The mouse androgen receptor. Functional analysis of the protein and characterization of the gene

Tissue control of androgen action: The ups and downs of androgen receptor expression

The hormone testosterone plays crucial roles during male development and puberty and throughout life, as an anabolic regulator of muscle and bone structure and function. The actions of testosterone are mediated, primarily, through the androgen receptor, a member of the nuclear receptor superfamily. The androgen receptor gene is located on the X-chromosome and receptor levels are tightly controlled both at the level of transcription of the gene and post-translationally at the protein level. Sp1 has emerged as the major driver of expression of the androgen receptor gene, while auto-regulation by androgens is associated with both positive and negative regulation in a possible cell-selective manner. Research into the networks of positive and negative regulators of the androgen receptor gene are vital in order to understand the temporal and spatial control of receptor levels and the consequences for healthy aging and disease. A clear understanding of the multiple transcription factors participating in regulation of the androgen receptor gene will likely aid in the development and application of hormone therapies to boast or curb receptor activity.

Short poly-glutamine repeat in the androgen receptor in New World monkeys

The androgen receptor mediates various physiological and developmental functions and is highly conserved in mammals. Although great intraspecific length polymorphisms in poly glutamine (poly-Q) and poly glycine (poly-G) regions of the androgen receptor in humans, apes and several Old World monkeys have been reported, little is known about the characteristics of these regions in New World monkeys. In this study, we surveyed 17 species of New World monkeys and found length polymorphisms in these regions in three species (common squirrel monkeys, tufted capuchin monkeys and owl monkeys). We found that the poly-Q region in New World monkeys is relatively shorter than that in catarrhines (humans, apes and Old World monkeys). In addition, we observed that codon usage for poly-G region in New World monkeys is unique among primates. These results suggest that the length of polymorphic regions in androgen receptor genes have evolved uniquely in New World monkeys.

The effect of diet-induced insulin resistance on DNA methylation of the androgen receptor promoter in the penile cavernosal smooth muscle of mice

Population studies have suggested an association between diabetes and the symptoms of testosterone deficiency. Recently, the expression of the androgen receptor (AR) has been shown to be decreased in diabetic patients. Furthermore, diabetes has been shown to induce global methylation. In this study, we used an animal model to investigate whether diabetes results in increased methylation of the AR promoter and whether these changes are associated with the decreased expression of AR in penile cavernosal smooth muscle tissue. Twenty C57BL/6J mice were divided into two groups, receiving either high- (mature diabetic) or low- (mature control) caloric meals for 14 weeks. Another 10 mice were killed at 1 week (young control). Animals in the mature diabetic group showed decreased testosterone levels, although this was not statistically significant. In both control groups, no significant methylation was observed in the AR promoter region CpG island (-85 to +339). In the mature diabetic group, significant methylation was observed at +185 and +200 of the AR promoter. These changes were associated with increased homeostatic model assessment for insulin resistance (HOMA-IR) and decreased corpus cavernosal tissue mass and expression of AR mRNA and protein. We conclude that in these animals, insulin resistance increased the methylation of the GC-rich regions of the AR promoter, leading to decreased AR expression.

Germline study of AR gene of Indian women with ovarian failure

OBJECTIVE

Present study was designed for carrying out the mutational analysis of the entire Androgen receptor (AR) gene including two microsatellite (CAG)n, (GGN)n, promoter region in cases of premature ovarian failure (POF) and primary amenorrhea (PA).

DESIGN

Previous reports of AR knockout mice model showed POF phenotype, this draws an attention on the role of AR gene in the aetiology of POF for the case-control association studies in POF samples (n = 133), PA samples (n = 63) and control samples (n = 200).

RESULTS

We identified six mutations including four novel mutations, i.e. c.636G > A, c.1885 + 9C > A, c.1948A > G, c.1972C > A, and two previously reported mutations, i.e. c.639G > A, c.2319-78T > G. Repeat length variation was noted in the two microsatellite regions CAG and GGN, located in the coding region of exon 1 at the N-terminal region of the AR gene. The CAG repeat length was homogeneously distributed with the same frequency and no association among all cases and controls. The GGN repeat showed a significant association among the SS and SL allele with p = 0.0231 and p = 0.0476, respectively, among the POF/control samples.

CONCLUSIONS

Thus, AR gene mutations may play a role in the genetic cause of POF. Identification of the underlying genetic alteration of the AR gene is important for a proper diagnosis of POF subjects.

Androgen receptor of the frog Rana rugosa: molecular cloning and its characterization

The androgen receptor(AR) gene is located on the Z and W sex chromosomes in the frog Rana rugosa, designated Z- and W-AR, respectively. Among various tissues of an adult frog, AR expression levels were highest in the testis and brain. In the testis, AR was expressed in germ cells. AR expression occured in developing embryos from stage 21 and was very high in the gonad of a male tadpole before the onset of sex determination. When Z- and W-AR were expressed in Xenopus A6 cells, they activated androgen-dependent transcription of a luciferase reporter gene. By contrast, estrogen receptor (ER) alpha and beta showed no sexually dimorphic expression during sex determination, but their expressions became much higher in the gonad of a female tadpole after sex determination. In addition, AR transcripts in the ZZ-tadpoles were twice as abundant as in the ZW genotype. In contrast, W-AR expression was extremely low although when W-AR was expressed in A6 cells, it activated transcription in the luciferase assay. In this regard it is worth noting that the promoter regions of Z- and W-AR are not identical. The results suggest that Z-AR plays an important role in the testis formation in a R. rugosa tadpole, whereas ERbeta is involved in ovary differentiation. Very low expression of W-AR may be due to its promoter region having mutations in key transcription factor binding sites, although these remain to be identified. Thus, it is proposed that AR could be a candidate for a male-determining gene in R. rugosa.

