Symbiotic N2-fixing bradyrhizobia nodulate various leguminous plants and possess a large symbiosis island (SI) encoding symbiotic functions in their genomes. We obtained 30 rhizobial isolates from root nodules of the tribe Desmodieae of native leguminous plants in northern Japan. Based on their 16S rRNA gene sequences, most isolates (24/30=80%) phylogenetically belonged to Bradyrhizobium. Two isolates (LCT1 and LCT2) from Lespedeza cuneata were placed phylogenetically with Bradyrhizobium diazoefficiens USDA110T, a well-studied soybean (Glycine max [L.] Merr.) symbiont. Genomic comparisons revealed different SIs in the Met-tRNA and Val-tRNA genes on the respective genomes. In contrast, core genomic regions outside the SI regions showed strong collinearity between strains LCT2 and USDA110. Phenotypically, LCT2 formed N2-fixing root nodules on L. cuneata, an original host plant, but not on soybean, whereas USDA110 formed N2-fixing root nodules on soybean, but not on L. cuneata. Therefore, the SI variants were expected to contain the genes responsible for this host specificity. Genes relevant to the type III secretion system (T3SS) showed less homology between LCT2 and USDA110 than nod genes encoding Nod factor biosynthesis. Host plant inoculations with T3SS mutants suggested the involvement of T3SS effectors in differential host specificity. Therefore, the acquisition of distinct SI variants may confer strong host specificity through symbiotic interactions between Bradyrhizobium and host legumes. We discuss the possible pathway of symbiotic bradyrhizobial evolution and its application to the mitigation of greenhouse gas emissions.
Keywords: Bradyrhizobium; genome; symbiosis island; type III secretion system.