重组人线粒体 RNA 聚合酶(POLRMT)及启动因子 TFAM 和 TFB2M 的表达和纯化

An Hsieh, Sean Reardon, Jubilee Munozvilla-Cabellon, Jiayu Shen, Smita Patel, Tatiana Mishanina
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摘要

人类线粒体DNA (mtDNA)编码氧化磷酸化的几个组成部分,负责大部分细胞能量的产生。mtDNA是由一种专门的人类线粒体RNA聚合酶(POLRMT)转录的,该酶在结构上与其核对应物不同,而与单亚基病毒RNA聚合酶(如T7 RNA聚合酶)非常相似。POLRMT启动转录需要两个启动因子:转录因子A,线粒体(TFAM)和转录因子B2,线粒体(TFB2M)。尽管体外生化和结构研究已经阐明了人类线粒体转录起始的许多细节,但与转录的机制和调控有关的许多问题仍有待解决。这种机制的研究需要可靠,高产,高纯度的蛋白质生产方法,本协议提供的细节和故障排除提示的水平,是必要的新手产生有意义的蛋白质的实验工作。目前的方案描述了如何使用亲和柱层析(Ni2+和肝素)等技术从大肠杆菌中纯化重组POLRMT, TFAM和TFB2M,如何使用TEV蛋白酶去除溶解度标签并回收未标记的感兴趣蛋白,以及如何克服在获得每种蛋白高产率方面常见的挑战。•本协议建立在Patel实验室(Ramachandran et al., 2017)和其他比以前发表的作品更详细的纯化方法的基础上。•该方案需要几天才能完成,因为各种步骤都是在一夜之间完成的。•重组纯化蛋白已成功用于体外转录实验,允许在极简系统中对实验成分进行更精细的控制。
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Expression and Purification of Recombinant Human Mitochondrial RNA Polymerase (POLRMT) and the Initiation Factors TFAM and TFB2M
Human mitochondrial DNA (mtDNA) encodes several components of oxidative phosphorylation responsible for the bulk of cellular energy production. The mtDNA is transcribed by a dedicated human mitochondrial RNA polymerase (POLRMT) that is structurally distinct from its nuclear counterparts, instead closely resembling the single-subunit viral RNA polymerases (e.g., T7 RNA polymerase). The initiation of transcription by POLRMT is aided by two initiation factors: transcription factor A, mitochondrial (TFAM), and transcription factor B2, mitochondrial (TFB2M). Although many details of human mitochondrial transcription initiation have been elucidated with in vitro biochemical and structural studies, much remains to be addressed relating to the mechanism and regulation of transcription. Studies of such mechanisms require reliable, high-yield, and high-purity methods for protein production, and this protocol provides the level of detail and troubleshooting tips that are necessary for a novice to generate meaningful amounts of proteins for experimental work. The current protocol describes how to purify recombinant POLRMT, TFAM, and TFB2M from Escherichia coli using techniques such as affinity column chromatography (Ni2+ and heparin), how to remove the solubility tags with TEV protease and recover untagged proteins of interest, and how to overcome commonly encountered challenges in obtaining high yield of each protein. Key features • This protocol builds upon purification methods developed by Patel lab (Ramachandran et al., 2017) and others with greater detail than previously published works. • The protocol requires several days to complete as various steps are designed to be performed overnight. • The recombinantly purified proteins have been successfully used for in vitro transcription experiments, allowing for finer control of experimental components in a minimalistic system.
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