Androgens and the male reproductive tract: an overview of classical roles and current perspectives

Androgens are steroid hormones that play key roles in the development and maintenance of male phenotype and reproductive function. These hormones also affect the function of several non-reproductive organs, such as bone and skeletal muscle. Endogenous androgens exert most of their effects by genomic mechanisms, which involve hormone binding to the androgen receptor (AR), a ligand-activated transcription factor, resulting in the modulation of gene expression. AR-induced non-genomic mechanisms have also been reported. A large number of steroidal and non-steroidal AR-ligands have been developed for therapeutic use, including the treatment of male hypogonadism (AR agonists) and prostate diseases (AR antagonists), among other pathological conditions. Here, the AR gene and protein structure, mechanism of action and AR gene homologous regulation were reviewed. The AR expression pattern, its in vivo regulation and physiological relevance in the developing and adult testis and epididymis, which are sites of sperm production and maturation, respectively, were also presented.

17Beta-estradiol modulates age-dependent binding of 40 kDa nuclear protein to androgen receptor promoter in mouse cerebral cortex

Androgen influences the function of central and peripheral nervous system and plays a crucial role in maintaining reproductive behaviors and neuroendocrine regulation. Such action is mediated by interaction of androgen receptor (AR) promoter with nuclear proteins, which are involved in transcriptional regulation of androgen responsive genes. We have analyzed the binding of AR core promoter to nuclear proteins from the cerebral cortex of adult and old mice of both sexes by electrophoretic mobility shift assay (EMSA) and characterized the bound protein by Southwestern blotting. EMSA showed that the binding of nuclear proteins declined in the cerebral cortex of intact old mice as compared to adult. Following gonadectomy, the binding was reduced in old male and adult female but increased in old female. In contrast, estradiol supplementation increased the binding in old male and adult female but decreased in old female. Southwestern blotting analysis revealed that a 40 kDa nuclear protein bound to the promoter and the binding pattern was similar to that observed in EMSA. Further characterization of this protein may help to explore the intricate mechanism that underlies the transcriptional regulation of androgen responsive genes during aging.

Mithramycin targets sp1 and the androgen receptor transcription level-potential therapeutic role in advanced prostate cancer

Multiple lines of evidence implicate over-expression and activation of the androgen receptor (AR) in the progression of prostate cancer (PC) to androgen-independence (AI) and resistance to therapy. The mechanisms leading to AR over-expression are not fully understood but binding of Sp1 to specific Sp1-binding sites in the AR promoter and 5'-untranslated region (5'-UTR) was shown to up-regulate AR transcription. In this work, we further characterized the role of Sp1 in the control of AR transcription and explored its potential as a therapeutic target in androgen-dependent (AD) and independent (AI) LNCaP cells. We identified a pair of new Sp1-binding site in the 5'-UTR of AR which we named ARSp1-3. ARSp1-3 binds Sp1 with higher affinity than other known Sp1-binding sites in the promoter/5'-UTR and in transfection experiments, the ARSp1-3 reporter showed higher transcriptional activity in AI than in AD cells. Treatment of these cells with nanomolar concentrations of Mithramycin inhibited binding of Sp1 to its binding sites in the promoter/5'-UTR of the AR gene but more specifically the binding of ARSp1-3 while other regulatory elements of the AR promoter were not affected. Inhibition of Sp1 binding by Mithramycin decreased the AR transcription and transactivation of PSA reporter constructs. At the lowest concentrations, Mithramycin decreased endogenous AR protein and proliferation of AD and AI LNCaP cells. The combinations of Mithramycin with either paclitaxel or bicalutamide were highly synergistic.

CONCLUSION

Sp1 binding induces AR transcription in LNCaP cells. The higher affinity of ARSp1-3 for Sp1 may support higher AR mRNA levels in AI than AD LNCaP cells. Mithramycin is a potent and specific inhibitor of Sp1 and AR transcription with potential, at very low concentrations, to enhance the efficacy of hormones or taxane based therapy in patients with recurrent or androgen-independent progression that sustain AR expression.

