Immunological similarity between the chick oviduct progesterone receptor forms A and B

Steroid hormone receptors

In the three decades since the original discovery of receptors for steroid hormones, much has been learned about the biochemical processes by which these regulatory agents exert their effects in target tissues. The intracellular receptor proteins are potential transcription factors, needed for optimal gene expression in hormone-dependent cells. They are present in an inactive form until association with the hormone converts them to a functional state that can react with target genes. Transformation of the receptor protein to the nuclear binding form appears to involve the removal of both macromolecular and micromolecular factors that act to keep the receptor form reacting with DNA. Much of the native receptor is present in the nucleus, loosely bound and readily extractable, but for some and possibly all steroid hormones, some receptor is in the cytoplasm, perhaps in equilibrium with a nuclear pool. Methods have been developed for the stabilization, purification, and characterization of receptor proteins, and through cloning and sequencing of their cDNAs, primary structures for these receptors are now known. This has led to the recognition of structural similarities among the family of receptors for the different steroid hormones and to the identification of regions in the protein molecule responsible for the various aspects of their function. Monoclonal antibodies recognizing specific molecular domains are available for most receptors. Despite the knowledge that has been acquired, many important questions remain unsolved. How does association with the steroid remove factors keeping the receptor protein in its native state, and how does binding of the transformed receptor to the response element in the promoter region enhance gene transcription? Once it has converted the receptor to the nuclear binding state, is there a further role for the steroid in modulating transcription? Still not entirely clear is the involvement of phosphorylation and/or dephosphorylation in hormone binding, receptor transformation, and transcriptional activation. Less vital to basic understanding but important in the overall picture is whether the native receptors for gonadal hormones are entirely confined to the nucleus or whether there is an intracellular distribution equilibrium. With the effort now being devoted to this field, and with the application of new experimental techniques, especially those of molecular biology, our understanding of receptor function is progressing rapidly. The precise mechanism of steroid hormone action should soon be completely established.

[3H]DU41165: a high affinity ligand and novel photoaffinity labeling reagent for the progesterone receptor

17 alpha-Acetoxy-6-fluoro-16-methylene-(9 beta, 10 alpha)pregna-4,6-dien- 3,20-dione (DU41165), a retroprogestin (9 beta, 10 alpha) embodying a fluorine-substituted dienone system, has been prepared in high specific activity tritium-labeled form (4 Ci/mmol) and shown to be a high affinity ligand for the progesterone receptor (PgR) and a highly selective photoaffinity labeling reagent for PgR. The radiosynthesis involved conversion of DU41231 (the 17 alpha-hydroxy analog of DU41165) to DU41165 by treatment with tritium-labeled acetic anhydride. The binding affinity of DU41165 for PgR was determined by both a competitive binding assay and a direct binding assay (Scatchard analysis) to be 1.6-2.2-times higher than that of the high affinity synthetic progestin promegestone (R5020). In unlabeled form, DU41165 demonstrates photoinactivation of PgR to the extent of 60% at 60 min. In radiolabeled form [3H]DU41165 demonstrates specific covalent attachment with an efficiency of 5-7%. SDS-polyacrylamide gel electrophoresis of photoattached [3H]DU41165 confirms that there is covalent labeling of both the B subunit (Mr = 118,000), and the A subunit (Mr = 88,000) of PgR in a molar ratio of approximately 1:3.

Two progesterone receptors in the oviduct of the freshwater turtle Chrysemys picta: possible homology to mammalian and avian progesterone receptor systems

