Partial purification of the glucocorticoid receptor from rat liver: a rapid, two-step procedure using DNA-cellulose.

Glucocorticoid receptor from rat liver was purified 1800-fold by a rapid two-step procedure using DNA-cellulose. The procedure is based on increasing the affinity of the glucocorticoid-receptor complex for DNA by heating the complex. During a first chromatography step, unheated glucocorticoid-receptor complex is separated from cytosol proteins that bind to DNA-cellulose with high affinity. During a second chromatographic step, heat-treated glucocorticoid-receptor complex is separated from proteins with low affinity for DNA. The partially purified complex is functionally competent in that it is taken up by isolated rat liver nuclei.     

The role of sulfhydryl groups in permitting transformation and DNA binding of the glucocorticoid receptor

Treatment of rat liver cytosol containing temperature-transformed, [3H]dexamethasone-bound receptors at 0 degree C with the sulfhydryl-modifying reagent methyl methanethiosulfonate (MMTS) inhibits the DNA-binding activity of the receptor, and DNA-binding activity is restored after addition of dithiothreitol (DTT). When cytosol containing untransformed receptors is heated at 25 degrees C in the presence of MMTS, the 90-kDa heat shock protein dissociates from the receptor in the same manner as in the absence of MMTS, and the receptor will bind to DNA-cellulose if DTT is added subsequently at 0 degree C. These observations are consistent with the conclusion of Bodwell et al. (Bodwell, J. E., Holbrook. N. J. and Munck, A. (1984) Biochemistry 23, 1392-1398) that sulfhydryl moieties on the receptor are absolutely required for the receptor to bind to DNA, and they show that the sulfhydryl-modifying reagent does not inhibit the temperature-mediated dissociation of the heteromeric receptor complex that accompanies transformation to the DNA-binding state. When steroid-receptor complexes that are prebound to DNA-cellulose are exposed to MMTS, the steroid rapidly dissociates, but the receptor remains bound to DNA. Thus, the presence of steroid is not required for the receptor to remain bound to DNA in a high affinity manner. Treatment of cytosol containing transformed glucocorticoid-receptor complexes at 0 degrees C with 20 mM hydrogen peroxide also inactivates the DNA-binding activity of the receptor. The peroxide-induced inactivation is reversed by DTT. Incubation of rat liver cytosol containing untransformed glucocorticoid-receptor complexes at 25 degrees C with hydrogen peroxide prevents their transformation to the DNA-binding form as shown by their inability to bind to DNA-cellulose after addition of DTT. The presence of peroxide during heating of the cytosol also prevents dissociation of the receptor complex as assayed both by reduction in sedimentation value of the receptor and by dissociation of the 90-kDa heat shock protein from the steroid-binding protein. These results strongly suggest that critical sulfur moieties in the receptor complex must be in a reduced form for the temperature-mediated dissociation of the receptor to occur.     

Extraction of DNA-cellulose-bound glucocorticoid-receptor complexes with sodium tungstate

Glucocorticoid-receptor complex from rat liver cytosol, activated by warming at 23°C or fractionation with (NH₄)₂SO₄, was adsorbed over DNA-cellulose. This DNA-cellulose-bound [³H]triamcinolone acetonide-receptor complex was extracted in a dose-dependent manner by incubation with different concentrations of sodium tungstate. A 50% recovery of receptor was achieved with 5 mM sodium tungstate. Almost the entire glucocorticoid-receptor complex bound to DNA-cellulose could be extracted with 20 mM sodium tungstate. The [³H]triamcinolone acetonide released from DNA-cellulose following tungstate and molybdate treatment was found to be associated with a macromolecule, as seen by analysis on a Sephadex G-75 column. The glucocorticoid-receptor complex extracted by both the compounds sedimented as a 4 S entity of 5–20% sucrose gradients under low- and high-salt conditions. Addition of tungstate or molybdate to the preparations containing activated receptor had no effect on the sedimentation rate of receptor. However, addition of tungstate to non-activated receptor preparation caused aggregates of larger size. The tungstate-extracted glucocorticoid-receptor complex failed to rebind to DNA-cellulose even after extensive dialysis, whereas receptor in molybdate-extract retained its DNA-cellulose binding capacity.     

