Possible crosstalk between leptin and prolactin during pregnancy.

Rodents exhibit leptin resistance and high levels of prolactin/placental lactogens during pregnancy. A crosstalk between prolactin and leptin signaling has been proposed as a possible mechanism to explain the changes in energy balance during gestation. However, it remains unclear if specific neuronal populations co-express leptin and prolactin receptors. Therefore, our present study was undertaken to identify in the mouse brain prolactin-responsive cells that possibly express the leptin receptor (LepR). In addition, we assessed the leptin response in different brain nuclei of pregnant and nulliparous mice. We used a LepR-reporter mouse to visualize LepR-expressing cells with the tdTomato fluorescent protein. Prolactin-responsive cells were visualized with the immunohistochemical detection of the phosphorylated form of the signal transducer and activator of transcription-5 (pSTAT5-ir). Notably, many neurons that co-expressed tdTomato and pSTAT5-ir were observed in the medial preoptic area (MPA, 27-48% of tdTomato cells), the retrochiasmatic area (34-51%) and the nucleus of the solitary tract (NTS, 16-24%) of prolactin-treated nulliparous mice, pregnant mice and prolactin-treated leptin-deficient (ob/ob) mice. The arcuate nucleus of the hypothalamus (8-22%), the medial tuberal nucleus (11-15%) and the ventral premammillary nucleus (4-10%) showed smaller percentages of double-labeled cells among the groups. Other brain nuclei did not show significant percentages of neurons that co-expressed tdTomato and pSTAT5-ir. Late pregnant mice exhibited a reduced leptin response in the MPA and NTS when compared with nulliparous mice; however, a normal leptin response was observed in other brain nuclei. In conclusion, our findings shed light on how the brain integrates the information conveyed by leptin and prolactin. Our results corroborate the hypothesis that high levels of prolactin or placental lactogens during pregnancy may directly interfere with LepR signaling, possibly predisposing to leptin resistance.

Neonatal RU-486 (mifepristone) exposure increases androgen receptor immunoreactivity and sexual behavior in male rats.

Progesterone and progestin receptors (PRs) are known to play a role in the development of brain physiology and behavior in many different species. The distribution and regulation of PRs within the developing brain suggest that they likely contribute to the organization of the brain and behavior in a sex-specific manner. We examined the role of PR signaling during development on the organization of adult sexual behavior and androgen receptor (AR) expression in the brain. We administered the PR antagonist, RU-486, subcutaneously to male and female rats on postnatal days 1-7 (0=day of birth) and examined adult sexual behavior and AR-immunoreactivity (AR-ir) in the adult brain. A typical sex difference in lordosis quotient (LQ) was observed and neonatal RU-486 treatment did not alter this behavior. In contrast, neonatal RU-486 treatment increased adult male sexual behavior and AR-ir in several brain areas in males. These data indicate that a transient disruption in PR signaling during development can have lasting consequences on the male brain and may increase male sexual behavior in part by increasing AR expression, and therefore androgen sensitivity, in adulthood.