Common and specific effects of the two major forms of prolactin in the rat testis.

Prolactin (PRL) has both stimulatory and inhibitory effects on testicular function, a finding we hypothesized may be related in some part to the form of the hormone present or administered. In the analysis of the pituitary secretion profiles of early pubescent vs. mature male rats, we found PRL released from early pubescent pituitaries had about twice the degree of phosphorylation. Treatment of mature males with either unmodified PRL (U-PRL) or phosphorylated PRL (via the molecular mimic S179D PRL) for a period of 4 wk (circulating level of approximately 50 ng/ml) showed serum testosterone decreased by approximately 35% only by treatment with the phospho-mimic S179D PRL. Given the specificity of this effect, it was initially surprising that both forms of PRL decreased testicular expression of 3beta-hydroxysteroid dehydrogenase and steroidogenic acute regulatory protein. Both forms also increased expression of the luteinizing hormone receptor, but only S179D PRL increased the ratio of short to long PRL receptors. Endogenous PRL and luteinizing hormone levels were unchanged in all groups in this time frame, suggesting that effects on steroidogenic gene expression were directly on the testis. Terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick end-labeling analysis combined with staining for 3beta-hydroxysteroid dehydrogenase and morphometric analysis showed that S179D PRL, but not U-PRL, increased apoptosis of Leydig cells, a finding supported by increased staining for Fas and Fas ligand in the testicular interstitium, providing an explanation for the specific effect on testosterone. S179D PRL, but not U-PRL, also increased apoptosis of primary spermatogonia, and U-PRL, but not S179D PRL, decreased apoptosis of elongating spermatids. Thus, in mature males, hyperprolactinemic levels of both forms of PRL have common effects on steroidogenic proteins, but specific effects on the apoptosis of Leydig and germ cells.

Transcriptional changes underlying the secretory activation phase of mammary gland development.

The secretory activation stage of mammary gland development occurs after parturition and converts inactive lobuloalveoli to active milk secretion. This process is triggered by progestin withdrawal and depends upon augmented prolactin (Prl) signaling. Little is known about the Prl-induced transcriptional changes that occur in the mammary gland to drive this process. To examine changes in the mammary transcriptome responsible for secretory activation, we have used transcript profiling of three mouse models that exhibit failure of secretory activation: knockout of galanin (a regulator of pituitary Prl production and a mammary cell autonomous modulator of Prl action); treatment with S179D Prl (a phosphoprolactin mimic); and knockout of a single Prl receptor allele. A significant reduction in expression was observed in genes belonging to 46 gene ontologies including those representing milk proteins, metabolism, lipid, cholesterol and fatty acid biosynthetic enzymes, immune response, and key transcription factors. A set of 35 genes, commonly regulated in all three models, was identified and their role in lactogenesis was validated by examining their expression in response to Prl stimulation or signal transducer and activator of transcription 5 knockdown in the HC11 mouse mammary cell culture model. The transcript profiles provided by these experiments identify 35 key genes (many for the first time) involved in the secretory activation phase of mammary gland development, show that S179D acts as an antagonist of Prl action, and provide insight into the partial penetrance of failed lactation in Prl receptor heterozygous females.

Unmodified prolactin (PRL) promotes PRL secretion and acidophil hypertrophy and is associated with pituitary hyperplasia in female rats.

In this study, we have tested the hypothesis that unmodified prolactin (U-PRL) and phosphorylated prolactin (P-PRL) have differential roles in the autoregulation of PRL secretion in vivo. Recombinant human U-PRL and a molecular mimic of P-PRL (S179D PRL) were administered to male rats and to female rats in different physiological states and the effect on rat PRL release was measured. Administration of U-PRL elevated rat PRL in all female animals, but was without effect in males. By contrast, S179D PRL was inactive in females, but inhibited PRL release in males. Morphometric and immunohistochemical analyses demonstrated acidophil hypertrophy and evidence of increased PRL secretion in the pituitaries of U-PRL-treated females. Analysis of the two forms of PRL during prolactinoma induction in two differentially susceptible strains of rats found a strong temporal correlation among increased ratios of U-PRL: P-PRL, increased circulating PRL, and increased cell proliferation. We conclude (1). that the autoregulatory mechanism(s) can distinguish between the two major forms of PRL and that higher proportions of U-PRL not only allow for higher circulating levels of PRL, but are also autostimulatory, (2). that the autoregulatory mechanism( s) are set differently in males and females such that females are more sensitive to autostimulation by U-PRL and less sensitive to inhibition by P-PRL, and (3). that U-PRL and P-PRL may also have differential roles in the regulation of pituitary cell proliferation.