about
The dynamics of spatio-temporal Rho GTPase signaling: formation of signaling patternsComputer vision profiling of neurite outgrowth dynamics reveals spatiotemporal modularity of Rho GTPase signalingGrowth cone MKK7 mRNA targeting regulates MAP1b-dependent microtubule bundling to control neurite elongationGrowth Cone Localization of the mRNA Encoding the Chromatin Regulator HMGN5 Modulates Neurite Outgrowth.Spatio-temporal co-ordination of RhoA, Rac1 and Cdc42 activation during prototypical edge protrusion and retraction dynamicsTwo distinct filopodia populations at the growth cone allow to sense nanotopographical extracellular matrix cues to guide neurite outgrowthFormin-like 2 drives amoeboid invasive cell motility downstream of RhoCCalcium-dependent homoassociation of E-cadherin by NMR spectroscopy: changes in mobility, conformation and mapping of contact regionsSpatiotemporal dynamics of RhoA activity in migrating cellsProtein kinase A governs a RhoA-RhoGDI protrusion-retraction pacemaker in migrating cells.p190RhoGAP negatively regulates Rho activity at the cleavage furrow of mitotic cells.GEF-H1 modulates localized RhoA activation during cytokinesis under the control of mitotic kinasesSpatial mapping of the neurite and soma proteomes reveals a functional Cdc42/Rac regulatory networkA growth factor-induced, spatially organizing cytoskeletal module enables rapid and persistent fibroblast migration.Functional proteometrics for cell migration.A switch in disulfide linkage during minicollagen assembly in Hydra nematocystsFilopodia: Nanodevices that sense nanotopographic ECM cues to orient neurite outgrowthDesigning biosensors for Rho family proteins--deciphering the dynamics of Rho family GTPase activation in living cells.Vinculin modulation of paxillin-FAK interactions regulates ERK to control survival and motility.Frequency modulation of ERK activation dynamics rewires cell fate.Spatio-temporal Rho GTPase signaling - where are we now?Measuring ERK Activity Dynamics in Single Living Cells Using FRET Biosensors.Homoassociation of VE-cadherin follows a mechanism common to "classical" cadherins.Analysis of heterophilic and homophilic interactions of cadherins using the c-Jun/c-Fos dimerization domains.Microfluidic platform for single cell analysis under dynamic spatial and temporal stimulation.Control of Cell Shape, Neurite Outgrowth, and Migration by a Nogo-A/HSPG Interaction.Developmental ERK Signaling Goes Digital.Network-based identification of feedback modules that control RhoA activity and cell migration.SrGAP2-Dependent Integration of Membrane Geometry and Slit-Robo-Repulsive Cues Regulates Fibroblast Contact Inhibition of Locomotion.Phosphatidylinositol 5-phosphate regulates invasion through binding and activation of Tiam1.Spatial Organization of Rho GTPase signaling by RhoGEF/RhoGAP proteinsE-cadherin is a ligand for integrin α2β1Frequency modulation of ERK activation dynamics rewires cell fateIntegrated Platform for Monitoring Single-cell MAPK Kinetics in Computer-controlled Temporal StimulationsAutomated profiling of growth cone heterogeneity defines relations between morphology and motilitySystems analysis of RhoGEF and RhoGAP regulatory proteins reveals spatially organized RAC1 signalling from integrin adhesionsTemporal perturbation of ERK dynamics reveals network architecture of FGF2/MAPK signalingDevelopmental Erk Signaling Illuminated
P50
Q26751231-9822C006-3419-4A57-A328-3DC00678C755Q27309190-CE161D1A-5D4B-4B1F-B1B4-2241E2231C2AQ27318614-AD183FCB-89D9-412F-A4C9-2C138F04280EQ27320882-13A5D88A-B4E3-4CE2-86B0-C6B4658BF77FQ27342706-7EACC6DB-BA9F-4921-9FA7-8C8E424E2E07Q27438067-AEAB6C80-BAD7-4492-952F-C259ED741B04Q28271418-F31757EF-BC5D-49C2-BA19-6F467F9863C7Q28510958-8E4ACE09-2D13-44C0-90E5-5796B66BBD58Q29618433-B08597B4-BA46-4A4E-BDAA-13E14600611FQ30417648-3A0C4093-BE26-476E-9944-1B97C762ABF8Q30436244-78696F3E-C946-4031-AA4C-5D44F2640B88Q30480028-C4F4BC32-97E5-47C5-8E94-6BE199AF3784Q30483613-8E14F9E9-D5BA-47A5-BC65-7D740D5E5746Q30635516-07B7232F-4A80-4D41-8009-3A9AD19F68DBQ33245683-F86E761B-5A52-47DE-B510-2DE511B12DF7Q34769688-0E7D43A3-B653-49AE-8C21-081559E272A1Q35236110-EBAAC070-4819-4B74-A33C-4CF2662EE6C3Q35691017-6384EA43-D054-433E-8120-885A8000AEBFQ36322135-21921451-CF3F-4305-9E82-E20251067CF2Q36349325-1FB461E5-07C0-4625-B542-8A9FCB625896Q37756431-5B85D79F-0058-4AAE-B063-968F58527517Q39125284-163CF81A-3E86-4FA9-BB02-F05CEA1AE701Q40680127-029D3676-F57C-4097-B690-7DBF0906CCC4Q40742966-9D88B85E-0F65-4149-BDFD-1A10E84BEAA6Q47196388-4EB7EE1F-4D25-4964-AE7A-2B355E21AB2DQ47752282-0FC3283F-8B8B-464D-8E35-234E8DDB6E07Q47816822-5830F1E9-ED99-44C7-814D-6FE2CDA53723Q48276915-5E16EAB4-5860-447A-8805-979DAAFFE004Q50557148-3EDBE303-00AE-4A9C-A507-C0328923CC96Q54346614-3160099F-E721-4D10-AEE2-83E814A20FF6Q57011734-431E3BDE-ED13-47DF-AF12-02394E7E0B96Q58057935-6ED27693-164E-4ACF-B8CE-D348F6FA87CEQ58376494-90797BC5-A813-4828-9742-B1131315A8CCQ58925480-848A646D-106F-4428-BEF8-E58C72E39D50Q90316045-92EED107-445B-4B8B-B393-16072F2996E9Q90591291-07741A8B-C711-45CB-87AF-D26FD334A58CQ91500340-AD7AE5F1-1868-4729-A7BB-750FC81021D1Q91503346-732EF123-5C69-4E47-B6F0-C2FF68F06307
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Olivier Pertz
@ast
Olivier Pertz
@en
Olivier Pertz
@es
Olivier Pertz
@nl
type
label
Olivier Pertz
@ast
Olivier Pertz
@en
Olivier Pertz
@es
Olivier Pertz
@nl
prefLabel
Olivier Pertz
@ast
Olivier Pertz
@en
Olivier Pertz
@es
Olivier Pertz
@nl
P106
P31
P496
0000-0001-8579-4919