Cytosol induces apparent selectivity of glucocorticoid receptor binding to nucleic acids of different secondary structure

Unpurified rat liver glucocorticoid-receptor complexes within cytosol show a distinct binding preference for double-stranded DNA over single-stranded DNA; the binding to Escherichia coli rRNA is negligible. Extensive purification of the receptor abolishes its ability to distinguish among DNAs of different secondary structure and the affinity of the purified receptor toward RNA is greatly enhanced, reaching 30–50% of that of DNA. The purification effect is reversible: after cytosol addition to purified receptor preparation the binding preference restores. NaCl does not mimic the effect of cytosol. The flow-through fraction of a phosphocellulose column retains the ability of crude cytosol to produce selective decrease in the receptor binding to single-stranded DNA. This effect may also be observed by using two types of DNA-cellulose bearing double-stranded or denatured DNA, pretreated with crude cytosol. Additionally, pretreatment of immobilized DNA with even low cytosol concentrations has been shown to markedly enhance receptor binding, although this enhancement was lacking specificity with respect to DNA secondary structure. The nature of cytosolic active principle and some possible regulatory implications are discussed.     

Dynamics of DNA-binding activity of cytoplasmic proteins in autoproteolysis

The quality proteolysis changing of DNA-binding proteins of cytosol mice liver was studied by affinity chromatography on DNA-cellulose. It is shown that neutral proteolysis leads to the second peak of DNA binding.     

Modulation of DNA binding of glucocorticoid receptor by aurintricarboxylic acid

Effects of aurintricarboxylic acid (ATA) were examined on the DNA binding properties of rat liver glucocorticoid-receptor complex. The DNA-cellulose binding capacity of the glucocorticoid-receptor complex was completely abolished by a pretreatment of receptor preparation with 0.1-0.5 mM ATA at 4 degrees C. The half-maximal inhibition (i.d.50) in the DNA binding of [3H]triamcinolone acetonide-receptor complex [( 3H]TARc) was observed at 130- and 40 microM ATA depending upon whether the inhibitor was added prior to or following the receptor activation. The entire DNA-cellulose bound [3H]TARc could be extracted in a concentration-dependent manner by incubation with 2-100 microns ATA. The [3H]TARc remained intact under the above conditions, the receptor in both control and ATA-treated preparations sedimented in the same region in salt-containing 5-20% sucrose gradients. The action of ATA appeared to be on the receptor and not on DNA-cellulose. The DNA-binding capacity of ATA-treated receptor preparations could be recovered upon exhaustive dialysis. The treatment with ATA did not appear to change the ionic behavior of heat activated GRc; the receptor in both control and the ATA-treated preparations showed similar elution profiles. Therefore, ATA appears to alter the binding to and dissociation of glucocorticoid-receptor complex from DNA. The use of ATA should offer a good chemical probe for analysis of the DNA binding domain(s) of the glucocorticoid receptor.     

Characterization of the DNA-binding properties of the receptor for 2,3,7,8-tetrachlorodibenzo-p-dioxin

The DNA-binding properties of the receptor for 2,3,7, 8-tetrachlorodibenzo-p-dioxin (TCDD) were investigated using chromatography on DNA-cellulose columns. A maximal binding of about 40% of the total receptor complex to DNA-cellulose was observed. In order to interact with DNA, the receptor must first bind TCDD. A heat-activation step followed by gel permeation chromatography using Sephadex G-25 increased the binding of the cytosolic receptor to DNA. The DNA-binding ability of the receptor was almost lost following mild proteolysis using trypsin or alpha-chymotrypsin, although these treatments did not reduce its ligand binding capacity and had no apparent effect on its size. Furthermore, pre-treatment of the DNA-cellulose column with an intercalating drug, ethidium bromide, resulted in inhibition of the binding of the TCDD-receptor complex to DNA, indicating that not only electrostatic interactions but also the configuration of DNA are of importance in receptor-DNA interactions.     

