Regulatory interfaces between the stress protein response and other gene expression programs in the cell

The stress protein response involves the immediate reprogramming of gene expression in cells exposed to proteomic insult leading to massive synthesis of heat shock proteins (HSP). We have examined the outcome when cells are induced to activate two other gene expression programs--the acute inflammatory response and entry of quiescent cells into the cell cycle--and then exposed to protein stress. We find that these responses are mutually antagonistic with, on the one hand, heat shock factor 1 (HSF1) inhibition through the phosphorylation of inhibitory serine residues after inflammatory or mitogenic stimulus and, on the other hand, after stress, HSF1 directly repressing the promoters of genes that mediate acute inflammation and mitogenesis. The expression of the stress protein response during periods of acute protein damage was shown to lead to efficient activation of HSF1 and HSP expression accompanied by repression of other gene expression programs.     

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)     

Stat1 mediates an auto-regulation of hsp90β gene in heat shock response

We have reported earlier that a heat shock element in the first intron of human hsp90β gene (iHSE) acts as an intronic enhancer to bind the heat shock factor (HSF1) and activates hsp90β gene under heat shock. Here, we show that, in addition to the HSF1, Stat1 phosphorylation is indispensable in the event. We show that Jak2, a Janus kinase specifically associated with the β subunit of IFNγ receptor, and PKCε? an isoform of the atypical PKC family, are the two dominant kinases responsible for the heat shock induced phosphorylation on Y701 and S727 of Stat1. However, the activation of these kinases under heat shock requires the association of chaperone proteins of the Hsp90 family, in particular, the Hsp90β under heat shock. Furthermore, Brg1, an ATPase subunit of the SWI/SNF chromatin remodeling complex is likely recruited by HSF1 and Stat1 at the iHSE under heat shock. Brg1 further confers an open chromatin conformation at the promoter region that is pivotal to the heat shock induced fully activation of the hsp90β gene in Jurkat cells. This is a novel example of how multiple activation steps occur under heat shock, first on the kinases and then the Stat1 and the SWI/SNF chromatin remodeling complex that follows to conduct an auto-regulation based fully activation of the gene.     

Regulation of Drosophila p38 activation by specific MAP2 kinase and MAP3 kinase in response to different stimuli

The p38 mitogen-activated protein kinase (MAPK) signaling pathway plays an important role in cellular responses to inflammatory stimuli and environmental stress. Activation of p38 is mediated through phosphorylation by upstream MAPKK, which in turn is activated by MAPKKK. However, the mechanism of how different upstream MAP2Ks and MAP3Ks specifically contribute to p38 activation in response to different stimuli is still not clearly understood. By using double-stranded RNA-mediated interference (RNAi) in Drosophila cells, we demonstrate that D-MKK3 is a major MAP2K responsible for D-p38 activation by UV, heat shock, NaCl or peptiodglycan (PGN). Stimulation of UV and PGN activates D-p38 through D-MEKK1, heat shock-induced activation of D-p38 signals through both D-MEKK1 and D-ASK1. On the other hand, maximal activation of D-p38 by NaCl requires the expression of four MAP3Ks.     

Implication of a small GTPase Rac1 in the activation of c-Jun N-terminal kinase and heat shock factor in response to heat shock

Heat shock induces c-Jun N-terminal kinase (JNK) activation as well as heat shock protein (HSP) expression through activation of the heat shock factor (HSF), but its signal pathway is not clearly understood. Since a small GTPase Rac1 has been suggested to participate in the cellular response to stresses, we examined whether Rac1 is involved in the heat shock response. Here we show that moderate heat shock (39-41 degrees C) induces membrane translocation of Rac1 and membrane ruffling in a Rac1-dependent manner. In addition, Rac1N17, a dominant negative mutant of Rac1, significantly inhibited JNK activation by heat shock. Since Rac1V12 was able to activate JNK, it is suggested that heat shock may activate JNK via Rac1. Similar inhibition by Rac1N17 of HSF activation in response to heat shock was observed. However, inhibitory effects of Rac1N17 on heat shock-induced JNK and HSF activation were reduced as the heat shock temperature increased. Rac1N17 also inhibited HSF activation by l-azetidine-2-carboxylic acid, a proline analog, and heavy metals (CdCl)), suggesting that Rac1 may be linked to HSF activation by denaturation of polypeptides in response to various proteotoxic stresses. However, Rac1N17 did not prevent phosphorylation of HSF1 in response to these proteotoxic stresses. Interestingly, a constitutively active mutant Rac1V12 did not activate the HSF. Therefore, Rac1 activation may be necessary, but not sufficient, for heat shock-inducible HSF activation and HSP expression, or otherwise a signal pathway(s) involving Rac1 may be indirectly involved in the HSF activation. In sum, we suggest that Rac1 may play a critical role(s) in several aspects of the heat shock response.