Heat shock factor 1 is a key regulator of the stress response in Chlamydomonas

We report here on the characterization of heat shock factor 1 (HSF1), encoded by one of two HSF genes identified in the genome of Chlamydomonas reinhardtii. Chlamydomonas HSF1 shares features characteristic of class A HSFs of higher plants. HSF1 is weakly expressed under non-stress conditions and rapidly induced by heat shock. Heat shock also resulted in hyperphosphorylation of HSF1, and the extent of phosphorylation correlated with the degree of induction of heat shock genes, suggesting a role for phosphorylation in HSF1 activation. HSF1, like HSFs in yeasts, forms high-molecular-weight complexes, presumably trimers, under non-stress, stress and recovery conditions. Immunoprecipitation of HSF1 under these conditions led to the identification of cytosolic HSP70A as a protein constitutively interacting with HSF1. Strains in which HSF1 was strongly under-expressed by RNAi were highly sensitive to heat stress. 14C-labelling of nuclear-encoded proteins under heat stress revealed that synthesis of members of the HSP100, HSP90, HSP70, HSP60 and small HSP families in the HSF1-RNAi strains was dramatically reduced or completely abolished. This correlated with a complete loss of HSP gene induction at the RNA level. These data suggest that HSF1 is a key regulator of the stress response in Chlamydomonas.     

Heat shock gene-expression in HSP-70 and HSF1 gene-transfected human epidermoid A-431 cells

Thermotolerant cells display attenuated heat shock protein 70 kD (HSP-70) gene expression and signal transduction such as intracellular Ca2+ concentration and inositol trisphosphate in response to sublethal heat. To further investigate the regulation of heat shock gene expression, we developed constructs containing human HSP-70 and HSF1 genes and transfected human epidermoid A-431 cells. These cells were chosen because skin cells are especially vulnerable to heat shock and other environmental stressors. We report that A431 cells can be successfully transfected with HSP-70 and HSF1 genes as shown by the elevated levels of respective message and protein. Overexpression of HSP-70 in cells transfected with HSP-70 gene led to a down-regulation of the HSF1 gene expression. Interestingly, transfection of cells with the HSF1 gene was not associated with increased expression of HSP-70. Exposure of HSF1 gene-transfected cells to heat resulted in a transient but significant increase in HSP-70 gene expression as compared to that found in vector-transfected cells, which was completely inhibited by treatment with staurosporine. In conclusion, we have demonstrated successful transfection of human A-431 cells with HSF1 and HSP-70 genes, where the regulation of their expression can be studied. (Mol Cell Biochem 167: 145-152, 1997)