about
The WASP and WAVE family proteinsWASH and WAVE actin regulators of the Wiskott-Aldrich syndrome protein (WASP) family are controlled by analogous structurally related complexesMolecular mechanisms and functional implications of polarized actin remodeling at the T cell immunological synapseIntegration of linear and dendritic actin nucleation in Nck-induced actin comets.DOCK8 is essential for T-cell survival and the maintenance of CD8+ T-cell memoryβ1 integrins regulate fibroblast chemotaxis through control of N-WASP stability.Physical mechanisms of signal integration by WASP family proteins.A DOCK8-WIP-WASp complex links T cell receptors to the actin cytoskeleton.Preclinical safety and efficacy of human CD34(+) cells transduced with lentiviral vector for the treatment of Wiskott-Aldrich syndrome.NMR determines transient structure and dynamics in the disordered C-terminal domain of WASp interacting proteinAge-Dependent Defects of Regulatory B Cells in Wiskott-Aldrich Syndrome Gene Knockout MiceCritical roles of the WASP N-terminal domain and Btk in LPS-induced inflammatory response in macrophages.Evolution of the eukaryotic ARP2/3 activators of the WASP family: WASP, WAVE, WASH, and WHAMM, and the proposed new family members WAWH and WAMLCompetition between Blown fuse and WASP for WIP binding regulates the dynamics of WASP-dependent actin polymerization in vivo.WASp-deficient B cells play a critical, cell-intrinsic role in triggering autoimmunity.Stem cell factor programs the mast cell activation phenotypeActin engine in immunological synapseMetabolic context regulates distinct hypothalamic transcriptional responses to antiaging interventionsImmune pathology associated with altered actin cytoskeleton regulation.Regulation of the actin cytoskeleton-plasma membrane interplay by phosphoinositides.Cytoskeleton in mast cell signaling.Molecular control of B cell activation and immunological synapse formation.Signal Integration during T Lymphocyte Activation and Function: Lessons from the Wiskott-Aldrich Syndrome.Membrane-targeted WAVE mediates photoreceptor axon targeting in the absence of the WAVE complex in Drosophila.Wsp1, a GBD/CRIB domain-containing WASP homolog, is required for growth, morphogenesis, and virulence of Cryptococcus neoformans.Quantitative analysis of B-lymphocyte migration directed by CXCL13Wsp1 is downstream of Cin1 and regulates vesicle transport and actin cytoskeleton as an effector of Cdc42 and Rac1 in Cryptococcus neoformans.Proline rich motifs as drug targets in immune mediated disorders.Caenorhabditis elegans wsp-1 regulation of synaptic function at the neuromuscular junction.Inhibiting Wipf2 downregulation by transgenic expression of its 3' mRNA-untranslated region improves cytotoxicity and vaccination response.Acting on identity: Myoblast fusion and the formation of the syncytial muscle fiber.Signals Controlling Lytic Granule Polarization at the Cytotoxic Immune Synapse.Triple-color FRET analysis reveals conformational changes in the WIP-WASp actin-regulating complex.WIP-YAP/TAZ as A New Pro-Oncogenic Pathway in Glioma.
P2860
Q21183891-01B29E24-AF52-419C-AC6C-6A09BFA8F012Q24314791-C008D65F-8AC6-49E9-AD31-F6F9EDA20A0FQ27026215-2BA81EC0-B8D6-45B2-AA48-5B006E2BCEDEQ27306650-FD0BBB9D-7A54-4C91-8807-9044D12292CFQ28506290-6DE3BC52-49E5-4F0F-86E3-EFA33F12BBBAQ28590876-14AF537E-F5B9-4C22-A888-F623482411BAQ30156827-887F7A23-7219-4075-B1F9-BD3AEFF1A37EQ30827629-EA1FB5AA-20ED-4F94-AC38-DD4617090E24Q33399943-72FE3FFD-4DC4-4AB8-9B59-D5E4B6898EFDQ33409233-BF22B9FF-DA04-46EE-94F5-0FC7BB286523Q33426553-A402DF30-35D9-4AD8-B468-DE684F8D0D8EQ34131208-CC131D4B-A576-485C-88F3-22DFB8AEC2B1Q34153579-E6DEE9E4-5C58-4CF5-B56B-A1512A7B9E37Q35229802-DFAB149C-AF43-4072-B178-57A1479E8EBAQ35237494-3BDCF55D-B851-4272-A7EA-00C90A034D98Q35981165-3289BB95-4F63-4D00-BC85-9109C8D89779Q36174795-767BF67E-3939-4298-9A06-D054714AFB2CQ36190308-F17428A8-54AC-479F-8D9A-3E836A5DAC06Q37650286-D8AEC746-3F6D-4E12-B263-6511876056D3Q37677924-DDF9825F-08B5-4BD4-BF40-37BBC7C7F089Q38015371-F12FB067-D7F1-4CC8-B65F-FC29D8FA24A8Q38339449-C3E2740F-0DBB-47E0-9347-3B1A95FF48F8Q38364694-3D281345-CE9C-4894-98BC-2BE343953706Q38864765-B8A34BA0-59EF-4B1B-A123-CA98E3DA219AQ39584930-0C4C8B53-45BA-4B51-A35F-2C0BDB60E36BQ41512337-FE41E01F-2D06-4920-868D-7A1B5176F254Q42088045-283B7B60-8553-4C81-973C-1DA3BBF2E532Q42124413-94CA6827-4DC9-4676-8CD9-8BCA2B3C70A6Q42724593-19CD3D9E-7084-4D3F-A7F2-C0AECF37B88EQ46514009-3F5E2548-12EC-44F2-8025-A7A04FBF0AF2Q50176856-FFE9A682-25FE-4A4F-A4A5-2A1AD807F47CQ52668321-7CDC215B-8C25-43C0-806A-D4686395D94AQ54342392-04973F94-B9FF-4FD0-A794-990961075235Q55456858-11EE347D-EEEC-42F4-83EC-9A82BDE55F3C
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on January 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Recent advances in the biology of WASP and WIP.
@en
Recent advances in the biology of WASP and WIP.
@nl
type
label
Recent advances in the biology of WASP and WIP.
@en
Recent advances in the biology of WASP and WIP.
@nl
prefLabel
Recent advances in the biology of WASP and WIP.
@en
Recent advances in the biology of WASP and WIP.
@nl
P1433
P1476
Recent advances in the biology of WASP and WIP.
@en
P2093
Narayanaswamy Ramesh
P2860
P2888
P304
P356
10.1007/S12026-008-8086-1
P577
2009-01-01T00:00:00Z