Multiple forms of oviduct progesterone receptors analyzed by ion exchange filtration and gel electrophoresis.

Resolution of the multiple forms of steroid receptors in small samples has been improved by two new techniques: preparative ion exchange filtration and electrophoresis in highly cross-linked polyacrylamide gels of varied concentration. These techniques were used in conjunction with protamine precipitation, gel filtration, and density gradient centrifugation to separate five forms of the progesterone receptor of chick oviduct cytosol. These complexes, numbered I to V in order of elution from agarose gel columns, have been characterized with respect to apparent molecular weight, shape, and relative net charge. Form I, which is eluted in the void volume after gel filtration of cytosol in hypotonic media, is heterodisperse with respect to sedimentation coefficient and electrophoretic mobility (Rf). Form I is converted to form III by KC1. Form II has the highest axial ratio and the highest Rf at pH 10.2. This 4.2S complex can be extracted from DEAE filters, but not from protamine-precipitated cytosol, by 0.3 to 0.5 M KC1. Form III is slightly smaller (3.9S) and less asymmetric than form II. It is relased from DEAE filters and protamine-precipitated cytosol by 0.15 M KC1 and displays increased Rf upon purification. Forms II and III correspond to the B and A components described by W. T. Schrader and B. W. O'Malley ((1972), J. Biol. Chem 247, 51). Form IV may result from the proteolytic cleavage of forms II and/or III. Form V is a globular polypeptide obtained in the presence of certain divalent cations. This complex has been named the "mero-receptor" since it is the smallest part or fragment of the receptor that contains the steroid-binding site.     

Reconstitution of progesterone receptor with heat shock proteins

Nonactivated chick progesterone receptor from hypotonic tissue extracts exists in a large complex containing the heat shock proteins hsp90 and hsp70 plus additional smaller proteins; activation of receptor to a DNA-binding form involves the dissociation of proteins from the complex. Whereas numerous attempts to reversibly bind components to the activated receptor have been unsuccessful, we now report conditions that promote the reassociation of hsp90 and hsp70 to progesterone receptor. Cytosolic receptor was dissociated from hsp90 and hsp70 by treatment with 0.5 M KCl and 10 mM ATP in the absence of progesterone. It was then purified by binding to immunoaffinity resins. After wash steps, the receptor-resin complex was incubated in rabbit reticulocyte lysate at 30 C, rewashed, and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Saturable binding of rabbit hsp90 and hsp70 to chick receptor was found after incubation with reticulocyte lysate; hsp binding was temperature dependent, but not dependent on exogenous ATP. Incubation of dissolved receptor with oviduct cytosol, from which receptor was obtained, or with purified hsp did not result in hsp binding. Furthermore, mixing oviduct cytosol with lysate inhibited hsp reconstitution, suggesting negative factors for hsp binding in oviduct cytosol. The steroid-binding domain of the receptor was required, since no hsp binding was observed in the reconstitution system using a receptor mutant lacking this domain. When the receptor was isolated in the presence of progesterone, reconstitution with hsp90 and hsp70 did not occur. This is consistent with the in vivo effects of progesterone in promoting hsp dissociation.     

Identification of two forms of progesterone receptor from chick oviduct cytosol using non-denaturing gel electrophoresis

Non-denaturing polyacrylamide gel electrophoresis and non-denaturing agarose gel electrophoresis have been used to resolve [3H]R5020-binding components from chick oviduct cytosol. From both gel systems 2 peaks of bound radioactivity are resolved which display these properties of authentic progesterone receptor: binding of R5020: steroid specificity, saturability, and restriction to target tissues. The two peaks are approximately equal in magnitude, and there is no evidence for interconversion of the 2 peaks. The presence or absence of 10-20 mM sodium molybdate during cytosol preparation had no effect on the magnitude or mobility of either peak. Neither peak contains salt-dissociable components which affect its electrophoretic properties, suggesting a possible alteration of native receptor forms during electrophoresis.     

