H-Y antigen: No evidence for alleles in wild strains of mice

H-Y antigen(s) coded or controlled by the Y chromosome in a variety of wild mouse strains have been compared with those of the inbred laboratory strains C57BL/6 (B6) and C57BL/10 (B10). H-Y antigen(s) were detected by H-2-restricted cytotoxic T cells from B6 and B10 female mice primed in vivo and boosted in vitro with syngeneic male spleen cells: There was no difference in the degree of H-Y specific lysis of male cells from the C57BL strains and of F₁ hybrids or B6 congenic mice carrying the Y chromosome from the wild mouse strains examined. This result indicated that at the level of target cell specificity the H-Y antigen(s) from wild and laboratory strains were indistinguishable. H-Y antigen(s) were also found to be indistinguishable at the level of the in vitro induction of the anti H-Y cytotoxic response: F₁ female mice, primed in vivo and boosted in vitro with homologous F₁ male cells, all made H-Y-specific responses and where it could be examined, the target cell specificity of the anti-H-Y cytotoxic cells showed that B10 male cells as well as the homologous F₁ male cells (where the Y chromosome was derived from the wild strain) were good targets. Finally, possible differences in H-Y transplantation antigens between the wild strains and the B10 laboratory strain were examined by grafting F₁ male mice, the progeny of B10 females, and wild strain males with B10 male skin. These grafts were not rejected during an observation period of more than 9 months. Taken together, neither the cytotoxic data nor the skin graft data provide any evidence for allelism of H-Y even though the mouse strains examined were collected from widely disparate geographical locations.     

Serological evidence for H-Y antigen in XO-female mice

Summary H-Y antigen was examined in XX-, XY-, and XO-mice using spleen, kidney, and liver cells of the animals for the absorption of the anti-H-Y antiserum produced in the rat. The cells of the XY- and XO-mice were found to be H-Y antigenpositive while the cells of the XX-mice were negative. As in Turner syndrome patients with 45,X, in the XO-female mice the H-Y antigen titre was reduced as compared to normal XY-male mice; intermediate values between those of normal male and female mice were obtained. These results clearly indicate that as in man, in the mouse the structural gene for H-Y antigen is not Y-linked but is located on an autosome. Furthermore, the concept of the regulation of the H-Y antigen gene expression in the human (Wolf et al. 1980a, b) by an X-linked repressor gene, escaping X-inactivation in the XX-female and an Y-linked inducer gene also seems to hold true in the mouse.     

H-Y transplantation antigen in human XO females

Summary When sensitized with human cultured fibroblasts of the XY and XO, but not XX, sex chromosomal types C57BL/6 female mice reject syngeneic male grafts accelerated (second set graft reaction). These findings demonstrate that the antigenic determinants of H-Y antigen of man and mouse are homologous and that XO females (at least those tested) carry the H-Y transplantation antigen. The results are discussed in the light of the question of differences between the H-Y antigen as defined by grafting and serology and the chromosomal localization of the H-Y structural gene(s).     

The H-Y antigen and its role in natural transplantation

Summary A concise overview of the transplantation biology of the H-Y antigen is presented with particular reference to: its prototypic behavior as a weak transplantation antigen; the facility with which mice of certain inbred strains can be rendered tolerant of H-Y incompatible skin grafts; its capacity to instigate graft-versus-host reactions; its significance in clinical transplantation; and finally, H-2 control of anti-H-Y immune responses.The role of the H-Y antigen in natural transplantation, i.e. pregnancy, is then reviewed. Evidence is presented to support the hypothesis that in certain cases maternal immune responses directed specifically to the H-Y antigen can exert selective pressures on male zygotes, producing deviant sex ratios in certain experimental and clinical situations.     

