Detection of spatially regulated gene expression by hybridization histochemistry.

Steady state measurements of kidney androgen-regulated protein (KAP) mRNA suggested that KAP gene expression was unusually sensitive to low hormone-receptor levels. Two of the criteria used to reach this conclusion involved relative insensitivity to treatment with a competitive antiandrogen and a partial androgen response of the gene in Tfm/Y androgen receptor (AR) deficient mice. These data may indicate the ability of the KAP gene to respond to an extremely low level of androgen-AR complex or that the effect of androgens is, at least in part, indirect. Hybridization in situ revealed that KAP mRNA expression was restricted to proximal tubule epithelial cells in the juxtamedullary region of castrated animals rather than throughout the cortex as in intact males. Examination of sections of kidneys from Tfm/Y mice before and after testosterone (T) treatment revealed that only the juxtamedullary tubules expressed KAP mRNA and that T increased the level of KAP mRNA in these cells. Treatment of Tfm/Y animals with other steroids showed that beta-estradiol treatment mimicked the effect of T while dihydrotestosterone (DHT) had no effect. The facts that DHT and T both stimulate cortical expression of KAP mRNA in normal animals but DHT has no effect on the juxtamedullary cells in the Tfm/Y variant may indicate that the action of T is due to an estrogenic metabolite. Castrated, hypophysectomized males exhibited no KAP gene expression, while in the presence of T, expression was observed throughout the cortex as in intact males. These results clearly indicate the involvement of pituitary hormones in KAP gene expression in the juxtamedullary tubules. These studies have shown that the regulation of KAP gene expression in the mouse kidney is much more complex than originally believed. Future studies will further investigate the roles of estrogen and specific pituitary hormones in KAP gene expression.     

Cell-specific expression of kidney androgen-regulated protein messenger RNA is under multihormonal control

Kidney androgen-regulated protein (KAP) gene expression is under androgenic control in the epithelial cells of the proximal convoluted tubule in the mouse kidney. In Tfm/Y androgen receptor-deficient mice, KAP mRNA was detected by in situ hybridization in a subpopulation of these cells only in the S3 segment of the proximal tubules in the outer medulla. Treatment of Tfm/Y animals with testosterone caused a partial induction of KAP mRNA levels, while dihydrotestosterone had no effect. These data suggested that the androgen receptor-independent induction of KAP gene expression in these animals was mediated by an estrogenic metabolite of testosterone, since dihydrotestosterone cannot be aromatized to an estrogenic form. Estrogen treatment of Tfm/Y mice caused an increase in KAP gene expression similar to that observed with testosterone. However, ovariectomy of normal female mice did not eliminate KAP gene expression in the S3 cells and, in fact, resulted in a slight increase. Adrenalectomy in combination with castration had no effect on KAP mRNA levels in S3 cells. However, hypophysectomy alone completely eliminated this cell-specific component of KAP gene expression. These results indicate that KAP gene expression is subject to cell-specific regulation in different segments of the proximal tubule and that this regulation is mediated by hormones of both gonadal and pituitary origin.     

Mouse kidney androgen-regulated protein messenger ribonucleic acid is expressed in the proximal convoluted tubules

Kidney androgen-regulated protein (KAP) mRNA represents the most abundant [approximately 4% of the total poly(A) RNA] mRNA species that is induced by androgens in the mouse kidney. Comparison of the expression of several androgen-regulated mRNAs in this tissue, revealed that the mRNAs were differentially regulated by the hormone. KAP mRNA exhibited unusual sensitivity to low concentrations of the androgen-receptor complex. Because of its unusual characteristics, it was of interest to determine in what cells of the kidney KAP mRNA was being produced. Using the technique of in situ hybridization with single stranded RNA probes, we have identified the epithelial cells of the renal proximal convoluted tubules as the site of synthesis of KAP mRNA. Interestingly, only a subpopulation of these cells, those located in the juxtamedullary region of the renal cortex, contain KAP mRNA in castrated males. After androgen treatment, cortical proximal tubules are also induced to express KAP mRNA. These results suggest that two types of response to androgens occur in these cells. One is the progressive increase of KAP gene expression in the juxtamedullary region while the other involves recruitment of new cells in the cortical proximal tubules to synthesize KAP mRNA.     