Two progesterone receptors in the oviduct of the freshwater turtle Chrysemys picta: possible homology to mammalian and avian receptor systems. Here we report the characterization of two specific progesterone receptors in nuclear extracts of the turtle oviduct. The receptors differ in dissociation constants (2.8 nM vs 27 nM) which can be separated on DEAE-Sepharose, the former eluting at 0.08 M KCl and the latter at 0.20 M KCl. [3H]R5020 photoaffinity labeling SDS-PAGE revealed that the 2.8 nM moiety migrates with an apparent molecular weight of 80 +/- 5 kDa and the 27 nM moiety migrates with an apparent molecular weight of 120 +/- 5 kDa. These receptors are termed PR-A and PR-B due to their molecular mass and elution profiles. DNA-cellulose chromatographic studies show that both bind DNA-cellulose with the PR-A eluting at 0.09 M NaCl and PR-B eluting between 0.20-0.21 M NaCl. In reproductively inactive turtles (from the months of January and February) estradiol is undetectable, and PR-B is absent as determined by Scatchard analysis, [3H]R5020 photoaffinity labeling electrophoretic studies and DEAE-Sepharose and DNA-cellulose chromatography. In these animals PR-B can be replenished by estrogen treatment, suggesting a physiological role for both PR-A and PR-B and dependence of PR-B on estradiol.

Biochemical characterization and subunit structure of quail oviduct progesterone receptor

The cytosolic quail oviduct progesterone receptor (PR) was studied under conditions that lead either to its stabilization or activation. Sedimentation coefficients and Stokes radii were respectively 7.8 +/- 0.2 S and 7.6 +/- 0.8 nm for the non transformed receptor (8S PR) and 3.9 +/- 0.4S and 4.8 +/- 0.6 nm for the transformed receptor (4S PR). The calculated molecular weight was 261 +/- 29 KDa for the 8S PR and 83 +/- 10 KDa for the 4S PR. Density gradient centrifugation analyses showed that the monoclonal antibody BF4, directed against the 90 KDa hsp of the chick oviduct, cross-reacted with the quail 8S PR but not with the 4S PR. In contrast, polyclonal IgG-G6 antibodies, raised against the purified non transformed chick PR, cross-reacted with the non transformed as well as the transformed quail PR. The quail 8S PR was partially purified using NADAc-Sepharose affinity chromatography and DEAE-Sephacel chromatography from cytosol prepared with protease inhibitors. The subunit structure of the purified quail and chick 8S PR were compared using SDS-PAGE, photoaffinity labeling and western immunoblotting. The quail PR was composed of two different proteins: a non-hormone binding protein (Mr approximately 90 KDa) which exhibited the same properties as the 90 KDa hsp protein of the chick oviduct and a single hormone binding subunit (Mr approximately 101 KDa). Based on its binding and immunological properties, this protein corresponded to the "B" form of the chick PR but was significantly smaller. In the quail cytosol or in purified PR preparations the "A" form of the PR was virtually absent; this observation is discussed.

Human progesterone A-receptors can be synthesized intracellularly and are biologically functional

In order to investigate the origin and functional independence of the human progesterone receptor A binding protein, we have expressed a truncated human progesterone receptor cDNA in both gene transfer and in vitro translation assays. Proteins identical in size and antigenicity to the A-receptors found naturally in human progesterone target cells are synthesized from this cDNA that lacks the putative B receptor initiator methionine codon of the complete cDNA. The functional independence of A-receptors is suggested by their ability to bind hormone and to stimulate transcription from the progestin responsive mouse mammary tumor virus promoter.

Molecular interactions of steroid hormone receptor with its enhancer element: evidence for receptor dimer formation

A steroid hormone responsive element (GRE/PRE), sufficient to confer glucocorticoid and progesterone inducibility when linked to a reporter gene, was used in band-shift assays to examine its molecular interactions with steroid hormone receptors. Both progesterone and glucocorticoid receptors bound directly and specifically to the GRE/PRE. The purine contact sites for both form A and form B chicken progesterone receptor, as well as those for rat glucocorticoid receptor, are identical. A peptide fragment produced in bacteria that primarily contain the DNA binding domain of the glucocorticoid receptor binds first to the TGTTCT half-site of the GRE/PRE, and a second molecule binds subsequently to the TGTACA (half-site) of the GRE/PRE in a cooperative manner. Utilizing the peptide fragment and the protein A-linked fragment, we demonstrated that the receptor interacts with its cognate enhancer as a dimer.

