XX sex reversal in the American cocker spaniel dog: phenotypic expression and inheritance

Summary This study was conducted to define the range of phenotypic expression and mode of inheritance of XX sex reversal in the cocker spaniel dog. Breeding experiments produced F1, F1BC, and F2 generations in which 29 XX true hermaphrodites and 3 XX males were defined by chromosome constitution, serial histologic sections of the gonads, and examination of the internal and external genitalia. In XX true hermaphrodites, the most common combination of gonads was bilateral ovotestes, followed by ovotestis and ovary, then ovotestis and testis. The amount of testicular tissue in the two gonads was closely correlated within each true hermaphrodite. The distribution of testicular tissue within ovotestes of true hermaphrodites was consistent with the hypothesis that testicular differentiation is initiated in the center of the gonad and spreads outward. XX males had bilateral aspermatogenic testes and the internal ducts and external genitalia were more masculinized than in true hermaphrodites. Results of breeding experiments are consistent with autosomal recessive inheritance, the affected phenotype being expressed only in dogs with an XX chromosome constitution. The phenotypic expression and mode of inheritance of this disorder is compared to XX sex reversal in humans and other animals.     

Müllerian inhibiting substance in sex-reversed dogs

In normal males, Müllerian Inhibiting Substance (MIS), produced by testes during an embryonic critical period, is thought to induce regression of the Müllerian duct system, including the oviducts and uterus. In XX sex-reversed dogs, an apparent contradiction has been reported: The uterus persists in the presence of testes or ovotestes. The objective of this study is to determine whether testes of XX male and ovotestes of true hermaphrodite dogs produce MIS, and to examine the anatomy of Müllerian duct derivatives of affected dogs for evidence of regression. Gonadal samples were tested for MIS activity in a bioassay. The mean MIS activity score of XX males was similar to that of normal XY males and significantly greater than that of normal XX females. The mean MIS activity score of XX true hermaphrodites was intermediate between normal XX females and XY males. Within the true hermaphrodite group, ovotestes in which the proportion of testicular tissue was greater than or equal to 1/2 had higher MIS scores than those in which the proportion of testicular tissue was less than 1/2. XX males had a well-developed epididymis adjacent to each testis, but no oviducts. In true hermaphrodites, the oviduct regressed and an epididymis was present when greater than or equal to 1/2 of the adjacent ovotestis was testicular, and MIS activity in that gonad was high. A few ovotestes with intermediate levels of MIS activity had both an oviduct and an epididymis. Regression of the oviductal portion of the Müllerian duct system was positively correlated to the amount of testicular tissue and the MIS activity of the gonad, as would be predicted by Jost's original hypothesis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetics, genomics, and molecular biology of sex determination in small animals

The genomic revolution is beginning to facilitate advances in canine and feline medicine, as illustrated in our research. Our studies are focused upon identifying the gene mutation that causes canine Sry-negative XX sex reversal, a disorder of sex determination in which chromosomal females (78,XX) develop testicular tissue, becoming either XX true hermaphrodites with ovotestes, or XX males with bilateral testes. A genome-wide screen, using mapped markers in our pedigree of Sry-negative XX sex reversed dogs founded upon the American cocker spaniel, identified five chromosomal regions in which the causative gene may be located. The canine genome was used to identify the canine homologue of goat Pisrt1 and so determine that canine and caprine Sry-negative XX sex reversal are genetically heterogeneous. A second goal of our research is to determine the molecular mechanism by which the mutation causes testis induction. Thus far, we have reported gonadal Sry and Sox9 expression patterns in normal embryos, which have temporal and spatial patterns similar to those reported in humans, sheep, and pigs. Once gene mutations causing such inherited disorders are identified, DNA tests will become a part of general veterinary practice, advancing both diagnostic techniques and preventative medicine.     

H-Y antigen expression in a case of XX true hermaphroditism

Summary Cells from an XX true hermaphrodite expressed a reduced amount of H-Y antigen when compared with normal XY cells and with cells from his father, who had an XY/XX chromosomal constitution. His mother had a normal karyotype and was H-Y negative. The four brothers of the patient were clinically and karyotypically normal. An X-Y interchange followed by random inactivation of the X chromosome is proposed to explain the H-Y antigen titer found in the patient.     

