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心肌细胞增强因子2A受到转录自调控。

Myocyte enhancer factor 2A is transcriptionally autoregulated.

作者信息

Ramachandran Bindu, Yu Gengsheng, Li Shiguang, Zhu Bangmin, Gulick Tod

机构信息

Diabetes Research Laboratory, Department of Medicine, Massachusetts General Hospital, Charlestown, Massachusetts 02129, USA.

出版信息

J Biol Chem. 2008 Apr 18;283(16):10318-29. doi: 10.1074/jbc.M707623200. Epub 2007 Dec 10.

Abstract

MEF2 (myocyte enhancer factor 2) proteins are a small family of transcription factors that play pivotal roles in striated muscle differentiation, development, and metabolism, in neuron survival and synaptic formation, and in lymphocyte selection and activation. Products of the four mammalian MEF2 genes, MEF2A, MEF2B, MEF2C, and MEF2D, are expressed with overlapping but distinct temporospatial patterns. Toward analysis of MEF2A functions and the determinants of its regulated expression, we have mapped and begun studies of the transcriptional control regions of this gene. Heterogeneous 5'-untranslated regions of MEF2A mRNAs result from use of alternative promoters and splicing patterns. The two closely approximated TATA-less promoters are approximately 65 kb upstream of the exon containing the sole initiation codon. Ribonuclease protection and primer extension assays show that each promoter is active in various adult tissues. A canonical MEF2 site overlies the major promoter 1 transcription start site. This element specifically binds MEF2 factors, including endogenous nuclear MEF2A according to chromatin immunoprecipitation studies, and is critical to MEF2A transcription in myocytes. The site exerts reciprocal control of the alternative promoters, silencing promoter 1 and activating promoter 2 under some conditions. Erk5 and p38 MAPK signaling stimulate MEF2A expression by activating both promoters from the MEF2 element. MEF2A transcription is therefore subject to positive or negative regulation by its protein products, depending on signaling activities that influence MEF2 factor trans-activity. The sole MEF2 gene of the cephalochordate amphioxus has a similar regulatory region structure, suggesting that this mode of autoregulatory control is conserved among higher metazoan MEF2 genes.

摘要

肌细胞增强因子2(MEF2)蛋白是一个小的转录因子家族,在横纹肌分化、发育和代谢、神经元存活和突触形成以及淋巴细胞选择和激活中起关键作用。四种哺乳动物MEF2基因(MEF2A、MEF2B、MEF2C和MEF2D)的产物以重叠但不同的时空模式表达。为了分析MEF2A的功能及其调控表达的决定因素,我们已经绘制了该基因的转录控制区域并开始进行研究。MEF2A mRNA的异质5'非翻译区是由于使用了替代启动子和剪接模式。两个紧密相邻的无TATA框启动子位于含有唯一起始密码子的外显子上游约65 kb处。核糖核酸酶保护和引物延伸分析表明,每个启动子在各种成年组织中均有活性。一个典型的MEF2位点位于主要启动子1转录起始位点之上。根据染色质免疫沉淀研究,该元件特异性结合MEF2因子,包括内源性核MEF2A,并且对肌细胞中MEF2A的转录至关重要。该位点对替代启动子进行反向控制,在某些条件下使启动子1沉默并激活启动子。Erk5和p38 MAPK信号通过从MEF2元件激活两个启动子来刺激MEF2A的表达。因此,MEF2A的转录受其蛋白产物的正向或负向调节,这取决于影响MEF2因子反式活性的信号活动。头索动物文昌鱼的唯一MEF2基因具有相似的调控区域结构,这表明这种自调控控制模式在高等后生动物MEF2基因中是保守的。

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