In utero contiguity to males does not influence morphology, behavioral sensitivity to testosterone, or hypothalamic androgen binding in CF-1 female mice

Non-model species deliver a non-model result: Nutria female fetuses neighboring males in utero have lower testosterone

Neighboring fetuses may impact their siblings in various respects, depending on their in utero location and sex. The effects of the intrauterine position (IUP) are widely studied in model organisms, especially laboratory bred murine strains that are characterized by short gestations and altricial offspring. In some species, the proximity to a male fetus and its higher circulating testosterone masculinizes neighboring female fetuses. In utero testosterone exposure might be manifested as higher testosterone concentrations, which contribute to a variation in morphology, reproductive potential and behavior. In this study, we examined the influence of neighboring an opposite sex fetus on testosterone levels in a feral animal model characterized by a long gestation and precocious offspring. Using necropsies of culled nutria (Myocastor coypus), we accurately determined the IUP and quantified testosterone immunoreactivity in fetal hair. We found that as expected, both male and female fetuses neighboring a male in utero had longer anogenital distance. However, females adjacent to males in utero showed lower testosterone levels than male fetuses, while testosterone levels of females without a male neighbor did not differ from those of males. This surprising result suggests an alternative mode by which local exogenous steroids may modify the local fetal environment. Our study emphasizes the importance of examining known phenomena in species with different life histories, other than the traditional murine models, to enhance our understanding of the evolutionary mechanisms that are driving sexual differentiation.

Variation in ano-genital distance in spontaneously cycling female mice

A recently observed developmental instability of the ano-genital distance (AGD) in female mice indicates that natural prenatal androgens do not have such a robust effect on female genital morphology as has been generally assumed. Part of this instability might be caused by oestrous cyclicity. To check this assumption, we examined the effect of the stage of the oestrous cycle on the AGD in adult (61-75 days old) female mice. Consistent with our assumption, the female AGD (1) varied during the oestrous cycle (p < 0.05), indicating thus rapid changes in morphology of female external genitalia, and (2) showed good repeatability (>0.66) in each stage of the oestrous cycle, suggesting that female genital morphology systematically varied within the oestrous cycle. Therefore, the stage of the oestrous cycle should be considered when assessing prenatal masculinization in adult female mice.

Testosterone treatment of pregnant rabbits affects sexual development of their daughters

The intrauterine position (IUP) may affect the sexual development of a female fetus in litter-bearing mammals. Females gestating between two males (2M) develop into masculinized adults compared to females without contiguous males (0M). Fetuses are known to secrete different types and amounts of steroid hormones during the prenatal period, and diffusing steroids may affect sexual differentiation of their neighbors, too. Exposure of elevated testosterone (T) levels generally results in masculinized anatomy and behavior in females of several rodent species. Our recent study showed that IUP-dependent masculinization is also present in the domestic rabbit, which shows large variation in sex related traits as adults. The aim of the present study was to test if the IUP effect in rabbits can be induced by exogenous testosterone treatment. By administering different doses of testosterone propionate (TP) to pregnant rabbits, and following anatomical and behavioral development of their female offspring, we obtained dose-dependent increase both in the anogenital distance (AGD) and chin-marking behavior of prenatal T exposed females. The effects of treatment corresponded to the variation due to intrauterine position in our previous study, namely, exposure to T of known external origin resulted in similar tendencies of masculinization in rabbit females as the in utero proximity to male siblings. Our results suggest that the IUP effects may have similar physiological bases across different mammalian taxa including Lagomorphs.

Intrauterine position effects on anogenital distance and digit ratio in male and female mice

Anogenital distance (AGD) and the ratio of the second (index) to fourth (ring) digit lengths (2D:4D) are two widely used indicators of prenatal androgen exposure. The former is commonly used in rodent models, while the latter is principally used in human studies. We investigated variation in these two traits in C57BL/6J mice to test the hypothesis that variation in these two traits reflect a common underlying variable, presumably testosterone exposure. AGD is a sexually dimorphic trait used to sex young rodents. This distance typically increases and becomes more male-like in female pups when their uterine neighbors are male. 2D:4D is sexually dimorphic in a number of species, including humans and other great apes. Lower digit ratios may be associated with greater exposure to androgens during fetal development in humans. We found the expected sexual dimorphism in AGD, but no significant sex difference in 2D:4D, and no correlation between 2D:4D and AGD. Gestating next to males increased a pup's 2D:4D ratio, but it had no effect on AGD. The lack of correlation between 2D:4D and AGDs in this mouse strain suggests that these two measures do not reflect a common influence of androgen exposure. The possible roles of temporal and localized effects of masculinization are discussed.