SRY protein is expressed in ovotestis and streak gonads from human sex-reversal

In mammals, a master gene located on the Y chromosome, the testis-determining gene SRY, controls sex determination. SRY protein is expressed in the genital ridge before testis determination, and in the testis it is expressed in Sertoli and germ cells. Completely sex-reversed patients are classified as either 46,XX males or 46,XY females. SRY mutations have been described in only 15% of patients with 46,XY complete or partial gonadal dysgenesis. However, although incomplete or partial sex-reversal affects 46,XX true hermaphrodites, 46,XY gonadal dysgenesis, and 46,XX/46,XY mosaicism, only 15% of the 46,XX true hermaphrodites analyzed have the SRY gene. Here, we demonstrate that the SRY protein is expressed in the tubules of streak gonads and rete testis, indicating that the SRY protein is normally expressed early during testis determination. Based on these results, we propose that some factors downstream from SRY may be mutated in these 46,XY sex-reversal patients. We have also analyzed SRY protein expression in the ovotestis from 46,XX true hermaphrodites and 46,XX/46,XY mosaicism, demonstrating SRY protein expression in both testicular and ovarian portions in these patients. This suggests that the SRY protein does not inhibit ovary development. These results confirm that other factors are needed for complete testis development, in particular, those downstream of the SRY protein.     

Absence of Y-specific DNA sequences in human 46,XX true hermaphrodites and in 45,X mixed gonadal dysgenesis

Summary A search for Y-specific DNA sequences has been performed in a sample of seven 46,XX true hermaphrodites and one 45,X mixed gonadal dysgenesis case and compared with a sample of 11 XX males. Using six Y-specific DNA probes no hybridization signal was obtained in the hermaphrodite group; in contrast, all XX males gave a positive signal with at least one probe. This difference is statistically highly significant. We conclude that the aetiology of true hermaphroditism is different from that of the XX male syndrome. As all cases of the hermaphrodite group are positive for the serological sex-specific antigen (Sxs) it is concluded that this antigen can be present even in the absence of Y-specific DNA.     

A highly sensitive peroxidase-antiperoxidase method for detection of H-Y antigen on cultivated human fibroblasts

Summary A peroxidase-anti-peroxidase method for the detection of H-Y antigen at the single cell level is described. The efficiency of the test was examined in cultivated fibroblasts derived from control subjects and from XX males and a true hermaphrodite. For comparison, H-Y antigen was determined in blood cells of the same probands using the cytotoxic test. The finding of H-Y positive fibroblasts in the intersex patients has implications for the origin of these disorders.     

Linkage to CFA29 detected in a genome-wide linkage screen of a canine pedigree segregating Sry-negative XX sex reversal

Canine Sry-negative XX sex reversal is a disorder of gonadal development wherein individuals having a female karyotype develop testes or ovotestes. In this study, linkage mapping was undertaken in a pedigree derived from one proven carrier American cocker spaniel founder male and beagle females. All affected dogs in the analysis were XX true hermaphrodites and confirmed to be Sry negative by polymerase chain reaction. A genome-wide linkage screen conducted using 245 microsatellite markers revealed highest LOD score of 3.4 (marker CPH9) on CFA29. Fine mapping with additional microsatellites in the region containing CPH9 localized the Sry-negative XX sex reversal locus to a 5.4-Mb candidate region between markers CPH9 and FH3003 (LOD score 3.15). Insignificant LOD scores were found at genome-wide screen or fine mapping markers that were within 10 Mb of 45 potential candidate genes reported to have a role in mammalian sex determination or differentiation. Together, these results suggest that a novel locus on CFA29 may be responsible for sex reversal in this pedigree.     

Morphological development of the mouse gonad in tda-1 XY sex reversal

tda-1 XY sex reversal occurs when the Y chromosome of at least some populations of wild Mus musculus domesticus is placed on the C57BL/6J genomic background. Gross anatomical observations have previously revealed morphological similarities among fetal ovotestes of tda-1 and Tas-inherited XY sex reversals and BALB/cWt mosaic hermaphrodites. We studied the histology of tda-1 XY sex-reversed gonads, ranging in age from day 14 of gestation to adult. The obtained data revealed additional similarities with ovotestes of BALB/cWt mosaic hermaphrodites as well as with ovotestes of hermaphrodites found in XXSxr and XX/XY chimeras. It is proposed that ovotestes occurring in these various hermaphroditic conditions may be formed through a common pathway.     

