Brain aromatization and its associated structures

Androgen Affects the Dynamics of Intrinsic Plasticity of Pyramidal Neurons in the CA1 Hippocampal Subfield in Adolescent Male Rats

Androgen receptor (AR) is abundantly expressed in the preoptico-hypothalamic area, bed nucleus of stria terminalis, and medial amygdala of the brain where androgen plays an important role in regulating male sociosexual, emotional and aggressive behaviors. In addition to these brain regions, AR is also highly expressed in the hippocampus, suggesting that the hippocampus is another major target of androgenic modulation. It is known that androgen can modulate synaptic plasticity in the CA1 hippocampal subfield. However, to date, the effects of androgen on the intrinsic plasticity of hippocampal neurons have not been clearly elucidated. In this study, the effects of androgen on the expression of AR in the hippocampus and on the dynamics of intrinsic plasticity of CA1 pyramidal neurons were examined using immunohistochemistry, Western blotting and whole-cell current-clamp recording in unoperated, sham-operated, orchiectomized (OCX), OCX + testosterone (T) or OCX + dihydrotestosterone (DHT)-primed adolescent male rats. Orchiectomy significantly decreased AR-immunoreactivity, resting membrane potential, action potential numbers, afterhyperpolarization amplitude and membrane resistance, whereas it significantly increased action potential threshold and membrane capacitance. These effects were successfully reversed by treatment with either aromatizable androgen T or non-aromatizable androgen DHT. Furthermore, administration of the AR-antagonist flutamide in intact rats showed similar changes to those in OCX rats, suggesting that androgens affect the excitability of CA1 pyramidal neurons possibly by acting on the AR. Our current study potentially clarifies the role of androgen in enhancing the basal excitability of the CA1 pyramidal neurons, which may influence selective neuronal excitation/activation to modulate certain hippocampal functions.

Towards a neurobiology of female aggression

Although many people think of aggression as a negative or undesirable emotion, it is a normal part of many species' repertoire of social behaviors. Purposeful and controlled aggression can be adaptive in that it warns other individuals of perceived breaches in social contracts with the goal of dispersing conflict before it escalates into violence. Aggression becomes maladaptive, however, when it escalates inappropriately or impulsively into violence. Despite ample data demonstrating that impulsive aggression and violence occurs in both men and women, aggression has historically been considered a uniquely masculine trait. As a result, the vast majority of studies attempting to model social aggression in animals, particularly those aimed at understanding the neural underpinnings of aggression, have been conducted in male rodents. In this review, we summarize the state of the literature on the neurobiology of social aggression in female rodents, including social context, hormonal regulation and neural sites of aggression regulation. Our goal is to put historical research in the context of new research, emphasizing studies using ecologically valid methods and modern sophisticated techniques. This article is part of the Special Issue entitled 'Current status of the neurobiology of aggression and impulsivity'.

Regulation of aromatase expression in the anterior amygdala of the developing mouse brain depends on ERβ and sex chromosome complement

During development sex differences in aromatase expression in limbic regions of mouse brain depend on sex chromosome factors. Genes on the sex chromosomes may affect the hormonal regulation of aromatase expression and this study was undertaken to explore that possibility. Male E15 anterior amygdala neuronal cultures expressed higher levels of aromatase (mRNA and protein) than female cultures. Furthermore, treatment with oestradiol (E2) or dihydrotestosterone (DHT) increased Cyp19a1 expression and aromatase protein levels only in female neuronal cultures. The effect of E2 on aromatase expression was not imitated by oestrogen receptor (ER) α agonist PPT or the GPER agonist G1, but it was fully reproduced by DPN, a specific ligand of ERβ. By contrast, the effect of DHT on aromatase expression was not blocked by the anti-androgen flutamide, but completely abrogated by the ERβ antagonist PHTPP. Experiments using the four core genotype model showed a sex chromosome effect in ERβ expression (XY > XX) and regulation by E2 or DHT (only XX respond) in amygdala neurons. In conclusion, sex chromosome complement governs the hormonal regulation of aromatase expression through activation of ERβ in developing mouse brain.

