kappa-Opioid tolerance and dependence in cultures of dopaminergic midbrain neurons.

Repeated cocaine exposure upregulates kappa opioids and their receptors in the mesocorticolimbic system; the ensuing kappa-mediated dysphoria appears to contribute to addiction and withdrawal. As a potential rehabilitation strategy to reverse cocaine-induced kappa sensitization, the present study used tritiated dopamine release assays to examine the induction of kappa-opioid tolerance in cultured mesencephalic neurons. Administration of the kappa agonist U69,593 inhibited tetrodotoxin-sensitive, spontaneous (EC(50) = 1.5 nM), and potassium-stimulated (EC(50) = 10 nM) release. These effects were blocked by pertussis toxin and by the kappa antagonist nor-binaltorphimine. The 2 d agonist exposure (1 microM) caused a shift in the U69,593 dose-response curve that was greater in the potassium-stimulated paradigm (140-fold) than in the spontaneous release assay (sixfold). These results were attributable to the attenuation of kappa-receptor signaling mechanisms and to dependence. In the stimulated release assay, attenuation of kappa signaling caused by 4 hr of U69,593 exposure recovered with a half-life of 1.1 hr, whereas attenuation after 144 hr of exposure recovered slowly (t(1/2) = 20 hr). In the spontaneous release assay, attenuation of kappa-opioid signaling occurred slowly (t(1/2) = 22 hr), and resensitization after a 144 hr exposure was rapid (t(1/2) < 1 hr). kappa-Opioid dependence was observed after 144 hr of U69,593 exposure. Thus multiple mechanisms of adaptation to kappa-opioid exposure occur in mesocorticolimbic neurons. These data support the idea that the administration of kappa opioids might facilitate drug rehabilitation.

A conserved proline in the hsp90 binding region of the glucocorticoid receptor is required for hsp90 heterocomplex stabilization and receptor signaling.

Studies of hsp90 in yeast have supported the notion that this chaperone plays a critical role in signaling by steroid receptors. One limitation to these studies is that yeast expressing hsp90 mutants may also be deficient in fundamental cellular functions of the chaperone required for steroid-dependent induction of transcription. In this work, we have prepared mutants of the glucocorticoid receptor (GR) that permit analysis of hsp90 binding and transcriptional activity in cells with normal chaperone function. Our previous data supported a model in which hsp90 binds to the receptor steroid binding domain according to a two-site model. By amino acid mutagenesis of these two sites, we have now generated three receptor mutants and analyzed their function. Upon their translation in vitro, all three mutants interacted with hsp90 similarly to the wild-type receptor. However, one mutant, P643A (GRo), was of particular interest because, although it showed normal steroid binding and transformation to a glucocorticoid response element-specific DNA binding form, it was remarkably deficient in nuclear translocation and transcriptional function at 37 degreesC. Furthermore, GRo.hsp90 heterocomplexes formed in vivo or assembled under cell-free conditions were much less stable than wild-type GR. hsp90 heterocomplexes. Our results demonstrate that Pro-643 plays a critical role in both stabilizing the receptor.hsp90 complex and in permitting an efficient nuclear translocation and, thus, support the concept that the chaperone is an integral component of the steroid-receptor signaling pathway.

Localization of the approximately 12 kDa M(r) discrepancy in gel migration of the mouse glucocorticoid receptor to the major phosphorylated cyanogen bromide fragment in the transactivating domain.

