Interaction of androgen receptors with chromatin and DNA

The methyltrienolone binding protein of JEG-3 cells and human placenta is localized within the nucleus and is tightly associated with chromatin

Human placenta contains the methyltrienolone binding protein (MTBP), an androgen binding protein which is distinct from the androgen receptor. This study demonstrates that the human choriocarcinoma cell line (JEG-3) also contains the MTBP and that in both human placenta and JEG-3 cells the MTBP is located exclusively in the nucleus and in particular is associated with DNase 1 resistant chromatin.

Sequence-specific binding of androgen-receptor complexes to prostatic binding protein genes

Prostatic binding protein is a complex glycoprotein comprising three components, C1, C2 and C3, organized into two different heterodimers (C1-C3 and C2-C3). The rat ventral prostate genes encoding all three constituent polypeptides are expressed under androgenic control. Analysis of genomic fragments containing the genes and flanking sequences revealed in each case one androgen receptor-binding region upstream of or within the promoter and another in the first intron. The effect of androgens on the expression of these genes may, therefore, be mediated by these direct receptor-DNA interactions. The genomic fragments which contain androgen receptor-binding regions all contain nucleotide sequences reminiscent of glucocorticoid response elements (GRE). Mutations in these sequences in restriction fragments and in synthetic oligonucleotides significantly decreased their affinity for androgen-receptor complexes and their introduction into nonspecific sequences conferred affinity for androgen-receptor complexes. Based on these data, a consensus sequence for putative androgen response elements (ARE) is proposed. However, despite the specific recognition of these sequences by the androgen receptor in vitro, only the C3(1) intronic fragment could confer significant androgen responsiveness on a heterologous promoter. While this could be due to the fact that the GRE-like sequences present in the other fragments are not strong AREs, alternative hypotheses are being investigated currently. Not least of these is that the similar localization of the binding sites in each gene might underlie a more complex androgen regulation mechanism.

Mechanism of androgen action: recent observations on the domain structure of androgen receptors and the induction of EGF-receptors by androgens in prostate tumor cells

In this paper two different aspects of androgen action are reviewed. Polyacrylamide gel electrophoresis of androgen receptors, photoaffinity labeled with R1881 showed that receptors isolated from both human prostate cells and calf uterine cytosol cells are proteins with a molecular mass of approx 110 kD. Purification to homogeneity of this form of the receptor from calf uterus also yielded a 110 kD protein. A molecular model for the DNA-binding form of the receptor is presented in which one polypeptide comprises three active domains: one for ligand binding, one for interaction with nuclear acceptor sites, and a third domain which modulates nuclear interaction. Mild digestion with chymotrypsin or a protease from rat prostates removes the modulating domain and leaves the ligand binding and nuclear interaction domain intact. Trypsin treatment yields a fragment of lower molecular mass containing the ligand binding domain with some affinity for RNA, but not DNA. In vitro studies with a human prostate tumor cell line (LNCaP), suggest that androgens not only directly effect cell growth, but also act indirectly. Both epidermal growth factor (EGF) and androgens stimulate cell growth. In addition androgens stimulate synthesis of receptors for EGF. Thus androgens effect tumor cell growth by autocrine or paracrine mechanisms by making the cells more sensitive for growth factor mediated stimuli.

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.

Tissue renin-angiotensin systems aspects of molecular biology and pharmacology

Advances in molecular biology over the last few years have made it possible to extend studies concerned with the role of renin in blood pressure regulation and fluid balance to the genetic level. Epidemiological data from cross-sectional population studies as well as experimental findings in spontaneously hypertensive rats suggest a greater disposition towards hypertension in males than in females. Testosterone (T) is known to raise blood pressure in female and castrated male SH-rats, while concomitantly increasing tissue renin activities. The availability of recombinant DNA technology and of a 32P labeled mouse submandibular gland renin cRNA as a hybridization probe enabled us to quantitatively assess whether this increase is paralleled by enhanced renin gene expression. In groups of female NMRI mice injected with DHT, we were able to show, that cardiac renin activity was significantly increased after 2 hours (1.6 fold) and 21 days (1.9 fold) of dihydrotestosterone (DHT) treatment compared to controls. DHT had no effect on renin mRNA concentration in the uterus, whereas in the ovary it resulted in a 50% decrease. We conclude that enhanced renin-activity and mRNA levels in peripheral organs and in the central nervous system are due to direct or indirect effects (cis, transacting) of T on renin gene expression. Thus, T may participate in the development of hypertension by stimulating the activity of tissue renin-angiotensin systems.

Androgen receptor-binding regions of an androgen-responsive gene

The interaction of 5 alpha-dihydrotestosterone-receptor complexes with purified DNA fragments representing upstream, coding and intervening sequences of the prostate binding protein C3(1) gene was investigated using a DNA-cellulose competition binding assay. The partially purified androgen-receptor complexes which were used in the assay had proven DNA-binding capabilities. Two fragments were identified with relatively high affinity for androgen-receptor complexes. A 300 bp fragment extending from -220 to +80 and a 500 bp fragment derived entirely from the first intron consistently competed most effectively in the system. The presence of a high affinity site or sites in or near the promoter region of the gene is consistent with current models of transcriptional activation of hormone-responsive genes by steroid receptors. High affinity sites for steroid receptors within introns may indicate a role for receptors in regulation of transcription at other stages, or in post-transcriptional modification.

Correlations between prostate chromatin structure and transcriptional activity and acceptor site distribution

Androgen-receptor complexes are intimately involved in the maintenance of rat ventral prostate chromatin in a transcriptionally active structure. The presence or absence of androgens influenced the quantity of transcriptionally active chromatin and the distribution of acceptor sites for androgen-receptor complexes as probed by endonucleolytic cleavage. After castration, changes in the sedimentation rates of nucleosome oligomers were consistent with the absence of androgen-receptor complexes and elongating polyribonucleotide chains. These changes were accompanied by decreases in the ability of chromatin released under conditions of minimal nuclease digestion to bind androgen-receptor complexes and to support incorporation of RNA precursors responsive to androgenic stimulation. Saturation analyses of chromatin and nuclear fractions with partially purified androgen-receptor complexes revealed two affinity classes of acceptor sites. After castration, alterations in the intrachromatin distribution of acceptor sites were consistent with their redeployment into areas of decreased nuclease sensitivity, as previously shown for androgen-responsive genes.