Relaxin family peptide 1 (RXFP1) receptor (LGR7) and RXFP2 receptor (LGR8) were recently identified as the receptor targets for H2 relaxin and insulin-like peptide 3 (INSL3), respectively. In this study, we define the pharmacology of these two receptors by using a number of receptor chimeras and relaxin family peptides. We have identified two binding sites on these receptors: one primary, high-affinity site within the ectodomain and a secondary, lower affinity site within the transmembrane region. The primary site was found to dictate receptor binding characteristics, although the lower affinity site also exerts some influence and modulates ligand affinity for the primary site in a manner dependent upon the peptide in question. Not all relaxin peptides were able to bind to the RXFP2 receptor, indicating that the relaxin-RXFP2 receptor interaction is species-specific. INSL3 was found to exhibit characteristics of a partial agonist at the RXFP2 and chimeric RXFP1/2 receptors, with low maximal cAMP responses but high potency in coupling to this pathway. cAMP accumulation studies also revealed that the binding sites couple to cAMP signaling pathways with differing efficiency: the high-affinity site signals with high efficiency, whereas the lower affinity site signals with little to no efficiency. Comparisons between RXFP1, RXFP2, the chimeric receptors, and the truncated receptors revealed that the interaction between receptor sites is critical for optimal ligand binding and signal transduction and that the ectodomain is essential for signaling. Evidence obtained in this study supports a two-stage binding model of receptor activation: binding to the primary site allows a conformational change and interaction with the low-affinity transmembrane site.Relaxin is a two-chain peptide that was discovered after the observation that serum from pregnant guinea pigs caused relaxation of the pubic ligament (Hisaw, 1926). It is structurally closely related to insulin: both peptides have an A and B chain joined by two interchain disulfide bonds, and one intra-A-chain disulfide bond. This discovery established the concept of the insulin-relaxin superfamily (Schwabe and McDonald, 1977). The high degree of similarity between insulin and relaxin precipitated a search for additional members of the insulin-relaxin superfamily with the same structural motif. To date, this peptide family includes insulin-like growth factor-1 and insulin-like growth factor-II (Humbel, 1990), INSL3 (Adham et al., 1993), INSL4 (Koman et al., 1996, INSL5 (Conklin et al., 1999), and INSL6 (Lok et al., 2000).Relaxin itself has many paralogs: in humans, three nonallelic genes produce H1 relaxin (Hudson et al., 1983), H2 relaxin (Hudson et al., 1984, and the recently identified H3 relaxin . H2 relaxin is the major circulating form of relaxin in the human and has equivalent orthologs in other species, including porcine relaxin (Hudson et al., 1981;Haley et al., 1982), rhesus monkey relaxin (Crawford et al., 1989), and rat relaxin (Hudson et al., 1981)...