Interaction of chick oviduct progesterone receptor with immobilized aurintricarboxylic acid

Aurintricarboxylic acid (ATA) was immobilized on Sepharose 4B via a carbodiimide coupling mechanism. A majority of the chick oviduct progesterone receptor was retained on the affinity resin and could be recovered upon washing the column with buffer containing free ligand or 3 M guanidine-HCl. The [3H]progesterone-receptor complex retained its integrity following the chromatography on ATA-Sepharose as judged by sedimentation analysis. The procedure allowed significant purification of progesterone receptor: SDS-polyacrylamide gel electrophoresis of the purified preparation revealed elimination of many peptide bands present in the cytosol prior to ATA-Sepharose chromatography. The technique thus has a clear potential in characterization and purification of progesterone receptor.     

Chick heat-shock protein of Mr = 90,000, free or released from progesterone receptor, is in a dimeric form

A monoclonal antibody (BF4) has been used to characterize and purify the heat-shock protein of Mr approximately 90,000 (hsp 90) present in the chick oviduct. In low salt cytosol, the sedimentation coefficient of hsp 90 is approximately 6.8 S, the Stokes radius approximately 7.1 nm, and the calculated Mr approximately 204,000, thus suggesting a dimeric structure. In 0.4 M KCl cytosol, only slightly smaller values were determined (approximately 6.5 S, approximately 6.8 nm, and approximately 187,000). Following purification by ion exchange and immunoaffinity chromatography, hsp 90 migrated as a single silver-stained band at Mr approximately 90,000 in sodium dodecyl sulfate-polyacrylamide gel electrophoresis, while the sedimentation coefficient 6.2 S, the Stokes radius approximately 6.8 nm, and the Mr approximately 178,000 confirmed the dimeric structure. However, in both antigen or antibody excess conditions, only one molecule of monoclonal antibody could be bound to the hsp 90 dimer. Whether steric hindrance in a homodimer or the presence of two different 90-kDa proteins in a heterodimer explains this result cannot yet be decided. The dimer is not dissociated by high salt (1 M KCl) or the chaotropic agent (0.5 M NaSCN), but is disrupted by 4 M urea, suggesting a stabilization of the structure by hydrogen bonds. The molybdate-stabilized progesterone receptor hetero-oligomer form of approximately 8 S sedimentation coefficient was purified, and its hsp 90 component was then released by salt treatment. It was found to sediment at approximately 5.8 S and have a Stokes radius approximately 7.1 nm, giving Mr approximately 174,000. This observation is consistent with a previous report suggesting from specific activity determination, scanning of polyacrylamide gels, and cross-linking experiments that each purified nontransformed progesterone receptor molecule includes one progesterone binding unit per two 90-kDa protein molecules (Renoir, J. M., Buchou, T., Mester, J., Radanyi, C., and Baulieu, E. E. (1984) Biochemistry 23, 6016-6023). This work brings direct evidence that both free hsp 90 and the non-hormone binding hsp 90 component released from the nontransformed steroid receptor in the cytosol are in a dimeric form.     

Evidence for two structurally related progesterone receptors in chick oviduct cytosol

The existence of two progesterone receptor forms present in crude cytosol of chick oviduct has been demonstrated by photoaffinity labelling using [3H]R5020. On SDS-polyacrylamide gels these two forms exhibit app. Mr-values of 79000 and 109000 corresponding to the progesterone receptor forms A and B. Peptide maps of photoaffinity-labelled steroid receptors have been established by limited proteolysis with alpha-chymotrypsin. The peptide map obtained for chick oviduct cytosol progesterone receptor crosslinked with [3H]R5020 proved to be the sum of peptides obtained from partially purified preparations of forms A and B. The peptide maps of both progesterone receptor forms were identical for peptides below the Mr-value of form A, indicating extensive homology of the two forms. A significantly different peptide pattern was observed for the rat liver glucocorticoid receptor crosslinked with [3H]triamcinolone acetonide. Prolonged proteolysis with chymotrypsin gave rise to peptides with Mr-values of 6000 and 10000 from the hormone-binding domain of progesterone and glucocorticoid receptors, respectively.     

