A molecular network for de novo generation of the apical surface and lumen - Wikidata - wikimedia - TriplyDB

A molecular network for de novo generation of the apical surface and lumen

A molecular network for de novo generation of the apical surface and lumen

http://www.wikidata.org/entity/Q42116509

about

CLASPs link focal-adhesion-associated microtubule capture to localized exocytosis and adhesion site turnover Early steps in primary cilium assembly require EHD1/EHD3-dependent ciliary vesicle formation Primary cilia membrane assembly is initiated by Rab11 and transport protein particle II (TRAPPII) complex-dependent trafficking of Rabin8 to the centrosome FIP5 phosphorylation during mitosis regulates apical trafficking and lumenogenesis The Exocyst Complex in Health and Disease The role of enterocyte defects in the pathogenesis of congenital diarrheal disorders The Exocyst at a Glance Polarity in mammalian epithelial morphogenesis Midbody: from cellular junk to regulator of cell polarity and cell fate Molecular complexes that direct rhodopsin transport to primary cilia Polar delivery in plants; commonalities and differences to animal epithelial cells Rho GTPases, phosphoinositides, and actin: a tripartite framework for efficient vesicular trafficking Rho GAPs and GEFs: controling switches in endothelial cell adhesion Molecular mechanisms controlling vascular lumen formation in three-dimensional extracellular matrices Molecular mechanism of protrusion formation during cell-to-cell spread of Listeria Normal morphogenesis of epithelial tissues and progression of epithelial tumors.GTPase networks in membrane traffic Targeting Cdc42 in cancer Atypical protein kinase C induces cell transformation by disrupting Hippo/Yap signaling.Exocyst subunits Exo70 and Exo84 cooperate with small GTPases to regulate behavior and endocytic trafficking in C. elegans Huntingtin Is Required for Epithelial Polarity through RAB11A-Mediated Apical Trafficking of PAR3-aPKC The fast-recycling receptor Megalin defines the apical recycling pathway of epithelial cells.Modelling kidney disease with CRISPR-mutant kidney organoids derived from human pluripotent epiblast spheroids Rab35 GTPase couples cell division with initiation of epithelial apico-basal polarity and lumen opening.Microtubule-dependent balanced cell contraction and luminal-matrix modification accelerate epithelial tube fusion.Kif3a guides microtubular dynamics, migration and lumen formation of MDCK cells Differential effects of TNF (TNFSF2) and IFN-γ on intestinal epithelial cell morphogenesis and barrier function in three-dimensional culture CLIC4 regulates apical exocytosis and renal tube luminogenesis through retromer- and actin-mediated endocytic trafficking Induction of lateral lumens through disruption of a monoleucine-based basolateral-sorting motif in betacellulin Cdc42 is required for cytoskeletal support of endothelial cell adhesion during blood vessel formation in mice.A rapid, membrane-dependent pathway directs furrow formation through RalA in the early Drosophila embryo.LGN/mInsc and LGN/NuMA Complex Structures Suggest Distinct Functions in Asymmetric Cell Division for the Par3/mInsc/LGN and Gαi/LGN/NuMA Pathways Rabs and the exocyst in ciliogenesis, tubulogenesis and beyond.A Rab8 guanine nucleotide exchange factor-effector interaction network regulates primary ciliogenesis The Arf GAP ASAP1 provides a platform to regulate Arf4- and Rab11-Rab8-mediated ciliary receptor targeting.Crosstalk of Arf and Rab GTPases en route to cilia.The roles of evolutionarily conserved functional modules in cilia-related trafficking.Multiple roles for keratin intermediate filaments in the regulation of epithelial barrier function and apico-basal polarity Cdc42 in oncogenic transformation, invasion, and tumorigenesis RalA and RalB differentially regulate development of epithelial tight junctions

