H-Y antigens

H-Y antigen is defined as a male histocompatibility antigen that causes rejection of male skin grafts by female recipients of the same inbred strain of rodents. Male-specific, or H-Y antigen(s), are also detected by cytotoxic T cells and antibodies. H-Y antigen appears to be an integral part of the membrane of most male cells. In addition, H-Y antibodies detect a soluble form of H-Y that is secreted by the testis. The gene (Smcy/SMCY) coding for H-Y antigen detected by T cells has been cloned. It is expressed ubiquitously in male mice and humans, and encodes an epitope that triggers a specific T -cell response in vitro. Additional epitopes coded for by different Y-chromosomal genes are probably required in vivo for the rejection of male grafts by female hosts. The molecular nature of H-Y antigen detected by antibodies on most male cells is not yet known. Testis-secreted, soluble H-Y antigen, however, was found to be identical to Müllerian-inhibiting substance (MIS). MIS cross-reacts with H-Y antibodies and identical findings were obtained for soluble H-Y antigen and MIS, i.e., secretion by testicular Sertoli and, to a lesser degree, ovarian cells, binding to a gonad-specific receptor, induction of gonadal sex reversal in vitro and, in cattle, in vivo. H-Y antisera also detect a molecule or molecules associated with the heterogametic sex in nonmammalian vertebrates. Molecular data on this antigen or antigens are not yet available.     

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.     

(AGCTG) (AGCTG) (AGCTG) (GGGTG) as the primordial sequence of intergenic spacers: the role in immunoglobulin class switch

The means employed for immunoglobulin heavy chain class switch appears to be no different from that by which meiotic intergenic crossing-overs at accomplished. As with other intergenic spacers, the 5' noncoding sequence of each Ig CH (immunoglobulin heavy chain constant region) gene apparently undergoes unconstrained sequence changes due to randomly sustained base substitutions, deletions, and duplications. Yet, there remains sufficient regional sequence homology between the Ig Cmu 5' noncoding sequence and those of its somatic recombination partners, e.g., Ig C gamma 1, Ig C gamma 2b, Ig C alpha, because each of these 5' noncoding sequences is made of multiple copies in various stages of degeneracy of one primordial 20 base pair-long sequence: (AGCTG) (AGCTG) (AGCTG) (GGGTG).     

(AGCTG) (AGCTG) (AGCTG) (GGGTG) as the Primordial Sequence of Intergenic Spacers: The Role in Immunoglobulin Class Switch

The means employed for immunoglobulin heavy chain class switch appears to be no different from that by which meiotic intergenic crossing-overs are accomplished. As with other intergenic spacers, the 5' noncoding sequence of each Ig C_H (immunoglobulin heavy chain constant region) gene apparently undergoes unconstrained sequence changes due to randomly sustained base substitutions, deletions, and duplications. Yet, there remains sufficient regional sequence homology between the Ig C_μ 5' noncoding sequence and those of its somatic recombination partners, e.g., Ig C_γ1, Ig C_γ2b, Ig C_α, because each of these 5' noncoding sequences is made of multiple copies in various stages of degeneracy of one primordial 20 base pair-long sequence: (AGCTG) (AGCTG) (AGCTG) (GGGTG).     

H-Y Antigen and Sex-Determination in Turtles

H-Y antigen was investigated in 14 turtle species belonging to five different families. In 13 species the female was typed as H-Y antigen positive, only in Chinemys reevesi was the male H-Y antigen positive. Since in all vertebrate species studied till now, the expression of H-Y antigen is strictly correlated with the heterogametic sex, it can be assumed that in turtles both types of sex determining mechanisms are realized, namely the ZZ/ZW-and the XX/XY mechanism; both mechanisms are realized in species belonging to one and the same turtle family. However, most turtle species seem to be endowed with a ZZ/ZW sex determining mechanism.     

