Experiential and endocrine dependence of gonadotropin responses in male mice to conspecific urine

Previous research has shown that a urinary pheromone of female mice acts via the vomeronasal organ of the accessory olfactory system to elicit rapid release of luteinizing hormone (LH) in conspecific males. Several experiments were conducted to examine the importance of sexual experience for gonadotropin responses in male mice to female urine, male urine, saline, or mixtures of these stimuli. Both sexually naive and sexually experienced male mice had significantly higher plasma LH levels after presentations of female urine than after presentations of male urine. However, sexual experience appeared to increase the reliability of the short-latency gonadotropin response to female urine relative to a sexually neutral component of urine such as sodium chloride, and male urine appeared to suppress spontaneous LH secretion episodes in both naive and sexually experienced males. Subsequent experiments with sexually experienced subjects demonstrated that male mouse urine is a powerful suppressant of LH release in other males. Specifically, female mouse urine mixed with male urine failed to elicit LH responses in male subjects, whereas female urine mixed with saline was highly effective. Urine obtained from castrated male donors was as potent as urine from intact males in suppressing the gonadotropin response to female urine. The suppressive activity in male mouse urine thus does not appear to be critically dependent on gonadal hormones. The existence of a potent stimulatory pheromone in female urine and a potent suppressive pheromone in male urine makes male mice an excellent model system for studying the neural regulation of LH secretion.     

The mouse putative pheromone receptor was specifically activated by stimulation with male mouse urine

To detect the biological activity of mammalian putative pheromone receptors (V1Rs and V2Rs), the mouse V1R gene was introduced into a primary culture of vomeronasal cells using the adenovirus expression system, and the response of these cells to mouse urine was analyzed by calcium imaging. These cells specifically responded to male but not female mouse urine. This response was attenuated by pertussis toxin, a specific inhibitor of G-protein G(ialpha)/G(oalpha) coupling from receptors. Our findings indicate that a putative pheromone receptor was specifically activated by mouse urine, a major source of mouse pheromones, and suggest that G(i)/G(o) are functionally coupled with the receptor.     

Biogenic Amines in the Vomeronasal Organ

The vomeronasal organ of frog and mouse was investigated forthe presence and content of serotonin and catecholamines bymeans of high-performance liquid chromatography. Measurableamounts of serotonin, adrenaline and noradrenaline were foundin the vomeronasal organ of adult individuals of both species.The amine content varied with sex of adult frogs and mice andsexual maturity of mice. In preliminary experiments, acute exposureto male urine containing pheromone affected the amine contentin the vomeronasal organ of adult female mice. These data suggestthat functional sex dimorphism is present in the vomeronasalorgan, and biochemical changes therein take place accordingto stage of sexual maturity. The role of biogenic amines inthe vomeronasal organ deserves further study. Chem. Senses 22:439–445, 1997.     

Involvement of contact stimuli in the male-induced implantation block (the Bruce effect) in mice

Confinement of newly inseminated female mice exposed to confined alien males significantly decreased the male-induced implantation failure (the Bruce effect). By contrast, free (unconfined) females exposed to confined alien males showed a high rate of implantation failure. The results suggest that the pheromone of male origin involved in the Bruce effect is non-volatile and acts on the female through contact. The vomeronasal organ appears to be involved in the perception of this pheromone.     

Partial isolation of a pheromone accelerating puberty in female mice.

The sexual development of female mice is accelerated by exposure to an adult male or to male urine. The component of the urine responsible for this effect is androgen-dependent, heat labile, nondialysable, precipitatable with ammonium sulphate, and is not extractable in ether. These results indicate that the pheromone causing accelerated sexual development is associated with a protein component of male urine. Tests of the active fraction after digestion with proteolytic enzymes suggest that the pheromone may be a portion of a protein or a substance bound to a protein.     

On the scent of sexual attraction

A study in the current issue of BMC Biology has identified a mouse major urinary protein as a pheromone that attracts female mice to male urine marks and induces a learned attraction to the volatile urinary odor of the producer. See research article     

Purification and analysis of a proteinaceous aphrodisiac pheromone from hamster vaginal discharge

Hormonally regulated proteinaceous material secreted in hamster vaginal discharge is detected via the vomeronasal organ and elicits copulatory behavior in males. The major soluble protein in estrous vaginal discharge has been isolated, characterized by molecular weight and amino acid content, and shown to have substantial aphrodisiac activity. The aphrodisiac activity of the purified protein is abolished by heating or proteolysis, and the native protein retains the activity after procedures for removing possible ligands such as volatile odorants, steroids, and peptides. This evidence that the protein is a reproductive pheromone indicates that the mammalian vomeronasal organ can mediate sensory detection of behaviorally relevant macromolecules.     