P2860

Q24298210-12902F17-E582-4230-A8B1-30D462CBC896 Q24319185-AB8EC89A-5A51-4607-8480-830C939C4F12 Q24338514-B4A84A9D-B9DC-4DD3-BA5E-CCF43A55D1AD Q24338653-70CA21B2-C4E3-4EEB-8B3B-ED2F906DB53C Q26752334-BB4D864E-B796-42CF-9B24-FFB4E2F0C6F7 Q26770040-7E7A614D-DD61-4AE8-AF22-3596E49242C6 Q26799386-BE1DD668-5A18-4E62-8EF7-A47D7D4BE896 Q26830318-730A3296-A3DC-4457-BA48-5728CC650FBB Q26860238-36502882-EAE2-420D-8AE0-0B694F3FD7A9 Q26860718-06E39E58-59DD-4D28-9A17-BAC4B94A1072 Q26862232-7C001B6E-6243-433C-AF83-89EA4C174485 Q26865752-075C44CC-B53A-402E-870B-C2D8BA6571AB Q26992281-EC5DF340-35D1-4029-BFFD-496EF7FD2E59 Q26996223-F8F15A19-BE47-4840-8545-053DCF1CAAD7 Q27006985-B29B0B9D-82CA-423A-AA88-0EBFA63F26EA Q27015094-DC33CA51-05E6-4BC8-AAEE-F8A5A1B414C3 Q27015776-35482F65-AE83-4FAC-B009-6C11AAC22F3F Q27028075-14D48D7B-BF2D-4031-8DE6-CD5EA5B226EE Q27305890-AC614EB9-BDA1-4550-9084-554329E70D3D Q27308745-8F0DB81C-CBA8-440F-9C99-DE5437363810 Q27312162-A50CC436-5A6D-4BE3-B224-8DFAF94CFF46 Q27316974-DFCB434D-3439-432B-8CFA-CD2CC4B53437 Q27319887-ED098E6C-B8E9-479F-B27B-1CF96AC3CF07 Q27321208-0C267A99-AB18-490D-A95C-DF0F0419A369 Q27321475-D223E306-80A5-402F-ACC0-917E7EFDC1E0 Q27323051-C73FB9ED-4192-47A3-BDFB-5F9447CBB383 Q27329003-D5CD1AC2-1143-42CA-B6C8-45BE4B97293C Q27334829-67F4F0E2-B22A-441A-9B32-381B534DBEF6 Q27339929-A7CD13B7-3B32-449F-B2FA-B66153152B22 Q27342778-9354F0B4-BBE6-473A-BEB3-59399B9FBB00 Q27343130-B68C622F-1E62-44AF-8CD7-B4AB50CE97B0 Q27671529-9D9AF0D1-895C-44A2-9EDE-6551FE32C494 Q28000050-20AC5977-4093-46BF-883F-71530F6A9408 Q28000096-CD186BBD-B460-4DB9-B743-1F030E379F24 Q28000111-4515FE87-525E-4F84-B7C3-155D27A1DB26 Q28000129-51A3957B-B80C-486B-84A8-9B67EE05F138 Q28000150-6C738A48-F616-4356-9193-27AFE7609DCB Q28076190-587BC043-17A8-4FFB-9B98-F3453A8C2271 Q28236231-CED5F4BB-4B72-43A2-81EB-87CD8720303C Q28250836-C400A296-C0A8-4F8F-9ADF-D955B99D395F

