Independent control of sexual and scent marking behaviors of male gerbils by cells in or near the medial preoptic area

Of mice and missing data: what we know (and need to learn) about male sexual behavior

With recent advances in molecular genetics, the popularity of mice as subjects for behavioral neuroscience is increasing at an exponential rate. Unfortunately, the existing body of knowledge on sexual behavior in male mice is not large and many basic gaps exist. The assumption that what is true of rats is also true of mice is a dangerous one that can misdirect and, in the worst case, impede progress. We summarize the current knowledge about the sexual behavior of male mice, with an emphasis on hormonal bases of these behaviors. Behavioral differences between strains, developmental actions of steroids, activational actions of steroids given peripherally and in the brain, and data generated in various receptor knockout and related mice are discussed. In addition, suggestions are made for the standardization of experimental protocols used in investigations of the sexual physiology and behavior of male mice in order to facilitate between-experiment and between-laboratory comparisons and to expedite the growth of knowledge in this area.

Intracranial androgenic activation of male-typical behaviours in house mice: concurrent stimulation of the medial preoptic area and medial nucleus of the amygdala

This experiment examined whether testosterone proprionate (T) action in the medial preoptic area (MPO) would synergize with T action in the medial nucleus of the amygdala (AME) for the expression of androgen-dependent behaviors in house mice. Cannulae containing T were bilaterally implanted into the MPO, the AME, or both areas concurrently (MPO/AME) of castrated males. In addition, other castrates were implanted subcutaneously with empty Silastic capsules (BSIL) or Silastic capsules containing T (TSIL). All subjects were examined for the following androgen-dependent, male-typical behaviors: mounting, urinary scent marking, preference for female urine over male urine, preference for female over male conspecifics and ultrasonic mating vocalizations. MPO implants restored ultrasonic vocalizations and preference for females, but had little or no effect upon urine marking, mounting or preference for female urine. In contrast, AME implants were ineffective at restoring any of these male-typical behaviors. The combined MPO/AME implants were not more effective in restoring male-typical behaviors than MPO implants alone, thus providing no evidence for synergy in hormone action between these two brain areas. In general, castration (BSIL) resulted in low levels of all behaviors whereas systemic T replacement (TSIL) resulted in high levels of behavior, verifying the androgen-dependence of these behaviors. Group differences in male-typical behavior could not be accounted for by differences in general activity levels. Moreover, none of the brain-implanted groups had larger seminal vesicles than those of the BSIL. Thus, when the brain implants affected behavior, they most probably did so through their effects within the brain. Although the AME is a target for steroid hormones and is an important area for the expression of male-typical behaviors, intracranial T implants into the AME did not demonstrate a role for androgen in the AME in restoring male-typical behaviors in castrated mice.

Implications of immediate-early gene induction in the brain following sexual stimulation of female and male rodents

Induction of immediate-early genes (IEGs), such as c-fos, has been widely used to mark the activation of brain regions following different types of sexual stimulation and behavior. A relatively common set of hormone-concentrating basal forebrain and midbrain structures in female and male rodents is activated by copulatory stimulation, in particular, stimulation of sensory nerves that innervate the penis or vagina/cervix, olfactory or pheromonal stimuli, and conditioned sexual incentives. These regions include the preoptic area, lateral septum, bed nucleus of the stria terminalis, paraventricular hypothalamus, ventromedial hypothalamus, medial amygdala, ventral premammillary nuclei, ventral tegmentum, central tegmental field, mesencephalic central gray, and peripeduncular nuclei. Regions that do not contain classic intracellular steroid receptors, such as the ventral and dorsal striatum or cortex, are also activated. IEGs have also been colocalized with cytoplasmic proteins like GnRH and oxytocin, and have been used in conjunction with retrograde tracers to reveal functional pathways associated with different sexual behaviors. Steroid hormones can also alter the ability of sexual stimulation to induce IEGs. Despite the many similarities, some differences in IEG induction between sexes have also been found. We review these findings and raise the question of what IEG induction in the brain actually means for sexual behavior, that is, whether it indicates the perception of sexual stimulation, commands for motor output, or the stimulation of a future behavioral or neuroendocrine event related to the consequences of sexual stimulation. To understand the role of a particular activated region, the behavioral or neuroendocrine effects of lesions, electrical stimulation, drug or hormone infusions, must also be known.

