In Vivo Base Editing of Scn5a Rescues Type 3 Long QT Syndrome in Mice.

BACKGROUND: Pathogenic variants in SCN5A can result in long QT syndrome type 3, a life-threatening genetic disease. Adenine base editors can convert targeted A T base pairs to G C base pairs, offering a promising tool to correct pathogenic variants. METHODS: We generated a long QT syndrome type 3 mouse model by introducing the T1307M pathogenic variant into the Scn5a gene. The adenine base editor was split into 2 smaller parts and delivered into the heart by adeno-associated virus serotype 9 (AAV9-ABEmax) to correct the T1307M pathogenic variant. RESULTS: Both homozygous and heterozygous T1307M mice showed significant QT prolongation. Carbachol administration induced Torsades de Pointes or ventricular tachycardia for homozygous T1307M mice (20%) but not for heterozygous or wild-type mice. A single intraperitoneal injection of AAV9-ABEmax at postnatal day 14 resulted in up to 99.20% Scn5a transcripts corrected in T1307M mice. Scn5a mRNA correction rate >60% eliminated QT prolongation; Scn5a mRNA correction rate <60% alleviated QT prolongation. Partial Scn5a correction resulted in cardiomyocytes heterogeneity, which did not induce severe arrhythmias. We did not detect off-target DNA or RNA editing events in ABEmax-treated mouse hearts. CONCLUSIONS: These findings show that in vivo AAV9-ABEmax editing can correct the variant Scn5a allele, effectively ameliorating arrhythmia phenotypes. Our results offer a proof of concept for the treatment of hereditary arrhythmias.

M2 Macrophage-Derived Exosomes Inhibit Atherosclerosis Progression by Regulating the Proliferation, Migration, and Phenotypic Transformation of Smooth Muscle Cells.

BACKGROUND: Vascular smooth muscle cell (VSMC) intimal migration, proliferation, and phenotypic transformation from a contractile to a synthetic state are hallmarks of the progression of atherosclerotic plaques. This study aims to explore the effects of exosomes derived from M2 macrophages (ExoM2) on the pathological changes of VSMCs in atherosclerosis (AS). METHODS: Cell Counting Kit-8 (CCK8) and wound healing assays were used to examine the impact of ExoM2 on platelet-derived growth factor-BB (PDGF-BB)-induced VSMC proliferation and migration, respectively. Western blotting was employed to analyze changes in the expression levels of contractile markers (e.g., alpha-smooth muscle actin [α-SMA]) and synthetic ones (e.g., osteopontin [OPN]) in VSMCs with or without ExoM2 treatment. ApoE-⁣/- mice on a high fat diet were utilized to observe the effects of ExoM2 on plaque progression and stability. Serial histopathological analysis was performed to elucidate the cellular mechanisms underlying the atheroprotective effects of ExoM2. RESULTS: Compared with controls, ExoM2 significantly inhibited PDGF-BB-induced VSMC proliferation, migration, and phenotypic transformation in vitro. In ApoE-⁣/- mice, ExoM2 treatment led to a marked reduction in plaque size, necrotic core area, the CD68/α-SMA ratio, and matrix metalloproteinase 9 (MMP9) and OPN levels, while enhancing plaque stability. CONCLUSIONS: ExoM2 inhibit AS progression by regulating VSMC proliferation, migration, and phenotypic transformation.