Litcius/Paper detail

Mechanical and chemical cues synergistically promote human venous smooth muscle cell osteogenesis through integrin β1‐ERK1/2 signaling: A cell model of hemodialysis fistula calcification

Chih‐Yu Yang, Pu‐Yuan Chang, Bo‐Sheng Wu, Der‐Cherng Tarng, Oscar Kuang‐Sheng Lee

2021The FASEB Journal10 citationsDOI

Abstract

Arteriovenous fistula (AVF) is the vascular access of choice for renal replacement therapy. However, AVF is susceptible to calcification with a high prevalence of 40%-65% in chronic hemodialysis patients. Repeated needle puncture for hemodialysis cannulation results in intimal denudation of AVF. We hypothesized that exposure to blood shear stress in the medial layer promotes venous smooth muscle cell (SMC) osteogenesis. While previous studies of shear stress focused on arterial-type SMCs, SMCs isolated from the vein had not been investigated. This study established a venous cell model of AVF using the fluid shear device, combined with a high phosphate medium to mimic the uremic milieu. Osteogenic gene expression of venous SMCs upon mechanical and chemical cues was analyzed in addition to the activated cell signaling pathways. Our findings indicated that upon shear stress and high phosphate environment, mechanical stimulation (shear stress) had an additive effect in up-regulation of an early osteogenic marker, Runx2. We further identified that the integrin β1-ERK1/2 signaling pathway was responsible for the molecular basis of venous SMC osteogenesis upon shear stress exposure. Mitochondrial biogenesis also took part in the early stage of this venopathy pathogenesis, evident by the up-regulated mitochondrial transcription factor A and mitochondrial DNA polymerase γ in venous SMCs. In conclusion, synergistic effects of fluid shear stress and high phosphate induce venous SMC osteogenesis via the ERK1/2 pathway through activating the mechanosensing integrin β1 signaling. The present study identified a promising druggable target for reducing AVF calcification, which deserves further in vivo investigations.

Topics & Concepts

Vascular smooth muscleIntegrinMedicineCellFistulaCalcificationVeinChemistryPathologyNeointimal hyperplasiaArteriovenous fistulaCell biologyAnatomyHemodialysisVenous bloodBlood vesselShear stressInternal medicineSignal transductionStenosisVenous ValvesCardiologyIn vivoFocal adhesionMyocyteMechanotransductionEndocrinologyRotator cuffCell adhesionOsteoblastHypoxia (environmental)Central Venous Catheters and HemodialysisDiagnosis and Treatment of Venous DiseasesDialysis and Renal Disease Management