Biased excitable networks: how cells direct motion in response to gradients.
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Mesenchymal chemotaxis requires selective inactivation of myosin II at the leading edge via a noncanonical PLCγ/PKCα pathway.Chemotaxis of Dictyostelium discoideum: collective oscillation of cellular contactsGeometry-Driven Polarity in Motile Amoeboid CellsInteraction of motility, directional sensing, and polarity modules recreates the behaviors of chemotaxing cellsOscillatory behavior of neutrophils under opposing chemoattractant gradients supports a winner-take-all mechanismLinking morphodynamics and directional persistence of T lymphocyte migrationMathematical modeling of eukaryotic cell migration: insights beyond experimentsSignaling networks that regulate cell migrationOptical control demonstrates switch-like PIP3 dynamics underlying the initiation of immune cell migration.An excitable signal integrator couples to an idling cytoskeletal oscillator to drive cell migration.Group choreography: mechanisms orchestrating the collective movement of border cellsMechanical feedback through E-cadherin promotes direction sensing during collective cell migration.The directional response of chemotactic cells depends on a balance between cytoskeletal architecture and the external gradient.F-actin bundles direct the initiation and orientation of lamellipodia through adhesion-based signaling.Analytical Prediction of the Spatiotemporal Distribution of Chemoattractants around Their Source: Theory and Application to Complement-Mediated Chemotaxis.Evolutionarily conserved coupling of adaptive and excitable networks mediates eukaryotic chemotaxis.Subcellular optogenetics - controlling signaling and single-cell behavior.Formation of transient lamellipodia.Regimes of wave type patterning driven by refractory actin feedback: transition from static polarization to dynamic wave behaviour.Dendritic spine geometry can localize GTPase signaling in neurons.Excitable behavior in amoeboid chemotaxis.The structure of dynamic GPCR signaling networks.Locally excitable Cdc42 signals steer cells during chemotaxis.Feedback regulation between plasma membrane tension and membrane-bending proteins organizes cell polarity during leading edge formation.Materials learning from life: concepts for active, adaptive and autonomous molecular systems.How to understand and outwit adaptationA model for intracellular actin waves explored by nonlinear local perturbation analysis.Effects of 3D geometries on cellular gradient sensing and polarizationExtracellular matrix stiffness and cell contractility control RNA localization to promote cell migration.A dual role model for active Rac1 in cell migration.From intracellular signaling to population oscillations: bridging size- and time-scales in collective behavior.Modeling Excitable Dynamics of Chemotactic Networks.Illuminating the Cell's Biochemical Activity Architecture.Direction of leukocyte polarization and migration by the phosphoinositide-transfer protein TIPE2.An excitable Rho GTPase signaling network generates dynamic subcellular contraction patterns.Follicular T-helper cell recruitment governed by bystander B cells and ICOS-driven motility.Actomyosin regulation and symmetry breaking in a model of polarization in the early Caenorhabditis elegans embryo : symmetry breaking in cell polarization.Rhythmicity and waves in the cortex of single cells.A RAB35-p85/PI3K axis controls oscillatory apical protrusions required for efficient chemotactic migration.Mechanisms of Cell Polarization.
P2860
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P2860
Biased excitable networks: how cells direct motion in response to gradients.
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年論文
@yue
2011年論文
@zh-hant
2011年論文
@zh-hk
2011年論文
@zh-mo
2011年論文
@zh-tw
2011年论文
@wuu
2011年论文
@zh
2011年论文
@zh-cn
name
Biased excitable networks: how cells direct motion in response to gradients.
@ast
Biased excitable networks: how cells direct motion in response to gradients.
@en
type
label
Biased excitable networks: how cells direct motion in response to gradients.
@ast
Biased excitable networks: how cells direct motion in response to gradients.
@en
prefLabel
Biased excitable networks: how cells direct motion in response to gradients.
@ast
Biased excitable networks: how cells direct motion in response to gradients.
@en
P2860
P1476
Biased excitable networks: how cells direct motion in response to gradients
@en
P2093
Peter N Devreotes
P2860
P304
P356
10.1016/J.CEB.2011.11.009
P577
2011-12-10T00:00:00Z