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.     

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.     

Steroid regulation of kidney histidine decarboxylase and ornithine decarboxylase levels in mouse kidney: effects of the mutation testicular feminization, Tfm

1. Testosterone represses kidney histidine decarboxylase levels in both normal male and female mice. Tfm/Y mutant mice lack an androgen receptor and are phenotypically female. It has been suggested that the testosterone induction of HDC levels in these animals is a result of aromatisation to oestrogens in the absence of the androgen receptor; the oestrogens then induce the enzyme. 2. It is shown that the induction of HDC in Tfm/Y mice is specific to testosterone and not other androgens and can be mimiced by low doses of beta-oestradiol in normal female mice. 3. Analysis of Tfm/+ mice indicates that the testosterone induction effect is a function of individual kidney cells.     

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.     

An abundant androgen-regulated mRNA in the mouse kidney.

We have identified an abundant 20,000 dalton protein (KAP) by in vitro translation of male mouse kidney mRNA. This protein is synthesized in reduced amounts from female kidney mRNA. A KAP cDNA fragment was purified and used for nucleic acid hybridization studies. Females and castrated males have 10 and 200 fold lower levels, respectively, of KAP mRNA relative to males. The administration of testosterone to females or castrated males results in the induction of KAP mRNA to normal male levels. Testicular feminized (Tfm) mice have 3 fold lower levels of KAP mRNA relative to normal males and are not induced by testosterone. KAP mRNA is not found in significant amounts in tissues other than the kidney, and the KAP gene renatures with kinetics similar to single-copy DNA. With the rapidly expanding knowledge of mouse genetics, KAP should prove useful in determining genetic factors which regulate the inducibility and tissue specificity of a hormonally regulated gene.     

Genomic organization and DNA sequence of the mouse kidney androgen-regulated protein (KAP) gene

The gene for kidney androgen-regulated protein (KAP) is expressed under androgenic control in the epithelial cells of the renal cortical proximal tubules. However, there is an androgen-independent component of the expression of this gene that occurs specifically in the outermedullary S3 segments of the proximal tubules. In these cells, the KAP gene is estrogen responsive and its expression is dependent on pituitary function. As a first step in correlating its interesting cell-specific and hormonal regulation with the structure of the gene, the genomic organization of the KAP gene was described and sequence of the gene and the proximal 1 kb of 5'-flanking DNA was determined. Sequence motifs were identified in the 5'-flanking DNA that may function in the regulation KAP gene expression by androgen, estrogen, and pituitary glycoprotein hormones. The gene is present in a single copy in the mouse genome and is 3,807 nucleotides in length. It contains 4 exons of 120, 177, 63, and 251 nucleotides and three intervening sequences of 1,450, 126, and 1,620 nucleotides. The gene exhibits a high degree of a genetic polymorphism as revealed by comparison of restriction digests of DNA from two highly inbred strains, BALB/c and C57BL/6.     

Mandible shape analysis in a testicular feminization (Tfm) strain of mice.

The role of androgens on the sexual dimorphism of mandible shape was investigated in mice carrying the X-linked gene for testicular feminization (Tfm), which is known to determine a profound insensitivity to testosterone and is associated with a severe reduction in androgen receptor levels in Tfm/Y males. Mandible shape analysis in an inbred strain of mice segregating for the Ta (tabby) and Tfm mutations showed that the sexual dimorphism observed between +Ta/+Ta females and +Ta/Y males almost disappeared between Tfm+/+Ta females and Tfm+/Y males. In addition, a canonical discriminant analysis showed that these two closely related classes, Tfm+/+Ta and Tfm+/Y, are readily differentiated from both the +Ta/+Ta and +Ta/Y classes. These results suggest that androgens are involved in the mandible shape sexual dimorphism and play a role in mandibular development in both males and females.     

Genetic variation in androgen regulation of ornithine decarboxylase gene expression in inbred strains of mice

Previous studies have indicated that androgen regulation of certain gene products in murine kidney is genetically controlled. In the present work, the expression of renal ornithine decarboxylase (ODC) gene(s) was used as a biological marker to study androgen responsiveness of eight inbred strains of mice (A/J, C57BR/cdJ, 129/J, C57L/J, BALB/cJ, SM/J, RF/J, and C57BL/6J). Kidneys of untreated females from these strains did not have significantly different basal ODC activities or ODC mRNA concentrations. However, renal enzyme concentrations in intact male mice exhibited marked strain-dependent variation; three strains (RF/J, SM/J, and C57BR/cdJ) had 5- to 20-fold higher activities than the other five strains. Renal ODC mRNA content showed similar genetic variability in the male mice; animals with highest enzyme activity had higher mRNA levels than those with low activity. These results could not be explained by differences in either serum testosterone levels or renal nuclear androgen receptor content, suggesting that the animals were differentially sensitive to endogenous androgens. To evaluate further the androgen regulation of ODC gene expression, female mice were treated with testosterone-releasing implants for 5-7 days. The two strains (A/J and C57BL/6J) that had low enzyme activity in response to endogenous testosterone in male mice also showed blunted responses to exogenous androgen administration, as measured by the induction of ODC and its mRNA. The relative distribution of the two mRNA species coding for ODC (2.2 and 2.7 kb in size) exhibited strain-dependent variation that did not, however, correlate with the androgen responsiveness. Studies of the mRNA levels in reciprocal F1 hybrids of C57BR/cdJ and C57BL/6J mice suggested that androgen sensitivity of ODC gene expression, at least in these crosses, was inherited in an autosomal dominant manner.     

