Role of the mismatch repair protein MSH7 in Arabidopsis adaptation to acute salt stress

Abstract

DNA mismatch repair (MMR) is a highly conserved pathway in evolution responsible for maintaining genomic stability. MMR is initiated when MutS proteins recognize and repair single base-base mismatches and small loops of unpaired nucleotides as well as certain types of DNA damage. Arabidopsis thaliana and other plants contain MutS protein homologs (MSH) found in other eukaryotic organisms and a unique MSH7 polypeptide. In this study, we first evaluated transient expression profiles of ten-days old pAtMSH7:GUS transgenic seedlings at different recovery times after an acute treatment for 48 hs with100 mM NaCl. GUS histochemical staining indicated that MSH7 expression is repressed by salt exposure but recovers progressively. Then, ten-days old mutants harboring two independent msh7 alleles were exposed for 48 hs with100 mM NaCl and different traits were measured over recovery time. Salt treated msh7 seedlings were defective in G2/M arrest. As a result, msh7 seedlings showed a reduced salt inhibitory effect as evidenced by a decreased reduction of rosette and leaf areas, stomatal density, total leaf number, silique length and seed number per silique. These findings suggest that disruption of MSH7 activity could be a promising approach for plant adaptive responses to salinity stress.