Cellular composition of the adult rat anterior pituitary is influenced by the neonatal sex steroid environment

Abstract

Growth hormone (GH) and prolactin (PRL) secretion differ significantly between adult males and females and this is due, at least in part, to the postpubertal hormone environment which affects GH and PRL gene expression, as well as somatotrope and lactotrope proliferation. However, the role of the neonatal steroid environment in this phenomenon is less well understood. 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 and of the pituitary transcription factor 1 (Pit-1). Neonatally castrated male rats that had been exposed to testosterone during the neonatal period, adulthood or during both periods, males castrated as adults, normal adult males and normal proestrous females were used. Orchidectomy of adult rats had no effect on the number of somatotropes or lactotropes, but significantly reduced GH and PRL mRNA levels. Neonatal castration significantly reduced the percentage of somatotropes and increased that of lactotropes in the adult male. In addition, GH and Pit-1 mRNA levels were reduced significantly, but PRL mRNA levels were not modified. Treatment of neonatally castrated males with testosterone during the neonatal period significantly increased the percentage of somatotropes and decreased the percentage of lactotropes compared to vehicle-treated animals. It also increased GH and Pit-1 mRNA levels, but did not affect PRL mRNA levels. Adult testosterone treatment significantly increased the percentage of both somatotropes and lactotropes, as well as GH, PRL and Pit-1 mRNA levels. Treatment of neonatally castrated males with testosterone during both the neonatal and adult periods returned the percentage of somatotropes and lactotropes, as well as GH, PRL and Pit-1 mRNA levels, to that of the intact male. These results suggest that, although the postpubertal steroid environment is important in determining anterior pituitary hormone synthesis and cellular composition, the neonatal steroid environment also plays an important role in this phenomenon.