The intact wild-type mouse glucocorticoid receptor has a theoretical molecular weight of approximately 96 kDa based on amino acid sequence, but on SDS-polyacrylamide gel electrophoresis it migrates as a protein of approximately 98 kDa. It is not known where the unusual primary structure or covalent modification responsible for this anomalous migration is located within the amino acid chain. In the course of examining the pattern of fragmentation of 32P-labeled glucocorticoid receptors from Chinese hamster ovary (CHO) cells containing amplified mouse receptor cDNA, we have found a localized region in the amino-terminal half of the receptor that accounts for this anomalous behavior. Cyanogen bromide treatment of the intact receptor produces a 23.4 kDa (theoretical) fragment consisting of residues 108-324 and containing all of the identified phosphorylated serines within the receptor. We find that the only large resolvable 32P-labeled receptor fragment produced after complete cyanogen bromide cleavage of intact receptors migrates with an apparent molecular weight of approximately 35 kDa. Because the apparent difference between the theoretical and the experimentally observed molecular weights of this cyanogen bromide fragment is essentially the same as the difference between the theoretical and experimental molecular weights of the intact mouse glucocorticoid receptor, we propose that some feature lying within this fragment accounts for slower migration. Although the existence of an additional phosphorylation site lying within the 15 kDa tryptic receptor fragment containing the DNA-binding domain has been contested, we also demonstrate that this fragment of the mouse glucocorticoid receptor is phosphorylated in vivo upon incubation of CHO cells in growth medium containing [32P]orthophosphate.

A model of glucocorticoid receptor unfolding and stabilization by a heat shock protein complex.

It has recently been reported that incubation of avian progesterone receptors, mouse glucocorticoid receptors, or the viral tyrosine kinase pp60src with rabbit reticulocyte lysate reconstitutes their association with the 90 kDa heat shock protein, hsp90. The reassociation is thought to require unfolding of the steroid receptor or pp60src before hsp90 can bind. The unfoldase activity may be provided by hsp70, which is also present in the reconstituted receptor heterocomplex. In this paper we review evidence that hsp70 and hsp90 are associated in cytosolic heterocomplexes that contain a limited number of other proteins. From an analysis of known receptor-hsp interactions and a predicted direct interaction between hsp90 and hsp70 we have developed an admittedly very speculative model of glucocorticoid receptor unfolding and stabilization. One important feature of the model is that the receptor becomes attached to a heat shock protein heterocomplex rather than undergoing independent unfolding and stabilization events. The model requires that hsp70 and hsp90 bind directly to the receptor at independent sites. Importantly, the model accommodates the stoichiometry of 2 hsp90 per 1 molecule of receptor that has been assayed in the untransformed GR heterocomplex in cytosols prepared from hormone-free cells.

Retinoic acid receptor belongs to a subclass of nuclear receptors that do not form "docking" complexes with hsp90.

We have recently reported that, in contrast to the glucocorticoid receptor, the thyroid hormone receptor does not bind to hsp90 when the receptor is translated in rabbit reticulocyte lysate [Dalman, F. C., Koenig, R. J., Perdew, G. H., Massa, E., & Pratt, W. B. (1990) J. Biol. Chem. 265, 3615-3618]. All of the steroid receptors that are known to bind hsp90 are recovered in the cytosolic fraction when hormone-free cells are ruptured in hypotonic buffer. In contrast, unliganded thyroid hormone receptors and retinoic acid receptors are tightly associated with nuclear components. In this paper, we translated the human estrogen receptor and the human retinoic acid receptor in reticulocyte lysate and then immunoadsorbed the [35S]methionine-labeled translation products with the 8D3 monoclonal antibody against hsp90. The estrogen receptor is bound to hsp90, as indicated by coimmunoadsorption, but the retinoic acid receptor is not. Translation and immunoadsorption of chimeric proteins containing the DNA binding domain of one receptor and the N-terminal and COOH-terminal segments of the other show that the DNA binding finger region of the estrogen receptor is neither necessary nor sufficient for hsp90 binding. These observations suggest that there are two classes within the steroid receptor family. In one class (e.g., glucocorticoid, mineralocorticoid, sex hormone, and dioxin receptors), the receptors bind to hsp90 and remain in some kind of inactive "docking" mode until hormone-triggered release of hsp90 occurs. In the retinoic acid/thyroid hormone class, the unligated receptors do not bind to hsp90, and the receptors appear to proceed directly to their high-affinity nuclear acceptor sites without entering the "docking" state.

