about
Drosophila as a genetic and cellular model for studies on axonal growthProperties of the force exerted by filopodia and lamellipodia and the involvement of cytoskeletal componentsEffects of cordycepin on the microglia-overactivation-induced impairments of growth and development of hippocampal cultured neuronsThe role of cytoskeleton in organizing growth cones: a microfilament-associated growth cone component depends upon microtubules for its localization.Actin-dependent anterograde movement of growth-cone-like structures along growing hippocampal axons: a novel form of axonal transport?Glioblastoma motility occurs in the absence of actin polymer.Less than 5 Netrin-1 molecules initiate attraction but 200 Sema3A molecules are necessary for repulsion.Comparison of the force exerted by hippocampal and DRG growth cones.Force generation in lamellipodia is a probabilistic process with fast growth and retraction events.Neurotrophins and the dynamic regulation of the neuronal cytoskeleton.Microtubule polarity reversal accompanies regrowth of amputated neuritesAxonal protein synthesis and degradation are necessary for efficient growth cone regeneration.Genes regulating touch cell development in Caenorhabditis elegans.Microtubule depolymerization in Caenorhabditis elegans touch receptor neurons reduces gene expression through a p38 MAPK pathwayGuiding neuronal growth cones using Ca2+ signals.Rapid retraction of neurites by sensory neurons in response to increased concentrations of nerve growth factor.Differences in the organization of actin in the growth cones compared with the neurites of cultured neurons from chick embryos.Inhibition of neurite initiation and growth by taxolSpatial organization of axonal microtubules.Tension and compression in the cytoskeleton of PC 12 neurites.Polarized compartmentalization of organelles in growth cones from developing optic tectumTension and compression in the cytoskeleton of PC-12 neurites. II: Quantitative measurements.A new perspective on microtubules and axon growth.Microtubule behavior in the growth cones of living neurons during axon elongation.Processes induced by tau expression in Sf9 cells have an axon-like microtubule organization.Function and translational regulation of mRNA in developing axonsCalcineurin is associated with the cytoskeleton of cultured neurons and has a role in the acquisition of polarity.PTRN-1, a microtubule minus end-binding CAMSAP homolog, promotes microtubule function in Caenorhabditis elegans neurons.The elementary events underlying force generation in neuronal lamellipodia.Changes in axonally transported proteins during axon regeneration in toad retinal ganglion cells.Structural and functional diversity in the neuronal microtubules of Caenorhabditis elegans.Providing positional information with active transport on dynamic microtubulesRegulation of cell polarity by microtubules in fission yeastInduction of growth cone formation by transient and localized increases of intracellular proteolytic activity.Tanshinone IIA Rescued the Impairments of Primary Hippocampal Neurons Induced by BV2 Microglial Over-Activation.Resveratrol Rescues the Impairments of Hippocampal Neurons Stimulated by Microglial Over-Activation In Vitro.Vimentin and 70K neurofilament protein co-exist in embryonic neurones from spinal ganglia.A regulatory role for sphingolipids in neuronal growth. Inhibition of sphingolipid synthesis and degradation have opposite effects on axonal branching.
P2860
Q21203077-85EDFEC5-E09D-4517-90B1-BF9D0FD6DF29Q27302614-1B672C15-9391-400C-AA4F-9CB3D053B76FQ28546945-18073532-882C-47F7-AFEE-604E23042723Q30442300-5C62B1BD-6B2D-48A6-B7CA-260D3F802952Q30472226-6BF784E3-F593-4881-8CFB-599FE7F44E17Q30502001-9EFF759D-7EF3-4795-BA4A-5603DF3F0965Q30525154-01E8ECFB-EF7D-4EFA-B083-BEF10964AB5AQ31133452-20642FD5-4FED-41E8-973F-7A719C9D9169Q33767660-F4811975-1773-4D7C-8E33-830467FAF089Q33996747-F170147F-48B0-4437-8566-DB0923406920Q34333742-660D8655-07E4-4586-99C9-2475C7B43674Q34383999-165C73FA-AE7B-4071-AE3E-4EA31BB71F60Q34612379-087DBE89-4780-4919-A322-3EA1E7DE8424Q34652394-9A5CA0F8-DC67-4150-847B-3D5DA953CB32Q35795892-4C063E4C-49E9-4367-A062-697DD7D7D371Q36201508-178CE819-F2BF-4F08-996B-8D2FD88C55BBQ36207966-3AAF5D02-D817-4654-A403-950A2A95A554Q36210577-0BFD3370-3E71-4547-A882-28636793DF4CQ36211065-C334870B-97D4-419E-BFBF-EE8F6EC5F64CQ36212806-18E86503-5AA0-4136-B445-4149150981CFQ36213661-88384F50-1B70-42B6-8F18-1185CE688954Q36219156-60B6DF66-7757-42A3-BF11-BC0FB5D352D0Q36232975-1867855B-3F21-4850-9477-5DDA5874EE68Q36530386-5C1875F6-F062-40E3-9428-71D4B6CABDACQ36530642-4157D4A3-478F-4CEE-A705-4AA1C6FE9DDAQ36810486-772161F7-30E5-4A97-B19B-DC2CE87D57C5Q37376728-B5580C40-3EB8-4F40-A7B5-3830130C2B8FQ37599085-BE96201A-7331-4E9E-BB49-BBF27B131036Q39871695-37EBF302-16A4-44E6-A2EC-F1D8027754A5Q41353399-9D1E0958-C53B-4D32-89A5-319298B5F57FQ41376858-8034A8A9-575B-400F-85E1-65F564A0A023Q41995049-642DBC36-AE55-4770-A68B-ED5B0F672810Q42633413-7D38A081-0F91-4DB3-AB4A-B6D87757EDB6Q42796176-AB647F84-902F-4630-AC23-5CDDE6BE6E12Q48159087-9F0B6CC3-DF1A-4D89-8559-A83DF00A8953Q48217856-42075AA1-A179-4124-9627-B0EAAB5B2EDCQ48961202-3702B378-E033-476A-9D3F-1F6AAE0444CAQ49165230-2781E0EF-969F-495A-8C43-2AAC58879B76
P2860
description
1978 nî lūn-bûn
@nan
1978年の論文
@ja
1978年論文
@yue
1978年論文
@zh-hant
1978年論文
@zh-hk
1978年論文
@zh-mo
1978年論文
@zh-tw
1978年论文
@wuu
1978年论文
@zh
1978年论文
@zh-cn
name
Growth cone formation in cultures of sensory neurons
@ast
Growth cone formation in cultures of sensory neurons
@en
type
label
Growth cone formation in cultures of sensory neurons
@ast
Growth cone formation in cultures of sensory neurons
@en
prefLabel
Growth cone formation in cultures of sensory neurons
@ast
Growth cone formation in cultures of sensory neurons
@en
P2093
P2860
P356
P1476
Growth cone formation in cultures of sensory neurons
@en
P2093
P2860
P304
P356
10.1073/PNAS.75.10.5226
P407
P577
1978-10-01T00:00:00Z