Joana Alves, Inga Dry, John H White, David T F Dryden, Nicola N Lynskey
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引用次数: 0
摘要
DNA 操作是分子微生物学研究的重要工具,它取决于细菌通过水平基因转移吸收和保存外来 DNA 的能力。细菌限制性修饰系统的活性会严重影响这一过程;细菌操作子包括成对的酶活性,可保护宿主 DNA 的甲基化,同时裂解传入的未经修饰的外来 DNA。Ocr 是一种噬菌体编码的蛋白质,可抑制 I 型限制性修饰系统,加入这种蛋白质可显著提高细菌转化效率。最近,我们利用市售的重组 Ocr 蛋白,针对重要的人类病原体 A 组链球菌制定了一套改进的高效转化方案。为了确保研究界能继续获得 Ocr 蛋白,我们开发了内部生产 Ocr 的工具和方法,并验证了纯化重组蛋白的活性。
Generation of tools for expression and purification of the phage-encoded Type I restriction enzyme inhibitor, Ocr.
DNA manipulation is an essential tool in molecular microbiology research that is dependent on the ability of bacteria to take up and preserve foreign DNA by horizontal gene transfer. This process can be significantly impaired by the activity of bacterial restriction modification systems; bacterial operons comprising paired enzymatic activities that protectively methylate host DNA, while cleaving incoming unmodified foreign DNA. Ocr is a phage-encoded protein that inhibits Type I restriction modification systems, the addition of which significantly improves bacterial transformation efficiency. We recently established an improved and highly efficient transformation protocol for the important human pathogen group A Streptococcus using commercially available recombinant Ocr protein, manufacture of which has since been discontinued. In order to ensure the continued availability of Ocr protein within the research community, we have generated tools and methods for in-house Ocr production and validated the activity of the purified recombinant protein.