Motoneurons dorsolateral to the central canal innervate perineal muscles in the Mongolian gerbil

The Mongolian gerbil provides a model in which sexually dimorphic areas in the hypothalamus are correlated with sociosexual behaviors such as scent marking and male copulatory behavior. To extend this model, investigations were conducted to determine whether sexually dimorphic areas existed in the spinal cord that could be relevant to male sexual behavior. The focus of these investigations was the perineal muscles associated with the penis. Therefore, this research identified the spinal motoneurons that innervate the bulbocavernosus, levator ani, anal sphincter, and ischiocavernosus muscles of Mongolian gerbils. The motoneuron pool that innervates the bulbocavernosus, levator ani, and anal sphincter was designated the spinal nucleus of the bulbocavernosus (SNB), as for other species of rodents. The motoneuron pool innervating the ischiocavernosus was identified as the dorsolateral nucleus, again, to be consistent with the designation for other rodents. The motoneurons of the gerbil SNB were distributed dorsolateral to the central canal in the lumbosacral transition zone of the spinal column. These motoneurons are located in the region classically defined as area X of the spinal cord. The number of SNB motoneurons was sexually dimorphic, with male gerbils having about five times as many SNB motoneurons as do female gerbils. The size of SNB motoneurons was also sexually dimorphic. The SNB motoneurons of males were 1.5 times larger than the SNB motoneurons of females. The effects of adult castration on the male SNB were also studied. After castration, the size, but not the number, of SNB motoneurons in males was significantly decreased. This decrease was prevented by testosterone treatment. The percentage of calcitonin gene-related peptide (CGRP)-immunoreactive SNB motoneurons was also affected by adult castration. The percentage of CGRP-immunoreactive motoneurons was significantly decreased after adult castration. Again, this decrease was reversed by testosterone treatment. These findings suggest that the SNB of gerbils is sexually dimorphic and is sensitive to circulating levels of gonadal steroids. The unique placement of the SNB motoneurons suggests that an alternative laminar organizational scheme may be necessary for Mongolian gerbil.

Intracranial androgenic activation of male-typical behaviors in house mice: motivation versus performance

Castrated male mice were bilaterally implanted with 27 ga cannulae containing testosterone into either the septum, medial preoptic area (MPO), or corticomedial amygdala. One additional group of castrates received no hormone and another received only systemic testosterone via subcutaneous silastic capsules. All males were subsequently tested for ultrasonic mating vocalizations, urine marking, mounting behavior, aggression and gender preference, all of which are androgen-dependent, male-typical behaviors. In general castrates receiving no hormone performed these behaviors at low levels and animals receiving systemic testosterone performed the behaviors at normal male-typical levels. Ultrasonic vocalizations in response to female urine were activated by MPO implants. Urine marking in response to female urine appeared to be partially activated only with MPO implants. Very little mounting or fighting were seen in the brain implanted groups. Gender preference (for females over males) was restored with MPO implants and appeared to be partially activated with septal implants. The seminal vesicles of the castrates receiving brain implants were not significantly different from those receiving no hormone indicating that little or no implanted hormone was exiting the brain into general circulation. The implications of these findings for the neuroanatomy of sexual motivation and performance are discussed.

Efferent projections of the sexually dimorphic area of the gerbil hypothalamus: anterograde identification and retrograde verification in males and females

