Selective activation of the probasin androgen-responsive region by steroid hormones.

Glucocorticoid and androgen receptors have been shown to function through the same palindromic glucocorticoid response element (GRE) and yet have differential effects on gene transcription. In this study, we examined the functional and structural relationship of the androgen and glucocorticoid receptors with the androgen responsive region (ARR) of the probasin (PB) gene containing two androgen receptor binding sites, ARBS-1 and ARBS-2. Transfection studies indicated that one copy of each cis-acting DNA element was essential for maximal androgen-induced chloramphenicol acetyltransferase (CAT) activity and that androgen selectivity was maintained when multiple copies of the minimal wild type (wt) androgen responsive region containing both ARBS-1 and ARBS-2 (-244 to -96) were subcloned in front of the thymidine kinase promoter. Furthermore, replacing the androgen response region with 1, 2 or 3 copies of either ARBS-1 or ARBS-2 restored less than 4% of the biological activity seen with the wt PB ARR. Multiple copies of either ARBS-1 or ARBS-2 did not result in glucocorticoid-induced CAT gene activity. By comparison, 1 or 2 copies of the tyrosine aminotransferase (TAT) GRE, as well as the mouse mammary tumour virus GRE, were strong inducers of CAT activity in response to both androgen and glucocorticoid treatment. In addition, band shift assays demonstrated that although the synthetic glucocorticoid receptor, GR-DNA binding domain (GR-DBD), and the synthetic androgen receptor, AR2, could interact with the TAT GRE (dissociation constants Kd of 63.9 and 14.1 respectively), only AR2 but not GR-DBD binding could be detected on ARBS-1 and ARBS-2. Our findings provide further evidence that androgen-induced regulation of gene transcription can occur through androgen-specific DNA binding sites that are distinct from the common GRE.

Differential transactivation by the androgen receptor in prostate cancer cells.

BACKGROUND: The purpose of this study was to determine the contribution of different transactivating regions of the androgen receptor (AR) to the induction of androgen-regulated promoters in poorly (PC3 cells) and well-differentiated (LNCaP cells) prostate cancer cell lines. METHODS: PC3 and LNCaP cells were co-transfected with plasmids expressing full-length AR or deletion mutants together with luciferase reporters linked to the probasin (PB) and PSA promoters; as well as to ARR3tk, a PB-derived recombinant promoter. RESULTS: Androgen induction of the ARR3tk promoter in the presence of AR was 8- to 10-fold higher than that seen with the PB promoter. Activation of ARR3tk was greatest with an androgen-independent construct in which the first 231 amino acids and the ligand binding domain had been removed, indicating that this promoter is more responsive to activating functions in the N-terminal domain than in the ligand binding domain. By comparison, induction of the PB promoter was greatest with the full-length AR, which suggests that the ligand binding domain also makes a major contribution to the activation of this promoter. In similar analyses with the PSA promoter, AR regions required for promoter induction was dependent on the host cell type. In PC3 cells, the predominant AR transactivation function was androgen-independent and resided in the N-terminal domain, whereas in LNCaP cells, the highest level of induction was androgen dependent and also required participation of the ligand binding domain. CONCLUSIONS: Our results indicate that the relative utilization of transactivating functions in N-terminal and ligand binding domains of the AR is promoter and cell specific.

Induction of cell-free, in vitro transcription by recombinant androgen receptor peptides.

An in vitro, cell-free transcription system, based on prostate-derived transcriptional machinery and very powerful androgen response elements (AREs), has been developed. Multiple (p(ARR3)LovTATA) AREs from the androgen-regulated probasin gene were linked to G-free cassettes and used in nuclear extracts prepared from prostate carcinoma cell lines (PC3 and LNCaP cells) to test specific induction of transcription by full-length AR and by glutathione-S-transferase (GST)-fusion peptides in which the androgen receptor (AR) DNA-binding domain alone (AR524-649), or together with the ligand-binding domain (AR524-902), or a portion of the NH2-terminal domain (AR232-649) were incorporated. In the presence of AR, nuclear extracts from PC3 cells had greater activity in supporting transcription than those from LNCaP cells; and lower background activity than those from HeLa cells. All of the AR forms correctly initiated in vitro transcription of ARE-templates in an androgen-independent manner. The amount of specific, inducible transcript was dependent on the concentration of AR peptide present. AR524-902 was the most potent transactivator tested, with the maximal level of specific transcript over 900-fold higher than the minimal level. At all concentrations this peptide was three to four times more active than either AR524-649 or AR232-649. In conclusion, we have developed a very specific and sensitive cell-free transcription system for delineating trans-activational regions of the AR.

Control of tumor progression by maintenance of apoptosis.

