植物SET结构域蛋白:结构、功能与调控

Danny W-K Ng, Tao Wang, Mahesh B. Chandrasekharan , Rodolfo Aramayo, Sunee Kertbundit , Timothy C. Hall
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引用次数: 170

摘要

组蛋白形成染色体DNA环的核心,组蛋白的修饰对相关DNA的转录、复制和修复的可及性具有深远的表观遗传影响。SET结构域通常具有针对组蛋白H3或H4的特定赖氨酸残基的甲基转移酶活性。SET结构域及其侧翼区域具有相当大的序列保守性。先前的综述表明,拟南芥和玉米的SET蛋白根据其序列和结构域结构可分为五类。这些分类通常反映了对特定底物的特异性。来自水稻的SET蛋白被发现属于类似的组,这加强了所采用方法的优点。另外两类,VI和VII,被建立,包括截断/中断SET结构域的蛋白质。SET蛋白的功能形成和调控涉及多种机制。其中包括通过分子内和分子间关联的蛋白质-蛋白质相互作用,这在植物发育过程中很重要,如开花时间控制和胚胎发生。选择性剪接可以产生两种到几种不同的转录异构体,现在已知这种剪接是广泛存在的。一个令人兴奋和诱人的问题是,这种选择性剪接是否或如何影响基因功能。例如,可以想象,一种异构体可能削弱甲基转移酶的功能,而另一种异构体可能增强甲基转移酶的功能,从而为差异调节提供了机会。本文推测SET蛋白功能的调节可能是由反义RNA或正反义RNA介导的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Plant SET domain-containing proteins: Structure, function and regulation

Modification of the histone proteins that form the core around which chromosomal DNA is looped has profound epigenetic effects on the accessibility of the associated DNA for transcription, replication and repair. The SET domain is now recognized as generally having methyltransferase activity targeted to specific lysine residues of histone H3 or H4. There is considerable sequence conservation within the SET domain and within its flanking regions. Previous reviews have shown that SET proteins from Arabidopsis and maize fall into five classes according to their sequence and domain architectures. These classes generally reflect specificity for a particular substrate. SET proteins from rice were found to fall into similar groupings, strengthening the merit of the approach taken. Two additional classes, VI and VII, were established that include proteins with truncated/ interrupted SET domains. Diverse mechanisms are involved in shaping the function and regulation of SET proteins. These include protein–protein interactions through both intra- and inter-molecular associations that are important in plant developmental processes, such as flowering time control and embryogenesis. Alternative splicing that can result in the generation of two to several different transcript isoforms is now known to be widespread. An exciting and tantalizing question is whether, or how, this alternative splicing affects gene function. For example, it is conceivable that one isoform may debilitate methyltransferase function whereas the other may enhance it, providing an opportunity for differential regulation. The review concludes with the speculation that modulation of SET protein function is mediated by antisense or sense–antisense RNA.

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