作者
Dandan Liao,Shuji Mizumoto,Wee Joo Chng,I Tanudin,E Motakis,Jing Tian,Rijan Gurung,Shuhei Yamada,Matthew Ackers‐Johnson,Mark Richards,Bruno Reversade,Roger Foo,M Y Chan,Rongrong Zhao,Cho Yeow Koh
摘要
Abstract Introduction Hyperplastic arterial remodelling is characterized by intima-media thickening, lumen narrowing, inflammation and increased extracellular matrix (ECM) deposition. Chondroitin sulfate (CS) glycosaminoglycans, the unbranched polysaccharide chains of proteoglycans, are important components of ECM. We previously found CS accumulated in adversely remodelled heart and artery, aggravating cardiac deterioration. Objective We aim to explore a therapeutic strategy to interfere with CS synthesis and investigate its potential in ameliorating hyperplastic arterial remodelling. Methods Through single-cell RNA sequencing of non-cardiomyocytes cardiac cells from mouse myocardial infarction model, chondroitin sulfate synthase 1 (CHSY1) was identified as the primary CS synthase and was increased during disease progression. A Chsy1 knockout (KO) mouse strain was generated. Fibrosis and arterial remodelling were induced using: (i) 4 weeks of angiotensin II/phenylephrine (AngII/PE) infusion through subcutaneous osmotic minipumps; and (ii) transverse aortic constriction surgery. To assess the therapeutic potential of CHSY1 inhibition in ameliorating hyperplastic arterial remodelling, Chsy1 was knockdown by dsiRNA post disease onset. Mechanism of action was investigated using primary vascular smooth muscle cells (VSMCs). Results Chsy1 KO reduced CS and its stereoisomer dermatan sulfate in the heart to 42 ± 22% and 36 ± 7% respectively, whereas other types of glycosaminoglycans remain intact. KO mice were protected against phenotypes of hyperplastic arterial remodelling induced by the two disease models in both the coronary and carotid arteries. For example, 90.1% of coronary arterial fibrosis and 79.7% of macrophage infiltration induced by AngII/PE was declined in KO mice compared to WT mice, while cardiac function as stroke volume was augmented by 41.3%. Concomitantly, carotid arterial wall thickening was lower by 36.5% and distensibility was higher by 36.7%, validating Chsy1 as a potent target. As a therapeutic approach, weekly intravenous injection of dsiRNA achieved Chsy1 reduced to 30.2 ± 5.5% in the carotid artery and 72.5 ± 4.7% in the heart. Post disease onset, Chsy1 KD therapy reduced fibrosis by 59.9% in the coronary artery (P = 0.006) and improved stroke volume by 25.6% (P = 0.036). The structural integrity and function of carotid arteries were well-reserved, manifesting as improved distensibility (29%, P = 0.016), increased elastin/perimeter ratio (15%, P = 0.002), and reduced macrophage infiltration (38%, P = 0.029). In vitro, CHSY1 inhibition suppressed migration and cytokine production of macrophages, fibroblast-to-myofibroblast transition, and VSMC hyperproliferation. NOTCH3 signalling was found to be positively correlated with CHSY1 modulation. Conclusions We demonstrated that inhibiting CHSY1 is necessary and sufficient to block CS synthesis. Chsy1 KD by dsiRNA is an effective therapy to ameliorate hyperplastic arterial remodelling.