Familial Leydig cell hypoplasia as a cause of male pseudohermaphroditism

A case of familial Leydig cell hypoplasia as a cause of male pseudohermaphroditism is described in two 46,XY female sibs. Biochemical and histologic evidence for such diagnosis is presented.     

Change of the heterogametic sex from male to female in the frog

Two different types of sex chromosomes, XX/XY and ZZ/ZW, exist in the Japanese frog Rana rugosa. They are separated in two local forms that share a common origin in hybridization between the other two forms (West Japan and Kanto) with male heterogametic sex determination and homomorphic sex chromosomes. In this study, to find out how the different types of sex chromosomes differentiated, particularly the evolutionary reason for the heterogametic sex change from male to female, we performed artificial crossings between the West Japan and Kanto forms and mitochondrial 12S rRNA gene sequence analysis. The crossing results showed male bias using mother frogs with West Japan cytoplasm and female bias using those with Kanto cytoplasm. The mitochondrial genes of ZZ/ZW and XX/XY forms, respectively, were similar in sequence to those of the West Japan and Kanto forms. These results suggest that in the primary ZZ/ZW form, the West Japan strain was maternal and thus male bias was caused by the introgression of the Kanto strain while in the primary XX/XY form and vice versa. We therefore hypothesize that sex ratio bias according to the maternal origin of the hybrid population was a trigger for the sex chromosome differentiation and the change of heterogametic sex.     

Bovine like-sexed male twins with chromosomal chimerism

Sex-chromosomal chimerism (XX/XY) was described in a pair of bovine like-sexed male twins. One of the twins showed malformed external genitalia, and the other was phenotypically normal. It is proposed that sex-chromosomal chimerism is associated with a choriovascular anastomosis between like-sexed twins examined and "female fetus" which may be overlooked at parturition.     

Prenatal diagnosis in a familial form of male pseudohermaphroditism due to 17-keto reductase deficiency

In an infant considered at birth as a female but with easily palpable gonads in the labia major, the XY karyotype and the endocrine studies (determination of plasma levels of steroid hormones under basal conditions and during hCG stimulation) were consistent with the diagnosis of male pseudohermaphroditism due to 17-keto reductase deficiency. During the second pregnancy an amniocentesis revealed a 46 XY karyotype. Endocrine studies performed on the amniotic fluid at midgestation suggested that the fetus was affected by the same enzyme defect. After birth, the diagnosis was demonstrated with anatomical an endocrine studies.     

The reproductive performance of XX/XY male chimeric mice

The reproductive performance of male aggregation chimeric mice was examined. C57BL/6 in equilibrium BALB/c male chimeras and control animals, C57BL/6, BALB/c, and their reciprocal F1 crosses, were mated with ICR females. Of 45 overt chimeras, 13 produced mixed-genotype progenies and were revealed to be XY/XY chimeras. By karyotype analysis 16 of 32 single-genotype progeny chimeras were determined to be XX/XY chimeras, but the remaining single-genotype progeny chimeras showed only XY metaphase plates, so that their chromosomal sex could not be determined. The mean litter size of C57BL/6 was significantly higher than that of BALB/c. In contrast, the birth rate of C57BL/6 was lower than that of BALB/c. XY/XY chimeras showed almost the same performance as C57BL/6 for litter size and as BALB/c for birth rate. There were no significant differences for both traits between the reciprocal F1 crosses and XY/XY chimeras. The mean litter size of XX/XY chimeras was lower than that of XY/XY chimeras and the differences was statistically significant. Some XX/XY chimeras had very small testes, while XY/XY chimeras had normal testes. Such results indicate that the reproductive performance of XX/XY male chimeras is inferior to that of XY/XY males.     

Reproductive performance of male and female phenotypes in three sex chromosomal genotypes(XX, XY, YY) in the killifish, Oryzias latipes.

The present study investigates the juvenile and adult reproductive performance of Japanese killifish, Oryzias latipes, which were successfully sex-reversed by feeding them male or female sex hormones during the fry stage. Sexual maturation of these laboratory grown fish of three known genotypes (XX, SY, YY) occurred earliest in untreated genotypes, next in genotypes treated with male hormone (methyl testosterone) and female hormone (estrone), respectively. The delay in sexual maturation caused by early exogenous, sex-hormone treatment may represent a disturbance in the delicate neural-gonadal axis. However, the degree of response was also strongly influenced by the animal's sex chromosomal genotype. XX fish, normally phenotypic females, were affected more by the male hormone than by the female hormone. XY and YY fish, normally phenotypic males, were delayed more by the female hormone than by the male hormone. This specific sex hormone-sex genotype interaction also influenced adult reproductive performance (sperm or egg production). Differences in the metabolism of male and female sex hormones by the XX, XY, and YY fish are probably responsible for these interesting findings.     

