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引用次数: 0
摘要
多亚基核糖核酸聚合酶(msRNAPs)负责所有生命王国的转录。这些msRNAPs的核心是一个超保守的活性位点结构域,即触发环(TL),通过影响底物选择、催化和易位的多个步骤的关键构象变化来协调转录速度和保真度。先前的研究观察到了真核RNA聚合酶II(Pol II)TL残基之间几种不同类型的遗传相互作用,表明TL的功能是由TL内部和周围残基的功能相互作用形成的。这些相互作用网络的范围以及它们如何控制msRNAP功能和进化仍有待确定。在这里,我们通过酿酒酵母Pol II的深度突变扫描,解剖了Pol II TL相互作用的景观。通过对15000多个等位基因的分析,我们确定了控制TL功能的相互作用网络,这些等位基因代表了所有的单突变体、合理设计的双突变体子集以及进化观察到的TL单倍型。取代残基产生等位基因特异性网络,并在Pol II活性位点上传播上位效应。此外,相互作用景观进一步区分了具有相似生长表型的等位基因,这表明与先前报道的单一突变表型景观相比,分辨率有所提高。最后,共同进化分析揭示了Pol II上的共同进化残基群汇聚到活跃位点,在那里进化约束与普遍的上位性相互作用。我们的研究为理解RNA聚合酶机制和进化的可塑性提供了一个强大的系统,并提供了第一个重要酶内高度保守和受限结构域中普遍存在的上位性景观的例子。
Widespread epistasis shapes RNA Polymerase II active site function and evolution.
Multi-subunit RNA Polymerases (msRNAPs) are responsible for transcription in all kingdoms of life. These enzymes rely on dynamic, highly conserved active site domains such as the so-called "trigger loop" (TL) to accomplish steps in the transcription cycle. Mutations in the RNA polymerase II (Pol II) TL confer a spectrum of biochemical and genetic phenotypes that suggest two main classes, which decrease or increase catalysis or other nucleotide addition cycle (NAC) events. The Pol II active site relies on networks of residue interactions to function and mutations likely perturb these networks in ways that may alter mechanisms. We have undertaken a structural genetics approach to reveal residue interactions within and surrounding the Pol II TL - determining its "interaction landscape" - by deep mutational scanning in Saccharomyces cerevisiae Pol II. This analysis reveals connections between TL residues and surrounding domains, demonstrating that TL function is tightly coupled to its specific enzyme context.
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