Reduced Platelet miR-223 Induction in Kawasaki Disease Leads to Severe Coronary Artery Pathology through a miR-223/PDGFRß Vascular Smooth Muscle Cell Axis

Yuan Zhang, Yanfei Wang, Li Zhang, Luoxing Xia, Minhui Zheng, Zhi Zeng, Yingying Liu, Timur Yarovinsky, Allison C. Ostriker, Xuejiao Fan, Kai Weng, Meiling Su, Ping Huang, Kathleen A. Martin, John Hwa, Wai Ho Tang

Research output: Contribution to journalArticlepeer-review

47 Citations (Scopus)

Abstract

Rationale: Kawasaki disease (KD) is an acute vasculitis of early childhood that can result in permanent coronary artery structural damage. The cause for this arterial vulnerability in up to 15% of patients with KD is unknown. Vascular smooth muscle cell dedifferentiation play a key role in the pathophysiology of medial damage and aneurysm formation, recognized arterial pathology in KD. Platelet hyperreactivity is also a hallmark of KD. We recently demonstrated that uptake of platelets and platelet-derived miRNAs influences vascular smooth muscle cell phenotype in vivo. Objective: We set out to explore whether platelet/vascular smooth muscle cell (VSMC) interactions contribute to coronary pathology in KD. Methods and Results: We prospectively recruited and studied 242 patients with KD, 75 of whom had documented coronary artery pathology. Genome-wide miRNA sequencing and droplet digital PCR demonstrated that patient with KD platelets have significant induction of miR-223 compared with healthy controls (HCs). Platelet-derived miR-223 has recently been shown to promote vascular smooth muscle quiescence and resolution of wound healing after vessel injury. Paradoxically, patients with KD with the most severe coronary pathology (giant coronary artery aneurysms) exhibited a lack of miR-223 induction. Hyperactive platelets isolated from patients with KD are readily taken up by VSMCs, delivering functional miR-223 into the VSMCs promoting VSMC differentiation via downregulation of PDGFRß (platelet-derived growth factor receptor ß). The lack of miR-223 induction in patients with severe coronary pathology leads to persistent VSMC dedifferentiation. In a mouse model of KD (Lactobacillus casei cell wall extract injection), miR-223 knockout mice exhibited increased medial thickening, loss of contractile VSMCs in the media, and fragmentation of medial elastic fibers compared with WT mice, which demonstrated significant miR-223 induction upon Lactobacillus casei cell wall extract challenge. The excessive arterial damage in the miR-223 knockout could be rescued by adoptive transfer of platelet, administration of miR-223 mimics, or the PDGFRß inhibitor imatinib mesylate. Interestingly, miR-223 levels progressively increase with age, with the lowest levels found in <5-year-old. This provides a basis for coronary pathology susceptibility in this very young cohort. Conclusions: Platelet-derived miR-223 (through PDGFRß inhibition) promotes VSMC differentiation and resolution of KD induced vascular injury. Lack of miR-223 induction leads to severe coronary pathology characterized by VSMC dedifferentiation and medial damage. Detection of platelet-derived miR-223 in patients with KD (at the time of diagnosis) may identify patients at greatest risk of coronary artery pathology. Moreover, targeting platelet miR-223 or VSMC PDGFRß represents potential therapeutic strategies to alleviate coronary pathology in KD.

Original languageEnglish
Pages (from-to)855-873
Number of pages19
JournalCirculation Research
Volume127
Issue number7
DOIs
Publication statusPublished - 11 Sept 2020
Externally publishedYes

Keywords

  • cell dedifferentiation
  • imatinib mesylate
  • knockout mice
  • platelet-derived growth factor receptor
  • vascular smooth muscle cell

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