Primary sex determination: genetics and biochemistry

Summary On the basis of widespread phylogenetic conservatism, it has been propose'd that serologically-defined H-Y antigen is the inducer of primary sex differentiation in mammals, causing the initially indifferent gonad to become a testis rather than an ovary. The proposal has withstood extensive testing in a variety of biological circumstances: XX males have testes and are H-Y⁺ and fertile XY females lack testicular tissue and are H-Y; soluble H-Y antigen induces testicular organogenesis in XX indifferent gonads of the fetal calf in culture; H-Y antibody blocks tubular reaggregation of dispersed XY testicular cells, causing them to organize follicular clusters.There is a gonadal receptor for H-Y antigen: fetal ovarian cells that have been exposed to soluble H-Y (released for example by testicular Sertoli cells) take up the molecule and acquire the H-Y⁺ phenotype; they absorb H-Y antibody in serological tests. Specific uptake of soluble H-Y does not occur in the extra-gonadal tissues.It may be inferred that H-Y antigen is disseminated during embryogenesis and bound by specific receptors in cells of the primordial gonad, and that reaction of H-Y and its receptor signals a program of testicular differentiation, regardless of karyotype. The several anomalies of primary sexual differentiation manifest in such conditions as the XX male, the XX true hermaphrodite, and the XY female can thus reasonably be viewed as specific errors of synthesis, dissemination, and binding of H-Y antigen.H-Y is secreted by Daudi cells, cultured from a human XY Burkitt lymphoma. The Daudi-secreted moiety is a single hydrophobic protein of 18,000 molecular weight. Early attempts to characterize H-Y secreted by testicular Sertoli cells have yielded two molecules, one of 16,500 MW (corresponding to the Daudi-secreted 18,000 MW protein), and one of 31,000 MW. It remains to be ascertained whether both are in fact H-Y antigens, and if so, whether one is a polymer of the other, or whether each represents the product of genes with discrete testis-determining functions.     

Increased H-Y antigen levels associated with behaviorally induced, female-to-male sex reversal in a coral-reef fish

It has been proposed that H-Y antigen is the synthetic product of sex-determining genes, and that H-Y antigen controls ontogenetic differentiation of the heterogametic sex throughout vertebrates. The coral-reef fish Anthias squamipinnis is a protogynous hermaphrodite in which all individuals mature initially as females. Males result when adult females change sex as a consequence of alterations in behavioral interactions within social groups. Three assay methods were used to measure H-Y antigen levels in the spleens, gonads, and epidermal tissue of 16 adult females and in 16 males that had been induced to change sex from a prior female phase by the removal of a pre-existing male from each of 16 social groups. In 15 male-female pairs, the H-Y antigen levels were higher in male than in female spleen, gonad, and epidermis tissues. The precise temporal relationship between the onset of sex change and the increase in the H-Y antigen level was not examined. If, as we strongly suspect, the temporal relationship proves to be close, the inference will be that the behavioral cues inducing sex change also influence the synthetic activity of genes controlling H-Y antigen production.     

H-Y Antigen Expression in Temperature Sex-Reversed Turtles (Emys orbicularis)

H-Y antigen has been used as a marker for the heterogametic sex and is assumed to be an organizing factor for the heterogametic gonad. In the turtle Emys orbicularis , H-Y antigen is restricted to the female cells, indicating a female heterogamety (ZZ/ZW) sex-determining mechanism. Moreover, the sexual differentiation of the gonads is temperature sensitive, and complete sex reversal can be obtained at will. In this framework the relationships between H-Y antigen, temperature, and gonadal phenotype were studied. Mouse H-Y antiserum was absorbed with blood and gonadal cells of control wild male and female adults, and with blood and gonadal cells from three lots of young turtles from eggs incubated at 25–26°C (100% phenotypic males), at 30–30.5°C (100% phenotypic females), or at 28.5–29°C (majority of females with some males and intersexes). The residual activity of H-Y antiserum was then estimated using an immunobacterial rosette technique. In adults, both blood cells and gonadal cells were typed as H-Y negative in males and as H-Y positive in females. In each of the three lots of young, blood cells were H-Y negative in some individuals and H-Y positive in others. The proposed interpretation is that the H-Y negative individuals were genotypic males (ZZ) and the H-Y positive were genotypic females (ZW). The gonads of these animals were then pooled in different sets according to their sexual phenotype and to the presumed genotypic sex (i.e., blood H-Y phenotype). Testicular cells were typed as H-Y negative in genotypic males as well as in the presumed sex-reversed genotypic females; likewise, ovarian cells were typed as H-Y positive in genotypic females as well as in the presumed sex-reversed genotypic males. These results provide additional evidence that H-Y antigen expression is closely associated with ovarian structure in vertebrates displaying a ZZ/ZW sex-determining mechanism.     

