Potential relation between cytoskeleton reorganization and e-NOS activity in sheared endothelial cells (Effect of rate and time of exposure)

Clinical Hemorheology and Microcirculation

Volumn 37, Issue 1-2, 2007, Pages 131-140

  Kadi, A ^a,b   De Isla, N ^a   Lacolley, P ^b   Stoltz, J F ^a   Menu, P ^a  

^a NANCY UNIVERSITÉ   (France)

^b UNIVERSITÉ DE LORRAINE   (France)

Author keywords

Cytoskeleton reorganization; e NOS; ECs; Hypertension; Nitric oxide; Shear stress; SMCs; Vasorelaxation

Indexed keywords

ENDOTHELIAL NITRIC OXIDE SYNTHASE;

ACTIN FILAMENT; CELL LABELING; CELL SHAPE; COLORIMETRY; CONFERENCE PAPER; CONFOCAL MICROSCOPY; CONTROLLED STUDY; CYTOSKELETON; ENDOTHELIUM CELL; ENZYME ACTIVITY; HUMAN; HUMAN CELL; HYPERTENSION; IN VITRO STUDY; LAMINAR FLOW; SHEAR STRENGTH; SHEAR STRESS;

CELL SHAPE; CELLS, CULTURED; CYTOSKELETON; ENDOTHELIAL CELLS; ENDOTHELIUM, VASCULAR; HUMANS; MICROFILAMENTS; NITRIC OXIDE; NITRIC OXIDE SYNTHASE TYPE III; STRESS, MECHANICAL; UMBILICAL VEINS;

EID: 34347347279     PISSN: 13860291     EISSN: None     Source Type: Journal    
DOI: None     Document Type: Conference Paper

References (25)

