Derivation of functional antagonists using N-terminal extracellular domain of gonadotropin and thyrotropin receptors

Receptors for the glycoprotein hormones, LH/CG, FSH, and TSH, are a unique subclass of the seven-transmembrane, G protein-coupled proteins with a large N-terminal extracellular (ecto-) domain. Although ecto-domains of gonadotropin receptors confer ligand binding, expression of soluble binding proteins has been difficult. We fused the ecto-domains of LH or FSH receptors to the single-transmembrane domain of CD8 and found that hybrid proteins anchored on the cell surface retained high-affinity ligand binding. Inclusion of a junctional thrombin cleavage site in the hybrids allowed generation of soluble receptor fragments that interfered with gonadotropin binding to their receptors and blocked cAMP production stimulated by gonadotropins. Cross-linking analyses confirmed the formation of high molecular weight complexes between receptor ecto-domains and their specific ligands. A similar approach also generated a soluble TSH receptor fragment capable of blocking TSH-induced signal transduction. When administered to rats, the soluble FSH receptor fragment retarded testis growth and induced testis cell apoptosis. These findings demonstrate the feasibility of generating ligand-binding regions of glycoprotein hormone receptors to selectively neutralize actions of gonadotropins and TSH, thus allowing future design of novel contraceptives and management of different gonadal and thyroid dysfunction. The present study represents the first successful derivation of soluble, ligand-binding domains from glycoprotein hormone receptors as functional antagonists. Similar approaches could allow generation of ecto-domains of related receptors to neutralize actions of ligands or receptor antibodies and to facilitate structural-functional analysis.

Cystine knot of the gonadotropin alpha subunit is critical for intracellular behavior but not for in vitro biological activity

The common alpha subunit of glycoprotein hormones contains five disulfide bonds. Based on the published crystal structure, the assignments are 7-31, 59-87, 10-60, 28-82, and 32-84; the last three comprise the cystine knot, a structure also seen in a variety of growth factors. Previously, we demonstrated that the efficiency of secretion and the ability to form heterodimers by alpha subunits bearing single cysteine residue mutants in the cystine knot were significantly reduced. These results suggested that the cystine knot is critical for the intracellular integrity of the subunit. To assess if the presence of the free thiol affected the secretion kinetics, we constructed paired cysteine mutants of each disulfide bond of the alpha subunit. The secretion rate for these monomers was comparable with wild type except for the alpha-10-60 mutant, which was 40% lower. The recovery of the alpha7-31 and alpha59-87 mutants was greater than 95%, whereas for the cystine knot mutants, it was 20-40%. Co-expression of the wild-type chorionic gonadotropin beta subunit with double cysteine mutants did not enhance the recovery of alpha mutants in the media. Moreover, compared with wild-type, the efficiency of heterodimer formation of the alpha10-60 or alpha32-84 mutants was less than 5%. Because subunit assembly is required for biological activity, studies on the role of these disulfide bonds in signal transduction were not possible. To bypass the assembly step, we exploited the single chain model, where the alpha and beta subunits are genetically fused. The recovery of secreted tethered gonadotropins bearing mutations in the cystine knot was increased significantly. Although dimer-specific monoclonal antibodies discriminated the conformation of single chain alpha10-60 and alpha32-84 mutants from the native heterodimer, these mutants were nevertheless biologically active. Thus, individual bonds of cystine knot are important for secretion and heterodimer formation but not for in vitro bioactivity. Moreover, the data suggest that the native heterodimer configuration is not a prerequisite for receptor binding or signal transduction.

Hormonal regulation of apoptosis an ovarian perspective

Using the ovary as a model system for studying the hormonal regulation of apoptosis, recent studies have revealed that the survival of growing follicles is under the regulation of a complex array of hormones through endocrine, paracrine, autocrine, or juxtacrine mechanism in a development-dependent manner. More effort is needed, however, to identify tissue-specific factors required for the survival of ovarian somatic and germ cells at specific stage of development. New insights based on characterization of conserved apoptotic effectors, both extracellular and intracellular, have suggested that apoptosis in ovarian cells may be mediated by apoptotic programs common to other cells but using specific members of the death domain proteins as well as ced-9/Bcl-2 and ced-3/ICE caspase families of genes. Future studies may provide new therapeutic modalities for different ovarian diseases caused by aberrant regulation of apoptosis in ovarian cells, including premature ovarian failure and polycystic ovarian syndrome. (Trends Endocrinol Metab 1997;8:207-213). (c) 1997, Elsevier Science Inc.

