Synaptic-like microvesicles of neuroendocrine cells originate from a novel compartment that is continuous with the plasma membrane and devoid of transferrin receptor.
about
Cholesterol binds to synaptophysin and is required for biogenesis of synaptic vesiclesRab15 effector protein: a novel protein for receptor recycling from the endocytic recycling compartment.Trafficking of vesicular neurotransmitter transportersThe zinc transporter ZnT3 interacts with AP-3 and it is preferentially targeted to a distinct synaptic vesicle subpopulationNeogenin-mediated hemojuvelin shedding occurs after hemojuvelin traffics to the plasma membraneSyntaxin 13 mediates cycling of plasma membrane proteins via tubulovesicular recycling endosomesStructure, Distribution, and Function of Neuronal/Synaptic Spinules and Related Invaginating ProjectionsRoles of BLOC-1 and adaptor protein-3 complexes in cargo sorting to synaptic vesiclesSodium/hydrogen exchanger NHA2 is critical for insulin secretion in β-cellsSingle point mutation in Bin/Amphiphysin/Rvs (BAR) sequence of endophilin impairs dimerization, membrane shaping, and Src homology 3 domain-mediated partnership.Targeting of the synaptic vesicle protein synaptobrevin in the axon of cultured hippocampal neurons: evidence for two distinct sorting steps.p120-Catenin regulates leukocyte transmigration through an effect on VE-cadherin phosphorylation.Dopamine and amphetamine rapidly increase dopamine transporter trafficking to the surface: live-cell imaging using total internal reflection fluorescence microscopyA distinct trans-Golgi network subcompartment for sorting of synaptic and granule proteins in neurons and neuroendocrine cells.SLC30A3 (ZnT3) oligomerization by dityrosine bonds regulates its subcellular localization and metal transport capacity.Regulation of neuronal function by protein trafficking: a role for the endosomal pathway.Rab4 regulates formation of synaptic-like microvesicles from early endosomes in PC12 cellsAn AP-3-dependent mechanism drives synaptic-like microvesicle biogenesis in pancreatic islet beta-cells.Molecular links between endocytosis and the actin cytoskeleton.The Dictyostelium Bcr/Abr-related protein DRG regulates both Rac- and Rab-dependent pathwaysMultiple and diverse forms of regulated exocytosis in wild-type and defective PC12 cells.SNARE proteins are highly enriched in lipid rafts in PC12 cells: implications for the spatial control of exocytosis.Neuroendocrine synaptic vesicles are formed in vitro by both clathrin-dependent and clathrin-independent pathways.GLUT4 and transferrin receptor are differentially sorted along the endocytic pathway in CHO cellsThy-1 is a component common to multiple populations of synaptic vesiclesVesiculation and sorting from PC12-derived endosomes in vitroDi-leucine signals mediate targeting of tyrosinase and synaptotagmin to synaptic-like microvesicles within PC12 cells.Synaptic vesicles form by budding from tubular extensions of sorting endosomes in PC12 cellsThe dopamine transporter constitutively internalizes and recycles in a protein kinase C-regulated manner in stably transfected PC12 cell lines.Regulation of epidermal growth factor receptor signaling by endocytosis and intracellular traffickingSynaptic vesicle protein trafficking at the glutamate synapse.Sorting to synaptic-like microvesicles from early and late endosomes requires overlapping but not identical targeting signals.Secretagogue-triggered transfer of membrane proteins from neuroendocrine secretory granules to synaptic-like microvesicles.Uptake and intracellular transport of acidic fibroblast growth factor: evidence for free and cytoskeleton-anchored fibroblast growth factor receptors.Brefeldin A sensitive mechanisms contribute to endocytotic membrane retrieval and vesicle recycling in cerebellar granule cells.Human L1CAM carrying the missense mutations of the fibronectin-like type III domains is localized in the endoplasmic reticulum and degraded by polyubiquitylation.Cytosolic stress reduces degradation of connexin43 internalized from the cell surface and enhances gap junction formation and function.Presynaptic mitochondria and the temporal pattern of neurotransmitter release.A v-SNARE participates in synaptic vesicle formation mediated by the AP3 adaptor complex.Protein folding coupled to disulphide bond formation.
