Jeffrey D. Blaustein

Sex Differences in the Brain: The Not So Inconvenient Truth

### Introduction In 2001 the Institute of Medicine, a branch of the National Academy of Sciences in the U.S.A., concluded that many aspects of both normal and pathological brain functioning exhibit important yet poorly understood sex differences ([Wizemann and Pardu, 2001][1]). Ten years later, the

Ovarian influences on the meal patterns of female rats

Abstract A series of experiments examined the effects of estrous cycles, ovariectomy, and estradiol-replacement on free-feeding meal patterns of female rats maintained on a liquid diet. The proestrous decrease in food intake was accomplished by a decrease in meal size and a less than fully compensatory increase in meal frequency. The hyperphagia induced by ovariectomy was reflected in an increase in meal size and a decrease in meal frequency. When food intake returned to preoperative levels, meal size remained elevated while frequency decreased further. Estradiol benzoate (2 μg/day) permanently decreased meal size in long-term ovariectomized rats. The subsequent return to food intake levels of controls was due primarily to an increase in meal frequency. These results suggest that the transient changes in food intake caused by estradiol withdrawal and replacement are accomplished by permanent changes in meal size followed by compensatory changes in the number of meals consumed per day. They suggest that the decrease in meal size at proestrus is due to a direct effect of estradiol on the mechanisms that terminate short-term food intake and are not secondary to changes in the level of total daily food intake.

Cytoplasmic progestin-receptors in guinea pig brain: characteristics and relationship to the induction of sexual behavior.

The synthetic progestin, R 5020, was used to measure cytoplasmic progestin receptors in the brain and pituitary gland of ovariectomized guinea pigs. Progestin receptors with a dissociation constant of 0.1--0.3 nM were measured by gel filtration in all brain regions studied, pituitary gland and the uterus. The receptor is progestin-specific; biologically potent progestins compete well against [3H]R 5020 for binding, but androgens, glucocorticoids and estrogens do not. The concentration of the cytoplasmic progestin receptor in hypothalamus-preoptic area-septum and midbrain is decreased in vivo by behaviorally effective doses of progesterone. In the pituitary gland, hypothalamus, preoptic area-septum and midbrain, but not other brain regions, the concentration of progestin receptors increases after estradiol benzoate-priming. The increase in the concentration of cytoplasmic progestin receptors in hypothalamus-preoptic area-septum is dependent on the dose of estradiol benzoate injected. After a single injection of a dose of estradiol benzoate routinely used to facilitate the display of sexual receptivity (1.6 microgram estradiol benzoate/animal), the latency to an increase and subsequent decrease in cytoplasmic progestin receptors in the hypothalamus-preoptic area-septum correlates well with the previously reported time course for progesterones facilitation of sexual receptivity after estradiol benzoate injection. The experiments are consistent with the notion that brain progestin receptors mediate at least some of the behavioral effects of progesterone.

Coexpression of ERβ with ERα and Progestin Receptor Proteins in the Female Rat Forebrain: Effects of Estradiol Treatment

Estrogen and progestin receptors (ER, PgR) play a critical role in the regulation of neuroendocrine functions in females. The neuroanatomical distribution of the recently cloned, ERβ, overlaps with both ERα and PgR. To determine whether ERβ is found within ERα- or PgR-containing neurons in female rat, we used dual label immunocytochemistry. ERβ-immunoreactivity (ERβ-ir) was primarily detected in the nuclei of cells in the periventricular preoptic area (PvPO), the bed nucleus of the stria terminalis (BNSTpr), the paraventricular nucleus, the supraoptic nucleus, and the medial amygdala (MEApd). Coexpression of ERβ-ir with ERα-ir or PgR-ir was observed in the PvPO, BNSTpr, and MEApd in ovariectomized rats. E2 treatment decreased the number of ERβ-ir cells in the PvPO and BNSTpr and the number of ERα-ir cells in the MEApd and paraventricular nucleus, and therefore decreased the number of cells coexpressing ERβ-ir and ERα-ir in the PvPO, BNSTpr, and MEApd. E2 treatment increased the amount of PgR-ir in cells o...

