A new exchange procedure for the quantitation of prostatic androgen receptor complexes formed in vivo

A procedure is described for the measurement of rat prostatic androgen receptor saturated in vivo with non-radioactive androgen. While NaSCN alone induces irreversible dissociation (denaturation) of androgen from the receptor, the combination of this chaotropic salt (0.15 M) with sucrose (15%) and sodium molybdate (10 mM) allows the exchange of R DHT with [3H]DHT at 0 degrees C with only minimal receptor denaturation. The validity of the present exchange assay is based on the following: a similar quantity of androgen receptor was detected when binding was measured directly after in vivo treatment with radioactive androgen or indirectly by [3H]DHT exchange after treatment with non-radioactive androgen. Steroid specificity, sedimentation analysis and equilibrium association constants indicated that this exchange assay labels the androgen receptor without interference from other prostatic steroid binding proteins. With this method it is now possible to quantitate not only prostatic androgen receptors bound to androgens in vitro but also hormone-receptor complexes formed in intact animals under the influence of endogenous androgen.     

Ribonucleic acid association with androgen receptor from rat submandibular gland

The transformed androgen receptor from rat submandibular gland converts to a faster sedimenting form (6-8S) on a glycerol gradient centrifugation after withdrawal of a transformation-inducing reagent (KCl or ATP). In this report, the association of cytosolic RNA with the transformed androgen receptor was investigated as a possible mechanism of molecular conversion of the androgen receptor. When the transformed and converted androgen receptors were treated with RNase A, these receptors sedimented at 4.5S in a low-salt glycerol gradient. Addition of RNA from rat submandibular gland to the RNase-Sepharose-treated transformed receptor caused a shift of receptor peak from 4.5S to 5.8S. RNA from rat submandibular gland, yeast RNA and E. coli rRNA inhibited DNA-cellulose binding of a RNase-treated transformed receptor in the absence of molybdate. These observations suggest that conversion from the transformed 4S androgen receptor to a 6-8S form resulted from the association of RNA(s) with the transformed receptor.     

4-Alkyl- and 3,4-dialkyl-1,2,3,4-tetrahydro-8-pyridono[5,6-g]quinolines: potent, nonsteroidal androgen receptor agonists.

A series of human androgen receptor (hAR) agonists based on 4-alkyl-; 4,4-dialkyl-; and 3,4-dialkyl-1,2,3,4-tetrahydro-8-pyridono[5,6-g]quinoline was synthesized and evaluated in competitive receptor binding assays and an androgen receptor cotransfection assay in a mammalian cell background. A number of compounds in this series demonstrated activity equal to or better than dihydrotestosterone in both assays and represent a novel class of compounds for use in androgen replacement therapy.     

Discovery of an androgen receptor modulator pharmacophore based on 2-quinolinones

A series of alkylamino-2-quinolinone compounds (3) was discovered as androgen receptor modulators based on an early linear tricyclic quinoline pharmacophore (1). The series demonstrated selective high binding affinity to androgen receptor and potent receptor modulating activities in the cotransfection assays.     

Characterization of androgen receptors after photoaffinity labelling with [3H]methyltrienolone (R1881)

The synthetic androgen 17 beta-hydroxy-17 alpha-[3H]methyl-4,9,11-estratrien-3-one (R1881) has been used as photoaffinity label to characterize androgen receptors in rat prostate, in a human transplantable prostatic adenocarcinoma (PC-82) and in calf uterus. Androgen receptors preparations were partially purified either via differential chromatography on 2',5'-ADP-Sepharose (rat prostate), via anion exchange fast protein liquid chromatography (rat prostate and PC-82) or via DNA-cellulose chromatography (calf uterus). Purification factors obtained with the three different methods were: 245, 75 and 40 respectively. Photolabelling of receptor preparations was performed via irradiation with a high pressure mercury lamp either before or after partial purification. Polyacrylamide gel electrophoresis under denaturing conditions showed that the DNA-binding form of the androgen receptor in calf uterus cytosol is a protein with a molecular mass of approx 95 kD. The covalent attachment of [3H]R1881 to the 95 kD protein could be completely suppressed by a 200-fold molar excess of dihydrotestosterone. In rat prostate cytosol an androgen receptor with a molecular mass of approx 50 kD could be photoaffinity labelled with R1881. A similar size was found for the androgen receptor in the human prostatic adenocarcinoma. Our results show that photoaffinity labelling of androgen receptors with [3H]R1881 as ligand can be applied for characterization of partial purified androgen receptor preparations.     