Chromatographic separation of nontransformed and transformed glucocorticoid-receptor complexes from rat liver cytosol. Use of tungstate in the purification, inactivation, and resolution of receptor forms

Aliquots of rat liver cytosol glucocorticoid-receptor complexes (GRc) were transformed by an incubation with 8-10 mM ATP at 0 degrees C and were compared with those transformed by an exposure to 23 degrees C. The extent of receptor transformation was measured by chromatography of the samples over columns of DEAE-Sephacel. The ATP-transformed complexes, like those which were heat-transformed, exhibited lower affinity for the positively charged ion-exchange resin and were eluted with 0.12 M KCl (peak-I): the nontransformed complexes appeared to possess higher affinity and required 0.21 M KCl (peak II) for their elution. As expected, the receptor in the peak-I exhibited the DNA-cellulose binding capacity and sedimented as 4S in sucrose gradients. Peak II contained an 8-9S glucocorticoid receptor (GR) form that showed reduced affinity for DNA-cellulose. Presence of sodium tungstate (5 mM) prevented both heat and ATP transformation of the GRc resulting in the elution of the complexes in the region of nontransformed receptors. When parallel experiments were performed, binding of the cytosol GRc to rat liver nuclei or DNA-cellulose was seen to increase 10-15 fold upon transformation by heat or ATP: tungstate treatment blocked this process completely. The transformed and nontransformed GRc were also differentially fractionated by (NH4)2SO4: tungstate-treated (nontransformed) receptor required higher salt concentration and was precipitated at 55% saturation. In addition, the GRc could be extracted from DNA-cellulose by an incubation of the affinity resin with sodium tungstate resulting in approximately 500-fold purification of the receptor with a 30% yield. These studies show that the nontransformed, and the heat-, salt-, and ATP-transformed GRc from the rat liver cytosol can be separated chromatographically, and that the use of tungstate facilitates the resolution of these different receptor forms. In addition, extraction of the receptor from DNA-cellulose by tungstate provides another new and efficient method of partial receptor purification.     

Characterization of the rat liver glucocorticoid receptor purified by DNA-cellulose and ligand affinity chromatography

Two rapid and high yield purification methods for the rat liver glucocorticoid receptor based on differential DNA affinity (method A) and ligand affinity (method B) chromatography are described. In method A, the amount of receptor in rat liver cytosol that can be activated and subsequently eluted from a DNA-cellulose column has been increased to 80% by introducing a second heat activation step. Using this method, 1.5 nmol of 25% pure glucocorticoid receptor can be routinely obtained per day from 15-20 rat livers. Method B yields about 2.2 nmol of 60% pure receptor with an overall yield of congruent to 60%. The quality of these purifications has been controlled by affinity labeling. In each case, more than 95% of purified binding activity represented the intact 92,000 +/- 400-Da glucocorticoid receptor polypeptide as shown by sodium dodecyl sulfate-gel electrophoresis and fluorography. No difference in the labeling pattern was observed using either [3H]triamcinolone acetonide (photoaffinity labeling) or [3H]dexamethasone 21-mesylate (electrophilic labeling). The electrophilic labeling step was performed in the cytosol prior to purification by method A to compare the labeled components thus purified with those obtained when the photoaffinity labeling was performed after the purification. Using this approach, distinct breakdown products of the glucocorticoid receptor were revealed, co-purifying during DNA affinity chromatography. Cross-linked receptor obtained by method A has been further purified to homogeneity by preparative sodium dodecyl sulfate-gel electrophoresis and successfully used as immunogen to raise glucocorticoid receptor antibodies in rabbits. These antibodies raised against glucocorticoid receptor, as well as those previously obtained using affinity chromatography-purified receptor, react with the receptor molecules irrespective of their method of purification. Glucocorticoid receptors purified by methods A and B have been analyzed for specific DNA-binding properties by the nitrocellulose filter binding assay.     