Outputs of the sexually dimorphic area (SDA) of the gerbil hypothalamus were identified by injecting Phaseolus vulgaris-leucoagglutinin into the medial or lateral SDA (mSDA, lSDA) in males and females. They were verified by injecting Fluoro-Gold or rhodamine-labeled beads into over half the areas that contained labeled fibers. Both anterograde and retrograde tracing showed that the mSDA and lSDA project to many of the same sites but often to differing degrees. The mSDA projects more heavily than the lSDA to many of their forebrain targets including the ventral part of the lateral septal nucleus, the bed nucleus of the stria terminalis, the medial tuberal area, and the anteroventral periventricular, arcuate, ventromedial and ventral premammillary nuclei of the hypothalamus. The lSDA projects more heavily than the mSDA to many of their mid- and hindbrain targets including the caudal, ventrolateral part of the periaqueductal gray, the retrorubral field, the pedunculopontine tegmental nucleus, and the locus coeruleus. In many other areas of the brain, the projections of the mSDA and lSDA are similar in size. These areas include the substantia innominata, the vascular organ of the lamina terminalis, the anterior amygdala, the posterior hypothalamus, the reuniens and paraventricular nuclei of the thalamus, and the pontine periaqueductal gray lateral to the fourth ventricle. The SDA pars compacta (SDApc), a small cell group embedded in the mSDA of males, projects to many fewer areas than the surrounding mSDA. It was strongly labeled when retrograde tracers were injected into the encapsulated part of the bed nucleus of the stria terminalis, the anteroventral periventricular nucleus, or the mSDA. It was also labeled from the vascular organ of the lamina terminalis, the caudal part of the lateral bed nucleus of the stria terminalis, the lSDA, the area lateral to the mSDA, the arcuate nucleus, the ventral premammillary nucleus, and the ventrolateral part of the ventromedial nucleus of the hypothalamus. Nothing resembling an SDApc was identified during retrograde tracing in females.

Ontogeny of the sexually dimorphic area of the gerbil hypothalamus

The sexually dimorphic area (SDA) of the gerbil hypothalamus is a set of cell groups in the medial preoptic area that is essential for masculine sexual behavior and implicated in the hormonal control of scent making and ultrasound production. The adult SDA shrinks after gonadectomy unless the gerbils receive testosterone. So does the SDA pars compacta, a small cell group in the SDA of males that is seldom seen in females. Here, development of the SDA and SDApc, and of a second, small, compact cell group, the cmSDApc, that lies caudal and medial to the SDApc, is described. Development of the SDApc and cmSDApc was studied quantitatively by assessing their incidence and volume in both sexes from birth (PND 1) to adulthood (PND 150). The volume of the entire SDA was studied from PND 45 to 150. In male gerbils, puberty begins around PND 40 and is complete by PND 90-120. The male SDA enlarged relative to the cross-sectional area of the hypothalamus as puberty began, but the female SDA did not. The SDApc was present in virtually all gerbils at birth and was the same size in both sexes. Over the next two weeks, the SDApcs of females disappeared while those of males persisted and doubled in size. Like the SDApc, the cmSDApc was larger and more common in males than in females, but it became smaller and less prevalent in both sexes during the first two weeks after birth.

Intracranial androgenic and estrogenic stimulation of male-typical behaviors in house mice (Mus domesticus)

Two experiments in house mice (Mus domesticus) examined the neural sites at which steroid hormones activate the following male-typical behaviors: 70 kHz ultrasonic mating vocalizations in response to stimulus females or their urine, urinary marking in response to stimulus males or stimulus females, mounting of estrous females, and intermale aggression. In the first experiment, four groups of castrated males received bilateral intracranial implants of testosterone (T) into either the septum (SEPTUM), medial preoptic area (MPO), anterior hypothalamus (AHA), or ventromedial hypothalamus (VMH). Two control groups received subcutaneous silastic capsules of T (TSIL) or empty silastic capsules (BSIL). The TSIL males performed all behaviors at male-typical levels while the BSIL males were unresponsive. MPO males emitted ultrasonic mating vocalizations at high levels while few vocalizations were seen in males of the other brain implant groups. The VMH, AHA, and MPO males urine marked at higher levels than the BSIL males but did not exhibit the high levels of the TSIL males. Mounting was observed only in MPO and TSIL males. Aggression was rare in males from any of the brain implant groups. In the second experiment, the hormone activity of the implants was increased by using testosterone propionate (TP) or a 50% mixture of estradiol (E2) and cholesterol. The six groups were SEPTUMTP, SEPTUME2, MPOTP, MPOE2, TPSIL, and BSIL. The TPSIL males performed all behaviors at male-typical levels while the BSIL males were unresponsive. TP was effective at restoring vocalizations and urine marking only when placed in the MPO; however, E2 was effective at both sites. Again aggression and mounting were less evident in the brain implanted males. In conclusion, implants of T or TP were effective in restoring ultrasonic mating vocalization when placed into the MPO. MPO implants of T and TP were also effective in stimulating urine marking, although VMH and AHA implants also showed some effectiveness. The restorative effects of E2 were not localized which is probably related to the greater hormonal activity of this treatment. Comparisons of the properties of the various brain implants to restore more than one behavior were discussed.