Estradiol-induced progestin receptor immunoreactivity is found only in estrogen receptor-immunoreactive cells in guinea pig brain.

A fluorescent immunocytochemical technique was developed to determine if cells in the guinea pig hypothalamus and preoptic area that contain estradiol-induced progestin receptors also contain estrogen receptors. With this technique little or no progestin receptor-immunoreactivity (PR-IR) was observed in the absence of estrogen treatment in ovariectomized guinea pigs. As has been reported previously, priming with estradiol caused a large increase in the concentration of PR-IR cells in discrete regions of the hypothalamus and preoptic area, primarily in the arcuate nucleus, ventrolateral area of the hypothalamus, periventricular preoptic area, medial preoptic nucleus, medial preoptic area, anterior hypothalamic nucleus and anterior hypothalamus. A range of lightly to intensely labeled estrogen receptor-immunoreactive (ER-IR) cells were observed in high concentration in each of these areas, as well as in some areas in which no PR-IR cells have been identified, such as the amygdala. PR-IR was only observed in cells that also had ER-IR. In some areas such as the ventrolateral hypothalamic area and arcuate nucleus, nearly all medium to highly-fluorescent ER-IR cells also contained estradiol-induced PR-IR, while in the amygdala no PR-IR was observed despite a high concentration of ER-IR cells. These results confirm the hypothesis that progestin receptors are produced in estrogen receptor-containing cells in the brain, and they suggest that these cells are the sites where estradiol and progesterone act to influence behavior and physiology.

Fos Expression in the Rat Brain Following Vaginal‐Cervical Stimulation by Mating and Manual Probing

Vaginal‐cervical stimulation (VCS), provided by mating or manual probing, induces many reproductive behavioral and endocrine changes in female rats. These changes include an increase in lordosis duration, heat termination and pseudopregnancy. Electro‐physiological and [14C]2‐deoxy‐D‐glucose studies collectively show that neurons in the medial preoptic area, ventromedial hypothalamus and midbrain central gray respond to manual VCS. In the present study we immunocytochemically labeled brain sections for Fos, the protein product of the immediate early gene c‐fos, to detect VCS‐responsive neurons in hormone‐primed animals receiving VCS by mating or manual probing. In Experiment 1, females receiving mounts and intromissions were compared to: 1) vaginally‐masked females receiving mounts but no VCS, 2) females exposed to an intact anesthetized male or 3) females not exposed to males or the testing arena. Those animals receiving VCS showed a dramatic increase in the number of Fos‐immunoreactive cells in the medial preoptic area, posterodorsal portion of the medial amygdala and bed nucleus of the stria terminalis, as well as the dorsomedial hypothalamus, ventromedial hypothalamus and midbrain central gray. These effects of VCS were confirmed in Experiment 2 in animals receiving manual vaginal‐cervical probing. These findings extend previous electrophysiological and [14C]2‐deoxy‐D‐glucose studies by providing evidence that additional brain areas respond to VCS by mating, as well as manual probing.

Immunocytochemical localization of estrogen-induced progestin receptors in guinea pig brain

By using a combination of monoclonal antibodies to progestin receptors and a double-bridge peroxidase-antiperoxidase technique, a sensitive immunocytochemical method was developed for visualizing progestin receptor immunoreactivity (PR-IR) in brains of estrogen-primed guinea pigs. PR-IR neurons were observed throughout the hypothalamus and preoptic area. They were seen in largest numbers in the arcuate nucleus, periventricular preoptic regions, medial preoptic nucleus, medial preoptic area and in the ventrolateral area of the hypothalamus. Lower numbers of PR-IR positive cells were detected in the bed nucleus of stria terminalis, paraventricular nucleus and lateral hypothalamus with scattered cells seen throughout the hypothalamus and preoptic area. The PR-IR was mostly intranuclear with lighter staining in neuronal processes. Electron microscopy confirmed the predominantly intranuclear localization and further demonstrated that the reaction product was dispersed throughout the nucleus, but not associated with the nucleolus. Few PR-IR cells were observed in the absence of estradiol priming, and the reaction product was much lighter than in the presence of estradiol. Progesterone injection was without apparent effect on intensity of the PR-IR.

