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A. Noghero, A. Perino, G. Seano, E. Saglio, G. Sasso, F. Veglio, L. Primo, E. Hirsch, F. Bussolino, F. Morello (2012)
Liver X Receptor Activation Reduces Angiogenesis by Impairing Lipid Raft Localization and Signaling of Vascular Endothelial Growth Factor Receptor-2Arteriosclerosis, Thrombosis, and Vascular Biology, 32
K. Bhadriraju, L. Hansen (2002)
Extracellular matrix- and cytoskeleton-dependent changes in cell shape and stiffness.Experimental cell research, 278 1
Yong Chen, Jie Qin, Jiye Cai, Zheng Chen (2009)
Cold Induces Micro- and Nano-Scale Reorganization of Lipid Raft Markers at Mounds of T-Cell Membrane FluctuationsPLoS ONE, 4
Fangfa Zeng, Wen Yang, Jie Huang, Yuan Chen, Yong Chen (2012)
Determination of the lowest concentrations of aldehyde fixatives for completely fixing various cellular structures by real-time imaging and quantificationHistochemistry and Cell Biology, 139
F. Byfield, H. Aranda‐Espinoza, V. Romanenko, G. Rothblat, I. Levitan (2004)
Cholesterol depletion increases membrane stiffness of aortic endothelial cells.Biophysical journal, 87 5
Björn Lillemeier, J. Pfeiffer, Z. Surviladze, B. Wilson, Mark Davis (2006)
Plasma membrane-associated proteins are clustered into islands attached to the cytoskeletonProceedings of the National Academy of Sciences, 103
R. Juliano, E. Gagalang (1977)
The adhesion of Chinese hamster cells. I. Effects of temperature, metabolic inhibitors and proteolytic dissection of cell surface macromoleculesJournal of Cellular Physiology, 92
Mingzhai Sun, Nathan Northup, F. Marga, Tamás Huber, F. Byfield, I. Levitan, G. Forgacs (2007)
The effect of cellular cholesterol on membrane-cytoskeleton adhesionJournal of Cell Science, 120
Koji Ando, Y. Obara, Jun Sugama, A. Kotani, N. Koike, S. Ohkubo, N. Nakahata (2010)
P2Y2 Receptor-Gq/11 Signaling at Lipid Rafts Is Required for UTP-Induced Cell Migration in NG 108-15 CellsJournal of Pharmacology and Experimental Therapeutics, 334
Wenxiang Shao, Hua Jin, Jie Huang, B. Qiu, Ruihua Xia, Z. Deng, Jiye Cai, Yong Chen (2013)
AFM investigation on Ox-LDL-induced changes in cell spreading and cell-surface adhesion property of endothelial cells.Scanning, 35 2
M. Frick, N. Bright, K. Riento, Aurélie Bray, Christien Merrified, B. Nichols (2007)
Coassembly of Flotillins Induces Formation of Membrane Microdomains, Membrane Curvature, and Vesicle BuddingCurrent Biology, 17
A. Kenworthy (2008)
Have we become overly reliant on lipid rafts?EMBO reports, 9
AK Kenworthy (2008)
Have we become overly reliant on lipid rafts? Talking point on the involvement of lipid rafts in T-cell activationEMBO Rep, 9
Jie Huang, Wenxiang Shao, L. Wu, Wen Yang, Yong Chen (2012)
Effects of exogenous ganglioside GM1 on different stages of cell spreading studied by directly quantifying spreading rateCell Communication & Adhesion, 19
J. Mounier, Valérie Laurent, Alan Hall, Philippe Fort, M. Carlier, Philippe Sansonetti, C. Egile (1999)
Rho family GTPases control entry of Shigella flexneri into epithelial cells but not intracellular motility.Journal of cell science, 112 ( Pt 13)
T. Murai, Y. Maruyama, K. Mio, H. Nishiyama, M. Suga, C. Sato (2010)
Low Cholesterol Triggers Membrane Microdomain-dependent CD44 Shedding and Suppresses Tumor Cell Migration*The Journal of Biological Chemistry, 286
L. Pike (2006)
Rafts defined: a report on the Keystone symposium on lipid rafts and cell function Published, JLR Papers in Press, April 27, 2006.Journal of Lipid Research, 47
LJ Pike (2006)
Rafts defined: a report on the Keystone Symposium on Lipid Rafts and Cell FunctionJ Lipid Res, 47