The ability to induce multiple apoptotic regressions of an androgen-dependent tumor cell population by repeated cycles of androgen withdrawal and replacement may be advantageous in therapeutic strategies aimed at delaying or preventing tumor progression. With greater insight into factors that either initiate or limit apoptosis, more efficient application of intermittent therapy might be achieved, especially if methods could be devised to increase the length or number of treatment cycles. Both calreticulin and clusterin represent proteins with a potential role in the regulation of apoptosis. Calreticulin may inhibit target gene transcription by interacting with steroid hormone receptors, thereby masking their DNA-binding sites and triggering the onset of the apoptotic process. Clusterin, on the other hand, is a membrane-stabilizing protein that appears to be involved in limiting the autophagic lysis of epithelial cells during apoptosis. Also, the increasing tendency for nuclear localization of clusterin after androgen withdrawal may preserve the nuclear environment, limiting the lethal effect of treatment. Thus, tumor progression, characterized by the loss of apoptotic potential, appears to be linked in part to the inappropriate activation of TRPM-2 gene, which accounts for the constitutive expression of clusterin.

Cooperative binding of androgen receptors to two DNA sequences is required for androgen induction of the probasin gene.

The functional and structural interactions of two androgen receptor-binding sites in the 5'-flanking DNA of the rat probasin gene were determined. Deletion mapping and DNase I footprinting analysis had previously identified two androgen receptor-binding sites (ARBS) necessary for androgen induction of the probasin gene: ARBS-1, which resembled a glucocorticoid-responsive element, and ARBS-2, which had a unique sequence. In this study, maximal androgen induction in transient transfection studies only occurred when both sites were present. Neither binding site functioned independently, and deletion of the DNA sequence between the sites resulted in a 60% loss of androgen inducibility. Moreover, point mutations in either ARBS-1 or ARBS-2 led to > 90% loss in activity. Scatchard analysis indicated that ARBS-1 and ARBS-2 bound a synthetic androgen receptor, AR2, with Kd values of 20.0 and 6.7 nM, respectively. Consistent with the higher affinity, ARBS-2 bound AR2 at half the threshold concentration (200 ng) of that required in reciprocal DNase I footprinting experiments with ARBS-1. By comparison, protection occurred at a much lower threshold concentration of AR2 (60 ng) and to the same extent over each site when both sites were present, suggesting a cooperative interaction between the two sites. The cooperative effect was further substantiated when a point mutation in ARBS-1 blocked AR2 binding not only to ARBS-1, but also to ARBS-2. Similarly, a point mutation in ARBS-2 also prevented receptor binding to both sites. Androgen-specific regulation of probasin gene transcription therefore required an androgen-responsive region (positions -286 and +28) containing two androgen receptor-binding sites, where the binding of the androgen receptor to both sites occurred in a cooperative, mutually dependent manner.

Characterization of two cis-acting DNA elements involved in the androgen regulation of the probasin gene.

The location and sequence of androgen responsive elements (AREs) in the 5'-flanking DNA of the androgen-regulated rat probasin (PB) gene were determined. The DNA- and steroid-binding domains of the rat androgen receptor [glutathione-S-transferase (GST)-AR1] and the DNA-binding domain and hinge region alone (GST-AR2) were expressed in Escherichia coli as isopropyl-B-D-thioglactopyranoside-induced fusion proteins with GST and purified using glutathione affinity chromatography. Band shift assays indicated that the AR1 peptide was at least five times more effective than AR2 in binding to PB 5'-flanking DNA (-426 to +28), although both gave qualitatively similar patterns and were displaced by anti-AR antibodies. DNase I footprinting experiments revealed two putative AREs: one between positions -236 and -223 (ARE-1) and the other between -140 and -117 (ARE-2). Hormonal regulation of PB was determined by cotransfecting reporter constructions containing the PB 5'-flanking region (-426 to +28) linked to the bacterial chloramphenicol acetyl transferase (CAT) gene with androgen, glucocorticoid, or progesterone receptor expression vectors into human prostatic carcinoma cells (PC-3). PB-CAT gene expression was more effectively induced by androgens than by glucocorticoids or progestins. Both 5'- and 3'-deletion mapping of the PB 5'-flanking DNA revealed that ARE-1 and ARE-2 were required for androgen regulation. A single base mutation in either ARE resulted in a more than 95% loss of androgen induction of CAT. In comparable transfection experiments, the PB hormone-responsive elements showed a greater induction by androgens than did mouse mammary tumor virus or tyrosine aminotransferase elements. Thus, the preferential androgen regulation of the PB gene involves the participation of two different cis-acting DNA elements that bind AR.

Primary structure and androgen regulation of a 20-kilodalton protein specific to rat ventral prostate.