Localization of the 90-kDa heat shock protein-binding site within the hormone-binding domain of the glucocorticoid receptor by peptide competition.

In this work, we used two approaches to localize the 90-kDa heat shock protein (hsp90)-binding site within the hormone-binding domain of the glucocorticoid receptor. In the first approach, derivatives of the glucocorticoid receptor deleted for increasing portions of the COOH terminus were translated in rabbit reticulocyte lysate, and the [35S]methionine-labeled translation products were immunoadsorbed with the 8D3 monoclonal antibody against hsp90. The data suggest that a segment from amino acids 604 to 659 (mouse) of the receptor is required for hsp90 binding. We have recently shown that the internal deletion mutant of the mouse receptor (delta 574-632) binds hsp90, although the complex is somewhat unstable (Housley, P. R., Sanchez, E. R., Danielsen, M., Ringold, G. M., and Pratt, W. B. (1990) J. Biol. Chem. 265, 12778-12781). The two observations indicate that amino acids 574-659 are involved in forming a stable receptor-hsp90 complex and that region 632-659 is especially important. To test this hypothesis directly, we synthesized three peptides corresponding to segments in region 624-665 and three peptides spanning the highly conserved sequence at amino acids 582-617, and we then tested the ability of the peptides to compete for the association of hsp90 with the L cell glucocorticoid receptor. In this assay, the immunopurified hsp90-free mouse receptor is incubated with rabbit reticulocyte lysate, which directs the association of rabbit hsp90 with the mouse receptor, simultaneously converting the receptor to the steroid binding state. All three peptides spanning region 624-665 and a peptide corresponding to segment 587-606 inhibited both hsp90 association with the receptor and reconstitution of steroid binding capacity. The data from all of the approaches support a two-site model for the hsp90-binding site in which the critical contact site occurs in region 632-659, which contains a short proline-containing hydrophobic segment and adjacent dipole-plus-cysteine motif that are conserved among all of the hsp90-binding receptors in the superfamily. A second hsp90 contact site is predicted in region 574-632, which contains the only highly conserved amino acid sequence in the receptor superfamily outside of the DNA-binding domain.

Structural and functional reconstitution of the glucocorticoid receptor-hsp90 complex.

Untransformed steroid receptors in cytosol preparations are associated with the 90-kDa heat shock protein hsp90, but the study of how hsp90 affects receptor function has been held back by the inability to reassociate steroid receptors with hsp90 in cell-free systems. Recently we showed (Dalman, F.C., Bresnick, E. H., Patel, P. D., Perdew, G. H., Watson, S. J., and Pratt, W. B. (1989) J. Biol. Chem. 264, 19815-19821) that glucocorticoid receptors translated in rabbit reticulocyte lysate bind to hsp90 at the termination of receptor translation. In this work we show that rabbit reticulocyte lysate promotes the temperature-dependent association of hsp90 with immunopurified mouse L cell glucocorticoid receptors. Reticulocyte lysate also promotes the temperature-dependent dissociation of hormone-free receptors from a prebound receptor-DNA complex. The glucocorticoid receptor is released from DNA in association with rabbit hsp90, and reconstitution of the receptor-hsp90 complex is accompanied by complete restitution of steroid binding activity and repression of DNA binding activity. This is the first time that transformation of a DNA-bound steroid receptor has been reversed and it raises the question of whether the same or a similar system is involved in the termination of transcriptional activation when steroid dissociates from DNA-bound receptors in intact cells.

The relationship between glucocorticoid receptor binding to Hsp90 and receptor function.

