4.8 Article

Collective cell migration during optic cup formation features changing cell-matrix interactions linked to matrix topology

Journal

CURRENT BIOLOGY
Volume 32, Issue 22, Pages 4817-+

Publisher

CELL PRESS
DOI: 10.1016/j.cub.2022.09.034

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Cell migration is crucial for organismal development, but the influence of physical properties on migration phenomena in vivo remains unclear. In this study, the researchers used zebrafish optic cup formation to investigate the role of extracellular matrix (ECM) properties in cell migration. They found that rim cells migrate over an immobile ECM and require cryptic lamellipodia for movement. The topology of the ECM changes along the migration path and is accompanied by changes in cell-matrix interactions. Matrix porosity is linked to efficient migration.
Cell migration is crucial for organismal development and shapes organisms in health and disease. Although a lot of research has revealed the role of intracellular components and extracellular signaling in driving single and collective cell migration, the influence of physical properties of the tissue and the environment on migration phenomena in vivo remains less explored. In particular, the role of the extracellular matrix (ECM), which many cells move upon, is currently unclear. To overcome this gap, we use zebrafish optic cup formation, and by combining novel transgenic lines and image analysis pipelines, we study how ECM properties influence cell migration in vivo. We show that collectively migrating rim cells actively move over an immobile extracellular matrix. These cell movements require cryptic lamellipodia that are extended in the direction of migration. Quantitative analysis of matrix properties revealed that the topology of the matrix changes along the migration path. These changes in matrix topologies are accompanied by changes in the dynamics of cell-matrix interactions. Experiments and theoretical modeling suggest that matrix porosity could be linked to efficient migration. Indeed, interfering with matrix topology by increasing its porosity results in a loss of cryptic lamellipodia, less-directed cell-matrix interactions, and overall inefficient migration. Thus, matrix topology is linked to the dynamics of cell-matrix interactions and the efficiency of directed collective rim cell migration during vertebrate optic cup morphogenesis.

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