Design of stable biologically active recombinant lutropin analogs

Glycoprotein hormones are noncovalent heterodimers comprised of a common alpha subunit and a hormone-specific beta subunit. Secretion and biologic action of these hormones are dependent on the formation of the heterodimer. The human LH beta subunit is unique among the other beta subunits in that it assembles inefficiently with the alpha subunit. To bypass this rate-limiting step, we constructed the LH single chains where the carboxy terminus of beta was fused to the amino terminus of alpha subunit through a linker. Compared to the human LH heterodimer, the extent of secretion was greater for the tethers although the rate was dependent on the nature of the linker. The LH single chains were biologically active even though there was loss of recognition by a LH-specific monoclonal antibody. This suggests that receptor binding of the single chains is not impaired by changes in the heterodimeric configuration resulting from tethering the subunits. In addition, single chains exhibited a remarkably greater in vitro stability than the heterodimer, implying that these analogs will be useful as diagnostic reagents and that their purification will be facilitated.

Preantral ovarian follicles in serum-free culture: suppression of apoptosis after activation of the cyclic guanosine 3',5'-monophosphate pathway and stimulation of growth and differentiation by follicle-stimulating hormone

Progression of preantral follicle development is essential to further follicle maturation and ovulation, but there are few models for studying the regulation of preantral follicle survival and growth. We have evaluated preantral follicle survival in vivo and in vitro, and have developed a serum-free rat follicle culture system that can be used to characterize the regulation of preantral follicle growth and differentiation. Analysis of ovarian cell DNA fragmentation during the first wave of follicle growth in the infantile rat indicated negligible apoptosis up to day 16 of age. However, a major increase in apoptosis was found by day 18, a time point associated with the appearance of large antral follicles. In situ analysis confirmed that apoptotic DNA fragments were limited to antral follicles. Culture of individual preantral follicles mechanically dissected from ovaries of 12- or 14-day-old rats in serum-free conditions led to major increases in follicle cell apoptosis, similar to that seen in cultures of antral and preovulatory follicles. In contrast to antral and preovulatory follicles, treatment of preantral follicles with gonadotropins or cAMP analogs did not prevent apoptosis. However, treatment with 8-bromo-cGMP or 10% serum suppressed apoptosis by 75% in cultured preantral follicles. In situ analysis identified granulosa cells as the cell type susceptible to apoptosis regulation. Taking advantage of the ability of the cGMP analog to suppress apoptosis, we evaluated the potential of FSH as a growth factor. In the absence of serum, FSH treatment for 48 h did not affect follicle size compared to controls; however, treatment with the cGMP analog together with FSH increased follicle diameter (13%; P < 0.01) and viable cells (2.4-fold; P < 0.01) compared to control values. Immunoblot analysis further indicated that the inhibin-alpha content of the cultured follicles was increased by treatment with the combination of FSH and 8-bromo-cGMP, demonstrating the induction of follicle cell differentiation during culture. Therefore, we demonstrated that activation of the cGMP pathway promotes the survival of cultured preantral follicles and that in the presence of alpha cGMP analog, FSH is a growth and differentiation factor for preantral follicles. The present serum-free follicle culture model system will be useful in further evaluation of the regulation of growth and differentiation of preantral follicles.

Telomerase activity in female and male rat germ cells undergoing meiosis and in early embryos

Telomerase is a ribonucleoprotein that synthesizes telomeric DNA at the ends of eukaryotic chromosomes. It has been hypothesized that telomerase activity is necessary for cellular immortalization and that telomerase activity is present in cells of germline origin. The objective of the present study was to determine the level of telomerase activity in the following rat cells: 1) oocytes from follicles at different stages of development, 2) spermatogenic cells, and 3) early embryos. Telomerase activity was quantitated using a recently developed, sensitive polymerase chain reaction-based assay and a human kidney cell line (293) as a standard. Telomerase activity was found in oocytes from early antral and preovulatory follicles, as well as in ovulated oocytes. The level of enzyme activity in early antral and preovulatory follicles was comparable to that of the 293 cells, while levels in ovulated oocytes were 50-fold lower. Telomerase activity was present in even lower levels in pachytene spermatocytes and round spermatids, and no telomerase activity was detected in spermatozoa from either the caput or the cauda epididymis. After fertilization, telomerase activity was present in 4-cell embryos. Telomerase activity was also detected in several rat somatic tissues. These data demonstrate that telomerase activity is present in germ cells at several stages of differentiation, with the exception of spermatozoa, and suggest that telomerase activity may be important during meiosis. The high levels of telomerase activity in individual oocytes may serve as a marker for monitoring the effects of hormonal agents, aging, and toxins on oocyte quality.

Genomic organization and polymorphism of human angiotensin II type 2 receptor: no evidence for its gene mutation in two families of human premature ovarian failure syndrome

Angiotensin II type 2 (AT(2)) receptor is highly expressed in the fetal tissues and decreases rapidly after birth. AT(2) receptor is re-expressed in the adult atretic ovarian follicles. Recently, it has been reported that AT(2) receptor mediates apoptosis. Primarily, we have cloned human AT(2) receptor cDNA and mapped it to the X-chromosome. To further analyze the organization and function of the AT(2) receptor gene, in this study we cloned the human AT(2) receptor genomic DNA. Human AT(2) receptor gene is composed of three exons and two introns. Primer extension analysis revealed a putative transcription initiation site at 24 bp downstream from TATA box. Furthermore, we identified a polymorphism (C-A) in 3' untranslated region of exon 3, which may be a useful genetic marker for genetic analysis of human X-linked inherited disease. In this study, we postulated that the patients with premature ovarian failure, which has been reported to be linked with X-chromosome abnormality, have AT(2) receptor mutation that may contribute to the early onset of atresia. We examined the entire coding sequence of this receptor in two different families of sisters with premature ovarian failure (POF) but found no changes in nucleotide sequences.

