Puberty acceleration by a urinary cue from male mice in feral populations

Male-mediated early maturation unlikely to evolve via adaptive evolution

The Vandenbergh effect, or male-mediated maturation, occurs when females reach sexual maturation upon exposure to a novel male. Male-mediated maturation is found across mammals, including in geladas, Theropithecus gelada, where it may be an adaptive counterstrategy to infanticide that follows the immigration of a new male; maturing after male immigration maximizes a female's chances of weaning her first offspring before the next infanticidal male immigrates (the 'optimal timing hypothesis'). Alternatively, the nonadaptive 'Bruce effect by-product hypothesis' posits that male-mediated maturation in geladas (and possibly other mammals) is triggered by the same physiological changes that, in pregnant females, produce spontaneous abortion (the Bruce effect). We test both hypotheses using theory and observational data. We show that neither male-mediated maturation nor its associated hormonal changes occur in baboons (Papio cynocephalus × P. anubis), a primate without the Bruce effect. An individual-based model suggests that male-mediated maturation should not evolve via adaptive evolution in either geladas or baboons. Finally, we derive the selection coefficient for male-mediated maturation and show it is likely to be very small because male-mediated maturation yields only marginal potential benefits unless the system is extremely fine-tuned. We conclude that male-mediated maturation in geladas is a by-product of the Bruce effect and more broadly that the Vandenbergh effect may be nonadaptive.

Effects of density on sex organ development and female sexual maturity in laboratory-bred Microtus fortis

Density dependence plays a key role in determining the population sizes of rodents. To explore density-dependent effects on sexual development, we documented and analyzed the development of the sex organs and hormone concentrations in both sexes, and the time to maturity in females of the reed vole in response to different population densities under laboratory conditions. Weaned voles were put into either same-sex or mixed-sex groups. Upon maturity, organ coefficients were calculated for sex organs as the length or weight of the sex organ divided by the length or weight of the body, respectively. The results demonstrate that, for individuals in same-sex groups, the coefficients for uterine length and short diameter of the testis decreased as population density increased. Population density had a highly significant effect on hormone concentrations as well as time to maturity in females. Population density in mixed-sex groups affects hormone concentrations, and increases the organ coefficients for ovarian weight, uterine weight, and uterine length; however, population density had no significant effect on the time to maturity of female voles in mixed-sex groups. These experiments showed that the effect of density dependence on the development of the vole differed between same-sex and mixed-sex conditions, the effects of increased density being greater in same-sex groups. We conclude that the effect of promoting sexual development between individuals might be greater than the effect of inhibition between individuals in mixed-sex groups.

Two of a Kind or a Full House? Reproductive Suppression and Alloparenting in Laboratory Mice

Alloparenting, a behavior in which individuals other than the actual parents act in a parental role, is seen in many mammals, including house mice. In wild house mice, alloparental care is only seen when familiar sibling females simultaneously immigrate to a male's territory, so in the laboratory, when a pair of unfamiliar female wild mice are mated with a male, alloparenting does not occur because one female will typically be reproductively suppressed. In contrast, laboratory mice are assumed to alloparent regardless of familiarity or relatedness and are therefore routinely trio bred to increase productivity. Empirical evidence supporting the presence of alloparental care in laboratory mice is lacking. Albino and pigmented inbred mice of the strain C57BL/6NCrl (B6) and outbred mice of the stock Crl:CF1 (CF1) were used to investigate alloparenting in laboratory mice since by mating pigmented and albino females with albino males of the same stock or strain, maternal parentage was easily determined. We housed pairs (M:F) or trios (M:2F) of mice in individually ventilated cages containing nesting material and followed reproductive performance for 16 weeks. Females in trios were tested to determine dominance at the start of the experiment, and again 5 days after the birth of a litter to determine if a female's dominance shifted with the birth of pups. Results showed a significant and expected difference in number of offspring produced by B6 and CF1 (p < 0.0001). Pigmented mice nursed and nested with albino pups and vice-versa, confirming empirical observations from many that group nesting and alloparenting occurs in unrelated laboratory mice. When overall production of both individual mice and cages was examined, reproductive suppression was seen in trio cages. Dominance testing with the tube test did not correlate female reproduction with female dominance in a female-female dyad. Due to the reproductive suppression noted in trios, on a per-mouse basis, pair mating outperformed trio mating (p = 0.02) when the measure was weaned pups/female/week. No infanticide was seen in any cages, so the mechanism of reproductive suppression in trio matings may occur before birth.

