Interconnectedness of Steroid Hormone-Binding Neurons: Existence and Implications

Fish as a model in social neuroscience: conservation and diversity in the social brain network

Mechanisms for fish social behaviours involve a social brain network (SBN) which is evolutionarily conserved among vertebrates. However, considerable diversity is observed in the actual behaviour patterns amongst nearly 30000 fish species. The huge variation found in socio-sexual behaviours and strategies is likely generated by a morphologically and genetically well-conserved small forebrain system. Hence, teleost fish provide a useful model to study the fundamental mechanisms underlying social brain functions. Herein we review the foundations underlying fish social behaviours including sensory, hormonal, molecular and neuroanatomical features. Gonadotropin-releasing hormone neurons clearly play important roles, but the participation of vasotocin and isotocin is also highlighted. Genetic investigations of developing fish brain have revealed the molecular complexity of neural development of the SBN. In addition to straightforward social behaviours such as sex and aggression, new experiments have revealed higher order and unique phenomena such as social eavesdropping and social buffering in fish. Finally, observations interpreted as 'collective cognition' in fish can likely be explained by careful observation of sensory determinants and analyses using the dynamics of quantitative scaling. Understanding of the functions of the SBN in fish provide clues for understanding the origin and evolution of higher social functions in vertebrates.

Mechanisms for the Approach/Avoidance Decision Applied to Autism

As a neurodevelopmental disorder with serious lifelong consequences, autism has received considerable attention from neuroscientists and geneticists. We present a hypothesis of mechanisms plausibly affected during brain development in autism, based on neural pathways that are associated with social behavior and connect the prefrontal cortex (PFC) to the basal ganglia (BG). We consider failure of social approach in autism as a special case of imbalance in the fundamental dichotomy between behavioral approach and avoidance. Differential combinations of genes mutated, differences in the timing of their impact during development, and graded degrees of hormonal influences may help explain the heterogeneity in symptomatology in autism and predominance in boys.

Testosterone Administration Moderates Effect of Social Environment on Trust in Women Depending on Second-to-Fourth Digit Ratio

Animal research has established that effects of hormones on social behaviour depend on characteristics of both individual and environment. Insight from research on humans into this interdependence is limited, though. Specifically, hardly any prior testosterone experiments in humans scrutinized the interdependency of testosterone with the social environment. Nonetheless, recent testosterone administration studies in humans repeatedly show that a proxy for individuals’ prenatal testosterone-to-estradiol ratio, second-to-fourth digit-ratio (2D:4D ratio), influences effects of testosterone administration on human social behaviour. Here, we systematically vary the characteristics of the social environment and show that, depending on prenatal sex hormone priming, testosterone administration in women moderates the effect of the social environment on trust. We use the economic trust game and compare one-shot games modelling trust problems in relations between strangers with repeated games modelling trust problems in ongoing relations between partners. As expected, subjects are more trustful in repeated than in one-shot games. In subjects prenatally relatively highly primed by testosterone, however, this effect disappears after testosterone administration. We argue that impairments in cognitive empathy may reduce the repeated game effect on trust after testosterone administration in subjects with relatively high prenatal testosterone exposure and propose a neurobiological explanation for this effect.

Anatomical connections between the anterior and posterodorsal sub-regions of the medial amygdala: integration of odor and hormone signals

In many rodent species, such as Syrian hamsters, reproductive behavior requires neural integration of chemosensory information and steroid hormone cues. The medial amygdala processes both of these signals through anatomically distinct sub-regions; the anterior region (MeA) receives substantial chemosensory input, but contains few steroid receptor-labeled neurons, whereas the posterodorsal region (MePD) receives less chemosensory input, but contains dense populations of androgen and estrogen receptors. Importantly, these sub-regions have considerable reciprocal connections, and previous studies in our laboratory have shown that functional interactions between MeA and MePD are required for the preference to investigate opposite-sex odors in male hamsters. We therefore hypothesized that chemosensory and hormone signals are conveyed directly between MeA and MePD. To test this hypothesis, we injected the retrograde tracer, cholera toxin B (CTB), into either MeA or MePD of male subjects and identified whether retrogradely labeled cells within MePD or MeA, respectively, expressed (1) Fos protein following exposure to female or male odors or (2) androgen receptors (AR). Approximately 36% of CTB-labeled cells within MeA (that project to MePD) also expressed Fos following exposure to either social odor, compared to the only 13% of CTB-labeled cells within MePD (that project to MeA) that also expressed odor-induced Fos. In contrast, 57% of CTB-labeled cells within MePD also contained AR, compared to the 28% of CTB-labeled cells within MeA that were double-labeled for AR/CTB. These results provide the first anatomical evidence that chemosensory and hormone cues are conveyed directly between MeA and MePD. Furthermore, these data suggest that chemosensory information is conveyed primarily from MeA to MePD, whereas hormone information is conveyed primarily from MePD to MeA. More broadly, the interactions between MeA and MePD may represent a basic mechanism by which the brain integrates information about social cues in the environment with hormonal indices of reproductive state.

