Literature DB >> 28809397

Fibroblasts in an endocardial fibroelastosis disease model mainly originate from mesenchymal derivatives of epicardium.

Hui Zhang1,2,3, Xiuzhen Huang1,2, Kuo Liu1,2,3, Juan Tang1,2, Lingjuan He1,2, Wenjuan Pu1,2, Qiaozhen Liu1,2, Yan Li1,2, Xueying Tian1,2, Yue Wang1,2, Libo Zhang1,2, Ying Yu2,2, Hongyan Wang1, Ronggui Hu1, Fengchao Wang4, Ting Chen4, Qing-Dong Wang5, Zengyong Qiao6, Li Zhang7, Kathy O Lui8, Bin Zhou1,2,3,9.   

Abstract

Endocardial fibroelastosis (EFE) refers to the thickening of the ventricular endocardium as a result of de novo deposition of subendocardial fibrous tissue layers during neonatal heart development. The origin of EFE fibroblasts is proposed to be postnatal endocardial cells that undergo an aberrant endothelial-to-mesenchymal transition (EndMT). Genetic lineage tracing of endocardial cells with the inducible endocardial Cre line Npr3-CreER and the endothelial cell tracing line Cdh5-CreER on an EFE-like model did not reveal any contribution of neonatal endocardial cells to fibroblasts in the EFE-like tissues. Instead, lineage tracing of embryonic epicardium by Wt1-CreER suggested that epicardium-derived mesenchymal cells (MCs) served as the major source of EFE fibroblasts. By labeling MCs using Sox9-CreER, we confirmed that MCs of the embryonic heart expand and contribute to the majority of neonatal EFE fibroblasts. During this pathological process, TGFβ signaling, the key mediator of fibroblasts activation, was highly upregulated in the EFE-like tissues. Targeting TGFβ signaling by administration of its antagonist bone morphogenetic protein 7 effectively reduced fibroblast accumulation and tissue fibrosis in the EFE-like model. Our study provides genetic evidence that excessive fibroblasts in the EFE-like tissues mainly originate from the epicardium-derived MCs through epicardial to mesenchymal transition (EpiMT). These EpiMT-derived fibroblasts within the EFE-like tissues could serve as a potential therapeutic target.

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Year:  2017        PMID: 28809397      PMCID: PMC5587848          DOI: 10.1038/cr.2017.103

Source DB:  PubMed          Journal:  Cell Res        ISSN: 1001-0602            Impact factor:   25.617


  71 in total

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