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.     

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.     

Susceptibility to db gene and streptozotocin-induced diabetes in C57BL mice: control by gender-associated,MHC-unlinked traits

H-2 haplotype differences distinguish the related C57BL/KsJ (BKs) and C57BL/6J (B6) inbred strains. BKs mice are more susceptible to diabetes induction by a recessive obesity gene, diabetes (db), or by multi-dose streptozotocin (MSZ) administration. The purpose of this study was to evaluate whether the H-2 differences were the important genetic background modifiers determining inbred strain susceptibility or resistance to these diabetogenic stresses. Diabetes susceptibility of BKs.B6-H-2 ^b congenic mice was compared with that of the parental BKs and B6 stocks. In addition, diabetes severity was studied in (B6 × BKs)F₁ and F₂ db/db mice and an H-2 segregation analysis was performed. BKs susceptibility genes expressed in a dominant fashion in the F₁ generation, and were transmitted to F₂ db/db males without apparent segregation. No association between H-2 ^b haplotype and B6-type diabetes resistance was found in response to either the db mutation or to MSZ. Insulitis, associated with development of hyperglycemia in BKs males, also occurred in the H-2 ^b congenic stock. However, an apparent interaction between H-2 ^b haplotype, the db mutation (on chromosome 4), and male gender (Y chromosome?) was indicated by a segregation ratio distortion in recovery of this genotype. A more moderate diabetes in some F₂ db/db females suggested that non-MHC-linked genes controlling sex steroid metabolism were the important determinants of diabetogenic sensitivities in the C57BL stocks. In support of the latter, strain differences were demonstrated in activity levels of steroid sulfatase, which is regulated by a sex-linked gene likely expressed on both the X and Y chromosome, and which may control tissue levels of active androgens and estrogens. We show that the diabetes-susceptible F₁ hybrids exhibit the higher activity associated with the BKs strain.     

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)     

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     

Androgens, androgen receptors, and male gender role behavior

Studies of genetic males with single gene mutations that impair testosterone formation or action and consequently prevent development of the normal male phenotype provide unique insight into the control of gender role behavior. 46,XY individuals with either of two autosomal recessive mutations [17 beta-hydroxysteroid dehydrogenase 3 (17 beta-HSD3) deficiency or steroid 5 alpha-reductase 2 (5 alpha-R2) deficiency] have a female phenotype at birth and are raised as females but frequently change gender role behavior to male after the expected time of puberty. In contrast, genetic males with mutations that impair profoundly the function of the androgen receptor are also raised as females and have consistent female behavior as adults. Furthermore, the rare men with mutations that impair estrogen synthesis or the estrogen receptor have male gender role behavior. These findings indicate that androgens are important determinants of gender role behavior (and probably of gender identity) and that this action is mediated by the androgen receptor and not the result of conversion of androgen to estrogen. The fact that all genetic males with 17 beta-HSD3 or 5 alpha-R2 deficiency do not change gender role behavior indicates that other factors are also important determinants of this process.     

Reduced reproductive performance in androgen-resistant Tfm/Tfm female mice

Androgen-resistant female mice (Tfm/Tfm) homozygous for the mutant gene Tfm were bred by making use of males chimaeric for the Tfm gene. All seven Tfm/Tfm females found were fertile, confirming that a normal level of androgen receptor protein is not essential for reproduction in female mice. However, when five of the seven were studied throughout their reproductive life they proved to have impaired reproductive performance and premature cessation of reproduction. No impairment of reproduction was seen in heterozygous Tfm/+ females. The ovarian histology suggested that in Tfm/Tfm the normal ageing processes were accelerated. This work is consistent with the work of others in that androgen is involved in the control of follicular maturation and atresia, and that the effect is mediated by the androgen receptor coded by the Tfm locus.     

