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

Functional significance of men's testosterone reactivity to social stimuli

Rapid testosterone fluctuations in response to social stimuli are observed across a wide range of species, and the highly conserved nature of these fluctuations suggests an adaptive function. This paper reviews the current literature on testosterone reactivity, primarily in human males, and illustrates how life-history theory provides an adequate theoretical framework to interpret findings. The review is structured around supporting evidence suggesting that situations implicated in mating effort either directly (e.g., interactions with a mate) or indirectly (e.g., intrasexual competition) are generally associated with a brief elevation of testosterone, while situations implicated in parenting effort (e.g., nurturant interactions with offspring) are generally associated with a decline in testosterone. Further, we discuss how these fluctuations in testosterone have been linked to future behaviors, and how situational, motivational, and physiological variables moderate the interplay between social stimuli, testosterone reactivity, and behavior. Supporting the notion that testosterone can play a causal role in modulating behavior in response to social stimuli, we also summarize recent single administration studies examining the effects of testosterone on physiology, neurobiology, and behavior. A conceptual model provides links between supported findings, and hypothesized pathways requiring future testing.

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.

Testosterone administration in females modulates moral judgment and patterns of brain activation and functional connectivity

Morality is defined as prescriptive norms regarding how people should treat one another, and includes concepts of fairness, justice, and rights. One recent study with moral dilemmas suggested that testosterone administration increases utilitarian judgments, which depends on second-to-fourth (2D: 4D) digit ratio, as a proxy of prenatal priming. However, the neural mechanism by which acute testosterone modulates moral reasoning remains to be determined. Using a placebo-controlled within-subject design, the current study examined the neuromodulatory effect of testosterone in young females by combining moral dilemmas, 2D: 4D, functional magnetic resonance imaging (fMRI), and subjective ratings of morally laden scenarios. Results showed that testosterone administration elicited more utilitarian responses to evitable dilemmas. The high 2D: 4D group scored more punishments for moral evaluation, whereas the low 2D: 4D group did the opposite. The activity in the amygdala, anterior insular cortex, and dorsolateral prefrontal cortex (dlPFC) was increased when participants evaluated morally unorthodox actions (intentional harm). The activity in the posterior superior temporal sulcus/temporoparietal junction (pSTS/TPJ) to accidental harm was decreased, specific to the high 2D: 4D group. The functional connectivity between the amygdala and dlPFC was reduced. The activity in the pSTS/TPJ to perceived agency predicted utilitarian responses to evitable dilemmas. The findings demonstrate the acute effect of testosterone on neural responses associated with moral judgment, and provide evidence to support that prenatal sex-hormones priming could be important for early neurodevelopment, which plays a crucial role in the neural and behavioral manifestations of testosterone on adult moral reasoning. Hum Brain Mapp 37:3417-3430, 2016. © 2016 Wiley Periodicals, Inc.

Testosterone and cortisol in relation to aggression in a non-clinical sample of boys and girls

Testosterone and cortisol have been proposed to jointly regulate aggressive behavior. However, few empirical studies actually investigated this joint relation in humans, and reported inconsistent findings. Also, samples in these studies were small and/or specific, and consisted largely of males. Therefore, in the current study testosterone and cortisol in relation to aggression were investigated in a non-clinical sample of 259 boys and girls (mean age 16.98 years, SD = 0.42, 56% boys). A positive testosterone/cortisol ratio, that is, high testosterone relative to cortisol, was found to be associated with aggressive behavior, explaining 7% of the variance. The interaction between testosterone and cortisol was not related to aggressive behavior and gender differences were not found. The ratio may reflect an imbalance leaving the individual more prone to rewarding aspects, than fearful of negative implications of aggressive behavior. Current findings indicate that this relation can be generalized to aggression in non-clinical adolescents.

