Backpropagation of physiological spike trains in neocortical pyramidal neurons: Implications for temporal coding in dendrites

dc.contributor.authorWilliams, Stephen
dc.contributor.authorStuart, Gregory J
dc.date.accessioned2015-12-07T22:44:01Z
dc.date.available2015-12-07T22:44:01Z
dc.date.issued2000
dc.date.updated2015-12-07T11:20:24Z
dc.description.abstractIn vivo neocortical neurons fire apparently random trains of action potentials in response to sensory stimuli. Does this randomness represent a signal or noise around a mean firing rate? Here we use the timing of action potential trains recorded in vivo to explore the dendric consequences of physiological patterns of action potential firing in neocortical pyramidal neurons in vitro. We find that action potentials evoked by physiological patterns of firing backpropagate threefold to fourfold more effectively into the distal apical dendrites (>600 μm from the soma) than action potential trains reflecting their mean firing rate. This amplification of backpropagation was maximal during high-frequency components of physiological spike trians (80-300 Hz). The disparity between backpropagation during physiological and mean firing patterns was dramatically reduced by dendritic hyperpolarization. Consistent with this voltage dependence, dendritic depolarization amplified single action potentials by fourfold to seven-fold, with a spatial profile strikingly similar to the amplification of physiological spike trains. Local blockade of distal dendritic sodium channels substantially reduced amplification of physiological spike trains, but did not significantly alter action potential trains reflecting their mean firing rate. Dendritic electrogenesis during physiological spike trains was also reduced by the blockade of calcium channels. We conclude that amplification of backpropagating action potentials during physiological spike trains is mediated by frequency-dependent supralinear temporal summation, generated by the recruitment of distal dendritic sodium and calcium channels. Together these data indicate that the temporal nature of physiological patterns of action potential firing contains a signal that is transmitted effectively throughout the dendritic tree.
dc.identifier.issn0270-6474
dc.identifier.urihttp://hdl.handle.net/1885/25030
dc.publisherSociety for Neuroscience
dc.sourceJournal of Neuroscience
dc.subjectKeywords: calcium channel; sodium channel; animal experiment; animal model; article; channel gating; controlled study; dendrite; in vivo study; nerve potential; nonhuman; priority journal; pyramidal nerve cell; rat; sensory stimulation; signal transduction; Action Action potential; Dendrite; Firing pattern; Neocortex; Patch clamp; Sodium channel
dc.titleBackpropagation of physiological spike trains in neocortical pyramidal neurons: Implications for temporal coding in dendrites
dc.typeJournal article
local.bibliographicCitation.lastpage8246
local.bibliographicCitation.startpage8238
local.contributor.affiliationWilliams, Stephen, College of Medicine, Biology and Environment, ANU
local.contributor.affiliationStuart, Gregory J, College of Medicine, Biology and Environment, ANU
local.contributor.authoremailu8807467@anu.edu.au
local.contributor.authoruidWilliams, Stephen, u9716958
local.contributor.authoruidStuart, Gregory J, u8807467
local.description.notesImported from ARIES
local.description.refereedYes
local.identifier.absfor110902 - Cellular Nervous System
local.identifier.ariespublicationMigratedxPub36
local.identifier.citationvolume20
local.identifier.scopusID2-s2.0-0034668846
local.identifier.uidSubmittedByMigrated
local.type.statusPublished Version

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