Naltrexone normalizes the suppression but not the surge of delta 5-3 beta-hydroxysteroid dehydrogenase activity in Leydig cells of stressed rat fetuses

Environmental and genetic contributors to salivary testosterone levels in infants

Transient activation of the hypothalamic-pituitary-gonadal axis in early infancy plays an important role in male genital development and sexual differentiation of the brain, but factors contributing to individual variation in testosterone levels during this period are poorly understood. We measured salivary testosterone levels in 222 infants (119 males, 103 females, 108 singletons, 114 twins) between 2.70 and 4.80 months of age. We tested 16 major demographic and medical history variables for effects on inter-individual variation in salivary testosterone. Using the subset of twins, we estimated genetic and environmental contributions to salivary testosterone levels. Finally, we tested single nucleotide polymorphisms (SNPs) within ±5 kb of genes involved in testosterone synthesis, transport, signaling, and metabolism for associations with salivary testosterone using univariate tests and random forest (RF) analysis. We report an association between 5 min APGAR scores and salivary testosterone levels in males. Twin modeling indicated that individual variability in testosterone levels was primarily explained by environmental factors. Regarding genetic variation, univariate tests did not reveal any variants significantly associated with salivary testosterone after adjusting for false discovery rate. The top hit in males was rs10923844, an SNP of unknown function located downstream of HSD3B1 and HSD3B2. The top hits in females were two SNPs located upstream of ESR1 (rs3407085 and rs2295190). RF analysis, which reflects joint and conditional effects of multiple variants, indicated that genes involved in regulation of reproductive function, particularly LHCGR, are related to salivary testosterone levels in male infants, as are genes involved in cholesterol production, transport, and removal, while genes involved in estrogen signaling are related to salivary testosterone levels in female infants.

Fetal testosterone surge: specific modulations induced in male rats by maternal stress and/or alcohol consumption

Plasma testosterone (T) was measured in control male and female rats on gestational days 16, 17, 18, 19, and 20 and on days 17-20 in males from dams who were fed ethanol and/or were stressed during pregnancy. Circulating T in control males showed an earlier rise, yielding a longer period of prenatal T elevation, than was reported previously (Endocrinology 106 (1980)306). Compared to control males, exposure to alcohol-alone augmented T on days 18 and 19, stress-alone attenuated prenatal T, and the combination of stress and alcohol completely blocked the normal rise in T between days 17 and 18. When these prenatal alterations in T are viewed along with effects these same treatments have on the postparturient T surge (Horm. Behav. 41 (2002) 229), a possible explanatory mechanism emerges for the uniquely different behavioral patterns of sexual behavior differentiation induced in males by prenatal exposure to alcohol, stress, or both factors. Whereas the potential for feminine behavior is retained to the extent that either the prenatal or the neonatal T surge is attenuated, the male potential is more sensitive to reductions in the fetal surge and is maximally disrupted if both the prenatal and the postparturitional T surges are suppressed.

Changes in the hormonal concentrations of pregnant rats and their fetuses following multiple exposures to a stressor during the third trimester

Human and animal studies indicate that stress during pregnancy can exert long-term effects on the development of the offspring, effects that appear to be mediated in part by the hypothalamic-pituitary-adrenal (HPA) axis. In this experiment changes in levels of a variety of HPA and other hormones in both pregnant rats and their fetuses were investigated. Trunk blood was collected from pregnant females and fetuses following repeated 45-min presentations of restraint, bright lights, and heat during the third trimester. In addition, testes were harvested from the male fetuses. Hormone concentrations were determined by radioimmunoassay. Pregnant females had elevated titers of plasma corticosterone, aldosterone, and ACTH for approximately 15 min following termination of the stressor. No differences were found for beta-endorphin or prolactin. Fetuses showed a pattern of changes in plasma corticosterone and aldosterone that was similar to that of pregnant females, but no effect was observed for fetal ACTH titers. These results are consistent with a role of the HPA axis in the effects of gestational stress. Testicular levels of CRF on gestational day 21 were lower in fetuses of stressed females than in those of nonstressed females. The reduced levels of testicular CRF suggest that CRF may be involved in the altered pattern of sexual differentiation of males stressed during gestation.

Stress during pregnancy alters rat offspring morphology and ultrasonic vocalizations

Stress during pregnancy, or prenatal stress, is known to alter offspring behavior, morphology and physiology. We found that a heat, light and restraint stressor applied during the third trimester of pregnancy: 1) decreased the weight gain of adult female rats during pregnancy; 2) reduced the weight of pups, as well as the anogenital distance of male offspring, at birth; and 3) increased the number of ultrasonic vocalizations emitted by pups during isolation in a novel environment on Postnatal Day 14. These results closely approximate those we previously observed after peripheral administration of corticotropin-releasing factor to pregnant females during the third trimester. Together, the studies strongly suggest a role for corticotropin-releasing factor and/or other hormones of the hypothalamic-pituitary-adrenal system in mediating some of the effects of gestational stress.

