Motile axonal mitochondria contribute to the variability of presynaptic strength.
about
PACAP27 is protective against tat-induced neurotoxicityThe rise of mitochondria in medicineAlterations in Mitochondrial Quality Control in Alzheimer's DiseaseThe axonal cytoskeleton: from organization to functionMitochondrial Dysfunction Contributes to the Pathogenesis of Alzheimer's DiseaseAxonal transport: cargo-specific mechanisms of motility and regulationMitochondrial fission is an acute and adaptive response in injured motor neuronsMitochondrial function in hypoxic ischemic injury and influence of agingCentral presynaptic terminals are enriched in ATP but the majority lack mitochondriaFacilitation of axon regeneration by enhancing mitochondrial transport and rescuing energy deficitsOptogenetic control of organelle transport and positioningMitochondrial Aspects of Synaptic Dysfunction in Alzheimer's Disease.Neuroglobin Can Prevent or Reverse Glaucomatous Progression in DBA/2J MicePharmacologic rescue of axon growth defects in a human iPSC model of hereditary spastic paraplegia SPG3A.The mitochondrial complex V-associated large-conductance inner membrane current is regulated by cyclosporine and dexpramipexoleBMP signaling and microtubule organization regulate synaptic strengthRegulation of mitochondrial transport in neurons.Chronic Fluoxetine Induces the Enlargement of Perforant Path-Granule Cell Synapses in the Mouse Dentate GyrusThe role of mitochondrially derived ATP in synaptic vesicle recyclingLKB1 Regulates Mitochondria-Dependent Presynaptic Calcium Clearance and Neurotransmitter Release Properties at Excitatory Synapses along Cortical AxonsMitochondrial functions modulate neuroendocrine, metabolic, inflammatory, and transcriptional responses to acute psychological stressUnderstanding the susceptibility of dopamine neurons to mitochondrial stressors in Parkinson's disease.Mitochondrial Calcium Uptake Modulates Synaptic Vesicle Endocytosis in Central Nerve TerminalsDifferential responses to lithium in hyperexcitable neurons from patients with bipolar disorder.A systems approach identifies networks and genes linking sleep and stress: implications for neuropsychiatric disorders.The ageing neuromuscular system and sarcopenia: a mitochondrial perspective.Impaired Mitochondrial Dynamics and Mitophagy in Neuronal Models of Tuberous Sclerosis Complex.Mitochondria impact brain function and cognition.Mitochondrial trafficking and anchoring in neurons: New insight and implications.Cytoskeletal and signaling mechanisms of neurite formation.Bcl-xL in neuroprotection and plasticity.Inhibiting the Mitochondrial Calcium Uniporter during Development Impairs Memory in Adult Drosophila.Astroglial glutamate transporters coordinate excitatory signaling and brain energetics.Adaptive responses of neuronal mitochondria to bioenergetic challenges: Roles in neuroplasticity and disease resistance.Mitochondria Localize to Injured Axons to Support Regeneration.The Interplay of Axonal Energy Homeostasis and Mitochondrial Trafficking and Anchoring.Isolated Mitochondria Transfer Improves Neuronal Differentiation of Schizophrenia-Derived Induced Pluripotent Stem Cells and Rescues Deficits in a Rat Model of the Disorder.Using FRAP or FRAPA to Visualize the Movement of Fluorescently Labeled Proteins or Cellular Organelles in Live Cultured Neurons Transformed with Adeno-Associated Viruses.Miro1-dependent mitochondrial positioning drives the rescaling of presynaptic Ca2+ signals during homeostatic plasticity.Mitochondrial support of persistent presynaptic vesicle mobilization with age-dependent synaptic growth after LTP.