Multiple genes coding for the androgen-regulated major urinary proteins of the mouse.

We have purified a cDNA fragment complementary to the mRNA coding for one of the major urinary proteins (MUPs) synthesized in the mouse liver. Using this cDNA as a hybridization probe, we have shown that the level of MUP mRNA is lower in the livers of females and castrated males than in those of males. The addition of testosterone to females and castrated males results in an increase in the concentration of the mRNA to levels found in males. There are approximately 15 gene per haploid genome coding for the MUPs; this allows a possible new interpretation of some of the genetic data concerning the regulation of levels of the different MUPs in the urine (Szoka and Paigen, 1978). Finally, we have shown that mouse MUP and rat alpha 2u-globulin mRNA share common sequences, but that there are surprising differences in gene number and regulation of the genes in these two closely related animals.     

Nucleotide sequence of kidney androgen-regulated protein mRNA and its cell-specific expression in Tfm/Y mice

Kidney androgen-regulated protein (KAP) mRNA is an abundant renal mRNA that was originally identified by comparisons of the products of in vitro translation of poly(A) RNA from animals before and after androgen stimulation. KAP mRNA is 607 nucleotides long, excluding its poly(A) segment, and encodes a protein of 13,265 mol wt. A hydrophobic N-terminal domain forms a putative signal peptide of 18 amino acids, the cleavage of which results in a 103-amino acid mature protein with a molecular size of 11,297. The protein is highly negatively charged and contains regions of clustered Pro, Glu/Asp, Ser, and Thr residues that are associated with proteins with short half-lives. KAP mRNA is unusual in that it is expressed in two distinct regions of the kidney under different hormonal treatments. It is expressed throughout the cortex in the epithelial lining of the proximal tubules in response to androgen stimulation. After castration, only tubules in the outer stripe of the medulla express KAP mRNA. The androgen receptor-deficient Tfm/Y mutant strain exhibits KAP mRNA induction only in this juxtamedullary region after testosterone treatment. Expression of KAP mRNA in these cells is responsible for the relatively high basal levels of KAP mRNA in female and castrated male animals, and induction in these cells occurs by an androgen receptor (AR)-independent mechanism.     

Cellular observations and hormonal correlates of feedback control of luteinizing hormone secretion by testosterone in long-term castrated male rhesus monkeys

Testosterone at physiological levels cannot exert negative feedback action on LH secretion in long-term castrated male monkeys. The cellular basis of this refractoriness is unknown. To study it, we compared two groups of male rhesus macaques: one group (group 1, n = 4) was castrated and immediately treated with testosterone for 30 days; the second group (group 2, n = 4) was castrated and treated with testosterone for 9 days beginning 21 days after castration. Feedback control of LH by testosterone in group 1 was normal, whereas insensitivity to its action was found in group 2. Using the endpoints of concentrations of aromatase activity (P450(AROM) messenger RNA [mRNA]) and androgen receptor mRNA in the medial preoptic anterior hypothalamus and in the medial basal hypothalamus, we found that aromatase activity in both of these tissues was significantly lower, P: < 0.01, in group 2 compared with group 1 males. P450(AROM) mRNA and androgen receptor mRNA did not differ, however. Our data suggest that the cellular basis of testosterone insensitivity after long-term castration may reside in the reduced capacity of specific brain areas to aromatize testosterone. Because P450(AROM) mRNA did not change in group 2 males, we hypothesize that an estrogen-dependent neural deficit, not involving the regulation of the P450(AROM) mRNA, occurs in long-term castrated monkeys.     

Differential gene expression of organic anion transporters in male and female rats.

