The early postnatal regulation of reproductive hormones seems to be more complex in girls than in boys. The aim of this study was to describe inhibins A and B, FSH, LH, estradiol, and SHBG in a large prospective cohort of 473 unselected, healthy, 3-month-old girls. In full term, appropriate-for- gestational-age girls (n = 355) hormones showed a marked interindividual variation, with concentrations up to pubertal values [medians (95% confidence intervals): inhibin B, 82 pg/ml (<20-175); FSH, 3.8 IU/liter (1.2-18.8); LH, 0.07 IU/liter (<0.05-1.07); estradiol, 31 pM (<18-83); SHBG, 137 nM (72-260)]. In 38%, FSH levels exceeded 4.5 IU/liter. Weight at 3 months had significant inverse relationships with estradiol and SHBG (P = 0.048 and P = 0.001, respectively). Gestational age was negatively correlated to estradiol (P = 0.001), with a similar trend for LH, FSH, and inhibin B. Inhibin B was higher in premature girls [126 pg/ml (<20-265)] than in term [80 pg/ml (<20-181), P = 0.002] and postmature girls [59 pg/ml (<20-152), P = 0.012]. Likewise, estradiol levels in prematures were higher than in mature girls [51 pM (<18-128) vs. 31 pM (<18-85), P = 0.009]. Estradiol was also higher in small-for-gestational-age than in appropriate-for-gestational-age girls (P = 0.046), with inhibin B and LH, but not FSH, showing a similar trend. In conclusion, reproductive hormones showed a large variation, and concentrations corresponded to those observed in puberty. Our findings support the concept of a minipuberty in infant girls similar to that in boys.
During fetal development the testes secrete anti-Mullerian hormone and testosterone to induce formation of the male phenotype. Adult Leydig cells secrete testosterone under the control of LH, but the role of the fetal pituitary in regulating fetal Leydig cell function is unclear. To study the early relationship between pituitary and Leydig cell function, we have examined the development of fetal pituitary LH levels and Leydig cell function in normal mice and in hypogonadal (hpg) mice that lack GnRH and, thus, circulating gonadotropins. In normal and hpg mice, pituitary LH content was barely detectable until embryonic day 17 (E17), when levels began to increase significantly in both groups. Pituitary levels of LH in hpg mice were, however, only about 10% of normal at all ages. Full-length LH receptor transcripts were first detectable in fetal testes on E16 in both normal and hpg mice. In normal mice, levels of testicular messenger RNA (mRNA) encoding cytochrome P450 side-chain cleavage and 17alpha-hydroxylase increased from E13 to reach a peak around birth. In hpg mice, levels of mRNA encoding these enzymes were normal until around birth, at which time there was a significant decline. Levels of testicular mRNA encoding 3beta-hydroxysteroid dehydrogenase type I were similar in normal and hpg mice and showed little change during development. Intratesticular testosterone reached a peak on E18 in normal animals before declining again after birth. In hpg mice, intratesticular testosterone levels were normal throughout fetal development and on the day of birth, but were barely detectable by postnatal day 5. Results show 1) that fetal Leydig cell function in the mouse is normal in the absence of endogenous circulating gonadotropins; 2) that Leydig cells become dependent on gonadotropins shortly after birth; and 3) that pituitary LH synthesis can start in the absence of GnRH but is dependent on LH for a normal level of synthesis and secretion.
The first postnatal months of life in boys are characterized by activation of the hypothalamic-pituitary-testicular axis that results in the well depicted surge of reproductive hormones. Serum testosterone levels at that time are high, but infants do not display signs of virilization, and subsequently there is only indirect evidence that circulating androgens during the surge are biologically active. We used a recombinant cell bioassay to determine serum androgen bioactivity in 80 3-month-old boys born after full-term pregnancies (37-42 wk) in whom localization of the testes was determined by palpation after birth and at a mean age of 3 months. At that age, serum androgen bioactivity ranged from less than 0.8 to 1.9 nM testosterone equivalents and correlated with serum testosterone concentration (r = 0.71; P < 0.0001; n = 34), free androgen index (r = 0.80; P < 0.0001; n = 34), age (r = -0.29; P < 0.01; n = 80), and localization of the testes (r = -0.24; P < 0.05; n = 80). Moreover, all boys in this study with detectable androgen bioactivity (n = 26) had testes located in scrotal or high scrotal position (n = 64), whereas all boys (n = 16) with at least 1 suprascrotal, inguinal, or nonpalpable testis had nonmeasurable androgen bioactivity in serum (P < 0.01). We conclude that 3-month-old boys are exposed to biological effects of androgens during the postnatal activation of the hypothalamic-pituitary-testicular axis, and that this exposure may be reduced in boys with at least 1 testis located superior to the scrotum.
We have developed an immunofluorometric assay (IFMA) for rat (r) LH, which is based on two monoclonal antibodies, one to bovine and the other to human LH. Signal detection occurs by time-resolved fluorescence evoked by a europium label (Delfia, Wallac). The method is fast in comparison to the standard RIA with the NIDDK reagents (4 h vs. 3 days). The sensitivity of the IFMA assay (0.75 pg/tube; NIDDK rLH RP-2) is over 30-fold higher than that of the NIDDK RIA (usual detection limit, 20-30 pg/tube). Using 25-microliters serum samples, the sensitivity of IFMA is 0.03 micrograms/liter; with 100-microliters samples, it is 0.0075 micrograms/liter. The cross-reactivity of the IFMA assay is 0.3% with rFSH, 3% with rTSH, and less than 0.05% with rGH, rPRL, and the rat alpha-subunit. A linear correlation between IFMA and RIA values is seen at serum levels above 0.4 micrograms/liter. Below this level, only IFMA is able to detect concentration differences between samples. In practice, this means that only IFMA is able to provide meaningful measurements of suppressed levels of serum LH. The correlation coefficient between IFMA and the mouse interstitial cell in vitro bioassay for LH in randomly selected rat pituitary homogenates was 0.93 (n = 47). The serum concentration of LH determined by IFMA is 0.57 +/- 0.10 micrograms/liter in intact adult male rats (mean +/- SEM; n = 12) and 0.41 +/- 0.10 micrograms/liter (n = 10) in randomly cycling females. The level in hypophysectomized rat serum is 0.035 +/- 0.0033 micrograms/liter (n = 8), if the limit of sensitivity (0.03 microgram/liter) is assigned to unmeasurable levels. One-week treatment of male rats with 2-cm Silastic implants containing testosterone suppressed serum LH, measured by IFMA, from 0.56 +/- 0.057 to 0.086 +/- 0.057 micrograms/liter (P < 0.01). The suppression of LH measured in the same samples by RIA was lower, from 0.73 +/- 0.057 to 0.44 +/- 0.048 micrograms/liter (P < 0.01). A 5-day starvation of intact male rats suppressed serum LH from 0.57 +/- 0.10 to 0.30 +/- 0.05 microgram/liter by IFMA (P < 0.01), whereas the decrease determined by RIA was not significant (0.80 +/- 0.07 vs. 0.66 +/- 0.13 micrograms/liter).(ABSTRACT TRUNCATED AT 400 WORDS)
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