Analysis of enzyme activity regulation by non-denaturing electrophoresis and application of this regulation for enzyme reactor production

Non-denaturing electrophoresis can be used to screen enzymes that self-regulate their activities by using a combination of enzymes and their inhibitors. Furthermore, this technique can be applied to develop enzyme reactors that self-regulate their activities. After separation of proteins from mouse liver cytosol by non-denaturing isoelectric focusing, lactate dehydrogense (LDH) and esterase activities were qualitatively and quantitatively examined using a combination of two-dimensional electrophoresis (2-DE) and non-denaturing stacking gel electrophoresis. Activities of mouse liver-derived LDH and carboxylesterase were reversibly inhibited by oxamate and 6,9-diamino-2-ethoxyacridine (acrinol), respectively, in the stacking gels and recovered when the enzymes migrated towards the separation gels. After separation and immobilization of the enzymes, their activities were inhibited by inhibitors and recovered after inhibitor removal. These results indicate that non-denaturing electrophoresis can be applied to select enzymes that self-regulate their activities and subsequently aid in the development of enzyme reactors that can control the enzyme activities.     

Immunologically distinct binding molecules for progesterone and RU38486 in the chick oviduct cytosol

[3H]Progesterone and [3H]RU38486 binding in the chick oviduct cytosol is associated with macromolecules which sediment as 8 S and 4 S moieties, respectively, in molybdate-containing 5-20% sucrose gradients. The [3H]progesterone binding could be displaced by excess progesterone, but not by RU38486. Conversely, the [3H]RU38486 binding was able to compete with RU38486 but not by excess progesterone. A preparation containing antibodies against chick oviduct progesterone receptor recognized only the [3H]progesterone-receptor complex but not the 4 S, [3H]RU38486 binding component of the chick cytosol. In the calf uterus cytosol, [3H]R5020 (a synthetic progestin) and [3H]RU38486 were associated with 8 S molecules and the peaks of radioactivity were displaceable upon preincubation with radionert steroids. In addition, the complexes were recognized by antibodies to chick oviduct progesterone receptor. Our data suggest that in the chick oviduct cytosol, RU38486 does not bind to progesterone receptor, but interacts with an immunologically distinct macromolecule.     

Evidence for separate binding sites for progesterone and RU486 in the chick oviduct

Binding characteristics of synthetic steroid, mifepristone (RU38486 - also referred to as RU486), were examined in cytosol prepared from the chick oviduct and the calf uterus, and were compared with those of progesterone and synthetic progestin R5020. Unlike [³H]progesterone binding, the [³H]RU486 binding in the oviduct cytosol did not saturate at 50 nM ligand concentration. The [³H]progesterone binding could not be eliminated in the presence of excess RU486, and [³H]RU486 binding was seen to be indisplaceable upon pretreatment of the chick oviduct cytosol with a 1000-fold excess progesterone. It is apparent that the chick oviduct cytosol is endowed with two separate sets of sites which interact with progesterone and RU486 independently. Furthermore, [³H]RU486 binding in the chick oviduct cytosol remained intact when incubated for 60 min at 37°C; it exhibited a single ionic form upon elution from DEAE-Sephacel and the [³H]RU486-associated radioactivity sedimented in the 4 S region both in salt-free and 0.3 M KCl-containing 5–20% sucrose gradients. In the calf uterus cytosol, both steroids exhibited comparable binding profiles. Our results provide evidence that chick oviduct possesses distinct binding sites that accept either progesterone or RU486, but not both, as is the case in the calf uterus.     