The biologic action of single-chain choriogonadotropin is not dependent on the individual disulfide bonds of the beta subunit

Disrupting disulfide loops in the human chorionic gonadotropin beta subunit (CGbeta) inhibits combination with the alpha subunit. Because the bioactivity requires a heterodimer, studies on the role of disulfide bonds on receptor binding/signal transduction have previously been precluded. To address this problem, we bypassed the assembly step and genetically fused CGbeta subunits bearing paired cysteine mutations to a wild-type alpha (WTalpha) subunit. The changes altered secretion of the single-chain mutants which parallel that seen for the CGbeta monomeric subunit. Despite conformational changes in CG disulfide bond mutants (assayed by gel electrophoresis and conformationally sensitive monoclonal antibodies), the variants bind to the lutropin/CG receptor and activated adenylate cyclase in vitro. The data show that the structural requirements for secretion and bioactivity are not the same. The results also suggest that the extensive native subunit interactions determined by the cystine bonds are not required for signal transduction. Moreover, these studies demonstrate that the single-chain model is an effective approach to structure-activity relationships of residues and structural domains associated with assembly of multisubunit ligands.

Regulation of ovarian follicle atresia

The majority of ovarian follicles undergo atresia, a hormonally controlled apoptotic process. Monitoring apoptotic DNA fragmentation provides a quantitative and sensitive endpoint to study the hormonal regulation of atresia in ovarian follicles. During follicle development, gonadotropins, together with local ovarian growth factors (IGF-I, EGF/TGF-alpha, basic FGF) and cytokine (interleukin-1 beta), as well as estrogens, activate different intracellular pathways to rescue follicles from apoptotic demise. In contrast, TNF-alpha, Fas ligand, presumably acting through receptors with a death domain, and androgens are atretogenic factors. These diverse hormonal signals probably converge on selective intracellular pathways (including genes of the bcl-2 and ICE families) to regulate apoptosis. With a constant loss of follicles from the original stockpile, the ovary provides a unique model for studying the hormonal regulation of apoptosis.

Expression of biologically active fusion genes encoding the common alpha subunit and either the CG beta or FSH beta subunits: role of a linker sequence

The gonadotropin/thyrotropin hormone family is characterized by a heterodimeric structure composed of a common alpha subunit non-covalently linked to a hormone-specific beta subunit. The conformation of the heterodimer is essential for controlling secretion, hormone-specific post-translational modifications and signal transduction. Structure-function studies of FSH and the other glycoprotein hormones are often hampered by mutagenesis induced defects in subunit combination. Thus, the ability to overcome the limitation of subunit assembly would expand the range of structure activity relationships that can be performed on these hormones. Here we converted the FSH heterodimer to a single chain by genetically fusing the carboxyl end of the FSH beta subunit to the amino end of the alpha subunit in the presence or absence of a natural linker sequence. In the absence of the CTP linker, the secretion rate was decreased over three fold. (The CTP sequence is the last 28 amino acids of the CG beta sequence and contains four serine-linked oligosaccharides). Unexpectedly however receptor binding/signal transduction was unaffected by absence of the linker. Molecular modelling of the tethers lacking the linker sequence show that the alignment of the alpha/beta domains in the single chain differ substantially from that seen in the heterodimer. These data show that the single chain FSH was secreted efficiently and is biologically active and that the conformation determinants required for secretion and biologic activity are not the same.

Targeted overexpression of Bcl-2 in ovaries of transgenic mice leads to decreased follicle apoptosis, enhanced folliculogenesis, and increased germ cell tumorigenesis

We have generated transgenic mice overexpressing Bcl-2, an apoptosis suppression protein, in ovarian cells using the inhibit-alpha gene promoter/enhancer. Ovarian apoptotic DNA fragmentation induced in immature animals by a low dose (2 IU) of PMSG was suppressed by greater than 55% in transgenic mice compared to their wild-type littermates. Morphological and in situ DNA end-labeling analyses showed that granulosa cells in large antral follicles of wild-type animals undergo apoptosis, but most follicles in transgenic animals are healthy. When the animals were treated with a high dose (4 IU) of PMSG to stimulate follicular growth, spontaneous ovulation was observed in 14 of 23 (61%) of the transgenic animals, but in only 3 of 18 (17%) of wild-type siblings. Furthermore, transgenic females had a larger litter size (9.07 +/- 0.25 pups/litter; n = 29) than wild-type controls (7.54 +/- 0.26 pups/litter; n = 28; P < 0.01). These data suggested that decreased ovarian apoptosis in transgenic animals could lead to enhanced folliculogenesis and ovulatory potential. Moreover, aging transgenic mice are susceptible to the development of benign cystic ovarian teratoma (4 in 20 transgenic animals and 0 in 26 wild-type controls). Some tumor tissues showed respiratory and intestinal cell types, whereas others showed the development of central nervous system-like structures. Because the bcl-2 transgene in these animals is overexpressed in somatic cells, but not oocytes, these findings suggest that enhanced survival of selected somatic cells in transgenic mice could lead to germ cell tumorigenesis. Thus, overexpression of Bcl-2 protein in the ovary leads to decreased ovarian somatic cell apoptosis, enhanced folliculogenesis, and increased susceptibility to ovarian germ cell tumorigenesis in transgenic animals. The present mouse model allows future studies on intracellular signal pathways regulating follicular atresia and on the potential role of ovarian somatic cell factors in germ cell tumorigenesis.