Purification, monoclonal antibody production and structural analyses of human progesterone receptors

Progesterone receptors (PR) from human breast cancer cells have been purified, and used as antigens to generate anti-PR monoclonal antibodies. Immunologic and in situ photoaffinity labeling methods were then used to study receptor structure, and we conclude that native human PR consist of two independent 8S receptors: one 8S subtype contains B-proteins (120,000 kDa) and the other contains A-proteins (94,000 kDa).

Purification of the intact monomeric 110 kDa form of the androgen receptor from calf uterus to near homogeneity

In the present study, calf uterine tissue has been used for isolation of androgen receptors. This tissue appeared to be a favourable source for large-scale purification of androgen receptors, because of the relatively high level of androgen receptors and the low concentration of proteolytic enzymes. The purification involved differential phosphocellulose and DNA affinity chromatography as first steps. The non-transformed receptor was passed through these matrices in order to remove contaminating DNA-binding proteins. After a transformation step to the DNA-binding state, the receptor was bound to DNA cellulose and subsequently eluted with MgCl2. A 0.5% pure androgen receptor preparation was obtained. Photoaffinity labelling with [3H]R1881 (methyltrienolone) was used to determine the size of the receptor at this stage of purification and during the following steps. Subsequently, isoelectric focussing of the partially purified androgen receptor preparation in an aqueous glycerol gradient was performed. In this step, the progesterone receptor, which is copurified with the androgen receptor protein during the first part of the purification procedure, focussed at pH 5.5 while the androgen receptor could be isolated at pH 5.8. The isoelectric focussing procedure could be applied in a preparative way for further purification of androgen receptors. After this step an approx. 8% pure preparation was obtained. Polyacrylamide gel electrophoresis of S-carboxymethylated androgen receptor was used as the final purification step. The [3H]methyltrienolone labelled androgen receptor from calf uterus was purified to homogeneity and consisted of one polypeptide with a molecular mass of 110 kDa.

Rat antibodies as probes for the characterization of progesterone receptor A and B proteins from laying hen oviduct cytosol

The chicken oviduct contains two different hormone binding forms of the progesterone receptor, A and B. We have prepared rat antisera against both forms of the receptor partially purified from laying hen oviduct. The anti-progesterone receptor A antiserum reacts with both receptor forms on Western blots, while the anti-progesterone receptor B antiserum reacts mainly with the B form. Both antisera also react with the native progesterone receptor proteins as shown by sedimentation analysis of the antibody-receptor complexes. Receptors A and B are recognized on Western blots of total protein from dissolved tissue, indicating that both forms are likely to be physiological components. Epitope mapping experiments show that immunogenicity of both receptor molecules is restricted to structurally related protein domains of 28 kDa in receptor A and of 52 kDa in receptor B.

Peptide sequencing of the chick oviduct progesterone receptor form B

The progesterone receptor form B has been isolated to apparent homogeneity from large scale preparations of laying hen oviduct cytosol. The quantities obtained were sufficient to monitor the separation of tryptic peptides on HPLC columns. Using a multi-dimensional microbore HPLC peptide purification protocol, several peptides were isolated in homogeneous form and sequenced up to 34 steps at the sub-40 pmol level using a gas phase sequenator. One of the peptides showed a striking homology with sequences of the putative steroid binding domain of the human glucocorticoid receptor; this region is also conserved in the human and chick estrogen receptor.

Evolving concepts in the mechanism of steroid action: current developments

The mechanisms of steroid action remain a poorly understood enigma. Although much effort has focused on the steroid receptor as a mediator of the steroid's effect in the cell, we are only beginning to understand the structure of steroid receptors. Development of monoclonal antibodies directed against both the steroid-binding "receptors" and receptor-associated proteins has allowed novel approaches to the problem. They were important in determining the nucleotide sequences of several receptor genes and subsequently the amino acid sequence of three receptors. Surprisingly, receptors contain amino acid sequences common to v-erb-A, a potentiator of oncogenic transformation. Two receptor-associated proteins have been found and their relationship to the receptors suggests the possibility of additional functions of receptors in addition to binding deoxyribonucleic acid. Thus the role of the receptor in the mechanism of steroid action is evolving from the "two-step mechanism" to one that includes the recently discovered receptor-associated proteins.

