How blebs and pseudopods cooperate during chemotaxis

Tyson, Richard A.; Zatulovskiy, Evgeny; Kay, Robert R.; Bretschneider, Till

doi:10.1073/pnas.1322291111

Cited by 79 publications

(128 citation statements)

References 34 publications

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“…The same mechanism could also explain the experimental observation that blebs are nucleated preferentially in regions of negative membrane curvature [43]. Changes in osmotic pressure gradients could also contribute to the process, as suggested previously [13,20,44], but are not explicitly included in our model.…”

Section: Experimentsupporting

confidence: 59%

Volume Changes During Active Shape Fluctuations in Cells

et al. 2015

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Cells modify their volume in response to changes in osmotic pressure but it is usually assumed that other active shape variations do not involve significant volume fluctuations. Here we report experiments demonstrating that water transport in and out of the cell is needed for the formation of blebs, commonly observed protrusions in the plasma membrane driven by cortex contraction. We develop and simulate a model of fluid mediated membrane-cortex deformations and show that a permeable membrane is necessary for bleb formation which is otherwise impaired. Taken together our experimental and theoretical results emphasize the subtle balance between hydrodynamics and elasticity in actively driven cell morphological changes.Cells can change their shape to explore their environment, communicate with other cells and self-propel. These macroscopic changes are driven by the coordinated action of localized motors transforming chemical energy into motion. Active processes in biological systems can be linked to a large variety of collective non-equilibrium phenomena such as phase-transitions, unconventional fluctuations, oscillations and pattern formation [1][2][3]. A vivid example of actively driven non-equilibrium shape fluctuations is provided by cellular blebs, the rounded membrane protrusions formed by the separation of the plasma membrane from the cortex as a result of acto-myosin contraction [4][5][6].Blebs occur in various physiological conditions [5,6], as for instance during zebrafish embryogenesis [7][8][9][10][11], or cancer invasion [5]. While some questions concerning the mechanisms governing bleb formation and its relation to migration have been resolved [4][5][6][7][12][13][14], key aspects of bleb mechanics remain unclear. Geometrical constraints dictate that active shape changes associated with blebs should necessarily involve either fluctuations in the membrane surface or in cellular volume, and possibly both. It is generally believed, however, that the cellular volume is not significantly altered during bleb formation, so that the cell is usually considered incompressible [8,12,14]. Yet, experimental evidence in vitro suggests that aquaporins (AQPs), a family of transmembrane water channel proteins [15], are involved in cell migration [16][17][18] and blebbing [19,20]. The implied significance of fluid transport through the membrane suggests that an interplay between hydrodynamic flow and active mechanics has an important but still unclear role in blebbing. In this letter, we reveal the role of the membrane permeability in the formation, expansion and retraction of cellular blebs. We show by direct experiments in vivo and numerical simulations that bleb formation involves volume fluctuations, considerable water flow through the membrane, and relatively smaller surface fluctuations. Experiment:One of the limitations impeding the experimental studies of the bleb dynamics is the lack of proper tools to generate high-resolution spatial-temporal data of bleb dynamics. This is due to the fact that the time scale...

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Section: Experimentsupporting

confidence: 59%

Volume Changes During Active Shape Fluctuations in Cells

et al. 2015

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“…Beside cortical tension [26,34], loss of cellular adhesion has been discussed as a potential reason for membrane blebbing [31]. Moreover, the impact of membrane curvature has been shown to influence bleb formation in dictyostelium [35]. All these mentioned parameters could potentially play a role in the experiments of this study, as a reduced spreading area on 1D tracks was observed (Fig.…”

Section: Discussionmentioning

confidence: 75%

Contractility as a global regulator of cellular morphology, velocity, and directionality in low-adhesive fibrillary micro-environments

et al. 2016

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“…Similarly, actively migrating PGCs exhibit membrane blebbing in Drosophila melanogaster embryos (2). Dictyostelium use membrane blebbing during chemotaxis (3,4). Thus, membrane blebbing is widely used as a driving force of motility across species (4,5).…”

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confidence: 99%

“…Dictyostelium use membrane blebbing during chemotaxis (3,4). Thus, membrane blebbing is widely used as a driving force of motility across species (4,5). In addition, cancer cells use a membrane blebbing-associated mode of motility in metastasis (6).…”

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confidence: 99%

A RhoA and Rnd3 cycle regulates actin reassembly during membrane blebbing

Aoki

Maeda

Nagasako

et al. 2016

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

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The actin cytoskeleton usually lies beneath the plasma membrane. When the membrane-associated actin cytoskeleton is transiently disrupted or the intracellular pressure is increased, the plasma membrane detaches from the cortex and protrudes. Such protruded membrane regions are called blebs. However, the molecular mechanisms underlying membrane blebbing are poorly understood. This study revealed that epidermal growth factor receptor kinase substrate 8 (Eps8) and ezrin are important regulators of rapid actin reassembly for the initiation and retraction of protruded blebs. Livecell imaging of membrane blebbing revealed that local reassembly of actin filaments occurred at Eps8-and activated ezrin-positive foci of membrane blebs. Furthermore, we found that a RhoA-ROCKRnd3 feedback loop determined the local reassembly sites of the actin cortex during membrane blebbing.membrane bleb | Rnd3 | Eps8 | actin cortex | cell migration

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How blebs and pseudopods cooperate during chemotaxis

Cited by 79 publications

References 34 publications

Volume Changes During Active Shape Fluctuations in Cells

Volume Changes During Active Shape Fluctuations in Cells

Contractility as a global regulator of cellular morphology, velocity, and directionality in low-adhesive fibrillary micro-environments

A RhoA and Rnd3 cycle regulates actin reassembly during membrane blebbing

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