Early onset of deoxyribonucleic acid fragmentation during atresia of preovulatory ovarian follicles in rats

Atretic demise rather than ovulation is the ultimate fate of the vast majority of ovarian follicles in mammals, affecting 70-99.9% of the follicles in various species. Recent studies have established that atretic degeneration of follicles is an apoptotic process, heralded by endonuclease degradation of DNA at internucleosomal sites, which generates DNA fragments in size multiples of 185-200 bp that are seen as distinct ladder bands after agarose gel electrophoresis. Using the well-characterized model of inducing atresia of preovulatory follicles in vivo by hypophysectomy and analyzing DNA fragmentation by autoradiography of size-fractionated DNA labeled at the 3' ends by [12P] dideoxy-ATP, we have examined the timing of atretic changes. DNA degradation was related to morphological signs of atresia, ovulability, and changes in follicular steroidogenesis. Rats were hypophysectomized on the morning of the day of proestrus, after which largest follicles were collected at various times. DNA fragmentation was analyzed in groups of five follicles. The increase in DNA fragments of low molecular weight up to 4 h after hypophysectomy was negligible (101 +/- 10%; 0 h time = 100%) but progressed 8, 12, 24, 48, and 72 h after hypophysectomy (143 +/- 20%, 168 +/- 27%, 235 +/- 29%, 3299 +/- 1075%, and 2249 +/- 805%, respectively; p < 0.03, n = 5). At 48 and 72 h, the extent of DNA degradation was higher than that observed in follicles cultured in a serum-free medium for 24 h. Likewise, staining of DNA by 4',6-diamido-2-phenylindole hydrochloride revealed apoptotic nuclei at 8 h after hypophysectomy (p < 0.01), and the percentage of such nuclei progressively increased afterwards. Thus, the increase in DNA fragmentation appeared concomitantly with atretic changes observed in previous studies (a decrease in ovulability at 6 h, and a spontaneous increase in progesterone accumulation and decrease in androgen and estrogen in follicles explanted 6 h after hypophysectomy) and preceded atresia detectable by morphological changes at 24 h. Detection of internucleosomal DNA degradation in preovulatory follicles early in the atretic cascade underscores the central role of apoptosis in ovarian follicle atresia.

Tumor necrosis factor-alpha and its second messenger, ceramide, stimulate apoptosis in cultured ovarian follicles

In the mammalian ovary, only a small fraction of follicles fully mature and ovulate, while most of them die via apoptosis. Multiple factors promoting follicle survival have been identified, but intraovarian mediators of apoptosis are poorly known. Tumor necrosis factor-alpha (TNF alpha) is a cytokine capable of inducing apoptosis in diverse cell types, and the apoptotic effect of TNF alpha is, partially, coupled to the sphingomyelin signaling pathway with ceramide as a second messenger. Because TNF alpha has been localized in the rat ovary, and TNF alpha treatment increases granulosa cell ceramide production, we studied the effect of treatment with TNF alpha and ceramide on follicle apoptosis. Immature rats were implanted with diethylstilbestrol to stimulate the development of early antral follicles. Follicles were isolated and cultured in a serum-free medium for 24 h with or without hormone treatments. During culture, spontaneous follicle apoptosis occurred (10-fold increase in DNA fragmentation), which was partially blocked by 100 ng/ml FSH (60% suppression). The effect of FSH was counteracted by TNF alpha in a dose-dependent manner, with the maximal effect at 100 ng/ml TNF alpha (90% reversal of FSH action). In situ analysis indicated that the granulosa cell is the follicle cell type undergoing DNA fragmentation. A membrane-permeable ceramide analog, C2-ceramide N-acetyl sphingosine, mimicked the effect of TNF alpha and was able to completely abolish the action of FSH at 50 microM. In contrast, another ceramide analog, C2-dihydroceramide N-acetyl dihydrosphingosine, did not alter the effect of FSH, verifying the specificity of ceramide action. To study the mechanism of TNF alpha and ceramide action, the effect of sodium aurathiomalate (ATM), an inhibitor of interleukin-1 beta-converting enzyme/ced-3-related cystine proteases known to be essential in the execution of mammalian cell apoptosis, was studied. Treatment with ATM (1 mM) prevented the apoptosis-inducing effect of both TNF alpha and ceramide, suggesting a role for cysteine proteases in mediating follicle apoptosis. Treatment with either TNF alpha or ceramide increased both basal and FSH-stimulated progesterone production by cultured follicles. Concomitant treatment by ATM did not alter the stimulatory effect of TNF alpha or ceramide on progesterone production, ruling out nonspecific toxic effect of the inhibitor and indicating that the apoptotic and steroidogenic pathways are independent. In summary, treatment with TNF alpha or its second messenger, ceramide, stimulates apoptosis of early antral follicles in culture, suggesting a potential role for TNF alpha as an intraovarian regulator of follicle atresia by acting through the ceramide signaling pathway.