Sex-specific responses to urinary chemicals by the mouse vomeronasal organ

Social behaviors of most mammals are affected by chemical signals, pheromones, exchanged between conspecifics. Previous experiments have shown that behavioral responses to the same pheromone differ depending on the sex and endocrine status of the respondent. Although the exact mechanism of this dimorphism is not known, one possible contributor may be due to sexually dimorphic receptors or due to differences in central processing within the brain. In order to investigate the differences in response between male and female mice to the same pheromonal stimulus two urinary compounds (2-heptanone and 2,5-dimethylpyrazine) were used to stimulate the production of Inositol (1,4,5)-trisphosphate (IP(3)) in microvillar membrane preparations of the vomeronasal organ as an indirect measurement of pheromonal stimulation. Incubation of such membranes from prepubertal mice with urine from the same sex or opposite sex, results in an increase in production of IP(3). This stimulation is mimicked by GTPgammaS and blocked by GDPbetaS. Furthermore we found that 2-heptanone present in both male and female urine was capable of stimulating increased production of IP(3) in the female VNO but not the male VNO. Finally, 2,5-dimethylpyrazine present only in female urine was also only capable of stimulating increased production of IP(3) in the female VNO.     

From sexual attraction to maternal aggression: When pheromones change their behavioural significance

This article is part of a Special Issue “Chemosignals and Reproduction”.This paper reviews the role of chemosignals in the socio-sexual interactions of female mice, and reports two experiments testing the role of pup-derived chemosignals and the male sexual pheromone darcin in inducing and promoting maternal aggression. Female mice are attracted to urine-borne male pheromones. Volatile and non-volatile urine fractions have been proposed to contain olfactory and vomeronasal pheromones. In particular, the male-specific major urinary protein (MUP) MUP20, darcin, has been shown to be rewarding and attractive to females. Non-urinary male chemosignals, such as the lacrimal protein ESP1, promote lordosis in female mice, but its attractive properties are still to be tested. There is evidence indicating that ESP1 and MUPs are detected by vomeronasal type 2 receptors (V2R).When a female mouse becomes pregnant, she undergoes dramatic changes in her physiology and behaviour. She builds a nest for her pups and takes care of them. Dams also defend the nest against conspecific intruders, attacking especially gonadally intact males. Maternal behaviour is dependent on a functional olfactory system, thus suggesting a role of chemosignals in the development of maternal behaviour. Our first experiment demonstrates, however, that pup chemosignals are not sufficient to induce maternal aggression in virgin females. In addition, it is known that vomeronasal stimuli are needed for maternal aggression. Since MUPs (and other molecules) are able to promote intermale aggression, in our second experiment we test if the attractive MUP darcin also promotes attacks on castrated male intruders by lactating dams. Our findings demonstrate that the same chemosignal, darcin, promotes attraction or aggression according to female reproductive state.     

Encoding choosiness: female attraction requires prior physical contact with individual male scents in mice

Scents, detected through both the main and vomeronasal olfactory systems, play a crucial role in regulating reproductive behaviour in many mammals. In laboratory mice, female preference for airborne urinary scents from males (detected through the main olfactory system) is learnt through association with scents detected through the vomeronasal system during contact with the scent source. This may reflect a more complex assessment of individual males than that implied by laboratory mouse studies in which individual variation has largely been eliminated. To test this, we assessed female preference between male and female urine using wild house mice with natural individual genetic variation in urinary identity signals. We confirm that females exhibit a general preference for male over female urine when able to contact urine scents. However, they are only attracted to airborne urinary volatiles from individual males whose urine they have previously contacted. Even females with a natural exposure to many individuals of both sexes fail to develop generalized attraction to airborne male scents. This implies that information gained through contact with a specific male's scent is essential to stimulate attraction, providing a new perspective on the cues and olfactory pathways involved in sex recognition and mate assessment in rodents.     

Female snake sex pheromone induces membrane responses in vomeronasal sensory neurons of male snakes

The vomeronasal organ (VNO) is important for activating accessory olfactory pathways that are involved in sexually dimorphic mating behavior. The VNO of male garter snakes is critically important for detection of, and response to, female sex pheromones. In the present study, under voltage-clamp conditions, male snake VNO neurons were stimulated with female sexual attractiveness pheromone. Thirty-nine of 139 neurons exhibited inward current responses (reversal potential: -10.6 +/- 2.8 mV). The amplitude of the inward current was dose dependent, and the relationship could be fitted by the Hill equation. Under current-clamp conditions, application of pheromone produced membrane depolarizing responses and increases in firing frequency. These results suggest that the female pheromone directly affects male snake VNO neurons and results in opening of ion channels, thereby converting the pheromone signal to an electrical signal. The response to female pheromone is sexually dimorphic, that is, the pheromone does not evoke responses in VNO neurons of female snakes. An associated finding of the present study is that the female sex pheromone, which is insoluble in aqueous solutions, became soluble in the presence of Harderian gland homogenate.     