Purification and comparative study of the properties of glucocorticoid- and estrogen-receptor complexes in the rat liver

Parallel purification of glucocorticoid- and estrogen-receptor complexes from rat liver cytosol has been accomplished. Some properties of purified steroid-receptor complexes (SRC) were determined. The procedure developed earlier when the two-step treatment of cytosol with DNA-cellulose alternated with SRC ammonium sulphate precipitation, was shown to be universally applicable for purification of various SRC. Certain modifications have been devised allowing some increase in the degree of receptor purification. The amount of estrogen-receptor complexes (ERC) isolated from male liver cytosol was 20-40 times less than that of glucocorticoid-receptor complexes (GRC) isolated simultaneously from the equal volume of the same cytosol. Both SRC types bind intensively to homologous DNA but not to poly(A). The elution of GRC from DNA cellulose was mainly achieved at 0.4 M NaCl. With this, GRC and ERC showed small, but reliable differences in the salt resistance of their associates with DNA: the ERC-DNA link was stable toward NaCl up to 0.1 M, whereas an appreciable amount of GRC was eluted from DNA-cellulose at 0.1 M NaCl. The stability of purified ERC exceeded that of purified GRC, which apparently reflects the differences in the hormone-receptor binding constants. The receptor stability under various environmental conditions is discussed and some recommendations on the improvement of the SRC stability and its control are given.     

Purification of the glucocorticoid receptor from rat liver cytosol.

The [3H]-triamcinolone acetonide-labeled glucocorticoid receptor from rat liver cytosol was purified to 85% homogeneity according to sodium dodecyl sulfate gel electrophoresis. It consisted of one subunit with a molecular weight of 89,000 and had one ligand-binding site per molecule. The purification involved sequential chromatography on phosphocellulose, DNA-cellulose twice, and Sephadex G-200. Between the two chromatography steps on DNA-cellulose, the receptor was heat activated. The receptor was affinity eluted from the second DNA-cellulose column with pyrodixal 5'-phosphate. The purification achieved in the first three chromatographic steps varied between 60 and 95% homogeneity in different experiments. After chromatography on the second DNA-cellulose column, the steroid.receptor complex had a Stokes radius of 6.0 nm and a sedimentation coefficient of 3.4 S in 0.15 M KCl. In the absence of KCl, the sedimentation coefficient was 3.6 S. After concentration on hydroxylapatite, the steroid.receptor complex was analyzed by isoelectric focusing in polyacrylamide gel. The radioactivity was shown to focus together with the major protein band with pI 5.8. Following limited proteolysis with trypsin, the radioactivity, together with the major protein band, focused at pI 6.2 as previously described for the unpurified steroid.receptor complex.     

Inactivation of rat liver glucocorticoid receptor by molybdate. Effects on both non-activated and activated receptor complexes.

When freshly prepared glucocorticoid-receptor complex from rat liver cytosol was incubated at 23 degrees C in the presence of sodium molybdate, its subsequent binding to isolated nuclei, DNA-cellulose and ATP-Sepharose was blocked. In addition, binding to these acceptors by cytosol receptor complex fractionated with (NH4)2SO4 was also blocked by incubation of the complexes with 50 mM-sodium molybdate. However, molybdate had no effect on the binding of activated receptor complexes to ATP-Sepharose. Molybdate was also effective in extracting the nuclear- and DNA-cellulose-bound glucocorticoid-receptor complexes in a dose-dependent manner. Molybdate appears to exert its effects directly on the receptor by interacting with both non-activated and activated receptor forms.     

Involvement of a low molecular weight component(s) in the mechanism of action of the glucocorticoid receptor.

[³H]Dexamethasone-receptor complexes from rat liver cytosol preincubated at 0° bind poorly to DNA-cellulose. However, if the steroid-receptor complex is subjected to gel filtration at 0–4° separating it from the low molecular weight components of cytosol, the steroid-receptor complex becomes “activated” enabling its binding to DNA-cellulose. This activation can be prevented if the gel filtration column is first equilibrated with the low molecular weight components of cytosol. In addition, if adrenalectomized rat liver cytosol, in the absence of exogeneous steroid, is subjected to gel filtration the macromolecular fractions separated from the “small molecules” of that cytosol have much reduced binding activity towards [³H]dexamethasone. These results suggest that rat liver cytosol contains a low molecular weight component(s) which maintains the glucocorticoid receptor in a conformational state that allows the binding of dexamethasone. Furthermore, this component must be removed from the steroid-receptor complex before binding to DNA can occur.     