Cloning and expression analysis of androgen receptor gene in chicken embryogenesis

We cloned a full-length androgen receptor (AR) cDNA from chicken (Gallus gallus) gonads. The cDNA sequence has an open reading frame of 2109 bp encoding 703 amino acids. The chicken AR (cAR) shares high homology with ARs from other species in its amino acid sequences, in particular DNA binding domain (DBD) and ligand binding domain (LBD). RT-PCR analysis revealed that cAR mRNA is expressed in several embryonic tissues of both sexes, and relatively higher expression was observed in left ovary compared with testis. The immunoreactive signal of AR was co-localized within the ovarian cell nucleus, while such nuclear localization was not detected in those of testis. To get insight on the possible role of androgen-AR signaling during gonadal development, non-steroidal AR antagonist, flutamide, was administrated in ovo. The treatment induced the disorganization of sex cords in ovarian cortex at day 12 of incubation. The effect was restored by testosterone co-treatment, implying the possibility that AR mediated signaling may be involved in ovarian morphogenesis. Furthermore, co-treatment of flutamide with estradiol-17beta (E2) also restored the phenotype, suggesting androgen-AR signaling might activate aromatase expression that is necessary for estrogen synthesis. These findings suggest androgen-AR signaling might contribute to chicken embryonic ovarian development.

Roles of steroid receptor coactivator (SRC)-1 and transcriptional intermediary factor (TIF) 2 in androgen receptor activity in mice

Genetic disruption of the steroid receptor coactivator (SRC)-1 and transcriptional intermediary factor (TIF)2/SRC-2 in mouse resulted in distinctive mutant phenotypes. To quantify their roles in the function of androgen receptor (AR) transcriptional activity in vivo, we generated a unique transgenic AR-reporter mouse and analyzed the cell-specific contributions of SRC-1 and TIF2 to the activity of AR in mouse testis. Transgenic AR-luciferase and transgenic AR-lacZ mice harbor a recombinant mouse AR gene, AR(GAL4DBD), which is functionally coupled with a upstream activation sequence-mediated reporter gene (AR activity indicator). After characterization of these mice in terms of AR function, we further derived bigenic mice by crossing AR activity indicator mice with the SRC-1-/- or TIF2+/- mutant mice. Analyses of the resultant bigenic mice by in vivo imaging and luciferase assays showed that testicular AR activity was decreased significantly in those with the TIF2+/- mutation but not in the SRC-1+/- background, suggesting that TIF2 serves as the preferential coactivator for AR in testis. Immunohistological analysis confirmed that AR and TIF2 coexist in mouse testicular Sertoli cell nuclei under normal conditions. Although SRC-1 concentrates in Sertoli cell nuclei in the absence of TIF2, nuclear SRC-1 is not able to rescue AR activity in the TIF2 mutant background. Interestingly, SRC-1 appears to negatively influence AR activity, thereby counterbalancing the TIF2-stimulated AR activity. Our results provide unique in vivo insights to the multidimensional cell-type-specific interactions between AR and coregulators.

The hamster androgen receptor promoter: a molecular analysis

The steroid/thyroid hormone receptors are members of a very large family of nuclear-activated transcription factors. These receptors play a crucial role in most biological function, including regulation of development, metabolism, behaviour and reproduction. Among androgen receptor (AR), we have recently demonstrated that its expression in the Harderian gland (HG) of the male hamster is under a well-co-ordinated cross-talk between various steroid hormone receptors. Here, are presented data on the sequence of hamster AR promoter region (5'UTR) and the molecular tools of its regulation. The 5'UTR is 1585 bp. The promoter region shows various responsive elements. Two putative CREM elements are present at -71 and -1576 bp. A putative retinoic acid responsive element is present at -1476 bp. An androgen/glucocorticoid responsive element is present at -473 bp. A putative thyroid hormone-responsive element at -381 bp and an estrogen responsive element at -230 bp. Also, a homopurinic stretch is evident between -1199 and -1118. Furthermore, Sp1 sites are also spread along the sequence. As well as for human, mouse, rat and pig, the hamster lacks the canonical promoter TATA and CCAAT boxes. Gel retardation experiments confirm the presence of active responsive elements for AR, estrogen receptor, glucocorticoid receptor and thyroid hormone receptor. Previous data on the regulation of expression of AR by other members of steroid/thyroid hormone receptors well correlate with sequence analysis and gel retardation experiments. Thus, androgens, thyroid hormone, stimulate the AR transcription, while synthetic glucocorticoid (Dex) and estrogen are potent inhibitors of AR expression. The comparison of hamster AR promoter sequence with other AR promoter shows an 89, 82, 84 and 84% identity with human, rat, mouse and pig AR promoter, respectively. These results, in the light of the extreme plasticity of hamster HG, suggest that the comparative study of expression and regulation of AR gene in the HG of the hamster offers a useful tool to approach the normal and pathological phenotype in human.

Androgen receptor mRNA expression in the bovine ovary

Previous studies have shown that androgen receptor (AR) is expressed in granulosa cells of healthy, growing ovarian follicles in rats and primates. However, AR expression in the bovine ovary has not been examined. Therefore, a 346-base pair segment of the bovine AR was cloned and sequenced. Using a ribonuclease protection assay, AR expression was detected in total RNA from bovine ovarian cortex. Expression (absence or presence) of AR mRNA was detected by in situ hybridization in bovine ovarian cortex. Follicles (n = 32) were classified as follows: type 1 (1 layer of flattened granulosa cells), type 2 (1-1.5 layers of cuboidal granulosa cells), type 3 (2-3 layers of granulosa cells), type 4 (4-6 layers of cuboidal granulosa cells and formation of thecal layer), and type 5 (>6 layers of cuboidal granulosa cells, defined theca layer, and antrum formation). Frequency of AR mRNA expression increased (P < 0.001) as follicles entered the growing pool. Expression of AR mRNA was absent in type 1 follicles (n = 8), but present in the granulosa cells of 41% of type 2 follicles (n = 12). In types 3-5 follicles, AR mRNA expression was present in granulosa cells of 100% of follicles examined (n = 4, 4, and 4, respectively) and was greater than type 1 follicles (P = 0.002). These data provide evidence of AR mRNA expression in bovine follicles and suggest that AR mRNA increases during early follicle development.

