Regulation of female fertility and identification of future contraceptive targets.

Mammalian reproduction is a complex physiological process involving a tightly regulated hypothalamic-pituitary-gonadal axis and the integration of a diverse array of molecular signals. Oral contraceptives (OCs) were introduced over 40 years ago and have evolved over the years through the discovery of new estrogens and progestins, the development of progestin-only pills and the reduction of the estrogen content in combined OCs. Despite the developments that improved the safety profile of current OCs, adverse metabolic and vascular effects caused by the estrogen component and possible neoplastic effects of OCs remain and, thus, necessitate efforts to develop newer, possibly non-steroidal and non-hormonal, contraceptives. Recent advances in our understanding of ovarian endocrinology, coupled with molecular biology and transgenic technology, have enabled identification of several factors that are functionally critical in the regulation of female fertility. Progress in the area of female reproduction is showing great promise for identifying new contraceptive drug targets. In this article, the authors review the field of female contraception with emphasis on novel targets involved in reproductive function and identified through genomics and proteomics. In addition, the usefulness of these targets for contraception purposes will be discussed.

Allosteric activation of the follicle-stimulating hormone (FSH) receptor by selective, nonpeptide agonists.

The pituitary glycoprotein hormones, luteinizing hormone and follicle-stimulating hormone (FSH), act through their cognate receptors to initiate a series of coordinated physiological events that results in germ cell maturation. Given the importance of FSH in regulating folliculogenesis and fertility, the development of FSH mimetics has been sought to treat infertility. Currently, purified and recombinant human FSH are the only FSH receptor (FSH-R) agonists available for infertility treatment. By screening unbiased combinatorial chemistry libraries, using a cAMP-responsive luciferase reporter assay, we discovered thiazolidinone agonists (EC50's = 20 microm) of the human FSH-R. Subsequent analog library screening and parallel synthesis optimization resulted in the identification of a potent agonist (EC50 = 2 nm) with full efficacy compared with FSH that was FSH-R-selective and -dependent. The compound mediated progesterone production in Y1 cells transfected with the human FSH-R (EC50 = 980 nm) and estradiol production from primary rat ovarian granulosa cells (EC50 = 10.5 nm). This and related compounds did not compete with FSH for binding to the FSH-R. Use of human FSH/thyroid-stimulating hormone (TSH) receptor chimeras suggested a novel mechanism for receptor activation through a binding site independent of the natural hormone binding site. This study is the first report of a high affinity small molecule agonist that activates a glycoprotein hormone receptor through an allosteric mechanism. The small molecule FSH receptor agonists described here could lead to an oral alternative to the current parenteral FSH treatments used clinically to induce ovarian stimulation for both in vivo and in vitro fertilization therapy.