Sex-related differential gene expression of organic anion transporters (rOAT1, rOAT2, and rOAT3) in rat brain, liver, and kidney was investigated. There were no sex differences in the expression of rOAT1 mRNA. rOAT2 mRNA was abundant in the liver and weakly expressed in the kidney of male rats; however, the OAT2 gene was strongly expressed in both organs of females. The abundance of rOAT2 mRNA markedly increased in castrated male rat kidney; however, treatment of castrated male rats with testosterone led to a decrease of rOAT2 mRNA. Expression of rOAT3 mRNA in intact female rats was found in the kidney and brain, whereas in males rOAT3 mRNA was also found in the liver. rOAT3 mRNA markedly decreased in the liver of castrated male rats but increased in testosterone-treated castrated male rats. Moreover, rOAT3 mRNA increased in the hypophysectomized female rat liver, indicating that rOAT3 is an inducible isoform. The present findings suggest that sex steroids play an important role in the expression and maintenance of OAT2/3 isoforms in the rat liver and kidney. Our results provide information on the differential gene expression of OAT isoforms with sex hormone dependency.     

Differential, multihormonal regulation of the mouse major urinary protein gene family in the liver.

The hormonal requirements for the regulation of the major urinary protein (MUP) mRNA levels in mouse liver have been examined. Previous experiments have shown that administration of testosterone to female or castrated male mice increases MUP mRNA levels approximately fivefold to normal male levels. We have found that thyroxine and the peptide hormone, growth hormone, each had a pronounced effect on MUP mRNA levels. MUP mRNA was reduced 150-fold in growth-hormone-deficient mutant mice (little). The administration of growth hormone and thyroxine induced MUP mRNA approximately 150-fold, and when administered together, they induced MUP mRNA approximately 1,000-fold. testosterone administration. When administered separately to these mice, growth hormone and thyroxine induced with MUP mRNA approximately 150-fold, and when administered together, they induced MUP mRNA approximately 1,000-fold. Testicular feminized mice, which lack a functional major testosterone receptor protein, can also be induced to male levels by treatment with both growth hormone and thyroxine. In addition, we present evidence which indicates that growth hormone, thyroxine, and testosterone differentially regulate the levels of distinct MUP mRNA species.     

mRNA synthesis rates in vivo for androgen-inducible sequences in mouse kidney.

A method was developed for measuring in vivo rates of mRNA synthesis in mice by pulse-labeling with the RNA precursor [3H]orotate and then using hybridization to recover specific mRNAs. The efficiency of recovery is determined with synthetic RNAs as internal hybridization standards. The method is particularly applicable to the kidney since this organ shows a strong preferential uptake of the label. Rates of synthesis, expressed as a fraction of total RNA synthesis, were measured for the androgen-inducible mRNAs coding for beta-glucuronidase (GUS), ornithine decarboxylase (ODC), the protein coded by the RP-2 gene, and the so-called kidney androgen-regulated protein (KAP). Control mRNAs coded for beta-actin, phosphoenolpyruvate carboxykinase, and major urinary protein. Testosterone markedly increased the synthesis of the androgen-inducible mRNAs, but not the control mRNAs. Induction was not seen in mutant mice lacking functional androgen receptor protein. For GUS, ODC, and RP-2 mRNAs, the fold induction of synthesis was less than the fold induction of concentration, suggesting that mRNA stabilization also plays a part in the response to androgen. For GUS, ODC, and RP-2 mRNAs, but not KAP mRNA, induction of synthesis was rapidly reversed after testosterone removal. KAP mRNA was also exceptional in that its concentration was disproportionately high compared with its rate of synthesis, implying that it is a particularly stable mRNA.     

Effects of castration and sex steroids on sexually dimorphic development of the mouse submandibular gland

The aims of this study were to characterize sexual dimorphism in the submandibular glands of young adult mice and to determine how sex differences arise during postnatal development. In the mouse submandibular glands, prominent sexual dimorphism was observed at 30 days of age, when the male gland was superior in both the relative occupied area (ROA) and the mitotic rate of the granular convoluted tubules (GCT) to those of the female. By neonatal castration, this sexual dimorphism was abolished, and the intraglandular structures of castrated males were similar to those of normal females. In castrated mice of both sexes, daily treatment with testosterone and 5 alpha-dihydrotestosterone for 10 days from 20 days induced only the ROA of the GCT to increase to the normal male levels but not those of the other three regions of the glands, the acini, intercalated ducts and excretory striated ducts. Testosterone responsiveness of the glands, considering both the glandular weight gain and the mitotic rate of the GCT, was significantly higher in castrated males than in castrated females. On the other hand, 17 beta-estradiol had no effect on the glands of castrated mice. Therefore, the present study suggests that the testicular hormones are responsible for the masculine development of GCT of the glands, but not the ovarian hormones, and that there is a sex difference in the responsiveness of the glands to testosterone, which is more effective in males than in females.     