P2860

A molecular network for de novo generation of the apical surface and lumen

http://www.wikidata.org/entity/Q42116509

description

2010 nî lūn-bûn

@nan

2010年の論文

@ja

2010年論文

@yue

2010年論文

@zh-hant

2010年論文

@zh-hk

2010年論文

@zh-mo

2010年論文

@zh-tw

2010年论文

@wuu

2010年论文

@zh

2010年论文

@zh-cn

name

A molecular network for de novo generation of the apical surface and lumen

@en

A molecular network for de novo generation of the apical surface and lumen

@nl

type

label

A molecular network for de novo generation of the apical surface and lumen

@en

A molecular network for de novo generation of the apical surface and lumen

@nl

prefLabel

A molecular network for de novo generation of the apical surface and lumen

@en

A molecular network for de novo generation of the apical surface and lumen

@nl

P1433

Q42116509-C2222E23-A283-4D75-AD47-B989515A6F69

P1476

Q42116509-59FDF768-1F68-49F7-ACEF-1992C3414654

P2093

Q42116509-25A8F069-9805-43A6-B398-9BCA0BC9E9B6

Q42116509-26007A93-2099-472B-B748-05D57836EBAA

Q42116509-58EBD42A-B04C-4D05-AD45-AA9021C0C088

Q42116509-D1491019-7343-4494-BB35-01F3ABF751DC

P2860

Q42116509-0793EF71-970F-4F09-842B-2EACB0A32A4B

Q42116509-08BAB1AD-8B7E-4E63-AB6C-51FA824F83EB

Q42116509-0CF3E94F-E2E5-4C76-A9E1-CC71FB7DB670

Q42116509-124BA3F1-C4D1-45FF-A3D3-1C611DA49256

Q42116509-12829282-4F4B-44A9-8521-D1B1F06BDA7C

Q42116509-14B6F381-2AE0-437E-88FD-111A00C96BCA

Q42116509-15700B6E-38B6-4E95-B3A2-308DCBEEB7CE

Q42116509-1F923F2B-7B9D-42C8-A579-4477F4766101

Q42116509-21DEFDB0-2950-4F11-9D6C-890E39883A6E

Q42116509-23D26052-920E-42EF-A158-370EC1EA1919

P2888

Q42116509-CA06B1C4-4437-4E4D-BE04-3EF09FA57DA3

P304

Q42116509-ACDEB9AF-2DC9-4672-A6D5-ECA5437BDF19

P31

Q42116509-CE87CE1A-812D-469A-B94F-8E5B62C89A31

P356

Q42116509-99FA033E-8A9E-4A7A-B340-7E198975C0B2

P433

Q42116509-E0A44DD1-C842-41C8-B3F4-0D036615DF58

P478

Q42116509-E0BB855C-BC6C-4AF8-95EF-F9AE28E0C4FB

P50

Q42116509-441A14DD-F443-4486-8249-81829955924C

Q42116509-EA281603-0BAB-43AF-A4A4-64555F21C1A7

P577

Q42116509-CA6B77BE-BED0-4A8F-AB7A-92E0CB2DC826

P5875

Q42116509-DC4B36A0-D570-45C1-89A7-4D3B22BA7999

P698

Q42116509-005A69A7-5D21-440A-B688-679061AAD23C

P932

Q42116509-17D14A72-DF7D-4323-968D-54F4FDD5F78E

P356

P1433

Nature Cell Biology

P1476

A molecular network for de novo generation of the apical surface and lumen

@en

P2093

Anirban Datta

http://www.w3.org/2001/XMLSchema#string

Fernando Martín-Belmonte

http://www.w3.org/2001/XMLSchema#string

Johan Peränen

http://www.w3.org/2001/XMLSchema#string

Keith E Mostov

http://www.w3.org/2001/XMLSchema#string

P2860

The cell-polarity protein Par6 links Par3 and atypical protein kinase C to Cdc42

Final stages of cytokinesis and midbody ring formation are controlled by BRUCE

The Cdc42 GEF Intersectin 2 controls mitotic spindle orientation to form the lumen during epithelial morphogenesis.

Functional dissection of Rab GTPases involved in primary cilium formation

A Rab8-specific GDP/GTP exchange factor is involved in actin remodeling and polarized membrane transport.

Gp135/podocalyxin and NHERF-2 participate in the formation of a preapical domain during polarization of MDCK cells

Asymmetric coiled-coil structure with Guanine nucleotide exchange activity

Sec15 interacts with Rab11 via a novel domain and affects Rab11 localization in vivo.

Ypt32 recruits the Sec4p guanine nucleotide exchange factor, Sec2p, to secretory vesicles; evidence for a Rab cascade in yeast.

The exocyst protein Sec10 is necessary for primary ciliogenesis and cystogenesis in vitro.

P2888

P304

1035-1045

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1038/NCB2106

http://www.w3.org/2001/XMLSchema#string

P433

11

http://www.w3.org/2001/XMLSchema#string

P478

12

http://www.w3.org/2001/XMLSchema#string

P50

Alejo E Rodríguez-Fraticelli

P577

2010-10-03T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

47300813

http://www.w3.org/2001/XMLSchema#string

P698

20890297

http://www.w3.org/2001/XMLSchema#string

P932

2975675

http://www.w3.org/2001/XMLSchema#string