H-Y antigen expression in different tissues from transsexuals

Summary H-Y-antigen expression was analyzed in patients with transsexuality. Peripheral blood lymphocytes and various tissues were examined using the cytotoxicity assay of Goldberg et al. (1971). Peripheral blood lymphocytes from healthy male and female subjects were used as controls as well as tissues from nontranssexual individuals and from male and female C57Bl/6J mice. In three female-to-male transsexuals the peripheral blood lymphocytes were H-Y antigen positive. In these patients also their ovaries, uterus, and mammae were found to be H-Y antigen positive. Three male-to-female transsexuals were examined. The peripheral blood lymphocytes in two of these patients were found to be H-Y antigen negative. Their testes were also H-Y antigen negative, as well as the epididymus, the corpus cavernosum penis, and the cremaster muscle which was analyzed in one of them. One male-to-female transsexual had peripheral blood lymphocytes which were H-Y antigen positive; this patient had testis and corpus cavernosum penis which were also H-Y-antigen positive.     

H-Y antigen in Turner's syndrome patients with different sex chromosome constitutions

Summary H-Y antigen was determined in seven XO-, nine XO/XX patients, in one patient with i(Xq), and in one patient with a mosaic XO/XYqh-. It turned out that all patients are H-Y antigen positive, confirming the results of earlier investigations of H-Y antigen in patients with Turner's syndrome. The results in XO/XX mosaics clearly demonstrate that the XO-cell is H-Y antigen positive and support the view of a regulatory gene for H-Y antigen gene expression which is located on the X chromosome.     

H-Y antigen in the teleost

H-Y antigen, presumably the product of mammalian testis-determining genes, has been detected in three species of teleost fish, Xiphophorus maculatus. Haplochromis burtoni, and Oryzias latipes, and in hybrids of the genus Tilapia. In X. maculatus H-Y was most readily detected in YY males, suggesting that a genetic determinant of H-Y antigen expression may exist on the teleost Y-chromosome. Although H-Y was detected in males and not in feamles in each of the species that we studied, male heterogamety has not been firmly established for H. burtoni. Thus despite the extreme phlyogenetic conservation of H-Y genes and their association with the Y-chromosome, it remains open to question whether H-Y will always be found in the heterogametic sex, and whether serologically defined H-Y antigen plays any part in the differentiation of the teleost gonad.     

Cytolytic and fluorescent detection of H-Y antigen on preimplantation mouse embryos

Monoclonal antibodies to histocompatibility (H-Y) antigen, of IgM subclass, were used to immunologically determine the sex of mouse embryos prior to transfer to pseudopregnant recipients. Two experiments were performed, one using cytolysis of H-Y positive embryos and the other using binding of a Fluorescein Isothiocyanate-(FITC) labeled second antibody. Eight- to 16-cell embryos used in the cytolytic assay were cultured in Whitten's Medium without bovine serum albumin (WM), to which monoclonal antibody and normal guinea pig serum were added. Embryos were classified as affected or unaffected, based on morphology of the embryo and its blastomeres. A total of 550 embryos were cultured; 294 (53.5%) were scored as unaffected and 263 of these were transferred to recipients. Forty-three (81.1%) of 53 pups born were female. Morulae and early blastocysts were used in the FITC-labeled second antibody assay. Embryos were cultured in WM containing monoclonal antibody, washed and placed in drops of WM containing FITC-labeled anti-IgM. Following another wash embryos were individually evaluated at 200X for fluorescence. Fifty-five percent (169 of 305) of the embryos displayed cell-specific fluorescence. A total of twenty-three pups, 18 males (78.3%) and five females (21.7%), were born following transfer of 156 fluorescing embryos. Four male (17.4%) and nineteen female (82.6%) pups resulted from embryos classified as non-fluorescing.     