Oocyte maturation involves compartmentalization and opposing changes of cAMP levels in follicular somatic and germ cells: studies using selective phosphodiesterase inhibitors

The second messenger cAMP has been implicated in the regulation of mammalian and amphibian oocyte maturation. Although a decrease in intraoocyte levels of cAMP precedes germinal vesicle breakdown (GVBD), the gonadotropin induction of ovulation and oocyte maturation is associated with major increases of cAMP in ovarian follicles. In the mammalian system, isolated oocytes undergo spontaneous maturation in vitro but this process is blocked by treatment with a phosphodiesterase (PDE) inhibitor, IBMX, which increases intraoocyte cAMP levels. In contrast, the same inhibitor, when added to cultured follicles for a brief time, increases follicle cAMP levels, followed by the induction of GVBD. To resolve the paradoxical actions of this PDE inhibitor on the maturation of isolated and follicle-enclosed oocytes, we hypothesized that meiotic maturation requires opposing fluctuations of cAMP levels in the somatic granulosa and germ cells. Such opposing fluctuations may result from selective expression and regulation of PDEs in the somatic and germ cell compartments of the follicle. To test this hypothesis, PDE activity was manipulated in different follicular cells using type-specific inhibitors. The impact of the ensuing changes in cAMP levels in the two compartments was monitored by the induction of GVBD. In isolated oocytes, spontaneous GVBD was blocked by two inhibitors of type 3 PDE (cGMP-inhibited: CGI-PDE), milrinone and cilostamide. In contrast, treatment with an inhibitor for type 4 PDE (cAMP-specific), rolipram, was ineffective. These findings suggest that the oocyte expresses type 3 but not type 4 PDE and that increases in intraoocyte cAMP suppress GVBD. This hypothesis was confirmed by in situ hybridization studies with PDE3 and PDE4 probes. PDE3B mRNA was concentrated in oocytes while PDE4D was mainly expressed in granulosa cells. In cultured follicles, LH treatment induced oocyte maturation but the gonadotropin action was blocked by inhibitors of type 3 but not the type 4 PDE inhibitors. Furthermore, treatment with the type 4, but not the type 3, PDE inhibitor mimics the action of LH and induces oocyte maturation, presumably by increasing cAMP levels in granulosa cells. Our findings indicate that PDE subtypes 4 and 3 are located in follicle somatic and germ cells, respectively. Preferential inhibition of PDE 3 in the oocyte may lead to a delay in oocyte maturation without affecting the cAMP-induced ovulatory process in the somatic cells. Conversely, selective suppression of granulosa cell cAMP-PDE may enhance the gonadotropin induction of ovulation and oocyte maturation. Thus, in addition to the well-recognized differential expression and regulation of adenylate cyclase in the somatic and germ cell compartments of the follicle, we suggest that selective regulation and expression of PDEs may be involved in the regulation of cAMP levels and control of oocyte maturation in the preovulatory mammalian follicle.

Transmembrane regions V and VI of the human luteinizing hormone receptor are required for constitutive activation by a mutation in the third intracellular loop

Gonadotropin receptors are members of the seven-transmembrane (TM) receptor family. Several point mutations in TM V and VI and the intracellular loop 3 (i3) have been identified in the luteinizing hormone (LH) receptor gene, leading to constitutive activation of the receptor. Because gonadotropin receptors are highly conserved, we mutated the follicle-stimulating hormone (FSH) receptor at the corresponding amino acids. However, the FSH receptor mutants showed minimal increases in basal cAMP production. Taking advantage of this difference between the two receptors, we designed chimeric receptors with or without a point mutation in the i3 to identify the region in the LH receptor important for its constitutive activation. Introduction of the point mutation into chimeric receptors containing only TM V to VI from the LH receptor led to major increases in ligand-independent cAMP production. Furthermore, a chimeric receptor with only TM V and VI derived from the LH receptor can be rendered constitutively active by the mutation in the i3 from the FSH receptor. These results suggest that interactions between TM V and VI of the FSH receptor are essential for maintaining the receptor in the more constrained state, whereas interactions between these domains of the LH receptor are permissive for constitutively activating mutations in the i3.