In this minireview we summarize evidence that the association of the glucocorticoid receptor (GR) with hsp90 may determine three functional states of the receptor. First, there is a direct correlation between hsp90 binding to the receptor and repression of DNA binding activity. Temperature-dependent dissociation of hsp90 from the cytosolic GR-hsp90 complex is promoted by hormone with simultaneous conversion of the receptor to the DNA binding state. GR that is translated in rabbit reticulocyte lysate binds to hsp90 at or near the termination of receptor translation and is in the non-DNA-binding form. Second, there is a direct correlation between binding of the immunopurified GR to hsp90 and the presence of a high affinity steroid binding conformation of the receptor. GR translated in reticulocyte lysate binds steroid with high affinity, but GR translated in wheat germ extract is not bound to hsp90, does not bind steroid with high affinity, and is in the DNA-binding form. When immunopurified, hsp90-free GR is incubated with rabbit reticulocyte lysate, hsp90 associates with the receptor and high affinity steroid binding capacity is completely reactivated. Third, there is a correlation between binding of hsp90 to steroid receptors and their retention in an inactive "docking" state until the binding of hormone in the intact cell triggers a progression to high affinity nuclear binding sites where the primary events involved in transcriptional activation occur. In contrast to the receptors that are retained in the docking state, the unliganded thyroid hormone receptor proceeds directly to high affinity nuclear binding sites. Consistent with this difference in behavior, the thyroid hormone receptor is translated in reticulocyte lysate in its DNA binding form and is not associated with hsp90.

In contrast to the glucocorticoid receptor, the thyroid hormone receptor is translated in the DNA binding state and is not associated with hsp90.

We have recently reported that the glucocorticoid receptor (GR) becomes bound to the 90-kDa heat shock protein (hsp90) at or near the end of receptor translation in vitro (Dalman, F. C., Bresnick, E. H., Patel, P. D., Perdew, G. H., Watson, S. J., Jr., and Pratt, W. B. (1989) J. Biol. Chem. 264, 19815-19821). In this paper we compare the hsp90 binding and DNA binding activities of the thyroid hormone receptor (TR) to those of the GR after cell-free translation of the two receptors in rabbit reticulocyte lysate. In contrast to the newly translated GR, which is bound to hsp90 and must be transformed to the DNA binding state, the TR is not bound to hsp90 and is translated in its DNA binding form without any requirement for transformation. When the GR is translated in wheat germ extract, which does not contain hsp90, it is translated in its DNA binding form in the same manner as the TR synthesized in reticulocyte lysate. These observations provide direct evidence that binding of GR to hsp90 is associated with repression of its DNA binding function. The fact that the TR does not bind to hsp90 and is translated in its DNA binding form is consistent with the different behavior of this receptor with respect to classic steroid receptors in the intact cell. We propose that binding to hsp90 may account for the fact that most of the steroid receptors are recovered in the cytosolic fraction after lysis of hormone-free cells in low salt buffer whereas the hormone-free TR is recovered in tight association with the nucleus.

Direct stoichiometric evidence that the untransformed Mr 300,000, 9S, glucocorticoid receptor is a core unit derived from a larger heteromeric complex.

We have used three methods to measure the stoichiometry of the glucocorticoid receptor and the 90-kDa heat shock protein (hsp90) in L-cell glucocorticoid receptor complexes that were purified by immunoadsorption to protein A-Sepharose with an anti-receptor monoclonal antibody, followed by a minimal washing procedure that permits retention of receptor-associated protein. In two of the methods, receptor was quantitated by radioligand binding, and receptor-specific hsp90 was quantitated against a standard curve of purified hsp90, either on Coomassie blue stained SDS gels by laser densitometry or on Western blots by quantitative immunoblotting with 125I-labeled counterantibody. The stoichiometry values obtained by densitometry and immunoblotting are 7 and 6 mol of hsp90/mol of receptor, respectively. In a third method, which detects total receptor protein rather than just steroid-bound receptor, the ratio of hsp90 to receptor was determined by immunopurifying receptor complexes from [35S]methionine-labeled L cells, and the amount of 35S incorporated into receptor and hsp90 was corrected for the established methionine content of the respective proteins. In complexes from L cells which are labeled to steady state (48 h), the ratio of hsp90 to GR is 4:1. When immunoadsorbed receptor complexes are washed extensively with 0.5 M NaCl and 0.4% Triton X-100 in the presence of molybdate, the ratio of hsp90 to GR is 2:1. In addition to hsp90, preparations of [35S]methionine-labeled untransformed receptor complex also contain a 55-kDa protein that the conclusion that the untransformed L-cell glucocorticoid receptor exists in cytosol in a much larger heteromeric complex than considered to date.(ABSTRACT TRUNCATED AT 250 WORDS)

