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Engineered CRISPR-OsCas12f1 and RhCas12f1 with robust activities and expanded target range for genome editing

Xiangfeng Kong, Hainan Zhang, Guoling Li, Zikang Wang, Xuqiang Kong, Lecong Wang, Mingxing Xue, Weihong Zhang, Yao Wang, Jiajia Lin, Jingxing Zhou, Xiaowen Shen, Yinghui Wei, Na Zhong, Weiya Bai, Yuan Yuan, Linyu Shi, Yingsi Zhou, Hui Yang

2023Nature Communications95 citationsDOIOpen Access PDF

Abstract

The type V-F CRISPR-Cas12f system is a strong candidate for therapeutic applications due to the compact size of the Cas12f proteins. In this work, we identify six uncharacterized Cas12f1 proteins with nuclease activity in mammalian cells from assembled bacterial genomes. Among them, OsCas12f1 (433 aa) from Oscillibacter sp. and RhCas12f1 (415 aa) from Ruminiclostridium herbifermentans, which respectively target 5' T-rich Protospacer Adjacent Motifs (PAMs) and 5' C-rich PAMs, show the highest editing activity. Through protein and sgRNA engineering, we generate enhanced OsCas12f1 (enOsCas12f1) and enRhCas12f1 variants, with 5'-TTN and 5'-CCD (D = not C) PAMs respectively, exhibiting much higher editing efficiency and broader PAMs, compared with the engineered variant Un1Cas12f1 (Un1Cas12f1_ge4.1). Furthermore, by fusing the destabilized domain with enOsCas12f1, we generate inducible-enOsCas12f1 and demonstate its activity in vivo by single adeno-associated virus delivery. Finally, dead enOsCas12f1-based epigenetic editing and gene activation can also be achieved in mammalian cells. This study thus provides compact gene editing tools for basic research with remarkable promise for therapeutic applications.

Topics & Concepts

Genome editingCRISPRNucleaseSubgenomic mRNAComputational biologyBiologyCas9GeneGenome engineeringGenomeSynthetic biologyEpigeneticsHEK 293 cellsGeneticsCRISPR and Genetic EngineeringInsect symbiosis and bacterial influencesRNA and protein synthesis mechanisms