Relationship between adenylate cyclase sensitivity to follitropin and FSH receptor mRNA expression in the ovary of the lizard Podarcis sicula

In mammals, gonadal functions are regulated by two pituitary gonadotropins, follicle-stimulating hormone (FSH) and luteinizing hormone (LH), that interact with gonadal membrane receptors to activate adenylate cyclase. In comparison to mammalian systems, in squamate reptiles a reduced amount of information exists on gonadotropins and their related receptors. This study is aimed at clarifying if, in the lizard Podarcis sicula, the ovarian sensitivity to FSH is correlated to the reproductive cycle and to the expression of membrane receptors involved in the hormone recognition. The results demonstrate that the ovarian adenylate cyclase responsiveness to FSH parallels ovarian functions, being maximal during the ovulatory period. The ovarian sensitivity to FSH is also related to oocyte growth and vitellogenesis. Northern blot analyses reveal that the FSH receptor mRNA is maximally expressed in vitellogenic oocytes during the reproductive period. These results suggest that, in lizard ovary, hormone activation of adenylate cyclase is mediated by de novo synthesis of receptors specifically involved in FSH recognition. In lizards treated in vivo with FSH during the pre-ovulatory period, adenylate cyclase becomes refractory to further FSH stimulation 2 hr after treatment, but sensitivity to the hormone is restored after 2 weeks. Nevertheless, while the restored level of activity never exceeds that observed during the nonreproductive period, the expression level of FSH receptor mRNAs is significantly enhanced in these animals. These results suggest that in lizard the processes that regulate ovarian growth, vitellogenesis, and ovulation are controlled by a complex network of signals including gonadotropin, FSH receptor expression, and adenylate cyclase.     

An RNA-binding domain in the thyroid hormone receptor enhances transcriptional activation

Thyroid hormone plays important roles in development, differentiation, and metabolic homeostasis by binding to nuclear thyroid hormone receptors, which regulate target gene expression by interacting with DNA response elements and coregulatory proteins. We show that thyroid hormone receptors also are single-stranded RNA binding proteins and that this binding is functionally significant. By using a series of deletion mutants, a novel RNA-binding domain was localized to a 41-amino acid segment of thyroid hormone receptor alpha1 between the second zinc finger and the ligand-binding domain. This RNA-binding domain was necessary and sufficient for thyroid hormone receptor binding to the steroid receptor RNA activator (SRA). Although SRA does not bind directly to steroid receptors, it has been identified as a steroid receptor coactivator, and was thought not to be a coactivator for thyroid hormone receptors. However, transfection studies revealed that SRA enhances thyroid hormone induction of appropriate reporter genes and that the thyroid hormone receptor RNA-binding domain is important for this enhancement. We conclude that thyroid hormone receptors bind RNA through a novel domain and that the interaction of this domain with SRA, and perhaps other RNAs, enhances thyroid hormone receptor function.     

Mechanisms of polarized targeting of the FSH receptor]

Gonadotropin and TSH receptors belong to a subgroup of G protein-coupled receptors. TSH and FSH receptor present a particular intracellular traffic: they present a polarized basolateral expression in thyroid follicular cells and in Sertoli cells respectively. By contrast, the LH receptor is expressed circumferentially in target gonadic cells. We expressed these receptors in MDCK cells (a well characterized model of polarized epithelial cells) to understand this difference of properties. We show that the three receptors have a polarized basolateral expression in these cells. All contain a basolateral targeting signal. Furthermore, gonadotropin receptors undergo a partial transcytosis which is not observed for the TSH receptor. We show that heterotrimeric G proteins play a role in this mechanism of transcytosis. This effect is not mediated by adenylate cyclase activation and involves a population of G proteins different from that involved in signal transduction. We thus used in vitro mutagenesis to delineate the basolateral localization signal of the FSH receptor. Surprisingly, the signal is localized in the C-terminal tail of the intracellular domain which is not conserved between the three receptors. It contains 14 amino-acids and its activity is mainly dependent on a tyrosine and a leucine residue. The basolateral localization signal of the FSHR is not colinear with its internalization signal. This signal is autonomous and dominant because, when transferred to an apically targeted membrane protein, the neurotrophin receptor, it redirects the chimeric construct to the basolateral domain of MDCK cells. The basolateral localization signal of the FSH receptor is thus the first signal identified for a G protein-coupled receptor and more generally for a hormone receptor.     