Nuclear and cytosolic forms of a 20-kdalton rat ventral prostate protein were purified and partially sequenced from their N-termini. Isolated nuclei were treated with micrococcal nuclease and extracted in 0.6 M NaCl, and proteins were separated by affinity chromatography on Matrex gel green A, ammonium sulfate fractionation, and fast protein liquid chromatography on Superose 12. The 43 amino acid N-terminal sequence of the nuclear 20-kdalton protein was identical with the cytosolic protein except it lacked 7 N-terminal amino acids present in the cytosolic form. The DNA sequence of a full-length complementary DNA clone isolated from a ventral prostate gt11 library extended the N-terminal sequence of the cytosolic form by an additional nine amino acids from the predicted initiation methionine. The cDNA included the nucleotide sequence for the 43 amino acid N-terminal sequence of the purified 20-kdalton protein and predicted molecular weights of 16,686, 17,521, and 18,650, respectively, for the nuclear, cytoplasmic, and nonprocessed proteins. Northern blot analyses of reproductive tract tissue RNAs using the 20-kdalton protein cDNA as probe revealed a single mRNA species of 0.92 kb detectable only in extracts of rat ventral prostate. Expression of the 0.92-kb mRNA was androgen dependent since the mRNA was undetectable in extracts obtained 4 days after castration and was restored 16 h after restimulation with androgen.

Involvement of the MN blood group antigen in shear-enhanced hemagglutination induced by the Escherichia coli F41 adhesin.

An adhesin from Escherichia coli F41 with an apparent subunit molecular weight of 28,000 daltons was isolated by using (NH4)2SO4 precipitation at pH 10 and Sephacryl S-500 gel filtration. The hemagglutination (HA) properties of the native high-molecular-weight adhesin were studied by using a viscometric assay, which provided a quantitative index of the degree of agglutination present as a function of time at a known rate of shear. Shear was found to enhance the degree of agglutination over a 20-min period. A strong, shear-enhanced HA was observed for all donors with the MM or MN blood type studied, but those with the NN blood type showed very little HA. In the microtiter HA assay, the selectivity of the adhesin for MM over NN erythrocytes was found to be dependent on pH and temperature. At 21 degrees C and pH 7.4, there was little difference in HA between the two blood types, but NN cells were progressively more weakly agglutinated than MM cells as the pH or the temperature was increased. Glycophorin A, which bears the M or N determinant, was isolated from individuals with the MM and NN blood types and was shown to be an effective inhibitor of the reaction, with the MM type being the more effective in both microtiter and viscometric assays. Acidic monosaccharides, particularly sialic acid, were also effective inhibitors of HA, although they were less potent on a molar basis than glycophorin. The adsorption isotherm of 125I-labeled adhesin was measured, and the binding was shown to be strongly inhibited by MM glycophorin and somewhat less strongly by NN glycophorin. Collectively, these data strongly suggest that glycophorin AM is a receptor for the F41 adhesin.

Chemical demonstration of nuclear androgen receptor following affinity chromatography with immobilized ligands.

With increasing purification of the androgen receptor from nuclei of rat ventral prostate, a receptor-like protein could be demonstrated by chemical staining with silver nitrate. After sonication and digestion of nuclei with micrococcal nuclease, the solubilized receptor was applied to a column of Matrex Gel Green A and eluted with a linear gradient of 0-2 M NaCl. Characterized by specific binding of dihydrotestosterone, this form of the receptor was also androgen dependent and yielded an apparent Mr of 33,000 when analyzed by polyacrylamide gel electrophoresis and silver nitrate staining. To facilitate recovery following chromatography, the receptor was precipitated with 0-40% ammonium sulfate. Analysis of the 15-fold enriched fraction by sucrose density-gradient centrifugation confirmed the presence of a 3S androgen-binding protein. About 200 ng of the precipitated protein was applied to a column of dihydrotestosterone-17 beta-succinyl agarose (ligand concentration, 0.25 mumol/ml). The fractions eluted with 50 microM dihydrotestosterone were electrophoresed and stained as before; again, the presence of a 33,000 Mr protein sensitive to castration was demonstrated. Alternatively, when the precipitated protein was fractionated by fast protein liquid chromatography utilizing a Superose 12 HR 10/30 column, the receptor coeluted with nuclear proteins in the 29,000-36,000 Mr range as determined both by retention time and electrophoresis. In combination, the above methods may be used to obtain a receptor protein purified to near homogeneity with a yield of 5-10%. The amount of receptor afforded by the purification sequence is small but nevertheless sufficient for chemical detection. We anticipate that with modification, the procedures may prove suitable for the recovery of nuclear androgen receptor on a preparative scale.