Sexuality and hermaphroditism in fishes. I. Synchronous functional hermaphroditism in the serranid fish Serranus scriba L

Anatomical and histological examination of Serranus scriba L. showed the existence of primary females (67%), hermaphrodites (31%) and primary males (2%). Synchronous functional hermaphroditism is described on the basis of an anatomical and histological study of the gonads. Although they function simultaneously, the testicular and ovarian parts of hermaphrodite gonads have completely separate ducts. Females and hermaphrodites have the same annual reproduction cycle. In hermaphrodites, the testicular part matures one month sooner than the ovarian part. Cross fertilization between primary females and hermaphrodite individuals and between two different hermaphrodites probably occurs, while self-fertilization is less likely. The testicular tissues of primary males are of the acinar type and those of hermaphrodites are of the radial type. It is possible that primary males do not take part in reproduction. Serranus scriba in Egyptian Mediterranean waters is a longperiod spawner, which spawns from June to the end of October, i.e. it is a summer-autumn spawner.     

XY female mice express H-Y antigen

Karyotypically XY individuals of the C57BL/6J-Y^POS mouse stock develop as females or hermaphrodites, but never as normal males. The aberrant sexual development results from the interaction of the C57BL/6J genetic background with the M. poschiavinus-derived Y chromosome. XY females from this stock were assayed for H-Y antigen. By the criteria of skin-grafting, the cell-mediated lympholysis test, and the popliteal lymph node assay, these XY females are antigenically indistinguishable from normal C57BL/6 males. Implications for the hypothesis that H-Y antigen induces formation of the mammalian testis are discussed.     

Androdioecy and hermaphroditism in five species of clam shrimps (Crustacea: Branchiopoda: Spinicaudata) from India and Thailand

Crustaceans in the order Spinicaudata display a broad range of reproductive strategies, ranging from pure hermaphroditism to pure dioecy (separate males and females), and intermediate combinations. One particularly interesting genus of these “clam shrimps” is Eulimnadia. Based on offspring sex ratios, it has been suggested that all members of the genus are androdioecious: populations consist of mixtures of males and hermaphrodites. However, only two of the ~40 species in this genus have been examined histologically to confirm the presence of ovotestes in the purported hermaphrodites of this group. Here, we report both sex ratio and histological evidence showing that populations of five additional Eulimnadia species from India and Thailand are indeed mixes of males and hermaphrodites (four species) or hermaphrodite only (one species). Sex ratios of adults and offspring from isolated hermaphrodites are in accordance with those previously reported for 15 Eulimnadia species, and histological assays of four of the five species show the presence of both testicular and ovarian tissue in these hermaphrodites. As has been previously reported, the testicular tissue in members of these Eulimnadia spp. is located in a small section at the distal end of the gonad. In addition, the sperm produced in these hermaphrodites forms distinct plaques of compacted chromatin. Overall, these data are consistent with a single origin of hermaphroditism in Eulimnadia, and support the notion that all members of the genus are either androdioecious or all‐hermaphroditic.     

Gonadal development in T16H/XSxr hermaphrodite mice

Sexual development was studied in 25 hermaphrodite mice with the genotype T16H/XSxr. The majority of the animals had a male phenotype similar to that seen in XXSxr males. A few, however, had feminized external genitalia and were classified as females. Examination of the gonads and reproductive tracts of the male hermaphrodites revealed a strong tendency for the left gonad to be more masculine than the right. Most of the gonads in male and female hermaphrodites appeared to be ovaries or testes rather than ovotestes.     