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.     

Identification of an androgen receptor in the adult chicken oviduct

The chicken oviduct androgen receptor was characterized by sucrose density gradient centrifugation, Scatchard analysis, competition studies, and affinity labeled with dihydrotestosterone 17 beta-bromoacetate. A specific 8.5 S peak was seen on 0.01 M KCl sucrose density gradients when the receptor was labeled with [3H]5 alpha-dihydrotestosterone. Specific 4.6 S peaks were seen when receptor labeled with [3H]5 alpha-dihydrotestosterone or [3H]dihydrotestosterone 17 beta-bromoacetate was analyzed on 0.3 M KCl sucrose density gradients. Scatchard analysis of [3H]5 alpha-dihydrotestosterone binding by oviduct cytosol was consistent with two binding sites. A Kd of 0.13 nM was found for the high affinity androgen receptor. Competition studies showed the following order of ligand affinity: 5 alpha-dihydrotestosterone greater than dihydrotestosterone 17 beta-bromoacetate greater than progesterone greater than estradiol. A 61.2 kDa protein was specifically covalently labeled with [3H]dihydrotestosterone 17 beta-bromoacetate. The chicken oviduct androgen receptor possesses characteristics similar to other androgen receptors, and provides a good source of androgen receptor for physicochemical studies of the native receptor protein.     

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

In the present study, culf 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.     

Androgens on the estrogen receptor II — correlation between nuclear translocation and uterine protein synthesis

In the immature rat uterus, occupation of the androgen and estrogen receptor sites after injection of 5 α dihydrotestosterone (DHT = 17β-hydroxy-5α-androstan-3-one) were compared to the biological responses induced by the androgen on protein synthesis. Injection of 100 μg DHT induced a maximal occupation of androgen receptor sites (RA) but was totally ineffective in translocating the estrogen receptor sites and in increasing general protein synthesis. Conversely, high doses of androgen (? 3 mg) translocated the estrogen receptor (RE) and stimulated general protein synthesis. In addition, these high doses induced a specific uterine protein undistinguishable from that induced by estradiol treatment (IP). These results strongly suggest that the uterotrophic response of the uterus to androgen is correlated with the nuclear translocation of the estrogen receptor and not with that of the androgen receptor which is present in much smaller amounts.     

Intracellular inhibition of chromatin binding and transformation of androgen receptor by 3'-deoxyadenosine

Incubation of minced rat ventral prostate with 3'-deoxyadenosine (3'-dA) prior to labeling with the androgen, tritiated 7 alpha, 17 alpha-dimethyl-19-nortestosterone, reduced the level of androgen receptor bound to chromatin and increased the level of cytosolic androgen receptor and the fraction of cytosolic androgen receptor that did not bind to DNA. This effect was specific for 3'-dA and not mimicked by adenosine, 2'-deoxy-adenosine, cytidine, guanosine, or uridine. Adenosine was a competitive inhibitor of the 3'-dA effect. Labeled cytosolic androgen receptor from 3'-dA-treated prostate had properties that were similar to those exhibited by untransformed androgen receptor from prostate cytosol prepared in the presence of Na2MoO4, an inhibitor of receptor transformation in cell-free systems. Both androgen receptors had sedimentation coefficients of 8-9 S in low-salt gradients, did not bind to DNA tightly, and had a high affinity for DEAE-cellulose. The 3'-dA effect on these properties was not observed if androgen receptor from 3'-dA-treated prostate was isolated on high-salt gradients. These findings show that androgen receptor transformation does take place in intact prostate cells and suggest that 3'-dA inhibits chromatin binding of androgen receptor by interfering with androgen receptor transformation. The transformation process appears to involve removal of components from androgen receptor. Since 3'-dA is a potent inhibitor of the synthesis, polyadenylation, and nucleocytoplasmic transport of RNA, the 3'-dA effect may indicate a role for RNA in the mechanism of receptor transformation in intact target cells.     

