Prolactin- and testosterone-induced inhibition of LH secretion after orchidectomy: role of preoptic and tuberoinfundibular γ-aminobutyric acidergic neurones

Abstract

The inhibitory amino acid neurotransmitter gamma-aminobutyric acid (GABA) may play an important role in the regulation of LH-releasing hormone secretion. The present study examined the effect of prolactin on GABAergic neuronal activity in microdissected brain regions of the orchidectomized rat, to determine whether inhibition of LH secretion after castration by acute hyperprolactinaemia was associated with prolactin-induced changes in GABAergic neuronal activity. The effects of prolactin were contrasted with the effects of testosterone on hypothalamic GABAergic neurones after orchidectomy. GABA concentrations were measured by high pressure liquid chromatography in eight microdissected brain regions in untreated rats and 60 min after inhibition of the GABA catabolic enzyme GABA transaminase by injection of amino-oxyacetic acid (AOAA). The rate of GABA accumulation in microdissected brain regions following injection of AOAA was taken as an index of GABAergic neuronal activity. Rats were divided into seven experimental groups: intact controls, 2 days after castration, 2 days after castration with prolactin treatment (2.5 mg ovine prolactin injected s.c. every 12 h, starting at the time of castration), 2 days after castration with testosterone replacement (30 mm silicone elastomer implant containing crystalline testosterone), 6 days after castration, 6 days after castration with prolactin treatment, and 6 days after castration with testosterone replacement. Both 2 and 6 days after castration, plasma LH was markedly elevated above levels in intact rats, and AOAA-induced GABA accumulation was significantly decreased in the diagonal band of Broca at the level of the organum vasculosum of the lamina terminalis, in the medial preoptic nucleus and in the median eminence. Hyperprolactinaemia significantly reduced LH levels 2 days but not 6 days after castration. GABAergic neuronal activity, however, was not significantly affected by prolactin at either time. Testosterone replacement blocked the postcastration elevation in plasma LH and prevented the castration-induced suppression of GABAergic neuronal activity both 2 and 6 days after castration. There were no castration- or hormone-induced changes in GABAergic neurones observed in the medial or lateral septum, caudate nucleus, cingulate cortex or arcuate nucleus. These results demonstrate that the activity of GABAergic neurones terminating in the rostral hypothalamus and the median eminence is positively regulated by testosterone, and that these steroid-sensitive GABAergic neurones may be important in the negative-feedback control of LH secretion. Inhibition of LH secretion by hyperprolactinaemia, however, may not be mediated by changes in GABAergic neuronal activity.