Metapopulation dominance and genomic-island acquisition of Bradyrhizobium with superior catabolic capabilities

Metapopulation dominance and genomic-island acquisition of Bradyrhizobium with superior catabolic capabilities

Root nodule-forming rhizobia exhibit a bipartite lifestyle, replicating in soil and also within plant cells where they fix nitrogen for legume hosts. Host control models posit that legume hosts act as a predominant selective force on rhizobia, but few studies have examined rhizobial fitness in natur...

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Bibliographic Details
Published in:Proceedings of the Royal Society. B, Biological sciences Vol. 283; no. 1829; p. 20160496
Main Authors: Hollowell, Amanda C., Regus, John U., Turissini, David, Gano-Cohen, Kelsey A., Bantay, Roxanne, Bernardo, Andrew, Moore, Devora, Pham, Jonathan, Sachs, Joel L.
Format: Journal Article
Language:English
Published: England The Royal Society 27-04-2016
Subjects:
Bradyrhizobium - classification
Bradyrhizobium - genetics
Bradyrhizobium - metabolism
Carbon Cycle
Epidemic
Evolution, Molecular
Fabaceae - microbiology
Fitness
Genomic Island
Genomic Islands
Haplotypes
Host Specificity - genetics
Lotus - microbiology
Models, Genetic
Phylogeny
Rhizobia
Root Nodules, Plant - microbiology
Selective Sweep
Soil Microbiology
Symbiont
Symbiosis - genetics
symbiont
rhizobia
epidemic
fitness
selective sweep
genomic island
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Summary:Root nodule-forming rhizobia exhibit a bipartite lifestyle, replicating in soil and also within plant cells where they fix nitrogen for legume hosts. Host control models posit that legume hosts act as a predominant selective force on rhizobia, but few studies have examined rhizobial fitness in natural populations. Here, we genotyped and phenotyped Bradyrhizobium isolates across more than 800 km of the native Acmispon strigosus host range. We sequenced chromosomal genes expressed under free-living conditions and accessory symbiosis loci expressed in planta and encoded on an integrated ‘symbiosis island’ (SI). We uncovered a massive clonal expansion restricted to the Bradyrhizobium chromosome, with a single chromosomal haplotype dominating populations, ranging more than 700 km, and acquiring 42 divergent SI haplotypes, none of which were spatially widespread. For focal genotypes, we quantified utilization of 190 sole-carbon sources relevant to soil fitness. Chromosomal haplotypes that were both widespread and dominant exhibited superior growth on diverse carbon sources, whereas these patterns were not mirrored among SI haplotypes. Abundance, spatial range and catabolic superiority of chromosomal, but not symbiosis genotypes suggests that fitness in the soil environment, rather than symbiosis with hosts, might be the key driver of Bradyrhizobium dominance.
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ISSN:0962-8452
1471-2954
DOI:10.1098/rspb.2016.0496