Self-organization of the phosphatidylinositol lipids signaling system for random cell migration

Arai, Yoshiyuki; Shibata, Tatsuo; Matsuoka, Satomi; Sato, Masayuki; Yanagida, Toshio; Ueda, Masahiro

doi:10.1073/pnas.0908278107

Cited by 196 publications

(289 citation statements)

References 37 publications

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“…It should be emphasized that 2D geometry is essential for understanding dynamics of the observed pattern and their transitions. In earlier models based on one-dimensional geometry (6,15,30,36), a switch of patterns such as reversion of wave propagation along the cell periphery occurs merely by stochastic noise (6). The current study suggests that such a view of pattern transition in many cases could be an oversimplification, because topological charge of the spiral core is robust and cannot simply be flipped by random noise.…”

Section: Phase-map Analysis Reveals Birth and Death Of Spatial Phasementioning

confidence: 80%

“…Because the observed wave geometries are generic (26), earlier models of PIP3/F-actin waves in Dictyostelium, whether they are abstract (19) or detailed (6,15), may also be able to capture some of the essential dynamics uncovered in this study. Future studies that include mutant analysis should allow comparison of details that delineate the existing models.…”

Section: Phase-map Analysis Reveals Birth and Death Of Spatial Phasementioning

confidence: 93%

“…To address how the observed wave patterns arise from regulation of PIP3, we studied a simplified mathematical model that describes the essence of the phosphorylation/dephosphorylation reaction of the phosphoinositides and their diffusion at the basal membrane (15,30) (Fig. S4A; see SI Text for details).…”

Section: Phase-map Analysis Reveals Birth and Death Of Spatial Phasementioning

confidence: 99%

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Phase geometries of two-dimensional excitable waves govern self-organized morphodynamics of amoeboid cells

Taniguchi¹,

Ishihara

Oonuki³

et al. 2013

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

137

182

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In both randomly moving Dictyostelium and mammalian cells, phosphatidylinositol (3,4,5)-trisphosphate and F-actin are known to propagate as waves at the membrane and act to push out the protruding edge. To date, however, the relationship between the wave geometry and the patterns of amoeboid shape change remains elusive. Here, by using phase map analysis, we show that morphology dynamics of randomly moving Dictyostelium discoideum cells can be characterized by the number, topology, and position of spatial phase singularities, i.e., points that represent organizing centers of rotating waves. A single isolated singularity near the cellular edge induced a rotational protrusion, whereas a pair of singularities supported a symmetric extension. These singularities appeared by strong phase resetting due to de novo nucleation at the back of preexisting waves. Analysis of a theoretical model indicated excitability of the system that is governed by positive feedback from phosphatidylinositol (3,4,5)-trisphosphate to PI3-kinase activation, and we showed experimentally that this requires F-actin. Furthermore, by incorporating membrane deformation into the model, we demonstrated that geometries of competing waves explain most of the observed semiperiodic changes in amoeboid morphology.reaction-diffusion | oscillations | excitable media | self-organization | PTEN

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Section: Phase-map Analysis Reveals Birth and Death Of Spatial Phasementioning

confidence: 80%

Section: Phase-map Analysis Reveals Birth and Death Of Spatial Phasementioning

confidence: 93%

Section: Phase-map Analysis Reveals Birth and Death Of Spatial Phasementioning

confidence: 99%

See 1 more Smart Citation

Phase geometries of two-dimensional excitable waves govern self-organized morphodynamics of amoeboid cells

Taniguchi¹,

Ishihara

Oonuki³

et al. 2013

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

137

182

View full text Add to dashboard Cite

show abstract

“…In contrast to the spatial distributions of cAMP/cAR1 association and G-protein activation, downstream signaling pathways are activated in an extremely biased manner at the anterior or posterior of the cell (3,4). For example, localized patches of phosphatidylinositol 3,4,5-trisphosphate (PIP 3 ) are generated at the plasma membrane by an intracellular signal transduction excitable network (STEN) and function as a cue to control the pseudopod formation of motile cells (9,10). Because PIP 3 patches have a relatively constant size of a few microns in diameter, this excitable mechanism can ensure a constant output of chemotactic responses over a wide range of concentrations.…”

mentioning

confidence: 99%

Heterotrimeric G-protein shuttling via Gip1 extends the dynamic range of eukaryotic chemotaxis

