdles imposed by such environmental constraints. The interplay between these two forces, related to evolution and ecology respectively, is the cause of the observed distribution of microbial taxa in different environments, and it has resulted in the partitioning of genomes into a core and a flexible
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