Feedback signaling controls leading-edge formation during chemotaxis.
about
EphA2 mediates ligand-dependent inhibition and ligand-independent promotion of cell migration and invasion via a reciprocal regulatory loop with AktNumb links extracellular cues to intracellular polarity machinery to promote chemotaxisBlurred line between chemotactic chase and phagocytic consumption: an immunophysical single-cell perspective.Distinct predictive performance of Rac1 and Cdc42 in cell migrationAn excitable cortex and memory model successfully predicts new pseudopod dynamicsNovel protein Callipygian defines the back of migrating cells.Activated membrane patches guide chemotactic cell motilityPtenb mediates gastrulation cell movements via Cdc42/AKT1 in zebrafishPositive feedback between Cdc42 activity and H+ efflux by the Na-H exchanger NHE1 for polarity of migrating cellsProtein kinase Czeta and glycogen synthase kinase-3beta control neuronal polarity in developing rodent enteric neurons, whereas SMAD specific E3 ubiquitin protein ligase 1 promotes neurite growth but does not influence polarityBacterial motility complexes require the actin-like protein, MreB and the Ras homologue, MglARandom versus directionally persistent cell migrationSignaling pathways in cell polarity.Widely conserved signaling pathways in the establishment of cell polarityCa2+ influx is an essential component of the positive-feedback loop that maintains leading-edge structure and activity in macrophages.Locally controlled inhibitory mechanisms are involved in eukaryotic GPCR-mediated chemosensing.RACK1 regulates directional cell migration by acting on G betagamma at the interface with its effectors PLC beta and PI3K gamma.Rapid turnover rate of phosphoinositides at the front of migrating MDCK cells.Dynamic localization of G proteins in Dictyostelium discoideum.Phosphatidylinositol 3-kinase facilitates microtubule-dependent membrane transport for neuronal growth cone guidanceDisruption of PKB signaling restores polarity to cells lacking tumor suppressor PTEN.Mechanical feedback through E-cadherin promotes direction sensing during collective cell migration.Activation of the WAVE complex by coincident signals controls actin assembly.Direct detection of guidance receptor activity during border cell migration.Involvement of the cytoskeleton in controlling leading-edge function during chemotaxis.Different modes of state transitions determine pattern in the Phosphatidylinositide-Actin system.A3 and P2Y2 receptors control the recruitment of neutrophils to the lungs in a mouse model of sepsisPurinergic regulation of neutrophil chemotaxis.The ins and outs of hematopoietic stem cells: studies to improve transplantation outcomes.Hyaluronic acid and thrombin upregulate MT1-MMP through PI3K and Rac-1 signaling and prime the homing-related responses of cord blood hematopoietic stem/progenitor cellsSHP2 phosphatase promotes mast cell chemotaxis toward stem cell factor via enhancing activation of the Lyn/Vav/Rac signaling axisMacrophage Migration and Its Regulation by CSF-1Negative feedback regulation of Rac in leukocytes from mice expressing a constitutively active phosphatidylinositol 3-kinase gamma.A Model for Direction Sensing in Dictyostelium discoideum: Ras Activity and Symmetry Breaking Driven by a Gβγ-Mediated, Gα2-Ric8 -- Dependent