Asp330 and Tyr331 in the C-terminal cysteine-rich region of the luteinizing hormone receptor are key residues in hormone-induced receptor activation

The luteinizing hormone (LH) receptor plays an essential role in male and female gonadal function. Together with the follicle-stimulating hormone (FSH) and thyroid stimulating hormone (TSH) receptors, the LH receptor forms the family of glycoprotein hormone receptors. All glycoprotein hormone receptors share a common modular topography, with an N-terminal extracellular ligand binding domain and a C-terminal seven-transmembrane transduction domain. The ligand binding domain consists of 9 leucine-rich repeats, flanked by N- and C-terminal cysteine-rich regions. Recently, crystal structures have been published of the extracellular domains of the FSH and TSH receptors. However, the C-terminal cysteine-rich region (CCR), also referred to as the "hinge region," was not included in these structures. Both structure and function of the CCR therefore remain unknown. In this study we set out to characterize important domains within the CCR of the LH receptor. First, we mutated all cysteines and combinations of cysteines in the CCR to identify the most probable disulfide bridges. Second, we exchanged large parts of the LH receptor CCR by its FSH receptor counterparts, and characterized the mutant receptors in transiently transfected HEK 293 cells. We zoomed in on important regions by focused exchange and deletion mutagenesis followed by alanine scanning. Mutations in the CCR specifically decreased the potencies of LH and hCG, because the potency of the low molecular weight agonist Org 41841 was unaffected. Using this unbiased approach, we identified Asp(330) and Tyr(331) as key amino acids in LH/hCG mediated signaling.     

Amino-terminal leucine-rich repeats in gonadotropin receptors determine hormone selectivity.

Recombinant expression of truncated receptors for luteinizing hormone/chorionic gonadotropin (LH/CG) revealed that the amino-terminal leucine-rich repeats 1-8 of the extracellular receptor domain bind human chorionic gonadotropin (hCG) with an affinity (Kd = 0.72 +/- 0.2 nM) similar to that of the native LH/CG receptor (Kd = 0.48 +/- 0.05 nM). LH/CG receptor leucine-rich repeats 1-8 were used to replace homologous sequences in the closely related receptor for follicle stimulating hormone (FSH). Cells expressing such chimeric LH/CG-FSH receptors bind hCG and show elevated cylic AMP levels when stimulated by hCG but not by recombinant human FSH (rhFSH). Similarly, a chimeric LH/CG receptor in which leucine-rich repeats 1-11 originated from the FSH receptor is activated by rhFSH but not by hCG. For this chimera, no residual [125I] hCG binding was observed in a range of 2 pM to 10 nM. Our results demonstrate that specificity of gonadotropin receptors is determined by a high affinity hormone binding site formed by the amino-terminal leucine-rich receptor repeats.     

Molecular cloning of new human TR2 receptors: a class of steroid receptor with multiple ligand-binding domains

Previously we isolated a new group of cDNA clones from human testis cDNA libraries which might code for new steroid receptors. The cDNA and predicted amino acid sequences of two of these receptors, named TR2-5 and TR2-7 receptors, were determined. We report here the nucleotide and deduced amino acid structures of two other receptors that we named TR2-9 and TR2-11 receptors. The calculated MW of TR2-5 receptor, TR2-7 receptor, TR2-9 receptor and TR2-11 receptor are 52,982, 20,528, 50,849 and 67,223 respectively, which match well with the apparent MW of in vitro translated products. The 26 amino acids involved in the formation of "Zn-fingers" are conserved. The ligand-binding domain of TR2-9 receptor is 16 amino acids shorter and has 3 different amino acids compared with TR2-5 receptor. The TR2-11 receptor has a ligand-binding domain which is longer and quite different compared with the other TR2 receptors. The multiple ligand-binding domains of TR2 receptor could be the products of different genes or may be due to RNA splicing errors. So far, we have failed to find binding activity with any known steroid hormone; this promotes the possibility that an unidentified steroid hormone may be involved.     

Cloning and sequencing of human FSH receptor cDNA.

We have isolated and sequenced a cDNA encoding the follicle stimulating hormone (FSH) receptor. The deduced amino acid sequence (678 residues) containing seven putative transmembrane segments which displays sequence similarity to G protein-coupled receptors. The receptor consists of 359 residue extracellular domain which contains four N-linked glycosylation sites. While the protein is 89% identical overall with the previously cloned rat FSH receptor, the most highly conserved regions are the putative transmembrane segments (95% similarity).     