Microimplants of estradiol in the sexually dimorphic area of the hypothalamus activate ultrasonic vocal behavior in male Mongolian gerbils

The hormonal control of ultrasonic vocal behavior in the male Mongolian gerbil was examined by comparing the behavioral effects of androgen with those of estrogen administered to the preoptic-anterior hypothalamic area (POA-AH) in castrates. By measuring radioactivity released from solid "floating" POA-AH microimplants (mean diameter, 141 microns) of testosterone (3H-T, mean weight, 880 ng) in Experiment 1, we found that the steroid had a concentration gradient which fell rapidly from the edge of the microimplant, suggesting restricted diffusion. Using floating microimplants in Experiment 2, we studied the effects of testosterone propionate (TP, 650 ng), estradiol-17 beta benzoate (EB, 439 ng), or cholesterol (C, 478 ng) on rates of a frequency modulated ultrasonic vocalization emitted during sexual interactions. The effects on the upsweep call were compared with those on sexual mounting. The upsweep rate remained significantly below precastration levels in C implanted males. EB reinstated upsweep calling within 5 days, 3 days earlier than TP microimplants. Mounting in EB implanted males was maintained at precastration levels, whereas TP implantation restored mounting to precastration levels only after 5 days. EB was effective in inducing ultrasonic vocalizations when placed in, or near, the sexually dimorphic area (SDA) in the medial preoptic area (POM). Our results indicate that brain mechanisms underlying both ultrasonic vocalizations and mounting are directly sensitive to estradiol (E2) in the male gerbil. We conclude that E2 affects mechanisms in the SDA associated with ultrasonic calling and suggest that T is likely to act via aromatization products in the brain.

Lesions of the SDN-POA inhibit sexual behavior of male Wistar rats

Discrete bilateral lesions in the SDN-POA of sexually naive adult male rats were found to decrease the number of animals ejaculating and/or to increase latencies to the first mount, intromission and ejaculation. The deleterious effects of the lesions disappeared after 4 tests for sexual behavior but were reinstated when the males were tested under suboptimal conditions, i.e., when they were tested with a marginally receptive female or when they had only limited access to the stimulus female. It was subsequently shown that males with a bilaterally lesioned SDN-POA still showed an increase in plasma testosterone. LH and prolactin levels in response to sexual stimulation. Effects of the lesions on scent marking were not found. Together with previous data indicating that SDN-POA-lesions disrupt masculine sexual behavior in females, these data are taken as evidence that the SDN-POA plays a role in the regulation of masculine sexual behavior. The data further suggest that previously reported negative results of SDN-POA-lesions on masculine sexual behavior in male rats might be attributed to the use of sexually experienced instead of sexually inexperienced animals.

Gender differences in the brain: are they relevant to the pathogenesis of schizophrenia?

Gender differences are present in the clinical expression of schizophrenia, age of onset, course of illness, and response to pharmacologic treatment. These differences are not surprising in view of the normal gender differences in brain growth, differentiation, adult brain structure, and neurochemistry. The present review examines what is presently known about brain gender differences, and whether this information is consistent with the published reports of brain functional and morphological abnormalities in schizophrenia. Whether gender differences in the brain can explain the gender differences in clinical aspects of the disorder remains unknown.

Ontogeny of a sexually dimorphic opioid system in the preoptic area of the rat

A striking sexual dimorphism exists in the distribution of Met-enkephalin (m-ENK) immunoreactive fibers in the preoptic area of the rat brain. A dense plexus of m-ENK fibers, approximately 100 microns wide, is present in the periventricular part of the preoptic area (pePOA) in adult females, but not in males. In the present study, we have examined the time of first expression of this female-typical system during the course of normal brain development. The female-typical plexus of m-ENK fibers in the pePOA is not expressed prepubertally, but first becomes evident during the late peri-pubertal period (usually by 40 days of age). In adult females, the maintenance of immunohistochemically detectable levels of m-ENK in this fiber system is dependent upon the presence of gonadal steroids, especially estradiol. Therefore, we examined whether exposure of pre-pubertal females to estradiol would result in precocious expression of the m-ENK fiber plexus. The results of this experiment demonstrate that exposure to estradiol for 7 days induces the full expression of the m-ENK fiber system in the pePOA of prepubertal females, such that it was indistinguishable from that seen in mature animals. These results demonstrate that while the sexually dimorphic m-ENK system of the pePOA is not normally expressed prepubertally, the neural substrate is nevertheless in place and capable of being activated by exposure to exogenous estradiol.

