Influence of sexual differentiation on striatal and limbic catecholamines

The influence of sexual differentiation of the brain on catecholamine content in the corpus striatum and limbic system was studied. Our results suggest that circulating ovary hormones during the critical period play an important role in the sexual differentiation of dopaminergic neurons in the corpus striatum and limbic system. Absence of androgenic steroids in the critical period leads to permanent alterations in the DA content of the limbic system in the male rat. Gonadectomy does not significantly alter NA levels in either of the two studied brain areas.     

Changes in the levels of protein and steroid hormones in the plasma and steroid hormone receptors in the uterus of normal cycling guinea pigs

This study deals with the estrous cycle of guinea pigs in relation to sexual behavior, uterine weight, levels of gonadotropins, steroid hormones, and steroid hormone receptors in the uterus. The guinea pigs in this study showed cyclic changes in various reproductive functions broadly similar to other laboratory species studied. The increase in the uterine weight coincided with high concentration of steroid hormones (estradiol and progesterone) secreted during proestrus and estrus. The elevated levels of steroid hormone receptor concentrations in the uterus during these periods also confirm the role of these hormones. The rise in progesterone level from day 14 of the cycle was associated with lordosis and its related behavior. It was noted that the "estrus behavior" is the most accurate external marker for ovulation and sexual receptivity to males. It was also observed that there is an association between follicle-stimulating hormone and luteinizing hormone during the preovulatory period that was not demonstrated in previous studies.     

Neuroanatomical distribution of aromatase mRNA in the rat brain: indications of regional regulation

Aromatase, the enzyme responsible for the conversion of testosterone to estradiol, is found in the rat brain and is present in regions of the preoptic area, hypothalamus, and limbic system. Gonadal steroid hormones regulate aromatase activity levels in many brain regions, but not all. Using in situ hybridization, we examined the distribution of aromatase mRNA in the adult male forebrain, as well as the levels of aromatase mRNA in the brains of males and females, and the regulation by gonadal steroid hormones. In the adult male, many heavily labelled cells were found in the encapsulated bed nucleus of the stria terminalis (BNST), the medial preoptic nucleus (MPN), the ventro-medial nucleus (VMN), the medial amygdala (mAMY) and the cortical amygdala (CoAMY). The regional distribution of aromatase mRNA was similar in males and females, but males tended to have a greater number of aromatase mRNA-expressing cells in each region compared to females. Aromatase mRNA levels in the BNST, MPN, VMN and mAMY tended to be lower in castrated males than in intact males, whereas aromatase mRNA levels were unaltered by castration in the CoAMY. Further analysis of individual cells expressing aromatase mRNA suggests that aromatase mRNA may be regulated by steroid hormones differentially in specific populations of cells in regions where enzyme activity levels are steroid-hormone-dependent.     

Sex hormone-binding globulin: Anatomy and physiology of a new regulatory system

Sex hormone-binding globulin (SHBG) is a plasma glycoprotein that binds a number of circulating steroid hormones (testosterone, dihydrotestosterone and estradiol) with high affinity, thus regulating their free concentration in plasma. In addition to binding steroids, SHBG itself binds to receptor sites on plasma membranes with somewhat unusual kinetics. Both the off and on rates are quite slow. The steroid-binding and membrane-binding functions are interwined in what is clearly an allosteric relationship. Occupation of SHBG's steroid-binding site by a steroid inhibits its ability to bind to its membrane receptor-binding site. This inhibition is not related to a steroid's biological activity. Metabolites of steroids without biological activity, e.g. 2-methoxyestradiol, actively inhibit SHBG's interaction with its membrane receptor. However, if unliganded SHBG is allowed to bind to its receptor on intact cells, and an appropriate steroid hormone then is introduced, adenylate cyclase is activated and intracellular cAMP increases. This function is specific for steroids with biological activity, 2-methoxyestradiol has no activity in this arena. These observations demonstrate a potentially important role for SHBG as a regulator of cell function. They also demonstrate an additional mode of action of steroid hormones, one that does not require that the steroid interact with a steroid receptor.     

Glia as mediators of steroid hormone action on the nervous system: An overview.

