St?rungen der m?nnlichen Gonadendifferenzierung

XY gonadal dysgenesis is characterized by a failure of testis differentiation and can be caused either by disturbed development of the urogenital ridge to the bipotential gonad or by impaired differentiation of the bipotential gonad to testis. Genes responsible for early gonadal development like WT1 and SF1 can be distinguished from genes involved in testis differentiation such as SRY, SOX9, DMRT, DAX1, WNT4, DHH, CBX2, TSPYL1, ATRX and ARX. In complete XY gonadal dysgenesis, M??llerian but no Wolffian structures are present. In partial XY gonadal dysgenesis, remnants of M??llerian and Wolffian ducts can be present and virilization of the external genitalia can take place. In about a third of cases, XY gonadal dysgenesis occurs in a syndromic form. In these syndromic forms, the extragenital phenotypes can indicate the causative genes, but these genes can also cause non-syndromic forms of XY gonadal dysgenesis.     

H-Y antigen in 46,XY gonadal dysgenesis

Summary Presence of H-Y antigen has been correlated with testicular differentiation, and absence of H-Y with failure of testicular differentiation, in a variety of mammalian species. To determine more precisely the relationship between expression of H-Y antigen and development of the testis, we studied the cells of phenotypic females with the 46,XY male karyotype. Blood leukocytes were typed H-Y⁺ in five XY females with gonadal dysgenesis, although in other studies blood leukocytes from XY females with gonadal dysgenesis were typed H-Y^-. Thus mere presence of H-Y antigen is not sufficient to guarantee normal differentiation of the testis. In the present paper we review evidence for an additional factor in gonadal organogenesis, the H-Y antigen receptor. We infer that testicular development requires engagement of H-Y and its receptor. It follows that XY gonadal dysgenesis is the consequence of functional absence of the H-Y testis inducer as in the following conditions: failure of synthesis of H-Y or failure of specific binding of H-Y.     

Sexually dimorphic gene expression in the developing mouse gonad

Over the course of a few days, the bipotential embryonic mouse gonad differentiates into either a testis or an ovary. Though a few gene expression differences that underlie gonadal sex differentiation have been identified, additional components of the testicular and ovarian developmental pathways must be identified to understand this process. Here we report the use of a PCR-based cDNA subtraction to investigate expression differences that arise during gonadal sex differentiation. Subtraction of embryonic day 12.5 (E12.5) XY gonadal cDNA with E12.5 XX gonadal cDNA yielded 19 genes that are expressed at significantly higher levels in XY gonads. These genes display a variety of expression patterns within the embryonic testis and encode a broad range of proteins. A reciprocal subtraction (of E12.5 XX gonadal cDNA with E12.5 XY gonadal cDNA) yielded two genes, follistatin and Adamts19, that are expressed at higher levels in XX gonads. Follistatin is a well-known antagonist of TGFbeta family members while Adamts19 encodes a new member of the ADAMTS family of secreted metalloproteases.     

Sex chromosome complement affects nociception in tests of acute and chronic exposure to morphine in mice

We tested the role of sex chromosome complement and gonadal hormones in sex differences in several different paradigms measuring nociception and opioid analgesia using "four core genotypes" C57BL/6J mice. The genotypes include XX and XY gonadal males, and XX and XY gonadal females. Adult mice were gonadectomized and tested 3-4 weeks later, so that differences between sexes (mice with testes vs. ovaries) were attributable mainly to organizational effects of gonadal hormones, whereas differences between XX and XY mice were attributable to their complement of sex chromosomes. In Experiment 1 (hotplate test of acute morphine analgesia), XX mice of both gonadal sexes had significantly shorter hotplate baseline latencies prior to morphine than XY mice. In Experiment 2 (test of development of tolerance to morphine), mice were injected twice daily with 10 mg/kg morphine or saline for 6 days. Saline or the competitive NMDA antagonist CPP (3-(2-carboxypiperazin-4yl) propyl-1-phosphonic acid) (10 mg/kg) was co-injected. On day 7, mice were tested for hotplate latencies before and after administration of a challenge dose of morphine (10 mg/kg). XX mice showed shorter hotplate latencies than XY mice at baseline, and the XX-XY difference was greater following morphine. In Experiment 3, mice were injected with morphine (10 mg/kg) or saline, 15 min before intraplantar injection of formalin (5%/25 microl). XX mice licked their hindpaw more than XY mice within 5 min of formalin injection. The results indicate that X- or Y-linked genes have direct effects, not mediated by gonadal secretions, on sex differences in two different types of acute nociception.     

