A molecular smart surface for spatio-temporal studies of cell mobility

Active migration in both healthy and malignant cells requires the integration of information derived from soluble signaling molecules with positional information gained from interactions with the extracellular matrix and with other cells. How a cell responds and moves involves complex signaling casc...

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Veröffentlicht in:	PloS one 2015-06, Vol.10 (6), p.e0118126-e0118126
Hauptverfasser:	Lee, Eun-ju, Luo, Wei, Chan, Eugene W L, Yousaf, Muhammad N
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Biology Cascades Cell adhesion Cell adhesion & migration Cell Adhesion - physiology Cell division Cell Line Cell migration Cell Movement - physiology Cell surface CHO Cells Cricetulus Cytoskeleton Cytoskeleton - metabolism Extracellular matrix Gene expression Genomes Ligands Mice Microscopy Models, Biological Molecular chains Signal transduction Signaling Substrates Surface chemistry Surface Properties Voltammetry
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creator	Lee, Eun-ju Luo, Wei Chan, Eugene W L Yousaf, Muhammad N
description	Active migration in both healthy and malignant cells requires the integration of information derived from soluble signaling molecules with positional information gained from interactions with the extracellular matrix and with other cells. How a cell responds and moves involves complex signaling cascades that guide the directional functions of the cytoskeleton as well as the synthesis and release of proteases that facilitate movement through tissues. The biochemical events of the signaling cascades occur in a spatially and temporally coordinated manner then dynamically shape the cytoskeleton in specific subcellular regions. Therefore, cell migration and invasion involve a precise but constantly changing subcellular nano-architecture. A multidisciplinary effort that combines new surface chemistry and cell biological tools is required to understand the reorganization of cytoskeleton triggered by complex signaling during migration. Here we generate a class of model substrates that modulate the dynamic environment for a variety of cell adhesion and migration experiments. In particular, we use these dynamic substrates to probe in real-time how the interplay between the population of cells, the initial pattern geometry, ligand density, ligand affinity and integrin composition affects cell migration and growth. Whole genome microarray analysis indicates that several classes of genes ranging from signal transduction to cytoskeletal reorganization are differentially regulated depending on the nature of the surface conditions.
doi_str_mv	10.1371/journal.pone.0118126
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In particular, we use these dynamic substrates to probe in real-time how the interplay between the population of cells, the initial pattern geometry, ligand density, ligand affinity and integrin composition affects cell migration and growth. 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How a cell responds and moves involves complex signaling cascades that guide the directional functions of the cytoskeleton as well as the synthesis and release of proteases that facilitate movement through tissues. The biochemical events of the signaling cascades occur in a spatially and temporally coordinated manner then dynamically shape the cytoskeleton in specific subcellular regions. Therefore, cell migration and invasion involve a precise but constantly changing subcellular nano-architecture. A multidisciplinary effort that combines new surface chemistry and cell biological tools is required to understand the reorganization of cytoskeleton triggered by complex signaling during migration. Here we generate a class of model substrates that modulate the dynamic environment for a variety of cell adhesion and migration experiments. 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subjects	Animals Biology Cascades Cell adhesion Cell adhesion & migration Cell Adhesion - physiology Cell division Cell Line Cell migration Cell Movement - physiology Cell surface CHO Cells Cricetulus Cytoskeleton Cytoskeleton - metabolism Extracellular matrix Gene expression Genomes Ligands Mice Microscopy Models, Biological Molecular chains Signal transduction Signaling Substrates Surface chemistry Surface Properties Voltammetry
title	A molecular smart surface for spatio-temporal studies of cell mobility
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