Activation of the olfactory system in response to male odors in female prepubertal mice

Exposure to male odors during the prepubertal period accelerates puberty, a phenomenon known as the Vandenbergh effect. This experiment identifies the parts of the olfactory pathway that respond to male odors in prepubertal female mice. Female mice were kept in a room free of adult male odors from birth until odor exposure. At post-natal day 21, 24 or 28, (ages representing time points early, intermediate, and late in the prepubertal period) mice were exposed to clean bedding, soiled bedding from castrated males, or soiled bedding from intact males. Each group was exposed to odor in separate rooms to prevent cross contamination. Ninety minutes after odor exposure, mice were sacrificed, the brains removed and prepared for c-Fos immunohistochemistry. The numbers of neurons expressing c-Fos were counted in a defined area of the following nuclei: AOB mitral layer, AOB granular layer, MOB, MEPV, MEPD, Aco, BNST, MPOA, and VMH. There was a significant effect of age on c-Fos-expression in the MEPV, MEPD, Aco, MPOA, BNST and piriform cortex. There was a significant effect of odor on c-Fos-expression in the MEPV, MEPD, Aco, MPOA, and VMH, showing that these areas are differentially sensitive to intact male odors vs. clean bedding and that these brain areas may be responsible for communicating odor information that drives puberty acceleration.

Chemosignals, hormones and mammalian reproduction

Many mammalian species use chemosignals to coordinate reproduction by altering the physiology and behavior of both sexes. Chemosignals prime reproductive physiology so that individuals become sexually mature and active at times when mating is most probable and suppress it when it is not. Once in reproductive condition, odors produced and deposited by both males and females are used to find and select individuals for mating. The production, dissemination and appropriate responses to these cues are modulated heavily by organizational and activational effects of gonadal sex steroids and thereby intrinsically link chemical communication to the broader reproductive context. Many compounds have been identified as "pheromones" but very few have met the expectations of that term: a unitary, species-typical substance that is both necessary and sufficient for an experience-independent behavioral or physiological response. In contrast, most responses to chemosignals are dependent or heavily modulated by experience, either in adulthood or during development. Mechanistically, chemosignals are perceived by both main and accessory (vomeronasal) olfactory systems with the importance of each system tied strongly to the nature of the stimulus rather than to the response. In the central nervous system, the vast majority of responses to chemosignals are mediated by cortical and medial amygdala connections with hypothalamic and other forebrain structures. Despite the importance of chemosignals in mammals, many details of chemical communication differ even among closely related species and defy clear categorization. Although generating much research and public interest, strong evidence for the existence of a robust chemical communication among humans is lacking.

Exposure to developing females induces polyuria, polydipsia, and altered urinary levels of creatinine, 17beta-estradiol, and testosterone in adult male mice (Mus musculus)

Novel male mice can accelerate reproductive maturation in proximal developing females, an effect mediated by the chemistry of the males' urine. Exogenous estrogens can similarly accelerate female sexual development. In Experiment 1, adult male mice were housed across wire grid from either empty compartments or those containing post-weanling females. Proximity of females caused males to urinate more, progressively over days of exposure, with most urination directed towards females' compartments. Male urine collected after 5 days in these conditions was analyzed by enzyme immunoassay for 17beta-estradiol, testosterone, and creatinine. Urinary creatinine of isolated males significantly exceeded that of female-exposed males. Unadjusted urinary steroids also trended toward higher levels in isolates, but creatinine-adjusted estradiol and testosterone of female-exposed males significantly exceeded that of isolated males. In Experiment 2, measurement of water consumption indicated significantly greater drinking by female-exposed as opposed to isolated males. In Experiment 3, males were housed in isolation or beside post-weanling intact (sham-operated) females, ovariectomized females, or intact (sham-operated) males. Male water consumption was elevated in all conditions involving social contact. Urinary creatinine was significantly lower in female-exposed males compared to isolated controls, while unadjusted testosterone was significantly lower in males in all social conditions. Again, creatinine-adjusted estradiol in female-exposed males significantly exceeded that of isolates. These data indicate that adult males drink and urinate more, have more dilute urine, and have a higher ratio of estradiol to creatinine when they are near developing females. These dynamics increase females' exposure to urinary steroids and other urinary constituents that can hasten sexual maturity.

