Modulatory effects of leptin on leydig cell function of normal and hyperleptinemic rats.

GIOVAMBATTISTA A; SUESCUN MO; NESSRALLA CC; FRANCA LR; SPINEDI E; CALANDRA RS

NEUROENDOCRINOLOGY

KARGER AG

Lugar: Basel; Año: 2003 vol. 78 p. 270 - 279

0028-3835

Neonatal L-monosodium glutamate (MSG) administration in rats induces several neuroendocrine and metabolic disruptions. Leptin, the adipocyte product, modulates several neuroendocrine systems including the hypothalamic-pituitary-gonadal (HPG) axis in mammals. The aim of the present study was to determine whether MSG-induced chronic hyperleptinemia could play any relevant role in the hypogonadism developed by male rats when examined in adulthood. We found that 120-day-old MSG male rats displayed significant hyperleptinemia, hypogonadism, and undisturbed basic testis structure and spermatogenesis. In vitro studies in purified Leydig cells from normal (CTR) and MSG-damaged rats revealed that basal and human chorionic gonadotropin (hCG)-stimulated 17-hydroxy-progesterone (17-HO-P(4)), Delta(4)-androstenedione (Delta(4)A) and testosterone (T) secretions were significantly lower in MSG than in CTR cells. Exposure to murine leptin (Mleptin, 10(-8)M) significantly inhibited hCG-elicited T secretion by CTR cells after 180 min incubation. While Mleptin significantly inhibited hCG-stimulated Delta(4)A output and the Delta(4)A:17-OH-P(4) ratio of secretion, conversely, it failed to modify the ratio T:Delta(4)A release by CTR Leydig cells. Interestingly, the effects of Mleptin found on CTR Leydig cells were absent in MSG Leydig cells. Finally, endogenous hyperleptinemia was associated with a significant decrease in Leydig cell expression of Ob-Rb mRNA in MSG rats. In summary, this study demonstrates that: (1) Mleptin inhibited testicular steroidogenesis in CTR rats; (2) MSG-treated rats showed lower in vitro 17-OH-P(4), Delta(4)A and T production under basal and post-hCG stimulation conditions; (3) purified Leydig cells from MSG-treated rats displayed resistance to the inhibitory action of Mleptin on T release, and (4) endogenous leptin exerts a modulatory effect on Leydig cell Ob-Rb mRNA expression. The inhibitory effect of leptin on testicular function is thus abrogated in MSG-damaged rats. The testicular leptin-resistance developed by MSG rats seems to be due to early chronic exposure of Leydig cells to high leptin circulating levels, which in turn down-regulate testicular Ob-Rb expression. It remains to be determined whether the testicular dysfunction of MSG rats can be reversed after correction of hyperleptinemia or whether it is an irreversible effect of the hypothalamic lesion.