From the structure of steroid receptors to their assessment by immunocytochemistry in target cells

Immunohistochemical studies with antibodies to steroid hormone receptors provide new insight in the mechanism of action of steroid hormones. Immunologically reactive estrogen and progesterone receptors are found exclusively in cell nuclei of target cells even in the absence of the hormonal ligand. A hormonal treatment inducing receptor transformation and "translocation" to the nucleus does not modify the intracellular distribution of the receptor. This result is in contradiction with most biochemical studies which show a displacement of receptor from the cytosolic fraction to the nuclear fraction after hormone-receptor complex formation. We propose that different affinity levels of the non-transformed and hormone-complexed receptor molecules for nuclear structure produce unequal losses of nuclear receptor during homogenization. A lesser loss appears as an increase in nuclear binding sites or immunologically reactive receptor. The glucocorticosteroid receptor differs from the others in that it shows an increase of nuclear immunoreactive receptor after hormone administration. This result was accepted as evidence for a nuclear translocation in the sense initially proposed for all steroid hormones. Alternatively, one may propose another explanation based on the same experimental artefact as invoked for the estrogen and progesterone cytosol receptors. A higher affinity of the hormone-complexed receptor entails a lesser loss from the nucleus during tissue processing, and consequently an apparent increase in nuclear staining. Such a possibility is currently tested in parallel with the progesterone receptor.

The structure and function of progesterone receptors in breast cancer

This paper is a review of the clinical role of progesterone receptors (PR) in the management of breast cancer, and the use of synthetic progestins in treatment of the metastatic disease. Also reviewed are our basic molecular studies dealing with the structure of human breast cancer PR, focusing on the two hormone binding proteins (the A- and B-receptors) and the role of phosphorylation. A model for the structure of PR and their subcellular compartmentalization following hormone treatment is presented.

Effect of photoaffinity labeling on rabbit uterine progesterone receptor

Photoaffinity labeling with [17 alpha-methyl-3H]promegestone ([ 3H]R5020) is an effective technique for the covalent labeling of the progesterone receptor (PR), which allows monitoring of the steroid receptor complex under denaturing conditions. The present study was initiated to evaluate whether photolabeled PR could be used also as a marker for PR under nondenaturing conditions. Accordingly, the effect of irradiation on each component of the reaction was evaluated separately. When [3H]R5020 alone was irradiated, there was a rapid (less than 5 min), light dependent destruction of [3H]R5020, as evident from increased formation of a more polar tritiated product on TLC and a concomitant decrease in the ability of the irradiated preparation to bind to PR. When rabbit uterine PR was irradiated in the absence of steroid, a gradual decrease in the binding capacity was observed, reaching 70% of the nonirradiated control in 10 min. The optimal irradiation time for covalent [3H]R5020-PR complex formation was determined by irradiation for up to 5 min, and separation of the products by sodium dodecylsulfate (SDS)-polyacrylamide gel electrophoresis. Specific labeling of proteins of Mr 116,000 and 85,000 was observed, with the rate of labeling of the two being similar, and reaching a plateau by 4 min of irradiation. The photolabeling efficiency ranged from 2 to 12%. Sucrose gradient ultracentrifugation of photolabeled PR revealed that both the irradiated sample and the nonirradiated control sedimented to the same position. Subsequent SDS-polyacrylamide gel electrophoresis of the sucrose gradient peak from the photolabeled sample showed the presence of both labeled proteins of Mr 116,000 and 85,000. In addition, photolabeled rabbit uterine PR (Mr 116,000 and 85,000) could be immunoprecipitated with a guinea pig antiserum raised against rabbit uterine PR. Analysis of the photoaffinity labeling procedure in our system revealed that the photodestruction of [3H]R5020 was very rapid. However, maximal labeling with [3H]R5020 was obtainable with minimal photodestruction of PR which suggests that photolabeled receptor can be used as a marker for PR under nondenaturing conditions.

