Modulation in fatty acid composition influences salinity stress tolerance in Frankia strains

Abstract

Frankia strains, isolated from Hippöphae salicifolia D. Don, were utilized to examine the utility of lipid amendments in the strains’ strategic survival against salinity. Frankia strains are known to withstand severe temperature fluctuations (−20 °C to +30 °C), nitrogen deprivation and low soil water content. It was interesting to note that these strains were also able to tolerate a considerable range of salinity. Strains were subjected to 250 mM (500 mM for HsIi10) and 750 mM NaCl treatment, which were the critical and inhibitory NaCl concentrations, respectively, for the experimental strains. Their lipid profiles showed dynamic modifications in saline environment; 16–18 carbon chain fatty acids were of predominant occurrence in the lipid membrane. In the critical NaCl environment, there was an increase in fatty acid unsaturation (measured in terms of MUFA/PUFA ratio), which preserved normal membrane fluidity. Conversely, at the inhibitory salinity level, increased fatty acid saturation made the membrane highly rigid and susceptible to breakage and electrolyte loss. The differential capability of fatty acid desaturation could be a major factor in variation of salt sensitivity/tolerance patterns among these strains. Also, management of the lipid profile in response to salinity was found to be a strain-specific character.