Your search keyword '"Dendritic spike"' showing total 793 results

151. Locally Balanced Dendritic Integration by Short-Term Synaptic Plasticity and Active Dendritic Conductances

Author

Vladislav Volman, Terrence J. Sejnowski, Eshel Ben-Jacob, and Herbert Levine

Subjects

Physiology, Spike train, Models, Neurological, Biophysics, Neural Conduction, Action Potentials, Dendritic branch, Hippocampal formation, Inhibitory postsynaptic potential, Animals, Computer Simulation, CA1 Region, Hippocampal, Probability, Membrane potential, Dendritic spike, Neuronal Plasticity, Chemistry, Pyramidal Cells, General Neuroscience, food and beverages, Articles, Dendrites, Electric Stimulation, Synapses, Synaptic plasticity, Excitatory postsynaptic potential, Calcium, Calcium Channels, Neuroscience

Abstract

The high degree of variability observed in spike trains and membrane potentials of pyramidal neurons in vivo is thought to be a consequence of a balance between excitatory and inhibitory inputs, which depends on the dynamics of the network. We simulated synaptic currents and ion channels in a reconstructed hippocampal CA1 pyramidal cell and show here that a local balance can be achieved on a dendritic branch with a different mechanism, based on presynaptic depression of quantal release interacting with active dendritic conductances. This mechanism, which does not require synaptic inhibition, allows each dendritic branch to remain sensitive to correlated synaptic inputs, induces a high degree of variability in the output spike train, and can be combined with other balance mechanisms based on network dynamics. This hypothesis makes a testable prediction for the cause of the observed variability in the firing of hippocampal place cells.

Published

2009

152. Complementary Theta Resonance Filtering by Two Spatially Segregated Mechanisms in CA1 Hippocampal Pyramidal Neurons

Author

Hua Hu, Lyle J. Graham, Johan F. Storm, and Koen Vervaeke

Subjects

Male, Membrane potential, Dendritic spike, Subthreshold conduction, Pyramidal Cells, General Neuroscience, Action Potentials, Dendrite, Articles, Hippocampal formation, Biology, Membrane Potentials, Rats, medicine.anatomical_structure, medicine, Animals, Soma, Neuron, Rats, Wistar, Theta Rhythm, Neural coding, CA1 Region, Hippocampal, Neuroscience

Abstract

Synaptic input to a neuron may undergo various filtering steps, both locally and during transmission to the soma. Using simultaneous whole-cell recordings from soma and apical dendrites from rat CA1 hippocampal pyramidal cells, and biophysically detailed modeling, we found two complementary resonance (bandpass) filters of subthreshold voltage signals. Both filters favor signals in the theta (3–12 Hz) frequency range, but have opposite location, direction, and voltage dependencies: (1) dendritic H-resonance, caused by h/HCN-channels, filters signals propagating from soma to dendrite when the membrane potential is close to rest; and (2) somatic M-resonance, caused by M/Kv7/KCNQ and persistent Na+(NaP) channels, filters signals propagating from dendrite to soma when the membrane potential approaches spike threshold. Hippocampal pyramidal cells participate in theta network oscillations during behavior, and we suggest that that these dual, polarized theta resonance mechanisms may convey voltage-dependent tuning of theta-mediated neural coding in the entorhinal/hippocampal system during locomotion, spatial navigation, memory, and sleep.

Published

2009

153. Postnatal Development of Dendritic Synaptic Integration in Rat Neocortical Pyramidal Neurons

Author

Stephen R. Williams and Susan E. Atkinson

Subjects

Male, Aging, Patch-Clamp Techniques, Potassium Channels, Dendritic spine, Physiology, Action Potentials, Cyclic Nucleotide-Gated Cation Channels, Neocortex, In Vitro Techniques, Membrane Potentials, Apical dendrite, Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels, medicine, HCN channel, Animals, Rats, Wistar, Analysis of Variance, Dendritic spike, biology, Chemistry, Pyramidal Cells, General Neuroscience, Excitatory Postsynaptic Potentials, Dendrites, Articles, Immunohistochemistry, Rats, Dendritic filopodia, medicine.anatomical_structure, Animals, Newborn, Synapses, biology.protein, Excitatory postsynaptic potential, Soma, Neuroscience

Abstract

The dendritic tree of layer 5 (L5) pyramidal neurons spans the neocortical layers, allowing the integration of intra- and extracortical synaptic inputs. Here we investigate the postnatal development of the integrative properties of rat L5 pyramidal neurons using simultaneous whole cell recording from the soma and distal apical dendrite. In young (P9-10) neurons, apical dendritic excitatory synaptic input powerfully drove action potential output by efficiently summating at the axonal site of action potential generation. In contrast, in mature (P25-29) neurons, apical dendritic excitatory input provided little direct depolarization at the site of action potential generation but was integrated locally in the apical dendritic tree leading to the generation of dendritic spikes. Consequently, over the first postnatal month the fraction of action potentials driven by apical dendritic spikes increased dramatically. This developmental remodeling of the integrative operations of L5 pyramidal neurons was controlled by a >10-fold increase in the density of apical dendritic Hyperpolarization-activated cyclic nucleotide (HCN)-gated channels found in cell-attached patches or by immunostaining for the HCN channel isoform HCN1. Thus an age-dependent increase in apical dendritic HCN channel density ensures that L5 pyramidal neurons develop from compact temporal integrators to compartmentalized integrators of basal and apical dendritic synaptic input.