Effects of calcium on the chick oviduct progesterone receptor

The chick oviduct cytosol progesterone receptor can be transformed to a small form (Rs = 21A, S20,w:2.9) denoted "mero-receptor" by incubation in the presence of Ca2+ [8]. In the molybdate-free cytosol all the progestin binding components could be completely transformed to mero-form by 1 h treatment with 100 mM Ca2+ at 0 degrees C. If EDTA was secondarily added, the ligand was rapidly released. If molybdate (20 mM) containing cytosol was incubated with Ca2+, no radioactivity was found in the meroposition on the Agarose A 0.5 m column, but the bound steroid sedimented at 2.9 S in sucrose gradients containing Ca2+ (and no molybdate). When 20 nM molybdate was added to cytosol containing receptor activated by 0.3 M KCl, complete mero-transformation by Ca2+ was obtained also by the gel filtration criterion, indicating that molybdate does not inhibit the mero-transforming factor. Ligand-free progesterone receptor could also be completely converted to mero-form by endogenous cytosolic transforming factor and calcium. The transforming factor was completely inactivated, when cytosol was run through Agarose A 0.5 m gel. Mero-transformation was found to be irreversible. The purified progesterone receptor subunit 110 K (B) was partially converted to smaller forms by calcium alone (100 mM, 0 degrees C, 1 h) whereas addition of a small amount of cytosol allowed complete conversion to mero-form.     

Biochemical characterization of the progesterone receptor in the chick bursa of Fabricius

In a previous work we demonstrated estrogen-inducible progesterone binding sites in the bursa of Fabricius. In the present study these were characterized and compared to the progesterone receptor (PR) in the chick oviduct. When the size of the binding sites was analyzed with sucrose gradient centrifugation, 2 peaks of bound progesterone were obtained. The sedimentation coefficients of the peaks were 8-9 S and 3-4 S. In size exclusion HPLC only 1 peak was seen with a size corresponding to the 8-9 S in the sucrose gradient. The Stokes radius was 7.7 nm. When the ionic strength was elevated or CaCl2 was added, smaller steroid binding forms were detected. The sizes of these progesterone binding molecules at low and high ionic strength and in the presence of CaCl2 were equal in bursa and oviduct when analyzed with HPLC. The Stokes radii of these forms were 5.6 nm in high salt and 2.1 nm with CaCl2. The steroid binding components in the bursa cytosol eluated as 2 peaks from the DEAE column with KCl gradient. The peaks corresponded to the so-called A and B components in the chick oviduct. In the presence of molybdate, bound progesterone eluated as one peak from DEAE in both oviduct and bursa. The progesterone binding capacity was shown to be heat labile with equal half-lives in the bursa and the oviduct. Progesterone and ORG 2058 had a high affinity for the binding site and their binding was specific for progestins. It is concluded that the estrogen-inducible progesterone binding site in the bursa of Fabricius resembles the oviductal progesterone receptor in structural and binding properties.     

Prostatic binding protein. A steriod-binding protein secreted by rat prostate.

Rat prostatic cytosol contains a high concentration of a prostatic binding protein with peculiar steroid-binding properties. Indeed, in spite of a relatively low affinity, charcoal adsorption can be used for its measurement. Furthermore, the binding is not specific for particular steroids and increases very strongly after delipidation. In delipidated cytosol the concentration of the binding site is 3.1 micronmol/g protein and the apparent affinity for pregenolone 1.7 X 10(6) M-1. The high concentration of prostatic binding protein in prostatic fluid shows that this substance is secreted by the prostate. Prostatic binding protein has the following physicochemical characteristics: it is precipitated by ammonium sulfate between 50 and 70% saturation; the elution position from a Sephadex G-100 column corresponds to a molecular weight of 51000; it sediments in sucrose density gradients at 3.7 S and is eluted from DEAE-cellulose columns at about 0.25 M KCl. On polyacrylamide gel electrophoresis the binding activity coincides with the major cytosolic protein band. This band has the same mobility as serum albumin in 7% gels, but a higher mobility in more concentrated gels.     

