1. New View on Endothelial Cell Migration: Switching Modes of Migration Based on Matrix Composition
- Author
-
Angelika M. Vollmar, Kerstin Kick, Katharina Nekolla, Stefan Zahler, and Markus Rehberg
- Subjects
0301 basic medicine ,rac1 GTP-Binding Protein ,Time Factors ,Angiogenesis ,Green Fluorescent Proteins ,RAC1 ,Mice, Transgenic ,CDC42 ,Retinal Neovascularization ,Transfection ,Time-Lapse Imaging ,Collagen Type I ,03 medical and health sciences ,0302 clinical medicine ,Laminin ,Live cell imaging ,Elastic Modulus ,Human Umbilical Vein Endothelial Cells ,Animals ,Humans ,cdc42 GTP-Binding Protein ,Cell Shape ,Cells, Cultured ,Matrigel ,Microscopy, Video ,biology ,Chemotaxis ,Retinal Vessels ,Cell migration ,Hydrogels ,Cell biology ,Extracellular Matrix ,Endothelial stem cell ,Drug Combinations ,030104 developmental biology ,Phenotype ,Cellular Microenvironment ,Immunology ,Proteolysis ,biology.protein ,Proteoglycans ,Collagen ,Cardiology and Cardiovascular Medicine ,030217 neurology & neurosurgery ,Protein Binding ,Signal Transduction - Abstract
Objective— Cell–matrix interactions are crucial for regulating cellular activities, such as migration. This is of special importance for morphogenic processes, such as angiogenesis (the development of new blood vessels). Most of our understanding of cell migration relies on 2-dimensional (2D) experiments. However, the awareness that 3D settings might elicit different results has increased. Knowledge about endothelial cell (EC) behavior in 3D environments and the influence of matrix composition on EC migration, in particular, is still limited. Approach and Results— We characterize the migration of single ECs through 2 structurally different hydrogels: spongy Matrigel and fibrillar collagen I. Our observations reveal an elongated migration phenotype in Matrigel and a rounded phenotype with pronounced cell blebs (blebs >2 µm) in collagen I, which have not previously been described in ECs. Directed migration seems to depend on Rac1 and Cdc42 in collagen, but not in Matrigel (shown using appropriate pharmacological inhibitors). By applying anti-integrin antibodies and supplementing laminin in collagen gels, we identify laminin as the main determinant of the elongated phenotype. Laminin seems to induce a morphological switch between modes of migration. As an in situ proof of principle, we performed live imaging of EC migration during vascular growth in a murine retina in the absence and presence of anti-integrin antibodies. Conclusions— We show that, surprisingly, ECs can evade the pharmacological inhibition of central signaling pathways involved in migration (contractility, small GTPases, and proteolysis) by shifting gears between modes of migration. This finding indicates an unexpected contextual plasticity of EC behavior.
- Published
- 2015