Paraburkholderia spp. are the main rhizobial microsymbionts of Mimosa tenuiflora (Willd.) Poir. in soils of the Brazilian tropical dry forests (Caatinga biome)

•Mimosa tenuiflora is nodulated preferably by Paraburkholderia in the Brazilian tropical dry forest (Caatinga).•Genetic variability was very high among the bacteria.•Some Paraburkholderia strains are probably members of a new symbiovar branch.•Horizontal gene transfer probably occurs among M. tenuif...

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Published in:Systematic and applied microbiology Vol. 44; no. 3; p. 126208
Main Authors: Dias, Marcos André Moura, Bomfim, Claudia Silva Gomes, Rodrigues, Dalila Ribeiro, da Silva, Aleksandro Ferreira, Santos, Jéssica Caroline Souza, do Nascimento, Tailane Ribeiro, Martins, Lindete Míria Vieira, Dantas, Bárbara França, Ribeiro, Paula Rose de Almeida, de Freitas, Ana Dolores Santiago, Fernandes-Júnior, Paulo Ivan
Format: Journal Article
Language:English
Published: Germany Elsevier GmbH 01-05-2021
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Summary:•Mimosa tenuiflora is nodulated preferably by Paraburkholderia in the Brazilian tropical dry forest (Caatinga).•Genetic variability was very high among the bacteria.•Some Paraburkholderia strains are probably members of a new symbiovar branch.•Horizontal gene transfer probably occurs among M. tenuiflora alpha- and beta-rhizobia. Mimosa tenuiflora (Willd.) Poir. is widespread in southern and central American drylands, but little information is available concerning its associated rhizobia. Therefore, this study aimed to characterize M. tenuiflora rhizobia from soils of the tropical dry forests (Caatinga) in Pernambuco State, Brazil, at the molecular and symbiotic levels. Soil samples of pristine Caatinga areas in four municipalities were used to grow M. tenuiflora. First, the bacteria from root nodules were subjected to nodC/nifH gene amplification, and the bacteria positive for both genes had the 16S rRNA gene sequenced. Then, ten strains were evaluated using recA, gyrB, and nodC gene sequences, and seven of them had their symbiotic efficiency assessed. Thirty-two strains were obtained and 22 of them were nodC/nifH positive. Twenty strains clustered within Paraburkholderia and two within Rhizobium by 16S rRNA gene sequencing. The beta-rhizobia were similar to P. phenoliruptrix (12) and P. diazotrophica (8). Both alpha-rhizobia were closely related to R. miluonense. The recA + gyrB phylogenetic analysis clustered four and five strains within the P. phenoliruptrix and P. diazotrophica branches, respectively, but they were somewhat divergent to the 16S rRNA phylogeny. For Rhizobium sp. ESA 637, the recA + gyrB phylogeny clustered the strain with R. jaguaris. The nodC phylogeny indicated that ESA 626, ESA 629, and ESA 630 probably represented a new symbiovar branch. The inoculation assay showed high symbiotic efficiency for all tested strains. The results indicated high genetic diversity and efficiency of M. tenuiflora rhizobia in Brazilian drylands and included P. phenoliruptrix-like bacteria in the list of efficient beta-rhizobia in the Caatinga biome.
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ISSN:0723-2020
1618-0984
DOI:10.1016/j.syapm.2021.126208