Expression of the H-Y Antigen on thymus cells and skin: Differential genetic control linked toK end ofH-2

The strength of the H-Y antigen on thymus cells and on skin was compared in differentH-2-congenic mouse strains using a host-versus-graft reaction popliteal lymph node assay, and skin grafts from males of parental strains grafted to F₁ hybrid females. The results revealed considerable differences in the strength of the H-Y antigen among different congenic strains; these differences demonstrate the effect of theH-2-linked gene on the expression of the H-Y antigen. The linkage withH-2 was also confirmed in tests with segregating F₂ generations. In the strains bearing recombinantH-2 haplotypes, the strength of the H-Y antigen is similar to that of parental strain from which the recombinant received itsK end, and the responsible gene (or genes) map to the left ofI-C. The effect of theH-2-linked gene(s) on thymus cells and skin is different. The gene linked to theK end ofH- 2^b determines a strong H-Y antigen on thymus cells, but a relatively weak H-Y antigen on skin. The gene linked to theK end ofH- 2^k determines a weak H-Y antigen on thymus cells, but a strong H-Y antigen on skin. The gene linked to theK end ofH- 2^d determines a weak H-Y antigen on both thymus cells and skin. Our observations raise the possibility that the structural gene for the H-Y antigen is linked toH-2. Alternative (but not exclusive) explanations invoke regulatory effects ofH-2 on the expression of the H-Y antigen, possibly by means of the control of the cellular andogen receptors.     

Conservatism of the H-Y/H-W receptor

Summary Soluble H-Y antigen is taken up by cells of the homogametic gonad of cattle, dog, chicken and South African clawed frog. After in vitro exposure to mouse testis supernatant or male fetal calf serum, XX ovary cells or ZZ testis cells, which are normally H-Y^-, acquire the H-Y⁺ (H-W⁺) phenotype and absorb mouse H-Y antibody in standard serological assays. In addition, H-Y antigens of the different species can compete for attachment to target cells of a single species. In a new competitive binding radioassay, uptake of tritiated human H-Y is blocked in XX bovine fetal ovarian cells exposed to non-labeled H-Y of mouse or fetal bull. Because H-Y antigens of the different species are cross-reactive serologically, positive reaction of H-Y from one species with gonadal cells of another signifies structural conservatism of the H-Y/H-W gonadal receptor. It follows that establishment of the H-Y/H-W-receptor complex is a common and critical early event in primary sex differentiation of the vertebrates, directing the initially indifferent embryonic gonad towards the heterogametic mode, which may be testicular or ovarian, depending on the species.     

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.     

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.     

Immunological and functional aspects of H-Y antigen

Summary Male-specific H-Y antigen may be defined by graft rejection, killer cell action or antibodies. Most commonly H-Y antigen is detected in assays using H-Y antisera. In these tests errors may arise from various causes: 1) Auto- and heteroantibodies cross-reacting with target cells. 2) Restriction phenomena. 3) MHC-dependent modification of the amount of H-Y antigen present on different tissues. 4) Modification of cell surface antigens by bacteria or viruses.Regarding the third definition of H-Y antigen, four different states can be distinguished in the mammalian male. H-Y occurs (1) as an integral part of the plasma membrane; (2) unspecifically attached to the membrane of human erythrocytes; (3) free in solution; (4) bound to its gonad-specific receptor.Redistribution experiments suggest that H-Y and ₂-m are associated on the cell membrane. Coredistribution is not found of H-Y and MHC antigens. An antibody blocking technique demonstrates association of H-Y and H-2D antigens on unfixed lymphoid, but not on testicular cells. Human erythrocytes lacking ₂-m do not integrate H-Y antigen into the cell membrane. Male erythrocytes, however, absorb H-Y antigen from the serum. The origin of H-Y antigen in the serum is not clear. It may be shed from cell membranes, derive from the testis which actively secretes H-Y antigen, or both.H-Y antigen is bound by a gonad-specific receptor. This receptor is present in the gonads of both sexes. H-Y antigen is supposed to mediate testis differentiation via this receptor. Reaggregation experiments in vitro using dissociated gonads of the newborn rat demonstrate that ovarian cells reorganize into testicular structures in the presence of H-Y antigen. The assumption cannot be confirmed that addition of H-Y antiserum to testicular cells results in ovarian structures. This finding, however, does not conflict with the view that H-Y antigen is involved in testis differentiation, e.g. by inducing testis cell-specific functions via the gonad-specific receptor.     

