Temporal Gradient in Shear But Not Steady Shear Stress Induces PDGF-A and MCP-1 Expression in Endothelial Cells

Bao, Xuping; Lu, Chuanyi M.; Frangos, John A.

doi:10.1161/01.atv.19.4.996

Cited by 199 publications

(130 citation statements)

References 59 publications

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“…2 These changes in gene expression result from modulation of either the production or the activity of transcription factors. [32][33][34] By stably overexpressing LKLF in cultured endothelial cells we now show that a distinct group of known shear-stress regulated genes involved in controlling vascular tone, ACE, EDN, ADM, and NOS3, can be transcriptionally regulated by LKLF. Furthermore, knockdown of LKLF using RNA interference revealed that the response of these genes to flow is primarily dependent on LKLF, with the exception of ACE.…”

Section: Discussionmentioning

confidence: 75%

Endothelial KLF2 Links Local Arterial Shear Stress Levels to the Expression of Vascular Tone-Regulating Genes

Dekker

Thienen

Rohlena

et al. 2005

The American Journal of Pathology

316

297

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Lung Krüppel-like factor (LKLF/KLF2) is an endothelial transcription factor that is crucially involved in murine vasculogenesis and is specifically regulated by flow in vitro. We now show a relation to local flow variations in the adult human vasculature: decreased LKLF expression was noted at the aorta bifurcations to the iliac and carotid arteries, coinciding with neointima formation. The direct involvement of shear stress in the in vivo expression of LKLF was determined independently by in situ hybridization and laser microbeam microdissection/reverse transcriptase-polymerase chain reaction in a murine carotid artery collar model, in which a 4-to 30-fold induction of LKLF occurred at the high-shear sites. Dissection of the biomechanics of LKLF regulation in vitro demonstrated that steady flow and pulsatile flow induced basal LKLF expression 15-and 36-fold at shear stresses greater than ϳ5 dyne/cm 2 , whereas cyclic stretch had no effect. The focal development of atherosclerosis has been linked to the local variations in blood flow that are observed near the irregular blood vessel geometries of bifurcations and bends. 1,2 Continuous exposure of endothelial cells to flow in vivo generates a tangential force, shear stress, across their apical surfaces. A large number of studies support the hypothesized antiatherosclerotic effect of shear stress on the endothelium, and are mainly based on the ability of shear stress to modulate endothelial gene expression. 3 Throughout the recent years, a collection of shear stress-responsive endothelial genes has been established. 4 -8 Usually no clear distinction is made between genes induced by prolonged shear and those induced by short-term shear (Ͻ24 hours), although the latter class typically represents a general stress response also observed with turbulent flow types and seems more related to endothelial dysfunction. Based on the rationale that only genes induced by prolonged shear would represent the healthy transcriptome, we previously identified a limited number of genes that are still highly induced after exposing human umbilical vein endothelial cells (HUVECs) to flow for 7 days, but which are not induced by various other (inflammatory) stimuli. 6 The expression of one of those genes, the transcription factor lung Krü ppel-like factor (LKLF/

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Section: Discussionmentioning

confidence: 75%

Endothelial KLF2 Links Local Arterial Shear Stress Levels to the Expression of Vascular Tone-Regulating Genes

Dekker

Thienen

Rohlena

et al. 2005

The American Journal of Pathology

316

297

View full text Add to dashboard Cite

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“…While human in vivo studies typically describe shear stress as a mean construct, numerous secondary phenomena associated with flow, including pulsatile flow, retrograde flow, and flow turbulence, can influence the regulation of endothelial cells [67][68][69][70][71][72] .…”

Section: Importance Of the Velocity Profilementioning

confidence: 99%

“…In vitro studies suggest that these two distinct fluid stimuli (velocity acceleration vs. steady shear) regulate short-and longterm endothelial function via independent biomechanical pathways 70,71,[73][74][75] . Studies have shown that the rate of velocity acceleration can affect the progression of atherosclerosis 70,73,76) , endothelial cell function 71 , 74) , mechanotransduction 77,78) , calcium kinetics 79,80) , and vascular tone 81,82) . Conditions which affect velocity acceleration include ventricular ischemia 83) , acute myocardial infarction 84) , stenosis 85) , hypertension 86) , and hyperthyroidism 87) .…”

Section: Velocity Acceleration and Endothelial Functionmentioning

confidence: 99%

Use of Ultrasound for Non-Invasive Assessment of Flow-Mediated Dilation

Stoner

Sabatier

2012

JAT

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The pathological complications of atherosclerosis, namely heart attacks and strokes, remain the leading cause of mortality in the Western world. Preceding atherosclerosis is endothelial dysfunction. There is therefore interest in the application of non-invasive clinical tools to assess endothelial function. The flow-mediated dilation (FMD) test is the standard tool used to assess endothelial function. Reduced FMD is an early marker of atherosclerosis and has been noted for its capacity to predict future cardiovascular disease events. This review discusses the measurement of endothelial function using ultrasound, with a focus on the FMD technique.

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“…6). In vitro studies suggest that these two distinct fluid stimuli (velocity acceleration vs. steady shear) regulate short-and long-term endothelial function via independent biomechanical pathways (Ojha 1994;Bao & Lu et al 1999;White & Haidekker et al 2001;Hsiai & Cho et al 2002DePaola, 1992 (Ojha 1994;Bao & Lu et al 1999;Hsiai & Cho et al 2001), endothelial cell function (White & Haidekker et al 2001 ;Hsiai & Cho et al 2002), mechanotransduction (Hsieh & Li et al 1993;Bao & Clark et al 2000), calcium kinetics (Helmlinger & Berk et al 1995;Blackman & Barbee et al 2000), and vascular tone (Frangos & Eskin et al 1985;Noris & Morigi et al 1995 ). Conditions which affect velocity acceleration include ventricular ischemia (Sabbah & Przybylski et al 1987), acute myocardial infarction (Kezdi & Stanley et al 1969), stenosis (Bassini & Gatti et al 1982), hypertension (Sainz & Cabau et al 1995), and hyperthyroidism (Chemla & Levenson et al 1990).…”

Section: Velocity Acceleration and Endothelial Functionmentioning

confidence: 99%