The etiology of maleness in XX men

Summary Information relating to the etiology of human XX males is reviewed. The lesser body height and smaller tooth size in comparison with control males and first-degree male relatives could imply that the patients never had any Y chromosome. Neither reports of occasional mitoses with a Y chromosome, nor of the occurrence of Y chromatin in Sertoli cells are convincing enough to support the idea that low-grade or circumscribed mosaicism is a common etiologic factor. Reports of an increase in length of one of the X chromosomes in XX males are few and some are conflicting. Nor is there any evidence to support the idea of loss of material. However, absence of visible cytogenetic alteration does not rule out the possibility of translocations, exchanges or deletions.A few familial cases are known. Mendelian gene mutations may account for a number of instances of XX males, similar genes being well known in several animal species. The existing geographical differences in the prevalence of human XX males could be explained by differences in gene frequency. But if gene mutation were a common cause of XX maleness there would be more familial cases.Any hypothesis explaining the etiology of XX males should take into account the following facts. There are at least 4 examples of XX males who have inherited the Xg allele carried by their fathers, and at least 9 of such males who have not. The frequency of the Xg phenotype among XX males is far closer to that of males than to that of females, while the absence of any color-blind XX males (among 40 tested) resembles the distribution in females. Furthermore, H-Y antigen is present in XX males, often at a strength intermediate between that in normal males and females. Finally, in a pedigree comprising three independently ascertained XX males, the mothers of all three are H-Y antigen-positive, and the pattern of inheritance of the antigen in two of them precludes X-chromosomal transmission.Many of the data are consistent with the hypothesis that XX males arise through interchange of the testic-determining gene on the Y chromosome and a portion of the X chromosome containing the Xg gene. However, actual evidence in favor of this hypothesis is still lacking, and the H-Y antigen data are not easy to explain. In contrast, if recent hypotheses on the mechanisms controlling the expression of H-Y antigen are confirmed, a gene exerting negative control on testis determination would be located near the end of of the short arm of the X chromosome. This putative gene is believed not to be inactivated in normal females, for at least two other genes located in the same region, i.e. Xg and steroid sulfatase, are not. Deletion or inactivation of these loci would explain how XX males arise and would be consistent with most, but not all, the facts.There is yet no single hypothesis that by itself can explain all the facts accumulated about XX males. While mosaicism appears very unlikely in most cases, Mendelian gene mutation, translocation, X-Y interchange, a minute deletion or preferential inactivation of an X chromosome, or part thereof, remain possible. The etiology of XX maleness may well be heterogeneous.     

Gonadal Growth in Embryos of Sex reversed Mice

Gonadal volumes were measured in litters of mouse embryos, aged 15 and 16 days, which were segregating for the Sex reversed factor. The testes of XY embryos were much larger than the ovaries of female embryos and the testes of XX Sex reversed males were almost, but not quite, as large as those of XY males. One of the 13 Sex reversed embryos had ovotestes.
It is concluded that the Sex reversed factor causes an increase in the growth rate of XX gonadal rudiments and that this is a necessary prerequisite for testicular differentiation. It is further postulated that the failure of spermatogenesis seen in adult Sex reversed , XX males is a result of the suboptimal growth rate of the gonads, compared to that of normal testes seen in the embryos. The formation of ovotestes may result from a growth rate which is at a lower limit of that necessary for testicular differentiation.     

Testes of XX ↔ XY chimeric mice develop from fetal ovotestes

The majority of XX ? XY chimeric mice develop into fertile males. The sexual differentiation of the gonads in these animals has been examined on days 12–14 postcoitum to determine if their development parallels that of normal testes. It was found that 50% of chimeric fetuses, the proportion predicted to be XX ? XY, had neither normal testes nor ovaries. Instead, ovotestes were present, with varying proportions of presumptive ovarian and testicular tissue. On day 12 the ovotestes were organized with testicular tissue in the central region and ovarian tissue at the craniad and/or caudad poles. In the more advanced fetuses there was evidence of regression of the ovarian portion, which would account for the testes found in adults. These results are discussed in light of current theories of sex determination and differentiation and what was previously known about gonads of sex mosaics.     

X-linked genes of the H-Y antigen system in the wood lemming (Myopus schisticolor)

Summary H-Y antigen was investigated in 18 specimens representing six different sex chromosome constitutions of the wood lemming (Myopus schisticolor). The control range of H-Y antigen was defined by the sex difference between normal XX females (H-Y negativeper definitionem) and normal XY males (H-Y positive, full titer). H-Y antigen titers of the X^*Y and X^*0 females were in the male control range, while in the X^*X and X0 females the titers were intermediary. Data were obtained with two different H-Y antigen assays: the Raji cell cytotoxicity test and the peroxidase-antiperoxidase (PAP) method. Fibroblasts, gonadal cells, and spleen cells were checked. Presence of full titers of H-Y antigen in the absence of testis differentiation is readily explained by the assumption of a deficiency of the gonadspecific receptor of H-Y antigen. Since sex reversal is inherited as an X-linked trait, genes for this receptor are most likely X-linked. The implications of our findings are discussed in connection with earlier findings concerning H-Y antigen in XY gonadal dysgenesis in man and the X0 situation in man and mouse.