Effects of vomeronasal organ removal on olfactory sex discrimination and odor preferences of female ferrets

Previous research suggests that body odorants, including anal scents and urinary odors, contribute to sex discrimination and mate identification in European ferrets of both sexes. We assessed the possible role of the vomeronasal organ (VNO) in these functions by surgically removing the organ bilaterally in sexually experienced female ferrets. Lesioned (VNOx) and sham-operated control (VNOi) females reliably discriminated between male- and female-derived anal scent gland as well as fresh urinary odors in habituation/dishabituation tests. However, VNOi females spent significantly more time than VNOx subjects investigating male urinary odors in these tests. Also, VNOi females, but not VNOx subjects, preferred to investigate day-old male versus female urine spots as well as wooden blocks that had previously been soiled by male versus female ferrets. Both groups of female ferrets preferred to approach volatile odors from a breeding male instead of an estrous female in Y-maze tests and both groups showed similar levels of receptive sexual behavior in response to a male's neck grip. The VNO is apparently not required for olfactory sex discrimination or mate recognition in this carnivore, but instead may play a role in promoting continued contact with nonvolatile body odors previously deposited by opposite-sex conspecifics during territorial scent marking.     

Hormonal influence on the olfactory response to a female-attracting pheromone, sodefrin, in the newt, Cynops pyrrhogaster

Sodefrin is a female-attracting pheromone isolated from the abdominal glands of male newts, Cynops pyrrhogaster. Previously, the preference of conspecific female newts for sodefrin was shown to be completely abolished by plugging the bilateral nostrils, indicating that it acts on the olfactory organ. To determine the sensitivity of the olfactory receptor cells to sodefrin, electro-olfactograms (EOGs) in response to sodefrin solution were recorded from the ventral nasal epithelium of sexually developed female newts. Sodefrin elicited marked EOG responses in a dose-dependent manner on the epithelium of the lateral nasal sinus (LNS) region, a putative vomeronasal organ. In ovariectomized females, treatment with prolactin (PRL) and estrogen markedly enhanced the EOG response to sodefrin. The EOG response to the pheromone was also enhanced considerably by treatment with either PRL or estrogen alone. A slight but significant elevation was observed in castrated males receiving PRL plus estrogen or estrogen alone. It was concluded that the main site of action of sodefrin resides in the lateral sinus region and that sensitivity to sodefrin is under the control of PRL and estrogen. The presence of a sex difference in olfactory sensitivity to the hormones and/or pheromone was also suggested.     

Conserved repertoire of orthologous vomeronasal type 1 receptor genes in ruminant species

Background  

In mammals, pheromones play an important role in social and innate reproductive behavior within species. In rodents, vomeronasal receptor type 1 (V1R), which is specifically expressed in the vomeronasal organ, is thought to detect pheromones. The V1R gene repertoire differs dramatically between mammalian species, and the presence of species-specific V1R subfamilies in mouse and rat suggests that V1R plays a profound role in species-specific recognition of pheromones. In ruminants, however, the molecular mechanism(s) for pheromone perception is not well understood. Interestingly, goat male pheromone, which can induce out-of-season ovulation in anestrous females, causes the same pheromone response in sheep, and vice versa, suggesting that there may be mechanisms for detecting "inter-species" pheromones among ruminant species.     

硬蜱盾窝腺释放性信息素

用生物测定和对盾窝进行x-射线微区分析相结合的方法,研究了亚洲璃眼蜱雌蜱性信息素的释放与吸血和交配的关系.生物测定结果表明:雌蜱通过盾窝释放性信息素,有性活力动能的雄蜱有所反应,爬向雌蜱进行交配.雌蜱吸血后第1天,有反应的雄蜱数目显著增加;吸血后的第3—5天,有反应的雄蜱数目达到最高峰,交配后有反应雄蜱的数目明显下降.如果用指甲油封闭雌蜱盾窝,有反应的雄蜱数目显著减少.由于性信息素的有效成分为2,6-二氯酚,故用x-射线微区分析方法测定盾窝氯含量的变化,可以表明雌蜱性信息素的释放量,其结果与生物测定结果一致:未吸血的雌蜱台氯水平为0.62,吸血后第1—2天均增到5.87,有非常显著的差异(P<0.001).吸血后第3—5天含氯水平为10.23,达到最高峰,与吸血后第1—2天的相比,差异也很显著(p<0.001).与雄蜱交配后含氯不平又降至0.89,性信息素含量明显降低,与来吸血的雌蜱含量接近.     