Preputialectomised and intact adult male mice exhibit an elevated urinary ratio of oestradiol to creatinine in the presence of developing females, whilst promoting uterine and ovarian growth of these females

Exposure to novel adult males and their urine can hasten the onset of sexual maturity in female mice. Some evidence implicates chemosignals from males’ preputial glands, while other evidence suggests that male urinary steroids, especially 17β-oestradiol, contribute to this effect. The present experiment was designed to determine whether preputial gland removal would influence the capacity of males to accelerate female sexual development, and to measure male urinary oestradiol and testosterone in the presence or absence of these glands. Juvenile females aged 28 days were housed for two weeks in isolation or underneath two outbred males that had undergone preputialectomy or sham surgery. Urine samples were collected non-invasively from males that were isolated or exposed to females, then assayed for oestradiol, testosterone and creatinine. Combined uterine and ovarian mass from females sacrificed at 43 days of age was increased by exposure to males, regardless of whether or not these males had been preputialectomised. Male urinary creatinine was reduced by exposure to developing females. Creatinine-adjusted oestradiol and testosterone were significantly greater in female-exposed than in isolated males, in both preputialectomised and intact males. These data suggest that the preputials are not necessary for the capacity of males to hasten female uterine and ovarian growth. As exogenous oestrogens can promote uterine growth and other parameters of female reproductive maturation, oestradiol in males’ urine may contribute to earlier sexual maturity in male-exposed females.

The role of pheromones and biostimulation in animal reproduction

It is now known that pheromonal communication plays an important role in mammalian behaviour and reproductive processes. Chemical communication with pheromones is one means of transmitting such information. In mammals, signalling and priming pheromones are thought to act either singly or in combination through olfaction, auditory, visual (sight) or tactile stimuli. Pheromones are air-borne chemical substances ("signals") released in the urine or feces of animals or secreted from cutaneous glands that are perceived by the olfactory system and that elicit both behavioural and endocrine responses in conspecifics. Extensive studies in insects, rodents, swine, sheep, goats and cattle have established the importance of pheromones in the strong influence exerted by the male on reproductive activity in the female. There is a pheromone produced by the queen honey bee, which has two functions: inhibition of queen rearing and suppression of oogenesis in workers and in addition attracts drones during nuptial flight. It has also been demonstrated that the urine of male mice, rats, feral species and other wild rodents contains a priming pheromone that is responsible for hastening puberty in the females. Pheromones in the wool, wax and urine of a ram are sufficient to stimulate ewes to ovulate, while the buck has a strong characteristic seasonal odor and a buck jar containing the odor of the buck can be used as an aid in the detection of oestrus in does. The mere presence of the boar at the time of insemination of the sow improves sperm transport and ovulation, while the presence of the vasectomised bull has been reported to hasten the onset of puberty in heifers and also early resumption of ovarian activity in cattle following parturition. The role of pheromones in bovine reproduction is not as clearly defined as in sheep, goats and swine. Pheromones and other allelomimetic cues can exert profound effects on reproductive activity via the hypothalamic system that generates pulses of gonadotropin-releasing hormone. Manipulations of these factors and other pathways linking environmental inputs to reproductive output can lead to developing the concept of "control systems technologies", aimed at controlling reproductive performance. The knowledge acquired on the effectiveness of biostimulation; the factor which conditions it and the biological mechanism which produces it in livestock species, allows its use as a breeding management tool. The understanding of the role of pheromones could be of potential economic importance in addressing some of the problems associated with livestock production in the tropics. The biostimulation technique offers a potentially useful and practical way to improve reproductive efficiency in livestock species in the tropics. The exact nature of the cues and the role of biostimulation in livestock species especially swine, sheep, goats and cattle in developing countries require more attention.

