Short-term regulation of prolactin receptors in the liver, mammary gland and kidney of pregnant and lactating rats infused with ovine prolactin or human growth hormone

Mathematical modelling of prolactin-receptor interaction and the corollary for prolactin receptor gene expression in skin

A mathematical model of prolactin regulating its own receptors was developed, and compared with experimental data on a qualitative level. The model incorporates the kinetics of prolactin-receptor interactions and subsequent signalling by prolactin-receptor dimers to regulate the production of receptor mRNA and hence the receptor population. The model relates changes in plasma prolactin concentration to prolactin receptor (PRLR) gene expression, and can be used for predictive purposes. The cell signalling that leads to the activation of target genes, and the mechanisms for regulation of transcription, were treated empirically in the model. The model's parameters were adjusted so that model simulations agreed with experimentally observed responses to administration of prolactin in sheep. In particular, the model correctly predicts insensitivity of receptor mRNA regulation to a series of subcutaneous injections of prolactin, versus sensitivity to prolonged infusion of prolactin. In the latter case, response was an acute down-regulation followed by a prolonged up-regulation of mRNA, with the magnitude of the up-regulation increasing with the duration of infusion period. The model demonstrates the feasibility of predicting the in vivo response of prolactin target genes to external manipulation of plasma prolactin, and could provide a useful tool for identifying optimal prolactin treatments for desirable outcomes.

Lactation increases prolactin receptor expression in spleen and thymus of rats

Prolactin receptors (PRL-R) are widely expressed on cells of the immune system. During lactation, the increase in serum PRL levels may modify the gene expression of these receptors. Specific PRL binding sites and the expressions of both PRL-R-L and PRL-R-S forms in thymus and spleen of nulliparous control, 10-day postpartum lactating, and 10-day postpartum nonlactating rats were studied. A semi-quantitative RT-PCR technique was used to detect the PRL-R gene transcript in the tissues. Our results showed that specific PRL binding sites and PRL-R-L mRNA and PRL-R-S mRNA were present in the lymphoid tissues with the PRL-R-L mRNA predominant. Lactation markedly increased specific binding sites and PRL-R-L mRNA in both spleen and thymus and only PRL-R-S in spleen. No differences between nulliparous control and postpartum nonlactating rats were observed in any of the parameters measured. The parallel increase in specific PRL binding sites and PRL-R-L mRNA suggests that lactation up-regulates PRL-R expression in lymphoid tissues and may be beneficial to the maternal immune system.

Ectopic expression of beta-lactoglobulin/human serum albumin fusion genes in transgenic mice: hormonal regulation and in situ localization

We produced transgenic mice carrying the native sheep beta-lactoglobulin (BLG) or fusion genes composed of the BLG promoter and human serum albumin (HSA) minigenes. BLG was expressed exclusively in the mammary glands of the virgin and lactating transgenic mice evaluated. In contrast, transgenic females carrying the BLG/HSA fusion constructs also expressed the HSA RNA ectopically in skeletal muscle, kidney, brain, spleen, salivary gland and skin. Ectopic expression of HSA RNA was detected only in strains that express the transgene in the mammary gland. There was no obvious correlation between the level of the HSA RNA expressed in the mammary gland and that found ectopically. In three transgenic strains analysed, the expression of HSA RNA in kidney and skeletal muscle increased during pregnancy and lactation, whereas in the brain HSA expression decreased during lactation in one of the strains. HSA protein was synthesized in skeletal muscle and skin of strain #23 and its level was higher in lactating mice compared with virgin mice. Expression of HSA was also analysed in males and was found to be more stringently controlled than in females of the same strains. In situ hybridization analyses localized the expressed transgene in the skin, kidney, brain and salivary glands of various transgenic strains. Distinct strain-specific and cell-type specific HSA expression patterns were observed in the skin. This is in contrast to the exclusive expression of the HSA transgene in epithelial cells surrounding the alveoli of the mammary gland. Taken together, these results suggest that the absence of sufficient mammary-specific regulatory elements in the BLG promoter sequences and/or the juxtaposition of the BLG promoter with the HSA coding sequences leads to novel tissue- and cell-specific expression in ectopic tissues of transgenic mice.

Effects of medroxyprogesterone acetate on serum prolactin levels and liver prolactin binding capacity in the rat

Modifications in liver prolactin (PRL) receptor levels and serum PRL concentration induced by administration of medroxyprogesterone acetate (MPA) were investigated in rats of both sexes. MPA induced a reduction both of the levels of PRL in the serum and of liver PRL receptors in the female rat. The reduction of the number of PRL receptors caused by MPA was rapid and almost complete after 10 days of treatment and appeared earlier than that of serum PRL levels. Furthermore the MPA-induced decrease in PRL receptors was specific, since insulin binding to the same liver membranes was not affected. MPA given simultaneously with oestradiol (which increases both the number of liver PRL receptors and the serum PRL levels in the male rats) was able to counteract the increase in PRL binding induced by oestradiol. On the contrary, the oestrogen-induced increase in serum PRL was not affected by MPA treatment. Similar results were obtained using tamoxifen, a well known antioestrogenic drug. In conclusion, our results show that the reduction of PRL receptor levels induced by MPA in rat liver is specific, not correlated to serum PRL concentration, and seems to depend on the antioestrogenic activity of the drug.