Testosterone modulates preattentive sensory processing and involuntary attention switches to emotional voices

Testosterone is capable of altering facial threat processing. Voices, similar to faces, convey social information. We hypothesized that administering a single dose of testosterone would change voice perception in humans. In a placebo-controlled, randomly assigned, double-blind crossover design, we administered a single dose of testosterone or placebo to 18 healthy female volunteers and used a passive auditory oddball paradigm. The mismatch negativity (MMN) and P3a in responses to fearfully, happily, and neutrally spoken syllables dada and acoustically matched nonvocal sounds were analyzed, indicating preattentive sensory processing and involuntary attention switches. Results showed that testosterone administration had a trend to shorten the peak latencies of happy MMN and significantly enhanced the amplitudes of happy and fearful P3a, whereas the happy- and fearful-derived nonvocal MMN and P3a remained unaffected. These findings demonstrated acute effect of testosterone on the neural dynamics of voice perception. Administering a single dose of testosterone modulates preattentive sensory processing and involuntary attention switches in response to emotional voices.

Sex difference in the relationship between salivary testosterone and inter-temporal choice

Humans often prefer a small immediate reward to large reward in the future. This myopic tendency in inter-temporal choice is termed delay discounting, and has been the focus of intensive research in the past decades. Recent studies indicate that the neural regions underlying delay discounting are influenced by the gonadal steroids. However, the specific relationship between the testosterone levels and delay discounting is unclear at this point, especially in females. The present study investigated the relationship between salivary testosterone concentrations and discounting rates in delay- and probability-discounting tasks with healthy males and females. The results revealed a positive correlation between testosterone concentrations and delay-discounting rates in females and a negative correlation in males. Testosterone concentrations were unrelated to probability-discounting rates. Although causal effects of testosterone cannot be certain in this correlational study, if testosterone directly influenced this behavior, observed sex differences in delay discounting may be evidence of a curvilinear effect of testosterone. Alternatively, the findings may reflect inverse pattern of responsiveness to testosterone between male and female neural systems, or basic sex-difference in the neural mechanism underlying delay-discounting independent of testosterone itself.

Differential effects of site-specific knockdown of estrogen receptor α in the medial amygdala, medial pre-optic area, and ventromedial nucleus of the hypothalamus on sexual and aggressive behavior of male mice

Testosterone is known to play an important role in the regulation of male-type sexual and aggressive behavior. As an aromatised metabolite of testosterone, estradiol-induced activation of estrogen receptor α (ERα) may be crucial for the induction of these behaviors in male mice. However, the importance of ERα expressed in different nuclei for this facilitatory action of testosterone has not been determined. To investigate this issue, we generated an adeno-associated virus vector expressing a small hairpin RNA targeting ERα to site-specifically knockdown ERα expression. We stereotaxically injected either a control or ERα targeting vector into the medial amygdala, medial pre-optic area (MPOA), or ventromedial nucleus of the hypothalamus (VMN) in gonadally intact male mice. Two weeks after injection, all mice were tested biweekly for sexual and aggressive behavior, alternating between behavior tests each week. We found that suppressing ERα in the MPOA reduced sexual but not aggressive behavior, whereas in the VMN it reduced both behaviors. Knockdown of ERα in the medial amygdala did not alter either behavior. Additionally, it was found that ERα knockdown in the MPOA caused a parallel reduction in the number of neuronal nitric oxide synthase-expressing cells. Taken together, these results indicate that the testosterone facilitatory action on male sexual behavior requires the expression of ERα in both the MPOA and VMN, whereas the testosterone facilitatory action on aggression requires the expression of ERα in only the VMN.

A review on the relationship between testosterone and the interpersonal/affective facet of psychopathy

Testosterone (T) has received increasing interest in the recent years as a probable biological determinant in the etiology of male-biased clinical conditions such as psychopathy (i.e. psychopathy is more prevalent in men and leads to an earlier onset and more severe expression of antisocial and aggressive behavior in men compared to women). In this review, the authors evaluated the potential relationship between T and different constructs closely related to the core characteristics of psychopathy (affective empathy, fear-reactivity, and instrumental aggression). After a thorough examination of the literature, it is concluded that high T exposure in utero and high circulating T levels throughout important life phases (most notably adolescence) or in response to social challenges (e.g. social stress, competition) could be an important etiological risk factor in the emergence of psychopathic behavior. Nevertheless, studies consistently indicate that high T is not related to a significantly reduced fear-reactivity and is only indirectly associated with the increased levels of instrumental aggression observed in psychopathic individuals. Therefore, psychopathy is likely to arise from an interaction between high T levels and other biological and socio-psychological risk factors, such as a constitutionally based dampened fear-reactivity, insecure/disordered attachment processes in childhood, and social discrimination/rejection in adolescence and/or adulthood.

