Treatment of a severe vascular disease using a bespoke CRISPR–Cas9 base editor in mice

IF 26.8 1区医学 Q1 ENGINEERING, BIOMEDICAL

Nature Biomedical Engineering Pub Date : 2025-09-11 DOI:10.1038/s41551-025-01499-1

Christiano R. R. Alves, Sabyasachi Das, Vijai Krishnan, Leillani L. Ha, Lauren R. Fox, Hannah E. Stutzman, Claire E. Shamber, Pazhanichamy Kalailingam, Siobhan McCarthy, Christian L. Lino Cardenas, Claire E. Fong, Takahiko Imai, Sunayana Mitra, Shuqi Yun, Rachael K. Wood, Friederike M. C. Benning, Kangsan Roh, Joseph Lawton, Nahye Kim, Rachel A. Silverstein, Joana Ferreira da Silva, Demitri de la Cruz, Rashmi Richa, Jun Xie, Heather L. Gray-Edwards, Rajeev Malhotra, David Y. Chung, Luke H. Chao, Shengdar Q. Tsai, Casey A. Maguire, Mark E. Lindsay, Benjamin P. Kleinstiver, Patricia L. Musolino

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Abstract

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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在小鼠中使用定制的CRISPR-Cas9碱基编辑器治疗严重血管疾病

α -肌动蛋白同型2 （ACTA2）基因的致病性错义突变导致多系统平滑肌功能障碍综合征（MSMDS），这是一种遗传性血管病变，与儿童中风、主动脉夹层和死亡有关。在这里，我们进行了突变特异性蛋白工程，开发了一种定制的CRISPR-Cas9酶，该酶对最常见的msmds致病突变ACTA2 R179H具有增强的靶向活性。为了直接纠正R179H突变，我们筛选了数十种碱基编辑器的配置，以开发一种高度精确的纠正性a - To - g编辑，并将使用野生型SpCas9碱基编辑器时普遍存在的有害的旁观者编辑最小化。我们创建了一个小鼠MSMDS模型，该模型显示了与人类患者一致的表型，包括血管病变和过早死亡，以探索该策略的体内治疗潜力。通过工程化的嗜平滑肌腺相关病毒（AAV-PR）载体递送定制的碱基编辑器，大大延长了MSMDS小鼠的生存期，并挽救了包括血管、主动脉和大脑在内的整个生命周期的系统表型。我们的研究结果强调了定制的突变特异性CRISPR-Cas9酶如何改善碱基编辑器的突变校正。

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来源期刊

Nature Biomedical Engineering Medicine-Medicine (miscellaneous)

CiteScore

45.30

自引率

1.10%

发文量

138

期刊介绍： Nature Biomedical Engineering is an online-only monthly journal that was launched in January 2017. It aims to publish original research, reviews, and commentary focusing on applied biomedicine and health technology. The journal targets a diverse audience, including life scientists who are involved in developing experimental or computational systems and methods to enhance our understanding of human physiology. It also covers biomedical researchers and engineers who are engaged in designing or optimizing therapies, assays, devices, or procedures for diagnosing or treating diseases. Additionally, clinicians, who make use of research outputs to evaluate patient health or administer therapy in various clinical settings and healthcare contexts, are also part of the target audience.