Leann Norman, Ratna Oetama, M. Dembo, F. Byfield, D. Hammer, I. Levitan, H. Aranda‐Espinoza (2010)
Modification of Cellular Cholesterol Content Affects Traction Force, Adhesion and Cell SpreadingCellular and Molecular Bioengineering, 3
M. Staykova, D. Holmes, C. Read, H. Stone (2011)
Mechanics of surface area regulation in cells examined with confined lipid membranesProceedings of the National Academy of Sciences, 108
Effects of Raft Disruption and/or Cold Treatment 199
Pere Roca-Cusachs, J. Alcaraz, R. Sunyer, J. Samitier, R. Farré, D. Navajas (2008)
Micropatterning of single endothelial cell shape reveals a tight coupling between nuclear volume in G1 and proliferation.Biophysical journal, 94 12
Hua Jin, Jiang Pi, Xun Huang, Feicheng Huang, Wenxiang Shao, Shengpu Li, Yong Chen, Jiye Cai (2012)
BMP2 promotes migration and invasion of breast cancer cells via cytoskeletal reorganization and adhesion decrease: an AFM investigationApplied Microbiology and Biotechnology, 93
Yunqi Wang, Yong Chen, Jiye Cai, L. Zhong (2009)
QD as a bifunctional cell-surface marker for both fluorescence and atomic force microscopy.Ultramicroscopy, 109 3
F. Rico, Calvin Chu, M. Abdulreda, Yujing Qin, V. Moy (2010)
Temperature modulation of integrin-mediated cell adhesion.Biophysical journal, 99 5
W. Huttner, J. Zimmerberg (2001)
Implications of lipid microdomains for membrane curvature, budding and fission.Current opinion in cell biology, 13 4
M. Langner, K. Kubica (1999)
The electrostatics of lipid surfaces.Chemistry and physics of lipids, 101 1
A. Mammoto, Sui Huang, K. Moore, P. Oh, D. Ingber (2004)
Role of RhoA, mDia, and ROCK in Cell Shape-dependent Control of the Skp2-p27kip1 Pathway and the G1/S Transition*Journal of Biological Chemistry, 279
Huanhuan Liao, H. He, Yuan Chen, Fangfa Zeng, Jie Huang, Li Wu, Yong Chen (2014)
Effects of long-term serial cell passaging on cell spreading, migration, and cell-surface ultrastructures of cultured vascular endothelial cellsCytotechnology, 66
Rebecca Winokur, J. Hartwig (1995)
Mechanism of shape change in chilled human platelets.Blood, 85 7
Patrick Lajoie, J. Goetz, J. Dennis, I. Nabi (2009)
Lattices, rafts, and scaffolds: domain regulation of receptor signaling at the plasma membraneThe Journal of Cell Biology, 185
Longhou Fang, Soo-Ho Choi, J. Baek, Chao Liu, F. Almazan, F. Ulrich, Philipp Wiesner, A. Taleb, E. Deer, J. Pattison, J. Torres-Vázquez, Andrew Li, Yury Miller (2013)
Control of Angiogenesis by AIBP-mediated Cholesterol EffluxNature, 498
B. Rubinsky (2003)
Principles of Low Temperature Cell PreservationHeart Failure Reviews, 8
Yong Chen, L. Shao, Zahida Ali, Jiye Cai, Zheng Chen (2008)
NSOM/QD-based nanoscale immunofluorescence imaging of antigen-specific T-cell receptor responses during an in vivo clonal Vγ2Vδ2 T-cell expansion.Blood, 111 8
T. Wakatsuki, R. Wysolmerski, E. Elson (2003)
Mechanics of cell spreading: role of myosin IIJournal of Cell Science, 116
Paolo Pierobon, G. Cappello (2012)
Quantum dots to tail single bio-molecules inside living cells.Advanced drug delivery reviews, 64 2
S. Mañes, E. Mira, C. Gómez-Moutón, Rosa Lacalle, P. Keller, Juan Labrador, C. Martínez-A (1999)
Membrane raft microdomains mediate front–rear polarity in migrating cellsThe EMBO Journal, 18
Ning Wang, D. Ingber (1994)
Control of cytoskeletal mechanics by extracellular matrix, cell shape, and mechanical tension.Biophysical journal, 66 6
D. Raucher, M. Sheetz (1999)
Characteristics of a membrane reservoir buffering membrane tension.Biophysical journal, 77 4
A. Bode, C. Knupp (1994)
Effect of cold storage on platelet glycoprotein Ib and vesiculationTransfusion, 34
