about
Lulu2 regulates the circumferential actomyosin tensile system in epithelial cells through p114RhoGEFThe kidney and planar cell polarity.Genetic controls and cellular behaviors in branching morphogenesis of the renal collecting systemEpidermal growth factor signalling controls myosin II planar polarity to orchestrate convergent extension movements during Drosophila tubulogenesisGPR56 is essential for testis development and male fertility in miceDrosophila sex combs as a model of evolutionary innovationsDistinct apical and basolateral mechanisms drive planar cell polarity-dependent convergent extension of the mouse neural plate.Rho-kinase directs Bazooka/Par-3 planar polarity during Drosophila axis elongation.A contractile actomyosin network linked to adherens junctions by Canoe/afadin helps drive convergent extension.Abl regulates planar polarized junctional dynamics through β-catenin tyrosine phosphorylationActomyosin-based self-organization of cell internalization during C. elegans gastrulation.From morphogen to morphogenesis and back.Complex interactions between GSK3 and aPKC in Drosophila embryonic epithelial morphogenesis.Development of head organizer of the mouse embryo depends on a high level of mitochondrial metabolism.Crumbs affects protein dynamics in anterior regions of the developing Drosophila embryoPlanar cell polarity in Drosophila.Regulation of cochlear convergent extension by the vertebrate planar cell polarity pathway is dependent on p120-cateninMultiple influences of blood flow on cardiomyocyte hypertrophy in the embryonic zebrafish heart.Myosin-IXA regulates collective epithelial cell migration by targeting RhoGAP activity to cell-cell junctionsMyosin-II-mediated cell shape changes and cell intercalation contribute to primitive streak formation.Whole population cell analysis of a landmark-rich mammalian epithelium reveals multiple elongation mechanisms.Stripy Ftz target genes are coordinately regulated by Ftz-F1.Junctional trafficking and epithelial morphogenesis.Spatial organization of adhesion: force-dependent regulation and function in tissue morphogenesis.Planar cell polarity signaling in the Drosophila eye.Translating cell polarity into tissue elongation.Planar cell polarity in kidney development and disease.Mesoderm layer formation in Xenopus and Drosophila gastrulationSelf-organization of developing embryo using scale-invariant approach.Dynamic analyses of Drosophila gastrulation provide insights into collective cell migration.Atonal and EGFR signalling orchestrate rok- and Drak-dependent adherens junction remodelling during ommatidia morphogenesis.RhoGAP control of pancreas development: putting cells in the right place at the right time.Vangl2 regulates E-cadherin in epithelial cells.Software-based measurement of thin filament lengths: an open-source GUI for Distributed Deconvolution analysis of fluorescence images.Myosin II Controls Junction Fluctuations to Guide Epithelial Tissue Ordering.Counter-rotational cell flows drive morphological and cell fate asymmetries in mammalian hair follicles.Planar cell movements and oriented cell division during early primitive streak formation in the mammalian embryo.The role of differential VE-cadherin dynamics in cell rearrangement during angiogenesis.ROCK1 and ROCK2 regulate epithelial polarisation and geometric cell shape.Using Zebrafish to Study Collective Cell Migration in Development and Disease
P2860
Q24293613-A2BD3B7B-3510-4BD5-B2A0-C0A5E4C4DB95Q26829303-9C30FE1B-6CCC-4AB4-B13A-135B5595BD27Q26996583-16038546-C296-4779-A378-35DA5D9AD88DQ27313550-C42CEBA1-B391-408F-B805-249A6C3CEB84Q28586188-3338ED39-1499-449A-A912-F57B69394A76Q28727360-81A79EF1-3BA4-4FD8-B694-6CD41825EFF6Q30405792-AC0356DC-903E-49C5-9B8A-EE6DDEC93F1BQ30502216-934417B3-B679-41C0-8B97-79AA2556FF40Q30502433-EC6987B1-B74C-4FE6-9A48-ED11D8C0908DQ30513412-0AA7E933-7921-47ED-9ADE-BDECF0A73FBBQ30536896-51816307-3A02-4E6B-BC86-D3BCA73CA92CQ33364605-3D52AC33-576B-4A5A-923B-62A11E38D99CQ33869158-5205AFD5-FDCD-4BB2-BCBE-7FA4806568EFQ34017353-68272D73-43F7-48F8-9A2A-879CEEB66DD2Q34650555-76D86CB0-89FA-4CFE-96A5-30556A0E4855Q35624641-337817FF-354B-4AE4-8A52-2A273DFC8617Q35741919-379EC487-0F4F-4442-B120-64EC40029002Q35758199-B12EB88A-8DCC-4777-AC40-A86CA77D0816Q35785344-1A9D36B5-442D-44DB-82DF-7674415F1822Q36951037-07248C4E-319A-4AF7-9EB9-F338C9A95BA4Q37323645-F25E1792-D160-489B-8F56-4CE5497856F9Q37442499-0FF53153-4EA8-4F00-B737-C13BD8B8A7CCQ37533062-0FBB3936-97B3-476C-AC18-76B7EFB8BCD3Q37780682-59A06804-22E5-41F5-9905-D1E1D765FE0FQ37801483-9F1008EB-4340-4D1C-A532-FCCAB687925CQ37943595-4E8B13A2-74CE-4BE2-B227-3F7EA8A5CF39Q37949488-804ACF13-2262-4000-98CC-511E0C8E8C3BQ39207735-14F5A04B-6217-40B5-A181-DE052835B8F1Q41786066-DC1D43DB-A096-4227-AFA2-0BC85F0C5560Q41858569-C283F5C8-DF5C-4897-8E43-DBD94CECA3CDQ42259701-FC0C2438-0B31-46F2-82DF-3E52E70E32A0Q42560232-E182D945-4C44-4D96-A5DF-F0A2A58456F0Q42977383-C5933F66-57E0-4274-AD7D-CDB89B66E2C3Q46369055-73DAF639-7F6F-446F-BBA7-5E570880A50AQ47098655-6A7E0213-B076-4C93-824B-F8DC491B84F0Q52319648-2DD4DD5F-5578-4432-B6C6-F2CF66D45E9DQ53213548-698949A4-1D79-4FFA-B45A-EDEEFA48B3A7Q54365519-1581DA39-C98A-402C-822C-ED190B92EAA8Q54520178-FCD60776-C92D-4788-AFC6-647F1834FD9DQ58769328-56FB1BA9-E24E-4BCD-8020-C6F2BAC41BF8
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 02 February 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Multicellular dynamics during epithelial elongation.
@en
Multicellular dynamics during epithelial elongation.
@nl
type
label
Multicellular dynamics during epithelial elongation.
@en
Multicellular dynamics during epithelial elongation.
@nl
prefLabel
Multicellular dynamics during epithelial elongation.
@en
Multicellular dynamics during epithelial elongation.
@nl
P2860
P1476
Multicellular dynamics during epithelial elongation
@en
P2093
Jennifer A Zallen
P2860
P304
P356
10.1016/J.SEMCDB.2008.01.005
P577
2008-02-02T00:00:00Z