Testicular hormones reduce individual differences in the aggressive behavior of male mice: a theory of hormone action

Achieving Permanent Male Infertility by Magnetic Nanoparticle Hyperthermia: A Breakthrough in Animal Fertility Management

Background/Objectives: Non-surgical neutering strategies have long been pursued for male animals. A previous study from our group showed that magnetic nanoparticle hyperthermia (MNH) applied directly to the testicles is a promising non-surgical sterilization method for male animals, causing testicular atrophy and complete disappearance of seminiferous tubules by the end of a 56 day observation. This long-term study was conducted to verify the long-term efficacy and safety of the method. Methods: Wistar rats treated with testicular MNH received an intratesticular injection of a magnetic fluid composed of manganese-ferrite nanoparticles functionalized with citrate (MnFe2O4-citrate) and were subsequently subjected to an alternating magnetic field. Reproductive parameters and animal health were evaluated by blood tests and abdominal ultrasound for 12 months. Results: All MNH-treated animals presented testicular degeneration and atrophy, together with severely reduced or undetectable serum testosterone levels. By the end of the experiment, all but two animals had no identifiable gonads. The only two animals still displaying gonadal-like structures were azoospermic, and histopathology revealed the remaining tissue was non-functional. The procedure was well-tolerated and MNH-treated animals presented no long-term side effects. Hemogram, ALT, AST, urea and creatinine levels were within the normal parameters for Wistar rats over the 12 month period. The liver, spleen, kidneys and lungs had normal structures as revealed by abdominal ultrasound and histopathological exams, with no nanoparticle accumulation in the organs over the long term. Conclusions: In conclusion, testicular MNH caused irreversible infertility in rats in a single application, with no adverse effects on general animal health.

The Role of Androgens and Estrogens in Social Interactions and Social Cognition

Gonadal hormones are becoming increasingly recognized for their effects on cognition. Estrogens, in particular, have received attention for their effects on learning and memory that rely upon the functioning of various brain regions. However, the impacts of androgens on cognition are relatively under investigated. Testosterone, as well as estrogens, have been shown to play a role in the modulation of different aspects of social cognition. This review explores the impact of testosterone and other androgens on various facets of social cognition including social recognition, social learning, social approach/avoidance, and aggression. We highlight the relevance of considering not only the actions of the most commonly studied steroids (i.e., testosterone, 17β-estradiol, and dihydrotestosterone), but also that of their metabolites and precursors, which interact with a plethora of different receptors and signalling molecules, ultimately modulating behaviour. We point out that it is also essential to investigate the effects of androgens, their precursors and metabolites in females, as prior studies have mostly focused on males. Overall, a comprehensive analysis of the impact of steroids such as androgens on behaviour is fundamental for a full understanding of the neural mechanisms underlying social cognition, including that of humans.

What is the impact of low testosterone levels on the anatomical and behavioral repertoire of long-term enriched housing of male mice?

Environmental enrichment is a strategy to improve animal welfare, providing brain plasticity with changes at cellular, molecular and behavioral levels. In order to test the long-term effects of enriched housing and the importance of testosterone levels for the expression of behavioral plasticity, 28 categories were assessed in 45 adult Swiss mice, subdivided in prepubertal castrated and non-castrated groups, maintained for seven months as three non-sibling mates. Enrichment consisted of introducing insets for gnawing, climbing and hiding. Tests of spontaneous exploration (barrier), territoriality (intruder) and hierarchical organization (group) were applied at once. Measurements of body weight and the relative weight of key organs were done at the end of the experiment. Mice kept in enriched cages, either castrated or non-castrated, showed more spontaneous exploration than those raised in standard cages. Non-castrated mice housed in structured cages had a lower frequency of attack in the resident-intruder test than the non-castrated standard caged mice, indicating a decrease in territoriality in the first group. Independent of the housing conditions, castrated mice showed reduction of offensive, defensive, and social contacts, as well as low frequency of attack in both agonistic tests. The well-known importance of testes to ensure the expression of aggressive and social contact behaviors was therefore not challenged by the enrichment condition. Behavioral repertoire at the home cage, performance in the group-test, and organometric measurements were not significantly different between the groups kept in enriched and non-enriched cages. Our results suggest that the experience in enriched environment does not increase aggressiveness in their routine in the home-cage nor negatively influence physiological parameters, independently of the testosterone level.

Androgen modulation of social decision-making mechanisms in the brain: an integrative and embodied perspective

Apart from their role in reproduction androgens also respond to social challenges and this response has been seen as a way to regulate the expression of behavior according to the perceived social environment (Challenge hypothesis, Wingfield et al., 1990). This hypothesis implies that social decision-making mechanisms localized in the central nervous system (CNS) are open to the influence of peripheral hormones that ultimately are under the control of the CNS through the hypothalamic-pituitary-gonadal axis. Therefore, two puzzling questions emerge at two different levels of biological analysis: (1) Why does the brain, which perceives the social environment and regulates androgen production in the gonad, need feedback information from the gonad to adjust its social decision-making processes? (2) How does the brain regulate gonadal androgen responses to social challenges and how do these feedback into the brain? In this paper, we will address these two questions using the integrative approach proposed by Niko Tinbergen, who proposed that a full understanding of behavior requires its analysis at both proximate (physiology, ontogeny) and ultimate (ecology, evolution) levels.