A. Magee, Jeremy Adler, I. Parmryd (2005)
Cold-induced coalescence of T-cell plasma membrane microdomains activates signalling pathwaysJournal of Cell Science, 118
D. Lingwood, K. Simons (2010)
Lipid Rafts As a Membrane-Organizing PrincipleScience, 327
G. Sagvolden, Ivar Giaever, Erik Pettersen, Jens Feder (1999)
Cell adhesion force microscopy.Proceedings of the National Academy of Sciences of the United States of America, 96 2
J. Kiely, Yenya Hu, G. Garcı́a-Cardeña, M. Gimbrone (2003)
Lipid Raft Localization of Cell Surface E-Selectin Is Required for Ligation-Induced Activation of Phospholipase Cγ 1The Journal of Immunology, 171
A. Shaw (2006)
Lipid rafts: now you see them, now you don'tNature Immunology, 7
S. Munro (2003)
Lipid rafts: elusive or illusive?Cell, 115 4
Xiaopin Wang, D. He, Jiye Cai, Tongsheng Chen, Feiyan Zou, Yalan Li, Yangzhe Wu, Zheng Chen, Yong Chen (2009)
WGA-QD probe-based AFM detects WGA-binding sites on cell surface and WGA-induced rigidity alternation.Biochemical and biophysical research communications, 379 2
Vera Michel, M. Bakovic (2007)
Lipid rafts in health and diseaseBiology of the Cell, 99
C. Gómez-Moutón, J. Abad, E. Mira, R. Lacalle, E. Gallardo, S. Jiménez-Baranda, I. Illa, A. Bernad, S. Mañes, C. Martínez-A (2001)
Segregation of leading-edge and uropod components into specific lipid rafts during T cell polarizationProceedings of the National Academy of Sciences of the United States of America, 98
J. Füllekrug, K. Simons (2004)
Lipid Rafts and Apical Membrane TrafficAnnals of the New York Academy of Sciences, 1014
The nonionic detergent extraction at 4 °C and the cholesterol-depletion-induced lipid raft disruption are the two widely used experimental strategies for lipid raft research. However, the effects of raft disruption and/or cold treatment on the ultrastructural and mechanical properties of cells are still unclear. Here, we evaluated the effects of raft disruption and/or cold (4 °C) treatment on these properties of living human umbilical vein endothelial cells (HUVECs). At first, the cholesterol-depletion-induced raft disruption was visualized by confocal microscopy and atomic force microscopy (AFM) in combination with fluorescent quantum dots. Next, the cold-induced cell contraction and the formation of end-branched filopodia were observed by confocal microscopy and AFM. Then, the cell-surface ultrastructures were imaged by AFM, and the data showed that raft disruption and cold treatment induced opposite effects on cell-surface roughness (a significant decrease and a significant increase, respectively). Moreover, the cell-surface mechanical properties (stiffness and adhesion force) of raft-disrupted- and/or cold-treated HUVECs were measured by the force measurement function of AFM. We found that raft disruption and cold treatment induced parallel effects on cell stiffness (increase) or adhesion force (decrease) and that the combination of the two treatments caused dramatically strengthened effects. Finally, raft disruption was found to significantly impair cell migration as previously reported, whereas temporary cold treatment only caused a slight but nonsignificant decrease in cell migration performed at physiological temperature. Although the mechanisms for causing these results might be complicated and more in-depth studies will be needed, our data may provide important information for better understanding the effects of raft disruption or cold treatment on cells and the two strategies for lipid raft research.
The Journal of Membrane Biology – Springer Journals
Published: Jan 8, 2014
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