Shandong Provincial Key Laboratory of Energy Genetics, Key Laboratory of Biofuels, Qingdao Institute of Bioenergy and Bioprocess Technology, Chinese Academy of Sciences, Qingdao, Shandong, PR China.
J Microbiol Methods. 2012 Jun;89(3):201-8. doi: 10.1016/j.mimet.2012.02.015. Epub 2012 Mar 15.
Genetic engineering of Clostridium cellulolyticum has been developed slowly compared with that of other clostridial species, and one of the major reasons might be the restriction and modification (RM) system which degrades foreign DNA. Here, a putative MspI endonuclease gene, ccel2866, was inactivated by a ClosTron-based gene disruption method. The resulting C. cellulolyticum mutant H10ΔmspI lost the MspI endonuclease activity and can accept unmethylated DNA efficiently. Following that, an oxygen-independent green fluorescence protein gene was introduced into H10ΔmspI without methylation, generating a convenient reporter system to evaluate the expression of heterologous protein in C. cellulolyticum by green fluorescence. To further demonstrate the efficiency of the H10ΔmspI, double mutants H10ΔmspIΔldh and H10ΔmspIΔack were constructed by disrupting lactate dehydrogenase gene ccel2485 and acetate kinase gene ccel2136 in H10ΔmspI, respectively, without DNA methylation, and the stability of the double mutation was confirmed after the 100th generation. The mutant H10ΔmspI constructed here can be used as a platform for further targeted gene manipulation conveniently and efficiently. It will greatly facilitate the metabolic engineering of C. cellulolyticum aiming at faster cellulose degradation and higher biofuel production at the molecular level.
与其他梭菌属物种相比,木葡聚糖降解梭菌(Clostridium cellulolyticum)的遗传工程发展缓慢,其中一个主要原因可能是限制修饰(RM)系统会降解外来 DNA。在此,我们采用基于 ClosTron 的基因敲除方法失活了一个假定的 MspI 内切酶基因 ccel2866。由此产生的 C. cellulolyticum 突变体 H10ΔmspI 失去了 MspI 内切酶活性,可以有效接受未甲基化的 DNA。接下来,我们将一个氧非依赖型绿色荧光蛋白基因引入到 H10ΔmspI 中,而无需甲基化,从而构建了一个方便的报告系统,可通过绿色荧光来评估异源蛋白在 C. cellulolyticum 中的表达情况。为了进一步证明 H10ΔmspI 的效率,我们通过在 H10ΔmspI 中敲除乳酸脱氢酶基因 ccel2485 和乙酰激酶基因 ccel2136,分别构建了双突变体 H10ΔmspIΔldh 和 H10ΔmspIΔack,而无需 DNA 甲基化,并且在第 100 代后确认了双突变的稳定性。这里构建的突变体 H10ΔmspI 可作为一个平台,方便高效地进行靶向基因操作。这将极大地促进木葡聚糖降解梭菌的代谢工程,旨在从分子水平上实现更快的纤维素降解和更高的生物燃料产量。
