Characterization of a lipid-associated gonadotropin receptor from the luteinized rat ovary

Abstract

Gonadotropin receptors which bind luteinizing hormone (lutropin) and human chorionic gonadotropin (hCG) in the ovaries of immature female rats showed a 30-fold increase after treatment of animals with pregnant mare serum gonadotropin (PMSG) and hCG. This marked induction of lutrophin/hCG receptors in the rat ovary was not accompanied by a change in binding affinity for labeled hCG. Such luteinized ovaries have been found consistently to contain a small proportion of soluble receptor sites, which comprised about 5% of the total receptor population. The soluble receptor sites were present in the floating lipid fraction of the 360 000 × g supernatant of homogenate prepared from luteinized ovaries, and could not be detected in similar fractions prepared from interstitial cells or homogenates of the normal rat testis. The physico-chemical properties of the spontaneously soluble ovarian receptors were similar to those derived for detergent-solubilized receptors prepared by extraction of particulate ovarian binding fractions with Triton X-100. The affinity constant to the soluble ovarian receptor sites for [ 125I]hCG was 0.70 · 10 10 M −1, and that of the receptors solubilized by Triton X-100 was 0.72 · 10 10 M −1. The sedimentation pattern of the soluble receptors during sucrose density gradient centrifugation showed extensive aggregation into rapidly sedimenting forms. However, centrifugation of the cytosol receptor in the presence of Triton X-100 gave a single 6.5 S component, corresponding to the solubilized receptors previously characterized in detergent extracts of the rat ovary and testis. The pesence of a spontaneously soluble lutropin/hCG receptor in ovarian cytosol fractions suggests that rapid synthesis and assembly of receptors in ovaries of PMSG-hCG-treated rats is accompanied by increased production of cytoplasmic receptor precursors; alternatively, this receptor population may represent a fraction that has been internalized or processed as during receptor turnover in the cell membrane.