Mouse major urinary proteins trigger ovulation via the vomeronasal organ

The major urinary proteins are a species-specific complex of proteins excreted by male mice that influence the reproductive behavior and the neuroendocrine condition of female mice through the olfactory system. The aim of this work is to determine their influence on ovulation. The major urinary proteins isolated from the urine of adult male mice were voided of bound odorants, dissolved at a physiological concentration in urine of prepubertal mice, and put on the nostril of reproductively cycling female mice housed in groups, the first day of estrus at 1100. The eggs shed in the oviducts were counted under dissection the morning of the second day of estrus. The results showed that 1) a single stimulus of the major urinary proteins increased ovulation nearly as much as the whole urine of male mice, 2) the effect was not elicited by male rat urine which contains different proteins, 3) a peptide with four residues of the amino-terminal sequence of the major urinary proteins stimulated ovulation, and 4) mice that had been isolated or had the vomeronasal organ (VNO) removed did not respond to the major urinary proteins and had a high spontaneous ovulation. The results suggest that the major urinary proteins activate the neuroendocrine system through the VNO and trigger ovulation.     

Decline in male mouse pheromone with age

An age-related decline in urinary-borne pheromone was found in male C57BL/6J mice aged from 2 to 30 months. Pheromone activity, estimated by bioassay, declined sharply after about 10 months of age. Two other strains of mice tested (DBA/2J and CBA/HT6J) also appeared to show an age-related decline in pheromone activity. Within each strain, however, pheromone activity was consistently similar to or higher than that of the C57BL/6J male mice. The DBA/2J and BALB/cWt strains appeared to be high pheromone producers, and the C57BL/6J and CBA/HT6J strains, low producers. This report is the first demonstration of a decline with age in male mouse pheromone activity. This decline appears to be synchronized with the well-defined loss of reproductive function in female mice.     

Vomeronasal/accessory olfactory system and pheromonal recognition

Pregnancy block in mice requires exposure of recently mated females to urinary pheromones of a strange male, and when working with inbred strains this invariably requires urine from an outbred line. The pheromones which induce oestrus and early puberty in mice have been identified as the brevicomins and dihydrothiazoles. Since the same vomeronasal, neural and neuroendocrine pathways are also activated in pregnancy block, these compounds are likely candidates for pregnancy blocking pheromones. However, these relatively simple chemicals lack the capacity to code for differing mouse strains. Since large quantities of the polymorphic major urinary proteins from the lipocalin family found in urine serve as transporters for the dihydrothiazoles and brevicomins, and differ across strains, then these proteins must participate in pheromone recognition in the context of pregnancy block.      

Peptide and protein pheromones in amphibians

Purification, characterization and biological activity of urodele and anuran sex-pheromones were reviewed. Female-attracting pheromones obtained from the abdominal gland of Cynops pyrrhogaster and C. ensicauda males are peptides consisting of 10 amino acid residues being designated sodefrin and silefrin, respectively. Each pheromone attracted only conspecific females. Molecular cloning of cDNAs encoding sodefrin and silefrin revealed that both are generated from precursor proteins. Synthesis of these pheromones is regulated by prolactin (PRL) and androgen. Responsiveness of the female vomeronasal epithelium to sodefrin is enhanced by PRL and estrogen. The submandibular gland of the male terrestrial salamander, Plethodon jardani secretes a 22-kD proteinaceous pheromone that enhances female receptivity. It was revealed that every salamander synthesizes multiple isoforms of this pheromone, Plethodontid receptivity factor. The magnificent tree frog, Litoria splendida breed in an aquatic environment. The skin glands of the male secrete a female-attracting peptide pheromone, splendipherin, comprising 25 amino acid residues. The significance of the structure of the amphibian sex-pheromone as peptide and protein is discussed in terms of their species specificity.     

Firing properties of accessory olfactory bulb mitral/tufted cells in response to urine delivered to the vomeronasal organ of gray short-tailed opossums

In comparison with many mammals, there is limited knowledge of the role of pheromones in conspecific communication in the gray short-tailed opossum. Here we report that mitral/tufted (M/T) cells of the accessory olfactory bulb (AOB) of male opossums responded to female urine but not to male urine with two distinct patterns: excitation followed by inhibition or inhibition. Either pattern could be mimicked by application of guanosine 5'-O-3-thiotriphosphate and blocked by guanosine 5'-O-2-thiodiphosphate, indicating that the response of neurons in this pathway is through a G-protein-coupled receptor mechanism. In addition, the inhibitor of phospholipase C (PLC), U73122, significantly blocked urine-induced responses. Male and female urine were ineffective as stimuli for M/T cells in the AOB of female opossums. These results indicate that urine of diestrous females contains a pheromone that directly stimulates vomeronasal neurons through activation of PLC by G-protein-coupled receptor mechanisms and that the response to urine is sexually dimorphic.