What does the "four core genotypes" mouse model tell us about sex differences in the brain and other tissues?

The "four core genotypes" (FCG) model comprises mice in which sex chromosome complement (XX vs. XY) is unrelated to the animal's gonadal sex. The four genotypes are XX gonadal males or females, and XY gonadal males or females. The model allows one to measure (1) the differences in phenotypes caused by sex chromosome complement (XX vs. XY), (2) the differential effects of ovarian and testicular secretions, and (3) the interactive effects of (1) and (2). Thus, the FCG model provides new information regarding the origins of sex differences in phenotype that has not been available from studies that manipulate gonadal hormone levels in normal XY males and XX females. Studies of the FCG model have uncovered XX vs. XY differences in behaviors (aggression, parenting, habit formation, nociception, social interactions), gene expression (septal vasopressin), and susceptibility to disease (neural tube closure and autoimmune disease) not mediated by gonadal hormones. Some sex chromosome effects are mediated by sex differences in dose of X genes or their parental imprint. Future studies will identify the genes involved and their mechanisms of action.

Lowered sperm motility in subordinate social status of mice

The correlation between social status and sperm motility of mice was investigated. From 5 to 15 weeks of age, mice were kept under two housing conditions, i.e., in pairs or in isolation. The social dominance in the paired mice was determined with the resident-intruder tests, which were carried out from 8 to 15 weeks of age. At the end of 15 weeks of age, sperm activity, weights of reproductive organs, and serum testosterone were determined. It was revealed that the sperm motility of dominant mice was significantly higher than that of the subordinates. The sperm motility of the isolated mice was also significantly higher than the subordinates. It was suggested that the subordinate social status lowered sperm motility.

Premenstrual syndrome

The Premenstrual Syndrome (PMS) was described as a unique entity meriting therapeutic attention in 1931. Although researchers in the area have failed to develop a widely accepted definition of PMS, substantial progress has been made in describing the variety of psychobiological profiles encompassed by this syndrome, particularly with respect to its typical symptoms, cyclical nature, symptoms recurrence and severity. Therapies ranging from diet and exercise to vitamin, hormone and drug treatment have been proposed. While none is more efficacious than placebo, several have been popularized. Our failure to develop adequate treatment may reflect our lack of understanding of either the psychosocial or biological factors involved in PMS. This, in turn, may reflect inadequate theoretical development in this research area. We provide a critical assessment of research on PMS, suggest a framework for theoretical development and advocate research strategies that might provide insights into the etiology of the premenstrual syndrome.

Environmental influences on masculine sexual behavior in mice

Retention of masculine copulatory behaviors following castration varies among B6D2F1 male mice. In the present study, we examined the effect of test environment and the amount of behavioral testing after castration, on retention of copulatory responses in castrated B6D2F1 male mice. Results showed that weekly behavioral testing after castration was not necessary for the retention of ejaculatory reflexes. However, the test environment had a major effect. Following castration, 26% of the males completely stopped showing ejaculatory responses when tested in the test arenas. When these males were tested in their home cages, 75% achieved at least one ejaculatory response in four home cage tests. Castrated males that continued to copulate in the test arena situation also achieved ejaculatory reflexes in their home cages. These results indicate that for some B6D2F1 males, the retention of sexual behaviors after castration is influenced by environmental factors.

Aggression in male mice: rapid-onset attack of lactating female mice following termination of hyperphysiological testosterone treatment

Gonadally-intact or castrated and testosterone-(T) treated male mice display aggressive behavior towards olfactory-bulbectomized male (OBM) stimuli, but not towards lactating female (LF) stimuli. By comparison, T-treated female mice display aggressive behavior towards both OBM and LF stimuli. The purpose of the present experiment was to determine if male mice given hyperphysiological T-treatment would display "female-typical" attack of OBM and LF stimuli. Hyperphysiological T-stimulation did not lead to the display of aggressive behavior towards OBM and LF stimuli; only OBM stimuli were attacked, suggesting a qualitative behavioral sex difference in response to T. However, the major finding of this study occurred following the termination of T-treatment. Castrated males that had previously received hyperphysiological T-treatment began to attack LF stimuli within 48 hr of treatment termination. By comparison, castrated males that had previously received physiological T-stimulation, as well as a gonadally-intact control group, generally began to attack LF stimuli 3-4 weeks following treatment-termination/castration. It is suggested that this unusual treatment-termination-induced behavioral display occurs via neurochemical mediation.