Hormone-induced dissociation of the androgen receptor-heat-shock protein complex: use of a new monoclonal antibody to distinguish transformed from nontransformed receptors.

The hormone-induced transformation process of the androgen receptor in the androgen-responsive human prostatic carcinoma cell line LNCaP was studied. Immunoprecipitation of the nontransformed cytosolic receptor (8S on sucrose gradients) with a specific monoclonal antibody (F39.4.1) resulted in coprecipitation of three heat-shock proteins (hsp90, hsp70, and hsp56). Upon incubation of the cells with the synthetic androgen R1881, the sedimentation value of the receptor complex decreased to an intermediate form of 6S, and an almost complete loss of coprecipitating heat-shock proteins was observed. After a 2-h incubation, the receptor was recovered in considerable part from the nuclear fraction (extraction with high salt; 4.6S form). By use of the bifunctional cross-linker dimethyl pimelimidate, dissociation of the 8S complex, but not of the 6S complex, was blocked. A newly developed monoclonal antibody (F52.24.4), directed against the C-terminal part of the DNA-binding domain of the androgen receptor, specifically recognized both the 4.6S and the 6S forms of the receptor but did not react with the nontransformed 8S form. It is concluded that the unoccupied androgen receptor is associated with several heat-shock proteins and that transformation of the receptor to the tight nuclear-binding form is a multistep process that involves the dissociation of heat-shock proteins from the receptor.     

Genital fibroblasts from normal individuals and patients with androgen insensitivity: demonstration of reduced or absent levels of a specific protein (Mr approximately 41K, pI approximately 6) in receptor negative cells

Genital fibroblasts were obtained from normal individuals and from patients with a variety of syndromes of defective androgenization (complete androgen insensitivity, partial androgen insensitivity, microgenitalia, hypospadias, infertility). Cells were labelled with [35S]methionine, and patterns of protein synthesis compared by two-dimensional gel electrophoresis, with isoelectrofocusing electrophoresis gels or non-equilibrated pH gradient electrophoresis (NEPHGE) gels as the first dimension. A protein (mol. wt approximately 41K, pI approximately 6) was found on NEPHGE gels to be reduced or absent in fibroblasts in which androgen receptor levels were abnormal. The protein was unaltered by prior incubation with 1-100 nM dihydrotestosterone for 48 h, and was present in cells both from normal controls, and from patients with abnormal sexual differentiation showing normal androgen receptor levels. The coincidence of low or absent 41K with low or absent androgen receptors suggested the possibility that it may constitute a steroid-binding moiety of the androgen receptor. To test this possibility cytosols from normal foreskins or normal cultured fibroblasts were adsorbed with testosterone-sepharose affinity resin to remove androgen receptors. Cytosols so treated showed levels of 41K on NEPHGE indistinguishable from those in untreated cytosols, or in cytosols treated with underivatized sepharose. We therefore conclude that the 41K protein, while an accurate marker of the presence or absence of androgen receptors over a range of clinical disorders, is neither an androgen-induced protein nor an androgen-binding protein.     

The rat androgen receptor: primary structure, autoregulation of its messenger ribonucleic acid, and immunocytochemical localization of the receptor protein

A composite androgen receptor DNA sequence 4,181 base pairs in length was determined from three cDNA clones isolated from a rat epididymal bacteriophage lambda gt11 library. An open reading frame of 902 amino acids encodes a protein of 98,227 mol wt. Structural domains characteristic of the steroid receptor family include an amino-terminal region with five repeated amino acid motifs, a central DNA-binding domain homologous with other steroid receptors, and a carboxyl-terminal steroid-binding region. A receptor cDNA probe used in Northern blot analysis hybridized with a predominant 10-kilobase androgen receptor mRNA in male reproductive tissues of the rat. Autoregulation of androgen receptor mRNA was indicated in rat ventral prostate by an increase in the level of 10-kilobase mRNA after castration and suppression of receptor mRNA upon androgen restimulation. A 15 amino acid peptide with sequence derived from the deduced androgen receptor sequence was synthesized and used as immunogen in raising receptor antibodies in rabbits. Antisera reacted with high titer against the synthetic peptide by enzyme-linked immunosorbent assay and against the native [3H]dihydrotestosterone-labeled androgen receptor as evidenced by an increase in receptor sedimentation rate determined by sucrose gradient centrifugation. Immunocytochemical staining localized the androgen receptor to epithelial cell nuclei in rat ventral prostate.     