Cross-frequency coupling of brain oscillations in studying motivation and emotion

Research has shown that brain functions are realized by simultaneous oscillations in various frequency bands. In addition to examining oscillations in pre-specified bands, interactions and relations between the different frequency bandwidths is another important aspect that needs to be considered in unraveling the workings of the human brain and its functions. In this review we provide evidence that studying interdependencies between brain oscillations may be a valuable approach to study the electrophysiological processes associated with motivation and emotional states. Studies will be presented showing that amplitude-amplitude coupling between delta-alpha and delta-beta oscillations varies as a function of state anxiety and approach-avoidance-related motivation, and that changes in the association between delta-beta oscillations can be observed following successful psychotherapy. Together these studies suggest that cross-frequency coupling of brain oscillations may contribute to expanding our understanding of the neural processes underlying motivation and emotion.

Socially explosive minds: the triple imbalance hypothesis of reactive aggression

The psychobiological basis of reactive aggression, a condition characterized by uncontrolled outbursts of socially violent behavior, is unclear. Nonetheless, several theoretical models have been proposed that may have complementary views about the psychobiological mechanisms involved. In this review, we attempt to unite these models and theorize further on the basis of recent data from psychological and neuroscientific research to propose a comprehensive neuro-evolutionary framework: The Triple Imbalance Hypothesis (TIH) of reactive aggression. According to this model, reactive aggression is essentially subcortically motivated by an imbalance in the levels of the steroid hormones cortisol and testosterone (Subcortical Imbalance Hypothesis). This imbalance not only sets a primal predisposition for social aggression, but also down-regulates cortical-subcortical communication (Cortical-Subcortical Imbalance Hypothesis), hence diminishing control by cortical regions that regulate socially aggressive inclinations. However, these bottom-up hormonally mediated imbalances can drive both instrumental and reactive social aggression. The TIH suggests that reactive aggression is differentiated from proactive aggression by low brain serotonergic function and that reactive aggression is associated with left-sided frontal brain asymmetry (Cortical Imbalance Hypothesis), especially observed when the individual is socially threatened or provoked. This triple biobehavioral imbalance mirrors an evolutionary relapse into violently aggressive motivational drives that are adaptive among many reptilian and mammalian species, but may have become socially maladaptive in modern humans.

Testosterone and unconscious positive priming increase human motivation separately

Clinical observations suggest that testosterone generates unconscious broad-spectrum motivations to act. It has also been suggested that subliminal positive-priming techniques also unconsciously enhances motivation for action. This placebo-controlled study examined the separate and possible joint contributions of these assumed unconscious sources of human motivation. Healthy females were administered 0.5 mg sublingual testosterone or placebo. Next, they were subliminally primed with action concepts that were paired with positive or neutral cues, and indicated their motivation for the respective action. Testosterone and positive priming both increased the motivation for action, but there was no joint contribution. Possibly, testosterone pushed the motivational brain system to a limit allowing no add-on contribution by priming, but our data also agree with neuroimaging evidence showing that the neural (subcortical and cortical) pathways of motivation can be functionally disconnected by testosterone administration.

The testosterone-cortisol ratio: A hormonal marker for proneness to social aggression

Social aggression is an escalating hazard for individuals and society. It is most frequently observed as impulsive-reactive aggression in antisocial personality disorder (APD), but in psychopathic aggressive personalities instrumental social aggression is more prominent. However, the psychobiological mechanisms underlying human social aggression are still poorly understood. Here we propose a psychobiological mechanism that may explain human social aggression wherein the steroid hormones cortisol and testosterone play a critical role. High levels of testosterone and low levels of cortisol have been associated with social aggression in several species but it seems that in those individuals wherein these hormonal markers combine social aggression is most violent. In this review we discuss fundamental and clinical research which underscores the potential of the testosterone-cortisol ratio as a possible marker for criminal aggressive tendencies.

