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大肠杆菌McrA(一种假定的5-甲基胞嘧啶特异性核酸酶)的克隆、纯化及初步表征

Cloning, purification and initial characterization of E. coli McrA, a putative 5-methylcytosine-specific nuclease.

作者信息

Mulligan Elizabeth A, Dunn John J

机构信息

Department of Molecular Genetics and Microbiology, School of Medicine, Stony Brook University, Stony Brook, NY 11794, USA.

出版信息

Protein Expr Purif. 2008 Nov;62(1):98-103. doi: 10.1016/j.pep.2008.06.016. Epub 2008 Jul 10.

Abstract

Expression strains of Escherichia coli BL21(DE3) overproducing the E. coli m(5)C McrA restriction protein were produced by cloning the mcrA coding sequence behind a T7 promoter. The recombinant mcrA minus BL21(DE3) host produces active McrA as evidenced by its acquired ability to selectively restrict the growth of T7 phage containing DNA methylated in vitro by HpaII methylase. The mcrA coding region contains several non-optimal E. coli triplets. Addition of the pACYC-RIL tRNA encoding plasmid to the BL21(DE3) host increased the yield of recombinant McrA (rMcrA) upon induction about 5- to 10-fold. McrA protein expressed at 37 degrees C is insoluble but a significant fraction is recovered as soluble protein after autoinduction at 20 degrees C. rMcrA protein, which is predicted to contain a Cys(4)-Zn(2+) finger and a catalytically important histidine triad in its putative nuclease domain, binds to several metal chelate resins without addition of a poly-histidine affinity tag. This feature was used to develop an efficient protocol for the rapid purification of nearly homogeneous rMcrA. The native protein is a dimer with a high alpha-helical content as measured by circular dichroism analysis. Under all conditions tested purified rMcrA does not have measurable nuclease activity on HpaII methylated (Cm(5)CGG) DNA, although the purified protein does specifically bind HpaII methylated DNA. These results have implications for understanding the in vivo activity of McrA in "restricting" m(5)C-containing DNA and suggest that rMcrA may have utility as a reagent for affinity purification of DNA fragments containing m(5)C residues.

摘要

通过将mcrA编码序列克隆到T7启动子下游,构建了过量表达大肠杆菌m(5)C McrA限制蛋白的大肠杆菌BL21(DE3)表达菌株。重组的mcrA缺失型BL21(DE3)宿主产生有活性的McrA,这可通过其获得的选择性限制含有经HpaII甲基化酶体外甲基化DNA的T7噬菌体生长的能力得到证明。mcrA编码区包含几个非最佳的大肠杆菌三联体。将编码pACYC-RIL tRNA的质粒添加到BL21(DE3)宿主中,诱导后重组McrA(rMcrA)的产量提高了约5至10倍。在37℃表达的McrA蛋白是不溶性的,但在20℃自动诱导后,有相当一部分以可溶性蛋白形式回收。rMcrA蛋白预计在其假定的核酸酶结构域中含有一个Cys(4)-Zn(2+)指状结构和一个催化重要的组氨酸三联体,在不添加多组氨酸亲和标签的情况下,它能与几种金属螯合树脂结合。利用这一特性开发了一种高效方案,用于快速纯化几乎均一的rMcrA。通过圆二色性分析测量,天然蛋白是一种具有高α-螺旋含量的二聚体。在所有测试条件下,纯化的rMcrA对HpaII甲基化(Cm(5)CGG)DNA没有可测量的核酸酶活性,尽管纯化的蛋白确实能特异性结合HpaII甲基化的DNA。这些结果对于理解McrA在“限制”含m(5)C DNA的体内活性具有启示意义,并表明rMcrA可能作为一种试剂用于亲和纯化含有m(5)C残基的DNA片段。

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