OBJECTIVE: Atherosclerosis-prone regions of arteries are characterized by complex flow patterns where the magnitude of shear stress is low and direction rapidly changes, termed disturbed flow. How endothelial cells sense flow direction and how it impacts inflammatory effects of disturbed flow are unknown. We therefore aimed to understand how endothelial cells respond to changes in flow direction. APPROACH AND RESULTS: Using a recently developed flow system capable of changing flow direction to any angle, we show that responses of aligned endothelial cells are determined by flow direction relative to their morphological and cytoskeletal axis. Activation of the atheroprotective endothelial nitric oxide synthase pathway is maximal at 180° and undetectable at 90°, whereas activation of proinflammatory nuclear factor-κB is maximal at 90° and undetectable at 180°. Similar effects were observed in randomly oriented cells in naive monolayers subjected to onset of shear. Cells aligned on micropatterned substrates subjected to oscillatory flow were also examined. In this system, parallel flow preferentially activated endothelial nitric oxide synthase and production of nitric oxide, whereas perpendicular flow preferentially activated reactive oxygen production and nuclear factor-κB. CONCLUSIONS: These data show that the angle between flow and the cell axis defined by their shape and cytoskeleton determines endothelial cell responses. The data also strongly suggest that the inability of cells to align in low and oscillatory flow is a key determinant of the resultant inflammatory activation.
OBJECTIVE:Atherosclerosis-prone regions of arteries are characterized by complex flow patterns where the magnitude of shear stress is low and direction rapidly changes, termed disturbed flow. How endothelial cells sense flow direction and how it impacts inflammatory effects of disturbed flow are unknown. We therefore aimed to understand how endothelial cells respond to changes in flow direction. APPROACH AND RESULTS: Using a recently developed flow system capable of changing flow direction to any angle, we show that responses of aligned endothelial cells are determined by flow direction relative to their morphological and cytoskeletal axis. Activation of the atheroprotective endothelial nitric oxide synthase pathway is maximal at 180° and undetectable at 90°, whereas activation of proinflammatory nuclear factor-κB is maximal at 90° and undetectable at 180°. Similar effects were observed in randomly oriented cells in naive monolayers subjected to onset of shear. Cells aligned on micropatterned substrates subjected to oscillatory flow were also examined. In this system, parallel flow preferentially activated endothelial nitric oxide synthase and production of nitric oxide, whereas perpendicular flow preferentially activated reactive oxygen production and nuclear factor-κB. CONCLUSIONS: These data show that the angle between flow and the cell axis defined by their shape and cytoskeleton determines endothelial cell responses. The data also strongly suggest that the inability of cells to align in low and oscillatory flow is a key determinant of the resultant inflammatory activation.
Authors: Mean Ghim; Paola Alpresa; Sung-Wook Yang; Sietse T Braakman; Stephen G Gray; Spencer J Sherwin; Maarten van Reeuwijk; Peter D Weinberg Journal: Am J Physiol Heart Circ Physiol Date: 2017-07-28 Impact factor: 4.733
Authors: Cristina M Ramírez; Xinbo Zhang; Chirosree Bandyopadhyay; Noemi Rotllan; Michael G Sugiyama; Binod Aryal; Xinran Liu; Shun He; Jan R Kraehling; Victoria Ulrich; Chin Sheng Lin; Heino Velazquez; Miguel A Lasunción; Guangxin Li; Yajaira Suárez; George Tellides; Filip K Swirski; Warren L Lee; Martin A Schwartz; William C Sessa; Carlos Fernández-Hernando Journal: Circulation Date: 2019-06-03 Impact factor: 29.690
Authors: Nicolas Baeyens; Chirosree Bandyopadhyay; Brian G Coon; Sanguk Yun; Martin A Schwartz Journal: J Clin Invest Date: 2016-03-01 Impact factor: 14.808
Authors: W Robert Taylor; Elizabeth Iffrig; Alessandro Veneziani; John N Oshinski; Alexander Smolensky Journal: Trans Am Clin Climatol Assoc Date: 2016