We used a microarray dataset that is deposited in the public database to evaluate plant responses to heat stress and selected two genes, OsSHSP1 (Os03g16030) and OsSHSP2 (Os01g04380), that are highly expressed under heat stress in rice. OsSHSP1 and OsSHSP2 gene transcripts were highly induced in response to salt and drought. In addition, OsSHSP1 and OsSHSP2 gene transcripts were induced under ABA and SA. Subcellular localization of proteins of 35S::OsSHSP1 were associated with the cytosol, whereas those of and 35S::OsSHSP2 were associated with the cytosol and nucleus. Heterogeneous overexpression of both genes exhibited higher germination rates than those of wild-type plants under the salt treatment, but not under heat or drought stress. The network of both genes harboring 9 sHSPs as well as at least 13 other chaperone genes might support the idea of a role for sHSPs in the chaperone network. Our findings might provide clues to shed light on the molecular functions of OsSHSP1 and OsSHSP2 in response to abiotic stresses, especially heat stress.

Previously, the wheat non-specific lipid transfer proteins (TaLTP), members of a small multigene family, appear to show a complex pattern of expression regulation. For further assessment of expression diversity of the TaLTP genes, we have attempted to evaluate their expression profiles of responses to abiotic stresses via the semi-quantitative RT-PCR method. The expression profiles revealed that the TaLTP genes in group A evidenced highly similar (but not identical) responses against abiotic stresses, whereas much differential expression pattern among genes in each group. The four promoters of TaLTP1, TaLTP7, and TaLTP10 of group A and TaLTP3 of group B were fused to a GUS reporter gene and the recombinant genes were introduced into Arabidopsis. The promoters of TaLTP1, TaLTP7 and TaLTP10 of group A, drove strong but various GUS expression in cotyledons, hypocotyls, epidemic and sub-epidemic cells of young shoots and leaves, floral organs as well as siliques. By contrast, the promoter of TaLTP3 just directed trace expression in cotyledons, young emerged leaves and epidemic cells of flower ovaries. The promoter of TaLTP1 directed the expression in root system whereas the promoters of TaLTP1 and TaLTP10 showed some degree of expression during seed development. The expression diversity of TaLTP genes suggests their multiple physiological functions, evidencing subfunctionalization over evolutionary time.