Shear stress modulates RAGE-mediated inflammation in a model of diabetes-induced metabolic stress

DeVerse JS, Bailey KA, Jackson KN, Passerini AG. Shear stress modulates RAGE-mediated inflammation in a model of diabetes-induced metabolic stress. Am J Physiol Heart Circ Physiol 302: H2498-H2508, 2012. First published March 30, 2012; doi:10.1152/ajpheart.00869.2011.-Atherosclerosis occurs preferentially at sites of disturbed blood flow despite the influence of risk factors contributing to systemic inflammation. The receptor for advanced glycation endproducts (RAGE) is a prominent mediator of inflammation in diabetes that is upregulated in atherosclerotic plaques. Our goal was to elucidate a role for arterial hemodynamics in the regulation of RAGE expression and activity. Endothelial RAGE expression was elevated at sites of flow disturbance in the aortas of healthy swine. To demonstrate a direct role for physiological shear stress (SS) in modulating RAGE expression, human aortic endothelial cells (HAEC) were exposed to high SS (HSS; 15 dyn/cm(2)), which downregulated RAGE by fourfold, or oscillatory SS (OSS; 0 +/- 5 dyn/cm(2)), which upregulated RAGE by threefold, compared with static culture at 4 h. In a model of diabetes-induced metabolic stress, HAEC were chronically conditioned under high glucose (25 mM) and then simultaneously stimulated with TNF-alpha (0.5 ng/ml) and the RAGE ligand high mobility group box 1 (HMGB1). A 50% increase in VCAM-1 expression over TNF-alpha was associated with increased cytoplasmic and mitochondrial reactive oxygen species and NF-kappa B activity. This increase was RAGE-specific and NADPH oxidase dependent. In activated HAEC, OSS amplified HMGB1-induced VCAM-1 (3-fold) and RAGE (1.6-fold) expression and proportionally enhanced monocyte adhesion to HAEC in a RAGE-dependent manner, while HSS mitigated these increases to the level of TNF-alpha alone. We demonstrate that SS plays a fundamental role in regulating RAGE expression and inflammatory responses in the endothelium. These findings may provide mechanistic insight into how diabetes accelerates the nonrandom distribution of atherosclerosis in arteries.