Specific morphogenetic events in mouse external genitalia sex differentiation are responsive/dependent upon androgens and/or estrogens

The objective of this study was to perform a comprehensive morphologic analysis of developing mouse external genitalia (ExG) and to determine specific sexual differentiation features that are responsive to androgens or estrogens. To eliminate sex steroid signaling postnatally, male and female mice were gonadectomized on the day of birth, and then injected intraperitoneally every other day with DES (200ng/g), DHT (1μg/g), or oil. On day-10 postnatal male and female ExG were dissected, fixed, embedded, serially sectioned and analyzed. We identified 10 sexually dimorphic anatomical features indicative of normal penile and clitoral differentiation in intact mice. Several (but not all) penile features were impaired or abolished as a result of neonatal castration. Those penile features remaining after neonatal castration were completely abolished with attendant clitoral development in androgen receptor (AR) mutant male mice (X(Tfm)/Y and X/Y AR-null) in which AR signaling is absent both pre- and postnatally. Administration of DHT to neonatally castrated males restored development of all 10 masculine features to almost normal levels. Neonatal ovariectomy of female mice had little effect on clitoral development, whereas treatment of ovariectomized female mice with DHT induced partial masculinization of the clitoris. Administration of DES to neonatally gonadectomized male and female mice elicited a spectrum of development abnormalities. These studies demonstrate that the presence or absence of androgen prenatally specifies penile versus clitoral identity. Differentiated penile features emerge postnatally and are sensitive to and dependent upon prenatal or pre- and postnatal androgen. Emergence of differentiated clitoral features occurs postnatally in either intact or ovariectomized females. It is likely that each penile and clitoral feature has a unique time-course of hormonal dependency/sensitivity.     

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.     

Variable onset determinants and consequences of diabetes (db/db) obesity mutation expression: adrenergic promotion of utero-ovarian dysfunction.

Expression of the diabetes ( db/db) genotype mutation in female C57BL/KsJ mice induces a complex diabetes-obesity syndrome (DOS) responsible for reproductive tract involution promoted by hypercytolipidemia (HCL). Current studies define the complex and influences of the endometabolic variables that promote reproductive tract involution at the time of initial db/db mutation expression onset in female C57BL/KsJ mice. Littermate-paired, normal ( +/?) and db/db groups were isolated between 2 - 4 weeks of age and tissue samples analyzed for utero-ovarian alterations induced by the systemic, tissue, cellular and structural consequences of mutation expression. Significantly elevated body weights, blood glucose concentrations and serum insulin levels contrasted with atrophic utero-ovarian indices in db/db mutants compared to +/? groups. The onset of the db/db-expression promoted obesity and a mild hyperglycemic-hyperinsulinemic state. Initial db/db expression was characterized by significantly increased utero-ovarian insulin binding without variation in membrane insulin receptor concentrations. However, significant elevations in tissue glucose sequestration rates, norepinephrine (NE) concentrations and triacylglyceride lipase activity in db/db groups indicated that a complex of endometabolic counter-regulatory influences promoted the metabolic shunting of excess glucose and triglyceride moieties towards hypercytolipidemic storage. The resulting DOS-promoted accumulation of utero-ovarian cytolipidemic pools compromised reproductive tract cytoarchitecture in db/db mice. The results of these studies indicate that the inability of utero-ovarian tissue compartments to exhibit metabolic adaptation to the enhanced availability, transport and cellular imbibition of extracellular glucose-lipid pools promotes the initial cellular compromise recognized to induce reproductive failure in db/db mutants.     

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.     

Effect of immunodeficiency on diabetogenesis in genetically diabetic (db/db) mice

The pathogenesis of diabetes in C57BL/KsJ-db/db mice has been proposed to entail autoimmune mechanisms. We have combined immunodeficiency genes with the db mutation to determine whether beta cell necrosis and establishment of severe diabetes would occur in the absence of normal T and/or B lymphocyte functions. Inbred mice carrying the recessive mutations, severe combined immunodeficiency (scid), X-linked immunodeficiency (xid), nude (nu), and the Y-linked autoimmune accelerator (Yaa), were crossed with strains congenic for the db mutation. The diabetes syndrome was studied in double homozygotes produced in the F2 generation. In another experiment, C57BL/KsJ-db/db males were made T cell function deficient by adolescent thymectomy followed by lethal irradiation and bone marrow reconstitution. None of these manipulations served to prevent the induction of a severe diabetes syndrome in any of the model systems analyzed. Thus, diabetogenesis characterized by massive necrosis of the pancreatic beta cells and atrophy of the pancreatic islets was observed in both the absence of normal T cell function (as assessed by absence of T cell mitogen response) and humoral autoimmunity against beta cell antigens (insulin, retroviral p73). In conclusion, our data indicate that anti-beta cell autoimmunity is not a primary event in the etiopathogenesis of diabetes in the db/db mouse.     

