共表达作为一种在细菌中生产和纯化核心组蛋白的便捷方法。

Co-expression as a convenient method for the production and purification of core histones in bacteria.

作者信息

Anderson Megan, Huh Joon H, Ngo Thien, Lee Alice, Hernandez Genaro, Pang Joy, Perkins Jennifer, Dutnall Robert N

机构信息

Section of Molecular Biology, Division of Biological Sciences, University of California San Diego, 9500 Gilman Drive, La Jolla, CA 92093-0347, USA.

出版信息

Protein Expr Purif. 2010 Aug;72(2):194-204. doi: 10.1016/j.pep.2010.03.013. Epub 2010 Mar 27.

DOI:10.1016/j.pep.2010.03.013

PMID:20347990

Abstract

Co-expression offers an important strategy for producing multiprotein complexes for biochemical and biophysical studies. We have found that co-expression of histones H2A and H2B (from yeast, chicken or Drosophila) leads to production of soluble heterodimeric H2AH2B complexes. Drosophila histones H3 and H4 can also be produced as a soluble (H3H4)(2) heterotetrameric complex if they are co-expressed with the histone chaperone Asf1. The soluble H2AH2B and (H3H4)(2) can be purified by simple chromatographic techniques and have similar properties to endogenous histones. Our methods should facilitate histone production for studies of chromatin structure and regulatory proteins that interact with histones. We describe a simple strategy for constructing co-expression plasmids, based on the T7 RNA polymerase system, which is applicable to other systems. It offers several advantages for quickly creating plasmids to express two or more proteins and for testing different combinations of proteins for optimal complex production, solubility or activity.

摘要

共表达为生化和生物物理研究生产多蛋白复合物提供了一种重要策略。我们发现，（来自酵母、鸡或果蝇的）组蛋白H2A和H2B的共表达会导致可溶性异二聚体H2AH2B复合物的产生。如果果蝇组蛋白H3和H4与组蛋白伴侣Asf1共表达，它们也可以作为可溶性（H3H4）2异源四聚体复合物产生。可溶性H2AH2B和（H3H4）2可以通过简单的色谱技术纯化，并且具有与内源性组蛋白相似的性质。我们的方法应该有助于生产组蛋白，用于研究染色质结构以及与组蛋白相互作用的调节蛋白。我们描述了一种基于T7 RNA聚合酶系统构建共表达质粒的简单策略，该策略适用于其他系统。它在快速创建表达两种或更多种蛋白质的质粒以及测试不同蛋白质组合以实现最佳复合物生产、溶解度或活性方面具有几个优点。

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共表达作为一种在细菌中生产和纯化核心组蛋白的便捷方法。

Co-expression as a convenient method for the production and purification of core histones in bacteria.

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