Dual-single-guide RNA strategy improves CRISPR-mediated homology-directed repair in Aspergillus
Fu Mingxin, Wang Jing, Li Jingyi, Zhou Yao, Huang Xiaofei, Jia Zehan, Luo Yiqing, Tan Xinyu, Gao Yan, Yu Bingzi, Duan Yuting, Bu Qianyun, Li Xiaoying, Wang Yifan, Takaya Naoki, Zhou Shengmin
Journal:NUCLEIC ACIDS RESEARCH
IF:15
DOI:10.1093/nar/gkag095
PMID:
Published:2026-02-05
research field:分子生物学基因编辑合成生物学真菌基因组学遗传学
Abstract
CRISPR–Cas9 knock-in efficiency is often limited by geometric misalignment between donor DNA and the endogenous strand-invasion path. In Aspergillus nidulans, we found that integration drops sharply when the insertion site is offset from the invasion entry point, producing premature annealing or unsupported 3′ ends that stall DNA synthesis. Chromatin immunoprecipitation-based profiling shows directional loading of the RAD51 homolog UvsC around Cas9-induced double-strand breaks, thereby defining the spatial origin of strand invasion. Guided by this insight, we introduce a dual-single-guide RNA design that places two cuts flanking the insertion site to create a geometry-matched strand-invasion window. This alignment consistently and markedly increases homology-directed-repair-mediated integration across insert sizes and editing tasks—including C-terminal tagging, bidirectional promoter rewiring, and long-distance dual-site mutagenesis—and generalizes across multiple fungal species. We propose a structural-docking model in which pairing fidelity between the resected chromosomal strand and donor homology arms governs knock-in outcomes, providing a practical design principle for efficient and precise genome engineering at structurally constrained loci.
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