Subnuclear Trafficking of Glucocorticoid Receptors In Vitro: Chromatin Recycling and Nuclear Export

We have used digitonin-permeabilized cells to examine in vitro nuclear export of glucocorticoid receptors (GRs). In situ biochemical extractions in this system revealed a distinct subnuclear compartment, which collects GRs that have been released from chromatin and serves as a nuclear export staging area. Unliganded nuclear GRs within this compartment are not restricted in their subnuclear trafficking as they have the capacity to recycle to chromatin upon rebinding hormone. Thus, GRs that release from chromatin do not require transit through the cytoplasm to regain functionality. In addition, chromatin-released receptors export from nuclei of permeabilized cells in an ATP- and cytosol-independent process that is stimulated by sodium molybdate, other group VI-A transition metal oxyanions, and some tyrosine phosphatase inhibitors. The stimulation of in vitro nuclear export by these compounds is not unique to GR, but is restricted to other proteins such as the 70- and 90-kD heat shock proteins, hsp70 and hsp90, respectively, and heterogeneous nuclear RNP (hnRNP) A1. Under analogous conditions, the 56-kD heat shock protein, hsp56, and hnRNP C do not export from nuclei of permeabilized cells. If tyrosine kinase inhibitors genistein and tyrphostin AG126 are included to prevent increased tyrosine phosphorylation, in vitro nuclear export of GR is inhibited. Thus, our results are consistent with the involvement of a phosphotyrosine system in the general regulation of nuclear protein export, even for proteins such as GR and hnRNP A1 that use distinct nuclear export pathways.     

Inhibition of glucocorticoid receptor nucleocytoplasmic shuttling by okadaic acid requires intact cytoskeleton.

It has been shown previously that glucocorticoid receptors (GRs) that have undergone hormone-dependent translocation to the nucleus and have subsequently exited the nucleus upon hormone withdrawal are unable to recycle into the nucleus if cells are treated during hormone withdrawal with okadaic acid, a cell-permeable inhibitor of certain serine/threonine protein phosphatases. Using a green fluorescent protein (GFP) GR chimera (GFP-GR), we report here that okadaic acid inhibition of steroid-dependent receptor recycling to the nucleus is abrogated in cells treated for 1 h with colcemid to eliminate microtubule networks prior to steroid addition. After withdrawal of colcemid, normal cytoskeletal architecture is restored and okadaic acid inhibition of steroid-dependent GFP-GR nuclear recycling is restored. When okadaic acid is present during hormone withdrawal, GR that is recycled to the cytoplasm becomes complexed with hsp90 and binds steroid, but it does not undergo the normal agonist-dependent dissociation from hsp90 upon retreatment with steroid. However, when the cytoskeleton is disrupted by colcemid, the GR in okadaic acid-treated cells recycles from the cytoplasm to the nucleus in an agonist-dependent manner without dissociating from hsp90. This suggests that under physiological conditions where the cytoskeleton is intact, a dephosphorylation event is required for loss of high affinity binding to hsp90 that is required for receptor translocation through the cytoplasm to the nucleus along cytoskeletal tracts.     

Differential roles of heat shock protein 70 in the in vitro nuclear import of glucocorticoid receptor and simian virus 40 large tumor antigen.