Signal Transduction Network.PIP3 waves and PTEN dynamics in the emergence of cell polarity.Cooperation of polarized cell intercalations drives convergence and extension of presomitic mesoderm during zebrafish gastrulationType I phosphatidylinositol 4-phosphate 5-kinase controls neutrophil polarity and directional movement.Linking Ras to myosin function: RasGEF Q, a Dictyostelium exchange factor for RasB, affects myosin II functions.Big roles for small GTPases in the control of directed cell movement.Regulation of PI3K by PKC and MARCKS: Single-Molecule Analysis of a Reconstituted Signaling Pathway
P2860
Q24310260-ECA183B2-347F-4D54-919D-AB987B8016E6Q24630294-AFE44FB7-595E-41C2-B3DA-38043E8C6729Q26827182-359BD53A-6584-4DBB-A27D-D9D18A23D612Q27304686-B6C27EEA-08B4-4310-9CFF-B1FD4B6C367CQ27306786-71C18187-0CFE-4FE8-886E-4474735491FEQ27321606-AC987F5C-AD41-4C24-A342-011EBF5C3B8CQ27333557-B373AAEB-01F7-4701-A3AC-ADA095993491Q27347612-9CFC63EC-CF6D-4022-9B79-4EB625D5FF37Q28256311-7BACEC8D-ABE3-4947-83CC-E0BF63A80B90Q28574398-A8F0F60A-0E80-48E0-8263-6EE76C2086E8Q28748834-5272D95B-1D26-4CC3-93D3-42E738652F7AQ29616686-0D6E9C7A-29AB-4AEB-B33E-BFFEC7667E97Q30412739-144C8095-C3EC-4EB3-9CDD-A04DD1AA5264Q30437961-75CE53B1-88FE-45AF-B793-80A1C0A96F45Q30480286-20EB5369-F5C8-4BC9-A65A-BD87F91C14DFQ30480509-1E05B118-B77C-4A9E-A833-F0838BFB2630Q30483264-3624F01B-A2A9-447B-8D55-97882F8C42FBQ30483788-BBB9A082-32B7-4A35-AEFC-691AAFEC6B90Q30495655-00991B85-B46F-4A12-9B89-9330A581FACEQ30497753-ED604C43-2160-4DB4-9D17-FD29E96B6416Q30498163-0395D5BF-1C0F-4D6B-8D4C-431D79E37525Q30585627-B710BF8B-6A14-4A7D-AC95-3643A52FF98FQ33638097-99934811-EF8E-4A14-AF78-2CDC83001722Q33842225-B594411F-6A83-46B2-84EA-5937BDB00E9EQ33881658-C0ACA1A4-EAAC-4C0F-BE8F-4BCA8FCD36A3Q34044088-5D99AF19-1A80-4C16-A625-8976A001F896Q34418996-96D852E4-49B0-48B9-9815-B7313F7F1F23Q34425713-54174BAA-4B6F-468A-8E72-EBC190C8F28CQ35041174-7CD06F2E-49DF-4B91-96D5-DF720ED0ECD8Q35084062-9F1D5267-B4ED-474C-B64E-37BBD7674E4AQ35248010-77429D43-E6C4-49A2-99E5-70E25740897FQ35811018-58EFBCD3-BD49-468A-8996-00F4F630F57EQ35950260-51B63F4C-6151-40B5-B356-21654D2703DCQ36010851-4F69B401-D269-44EA-829E-F6DDCAD1A605Q36246549-15A8673E-6FFF-4041-A017-BF67F8D9F074Q36404910-AED882ED-2DDC-4F16-AF77-36536685922DQ36639138-36DBFF05-0C4C-48E9-AC25-FEB4933A3EA1Q36677528-373AA264-E311-4E9A-A8C2-79BFEE7B8259Q36686091-DD1042F0-4571-4F5A-A2F5-40FF0E122BF5Q36849876-36C2C236-5D86-4F55-8B10-11A371FAD596
P2860
Feedback signaling controls leading-edge formation during chemotaxis.
description
2006 nî lūn-bûn
@nan
2006年の論文
@ja
2006年論文
@yue
2006年論文
@zh-hant
2006年論文
@zh-hk
2006年論文
@zh-mo
2006年論文
@zh-tw
2006年论文
@wuu
2006年论文
@zh
2006年论文
@zh-cn
name
Feedback signaling controls leading-edge formation during chemotaxis.
@ast
Feedback signaling controls leading-edge formation during chemotaxis.
@en
type
label
Feedback signaling controls leading-edge formation during chemotaxis.
@ast
Feedback signaling controls leading-edge formation during chemotaxis.
@en
prefLabel
Feedback signaling controls leading-edge formation during chemotaxis.
@ast
Feedback signaling controls leading-edge formation during chemotaxis.
@en
P1476
Feedback signaling controls leading-edge formation during chemotaxis.
@en
P2093
Pascale G Charest
Richard A Firtel
P304
P356
10.1016/J.GDE.2006.06.016
P577
2006-06-27T00:00:00Z