Molecular characterization of the injury-induced aromatase transcript in the adult zebra finch brain

In the zebra finch (Taeniopygia guttata), the aromatase gene is transcribed from one of two promoters resulting in two transcripts constitutively expressed in brain or ovary. These transcripts differ only in Exon 1 which lies in the 5' un-translated region (UTR). An inducible form of aromatase is expressed following brain injury in glia. Towards characterizing this transcript, we (a) examined the up-regulation of amplicons within the aromatase transcript using quantitative PCR (qPCR), (b) performed 5' and 3' rapid amplification of cDNA ends (RACE) on injured brain RNA and (c) sequenced the injury-induced aromatase transcript. qPCR suggested that inducible aromatase may contain a novel 3'UTR. However, neither 3' nor 5' RACE revealed novel UTRs in the injured telencephalon. We then sequenced aromatase from injured entopallium, a region that lacks detectable constitutive aromatase. Inducible aromatase was identical in sequence to the known neural aromatase transcript. These data suggest that injury-induced aromatase differs from ovarian, but is indistinguishable from neuronal aromatase. We suggest that an injury-specific signal in glia may modulate aromatase transcription. Alternatively, injury-induced aromatase transcription may be silenced under constitutive conditions. To the best of our knowledge, this is the first report that documents the sequence of inducible aromatase in any vertebrate.

Region-specific expression and sex-steroidal regulation on aromatase and its mRNA in the male rat brain: immunohistochemical and in situ hybridization analyses

The brain has an estrogen-biosynthetic potential resulting from the presence of neuronal aromatase, which controls the intraneural sex-steroidal milieu and is involved in brain sexual differentiation, psychobehavioral regulation, and neuroprotection. In the rat brain, three distinct aromatase-P450-immunoreactive (AromP450-I) neural groups have been categorized in terms of their peak expression time (fetal, fetoneonatal, and young-to-adult groups), suggesting the presence of region-specific regulation on brain AromP450. In the present study, we compared the expressions between AromP450 protein and mRNA by using immunohistochemistry and in situ hybridization with an ovary-derived cRNA probe in serial sections of fetal, fetoneonatal, and adult male rat brains and then performed steroidal manipulations to evaluate the sex-steroidal effects on AromP450 in adult orchiectomized and adrenalectomized (OCX + ADX) male rats. As a result, prominent mRNA signals were detected in the fetal (i.e., the anterior medial preoptic nucleus) and fetoneonatal (i.e., the medial preopticoamygdaloid neuronal arc) groups, although no detectable signal was found in the "young-to-adult" group (i.e., the central amygdaloid nucleus). In addition, the "fetoneonatal" AromP450-I neurons were prominently reduced in number and intensity after OCX + ADX and then were reinstated by the administration of dihydrotestosterone, testosterone, or 17beta-estradiol. In contrast, none of the sex steroids had any significant effects on the young-to-adult group. Several possible explanations were explored for why the young-to-adult group may differ in aromatase expression and regulation, including the possibility that distinct splicing variants or isozymes for aromatase exist in the rat brain.

Immunocytochemical detection of progesterone receptor in the female rabbit forebrain: distribution and regulation by oestradiol and progesterone

There is no information on the neuroanatomical distribution of the progesterone receptor (PR) in the rabbit. Therefore, we mapped the distribution of PR-immunoreactive cells in the forebrain of ovariectomized female rabbits. Vehicle-injected ovariectomized rabbits showed PR-immunoreactive cells only in the infundibular nucleus (IN) and nucleus X (lateral to the ventromedial hypothalamic nucleus). The injection of oestradiol benzoate (EB; 5 micro g/day for 5 days) increased the number of PR-immunoreactive cells in the IN and in three nuclei of the preoptic region (periventricular, medial, and principal). Abundant PR were also found in the paraventricular nucleus and nucleus X. Administration of progesterone (10 mg/day) for 3 days to EB-treated rabbits (a treatment that induces digging behaviour for the maternal nest and suppresses sexual receptivity and scent-marking) eliminated PR-immunoreactivity from all brain areas analysed except the IN. Thus, one-third of the number of cells seen in the ovariectomized + EB condition persisted in this region despite progesterone injections. Withdrawal of progesterone (and continuation of EB) for 5 (but not for 2) days (in a schedule similar to the one that induces straw-carrying and hair-pulling for the maternal nest) increased the number of PR-immunoreactive cells in all regions analysed. These results show that restricted regions of the female rabbit forebrain express abundant PR which are either: (i). up-regulated by oestradiol and down-regulated by progesterone; (ii). oestradiol-insensitive and down-regulated by progesterone; or (iii). insensitive to both oestradiol and progesterone.