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.     

Androgen receptor in genital tubercle of rabbit fetuses and newborns. Ontogeny and properties

In newborn rabbits of both sexes, an androgen receptor was characterized in the genital tubercle. Homogenates exhibited high affinity (Kd was about 0.4 nM) and saturable binding of [3H]methyltrienolone. The half-life of the [3H]5 alpha-dihydrotestosterone-androgen receptor complex was 72 h at 4 degrees C. The receptor was inactivated by heat and pronase and the binding was specific for potent androgens. Sucrose gradient analysis revealed a 8-9 S [3H]methyltrienolone binding protein in cytosols from both sexes. Androgen binding, in the homogenate, was detected as soon as day 18 of gestation in both sexes and the number of binding sites increased until birth. During sexual organogenesis and at birth there were no major differences between males and females in the amount or affinity of androgen binding. Specific androgen binding was also detected in sexual ducts of male and female newborns.     

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.     

Male rats with the testicular feminization mutation of the androgen receptor display elevated anxiety-related behavior and corticosterone response to mild stress

Testosterone influences the hypothalamic–pituitary–adrenal axis, anxiety-related behavior, and sensorimotor gating in rodents, but little is known about the role of the androgen receptor (AR) in mediating these influences. We compared levels of the stress hormone corticosterone at baseline and following exposure to a novel object in an open field in wild type (wt) male and female rats, and male rats with the testicular feminization mutation (Tfm) of the AR, which disables its function. Basal corticosterone was equivalent in all groups, but exposure to a novel object in an open field elicited a greater increase in corticosterone in Tfm males and wt females than in wt males. Tfm males also showed increased behavioral indices of anxiety compared to wt males and females in the test. Analysis of the immediate early gene c-Fos expression after exposure to a novel object revealed greater activation in Tfm males than wt males in some regions (medial preoptic area) and lesser activation in others (dentate gyrus, posterodorsal medial amygdala). No differences were found in a measure of sensorimotor gating (prepulse inhibition of the acoustic startle response), although Tfm males had an increased acoustic startle response compared to wt males and females. These findings demonstrate that ARs play a role in regulating anxiety-related behaviors, as well as corticosterone responses and neural activation following exposure to a mild stressor in rats.     

Fine structure of submandibular glands of mice with testicular feminization (Tfm/Y)

Summary The fine structure of the submandibular gland of the mouse with testicular feminization (Tfm/Y) was studied by light and electron microscopy. The architecture of the Tfm/Y gland proved to be rather similar to that of the normal female mouse in both tubular ratio and structure. Granular convoluted tubular cells in Tfm/Y mice characteristically had fewer secretory granules and increased cytoplasmic vacuoles than normal littermates, suggesting an altered synthesis of secretory granules in this cell type of the Tfm/Y mouse. Moreover, there were differences in the ultrastructure of submandibular glands between Tfm/Y and normal female mice. In the gland of the Tfm/Y mouse, basal striations of the striated secretory tubular cells were not so developed and granular intercalated duct cells were less than those of normal females. These findings support the evidence that the secretory tubule of the mouse submandibular gland responds to androgens, resulting in accentuated development in the male, while also suggesting the possibility that the mouse submandibular gland is regulated by other factors which lead to the prominent sexual dimorphism observed in this gland.     

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.     