This special issue on steroids and glia represents the intersection of two emerging themes in the neurosciences: (a) Glia actively modulate and participate in brain function throughout life, and (b) glia are sensitive to steroid hormones. This overview begins by reviewing some of the basic principles of steroid hormone action on the brain and introducing the various glia that inhabit the peripheral and central nervous system. A prominent theme among the articles that follow is that glia may be direct targets for steroid hormones since they possess steroid receptors and the promoter region of glial-specific genes such as glutamine synthetase contain hormone-responsive elements. The articles in this special issue discuss evidence that glia may mediate steroid action on the nervous system in the context of (a) steroid metabolism, which may control the hormonal microenvironment of neurons both in the normal and injured brain; (b) brain development including sexual differentiation; (c) synaptic plasticity which may underlie the cyclic release of luteinizing hormone releasing hormone in the female rodent brain; (d) neural repair and aging; and (e) brain immune function. Another theme among these articles is that glia influence neurons via specific secreted and cell-surface molecules, and that steroids affect this mode of communication by altering the level of glial production of these signaling molecules and/or the sensitivity of neurons to such signals.     

Enhanced expression of tubulin-specific chaperone protein A, mitochondrial ribosomal protein S27, and the DNA excision repair protein XPACCH in the song system of juvenile male zebra finches

Recent evidence suggests that sexual dimorphisms in the zebra finch song system and behavior arise due to factors intrinsic to the brain, rather than being solely organized by circulating steroid hormones. The present study examined expression of 10 sex chromosome genes in the song system of 25-day-old zebra finches in an attempt to further elucidate these factors. Increased expression in males was confirmed for nine of the genes by real-time qPCR using cDNA from individual whole telecephalons. In situ hybridization at the same age revealed specific, male-enhanced mRNA for three of the nine genes in one or more song control nuclei. These genes encode tubulin-specific chaperone A, mitochondrial ribosomal protein S27, and a DNA repair protein XPACCH. Based on what is currently known about these proteins' functions and their localization to particular components of the song circuit, we hypothesize that they each may be involved in specific aspects of masculinization.     

Rapid steroid influences on visually guided sexual behavior in male goldfish

The ability of steroid hormones to rapidly influence cell physiology through nongenomic mechanisms raises the possibility that these molecules may play a role in the dynamic regulation of social behavior, particularly in species in which social stimuli can rapidly influence circulating steroid levels. We therefore tested if testosterone (T), which increases in male goldfish in response to sexual stimuli, can rapidly influence approach responses towards females. Injections of T stimulated approach responses towards the visual cues of females 30–45 min after the injection but did not stimulate approach responses towards stimulus males or affect general activity, indicating that the effect is stimulus-specific and not a secondary consequence of increased arousal. Estradiol produced the same effect 30–45 min and even 10–25 min after administration, and treatment with the aromatase inhibitor fadrozole blocked exogenous T's behavioral effect, indicating that T's rapid stimulation of visual approach responses depends on aromatization. We suggest that T surges induced by sexual stimuli, including preovulatory pheromones, rapidly prime males to mate by increasing sensitivity within visual pathways that guide approach responses towards females and/or by increasing the motivation to approach potential mates through actions within traditional limbic circuits.     

Ovarian steroids and serotonin neural function

The serotonin neural system originates from ten nuclei in the mid- and hindbrain regions. The cells of the rostral nuclei project to almost every area of the forebrain, including the hypothalamus, limbic regions, basal ganglia, thalamic nuclei, and cortex. The caudal nuclei project to the spinal cord and interact with numerous autonomic and sensory systems. This article reviews much of the available literature from basic research and relevant clinical research that indicates that ovarian steroid hormones, estrogens and progestins, affect the function of the serotonin neural system. Experimental results in nonhuman primates from this laboratory are contrasted with studies in rodents and humans. The sites of action of ovarian hormones on the serotonin neural system include effects within serotonin neurons as well as effects on serotonin afferent neurons and serotonin target neurons. Therefore, information on estrogen and progestin receptor-containing neurons was synthesized with information on serotonin afferent and efferent circuits. The ability of estrogens and progestins to alter the function of the serotonin neural system at various levels provides a cellular mechanism whereby ovarian hormones can impact mood, cognition, pain, and numerous other autonomic functions.     

How sex and age affect immune responses,susceptibility to infections,and response to vaccination

Do men die young and sick, or do women live long and healthy? By trying to explain the sexual dimorphism in life expectancy, both biological and environmental aspects are presently being addressed. Besides age-related changes, both the immune and the endocrine system exhibit significant sex-specific differences. This review deals with the aging immune system and its interplay with sex steroid hormones. Together, they impact on the etiopathology of many infectious diseases, which are still the major causes of morbidity and mortality in people at old age. Among men, susceptibilities toward many infectious diseases and the corresponding mortality rates are higher. Responses to various types of vaccination are often higher among women thereby also mounting stronger humoral responses. Women appear immune-privileged. The major sex steroid hormones exhibit opposing effects on cells of both the adaptive and the innate immune system: estradiol being mainly enhancing, testosterone by and large suppressive. However, levels of sex hormones change with age. At menopause transition, dropping estradiol potentially enhances immunosenescence effects posing postmenopausal women at additional, yet specific risks. Conclusively during aging, interventions, which distinctively consider the changing level of individual hormones, shall provide potent options in maintaining optimal immune functions.     