P2860
Q22011017-71ED4A8B-EF46-4B04-BC33-DAA88251E5D1Q24337340-23ED8945-C866-4953-A6E5-B828437EA339Q24619054-BE591A8F-EF39-4AA0-929F-DC04392D3667Q24626701-79796CAF-B32F-4867-B868-5ED257232393Q24655380-870DD5BE-DE55-4A6E-92CC-A80C4F16BC20Q24682732-D070711E-DE54-4D22-8D7F-D6F1DD66AB6CQ26823244-EB75A0FD-A60D-4CDA-94F7-7DE9E111BC5BQ28594620-E0732BC9-ADC2-4C8E-80B1-02C5BF012474Q28910221-3500CFEF-1AF5-48F6-822D-4CEF363E094DQ30010188-EAC34620-26BE-4262-BE38-FF9BBF8A2336Q30442138-49AA909F-4529-410E-8E79-A3A7B50BAB8BQ30483820-EF955E91-DDF3-4D19-8375-0912AEB5C4A2Q30487730-F02D7147-61FC-4ED4-B273-D94F089FDB74Q30498182-DE1F4E4C-76D4-4F1A-BA58-845F88AB443CQ33466789-A84BF4FF-7136-4490-8230-ED6468257B48Q33919090-0F6FD5C3-FE5E-4029-90E9-D198E1F84B55Q33948587-00070728-07BA-4D92-97D8-4406D16269B7Q33994381-856F9426-2FB3-45CF-8365-F2B3C1CAC45CQ34023649-C6936525-B983-4109-81C6-1189287AF348Q34584212-C142E09E-7872-4638-A158-120D8C495CF6Q34936861-E16FFD41-BBBE-4F0E-80C0-BC662CDA31D2Q35888471-4CFA863E-BADC-4022-931E-6149FE20B04DQ36255854-609812F5-001C-489F-AE2E-B92B4EAC8F05Q36274878-FDC9F3E2-3AAE-425D-8B86-616743003CA0Q36274886-E467F89F-65E1-4983-ABD2-7E489ACFDCF7Q36308652-354CB0C4-778B-4D15-A5DA-4EB871965B66Q36941351-6C8BC2CC-C285-4DF5-B5D2-26FA256C9616Q36953590-FDE26356-0FDA-48AF-83A8-5E6B483D74ECQ37004117-AD8F9437-0559-4B90-89DD-265E44769799Q37074180-2DF018C1-292D-4F09-83CB-1D564174EC71Q37160079-E7BD1AE9-20E3-4E29-88D6-64B51BB4B72BQ38482840-1860868C-6F04-4DC9-8058-5E51B741E9EAQ38612806-226F72DE-6FFD-4E78-8A53-DCFA3371F6CBQ38614672-5A1B7349-FE89-44AF-A1E6-3AF456C82644Q38906970-CF24CDC8-21E5-4BA2-959A-D052F7122D12Q39521496-1D90F84F-8259-4BA2-A3A8-67F7E8053BB2Q40379222-9C456F52-79C1-43FE-B604-1DCE4ECF2A92Q40856387-215D4A69-3EAC-4BC6-A3C6-F270B91F67F4Q41644775-824C421C-D382-4DA1-8561-2795EA62D063Q41648380-AFD3E873-8B78-4023-9CD4-CAA26250A14A
P2860
Synaptic-like microvesicles of neuroendocrine cells originate from a novel compartment that is continuous with the plasma membrane and devoid of transferrin receptor.
description
1997 nî lūn-bûn
@nan
1997年の論文
@ja
1997年論文
@yue
1997年論文
@zh-hant
1997年論文
@zh-hk
1997年論文
@zh-mo
1997年論文
@zh-tw
1997年论文
@wuu
1997年论文
@zh
1997年论文
@zh-cn
name
Synaptic-like microvesicles of ...... evoid of transferrin receptor.
@en
Synaptic-like microvesicles of ...... evoid of transferrin receptor.
@nl
type
label
Synaptic-like microvesicles of ...... evoid of transferrin receptor.
@en
Synaptic-like microvesicles of ...... evoid of transferrin receptor.
@nl
prefLabel
Synaptic-like microvesicles of ...... evoid of transferrin receptor.
@en
Synaptic-like microvesicles of ...... evoid of transferrin receptor.
@nl
P2093
P2860
P356
P1476
Synaptic-like microvesicles of ...... evoid of transferrin receptor.
@en
P2093
M J Hannah
W B Huttner
P2860
P304
P356
10.1083/JCB.137.2.445
P407
P577
1997-04-01T00:00:00Z