An alteration in molecular form associated with activation of human heat shock factor

In higher eucaryotes, heat shock factor (HSF) exists in a cryptic form in unstressed cells. We investigated molecular forms of human HSF before and after activation by sucrose density gradient centrifugation and by gel mobility shift assay using a 32P-labeled heat shock element (HSE). We found that the in vivo or in vitro activated HSF, which is capable of binding to HSE, and its inactive form present in unstressed cells have different sedimentation coefficient; the former is 8 S whereas the latter is 4-5 S. Both the 8 S and 4-5 S forms contain the HSF polypeptide which has the ability to bind to HSE upon activation. The inactive 4-5 S form acquires HSE-binding ability when activated by heat shock or other stimuli. This HSF activity was greatly reduced, however, during recentrifugation in sucrose density gradient and, in addition, the residual activity was not recovered in 8 S fractions. Transformation of the inactive 4-5 S form of HSF to the stable, active 8 S form was achieved when the inactive form was activated and mixed with cytosols of unstressed cells.     

Cooperative binding of Drosophila heat shock factor to arrays of a conserved 5 bp unit

Drosophila heat shock factor (HSF) exists as a multimer in solution and when bound to its regulatory element (HSE). We have previously reported evidence that subunits of HSF associate to form homotrimers and that each subunit contacts a conserved 5 bp DNA sequence repeated within an HSE. Here we show that HSF binding is highly cooperative at two distinct levels: between subunits of the HSF multimer, and between multimers. The binding of HSF to one of a pair of adjacent trimeric binding sites facilitates HSF binding to the second by over 2000-fold. This cooperativity is particularly important in binding HSF at 37 degrees C, and could account for the requirement for multiple binding sites in vivo and, in part, for the differential expression of heat shock genes.     

Proteasome inhibitors lactacystin and MG132 inhibit the dephosphorylation of HSF1 after heat shock and suppress thermal induction of heat shock gene expression.

Recently, we have shown that two proteasome inhibitors, MG132 and lactacystin, induce hyperphosphorylation and trimerization of HSF1, and transactivate heat shock genes at 37 degrees C. Here, we examined the effects of these proteasome inhibitors and, in addition, a phosphatase inhibitor calyculin A (CCA) on the activation of HSF1 upon heat shock and during post-heat-shock recovery, with emphasis on HSF1 hyperphosphorylation and the ability of HSF1 to transactivate heat shock genes. When lactacystin, MG132, or CCA was present after heat shock, HSF1 remained hyperphosphorylated during post-heat-shock recovery at 37 degrees C. Failure of HSF1 to recover to its preheated dephosphorylated state correlated well with the suppression of the heat-induced hsp70 expression. In vitro, HSF1 from heat-shocked cells, when dephosphorylated, showed an increase in HSE-binding affinity. Taken together, these data suggest that phosphorylation of HSF1 plays an important role in the negative regulation of heat-shock response. Specifically, during post-heat-shock recovery phase, prolonged hyperphosphorylation of HSF1 suppresses heat-induced expression of heat shock genes.     

Temperature-dependent increase in the DNA-binding activity of a heat shock factor in an extract of tobacco cultured cells

The DNA-binding activity of a tobacco heat shock factor (HSF) was induced by heat treatment (37–40 °C) of a cell-free extract that contained extra-nuclear fraction, but not in an extract of isolated nuclei. These observations suggest that an inactive form of HSF can directly recognize and transduce the heat shock signal and that such transduction requires components of the extranuclear fraction. Addition of ATP or of most other nucleoside triphosphates reduced the binding of the HSF to the heat shock element (HSE) in the same extract, and removal of ATP by dialysis from the extract restored the ability of the HSF to bind to DNA. The restored activity of the HSF could be eliminated again by a second addition of ATP. Our observations provide the first example of the involvement of ATP in the regulation of the reversible changes in HSF that control its ability to bind to HSEs in a cell-free extract.Abbreviations AMP-PNP adenylyl imidodiphosphate - GUS -glucuronidase - HSE heat shock element - HSF heat shock factor