Affinity labelling of steroid hormone receptors

Affinity labelling techniques have proved indispensable for the study of reversible biological recognition systems, since they conserve ligand-receptor interaction by covalent linkage. Using photo- and electrophilic labelling, it has become possible to unequivocally identify steroid hormone receptors and their proteolytic degradation products and it is simple to establish receptor peptide maps even in crude receptor preparations. The isolation of receptor proteins has been greatly simplified, as their integrity can be analyzed at any step of a purification protocol by SDS-PAGE analysis after crosslinking. Moreover, affinity-labelled receptors can be purified under denaturing conditions, e.g., in high-resolving preparative SDS-PAGE, and the material obtained can be efficiently used to generate anti-receptor antibodies. Peptide mapping after crosslinking of related receptors has been used to assess the degree of structural homology between different forms of steroid hormone receptors and receptors of different species. Peptide sequence analysis of purified crosslinked receptor protein and anti-receptor antibodies have provided the basis for cloning corresponding genes. Techniques have been established to demonstrate--via crosslinking--that the cloned DNA sequences correspond to the receptor gene binding the correct ligand. The analytical and preparative crosslinking methods developed for steroid receptors are potentially important for the study of any system in which signal transduction proceeds via the reversible interaction between biological macromolecules.

Hormone-dependent covalent modification and processing of human progesterone receptors in the nucleus

In situ photoaffinity labeling, which minimizes in vitro incubations and proteolytic artifacts, was used to study the structure of progesterone receptors (PR) in intact T47D human breast cancer cells. These cells, rich in PR, were incubated with the photoreactive progestin [3H]R5020 at 0 degrees C for 3 hr to keep PR in their untransformed state, or at 37 degrees C for 5 min to transform PR and convert them to tight chromatin-binding proteins. The cells, still intact, were then irradiated with 300-nm UV light to link the hormone covalently to receptors at any intracellular location. In T47D cells, untransformed PR, as well as transformed nuclear-bound PR, have equimolar amounts of proteins A (Mr approximately 94,000) and B (Mr approximately 120,000). The quantitative relationship between these is stable--no degradation of B to A is seen even if in situ photolabeled receptors are incubated in vitro at 37 degrees C for as long as 1 hr. Analysis of the in situ labeled receptors on gradient NaDodSO4-polyacrylamide gels shows that the untransformed B protein is a doublet of Mr approximately 117,000 and 120,000, while the A protein is a singlet. After R5020 treatment, transformed hormone-receptor complexes rapidly (5 min) translocate to nuclei. During the next 30 min the B protein becomes modified and shifts entirely to the heavier, Mr approximately 120,000 form. Between 30 and 60 min after nuclear binding, the A protein first splits, and then also becomes approximately 3000 daltons heavier. These changes are consistent with asynchronous modification--occurring first in protein B and then in protein A. Four to 8 hr after nuclear residence, receptor "processing" leads to the simultaneous disappearance of both proteins without generation of smaller molecular weight fragments. Peptide mapping shows that proteins A and B are closely related: despite the initial difference in molecular weight of A and B, digestion with Staphylococcus aureus V8 protease yields identical fragmentation patterns for each, with sequential peptides of Mr approximately 49,000, 39,000, 26,000, and 14,000. These data are consistent with the hypothesis that B and A are closely related integral intracellular proteins; that in their untransformed state only B is phosphorylated; that hormone treatment leads to their rapid (5 min) transformation to nuclear and DNA binding states; and that a nuclear phosphoprotein kinase(s) then modifies both proteins further to influence their gene regulatory activities.