Alterations in the maternal endocrine, nutritional, and metabolic environment disrupt the developmental trajectory of the fetus, leading to adult diseases. Female offspring of rats, subhuman primates, and sheep treated prenatally with testosterone (T) develop reproductive/metabolic defects during adult life similar to those that occur after intrauterine growth retardation. In the present study we determined whether prenatal T treatment produces growth-retarded offspring. Cottonseed oil or T propionate (100 mg, im) was administered twice weekly to pregnant sheep between 30-90 d gestation (term = 147 d; cottonseed oil, n = 16; prenatal T, n = 32). Newborn weight and body dimensions were measured the day after birth, and postnatal weight gain was monitored for 4 months in all females and in a subset of males. Consistent with its action, prenatal T treatment produced females and males with greater anogenital distances relative to controls. Prenatal T treatment reduced body weights and heights of newborns from both sexes and chest circumference of females. Prenatally T-treated females, but not males, exhibited catch-up growth during 2-4 months of postnatal life. Plasma IGF-binding protein-1 and IGF-binding protein-2, but not IGF-I, levels of prenatally T-treated females were elevated in the first month of life, a period when the prenatally T-treated females were not exhibiting catch-up growth. This is suggestive of reduced IGF availability and potential contribution to growth retardation. These findings support the concept that fetal growth retardation and postnatal catch-up growth, early markers of future adult diseases, can also be programmed by prenatal exposure to excess sex steroids.
Polycystic ovary syndrome (PCOS) is the most common endocrinopathy of reproductive-aged women and is exacerbated by obesity. Exposure of ewes to excess testosterone (T) from d 30-90 of gestation culminates in anovulation, functional hyperandrogenism, LH excess, and polyfollicular ovaries, features similar to those of women with PCOS, with some reproductive defects programmed by androgenic actions of T and others not. Excess weight gain during postnatal life increases the severity of these reproductive defects. Prenatal T-treated ewes also manifest reduced insulin sensitivity, a feature found in more than 70% of PCOS women. We tested the hypotheses that reduced insulin sensitivity of prenatal T-treated ewes is programmed by androgenic actions of T, and excess postnatal weight gain exaggerates this defect. In addition, we tested whether disruptive effects of excess weight gain on insulin sensitivity index are transferred to female offspring. Insulin sensitivity was assessed using iv glucose tolerance tests. Results revealed that disruptive effects of prenatal T excess on insulin sensitivity were programmed by androgenic action of T and postnatal overfeeding-impaired insulin sensitivity in both T-treated and controls and that prenatal T-treated sheep tend to manifest such overfeeding impairments earlier than controls. Importantly, offspring of overweight controls also manifest defects in insulin dynamics supportive of intergenerational transfer of obesity-related traits. The findings are of relevance in the context of developmental programming of insulin resistance by prenatal steroids and excess weight gain.
We studied the impact of prenatal androgen exposure on the timing of onset of puberty, maintenance of cyclicity in the first breeding season, and the LH surge mechanism in female sheep. Pregnant sheep were injected with testosterone propionate (100 mg i.m.) twice each week from Day 30 to Day 90 (D30-90) or from Day 60 to Day 90 (D60-90) of gestation (term = 147 days). Concentrations of plasma progesterone and gonadotropins were measured in blood samples collected twice each week from control (n = 10), D60-90 (n = 13), and D30-90 (n = 3) animals. Rate of weight gain and initiation of estrous behavior were also monitored. After the first breeding season, when the animals entered anestrus, competency of the gonadotropin surge system to respond to estradiol positive feedback was tested in the absence or presence of progesterone priming for 12 days. Prenatally androgenized females had similar body weight gain and achieved puberty (start of first progestogenic cycle) at the same time as controls. Duration of the breeding season and the number of cycles that occurred during the first breeding season were similar between control and prenatally androgenized sheep. In contrast, prenatal exposure to androgens compromised the positive feedback effects of estradiol. Onset of LH/FSH surges following the estradiol stimulus was delayed in both groups of androgenized ewes compared with the controls in both the absence and presence of progesterone priming. In addition, the magnitude of LH and FSH surges in the two animals that surged in the D30-90 group were only one third and one half, respectively, of the magnitudes observed in the control and D60-90 groups. The present findings indicate that disruption of the surge system can account for the fertility problems that occur during adulthood in prenatally androgenized sheep.
Exposure of female sheep fetuses to excess testosterone (T) during early to midgestation produces postnatal hypergonadotropism manifest as a selective increase in LH. This hypergonadotropism may result from reduced sensitivity to estradiol (E 2 ) negative feedback and/or increased pituitary sensitivity to GnRH. We tested the hypothesis that excess T before birth reduces responsiveness of LH and FSH to E 2 negative feedback after birth. Pregnant ewes were treated with T propionate (100 mg/kg in cotton seed oil) or vehicle twice weekly from d 30 -90 gestation. Responsiveness to E 2 negative feedback was assessed at 12 and 24 wk of age in the ovaryintact female offspring. Our experimental strategy was first to arrest follicular growth and reduce endogenous E 2 by administering the GnRH antagonist (GnRH-A), Nal-Glu (50 g/kg sc every 12 h for 72 h), and then provide a fixed amount of exogenous E 2 via an implant. Blood samples were obtained every 20 min at 12 wk and every 10 min at 24 wk before treatment, during and after GnRH-A treatment both before and after E 2 implant. GnRH-A ablated LH pulsatility, reduced FSH by approximately 25%, and E 2 production diminished to near detection limit of assay at both ages in both groups. Prenatal T treatment produced a precocious and selective reduction in responsiveness of LH but not FSH to E 2 negative feedback, which was manifest mainly at the level of LH/GnRH pulse frequency. Collectively, these findings support the hypothesis that prenatal exposure to excess T decreases postnatal responsiveness to E 2 inhibitory feedback of LH/GnRH secretion to contribute to the development of hypergonadotropism. (Endocrinology 146: 4281-4291, 2005)
Prenatal testosterone excess leads to neuroendocrine, ovarian, and metabolic disruptions, culminating in reproductive phenotypes mimicking that of women with polycystic ovary syndrome (PCOS). The objective of this study was to determine the consequences of prenatal testosterone treatment on periovulatory hormonal dynamics and ovulatory outcomes. To generate prenatal testosterone-treated females, pregnant sheep were injected intramuscularly (days 30-90 of gestation, term=147 days) with 100 mg of testosterone-propionate in cottonseed oil semi-weekly. Female offspring born to untreated control females and prenatal testosterone-treated females were then studied during their first two breeding seasons. Sheep were given two injections of prostaglandin F2alpha 11 days apart, and blood samples were collected at 2-h intervals for 120 h, 10-min intervals for 8 h during the luteal phase (first breeding season only), and daily for an additional 15 days to characterize changes in reproductive hormonal dynamics. During the first breeding season, prenatal testosterone-treated females manifested disruptions in the timing and magnitude of primary gonadotropin surges, luteal defects, and reduced responsiveness to progesterone negative feedback. Disruptions in the periovulatory sequence of events during the second breeding season included: 1) delayed but increased preovulatory estradiol rise, 2) delayed and severely reduced primary gonadotropin surge in prenatal testosterone-treated females having an LH surge, 3) tendency for an amplified secondary FSH surge and a shift in the relative balance of FSH regulatory proteins, and 4) luteal responses that ranged from normal to anovulatory. These outcomes are likely to be of relevance to developmental origin of infertility disorders and suggest that differences in fetal exposure or fetal susceptibility to testosterone may account for the variability in reproductive phenotypes.
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