Ernest Loumaye

Compartmentalization of luteinizing hormone pools: Dynamics of gonadotropin releasing hormone action in superfused pituitary cells

Cultured rat anterior pituitary cells were continuously perfused with medium 199, and exposed to short (5 min), intermediate (30 min), or long (6 h) pulses of a maximally effective concentration of gonadotropin-releasing hormone (GnRH). Assay of the effluent by radioimmunoassay and interstitial-cell bioassay revealed a biphasic response to GnRH, and indicated that 3 pools of luteinizing hormone (LH) are present in the gonadotroph. A rapidly releasable peak of bioactive LH comprising about 2% of the total cellular LH was mobilized within 1 min of GnRH addition, lasted for 3-4 min, and was independent of the duration of stimulation. The second, larger pool of bioactive LH varied from 15 to 50% of the total LH as the duration of exposure to GnRH was increased from 5 min to 6 h. A third LH pool comprising up to 50% of the total LH could be mobilized by 50 mM potassium but not by continuous GnRH treatment, due to refractoriness of the cells to prolonged stimulation by the decapeptide. In contrast, repeated pulses of GnRH evoked a series of biphasic LH peaks with profiles similar to that observed during a single response to GnRH, indicating that continuous exposure to GnRH is necessary for densensitization. Release of LH from the perfused cells was calcium-dependent, and the bio-immuno ratio of the first and second pools of LH was similar. The in vitro secretion profile of cultured rat cells is comparable with the early and late phases of LH release observed in GnRH-infused man, but occurs much more rapidly, and demonstrates heterogeneity of the LH release process at the level of the gonadotroph. The superfusion technique provides a powerful tool to further investigate the bioactivity of GnRH and its analogs for use in fertility control.

GnRH receptors and actions in the control of reproductive function.

The hypothalamic control of reproductive function is expressed through the receptor-mediated actions of GnRH on the pituitary gonadotroph. GnRH receptors in the pituitary gland exhibit prominent variations in number during the ovarian cycle and after changes in steroid feedback, and are modulated by the rate of GnRH secretion from the hypothalamus. In cultured pituitary cells, GnRH receptors undergo down-regulation during exposure to GnRH agonists, followed by a subsequent elevation of sites that is dependent on protein synthesis. GnRH antagonists do not cause receptor down-regulation, but high-affinity antagonist analogs bind for extended periods to cause receptor occlusion and prolonged inhibition of GnRH action. Analysis of the rat pituitary GnRH receptor by photoaffinity labeling reveals two binding subunits of mol. wt 53,000 and 42,000. The receptor-activated processes leading to gonadotropin secretion are highly calcium-dependent, and are initiated by rapid phospholipid hydrolysis with production of arachidonic acid metabolites, diacylglycerol, and inositol phosphates. The role of protein kinase C in gonadotropin secretion is indicated by the ability of phorbol esters and synthetic diacylglycerols to stimulate LH release, the inhibition of protein kinase C and LH release by retinal, and the redistribution of protein kinase C between cytosol and membrane fractions during stimulation of pituitary gonadotrophs by GnRH. It is likely that the effects of arachidonate metabolites are integrated with those of calcium-calmodulin and calcium, phospholipid-dependent protein kinases during the immediate and sustained phases of GnRH-induced gonadotropin secretion.

Kit Ligand and the Somatostatin Receptor Antagonist, BIM-23627, Stimulate in Vitro Resting Follicle Growth in the Neonatal Mouse Ovary

In the mammalian ovary, kit ligand (KL), coded by a cAMP-stimulatable gene, is a protein that promotes initiation of follicle growth. The neuropeptide somatostatin (SST) is a small peptide that inhibits cAMP generation in many cell types. Consequently, SST receptor agonists might alter KL production and subsequent follicle growth. The present study was undertaken to look for the existence of a functional SST system in the mouse ovary, to test the effects of the SST receptor 2 (SSTR-2) antagonist BIM-23627 on in vitro folliculogenesis, and to compare them with those of KL, which was demonstrated to stimulate follicle growth in the neonatal rat ovary. Pairs of ovaries from 5-d-old mice were incubated in vitro during 15 d in the presence of either KL or BIM-23627. For every mouse, one ovary was cultured in culture medium (control), and the other ovary was cultured in the presence of either KL or BIM-23627. After 5, 10, and 15 d culture, the ovaries were histologically assessed for the content of primordial, primary, and secondary follicles. The SSTR-2 and -5, but not SST, were identified at the transcriptional and translational (mainly in granulosa cells) levels. Both KL and BIM-23627 triggered a reduction of the percentages of primordial follicles and an increase of the percentages of primary and secondary follicles when compared with control ovaries from the same animal. In conclusion, extraovarian SST, acting through its receptors 2 and 5 present on granulosa cells, may be involved in mouse folliculogenesis by reducing recruitment of resting follicles.