Corepressors, nuclear receptors, and epigenetic factors on DNA: a tail of repression

The differential exposure to circulating steroid hormones during brain development can have lasting consequences on brain function and behavior; therefore, the tight control of steroid hormone action within the developing brain is necessary for the expression of appropriate sex-typical behavior patterns later in life. The restricted control of steroid hormone action at the level of the DNA can be accomplished through the recruitment of coregulatory complexes. Nuclear receptor action can either be enhanced by the recruitment of coactivator complexes or suppressed by the formation of corepressor complexes. Alternatively, the regulation of nuclear receptor-mediated gene transcription in the developing brain may involve a dynamic process of coactivator and corepressor function on DNA. It is likely that understanding how different combinations of coregulatory matrixes assembly on DNA will lead to further understanding of heterogeneous responses to nuclear receptor activation. We will discuss how coregulators influence gene transcription and repression, the role of chromatin-binding factors in the regulation of gene transcription, and their potential impact on brain development.

Gonadal steroid receptors colocalize with central nervous system neurons projecting to the rat prostate gland

Mating-induced Fos-immunoreactive (-ir) cells are colocalized with androgen receptors (AR), estrogen receptors (ER), or both in limbic and hypothalamic areas known to mediate male rat mating behavior. A steroid-responsive neural network might govern copulatory behavior in male laboratory rats that is analogous to the network described in female rats that governs the lordosis response. This hypothesized network in males may synchronize and coordinate sexual behavioral responses with physiological responses of the genitals and the internal organs of reproduction. Therefore, the pseudorabies virus (PRV; Bartha strain), a transneuronal, viral retrograde tract tracer, was microinjected into the prostate gland to label this network. After 7 days, brains from infected animals were processed for immunohistochemical labeling of AR, ER, and PRV. The majority of PRV-ir cells exhibited either AR or ER immunoreactivity in the medial preoptic area, median preoptic nucleus, bed nucleus of stria terminalis, hypothalamic paraventricular nucleus, and zona incerta, areas known to play roles in male rat mating behavior. Other structures such as the central tegmental field/subparafascicular nucleus of the thalamus, central nucleus of the amygdala, and medial amygdala, also important in the display of male copulatory behavior, were less reliably labeled. Collectively, a steroid receptor-containing neuronal circuit, largely contained in the diencephalon, was revealed that likely is involved in the autonomic control of the prostate gland and the consummatory aspects of male rat mating behavior.

Implants of estradiol conjugated to bovine serum albumin in the male rat medial preoptic area promote copulatory behavior

The expression of mating behavior in male rats is dependent on estrogen-responsive neurons in the medial preoptic area (MPO). Previous reports showed that mating is attenuated if the aromatization of testosterone to estradiol (E2) is blocked in the MPO and that mating is maintained by MPO E2 implants. However, the mechanisms by which E2 exerts its action are not fully understood. It had been thought that E2 acted exclusively by binding to nuclear estrogen receptors to exert it effects; however, recent reports suggest that E2 also binds to membrane-associated receptors activating downstream intracellular cascade responses. In this study, we aimed to determine if an action of E2 at the cell surface is sufficient to support mating behavior. Therefore, either vehicle, E2, or E2 conjugated to bovine serum albumin (BSA-E2: a complex of E2 and a large protein that will not cross the plasma membrane, thereby restricting the action of E2 to cell surface signaling) was chronically administered bilaterally to the MPO of castrated, dihydrotestosterone-treated male rats. Mating behavior was supported by MPO BSA-E2 implants, suggesting that E2 operates in the MPO via a cell surface mechanism to facilitate male rat mating behavior.