Cloning and characterization of androgen receptor from bullfrog, Rana catesbeiana

We have cloned and characterized a full-length cDNA of androgen receptor (AR) from the testis of bullfrog, Rana catesbeiana. The cDNA contains an open reading frame of 2328 nucleotides encoding a protein of 776 amino acid residues. The bullfrog AR shows high homology with ARs from other species in its amino acid sequence. Its overall homology with those of African clawed frog, Japanese eel and human is 70, 53, and 63%, respectively. As expected, the N-terminal domain shows much less homology (30-59%) than both DNA-binding domain (85-92%) and ligand binding domain (80-89%). Northern blot analysis detected the bullfrog AR message as a single transcript of around 9 kb only in the testis. However, RT-PCR analysis revealed that AR mRNA is also expressed in other tissues although the levels are very low compared to that in the testis. Western blot analysis of whole tissue extracts showed the presence of AR protein in fore brain, heart, and testis. The AR gene is present as a single copy in bullfrog based on Southern blot analysis of genomic DNA. Altogether, the results suggest that the bullfrog AR is evolutionary conserved and may have functions similar to those shown in other species.

Mouse sperm cell-specific DnaJ first homologue: an evolutionarily conserved protein for spermiogenesis

Msj-1 (mouse sperm cell-specific DnaJ first homologue) is a gene specifically expressed in germ cells at haploid stages. The protein first appears in round spermatids, accumulates in the periacrosomal region of elongating spermatids, and is maintained in spermatozoa. The msj-1 expression pattern is consistent with a role for this DnaJ protein in the spermiogenesis process. In this study, we used two experimental models, the anuran amphibian Rana esculenta and the wobbler mutant mouse, to explore the role of MSJ-1 during spermatogenesis, with a focus on spermiogenesis. Mice homozygous for the recessive mutation wobbler (wr/wr), a mutation of unknown identity, produce sperm cells characterized by a missing acrosome. In Rana esculenta testis, detection of high levels of MSJ-1 protein coincided with the appearance of postmeiotic germ cells during the annual sexual cycle. Conversely, elimination of the meiotic and postmeiotic stages, through gonadotropin administration at low temperature, abolished the MSJ-1 immunoreactive signal. In 20-day-old mice, when postmeiotic germ cells appeared for the first time, MSJ-1 mRNA and protein were observed in +/+ testis but were barely detectable in wr/wr testis. In adult testis, reduced MSJ-1 protein levels were observed in both +/wr and wr/wr testis, as compared with +/+ controls. Similarly, numbers of spermatids that stained by immunofluorescence for MSJ-1 appeared to be progressively reduced in adult +/+, +/wr, and wr/wr mouse testes, respectively. Characterization of the endocrine status of wobbler testis revealed reduced transcript levels of estrogen receptor alpha and reduced intratesticular androgen levels. However, androgen treatment did not affect MSJ-1 protein levels in either frogs or mice. In conclusion, our data in Rana esculenta and the wobbler mouse demonstrate a tight correlation between MSJ-1 protein expression and postmeiotic stages. In particular, the findings in the wobbler testis suggest a role for this protein in acrosomogenesis.

Molecular cloning and functional characterization of the canine androgen receptor

Sex steroids, including testosterone, play a major role in determining peak bone mass in mammals and the subsequent loss of total bone mass with advancing age. Testosterone, and its active metabolite dihydrotestosterone (DHT), bind with high affinity to the androgen receptor (AR), a member of the nuclear hormone receptor superfamily. These receptors function as transcription factors, binding together with accessory proteins to specific DNA response elements in the promoters of androgen responsive genes. To further characterize AR function in a model species of relevance to bone and pharmaceutical research, we cloned a partial canine AR from a canine kidney cDNA library and then cloned the remaining 5' segment by PCR from canine ventral prostate cDNA. The complete sequence obtained was 3577 bp. This sequence contained a single open reading frame of 2721 bp, potentially encoding a protein of 907 amino acids with a predicted molecular weight of 98.7 kD. Sequence analysis of the protein encoded by this open reading frame reveals that the modular domains providing the DNA binding and ligand binding functions are identical to those reported for eight other mammalian ARs. Northern analysis of poly-A+ RNA from ventral prostate revealed three very low abundance transcripts of approximately 9 kb and RT-PCR analysis showed relatively high expression of AR in canine ventral prostate, testis, and kidney, with lower levels detectable in spleen, skeletal muscle, heart, and liver. Competition binding studies using 3H-DHT as ligand demonstrated specific displacement by DHT, testosterone, and the anabolic steroid stanozolol, with IC50 values of 1.3, 2.5 and 3.8 nM, respectively. Binding of DHT also resulted in the stimulation of an androgen responsive-luciferase reporter following cotransfection with the canine AR into 293 cells. Immunohistochemistry using an antibody directed to the C-terminal 19 amino acids of the human AR showed strong staining of the secretory epithelial cells in canine ventral prostate. Together, these data indicate that we have cloned the canine AR and that its functional DNA binding and ligand binding domains are absolutely conserved with those reported for eight other species.