Effects of lesions of the sexually dimorphic nucleus on sexual behavior of testosterone-treated female Wistar rats

Discrete bilateral lesions were placed into the sexually dimorphic nucleus (SDN) of the medial preoptic area (MPOA) of ovariectomized female Wistar rats, chronically treated with testosterone (T). Effects of these lesions upon masculine and feminine sexual behavior were studied by comparing the results of pre- and postoperative tests, using sham-operated and unoperated females as controls. Bilaterally-lesioned and, to a lesser extent, unilaterally-lesioned females, showed a marked and significant reduction of masculine sexual behavior (i.e., mounting), especially in the first postoperative tests. Feminine sexual responses, i.e., receptive and proceptive behavior, although slightly lower in bilaterally-lesioned females, did not change significantly. Sexual partner preference, operationalized as the choice between a receptive female and a sexually active male, remained unaffected by the lesions. Plasma levels of testosterone were similar in the various groups. It is concluded that the SDN may be functionally implicated in the control of masculine sexual behavior in T-treated females.

Atropine infusions near the sexually dimorphic area of the gerbil hypothalamus facilitate hormonal induction of scent marking

The sexually dimorphic area (SDA) of the gerbil hypothalamus contains cells in which acetylcholinesterase activity is stimulated by testosterone. These cells are probably cholinoceptive. Because cholinoceptive cells and the SDA are both implicated in hormonal control of gerbil scent marking, marking was studied in castrated males given a low dose of testosterone systemically, and atropine, a cholinergic antagonist, near the SDA. Controls received saline near the SDA or atropine in the thalamus. Subjects were also tested for male sexual behavior, since it is also affected by the SDA. Infusing 25-35 micrograms atropine methyl nitrate near the SDA twice a week facilitated marking but did not affect mating. Experimental males marked more, whereas controls marked less, while receiving infusions, than they did before castration. The two control groups did not differ from each other. After infusions stopped, marking by experimental males decreased, though residual effects were detected in one test setting. The data suggest that a cholinoceptive system in or near the SDA participates in hormonal control of gerbil scent marking.

Afferent connections of the sexually dimorphic area of the hypothalamus of male and female gerbils

We studied neural inputs to the sexually dimorphic area (SDA) of the gerbil hypothalamus by injecting wheat-germ agglutinin-horseradish peroxidase into its medial or lateral components in males and females. To confirm the topography of SDA afferents, we injected Phaseolus vulgaris-leucoagglutinin into areas where retrograde labeling from the medial and lateral SDA differed. Both methods indicated that the medial SDA received stronger inputs from the medial part of the bed nucleus of the stria terminalis, the ventral part of the lateral septal nucleus, the medial amygdaloid nucleus, and the amygdalohippocampal area, than the lateral SDA does. In contrast, the rostrodorsal part of the lateral septum, the lateral part of the bed nucleus of the stria terminalis, the anterior and posterior hypothalamic areas, and the dorsomedial hypothalamic nucleus project more heavily to the lateral than to the medial SDA. In addition, retrograde labeling suggested that the ventral part of the premammillary nucleus projects more strongly to the medial than to the lateral SDA, whereas the infralimbic area of the cortex and the lateral preoptic area project more strongly to the lateral than to the medial SDA. The densities of cells in the bed nucleus of the stria terminalis and medial amygdaloid nucleus that could be retrogradely labeled from the medial SDA were greater in males than in females. This was not true of labeling in the arcuate nucleus or in the ventral part of the lateral septal nucleus. Since the medial SDA receives strong inputs from areas with many steroid-accumulating cells, it could respond to steroids directly and via these afferents. In contrast, hormonal effects on the lateral SDA are more likely to occur locally.

