Yuguo Yu scite author profile

Traditionally, neuronal operations in the cerebral cortex have been viewed as occurring through the interaction of synaptic potentials in the dendrite and soma, followed by the initiation of an action potential, typically in the axon. Propagation of this action potential to the synaptic terminals is widely believed to be the only form of rapid communication of information between the soma and axonal synapses, and hence to postsynaptic neurons. Here we show that the voltage fluctuations associated with dendrosomatic synaptic activity propagate significant distances along the axon, and that modest changes in the somatic membrane potential of the presynaptic neuron modulate the amplitude and duration of axonal action potentials and, through a Ca2+-dependent mechanism, the average amplitude of the postsynaptic potential evoked by these spikes. These results indicate that synaptic activity in the dendrite and soma controls not only the pattern of action potentials generated, but also the amplitude of the synaptic potentials that these action potentials initiate in local cortical circuits, resulting in synaptic transmission that is a mixture of triggered and graded (analogue) signals.

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Synaptic and Network Mechanisms of Sparse and Reliable Visual Cortical Activity during Nonclassical Receptive Field Stimulation

Haider

Krause

Duque

et al. 2010

Neuron

256

288

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SUMMARY During natural vision, the entire visual field is stimulated by images rich in spatiotemporal structure. Although many visual system studies restrict stimuli to the classical receptive field (CRF), it is known that costimulation of the CRF and the surrounding nonclassical receptive field (nCRF) increases neuronal response sparseness. The cellular and network mechanisms underlying increased response sparseness remain largely unexplored. Here we show that combined CRF + nCRF stimulation increases the sparseness, reliability, and precision of spiking and membrane potential responses in classical regular spiking (RSC) pyramidal neurons of cat primary visual cortex. Conversely, fast-spiking interneurons exhibit increased activity and decreased selectivity during CRF + nCRF stimulation. The increased sparseness and reliability of RSC neuron spiking is associated with increased inhibitory barrages and narrower visually evoked synaptic potentials. Our experimental observations were replicated with a simple computational model, suggesting that network interactions among neuronal subtypes ultimately sharpen recurrent excitation, producing specific and reliable visual responses.

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Cortical Action Potential Backpropagation Explains Spike Threshold Variability and Rapid-Onset Kinetics

Shu²,

2008

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Neocortical action potential responses in vivo are characterized by considerable threshold variability, and thus timing and rate variability, even under seemingly identical conditions. This finding suggests that cortical ensembles are required for accurate sensorimotor integration and processing. Intracellularly, trial-to-trial variability results not only from variation in synaptic activities, but also in the transformation of these into patterns of action potentials. Through simultaneous axonal and somatic recordings and computational simulations, we demonstrate that the initiation of action potentials in the axon initial segment followed by backpropagation of these spikes throughout the neuron results in a distortion of the relationship between the timing of synaptic and action potential events. In addition, this backpropagation also results in an unusually high rate of rise of membrane potential at the foot of the action potential. The distortion of the relationship between the amplitude time course of synaptic inputs and action potential output caused by spike backpropagation results in the appearance of high spike threshold variability at the level of the soma. At the point of spike initiation, the axon initial segment, threshold variability is considerably less. Our results indicate that spike generation in cortical neurons is largely as expected by Hodgkin-Huxley theory and is more precise than previously thought.

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Selective control of cortical axonal spikes by a slowly inactivating K ⁺ current