Growth factors and steroid hormones: a complex interplay in the hypothalamic control of reproductive functions

The mechanisms through which LHRH-secreting neurons are controlled still represent a crucial and debated field of research in the neuroendocrine control of reproduction. In the present review, we have specifically considered two potential signals reaching these hypothalamic neurons: steroid hormones and growth factors. Examples of the relevant physiological role of the interactions between these two families of biologically acting molecules have been provided. In many cases, these interactions occur at the level of hypothalamic astrocytes, which are presently accepted as functional partners of the LHRH-secreting neurons. On the basis of the observations here summarized, we have formulated the hypothesis that a functional co-operation of steroid hormones and growth factors occurring in the hypothalamic astrocytic compartment represents a key factor in the neuroendocrine control of reproductive functions.

Effects of ageing and dehydroepiandrosterone administration on pro-opiomelanocortin mRNA expression in the anterior and intermediate lobes of the rat pituitary

There is still controversy about the influence of ageing on the activity of the hypothalamo-pituitary-adrenocortical (HPA) axis in the rat. The first objective of the present study was to evaluate the influence of ageing on the activity of the HPA axis by measuring pituitary proopiomelanocortin (POMC, the precursor of ACTH and alphaH) mRNA levels in the anterior and intermediate lobes in young (50-55-day old) and aged (18-month-old) rats of both sexes. The second goal of the study was to evaluate the effect of 2.5 day administration of dehydroepiandrosterone (DHEA), a steroid precursor which has been shown to improve some ageing-associated deficits. In the young male anterior pituitary, DHEA induced a 17.5% increase in POMC mRNA levels. In aged males, anterior pituitary POMC mRNA levels were 22% lower than those detected in young animals. DHEA treatment produced a 26% increase, then completely restoring mRNA levels when compared to those found in young vehicle-treated males. In the young female, DHEA did not induce any changes in anterior pituitary POMC mRNA. In aged females a 24% reduction in the hybridization signal was observed. This reduction was completely reversed by DHEA which induced a 45% increase over the levels observed in vehicle-treated aged animals. In the intermediate lobe, the results were very similar to those obtained in the anterior lobe, although the observed effects induced by ageing and DHEA were less striking. These results together with previous ones indicating an age-related decrease in corticotropin-releasing hormone (CRH) neuronal activity suggest that ageing is associated with a decrease in HPA axis activity. They also demonstrate that a short-term DHEA treatment can exert a beneficial influence by reversing the decrease in pituitary POMC mRNA expression which occurs as a consequence of ageing.

Steroid metabolism in the mammalian brain: 5alpha-reduction and aromatization

Several steroid molecules, including androgens, estrogens, progestagens, and corticostereroids, are able to modulate the brain development and functions. These compounds are not always active in their own natural molecular configuration but they often need to be transformed at the level of their target cells into 'active metabolites'. The two major metabolic pathways that transform steroids in the brain are: the 5alpha-reductase-3alpha-hydroxy-steroid dehydrogenase and the aromatase pathways. Both are present in the brain and probably exert specific roles in the mechanism of action of hormonal steroids. In this article we briefly review some important findings achieved in our own and in other laboratories concerning the cellular and subcellular brain distribution, development, regulation, cloning, and molecular characterization of the involved enzymes. In particular, the recent identification of two isoforms of the 5alpha-reductase, the type 1 and type 2, possessing different structural, biochemical, and distribution characteristics has attracted a considerable attention. The few data available on their brain distribution have been carefully considered. Finally, we have tried to focus on the role of the steroid metabolites in the brain, both when they interact with genomic and with membrane receptors. In particular, some unpublished observations on the effects of two 5alpha-reductase inhibitors on progesterone-induced anesthesia, a phenomenon mediated through the GABA(A) receptor, are presented.

