Cemeroglu A P, Barkan A L, Kletter G B, Beitins I Z, Foster C M
Department of Pediatrics, University of Michigan Medical School, Ann Arbor 48109, USA.
J Clin Endocrinol Metab. 1997 Jul;82(7):2166-71. doi: 10.1210/jcem.82.7.4076.
Acceleration of linear growth during puberty is associated with increased GH secretion, although the relationship between growth and GH is complex. As GH exists as a family of isoforms, some of which may not be identified by immunoassay, there may be alterations in isoform secretion during pubertal maturation that result in increased growth. The changes in serum immunoreactive and bioactive GH concentrations across pubertal maturation were determined in 30 boys, aged 6.5-19.3 yr, with idiopathic short stature or constitutional delay of adolescence. Data were grouped as follows: 1) 6 prepubertal boys with bone age 7 yr or less; 2) 5 prepubertal boys with bone age of more than 7 yr, 3) 10 boys in early puberty; 4) 9 boys with mid- to late puberty. Blood was obtained every 20 min from 2000-0800 h. An equal aliquot of each serum sample was pooled for determination of GH by bio- and immunoassays. The mean serum immunoreactive GH concentration increased from 2.1 +/- 0.3, 1.8 +/- 0.3, and 2.9 +/- 0.5 micrograms/L in groups 1, 2, and 3, respectively, to a peak of 4.6 +/- 0.7 micrograms/L in group 4 (P < 0.05 vs. groups 1-3). The mean serum GH bioactivity was 48 +/- 13 micrograms/L in group 1 and declined to 39 +/- 8 and 31 +/- 3 micrograms/L in groups 2 and 3, increasing to a maximum of 64 +/- 15 micrograms/L in group 4 (P < 0.05 vs. group 3). The ratio of bioactive to immunoreactive GH suggests that the biopotencies of secreted isoforms do not increase during pubertal maturation. The role of E2 in increasing GH secretion was characterized in 8 additional early pubertal boys. Each boy received a saline infusion from 1000-0800 h, followed 1 week later by an infusion of E2 at 4.6 nmol/m2.h. Blood was obtained every 15 min from 2200-0800 h for GH and LH and every 60 min for E2 and testosterone. An equal aliquot of each overnight serum sample was pooled for insulin-like growth factor I (IGF-I) and GH by immuno- and bioassays. The mean serum LH concentration decreased from 5.0 +/- 0.9 to 2.3 +/- 0.6 IU/L (P < 0.01), and the E2 concentration increased from 22 +/- 4 to 81 +/- 26 pmol/L (P < 0.01) during saline and E2 infusions, respectively. Mean serum GH concentrations as measured by immunoassay were similar during both infusions (6.6 +/- 1.4 vs. 9.7 +/- 2.1 micrograms/L; saline vs. E2 infusion, respectively). In contrast, the mean serum GH concentration, as measured by bioassay, decreased from 48 +/- 10 micrograms/L during saline infusion to 16 +/- 3 micrograms/L during E2 infusion (P < 0.05). The mean serum IGF-I concentration also decreased significantly from 116 +/- 17 to 93 +/- 15 micrograms/L (saline vs. E2 infusion, respectively; P < 0.05). Thus, although mean overnight serum GH concentrations increase in late puberty, whether measured by immuno- or bioassay, an acute increase in E2 produces an acute decline in serum GH bioactivity and a lesser decline in the serum IGF-I concentration. These unexpected changes indicate that E2 may affect pubertal growth and GH secretion in a complex or biphasic manner depending on the context in which it is administered.
青春期线性生长加速与生长激素(GH)分泌增加有关,尽管生长与GH之间的关系很复杂。由于GH以同工型家族形式存在,其中一些可能无法通过免疫测定法识别,因此青春期成熟过程中同工型分泌可能发生改变,从而导致生长加速。对30名年龄在6.5 - 19.3岁、患有特发性身材矮小或青春期体质性发育延迟的男孩,测定了青春期成熟过程中血清免疫反应性GH和生物活性GH浓度的变化。数据分组如下:1)6名骨龄7岁及以下的青春期前男孩;2)5名骨龄超过7岁的青春期前男孩;3)10名青春期早期男孩;4)9名青春期中晚期男孩。在20:00 - 08:00期间,每20分钟采集一次血液。将每个血清样本的等量等分混合,用于通过生物测定法和免疫测定法测定GH。第1、2和3组的平均血清免疫反应性GH浓度分别为2.1±0.3、1.8±0.3和2.9±0.5微克/升,在第4组升至峰值4.6±0.7微克/升(与第1 - 3组相比,P < 0.05)。第1组的平均血清GH生物活性为48±13微克/升,在第2组和第3组降至39±8和31±3微克/升,在第4组升至最高64±15微克/升(与第3组相比,P < 0.05)。生物活性GH与免疫反应性GH的比值表明,分泌的同工型生物活性在青春期成熟过程中并未增加。在另外8名青春期早期男孩中研究了雌二醇(E2)在增加GH分泌中的作用。每个男孩在10:00 - 08:00期间接受生理盐水输注,1周后接受4.6 nmol/m²·h的E²输注。在22:00 - 08:00期间,每15分钟采集一次血液用于测定GH和促黄体生成素(LH),每60分钟采集一次血液用于测定E2和睾酮。将每个过夜血清样本的等量等分混合,用于通过免疫测定法和生物测定法测定胰岛素样生长因子I(IGF - I)和GH。在生理盐水输注和E2输注期间,平均血清LH浓度分别从5.0±0.9降至2.3±0.6 IU/L(P < 0.01),E2浓度从22±4升至81±26 pmol/L(P < 0.01)。通过免疫测定法测得的平均血清GH浓度在两次输注期间相似(分别为6.6±1.4和9.7±2.1微克/升;生理盐水输注与E2输注)。相比之下,通过生物测定法测得的平均血清GH浓度在生理盐水输注期间为48±10微克/升,在E2输注期间降至16±3微克/升(P < 0.05)。平均血清IGF - I浓度也从116±17显著降至93±15微克/升(分别为生理盐水输注与E2输注;P < 0.05)。因此,尽管青春期晚期平均过夜血清GH浓度升高,无论通过免疫测定法还是生物测定法测量,E2的急性增加都会导致血清GH生物活性急性下降以及血清IGF - I浓度较小程度的下降。这些意外变化表明,E2可能根据给药背景以复杂或双相方式影响青春期生长和GH分泌。