P2860
Q24293525-40B05581-E1E5-4746-A6DA-1076CF253D3CQ26740014-D636F7F0-2908-4704-A7A1-B0E64D42A6E9Q26768215-589F0104-364A-4FBB-8B17-FA2FDEAEFE22Q26796245-8D6A0A1D-A7CF-4C00-BF83-5B046120B6DCQ26801929-0129DDC0-575F-4ECC-BD22-1F4B2F2D340EQ26827748-CD9E6759-A95E-49CB-A2CB-1748A5A2544AQ27335694-C4EEDB52-6DFC-4938-9406-F9A4782DACB8Q28396663-0E50D956-D0ED-46DD-BCA7-0B2376664753Q28546888-53C3B919-3653-4BF1-B825-CC0AA3E4E3D7Q30780429-732DEA88-F467-4F04-8950-7C93C3D5DF53Q30822029-EA2EFA0C-171C-41C9-B2C5-781DE5BC3A3EQ33585950-D6E38834-7EED-4BD9-9CF9-F44C2A2885A8Q33681127-376F7E1D-F10F-48E4-8926-27A401AA106DQ34307291-A5735952-242F-472E-AE2E-2EB8CBDE5548Q34785470-2A79F1E5-04E8-44F5-B710-804E2B26117DQ35205303-83F2F9B5-9BBB-4287-A87A-BAC231A435F5Q35612981-FE0D737F-8C3A-45D5-9E89-38A8D1F58690Q35898760-59EABAA0-06A7-4FF2-888D-C0F2588AAA41Q36049861-77C3B93F-C000-410A-AA28-FFF2179F9B7EQ36080439-330F818E-4424-4FDF-A498-482DFE246B39Q36354896-F54B254A-EFB2-4ABF-9BD9-E93C1EE450A2Q36372732-471694CC-FAC0-4539-B89E-A140C63D9AC7Q36518230-CFF236C5-C070-497C-8E1E-436862027F5EQ36546243-E2B2602B-4EDA-4BFF-9984-A3B287C97F80Q36702269-5A3847BB-4A90-41E5-9EF8-19F42F154A1CQ37172598-E0D7209C-3C46-4296-96E0-5038D8509A25Q37364126-3DEB2026-9656-4709-AB7A-BEE674CCBD20Q37475044-BAF3DDBC-0212-4FB1-8E24-BFB91646124FQ37677601-053F912E-478F-4A33-AF73-A25E6DCCD8ADQ38235653-0F6BBE98-92CE-4804-9E05-89DEBDE8B387Q38256367-81399C4E-DB37-4512-849E-9A9D27FEA232Q38436297-99979E92-41A0-4B44-AC76-06A803DCD6B8Q38788230-D60B3BD8-3ACD-4BC1-853D-E9203116C9D7Q39026385-911B16FF-43FF-4932-907E-372E21FE359FQ39069151-448327B2-C5D2-43E3-BBD6-D33BE1CB47E1Q39147055-12B75ED7-AD27-4B46-9C54-D0D538E550AEQ40170953-4C6FBCE6-2BB4-4DD2-A541-A2E48B0BB41BQ40579127-6341AED6-38FC-4E98-A9DB-1FA48AF0F640Q41865556-3CE84166-7F7A-4E62-BF0D-CFE527ED4AA2Q42089946-0369B669-4FA5-42AC-AED9-FE34FC8E47F9
P2860
Motile axonal mitochondria contribute to the variability of presynaptic strength.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 25 July 2013
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Motile axonal mitochondria contribute to the variability of presynaptic strength.
@en
Motile axonal mitochondria contribute to the variability of presynaptic strength.
@nl
type
label
Motile axonal mitochondria contribute to the variability of presynaptic strength.
@en
Motile axonal mitochondria contribute to the variability of presynaptic strength.
@nl
prefLabel
Motile axonal mitochondria contribute to the variability of presynaptic strength.
@en
Motile axonal mitochondria contribute to the variability of presynaptic strength.
@nl
P2093
P2860
P1433
P1476
Motile axonal mitochondria contribute to the variability of presynaptic strength.
@en
P2093
Haifa Qiao
Ping-Yue Pan
Yanmin Chen
Zu-Hang Sheng
P2860
P304
P356
10.1016/J.CELREP.2013.06.040
P577
2013-07-25T00:00:00Z