Hypothalamic regulatory peptides and their receptors: cytochemical studies of their role in regulation at the adenohypophyseal level.

Hypothalamic regulatory peptides bind to specific receptors on target cells in the pituitary and control secretion. They in turn can be regulated at the pituitary level by steroid and peptide modulators. Affinity cytochemical techniques are important tools for the identification of specific target binding sites for these regulatory peptides. This presentation reviews the work in which potent, biotinylated ligands of gonadotropin releasing hormone (bio-GnRH), corticotropin releasing hormone (bio-CRH), and arginine vasopressin (bio-AVP) were applied to study the target cell responses. Bio-GnRH, bio-CRH, and bio-AVP bind to membrane receptors on specific anterior pituitary cells. Dual labeling for either gonadotropin or adrenocorticotropin (ACTH) antigens further identified the target cells. After 1-3 minutes, the label was in patches or capped on the surface. After 3 minutes, it was internalized in small vesicles and sent to receptosomes and vacuoles in the Golgi complex. Eventually the biotinylated peptides, or a metabolite, was found in the lysosomes (multivesicular bodies) and a subpopulation of secretory granules. The route and rate of uptake was similar to that described for the classical receptor-mediated endocytosis process. In contrast, intermediate lobe corticotropes internalized the bio-CRH in less than 1 minute. The route through the Golgi complex appeared to be bypassed. Instead the labeled peptide was in vesicles, on the membranes of scattered vacuoles, and in multivesicular bodies. Modulation of ligand binding by steroids showed that changes in receptor numbers correlated with changes in the number of cells that bound the ligand. In male rats, dihydrotestosterone reduced the percentage of GnRH-bound cells by 50%. Most of the reduction appeared in cells that stored luteinizing hormone (LH) antigens. In diestrous female rats, estradiol increased the percentage of bio-GnRH-bound cells. However, the steroid decreased the percentage of GnRH-bound cells in cells from proestrous rats. Glucocorticoids decreased the percentage of CRH-bound corticotropes in as little as 10 minutes. Potentiation of secretion by these ligands was correlated with increases in the percentage of ligand-bound cells. AVP pretreatment of corticotropes increased the percentage of cells that bound bio-CRH. It also increased the rate of receptor-mediated endocytosis of CRH and changed the route so that the Golgi complex was bypassed. This effect could be mimicked by activation of its second messengers (calcium and protein kinase C). Similarly, CRH pretreatment increased the percentage of corticotropes that bound AVP. Thyrotropin releasing hormone (TRH) pretreatment also increased the percentage of thyrotropes that bound AVP.(ABSTRACT TRUNCATED AT 400 WORDS)

Cytochemical and cytophysiological studies of gonadotropin-releasing hormone (GnRH) target cells in the male rat pituitary: differential effects of androgens and corticosterone on GnRH binding and gonadotropin release.

Steroid hormones can differentially modify gonadotropin release stimulated by GnRH. Decreased GnRH-mediated gonadotropin release has been observed in vitro after pretreatment with androgens or glucocorticoids. In this study, we tested this phenomenon further with the use of a new cytochemical stain for a potent biotinylated analog of GnRH ([Biotinyl D-Lys6]GnRH) combined with stains for LH and FSH and gonadotropin RIAs. The first phase of the study involved characterization of the GnRH target cells in monolayer cultures from male rats. Dose-response curves (measured as the ability to release both LH and FSH) showed that biotinylated GnRH (Bio-GnRH) was equipotent with or more potent than unlabeled [D-Lys6]GnRH in parallel cultures. The avidin-biotin complex stain demonstrated that 16% of the 2- to 3-day pituitary monolayer cells were labeled for Bio-GnRH within 10 min of exposure. Double stains for gonadotropins showed that 37% of the LH gonadotropes and 42% of the FSH gonadotropes did not stain for Bio-GnRH. During the second phase of these studies, the cultures were pretreated for 48 h with 1-100 nM 5 alpha-dihydrotestosterone (DHT), 100 nM corticosterone (CT), or 100 nM epitestosterone (ET) to test the effects of these steroids on the number of cells to which Bio-GnRH bound and the gonadotrope secretory response. Compared with ET- or vehicle-pretreated control cultures, DHT and CT both reduced the amount of LH and FSH release stimulated by GnRH. The magnitude of the reduction in LH release was much greater than that in FSH release, especially after pretreatment with CT. DHT and CT had remarkably different effects on the percentages of cells stained for GnRH. Pretreatment with DHT caused a reduction in the percentages of cells staining for bound Bio-GnRH to 9% compared with 14.3% after CT treatment and 16% after vehicle or ET treatment. The counts of the stained gonadotropes suggested that most of the reduction occurred in the LH gonadotrope population. Because both DHT and CT reduced GnRH-mediated gonadotropin release, but only DHT reduced the percentage of cells that bound Bio-GnRH, it is suggested that the two steroids affect gonadotropin release by separate mechanisms.