Molecular mechanism for loss of nodulation properties of Rhizobium trifolii.

Abstract

Of 18 Rhizobium trifolii strains tested, 12 showed a high frequency of loss of nodulation ability after incubation in cultures at elevated temperatures. A correlation between loss of nodulation ability and loss of a large plasmid was demonstrated for R. trifolii. In some nonnodulating (Nod-) mutants, deletions occurred instead of total elimination of the plasmid molecule. The maximum curing effect was observed in bacteria incubated at 35 degrees C. After 4 or more days of incubation at this temperature, the viability of bacteria decreased markedly, and the number of nonnodulating mutants increased significantly. At the elevated temperature DNA synthesis was stopped completely after 2 h, whereas protein synthesis proceeded for a few days. Microscopic observations showed that during the first 3 days of incubation at the elevated temperature, the bacterial cells increased markedly in size. These large irregular cells then divided and produced Nod- clones. Nonnodulating clones did not result from the selection of temperature-resistant mutants. The presence of P-group plasmids in Rhizobium strains strongly inhibited the loss of nodulation ability during incubation at 35 degrees C. The observed phenomenon did not result from integrative suppression. It is possible that a product(s) of the genes of R-plasmids acts as a stabilizing agent on the replication process of the indigenous Rhizobium plasmids.