定制
错义突变
单倍率不足
表型
基因组编辑
突变
疾病
医学
Wiskott-Aldrich综合征
生物信息学
免疫学
体内
生物
移码突变
临床表型
点突变
癌症研究
主动脉
Cas9
病变
解剖(医学)
病理
基因
作者
Christiano R. R. Alves,Sabyasachi Das,Vijai Krishnan,Leillani L. Ha,Lauren R. Fox,Hannah E. Stutzman,Claire E. Shamber,Pazhanichamy Kalailingam,Siobhán McCarthy,Christian L. Lino Cardenas,C.K. Fong,Takahiko Imai,Sunayana Mitra,Shuqi Yun,Rachael K. Wood,Friederike M. C. Benning,Kangsan Roh,Joseph Lawton,Nahye Kim,Rachel A. Silverstein
标识
DOI:10.1038/s41551-025-01499-1
摘要
Pathogenic missense mutations in the alpha actin isotype 2 (ACTA2) gene cause multisystemic smooth muscle dysfunction syndrome (MSMDS), a genetic vasculopathy that is associated with stroke, aortic dissection and death in childhood. Here we perform mutation-specific protein engineering to develop a bespoke CRISPR-Cas9 enzyme with enhanced on-target activity against the most common MSMDS-causative mutation ACTA2 R179H. To directly correct the R179H mutation, we screened dozens of configurations of base editors to develop a highly precise corrective A-to-G edit with minimal deleterious bystander editing that is otherwise prevalent when using wild-type SpCas9 base editors. We create a murine model of MSMDS that shows phenotypes consistent with human patients, including vasculopathy and premature death, to explore the in vivo therapeutic potential of this strategy. Delivery of the customized base editor via an engineered smooth muscle-tropic adeno-associated virus (AAV-PR) vector substantially prolongs survival and rescues systemic phenotypes across the lifespan of MSMDS mice, including in the vasculature, aorta and brain. Our results highlight how bespoke mutant-specific CRISPR-Cas9 enzymes can improve mutation correction with base editors.
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