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.     

In vitro studies of gonadal organogenesis in the presence and absence of H-Y antigen.

In a very strict sense, the primary (gonadal) sex of mammals is determined not so much by the presence or absence of the Y but the expression or nonexpression of the evolutionary extremely conserved plasma membrane H-Y antigen. The central somatic blastema of embryonic indifferent gonads contains one cell lineage characterized by the possession of S-F differentiation antigen that differentiates into testicular Sertoli cells in the presence of H-Y and into ovarian follicular (granulosa) cells in its absence. This cell lineage appears to play the most critical role in gonadal differentiation. Whether or not testicular Leydig cells and ovarian theca cells are similarly derived from the common cell lineage has not been determined. Nevertheless, if given H-Y antigen, presumptive theca-cell precursors of the fetal ovary acquire hCG (LH?)-receptors-the characteristic of fetal Leydig cells.     

The effects of neuraminidase and gangliosides on ovarian LH/hCG receptors during rat development

Ovaries of neonatal rats are not endowed with specific LH/hCG receptors up to 6-8 days of age. Treatment of ovarian membranes of the neonatal rat with neuraminidase results in a specific binding of radioactively labeled hCG, while an increase of hormone binding is observed after neuraminidase treatment of ovarian membranes of the 21-day-old rat. These changes in hormone receptor sites in the ovary are dependent on the neuraminidase concentration used and are due to a receptor with a dissociation constant (KD) of about 10(-9) M. The KD of the receptor in the LH/hCG sensitive ovary without neuraminidase treatment is about 10(-10) M. These results indicate the presence of two different LH/hCG receptors in the ovarian membrane. The unmasking effect of neuraminidase onto LH/hCG receptors indicate that ganglioside-like structures are responsible for the masking of receptors in the neonatal, insensitive rat ovary and also in the 21-day-old sensitive ovary. Ganglioside preparations are able to inhibit the binding, and the fractionation of ovary gangliosides results in a fraction with a rather high inhibition potency of LH/hCG binding to the receptor. It is hypothesized that the masked receptor in the sensitive period represent a store of receptors for the reconstitution of the ovarian cells with active receptors after internalization of the hormone-receptor complex. Thus the masking of the receptors in the early postnatal rat ovary could be a prerequisite for the female differentiation of hypothalamic centers. The observed neuraminidase effect in vitro could reflect a physiologic situation. Neuraminidase was found in the ovary, and during early postnatal development the neuraminidase activity pattern coincides with that of the ovarian LH/hCG receptor changes.     

The Effects of Neuraminidase and Gangliosides on Ovarian LH/hCG Receptors During Rat Development

Ovaries of neonatal rats are not endowed with specific LH/hCG receptors up to 6–8 days of age. Treatment of ovarian membranes of the neonatal rat with neuraminidase results in a specific binding of radioactively labeled hCG, while an increase of hormone binding is observed after neuraminidase treatment of ovarian membranes of the 21-day-old rat. These changes in hormone receptor sites in the ovary are dependent on the neuraminidase concentration used and are due to a receptor with a dissociation constant (K_D) of about 10⁻⁹ M. The K_D of the receptor in the LH/hCG sensitive ovary without neuraminidase treatment is about 10⁻¹⁰ M. These results indicate the presence of two different LH/hCG receptors in the ovarian membrane. The unmasking effect of neuraminidase onto LH/hCG receptors indicate that ganglioside-like structures are responsible for the masking of receptors in the neonatal, insensitive rat ovary and also in the 21-day-old sensitive ovary. Ganglioside preparations are able to inhibit the binding, and the fractionation of ovary gangliosides results in a fraction with a rather high inhibition potency of LH/hCG binding to the receptor. It is hypothesized that the masked receptors in the sensitive period represent a store of receptors for the reconstitution of the ovarian cells with active receptors after internalization of the hormone-receptor complex. Thus the masking of the receptors in the early postnatal rat ovary could be a prerequisite for the female differentiation of hypothalamic centers. The observed neuraminidase effect in vitro could reflect a physiologic situation. Neuraminidase was found in the ovary, and during early postnatal development the neuraminidase activity pattern coincides with that of the ovarian LH/hCG receptor changes.     