Kidney androgen-regulated protein interacts with cyclophilin B and reduces cyclosporine A-mediated toxicity in proximal tubule cells

The gene for kidney androgen-regulated protein (KAP) is the most abundant and specific gene expressed in mouse kidney proximal tubule cells, where it is tightly regulated by steroid and thyroid hormones in different tubule segments. Despite the cell-specific expression, strict regulatory mechanisms, and relative abundance, nothing is known of the function of its encoded protein, which does not exhibit known structural or functional domains, or homologies with other sequences in the data bases. We raised monoclonal antibodies against KAP, which specifically recognize a protein with an apparent molecular mass of 20 kDa in crude kidney homogenates, the distribution and regulation of which parallel that of its mRNA. To gain insight into its function, we performed a yeast two hybrid screen and determined that KAP specifically interacts with cyclophilin B. Furthermore, cyclosporine A (CsA)-treated mice exhibited a significant decrease in KAP levels, and tetracycline-controlled overexpression of KAP in stably transfected proximal tubule cells significantly decreased the toxic effects of CsA. Taken together, these results indicate a functional relationship among KAP-, cyclophilin B-, and CsA-mediated nephrotoxicity and suggest an important role of KAP in renal physiology, providing new data on the molecular mechanisms implied in the toxic effects of CsA.     

A floxed allele of the androgen receptor gene causes hyperandrogenization in male mice.

We previously generated a conditional floxed mouse line to study androgen action, in which exon 3 of the androgen receptor (AR) gene is flanked by loxP sites, with the neomycin resistance gene present in intron 3. Deletion of exon 3 in global AR knockout mice causes androgen insensitivity syndrome, characterized by genotypic males lacking normal masculinization. We now report that male mice carrying the floxed allele (AR(lox)) have the reverse phenotype, termed hyperandrogenization. AR(lox) mice have increased mass of androgen-dependent tissues, including kidney, (P < 0.001), seminal vesicle (P < 0.001), levator ani muscle (P = 0.001), and heart (P < 0.05). Serum testosterone is not significantly different. Testis mass is normal, histology shows normal spermatogenesis, and AR(lox) males are fertile. AR(lox) males also have normal AR mRNA levels in kidney, brain, levator ani, liver, and testis. This study reaffirms the need to investigate the potential phenotypic effects of floxed alleles in the absence of cre in tissue-specific knockout studies. In addition, this androgen hypersensitivity model may be useful to further investigate the effects of subtle perturbations of androgen action in a range of androgen-responsive systems in the male.     

Testosterone and GHRH gene expression in adult and old rats

The effect of castration and testosterone replacement on GHRH gene expression was evaluated in adult male rats. Castration for 21 days did not affect GHRH mRNA levels, and also ineffective in this context was acute or chronic administration of testosterone to castrated rats. Hypothalamic GHRH mRNA was significantly reduced in aged male rats, but restoration of plasma testosterone concentrations via implanted capsules did not modify the low levels of GHRH mRNA. All in all, these findings support the notion that in adult and aged male rats GHRH-producing structures are insensitive to androgens.     

Unique patterns of androgen regulation of the expression of two genes in murine kidney

The kidneys of androgen stimulated mice exhibit a hypertrophic response but no hyperplasia or concomitant DNA replication. Androgens increase the expression of several genes in mouse kidney. The response of the beta-glucuronidase gene to testosterone in this tissue is characterized by a 1-2 day lag and relatively slow induction kinetics. The gene coding for kidney androgen-regulated protein (KAP) exhibits quite a different response to the hormone when compared on the basis of initial response to a given dose, dose required to produce maximal response, and apparent sensitivity to low levels of androgen-receptor complexes in renal nuclei. The analysis of the accumulation of the mRNAs produced by these two genes suggests that gene-specific differential sensitivity to androgen receptor complexes governs the development of the cellular male phenotype in this tissue.     

