Actin dynamics at the leading edge: from simple machinery to complex networks.
about
A novel GRK2/HDAC6 interaction modulates cell spreading and motilityDifferential remodeling of actin cytoskeleton architecture by profilin isoforms leads to distinct effects on cell migration and invasionThe RNA binding protein Larp1 regulates cell division, apoptosis and cell migrationInhibitory signalling to the Arp2/3 complex steers cell migrationPhosphoinositide signaling regulates the exocyst complex and polarized integrin trafficking in directionally migrating cellsBlurred line between chemotactic chase and phagocytic consumption: an immunophysical single-cell perspective.The melanocyte lineage in development and diseaseGeneration of membrane structures during phagocytosis and chemotaxis of macrophages: role and regulation of the actin cytoskeletonThe regulatory role of serum response factor pathway in neutrophil inflammatory responseRho GTPases as pathogen targets: Focus on curable sexually transmitted infectionsActin polymerization controls the organization of WASH domains at the surface of endosomesLamellipodin promotes invasive 3D cancer cell migration via regulated interactions with Ena/VASP and SCAR/WAVE.The human fungal pathogen Cryptococcus neoformans escapes macrophages by a phagosome emptying mechanism that is inhibited by Arp2/3 complex-mediated actin polymerisationRegulation of the actin cytoskeleton by the Ndel1-Tara complex is critical for cell migration.Cortactin phosphorylated by ERK1/2 localizes to sites of dynamic actin regulation and is required for carcinoma lamellipodia persistencePseudopod growth and evolution during cell movement is controlled through SCAR/WAVE dephosphorylation.Extracellular Acidification Acts as a Key Modulator of Neutrophil Apoptosis and FunctionsChemotaxis: a feedback-based computational model robustly predicts multiple aspects of real cell behaviourControl of directed cell migration in vivo by membrane-to-cortex attachmentNeogenin recruitment of the WAVE regulatory complex maintains adherens junction stability and tension.A translocated effector required for Bartonella dissemination from derma to blood safeguards migratory host cells from damage by co-translocated effectorsDynamic modeling of cell migration and spreading behaviors on fibronectin coated planar substrates and micropatterned geometriesERK reinforces actin polymerization to power persistent edge protrusion during motility.Loss of myoferlin redirects breast cancer cell motility towards collective migrationReactive oxygen species regulate protrusion efficiency by controlling actin dynamicsMicrotubules as platforms for assaying actin polymerization in vivoMaturation of filopodia shaft adhesions is upregulated by local cycles of lamellipodia advancements and retractionsThe p38/MK2/Hsp25 pathway is required for BMP-2-induced cell migrationHigh-Resolution X-Ray Structure of the Trimeric Scar/WAVE-Complex Precursor Brk1Mechanism of IRSp53 inhibition and combinatorial activation by Cdc42 and downstream effectorsThe cytoskeleton and neurite initiationRole of the WASP and WAVE family proteins in breast cancer invasion and metastasisArp2/3- and cofilin-coordinated actin dynamics is required for insulin-mediated GLUT4 translocation to the surface of muscle cellsSpatial regulation of RhoC activity defines protrusion formation in migrating cellsSingle-Cell Migration in Complex Microenvironments: Mechanics and Signaling DynamicsThe novel RacE-binding protein GflB sharpens Ras activity at the leading edge of migrating cellsCurvature recognition and force generation in phagocytosis.Signaling networks that regulate cell migrationA FAK-Cas-Rac-lamellipodin signaling module transduces extracellular matrix stiffness into mechanosensitive cell cycling.Adhesion dynamics at a glance.