Regulation of LH/hCG receptor by gonadotropins in rat ovary

To investigate the regulation of the LH/hCG receptor gene by gonadotropins, we examined the effect of PMSG and hCG on the expression of LH/hCG receptor in immature rat ovary. Northern blot analysis of ovarian RNA revealed a major mRNA of 5400 nucleotides and minor species of 7500, 3600, 2300, and 1200 nucleotides, and PMSG treatment slightly increased the intensity of all LH/hCG receptor messengers. Subsequently, hCG treatment decreased the number of LH/hCG receptor by day 2 and mRNA levels by 12h after injection. The level of mRNA recovered and increased 5-fold of control by day 6, then returned to control levels by day 10, followed by slower decline in LH/hCG receptor in plasma membrane. These studies demonstrate that the effects of PMSG and hCG on the number of LH/hCG receptor are closely related to the actions of these hormones on LH/hCG receptor messenger levels.     

In vitro studies of gonadal organogenesis in the presence and absence of H-Y antigen

Summary In a very strict sense, the primary (gonadal) sex of mammals is determined not so much by the presence or absence of the Y but the expression or nonexpression of the evolutionary extremely conserved plasma membrane H-Y antigen. The central somatic blastema of embryonic indifferent gonads contains one cell lineage characterized by the possession of S−F differentiation antigen that differentiates into testicular Sertoli cells in the presence of H-Y and into ovarian follicular (granulosa) cells in its absence. This cell lineage appears to play the most critical role in gonadal differentiation. Whether or not testicular Leydig cells and ovarian theca cells are similarly derived from the common cell lineage has not been determined. Nevertheless, if given H-Y antigen, presumptive theca-cell precursors of the fetal ovary acquire hCG (LH?)-receptors—the characteristic of fetal Leydig cells. Presented in the formal symposium on Sexual Differentiation in Vitro and in Vivo at the 29th Annual Meeting of the Tissue Culture Association, Denver, Colorado, June 4–8, 1978. This work was supported by Contract NO1-CB-33907, and Grants No. 1 RO1 AG00042 and No. 5 RO1 CA16952 from the National Institutes of Health.     

Testicular cells lysostripped of H-Y antigen organize ovarian follicle-like aggregates.

A suspension of free testicular cells were obtained by mild trypsin treatment from newborn BALB/c testes, and their plasma membrane H-Y antigen sites were blocked (lysostripped) by an excess of H-Y antibody of proven specificity and potency (45 min in ice). Upon 16 h of the Moscona-type rotation culture, these treated testicular cells yielded primarily spherical aggregates, more than half of which demonstrated a strong resemblance to ovarian follicles. The resemblance was particularly striking between the smallest testicular folliculoids and primordial ovarian follicles that abound in the newborn female gonad. Under the same condition, control serum-treated testicular cells primarily yielded cylindrical tubular structures that can be very long. Over a critical range, concentrations of H-Y antibody apparently influenced the frequency of testicular folliculoid formation. The above directly supports the proposed testis-organizing function of H-Y antigen and is certainly compatible with the genetic situation encountered in the wood lemming (Myopus schisticolor), that in the functional absence of H-Y antigen, XY gonadal cells readily organize an ovary.     

Evidence for a gonad-specific receptor for H-Y antigen: binding of exogenous H-Y antigen to gonadal cells is independent of beta 2-microglobulin.

This report addresses the question whether two different types of binding exist for the reaction of H-Y antigen with the cell surface. Anti-H-Y antiserum in the presence of complement was cytotoxic only for gonadal cells expressing their own H-Y antigen, but not to ovarian cells loaded with H-Y antigen. H-Y antigen was co-redistributed with beta 2--microglobulin on newborn testicular cells, but some residual H-Y activity was found on similarly treated testis cells from 15 day old rats. After beta 2--microglobulin redistribution, testis cells maintained their binding capacity for exogenous H-Y antigen prepared from epididymal fluid or Daudi cell culture supernatants. This result suggests that exogenous H-Y antigen is bound via a gonad-specific receptor which is independent of beta 2--microglobulin and that this type of binding for H-Y antigen is different from the beta 2--m-associated expression of H-Y antigen on the cell surface.     

