Wang Bin, Wu Yaokang, Lv Xueqin, Liu Long, Li Jianghua, Du Guocheng, Chen Jian, Liu Yanfeng
School of Biotechnology and Key Laboratory of Carbohydrate Chemistry and Biotechnology, Ministry of Education, School of Biotechnology, Jiangnan University, Wuxi, 214122, China.
Science Center for Future Foods, Jiangnan University, Wuxi, 214122, China.
Synth Syst Biotechnol. 2025 Apr 21;10(3):876-886. doi: 10.1016/j.synbio.2025.04.010. eCollection 2025 Sep.
Targeted hypermutation mediated by base deaminase-T7 RNA polymerase (T7 RNAP) fusions promotes genetic diversification and accelerates continuous directed evolution. Due to the lack of a T7RNAP expression regulation system and functionally compatible linker for fusion protein expression, T7RNAP-guided continuous evolution has not been established in , which limited long gene fragment continuous evolution targeted on genome. Here, we developed BS-MutaT7 system, which introduced mutations into specific genomic regions by leveraging chimeric fusions of base deaminases with T7RNAP in We selected seven different sources of adenosine and cytosine deaminases, 14 fusion protein linkers to be fused with T7RNAP, constructing four libraries with the size of 5000, where deaminases were fused at either the N- or C-terminus of T7RNAP. Based on the efficiency of binding to T7 promoter and high mutagenesis activity, two optimal chimeric mutators, BS-MutaT7 (TadA8e-Linker0-T7RNAP) and BS-MutaT7 (PmCDA1-(GGGGS)-T7RNAP co-expressed with UGI) were identified. The target mutation rates reached 1.2 × 10 per base per generation (s.p.b.) and 5.8 × 10 s.p.b., representing 7000-fold and 37,000-fold increases over the genomic mutation rate, respectively. Both exhibited high processivity, maintaining mutation rates of 5.8 × 10 s.p.b. and 2.9 × 10 s.p.b. within a 5 kb DNA region. Notably, BS-MutaT7 exhibited superior mutagenic activity, making it well-suited for applications requiring intensive and sustained genomic diversification. Application of BS-MutaT7 enabled a 16-fold increase in tigecycline resistance and enhanced β-lactoglobulin (β-Lg) expression by evolving the global transcriptional regulator , achieving a β-Lg titer of 3.92 g/L. These results highlight BS-MutaT7 as a powerful and versatile tool for genome-scale continuous evolution in .
由碱基脱氨酶 - T7 RNA聚合酶(T7 RNAP)融合介导的靶向超突变可促进基因多样化并加速连续定向进化。由于缺乏T7 RNAP表达调控系统以及用于融合蛋白表达的功能兼容接头,T7 RNAP引导的连续进化尚未在[具体物种或系统,原文未明确]中建立,这限制了针对基因组的长基因片段连续进化。在此,我们开发了BS - MutaT7系统,该系统通过利用碱基脱氨酶与T7 RNAP的嵌合融合在[具体物种或系统,原文未明确]中将突变引入特定基因组区域。我们选择了七种不同来源的腺苷和胞嘧啶脱氨酶、14种与T7 RNAP融合的融合蛋白接头,构建了四个大小为5000的文库,其中脱氨酶在T7 RNAP的N端或C端融合。基于与T7启动子的结合效率和高诱变活性,鉴定出两种最佳嵌合诱变剂,即BS - MutaT7(TadA8e - Linker0 - T7RNAP)和BS - MutaT7(PmCDA1 - (GGGGS) - T7RNAP与UGI共表达)。目标突变率分别达到每代每个碱基1.2×10[具体数值,原文此处不完整]和5.8×10[具体数值,原文此处不完整],分别比基因组突变率提高了7000倍和37000倍。两者均表现出高持续性,在5 kb DNA区域内保持5.8×10[具体数值,原文此处不完整]和2.9×10[具体数值,原文此处不完整]的突变率。值得注意的是,BS - MutaT7表现出卓越的诱变活性,使其非常适合需要密集和持续基因组多样化的应用。BS - MutaT7的应用使替加环素抗性提高了16倍,并通过进化全局转录调节因子增强了β - 乳球蛋白(β - Lg)的表达,实现了3.92 g/L的β - Lg滴度。这些结果突出了BS - MutaT7作为[具体物种或系统,原文未明确]中基因组规模连续进化的强大且通用工具的地位。