Prenatal dexamethasone or stress but not ACTH or corticosterone alter sexual behavior in male rats

Prenatal maternal stress in rats and mice can demasculinize and feminize the sexual behavior of adult male offspring. Causal mechanisms are unknown, but one attractive hypothesis is that stress activation of maternal adrenal glucocorticoid secretion is the responsible agent. To test this hypothesis, pregnant rats were exposed to a variety of substances which enhance glucocorticoid actions. These included ACTH (20 IU of a gel preparation, SC once daily), corticosterone (CORT; 7 mg/kg SC in oil, three times daily), or dexamethasone (DEX; 0.1 mg/kg, SC once daily). Controls included noninjected dams and a positive stress control group (restraint under bright lights three times daily). All treatments reduced maternal weight gain, DEX most potently. No treatment altered litter size, stillbirths, or sex ratio, but DEX reduced weight at birth, an effect still seen at postnatal day 85. DEX, CORT, and stress reduced male adrenal weight at birth, while DEX and CORT altered sexual differentiation as measured by anogenital distance. Stress impaired adult male sexual performance but not the lordosis quotient following exposure of animals to stud males. DEX affected both measures. No other treatment had any significant effect on sexual behavior. No treatment altered plasma LH levels, either basal or in response to an estrogen challenge in adult gonadectomized males. In adulthood there was no treatment effect on stress reactivity, measured behaviorally or by plasma glucocorticoids. Correlational analysis revealed that weight gain during pregnancy was the single best predictor of subsequent sexual performance. It is concluded that prenatal dexamethasone exposure demasculinizes and feminizes male offspring.(ABSTRACT TRUNCATED AT 250 WORDS)

Sexually dimorphic areas in the rat medial amygdala: resistance to the demasculinizing effect of prenatal stress

Exposure to prenatal stress blocks full masculinization of several sexually dimorphic nuclei in the brain and spinal cord of male rats. We now compare the adult volume of the medical amygdala (MA) and two of its component cell groups, posterodorsal (MePD) and posteroventral (MePV), in prenatally stressed male rats and nonstressed males and females. Previous reports of sex differences (male > female) in the overall size of the MA and the MePD component were confirmed, and we identified a previously unreported sex difference (male > female) in MePV. Prenatal stress had no effect on the size of the total MA, or of the MePD or MePV in males. Maternal stress attenuates the surge in plasma testosterone (T) which normally occurs on days 18 and 19 of gestation in male rats. This brief suppression of T during prenatal development leads to incomplete masculinization of some sexually dimorphic features of the CNS (i.e. the SDN-MPOA of the hypothalamus, and SNB and DLN of the spinal cord) but not others (i.e. the MA, MePD, and MePV). The selective effects of prenatal stress on neural differentiation may be due to differences in the onset and duration of the periods when each of these structures in most sensitive to T and/or its metabolites.

Leydig cell heterogeneity as judged by quantitative cytochemistry of 3 beta-hydroxysteroid dehydrogenase activity in individual rat Leydig cells

3 beta-Hydroxysteroid dehydrogenase (3 beta-HSD) is one of the key enzymes involved in the steroidogenic pathway of Leydig cells. In this study, quantitative cytochemistry was used to detect the 3 beta-HSD staining intensity in individual rat Leydig cells. The measurement of the intensity of staining was a reliable method reflecting the relative amount of 3 beta-HSD activity. The objective was to determine the presence, basal and hCG-mediated effect of 3 beta-HSD activity in individual Leydig cells. 3 beta-HSD cytochemistry was performed in both, 8 and 12 microns diameter rat Leydig cells. The results showed that both populations of Leydig cells have different basal 3 beta-HSD activity. The 8 microns cells showed a greater basal 3 beta-HSD activity than the 12 microns cells when their optical density values were normalized to their size. A difference in regulation of the enzymatic activity by LH/hCG was observed in the two types of Leydig cells. Incubation of the whole population of Leydig cells with hCG (1IU), decreased the 3 beta-HSD activity in the 8 microns cells, but increased the activity in the 12 microns cells. The results describe for the first time that the 3 beta-HSD activity may be differentially regulated by LH/hCG in Leydig cells.

Prenatal stress feminizes juvenile play patterns in male rats

Sexually dimorphic rough-and-tumble play patterns were compared in male and female rats derived from control mothers and mothers stressed from days 14-21 of pregnancy. Animals were weaned into groups of 8 consisting of 2 males and 2 females from each treatment. Play in the home cage was recorded at 25, 28, 31, 34, 37 and 45 days of age and was most intense on day 31. The overall level of play was significantly higher in control males than in females or stressed males. Control males showed higher levels of the pinning component of rough-and-tumble play than females or stressed males. No play partner preferences were detected in any group. In adulthood, a higher percentage of stressed than control males displayed the female lordotic pattern. No deficits in ejaculatory behavior occurred in the stressed males. Since maternal stress alters patterns of plasma testosterone in male fetuses, the data suggest that the sexual differentiation of social play begins during prenatal ontogeny in the rat. The present results show that sexually dimorphic behaviors displayed before puberty are incompletely masculinized in prenatally stressed males, a finding similar to that reported for a number of adult behaviors.

Prenatal stress alters sexually dimorphic nuclei in the spinal cord of male rats

The spinal nucleus bulbocavernosus (SNB), the dorsolateral nucleus of the spinal cord (DLN), and the bulbocavernosus/levator ani (BC/LA) muscle complex were examined in prenatally stressed and control adult male rats, which had been screened for male copulatory behavior. There was a small but significant decrease in the number of DLN (5%) and SNB (3%) neurons in prenatally stressed males compared to controls. Prenatal stress had no effect on the somal or nuclear area of individual neurons within either nucleus, nor did it affect the weight of the BC/LA muscle complex. There were no differences in any of these measures between males that ejaculated and those did not in either the stressed or the control group. These data suggest that exposure of pregnant rats to transient environmental stressors may result in permanent alterations in androgen-sensitive CNS structures in their male offspring.