about
Keratin dynamics: modeling the interplay between turnover and transportFocal adhesions are hotspots for keratin filament precursor formationp38 MAPK-dependent shaping of the keratin cytoskeleton in cultured cells.Epidermolysis bullosa simplex-type mutations alter the dynamics of the keratin cytoskeleton and reveal a contribution of actin to the transport of keratin subunits.Identification of novel principles of keratin filament network turnover in living cellsDissection of keratin network formation, turnover and reorganization in living murine embryos.The keratin-filament cycle of assembly and disassembly.3D segmentation of keratin intermediate filaments in confocal laser scanning microscopy.Tetraspan vesicle membrane proteins: synthesis, subcellular localization, and functional properties.Placental vasculogenesis is regulated by keratin-mediated hyperoxia in murine decidual tissuesDesmoglein 2 mutant mice develop cardiac fibrosis and dilation.Synaptic tetraspan vesicle membrane proteins are conserved but not needed for synaptogenesis and neuronal function in Caenorhabditis elegans.Effects of Plectin Depletion on Keratin Network Dynamics and Organization.Keratins as the main component for the mechanical integrity of keratinocytes.Intermediate filaments in Caenorhabditis elegans.Intermediate filaments and the regulation of focal adhesion.Intracellular Motility of Intermediate Filaments.Desmosome assembly and cell-cell adhesion are membrane raft-dependent processes.Requirements for leukocyte transmigration via the transmembrane chemokine CX3CL1.Desmosomes: interconnected calcium-dependent structures of remarkable stability with significant integral membrane protein turnover.Threonine 150 phosphorylation of keratin 5 is linked to EBS and regulates filament assembly and cell viability.ADAM12 is expressed by astrocytes during experimental demyelination.Induction of rapid and reversible cytokeratin filament network remodeling by inhibition of tyrosine phosphatases.Light-induced resistance of the keratin network to the filament-disrupting tyrosine phosphatase inhibitor orthovanadate.A rim-and-spoke hypothesis to explain the biomechanical roles for cytoplasmic intermediate filament networks.Symbiosis of the Hydrothermal Vent Gastropod Ifremeria nautilei (Provannidae) With Endobacteria-Structural Analyses and Ecological Considerations.Maintenance of the intestinal tube in Caenorhabditis elegans: the role of the intermediate filament protein IFC-2.Loss of desmoglein 2 suggests essential functions for early embryonic development and proliferation of embryonal stem cellsVisualization of gap junction mobility in living cellsRedistribution of adhering junctions in human endometrial epithelial cells during the implantation window of the menstrual cycleSignal and noise modeling in confocal laser scanning fluorescence microscopyMultidimensional Monitoring of Keratin Intermediate Filaments in Cultured Cells and TissuesRegulation of keratin network dynamics by the mechanical properties of the environment in migrating cellsAlloxan Disintegrates the Plant Cytoskeleton and Suppresses mlo-Mediated Powdery Mildew ResistanceHemidesmosomes and Focal Adhesions Treadmill as Separate but Linked Entities during Keratinocyte MigrationThe keratin-desmosome scaffold: pivotal role of desmosomes for keratin network morphogenesisCellular responses to beating hydrogels to investigate mechanotransduction
P50
Q27311153-B026FEE9-01C1-4E20-AF5C-C1A1EF16B956Q30444216-2179AD6F-2D00-44DC-ADEA-29B3AA110A03Q30480462-8FA071FA-F8D8-41F5-840F-57F736728FDDQ30539002-0EDA1A60-42BD-46C8-82EF-4E827C83693AQ30579430-5C85E745-373C-412D-B065-1B8117448386Q30626598-811EC914-C9EE-4755-8D1B-F6AB62D2DC44Q34121200-5932D5FE-64FC-4D81-82CB-7BD6931D6D3EQ34132064-73A12ACF-E17C-4201-A6B2-5A627EE18AAAQ34562995-A7B69BAB-B341-46D5-98F6-8300085E26C1Q34805548-9531AB4A-7CE0-4963-8911-0B35B918C4D0Q35017328-21CDACFF-7C1D-433D-8C33-DB30C83FFDD7Q35039350-B6392B46-5C6F-4A3A-914F-F2025A719BF5Q35967425-EAD94156-3987-4DD9-9BC2-8B804EDA3CC3Q37319476-3933FEEE-FB3B-464F-ACFD-24CA5F85BD45Q37479445-1569E288-742F-4AB0-88CE-51A367112838Q38280573-5E0847E8-710C-403B-8CFC-38BFD9131F52Q39345049-87FE21EB-0668-4BE0-BEF2-480AB10E1872Q39632878-41AFF049-B722-4ECA-9A56-9A0468DDBF33Q39691199-CCDDE10C-3128-45E1-8189-8E34480CF872Q40738524-524F25E5-C6F2-4248-86FD-3BCC31438550Q42517661-42737D6C-80EB-4FE1-960C-0E288C9670CAQ43153918-642386CB-F93F-44E1-848C-057DE95DD103Q44161200-F2CC16AF-5403-4BCB-B33A-4749C7BB9F31Q44287688-B298DF16-C3C8-42DC-8FE3-3E3BC529103BQ48186384-4BD4D5A2-6BDF-4597-90F0-916C37E48C0DQ51207582-0B24C246-D025-4EC9-A631-D697D3DE473FQ51958137-39352392-7774-4247-9AF7-0E9B11D1343DQ58438407-8E98D1EC-8BDD-4BFE-AF09-B4D368BDFEFFQ73691903-FF6BA532-5AA6-4D29-A222-215335E05CC5Q83429153-2A463167-23B5-4589-9978-852ECE78425AQ85833705-14D73700-795A-4031-9BA0-F6070766D75BQ87131051-AD70AB37-97EB-4004-8D8D-BFB3A3AF6A97Q90282160-16330CFA-63EC-437B-85C9-A3748B65C96DQ91322150-8C24EBAD-6185-47BB-BB12-E1F9B8D2F060Q92878228-DA538A6A-470E-4DA1-802B-8450438CA107Q93054376-DD467EEB-169A-4D5D-B174-F946D0B54B25Q93161819-6160FD05-74AB-4F51-9A1E-37C2678545E5
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Reinhard Windoffer
@ast
Reinhard Windoffer
@en
Reinhard Windoffer
@es
Reinhard Windoffer
@nl
type
label
Reinhard Windoffer
@ast
Reinhard Windoffer
@en
Reinhard Windoffer
@es
Reinhard Windoffer
@nl
prefLabel
Reinhard Windoffer
@ast
Reinhard Windoffer
@en
Reinhard Windoffer
@es
Reinhard Windoffer
@nl
P106
P31
P496
0000-0003-1403-5880