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.     

Labeling of LH/hCG receptor in rat ovaries.

Human chorionic gonadotropin (hCG) was found to stimulate the incorporation of [¹⁴C] N-acetyl-D-glucosamine in rat ovary in vitro. Subcellular fractionation of the ovarian tissue revealed that the plasma membranes were stimulated maximally to the extent of 200 to 300% by the hormone indicating the stimulation of the synthesis of plasma membrane glycoproteins. In addition, and appreciable amount of the radioactivity was incorporated in the cell surface LH/hCG receptor. The evidence in support of the labeling of the receptor was derived from the behavior of the detergent solubilized receptor on Sepharose 6B column and on hCG-Sepharose affinity adsorbent. The labeled receptor thus purified showed binding affinity for [¹²⁵I] hCG. Thus, the hormone stimulates the synthesis of cell surface glycoproteins as well as the LH/hCG receptor.     

Purification, characterization, and amino-terminal sequence of rat ovarian receptor for luteinizing hormone/human choriogonadotropin

The luteinizing hormone (LH)/human choriogonadotropin (hCG) receptor of rat ovary was solubilized with Lubrol PX in the presence of 20% glycerol and protease inhibitors, and purified by one-step affinity chromatography. Purified receptor had a specific hCG binding capacity of 4900 pmol/mg protein, and displayed a single class of high affinity binding sites (Ka = 6.20 X 10(9) M-1). An 11,200-fold purification over the starting crude homogenate was achieved. The purified LH/hCG receptor was identified by sodium dodecyl sulfate-gel electrophoresis and silver staining as a single protein of 92 kDa. The ability of the purified 92-kDa protein to specifically bind hormone was demonstrated by electroblotting onto Immobilon P membrane, incubation with 125I-labeled hCG, and autoradiography of the blot. In addition to a 92-kDa band, ligand blotting also yielded a 170-kDa band representing receptor dimer. Covalent cross-linking of hCG, with isotope in either the alpha- or beta-subunit, to membrane-bound receptor produced complexes that contained a single receptor component of approximately 92 kDa. The cross-linking studies indicated that both subunits interact with receptor and also suggested receptor dimer formation. Following sodium dodecyl sulfate-electrophoresis, purified receptor was electroblotted onto polyethylenimine-treated glass fiber filters for direct microsequencing in a gas-phase sequenator. Eleven cycles of sequence analysis yielded the unique sequence: NH2-Arg-Glu-Leu-Ser-Gly-Ser-Leu-XXX-Pro-Glu-Pro-COOH. These results indicate that the rat ovarian LH/hCG receptor is a protein of 92 kDa which can be easily purified in microgram amounts. This study also describes a relatively simple technique for electroblotting and microsequencing that should be applicable to other membrane-bound hormone receptors.     

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.     

Organization in vitro of ovarian cells into testicular structures

Summary While it has been shown previously (Zenzes et al., 1978; Ohno et al., 1978) that when dissociated testicular cells are exposed to anti-H-Y antiserum in vitro they are prevented from reorganizing into testicular structures, forming ovarian follicular structures instead, the most conclusive evidence for the action of H-Y antigen would be the conversion of ovarian cells into testicular organization. Testing for H-Y antigen of the medium collected from cultivated testicular cells revealed a positive reaction. Dissociated ovarian cells of newborn rats cultivated in this medium reorganize into testicular structures. It is concluded that H-Y antigen is responsible for this histomorphologic change.     

Serological H-Y antigen in the female chicken occurs during gonadal differentiation

In the chicken, serological H-Y antigen is specific for the female sex. Male gonad differentiation can be experimentally influenced by estrogens, resulting in the transient formation of an ovotestis. The sex-inverted gonad becomes positive for H-Y antigen. Therefore, the question arises whether, in normal gonadogenesis also, the female gonad at the indifferent stage, before estrogens are produced, is negative for H-Y antigen. Here we show that this is indeed the case. The female gonad becomes positive for H-Y antigen when the ovary starts its organotypic differentiation at about day 6 1/2 of embryonal development. It is assumed that estrogens are responsible for the occurrence of H-Y antigen. This finding supports the view that H-Y antigen plays a role in primary ovogenesis in the chicken.     

