Competition among Bradyrhizobium strains for nodulation of green gram (Vigna radiata): use of dark-nodule strain.

The competitiveness of dual-strain inoculum of Bradyrhizobium strains S24 and GR4 was demonstrated for nodulation of green gram (Vigna radiata). Strain S24 formed pink nodules, GR4 produced visually distinguishable dark-brown nodules. When a mixture of these Bradyrhizobium strains was applied as inoculum, nodules of both pink and dark-brown types were formed on the same root. The strain GR4, which was less competitive than strain S24, was mutagenized with N-methyl-N'-nitro-N-nitrosoguanidine to obtain pigment-diverse mutants and six selected mutants were screened for symbiotic parameters. One mutant produced pink nodules and appreciably increased plant dry mass. The competitive ability of this mutant lacking brown pigment was compared with that of strain S24 by using antibiotic resistance markers; it showed increased nodulation competitiveness than its parent strain GR4. The dark-brown nodule-phenotype could be useful in evaluating nodulation competitiveness of "cowpea miscellany" bradyrhizobia in soil where dark-brown nodule-forming strains are not indigenous.

Associative diazotrophs of pearl millet (Pennisetum glaucum) from semi arid region--isolation and characterization.

Diversity of the native diazotrophs associated with the rhizosphere of pearl millet (P. glaucumn), grown in nutritionally poor soils of semi-arid regions was studied with a view to isolate effective nitrogen fixing and plant growth stimulating bacteria with root associative characteristics. The native population varied from 10(3)-10(4) g(-1) of rhizosphere soil after 40 d growth and belonged to genera Azospirillum, Azotobacter and Klebsiella. Another non-diazotrophic root associative group was Pseudomonas sp., which also produced IAA and enhanced plant growth. Some of these rhizobacteria showed high in vitro acetylene reduction activity along with production of indole acetic acid. Out of 11 selected diazotrophs used as seed inoculants, M10B (Azospirillum sp.), M11E (Azotobacter sp.) and M12D4 (Klebsiella sp.) resulted in significant increase in total root and shoot nitrogen at 45 and 60 days of plant growth under pot culture conditions.

Azide-resistant mutants of Azorhizobium caulinodans with enhanced symbiotic effectiveness.

Azide-resistant mutants of Azorhizobium caulinodans strains Sb3, S78, SrR13 and SrS8 were isolated and screened for nitrate reductase activity. Selected nitrate reductase negative mutants were inoculated on Sesbania bispinosa and S. rostrata under sterile conditions in chillum jars to study their symbiotic behavior. Azide-resistant mutants exhibited either similar or higher symbiotic effectiveness than the parent strain after 30 d of plant growth. Nodule mass, nitrogenase activity and uptake hydrogenase activity of the mutants varied depending on the host as well as on the plant growth stage. In comparison to wild-type parent strains, four azide-resistant mutants, Sb3Az18, S78Az21, SrR13Az17 and SrS8Az6 showed significant increase in nodulation and nitrogen fixation as well as shoot dry mass of the inoculated plants.

Symbiotic effectiveness of spontaneous antibiotic-resistant mutants of Rhizobium sp. Cicer nodulating chickpea (Cicer arietinum).

Spontaneous streptomycin-resistant mutants were isolated from two fast growing gum-producing strains Ca85 and Ca401 and from two moderately growing strains Ca181 and Ca534 of Rhizobium sp. Cicer. The nodulation ability and symbiotic effectiveness of the mutants relative to parent strains were evaluated on chickpea (Cicer arietinum) grown in sterilized chillum jars. Some mutants of strains Ca85 and Ca401 showed Nod phenotype whereas some mutants of strains Ca181 and Ca534 showed Nod(+) fix(-) phenotype. Other mutants also showed decreased nodule number and reduction in nitrogenase activity as well as in shoot dry weight as compared to inoculation with parental strains. The results showed that acquisition of streptomycin resistance in Rhizobium sp. Cicer strains is associated with decreased symbiotic effectiveness in chickpea, suggesting that antibiotic-resistant mutants first should be analyzed for symbiotic effectiveness before using these mutants for ecological studies or nodulation competitiveness.

Symbiotic effectiveness of bacteriocin producing and non-producing strains of Rhizobium in green gram (Vigna radiata).

Rhizobium strains nodulating green gram [Vigna radiata (L.) Wilczek] were found to produce bacteriocin on modified Bergersen's medium and inhibited the growth of homologous Rhizobium strains. Four bacteriocin producing and four bacteriocin non-producing strains were compared for their effect on nodulation, in planta nitrogenase activity and plant dry weight of green gram. The bacteriocin producers formed more nodules in comparison to non-bacteriocin producers. However, the symbiotic effectiveness of bacteriocin producers was less in terms of plant dry weight in comparison to non-bacteriocin producers.

Chitinolytic and cellulolytic Pseudomonas sp. antagonistic to fungal pathogens enhances nodulation by Mesorhizobium sp. Cicer in chickpea.

Pseudomonas strains isolated from the rhizosphere of chickpea (Cicer arietinum L.) and green gram (Vigna radiata L.) were screened for the production of chitinases and cellulases. Five Pseudomonas strains were found to produce appreciable amounts of both enzymes in culture-free supernatants and showed growth inhibition of the two fungi Pythium aphanidermatum (Oomycete) and Rhizoctonia solani (Basidiomycete) in plates on potato dextrose agar medium. The fungal growth inhibition was not correlated with cell wall-degrading enzyme activity, which suggested that other antifungal compounds produced by these rhizobacteria were also involved in antagonism. Coinoculation of the Pseudomonas strains with the Mesorhizobium sp. Cicer strain Ca 181 resulted in a significant increase in nodule biomass when grown under sterilized chillum jar conditions. The results suggest that hydrolytic enzymes produced by Pseudomonas sp. contribute to suppression of plant diseases by inhibiting growth of phytopathogenic fungi and also promote nodulation of legumes by rhizobia.