Manasco P K, Umbach D M, Muly S M, Godwin D C, Negro-Vilar A, Culler M D, Underwood L E
Laboratory of Molecular and Integrative Neurosciences, National Institute of Environmental Health Sciences, Research Triangle Park, North Carolina 27709-2700, USA.
J Clin Endocrinol Metab. 1995 Jul;80(7):2046-52. doi: 10.1210/jcem.80.7.7608253.
To investigate hormonal changes occurring in male puberty, we measured LH, FSH, testosterone, and alpha-inhibin immunoactivity in serum samples drawn every 10 min for 8 h (2100-0500 h) from each of 50 normal prepubertal and pubertal boys, aged 8.4-18.8 yr. We measured gonadotropins with ultrasensitive immunofluorometric assays, and testosterone and alpha-inhibin with RIAs. Unlike previous studies, which indexed pubertal development with Tanner stages, we used testicular volume, a more finely graduated indicator of development, to reveal patterns that were obscured when subjects were grouped by Tanner stage. The overnight mean concentration of each hormone increased with testis volume, but the rate of increase on a logarithmic scale slowed as testes grew. Log LH rose precipitously in the late prepubertal and early pubertal periods and plateaued during mid- and late puberty. Based on fitted regression curves, LH increased about 20-fold (from 0.11 IU/L) between testis volumes of 1 and 10 mL, but only an additional 1.5-fold by 30 mL. The developmental trajectory of log testosterone was like that of log LH, but rose less steeply early in puberty. From 0.14 micrograms/L at a testis volume of 1 mL, testosterone increased about 8.5-fold by 10 mL and an additional 3-fold by 30 mL. In contrast, logarithms of overnight mean FSH and alpha-inhibin concentrations rose at a more nearly constant rate throughout puberty. From 0.62 IU/L at a testis volume of 1 mL, the FSH concentration doubled by 10 mL and increased an additional 1.7-fold by 30 mL. From 270 ng/L at a testis volume of 1 mL, inhibin increased 1.5-fold by 10 mL and an additional 1.3-fold by 30 mL. Overnight pulse amplitudes exhibited developmental trajectories similar to those of the corresponding overnight mean concentrations. The number of LH and testosterone pulses during the sampling period averaged 2.2 and 2.1, respectively, at Tanner stage 1 and increased to 4.5 and 3.2, respectively, at Tanner stage 5. The number of FSH and inhibin pulses remained constant throughout puberty, averaging 3.3 and 3.5, respectively. Pairwise correlations among hormone concentrations were strong, reflecting common increasing trends through puberty; however, after accounting for developmental trends, FSH, LH, and testosterone concentrations remained correlated, whereas inhibin was uncorrelated with each of the other three hormones. Measuring gonadotropins with ultrasensitive assays and analyzing the results on a logarithmic scale as a function of testis volume made clear the dramatic hormonal changes that begin before the clinical changes of puberty.
为研究男性青春期发生的激素变化,我们对50名年龄在8.4 - 18.8岁的正常青春期前和青春期男孩,于21:00至05:00期间每隔10分钟采集一次血清样本,共采集8小时,测量其中促黄体生成素(LH)、促卵泡生成素(FSH)、睾酮和α抑制素的免疫活性。我们采用超灵敏免疫荧光分析法测量促性腺激素,用放射免疫分析法测量睾酮和α抑制素。与以往用坦纳分期来评估青春期发育的研究不同,我们使用睾丸体积这一更为精细的发育指标,以揭示按坦纳分期分组时所掩盖的模式。每种激素的夜间平均浓度随睾丸体积增加而升高,但在对数尺度上,随着睾丸增大,升高速率减缓。促黄体生成素(LH)在青春期前后期和青春期早期急剧上升,在青春期中期和后期趋于平稳。根据拟合的回归曲线,在睾丸体积从1毫升增加到10毫升之间,LH增加了约20倍(从0.11 IU/L开始),但到30毫升时仅再增加1.5倍。睾酮(testosterone)对数的发育轨迹与LH相似,但在青春期早期上升较平缓。在睾丸体积为1毫升时,睾酮浓度为0.14微克/升,到10毫升时增加约8.5倍,到30毫升时再增加3倍。相比之下,促卵泡生成素(FSH)和α抑制素夜间平均浓度的对数在整个青春期以更近乎恒定的速率上升。在睾丸体积为1毫升时,FSH浓度为0.62 IU/L,到10毫升时翻倍,到30毫升时再增加1.7倍。在睾丸体积为1毫升时,抑制素浓度为270 ng/L,到10毫升时增加1.5倍,到30毫升时再增加1.3倍。夜间脉冲幅度呈现出与相应夜间平均浓度相似的发育轨迹。在坦纳1期,采样期间LH和睾酮脉冲数平均分别为2.2次和2.1次,在坦纳5期分别增至4.5次和3.2次。FSH和抑制素脉冲数在整个青春期保持恒定,平均分别为3.3次和3.5次。激素浓度之间的两两相关性很强,反映了青春期共同的上升趋势;然而,在考虑发育趋势后,FSH、LH和睾酮浓度仍保持相关,而抑制素与其他三种激素均不相关。采用超灵敏分析法测量促性腺激素,并将结果按对数尺度作为睾丸体积的函数进行分析,明确了在青春期临床变化之前就开始的显著激素变化。
