Distribution of progesterone receptor immunoreactivity in the midbrain and hindbrain of postnatal rats.

Nuclear steroid hormone receptors are powerful transcription factors and therefore have the potential to influence and regulate fundamental processes of neural development. The expression of progesterone receptors (PR) has been described in the developing forebrain of rats and mice, and the mammalian brain may be exposed to significant amounts of progesterone, either from maternal sources and/or de novo synthesis of progesterone from cholesterol within the brain. The present study examined the distribution of PR immunoreactive (PRir) cells within the midbrain and hindbrain of postnatal rats. The results demonstrate that PR is transiently expressed within the first 2 weeks of life in specific motor, sensory and reticular core nuclei as well as within midbrain dopaminergic cell groups such as the substantia nigra and the ventral tegmental area. Additionally, robust PRir was observed in cells of the lower rhombic lip, a transient structure giving rise to precerebellar nuclei. These results suggest that progestins and progesterone receptors may play a fundamental role in the postnatal development of numerous midbrain and hindbrain nuclei, including some areas implicated in human disorders. Additionally, these findings contribute to the increasing evidence that steroid hormones and their receptors influence neural development in a wide range of brain areas, including many not typically associated with reproduction or neuroendocrine function.

Regulation of progesterone receptor expression by estradiol is dependent on age, sex and region in the rat brain.

Progesterone receptor (PR) expression is highly dependent on estradiol in the medial preoptic nucleus (MPN) and the ventromedial nucleus (VMN) of the adult rat brain. During development, males express high levels of PR in the MPN, whereas females have virtually no PR, a sex difference resulting entirely from differential exposure to estradiol. Because PR is also estradiol dependent in the adult VMN, the present study examined the regulation of PR immunoreactivity (PRir) in the developing VMN. Surprisingly, PRir was present at high levels in the VMN of both neonatal males and females. In the neonatal VMN, PR expression was dependent on gonadal hormones in males but not females. When females were ovariectomized and exposed to estradiol at various ages from neonatal to adulthood, estradiol reliably induced PRir in the MPN at postnatal d 7 but failed to induce PRir in the VMN of the same animals. Only later in development, around postnatal d 14, did estradiol increase PRir in the female VMN. There appears to be a developmental switch in the VMN when PR expression changes from estradiol independent to estradiol dependent. Furthermore, this switch is anatomically specific and does not exist in the MPN. The present results indicate that the regulation of PR expression by estradiol is dependent on age, sex, and brain region, suggesting that PR may play a critical but specific role in the normal development of these reproductively important brain areas. In addition, the neonatal female VMN may provide a unique model in which to examine the mechanisms underlying the specificity of steroid-induced gene expression.

Distribution of progesterone receptor immunoreactivity in the fetal and neonatal rat forebrain.

Steroid hormones play an influential role in neural development. In addition to androgens and estrogens of fetal and neonatal origin, the developing brain may also be exposed to progesterone. In this regard, identifying forebrain nuclei that are sensitive to progesterone during neural development may elucidate the impact of progesterone on the developing brain. Using immunocytochemistry, the present study documented the distribution of progesterone receptor (PR) expression in the rat forebrain from embryonic day (E) 17 through postnatal day (P) 28. The results indicate that PR expression in the developing brain is extensive, present in numerous forebrain nuclei, but transient, in that PR expression was absent in most nuclei by P28. Regions displaying the highest levels of PR-immunoreactivity (PRir) were found in preoptic and hypothalamic nuclei including the medial preoptic, anteroventral periventricular, arcuate, and ventromedial nuclei. PRir was moderately abundant in the limbic region, particularly in subdivisions of the amygdala, the bed nucleus of the stria terminalis, and hippocampus. The choroid plexus and neocortex were additional structures that demonstrated relatively abundant levels of PRir. The presence PR expression in the developing forebrain implicates the involvement of progesterone and PR in fundamental mechanisms of neural development.

Neonatal mice possessing an Sry transgene show a masculinized pattern of progesterone receptor expression in the brain independent of sex chromosome status.

To assess the relative roles of sex chromosome genes and gonadal steroid hormones in producing sex differences in progesterone receptor (PR) expression in the forebrain of neonatal mice, we used mice in which the Sry gene had been deleted from the Y-chromosome and inserted as a transgene on an autosome in both XX and XY genotypes. Levels of PR immunoreactivity (PRir) in the anteroventral periventricular nucleus, the medial preoptic nucleus, and the ventromedial nucleus were significantly higher in mice that possessed an Sry transgene compared with mice that lacked an Sry transgene, regardless of their complement of sex chromosomes (XX vs. XY). This result suggests that sexual differentiation of PR expression in these regions is likely controlled mainly by gonadal hormones, not by the genetic sex of the brain cells. No differences in PRir were detected between wild-type XY mice with the Sry gene on the Y-chromosome and XY mice with the Sry transgene, suggesting that testicular hormones produced in these two genotypes have comparable effects on neural tissue.

Sex differences in progesterone receptor expression: a potential mechanism for estradiol-mediated sexual differentiation.

The differential exposure of males and females to testosterone (T) and its metabolite estradiol (E) contributes to the development of sex differences in the brain. However, the mechanisms by which T and E permanently alter neural development remain virtually unknown. Two regions of the rat preoptic area, the anteroventral periventricular nucleus (AVPv) and the medial preoptic nucleus (MPN), are sexually dimorphic and serve as models for studying the hormonal mechanisms of sexual differentiation. Around birth, these regions express dramatically higher levels of progesterone receptor immunoreactivity (PRir) in males than they do in females. The present study examined the possibility that sexually dimorphic induction of PR expression in these two regions constitutes a potential mechanism of E-mediated sexual differentiation. Prenatal exposure to either T propionate or the synthetic estrogen, diethylstilbestrol, but not dihydrotestosterone propionate, significantly increased PRir levels in the MPN and AVPv of fetal females compared with controls. Prenatal exposure to the aromatase inhibitor, 1,4,6-androstatriene-3,17-dione, significantly reduced PRir in the MPN and AVPv of fetal males, whereas the androgen receptor antagonist flutamide had no effect. This suggests that aromatization of T into E is crucial for the sex difference in PR expression in the MPN and AVPv during development.

Progesterone receptors and the sexual differentiation of the medial preoptic nucleus.

The central component of the medial preoptic nucleus (MPNc) of the rat has served as an excellent model of sexual differentiation. The MPNc is larger in adult males than in females, and its development is regulated by perinatal gonadal hormones. Although testosterone (T) and its metabolite estradiol (E) sexually differentiate this region, the exact mechanism by which they act during development is not known. There is a dramatic sex difference in the expression of progesterone receptors (PR) in the MPN during development; perinatal males express higher levels of PR than females. Additionally, PR expression during this time is dependent on exposure to T. Thus, PR induction may be one mechanism by which T sexually differentiates the MPN. The present study investigated the potential role of PR in the sexual differentiation of the MPNc. Anatomical examination of PR distribution within the MPN of neonatal males revealed the presence of PR immunoreactive cells within the MPNc, suggesting a direct route of action for PR in the development of the MPNc. Additionally, we measured the effects of neonatal RU486 treatment, a progesterone and glucocorticoid receptor antagonist, on subsequent MPNc volume in neonatally T-treated females and neonatally castrated males, given T. RU486 treatment reduced the MPNc volume of T-treated females while it increased the volume in T-treated, neonatally castrated males. These results, taken together with the expression of PR in the MPNc, suggest that PR may influence the sexual differentiation of the MPNc volume.