Sexual dimorphism of blood pressure: Possible role of the renin-angiotensin system

The prevalence of hypertension in men is higher than in women and the onset of this disease is earlier in male than in female subjects. In spontaneously hypertensive rats, males also have higher blood pressures than females. Evidence from epidemiological, physiological, molecular biological and morphological studies concerning this sexual dimorphism is reviewed. We demonstrate that the gonadal steroids testosterone and estrogen have important effects on the gene regulation of the renin-angiotensin system. This may in part contribute to the sexual dimorphism in blood pressure control. The direct effect of steroid hormones on genes related to hypertension provides a suitable paradigm to improve our understanding of molecular and cellular mechanisms of cardiovascular control.     

Old experiments and new trends in avian sex differentiation

Summary The influence of steroid hormones on sex differentiation was first demonstrated in birds in 1935. Steroid female hormones injected in vivo into male embryos determined a partial or total feminization of gonads and genital ducts. Male hormones determined only the sex reversal of the ducts. Some substances of the group of androgens, such as dehydroandrosterone, had a paradoxical effect; they feminized males and masculinized females. Similar effects were observed later by several authors in all groups of vertebrates. In placentary mammals, only genital ducts were transformed. Castration of avian embryos also demonstrated the role of embryonic sexual hormones on genital ducts. These results, first obtained in vivo, were confirmed by experiments in vitro. Since then numerous studies have been undertaken on the nature of the hormone responsible for the regression of müllerian ducts in embryos of birds and other groups of vertebrates. Some authors assumed that these substances are proteins; many offered new evidence for the role of steroid sexual hormones during sex differentiation. Thus the problem appeared more complicated than it was thought at first. In recent years, synthesis of steroid sexual hormones have been demonstrated in young embryos during or even before sex differentiation; and enzymes that catalyze the synthesis of these hormones, such as hydroxysteroiddehydrogenase, also have been discovered. Further research has been oriented toward the characterization of steroid hormones by techniques of immunochemistry and labeled isotopes confirming the results obtained by other techniques. Specific proteins are being isolated in the effectors; they work as receptors of steroid hormones. Nuclear receptors of estradiol have been discovered in the embryonic gonads and in the cloacal wall at the time of sexual differentiation. Thus a mechanism can be conceived in which proteins and steroid hormones play mutual roles in the process of sex differentiation. Presented in the formal symposium on Sexual Differentiation in Vitro and in Vivo at the 29th Annual Meeting of the Tissue Culture Association, Denver, Colorado, June 4–8, 1978.     

Rapid steroid influences on visually guided sexual behavior in male goldfish

The ability of steroid hormones to rapidly influence cell physiology through nongenomic mechanisms raises the possibility that these molecules may play a role in the dynamic regulation of social behavior, particularly in species in which social stimuli can rapidly influence circulating steroid levels. We therefore tested if testosterone (T), which increases in male goldfish in response to sexual stimuli, can rapidly influence approach responses towards females. Injections of T stimulated approach responses towards the visual cues of females 30–45 min after the injection but did not stimulate approach responses towards stimulus males or affect general activity, indicating that the effect is stimulus-specific and not a secondary consequence of increased arousal. Estradiol produced the same effect 30–45 min and even 10–25 min after administration, and treatment with the aromatase inhibitor fadrozole blocked exogenous T's behavioral effect, indicating that T's rapid stimulation of visual approach responses depends on aromatization. We suggest that T surges induced by sexual stimuli, including preovulatory pheromones, rapidly prime males to mate by increasing sensitivity within visual pathways that guide approach responses towards females and/or by increasing the motivation to approach potential mates through actions within traditional limbic circuits.     

Sexual experience and testosterone during adolescence alter adult neuronal morphology and behavior

Steroid hormones released immediately before and after birth provoke sexual differentiation of neural circuits. Further, steroid hormones secreted during adolescence also exert long lasting effects on the nervous system. Hormones secreted during development may act through two distinct pathways: (1) hormones can directly affect neuron and synapse elimination and (2) endocrine changes in the nervous system may occur secondary to changes in social behaviors. Therefore, a critical period for organization of the nervous system by steroid hormones during adolescence may also be a sensitive period for the effects of social experience. The overall goal of this experiment was to determine whether the opportunity to mate with a sexually receptive female during this adolescent critical period would have enduring effects on behavior and neuronal morphology into adulthood. A second question was to determine the extent to which testosterone mediated the effects of these social interactions on adult outcomes. Compared to sexually inexperienced hamsters and those that experienced sex for the first time in adulthood, hamsters that experienced adolescent sexual experience displayed increased anxiety- and depressive-like behavioral responses. Adolescent sexual experiences decreased the complexity and length of dendrites on prefrontal cortical neurons and increased the expression of the pro-inflammatory cytokine interleukin 1β (IL-1β) in the PFC. In a second experiment, administration of testosterone during the adolescent period largely recapitulated the effects of adolescent sexual experience. These data support the overall hypothesis that a sensitive period extends into adolescence and that salient social stimuli during this time can significantly and persistently alter adult phenotype.     

