Real-time two- and three-dimensional imaging of monocyte motility and navigation on planar surfaces and in collagen matrices: roles of Rho

We recently found that macrophages from RhoA/RhoB double knockout mice had increased motility of the cell body, but severely impaired retraction of the tail and membrane extensions, whereas RhoA- or RhoB-deficient cells exhibited mild phenotypes. Here we extended this work and investigated the roles...

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Bibliographic Details
Published in:Scientific reports 2016-04, Vol.6 (1), p.25016-25016, Article 25016
Main Authors: Bzymek, Robert, Horsthemke, Markus, Isfort, Katrin, Mohr, Simon, Tjaden, Kerstin, Müller-Tidow, Carsten, Thomann, Marlies, Schwerdtle, Tanja, Bähler, Martin, Schwab, Albrecht, Hanley, Peter J.
Format: Article
Language:English
Subjects:
631/250/2503
631/80/84/1372
96
Cell body
Cell migration
Cell Movement
Cells, Cultured
Chemotaxis
Collagen
Collagen (type I)
Confined spaces
Confocal microscopy
Fluorescence microscopy
Humanities and Social Sciences
Humans
Imaging, Three-Dimensional
Macrophages
Microscopes
Microscopy
Microscopy, Fluorescence
Monocytes
Monocytes - physiology
Motility
multidisciplinary
Myosin
rho GTP-Binding Proteins - antagonists & inhibitors
rho GTP-Binding Proteins - metabolism
RhoA protein
Science
Time-Lapse Imaging
Topology
Velocity
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Summary:We recently found that macrophages from RhoA/RhoB double knockout mice had increased motility of the cell body, but severely impaired retraction of the tail and membrane extensions, whereas RhoA- or RhoB-deficient cells exhibited mild phenotypes. Here we extended this work and investigated the roles of Rho signaling in primary human blood monocytes migrating in chemotactic gradients and in various settings. Monocyte velocity, but not chemotactic navigation, was modestly dependent on Rho-ROCK-myosin II signaling on a 2D substrate or in a loose collagen type I matrix. Viewed by time-lapse epi-fluorescence microscopy, monocytes appeared to flutter rather than crawl, such that the 3D surface topology of individual cells was difficult to predict. Spinning disk confocal microscopy and 3D reconstruction revealed that cells move on planar surfaces and in a loose collagen matrix using prominent, curved planar protrusions, which are rapidly remodeled and reoriented, as well as resorbed. In a dense collagen type I matrix, there is insufficient space for this mode and cells adopt a highly Rho-dependent, lobular mode of motility. Thus, in addition to its role in tail retraction on 2D surfaces, Rho is critical for movement in confined spaces, but is largely redundant for motility and chemotaxis in loose matrices.
ISSN:2045-2322
2045-2322
DOI:10.1038/srep25016