Title: Wound closure in the lamellipodia of single cells: mediation by actin polymerization in the absence of an actomyosin purse string.

Authors: Henson, John H; Nazarian, Ronniel; Schulberg, Katrina L; Trabosh, Valerie A; Kolnik, Sarah E; Burns, Andrew R; McPartland, Kenneth J

Published In Mol Biol Cell, (2002 Mar)

Abstract: The actomyosin purse string is an evolutionarily conserved contractile structure that is involved in cytokinesis, morphogenesis, and wound healing. Recent studies suggested that an actomyosin purse string is crucial for the closure of wounds in single cells. In the present study, morphological and pharmacological methods were used to investigate the role of this structure in the closure of wounds in the peripheral cytoplasm of sea urchin coelomocytes. These discoidal shaped cells underwent a dramatic form of actin-based centripetal/retrograde flow and occasionally opened and closed spontaneous wounds in their lamellipodia. Fluorescent phalloidin staining indicated that a well defined fringe of actin filaments assembles from the margin of these holes, and drug studies with cytochalasin D and latrunculin A indicated that actin polymerization is required for wound closure. Additional evidence that actin polymerization is involved in wound closure was provided by the localization of components of the Arp2/3 complex to the wound margin. Significantly, myosin II immunolocalization demonstrated that it is not associated with wound margins despite being present in the perinuclear region. Pharmacological evidence for the lack of myosin II involvement in wound closure comes from experiments in which a microneedle was used to produce wounds in cells in which actomyosin contraction was inhibited by treatment with kinase inhibitors. Wounds produced in kinase inhibitor-treated cells closed in a manner similar to that seen with control cells. Taken together, our results suggest that an actomyosin purse string mechanism is not responsible for the closure of lamellar wounds in coelomocytes. We hypothesize that the wounds heal by means of a combination of the force produced by actin polymerization alone and centripetal flow. Interestingly, these cells did assemble an actomyosin structure around the margin of phagosome-like membrane invaginations, indicating that myosin is not simply excluded from the periphery by some general mechanism. The results indicate that the actomyosin purse string is not the only mechanism that can mediate wound closure in single cells.

PubMed ID: 11907278

MeSH Terms: Actins/metabolism*; Animals; Bicyclo Compounds, Heterocyclic/pharmacology; Cell Membrane/metabolism; Cytochalasin D/pharmacology; Enzyme Inhibitors/pharmacology; Humans; Microscopy, Video; Myosin Type II/metabolism; Nucleic Acid Synthesis Inhibitors/pharmacology; Phalloidine/metabolism; Pseudopodia/metabolism*; Sea Urchins/drug effects; Sea Urchins/metabolism; Sea Urchins/ultrastructure*; Staurosporine/pharmacology; Thiazoles/pharmacology; Thiazolidines