[Design of Guide RNA for CRISPR/Cas Plant Genome Editing].

CRISPR/Cas technology of genome editing is a powerful tool for making targeted changes in the DNA of various organisms, including plants. The choice of the precise nucleotide sequence (protospacer) in the gene to be edited is important in the design of guide RNA, which can be carried out by specialized software. We review and compare all the known on-line and off-line resources for guide RNA design, with special attention paid to tools capable of searching for off-target edits sites in plant genomes. The use of Cas12a may be preferable to Cas9. Techniques allowing C→T and G→A base editing without DNA cleavage are discussed along with the basic requirements for the design of effective and highly specific guide RNAs. Ways for improving guide RNA design software are presented. We also discuss the lesser risks of off-target editing in plant genomes as opposed to animal genomes. Examples of edited plant genomes including those that do not lead to the creation of transgenic plants are reviewed.

[Role of Bacterial Adhesin RAPA1 in Formation of Efficient Symbiosis of Rhizobium leguminosarum with Bean Plants].

Bacterial adhesins, the proteins responsible for attachment of plant growth-promoting rhizobacteria to plant roots, are involved in formation of stable associative symbioses. In the present work enhanced expression of the rapA1 adhesin gene in Rhizobium leguminosarum PVu5 was shown to improve the efficiency of nodulation on bean roots inoculated with the modified strain. The rapA1 gene was cloned into the pJN105Turbo plasmid, this construct was used for transformation of R. leguminosarum PVu5, bean plants were inoculated by this transgenic strain, and efficiency of root nodule formation was determined. In the plants treated with rapA1-transgenic rhizobia, the number of root nodules was on average two times higher than in the plants inoculated with the original strain. Aggregation of R. leguminosarum was achieved when the rapA1 gene expression was enhanced either in rhizobia or in the co-cultured modified strain E. coli pJN105TurboRapA1.

[Carbohydrate-binding sequences of the lectin genes in leguminous plants from the Galegeae and Hedysareae tribes].

The carbohydrate-binding sequences (CBS) of the lectin genes from legume plants of the genera Astragalus Lam., Oxytropis DC., and Hedysarum L. were determined. Computer-assisted analysis of nucleotide and predicted amino acid sequences of the lectin gene fragments examined revealed a high homology level between their CBS. At the same time, the CBS of Astragalus and Oxytropis were considerably different from the lectin gene CBS in the earlier examined representatives of the tribe Galegeae, Caragana frutex and C. arborescens. This fact probably points to the differences in the carbohydrate-binding specificity of the proteins examined, which can eventually affect their functional activity.

[Genetic characterization of wild leguminous nodular bacteria living in the South Urals].

Genetic diversity and phylogeny of rhizobia that nodulate 18 species of wild-growing bean plants of South Urals from 8 genera belonging to 4 tribes (Loteae, Genisteae, Galegeaev and Hedysareae) was studied. It was demonstrated that for the wild-growing plants of Galegeae and Hedysareae tribes symbiotic interaction with various strains of nodule bacteria that closely related to bacteria of Mesorhizobium sp. was typical of the plants of Genisteae tribe--to bacteria of Bradyrhizobium sp. In the nodules of Lortus ucrainicus from Loteae tribe we have found a rhizobium that is closely related to the bacteria of Mesorhizobium sp., and at Coronilla varia rhizobia strains obtained by us were close by sequence of a 16S pRNA gene to Rhizobium sp. In the nodules of some kinds of the investigated plants we found also minor species of a rhizobia, which structure is under the great influence of conditions of the host plant growth.

[Polymorphism of lectin genes in Lathyrus plants].

The carbohydrate-binding sequences of the lectin genes from spring vetchling Lathyrus vernus (L.) Bernh., marsh vetchling L. palustris (L.), and Gmelin's vetchling L. gmelinii (Fitsch) (Fabaceae) were determined. Computer-aided analysis revealed substantial differences between nucleotide and predicted amino acid sequences of the lectin gene regions examined in each of the three vetchling species tested. In the phylogenetic trees based on sequence similarity of carbohydrate-biding regions of legume lectins, the sequences examined formed a compact cluster with the lectin genes of the plants belonging to the tribe Fabeae. In each plant, L. vernus, L. palustris, and L. gmelinii, three different lectin-encoding genes were detected. Most of the substitutions were identified within the gene sequence responsible for coding the carbohydrate-binding protein regions. This finding may explain different affinity of these lectins to different carbohydrates, and as a consequence, can affect the plant host specificity upon development of symbiosis with rhizobium bacteria.