Prostatic intraepithelial neoplasia in mice expressing an androgen receptor transgene in prostate epithelium

Prostate cancer (PCa) is an androgen dependent disease that can be treated by androgen ablation therapy, and clinical trials are under way to prevent PCa through the reduction of androgen receptor (AR) activity. However, there are no animal models of AR-mediated prostatic neoplasia, and it remains unclear whether the AR is a positive or negative regulator of cell growth in normal prostate secretory epithelium. To assess the direct effects of the AR in prostate epithelium, a murine AR transgene regulated by the rat probasin promoter (Pb) was used to generate transgenic mice expressing increased levels of AR protein in prostate secretory epithelium. The prostates in younger (<1 year) Pb-mAR transgenic mice were histologically normal, but Ki-67 immunostaining revealed marked increases in epithelial proliferation in ventral prostate and dorsolateral prostate. Older (>1 year) transgenic mice developed focal areas of intraepithelial neoplasia strongly resembling human high-grade prostatic intraepithelial neoplasia (PIN), a precursor to PCa. These results demonstrate that the AR is a positive regulator of cell growth in normal prostate epithelium and provide a model system of AR-stimulated PIN that can be used for assessing preventative hormonal therapies and for identifying secondary transforming events relevant to human PCa.

Analysis of glucocorticoid and androgen receptor gene fusions delineates domains required for transcriptional specificity

Androgen receptor (AR) and glucocorticoid receptor (GR) influence distinct physiologic responses in steroid-responsive cells despite their shared ability to selectively bind in vitro to the same canonical DNA sequence (TGTTCT). While the DNA-binding domains (DBDs) of these receptors are highly conserved, the amino N-terminal domain (NTD) and hormone-binding domain (HBD) are evolutionarily divergent. To determine the relative contribution of these functional domains to steroid-specific effects in vivo, we constructed a panel of AR/GR gene fusions by interchanging the NTD, DBD, and HBD regions of each receptor and measured transcriptional regulatory activities in transfected kidney and prostate cell lines. We found that GR was approximately 10-fold more active than AR when tested with the mouse mammary tumor virus promoter, and that this difference in activity was primarily owing to sequence divergence in the NTDs. We also tested transcriptional activation of the androgen-dependent rat probasin promoter, and in this case, AR was at least twofold more active than GR. Analysis of the chimeric receptors revealed that this difference mapped to the DBD region of the two receptors. Transcriptional repression functions of the wild-type and chimeric receptors were measured using an activator protein 1 (AP-1) transrepression assay and identified the GR HBD as a more potent transrepressor of AP-1 transcriptional activation than the AR HBD. Taken together, our analyses reveal that evolutionary sequence divergence between AR and GR functional domains results in unique promoter-specific activities within biologic systems in which both AR and GR are normally expressed.

Two distinct forms of the 64,000 Mr protein of the cleavage stimulation factor are expressed in mouse male germ cells

Polyadenylation in male germ cells differs from that in somatic cells. Many germ cell mRNAs do not contain the canonical AAUAAA in their 3' ends but are efficiently polyadenylated. To determine whether the 64,000 Mr protein of the cleavage stimulation factor (CstF-64) is altered in male germ cells, we examined its expression in mouse testis. In addition to the 64,000 Mr form, we found a related approximately 70,000 Mr protein that is abundant in testis, at low levels in brain, and undetectable in all other tissues examined. Expression of the approximately 70,000 Mr CstF-64 was limited to meiotic spermatocytes and postmeiotic spermatids in testis. In contrast, the 64,000 Mr form was absent from spermatocytes, suggesting that the testis-specific CstF-64 might control expression of meiosis-specific genes. To determine why the 64,000 Mr CstF-64 is not expressed in spermatocytes, we mapped its chromosomal location to the X chromosome in both mouse and human. CstF-64 may, therefore, be absent in spermatocytes because the X chromosome is inactivated during male meiosis. By extension, the testis-specific CstF-64 may be expressed from an autosomal homolog of the X chromosomal gene.

Two distinct isoforms of cDNA encoding rainbow trout androgen receptors

Androgens play an important role in male sexual differentiation and development. The activity of androgens is mediated by an androgen receptor (AR), which binds to specific DNA recognition sites and regulates transcription. We describe here the isolation of two distinct rainbow trout cDNA clones, designated rtAR-alpha and rtAR-beta, which contain the entire androgen receptor coding region. Comparison of the predicted amino acid sequence of rtAR-alpha to that of rtAR-beta revealed 85% identity. Interestingly, despite this high homology, rtAR-alpha activated transcription of an androgen-responsive reporter gene in co-transfection assays, but rtAR-beta did not. These results suggest that rainbow trout contains two distinct isoforms of androgen receptors whose functions differ. The region of rtAR-beta responsible for its inactivity was mapped to its ligand binding domain by analyzing chimeras of the rtAR-alpha, rtAR-beta, and rtGR-I (glucocorticoid) receptors. Alteration of any one of three out of four segments within this domain restored activity. Extracts made from COS-1 cells transfected with an rtAR-alpha expression plasmid produced a high level of [3H]mibolerone binding, whereas no binding was observed by extracts of cells transfected with an rtAR-beta expression plasmid. These data demonstrate that the lack of transactivation activity of rtAR-beta is due to its inability to bind hormone.

