Shailaja K. Mani

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.

Distribution and Estrogen Regulation of Membrane Progesterone Receptor-β in the Female Rat Brain

Although several studies have reported the localization of membrane progesterone (P(4)) receptors (mPR) in various tissues, few have attempted to describe the distribution and regulation of these receptors in the brain. In the present study, we investigated expression of two mPR subtypes, mPRα and mPRβ, within regions of the brain, known to express estradiol (E(2))-dependent [preoptic area (POA) and hypothalamus] and independent (cortex) classical progestin receptors. Saturation binding and Scatchard analyses on plasma membranes prepared from rat cortex, hypothalamus, and POA demonstrated high-affinity, specific P(4)-binding sites characteristic of mPR. Using quantitative RT-PCR, we found that mPRβ mRNA was expressed at higher levels than mPRα, indicating that mPRβ may be the primary mPR subtype in the rat brain. We also mapped the distribution of mPRβ protein using immunohistochemistry. The mPRβ-immunoreactive neurons were highly expressed in select nuclei of the hypothalamus (paraventricular nucleus, ventromedial hypothalamus, and arcuate nucleus), forebrain (medial septum and horizontal diagonal band), and midbrain (oculomotor and red nuclei) and throughout many areas of the cortex and thalamus. Treatment of ovariectomized female rats with E(2) benzoate increased mPRβ immunoreactivity within the medial septum but not the medial POA, horizontal diagonal band, or oculomotor nucleus. Together, these findings demonstrate a wide distribution of mPRβ in the rodent brain that may contribute to functions affecting behavioral, endocrine, motor, and sensory systems. Furthermore, E(2) regulation of mPRβ indicates a mechanism through which estrogens can regulate P(4) function within discrete brain regions to potentially impact behavior.

Impaired Male Sexual Behavior in Activin Receptor Type II Knockout Mice

Abstract Integration of multiple hormonal and neuronal signaling pathways in the medial preoptic area (mPOA) is required for elicitation of male sexual behavior in most vertebrates. Perturbation of nitric oxide synthase (NOS) activity in the mPOA causes significant defects in male sexual behavior. Although activins and their signaling components are highly expressed throughout the brain, including the mPOA, their functional significance in the central nervous system (CNS) is unknown. Here, we demonstrate a neurophysiologic role for activin signaling in male reproductive behavior. Adult activin receptor type II null (Acvr2−/−) male mice display multiple reproductive behavioral deficits, including delayed initiation of copulation, reduced mount, and intromission frequencies, and increased mount, intromission, and ejaculation latencies. These behavioral defects in the adult mice are independent of gonadotropin-releasing hormone (GnRH) homeostasis or mating-induced changes in luteinizing hormone (LH) and testosterone levels. The impairment in behavior can be correlated to the nitric oxide content in the CNS because Acvr2−/− males have decreased NOS activity in the mPOA but not the rest of the hypothalamus or cortex. Olfactory acuity tests confirmed that Acvr2−/− mice have no defects in general odor or pheromone recognition. In addition, motor functions are not impaired and the mutants demonstrate normal neuromuscular coordination and balance. Furthermore, the penile histology in mutant mice appears normal, with no significant differences in the expression of penile differentiation marker genes compared with controls, suggesting the observed behavioral phenotypes are not due to structural defects in the penis. Our studies identify a previously unrecognized role of activin signaling in male sexual behavior and suggest that activins and/or related family members are upstream regulators of NOS activity within the mPOA of the forebrain.

Research Resource: Loss of the Steroid Receptor Coactivators Confers Neurobehavioral Consequences

