Stat1 mediates an auto-regulation of hsp90beta gene in heat shock response.

We have reported earlier that a heat shock element in the first intron of human hsp90beta gene (iHSE) acts as an intronic enhancer to bind the heat shock factor (HSF1) and activates hsp90beta 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 beta subunit of IFNgamma receptor, and PKCepsilon 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 Hsp90beta 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 hsp90beta 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.

Diverse effects of Stat1 on the regulation of hsp90alpha gene under heat shock.

Stat1 has been known as a regulator of gene expression and a mediator of IFNgamma signaling in mammalian cells, while its effect in a heat shock response remains unclear. We used RNAi knockdown, point mutations, ChIP and promoter activity assays to study the effect of Stat1 on the heat-shock induction of the hsp90alpha gene under heat shock conditions. We found that Stat1 regulates the heat shock induction of its target genes, the hsp90alpha gene in a heat shock response while the constitutive activity of the gene remains unaffected. The result of Stat1 in complex with Stat3 and HSF1 that bound at the GAS to lead a moderate heat shock induction was designated as an "intrinsic" induction of the hsp90alpha gene. Additionally a reduced or an elevated level of heat shock induction was also controlled by the Stat1 on hsp90alpha. These diverse effects on the hsp90alpha gene were a "reduced" induction with over-expressed Stat1 elicited by transfection of wild-type Stat1 or IFNgamma treatment, bound at the GAS as homodimer; and an "enhanced" heat shock induction with a mutation-mediated prohibition of Stat1/GAS binding. In conclusion, the status and efficacy of Stat1 bound at the GAS of its target gene are pivotal in determining the impact of Stat1 under heat shock. The results provided the first evidence on the tumor suppressor Stat1 that it could play diverse roles on its target genes under heat shock that also shed lights on patients with fever or under thermotherapy.

Repression of hsp90beta gene by p53 in UV irradiation-induced apoptosis of Jurkat cells.

Tumor suppressor p53 has been implicated in cell stress response and determines cell fate of either growth arrest or apoptosis. Heat shock proteins (Hsps) expressed under stress usually confer survival protection to the cell or interruption in the apoptotic pathways. Although Hsp90 can physically interact with p53, whether or not the hsp90 gene is influenced downstream of p53 in UV irradiation-induced apoptosis remains unclear. We have found that the level of p53 is elevated with the decline of Hsp90 in UV-irradiated cells and that malfunction of Hsp90, as inhibited by geldanamycin, enhances the p53-involved UV irradiation-induced apoptosis. In addition, the expression of the hsp90beta gene was reduced in both UV-irradiated and wild type p53-transfected cells. These results suggest a negative correlation between the trans factor p53 and a chaperone gene hsp90beta in apoptotic cells. Mutation analysis demonstrated that the p53 binding site in the first exon was indispensable for p53 regulation on the hsp90beta gene. In addition, with p53 bound at the promoter of the hsp90beta gene, mSin3a and p300 were differentially recruited in UV irradiation-treated or untreated Jurkat cells in vivo. The evidence of p53-repressed hsp90beta gene expression in UV-irradiated cells shed light on a novel pathway of Hsp90 in the survival control of the stressed cells.

[Chromatin immunoprecipitation and its preliminary application for gene regulation].

OBJECTIVE: To verify the binding of p53 to p21WAF1/CIP1 gene promoter and detect its binding to hsp90 beta gene promoter in vivo. METHODS: Chromatin immunoprecipitation and PCR analysis were used to measure specific gene regulation sequence and Western blot analysis to investigate p53 protein. RESULTS: The p53 binding sequences on the promoters of p21WAF1/CIP1 and hsp90 beta gene were found in the p53 antibody immunoprecipitated DNA fragments and p53 was detected in the immunoprecipitated samples. CONCLUSIONS: p53 binds to promoters of p21WAF1/CIP1 and hsp90 beta gene in vivo, and regulates the expression of the two genes.

PKC epsilon is a unique regulator for hsp90 beta gene in heat shock response.

An early event in cellular heat shock response is the transmittance of stress signals from the cell surface into the nuclei, resulting in the induction of heat shock proteins (Hsps). Protein kinase C (PKC) has been implicated as a key player in transducing stress signals. However, mechanism(s) by which PKC regulates heat shock-induced events remains largely unknown. Here we present data that pan-PKC inhibitor GF109203X, but not classic PKC inhibitor Gö6976, specifically repressed heat shock-induced accumulation of mRNA as well as promoter activity of hsp90 beta, but not hsp90 alpha, in Jurkat cells. Subcellular fractionation studies revealed that heat shock exclusively induced PKC-epsilon membrane translocation. Consistently, expression of a constitutively active PKC-epsilon(A159E) resulted in an enhanced promoter activity of hsp90 beta upon heat shock, whereas a dominant-negative PKC-epsilon(K437R) abolished this effect. In contrast, constitutively active-PKC-alpha or dominant-negative-PKC-alpha had no effects on heat shock induction of the gene. The effect of PKC-epsilon on hsp90 beta expression seems to be stimuli-specific, as phorbol myristate acetate-mediated hsp90 beta expression was PKC-epsilon-independent. We conclude that PKC-epsilon is specifically required in the signaling pathway leading to the induction of hsp90 beta gene in response to heat shock.

Differential hypersensitivity to DNase I in the regulatory region of human hsp90 beta gene in heat shock and constitutive expression.

DNase I hypersensitivity analysis is a useful tool to investigate impact of structure changes in chromatin on the expression of a gene. In order to unravel chromatin regulation on human hsp90 beta gene, differential sensitivity to DNase I in non-treated and heat-shocked Jurkat cells are examined. Four major hypersensitive sites at -120/-20 bp (HS1), +360 bp (HS2), +630/+780 bp (HS4) and around +1020 bp (HS5) with respect to the transcription start site of hsp90 beta gene have been identified. The HS1 is shared by both constitutive and heat shock, while the intronic sites of HS4 and HS5 are elicited by heat shock and HS2 is illustrated only in constitutive expression. In addition, distal HSs at around 8.7 kb upstream and 6.8 kb downstream are found in both constitutive and heat shock expression, which indicate that the boundaries of the hsp90 beta gene extend for some 16 kb. The HS patterns confirm chromatin regulation in the expression of hsp90 beta gene under various treatments.