Sexually dimorphic duct system of the submandibular gland in mouse with testicular feminization mutation (Tfm/Y).

The X-linked testicular feminization mutation (Tfm/Y) in the mouse is characterized by androgen insensitivity of the target cells. The aim of this study was to examine sexually dimorphic development of the submandibular gland of Tfm/Y mutant mice in comparison with those of wild-type male, wild-type female and heterozygous Tfm female mice. In either 30- or 90-day-old wild-type male mice, the granular convoluted tubules (GCT) of the glands were more developed, and the relative occupied areas (ROA) of GCT were superior to those of the age-matched wild-type and heterozygous Tfm females. In androgen-insensitive Tfm/Y mice, the glandular structures rather resembled the female glands, showing lower values of the ROA of the GCT. Sex differences in the mitotic rate were observed at 30 days of age, being significantly higher in the wild-type male GCT than in the female GCT. Thereafter, the mitotic rate of the wild-type male GCT declined to the female levels by 90 days of age. The mitotic rate of GCT in Tfm/Y mutants was as low as those of the females during observation periods. An other three regions, the acini, the intercalated ducts and the excretory striated ducts, were not significantly different in either the ROA or the mitotic rate among wild-type males and females, and Tfm/Y. On the other hand, either the ROA or the mitotic activity of GCT of the glands in Tfm/Y mutants was completely unaffected by 5 alpha-dihydrotestosterone (DHT).(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic and molecular evidence of an X-chromosome deletion spanning the tabby (Ta) and testicular feminization (Tfm) loci in the mouse

A new radiation-induced mutation in the mouse, tabby-25H (Ta25H), has proved to be a deletion which spans both the tabby and testicular feminization (Tfm) loci on the X chromosome. The Ta phenotype closely resembles that of the original TaFa mutation in both the heterozygous and hemizygous conditions but Ta25H/Y animals additionally show the Tfm/Y phenotype, being externally female but possessing abdominally located testes. There is a shortage of both Ta25H/+ and Ta25H/Y classes relative to their normal sibs among the progeny of Ta25H/+ females at weaning age and this was indicated to be due to prenatal or neonatal losses. Exencephaly was observed in some members of both classes prior to birth. Both Ta25H classes tend to be runted at weaning but, remarkably, Ta25H/+ females often show a range of abnormalities not evident in Ta25H/Y animals. When probes for the Zfx, Ccg-1, Phk, and DXPas19 loci, which lie close to Ta, were hybridised to DNAs from Ta25H hemizygotes, the profiles of the X-linked bands were similar to those of control DNAs, suggesting these loci lie outside the deletion. However, a clear absence of an X-linked band was found with human androgen receptor probes, indicating that the Tfm locus is indeed missing. The deletion, therefore, extends a minimum of 1.5 cM and, with its proximal and distal boundaries partially defined, it could be as large as 4 cM. As Ta25H/+ females show the striped X-inactivation coat pattern, the putative X-inactivation centre, Xce, which lies close to Ta, cannot be located within the region deleted. The greasy (Gs) locus similarly appears to lie outside the deletion.     

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.     

High somatic mutation frequencies in a LacZ transgene integrated on the mouse X-chromosome

To study spontaneous and induced mutagenesis in vivo we recently constructed a series of transgenic mice harboring different numbers of bacteriophage lambda shuttle vectors, provided with a LacZ mutational target gene, integrated in their genome. The transgenic mice enabled analysis of spontaneous and induced mutation frequencies in postmitotic tissues like liver and brain. The obtained data indicated spontaneous mutation frequencies in the order of ⁻⁵ - 10⁻⁶. Here we report a 25–100 times higher spontaneous mutation frequency in liver and brain DNA of mice from strain 35.5, with the lambda-gt10LacZ concatemer integrated on the X-chromosome. These results indicate the presence of a mutational ‘hot spot’ in the mammalian somatic genome in vivo.     

TfM mutation and masculinization versus feminization of the mouse central nervous system

The sexual behavior of mice of various genotypes has been studied in our stock in which X-linked genes, Tfm and (O^hv), as well as an autosomal dominant gene, Sxr, are maintained. Since the absence of neonatal imprinting in Tfm (O^hv)/Y^ leads to no sexual behavior, we conclude that neonatal imprinting is the prerequisite for feminization as well as masculinization of the central nervous system. Since individual components of sexual behavior may become feminine or absent instead of being masculine in sex-reversed Tfm (O^hv)/+(O⁺, Sxr/+^♂ with mosaic brains, we conclude that neonatal imprinting directly involves individual neurons, and that different degrees of imprinting by the same agent lead to masculinization or feminization. In accordance with recent views, we believe estradiol to be this imprinting agent.We envisage the role of the Tfm locus in the central nervous system as follows: within individual neurons for sexual behavior, the synthesis of aromatizing enzymes is normally inducible by androgens; these enzymes are therefore noninducible in Tfm (O^hv)/Y^. In normal neonates, exposure to testosterone leads to the induced intracellular conversion of testosterone to estradiol, self imprinting by estradiol causing masculinization. Feminization may normally be due to the direct exposure of these neurons to a low circulating concentration of estradiol. An alternative explanation might be that the estradiol-receptor protein in these neurons also is normally inducible by testosterone. In this case, neonatally testosterone-exposed neurons would become inherently more responsive to estradiol than neonatally estradiol-exposed neurons.     