Neuro-steroids: 3β-hydroxy-Δ5-derivatives in the rodent brain

Pregnenolone, dehydroepiandrosterone and their sulfate esters have been characterized in the rat brain. Their formation or accumulation depend on in situ mechanisms unrelated to the peripheral endocrine glands. Although their functions are still poorly understood, they may affect the brain by metabolism to sex steroid hormones and they may be functionally related to sexual behavior, possibly through direct modulations of the firing rates of neurons.     

Control of masculinization of the brain and behavior

Sex steroid hormones exert a profound influence on the sexual differentiation and function of the neural circuits that mediate dimorphic behaviors. Both estrogen and testosterone are essential for male typical behaviors in many species. Recent studies with genetically modified mice provide important new insights into the logic whereby these two hormones coordinate the display of sexually dimorphic behaviors: estrogen sets up the masculine repertoire of sexual and territorial behaviors and testosterone controls the extent of these male displays.     

Seasonal covariation in progesterone and odorant emissions among breeding crested auklets (Aethia cristatella)

Crested auklets emit a citrus-like odorant that is seasonally modulated, suggesting that it is a secondary sexual trait. We hypothesized that expression of the chemical odorant is facilitated by steroid hormones, similar other secondary sexual traits in birds. Therefore we examined variation in concentrations of hormones in blood plasma and odor production during incubation and early chick rearing. A novel method was used to obtain and measure chemical emissions of crested auklets. Blood plasma samples were analyzed by radioimmunoassay. Progesterone was detected in all birds, and it varied during the breeding season. Octanal emissions covaried with progesterone levels in males but not in females. No seasonal patterns were detected in testosterone, estrogen or DHT, and these hormones were not detected in all breeding adults. Covariance of progesterone and octanal emissions in males suggests there could be at least an indirect relationship between odor emissions and steroid hormones in this species. Thus expression of the citrus-like odorant of crested auklets, like other secondary sexual traits in birds, could be regulated by steroid hormones.     

Aging-related changes in ovarian hormones, their receptors, and neuroendocrine function

Ovarian steroid hormones exert a broad range of effects on the body and brain. In the nervous system, estrogen and progesterone have crucial feedback actions on the hypothalamic neurons that drive the reproductive axis. In addition, hormones exert a variety of actions on other traditionally nonreproductive functions such as cognition, learning and memory, neuroprotection, mood and affective behavior, and locomotor activity. The actions of hormones on the hypothalamus are largely mediated by their nuclear hormone receptors, the two estrogen receptors, ERalpha and ERbeta, and the two progesterone receptor isoforms, PR-A and PR-B. Thus, changes in the circulating concentrations of estrogens and progestins during the life cycle can result in differential activation of their receptors. Furthermore, changes in the numbers, activity, and distribution of hypothalamic ERs and PRs can occur as a function of developmental age. The purpose of this article is to review the literature on the causes and consequences of alterations in steroid hormones, their neural receptors, and their interactions on reproductive senescence. We have also discussed several important experimental design considerations, focusing on rodent models in current use for understanding the mechanisms of menopause in women.     

Progestin receptors and the activation of female reproductive behavior: A critical review

Gonadal steroid hormones act upon the central nervous system (CNS) to regulate a variety of behavioral and neuroendocrine functions. Much attention has been focused on the mechanisms by which steroids interact with the brain to coordinate mammalian reproduction, particularly their role in the activation of mating behavior and in the feedback control of gonadotropin release. For example, female rodent reproductive behavior is abolished within a day or two following gonadectomy (Powers, 1970) and can be restored in a dose-dependent manner by exogenously administered estradiol and progesterone ( Boling and Blandau, 1939; Beach, 1942; Whalen, 1974). The molecular mechanisms underlying steroid induction of female rodent sexual behavior have been extensively investigated (for recent reviews see Feder, Landau, and Walker, 1979; McEwen, Davis, Parsons, and Pfaff, 1979; McEwen, 1981; Feder, 1984). To date, however, there is little conclusive evidence regarding the details of the molecular mechanisms by which estradiol and progesterone facilitate estrous behavior.