Effects of estrogen in the male rat medial amygdala: infusion of an aromatase inhibitor lowers mating and bovine serum albumin-conjugated estradiol implants do not promote mating

In male rats, copulatory behavior depends on estrogen-responsive neurons located in brain areas known to be crucial for mating. Blocking the aromatization of testosterone (T) to estradiol (E(2)) either throughout the brain or within the medial preoptic area (MPO) reduces mating, whereas E(2) treatment of either the MPO or the medial amygdala (MEA) maintains sexual behavior. The effects of T aromatization in the MEA have received less attention; therefore, 2 studies were done to further elucidate the effects of E(2) in the MEA. In experiment 1, gonadally intact male rats that showed robust mating behavior were administered chronic fadrozole, a nonsteroidal aromatase inhibitor, to the MEA to stop the conversion of T to E(2) and then paired with receptive females. Infusion of fadrozole to the MEA significantly lowered mating behavior in experimental males compared to vehicle-infused control males. To further investigate the mechanism by which E(2) acts in the MEA, in experiment 2, E(2) conjugated to bovine serum albumin (BSA-E(2): a complex of E(2 )and a large protein that does not cross the plasma membrane, thereby restricting the action of E(2) to cell-surface signaling) was chronically administered bilaterally to the MEA of castrated, dihydrotestosterone-treated males. This treatment did not maintain mating behavior. These studies show that E(2) acts in the MEA to promote male sexual behavior and suggest an intercellular mechanism of E(2) action.

The effects of mating stimulation on c-Fos immunoreactivity in the female hamster medial amygdala are region and context dependent

During mating in hamsters, both tactile and nontactile sensory stimulation experienced by the female affect sexual behavior and progestational neuroendocrine reflexes. To test the interactions of these types of mating stimulation, c-Fos immunohistochemistry measured brain cellular activity during sexual behavior under conditions that included combinations of tactile and nontactile mating stimulation. Test groups received: (1) mating stimulation from a male, females being either fully mated or mated while wearing a vaginal mask, or (2) experimenter applied manual vaginocervical stimulation (VCS)-with or without males present, or (3) handling similar to VCS but without insertions-with or without males present. Numbers of c-Fos immunoreactive cells were counted in specific subdivisions of the posterior medial amygdala (MeP) and ventromedial hypothalamus (VMH). The medial amygdala dorsal and ventral subdivisions responded differentially to components of mating stimulation. The posterodorsal Me (MePD) cellular activation was greatest during mating conditions that included VCS and/or males present. However, the posteroventral Me (MePV) was sensitive to male exposure and not to VCS. Also, MePV and VMH shell responses mirrored each other, both being primarily sensitive to male exposure. In separate tests, manual VCS induced pseudopregnancy, though the procedure was most effective with additional nontactile stimulation from males present. In summary, contextual cues provided by nontactile male stimulation enhance the effect of vaginocervical and other tactile stimulation on reproductive processes. Furthermore, c-Fos expression in the female hamster medial amygdala is region and context dependent.

Estradiol in the male rat amygdala facilitates mounting but not ejaculation

Mating activates estrogen sensitive neurons in several regions of male rat brain, including the medial amygdala (MEA). Infusion of the aromatase inhibitor, Fadrozole, into the MEA reduced mating, presumably by inhibiting conversion of testosterone (T) to estradiol (E(2)). We investigated whether administering E(2) locally into the amygdala (AMG) would maintain sexual behavior in male rats given systemic Fadrozole to eliminate E(2) elsewhere in the brain. Gonadally intact male rats were divided into two matched groups, based on ejaculatory performance in weekly tests with receptive females. All males received 0.29 mg/kg/day sc Fadrozole and bilateral implants to AMG. E(2)-in-AMG males (N=6 experimentals) received implants tipped with a cured mixture of E(2) in Silastic Medical Adhesive, whereas Vehicle-in-AMG males (N=6 controls) received implants tipped with cured adhesive alone (without E(2)). In E(2)-in-AMG males, postoperative mount and intromission frequency did not differ significantly from pretreatment baseline levels, but ejaculation frequency declined significantly (P<.01). Conversely, in Vehicle-in-AMG males, postoperative mounts and intromissions (P<.01) and ejaculations (P<.01) declined significantly. Postoperative mount and intromission frequency of Vehicle-in-AMG males was significantly lower than that of E(2)-in-AMG males (P<.01), but ejaculation frequency did not differ significantly between groups. This suggests that E(2)-sensitive AMG neurons are important for sexual arousal but not ejaculatory performance.