Intrauterine position and postnatal growth in Sprague–Dawley rats and ICR mice

In rodents, steroid hormones are thought to be transported between adjacent fetuses, and male or female fetuses that develop in utero between female fetuses may have higher serum levels of estradiol, and lower serum levels of testosterone, relative to siblings of the same sex that develop between two male fetuses. The consequence in the variation of postnatal growth, development, and function in the intrauterine position, using various parameters such as anogenital distance, preputial separation and vaginal opening, estrous cycle, locomotor activity, and growth of reproductive organs, were examined in Sprague-Dawley rats. ICR mice were treated with 17beta-estradiol before copulation and during pregnancy to address the interaction with endogenous estradiol during pregnancy. In rats, no evidence of effects of prior intrauterine position was observed for any of the parameters examined. Mouse fetal exposure via the mother to low-dose 17beta-estradiol revealed no changes in the rate of postnatal growth in males and females that developed in any intrauterine position in utero. The results of this study suggested that the intrauterine position of the embryos/fetuses did not affect the postnatal growth of the reproductive organs, sexual maturation, or behavior in rats and mice.

Intrauterine position effects

A review of the literature suggests that individual variability in sex-related traits may be influenced by variations in hormonal exposure during fetal development. In litter-bearing mammals, fetuses develop in utero and may be subjected to differing hormonal environments based upon the sex of neighboring fetuses. Female fetuses developing between two males tend to show masculinized anatomical, physiological and behavioral traits as adults. Female fetuses developing without adjacent males, on the other hand, tend to show more feminized traits as adults. These traits include permanently altered hormone levels, reproductive organs, aggressive behaviors, secondary sex ratios and susceptibility to endocrine disruption. This intrauterine effect is due to the transfer of testosterone from male fetuses to adjacent fetuses. While these effects have been most clearly demonstrated in mice, other rodents and swine also show intrauterine position (IUP) effects. Some of these effects are similar to the influence of prenatal stress on adult phenotypes. A few reports on human twins suggest that variability in some masculine and feminine traits may be due to intrauterine hormonal signals. IUP effects may impact a number of scientific fields of research such as endocrine disruption, toxicology, population biology, animal production and health.

Effect of prenatal uterine position on male and female rats sexual behavior

It is well known that female rats developing close to a male in utero show a higher frequency of heterotypical or male-like behavior in adulthood, and have longer anogenital distances. The present investigation was designed to evaluate the in utero masculine influence on the homotypical sexual behavior of male and female rats. Also explored was the influence on body weight on Gestation Day 21 (day of cesarean delivery) and 21, 40. and 120 days after birth, testicle weight following the gonadectomy of males on Day 40, and serum testosterone in males and females on the day of delivery. The presence of a contiguous male fetus located caudally with respect to uterine blood flow led to the masculinization of male-like behavior in male rats, the defeminization of female like behavior in females and to increased body weights on Day 21 of gestation in both sexes. No significant differences were detected in the remaining parameters. Findings indicated a gradation in the intensity of expression of male and female sexual behavior in adulthood related to the intrauterine position resulting in interindividual variability. The possible implication of this physiological phenomenon in the structure of rodent populations is discussed.

Effects of sex composition of the litter on anogenital distance in California mice (Peromyscus californicus)

Anogenital distance (AGD) is longer in male than in female neonatal rodents, but can be altered by the prenatal environment. The aim of this experiment was to examine the effects of the sex composition of the litter on AGD in a species with a small litter size. We found that the AGD distributions of male and female California mice, Peromyscus californicus, overlap before weaning (33 days of age), but after weaning, males have a larger AGD than females. Because AGD is significantly correlated with body mass in both males and females, we analyzed the effect of the sex composition of the litter on AGD, using ANCOVA on logarithmically transformed data, with the logarithm of body mass as the covariate. We showed that the sex composition of the litter does not affect AGD in males but has an effect on the AGD in females at birth and this effect is significant at 33 days of age. Females from litters composed of more than 75% males had a longer AGD than those born in litters composed principally of females. This study shows that intrauterine litter composition affects AGD in females of a species characterized by small litter sizes, as has been shown in rodent species with large litter sizes. Thus, AGD can be used as a predictor of masculinization of females due to intrauterine position.