Testosterone administration reduces empathetic behavior: a facial mimicry study

Although high baseline testosterone levels correlate with low empathy, there is no causal evidence for this association in humans. The present study tested the causality of this relationship by manipulating testosterone levels in a double-blind placebo controlled crossover design. 20 healthy female participants received either a sublingual administration of a single dose of testosterone or placebo on 2 days and were tested 4 h after administration. Because research has shown that facial expression mimicry is a non-obtrusive index of empathy, facial electromyography was measured in response to dynamic facial expressions of happy and angry faces. Results showed that testosterone generally decreased facial mimicry. These findings are consistent with models that assign a critical role to mimicry in the ability to develop and communicate empathy towards conspecifics, and provide a potential causal mechanism of effects of testosterone on empathy.

Unmasking feigned sanity: a neurobiological model of emotion processing in primary psychopathy

INTRODUCTION

The neurobiological basis of primary psychopathy, an emotional disorder characterised by a lack of fear and empathy, on the one hand, and extremely violent, antisocial tendencies, on the other, is relatively unknown. Nevertheless, theoretical models that emphasise the role of fearlessness, imbalanced motivation, defective somatic markers, and dysfunctional violence inhibition mechanisms have complementary proposals regarding motivations and brain mechanisms involved.

METHODS

Presently, incorporating the heuristic value of these models and further theorising on the basis of recent data from neuropsychology, neuroendocrinology, neuroimaging, and repetitive transcranial magnetic stimulation (rTMS), an attempt is made to construct a neurobiological framework of emotion processing in primary psychopathy with clinical applicability.

RESULTS

According to this framework, defective emotional processing in primary psychopathy results from bottom-up hormone-mediated imbalances at: (1) the subcortical level; (2) in subcortico-cortical "cross-talk"; that end up in an instrumental stance at the cortical level (3). An endocrine dual-system approach for the fine-tuned restoration of these hormone-mediated imbalances is proposed as a possible clinical application.

DISCUSSION

This application may be capable of laying a neurobiological foundation for more successful sociotherapeutic interventions in primary psychopathy.

Electrophysiological correlates of cortico-subcortical interaction: A cross-frequency spectral EEG analysis

OBJECTIVE

Several studies have provided evidence for the notion that the coupling between slow and fast frequency in the EEG spectrum indicates cortico-subcortical cross-talk (CSC-ct). In addition, findings for increased limbic activation due to reduced cortical inhibition have recently been acquired. To get further insights into these mechanisms, the current study investigated whether CSC-ct would decrease as a function of increased slow (SW) or fast wave (FW) activity.

METHODS

Resting state EEG recordings were obtained from 46 healthy, right-handed participants. CSC-ct was quantified by computing cross-frequency correlations between the power in the slow and fast frequency range. CSC-ct was compared between groups with relatively low and high SW activity and groups with relatively low and high FW activity.

RESULTS

Relatively reduced SW, but not FW activity was associated with a significant coupling between slow and fast frequency EEG. Furthermore, relatively enhanced resting state SW activity was paralleled by slow and fast frequency EEG decoupling.

CONCLUSIONS

These findings are in line with the notion that increased subcortical drive can go accompanied by reduced CSC-ct.

SIGNIFICANCE

Cross-frequency EEG analyses might provide a unique approach to obtain novel insights into cortico-subcortical interactions in relation to affective and cognitive behavior.

