Actin filament organization in the fish keratocyte lamellipodium.

Small, J. Victor; Herzog, M.; Anderson, Kurt I.

doi:10.1083/jcb.129.5.1275

Cited by 222 publications

(222 citation statements)

References 46 publications

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“…When scaling the image contrast to reveal speckles at the cell front the latter two zones seemed saturated, lacking any useful information. This intensity distribution was in apparent discrepancy with the opposite gradient of F-actin density in keratocytes (Small et al, 1995;Svitkina et al, 1997). To explain this effect, it has to be noted that the speckle intensity depends not only on the actin density but also on the local concentration of phalloidin available for binding to actin polymer.…”

mentioning

confidence: 78%

Tracking Retrograde Flow in Keratocytes: News from the Front

Vallotton

Danuser

Bohnet

et al. 2005

MBoC

130

111

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Actin assembly at the leading edge of the cell is believed to drive protrusion, whereas membrane resistance and contractile forces result in retrograde flow of the assembled actin network away from the edge. Thus, cell motion and shape changes are expected to depend on the balance of actin assembly and retrograde flow. This idea, however, has been undermined by the reported absence of flow in one of the most spectacular models of cell locomotion, fish epidermal keratocytes. Here, we use enhanced phase contrast and fluorescent speckle microscopy and particle tracking to analyze the motion of the actin network in keratocyte lamellipodia. We have detected retrograde flow throughout the lamellipodium at velocities of 1-3 m/min and analyzed its organization and relation to the cell motion during both unobstructed, persistent migration and events of cell collision. Freely moving cells exhibited a graded flow velocity increasing toward the sides of the lamellipodium. In colliding cells, the velocity decreased markedly at the site of collision, with striking alteration of flow in other lamellipodium regions. Our findings support the universality of the flow phenomenon and indicate that the maintenance of keratocyte shape during locomotion depends on the regulation of both retrograde flow and actin polymerization. INTRODUCTIONThe lamellipodium of motile cells is formed of a dense network of branched actin filaments (F-actin) polymerizing in the direction of cell movement. Network assembly at the leading edge is thought to generate the forces that push the plasma membrane forward (Theriot and Mitchison, 1991;Mogilner and Oster, 1996;Carlier et al., 2003;Pollard and Borisy, 2003). In most motile cells, the network is simultaneously transported away from the leading edge in a process known as retrograde flow (Cramer, 1997). The flow may be the result of forces of membrane tension counteracting actin polymerization at the edge of the cell (Raucher and Sheetz, 2000) and/or contractile forces of myosin motors (Lin et al., 1996). The balance between forward movement of the cell and backward movement of the actin network is believed to depend on a clutch-like substrate-adhesion mechanism (Smilenov et al., 1999;Jay, 2000). When the actin network is tightly coupled to the substrate (clutch fully engaged), actin polymerization effectively pushes the plasma membrane forward, and myosin-based contraction pulls the cell body in the direction of the leading edge. Conversely, when the clutch is loose, polymerization against the membrane pushes the network backward in concert with contraction pulling the actin network away from the leading edge. Thus, a possible mechanism for the cell to control its shape and net movement is by shifting the balance between protrusion and retrograde flow, supplementing the more widespread notion of spatial variation of actin assembly being the key regulator of cell motility (Pollard et al., 2000). Indeed, several studies report a relationship between retrograde flow and cell motion: the rate of retrograde...

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mentioning

confidence: 78%

Tracking Retrograde Flow in Keratocytes: News from the Front

Vallotton

Danuser

Bohnet

et al. 2005

MBoC

130

111

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“…One proposed mechanism to explain actin cycling associated with cell crawling movements is a simple treadmill on linear (40,41) or branched (42) filament arrays in the cell periphery. Acceleration of such treadmills, however, would not explain the different actin filament length or actin filament fraction profiles in slow and fast cells.…”

Section: Discussionmentioning

confidence: 99%

Regulation of the actin cycle in vivo by actin filament severing

McGrath

Osborn²,

Tardy³

et al. 2000

Proc. Natl. Acad. Sci. U.S.A.

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Cycling of actin subunits between monomeric and filamentous phases is essential for cell crawling behavior. We investigated actin filament turnover rates, length, number, barbed end exposure, and binding of cofilin in bovine arterial endothelial cells moving at different speeds depending on their position in a confluent monolayer. Fast-translocating cells near the wound edge have short filament lifetimes compared with turnover values that proportionately increase in slower moving cells situated at increasing distances from the wound border. Contrasted with slow cells exhibiting slow actin filament turnover speeds, fast cells have less polymerized actin, shorter actin filaments, more free barbed ends, and less actin-associated cofilin. Cultured primary fibroblasts manifest identical relationships between speed and actin turnover as the endothelial cells, and fast fibroblasts expressing gelsolin have higher actin turnover rates than slow fibroblasts that lack this actin-severing protein. These results implicate actin filament severing as an important control mechanism for actin cycling in cells.cell motility ͉ actin polymerization ͉ actin severing ͉ ADF/cofilin ͉ gelsolin

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“…Blebs, that protrude at rates of ~0.4 μm.s −1 [29], are more dramatic than standard, controlled protrusive events at the leading edge of motile cells. For example, lamellipodia protrude at ~0.15 μm.s −1 in rapidly moving fish keratocytes [44], and slower in most other cell types.…”

Section: Exhibit 1: Blebbing As a Window Into Cell Hydraulicsmentioning

confidence: 99%

Implications of a poroelastic cytoplasm for the dynamics of animal cell shape

Mitchison

Charras

Mahadevan

2008

Seminars in Cell & Developmental Biology

143

113

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Two views have dominated recent discussions of the physical basis of cell shape change during migration and division of animal cells: the cytoplasm can be modeled as a viscoelastic continuum, and the forces that change its shape are generated only by actin polymerization and actomyosin contractility in the cell cortex. Here, we question both views: we suggest that the cytoplasm is better described as poroelastic, and that hydrodynamic forces may be generally important for its shape dynamics. In the poroelastic view, the cytoplasm consists of a porous, elastic solid (cytoskeleton, organelles, ribosomes) penetrated by an interstitial fluid (cytosol) that moves through the pores in response to pressure gradients. If the pore size is small (30-60nm), as has been observed in some cells, pressure does not globally equilibrate on time and length scales relevant to cell motility. Pressure differences across the plasma membrane drive blebbing, and potentially other type of protrusive motility. In the poroelastic view, these pressures can be higher in one part of a cell than another, and can thus cause local shape change. Local pressure transients could be generated by actomyosin contractility, or by local activation of osmogenic ion transporters in the plasma membrane. We propose that local activation of Na+/H+ antiporters (NHE1) at the front of migrating cells promotes local swelling there to help drive protrusive motility, acting in combination with actin polymerization. Local shrinking at the equator of dividing cells may similarly help drive invagination during cytokinesis, acting in combination with actomyosin contractility. Testing these hypotheses is not easy, as water is a difficult analyte to track, and will require a joint effort of the cytoskeleton and ion physiology communities.

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Actin filament organization in the fish keratocyte lamellipodium.

Cited by 222 publications

References 46 publications

Tracking Retrograde Flow in Keratocytes: News from the Front

Tracking Retrograde Flow in Keratocytes: News from the Front

Regulation of the actin cycle in vivo by actin filament severing

Implications of a poroelastic cytoplasm for the dynamics of animal cell shape

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