The effects of estradiol on gonadotropin-releasing hormone neurons in the developing mouse brain

The hypothalamic-pituitary-gonadal (HPG) axis plays a critical role in the control of reproduction. Two key hormonal components of the HPG axis are gonadal steroids and gonadotropin-releasing hormone (GnRH). Gonadal steroids are known to organize the development of neural substrates which control adult reproductive behavior; GnRH is required for normal reproductive structure and function. The possibility that gonadal steroids may produce organizational changes in the pattern of GnRH staining observed in the brain is investigated through the use of injections of estradiol to neonatal mice and subsequent GnRH immunocytochemistry at 2 months of age. Our results indicate that the number of GnRH-immunoreactive (GnRH-ir) cells is normally lower in females than males. Estradiol did not affect the number of GnRH-ir cells in females, but significantly increased the number of GnRH-ir cells in males, suggesting that early exposure to estradiol results in masculinization of the GnRH axis of males.

Development and expression of hormonal systems regulating aggression

There are multiple pathways involved in the regulation of male typical aggression by T, and the functional pathway is determined by genotype. Target-tissue sensitivity to the aggression-promoting properties of T and its estrogenic and androgenic metabolites is determined by a complex sequence of events in which steroid receptors play a critical role. To date, it appears that the relative density of AR may be an important factor in the biobehavioral effects of androgens. Regarding sensitivity to estrogens, characterization of ER-NM interactions, and understanding of the contribution of the two activating functions within ER, appears to be necessary to comprehensively describe the cellular basis for responsiveness to the aggression-promoting effect of this T metabolite. In broader terms, these observations indicate that understanding the relationship between T and the expression of aggression in humans will require models that incorporate cellular aspects of steroid hormone action, including metabolism, receptor function, and gene regulation.

Genetic differences in female house mice in aggressive response to sex steroid hormone treatment

Male mice, genetically selected for aggression, characterized by short attack latency (SAL) or long attack latency (LAL), differ on several testosterone (T)-related parameters during ontogeny and adult age. The variation in aggressive behavior at adult age may be due to differences in degree of androgenization prenatally. When exposed to T at prenatal, neonatal, and/or adult age, nonlactating females also display intraspecific fighting behavior. In the present study, we investigated in females of the SAL and LAL selection lines, whether the differentiation of aggression involves processes similar to ones seen in males. Therefore, we injected females with testosterone propionate (TP) or vehicle on the day of birth, treated them after ovariectomy at adult age with T, estradiol (E), or vehicle, and tested their aggressive response. We found that neonatally vehicle-treated SAL females show a higher aggressive response to chronic T treatment at adult age than LAL females receiving the same treatment. Females of both selection lines treated with vehicle or E as adults were not aggressive. Neonatal TP treatment did not influence the adult T sensitivity and difference between selection lines in response to T at adult age. However, neonatally TP-treated SAL females showed aggressive behavior when treated with E at adult age, whereas LAL females failed to do so. These results suggest a genetic difference in susceptibility to T and E, which plays a major role prenatally, in organizing the development of sex steroid-dependent neural systems.

Genotype, uterine position, and testosterone sensitivity in older female mice

CF-1 and CK (C57BL/6J x AKr) female mice that developed in utero between two males (2M), adjacent to one male (1M), or between two females (0M) were tested for their sensitivity to the aggression-promoting property of testosterone (T) beginning at 9 months of age. Comparisons between the strains showed that a higher proportion of CF-1 females fought in response to T and that the period of hormone exposure required to induce aggression also was shorter in this strain. Within each of the genotypes, there were no systematic differences in responsiveness to T related to contiguity to males during fetal development. While the results provide further evidence for genotype as a major influence on neural sensitivity to androgen, they do not support uterine position of females relative to males as a source of phenotypic variation in responsiveness.

The intrauterine position phenomenon and precopulatory behaviors of house mice

The effects of intrauterine position on two sexually dimorphic, precopulatory, reproductive behaviors, were investigated in male and female mice of three different genetic strains. The two behaviors were: (i) urinary odor preference and (ii) ultrasonic mating vocalizations. In addition, anogenital distance was measured both at birth and later in adulthood as a morphological index of masculinization. The intrauterine positions of individual mice relative to male and female siblings were classified according to two different classification schemes based upon hypotheses of interfetal steroid transfer: (i) the contiguity hypothesis which is based on diffusion of steroids within the uterus and (ii) the transvasculature hypothesis which posits the movement of fetal steroids via the maternal vasculature. In contrast to expectations, intrauterine position defined by either the contiguity hypothesis or the transvasculature hypothesis, did not have a consistent effect on urinary odor preferences, ultrasonic mating vocalizations, or anogenital distance in male and female house mice.