Nuclear import of glucocorticoid receptors (GRs) was analyzed in vitro with digitonin-permeabilized cells (S. A. Adam, R. Sterne-Marr, and L. Gerace, J. Cell Biol. 111:807-816, 1990). Indirect immunofluorescence methods were used to monitor the transport of GRs from rat hepatoma and fibroblast cell cytosol into HeLa nuclei. In vitro nuclear import of GRs was shown to be hormone dependent and to require ATP and incubation at ambient temperatures (i.e., 30 degrees C). Hormone-dependent dissociation of GR-bound proteins, such as the 90-kDa heat shock protein, hsp90, is part of an activation process that is obligatory for the expression of the receptor's DNA-binding activity. Inhibition of in vitro GR activation by Na2MoO4 blocked hormone-dependent nuclear import, demonstrating that receptor activation is required for nuclear import. The addition to GR-containing cytosol of antiserum directed against the cytosolic 70-kDa heat shock protein, hsp70, while effective in blocking the nuclear import of simian virus 40 large tumor antigen (SV40 TAg), did not affect hormone-dependent nuclear import of endogenous, full-length GRs or an exogenously added truncated GR protein (i.e., XGR556) that lacks a hormone-binding domain but possesses a constitutively active nuclear localization signal sequence (NLS). Depletion of hsp70 from HeLa cell cytosol did not affect the nuclear import of exogenously added XGR556 but led to inhibition of SV40 TAg nuclear import. Thus, two closely related NLSs, one contained within GRs and the other contained within SV40 TAg, are distinguished by their differential requirements for hsp70 in vitro.     

Recycling and desensitization of glucocorticoid receptors in v-mos transformed cells depend on the ability of nuclear receptors to modulate gene expression

In v-mos transformed cells, glucocorticoid receptor (GR) proteins that bind hormone agonist are not efficiently retained within nuclei and redistribute to the cytoplasmic compartment. These cytoplasmic desensitized receptors cannot be reutilized and may represent trapped intermediates derived from GR recycling. We have used the glucocorticoid antagonist RU486 to examine whether v-mos effects can be exerted on any ligand-bound GR. In the rat 6m2 cell line that expresses a temperature-sensitive p85gag-mos oncoprotein, RU486 is a complete antagonist and suppresses dexamethasone induction of metallothionein-1 mRNA at equimolar concentrations. Using indirect immunofluorescence, we observe efficient nuclear translocation of GR in response to RU486 treatment in either the presence or absence of v-mos oncoproteins. However, in contrast to the redistribution of agonist-bound nuclear receptors to the cytoplasm of v-mos-transformed cells, RU486-bound GRs are efficiently retained within nuclei. Interestingly, withdrawal of RU486 does not lead to efficient depletion of nuclear GR in either nontransformed or v-mos transformed cells. It is only after the addition of hormone agonist to RU486 withdrawn v-mos-transformed cells that GRs are depleted from nuclei and subsequently redistributed to the cytoplasm. Thus, only nuclear GRs that are agonist-bound and capable of modulating gene activity can be subsequently processed and recycled into the cytoplasm.     

Protracted nuclear export of glucocorticoid receptor limits its turnover and does not require the exportin 1/CRM1-directed nuclear export pathway

Glucocorticoid receptors (GRs) are shuttling proteins, yet they preferentially accumulate within either the cytoplasmic or nuclear compartment when overall rates of nuclear import or export, respectively, are limiting. Hormone binding releases receptors from stable heteromeric complexes that restrict their interactions with soluble nuclear import factors and contribute to their cytoplasmic retention. Although hormone dissociation leads to the rapid release of GRs from chromatin, unliganded nuclear receptors are delayed in their export. We have used a chimeric GR that contains a heterologous, leucine-rich nuclear export signal sequence (NES) to assess the consequences of accelerated receptor nuclear export. Leucine-rich NESs utilize the exportin 1/CRM1-dependent nuclear export pathway, which can be blocked by leptomycin B (LMB). The fact that rapid nuclear export of the NES-GR chimera, but not the protracted export of wild-type GR, is sensitive to LMB, suggests that GR does not require the exportin 1/CRM1 pathway to exit the nucleus. Despite its more rapid export, the NES-GR chimera appears indistinguishable from wild-type GR in its transactivation activity in transiently transfected cells. However, accelerated nuclear export of the NES-GR chimera is associated with an increased rate of hormone-dependent down-regulation. The increase in NES-GR down-regulation is overcome by LMB treatment, thereby confirming the connection between receptor nuclear export and down-regulation. Given the presence of a nuclear recycling pathway for GR, the protracted rate of receptor nuclear export may increase the efficiency of biological responses to secondary hormone challenges by limiting receptor down-regulation and hormone desensitization.     