H-Y antigen in transsexuality,and how to explain testis differentiation in H-Y antigen-negative males and ovary differentiation in H-Y antigen-positive females

Summary H-Y antigen was determined in eight transsexual patients. Two of the four male-to-female transsexual patients typed as H-Y antigen-negative, while the other two typed as expected from their phenotypic and gonadal sex, namely H-Y antigen-positive. Of the four female-to-male transsexual patients, three typed as H-Y antigen-positive and one was H-Y antigen-negative, as expected. The presence of normal testes in H-Y antigen-negative males is assumed to result from a mutation of nucleotide sequences of the H-Y structural gene for antigenic determinants. Thus, an H-Y is produced with normal receptor-binding activity which can sustain the testis determination of the bipotent gonadal anlage. In the case of H-Y antigen-positive females with normal ovaries a deletion of the autosomally located H-Y structural gene is assumed. This deletion should affect sequences for repressor-binding (as was suggested for H-Y antigen-positive XX-males) and for receptor-binding activity of the H-Y antigen molecule. The resulting H-Y antigen is unable to bind to the gonadal receptor of the bipotent gonadal anlage. Thus an ovary is determined. The relevance of H-Y antigen for the aetiology of transsexualism is discussed.     

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.     

Complete chloroplast genome sequences of Solanum bulbocastanum, Solanum lycopersicum and comparative analyses with other Solanaceae genomes

Despite the agricultural importance of both potato and tomato, very little is known about their chloroplast genomes. Analysis of the complete sequences of tomato, potato, tobacco, and Atropa chloroplast genomes reveals significant insertions and deletions within certain coding regions or regulatory sequences (e.g., deletion of repeated sequences within 16S rRNA, ycf2 or ribosomal binding sites in ycf2). RNA, photosynthesis, and atp synthase genes are the least divergent and the most divergent genes are clpP, cemA, ccsA, and matK. Repeat analyses identified 33–45 direct and inverted repeats ≥30 bp with a sequence identity of at least 90%; all but five of the repeats shared by all four Solanaceae genomes are located in the same genes or intergenic regions, suggesting a functional role. A comprehensive genome-wide analysis of all coding sequences and intergenic spacer regions was done for the first time in chloroplast genomes. Only four spacer regions are fully conserved (100% sequence identity) among all genomes; deletions or insertions within some intergenic spacer regions result in less than 25% sequence identity, underscoring the importance of choosing appropriate intergenic spacers for plastid transformation and providing valuable new information for phylogenetic utility of the chloroplast intergenic spacer regions. Comparison of coding sequences with expressed sequence tags showed considerable amount of variation, resulting in amino acid changes; none of the C-to-U conversions observed in potato and tomato were conserved in tobacco and Atropa. It is possible that there has been a loss of conserved editing sites in potato and tomato.Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

A quantitative radioimmunoassay for membranous and soluble H-Y antigen typing

Summary Two sensitive and quantitative methods for membranous or soluble H-Y antigen typing using rat anti-H-Y immune sera and ¹²⁵I labelled protein A were carried out.These techniques were used to study H-Y antigen expression in human cell lines, and to refine the hypothesis that ( ₂m) serves as an anchorage point for H-Y antigen.     