CCAAT/enhancer binding protein-mediated role of thyroid hormone in the developmental expression of the kidney androgen-regulated protein gene in proximal convoluted tubules

The kidney androgen-regulated protein (KAP) gene is exclusively expressed in proximal tubules of mouse kidney and in the uterus of pregnant females before they give birth. It displays an exquisite and differential regulation of expression by steroid and thyroid hormones (THs) in different proximal tubule segments. Whereas the pars recta (PR cells) responds to thyroid and sexual hormones, the pars convoluta (PCT cells) represents a truly androgen-dependent compartment because expression occurs only in the presence of androgens and functional androgen receptors. Nevertheless, different hypothyroidism models have indicated that TH might also contribute to the androgenic response in PCT cells. In the present study, we aimed to determine the molecular mechanisms that ultimately control KAP expression in these cells. Using several genetically deficient mouse models and different pharmacologic and hormonal treatments, we determined that thyroid and GH modulate CCAAT/enhancer binding protein alpha and beta levels that, in turn, control KAP expression in PCT cells in a developmentally dependent manner. We demonstrated that these factors bind to sites in the proximal KAP promoter, thereby collaborating with androgens for full KAP expression. Finally, we propose that TH and GH, acting through CCAAT/enhancer binding protein, may constitute a general regulatory mechanism of androgen-dependent genes in mouse kidney.     

KAP degradation by calpain is associated with CK2 phosphorylation and provides a novel mechanism for cyclosporine A-induced proximal tubule injury

The use of cyclosporine A (CsA) is limited by its severe nephrotoxicity that includes reversible vasoconstrictor effects and proximal tubule cell injury, the latter associated whith chronic kidney disease progression. The mechanisms of CsA-induced tubular injury, mainly on the S3 segment, have not been completely elucidated. Kidney androgen-regulated protein (KAP) is exclusively expressed in kidney proximal tubule cells, interacts with the CsA-binding protein cyclophilin B and its expression diminishes in kidneys of CsA-treated mice. Since we reported that KAP protects against CsA toxicity in cultured proximal tubule cells, we hypothesized that low KAP levels found in kidneys of CsA-treated mice might correlate with proximal tubule cell injury. To test this hypothesis, we used KAP Tg mice developed in our laboratory and showed that these mice are more resistant to CsA-induced tubular injury than control littermates. Furthermore, we found that calpain, which was activated by CsA in cell cultures and kidney, is involved in KAP degradation and observed that phosphorylation of serine and threonine residues found in KAP PEST sequences by protein kinase CK2 enhances KAP degradation by calpain. Moreover, we also observed that CK2 inhibition protected against CsA-induced cytotoxicity. These findings point to a novel mechanism for CsA-induced kidney toxicity that might be useful in developing therapeutic strategies aimed at preventing tubular cell damage while maintaining the immunosuppressive effects of CsA.     

Intact testosterone receptor complex does not induce RNA synthesis of tfm-nuclei in multinucleated urethral muscle fibres of mosaic mice

Summary The X-linked testicular feminization mutation (Tfm) of the mouse leads to androgen insensitivity of target cells. Through the autosomal sex reversed (Sxr) factor we have converted female heterozygotes into males. Due to X-inactivation, mosaic animals arise which are composed of androgen sensitive wild-type and androgen insensitive Tfm cells. In the androgen dependent striated urethral muscle, Tfm and wild-type cells fuse and form multinucleated muscle fibres. In the muscle fibres the Tfm nuclei are exposed to the intact cytoplasmic testosterone receptor complex coded for by the wildtype nuclei. We ask the question whether under these conditions RNA synthesis can be stimulated in the Tfm nuclei. Castrated mosaic animals were injected with testosterone, and incorporation of ³H-uridine was studied by autoradiography. We found two classes of muscle cell nuclei, those with low grain counts corresponding to the Tfm controls and those with high grain counts corresponding to the stimulated male controls. The results indicate that the Tfm nuclei are not stimulated by the intact testosterone receptor complex.This study is dedicated to Prof. Dr. W. Graumann on occasion of his 65th birthday     

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.     