Evidence that pH induced activation of the rat hepatic glucocorticoid-receptor complex is irreversible

The possible reversibility of pH induced activation of the glucocorticoid-receptor complex was studied. Generally, this was accomplished by activating rat liver cytosol at pH 8.5 (15 degrees C, 30 min), and then returning it to pH 6.5 for a second incubation (15 degrees C, 30 min). Activation was quantitated by measuring the binding of [3H]triamcinolone acetonide [( 3H]TA)-receptor complexes to DNA-cellulose. When cytosol was incubated at pH 6.5, only 4.1% of the [3H]TA-receptor complexes bound to DNA-cellulose. However, 39.2% of the complexes bound when the cytosol was pH activated. When pH activation was followed by a second incubation at pH 6.5, 47.0% of the steroid-receptor complexes bound. Thus, according to the DNA-cellulose binding assay, pH induced activation was irreversible. In order to visualize both activated and unactivated [3H]TA-receptor complexes during this process, diethylaminoethyl (DEAE)-cellulose chromatography was performed. When cytosol was incubated at pH 6.5, only 19.6% of the [3H]TA-receptor complexes were eluted in the activated form from DEAE-cellulose. However, 67.5% of the complexes were eluted in the activated form when cytosol was pH activated. When pH activation was followed by a second incubation at pH 6.5, 74.9% of the steroid-receptor complexes were eluted in the activated form. Thus, DEAE-cellulose chromatography also showed that pH induced activation was irreversible. This is the first known report that the combination of DNA-cellulose binding and DEAE-cellulose chromatography have been used to study pH induced activation of the glucocorticoid-receptor complex. By these criteria, we conclude that in vitro pH induced activation is irreversible.     

Purification and structural analysis of the modulator of the glucocorticoid-receptor complex. Evidence that modulator is a novel phosphoglyceride

Modulator is the low molecular weight heat-stable inhibitor of glucocorticoid-receptor complex activation. We have purified modulator to apparent homogeneity from heated rat liver cytosol. This was accomplished using Sephadex G-15 gel filtration, Dowex 1 anion-exchange chromatography, and preparative silica high-performance liquid chromatography. The modulator preparation was judged to be homogeneous by analytical silica high-performance liquid chromatography, two-dimensional silica thin-layer chromatography, and proton nuclear magnetic resonance spectroscopy. The apparent concentration of modulator in rat liver cytosol is 6.5 microM. The purified modulator inhibits heat activation of the rat liver glucocorticoid-receptor complex and stabilizes the steroid binding ability of the unoccupied rat liver glucocorticoid receptor in a dose-dependent manner. At a concentration of 5-6.5 microM, modulator inhibits receptor activation and stabilizes the unoccupied receptor by 50%. At a concentration of 500-630 microM, sodium molybdate also inhibits receptor activation and stabilizes the unoccupied receptor by 50%. Thus, modulator appears to be the endogenous factor that exogenous sodium molybdate mimics in vitro. Chemical analysis of the purified modulator following two-dimensional silica thin-layer chromatography indicates that modulator is an aminophospholipid. Physical analysis of the purified modulator by infrared and nuclear magnetic resonance spectroscopy, as well as mass spectrometry, demonstrates that modulator is an ether aminophosphoglyceride.     

Interaction of the hepatic receptor protein for 2,3,7,8-tetrachlorodibenzo-p-dioxin with DNA

2,3,7,8-Tetrachlorodibenzo-p-dioxin (TCDD) binds to a specific, high-affinity, low-capacity protein in rat liver cytosol. The TCDD-receptor complex is a large molecule with a Stokes radius of 6.6 nm as determined by gel filtration on calibrated columns. The receptor complex sediments at 5.0 S on glycerol gradients. The calculated molecular weight from the physical parameters was 136 000 and the frictional ratio 1.79.The TCDD-receptor complex binds to DNA-cellulose without preceding heat activation or incubation at high ionic strength. The receptor must first bind TCDD before it can interact with DNA. The DNA-binding ability can be removed from the TCDD receptor by limited proteolysis with trypsin. This treatment does not affect the TCDD-binding site of the receptor. The proteolytic fragment of the TCDD-receptor complex containing the TCDD-binding site but not the ability to bind to DNA appears to be approximately the same size as the native receptor, as judged from chromatography of Sepharose CL-6B and glycerol gradient centrifugation.     