The C-terminal third of the human luteinizing hormone (LH) receptor is important for inositol phosphate release: analysis using chimeric human LH/follicle-stimulating hormone receptors

Gonadotropin and TSH receptors represent a subgroup of seven transmembrane-spanning, G protein-coupled receptors with a large extracellular ligand-binding region. After ligand binding to their receptors, the majority of actions of gonadotropins and TSH are believed to be mediated by the cAMP-protein kinase A pathway. Although formation of inositol phosphates (IP) has been reported after stimulation of rodent gonadotropin receptors, activation of phospholipase C after ligand binding of human LH or FSH receptors has not been investigated. Human gonadotropin receptors were transiently expressed in 293 cells, and the agonist-induced stimulation of IP formation was measured. The LH receptor responded to a saturating dose of human CG (hCG) with a 5.2-fold increase of IPs whereas the FSH receptor responded to a saturating dose of FSH with only a 50% increase. On the basis of these differences and in view of the homologous nature of the two gonadotropin receptors, chimeric receptors were constructed using domain transfer to identify the regions in the human LH receptor important for phosphatidylinositol hydrolysis. Chimeric receptors containing the entire extracellular region of the FSH receptor and the seven transmembrane region plus the cytoplasmic tail of the LH receptor responded to FSH treatment with a 4.7-fold increase in IP accumulation. In contrast, the chimeric receptor with the extracellular region of the LH receptor and the TM region plus the cytoplasmic tail of the FSH receptor responded minimally (50%) to hCG treatment. When the C-terminal third (from TM V to the cytoplasmic tail) of the FSH receptor was replaced with the LH receptor sequence, the chimeric receptor still responded to FSH treatment with a large (6.2-fold) increase in IP release, similar to that of the wild type LH receptor (to hCG), suggesting that C-terminal third of the human LH receptor confers IP signaling ability. This functional domain was further divided into two areas, namely TM V to TM VI and TM VII to the cytoplasmic tail. The chimeric receptors F(I-IV)L(V-VI)F(VII-C)R and F(I-VI)L-VII-C)R, in which these two regions of the FSH receptor were replaced by the corresponding sequences of the LH receptor, responded to FSH treatment with partial increases in phosphatidylinositol hydrolysis (2.0- and 3.7-fold, respectively). Furthermore, when TM VII and the cytoplasmic tail of the LH receptor were replaced with the corresponding sequence of the FSH receptor, this chimeric receptor showed a diminished (2.0-fold) response to hCG in IP release. For all the chimeric receptor constructs analyzed, overall expression, equilibrium binding constants, and adenyl cyclase activation were not altered. Thus, unlike studies using chimeric muscarinic and dopaminergic receptors in which the second and third intracellular loops were found to be important for IP signaling, the entire C-terminal third of the human LH receptor is important for IP release. Future analysis using the chimeric receptor approach should provide new information on the structure-function relationship of gonadotropin, TSH, and other seven transmembrane-spanning receptors.

Compound heterozygous mutations of the luteinizing hormone receptor gene in Leydig cell hypoplasia

The human LH receptor (hLHR) is a member of the G protein-coupled receptors characterized by the presence of seven-transmembrane (TM) helices. Inactivating mutations of the hLHR lead to Leydig cell hypoplasia (LCH), a form of male pseudohermaphroditism resulting from the failure of fetal testicular Leydig cell differentiation. We have identified three mutations of the hLHR in a patient with LCH: deletion of exon 8 (delta Exon 8), A872G transition resulting in Asn291Ser substitution in the extracellular domain, and C1847A transversion resulting in Ser616Tyr substitution in the seventh TM helix. Nucleotide sequencing, gene dosage, and allele-specific amplification analyses revealed that exon 8 deletion and the two missense mutations are present in different alleles of the hLHR. Constructs of mutated hLHR (hLHR-delta Exon8, hLHR-872/1847, hLHR-1847, and hLHR-872) were used to transfect 293 cells, and the properties of the hLHR expressed were examined. Ligand-binding assays failed to detect the expression of hLHR-delta Exon8. Transfectants expressing hLHR-872/1847 demonstrated greatly reduced ligand binding and ligand-induced cAMP accumulation in comparison to those expressing wild type hLHR. Similar reduction in cAMP accumulation was observed in transfectants expressing hLHR-1847, but not hLHR-872 alone. These findings suggest that, in addition to the 7-TM helices, the polypeptide encoded by exon 8 plays an important role in LHR expression and signal transduction. On the other hand, glycosylation of Asn291 may not be critical for these activities. These results also establish that LCH can result from impaired signal transduction due to compound heterozygous mutations. Implications of these mutations on structure-function relationship of the hLHR and the genotype-phenotype correlation in LCH are discussed.