Assembly of progesterone receptor with heat shock proteins and receptor activation are ATP mediated events.

To better understand assembly mechanisms of progesterone receptor (PR) complexes, we have developed a cell-free system for studying PR interactions with the 90- and 70-kDa heat shock proteins (hsp90 and hsp70), and we have used this system to examine requirements for hsp90 binding to PR. Purified chick PR, free of hsp90 and immobilized on an antibody affinity resin, will rebind hsp90 in rabbit reticulocyte lysate when several conditions are met. These include: 1) absence of progesterone, 2) elevated temperature (30 degrees C), 3) presence of ATP, and 4) presence of Mg2+. We have obtained maximal hsp90 binding to receptor when lysate is supplemented with 3 mM MgCl2 and an ATP-regenerating system. ATP depletion of lysate by dialysis or by enzymatic means blocks hsp90 binding to PR; likewise, addition of EDTA to lysate blocks hsp90 binding, but binding is restored by the addition of excess Mg2+. Addition to lysate of monoclonal antibody against hsp70 inhibits hsp90 binding to PR and destabilizes preformed complexes. Stabilization of hsp90-receptor complexes also requires ATP, indicating that ATP and hsp70 are needed to form and to maintain hsp90 complexes. Hormone-dependent activation of reconstituted receptor complexes was also examined. The addition of progesterone to the reticulocyte lysate promotes dissociation of hsp90 and hsp70 from the receptor. This also appears to require ATP and dissociation is most efficient in the presence of an ATP-regenerating system. In conclusion, these studies indicate that PR-hsp90 complexes do not self-assemble; instead, assembly is probably a multistep process requiring ATP and other cellular factors.     

Glucocorticoid receptors: ATP-dependent cycling and hormone-dependent hyperphosphorylation

The dependence of hormone binding to glucocorticoid receptors (GRs) on cellular ATP levels led us to propose that GRs normally traverse an ATP-dependent cycle, possibly involving receptor phosphorylation, and that without ATP they accumulate in a form that cannot bind hormone. We identified such a form, the null receptor, in ATP-depleted cells. GRs are basally phosphorylated, and become hyperphosphorylated after treatment with hormone (but not RU486). In mouse receptors we have identified 7 phosphorylated sites, all in the N-terminal domain. Most are on serines and lie within a transactivation region. The time-course of hormone-induced hyperphosphorylation indicates that the primary substrates for hyperphosphorylation are the activated receptors; unliganded and hormone-liganded nonactivated receptors become hyperphosphorylated more slowly. After dissociation of hormone, most receptors appear to be recycled and reutilized in hyperphosphorylated form. From these and related observations, we have concluded that the postulated ATP-dependent cycle can be accounted for by hormone-induced or spontaneous dissociation of receptor-Hsp90 complexes, followed by reassociation of unliganded receptors with Hsp90 via an ATP-dependent reaction like that demonstrated in cell-free systems. Other steroid hormone receptors might traverse a similar cycle. Four of the 7 phosphorylated sites in the N-terminal domain are in consensus sequences for p34^cdc2 kinases important in cell cycle regulation. This observation, along with the known cell cycle-dependence of sensitivity to glucocorticoids and other evidence, point to a role for receptor phosphorylation in controlling responses to glucocorticoids through the cell cycle.     

Evidence that the peptidylprolyl isomerase domain of the hsp90-binding immunophilin FKBP52 is involved in both dynein interaction and glucocorticoid receptor movement to the nucleus