Expression of androgen receptor mRNA during mouse embryogenesis

Androgen receptor (AR) is a member of the nuclear receptor superfamily which acts as a ligand-dependent transcription factor (Beato, M., Herrlich, P., Schütz, 1989. Steroid hormone receptors: many actors in search of a plot. Cell 83, 851-857). It plays a pivotal role in sexual development and reproduction (Wilson, J.D., Griffin, J.E., George, F.W., Leshin, M., 1981. The role of gonadal steroids in sexual differentiation. Rec. Prog. Horm. Res. 37, 1-39; Jost, A., 1990. Hormonal control of the masculinization of the body. In: Baulieu, E.E., Kelly, D.A., (Eds.), Hormones, from Molecules to Disease. Chapman and Hall, New York and London, pp. 439-442.). Mutations in the AR sequence cause a number of physiological disorders, such as partial and complete androgen insensitivity syndromes, that lead to abnormal sexual development (Patterson, M.N., McPhaul, M.J., Hughes, I.A., 1994. Androgen insensitivity syndrome. Ballière's Clin. Endocrinol. Metab. 8, 379-404.). There are indications that AR may also have other functions. For example, structural alterations of the AR sequence have been implicated in prostate cancer (Visakorpi, T., Huytinen, E., Koivisto, P., Tanner, M., Keinänen, R., Palmberg, C., Palotie, A., Tammela, T., Isola, J., Kallioniemi, O.-P., 1995. In vivo amplification of the androgen receptor gene and progression of human prostate cancer. Nature Genet. 9, 401-406.) and in the development of spinal and bulbar muscular atrophy, a neurodegenerative disease (Kennedy, W.R., Alter, M., Sung, J.H., 1968. Progressive proximal spinal and bulbar muscular atrophy of late onset: a sex-linked recessive trait. Neurology 18, 671-680.). Here, we have investigated the spatial and temporal expression of AR during mouse organogenesis by in situ hybridisation. We demonstrate that AR transcripts occur in the developing external genitalia, pituitary, adrenals, kidneys and musculus levator ani, in addition to the known expression sites in the Wolffian ducts and its derivatives and during development of the mammary glands.

Transcriptional regulation of the steroid receptor genes

Steroid hormones, via their binding to specific receptors, are involved in the development, differentiation, and physiological response of cells to diverse stimuli. Activation by hormonal ligands induces conformational change in the receptor, enabling interaction with the target genes. The steroid receptor superfamily includes androgen, glucocorticoid, mineralocorticoid, progesterone, estrogen, thyroid, vitamin D, retinoic acid, and orphan receptors. This review will focus on the classic steroid receptors, i.e., the androgen, glucocorticoid, progesterone, and estrogen receptors, with emphasis on their transcriptional regulation. Readers are directed to several authoritative reviews for further details of steroid receptors (1-11).

Transcriptional up-regulation of the human androgen receptor by androgen in bone cells

Androgen regulation of androgen receptor (AR) expression has been observed in a variety of tissues, generally as inhibition, and is thought to attenuate cellular responses to androgen. AR is expressed in osteoblasts, the bone-forming cell, suggesting direct actions of androgens on bone. Here we characterized the effect of androgen exposure on AR gene expression in human osteoblastic SaOS-2 and U-2 OS cells. Treatment of osteoblastic cells with the nonaromatizable androgen 5alpha-dihydrotestosterone increased AR steady state messenger RNA levels in a time- and dose-dependent fashion. Reporter assays with 2.3 kilobases of the proximal 5'-flanking region of the human AR promoter linked to the chloramphenicol acetyltransferase gene in transfected cultures showed that up-regulation of AR promoter activity by androgen was time and dose dependent. Treatment with other steroid hormones, including progesterone, 17beta-estradiol, and dexamethasone, was without effect. The antiandrogen hydroxyflutamide completely antagonized androgen up-regulation. Thus, in contrast to many other androgen target tissues, androgen exposure increases steady state AR messenger RNA levels in osteoblasts. This regulation occurs at least partially at the level of transcription, is mediated by the 5'-promoter region of the AR gene, and is dependent on functional AR. These results suggest that physiological concentrations of androgens have significant effects on AR expression in skeletal tissue.

Codon repeats in genes associated with human diseases: fewer repeats in the genes of nonhuman primates and nucleotide substitutions concentrated at the sites of reiteration

Five human diseases are due to an excessive number of CAG repeats in the coding regions of five different genes. We have analyzed the repeat regions in four of these genes from nonhuman primates, which are not known to suffer from the diseases. These primates have CAG repeats at the same sites as in human alleles, and there is similar polymorphism of repeat number, but this number is smaller than in the human genes. In some of the genes, the segment of poly(CAG) has expanded in nonhuman primates, but the process has advanced further in the human lineage than in other primate lineages, thereby predisposing to diseases of CAG reiteration. Adjacent to stretches of homogeneous present-day codon repeats, previously existing codons of the same kind have undergone nucleotide substitutions with high frequency. Where these lead to amino acid substitutions, the effect will be to reduce the length of the original homopolymeric stretch in the protein.

