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dc.contributor.authorKelley, Craig
dc.contributor.authorDura-Bernal, Salvador
dc.contributor.authorNeymotin, Samuel A
dc.contributor.authorAntic, Srdjan D
dc.contributor.authorCarnevale, Nicholas T
dc.contributor.authorMigliore, Michele
dc.contributor.authorLytton, William W
dc.date.accessioned2023-04-10T15:41:21Z
dc.date.available2023-04-10T15:41:21Z
dc.date.issued2021-03-10
dc.identifier.citationKelley C, Dura-Bernal S, Neymotin SA, Antic SD, Carnevale NT, Migliore M, Lytton WW. Effects of Ih and TASK-like shunting current on dendritic impedance in layer 5 pyramidal-tract neurons. J Neurophysiol. 2021 Apr 1;125(4):1501-1516. doi: 10.1152/jn.00015.2021. Epub 2021 Mar 10. PMID: 33689489; PMCID: PMC8282219.en_US
dc.identifier.eissn1522-1598
dc.identifier.doi10.1152/jn.00015.2021
dc.identifier.pmid33689489
dc.identifier.urihttp://hdl.handle.net/20.500.12648/8560
dc.description.abstractPyramidal neurons in neocortex have complex input-output relationships that depend on their morphologies, ion channel distributions, and the nature of their inputs, but which cannot be replicated by simple integrate-and-fire models. The impedance properties of their dendritic arbors, such as resonance and phase shift, shape neuronal responses to synaptic inputs and provide intraneuronal functional maps reflecting their intrinsic dynamics and excitability. Experimental studies of dendritic impedance have shown that neocortical pyramidal tract neurons exhibit distance-dependent changes in resonance and impedance phase with respect to the soma. We, therefore, investigated how well several biophysically detailed multicompartment models of neocortical layer 5 pyramidal tract neurons reproduce the location-dependent impedance profiles observed experimentally. Each model tested here exhibited location-dependent impedance profiles, but most captured either the observed impedance amplitude or phase, not both. The only model that captured features from both incorporates hyperpolarization-activated cyclic nucleotide-gated (HCN) channels and a shunting current, such as that produced by Twik-related acid-sensitive K (TASK) channels. TASK-like channel density in this model was proportional to local HCN channel density. We found that although this shunting current alone is insufficient to produce resonance or realistic phase response, it modulates all features of dendritic impedance, including resonance frequencies, resonance strength, synchronous frequencies, and total inductive phase. We also explored how the interaction of HCN channel current () and a TASK-like shunting current shape synaptic potentials and produce degeneracy in dendritic impedance profiles, wherein different combinations of and shunting current can produce the same impedance profile. We simulated chirp current stimulation in the apical dendrites of 5 biophysically detailed multicompartment models of neocortical pyramidal tract neurons and found that a combination of HCN channels and TASK-like channels produced the best fit to experimental measurements of dendritic impedance. We then explored how HCN and TASK-like channels can shape the dendritic impedance as well as the voltage response to synaptic currents.
dc.language.isoenen_US
dc.relation.urlhttps://journals.physiology.org/doi/full/10.1152/jn.00015.2021en_US
dc.rightsAttribution-NonCommercial-NoDerivatives 4.0 International*
dc.rights.urihttp://creativecommons.org/licenses/by-nc-nd/4.0/*
dc.subjectTwik-related acid-sensitive K+(TASK) channelsen_US
dc.subjecth-current (Ih)en_US
dc.subjectimpedanceen_US
dc.subjectpyramidal tract neuronsen_US
dc.subjectresonanceen_US
dc.titleEffects of and TASK-like shunting current on dendritic impedance in layer 5 pyramidal-tract neurons.en_US
dc.typeArticle/Reviewen_US
dc.source.journaltitleJournal of neurophysiologyen_US
dc.source.volume125
dc.source.issue4
dc.source.beginpage1501
dc.source.endpage1516
dc.source.countryUnited States
dc.source.countryUnited States
dc.source.countryUnited States
dc.source.countryUnited States
dc.source.countryUnited States
dc.source.countryUnited States
dc.description.versionVoRen_US
refterms.dateFOA2023-04-10T15:41:22Z
html.description.abstractPyramidal neurons in neocortex have complex input-output relationships that depend on their morphologies, ion channel distributions, and the nature of their inputs, but which cannot be replicated by simple integrate-and-fire models. The impedance properties of their dendritic arbors, such as resonance and phase shift, shape neuronal responses to synaptic inputs and provide intraneuronal functional maps reflecting their intrinsic dynamics and excitability. Experimental studies of dendritic impedance have shown that neocortical pyramidal tract neurons exhibit distance-dependent changes in resonance and impedance phase with respect to the soma. We, therefore, investigated how well several biophysically detailed multicompartment models of neocortical layer 5 pyramidal tract neurons reproduce the location-dependent impedance profiles observed experimentally. Each model tested here exhibited location-dependent impedance profiles, but most captured either the observed impedance amplitude or phase, not both. The only model that captured features from both incorporates hyperpolarization-activated cyclic nucleotide-gated (HCN) channels and a shunting current, such as that produced by Twik-related acid-sensitive K (TASK) channels. TASK-like channel density in this model was proportional to local HCN channel density. We found that although this shunting current alone is insufficient to produce resonance or realistic phase response, it modulates all features of dendritic impedance, including resonance frequencies, resonance strength, synchronous frequencies, and total inductive phase. We also explored how the interaction of HCN channel current () and a TASK-like shunting current shape synaptic potentials and produce degeneracy in dendritic impedance profiles, wherein different combinations of and shunting current can produce the same impedance profile. We simulated chirp current stimulation in the apical dendrites of 5 biophysically detailed multicompartment models of neocortical pyramidal tract neurons and found that a combination of HCN channels and TASK-like channels produced the best fit to experimental measurements of dendritic impedance. We then explored how HCN and TASK-like channels can shape the dendritic impedance as well as the voltage response to synaptic currents.
dc.description.institutionSUNY Downstateen_US
dc.description.departmentNathan Kline Institute for Psychiatric Researchen_US
dc.description.departmentPhysiology and Pharmacologyen_US
dc.description.degreelevelN/Aen_US
dc.identifier.journalJournal of neurophysiology


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