The adult female pituitary has significantly more lactotrophs than that of the male, while the later has a higher percent of somatotrophs. It is clear that GH and prolactin (PRL) gene expression and somatotroph and lactotroph proliferation are modulated by the postpubertal hormone environment; however, the role of the neonatal steroid environment in this process is not known. We have used in situ hybridization to determine the number of GH and PRL mRNA-containing cells, as well as the level of expression of these two hormones, in response to neonatal and adult testosterone treatment. Female rats exposed to testosterone during the neonatal period, adulthood or both periods, as well as normal females and males were used. Exposure to testosterone during the neonatal period significantly increased the percentage of somatotrophs (ANOVA: P<0. 005) and decreased that of lactotrophs in the adult female rat (ANOVA: P<0.001). Adult testosterone treatment had no significant effect on the percentage of somatotrophs. The percentage of lactotrophs was significantly increased by adult testosterone only in those rats also exposed to neonatal testosterone. PRL mRNA concentrations, as reflected by silver grains/cell, were reduced by neonatal testosterone and increased by adult testosterone treatment (ANOVA: P<0.0001). Overall PRL mRNA levels, measured by densitometry, were also reduced by neonatal testosterone exposure, but adult testosterone had no effect (ANOVA: P<0.001). GH mRNA levels per cell, as reflected by silver grains/cell, were increased by adult testosterone, while neonatal testosterone treatment had no effect. Overall GH mRNA levels per unit area, determined by densitometry measurements, were increased by both neonatal and adult testosterone treatment, with the combination of these two treatments resulting in adult females having levels indistinguishable from intact males (ANOVA: P<0.003). These results suggest that, in combination with postpubertal sex steroids, the neonatal gonadal steroid environment plays an important role in determining anterior pituitary hormone synthesis and cellular composition.

This article has been cited by other articles:

				A. S. Khan, M. L. Fiorotto, L.-A. Hill, P. B. Malone, K. K. Cummings, D. Parghi, R. J. Schwartz, R. G. Smith, and R. Draghia-Akli Nonhereditary Enhancement of Progeny Growth Endocrinology, September 1, 2002; 143(9): 3561 - 3567. [Abstract] [Full Text] [PDF]