Analysis of male meiotic "sex body" proteins during XY female meiosis provides new insights into their functions

During male meiosis in mammals the X and Y chromosomes become condensed to form the sex body (XY body), which is the morphological manifestation of the process of meiotic sex chromosome inactivation (MSCI). An increasing number of sex body located proteins are being identified, but their functions in relation to MSCI are unclear. Here we demonstrate that assaying male sex body located proteins during XY female mouse meiosis, where MSCI does not take place, is one way in which to begin to discriminate between potential functions. We show that a newly identified protein, "Asynaptin" (ASY), detected in male meiosis exclusively in association with the X and Y chromatin of the sex body, is also expressed in pachytene oocytes of XY females where it coats the chromatin of the asynapsed X in the absence of MSCI. Furthermore, in pachytene oocytes of females carrying a reciprocal autosomal translocation, ASY associates with asynapsed autosomal chromatin. Thus the location of ASY to the sex body during male meiosis is likely to be a response to the asynapsis of the non-homologous regions [outside the pseudoautosomal region (PAR)] of the heteromorphic X-Y bivalent, rather than being related to MSCI. In contrast to ASY, the previously described sex body protein XY77 proved to be male sex body specific. Potential functions for MSCI and the sex body are discussed together with the possible roles of these two proteins.     

Genetic mechanisms underlying male sex determination in mammals

Genetic control of gonadal development proceeds through either the male or female molecular pathways, driving bipotential gonadal anlage differentiation into a testis or ovary. Antagonistic interactions between the 2 pathways determine the gonadal sex. Essentially sex determination is the enhancement of one of the 2 pathways according to genetic sex. Initially, Sry with other factors upregulatesSox9 expression in XY individuals. Afterwards the expression ofSox9 is maintained by a positive feedback loop withFgf9 and prostaglandin D₂ as well as by autoregulative ability of Sox9. If these factors reach high concentrations, then Sox9 and/or Fgf9 may inhibit the female pathway. Surprisingly, splicing, nuclear transport, and extramatrix proteins may be involved in sex determination. The male sex determination pathway switches on the expression of genes driving Sertoli cell differentiation. Sertoli cells orchestrate testicular differentiation. In the absence of Sry, the predomination of the female pathway results in the realization of a robust genetic program that drives ovarian differentiation.     

F prostaglandins function as potent olfactory stimulants that comprise the postovulatory female sex pheromone in goldfish

This study establishes that ovulated female goldfish release F type prostaglandins (PGFs) to the water where they stimulate male spawning behavior and comprise the goldfish postovulatory pheromone. We first demonstrated that ovulated and prostaglandin-injected female goldfish release immunoreactive PGFs to the water. Next, using electro-olfactogram recording (EOG), we determined that waterborne prostaglandins function as potent olfactory stimulants for mature male goldfish. Prostaglandin F2 alpha (PGF2 alpha) and its metabolite 15-keto-prostaglandin F2 alpha (15K-PGF2 alpha) were the most potent prostaglandins; the former had a detection threshold of 10(-10) M and the latter a detection threshold of 10(-12) M. Studies of prostaglandin-injected fish indicated that PGF metabolites are an important component of the pheromone. Cross-adaptation experiments using the EOG demonstrated that goldfish have separate olfactory receptor sites for PGF2 alpha and 15K-PGF2 alpha that are independent from those that detect other olfactory stimulants. Finally, we established that male goldfish exposed to low concentrations of waterborne PGFs exhibit reproductive behaviors similar to those elicited by exposure to the odor of ovulated fish. Together with our recent discovery that a steroidal maturational hormone functions as a preovulatory "priming" pheromone for goldfish, these findings suggest that hormones and their metabolites may commonly serve as reproductive pheromones in fish.     

46,XY phenotypic male with focal segmental glomerulosclerosis caused by the WT1 splice site mutation

OBJECTIVE: Frasier syndrome is characterized by progressive glomerulopathy due to nonspecific focal and segmental glomerulosclerosis (FSGS), 46,XY sex reversal and the development of gonadoblastoma from dysgenetic gonads. Donor splice site heterozygous mutations in intron 9 of the Wilms' tumor gene (WT1) cause this disease. We investigated whether WT1 mutations showed clinical heterogeneity. PATIENTS AND METHODS: A 6-year-old phenotypic boy was diagnosed as having FSGS. His karyotype was 46,XY. Gonadotropin-releasing hormone and human chorionic gonadotropin stimulation tests revealed normal luteinizing hormone, follicle-stimulating hormone and testosterone responses. The other patient was a 7-year-old 46,XY female with FSGS. Prophylactic gonadectomy was performed and gonadoblastoma was found. By polymerase chain reaction and direct sequencing, WT1 was analyzed in these patients. RESULTS AND CONCLUSION: Both patients had IVS9 + 5G-->A in intron 9 of the WT1. Our study indicates a normal 46,XY phenotypic male patient with FSGS. The phenotypic variations of the WT1 splice site mutations are further expanded.     