Heterogeneity of activating mutations of the human luteinizing hormone receptor in male-limited precocious puberty

Male-limited precocious puberty (MPP) is a gonadotropin-independent disorder that occurs sporadically or is inherited in an autosomal dominant, male-limited pattern. Recent studies have identified constitutively activating missense mutations in the human luteinizing hormone receptor (hLHR) gene leading to Leydig cell activation and precocious puberty. Patients with sporadic MPP (SMPP) or with different ethnic backgrounds appear to have a greater likelihood of having novel mutations. In the current study we examined genomic DNA from two unrelated cases of SMPP of African-American descent for novel mutations of the hLHR gene. A heterozygous A to C transversion at nucleotide 1723 resulting in substitution of Leu for lle575 in transmembrane helix 6 was identified. Human embryonic kidney cells transfected with cDNA for the mutant hLHR-I575L, created by polymerase chain reaction-based mutagenesis of the wild-type (hLHR-wt) cDNA, exhibited increased basal levels of cAMP production in the absence of agonist, indicating constitutive activation. Surface expression of hLHR-I575L, as reflected by human chorionic gonadotropin binding, was diminished compared to hLHR-wt, while agonist affinity was unaffected. With the exception of two polymorphic bases, no mutation was identified within the coding sequence of the hLHR in the second case of SMPP. We conclude that I575L is a unique constitutively activating mutation that impairs cell surface expression of the receptor but does not alter agonist affinity. Furthermore, mutations of the hLHR gene causing SMPP are highly heterogeneous and may be found in regions other than exon 11 of the hLHR. Last, patients with MPP from different ethnic backgrounds are likely to have novel mutations.

The mouse inhibin alpha-subunit promoter directs SV40 T-antigen to Leydig cells in transgenic mice

Testicular tumorigenesis was observed in transgenic mice expressing the 6-kb mouse inhibin alpha-subunit promoter/Simian virus 40 T-antigen (SV40 Tag) fusion gene. The tumors were confined to Leydig cells using immunohistochemistry with anti-Tag antibody, specific binding of biotinylated hCG and histochemistry for 3 beta-hydroxysteroid dehydrogenase. Leydig cell hyperplasia and presence of Tag protein in the testicular interstitial tissue were already evident at 5 and 6.5 days of age, respectively. An immortalized cell line, BLT-1, was established from one testicular tumor. These cells expressed the LH receptor and P450scc mRNAs, and displayed LH-responsive cAMP and progesterone production, and low testosterone production. The cells also specifically bound 125I-labeled recombinant human LH with high affinity (36000 binding sites/cell), and the binding was regulated by 8Br-cAMP and hCG. This gonadal tumor model is valuable for further studies on endocrine functions of Leydig cells and their tumorigenesis in vivo and in vitro.

Expression of biologically active fusion genes encoding the common alpha subunit and the follicle-stimulating hormone beta subunit. Role of a linker sequence

The gonadotropin/thyrotropin hormone family is characterized by a heterodimeric structure composed of a common alpha subunit noncovalently linked to a hormone-specific beta subunit. The conformation of the heterodimer is essential for controlling secretion, hormone-specific post-translational modifications, and signal transduction. Structure-function studies of follicle-stimulating hormone (FSH) and the other glycoprotein hormones are often hampered by mutagenesis-induced defects in subunit combination. Thus, the ability to overcome the limitation of subunit assembly would expand the range of structure-activity relationships that can be performed on these hormones. Here we converted the FSH heterodimer to a single chain by genetically fusing the carboxyl end of the FSH beta subunit to the amino end of the alpha subunit in the presence or absence of a linker sequence. In the absence of the CTP linker, the secretion rate was decreased over 3-fold. Unexpectedly, however, receptor binding/signal transduction was unaffected by the absence of the linker. These data show that the single-chain FSH was secreted efficiently and is biologically active and that the conformation determinants required for secretion and biologic activity are not the same.

Hormonal regulation of apoptosis in early antral follicles: follicle-stimulating hormone as a major survival factor