Differences in the characteristics and distribution of rat luteal receptors for native and deglycosylated human choriogonadotropin.

Previous work has suggested that rat luteal cells have two populations of LH/hCG receptors that are located in different parts of the cell membrane. The possibility that these two receptor pools may have functional differences has been investigated through examination of the binding and action of native and deglycosylated hCG to different membrane fractions. Ovaries from eCG/hCG-primed immature female rats were separated into 1,000 x g (heavy) and 20,000 x g (light) particulate fractions. Increasing concentrations of NaCl had a biphasic effect on the binding of native and deglycosylated hCG to both membrane fractions, causing an increase in binding at low concentrations and a decrease in binding at higher concentrations. The binding of deglycosylated hCG to both membrane preparations and the binding of native hCG to light-membrane preparations was maximal at approximately the same NaCl concentration (50-65 mM). This was higher than the concentration of NaCl necessary for maximal binding of native hCG to the heavy-membrane preparation. In addition, maximal native hCG binding to this preparation occurred over a broader NaCl concentration range (15-65 mM). Equilibrium binding experiments showed differences in hCG binding to both fractions. In light membranes there were significantly more receptor sites for deglycosylated hCG (11.2 +/- 4.8 fmol/mg ovary) than for native hCG (4.8 +/- 0.7 fmol/mg ovary), with no significant different in affinity. In contrast, in heavy membranes the affinity for deglycosylated hCG (6.30 +/- 0.19.10(9) M-1), was significantly higher than that for native hCG (2.60 +/- 0.13.10(9) M-1), with no significant differences in receptor number.(ABSTRACT TRUNCATED AT 400 WORDS)     

Comparison of monoclonal luteinizing hormone (LH) receptor antibody and LH binding sites in vibratome sections of rat ovary by immunohistochemistry

To identify luteinizing hormone (LH) receptors, a monoclonal antibody (MAb) was produced by immunization of Balb/c mice with rat luteal cell membranes. Hybridomas, produced by a method for proteins of low antigenicity, were selected by competition with [125I]-hCG (LH) for luteal membrane binding. Conditions for analysis of LH receptor antibody (IgG2b isotype) binding by immunohistochemistry with an avidin-biotin-peroxidase complex were examined and results compared to localization of bound hCG, to detect receptors. By light microscopy, both bound hCG and the LH receptor antibody were located on luteal cell surfaces. In addition, the LH receptor antibody was associated with luteal cell cytoplasm. Cell surface membrane binding, but not cytoplasmic staining, was reduced in ovaries from rats injected with hCG. By electron microscopy, LH receptor antibody was observed in patches on luteal cell surface membranes and was associated with polysomes, small vesicles, and occasionally with discrete areas of endoplasmic reticulum. Therefore, detection of LH receptors with bound hCG may be limited to receptors found on cell surfaces, while additional LH receptors are revealed by use of a receptor antibody. The cytoplasmic LH receptor may represent stages in the processing of receptor protein. Furthermore, the methodology used in this study should be generally useful for immunohistochemistry with other MAb to receptors.     

Effects of photoperiod and hCG on the regulation of testicular LH/hCG receptors in Syrian hamsters (Mesocricetus auratus)

The regulation of testicular LH/hCG receptors was studied in Syrian (golden) hamsters with testicular atrophy induced by exposure to short photoperiod (5L:19D) and in gonadally active hamsters kept in a long photoperiod (14L:10D). By 24 h after injection of hCG, long-photoperiod hamsters showed a dose-related decrease in the number of testicular LH/hCG receptors. At 48 and 72 h, there was a recovery from this 'down-regulation'. The recovery was much faster than has been reported for the rat and mouse, and it resulted in elevation of testicular LH/hCG receptor concentrations above basal values. Hamsters with short photoperiod-induced testicular atrophy showed an increase in testicular LH/hCG receptors after injection of hCG, except for animals injected with a very high dose. The hCG-induced increase in testicular LH/hCG binding in these animals was associated with reappearance of testosterone responses to subsequent hCG stimulation. Response of testicular LH/hCG receptors to hCG in prepubertal hamsters resembled that measured in animals with short photoperiod-induced gonadal atrophy.