Correlation between sexual phenotype and X-chromosome inactivation pattern in the X*XY wood lemming

Replication patterns of the X chromosomes were studied in X*XY wood lemmings with male and female phenotypes. The wild-type X was late replicating (ie, inactivated) in all cells of the X*XY female, whereas the mutated X* was late replicating in all cells of the X*XY male. These findings are compared with those obtained in sex-reversed (Sxr) mice.     

Gynandromorphs reveal two separate primordia for male and female genitalia inDrosophila melanogaster

Summary The derivatives of 110 mosaic genital discs of gynandromorphs have been analysed microscopically. It has been found that theanalia of both sexes are homologous and derive from a single primordium (see Fig. 1a). Whether male or female anal plates are formed depends on the genetic constitution of the cells. This is analogous to the development of male sex combs versus female transversal rows on the forelegs of gynandromorphs. In contrast, the data for thegenitalia (see Fig. 1 b) are best explained if it is assumed that there are two genital primordia in everyDrosophila embryo: a male primordium that will only develop into genitalia if populated by XY (or XO) nuclei, and a female primordium that will only do so if populated by XX nuclei. This model, as depicted in Figure 2, is compatible with all our gynandromorph data and also with observations onMusca andCalliphora where in fact two separate genital primordia are found.     

Recombination in the pseudoautosomal region in a 47,XYY male

Males with a 47,XYY karyotype generally have chromosomally normal children, despite the high theoretical risk of aneuploidy. Studies of sperm karyotypes or FISH analysis of sperm have demonstrated that the majority of sperm are chromosomally normal in 47,XYY men. There have been a number of meiotic studies of XYY males attempting to determine whether the additional Y chromosome is eliminated during spermatogenesis, with conflicting results regarding the pairing of the sex chromosomes and the presence of an additional Y. We analyzed recombination in the pseudoautosomal region of the XY bivalent to determine whether this is perturbed in a 47,XYY male. A recombination frequency similar to normal 46,XY men would indicate normal pairing within the XY bivalent, whereas a significantly altered frequency would suggest other types of pairing such as a YY bivalent or an XYY trivalent. Two DNA markers, STS/STS pseudogene and DXYS15, were typed in sperm from a heterozygous 47,XYY male. Individual sperm (23,X or Y) were isolated into PCR tubes using a FACStarPlus flow cytometer. Hemi-nested PCR analysis of the two DNA markers was performed to determine the frequency of recombination. A total of 108 sperm was typed with a 38% recombination frequency between the two DNA markers. This is very similar to the frequency of 38.3% that we have observed in 329 sperm from a normal 46,XY male. Thus our results suggest that XY pairing and recombination occur normally in this 47,XYY male. This could occur by the production of an XY bivalent and Y univalent (which is then lost in most cells) or by loss of the additional Y chromosome in some primitive germ cells or spermatogonia and a proliferative advantage of the normal XY cells.     

An unusual sex-determination system in South American field mice (Genus Akodon): the role of mutation, selection, and meiotic drive in maintaining XY females

The mechanism of sex determination in mammals appears highly conserved: the presence of a Y chromosome triggers the male developmental pathway, whereas the absence of a Y chromosome results in a default female phenotype. However, if the Y chromosome fails to initiate the male pathway (referred to as Y*), XY* females can result, as is the case in several species of South American field mice (genus Akodon). The breeding genetics in this system inherently select against the Y* chromosome such that the frequency of XY* females should decrease rapidly to very low frequencies. However, in natural populations of Akodon, XY* females persist at substantial frequencies; for example, 10% of females are XY* in A. azarae and 30% in A. boliviensis. We develop a mathematical model that considers the potential roles of three evolutionary forces in maintaining XY* females: Y-to-Y* chromosome transitions (mutation), chromosome segregation distortion (meiotic drive), and differential fecundity (selection). We then test the predictions of our model using data from breeding colonies of A. azarae. We conclude that any single force is inadequate to maintain XY* females. However, a combination of segregation bias of the male and female Y chromosomes during spermatogenesis/oogenesis and increased fecundity in XY* females could account for the observed frequencies of XY* females.     

