Xie Chichu, Gan Jinfeng, Zhang Yuanhao, Yu Wentao, Li Ruirui, Yu Dan, Liu Yu, Zheng Song Guo, Qi Guangying
Guangxi Key Laboratory of Tumor Immunology and Microenvironmental Regulation, Guilin Medical University, Guilin, 541199, China.
Department of Clinical Immunology, The Third Affiliated Hospital of Sun Yat-Sen University, Guangzhou, 510630, China.
J Biol Eng. 2025 Sep 1;19(1):79. doi: 10.1186/s13036-025-00551-7.
Site-specific recombination (SSR) systems are essential tools for conditional genetic manipulation and are valued for their efficacy and user friendliness. However, the development of novel SSR strategies is urgently needed. This study aimed to identify a split Dre protein configuration that can self-activate.
By exploiting the homology between Dre and Cre, we designed a strategy to split the Dre protein at specific amino acid residues and systematically pair the resulting peptide fragments. Among these combinations, the N191/192C pair exhibited detectable recombinase activity when mediating recombination between episomal rox sites in 293T cells, whereas the other pairs presented minimal recombinase activity. Subsequent experiments revealed that the N191/192C combination efficiently mediated site-specific recombination at the integrated rox sites, without the need for auxiliary protein fusions, and demonstrated recombinase activity that is at least equivalent to that of the intact Dre protein. Interestingly, while fusion with the intein peptide increased the activity of N60/61C pair, it had a deleterious effect on the N191/192C pair. The N191/192C combination also displayed robust recombinase activity in both the murine 4T1 cell line and E. coli bacteria. Finally, our experiments demonstrated that there was no detectable cross-complementation between the split Dre and split Cre proteins.
The N191/192C split Dre protein and the intein-fused N60/61C split Dre protein can effectively mediate recombination of the integrated rox sites without the need for external signals such as light or chemical compounds. Split Dre and Cre proteins can be used together in the same cell without interfering with each other. These findings introduce new tools and strategies for gene editing and the generation of transgenic animals.
位点特异性重组(SSR)系统是条件性基因操作的重要工具,因其有效性和用户友好性而受到重视。然而,迫切需要开发新的SSR策略。本研究旨在鉴定一种可自我激活的分裂Dre蛋白构型。
通过利用Dre和Cre之间的同源性,我们设计了一种策略,在特定氨基酸残基处分裂Dre蛋白,并系统地配对产生的肽片段。在这些组合中,N191/192C对在介导293T细胞中游离型rox位点之间的重组时表现出可检测到的重组酶活性,而其他对则表现出最小的重组酶活性。后续实验表明,N191/192C组合在整合的rox位点处有效地介导了位点特异性重组,无需辅助蛋白融合,并证明其重组酶活性至少与完整的Dre蛋白相当。有趣的是,虽然与内含肽融合增加了N60/61C对的活性,但对N191/192C对有有害影响。N191/192C组合在小鼠4T1细胞系和大肠杆菌中也表现出强大的重组酶活性。最后,我们的实验表明,分裂的Dre蛋白和分裂的Cre蛋白之间没有可检测到的交叉互补。
N191/192C分裂Dre蛋白和内含肽融合的N60/61C分裂Dre蛋白可以有效地介导整合的rox位点的重组,而无需光或化合物等外部信号。分裂的Dre蛋白和Cre蛋白可以在同一细胞中共同使用而不相互干扰。这些发现为基因编辑和转基因动物的产生引入了新的工具和策略。
