Cooke R R, McIntosh J E, McIntosh R P
Department of Obstetrics and Gynaecology, Wellington School of Medicine, University of Otago, New Zealand.
Clin Endocrinol (Oxf). 1993 Aug;39(2):163-71. doi: 10.1111/j.1365-2265.1993.tb01769.x.
We measured the changes in testosterone fractions in serum of normal men over a 24-hour period, and determined whether they could be simulated on the basis of current understanding of the interactions between steroids and binding proteins in the blood.
Starting from between 0830 and 0930 h, blood samples were taken every 45 minutes for 25.5 hours.
Five healthy males aged 26-45 years. All participants worked on a hospital campus and while being sampled carried out their normal activities during waking hours.
The concentrations of testosterone (RIA) and albumin, and the percentage non-sex hormone binding globulin-bound testosterone (ammonium sulphate precipitation) and percentage free testosterone (rate dialysis), were measured on each sample. Cortisol (RIA) and sex hormone-binding globulin (SHBG) (IRMA) concentrations were measured on every second sample, and that of corticosteroid-binding globulin on two samples from each series.
In all participants the levels of free and non-SHBG-bound testosterone in early morning samples (near 0530 h) were significantly different from those taken before midnight (P < 0.0005). Significant circadian rhythms (P < 0.05) in the concentration of testosterone and in the level of the free fraction were detected in all participants, and in four of the five participants for the non-SHBG-bound fraction. The amplitude of the free testosterone rhythm (34 +/- 2% of basal) was greater than that for testosterone itself (24 +/- 3% of basal). The 24-hour rhythm of the non-SHBG-bound fraction was similar to the total and free fractions except for the period 0330-0900 h when the level of this fraction declined by 15-45% over 1.5-3 hours. This decline was coincident with the initial rise in the concentration of cortisol. A decline of 10.5 +/- SEM 1.0% in the concentration of albumin, and 12.0 +/- 1.1% in that of SHBG occurred when the mean ambulant and supine levels were compared; analysis indicated significant circadian rhythms in the concentrations of these proteins. Simulation was used to investigate possible causes for the circadian rhythms in free and non-SHBG-bound testosterone. Simulation results matched the measured data well in qualitative terms, but quantitatively there were differences.
Increasing saturation of the binding proteins following rises in testosterone production, and the small but significant changes in protein concentration, probably related to postural changes, were implicated as the major factors in the rhythm amplitude. However, the early morning decline in the non-SHBG-bound fraction was not explained by these factors. The rise in cortisol concentration at this time is a probable cause. Alternatively, simulation suggests that a substance appearing in the early morning and competing with testosterone for albumin binding sites may be responsible.
我们测量了正常男性血清中睾酮各组分在24小时内的变化,并根据目前对血液中类固醇与结合蛋白相互作用的理解,确定这些变化是否可以被模拟出来。
从08:30至09:30开始,每45分钟采集一次血样,共采集25.5小时。
5名年龄在26 - 45岁之间的健康男性。所有参与者均在医院院区工作,采样期间在清醒时间进行正常活动。
对每个样本测量睾酮浓度(放射免疫分析法)、白蛋白浓度、非性激素结合球蛋白结合睾酮百分比(硫酸铵沉淀法)和游离睾酮百分比(速率透析法)。每隔一个样本测量皮质醇浓度(放射免疫分析法)和性激素结合球蛋白(SHBG)浓度(免疫放射分析法),每个系列的两个样本测量皮质类固醇结合球蛋白浓度。
在所有参与者中,清晨样本(接近05:30)中的游离睾酮和非SHBG结合睾酮水平与午夜前采集的样本有显著差异(P < 0.0005)。在所有参与者中均检测到睾酮浓度和游离组分水平有显著的昼夜节律(P < 0.05),在五名参与者中的四名中,非SHBG结合组分也有昼夜节律。游离睾酮节律的幅度(基础值的34 ± 2%)大于睾酮本身的幅度(基础值的24 ± 3%)。非SHBG结合组分的24小时节律与总组分和游离组分相似,除了03:30 - 09:00期间,该组分水平在1.5 - 3小时内下降了15 - 45%。这种下降与皮质醇浓度的初始升高同时发生。比较平均活动和平卧水平时,白蛋白浓度下降了10.5 ± 标准误1.0%,SHBG浓度下降了12.0 ± 1.1%;分析表明这些蛋白质的浓度有显著的昼夜节律。使用模拟方法研究游离睾酮和非SHBG结合睾酮昼夜节律的可能原因。模拟结果在定性方面与实测数据匹配良好,但在定量方面存在差异。
睾酮生成增加后结合蛋白饱和度的增加,以及可能与体位变化有关的蛋白质浓度的微小但显著的变化,被认为是节律幅度的主要因素。然而,这些因素无法解释清晨非SHBG结合组分的下降。此时皮质醇浓度的升高可能是一个原因。或者,模拟表明清晨出现的一种物质与睾酮竞争白蛋白结合位点可能是原因所在。
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