[ITS-polymorphism of salt-tolerant and salt-sensitive native isolates of Sinorhizoblum meliloti--symbionts of alfalfa, clover and fenugreek plants].

Polymorphism of rrs-rrl sequence of ribosomal operons (intergenic sequence, ITS) was studied among 81 isolates of Sinorhizobium meliloti (AK001-AK210) derived from the collection of alfalfa nodulating bacteria of the Laboratory of genetics of ARRIAM, by using species-specific primers FGPS 1490/FGPL132VM. Isolates were obtained from nodules of different species of wild host plants from Medicago, Melilotus and Trigonella genera grown in salinized North-Western region of Kazakhstan. The typical structure of ITS, similar to that of test strain Rm1021, was dominant in native rhizobia population, while in one third of the isolates (33.3%) this sequence was divergent. Among the latter, the ITS type of strain AK83 (RCAM00182) was dominant. Here, we show for the first time that isolates with reduced level of salt-tolerance had more diverse intergenic sequences of rrn-operons. No phylogenetic separation was observed between isolates grouped on the basis of their tolerance or sensitivity towards 0.6 M NaCl. However, the frequency of divergent ITS types within the two groups of rhizobia depended on the host symbiotic preference observed in natural environment, allowing to speculate about the existence of a chromosome types specific for S. meliloti isolates with differential salt tolerance. In conclusion, we propose that in the area subjected to secondary salinization, which are also the centre of introgressive hybridization of alfalfa, micro-evolutionary processes, affecting rrn-operons and associated with salt adaptation, are also occurring in symbiotic root nodule bacteria populations.

[Genetic resources of nodule bacteria].

Nodule bacteria (rhizobia) form highly specific symbiosis with leguminous plants. The efficiency of accumulation of biological nitrogen depends on molecular-genetic interaction between the host plant and rhizobia. Genetic characteristics of microsymbiotic strains are crucial in developing highly productive and stress-resistant symbiotic pairs: rhizobium strain-host plant cultivar (species). The present review considers the issue of studying genetic resources of nodule bacteria to identify genes and their blocks, responsible for the ability of rhizobia to form highly effective symbiosis in various agroecological conditions. The main approaches to investigation of intraspecific and interspecific genetic and genomic diversity of nodule bacteria are considered, from MLEE analysis to the recent methods of genomic DNA analysis using biochips. The data are presented showing that gene centers of host plants are centers of genetic diversification of nodule bacteria, because the intraspecific polymorphism of genetic markers of the core and the accessory rhizobial genomes is extremely high in them. Genotypic features of trapped and nodule subpopulations of alfalfa nodule bacteria are discussed. A survey of literature showed that the genomes of natural strains in alfalfa gene centers exhibit significant differences in genes involved in control of metabolism, replication, recombination, and the formation of defense response (hsd genes). Natural populations of rhizobia are regarded as a huge gene pool serving as a source of evolutionary innovations.

[Symbiosis between the nodule bacterium Sinorhizobium meliloti and alfalfa (Medicago sativa) under salinization conditions].

Two hundred forty-three isolates of alfalfa nodule bacteria (Sinorhizobium meliloti) were obtained from legume nodules and soils sampled in the northern Aral region, experiencing secondary salinization. Isolates obtained from nodules (N isolates) were significantly more salt-tolerant than those from soils (S isolates) when grown in a liquid medium with 3.5% NaCl. It was found that wild species of alfalfa, melilot, and trigonella preferably formed symbioses with salt-tolerant nodule bacteria in both salinized and nonsalinized soils. Only two alfalfa species, Medicago falcata and M. trautvetteri, formed efficient symbioses in soils contrasting in salinity. The formation of efficient symbiosis with alfalfa in the presence of 0.6% NaCl was studied in 36 isolates (N and S) differing in salt tolerance and symbiotic efficiency. Fifteen isolates formed efficient symbioses in the presence of salt. The increase in the dry weight of the plants was 25-68% higher than in the control group. The efficiency of symbiotic interaction under salinization conditions depended on the efficiency of the isolates under standard conditions but did not correlate with the source of nodule bacteria (soil or nodule) or their salt tolerance. The results indicate that nodule bacterium strains forming efficient symbioses under salinization conditions can be found.

[Instability of a cryptic plasmid in Sinorhizobium meliloti P108 during symbiosis of it with alfalfa Medicago sativa]. / Nestabil'nost' kripticheskikh plazmid u shtamma Sinorhizobium meliloti P108 v protsesse simbioza ego s liutsernoi Medicago sativa.

Instability of cryptic plasmids in Sinorhizobium meliloti laboratory strains SKhM1-188, DM7-R, and P108 as well as in their clones isolated from nodules of alfalfa grown during a long-term microvegetation experiment (120 days) was studied. The isolated clones of strains SKhM1-188 and DM7-R manifested stable inheritance of plasmids, whereas 12.7-14.0% of clones with changed plasmid profile were detected in a population of clones from strain P108. These segregants were designated as P108c. Segregants P108c exhibited significantly decreased symbiotic effectiveness, nitrogenase activity, and the competitiveness with respect to alfalfa, compared to the original strain P108. It was established that a 80-kb deletion occurred in a larger of two cryptic plasmids (240 and 230 kb) of segregants P108c. It was concluded that genetic rearrangements are possible in rhizobial clones that did not undergo structural transformation and retained viability in the nodule during the natural vegetation period of alfalfa.

[Genetic diversity of a natural population of Sinorhizobium meliloti, detected during analysis of a cryptic plasmid and ISRm2011-2 fingerprints]. / Geneticheskoe raznoobrazie prirodnoi populiatsii Sinorhizobium meliloti, vyiavlennoe pri analize kripticheskikh plazmid i ISRm2001-2-fingerprintov.

Fifty-six natural strains of alfalfa nodule bacteria were isolated from samples of the soil under wild legume and alfalfa in two different field sites of Irkutsk oblast. Based on the results of analysis of plasmid profile, 11 different types of strains were detected, and 43 types were identified based on the results of hybridization with the insertion sequence element ISRm2011-2. Significant differences were found in the plasmid profile and IS fingerprints between strains isolated from the soil under alfalfa and the soil under legume. In contrast, strains growing at some distance from each other differed only in the IS fingerprints. From a comparison of results obtained in the assessment of plasmid profile and in analysis of IS fingerprints with results of RFLP analysis in strains, the conclusion about the transference of cryptic plasmids between strains and genetic rearrangements in strains of this population was drawn.

[Analysis of plasmids in Rhizobium meliloti strains of different geographical origin]. / Analiz plazmid u shtammov Rhizobium meliloti razlichnogo geograficheskogo proiskhozhdeniia.

The presence of 1-3 additional plasmids ranging from 16 to 400 Md in mol mass was revealed in bacterial cells besides a megaloplasmid in most of 34 Rhizobium meliloti strains studied. No correlation was found between plasmids pattern and geographical origin of isolation source of the strain analyzed.