Bruhn T O, Huang S S, Vaslet C, Nillni E A
Institut für Zellbiochemie und klinische Neurobiologie, Universität Hamburg (UKE), Germany.
Endocrine. 1998 Oct;9(2):143-52. doi: 10.1385/ENDO:9:2:143.
The thyrotropin- (TRH) releasing hormone precursor (26 kDa) undergoes proteolytic cleavage at either of two sites, generating N-terminal 15 kDa/9.5 kDa or C-terminal 16.5/10 kDa intermediate forms that are processed further to yield five copies of TRH-Gly and seven non-TRH peptides. Glucocorticoids (Gcc) have been shown to enhance TRH gene expression in three different cell systems in vitro, an effect that occurs, at least in part, through transcriptional activation. Although this implies that an increase of TRH prohormone biosynthesis would take place, this had not been demonstrated as yet. We report here that the synthetic glucocorticoid dexamethasone (Dex) substantially elevated the de novo biosynthesis of the intact 26-kDa TRH prohormone and its intermediate products of processing in cultured anterior pituitary cells, an observation that is consistent with an overall upregulation of both the biosynthesis and degradation of the TRH precursor. We reasoned that Gcc may act not only at the transcriptional, but also at the translational/posttranslational level. To address this question we chose a different cell system, AtT20 cells transfected with a cDNA encoding preproTRH. Since TRH gene expression in these cells is driven by the CMV-IE promoter and not by an endogenous "physiological" promoter, these cells provide an ideal model to study selectively the effects of Gcc on the translation and posttranslational processing of proTRH without interference from a direct transcriptional activation of the TRH gene. Dex caused a significant 75.7% increase in newly synthesized 26-kDa TRH prohormone, suggesting that the glucocorticoid raised the translation rate. We then demonstrated that Dex treatment accelerated TRH precursor processing. Of interest, processing of the N- vs the C-terminal intermediate was influenced differentially by the glucocorticoid. Although the N-terminal intermediate product of processing accumulated, the C-terminal intermediate was degraded more rapidly. Consistent with these observations was the finding that the intracellular accumulation of the N-terminally derived peptide preproTRH 25-50 was enhanced, but levels of the C-terminally derived peptide preproTRH208-255 were reduced. Accumulation of TRH itself, whose five copies are N- and C-terminally derived, was also enhanced. We conclude that Gcc induce changes in the biosynthesis and processing of proTRH by increasing the translation rate and by differentially influencing the processing of N- vs C-terminal intermediates of the precursor molecule. These effects of Gcc at the translational and posttranslational levels result in an increase in TRH production accompanied by differential effects on the accumulation of N- and C-terminal non-TRH peptides.
促甲状腺激素释放激素(TRH)前体(26 kDa)在两个位点之一进行蛋白水解切割,产生N端15 kDa/9.5 kDa或C端16.5/10 kDa的中间形式,这些中间形式会进一步加工产生五个拷贝的TRH-甘氨酸和七种非TRH肽。糖皮质激素(Gcc)已被证明在体外三种不同的细胞系统中可增强TRH基因表达,这种作用至少部分是通过转录激活实现的。虽然这意味着TRH前体激素的生物合成会增加,但这一点尚未得到证实。我们在此报告,合成糖皮质激素地塞米松(Dex)显著提高了培养的垂体前叶细胞中完整26 kDa TRH前体激素及其加工中间产物的从头生物合成,这一观察结果与TRH前体的生物合成和降解的总体上调一致。我们推测Gcc可能不仅作用于转录水平,还作用于翻译/翻译后水平。为了解决这个问题,我们选择了一个不同的细胞系统,即转染了编码前促甲状腺激素释放激素(preproTRH)cDNA的AtT20细胞。由于这些细胞中的TRH基因表达由巨细胞病毒立即早期(CMV-IE)启动子驱动,而不是由内源性“生理”启动子驱动,因此这些细胞提供了一个理想的模型,可用于选择性研究Gcc对前促甲状腺激素释放激素(proTRH)翻译和翻译后加工的影响,而不受TRH基因直接转录激活的干扰。地塞米松使新合成的26 kDa TRH前体激素显著增加75.7%,表明糖皮质激素提高了翻译速率。然后我们证明地塞米松处理加速了TRH前体的加工。有趣的是,糖皮质激素对N端与C端中间产物的加工影响不同。虽然加工的N端中间产物积累,但C端中间产物降解更快。与这些观察结果一致的是,发现N端衍生肽前促甲状腺激素释放激素25-50的细胞内积累增加,但C端衍生肽前促甲状腺激素释放激素208-255的水平降低。TRH本身(其五个拷贝来自N端和C端)的积累也增加了。我们得出结论,Gcc通过提高翻译速率并差异影响前体分子N端与C端中间产物的加工,诱导前促甲状腺激素释放激素(proTRH)生物合成和加工的变化。Gcc在翻译和翻译后水平的这些作用导致TRH产生增加,同时对N端和C端非TRH肽的积累产生不同影响。