Degradation without apparent change in size of molybdate-stabilized nonactivated glucocorticoid-receptor complexes in rat thymus cytosol

We have investigated the stability of the [3H]dexamethasone 21-mesylate-labeled nonactivated glucocorticoid-receptor complex in rat thymus cytosol containing 20 mM sodium molybdate. Cytosol complexes were analyzed under nondenaturing conditions by gel filtration chromatography in the presence of molybdate and under denaturing conditions by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. When analyzed under nondenaturing conditions, complexes from fresh cytosol and from cytosol left for 2 h at 3 degrees C eluted from gel filtration as a single peak of radioactivity with a Stokes radius of approximately 7.7 nm, suggesting that no proteolysis of the complexes had occurred in either cytosol. When analyzed under denaturing conditions, however, whereas the fresh cytosol gave a receptor band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis at Mr approximately 90,000 (corresponding to the intact complex), the cytosol that had been left for 2 h at 3 degrees C gave only a fragment (Mr approximately 50,000). This fragment, just as the intact complex, could be thermally activated to a DNA-binding form. Proteolysis of the receptor could be blocked by preparing the cytosol in the presence of EGTA, leupeptin, or a heat-stable factor present in the cytosol of rat liver and WEHI-7 mouse thymoma cells. From these results we conclude: (i) 20 mM molybdate does not protect the nonactivated glucocorticoid-receptor complex present in rat thymus cytosol against proteolysis under conditions which are commonly used for cell-free labeling of the receptor, and (ii) the demonstration of a Stokes radius of approximately 8 nm for the nonactivated glucocorticoid-receptor complex is not sufficient to indicate that the receptor complex is present in its intact form.     

Influence of hydrophobic interactions on the structure and steroid-binding properties of glucocorticoid receptors

Glucocorticoid-receptor complexes in rat thymus cytosol were characterized by gel-filtration and ion-exchange chromatography and by other procedures. Two forms of non-transformed complex were identified at low ionic strength in the presence of molybdate, with Stokes radii of approx. 8 and 6 nm. The 8 nm molybdate-stabilized form could be converted to the 6 nm form by chromatography on Sephacryl S-300 or Lipidex 1000 or by incubation with charcoal or phospholipase C, but not by chromatography on Sephadex G-25. The dissociation rate of the complex was reduced by treatment with charcoal or Lipidex 1000, but none of the treatments caused transformation to a DNA-binding form. Transformation of the complex, by exposure to elevated temperature or ionic strength in the absence of molybdate, resulted in the appearance of a different 6 nm form, distinguished by an increased affinity for DNA-cellulose and a reduced affinity for DEAE-cellulose. These results suggest that receptor transformation is preceded by structural changes associated with the loss of a lipid factor from the complex. Non-polar steroid antagonists, and lipophilic compounds such as phenothiazines, were found to bind to secondary, hydrophobic sites on the receptor and to exert allosteric effects on the primary steroid-binding site; these and other observations emphasize the importance of hydrophobic interactions as determinants of the structure and properties of glucocorticoid receptors.     

Effect of the 90 kDa heat shock protein, HSP90, on glucocorticoid receptor binding to DNA-cellulose

Glucocorticoid receptors in the IM-9 human lymphoblastoid cell line were affinity labeled with [3H]dexamethasone 21-mesylate and activated to a DNA-binding form by filtration through a Bio-Gel A-1.5m column. The 90 kDa heat shock protein, HSP90, was identified by labeling IM-9 cells with 35S-methionine at both 37 degrees C and 42 degrees C and purified to near homogeneity by sequential chromatography through DE52 and hydroxyapatite. Addition of purified HSP90 to activated, affinity labeled glucocorticoid receptors in a molecular ratio of 16 to 1 inhibited the binding of the receptors to DNA-cellulose. HSP90 did not affect the binding of other proteins to DNA-cellulose, indicating that the inhibitory effect of HSP90 was specific for the glucocorticoid receptor. These results suggest that HSP90 may associate with the glucocorticoid receptor, masking its DNA-binding site and thereby inhibiting receptor interaction with DNA.