Asymmetric redistribution of GABA receptors during GABA gradient sensing by nerve growth cones analyzed by single quantum dot imaging
about
A mechanism for the polarity formation of chemoreceptors at the growth cone membrane for gradient amplification during directional sensingAutocatalytic loop, amplification and diffusion: a mathematical and computational model of cell polarization in neural chemotaxisDecoupling polarization of the Golgi apparatus and GM1 in the plasma membraneDesign of quantum dot-conjugated lipids for long-term, high-speed tracking experiments on cell surfaces.Bayesian model predicts the response of axons to molecular gradients.Disrupting microtubule network immobilizes amoeboid chemotactic receptor in the plasma membrane.Cytoskeletal control of CD36 diffusion promotes its receptor and signaling function.A Quantum Dot-Immunofluorescent Labeling Method to Investigate the Interactions between a Crinivirus and Its Whitefly Vector.Single Molecule Imaging Deciphers the Relation between Mobility and Signaling of a Prototypical G Protein-coupled Receptor in Living Cells.Axon guidance: asymmetric signaling orients polarized outgrowth.Cellular responses to extracellular guidance cuesThe growth cone: an integrator of unique cues into refined axon guidanceMembrane protein dynamics and functional implications in mammalian cells.Detection, counting, and imaging of single nanoparticles.How receptor diffusion influences gradient sensingSecond messengers and membrane trafficking direct and organize growth cone steering.Cytoskeletal rearrangement and Src and PI-3K-dependent Akt activation control GABA(B)R-mediated chemotaxisNovel tools integrating metabolic and gene function to study the impact of the environment on coral symbiosis.Observing GLUT4 translocation in live L6 cells using quantum dots.Quantum dots: synthesis, bioapplications, and toxicityVisualization of lipid raft membrane compartmentalization in living RN46A neuronal cells using single quantum dot trackingAmplification and temporal filtering during gradient sensing by nerve growth cones probed with a microfluidic assaySpatial and temporal sensing limits of microtubule polarization in neuronal growth cones by intracellular gradients and forcesImaging GABAc receptors with ligand-conjugated quantum dots.DNA target sequence identification mechanism for dimer-active protein complexes.Biocompatible quantum dots for biological applications.Labeling of neuronal receptors and transporters with quantum dotsSynaptic receptor trafficking: the lateral point of viewTracking bio-molecules in live cells using quantum dots.Shaping the synaptic signal: molecular mobility inside and outside the cleft.Regulation from within: the cytoskeleton in transmembrane signaling.Quantum dots in bioanalysis: a review of applications across various platforms for fluorescence spectroscopy and imaging.Tracking of single receptor molecule mobility in neuronal membranes: a quick theoretical and practical guide.Cell biology in neuroscience: RNA-based mechanisms underlying axon guidance.Second messenger networks for accurate growth cone guidance.Quantum dots: bright and versatile in vitro and in vivo fluorescence imaging biosensors.What do diffusion measurements tell us about membrane compartmentalisation? Emergence of the role of interprotein interactions.Efficient Delivery of Quantum Dots into the Cytosol of Cells Using Cell-Penetrating Poly(disulfide)s.A hybrid computational model to predict chemotactic guidance of growth cones.GABA accumulation causes cell elongation defects and a decrease in expression of genes encoding secreted and cell wall-related proteins in Arabidopsis thaliana
P2860
Q28472985-E720A712-0D0F-4973-BC65-FADFD4D9C3ACQ28475953-FAABA584-C836-47B1-A9DA-37F9A7711C3FQ28535581-BEE9F91E-A4ED-41A2-9D3F-6A0CAD89E960Q30485984-D828E5D5-E03B-417F-A87E-3CA12E17801EQ30488359-A9DED6A5-B7D9-43B4-BD46-7D070AFB878FQ30499739-DEE41B27-EC9D-4CEB-BD3C-5C8BDD52DC9BQ30503662-1F686806-4E7F-4B81-8E62-EFC4F44BFC5BQ30538390-C54C5619-E8B3-4324-9B35-7560106006B1Q30677207-32E29646-58A5-4561-9F66-6403D54D9F12Q33854522-4A4C2B27-E232-4EB5-AB64-21624AC210F7Q34076254-C055FC2D-6653-4600-A4EE-DD971B6021B4Q34076374-354A9B1C-C2E4-4DFF-92FF-6C962F9C1739Q34383874-4E336F88-7D35-4637-9916-4EEA0E3FC7B0Q34746991-E5E4286A-4A9C-478F-937F-7F5B8496A4E4Q34775332-1F71F8CC-0F6F-4CE9-9FF1-BBE74A148568Q35097793-1243ACB3-FE1B-4644-9447-7825634456C5Q35238331-3082B2CE-EF40-4486-A28A-6CEC2D1CDC96Q35239356-792E3451-2105-4D8D-BE46-FFB3CA2AFA99Q35741236-55AE181F-AEB8-428A-90DC-782CA8DCF559Q36295153-743C008F-A1A6-4CB1-B83F-3BC2170B3FC2Q36326789-AB4FDEBB-6F17-4B20-8137-ECCF2EB76567Q36330054-A17DCD61-6E3A-4621-854C-BCBC1F546E78Q36476708-A0553F0B-10E4-4751-8928-7ECC04077476Q36571299-7A7297C2-EC1F-4078-B1B0-61B00B457804Q36619919-BA50C4FA-839D-401C-9787-BD919718E704Q37120089-A3024BC8-E1A4-4A15-895D-4B5B53010BC6Q37120125-9B94B01E-3A9B-44F9-B771-6BB00212EC1AQ37153917-1FC247E9-3AF1-4800-BDC5-58AFE34E269DQ37431815-16DBE044-262B-4024-904F-7305755A7D93Q37862418-6D0757E4-CF09-415D-B204-33810FAB9D72Q38037204-CE6DEF59-8EAC-4AF2-9A48-FDF89C95562DQ38085750-C1F76A01-06FA-4FB1-AD41-9C38E0ED4E73Q38127441-36FCA544-6D11-4F3F-B390-58F138635BACQ38148010-1D52D635-F679-4281-8534-677C24ACBCCEQ38166999-12E8B519-B0D4-4CD8-A478-4EE3761D80B8Q38380533-96CEA926-6C20-48A4-A796-FC3F34E5464BQ39966423-C3297FBA-48EB-4BDE-B6D6-4CCD82FD48B8Q41362676-6A6A6625-074B-40C1-AE9B-93B767BAACC7Q41827440-1D173FB8-2D3A-41ED-8CFB-79F94883495FQ42732464-EAAEDA17-40A0-408C-B59B-10693281EFCC
P2860
Asymmetric redistribution of GABA receptors during GABA gradient sensing by nerve growth cones analyzed by single quantum dot imaging
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Asymmetric redistribution of G ...... by single quantum dot imaging
@ast
Asymmetric redistribution of G ...... by single quantum dot imaging
@en
type
label
Asymmetric redistribution of G ...... by single quantum dot imaging
@ast
Asymmetric redistribution of G ...... by single quantum dot imaging
@en
prefLabel
Asymmetric redistribution of G ...... by single quantum dot imaging
@ast
Asymmetric redistribution of G ...... by single quantum dot imaging
@en
P2093
P2860
P356
P1476
Asymmetric redistribution of G ...... by single quantum dot imaging
@en
P2093
Antoine Triller
Cédric Bouzigues
Mathieu Morel
P2860
P304
11251-11256
P356
10.1073/PNAS.0702536104
P407
P50
P577
2007-06-25T00:00:00Z