Puberty and the maturation of the male brain and sexual behavior: recasting a behavioral potential

The pubertal transition from the juvenile to adult state requires significant changes in behavior to meet the demands for success and survival in adulthood. These behavioral changes during puberty must be mediated by changes in the structure and/or function of the central nervous system. Despite the profound consequences of puberty on an animal's behavioral repertoire, the mechanisms underlying pubertal maturation of the nervous system remain largely unknown. In this review, we provide a synthesis of neural development during puberty as it relates to maturation of male reproductive behavior. We first outline neuroendocrine events associated with puberty and review work from our laboratory that identifies pubertal changes in the neural substrate controlling male reproduction by comparing the neural responses of prepubertal and adult males to steroids and female chemosensory cues. We then raise the question of whether puberty is a sensitive period in which gonadal hormones influence the structural and functional organization of neural circuits underlying male reproductive behavior. The central thesis of this review is that the development of the nervous system during puberty alters the way in which the male responds to social stimuli, involving the restructuring of neural circuits that integrate steroidal and sensory information and ultimately mediate steroid-dependent social behaviors in adulthood.

A single administration of testosterone induces cardiac accelerative responses to angry faces in healthy young women

Recently, it was demonstrated how individuals with high levels of testosterone selectively attend toward angry faces. It was argued that this suggests that high levels of testosterone are associated with an aggressive, dominating personality style. In this study, the authors used a double-blind, placebo-controlled design to examine whether exogenous testosterone would induce cardiac acceleration in response to angry faces. Participants (healthy young women) were exposed to neutral, happy, or angry faces. Administration of a single dosage of testosterone (0.5 mg) induced an accelerative cardiac response to angry faces. It is argued that this effect is due to the encouragement of dominance behavior and the inclination toward aggression. Possible mechanisms behind testosterone-driven changes in behavior are discussed with relevance to steroid-responsive networks in the limbic system that drive and control motivational and physiological aspects of social behavior.

Estrogens, brain and behavior: studies in fundamental neurobiology and observations related to women's health

Mechanisms and consequences of the effects of estrogen on the brain have been studied both at the fundamental level and with therapeutic applications in mind. Estrogenic hormones binding in particular neurons in a limbic-hypothalamic system and their effects on the electrophysiology and molecular biology of medial hypothalamic neurons were central in establishing the first circuit for a mammalian behavior, the female-typical mating behavior, lordosis. Notably, the ability of estradiol to facilitate transcription from six genes whose products are important for lordosis behavior proved that hormones can turn on genes in specific neurons at specific times, with sensible behavioral consequences. The use of a gene knockout for estrogen receptor alpha (ERalpha) revealed that homozygous mutant females simply would not do lordosis behavior and instead were extremely aggressive, thus identifying a specific gene as essential for a mammalian social behavior. In dramatic contrast, ERbeta knockout females can exhibit normal lordosis behavior. With the understanding, in considerable mechanistic detail, of how the behavior is produced, now we are also studying brain mechanisms for the biologically adaptive influences which constrain reproductive behavior. With respect to cold temperatures and other environmental or metabolic circumstances which are not consistent with successful reproduction, we are interested in thyroid hormone effects in the brain. Competitive relations between two types of transcription factors - thyroid hormone receptors and estrogen receptors have the potential of subserving the blocking effects of inappropriate environmental circumstances on female reproductive behaviors. TRs can compete with ERalpha both for DNA binding to consensus and physiological EREs and for nuclear coactivators. In the presence of both TRs and ERs, in transfection studies, thyroid hormone coadministration can reduce estrogen-stimulated transcription. These competitive relations apparently have behavioral consequences, as thyroid hormones will reduce lordosis, and a TRbeta gene knockout will increase it. In sum, we not only know several genes that participate in the selective control of this sex behavior, but also, for two genes, we know the causal routes. Estrogenic hormones are also the foci of widespread attention for their potential therapeutic effects improving, for example, certain aspects of mood and cognition. The former has an efficient animal analog, demonstrated by the positive effects of estrogen in the Porsolt forced swim test. The latter almost certainly depends upon trophic actions of estrogen on several fundamental features of nerve cell survival and growth. The hypothesis is raised that the synaptic effects of estrogens are secondary to the trophic actions of this type of hormone in the nucleus and nerve cell body.