Neonatal release of gonadotropins is essential for development of ovarian follicle-stimulating hormone receptors

In the rat, ovarian follicle-stimulating hormone (FSH) receptors increase markedly during the first two postnatal weeks, when serum gonadotropin levels are most elevated. This study was conducted to evaluate the hypothesis that these high gonadotropin levels, and in particular FSH, are involved in the acquisition of FSH receptors by the developing ovary. Gonadotropin release was suppressed by administration of several non-aromatizable androgens, among which dihydrotestosterone propionate (DHTP) was the most effective. In one series of experiments the steroids were administered from Days 5 to 11, and serum FSH and luteinizing hormone (LH) were measured on Day 12. Surprisingly, FSH receptor content was greater in rats with suppressed serum gonadotropins than in controls. The greatest increase in available receptors was observed in DHTP-treated rats in which serum FSH was reduced to 20% of control values and LH suppressed to undetectable values. DHTP failed to directly increase available FSH receptors in hypophysectomized immature rats. Magnesium chloride (MgCl2) treatment of ovarian membranes removed bound 125I-hFSH by 87% without affecting receptor viability. Exposure of control 12-day-old ovaries to MgCl2 increased available FSH receptors to a level similar to that of ovaries from DHTP-treated rats not exposed to MgCl2, suggesting that more receptors were available in DHTP-treated rats because serum FSH was suppressed. Earlier initation of DHTP treatment (postnatal Day 1) suppressed serum FSH and LH to undetectable values by Day 5 and decreased FSH receptor content below control values by Day 12. MgCl2 treatment only slightly increased available receptors in these DHTP-treated animals.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tyrosine sulfation is required for agonist recognition by glycoprotein hormone receptors

The glycoprotein hormone receptors (thyrotrophin receptor, TSHr; luteinizing hormone/chorionic gonadotrophin receptor, LH/CGr; follicle-stimulating hormone receptor, FSHr) constitute a subfamily of rhodopsin-like G protein-coupled receptors (GPCRs) with a long N-terminal extracellular extension responsible for high-affinity hormone binding. These ectodomains contain two cysteine clusters flanking nine leucine-rich repeats (LRR), a motif found in several protein families involved in protein-protein interactions. Similar to the situation described recently in CCR5, we demonstrate here that the TSHr, as it is present at the cell surface, is sulfated on tyrosines in a motif located downstream of the C-terminal cysteine cluster. Sulfation of one of the two tyrosines in the motif is mandatory for high-affinity binding of TSH and activation of the receptor. Site-directed mutagenesis experiments indicate that the motif, which is conserved in all members of the glycoprotein hormone receptor family, seems to play a similar role in the LH/CG and FSH receptors.     

Trans-activation of mutant follicle-stimulating hormone receptors selectively generates only one of two hormone signals

Previously, we reported that a liganded LH receptor (LHR) is capable of activating itself (cis-activation) and other nonliganded LHRs to induce cAMP (trans-activation). Trans-activation of the LHR raises two crucial questions. Is trans-activation unique to LHR or common to other G protein-coupled receptors? Does trans-activation stimulate phospholipase Cbeta as it does adenylyl cyclase? To address these questions, two types of novel FSH receptors (FSHRs) were constructed, one defective in hormone binding and the other defective in signal generation. The FSHR, a G protein-coupled receptor, comprises two major domains, the N-terminal extracellular exodomain that binds the hormone and the membrane-associated endodomain that generates the hormone signals. For signal defective receptors, the exodomain was attached to glycosyl phosphatidylinositol (ExoGPI) or the transmembrane domain of CD8 immune receptor (ExoCD). ExoGPI and ExoCD can trans-activate another nonliganded FSH. Surprisingly, the trans-activation generates a signal to activate either adenylyl cyclase or phospholipase Cbeta, but not both. These results indicate that trans-activation in these mutant receptors is selective and limited in signal generation, thus providing new approaches to investigating the generation of different hormone signals and a novel means to selectively generate a particular hormone signal. Our data also suggest that the FSHR's exodomain could not trans-activate LHR.     