Gender- and androgen-related influence on the expression of proto-oncogene and apoptotic factor mRNAs in lacrimal glands of autoimmune and non-autoimmune mice

Our previous studies have shown that the mRNA levels of c-myb, c-myc, bcl-2 and p53 are higher, and partial Fas antigen (i.e. exons 1-2) lower, in lacrimal tissues of female, as compared to male, MRL/lpr mice, which are a model of Sj?gren's syndrome. We have also found that this gender-related difference in bcl-2 and c-myb expression appears to be due to the influence of androgens. To extend these findings, we sought to determine: first, whether these gender- and/or hormone-associated variations in mRNA content are unique to MRL/lpr mice, or are also present in lacrimal glands of other murine strains, including autoimmune NZB/NZW F1 (F1) and non-obese diabetic (NOD), as well as non-autoimmune C3H/HeJ (C3H) and BALB/c, mice; and second, whether the levels of these apoptotic factor mRNAs are altered in lacrimal tissues of mice (i.e. testicular feminized (Tfm) with dysfunctional androgen receptors, as compared to glandular amounts in their 'normal' controls (i.e. Tabby). Lacrimal tissues were obtained from adult mice, which were either untreated or treated with placebo or testosterone for 21 days. Glands were processed for the analysis of proto-oncogene mRNAs by RT-PCR (at exponential phase of amplification) and data were standardized to the corresponding levels of beta-actin mRNA. Our results demonstrate that Fas antigen, Fas ligand, c-myb, c-myc, bcl-2, Bax and p53 mRNAs are present in lacrimal tissues of F1, NOD, C3H, BALB/c, Tabby and Tfm mice. The relative levels of Fas antigen mRNA are consistently higher in glands of males, whereas amounts of bcl-2 mRNA are greater in tissues of F1, C3H and BALB/c females. Testosterone administration induced a significant increase in the lacrimal gland content of Bax mRNA, but a striking decrease in the lacrimal tissue level of bcl-2 mRNA in F1 and C3H mice. Lacrimal glands of Tfm mice contained elevated amounts of bcl-2 mRNA, as compared to values in tissues of their Tabby controls. In summary, our findings show that fundamental gender-related differences exist in the expression of genes associated with programmed cell death in lacrimal glands of autoimmune and normal mice. In addition, some of these differences may be due, at least in part, to the effect of androgens.     

The genetics of diabetes susceptibility in mice

The factors associated with a diabetes-susceptible genotype in mice exhibiting various forms of heritable glucose intolerance syndromes are discussed. Genetic models of insulin-dependent and non-insulin-dependent diabetes in mice are described. Although single gene mutations can be defined for each model that are major contributors to diabetogenic stress, polygenic interactions are required for the expression of a diabetic phenotype, and environmental factors are also contributory. Several strongly penetrant single gene mutations are capable of affecting obesity and insulin-resistant states. Analysis of inbred strain genomic interactions with one of these recessive obesity-producing genes, diabetes (db), suggests that development of a diabetic phenotype is dependent on the strength of an interaction between the db gene and sulfotransferase enzymes. Specifically, diabetes-susceptible vs. resistant inbred strain backgrounds can be distinguished by the extent to which the db mutation elicits an accelerated sequestration by sulfoconjugation of tissue estrogens while androgens remain free. In a male gender- (and Y chromosome-)associated model of transient glucose intolerance, stress as well as a requirement for both adrenal and testicular secretions are each components of the susceptibility background. In the obesity-associated diabetes models, autoimmunity, when it occurs, is a secondary reflection of pancreatic beta cell destruction. The nonobese diabetic (NOD) mouse, in contrast, represents a model in which autoimmunity against beta cells is a primary event in the development of insulin-dependent diabetes. In NOD mice, a gene that is either the unique class II gene in the major histocompatibility complex or is in linkage disequilibrium with this complex makes a major (recessivelike) contribution to diabetes susceptibility. However, diabetogenesis can be mediated only through a multifactorial interaction among this susceptibility locus and multiple unlinked genetic loci regulating immune responsiveness. In addition, the NOD mouse represents one of the best models of diabetes available for demonstrating a critical interaction between heredity and environmental factors. The polygenic nature of the various heritable forms of glucose intolerance syndromes in mice points to a comparable or even greater genetic heterogeneity underlying the major types of diabetes in humans.