Castration rapidly decreases hypothalamic gamma-aminobutyric acidergic neuronal activity in both male and female rats

The postcastration LH response is greater and somewhat more rapid in male than female rats. We have previously demonstrated that hypothalamic gamma-aminobutyric acid (GABA)ergic neuronal activity decreases following gonadectomy in male rats. To investigate whether these same hypothalamic GABA neurons decrease their activity postcastration in female rats, and whether more rapid and or greater postcastration decreases occur in male rats, we determined the timing and magnitude of the postcastration decreases in GABA turnover which are associated with the sexually dimorphic postcastration LH response. Adult male and 4-day cycling female rats were castrated between 0800 and 1000 h (females ovariectomized on diestrus day 1). Serum LH levels increased significantly by 12 h postcastration in both males and females with the magnitude of the increases being 6.2-fold in males and 2.8-fold in females. GABA turnover was determined in 16 microdissected brain structures by the GABA transaminase inhibition method at 0 h (sham-operated controls), 6 h, 12 h and 1, 2, 4 and 6 days postcastration. In male rats, in the diagonal band of Broca at the level of the organum vasculosum of the lamina terminalis [DBB(ovlt)], the rate of GABA turnover decreased significantly already by 6 h postcastration compared with the 0 h controls, and remained suppressed through 6 days. This rapid down regulation of DBB(ovlt) GABAergic neurons also occurred in female rats, however, the duration of the decrease was not as prolonged as in male rats. Similar changes occurred in the tuberoinfundibular GABAergic (TIGA) neurons projecting to the median eminence in both males and females. Down regulation of these GABAergic neurons precedes or is coincident with increased postcastration LH secretion in both sexes, and the duration of the decreases is consistent with the less robust postcastration LH response in female rats. In addition, the rate of GABA turnover decreased after castration in the interstitial (bed) nucleus of the stria terminalis, ventral aspect (INSTv), the medial preoptic nucleus, dorsomedial aspect (MPNdm) and the ventromedial nucleus, ventrolateral aspect (VMNvl) in male rats, and in the INSTv and VMNvl of female rats, while there was no effect of castration in other hypothalamic regions or control structures. The result in the female VMNvl is consistent with reports that GABA facilitates lordosis behavior in this hypothalamic structure. These findings are consistent with the hypothesis that discrete hypothalamic populations of sex steroid-sensitive GABAergic neurons mediate the postcastration LH responses in both male and female rats, and may underlie other sexually dimorphic adult phenotypes such as sex behavior.

Seasonal specificity of hormonal, behavioral, and coloration responses to within- and between-sex encounters in male lizards (Sceloporus undulatus)

This study reports the gender and seasonal specificity of hormonal, behavioral, and coloration responses displayed by "resident" male lizards (Sceloporus undulatus) exposed to male or female "intruders" during staged encounters in outdoor enclosures. Resident males were engaged in staged encounters with males or females for 1 h per day on 9 consecutive days during the breeding and postbreeding seasons. Male-specific responses occurred during the breeding but not the postbreeding season. These included (1) a transient increase in plasma testosterone (T) that was evident on Day 4 and had subsided by Day 10, (2) behavioral displays of aggression (full shows and chases), and (3) a lightening of dorsal integumental color. Female-specific behavioral responses (nod sets) were displayed in both seasons. Season-specific responses consisted only of a transient increase in plasma corticosterone (B) during the breeding season that was evident on Day 4 and had subsided by Day 10. Pushups were displayed in response to both genders during both seasons, although the frequency of pushups was significantly higher in response to females than to males during the postbreeding season. The coloration of residents did not change in response to male intruders during the postbreeding season or to females during either season. These results define the gender and seasonal specificity of hormonal, behavioral, and coloration responses of resident male S. undulatus in social interactions with conspecifics. Thus, our results clarify the biological significance of these responses in terms of potentially aggressive versus courtship interactions and breeding versus postbreeding contexts.

The medial extended amygdala in male reproductive behavior. A node in the mammalian social behavior network

Hormonal and chemosensory signals regulate social behaviors in a wide variety of mammals. In the male Syrian hamster, these signals are integrated in nuclei of the medial extended amygdala, where olfactory and vomeronasal system transmission is modulated by populations of androgen- and estrogen-sensitive neurons. Evidence from behavioral changes following lesions and from immediate early gene expression supports the hypothesis that the medial extended amygdala and medial preoptic area belong to a circuit that functions selectively in male sexual behavior. However, accumulated behavioral, neuroanatomical, and neuroendocrine data in hamsters, other rodents, and other mammals indicate that this circuit is embedded in a larger integrated network that controls not only male mating behavior, but female sexual behavior, parental behavior, and various forms of aggression. In this context, perhaps an individual animal's social responses can be more easily understood as a repertoire of closely interrelated, hormone-regulated behaviors, shaped by development and experience and modulated acutely by the environmental signals and the hormonal milieu of the brain.