Neuroendocrine and behavioral development during puberty: a tale of two axes

Puberty is marked by dramatic changes in neuroendocrine function. These changes have profound effects on the structure and function of the maturing nervous system, resulting in altered physiological and behavioral potentials in the adult organism. Indeed, the changes in neurobehavioral development during puberty rival those occurring during neonatal development. This review discusses the pubertal maturation of the hypothalamic-pituitary-gonadal and hypothalamic-pituitary-adrenal axes; specifically, how the pubertal rise in gonadal hormones influences the development of various steroid-dependent motivated behaviors in adulthood, as well as the differences in stress reactivity in prepubertal and adult animals. We conclude that puberty represents another significant and perhaps critical period of neurobehavioral development. Furthermore, we suggest that perturbations of the developing nervous system during this period of maturation may result in deleterious outcomes in the future physiological and behavioral function of an individual on reaching adulthood.

Ontogeny of bidirectional connections between the medial nucleus of the amygdala and the principal bed nucleus of the stria terminalis in the rat

Nuclei in the amygdala and bed nuclei of the stria terminalis (BST) form functionally organized units that are linked by topographically organized connections. The posterodorsal part of the medial nucleus of the amygdala (MEApd) and the principal nucleus of the BST (BSTpr) share strong birectional connections that project primarily through the stria terminalis. The presence of structural and neurochemical sexual dimorphisms in both the MEApd and BSTpr suggests that connections between the nuclei may develop during the postnatal critical period for sexual differentiation. In this study, 1,1'dioctadecyl-3,3,3'-tetramethylindocarbocyanine perchlorate (DiI) axonal labeling was used to define the ontogeny of this bidirectional pathway. Placement of DiI crystals into the MEApd of rats perfused on embryonic day (E) 20 resulted in DiI-labeled fibers with axonal morphology in the BSTpr, but similar labeling was not evident in the MEApd until after birth. However, as early as E14, tracer implants into the caudal MEA (the presumptive MEApd) labeled elongated cellular processes in the region of the stria terminalis that extended into the presumptive BSTpr. Based on the correspondence of these DiI-labeled processes with immunostaining for vimentin, these cellular processes are probably derived from glial cells. Implants of DiI into the posterior BST also labeled cellular processes that extended through the medial part of the stria terminalis, but they remained confined to the molecular layer of the MEApd from E14 through P1. Labeled axons derived from the BSTpr were not observed in the MEApd until P5, demonstrating that the bidirectional connections that exist between the MEApd and BSTpr in mature rats do not develop simultaneously. The density of connections between the BSTpr and MEApd increased during the postnatal period and was similar to that of adults by P15. These findings suggest that projections from the MEApd through the stria terminalis to the BSTpr may be specified initially by a glial substrate and that return projections to the amygdala from the BSTpr develop secondary to its innervation by the MEApd.

Testosterone reduces unconscious fear but not consciously experienced anxiety: implications for the disorders of fear and anxiety

BACKGROUND

The fear-reducing properties of testosterone have been firmly established in animals but not in humans. However, human data on the relation between testosterone, fear, and anxiety have predominantly involved questionnaires that index cortically executed conscious appraisal of anxious mood. Animal studies, on the other hand, indicate that the effects of testosterone on motivation and emotion are of subcortical origin and of unconscious nature. Presently, it was hypothesized that a single testosterone administration to humans would reduce unconscious fear but not consciously experienced anxiety.

METHODS

In a placebo-controlled, double-blind crossover design, a single dose of testosterone (.5 mg) or placebo was administered to 16 healthy female volunteers. Afterward, a masked emotional Stroop task measured unconscious emotional responses to fearful faces, while multiple self-reports of mood indexed consciously experienced anxiety.

RESULTS

As hypothesized, the habitual vigilant emotional response to the masked fearful face observed in the placebo condition was significantly reduced after testosterone was administered, while the self-reported measures of anxiety remained unaffected.

CONCLUSIONS

These data provide the first direct evidence for fear-reducing properties of testosterone in humans. Furthermore, by dissociating specific aspects of fear and anxiety in humans, this outcome highlights that testosterone's effects on motivation and emotion concern the subcortical affective pathways of the brain.