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.     

Germ cell chimerism in male marmosets

Marmosets normally produce biovular twins which are connected, via placental vascular anastomoses, as early as pre-somite stages of development. These anastomoses allow the exchange of lymphoid and hematopoietic tissue, as demonstrated by karyotype analysis in heterosexual twins. Because germ cells are also motile during development, i.e., they migrate from the yolk sac endodermal epithelium to the germinal ridges, the possibility exists that germ cells could also be exchanged between heterosexual twins. Testicular squash preparations were examined from 22 adult male marmosets of several species. During the diakinesis stage of meiotic prophase the XY chromosome pair was distinct. Spermatocytes which lacked the conspicuous end-to-end association of the XY pair were considered to have originated from germ cells with an XX sex chromosome constitution. In approximately half the animals examined, all diakinesis figures contained an end-to-end XY pair. In the remaining animals, primary spermatocytes were seen that clearly did not contain an endto-end XY pair. The largest number of such XX primary spermatocytes in any one animal was 21% (9 of 43 cells examined). The effects of germ cell chimerism on the sex ratio of offspring was also investigated.     

Effects of sex chromosome aneuploidy on male sexual behavior

Incidence of sex chromosome aneuploidy in men is as high as 1:500. The predominant conditions are an additional Y chromosome (47,XYY) or an additional X chromosome (47,XXY). Behavioral studies using animal models of these conditions are rare. To assess the role of sex chromosome aneuploidy on sexual behavior, we used mice with a spontaneous mutation on the Y chromosome in which the testis-determining gene Sry is deleted (referred to as Y⁻) and insertion of a Sry transgene on an autosome. Dams were aneuploid (XXY⁻) and the sires had an inserted Sry transgene (XY Sry ). Litters contained six male genotypes, XY, XYY⁻, XX Sry , XXY⁻ Sry , XY Sry and XYY⁻ Sry . In order to eliminate possible differences in levels of testosterone, all of the subjects were castrated and received testosterone implants prior to tests for male sex behavior. Mice with an additional copy of the Y⁻ chromosome (XYY⁻) had shorter latencies to intromit and achieve ejaculations than XY males. In a comparison of the four genotypes bearing the Sry transgene, males with two copies of the X chromosome (XX Sry and XXY⁻ Sry ) had longer latencies to mount and thrust than males with only one copy of the X chromosome (XY Sry and XYY⁻ Sry ) and decreased frequencies of mounts and intromissions as compared with XY Sry males. The results implicate novel roles for sex chromosome genes in sexual behaviors.     

Increase of cortisol levels after temperature stress activates dmrt1a causing female‐to‐male sex reversal and reduced germ cell number in medaka

In vertebrates, there is accumulating evidence that environmental factors as triggers for sex determination and genetic sex determination are not two opposing alternatives but that a continuum of mechanisms bridge those extremes. One prominent example is the model fish species Oryzias latipes which has a stable XX/XY genetic sex determination system, but still responds to environmental cues, where high temperatures lead to female‐to‐male sex reversal. However, the mechanisms behind are still unknown. We show that high temperatures increase primordial germ cells (PGC) numbers before they reach the genital ridge, which, in turn, regulates the germ cell proliferation. Complete ablation of PGCs led to XX males with germ cell less testis, whereas experimentally increased PGC numbers did not reverse XY genotypes to female. For the underlying molecular mechanism, we provide support for the explanation that activation of the dmrt1a gene by cortisol during early development of XX embryos enables this autosomal gene to take over the role of the male determining Y‐chromosomal dmrt1bY.     

Chromosome banding in Amphibia. XXII. Atypical y chromosomes in Gastrotheca walkeri and Gastrotheca ovifera (Anura,Hylidae)

The chromosomes of the rare South American marsupial frogs Gastrotheca walkeri and G. ovifera were extensively reexamined with various banding techniques. The karyotypes of both species are distinguished by a new category of XY female symbol /XX male symbol female sex chromosomes. The unusual Y chromosomes are characterized by containing the least amount of constitutive heterochromatin in the karyotypes. This is in contrast to all previously known amphibian Y chromosomes and does not fit the evolutionary model of early XY differentiation in vertebrates. In male meiosis, the heteromorphic XY chromosomes of both species still exhibit the same pairing configurations as the autosomes. DNA flow cytometric measurements show the nuclear DNA amount of G. walkeri to be 10.90 pg. The significance of the XY/XX sex chromosomes of these marsupial frogs, the various classes of constitutive heterochromatin detected, and the data obtained from meiotic analyses are discussed in detail.