Testosterone stimulation of the medial preoptic area and medial amygdala in the control of male hamster sexual behavior: redundancy without amplification

Receptors for gonadal steroids are present in an interconnected network of limbic nuclei. The existence of this network structure has important implications for how steroids control reproductive physiology and behavior. In 1986, Cottingham and Pfaff proposed that properties of a steroid-responsive neural network could include redundancy, amplification, stability and selective filtering. The present study tested the concept of steroid amplification, using male hamster sexual behavior as a model. In the male hamster, the medial amygdaloid nucleus (Me) and medial preoptic area (MPOA) are essential for mating behavior, and both nuclei transduce steroid cues to facilitate copulation. To determine if steroid action at multiple interconnected nuclei amplifies mating, the present study compared sexual behavior in castrated male hamsters bearing unilateral intracranial implants of testosterone in Me or MPOA with that of males with dual testosterone implants in Me and MPOA. Implants that stimulated androgen receptor-containing neurons in Me or MPOA stimulated copulatory behavior above castrate levels. However, behavior of males with dual implants was not significantly different from that of males with single implants. This suggests that steroid action at either MPOA or Me is sufficient to facilitate mating, but dual stimulation of these reciprocally-connected nuclei does not amplify sexual behavior.

Integration of chemosensory and hormonal input in the male Syrian hamster brain

Mating in the male Syrian hamster requires the interaction of chemosensory and hormonal stimuli. Chemosensory cues from the vomeronasal organ and olfactory mucosa are transmitted through limbic nuclei that contain receptors for gonadal steroid hormones, including the medial amygdaloid nucleus (Me) and medial preoptic area (MPOA). This pathway is essential for mating, as lesions that interrupt transmission of chemosensory cues to MPOA will abolish copulation. Likewise, gonadal steroids facilitate sexual behavior through Me and MPOA, as demonstrated using intracranial implants in the brains of castrate males. In addition, odor and hormonal signals must be integrated in the brain for copulation to occur. Mating is prevented when olfactory bulbectomy is performed ipsilateral to an intracranial testosterone implant, thereby preventing the interaction of odors and hormones. According to our current model, hormones may act as a gating signal to strengthen synaptic contacts along the chemosensory pathway, thereby permitting or enhancing transmission of chemosensory cues.

Bidirectional connections of the medial amygdaloid nucleus in the Syrian hamster brain: simultaneous anterograde and retrograde tract tracing

In the male Syrian hamster, mating is dependent on chemosensory and hormonal stimuli, and interruption of either input prevents copulation. The medial amygdaloid nucleus (Me) is a key nodal point in the neural circuitry controlling male sexual behavior because it relays both odor and steroid cues. Me is comprised of two major subdivisions, anterior (MeA) and posterior (MeP), which have distinct, although overlapping efferent projections. The present study investigated the afferents and efferents of MeA and MeP by using combined anterograde and retrograde tract tracing. Phaseolus vulgaris-leucoagglutinin and cholera toxin B were injected by iontophoresis through a single glass micropipette and detected by immunohistochemistry. MeA has widespread connections with olfactory structures, whereas MeP is heavily interconnected with steroid-responsive brain regions. The efferent projections of MeA and MeP were similar to those reported previously for the rat and hamster. In particular, MeP projects to the posteromedial subdivision of the bed nucleus of the stria terminalis (BNST) and to the medial preoptic nucleus, whereas MeA projects to adjacent subnuclei in BNST and the preoptic area. MeA and MeP also have distinct patterns of afferent input. Furthermore, the combination of anterograde and retrograde tract tracers shows that MeA and MeP are each bidirectionally connected with each other and with limbic nuclei. These results demonstrate that subnuclei of Me are interconnected with limbic structures in hamster brain. These connections may contribute to chemosensory and hormonal integration to control male sexual behavior.

Thinking about networks in the control of male hamster sexual behavior

Motivated social behaviors such as mating are controlled by a complex network of limbic nuclei. Concepts of network organization derived from computational neuroscience may aid our understanding of the links between the neuroanatomical circuitry and what is represented by the anatomy. Research in my laboratory uses mating behavior in the male Syrian hamster as a model to elucidate how chemosensory and steroid cues are integrated in the brain. An interaction of odors and hormones is required for mating in this species. These two essential stimuli are transmitted through separate parallel pathways in the limbic system. The functional organization of the hamster mating behavior circuit is characterized by distributed representation, divergent and convergent neural pathways, and recurrent feedback. Odors and hormones have different modes of action on this neural network. While chemosensory cues stimulate the input units of the network, steroids facilitate behavior through the hidden units. In this manner, steroids appear to create a permissive environment for subsequent activation by odor cues.

