Whole-brain in vivo base editing reverses behavioral changes in Mef2c-mutant mice.
Wei-Ke LiShu-Qian ZhangWan-Ling PengYu-Han ShiBo YuanYi-Ting YuanZhen-Yu XueJin-Cheng WangWen-Jian HanZhi-Fang ChenShi-Fang ShanBi-Qing XueJin-Long ChenCheng ZhangShu-Jia ZhuYi-Lin TaiTian-Lin ChengZi-Long QiuPublished in: Nature neuroscience (2023)
Whole-brain genome editing to correct single-base mutations and reduce or reverse behavioral changes in animal models of autism spectrum disorder (ASD) has not yet been achieved. We developed an apolipoprotein B messenger RNA-editing enzyme, catalytic polypeptide-embedded cytosine base editor (AeCBE) system for converting C·G to T·A base pairs. We demonstrate its effectiveness by targeting AeCBE to an ASD-associated mutation of the MEF2C gene (c.104T>C, p.L35P) in vivo in mice. We first constructed Mef2cL35P heterozygous mice. Male heterozygous mice exhibited hyperactivity, repetitive behavior and social abnormalities. We then programmed AeCBE to edit the mutated C·G base pairs of Mef2c in the mouse brain through the intravenous injection of blood-brain barrier-crossing adeno-associated virus. This treatment successfully restored Mef2c protein levels in several brain regions and reversed the behavioral abnormalities in Mef2c-mutant mice. Our work presents an in vivo base-editing paradigm that could potentially correct single-base genetic mutations in the brain.
Keyphrases
- crispr cas
- genome editing
- autism spectrum disorder
- blood brain barrier
- wild type
- high fat diet induced
- white matter
- resting state
- cerebral ischemia
- attention deficit hyperactivity disorder
- healthcare
- randomized controlled trial
- intellectual disability
- genome wide
- systematic review
- gene expression
- type diabetes
- insulin resistance
- high frequency
- low dose
- nucleic acid