1. Y.S. Li, J.H. Haga and S. Chien, Molecular basis of the effects of shear stress on vascular endothelial cells, J. Biomech. 10 (2005), 1949-1971.
2. S. Lehoux, Y. Castier and A. Tedgui, Molecular mechanisms of the vascular responses to haemodynamic forces, J. Intern. Med. 4 (2006), 381-392.
3. S. Mélançon, H. Bachelar, M. Badeau, F. Bourgoin, M. Pitre, R. Larivière and A. Nadeau, Effect of high sucrose feeding on insulin resistance and hemodynamic responses to insulin in spontaneously hypertensive rats, Am. J. Physiol - Heart Circ. Physiol. 6 (2006), H2571-H2581.
4. J.S. Isenberg, N. Tabatabai and H.M. Spinelli, Nitric oxide modulation of low-density mononuclear cell transendothelial migration, Microsurgery 5 (2005), 452-456.
5. I. Fleming and R. Busse, Signal transduction of eNOS activation. Cardiovascular Research 43 (1999), 532-541.
6. J.B. Michel, Rôle du monoxide d'azote endothelial dans la regulation du tonus artériel, La revue du praticien (1997), 47.
7. G. Wu and C.J. Meininger, Regulation of L-arginine synthesis from L-citrulline by L-glutamine in endothelial cells, Am. J. Physiol. 6 (1993), H1965-1971.
8. G. Keilhoff, M. Reiser, A. Stanarius, E. Aoki and G. Wolf, Citrulline immunohistochemistry for demonstration of NOS activity in vivo and in vitro, Nitric Oxide 4 (2000), 343-353.
9. W.K. Alderton, C.E. Cooper and R.G. Knowles, Nitric oxide synthases: Structure, function and inhibition, Biochem. J. 357 (2001), 593-615.
10. N. Sennequier and S.V.-L. Goff, Biosynthèse du monoxide d'azote (NO): mécanisme, régulation et contrôle, Médecine/sciences 14 (1998), 1185-1195.
11. B. Guerci, A. Kearney-Schwartz, P. Bohme, F. Zannad and P. Drouin, Endothelial dysfunction and type 2 diabetes. Part 1: Physiology and methods for exploring the endothelial function, Diabetes Metab. 4 (2001), 425-434.
12. S. McCue, S. Noria and B.L. Langille, Shear-induced reorganization of endothelial cell cytoskeleton and adhesion complexes, Trends Cardiovasc. Med. 4 (2004), 143-151.
13. C. Boura, S. Muller, J.C. Voegel, P. Schaaf, J.F. Stoltz and P. Menu, Influence of polyelectrolyte multilayer films on the ICAM-1 expression of endothelial cells, Cell Biochem. Biophys. 2 (2006), 223-231.
14. H. Wessells, T.H. Teal, K. Engel, C.J. Sullivan, B. Gallis, K.B. Tran and K. Chitaley, Fluid shear stress-induced nitric oxide production in human cavernosal endothelial cells: Inhibition by hyperglycaemia, BJU Int. 5 (2006), 1047-1052.
15. E.A. Osborn, A. Rabodzey, C.F. Dewey Jr and J.H. Hartwig, Endothelial actin cytoskeleton remodeling during mechanostimulation with fluid shear stress, Am. J. Physiol. Cell. Physiol. 2 (2006), C444-452.
16. C.G. Galbraith, R. Skalak and S. Chien, Shear stress induces spatial reorganization of the endothelial cell cytoskeleton, Cell Motil. Cytoskeleton. 4 (1998), 317-330.
17. K.G. Birukov, A.A. Birukova, S.M. Dudek, A.D. Verin, M.T. Crow, X. Zhan, N. DePaola and J.G. Garcia, Shear stress-mediated cytoskeletal remodeling and cortactin translocation in pulmonary endothelial cells, Am. J. Respir. Cell. Mol. Biol. 4 (2002), 453-464.
18. E. Tzima, M.A. Del Pozo, W.B. Kiosses, S.A. Mohamed, S. Li, S. Chien and M.A. Schwartz, Activation of Rac1 by shear stress in endothelial cells mediates both cytoskeletal reorganization and effects on gene expression, EMBO J. 24 (2002), 6791-6800.
19. A.J. Ridley, M.A. Schwartz, K. Burridge, R.A. Firtel, M.H. Ginsberg, G. Borisy, J.T. Parsons and A.R. Horwitz, Cell migration: Integrating signals from front to back, Science 5651 (2003), 1704-1709.
20. B. Imberti, M. Morigi, C. Zoja, S. Angioletti, M. Abbate, A. Remuzzi and G. Remuzzi, Shear stress-induced cytoskeleton rearrangement mediates NF-kappaB-dependent endothelial expression of ICAM-1, Microvasc. Res. 2 (2000), 182-188.
21. S. Noria, F. Xu, S. McCue, M. Jones, A.I. Gotlieb and B.L. Langille, Assembly and reorientation of stress fibers drives morphological changes to endothelial cells exposed to shear stress, Am. J. Pathol. 4 (2004), 1211-1223.
22. M.L. Albuquerque and A.S. Flozak, Patterns of living beta-actin movement in wounded human coronary artery endothelial cells exposed to shear stress, Exp. Cell Res. 2 (2001), 223-234.
23. M. Noris, M. Morigi, R. Donadelli, S. Aiello, M. Foppolo, M. Todeschini, S. Orisio, G. Remuzzi and A. Remuzzi, Nitric oxide synthesis by cultured endothelial cells is modulated by flow conditions, Circ. Res. 4 (1995), 536-543.
24. D. Kondrikov, H.R. Han, E.R. Block and Y. Su, Growth and density-dependent regulation of NO synthase by the actin cytoskeleton in pulmonary artery endothelial cells, Am. J. Physiol. Lung. Cell. Mol. Physiol. 1 (2006), L41-50.
25. M. Schleicher, F. Brundin, S. Gross, W. Muller-Esterl and S. Oess, Cell cycle-regulated inactivation of endothelial NO synthase through NOSIP-dependent targeting to the cytoskeleton, Mol. Cell Biol. 18 (2005), 8251-8258.