Abstract
The mechanism by which epithelial, endothelial and other strongly cell-cell adhesive cells migrate collectively as continuous sheets is not clear, even though this process is crucial for embryonic development and tissue repair in virtually all multicellular animals. Wound closure in Madin-Darby canine kidney (MDCK) epithelial cell monolayers involves Rac GTPase-dependent migration of cells both at and behind the wound edge. We report here for the first time that cells behind the margin of wounded MDCK cell monolayers, even hundreds of microns from the edge, extend 'cryptic' lamellipodia against the substratum beneath cells in front of them, toward the wound, as determined by confocal, two-photon and transmission electron microscopy. These so-called submarginal cells nevertheless strictly maintain their more apical cell-cell contacts when they migrate as part of a coherent cell sheet, hiding their basal protrusions from conventional microscopy. The submarginal protrusions display the hallmarks of traditional lamellipodia based on morphology and dynamics. Cells behind the margin therefore actively crawl, instead of just moving passively when cells at the margin pull on them. The rate of migration is inversely proportional to the distance from the margin, and cells move co-ordinately, yet still in part autonomously, toward the wound area. We also clarify the ancillary role played by nonprotrusive contractile actin bundles that assemble in a Rho GTPase-dependent manner at the margin after wounding. In addition, some cell proliferation occurs at a delay after wounding but does not contribute to closure. Instead, it apparently serves to replace damaged cells so that intact spread cells can revert to their normal cuboidal morphology and the original cell density of the unbroken sheet can be restored.
Highlights
The migration of cells as continuous sheets is much less studied but no less important a phenomenon than the migration of cells as single free entities
We sought other means to discover whether submarginal cells extend any hidden lamellipodia
We found that lamellipodia clearly protrude from submarginal cells in the direction of movement toward the wound (Fig. 1A,B)
Summary
The migration of cells as continuous sheets is much less studied but no less important a phenomenon than the migration of cells as single free entities. In contrast to other epithelial cell systems that strictly maintain cell-cell contacts during sheet migration without any discontinuity in the monolayer observed at any time, small gaps appear to briefly open up between cells in the migrating Xenopus epidermis (Radice, 1980b). This allows so-called submarginal cells behind the leading edge of the advancing sheet to extend protrusions into the area temporarily vacated by the retracting trailing edges of cells in front of them, with the stimulus for submarginal protrusion possibly being the transient availability of an unoccupied substratum for spreading of submarginal cells. In the mouse corneal epithelium, which is composed of two to three cell layers behind the margin of an introduced wound, submarginal cells have – in cross section – a tapered profile that may reflect lamellipodial protrusion
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