Sequence Variation and Comparison of the 5S rRNA Sequences in <Emphasis Type="Italic">Allium</Emphasis> Species and their Chromosomal Distribution in Four <Emphasis Type="Italic">Allium</Emphasis> Species

The gene structure and sequence diversity of 5S rRNA genes were analyzed in 13 Allium species. While the lengths and sequences of the coding gene segments were conserved, the spacers were highly variable and could be characterized as either short (213–404 bp) or long (384–486 bp) spacers. The short spacers were further classified into five subtypes (SS-I to SS-V) and the long spacers into four subtypes (LS-I to LS-IV). The short spacers were more conserved than were the long spacers. There was a sequence duplication of 85 bp in SS-III that distinguished it from SS-II. The coding sequences of the 5S rRNA genes started with CGG and ended with either CCC or TCC. Both long and short spacers started with TTTT at their 5′-ends. However, the long spacers ended with a 3′-TGA sequence, whereas the short spacers terminated with various sequences, such as TTA, ATA, or TGA. GC content ranged from 27 to 41% in whole repeats, and the GC content in the long spacers was lower than in the short spacers. The nucleotide diversity in the coding regions was lower than in the spacers, and the nucleotide diversity in the coding regions did not correlate with that of the spacers. FISH analysis confirmed that each Allium species has either short spacers or long spacers. Although chromosomal locations of the 5S rRNA genes in Allium wakegi confirmed the allodiploid nature of A. cepa and A. fistulosum, spacer sequences revealed the absence of SS-II in A. cepa and in A. wakegi. The current study demonstrated that the 5S rRNA genes diverged in early stages in Allium species differentiation except of the allodiploid A. wakegi.     

Testis-determining H-Y antigen in XO males of the mole-vole (Ellobius lutescens)

The XO sex chromosome constitution has been found in both sexes of the mole-vole (Ellobius lutescens) belonging to the rodent family Microtinae. This enigmatic species has apparently been enduring a 50% zygotic lethality. The current serological study revealed the presence in XO males and the absence from XO females of H-Y (histocompatibility Y) antigen. In all the mammalian species studied thus far, the expression of H-Y antigen strictly coincided with the presence of testicular tissue and not necessarily with the presence of the Y chromosome. The testis-organizing function of the H-Y gene appears to have been confirmed.In the mole-vole, X linkage of the testis-organizing H-Y gene is favored over its autosomal inheritance. Only X linkage of the H-Y gene creates a compelling evolutionary need to change the female sex chromosome constitution from XX to XO, and to abandon the dosage compensation by an X inactivation mechanism, so that the nonproductive X^H-YX zygote can be eliminated as an embryonic lethal. With regard to the electrophoretic mobilities of three X-linked marker enzymes, however, a genetic difference between the male-specific X^H-Y and the female-specific X was not detected. This might reflect a relatively recent speciation.     

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.     

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.     

H-Y binding in the gonad: inhibition by a supernatant of the fetal ovary.

H-Y antigen, the product of mammalian testis-determining genes, is released in the free state by testicular cells. Molecules of free H-Y antigen are bound in vitro by dispersed cells of the adult ovary. The binding reaction is inhibited by specific H-Y antibody. It is also inhibited by a diffusible factor of the newly differentiated fetal ovary. These observations favor the view that testicular organogenesis depend upon dissemination and binding of H-Y molecules by cells of the undifferentiated gonad (XY or XX, both having H-Y receptors), and raise the question of whether ovarian organogenesis may be promoted by a "female" molecule corresponding to H-Y of the male.     

Does H-Y antigen induce the heterogametic ovary?

To determine whether phylogenetically conservative H-Y antigen plays any part in gonadal differentiation among the nonmammalian vertebrates, we studied expression and binding of H-Y in the frog, Xenopus laevis. Soluble H-Y obtained from mouse testis and soluble H-W from chicken ovary bound specifically to cells of the ZZ testis from normal Xenopus males. In addition, H-Y (H-W) appeared selectively in the ovaries of ZZ genetic males that had been induced to become functional females by exposure to estradiol. Our observations suggest that H-Y (H-W) antigen may be involved in differentiation of the ZW ovary, and also that synthesis of H-Y may be regulated by sex steroids in the primitive $\text{ZW}\text{ZZ}$ species.