The common aldehyde dehydrogenase 2 ( ALDH2 ) alcohol flushing variant known as ALDH2*2 affects ∼8% of the world’s population. Even in heterozygous carriers, this missense variant leads to a severe loss of ALDH2 enzymatic activity and has been linked to an increased risk of coronary artery disease (CAD). Endothelial cell (EC) dysfunction plays a determining role in all stages of CAD pathogenesis, including early-onset CAD. However, the contribution of ALDH2*2 to EC dysfunction and its relation to CAD are not fully understood. In a large genome-wide association study (GWAS) from Biobank Japan, ALDH2*2 was found to be one of the strongest single-nucleotide polymorphisms associated with CAD. Clinical assessment of endothelial function showed that human participants carrying ALDH2*2 exhibited impaired vasodilation after light alcohol drinking. Using human induced pluripotent stem cell–derived ECs (iPSC-ECs) and CRISPR-Cas9–corrected ALDH2*2 iPSC-ECs, we modeled ALDH2*2 -induced EC dysfunction in vitro, demonstrating an increase in oxidative stress and inflammatory markers and a decrease in nitric oxide (NO) production and tube formation capacity, which was further exacerbated by ethanol exposure. We subsequently found that sodium-glucose cotransporter 2 inhibitors (SGLT2i) such as empagliflozin mitigated ALDH2*2 -associated EC dysfunction. Studies in ALDH2*2 knock-in mice further demonstrated that empagliflozin attenuated ALDH2*2 -mediated vascular dysfunction in vivo. Mechanistically, empagliflozin inhibited Na + /H + -exchanger 1 (NHE-1) and activated AKT kinase and endothelial NO synthase (eNOS) pathways to ameliorate ALDH2*2 -induced EC dysfunction. Together, our results suggest that ALDH2*2 induces EC dysfunction and that SGLT2i may potentially be used as a preventative measure against CAD for ALDH2*2 carriers.
Introduction: Hypoplastic left heart syndrome (HLHS) is a severe form of single ventricle congenital heart disease characterized by the underdeveloped left ventricle. Early serial postmortem examinations revealed a high rate of coronary artery abnormalities in HLHS fetal hearts (e.g., thickened wall and kinking arteries). However, the intrinsic defect in HLHS coronary vessels and its genetic basis remain unclear. Methods: We profiled human fetal heart with an underdeveloped left ventricle (ULV) and induced pluripotent stem cells derived endothelial cells (iPSC-ECs) from HLHS patients at single-cell resolution. CD144 + / NPR3 - vascular ECs were selected and classified as venous, arterial, and late arterial populations. To study the arterial EC phenotypes, we generated iPSC-arterial ECs (AECs, CDH5 + CXCR4 + NT5E -/low ) derived from 3 HLHS patients and 3 age-matched controls, and evaluated their functionalities including cell cycle regulation, angiogenesis, and inflammatory response. Results: Revealed by single cell RNA-seq and subsequent gene ontology analysis, ULV late arterial EC population showed significant defects in EC development, proliferation, angiogenesis, and Notch signaling compared to the control. Consistently, HLHS iPSCs exhibited impaired AEC differentiation judged by the reduced CXCR4 + NT5E -/low AEC progenitors. Mature HLHS iPSC-AECs showed reduced angiogenesis and enhanced G0/G1 cell cycle arrest with downregulated cell cycle-related genes (e.g., Ki67, CCND1/2 ). Healthy human aortic smooth muscle cells exhibited abnormal proliferation and synthetic phenotypes when co-cultured with HLHS iPSC-AECs. Additionally, NOTCH pathway genes (e.g., DLL4, HEY1, GJA5 ) were suppressed in both ULV AECs and HLHS iPSC-AECs. HLHS de novo variant KMT2D directly regulated the transcription of NOTCH targeted genes involved in arterial development and proliferation via H3K4me2. Intriguingly, the treatment of NOTCH ligands (Jag1, Dll1) significantly improved the proliferation of HLHS AECs. Conclusions: Our study revealed that HLHS coronary AECs were dysfunctional in angiogenesis, proliferation, and EC-SMC interaction. KMT2D-NOTCH signaling may contribute to the impaired development and proliferation of HLHS AECs.
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