Aberrant testicular differentiation in 46,XY gonadal dysgenesis: Morphology,endocrinology, serology

Summary In an infant with gonadal dysgenesis and somatic anomalies, the internal and external genitalia were female but the gonads contained tubular structures suggesting male differentiation. The karyotype was 46,XY with no evidence of structural aberration or mosaicism. Hormonal metabolism and H-Y antigen expression were assayed in cultured gonadal cells. Although unable to synthesize testosterone, the cultured cells were able to convert it to dihydrotestosterone. H-Y antigen was present, perhaps at a level lower than that in cells from normal XY males. Our observations indicate that a modicum of testicular organogenesis may precede the involution that results in a streak gonad in some cases of gonadal dysgenesis.     

Embryonic testicular regression syndrome and severe mental retardation in sibs

The embryonic testicular regression syndrome associated with severe mental retardation is reported in three 46,XY sibs each of whom has a 46,XY chromosome complement. A fourth sib, a sister, also is severely retarded mentally; her chromosome complement is 46,XX. The 46,XY individuals, who were raised as females, presented varying degrees of genital ambiguity, indicating that their gonadal activities had been arrested at different times during embryogenesis. No trace of gonadal tissue could be found in either patient. The coincidence of the embryonic testicular regression syndrome and severe mental retardation in the same sibship is discussed.     

46,XY gonadal dysgenesis: Isoncogenesis related to H-Y phenotype or breast development?

Summary Among women with 46,XY gonadal dysgenesis, there is a high incidence of gonadal tumors. Because of evidence of a connection between occurrence of those tumors, H-Y phenotype, and breast development, we surveyed 55 cases of 46,X gonadal dysgenesis and 12 related cases involving chromosomal and/or skeletal abnormalities. Our survey, including three new cases presented here, indicates that H-Y phenotype but not breast development may be related to the development of the gonadoblastoma-dysgerminoma. Thus among women with 46,XY gonadal dysgenesis, there are H-Y^– and H-Y⁺ classes, but gonadal tumors are found almost exclusively in the H-Y⁺ class. Yet one of our patients may represent an exception to the association of H-Y⁺ phenotype and gonadal tumors in this syndrome.     

Investigation of the ZFY gene in XX true hermaphroditism and Swyer syndrome

Summary Four patients with 46,XX true hermaphroditism and one patient with 46,XY pure gonadal dysgenesis (Swyer syndrome) were analyzed with a Y chromosome-derived probe that detects a specific fragment on the short arm of the Y chromosome in the putative testicle-determining region and also a fragment on the short arm of the X chromosome. Normal males and females, an individual with Turner syndrome, and patients with various causes of anomalous gonadal differentiation accompanied by cytogenetically present Y chromosome were used as controls. The Y-specific fragment was not detected in any of the persons with 46,XX true hermaphroditism. However, this fragment was positive in the 46,XY female and in all Y-bearing patients. Cytogenetic and molecular absence of the ZFY sequence in 46,XX true hermaphrodites calls for explanations other than the classic embryogenie theory. The absence of testicular differentiation in the ZFY-positive XY female evidences functionally altered sex determination or, alternatively, defective gonadal receptors.     

The number of x chromosomes causes sex differences in adiposity in mice

Sexual dimorphism in body weight, fat distribution, and metabolic disease has been attributed largely to differential effects of male and female gonadal hormones. Here, we report that the number of X chromosomes within cells also contributes to these sex differences. We employed a unique mouse model, known as the "four core genotypes," to distinguish between effects of gonadal sex (testes or ovaries) and sex chromosomes (XX or XY). With this model, we produced gonadal male and female mice carrying XX or XY sex chromosome complements. Mice were gonadectomized to remove the acute effects of gonadal hormones and to uncover effects of sex chromosome complement on obesity. Mice with XX sex chromosomes (relative to XY), regardless of their type of gonad, had up to 2-fold increased adiposity and greater food intake during daylight hours, when mice are normally inactive. Mice with two X chromosomes also had accelerated weight gain on a high fat diet and developed fatty liver and elevated lipid and insulin levels. Further genetic studies with mice carrying XO and XXY chromosome complements revealed that the differences between XX and XY mice are attributable to dosage of the X chromosome, rather than effects of the Y chromosome. A subset of genes that escape X chromosome inactivation exhibited higher expression levels in adipose tissue and liver of XX compared to XY mice, and may contribute to the sex differences in obesity. Overall, our study is the first to identify sex chromosome complement, a factor distinguishing all male and female cells, as a cause of sex differences in obesity and metabolism.     