Hormonal regulation of apoptosis has been studied in cultured preovulatory follicles. Because early antral follicles are most vulnerable to undergo atretic degeneration under physiological conditions in vivo, the present studies were designed to investigate the hormonal regulation of apoptosis using in vitro culture of early antral follicles. Rats were implanted with diethylstilbestrol at 24 days of age to stimulate the development of early antral follicles, and ovaries were collected at day 27 of age. Early antral follicles were dissected and cultured (four per vial) for 24 h with or without hormonal treatments. After culture, DNA was extracted from follicles, and the degree of apoptotic DNA fragmentation was determined using 3'-end labeling and gel electrophoresis. In situ analysis of apoptotic DNA fragmentation revealed that granulosa cells in these follicles are the main cell type undergoing apoptosis. Follicles cultured in the absence of hormones showed a 12-fold increase in the level of apoptotic DNA fragmentation which was prevented by treatment with FSH in a dose-dependent manner (60% maximal suppression and apparent ED50 of 30 ng/ml). Similarly, treatment with (Bu)2cAMP also suppressed follicle apoptosis. Treatment with LH or human CG, however, minimally suppressed apoptotic DNA fragmentation (35% maximal suppression). Insulin-like growth factor-I (IGF-I) also suppressed apoptosis by 45%. Moreover, the suppressive effect of FSH on apoptosis was partially reversed by coincubation with IGF-binding protein-3, suggesting a potential mediatory role of endogenous IGF-I. However, recombinant bovine GH had no effect on follicle apoptosis despite its ability to stimulate IGF-I messenger RNA (mRNA) levels. Incubation of follicles with epidermal growth factor (EGF) and basic fibroblast growth factor maximally suppressed follicle apoptosis by only 32% and 42%, respectively. Ligand binding analysis indicated the minimal effectiveness of EGF on apoptosis in early antral follicles, as compared with its potent action in preovulatory follicles reported earlier, may be due to a 3.5 fold increase in EGF receptor concentration in the mature follicles. High doses (150 or 500 ng/ml) of interleukin-1beta also suppressed apoptosis by 48% whereas treatment with an NO generator, sodium nitroprusside, or a cyclic GMP analog suppressed apoptosis as effectively as that of FSH. Furthermore, treatment with activin resulted in a dose-related suppression of follicle apoptosis, reaching a maximal 40% suppression. In contrast, cotreatment of activin with its binding protein, follistatin, abolished this effect. Collectively, these data demonstrated a stage-dependent difference in the hormonal regulation of follicle apoptosis. Although FSH, LH/human CG, GH, IGF-I, EGF, basic fibroblast growth factor, and interleukin-1beta are all effective survival factors for preovulatory follicles, FSH is a major survival factor for early antral follicles, the stage during which a majority of follicle undergo atresia under physiological conditions.

Gonadal cell apoptosis: hormone-regulated cell demise

It has become evident that apoptosis, an active form of cell 'suicide', plays an important role in the normal function of all tissues. A balance of cell proliferation and apoptosis is maintained in a healthy individual and any imbalance of the two processes could lead to pathological changes. In both sexes, massive apoptosis accounts for the demise of a majority of gonadal cells (ovarian granulosa cells and male germ cells) during reproductive life. Recent studies have indicated the important role of gonadotrophins as survival factors in both the ovary and the testis. Furthermore, intra-gonadal survival. factors in the ovary (oestrogens, insulin-like growth factor I, epidermal growth factor, basic fibroblast growth factor, interleukin-1 beta, nitric oxide, etc.) and testis (androgens) have been shown to act in concert with the gonadotrophins. In contrast, several apoptotic factors (androgens, gonadotrophin-releasing hormone-like peptide and interleukin-6) may be important in inducing the demise of ovarian follicles. Understanding of the hormonal and cellular mechanisms responsible for gonadal cell apoptosis will provide new approaches for the treatment of gonadal degenerative conditions such as premature ovarian failure and cryptorchidism, as well as for the design of new contraceptive approaches.

Different 5'-flanking regions of the inhibin-alpha gene target transgenes to the gonad and adrenal in an age-dependent manner in transgenic mice

The inhibin-alpha gene is expressed in a tissue-specific manner, and its protein product dimerizes with one of two beta-subunits to form bioactive heterodimers. To characterize the cis-acting elements involved in directing gonad- and adrenal-specific expression of inhibin-alpha, transgenic mice were generated that carried 2.5 or 6 kilobases (kb) of the 5'-flanking region of the mouse inhibin-alpha gene driving the human bcl-2 complementary DNA. Using an antibody specific for human Bcl-2, Western blotting and immunocytochemical analyses showed that both enhancer/promoter fragments direct transgene expression to the ovary, testis, and adrenal gland. The 6-kb fragment targeted the ovarian transgene expression in interstitial cells and young corpora lutea as well as granulosa and thecal cells of secondary, antral, and preovulatory follicles. In ovaries of animals with the 2.5-kb fragment, transgene expression was also detected in interstitial cells and young corpora lutea, but only in granulosa and thecal cells from antral and preovulatory follicles. The ovarian transgene expression in animals carrying the 6-kb inhibin-alpha promoter/bcl-2 construct was stimulated by gonadotropin treatment, with greater than 10-fold increases observed 2 days after PMSG stimulation. In the testes of both types of transgenic animals, immunoreactive Bcl-2 was predominantly detected in Sertoli cells of seminiferous tubules. Sporadic expression was also observed in some interstitial cells. In the adrenal gland, reporter protein was detected in the zona fasciculata of both types of transgenic animals during adult life; however, transgene expression was detected in zona fasciculata of young (21-day-old) animals with the 6-kb, but not the 2.5-kb, promoter construct. Thus, the 2.5-kb inhibin-alpha 5'-proximal DNA sequence directs transgene expression in mature ovarian follicles and testicular Sertoli cells. In contrast, enhancer elements in the 6-kb fragment are required for expression in preantral follicles and in the adrenal of immature animals. The inhibin-alpha promoter/enhancer used here represents unique DNA sequences for ovarian-specific transgene expression and is useful for future analysis of gonadal and adrenal cell functions.