Progesterone Receptor Function from a Behavioral Perspective

Hormonal induction of sexual receptivity in ovariectomized female mice can be effectively reinstated by sequential administration of estradiol and progesterone. In this regard, mice appear to be similar to other rodents. While it is generally accepted that hypothalamic progesterone receptors function as estradiol-induced transcription factors in the induction of sexual receptivity in rats, hamsters, and guinea pigs, relatively little is known about their role in the mouse, a species which exhibits genotypic and strain differences in the responsiveness to steroid hormones. Using a transgenic mouse carrying a null mutation for the progesterone receptor by gene targeting, we examined the role of the progesterone receptor as a coordinator of key regulatory events in the induction of sexual receptivity. A concordance between hypothalamic progesterone receptor levels and behavioral responsiveness was established by comparing the homozygous mutant, heterozygous mutant, and wild-type littermates. The behavioral and biochemical findings reveal the importance of estradiol-induced progesterone receptors for the expression of sexual behavior in female mice. The behavioral response of the two parental mouse strains from which the recombinant genotype was generated was also examined. As an extension of our earlier studies on the ligand-independent activation of progesterone receptors by neurotransmitters, the behavioral effect of dopamine in the facilitation of sexual receptivity in mice was also examined. The studies provide further evidence that steroid hormone receptors function as general transcription factors to achieve the integration of neural information in the central nervous system, and they assign a more important role for progesterone receptors than hitherto envisioned.

Estrogen-receptor immunoreactivity in hamster brain: preoptic area, hypothalamus and amygdala

The distribution of estrogen-receptor containing cells in the preoptic area, hypothalamus and amygdala of female Syrian hamster brain was studied by immunocytochemical methods. Dense populations of estrogen-receptor immunoreactive (ER-IR) cells were found in the medial preoptic area, the bed nucleus of the stria terminalis, amygdala, ventral and lateral parts of the hypothalamus, and the arcuate nucleus. Injection of estradiol caused a decrease in estrogen-receptor immunoreactivity (ERIR) containing cells within one hour, a decrease that may reflect a change in the ability of the occupied estrogen receptor to bind the particular antibody (H222) used rather than down-regulation of the estrogen receptor. Our findings on the distribution of estrogen-receptor containing cells in these areas using an immunocytochemical technique are consistent with and extend the findings of others using autoradiographic and in vitro binding techniques to study estrogen receptor distribution in hamster brain.

Estrogen receptor-immunostaining of neuronal cytoplasmic processes as well as cell nuclei in guinea pig brain

We have recently developed an immunocytochemical technique for staining estrogen receptors in cell nuclei of some cells in the guinea pig brain. With optimization of this technique, we have now been successful in staining estrogen receptor-immunoreactivity in processes of many neurons in the guinea pig brain that also contain estrogen receptor-immunoreactive cell nuclei. While reaction product is visible in cell nuclei under a wide variety of conditions, neuronal processes are darkly immunostained only with modifications of the procedure optimized for maximum sensitivity, for example, the multiple-bridge immunocytochemical procedure. Omission of Triton X-100 and/or dimethylsulfoxide, usually used to increase penetration of the antibodies, had no effect on immunostaining in processes or cell nuclei, and immunostaining was apparent in both vibratome-cut and freezing microtome-cut sections. Injection of estradiol, but not progesterone, caused the total loss of cytoplasmic estrogen receptor-immunostaining, consistent with the idea that the cytoplasmic immunostaining, like the cell nuclear immunostaining is due to the presence of estrogen receptors. In all neuroanatomical regions containing estrogen receptor-immunoreactive cell nuclei, associated processes of some, but not all cells were also immunostained. However, in certain areas, such as the midbrain central gray and the preoptic area, cytoplasmic staining was particularly dark. The cellular characteristics that result in immunostaining in some estrogen receptor-immunoreactive cells, and not in others is under investigation.