Role of neonatal androgens in sexual differentiation of brain structure, scent marking, and gonadotropin secretion in gerbils

Gerbils display a sexually dimorphic scent marking behavior that responds to testosterone (T) in adulthood and develops under the influence of testosterone perinatally. A complex of cell groups between the preoptic area and anterior hypothalamus of the gerbil brain is also sexually dimorphic and responsive to testosterone. One of these cell groups, the sexually dimorphic area pars compacta (SDApc), usually exists only in males. Even when given testosterone, adult female gerbils rarely have an SDApc. To determine if the SDApc develops under the influence of testosterone, male gerbils were castrated or given sham operations on the day they were born or 1 day later, or were not manipulated. Female gerbils were injected subcutaneously with 0, 50, or 100 micrograms testosterone propionate (TP) on the day after birth. When given ovarian transplants as adults, neonatally castrated males scent marked at low levels typical of females. Neonatally androgenized females given testosterone as adults scent marked at high levels typical of males. Neonatal castration did not affect the probability that the SDApc would develop, but neonatal androgenization did. Half the females given either dose of TP as neonates had SDApcs bilaterally. The sizes of the SDApcs present in females depended on the dose of testosterone given neonatally. The larger dose produced larger SDApcs. The 100-micrograms dose of TP also defeminized gonadotropin secretion, but the 50-micrograms dose did not. The castration of males neonatally prevented the defeminization normally caused by endogenous testosterone. Both groups of neonatally castrated males formed corpora lutea in their ovarian transplants, but control males did not.

Sexually dimorphic opioid distribution in the preoptic area: manipulation by gonadal steroids

A striking sexual dimorphism has been found in the density of Met-enkephalin immunoreactive fibers in the periventricular region of the preoptic area in the rat: the enkephalinergic fiber system is much denser in females. The expression of this female-typical fiber plexus is regulated by the actions of gonadal steroids both during development and in adulthood. In light of abundant evidence demonstrating the ability of the opioid peptides to modulate various sexually differentiated neuroendocrine processes and behaviors, this dimorphic system may represent an important anatomical substrate underlying these functions.

Role of the flank gland in vasopressin induced scent marking behavior in the hamster

The present study examined whether the induction of scent marking behavior and grooming of the flank gland region by injection of arginine-vasopressin (AVP) or oxytocin (OXY) into the anterior hypothalamus-medial preoptic area (AH-MPOA) required the presence of the flank glands. The flank glands were surgically removed (GLDX) in ten hamsters or patches of skin just dorsal to the flank glands were removed (SHAM) in the control group (N = 7). No statistically significant differences were observed in flank marking or flank grooming between the GLDX and SHAM groups during a 10 min test period immediately following injection of AVP or OXY. AVP and OXY injection produced similar amounts of flank grooming, but AVP resulted in significantly (p less than 0.01) more flank marking than OXY. These data indicate that scent marking induced by AVP injected into the AH-MPOA is similar to environmentally induced scent marking in not requiring the presence of an intact scent gland.

A genetic variant in the morphology of the medial preoptic area in mice

Inbred mice of the DBA/2J and C57BL/6J strains are known to differ in physiological and behavioral characteristics that are partially controlled by nuclei in the preoptic area/anterior hypothalamus. We describe a distinguishing nucleus of darkly staining, densely packed cells, which we term the medioventral pars compacta (MVPC), within the medial preoptic nucleus of DBA/2J, but not C57BL/6J mice. The analysis also indicates that this nucleus is nearly 80% larger in volume in females vs males of the DBA/2J strain. The strain difference may be used to define genetic influences on this neuroanatomical and functional property.

Autoradiographic localization of estrogen and androgen receptors in the sexually dimorphic area and other regions of the gerbil brain

Autoradiography was used to localize sex hormone-accumulating cells in the gerbil brain. Some areas had a high density of both androgen and estrogen receptors. These areas included the lateral septum, the bed nucleus of the stria terminalis, the medial and cortical amygdaloid nuclei, the medial preoptic area (MPOA), the arcuate nucleus, the ventromedial hypothalamus, and the periventricular central gray. This distribution of hormone receptors agrees closely with that seen in other mammals. In contrast to what has been reported for other species, the distribution of estradiol-accumulating cells in the gerbil MPOA is different in males and females. Estradiol uptake in the posterior MPOA followed the morphology of a sexually dimorphic area (SDA) and was therefore sexually dimorphic. Moreover, the percentage of SDA cells that accumulated estradiol appeared to be higher in males than in females. The pattern of androgen accumulation also followed the morphology of the SDA but differed from the pattern of estrogen accumulation in one way. The uptake of 5 alpha-dihydrotestosterone in the SDA pars compacta (pc), a component of the SDA, was much greater than in the rest of the SDA. This was not true for estradiol. Since most females lack the SDApc, androgen uptake in the gerbil SDA may also be sexually dimorphic. Androgen uptake was more widespread than estrogen uptake in the brainstem. Brainstem nuclei that accumulated 5 alpha-dihydrotestosterone included the locus ceruleus, the dorsal raphe, the hypoglossal nucleus, the area postrema, the nucleus of the solitary tract, and the dorsal nucleus of the vagus.