Direct evidence that the glucocorticoid receptor binds to hsp90 at or near the termination of receptor translation in vitro.

We have translated the rat glucocorticoid receptor in both reticulocyte lysate and in wheat germ extract. Receptor synthesized in the reticulocyte lysate is immunoadsorbed by the 8D3 monoclonal antibody directed against the 90-kDa heat shock protein (hsp90) and it has a normal ability to bind glucocorticoid in a high affinity manner. Although the wheat germ extract synthesizes the full length receptor, the receptor is not immunoadsorbed by 8D3 and we cannot demonstrate high affinity steroid binding. Receptor synthesized by the reticulocyte lysate can be immunoadsorbed by antibody directed against hsp90 as soon as the translation product is full length, suggesting that the receptor becomes associated with hsp90 late during translation or immediately at the termination of translation. When newly synthesized receptor is bound with steroid and incubated at 25 degrees C, it is converted to a form that binds to DNA. This study provides direct evidence that association of hsp90 with the glucocorticoid receptor is a very early event and that the newly formed heteromeric receptor-hsp90 complex is fully competent to undergo transformation.

Interaction of the glucocorticoid receptor with the Mr 90,000 heat shock protein: an evolving model of ligand-mediated receptor transformation and translocation.

Reports from several laboratories support a model for glucocorticoid receptor (GR) transformation in cytosol in which a heteromeric 9S complex of GR and the Mr 90,000 heat shock protein undergo a temperature-dependent and hormone-promoted dissociation to yield the free DNA-binding form of the receptor. In this paper, we review evidence that the 9S heteromeric complex is derived from the normal inactive state of the receptor in the intact cell and that both Mr 90,000 heat shock protein and the untransformed GR localize by immunofluorescence with specific monoclonal antibodies to microtubules in a variety of cell types in culture. We propose that an association with cytoskeleton may be required for translocating the GR from its cytoplasmic site of synthesis to its nuclear site of action and that the 9S complex is derived from this cytoskeleton-associated form. Similar molybdate-stabilized 9S complexes can be obtained for all of the steroid receptors, several of which clearly are localized to the nucleus prior to exposure to hormone. These receptors may have moved to the terminus of the translocation pathway where they remain in a cytoskeleton-bound "docking" position. We speculate that, in the intact cell, ligand-dependent dissociation of Mr 90,000 heat shock protein permits the steroid receptors to progress by some ordered mechanism to their high affinity sites of action within the nucleus.

Evidence that the 90-kDa heat shock protein is necessary for the steroid binding conformation of the L cell glucocorticoid receptor.