Testosterone shifts the balance between sensitivity for punishment and reward in healthy young women

Animal research has demonstrated reductions in punishment sensitivity and enhanced reward dependency after testosterone administration. In humans, elevated levels of testosterone have been associated with violent and antisocial behavior. Interestingly, extreme forms of violent and antisocial behavior can be observed in the psychopath. Moreover, it has been argued that reduced punishment sensitivity and heightened reward dependency are crucially involved in the etiology and maintenance of psychopathy. A task that has been proven to be capable of simulating punishment-reward contingencies is the IOWA gambling task. Decisions to choose from decks of cards become motivated by punishment and reward schedules inherent in the task. Importantly, clinical and subclinical psychopaths demonstrate a risky, disadvantageous pattern of decision-making in the task, indicating motivational imbalance (insensitivity for punishment and enhanced reward dependency). Here, in a double-blind placebo-controlled crossover design (n = 12), whether a single administration of testosterone would shift the motivational balance between the sensitivity for punishment and reward towards this tendency to choose disadvantageously was investigated. As hypothesized, subjects showed a more disadvantageous pattern of decision-making after testosterone compared to placebo administration. These findings not only provide the first direct evidence for the effects of testosterone on punishment-reward contingencies in humans, but they also give further insights into the hypothetical link between testosterone and psychopathy.

Low cortisol levels and the balance between punishment sensitivity and reward dependency

The neuro-endocrinological basis of psychopathy, a disorder characterized by lack of fear, is relatively unknown. However, low levels of cortisol may result in fearlessness and have been observed in individuals with psychopathic tendencies. Low fear models state that psychopaths are not motivated to avoid punishment, especially when reward is pending. In agreement, disadvantageous decision making on the IOWA gambling task in psychopaths and psychopathic analogous, indicates low punishment sensitivity and high reward dependency. Here, it was investigated whether low basal cortisol levels predicted the balance between punishment sensitivity and reward dependency in the same manner. As hypothesized, the most disadvantageous pattern of decision making was found in the subjects with the lowest cortisol levels. These findings suggest that low levels of cortisol may set the balance between the sensitivity for punishment and reward dependency towards a pre-disposition for psychopathy.

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.

Estradiol induces hypothalamic progesterone receptors but does not activate mating behavior in male hamsters (Mesocricetus auratus) before puberty

This study investigated pubertal changes in neural and behavioral responses to estradiol. Gonadectomized pre- and postpubertal male hamsters (Mesocricetus auratus) were treated with 0.00, 0.05, 0.10, or 0.25 mg estradiol and tested 1 week later for sexual behavior with a receptive female. Estradiol activated behavior in postpubertal, but not prepubertal, males. In contrast, estrogen receptor alpha (ERalpha) and progesterone receptor (PR) immunoreactivity in forebrain nuclei that mediate mating behavior was similar in pre- and postpubertal males. Thus, absence of a behavioral response before puberty is not associated with reduced levels of steroid receptors. Because estradiol induced PR in prepubertal males, these data also suggest that ERa is functional before puberty. Therefore, gonadal steroids facilitate male reproductive behavior only after as-yet-unidentified developmental processes occur during puberty.

Antifertility effects of estradiol in adult male rats

The dose-related effects of estradiol 17-beta at the doses 0.1 pg, 10 microg, 100 microg, 200 microg, 300 microg, 400 microg, 1,000 microg/kg/day were determined on sperm motility, potency, fertility parameters, serum levels of LH, FSH, PRL and testosterone, weights of testes and accessory sex organs, weights of pituitary and adrenal glands. The drug was administered daily via sc route for a period of 60 days. Dose-related effects on fertility parameters of the estradiol-treated male rats were ascertained by allowing them to mate with normal cycling female rats. Estradiol at 0.1 microg/kg/day dose significantly reduced sperm motility with no effects seen on potency or fecundity, serum LH, FSH, PRL or testosterone, weights of testes and accessory sex organs while pituitary weight increased. Estradiol at 10 microg/kg/day dose significantly reduced motility, serum LH, FSH, weights of testes and accessory sex organs, while pituitary weight increased with no effects seen on potency, fecundity, PRL or testosterone. Estradiol at 100-1,000 microg/kg/day dose significantly reduced motility, potency and fecundity, serum LH, FSH and testosterone, weights of testes and accessory sex organs while serum PRL and the weights of pituitary and adrenal glands increased significantly. Histology of the testes revealed disorganization of the cytoarchitecture in the seminiferous tubules, vacuolation, absence of lumen and compartmentalization of spermatogenesis. Estradiol withdrawal, testosterone propionate at 100 pg/kg/day or antiestrogen (tamoxifen citrate) at 400 microg/kg/day prevented the histological changes. It is conduded that estradiol reduces sperm motility even at a low dose. Low doses (<10 microg/kg/ day) appear to maintain whilst high doses (>10 microg/kg/day) reversibly disrupt spermatogenesis. Prevention of disruption by testosterone or antiestrogen indicates crosstalk between androgen and estrogen receptors in Sertoli cells. Loss of potency and fecundity also suggests effects on crosstalk between these receptors in other male reproductive organs.