We have previously shown that immunoadsorption of the FKBP52 immunophilin component of steroid receptor.hsp90 heterocomplexes is accompanied by coadsorption of cytoplasmic dynein, a motor protein involved in retrograde transport of vesicles toward the nucleus. Coimmunoadsorption of dynein is competed by an expressed fragment of FKBP52 comprising its peptidylprolyl isomerase (PPIase) domain (Silverstein, A. M., Galigniana, M. D., Kanelakis, K. C., Radanyi, C., Renoir, J.-M., and Pratt, W. B. (1999) J. Biol. Chem. 52, 36980-36986). Here we show that cotransfection of 3T3 cells with the FKBP52 PPIase domain and a green fluorescent protein (GFP) glucocorticoid receptor (GR) chimera inhibits dexamethasone-dependent movement of the GFP-GR from the cytoplasm to the nucleus. Cotransfection with FKBP12 does not affect GFP-GR movement. Inhibition of movement by the FKBP52 PPIase domain is abrogated in cells treated with colcemid to eliminate microtubules prior to steroid addition. After withdrawal of colcemid, microtubules reform, and PPIase inhibition of GFP-GR movement is restored. These observations are consistent with the notion that FKBP52 targets retrograde movement of the GFP-GR along microtubules by linking the receptor to the dynein motor. Here, we also show that native GR.hsp90 heterocomplexes immunoadsorbed from L cell cytosol contain dynein and that GR.hsp90 heterocomplexes assembled in reticulocyte lysate contain cytoplasmic dynein in a manner that is competed by the PPIase domain of FKBP52.     

Evidence for glucocorticoid receptor transport on microtubules by dynein

Rapid, ligand-dependent movement of glucocorticoid receptors (GR) from cytoplasm to the nucleus is hsp90-dependent, and much of the movement system has been defined. GR.hsp90 heterocomplexes isolated from cells contain one of several hsp90-binding immunophilins that link the complex to cytoplasmic dynein, a molecular motor that processes along microtubular tracks to the nucleus. The immunophilins link to dynein indirectly via the dynamitin component of the dynein-associated dynactin complex (Galigniana, M. D., Harrell, J. M., O'Hagen, H. M., Ljungman, M., and Pratt, W. B. (2004) J. Biol. Chem. 279, 22483-22489). Although it is known that rapid, hsp90-dependent GR movement requires intact microtubules, it has not been shown that the movement is dynein-dependent. Here, we show that overexpression of dynamitin, which blocks movement by dissociating the dynein motor from its cargo, inhibits ligand-dependent movement of the GR to the nucleus. We show that native GR.hsp90.immnunophilin complexes contain dynamitin as well as dynein and that GR heterocomplexes isolated from cytosol containing paclitaxel and GTP to stabilize microtubules also contain tubulin. The complete movement system, including the dynein motor complex and tubulin, can be assembled under cell-free conditions by incubating GR immune pellets with paclitaxel/GTP-stabilized cytosol prepared from GR(-) L cells. This is the first evidence that the movement of a steroid receptor is dynein-dependent, and it is the first isolation of a steroid receptor bound to the entire system that determines its retrograde movement.     

A role for HDJ-2/HSDJ in correcting subnuclear trafficking, transactivation, and transrepression defects of a glucocorticoid receptor zinc finger mutant.

All steroid receptors possess a bipartite nuclear localization signal sequence (NLS) that localizes within the second zinc finger of their DNA-binding domain. Fine-structure mapping of the rat glucocorticoid receptor (rGS) NLS identified a composite signal composed of three distinct proto-NLSs that function effectively when present in unique pairs. At least one of the rGR proto-NLSs appears to influence receptor trafficking within the nucleus, as revealed by a unique nuclear staining pattern of receptors possessing a point mutation (i.e., arginine at position 496; R496), at proto-NLS, pNLS-2. Specifically, carboxyl-terminal-truncated rGRs possessing various point mutations at R496 localized within a limited number of large foci in nuclei of transiently transfected COS-1 cells. R496 mutations did not affect subnuclear targeting when present in full-length rGR, reflecting a protective effect of the receptor's ligand-binding domain that can be exerted in cis and in trans. The effects of rGR R496 mutations on subnuclear targeting were not autonomous because we also observed a coincident localization of hsp70, the 70-kDa heat shock protein, within nuclear foci that include r496 mutant receptors. The elimination of R496 mistargeting by overexpression of an hsp70 partner (i.e., the DnaJ homologue, HDJ-2/HSDJ) suggests that the hsp70/DnaJ chaperone system is mobilized to specific sites within the nucleus in response to inappropriate targeting or folding of specific mutant receptors. HDJ-2/HSDJ overexpression also corrects defective transactivation and transrepression activity of R496 mutant GRs. Thus, molecular chaperones, such as members of the hsp70 and DnaJ families, may survey the nucleus for misfolded proteins and actively participate in their refolding into biologically active conformational states.     

