CDB15:0001024 LHB — LHCGR

ABSTRACT: Studies on human LH receptors are difficult due to the limited availability of clinical samples. Recent cloning of rat and porcine LH receptor cDNAs indicated that these binding sites are single polypeptides of the G-protein-coupled receptor family with seven transmembrane domains. Based on the conserved sequences of rat and porcine receptors, we performed reverse transcription polymerase chain reaction, using human ovarian mRNA as template and obtained partial human LH receptor cDNA clones. Further screening of a human ovary cDNA library and subsequent ligation of individual cDNA clones generated a human LH receptor cDNA containing the entire amino acid-coding region. Sequence analysis indicated that the human receptor cDNA displays 89% and 82% homology at the nucleotide level with its porcine and rat counterparts, respectively. A region spanning the second extracellular and third transmembrane domains is highly conserved among the human LH, FSH, and TSH receptors. The ovarian LH receptor clone is, however, significantly different from an incompletely spliced LH receptor cDNA recently obtained from a human thyroid library. Unlike the thyroid clone, the ovarian LH receptor cDNA could be expressed in the human fetal kidney cell line (293), and radioligand receptor assay identified high affinity (Kd, 1.2 x 10(-10) M) LH/hCG-binding sites on the plasma membrane. Binding specificity of the human LH receptor was studied using recombinant human CG, LH, and FSH secreted by CHO cells transfected with the respective genes. Human CG and LH displaced [125I]hCG binding with an ED50 of 4.3 and 4.8 ng/ml, respectively. In contrast, recombinant FSH was not effective. Treatment of transfected cells with recombinant gonadotropins also induced dose-dependent increases in extracellular cAMP production (hCG = LH much greater than FSH; ED50 25, 10, and greater than 3000 ng/ml). Although equine, rat, and ovine LH as well as equine CG competed effectively for rat testicular LH receptor binding, these hormones were unable to displace [125I]hCG binding to the human receptor, suggesting evolutionary changes in receptor binding specificity and the importance of using human receptors for clinical studies. Thus, the cloning and expression of the human LH receptor cDNA allowed analysis of interactions between human LH receptor and gonadotropins from diverse species. The present work should provide the basis for future design of therapeutic agents capable of interacting with the human receptor and for understanding the structural basis for LH receptor binding to different gonadotropins.

ABSTRACT: Synthetic fragments have not been widely used thus far to evaluate structure-activity relations in the glycoprotein hormones. We prepared a series of peptides representing the intercysteine "loop" sequence (residues 38-57) in human choriogonadotropin (hCG) and lutropin (hLH) beta subunits, anticipating that it might be oriented toward the surface and accessible to receptors. The peptides were characterized chemically and tested for bioactivity by binding to rat ovarian membrane receptor and stimulation of Leydig cell testosterone production. The hCG beta-(38-57) and hLH beta-(38-57) peptides inhibited binding of 125I-labeled hCG half-maximally at 1.51 X 10(-4) and 2.03 X 10(-5) M, respectively, while other peptide hormones and fragments from elsewhere in the beta subunit were inactive. Both peptides stimulated testosterone production, with half-maximal responses at 3.55 X 10(-5) M (hCG) and 2.18 X 10(-5) M (hLH). By radioimmunoassay with an antibody to thyroglobulin-conjugated hCG beta-(38-57) peptide, native hCG and beta subunit were highly reactive, as were the reduced and carboxymethylated subunit and peptide. Helical-wheel projection predicted an amphipathic region in the N-terminal portion of the 38-57 sequence, and circular dichroic measurements showed an increase in ordered structure, especially alpha-helix, when the 38-57 peptides were transferred from an aqueous to a more lipophilic (90% trifluoroethanol) environment. These results indicate that the 38-57 region of beta subunit is exposed on the surface and constitutes a component in the receptor-binding domain for hCG and hLH. A region of amphipathic-helical structure in the 38-57 sequence may promote hormone-receptor interactions in a manner proposed for several other peptide hormones.