Age-related decrease in the hypothalamic CRH mRNA expression is reduced by dehydroepiandrosterone (DHEA) treatment in male and female rats

Aging is frequently associated with changes in physiological and cognitive processes. Among these changes, it has been shown that aging has a profound impact on the hypothalamo-pituitary-adrenocortical (HPA) axis. Since there is controversy about the influence of aging on the HPA axis, the first objective of the present study was to clarify the effects of aging on the HPA axis using the genetic expression of hypothalamic corticotropin-releasing hormone (CRH). Changes in the CRH mRNA expression were quantified in the hypothalamic paraventricular nucleus (PVN) using in situ hybridization, in young (50 days) and old (18 months) rats of both sexes. The second objective was to determine the effects of dehydroepiandrosterone (DHEA) treatment on the age-related changes in CRH mRNA in both sexes. In aged animals of both sexes, CRH mRNA levels in PVN were significantly reduced by 20%. DHEA treatment increased the CRH mRNA expression in young rats and reversed the decrease in the CRH mRNA expression in old rats. Young males were more sensitive to DHEA than young females (+15% vs. +9%) whereas in old animals females showed more striking changes than males (+38% vs. +24%). These findings clearly demonstrate that in old apparently healthy rats of both sexes aging process induced a significant decrease in basal CRH mRNA levels and that DHEA treatment which exerts a positive influence on CRH gene expression completely reversed the decrease of the CRH mRNA levels associated with aging.

Roles of steroid hormones and their receptors in structural organization in the nervous system

Due to their chemical properties, steroid hormones cross the blood-brain barrier where they have profound effects on neuronal development and reorganization both in invertebrates and vertebrates, including humans mediated through their receptors. Steroids play a crucial role in the organizational actions of cellular differentiation representing sexual dimorphism and apoptosis, and in the activational effects of phenotypic changes in association with structural plasticity. Their sites of action are primarily the genes themselves but some are coupled with membrane-bound receptor/ion channels. The effects of steroid hormones on gene transcription are not direct, and other cellular components interfere with their receptors through cross-talk and convergence of the signaling pathways in neurons. These genomic and non-genomic actions account for the divergent effects of steroid hormones on brain function as well as on their structure. This review looks again at and updates the tremendous advances made in recent decades on the study of the role of steroid (gonadal and adrenal) hormones and their receptors on developmental processes and plastic changes in the nervous system.

Effects of dehydroepiandrosterone (DHEA) on pituitary prolactin and arcuate nucleus neuron tyrosine hydroxylase mRNA levels in the rat

It is well documented that dehydroepiandrosterone (DHEA), an adrenal androgen, is converted into potent androgens and/or estrogens in peripheral tissues. Since sex steroids are involved in the regulation of prolactin (PRL) secretion, we have studied the effect of DHEA administration on PRL mRNA levels in both adult male and female rats. Since tuberoinfundibular dopaminergic (TIDA) neurons are involved in the negative regulation of PRL, we have also evaluated the effects of DHEA on the genetic expression of tyrosine hydroxylase (TH), the limiting enzyme in catecholamine biosynthesis in TIDA neurons. Sham-operated and castrated animals of both sexes received during 2 days DHEA at the dose of 6 mg/kg/day, starting on the first day after castration. PRL and TH mRNA levels were measured by quantitative in situ hybridization. In the male rat, orchiectomy performed 3 days earlier did not modify PRL mRNA levels. DHEA administration increased the hybridization signal in both sham-operated and orchiectomized animals. In the female, ovariectomy decreased PRL mRNA levels and, as observed in the male, DHEA treatment induced an increase in the hybridization signal in both control and ovariectomized rats. In TIDA neurons, castration increased TH mRNA levels as evaluated by number of grains over labelled neurons and the number of TH-labelled cells per section in both male and female animals. In both sham-operated male rats and orchiectomized animals, DHEA decreased the hybridization signal. In the female, DHEA administration completely prevented the increase in TH mRNA levels due to ovariectomy. In sham-operated female rats, the treatment had no effect. These data clearly indicate that in both male and female rats DHEA exerts an estrogenic influence on both PRL and TH gene expression. Although these in vivo experiments do not allow to establish whether the stimulation of PRL gene expression is due to an action of the steroid on the pituitary or at the hypothalamic level or alternatively at both sites, it is likely that one of the mechanisms of action of DHEA might be related to a decrease in dopamine release following a depression of TIDA neuron activity.

Presence of estrogen receptors in aromatase-immunoreactive neurons in the mouse brain

The present study was undertaken to demonstrate estrogen receptors in aromatase-immunoreactive neurons showed the immunoreactivity for estrogen receptors in the cell nuclei in the medial subdivision of the bed nucleus of the stria terminalis and the posterodorsal division of the medial amygdaloid nucleus, but a few did in the medial preoptic area. These results suggest that aromatase-immunoreactive neurons in the former two areas are regulated by steroids through estrogen receptors in their cell nuclei.