Non-androgenic testicular mediation of androphilia in male mice with global overexpression of androgen receptors.

Sexual attraction is robustly sexually differentiated among mammalian species. Gonadal androgens acting perinatally and in adulthood are required for male-typical preference for female sexual cues. Recent evidence suggests that at the high extent of AR signaling, male mice show an increased preference for same-sex odor cues. These findings were found only in mice that overexpress AR globally in all tissues (CMV-AR), whereas neural AR overexpression (Nestin-AR) did not affect sexual preference. The present studies investigated the endocrine basis of this phenotype and examined whether preference for male or female stimulus animals (partner preference) was also affected in these transgenic animals. We manipulated adult gonadal hormones in male mice that overexpress AR globally and males that overexpress AR only in neural tissue. We replicate the finding that androphilia is increased in gonadally intact CMV-AR males, and these males exhibited reduced neural activation in response to estrus female odors. Testosterone treatment of gonadectomized CMV-AR males was sufficient to induce a gynephilic olfactory preference, while a gynephilic partner preference was induced with gonadectomy alone. These findings suggest that altered sexual preference of CMV-AR male mice is mediated by inhibitory activational functions of the testes. Together, these results suggest that at the high extent of AR signaling, non-neural AR via the gonads, can promote androphilia.

Neural androgen receptor overexpression affects cell number in the spinal nucleus of the bulbocavernosus.

The spinal nucleus of the bulbocavernosus (SNB) is a sexually dimorphic neuromuscular system in which the masculinisation of cell number is assumed to depend on the action of perinatal androgen in non-neural targets, whereas the masculinisation of cell size is assumed to depend primarily on the action of adult androgen on SNB cells themselves. To test these hypotheses, we characterised the SNB of Cre/loxP transgenic mice that overexpress androgen receptor (AR) throughout the body (CMV-AR) or in neural tissue only (Nestin-AR). Additionally, we examined the effects of androgen manipulation in male mutants and wild-type (WT) controls. We reproduced the expected sex differences in both motoneurone number and size, as well as the expected adult androgen dependence of SNB size. We found effects of genotype such that both Nestin-AR and CMV-AR have more SNB motoneurones than WT littermates and also that CMV-AR females have larger SNB motoneurones than Nes-AR or WT females. These results raise the possibility that AR can act in neurones and/or glia to rescue SNB motoneurones, as well as on non-neural AR to increase SNB cell size.

Non-neural androgen receptor promotes androphilic odor preference in mice.

In mice, male-typical preference for female olfactory cues results largely from sexually differentiated testosterone production. It is currently unclear on which cells and tissues testosterone acts to produce male-typical preference for female olfactory cues. To further address the site of androgen action on olfactory preference, we have developed a loxP-based transgenic mouse that overexpresses androgen receptors (AR) only when activated by Cre. We used this transgene to overexpress AR globally in all tissues using a CMV-Cre driver and a Nestin-Cre driver to overexpress AR selectively in neural tissue. We then examined olfactory preference in transgenic and wildtype (Wt) littermates by simultaneously exposing animals to female-soiled, male-soiled and clean bedding. Ubiquitous overexpression of AR in CMV-AR mice increased preference for male bedding, whereas neural-specific AR overexpression in Nestin-AR transgenic mice did not differ from wildtype siblings in olfactory preference. Neural activation of olfactory brain areas in response to female-soiled bedding was also evaluated in these mice by measuring FOS immunoreactivity. This revealed a decrease in neural activity along the accessory olfactory pathway that accompanied the decrease in preference for female odors in CMV-AR males, compared to both Nestin-AR and Wt male siblings. Together, results indicate that androgens act via non-neural AR to mediate olfactory preference and neural responses to olfactory stimuli, and further suggest that AR in non-neural tissues can promote androphilic odor preferences in male mice.In mice, male-typical preference for female olfactory cues results largely from sexually differentiated testosterone production. It is currently unclear on which cells and tissues testosterone acts to produce male-typical preference for female olfactory cues. To further address the site of androgen action on olfactory preference, we have developed a loxP-based transgenic mouse that overexpresses androgen receptors (AR) only when activated by Cre. We used this transgene to overexpress AR globally in all tissues using a CMV-Cre driver and a Nestin-Cre driver to overexpress AR selectively in neural tissue. We then examined olfactory preference in transgenic and wildtype (Wt) littermates by simultaneously exposing animals to female-soiled, male-soiled and clean bedding. Ubiquitous overexpression of AR in CMV-AR mice increased preference for male bedding, whereas neural-specific AR overexpression in Nestin-AR transgenic mice did not differ from wildtype siblings in olfactory preference. Neural activation of olfactory brain areas in response to female-soiled bedding was also evaluated in these mice by measuring FOS immunoreactivity. This revealed a decrease in neural activity along the accessory olfactory pathway that accompanied the decrease in preference for female odors in CMV-AR males, compared to both Nestin-AR and Wt male siblings. Together, results indicate that androgens act via non-neural AR to mediate olfactory preference and neural responses to olfactory stimuli, and further suggest that AR in non-neural tissues can promote androphilic odor preferences in male mice.