A mutation in mouse rad51 results in an early embryonic lethal that is suppressed by a mutation in p53.

RecA in Escherichia coli and its homolog, ScRad51 in Saccharomyces cerevisiae, are known to be essential for recombinational repair. The homolog of RecA and ScRad51 in mice, MmRad51, was mutated to determine its function. Mutant embryos arrested early during development. A decrease in cell proliferation, followed by programmed cell death and chromosome loss, was observed. Radiation sensitivity was demonstrated in trophectoderm-derived cells. Interestingly, embryonic development progressed further in a p53 null background; however, fibroblasts derived from double-mutant embryos failed to proliferate in tissue culture.     

The role of the hypophysis and the hypophyseal hormone prolactin in maintenance of the sexual specificity of the metabolism of testosterone and 5-alpha-dihydrotestosterone in rat liver slices]

Hypophysectomy of rats 55 days after birth causes profound changes in the sexually differentiated liver metabolism of testosterone and 5alpha-dihydrotestosterone, which were studied when the rats were 80 days old. 1. Metabolism of testosterone after hypophysectomy: The turnover of testosterone decreased significantly to the same level in both sexes. The effect was especially marked in the female, which normally has a high turnover of this compound. The sexual differences in the patterns of metabolites were also lost, owing to the following changes: In the male, the high level of metabolites of the 3beta-hydroxy-5alpha-androstane type falls to the low level found in the female controls. The low level of 4-androstene-3,17-dione in the female increases to the high level found in the male controls. The concentrations of testosterone increase and those of the metabolites of the 3-oxo- and 3alpha-hydroxy-5alpha-androstane decrease to values that are significantly much higher or lower, respectively, than the normal values found in the control animals. 2. Metabolism of 5alpha-dihydrotestosterone after hypophysectomy: In comparison with the controls, the turnover of this substrate is significantly decreased by the same factor in both sexes; thus the difference between the sexes persists. In the pattern of metabolites, the sexual differences are still apparent, but less marked. The levels of metabolites show two opposing changes: a significant increase in the concentration of 3beta-hydroxy metabolites, and a significant decrease in the concentration of 3alpha-hydroxy metabolites; although the activity of the microsomal 3alpha-hydroxysteroid dehydrogenase increases by a factor of 3 - 4 in both sexes after hypophysectomy[1]. This discrepancy indicates a compartmentalization of androgen metabolism in the liver cell, in which delta4-5alpha- and 3beta-hydrogenation occur on the membranes of the endoplasmic reticulum, whereas 3alpha-hydrogenation occurs in the cytosol. 3. Action of prolactin on the metabolism of testosterone in hypophysectomized animals: Prolactin (125 mug twice daily from the 70th to the 79th day of life) causes a significant acceleration of the delta4-5alpha-hydrogenation, which is recognized as a significant increase in the concentrations of 5alpha-androstane metabolites; the 3beta-hydroxy compounds in both sexes reach the normal level of male control animals. The significant increase in the concentration of 3alpha-hydroxy compounds is accompanied by a partial reestablishment of the sexual differences. The sex differences in androgen turnover and metabolite pattern are subject to a hypophyseal regulation, which is separate from the gonadotropic partial function. The hydroxylation activity of the liver, measured as the production of C19O3-steroids, is not significantly affected by hypophysectomy or by treatment with prolactin.     

Mice with the testicular feminization mutation demonstrate a role for androgen receptors in the regulation of anxiety-related behaviors and the hypothalamic-pituitary-adrenal axis

Testosterone (T) appears to play a role in anxiety and sensorimotor gating in rodents, but whether T acts through the androgen receptor (AR) to influence these behaviors is less clear. We compared adult genetic male mice with the testicular feminization mutation (Tfm), which lack functional ARs, to wild type male littermates (wt males) on an assay of sensorimotor gating (prepulse inhibition of the acoustic startle response; PPI) and several tests thought to reflect anxiety: open field exposure, novel object exposure, elevated plus maze (EPM), and light/dark (LD) box. PPI was similar between groups, but indices of anxiety in the novel object and LD box tests were increased in Tfm males with no significant differences found in the open field or EPM. Since Tfm male mice have decreased circulating T, the same tests were conducted in mice that were gonadectomized (wt males) or sham-operated (Tfm males) as adults and supplemented with T or nothing (B). While T treatment reduced indices of anxiety in the novel object and LD box tests in wt males, it was ineffective in Tfm males. Increased indices of anxiety in Tfm males appear to be related to hyper-activation of the hypothalamic–pituitary–adrenal axis since levels of the stress hormone corticosterone were elevated in Tfm males compared to wt males at baseline and at several time points after exposure to a novel object. These findings demonstrate that ARs influence anxiety and stress responses in mice.     

Maternal meiosis II nondisjunction in a case of 47,XXY testicular feminization

Summary An 11-year-old patient with incomplete testicular feminization and a 47,XXY karyotype is described. The patient had female external genitalia, clitoromegaly, and some features of Klinefelter's syndrome, including speech delay and delayed intellectual development. DNA analysis using X chromosomal DNA sequences suggests that the supernumerary X chromosome in the patient resulted from maternal nondisjunction during meiosis II. The M II error thereby provides the basis for homozygosity of a mutation in the androgen receptor locus.