Alpha-helix 1 in the DNA-binding domain of heat shock factor 1 regulates its heat-induced trimerization and DNA-binding

Heat shock factor 1 (HSF1) primarily regulates various cellular stress responses. The role of α-helix1 (H1) in its DNA-binding domain (DBD) during HSF1 activation remains unknown. Here, HSF1 lacking H1 loses its heat-induced activity, suggesting the importance of the latter. Furthermore, the CD spectra and AMBER prediction show that this H1 deficiency does not change the structure of HSF1 monomer, but does impact its heat-induced trimerization. Point mutation showed that Phe18 in H1 interacts with Tyr60, and that Trp23 interacts with Phe104 by an aromatic-aromatic interaction. Thus, the presence of H1 stabilizes the DBD structure, which facilitates the heat-induced trimerization and DNA-binding of HSF1.     

A heat shock protein 90 inhibitor that modulates the immunophilins and regulates hormone receptors without inducing the heat shock response

When a cell encounters external stressors, such as lack of nutrients, elevated temperatures, changes in pH or other stressful environments, a key set of evolutionarily conserved proteins, the heat shock proteins (hsps), become overexpressed. Hsps are classified into six major families with the hsp90 family being the best understood; an increase in cell stress leads to increased levels of hsp90, which leads to cellular protection. A hallmark of hsp90 inhibitors is that they induce a cell rescue mechanism, the heat shock response. We define the unique molecular profile of a compound (SM145) that regulates hormone receptor protein levels through hsp90 inhibition without inducing the heat shock response. Modulation of the binding event between heat shock protein 90 and the immunophilins/homologs using SM145, leads to a decrease in hormone receptor protein levels. Unlike N-terminal hsp90 inhibitors, this hsp90 inhibitor does not induce a heat shock response. This work is proof of principle that controlling hormone receptor expression can occur by inhibiting hsp90 without inducing pro-survival protein heat shock protein 70 (hsp70) or other proteins associated with the heat shock response. Innovatively, we show that blocking the heat shock response, in addition to hsp90, is key to regulating hsp90-associated pathways.     

Pressure activation of the chaperone function of small heat shock proteins.

Small heat shock proteins play an important role in the stress response of cells and in several other cellular functions. They possess chaperone-like activity; i.e. they can bind and protect damaged proteins from aggregation and maintain them in a folding-competent state. Two members of this family were investigated in this work: bovine alpha-crystallin and heat shock protein (HSP)16.5 from the thermophilic archaebacteria Methanococcus jannaschii. We reported earlier the enhancement of chaperone potency of alpha-crystallin by high pressure. We now report the completion of the work with results on HSP16.5. The chaperone potency of both proteins can be enhanced significantly by applying high pressure. Evidence by light scattering, Fourier transform infrared (FT-IR) and tryptophan fluorescence experiments show that while the secondary and tertiary structure of these proteins are not influenced by high pressure, their quatemary structure becomes affected: H bonds between subunits are weakened or broken, tryptophan environments become more polar, oligomers dissociate to some extent. We conclude that the oligomeric structure of both proteins is loosened, resulting in stronger dynamics and in more accessible hydrophobic surfaces. These properties lead to increased chaperone potency.