Abstract
Eighty four halotolerant bacterial strains were isolated from the saline habitats and screened for growth at different NaCl concentrations. All grew well at 5% NaCl, but only 25% isolates showed growth at 20% NaCl concentration. Five strains SL3, SL32, SL35, J8W and PU62 growing well in 20% NaCl concentrations were further characterized for multiple plant growth promoting traits such as indole −3- acetic acid (IAA) production, HCN and siderophore production, ACC deaminase activity and P-solubilization. None were positive for HCN production and PCR amplification of acdS, the structural gene for ACC deaminase enzyme was found negative. 16S rRNA gene sequencing analysis of the five strains showed them to belong to two genera Bacillus and Hallobacillus. In vitro experiments showed that salt concentrations had significant inhibitory effects on development of seedlings but not on the growth of the bacterial strains. Inoculation of the 5 halotolerant bacterial strains to ameliorate salt stress (80 mM, 160 mM and 320 mM) in wheat seedlings produced an increase in root length of 71.7% in comparison with uninoculated positive controls. In particular, Hallobacillus sp. SL3 and Bacillus halodenitrificans PU62 showed more than 90% increase in root elongation and 17.4% increase in dry weight when compared to uninoculated wheat seedlings at 320 mM NaCl stress indicating a significant reduction of the deleterious effects of NaCl. These results indicate that halotolerant bacteria isolated from saline environments have potential to enhance plant growth under saline stress through direct or indirect mechanisms and would be most appropriate as bioinoculants under such conditions.
Highlights
Salinity is one major limiting factor to plant growth and crop productivity [1]
Isolation and screening of salt tolerant bacteria Eighty four bacterial strains were selected based on distinct morphology on nutrient agar (NA) (1% NaCl) plates
Phylogenetic analysis of five halotolerant bacterial 16S rDNA gene sequence revealed them to belong to Bacillus and Hallobacillus species
Summary
Salinity is one major limiting factor to plant growth and crop productivity [1]. Cultivated soils worldwide are becoming more saline from marginal irrigation water, excessive fertilization, and desertification processes. Strategies for alleviation of salt stress involve developing salt-resistant cultivars, leaching excess soluble salts from upper to lower soil depths, flushing soils that contain soil crusts at the surface, reducing salt by harvesting salt-accumulating aerial plant parts in areas with negligible irrigation water or rainfall for leaching, and amelioration of saline soils under cropping and leaching [3]. PGPB with ACC deaminase activity have been successfully used to reduce the negative effects of salinity by lowering stress ethylene production in the vicinity of growing root [9,10,11,12]. Mayak et al [9] reported that ACC deaminase producing salt tolerant bacteria can survive well in a saline environment and that their beneficial properties help plants to overcome stress effects. Microorganisms surviving at extreme environmental conditions have been found suitable for use in different agricultural practices [14]
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