Shu

Yang

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

196

234

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Neurons are flexible electrophysiological entities in which the distribution and properties of ionic channels control their behaviors. Through simultaneous somatic and axonal whole-cell recording of layer 5 pyramidal cells, we demonstrate a remarkable differential expression of slowly inactivating K ؉ currents. Depolarizing the axon, but not the soma, rapidly activated a lowthreshold, slowly inactivating, outward current that was potently blocked by low doses of 4-aminopyridine, ␣-dendrotoxin, and rTityustoxin-K␣. Block of this slowly inactivating current caused a large increase in spike duration in the axon but only a small increase in the soma and could result in distal axons generating repetitive discharge in response to local current injection. Importantly, this current was also responsible for slow changes in the axonal spike duration that are observed after somatic membrane potential change. These data indicate that low-threshold, slowly inactivating K ؉ currents, containing Kv1.2 ␣ subunits, play a key role in the flexible properties of intracortical axons and may contribute significantly to intracortical processing.axon ͉ cortex ͉ plasticity ͉ synaptic transmission T he precise distribution and properties of ionic channels in cortical neurons strongly influence both the cell's intrinsic electrophysiological properties and its operation within cortical networks. Although the properties of cortical neuronal cell bodies and dendrites have been extensively studied, the study of neocortical axons has been largely confined to recordings from axonal segments near the cell body (e.g., see refs. 1 and 2).Far from being simple static structures that merely communicate spikes, the dynamical properties of intracortical axons may contribute critically to the operation of local cortical networks (reviewed in ref.3). Recently, it was shown that the amplitude of excitatory postsynaptic potentials evoked between excitatory neurons depends on the membrane potential of the presynaptic cell (4, 5). Modest somatic depolarization of presynaptic neocortical pyramidal cells increased the average excitatory postsynaptic potential (EPSP) amplitude evoked in nearby pyramidal cells. Interestingly, simultaneous axonal and somatic patch clamp recordings revealed that these somatic depolarizations increased axonal spike duration over a time course that was similar to the slow component of synaptic facilitation. These results suggest that information transmission within local cortical networks may operate in a mixed

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Properties of Action-Potential Initiation in Neocortical Pyramidal Cells: Evidence From Whole Cell Axon Recordings

Shu¹,

Duque²,

Yu³

et al. 2007

Journal of Neurophysiology

205

216

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Cortical pyramidal cells are constantly bombarded by synaptic activity, much of which arises from other cortical neurons, both in normal conditions and during epileptic seizures. The action potentials generated by barrages of synaptic activity may exhibit a variable site of origin. Here we performed simultaneous whole cell recordings from the soma and axon or soma and apical dendrite of layer 5 pyramidal neurons during normal recurrent network activity (up states), the intrasomatic or intradendritic injection of artificial synaptic barrages, and during epileptiform discharges in vitro. We demonstrate that under all of these conditions, the real or artificial synaptic bombardments propagate through the dendrosomatic-axonal arbor and consistently initiate action potentials in the axon initial segment that then propagate to other parts of the cell. Action potentials recorded intracellularly in vivo during up states and in response to visual stimulation exhibit properties indicating that they are typically initiated in the axon. Intracortical axons were particularly well suited to faithfully follow the generation of action potentials by the axon initial segment. Action-potential generation was more reliable in the distal axon than at the soma during epileptiform activity. These results indicate that the axon is the preferred site of action-potential initiation in cortical pyramidal cells, both in vivo and in vitro, with state-dependent back propagation through the somatic and dendritic compartments.

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Yuguo Yu

Modulation of intracortical synaptic potentials by presynaptic somatic membrane potential

Synaptic and Network Mechanisms of Sparse and Reliable Visual Cortical Activity during Nonclassical Receptive Field Stimulation

Cortical Action Potential Backpropagation Explains Spike Threshold Variability and Rapid-Onset Kinetics

Selective control of cortical axonal spikes by a slowly inactivating K ⁺ current

Properties of Action-Potential Initiation in Neocortical Pyramidal Cells: Evidence From Whole Cell Axon Recordings

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Yuguo Yu

Modulation of intracortical synaptic potentials by presynaptic somatic membrane potential

Synaptic and Network Mechanisms of Sparse and Reliable Visual Cortical Activity during Nonclassical Receptive Field Stimulation

Cortical Action Potential Backpropagation Explains Spike Threshold Variability and Rapid-Onset Kinetics

Selective control of cortical axonal spikes by a slowly inactivating K + current

Properties of Action-Potential Initiation in Neocortical Pyramidal Cells: Evidence From Whole Cell Axon Recordings

Contact Info

Product

Resources

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Selective control of cortical axonal spikes by a slowly inactivating K ⁺ current