Using L cell glucocorticoid receptors that have been immunopurified by adsorption to protein A Sepharose with a monoclonal antireceptor antibody, we have developed an assay to study the requirements for maintenance of steroid-binding capacity. After rapid purification by immunoadsorption, heteromeric receptor complexes retain the ability to bind glucocorticoid hormone. When the receptor complexes are warmed at 20 degrees C, steroid-binding capacity is lost, and the 90-kDa heat shock protein (hsp90) dissociates from the receptor. The rates of both temperature- and salt-dependent dissociation of hsp90 parallel the rates of loss of hormone-binding activity. Molybdate and hydrogen peroxide stabilize the hsp90-receptor complex against temperature-dependent dissociation. Molybdate, however, is much more effective in stabilizing steroid-binding capacity than peroxide. Receptors that have been inactivated in the absence of molybdate or peroxide cannot be reactivated. Inactivation of steroid-binding capacity occurs in the presence or absence of reducing agent, and inactivation is not accompanied by receptor cleavage or dephosphorylation. Under no conditions does an hsp90-free receptor bind steroid. Receptor bound to hsp90 can be cleaved to the 27-kDa meroreceptor in the presence of molybdate with retention of both hsp90 and steroid-binding activity. These observations lead us to propose that hsp90 is necessary but not sufficient for maintaining a competent high affinity glucocorticoid-binding site. Although the 27-kDa meroreceptor fragment is not itself sufficient for a competent binding site, it is sufficient when it is associated with hsp90.

Localization of phosphorylation sites with respect to the functional domains of the mouse L cell glucocorticoid receptor.

Digestion of the rat liver glucocorticoid receptor with chymotrypsin results in the generation of a 42-kDa fragment which contains the steroid-binding and DNA-binding domains and the antigenic site for the BuGR anti-glucocorticoid receptor monoclonal antibody, while digestion with trypsin generates a 15-kDa receptor fragment containing only the DNA-binding function and the BuGR epitope (Eisen, L.P., Reichman, M.E., Thompson, E.B., Gametchu, B., Harrison, R. W., and Eisen, H.J. (1985) J. Biol. Chem. 260, 11805-11810). In this paper, glucocorticoid receptor of mouse L cells that were grown in the presence of [32P]orthophosphate was digested with trypsin or chymotrypsin (either before or after immune purification with BuGR antibody) and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, autoradiography, and Western blotting. The receptor is endogenously phosphorylated only on serine residues. Chymotrypsin digestion results in a 32P-labeled 42-kDa receptor fragment which contains steroid-binding, DNA-binding, and BuGR-reactive sites. Trypsin digestion generates a 27-kDa steroid-bound fragment (meroreceptor) which is not labeled with 32P and a 32P-labeled 15-kDa fragment which contains both the DNA-binding domain and the BuGR epitope. We have calculated that there are 4 times as many phosphate residues in the intact receptor than in the 42-kDa chymotrypsin fragment. From examination of 32P-labeled receptor fragments, we have deduced that one phosphate is located between amino acids 398 and 447, a region containing the BuGR epitope and about one-third of the DNA-binding domain, and the remaining three phosphates appear to be clustered just to the amino-terminal side of the BuGR epitope in a region defined by amino acids 313 to 369. Treatment of intact 32P-labeled receptor in cytosol with alkaline phosphatase removes these three phosphates, but it does not remove the phosphate from the DNA-binding-BuGR-reactive fragment and it does not affect the ability of the transformed receptor to bind to DNA-cellulose.

Glucocorticoid receptor phosphorylation in mouse L-cells.

This paper summarizes our observations on the phosphorylation state of untransformed and transformed glucocorticoid receptors isolated from 32P-labeled L-cells. The 300-350-kDa 9S untransformed murine glucocorticoid receptor complex is composed of a 100-kDa steroid-binding phosphoprotein and one or possibly two units of the 90-kDa heat shock protein (hsp90), which is also a phosphoprotein. Transformation of this complex to the 4S DNA-binding state is accompanied by dissociation of hsp90. When receptors in cytosol are transformed by heating at 25 degrees C, there is no gross change in the degree of phosphorylation of the steroid-binding protein. Both receptors that are bound to DNA after transformation under cell-free conditions and receptors that are located in the nucleus of cells incubated at 37 degrees C in the presence of glucocorticoid are labeled with 32P. The results of experiments in which the 32P-labeled receptor was submitted to limited proteolysis suggest that the 16-kDa DNA-binding domain is phosphorylated and that the 28-kDa steroid-binding domain is not.