A sex-limited serum protein variant in the mouse: Hormonal control of phenotypic expression

The sex-limited protein (Slp) antigen of the mouse is first detected in the serum of strain DBA/2J males at 5–6 weeks of age and reaches full adult levels by 10 weeks. This antigen is normally absent in females. Immature DBA/2J males castrated at 3 1/2 weeks of age failed to develop Slp antigen, while DBA/2J females treated with testosterone propionate starting at 3 1/2 weeks developed normal adult male levels of Slp antigen. Similar hormone-influenced effects were demonstrated in adult males and females of the same strain. Experiments indicated that testosterone does not act directly in the serum to expose Slp antigenic sites. Testosterone treatment of both males and females of strain C57BL/10JSf, which does not carry the gene for the presence of the Slp antigen, failed to stimulate the appearance of the antigen. Thus, the presence of Slp antigen in the serum is dependent on both the proper genotype and the presence of male hormone.Supported by U.S.P.H.S. Research Grant GM-15419, U.S.P.H.S. Training Grant 2T01-GM-00071 (H.C.P.), and U.S.P.H.S. Career Development Award K3-HE-24,980 (D.C.S.).     

Endogenous testosterone increases L-type Ca2+ channel expression in porcine coronary smooth muscle

Evidence indicates that gender and sex hormonal status influence cardiovascular physiology and pathophysiology. We recently demonstrated increased L-type voltage-gated Ca2+ current (ICa,L) in coronary arterial smooth muscle (CASM) of male compared with female swine. The promoter region of the L-type voltage-gated Ca2+ channel (VGCC) (Cav1.2) gene contains a hormone response element that is activated by testosterone. Thus the purpose of the present study was to determine whether endogenous testosterone regulates CASM ICa,L through regulation of VGCC expression and activity. Sexually mature male and female Yucatan swine (7-8 mo; 35-45 kg) were obtained from the breeder. Males were left intact (IM, n=8), castrated (CM, n=8), or castrated with testosterone replacement (CMT, n=8; 10 mg/day Androgel). Females remained gonad intact (n=8). In right coronary arteries, both Cav1.2 mRNA and protein were greater in IM compared with intact females. Cav1.2 mRNA and protein were reduced in CM compared with IM and restored in CMT. In isolated CASM, both peak and steady-state ICa were reduced in CM compared with IM and restored in CMT. In males, a linear relationship was found between serum testosterone levels and ICa. In vitro, both testosterone and the nonaromatizable androgen, dihydrotestosterone, increased Cav1.2 expression. Furthermore, this effect was blocked by the androgen receptor antagonist cyproterone. We conclude that endogenous testosterone is a primary regulator of Cav1.2 expression and activity in coronary arteries of males.     

Effect of antiandrogen cyproterone acetate on the action of testosterone on mouse kidney.

The loss of endogenous testosterone in castrated male mice leads to a marked decrease in seminal vesicle and kidney tissue weight. 21 days' administration of exogenous testosterone abolished the effect of castration on the seminal vesicles and kidney tissue. The antiandrogen cyproterone acetate produced significant changes in the target tissue for androgens, i.e. in the seminal vesicles. In every case it blocked the action of both exogenous and endogenous testosterone on the seminal vesicles, but failed to block the "renotropic" action of testosterone, expressed as relative kidney weight. Contrary to its effect on the seminal vesicles, it did not influence relative kidney weight in normal animals. It likewise did not block the effect of exogenous testosterone on kidney tissue. The mechanism of the action of cyproterone acetate in androgen-dependent tissues is known to consist in inhibition of androgen binding to specific cell receptors in the target tissues. Some of the specific androgen receptors in mouse kidney are evidently different in character from those in the accessary sex glands, that being the reason why cyproterone acetate has an antiandrogenic, but not an antirenotropic effect. In agreement with experiments on rats, adrenal weight also decreases in mice after the administration of cyproterone acetate.