Nuclear origin of progesterone receptor of the chick oviduct cytosol. An immunoelectron microscopic study

Progesterone receptor (PR) was studied immunoelectron microscopically from fixed vibratome sections of the chick oviduct and biochemically from the fractionated oviduct homogenate. Immunoelectron microscopically both unoccupied and occupied PR were localized inside the nuclei. Only a few cells showed PR immunoreactivity in the endoplasmic reticulum which probably represents newly synthetized PR. Biochemically unoccupied PR was in the cytosol fraction. The cytosol and nuclear PR as well as the non-transformed 8S-form and the transformed 4S-forms of cytosol PR were recognized by the anti-PR antibody (IgG-RB). The lack of PR immunostaining in the cytoplasm is therefore not due to lack of recognition by IgG-RB. We propose that in the chick oviduct progesterone receptor is a nuclear protein but synthetized in the endoplasmic reticulum.     

Nuclear origin of progesterone receptor of the chick oviduct cytosol

Summary Progesterone receptor (PR) was studied immunoelectron microscopically from fixed vibratome sections of the chick oviduct and biochemically from the fractionated oviduct homogenate. Immunoelectron microscopically both unoccupied and occupied PR were localized inside the nuclei. Only a few cells showed PR immunoreactivity in the endoplasmic reticulum which probably represents newly synthetized PR. Biochemically unoccupied PR was in the cytosol fraction. The cytosol and nuclear PR as well as the non-transformed 8S-form and the transformed 4S-forms of cytosol PR were recognized by the anti-PR antibody (IgG-RB). The lack of PR immunostaining in the cytoplasm is therefore not due to lack of recognition by IgG-RB. We propose that in the chick oviduct progesterone receptor is a nuclear protein but synthetized in the endoplasmic reticulum.     

Progesterone binding components of chick oviduct. X. Purification by affinity chromatography.

Cytoplasmic progesterone receptors of chick oviduct have been purified in 8% yield by steroid affinity and ion exchange chromatography. The affinity resin, deoxycorticosterone-bovine serum albumin-Sepharose, binds progesterone receptors with high affinity (KD equals 8 times 10-minus 10 M) and its use resulted in a greater than 2000-fold purification over the starting material in a single step. DEAE-Sephadex A-50 chromatography was then used to achieve final purification. NA dodecyl-SO4 gel electrophoresis and DEAE-cellulose chromatography showed that the purified receptors contained both of the previously described 4 S progesterone binding components in near equal amounts. Na dodocyl-SO4 gel electrophoresis also showed that these components consisted of single polypeptide chains with molecular weights of 110, 000 (A component) and 117, 000 (B component). There was no evidence for subunits of lower molecular weight. The purified materials have identical hormone-binding kinetics and steroid specificity to crude cytosol receptors. The isolated receptors retain the three biologically important properties exhibited by progesterone binding components present in cruder preparations: they bind specifically to (a) nuclei (KD equals 1.1 times 10-minus 9 M, 10, 000 sites per nucleus); (b) chromatin (KD equals 3 times 10-minus 9 M, 2000 sites per pg of DNA-);and (C) DNA.     

Progesterone-binding protein in the corpus luteum, blood and lymph of sheep

A protein which binds progesterone but not cortisol was found in luteal cytosol, utero-ovarian venous plasma, ovarian lymph and jugular venous plasma of sheep. The protein was isolated from other steroid-binding activities present in luteal cytosol and plasma by de-adsorption from hydroxyapatite with 40 mM phosphate. In all cases, it bound progesterone at 4 degrees C with an equilibrium affinity constant of the order of 10(6) l/mol, but did not bind cortisol. After chromatography on hydroxyapatite and Sephadex G-200, the protein obtained from utero-ovarian venous plasma had lost much of its steroid-binding activity, but migrated as a monomer of molecular weight 64 000 in polyacrylamide gel. Bovine luteal cytosol is reported to contain two proteins which bind progesterone similarly. In ruminants, these proteins may participate in the biosynthesis and secretion of progesterone from luteal cells and its transport in blood.     