Integration of chemosensory and hormonal cues is essential for sexual behaviour in the male Syrian hamster: role of the medial amygdaloid nucleus

Mating behaviour in the male hamster requires chemosensory and hormonal cues, and copulation is abolished if either signal is interrupted. In addition, the integration of chemosensory stimuli with steroid signals is essential for mating. In castrated male hamsters, implantation ofa testosterone-filled cannula in the preoptic area stimulates mating behaviour. However, removal of the ipsilateral olfactory bulb prevents steroid facilitation of sexual activity. The present studies determined if the integration of chemosensory and hormonal cues necessary for mating behaviour is distributed within steroid-sensitive nuclei in the brain, or is restricted to the preoptic area. Specifically, the hypothesis was tested that the medial amygdala is capable of odour and hormone integration. Castrated male hamsters received an intracerebral implant of testosterone in the medial amygdala combined with removal of a single olfactory bulb, ipsilateral or contralateral to the implant. Mating behaviour did not increase after implant surgery and bulbectomy in either ipsilateral or contralateral bulbectomized males. In a second study, males were bulbectomized three weeks after implant surgery, to demonstrate the ability of testosterone in the medial amygdala to stimulate male sexual behaviour, and the loss of behaviour following bulbectomy. The results confirm that integration of odour and steroid cues is essential for mating in the male hamster. Moreover, the medial amygdaloid nucleus contributes to chemosensory and hormonal integration. However, compared with steroid stimulation in the preoptic area, the behavioural effects of testosterone in the medial amygdaloid nucleus are more sensitive to manipulations of the olfactory system, suggesting that the amygdala requires bilateral chemosensory input.

Estrogen-excitable forebrain projections to the ventral premammillary nucleus of the female rat

Retrograde labels by Nuclear Yellow from the female rat ventral premammillary nucleus (PMv) were most numerous in the lateral septum (LS) and the preoptic area (POA) and spread laterally into the substantia innominata. Other labels were in the diagonal band nucleus, the substantia innominata and the bed nucleus of the stria terminalis. Constant-current, single-pulse electrical stimulation of the PMv in urethane-anesthetized ovariectomized rats elicited antidromic action potentials in the cingulate cortex, in addition to the structures that contained labeled neurons. In the LS or cingulate cortex, but not in the POA, estrogen decreased antidromic activation thresholds and shortened refractory periods. The PMv is a way station that relays estrogen-excitable septal, but not preoptic, effects. The PMv also contains fibers of passage that originate in estrogen-excitable cingulate neurons.

Effects of melatonin on estrogen receptor expression in the forebrain of outbred (Lak.LVG) golden hamsters

Studies have shown that the pineal gland via its hormone, melatonin, induces the involution of male and female reproductive systems in seasonally reproducing animals. Melatonin has direct inhibitory effects on both hypothalamic and pituitary functions, which are also exquisitely sensitive to the feedback effects of estradiol. Since melatonin can modulate estrogen receptor (ER) expression in other tissues, immunocytochemical and ribonuclease protection analyses were used to examine the effects of 12 weeks of daily late afternoon injections of melatonin on ER protein and mRNA levels in the hypothalamus of Lak.LVG golden hamsters. Significant decreases in ER-immunoreactivity were noted in the medial preoptic area (MPOA) and bed nucleus of the stria terminalis (BNST) in response to melatonin, while other hypothalamic areas which express ER, e.g. the anterior hypothalamus, showed less dramatic changes. Hypothalamic ER mRNA was decreased in response to melatonin in both intact and ovariectomized animals by 25%. In intact, cycling female hamsters, there was a significant reduction in uterine weight after melatonin treatment. These results suggest that melatonin exerts its anti-reproductive effects in hamsters by modulating ER levels in neurons of the MPOA and BNST, thereby influencing steroid feedback mechanisms.

Functions of the steroid-responsive neural network in the control of male hamster sexual behavior

Gonadal steroid receptor-containing neurons in the brain are densely interconnected to form a steroid-responsive neural network within the limbic system. The possible functions of such a network include redundancy, signal amplification, stability, and selective filtering of hormonal cues to control steroid-dependent aspects of neuroendocrine secretion and behavior. Recently, the neural circuitry underlying male sexual behavior in the Syrian hamster has been used as a model for testing certain of these concepts. These studies provide functional evidence to support the network properties of gonadal steroid-responsive neurons in controlling hormone-dependent sexual behavior.