Autoradiographic studies with 3H dihydrotestosterone in the brain of sex reversed mice,heterozygous for androgen insensitive testicular feminization (Tfm)

Summary Specific binding sites for ³H dihydrotestosterone are demonstrated by autoradiography in brain nuclei of sex reversed mice heterozygous for testicular feminization (Tfm) which are phenotypically intersexes with testes and accessory sex glands that consist of a mosaic of androgen insensitive Tfm cells which lack specific dihydrotestosterone binding and androgen sensitive normal cells. The nuclear group evaluated include: nucleus (n.) septi lateralis, n. interstitialis striae terminalis, n. medialis amygdalae, the hypothalamic n. arcuatus, n. ventromedialis lateralis, n. premammillaris ventrialis, n. preopticus medialis, and nuclei of the cranial nerves VII, X, and XII. In the sex reversed males and the female, used as controls, the frequency of neurons with specific DHT binding show a distinct male-female difference in the caudal part of the arcuate nucleus. In the sex reversed Tfm heterozygotes, in all brain nuclei studied, the frequency of labeled neurons is reduced. The extent of reduction of androgen binding in the different brain nuclei varies among as well as within individual sex reversed Tfm heterozygotes, suggesting variations of the ratio of normal to Tfm neurons in sex reversed Tfm heterozygotes. The differentially reduced androgen binding of different brain systems corresponds to a differentially reduced androgen dependent behaviour reported in the literature.Supported by US PHS grant NSO9914 to W.E.S. and Deutsche Forschungsgemeinschaft Dr94/4 to U.D.. The work of Dr. Schleicher and his stay in Chapel Hill were sponsored by Studienstiftung des Deutschen Volkes and Boehringer-Ingelheim Fonds     

Beta-glucuronidase activity is present in the microscopic epididymis of the Tfm/Y mouse

The sex-linked recessive gene Tfm in the mouse produces a condition of testicular feminization (androgen insensitivity syndrome, AIS) in hemizygotes, comparable to the condition of the same name in humans. The murine mutant was originally believed to have no derivatives of the mesonephric duct system (MDS), and this absence was ascribed to dependence of these derivatives on androgens for survival. However, microscopical epididymides, retia testes, and vasa deferentia were identified in these animals in our laboratory. These micro-organs may play a role in meiosis induction in Tfm/Y animals. The present study was designed to determine whether survival of these organs is due to retention of an ability to respond to androgens, or whether they are unique amongst MDS derivatives in being independent of androgens. Previous studies in our laboratory demonstrated that the enzyme beta-glucuronidase (beta G) is androgen sensitive in the epididymis of the normal mouse. In the present investigation we used this enzyme as a marker to study androgen sensitivity in the microscopical epididymides of Tfm/Y hemizygotes and in the epididymides of control +/Y litter-mate brothers. Both mutant and control animals were studied with and without exogenous androgen stimulation. Tfm/Y hemizygotes demonstrated low levels of diffuse, cytoplasmic beta G activity that appears to be unresponsive to exogenous androgen stimulation. In light of our previous studies, this distribution of beta G reaction products suggests some degree of androgen sensitivity. The survival of these micro-organs and their partial androgen sensitivity may be related to the role of the MDS in inducing meiosis.     

Differentiation between androgen and estrogen receptor mediated effects of testosterone on FSH using androgen receptor deficient (Tfm) and normal mice

The comparison of normal and androgen receptor (AR) deficient Tfm-mice allows distinction between AR mediated and estrogen receptor (ER) mediated effects of testosterone (T)--the latter after aromatization of T to estrogens--on serum and pituitary FSH. Normal male and female as well as Tfm mice were gonadectomized after 8 days and treated for 11 days with either T, estradiol (E2) or vehicle. Serum and pituitary FSH was determined by RIA for rat FSH. In Tfm mice T caused a suppression of serum FSH, indicating an ER mediated effect. Lower serum FSH levels after T in normal mice than Tfm mice indicate an additional AR mediated suppression. Lower serum FSH values in E2 treated Tfm than in T treated Tfm mice--where T acts only through ER--suggest two classes of estrophilic cells: one which aromatizes, thus being susceptible for both T and E2, and the other which does not aromatize. Only AR but not ER mediated T effects on pituitary FSH could be demonstrated.     

Autoradiographic studies with 3H dihydrotestosterone in the brain of sex reversed mice, heterozygous for androgen insensitive testicular feminization (Tfm). A comparison with normal female mice and sex reversed male mice

Specific binding sites for 3H dihydrotestosterone are demonstrated by autoradiography in brain nuclei of sex reversed mice heterozygous for testicular feminization (Tfm) which are phenotypically intersexes with testes and accessory sex glands that consist of a mosaic of androgen insensitive Tfm cells which lack specific dihydrotestosterone binding and androgen sensitive normal cells. The nuclear group evaluated include: nucleus (n.) septi lateralis, n. interstitialis striae terminalis, n. medialis amygdalae, the hypothalamic n. arcuatus, n. ventromedialis lateralis, n. pre-mammillaris ventralis, n. preopticus medialis, and nuclei of the cranial nerves VII, X, and XII. In the sex reversed males and the female, used as controls, the frequency of neurons with specific DHT binding show a distinct male-female difference in the caudal part of the arcuate nucleus. In the sex reversed Tfm heterozygotes, in all brain nuclei studied, the frequency of labeled neurons is reduced. The extent of reduction of androgen binding in the different brain nuclei varies among as well as within individual sex reversed Tfm heterozygotes, suggesting variations of the ratio of normal to Tfm neurons in sex reversed Tfm heterozygotes. The differentially reduced androgen binding of different brain systems corresponds to a differentially reduced androgen dependent behaviour reported in the literature.