H-Y antigen in Swyer syndrome and the genetics of XY gonadal dysgenesis

Summary The H-Y antigen is a plasma membrane antigen involved in the organogenesis of the mammalian testis. Its expression on human cells is determined by a Y-linked gene. Phenotypic females affected by 46,XY gonadal dysgenesis (Swyer's syndrome) can be either H-Y-positive or H-Y-negative. In this paper we report H-Y antigen and endocrine studies in a sibship with three affected sisters. Immunological studies were performed on two of the patients, and a clearly positive expression was detected in both cases. Endocrine studies consisted in the investigation of the hypothalamic-pituitary-gonadal axis, which revealed that gonadal hormone insufficiency is the only endocrine abnormality associated with the syndrome. A new genetic interpretation and classification of XY gonadal dysgenesis is proposed.     

Sex difference in neural tube defects in p53-null mice is caused by differences in the complement of X not Y genes

To shed light on the biological origins of sex differences in neural tube defects (NTDs), we examined Trp53-null C57BL/6 mouse embryos and neonates at 10.5 and 18.5 days post coitus (dpc) and at birth. We confirmed that female embryos show more NTDs than males. We also examined mice in which the testis-determining gene Sry is deleted from the Y chromosome but inserted onto an autosome as a transgene, producing XX and XY gonadal females and XX and XY gonadal males. At birth, Trp53 nullizygous mice were predominantly XY rather than XX, irrespective of gonadal type, showing that the sex difference in the lethal effect of Trp53 nullizygosity by postnatal day 1 is caused by differences in sex chromosome complement. At 10.5 dpc, the incidence of NTDs in Trp53-null progeny of XY* mice, among which the number of the X chromosomes varies independently of the presence or absence of a Y chromosome, was higher in mice with two copies of the X chromosome than in mice with a single copy. The presence of a Y chromosome had no protective effect, suggesting that sex differences in NTDs are caused by sex differences in the number of X chromosomes.     

A novel missense mutation (S18N) in the 5′ non-HMG box region of the SRY gene in a patient with partial gonadal dysgenesis and his normal male relatives

Mutations in the sex-determining region of the Y chromosome (the SRY gene) have been reported in low frequency in patients with 46,XY gonadal dysgenesis. We investigated 21 Brazilian 46,XY sex-reversed patients, who presented either complete or partial gonadal dysgenesis or embryonic testicular regression syndrome. Using Southern blotting, polymerase chain reaction, denaturing gradient gel electrophoresis and direct sequencing, we analyzed deletions and point mutations in the SRY gene. We found a missense mutation at codon 18 upstream of the 5′ border of the HMG box of the SRY gene in one patient with partial gonadal dysgenesis. This variant sequence was also found in DNA obtained from blood and sperm cells of his father and in blood cells of his normal brother. The S18N mutation was not found in 50 normal males, ruling out the possibility of a common polymorphism. We identified a novel familial missense mutation (S18N) in the 5’ non-HMG box of the SRY gene in 1 of 21 patients with 46,XY sex reversal. Received: 6 May 1997 / Accepted: 2 October 1997     

XY gonadal dysgenesis: Genetic heterogeneity based upon clinical observations,H-Y antigen status and segregation analysis

Summary Clinical observations and segregation analysis indicate that XY gonadal dysgenesis is characterized by genetic heterogeneity. In addition to the type inherited in X-linked recessive fashion, segregation analysis of other families suggested another type by revealing that the proportion of affected sibs did not differ from that expected on the basis of a male-limited autosomal recessive inheritance. Further heterogeneity may be deduced on the basis of coexisting campomelic dwarfism or possibly also renal parenchymal abnormalities. These observations of genetic heterogeneity must be considered when interpreting studies in which individuals with XY gonadal dysgenesis may or may not show H-Y antigen.     

Complete XY gonadal dysgenesis due to p.D293N homozygous mutation in theNR5A1 gene: a case study

TheSRY gene (sex-determining region on the Y chromosome; MIM *480000) is responsible for initiating male gonadal development. However, only 15–20% of the cases of XY gonadal dysgenesis are due to mutations in its sequence. Recently, heterozygous mutations in theNR5A1 gene (nuclear receptor subfamily 5, group A, member 1; MIM +184757) have been described in association with ovarian failure and disorders of testis development with or without adrenal failure. Here we describe a case of XY complete gonadal dysgenesis due to a p.D293N homozygous mutation in theNR5A1 gene, with normalSRY and no adrenal failure.     