Hormone-induced conformational change of the purified soluble hormone binding domain of follitropin receptor complexed with single chain follitropin

Human follicle-stimulating hormone receptor (hFSHR) belongs to family I of G protein-coupled receptors. FSHR extracellular domain (ECD) is predicted to have 8-9 alphabeta or leucine-rich repeat motif elements. The objective of this study was to identify elements of the FSHR ECD involved in ligand binding. Preincubation of recombinant hFSHR ECD with rabbit antisera raised against synthetic peptides of hFSHR ECD primary sequence abolished follitropin binding primarily in the region of amino acids 150-254. Accessibility of hFSHR ECD after hormone binding, captured by monoclonal antibodies against either ECD or FSH, was decreased for the region of amino acids 150-220 but additionally for amino acids 15-100. Thus, when hFSH bound first, accessibility of antibody binding was decreased to a much larger extent than if antibody was bound first. This suggestion of a conformational change upon binding was examined further. Circular dichroism spectra were recorded for purified single chain hFSH, hFSHR ECD, and hFSHR ECD-single chain hFSH complex. A spectral change indicated a small but consistent conformational change in the ECD.FSH complex after hormone binding. Taken together, these data demonstrate that FSH binding requires elements within the leucine-rich repeat motifs that form a central region of hFSHR ECD, and a conformational change occurs upon hormone binding.     

Autologous biological response modification of the gonadotropin receptor

It is generally held with respect to heterotrimeric guanine nucleotide binding protein-coupled receptors that binding of ligand stabilizes a conformation of receptor that activates adenylyl cyclase. It is not formally appreciated if, in the case of G-protein-coupled receptors with large extracellular domains (ECDs), ECDs directly participate in the activation process. The large ECD of the glycoprotein hormone receptors (GPHRs) is 350 amino acids in length, composed of seven leucine-rich repeat domains, and necessary and sufficient for high affinity binding of the glycoprotein hormones. Peptide challenge experiments to identify regions in the follicle-stimulating hormone (FSH) receptor (FSHR) ECD that could bind its cognate ligand identified only a single synthetic peptide corresponding to residues 221-252, which replicated a leucine-rich repeat domain of the FSHR ECD and which had intrinsic activity. This peptide inhibited human FSH binding to the human FSHR (hFSHR) and also inhibited human FSH-induced signal transduction in Y-1 cells expressing recombinant hFSHR. The hFSHR-(221-252) domain was not accessible to anti-peptide antibody probes, suggesting that this domain resides at an interface between the hFSHR ECD and transmembrane domains. CD spectroscopy of the peptide in dodecyl phosphocholine micelles showed an increase in the ordered structure of the peptide. CD and NMR spectroscopies of the peptide in trifluoroethanol confirmed that hFSHR-(221-252) has the propensity to form ordered secondary structure. Importantly and consistent with the foregoing results, dodecyl phosphocholine induced a significant increase in the ordered secondary structure of the purified hFSHR ECD as well. These data provide biophysical evidence of the influence of environment on GPHR ECD subdomain secondary structure and identify a specific activation domain that can autologously modify GPHR activity.     

Cloning, functional characterization, and expression of a gonadotropin receptor cDNA in the ovary and testis of amago salmon (Oncorhynchus rhodurus).

A gonadotropin receptor was cloned from amago salmon (Oncorhynchus rhodurus) ovarian follicles. This receptor (sGTH-R) belongs to the glycoprotein hormone receptor family with a large extracellular and seven-transmembrane domains. Its sequence homology is highest with mammalian LH receptors. Phylogenetic analysis reveals that sGTH-R is grouped with mammalian and chicken FSH and LH receptors, but not with mammalian TSH receptors. sGTH-R is expressed dominantly in the ovary and testis. Functional characterization examined with transiently transfected mammalian cells revealed increased intracellular cAMP level when exposed to mammalian and fish gonadotropins; the most potent hormone was salmon GTH II. These results indicate that the cloned cDNA encodes a functional amago salmon GTH receptor protein.     

Endocytosis of follicle-stimulating hormone by ovarian granulosa cells: analysis of hormone processing and receptor dynamics