Steroid receptor coactivators (SRCs) are important transcriptional modulators that regulate nuclear receptor and transcription factor activity to adjust transcriptional output to cellular demands. Highlighting their pleiotropic effects, dysfunction of the SRCs has been found in numerous pathologies including cancer, inflammation, and metabolic disorders. The SRC family is expressed strongly in the brain including the hippocampus, cortex, and hypothalamus. Studies focusing on the effect of SRC loss using congenic SRC knockout mice (SRC(-/-)) are limited in number, yet strongly indicate that the SRCs play important roles in regulating reproductive behavior, development, and motor coordination. To better understand the unique functions of the SRCs, we performed a neurobehavioral test battery focusing on anxiety and exploratory behaviors, motor coordination, sensorimotor gating, and nociception in both male and female null mice and compared them with their wild-type (WT) littermates. Results from the test battery reveal a role for SRC1 in motor coordination. Additionally, we found that SRC1 regulates anxiety responses in SRC1(-/-) male and female mice, and nociception sensitivity in SRC1(-/-) male but not female mice. By comparison, SRC2 regulates anxiety response with SRC2(-/-) females showing decreased anxiety in novel environments, as well as increased exploratory behavior in the open field compared with WT littermates. Additionally, SRC2(-/-) males were shown to have deficits in sensorimotor gating. Loss of SRC3 also shows sex differences in anxiety and exploratory behaviors. In particular, SRC3(-/-) female mice have increased anxiety and reduced exploratory activity and impairments in prepulse inhibition, whereas SRC3(-/-) male mice show no significant behavioral differences. In both genders, ablation of SRC3 decreases nocifensive behaviors. Collectively, these resource data suggest that loss of the SRCs results in behavioral phenotypes, underscoring the importance of understanding both the general and gender-based activity of SRCs in the brain.

In Vitro Models of Implantation

Blastocysts are capable of attaching to a uterus only after it has been appropriately prepared by ovarian steroid hormones (receptive uterus). 1,2 They can, however, attach to extrauterine sites regardless of the hormonal environment.3 These data suggest that under certain conditions the apical surface of the uterine epithelial (UE) cell expresses molecules (ligands) which do not permit blastocyst attachment (non-receptive). It has been proposed that interactions between UE cells and various regulatory agents (hormones, growth factors) effect (induce, stimulate, repress) structural and functional changes at the apical surface of the UE cell that allow nidation.

Knockout of the Histone Demethylase Kdm3b Decreases Spermatogenesis and Impairs Male Sexual Behaviors

Kdm3b is a JmjC domain-containing histone H3 (H3) demethylase and its physiological functions are largely unknown. In this study, we found that Kdm3b protein is highly expressed in multiple cell types in the mouse testes, including Leydig cells, Sertoli cells, spermatogonia and spermatocytes at different differentiation stages. We also observed Kdm3b protein in the epithelial cells of the caput epididymis, prostate and seminal vesicle. Breeding tests revealed that the number of pups produced by the breeding pairs with Kdm3b knockout (Kdm3bKO) males and wild type (WT) females was reduced 68% because of the decreased number of litters when compared with the breeding pairs with WT males and females. Further analysis demonstrated that Kdm3bKO male mice produced 44% fewer number of mature sperm in their cauda epididymides, displaying significantly reduced sperm motility. No significant differences in the circulating concentration of testosterone and the expression levels of androgen receptor and its representative target genes in the testis were observed. However, the circulating levels of 17β-estradiol, a modulator of sperm maturation and male sexual behaviors, was markedly reduced in Kdm3bKO male mice. Strikingly, abrogation of Kdm3b in male mice significantly increased the latencies to mount, intromit and ejaculate and decreased the number of mounts and intromissions, largely due to their loss of interest in female odors. These findings indicate that Kdm3b is required for normal spermatogenesis and sexual behaviors in male mice.

Steroid Hormone Signaling Pathways and Sex Differences in Neuroendocrine and Behavioral Responses to Stress

The hypothalamo–pituitary–adrenal (HPA) axis responds to stress by redirecting the physiology and behavior of an organism toward survival and maintenance of homeostasis using a coordinated and well-orchestrated activation of the neuroendocrine and autonomic nervous systems. A plethora of studies have demonstrated the existence of sex differences in the components of the HPA axis and its response to stress, with the females reacting more rapidly and robustly compared with males. Gonadal steroid hormones mediate these sex differences, not only by organizing the HPA axis during development, but also by modulating HPA function in adulthood, with estrogens enhancing and androgens inhibiting HPA axis activity. Part of this involves interactions with circulating glucocorticoids, which exert negative feedback actions on HPA function. Cellular and molecular evidence indicates that androgens, estrogens, and glucocorticoids can interact to affect stress responses through intracellular, membrane-associated, or extranuclear receptors in the central nervous system.