Lesions of the sexually dimorphic area disrupt mating and marking in male gerbils

At the border between the medial preoptic area (MPOA) and the anterior hypothalamus (AH), gerbils have a sexually dimorphic area (SDA) that accumulates and responds to gonadal steroids. To assess the role of the SDA in the hormonal control of two sexually dimorphic behaviors, masculine sexual behavior and ventral scent marking, we studied changes in these behaviors in male gerbils after lesioning the lateral SDA or the entire SDA. Lateral SDA lesions disrupt openfield scent marking, at least temporarily, and produce long-lasting deficits in, but do not abolish, mating behavior. Lesioning both the medial and the lateral SDA produces more profound deficits in mating and marking. Similar lesions anterior or posterior to the SDA also impair these behaviors, but their effects are less severe. Thus the SDA is more important than other parts of the MPOA-AH in the control of mating and marking in male gerbils.

Adult testosterone levels influence the morphology of a sexually dimorphic area in the Mongolian gerbil brain

This research shows that the medial preoptic area-anterior hypothalamus (MPOA-AH) of the gerbil contains a sexually dimorphic area (SDA) whose morphology is influenced by adult gonadal steroids. The characteristics of the SDA were studied initially in gonadally intact males and females and later in males and females that had been gonadectomized or gonadectomized and given testosterone. Coronal sections through the MPOA-AH were stained with thionin to visualize the SDA. In male gerbils, the SDA is a darkly staining, hook-shaped structure on either side of the third ventricle, above the suprachiasmatic nuclei and below the anterior commissure. Within the male SDA lies a small, dense cluster of cells, the SDA pars compacta (SDApc). In female gerbils, the SDA is more ovoid and diffuse and the SDApc is absent. Camera lucida tracings and planimeter measurements of the SDA showed that the total volume of the SDA is similar in the two sexes, but the proportion of the SDA that stains darkly and/or stands out clearly from the surround (dark volume) is larger in males. Gonadectomy decreases both total and dark volume of the SDA in both sexes and decreases the volume of the SDApc in males. Testosterone treatment prevents these changes. This is the first report of changes in the gross morphology of the mammalian brain after steroid hormone manipulations in adulthood. The changes in the SDA may be related to testosterone activation of scent marking behavior.

Acetylcholinesterase activity in the sexually dimorphic area of the gerbil brain: sex differences and influences of adult gonadal steroids

The morphology of the medial preoptic area-anterior hypothalamus (MPOA-AH) of gerbils is sexually dimorphic and influenced by adult gonadal hormones. This research shows that the distribution of (MPOA-AH) cells that synthesize acetylcholinesterase (AChE) and the activity of AChE within the MPOA-AH are also sexually dimorphic and hormone sensitive. Adult male and female gerbils were gonadectomized, gonadectomized and implanted subcutaneously with testosterone (T), or sham operated 4-8 weeks before sacrifice. Coronal sections through the sexually dimorphic area (SDA) of the MPOA-AH were stained for AChE. Planimeter measurements of camera lucida drawings showed that the total volume of the SDA is similar in the two sexes, but the proportion of the SDA that stains darkly and/or stands out clearly from the surround (dark volume) is larger in males. Optical density readings also indicated that AChE staining is darker in the male SDA. Gonadectomy decreases staining intensity in both sexes and reduces total SDA volume. Dark volume decreases more than 50%. Testosterone treatment reverses all effects of gonadectomy, although hormonal influences are smaller in females than in males. There were no sex differences or hormonal influences on AChE staining lateral to the SDA. The pars compacta of the male SDA was essentially devoid of AChE, indicating that this cell group is distinct from the rest of the SDA. It also shrinks after castration unless the males receive T. Histochemical changes in the SDA may be related to hormonal control of scent marking, a form of communication in this species.