Immunological evidence that the nonhormone binding component of avian steroid receptors exists in a wide range of tissues and species

A monoclonal antibody to a fungal protein has been used to demonstrate the presence of the nonhormone binding component of molybdate-stabilized steroid receptors in a variety of vertebrate tissues. We recently identified a steroid receptor in the aquatic fungus Achlya ambisexualis where sexual morphogenesis of the male is directed by the steroid antheridiol. This receptor resembles receptors of higher organisms in exhibiting an 8S, molybdate-stabilized form. In the chick oviduct, a 90 000 molecular weight protein has previously been shown to be associated with the molybdate-stabilized complex of the progesterone receptor. We have isolated a similar protein of molecular weight about 88 000 from A. ambisexualis and have obtained a hybridomal-derived monoclonal antibody directed against it. This mouse anti-Achlya immunoglobulin G1 (IgG1) cross-reacts with the 90 000 molecular weight protein in chick oviduct cytosol and was used to detect analogous 90 000 molecular weight proteins in mammalian tissues. Tissue cytosols were incubated with antibody, and the complexes were isolated onto protein A-Sepharose. The resin-bound proteins were then analyzed by gel electrophoresis. This procedure revealed the presence of 90 000 molecular weight proteins in several mammalian tissues including rat liver, mouse liver and uterus, pig ovarian granulosa cells, human endometrium, and HeLa cells. These results demonstrate that the 90 000 molecular weight protein is not peculiar to the chick oviduct but is present in several different tissues from a variety of animals. This antibody should be a useful probe for further studies on the biological role of these proteins.     

Effects of histone acetylation on nucleosome properties as evaluated by polyacrylamide gel electrophoresis and hydroxylapatite dissociation chromatography

The release of acetylated histones from chick oviduct chromatin was analyzed by hydroxylapatite column chromatography. By raising of the NaCl concentration, acetylated histones were eluted from hydroxylapatite-bound chromatin depending on their release from nucleosomal DNA. Electrophoresis on acid-urea gel showed that hyperacetylated forms of histone H4 were eluted at a lower NaCl concentration than non-acetylated or hypoacetylated H4, suggesting that hyperacetylated H4 has decreased stability in nucleosomes. However, under milder ionic conditions which do not induce dissociation between histones and DNA, polyacrylamide gel electrophoresis of purified nucleosome cores showed no evidence for their unfolding or for increased accessibility by high mobility group protein-17.     

Electrophoretic analysis of the estrogen receptor. Molybdate stabilization and identification of the classical estrogen receptor

Conditions are defined which permit analysis of estrogen receptors from the mammalian uterus by polyacrylamide gel electrophoresis, thereby solving a longstanding problem encountered in previous attempts at such analysis, namely the failure of a large portion of the receptor population to enter such gels. A paramount requirement for entry of the estrogen-receptor complex into polyacrylamide gels is its maintenance in an untransformed state which does not form aggregates that are excluded from these gels. Of the multiple estrogen-binding proteins separated, only one (relative mobility of 0.5-0.6) possessed the definitive characteristics of the classical estrogen receptor. The inclusion of molybdate in extraction buffers selectively enhanced receptor recovery and facilitated its separation. Moreover, the estrogen-receptor complex so resolved is separated from other types of estrogen-binding proteins present in the uterine cytosol. These findings show that the molybdate-stabilized estrogen receptor exists in a single discrete form, but otherwise exhibits multiple forms that are probably artifactual. Electrophoresis in discontinuous buffers, but not in a continuous buffer system, promoted aggregate formation. This finding has implications concerning the subunit structure of the untransformed receptor.     

Biochemical isolation and physiological identification of the egg- laying hormone in Aplysia californica

It has been determined that the bag cells of Aplysia californica produce two polypeptide species that comigrate on electrophoretic gels containing sodium dodecyl sulfate. By this separation procedure both species can be assigned a molecular weight of approximately 6,000. One of these molecules has an Rf of 0.65 on alkaline discontinuous electrophoresis gels, an isoelectric point at pH 4.8, a gel filtration molecular weight of approximately 12,000, and has no known biological function. The other does not enter alkaline disk gels, has an isoelectric point at approximately pH 9.3, shows a gel filtration molecular weight consistent with that determined by SDS gel electrophoresis, and is the egg-laying hormone.