Dihydrotestosterone activates sexual behavior in adult male hamsters but not in juveniles

The effect of an androgenic metabolite of testosterone, dihydrotestosterone (DHT), on reproductive behavior and brain androgen receptor (AR) immunoreactivity was compared in juvenile and adult male Syrian hamsters. Prepubertal and adult animals were castrated and treated with 0, 500, or 1000 microg of DHT daily for 1 week and then tested for their ability to engage in mating behavior. The 1000-microg dose of DHT activated intromissions in adult but not prepubertal males. Brains were collected immediately after the behavioral test to investigate whether the lack of a behavioral response to DHT prior to puberty is associated with fewer AR-immunoreactive (AR-ir) cells in the forebrain nuclei that mediate male sexual behavior. In four of the five nuclei within the behavioral circuit that were examined, the number of AR-containing cells was similar in prepubertal and adult males treated with 1000 microg of DHT. Only in the anterior medial amygdala (MeA) was there a greater number of AR-ir cells in adults. These data indicate that (1) DHT does not activate components of male reproductive behavior prior to puberty and (2) the lack of behavioral responsiveness to DHT in prepubertal males is most likely not related to an overall reduction in ARs within the forebrain circuit that mediates mating behavior.

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.

Pubertal and seasonal plasticity in the amygdala

The present experiments investigated the effects of pubertal maturation and photoperiod on the size of brain regions that mediate mating behavior in the male Syrian hamster. We hypothesized that the low levels of reproductive behavior exhibited by prepubertal and photoinhibited males would be correlated with morphological changes in the neural circuit that mediates mating behavior. We found that the Nissl-stained cross-sectional area of the posterodorsal subdivision of the medial amygdala was significantly smaller in prepubertal and photoinhibited males compared to photostimulated adult males. These differences appear to be caused by a decrease in somal size of individual cells in the ventral aspect of this nucleus. We also found that prepubertal males have a larger anterior subdivision of the medial amygdala (MeA) compared to adults. This difference in the MeA does not appear to be caused by alteration in somal size since somal size did not differ significantly between juveniles and adults. It is concluded that the neural circuit that mediates male mating behavior in this species is capable of significant morphological plasticity during both pubertal development and in adulthood. Furthermore, these alterations may reflect underlying mechanisms of the deficits in sexual behavior exhibited by prepubertal and photoinhibited males.

Lesions to the medial preoptic area affect singing in the male European starling (Sturnus vulgaris)

The aromatization of testosterone (T) in the medial preoptic nucleus (POM) is known to regulate male courtship and sexual behaviors expressed prior to, and in anticipation of, copulation. Singing in male European starlings is used to attract mates prior to physical sexual contact, suggesting that the POM might be involved. The present study was performed to examine the effects of lesions targeting the POM on singing and courtship behavior in reproductively active male starlings. A significant decrease in song output and the gathering of green nest materials was observed in males with lesions to the POM compared to males with damage to brain areas outside of the POM. Lesions did not affect a male's tendency to remain near a female or to occupy a nestbox, suggesting that the effects of POM lesions were specific to courtship behaviors. Behavioral differences were not related to testis mass or volume, and GnRH immunoreactivity was observed within the hypothalamus and median eminence for each male, suggesting that the effects of POM lesions were related specifically to POM involvement in song expression rather than to a disruption of the GnRH axis. These results suggest a general role for the POM in the expression of behaviors related to sexual arousal or anticipation, including song.

