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Literature DB >> 31763999

Smooth muscle cell-specific fibronectin-EDA mediates phenotypic switching and neointimal hyperplasia.

Manish Jain¹, Nirav Dhanesha¹, Prakash Doddapattar¹, Mehul R Chorawala¹, Manasa K Nayak¹, Anne Cornelissen², Liang Guo², Aloke V Finn², Steven R Lentz¹, Anil K Chauhan¹.

Abstract

Fibronectin-splice variant containing extra domain A (Fn-EDA) is associated with smooth muscle cells (SMCs) following vascular injury. The role of SMC-derived Fn-EDA in SMC phenotypic switching or its implication in neointimal hyperplasia remains unclear. Herein, using human coronary artery sections with a bare metal stent, we demonstrate the expression of Fn-EDA in the vicinity of SMC-rich neointima and peri-strut areas. In mice, Fn-EDA colocalizes with SMCs in the neointima of injured carotid arteries and promotes neointima formation in the comorbid condition of hyperlipidemia by potentiating SMC proliferation and migration. No sex-based differences were observed. Mechanistic studies suggested that Fn-EDA mediates integrin- and TLR4-dependent proliferation and migration through activation of FAK/Src and Akt1/mTOR signaling, respectively. Specific deletion of Fn-EDA in SMCs, but not in endothelial cells, reduced intimal hyperplasia and suppressed the SMC synthetic phenotype concomitant with decreased Akt1/mTOR signaling. Targeting Fn-EDA in human aortic SMCs suppressed the synthetic phenotype and downregulated Akt1/mTOR signaling. These results reveal that SMC-derived Fn-EDA potentiates phenotypic switching in human and mouse aortic SMCs and neointimal hyperplasia in the mouse. We suggest that targeting Fn-EDA could be explored as a potential therapeutic strategy to reduce neointimal hyperplasia.

Entities: Disease Gene Species

Keywords: Extracellular matrix; Fibronectin; Vascular Biology

Mesh：

Substances：

Year: 2020 PMID： 31763999 PMCID： PMC6934199 DOI： 10.1172/JCI124708

Source DB: PubMed Journal: J Clin Invest ISSN： 0021-9738 Impact factor: 14.808

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1. Elevated plasma levels of ED1+ ("cellular") fibronectin in patients with vascular injury.

Authors: J H Peters; R J Maunder; A D Woolf; C G Cochrane; M H Ginsberg
Journal: J Lab Clin Med Date: 1989-05

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Review 4. Molecular mechanisms of in-stent restenosis and approach to therapy with eluting stents.

Authors: Ciro Indolfi; Annalisa Mongiardo; Antonio Curcio; Daniele Torella
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5. Human endothelial cells synthesize, process, and secrete fibronectin molecules bearing an alternatively spliced type III homology (ED1).

Authors: J H Peters; L A Sporn; M H Ginsberg; D D Wagner
Journal: Blood Date: 1990-05-01 Impact factor: 22.113

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Authors: Swati Bhattacharyya; Zenshiro Tamaki; Wenxia Wang; Monique Hinchcliff; Paul Hoover; Spiro Getsios; Eric S White; John Varga
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7. Fibronectin extra domain A stabilises atherosclerotic plaques in apolipoprotein E and in LDL-receptor-deficient mice.

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Journal: Sci Rep Date: 2015-03-12 Impact factor: 4.379

9. EDA-containing fibronectin increases proliferation of embryonic stem cells.

Authors: Noelia Losino; Ariel Waisman; Claudia Solari; Carlos Luzzani; Darío Fernández Espinosa; Alina Sassone; Andrés F Muro; Santiago Miriuka; Gustavo Sevlever; Lino Barañao; Alejandra Guberman
Journal: PLoS One Date: 2013-11-14 Impact factor: 3.240

10. Analysis of Soluble Molecular Fibronectin-Fibrin Complexes and EDA-Fibronectin Concentration in Plasma of Patients with Atherosclerosis.

Authors: Anna Lemańska-Perek; Dorota Krzyżanowska-Gołąb; Małgorzata Pupek; Piotr Klimeczek; Wojciech Witkiewicz; Iwona Kątnik-Prastowska
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