Sharing of an HLA-B27-restricted H-Y antigen between rat and mouse

The purpose of this work was twofold: 1 to learn whether rats transgenic for HLA-B27 and the human ₂-microglobulin gene HB2M can mount B27-restricted cytolytic T lymphocyte (CTL) responses to the male H-Y antigen, and 2 to learn whether such CTLs would recognize both rat and mouse H-Y in the context of HLA-B27. Female rats of the B27/HB2M transgenic line 21-4L were primed in vivo with cells from males of the same line. CTL effectors were generated from lymph node cells of these females following culture with irradiated antigen-presenting cells from either male 21-4L rats or male mice of the B27/HB2M transgenic 56-3 line. The CTLs showed male-specific, B27-specific lysis of both rat and mouse targets. Lysis of B27 targets was inhibitable by monoclonal antibodies specific for B27 or rat CD8. Specific lysis of male B27 rat and mouse targets was inhibitable equally by either rat or mouse male B27 cold targets, but not significantly by female or nontransgenic cold targets. The B27-restricted CTLs neither recognized nor were inhibited by B27⁺ or B27^- male or female human targets. These results demonstrate that CD8⁺, B27-restricted, anti-H-Y CTLs recognize and evolutionarily conserved H-Y peptide antigen in both rats and mice. In addition, they establish the transgenic rat as a model system for examining the T-cell response to antigen presented by class I HLA molecules. Correspondence to: J. D. Taurog.     

Studies on H-Y antigen in different cell fractions of the testis during pubescence

Summary Various cell types of the rat testis during pubescence, including germ, Sertoli, and Leydig cells, were partially enriched. The fractions were tested for the presence, binding, and secretion of H-Y antigen. The main results are: Immature germ cells are H-Y antigen-negative until the late diploid stages, and late primary spermatocytes or spermatids become positive; the somatic cells of the gonad are positive at all ages examined (18 days old to adulthood). Secretion of H-Y antigen is restricted to the Sertoli cell fraction. Binding of externally supplied antigen takes place on Leydig cells; the Sertoli cell surface will be saturated because of active secretion; there is no binding to germ cells. Thus, immature germ cells seem to be the only H-Y antigen-negative cells of the male organism, and the Sertoli cells seem to be the only ones to secrete H-Y antigen.     

H-Y antigen and sexual dysgenesis in man

H-Y antigen is a surface component associated with the heterogametic sex of various species and supposed to induce testicular differentiation. Genes controlling directly or not the expression of H-Y antigen and testicular differentiation have been localized on Y as well as on X chromosome and even autosomal chromosome. However the genetical localization of the H-Y structural gene remains unknown. We analysed the expression of H-Y antigen in three types of sexual dysgenesis (males bearing XX caryotype, testicular feminization syndrome and one case of hermaphroditism) to clarify the function and the genetics of this antigen.     

Studies on the H-Y antigen in rats

The H-Y antigen has been studied under a variety of experimental conditions in BN and Lewis rats. The results indicate that 1. graft size is crucially important in determining the fate of male skin isografts on females; 2. H-Y incompatible ear skin grafts survive significantly better than those of trunk origin; 3. prior exposure of females to male lymphoid cells greatly increases their capacity to reject male skin isografts; 4. neonatal castration has no influence on the expression of H-Y; 5. multiparity can induce unresponsiveness to H-Y; and 6. although BN females respond better than do Lewis females to H-Y, the antigen is stronger in Lewis males. These findings are compared with the results of similar experiments conducted with mice.Submitted in memory of Dr. Joy Palm, member of the Wistar Institute, who pioneered the genetic analysis of histocompatibility in rats.     

The testis as a secretory organ for H-Y antigen

Summary After cultivation of dissociated rat testicular tissues, H-Y antigen is detectable in the medium; this is not the case if nongonadal male tissues are incubated. Release of H-Y antigen by testis cells is inhibited by the addition of cycloheximide. All tissues still type H-Y positive after culture. It is assumed that the testis actively secretes H-Y antigen. This assumption is supported by the finding that the amount of H-Y antigen in the epididymal fluid increases with the age of the animals.     

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.     

Binding studies of H-Y antigen in rat tissues

Summary The binding capacity for H-Y antigen was studied in various rat tissues of both sexes. In nongonadal tissues (liver, kidney, brain, epidermis) binding could not be demonstrated. In contrast, the gonads are able to bind exogenously supplied H-Y antigen. In the ovary, the binding capacity remains unchanged in newborn and adult animals, while in the testis, this capacity decreases with age. A receptor like that of a proteohormone is assumed to exist in the gonads but not in other tissues. In nongonadal tissues, H-Y antigen apparently is present only if the cell itself synthesizes the antigen. The H-Y antigen receptor of the gonads is not sex-specific. Thus, the primary sex differentiation depends on whether H-Y antigen is synthesized in the organism.