[Bioengineering of symbiotic systems: creation of new associative symbiosis with the use of lectins on the example of tobacco and colza].

"Barbate roots" in tobacco and colza transgenic on lectin gene were obtained with the use of a wild strain of Agrobacterium rhizogenes 15834 transformed with pCAMBIA1305.1 plasmid containing the full-size lectin gene (psl) from the Pisum sativum. Influence of expression oflectin gene on colonization oftransgenic roots with symbiont of pea (Rhizobium leguminosarum) was investigated. The number of adhered bacteria onto the roots transformed with lectin gene was 14-fold and 37-fold higher in comparison with the control; this confirms the interaction of R. leguminosarum with pea lectin at the surface of the transformed roots of tobacco and colza. The developed experimental approach, based on the simulation of recognition processes and early symbiotic interactions with lectins of pea plants, may, in perspective, be used for obtaining stable associations of economically valuable, nonsymbiotrophic plant species with rhizobia.

[Phylogenetic analysis of symbiotic genes of nodule bacteria in the plants of the genus Lathyrus (L.) (Fabaceae)].

The comparative analysis of the symbiotic genes nifD, nifH, nodA of wild-growing Lathyrus L. species (Fabaceae) connected by genes sequences of 16S aRNA to Rhizobium leguminosarum bv. viceae, Rhizobium tropici, Agrobacterium sp., and Phyllobacterium sp. was carried out. It was demonstrated that all tested genes of strains taken for analysis had high degree of homology with analogous genes of Rhizobium leguminosarum bv. viceae. It was suggested that symbiotic genes were introduced into Rhizobium tropici, Agrobacterium sp., and Phyllobacterium sp. strains by means of horizontal gene transfer over from Rhizobium leguminosarum bv. viceae strain. The recombinant strains were formed, capable to nodulate Lathyrus L. species that earlier was not considered characteristic for these plants.

[The symbiosis between oriental goat's rue and the root nodule bacteria Rhizobium galegae: specificity and competitiveness].

Competitiveness and genetic variation of the Rhizobium galegae strains from the collection of the All-Russia Institute of Agricultural Microbiology, Russian Academy of Agricultural Sciences, causing nodulation of oriental goat's rue under conditions of Bashkortostan soils (lacking this rhizobial species) were studied. It was demonstrated that of all the tested strains, the strains CIAM 0702 and CIAM 0704, each carrying two megaplasmids of 1500 and 2000 MDa, were the most competitive. RAPD (random amplified polymorphic DNA) analysis showed that R. galegae strains were able to intensively exchange the genetic material in the host plant rhizosphere. We did not succeed in detecting the local root nodule bacteria that were either initially able to infect oriental goat's rue or had adapted to infecting this species due to various genetic rearrangements.

[Bacteria closely related to Phyllobacterium trifolii according to their 16S rRNA gene are discovered in the nodules of Hungarian sainfoin].

The population genetic diversity and phylogeny of the bacteria entering the symbiosis with sainfoin that grows on the Chesnokovskaya Mountain, Ufa region, Republic of Bashkortostan, have been studied. RAPD analysis of DNA polymorphism of the microbial strains grown from the nodules of 20 plants using several random primers detected a high degree of genetic homogeneity in their population as compared with the populations of rhizobia of other leguminous plants growing at the same site. Sequencing of 16S rRNA genes of the three most different samples have demonstrated that these genes were identical and display 99.9% homology with the sequence of Phyllobacterium trifolii 16S rRNA gene.

[The carbohydrate-binding sequences in lectins of the clovers trifolium repens, T. pratense, and T. trichocephalum].

The carbohydrate-binding sequences (CBS) in the lectin genes of Trijilium repens, T. pratense, and T. tri-chocephalum were sequenced. The gene regions encoding lectin CBS of T. pratense and T. repens displayed a considerable similarity; however, the CBS of these species differed essentially. Moreover, T. repens formed a compact cluster with Melilotus albus and M. officinalis in the phylogenetic trees constructed according to the nucleotide sequences and the corresponding CBS of legume lectins. T. trichocephalum does not fall into the group of the tribe Trifolieae members according to both the amino acid sequence of lectin carbohydrate-binding region and the nucleotide sequence of lectin gene.