Suspensions of freshly isolated rat granulosa cells were used to study endocytosis and processing of radioiodinated ovine follicle-stimulating hormone (I-oFSH) and to analyze the dynamics of its receptor. Ovine FSH was iodinated to a specific activity of 26 microCi/micrograms as determined by radioreceptor self-displacement assays with maximum specific binding to excess membrane receptors of 46%. Radiolabeled oFSH was judged biologically equivalent to the unlabeled hormone since I-oFSH shows saturation-binding kinetics and stimulates steroidogenesis in a similar dose-related manner to unlabeled oFSH. Experiments designed to study the extent and time course of degradation involved continuous exposure of isolated granulosa cells to I-oFSH. Saturation of membrane receptors was achieved within 1.5 h of incubation, and internalization of FSH occurred in a linear manner for up to 6 h. The rate of internalization was equivalent to 2,780 FSH molecules/cell/h. Degradation of FSH became apparent after 6 h of incubation and increased to 86% of total cellular-associated radioactivity at 22 h. FSH degradation was inhibited by 100 microM chloroquine or 0.45 mM leupeptin. The measurement of cell surface I-oFSH binding in the combined presence of 100 microM chloroquine and 0.5 mM cycloheximide was unchanged for up to 22 h of incubation. This and other receptor binding data suggest that there is no reutilization of FSH receptors. Scatchard analyses of 4 degrees C binding assays on intact cells indicated that a two-site model best fit the data with association constants of K11 = 1.44 (+/- .42) X 10(10) and K12 = 4.35 (+/- .91) X 10(8). Receptor binding and activation studies for progesterone production yielded ED50s of 270 pM and 7.7 pM, respectively, and also indicated that 20% receptor occupancy is sufficient to stimulate maximal progesterone production. We conclude that after the initial binding event, FSH is endocytosed very slowly and is subsequently shuttled to the lysosomal compartment for degradation. The retarded rate of endocytosis may relate to novel pathways of hormone processing.     

Regulation of follicle-stimulating hormone binding to receptors on bovine calf testis membranes by cholera toxin-sensitive guanine nucleotide binding protein

In a previous study we reported that FSH receptors in bovine testes membranes are physically and functionally associated with a guanine nucleotide-binding protein (N protein). In this study we examined the mechanism whereby GTP binding to N protein regulates FSH binding to its receptors. Binding of FSH to receptors decreased in the presence of GTP in a dose-dependent and noncompetitive manner. This effect did not require the presence of Mg+2 and is in contrast to the reported requirement for Mg+2 for GTP effects on human CG binding to ovarian receptors. Equilibrium binding experiments indicated that decreased hormone binding in the presence of GTP was not due to a decrease in the number of FSH receptors per se; rather, the altered binding isotherm was the result of a decrease in affinity of receptors for FSH. Moreover, the dissociation of [125I]human FSH from preformed FSH-receptor complex was rapid in onset and significantly accelerated in the presence of GTP. In a series of nucleotides, GTP was most effective in causing this effect. Evidently, occupancy of GTP binding sites on the N protein, including low affinity and high capacity sites, is necessary for GTP regulation of FSH binding to receptors. The fact that pretreatment of bovine testis membranes with cholera toxin plus NAD, but not pertussis toxin plus NAD, eliminates the GTP effect on FSH binding to its receptors suggests that the GTP regulatory binding protein mediating the GTP regulation of FSH binding is probably Ns and not Ni. Further characterization of FSH receptor sensitivity to GTP, however, indicated that the N protein involved does not exhibit all of the characteristics reported for Ns. For example, the affinity of GTP for N protein is relatively low even under conditions where GTP hydrolysis has a minimal effect in reducing the total concentration of GTP. Also, the absence of a requirement for Mg+2 in high affinity FSH receptor-N protein coupling is different from the requirement for Mg+2 seen with the beta-adrenergic receptor and Ns. Moreover, the N protein which mediates GTP regulation of FSH-receptor binding appears to be relatively insensitive to N-ethylmaleimide, unlike the N-ethylmaleimide sensitivity of the turkey erythrocyte Ns. These results suggest that differences may exist in the structure-function features of GTP regulatory binding protein associated with different types of hormone ligands and receptors.     

Extracellular domain of lutropin/choriogonadotropin receptor expressed in transfected cells binds choriogonadotropin with high affinity

The lutropin-choriogonadotropin (LH/CG) receptor is a cell surface receptor comprised of two domains of roughly equivalent size. The amino-terminal half of the receptor is relatively hydrophilic and is located extracellularly, whereas the carboxyl-terminal half of the receptor shares amino acid homology with other receptors that couple to G proteins and is similarly thought to span the plasma membrane seven times, ending with a relatively short carboxyl-terminal tail. In order to test the role of the extracellular domain in binding hormone, we constructed a mutated rat luteal LH/CG receptor cDNA (termed pCLHR-D2), which encodes for only the extracellular domain, and used it to transiently transfect human kidney 293 cells. Here we report that the expressed extracellular domain of the LH/CG receptor is capable of binding human CG with a high affinity, comparable with that of the full-length receptor. Thus, not only is the extracellular domain of the glycoprotein hormone receptors involved in binding hormone, but it alone is capable of conferring high affinity binding. Unexpectedly, it was also found that this truncated receptor is not secreted into the culture media but remains trapped within the cells.