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.     

Cell cycle regulation of glucocorticoid receptor function.

Glucocorticoid receptor (GR) nuclear translocation, transactivation and phosphorylation were examined during the cell cycle in mouse L cell fibroblasts. Glucocorticoid-dependent transactivation of the mouse mammary tumor virus promoter was observed in G0 and S phase synchronized L cells, but not in G2 synchronized cells. G2 effects were selective on the glucocorticoid hormone signal transduction pathway, since glucocorticoid but not heavy metal induction of the endogenous Metallothionein-1 gene was also impaired in G2 synchronized cells. GRs that translocate to the nucleus of G2 synchronized cells in response to dexamethasone treatment were not efficiently retained there and redistributed to the cytoplasmic compartment. In contrast, GRs bound by the glucocorticoid antagonist RU486 were efficiently retained within nuclei of G2 synchronized cells. Inefficient nuclear retention was observed for both dexamethasone- and RU486-bound GRs in L cells that actively progress through G2 following release from an S phase arrest. Finally, site-specific alterations in GR phosphorylation were observed in G2 synchronized cells suggesting that cell cycle regulation of specific protein kinases and phosphatases could influence nuclear retention, recycling and transactivation activity of the GR.     

Evidence from pulse-chase labeling studies that the antiglucocorticoid hormone RU486 stabilizes the nonactivated form of the glucocorticoid receptor in mouse lymphoma cells

A pulse-chase labeling technique was used to determine the properties of glucocorticoid receptors occupied by the antiglucocorticoid hormone RU486 in S49.1 mouse lymphoma cells. Cells were pulse-labeled with [35S]methionine and then at the beginning of the chase, either no hormone (control), dexamethasone, or RU486 was added to cells. At 4 h into the chase, cytosol was prepared and receptors were immunoadsorbed to protein A-Sepharose using the BuGR2 antireceptor antibody. Immunoadsorbed proteins were resolved by gel electrophoresis and analyzed by autoradiography. The 90 kDa heat shock protein (hsp90) coimmunoadsorbed with receptors from control cells when protein A-Sepharose pellets were washed with 250 mM NaCl but not when protein A-Sepharose pellets were washed with 500 mM NaCl, indicating that hsp90-receptor complexes are disrupted by a high concentration of salt in the absence of molybdate. hsp90 coimmunoadsorbed with receptors from RU486-treated cells even when protein A-Sepharose pellets were washed with 500 mM NaCl, indicating that RU486 stabilizes the association of hsp90 with the glucocorticoid receptor. In contrast, hsp90 did not coimmunoadsorb with receptors from dexamethasone-treated cells, consistent with earlier evidence that hsp90 dissociates from the receptor when the receptor binds glucocorticoid hormone. Dexamethasone induced a rapid quantum decrease in the amount of normal receptor recovered from cytosol but did not induce a decrease in the amount of nuclear transfer deficient receptor recovered from cytosol, consistent with tight nuclear binding of normal receptors occupied by dexamethasone. In contrast, RU486 did not induce a quantum decrease in the recovery of normal receptors from cytosol, indicating that receptors occupied by RU486 are not tightly bound in the nuclear fraction. We conclude that the antiglucocorticoid hormone RU486, in contrast to the glucocorticoid hormone dexamethasone, stabilizes the association between the glucocorticoid receptor and hsp90. The decreased affinity of receptors occupied by RU486 for the nuclear fraction may be due to their association with hsp90 and may account for the failure of RU486 to exert agonist activity.