Cross-linking of actin filaments by myosin II is a major contributor to cortical integrity and cell motility in restrictive environments

doi:10.1242/jcs.00684

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JCS ePress online publication date 30 Jul 2003
doi: 10.1242/jcs.00684

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Research Article

Cross-linking of actin filaments by myosin II is a major contributor to cortical integrity and cell motility in restrictive environments

Gary Laevsky and David A. Knecht^*
^* Author for correspondence (e-mail: Knecht{at}UCONN.edu)

Cells are frequently required to move in a local environmentthat physically restricts locomotion, such as during extravasationor metastatic invasion. In order to model these events, we havedeveloped an assay in which vegetative Dictyostelium amoebaeundergo chemotaxis under a layer of agarose toward a sourceof folic acid [Laevsky, G. and Knecht, D. A. (2001). Biotechniques31, 1140-1149]. As the concentration of agarose is increasedfrom 0.5% to 3% the cells are increasingly inhibited in theirability to move under the agarose. The contribution of myosinII and actin cross-linking proteins to the movement of cellsin this restrictive environment has now been examined. Cellslacking myosin II heavy chain (mhcA^-) are unable to migrateunder agarose overlays of greater than 0.5%, and even at thisconcentration they move only a short distance from the trough.While attempting to move, the cells become stretched and fragmenteddue to their inability to retract their uropods. At higher agaroseconcentrations, the mhcA^- cells protrude pseudopods under theagarose, but are unable to pull the cell body underneath. Consistentwith a role for myosin II in general cortical stability, GFP-myosindynamically localizes to the lateral and posterior cortex ofcells moving under agarose. Cells lacking the essential lightchain of myosin II (mlcE^-), have no measurable myosin II motoractivity, yet were able to move normally under all agarose concentrations.Mutants lacking either ABP-120 or ${alpha}$ -actinin were also able tomove under agarose at rates similar to wild-type cells. We hypothesizethat myosin stabilizes the actin cortex through its cross-linkingactivity rather than its motor function and this activity isnecessary and sufficient for the maintenance of cortical integrityof cells undergoing movement in a restrictive environment. Theactin cross-linkers ${alpha}$ -actinin and ABP-120 do not appear to playas major a role as myosin II in providing this cortical integrity.

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