Oestrogen blocks the nuclear entry of SOX9 in the developing gonad of a marsupial mammal

Background  

Hormones are critical for early gonadal development in nonmammalian vertebrates, and oestrogen is required for normal ovarian development. In contrast, mammals determine sex by the presence or absence of the SRY gene, and hormones are not thought to play a role in early gonadal development. Despite an XY sex-determining system in marsupial mammals, exposure to oestrogen can override SRY and induce ovarian development of XY gonads if administered early enough. Here we assess the effect of exogenous oestrogen on the molecular pathways of mammalian gonadal development.     

H-Y Antigen Negative Germ Cells in Gonadal Sex Organization in vitro

Dissociation-reorganization experiments were done with gonadal cells of newborn rats. Rotation cultures consisted of mixtures of somatic and germ cells of opposite sex. Somatic cells, ovarian or testicular, determined a female or male type respectively, of gonadal histomorphic organization. Germ cells did not affect the type of organization of somatic cells. Accordingly, suspensions containing somatic cells of one sex together with germ cells of both sexes, reorganized in rotation culture, into either a) follicles containing XX or XY germ cells, or b) tubules containing XX or XY or both types of germ cells. These results give morphological evidence for heterosexual germ-somatic cells interactions. Based on morphological and H-Y antigen studies, failure of germ cells to bind and express H-Y antigen is considered as a possible factor for this failure of germ cells to affect gonadal sex.     

Molecular analysis of 46,XY females and regional assignment of a new Y-chromosome-specific probe

Summary The relationship between Y-chromosome abnormalities and gonadal differentiation was investigated in six phenotypic females with a 46,XY karyotype and one patient with ambiguous genitalia secondary to apparently nonmosaic 46,XY mixed gonadal dysgenesis. No alterations were found in the Y chromosomes of six of these individuals by the use of either cytogenetic or molecular techniques. Cytogenetic analysis with high-resolution G-banding and Q-banding revealed a small deletion in the short arm of the Y chromosome in one female patient with some features of Turner syndrome. Southern hybridization with Y-specific probes showed a loss of DNA within deletion intervals 1, 2, and 3 of the Y chromosome. A new Y-chromosome-specific DNA probe that hybridizes to deletion interval 3 is described.     

XY sex reversal syndrome in the mare: clinical and behavioral studies,H-Y phenotype

Summary An inherited genetic disorder causes XY embryos of the horse to develop as mares. On the basis of our study of 38 such mares, we have identified four grades or classes of XY sex reversal according to this scheme: class I, nearly normal female, of which some are fertile; class II, female with gonadal dysgenesis, normal mullerian development; calss III, intersex mare with gonadal dysgenesis, abnormal mullerian development, enlarged clitoris; class IV, virilized intersex characterized by high levels of testosterone. In general, class I and calss II mares were typed H-Y antigen-negative whereas class III and class IV mares were typed H-Y antigen-positive.     

The Sex Chromosome Trisomy mouse model of XXY and XYY: metabolism and motor performance

Background

Klinefelter syndrome (KS), caused by XXY karyotype, is characterized by low testosterone, infertility, cognitive deficits, and increased prevalence of health problems including obesity and diabetes. It has been difficult to separate direct genetic effects from hormonal effects in human studies or in mouse models of KS because low testosterone levels are confounded with sex chromosome complement.

Methods

In this study, we present the Sex Chromosome Trisomy (SCT) mouse model that produces XXY, XYY, XY, and XX mice in the same litters, each genotype with either testes or ovaries. The independence of sex chromosome complement and gonadal type allows for improved recognition of sex chromosome effects that are not dependent on levels of gonadal hormones. All mice were gonadectomized and treated with testosterone for 3 weeks. Body weight, body composition, and motor function were measured.

Results

Before hormonal manipulation, XXY mice of both sexes had significantly greater body weight and relative fat mass compared to XY mice. After gonadectomy and testosterone replacement, XXY mice (both sexes) still had significantly greater body weight and relative fat mass, but less relative lean mass compared to XY mice. Liver, gonadal fat pad, and inguinal fat pad weights were also higher in XXY mice, independent of gonadal sex. In several of these measures, XX mice also differed from XY mice, and gonadal males and females differed significantly on almost every metabolic measure. The sex chromosome effects (except for testis size) were also seen in gonadally female mice before and after ovariectomy and testosterone treatment, indicating that they do not reflect group differences in levels of testicular secretions. XYY mice were similar to XY mice on body weight and metabolic variables but performed worse on motor tasks compared to other groups.

Conclusions

We find that the new SCT mouse model for XXY and XYY recapitulates features found in humans with these aneuploidies. We illustrate that this model has significant promise for unveiling the role of genetic effects compared to hormonal effects in these syndromes, because many phenotypes are different in XXY vs. XY gonadal female mice which have never been exposed to testicular secretions.