The staggerer gene curtails the reproductive life span of females

Three studies were undertaken to investigate some features of the reproductive activity of female staggerer mice of the C57BL/6 strain. It was found that in the staggerer female, (1) vaginal opening and onset of vaginal estrous cycling were delayed; (2) the vaginal estrous cycle was irregular and characterized by abnormally prolonged diestrous and estrous phases, and (3) the reproductive life span of the mutant female was confined to a 3-month period after puberty. The abnormalities observed in sexual functions suggest a specific influence of the staggerer gene on reproductive activity.

Environmental factors and age of puberty in female house mice

Genetics, urinary chemosignals and related social influences, and ambient conditions affect reproduction in female mice. Five experiments tested the effects of environmental stressors on age at first vaginal estrus in female house mice. Environmental disruption in the form of changing the cage bedding and/or nesting material at various prescribed intervals resulted in different degrees of puberty delay relative to non-disrupted control mice. Disruption in the form of a male chasing the female for one to three 15-min intervals each day or the female being trapped and held in a live-trap for one to three 15-min intervals each day resulted in delays in puberty for treatments involving multiple daily disruptions. Food deprivation, but not water deprivation, influenced the onset of puberty. Variations in temperature and humidity resulted in differences in the age of puberty; low but not high temperatures and extremely low humidity levels delayed sexual maturation.

Acceleration and delay of puberty in female mice via urinary chemosignals: age of the urine stimulus

Five experiments were conducted to test the effects of the age of urine on the acceleration and delay of puberty in female mice resulting from treatment with urinary chemosignals. The chemosignal in the urine of male mice that accelerates female puberty was not affected by remaining exposed to the air at room conditions for up to 7 days, or when dried in air and reconstituted with water. The chemosignal in the urine of grouped female mice that delays puberty in females and the chemosignal present in the urine of pregnant and lactating female mice that accelerates female puberty were affected to varying degrees by exposure to room conditions; at 5-to-7 days of exposure the urine samples lost their capacity to delay or accelerate sexual maturation. These results are in agreement with earlier work indicating that the male chemosignal is not volatile, whereas the substances in urine from grouped females and pregnant or lactating females are more volatile. The results also have implications for interpretations of how the urinary chemosignals may affect the population biology of house mice under natural conditions.

alpha 2u-Globulin is present in the rat anterior pituitary

The possibility that the pituitary gland may contain as yet undiscovered regulatory factors is intriguing. Recent reports have suggested the presence, in the anterior pituitary, or a number of proteins of extrapituitary origin. alpha 2u-Globulin, a rat serum and urinary protein, previously shown to be synthesized in the submaxillary gland and in the liver under anterior pituitary control, has now been localized by immunocytochemistry in the cytoplasm of some cells of the anterior pituitary. No alpha 2u-globulin could be detected in either the intermediate or posterior pituitary. The presence of alpha 2u-globulin was confirmed and quantitated by radioimmunoassay. Using RNA blot analysis and cloned alpha 2u-globulin cDNA probes, we could not detect alpha 2u-globulin mRNA sequences in pituitary RNA, indicating that alpha 2u-globulin is not synthesized therein. The presence of alpha 2u-globulin, presumably of circulatory origin, in certain anterior pituitary cells suggests that it may play a role in anterior pituitary function.

Delay and acceleration of puberty in female mice by urinary chemosignals from other females

A sequence of 7 experiments tested various aspects of the acceleration and delay of sexual maturation in young female mice as affected by cues from other females: Singly caged females produce the maturation-delaying chemosignal when exposed to urine from grouped females. Urine from females housed 3 or more/cage produces delays in puberty for young females. Urine from females in estrus accelerates puberty in young females relative to untreated controls or urine from non-estrous females. The delay-of-maturation phenomenon in female mice is not affected by reproductive history, cross-fostering of pups, or varying the cagemates according to whether they are sibs or nonsibs. Taken together these and previous findings suggest that female mice excrete, in their urine, a series of chemicals which act as signals regarding the adequacy of reproductive conditions.