The decapeptide [hydroxyproline9]GnRH (HypGnRH) has been characterized as an endogenous posttranslational product of the gonadotropin-releasing hormone (GnRH) precursor in a wide range of mammalian brains. Despite consistent biological effects, its secretion by the hypothalamus remains hypothetical. We report here in vitro secretion of HypGnRH and GnRH by the hypothalamus from intact and castrated male rats and provide evidence that they are differentially regulated. Both peptides were identified by two anti-GnRH antibodies of different specificities after separation under two high-performance liquid chromatography conditions. Calcium dependency of HypGnRH release was demonstrated under stimulation with KCl in the absence or presence of Ca2+, as well as with Bay K 8644, veratridine, methoxyverapamil, or tetrodotoxin. Activation of signaling pathways involving adenylate cyclase and protein kinases A and C (PKC) induced HypGnRH release. Expression of data as percentage of release over tissue stores revealed a two- to threefold higher release of HypGnRH than of GnRH under the different modes of stimulation used, except under PKC activation which triggered a comparable recruitment of both peptides. Castration selectively affected PKC-coupled GnRH secretion which showed a twofold lesser release than in intact rats, while the HypGnRH release was unaffected. We conclude that HypGnRH and GnRH are not secreted from the hypothalamus according to the same mechanisms.
The differential secretion of gonadotropin-releasing hormone (GnRH) and [hydroxyproline9]GnRH (HypGnRH) has been recently reported from the adult rat hypothalamus. We report here in vitro cosecretion of HypGnRH and GnRH by the hypothalamus of 2-45 day-old-rats and provide evidence that they are differentially regulated throughout development. The secretion of both forms of GnRH was increased in a dependent manner during depolarization by high K+ solutions, and was stimulated by forskolin and 12-O-tetradecanoylphorbol-13-acetate (TPA), activators of adenylate cyclase and protein kinase C pathways, respectively. The proportion of HypGnRH in the release of GnRH-like peptides remained stable and high (33-40%) under basal and K+-induced conditions until days 13 and 21, respectively. By contrast, the proportion of HypGnRH in the total GnRH-like content of the developing hypothalamus continuously decreased (from 37% to 14%). Similarly, the proportion of HypGnRH: total GnRH-like material released remained stable in TPA- (30%) and forskolin- (50%) induced secretion until postnatal day 8. Evaluation of release over tissue store ratios revealed a 1.3-to 2.8-fold higher release of HypGnRH compared to GnRH according to the different secretions and postnatal periods examined. The preferential recruitment of HypGnRH was maintained under basal and K+ conditions during postnatal development, but it disappeared under TPA stimulation from day 13 onwards. After forskolin stimulation, the preferential mobilization of HypGnRH was markedly reduced from day 2 to day 13 but recovered its high perinatal level during puberty. Taken together, our results support the hypothesis that HypGnRH may play a specific role in development. In addition, a specific function of this peptide taking place during puberty through the activation of the adenylate cyclase pathway is suggested.
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