Clinical and genetic characterization of complete androgen insensitivity syndrome in a Chinese family

We studied a family with two cousins who were diagnosed with complete androgen insensitivity syndrome, an X-linked disorder caused by mutations in the androgen receptor gene. A pedigree analysis and a molecular study using PCR and DNA sequencing clarified each female family member's androgen receptor status and revealed a mutation consisting of the deletion of exon 2 and surrounding introns of the androgen receptor gene. Based on the relative nucleotide positions, we concluded that the deletion mutation in exon 2 and its surrounding introns was approximately 6000 to 7000 bp. This mutation, never previously fully characterized using DNA sequencing, was responsible for complete androgen insensitivity syndrome in this family. Pedigree analysis with a molecular study of the androgen receptor gene in affected families facilitates genetic counseling provided to family members.     

Partial purification of androgen receptor from hypertrophic human prostate

For purification of androgen receptor from hypertrophic human prostate, solutions used for elution of androgen receptor from DNA Sepharose, affinity labeling of the receptor and ability of affinity gel to retain the receptor were examined. Elution with 20 mM pyridoxal 5'-phosphate of the receptor from DNA Sepharose was more efficient than that with diluted pyridoxal 5'-phosphate, high ionic solution or various concentrations of Mg++, 3H-dihydrotestosterone bromoacetate was applicable to covalent binding with partially purified androgen receptor regardless of the low specificity of the ligand. Affinity gel of thiopropyl-Sepharose 6B coupled to 17 alpha-(2', 3'-epoxy-propyl)-5 alpha-dihydrotestosterone was better than Affigel 102 coupled to N-[3-(3-oxo-5 alpha-androstane-17 beta-yloxycarbonyl) propionyloxy] succimide or aminoethyl-Sepharose 4B coupled to 17 alpha-carboxyethynyl testosterone with respect to the rate of retention of androgen receptor. In view of these observations, the following purification procedures were constructed: Removal of DNA Sepharose-binders from the cytosol, 40% ammonium sulfate precipitation, affinity chromatography using thiopropyl-Sepharose 6B coupled to 17 alpha-(2',3'-epoxypropyl)-5 alpha-dihydrotestosterone, and DNA Sepharose chromatography. After affinity labeling of the receptor thus obtained, the molecular weight was estimated. Some 1300-fold purification with a yield of 0.25% of the androgen receptor was achieved. The molecular weight of the receptor was mainly 45 K with 90 K in a lesser amount. The Stokes radius was calculated as 30 A.     

Castration induced changes in dog prostate gland associated with diminished activin and activin receptor expression

This study was conducted to evaluate the effect of androgen ablation on dog prostate gland structure and the proliferation capacity of the prostatic cells and their association with the expression of Activin A and Activin RIIA receptor. The effect of androgen on the prostate gland was compared in intact and castrated dogs after one and two weeks. Specific primary antibodies were used to immunolocalize activin-A, activin receptor type II A and the proliferation marker (PCNA). The results showed that the glandular acini of the prostate gland of intact dogs are lined by tall columnar secretory cells and less abundant flattened basal cells and surrounded by a thin fibromuscular tissue. The cytoplasm of the glandular cells exhibited an intense immunoreaction for activin A and activin RIIA receptor while basal cells expressed PCNA. Castration induced a remarkable atrophy of the prostatic acini associated with a progressive loss of secretory epithelial cells, which showed a dramatic decrease to complete disappearance of Activin A and Activin RIIA receptor immunoreactions. The remaining cells of the atrophied acini continue to express PCNA and the inter-acinar fibromuscular tissue showed a remarkable increase in its mass and are induced to express PCNA. These results indicated that androgen is required for the survival of epithelial cells and to maintain growth-quiescent fibromuscular cells, while basal cell proliferation is androgen independent. The changes in the Activin A and Activin RIIA receptor localization and their association with the dynamic pattern of prostate gland regression after castration suggested that Activin A and Activin RIIA receptor expression are androgen dependent.