P2860
Q24300454-E0CC72A4-8D17-4308-8B54-54BA74D48369Q24303907-8D5AF247-2B5C-44B6-94FA-AEF22D560F4CQ24308702-6712AAE1-9453-4C31-9688-3060C0177196Q24338480-32902E0B-580A-4CCA-A789-C90886785D42Q24602665-971A2ABA-1ACF-4CE9-ACBF-19DE683D021AQ26827182-9CDE0262-CA9C-4482-AFD0-EAEF88B3DED9Q26853648-1DD3FE51-9E18-4097-95A6-B5CDCF0F4897Q26865586-B1557196-63C6-44C5-AD69-F52D3232E817Q26998761-794FD499-9306-4247-9C59-A1B34245C9E0Q27000265-8058507D-EEF2-48EA-BCF0-766AF958D618Q27300446-307203DD-91B9-4B95-97E0-2715788C6D24Q27309896-D955831F-9E91-4255-904F-B7236FC7E01EQ27313893-A8F1224E-F6D6-4843-921D-EC22CBB5AF3BQ27316337-D1F0B9C4-897F-47C2-B647-8BEC3E606863Q27316921-5D26E30F-B41C-4D35-8A7B-F28335740EC0Q27317034-EA93C415-57DF-41F9-8AA0-D505A33E430AQ27319901-9784E7E7-92C5-431F-A8FA-12FC1BD481DDQ27321808-A0761EB1-A033-4F1E-A050-43E826D9E3ECQ27322747-132DDB19-7D50-4F49-8CC6-5389936AEE39Q27322921-0A7887EF-D58A-4EA6-9E87-EFE358BE3F01Q27325159-6D9AC625-A40F-4C08-A396-0BE4E0EEFC50Q27325533-D9A9339A-D6D9-4664-8366-A3EDDB27508BQ27329741-A080ED45-35D8-415E-B318-07F553CF1538Q27331969-42654A34-434D-4881-992C-AE7365DE999DQ27332266-E11D753E-6F16-41D6-B10D-5C3F0BD8FF9BQ27340240-9B338451-02B7-4944-A1F3-AA91AE0354DFQ27348613-AFFB10A1-94A3-4135-B801-419E44090EA9Q27437628-C8C15E0D-0ADB-4A60-AFCA-4BD6D7349FF9Q27670540-24EBFDD5-204D-4279-8BD7-C1AE46899C54Q27681941-9F472E5D-42F9-4F99-9EEA-F01225420C24Q27687036-0C7773AF-B5DC-4504-B687-8A3FF90DFCF6Q28082304-DF120330-AE4B-48A6-BBAF-CEBCB740E1CDQ28575827-CAFF1D44-C595-4558-A9D2-0A9DE4E68ED3Q28771327-F9A6F19F-1ED8-408A-99F4-0E7F574BF1E1Q28834278-F1D3FBC7-8F36-4B6C-A7CB-E2C618E07108Q28834346-307CA4C3-1DC1-4AAD-9CF9-AEA093A990D0Q30155912-7903E7FE-B431-4A08-B9A1-E55C66868BFCQ30278918-A4403BB3-E888-4A1E-B257-F14EB490BF2AQ30407809-F5D665CE-0294-405F-B784-F48DB7C80E6DQ30423679-7D57513E-A6B9-4BD9-A75A-6849D0D9BEE9
P2860
Actin dynamics at the leading edge: from simple machinery to complex networks.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on September 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Actin dynamics at the leading edge: from simple machinery to complex networks.
@en
Actin dynamics at the leading edge: from simple machinery to complex networks.
@nl
type
label
Actin dynamics at the leading edge: from simple machinery to complex networks.
@en
Actin dynamics at the leading edge: from simple machinery to complex networks.
@nl
prefLabel
Actin dynamics at the leading edge: from simple machinery to complex networks.
@en
Actin dynamics at the leading edge: from simple machinery to complex networks.
@nl
P1433
P1476
Actin dynamics at the leading edge: from simple machinery to complex networks
@en
P2093
Laura M Machesky
P304
P356
10.1016/J.DEVCEL.2009.08.012
P407
P577
2009-09-01T00:00:00Z