In vitro formation of estrogen receptor-heat shock protein 90 complexes

The N-terminal adenosine triphosphate binding domain of Hsp90 is necessary and sufficient for interaction with estrogen receptor

To understand how the molecular chaperone Hsp90 participates in conformational maturation of the estrogen receptor (ER), we analyzed the interaction of immobilized purified avian Hsp90 with mammalian cytosolic ER. Hsp90 was either immunoadsorbed to BF4 antibody-Sepharose or GST-Hsp90 fusion protein (GST.90) was adsorbed to glutathione-Sepharose. GST.90 was able to retain specifically ER, similarly to immunoadsorbed Hsp90. When cells were treated with estradiol and the hormone treatment was maintained during cell homogenization, binding, and washing steps, GST.90 still interacted efficiently with ER, suggesting that ER may form complexes with Hsp90 even after its activation by hormone and salt extraction from nuclei. The GST.90-ER interaction was consistently reduced in the presence of increasing concentrations of potassium chloride or when cytosolic ER-Hsp90 complexes were previously stabilized by molybdate, indicating that GST.90-ER complexes behave like cytosolic Hsp90-ER complexes. A purified thioredoxin-ER fusion protein was also able to form complexes with GST.90, suggesting that the presence of other chaperones is not required. ER was retained only by GST.90 deletion mutants bearing an intact Hsp90 N-terminal region (1-224), the interaction being more efficient when the charged region A was present in the mutant (1-334). The N-terminal fragment 1-334, devoid of the dimeric GST moiety, was also able to interact with ER, pointing to the monomeric N-terminal adenosine triphosphate binding region of Hsp90 (1-224) as the region necessary and sufficient for interaction. These results contribute to understand the Hsp90-dependent process responsible for conformational competence of ER.

Selective interaction of hsp90 with an estrogen receptor ligand-binding domain containing a point mutation

The 90-kDa heat shock protein (hsp90) has been implicated in modulating steroid receptor function in vitro and in vivo. Previous studies have suggested that hsp90 interacts with large portions of the estrogen receptor (ER) ligand-binding domain and sequences of the receptor required for stable DNA binding. To characterize the interaction of the ER ligand-binding domain with hsp90, we have compared the properties of chimeras created by coupling the ligand-binding domain to the constitutive transactivator VP16-GAL. Two types of chimeras were created: VP16-GAL-ERG, containing the wild-type ligand-binding domain derived from the cDNA HEG0, and VP16-GAL-ERV, containing the substitution G400V derived from the ligand-binding domain of the original ER cDNA isolate, HE0. The G400V mutation alters the physical properties of VP16-GAL-ERV by rendering it hormone-dependent for DNA binding and more strongly dependent on estradiol for transactivation compared with VP16-GAL-ERG. Glycerol gradient analyses and chemical cross-linking/coimmunoprecipitation showed that, unlike VP16-GAL-ERG, VP16-GAL-ERV formed stable complexes with hsp90 in vitro. These data show that hsp90 selectively recognizes the altered ER ligand-binding domain containing the G400V substitution and indicate that the wild-type ER ligand-binding domain of VP16-GAL-ERG does not interact with hsp90 in vitro. Hormone binding studies showed that the ligand-binding domain of VP16-GAL-ERV was destabilized by incubation in the presence of high concentrations of salt or in the absence of sodium molybdate, conditions that disrupt its interaction with hsp90. The ligand-binding domain of the Val-400 ER thus behaves similarly to that of the wild-type glucocorticoid receptor, which has previously been shown to interact with hsp90 in vitro. These results provide evidence for the action of hsp90 as a molecular chaperone by selectively recognizing destabilized proteins.