Nitric oxide synthase in mating behavior circuitry of male Syrian hamster brain

Chemosensory and hormonal stimuli are essential for mating in the male Syrian hamster. These signals are processed in a neural circuit that includes the medial amygdaloid nucleus (Me), bed nucleus of the stria terminalis (BNST), and medial preoptic area (MPOA). Nitric oxide is implicated in the regulation of male sexual behavior, and nitric oxide synthase (NOS), the enzyme that catalyzes the production of nitric oxide, is present in the limbic system. In this study, the distribution of NOS-containing neurons in mating behavior circuitry of the male Syrian hamster brain was determined using labeling for brain NOS (bNOS) and reduced nicotinamide adenine dinucleotide phosphate diaphorase (NADPH-d). bNOS and NADPH-d labeled equivalent populations of neurons. NOS-containing neurons were clustered in specific subnuclei with in the Me, BNST, and MPOA. NOS-positive fibers and neurons were seen in the stria terminalis and ventral amygdalofugal pathway, which link the Me with BNST and MPOA. Many NOS-positive neurons in the posterior subdivision of the Me, the medial preoptic nucleus (MPN), and the ventral premammillary nucleus contain androgen receptors. Castration reduced NOS-positive neurons in the MPN, implying a selective regulation of NOS by gonadal steroids. Together, these results suggest that NOS may contribute to the regulation of male sexual behavior by influencing the central neural processing of hormonal and chemosensory signals in the hamster limbic system.

Catecholamine-CRF synaptic interaction in a septal bed nucleus: afferents of neurons in the bed nucleus of the stria terminalis

Projections of catecholamine neurons to the bed nucleus of the stria terminalis (BST), especially its corticotropin releasing factor (CRF)-producing neurons, are implicated as being major contributors to the neurochemically mediated central regulation of the stress response. The purpose of the present study was to examine in the BST of the rat brain the morphological characteristics of interactions between two neuron populations of the brain, catecholaminergic and CRF neurons. A double-label immunocytochemical, light and electron microscopic technique allowed the demonstration of the synaptic interaction between dopamine (DA, i.e., tyrosine hydroxylase-containing) and norepinephrine (NE, i.e., dopamine-beta-hydroxylase-containing) axons and CRF neurons in the BST. DA terminals formed synapses with dendrites and soma of CRF neurons in the dorsolateral BST. NE terminals formed synapses with dendrites of CRF neurons in the ventrolateral BST. In conclusion, catecholamine afferents can directly affect the contribution of CRF neurons of the BST to an animals response to stress.

Monoamine innervation of bed nucleus of stria terminalis: an electron microscopic investigation

Immunocytochemical studies showed distinctive monoamine input to the bed nucleus of the stria terminalis (BST). A comparison of axons immunoreactive (IR) for a catecholamine synthetic enzyme [tyrosine hydroxylase (TH) or dopamine beta-hydroxylase (DBH) or phenylethanolamine-N-methyl transferase (PNMT)] or serotonin (5-HT) was performed. TH-IR axons had a greater density in the lateral BST, but DBH-IR and 5-HT-IR axons had a greater density in the medial BST. PNMT-IR axons were dense in the intermediate BST. TH-IR axons had a greater density than DBH- and PNMT-IR axons in the dorsolateral BST, but DBH-IR axons had the greatest density in the ventrolateral BST. Ultrastructural studies revealed that TH-IR terminals formed synapses with soma, dendrites, spines, and axons in the dorsolateral BST. DBH-IR terminals formed synapses with dendritic shafts and spines, and 5-HT-IR terminals formed synapses with dendrites in the ventrolateral BST. Only some 5-HT-IR axons were myelinated. The medial vs. lateral organization of the noradrenergic and dopaminergic afferents in the BST of the rat brain is now evident and is similar to the human brain. The medial-lateral functional subdivision of the BST is supported by the pattern of dopaminergic, noradrenergic, and serotonergic afferents. This demonstration of epinephrine-producing afferents in the BST is the first detailed description of adrenergic input to the BST and aided the determination that catecholaminergic innervation of the ventrolateral BST is predominantly noradrenergic as has been proposed for many years. However, the additional demonstration of rich dopaminergic innervation of the dorsolateral subnucleus suggests further division of the BST into dorsal and ventral functional subgroups.