The androgen receptor is transcriptionally suppressed by proteins that bind single-stranded DNA

The androgen receptor (AR) is a nuclear transcription factor that is essential for development of the male urogenital tract. In the current work, we have characterized the mouse androgen receptor suppressor (mARS). A single, 20-base pair, region (TCCCCCCACCCACCCCC-CCT) was sufficient for suppression in chloramphenicol acetyltransferase assays. Northern analysis indicated that translational regulation is not necessary for the suppression. Analysis of the AR mRNA half-life indicated that the mARS does not affect AR RNA degradation. Gel mobility assays showed that the mARS is bound by multiple proteins that can recognize single-stranded DNA and RNA. In addition, differing proteins are expressed in distinct tissues. Purification of some of these proteins has shown that a doublet of 33 and 35 kDa binds to the G-rich strand and that a 52-kDa protein binds to the C-rich strand. Southwestern blots have confirmed that these proteins are indeed recognized by the mARS. The results of these experiments indicate that the AR 5'-untranslated region contains a suppressor element that can be bound by multiple proteins. The mARS appears to be acting either by altering transcription initiation or blocking transcription elongation. Characterization of this suppressor may provide insight into the physiological means by which the AR is regulated.

Identification and characterization of a suppressor element in the 5'-flanking region of the mouse androgen receptor gene

Androgens play an important role in the development and maintenance of male reproductive organs through the androgen receptor (AR). In order to study the mechanism of regulation of AR at the molecular level, a 1571 bp fragment in the 5'-flanking region of the mouse androgen receptor (mAR) gene was isolated and sequenced. Transfection of 5'-deletion constructs cloned into vectors containing the chloramphenicol acetyl transferase (CAT) gene indicated the presence of a promoter in the sequence -146 to +131. These experiments also suggested the presence of a suppressor element. Further characterization indicated that the suppressor is present between -486 to -351. It is functional in the context of the natural AR promoter and the heterologous thymidine kinase promoter. Transfection of a -546/ + 131 construct in which the putative suppressor element (-421 to -448) had been deleted caused increased basal CAT activity suggesting that the suppressor is limited to this 28 bp element in the 5'-flanking region of the mouse AR gene.

The receptor, metabolism and effects of androgen in osteoblastic MC3T3-E1 cells

We investigated the androgen receptor (AR), metabolism and effects of androgens in osteoblastic MC3T3-E1 cells. AR was proved as a transcript of a 10-kb mRNA and as a 110-kDa protein. An immunocytochemical study showed that AR was located mainly in the nuclei. Specific binding of [3H]DHT was observed in both the nuclear and cytosol fractions. MC3T3-E1 cells possessed approximately 1190 binding sites per cell and most of the sites (1150 sites) situated in the nucleus. The apparent Kd value in the nuclear fraction was 1.35 nM for [3H]DHT binding, and it was similar to that for [3H]testosterone. In the competition analysis, there was not much difference in the displacement of the [3H]DHT binding from AR between the addition of radioinert DHT and testosterone. In studies of 5 alpha-reductase activity and aromatase activity of the cells, both activities were lower than the respective values in classical androgen target tissues. Androgens stimulated the incorporation of [3H]thymidine into the cell, and DHT and testosterone had a similar potency on the cell proliferation. Thus, these results suggest testosterone itself acts mainly on the osteoblasts without conversion to DHT.

Human androgen receptor expressed in HeLa cells activates transcription in vitro

The androgen receptor (AR) is a ligand-responsive transcription factor, belonging to the class of steroid receptors. AR mutations have been associated with various X-linked diseases, characterized by complete or partial resistance to androgens. To further analyse the molecular mechanism of action of the AR, we have produced the human AR in HeLa cells with a Vaccinia virus expression system. Binding studies on infected HeLa cells demonstrate that the recombinant AR interacts specifically and with high affinity with natural and synthetic androgens. In a gel retardation assay the partially purified AR specifically recognizes an androgen response element of the rat prostatic binding protein gene. Moreover, the recombinant AR activates transcription in vitro from a synthetic promoter construct containing glucocorticoid response elements (GRE).

The effect of androgens and antiandrogens on the immunohistochemical localization of the androgen receptor in accessory reproductive organs of male rats

The androgen receptor (AR) was localized immunohistochemically after different hormonal treatments in the ventral prostate, coagulating gland, seminal vesicle and epididymis of the adult rat. In the untreated controls AR-immunoreactivity was confined to the cell nuclei. One week after castration or treatment with the gonadotropin-releasing hormone antagonist Cetrorelix (150 micrograms/animal per day) a cytoplasmic staining occurred in the epithelial cells of the ventral prostate and in part of the coagulating gland and seminal vesicle. In contrast, the AR remained exclusively in the nuclei in the epididymal epithelium and the glandular smooth muscle layer even after 2 weeks of androgen depletion. Bolus injections of either dihydrotestosterone (1 mg/kg), the antiandrogen flutamide (40 mg/kg), or the novel non-steroidal antiandrogen casodex (40 mg/kg) to androgen-depleted animals eliminated cytoplasmic AR-immunoreactivity and restored the nuclear staining pattern in the ventral prostate. A sustained 2-week treatment with the antiandrogens resulted in a loss of weight in all organs but did not alter the distribution of AR-immunoreactivity. The data show an apparent cytoplasmic/nuclear ligand-dependent translocation of the AR in the ventral prostate, coagulating gland and seminal vesicle but not in the epididymis of the adult rat.