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.

Effects of brain testosterone implants on appetitive and consummatory components of male sexual behavior in Japanese quail

Aromatization of testosterone (T) into an estrogen is necessary for the activation of consummatory and appetitive sexual behavior in male Japanese quail. T action within the medial preoptic nucleus (POM) is necessary and sufficient to activate consummatory behavior, and some evidence suggests that POM might be involved in the control of appetitive behavior, but other brain regions, such as the bed nucleus of the stria terminalis (BST), an area that contains a dense population of aromatase-immunoreactive neurons, are also likely to be involved. This study was performed to assess the effects of stereotaxic T implants targeting either the POM or the BST on the activation of both components of sexual behavior in castrated male quail. Appetitive sexual behavior was measured by an acquired social proximity response in which a male will approach a window providing visual access to a female after the window has been repeatedly paired with physical access to a female and the possibility to freely interact with her. Rhythmic cloacal sphincter movements that are produced by the male when given visual access to a female were used as another measure of appetitive sexual behavior that does not appear to depend on sexual learning. The experiments confirmed that copulation is necessary for males to develop the social proximity response that is used to measure the appetitive sexual behavior. T implants in the POM activated both components of sexual behavior, suggesting that these components cannot be completely dissociated. In contrast, T implants located within the BST did not affect either component, but because implants in the BST did not activate copulatory behavior, these results do not preclude a role for BST in the expression of a previously acquired appetitive 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.

Androgens and male sexual behavior from mice to men

Exogenous androgenic hormones or drugs that affect endogenous androgen levels are now used in a variety of human applications [cf. Bardin et al. (1991)]. Therefore, an increasing number of well-controlled physiological, clinical, and psychological studies have examined the effects of androgens on muscle, prostate, lipids, and bone, as well as the cardiovascular, immune, and nervous systems. The increasing number of androgens and delivery systems that are currently available or under development should also increase the prevalence of androgen therapy (Table 1). As androgen use increases, a crucial area of research is the effect of androgens on sexual behavior, which encompasses sexual desire, motivation, performance, and satisfaction. There is a large body of animal data documenting hormonal regulation of male sexual behavior and the neural sites of action of these hormones. Clinical data on the effects of androgens on human male sexuality come from correlative studies of endogenous testosterone levels and sexual function, treatment of men who are testosterone deficient, and men using hormonal contraceptives.

Steroid regulation of sexual behavior

Investigation into the hormonal control of sexual behavior has a rich and extensive history. For many researchers currently active in the field, the physiological psychologist Frank A. Beach is recognized as the modern father of the study of hormones and behavior. His publication of the seminal book Hormones and Behavior-A Survey of Interrelationships Between Endocrine Secretions and Patterns of Overt Response, published in 1948, was a compilation of the previous 20 years of research establishing that gonadal secretions acted in the brain and modulated behavior. The question of precisely how hormones can alter brain functioning in a coordinated fashion and profoundly influence the patterns of behavioral responsiveness remains unanswered. As with many research areas, application of new techniques and approaches to the problem reveals additional layers of complexity and previously unimagined relationships between hormones, brain, and behavior. In addition, with the increasing understanding that the brain is a target organ for steroids, the implications of the ramifications of this steroid sensitivity have broadened. The hormonal regulation of sexual behavior is not an isolated aspect of steroid action in the brain; rather, it is one component of a host of physiological responses influenced by steroids. These include such diverse responses as anxiety, aggression, feeding, and learning and memory. An appreciation of the diverse effects of steroids has emerged from studies on sexual behavior, and a mutually beneficial relationship between this and other aspects of behavioral neuroscience has flourished and endured. As with all of neuroscience, this research area has been dynamic and progressive and has additionally benefited from a long history of comparative and integrative approaches to animal behavior.