Gene expression profile of human endothelial cells exposed to sustained fluid shear stress

doi:10.1152/physiolgenomics.00102.2002

Gene expression profile of human endothelial cells exposed to sustained fluid shear stress

Scott M. Wasserman¹^,2, Fuad Mehraban³, Laszlo G. Komuves¹, Ruey-Bing Yang¹, James E. Tomlinson¹, Ying Zhang², Frank Spriggs³ and James N. Topper¹

¹ Millennium Pharmaceuticals, Inc., South San Francisco 94080
² Division of Cardiovascular Medicine, Stanford University, Stanford, California 94305
³ CuraGen Corporation, New Haven, Connecticut 06511

Biomechanical forces can modulate endothelial phenotype throughchanges in gene expression. We hypothesized that physiologicallaminar shear stresses (LSS) act as differentiative stimulion endothelial cells (EC) to alter gene expression, creatingan antioxidant, anti-apoptotic and anti-proliferative environment.The transcriptional profile of cultured human umbilical veinendothelial cells (HUVEC) exposed to LSS was evaluated by GeneCalling;107 genes demonstrated at least a twofold change in expressionat 24 h (LSS vs. static). These flow-responsive genes representa limited number of functional clusters that include transcriptionfactors, antioxidants, signaling molecules, cell cycle regulators,and genes involved in cellular differentiation. Immunohistochemistryand in situ hybridization confirmed that many of these flow-responsivegenes, including the novel basic helix-loop-helix transcriptionfactor Hath6, are expressed in EC in vivo. Thus these data identifya limited set of flow-responsive genes expressed in the endotheliumthat may be responsible for the establishment and maintenanceof the flow-adapted endothelial phenotype in vivo.

transcriptional profile; laminar shear stress; endothelium; biomechanical force; vascular biology

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