Molecular mechanisms of androgen action

Androgens directly regulate a vast number of physiological events. These direct androgen effects are mediated by a nuclear receptor that exhibits four major functions or activities: steroid binding, DNA binding, transactivation, and nuclear localization. The SBD consists of a hydrophobic pocket of amino acids that exhibits high-affinity, androgen-specific binding. Based on studies of mutant AR, it appears that a number of different amino acids contribute to the steroid binding characteristics of the AR. The DNA binding domain confers sequence-specific binding to structures called androgen-responsive elements. The specificity of steroid binding and DNA binding provides a crucial basis for androgen-specific regulation of target genes. The nuclear localization signal shares homology with known nuclear localization signals and, coupled with the presence of androgens, is responsible for localizing the AR to the nucleus. The transactivation functions reside mostly in the NH2 terminus but the responsible domains are as yet poorly defined. Though the different domains can act as independent moieties, one domain can clearly alter the behavior of another domain. For instance, the SBD appears to inhibit the transactivating functions until steroid is bound and the amino terminus prevents DNA binding activity until steroid is bound. The relative ease of introducing mutations with polymerase chain reaction technology will facilitate further delineation of critical amino acids and domains responsible for the various activities of the AR. The recent cloning and characterization of AR promoters revealed that the AR genes are driven by a TATA-less promoter characteristics of housekeeping genes. Analysis of transcription rates, mRNA levels, and protein levels indicates that androgens and pkA and pkC pathways modulate expression of AR mRNA and protein. This indicates that the same signal pathways that interact to regulate androgen target genes also regulate the levels of AR in the target tissues. Surprisingly few androgen-regulated genes have been well characterized for the mechanisms by which androgen regulates the gene. The C(3), Slp, probasin, PSA, and hKLK2 genes have provided examples where androgens regulate transcription. Posttranscriptional regulation by androgens has been demonstrated for the SVP1, 2, 3, and 4 and AR genes. The mechanisms underlying posttranscriptional regulation are poorly defined but substantial progress has been made in defining the critical elements that mediate transcriptional effects of androgens. Transcriptional effects are mediated through binding of androgen-AR complexes to specific DNA sequences called AREs. Simple AREs such as those found in C(3) and kallikrein genes tend to be permissive in that GR and PR can also act through the same element.(ABSTRACT TRUNCATED AT 400 WORDS)

Reduced transcriptional regulatory competence of the androgen receptor in X-linked spinal and bulbar muscular atrophy

Expansion of the long (CAG; glutamine)n repeat in the first exon of the X-linked human androgen receptor gene (hAR) causes spinal and bulbar muscular atrophy, frequently in association with mild androgen insensitivity. The relevant normal motor neurons are preferentially stimulated by androgen, however no motor neuron disorder occurs with any other known AR mutation, including those that cause complete androgen insensitivity. We have found that a polyglutamine (Gln) expanded AR transactivates an androgen-responsive reporter gene subnormally. Other groups have reported that a poly Gln-deleted AR transactivates normally. A parsimonious interpretation of all these facts is that poly Gln expansion causes the AR to lose a function that is necessary for full androgen sensitivity and to gain a function that is selectively motor neuronotoxic.

Up-regulation of the levels of androgen receptor and its mRNA by androgens in smooth-muscle cells from rat penis

Smooth-muscle cells cultured from the penis of sexually immature (I-PSMC) and adult (A-PSMC) rats express similar high levels of the androgen receptor (AR) mRNA. This contrasts with the marked in vivo decline of both AR mRNA and androgen binding in the penile smooth muscle of adult rats, which appears to be responsible for the cessation of androgen-dependent penile growth upon sexual maturation. PSMC is therefore a good model to study putative down-regulators of AR expression as a function of cell proliferation in the smooth muscle of androgen-responsive vascular tissue. In order to determine whether AR protein levels in PSMC correlate with AR mRNA levels, the immunocytochemical detection of ARs and their androgen binding capacity were compared between I- and A-PSMC. The number of ARs and their protein half-lives suggested similar levels of translation of the AR mRNA in both cell lines. The effect of the synthetic analog methyltrienolone (R-1881) on androgen binding was studied in contact-inhibited androgen-deprived PSMC. In contrast to the postulated role of androgens as down-regulators of AR expression in rat penis, ARs were up-regulated in A-PSMC by R-1881. Contact inhibition of A-PSMC combined with serum depletion and androgen deprivation down-regulated AR mRNA levels, and dihydrotestosterone (DHT) counteracted this effect. These results suggest that the loss in A-PSMC of the age-dependent down-regulation of ARs observed in vivo in adult corpora cavernosa smooth muscle is related to the in vitro resumption of cell proliferation and that DHT acts directly on the penile smooth muscle as a positive modulator of AR levels.