Kamimura

Miyanaga

Ueda

2016

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

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Chemotactic eukaryote cells can sense chemical gradients over a wide range of concentrations via heterotrimeric G-protein signaling; however, the underlying wide-range sensing mechanisms are only partially understood. Here we report that a novel regulator of G proteins, G protein-interacting protein 1 (Gip1), is essential for extending the chemotactic range of Dictyostelium cells. Genetic disruption of Gip1 caused severe defects in gradient sensing and directed cell migration at high but not low concentrations of chemoattractant. Also, Gip1 was found to bind and sequester G proteins in cytosolic pools. Receptor activation induced G-protein translocation to the plasma membrane from the cytosol in a Gip1-dependent manner, causing a biased redistribution of G protein on the membrane along a chemoattractant gradient. These findings suggest that Gip1 regulates G-protein shuttling between the cytosol and the membrane to ensure the availability and biased redistribution of G protein on the membrane for receptor-mediated chemotactic signaling. This mechanism offers an explanation for the wide-range sensing seen in eukaryotic chemotaxis.eukaryotic chemotaxis | gradient sensing | dynamic range extension | heterotrimeric G protein C hemotaxis in eukaryotic cells is observed in many physiological processes including embryogenesis, neuronal wiring, wound healing, and immune responses (1, 2). Chemotactic cells share basic properties including high sensitivity to shallow gradients and responsiveness to a wide dynamic range of chemoattractants (3, 4). For instance, human neutrophils and Dictyostelium cells can sense spatial differences in chemoattractant concentration across the cell body in shallow gradients as low as 2% and exhibit chemotaxis over a 10 5 -10 6 -fold range of background concentrations (5-7). Thus, wide-range sensing and adaptation are critical features of chemotaxis as well as other sensory systems such as visual signal transduction (8). However, the underlying regulatory mechanisms in eukaryotic chemotaxis remain unclear.The molecular mechanisms of chemotaxis are evolutionarily conserved among many eukaryotes that use G protein-coupled receptors (GPCRs) and heterotrimeric G proteins to detect chemoattractant gradients (3, 4). In Dictyostelium cells, extracellular cAMP works as a chemoattractant, and binding to its receptor cyclic AMP receptor 1 (cAR1) activates G proteins (Gα2Gβγ) along the concentration gradient, leading to the activation of multiple signaling cascades including the PI3K-PTEN, TorC2-PDK-PKB, phospholipase A2, and guanylyl cyclase pathways. In contrast to the spatial distributions of cAMP/cAR1 association and G-protein activation, downstream signaling pathways are activated in an extremely biased manner at the anterior or posterior of the cell (3, 4). For example, localized patches of phosphatidylinositol 3,4,5-trisphosphate (PIP 3 ) are generated at the plasma membrane by an intracellular signal transduction excitable network (STEN) and function as a cue to control the pseudopod formation of...

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“…In stimulated thin neuronal protrusions, it has been observed that slowly diffusing autocatalytic CaMKII kinases exhibit pulsatile compartmentalized activity [36]; a spatially extended bistable system can spontaneously generate subregions, where different steady states dominate [37]. Self-organized foci of activity can generate activating travelling waves [38]. Propagation of waves can give rise to long-lasting cell polarity when the fast-diffusing inhibitor accumulates proportionally to the amount of slow-diffusing activated molecules so that the wavefront can be stalled.…”

Section: State-to-state Transitions In Biological Membrane Systemsmentioning

confidence: 99%

Stochastic transitions in a bistable reaction system on the membrane

Kochańczyk

Jaruszewicz

Lipniacki

2013

J. R. Soc. Interface.

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Transitions between steady states of a multi-stable stochastic system in the perfectly mixed chemical reactor are possible only because of stochastic switching. In realistic cellular conditions, where diffusion is limited, transitions between steady states can also follow from the propagation of travelling waves. Here, we study the interplay between the two modes of transition for a prototype bistable system of kinase-phosphatase interactions on the plasma membrane. Within microscopic kinetic Monte Carlo simulations on the hexagonal lattice, we observed that for finite diffusion the behaviour of the spatially extended system differs qualitatively from the behaviour of the same system in the well-mixed regime. Even when a small isolated subcompartment remains mostly inactive, the chemical travelling wave may propagate, leading to the activation of a larger compartment. The activating wave can be induced after a small subdomain is activated as a result of a stochastic fluctuation. Such a spontaneous onset of activity is radically more probable in subdomains characterized by slower diffusion. Our results show that a local immobilization of substrates can lead to the global activation of membrane proteins by the mechanism that involves stochastic fluctuations followed by the propagation of a semi-deterministic travelling wave.

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Self-organization of the phosphatidylinositol lipids signaling system for random cell migration

Cited by 196 publications

References 37 publications

Phase geometries of two-dimensional excitable waves govern self-organized morphodynamics of amoeboid cells

Phase geometries of two-dimensional excitable waves govern self-organized morphodynamics of amoeboid cells

Heterotrimeric G-protein shuttling via Gip1 extends the dynamic range of eukaryotic chemotaxis

Stochastic transitions in a bistable reaction system on the membrane

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