Published

2009

154. Maximization of the connectivity repertoire as a statistical principle governing the shapes of dendritic arbors

Author

Quan Wen, Guy N. Elston, Armen Stepanyants, Dmitri B. Chklovskii, and Alexander Y. Grosberg

Subjects

Physics, Dendritic spike, Multidisciplinary, Extramural, Pyramidal Cells, Repertoire, Models, Neurological, fungi, Action Potentials, Dendrites, Haplorhini, Maximization, Biological Sciences, Axons, Rats, Purkinje Cells, medicine.anatomical_structure, nervous system, Neural Pathways, Synapses, medicine, Animals, Pyramidal cell, Neuroscience, Algorithms

Abstract

The shapes of dendritic arbors are fascinating and important, yet the principles underlying these complex and diverse structures remain unclear. Here, we analyzed basal dendritic arbors of 2,171 pyramidal neurons sampled from mammalian brains and discovered 3 statistical properties: the dendritic arbor size scales with the total dendritic length, the spatial correlation of dendritic branches within an arbor has a universal functional form, and small parts of an arbor are self-similar. We proposed that these properties result from maximizing the repertoire of possible connectivity patterns between dendrites and surrounding axons while keeping the cost of dendrites low. We solved this optimization problem by drawing an analogy with maximization of the entropy for a given energy in statistical physics. The solution is consistent with the above observations and predicts scaling relations that can be tested experimentally. In addition, our theory explains why dendritic branches of pyramidal cells are distributed more sparsely than those of Purkinje cells. Our results represent a step toward a unifying view of the relationship between neuronal morphology and function.

Published

2009

155. Pathway Interactions and Synaptic Plasticity in the Dendritic Tuft Regions of CA1 Pyramidal Neurons

Author

Hiroto Takahashi and Jeffrey C. Magee

Subjects

Patch-Clamp Techniques, Dendritic tuft, Neuroscience(all), Long-Term Potentiation, Biophysics, Spider Venoms, Tetrodotoxin, Biology, In Vitro Techniques, Hippocampus, MOLNEURO, Membrane Potentials, Rats, Sprague-Dawley, Plateau potentials, Neural Pathways, medicine, Animals, Anesthetics, Local, Dendritic spike, Neuronal Plasticity, Perforant Pathway, General Neuroscience, Pyramidal Cells, Long-term potentiation, Dendrites, Perforant path, Calcium Channel Blockers, Electric Stimulation, Rats, medicine.anatomical_structure, nervous system, Animals, Newborn, Inhibitory Postsynaptic Potentials, Schaffer collateral, Synaptic plasticity, Synapses, CELLBIO, Calcium, Neuroscience, Excitatory Amino Acid Antagonists

Abstract

SummaryInput comparison is thought to occur in many neuronal circuits, including the hippocampus, where functionally important interactions between the Schaffer collateral and perforant pathways have been hypothesized. We investigated this idea using multisite, whole-cell recordings and Ca2+ imaging and found that properly timed, repetitive stimulation of both pathways results in the generation of large plateau potentials in distal dendrites of CA1 pyramidal neurons. These dendritic plateau potentials produce widespread Ca2+ influx, large after-depolarizations, burst firing output, and long-term potentiation of perforant path synapses. Plateau duration is directly related to the strength and temporal overlap of pathway activation and involves back-propagating action potentials and both NMDA receptors and voltage-gated Ca2+ channels. Thus, the occurrence of highly correlated SC and PP input to CA1 is signaled by a dramatic change in output mode and an increase in input efficacy, all induced by a large plateau potential in the distal dendrites of CA1 pyramidal neurons.

Published

2009

156. Dendritic Excitability and Neuronal Morphology as Determinants of Synaptic Efficacy

Author

Alexander O. Komendantov and Giorgio A. Ascoli

Subjects

Physiology, Models, Neurological, Biophysics, Hippocampus, Dendrite, Retinal ganglion, Biophysical Phenomena, medicine, Animals, Premovement neuronal activity, Neurons, Dendritic spike, Chemistry, General Neuroscience, Articles, Dendrites, Synaptic Potentials, Granule cell, Electric Stimulation, medicine.anatomical_structure, Spinal Cord, Synapses, Excitatory postsynaptic potential, Soma, Ion Channel Gating, Neuroscience

Abstract

The ability to trigger neuronal spiking activity is one of the most important functional characteristics of synaptic inputs and can be quantified as a measure of synaptic efficacy (SE). Using model neurons with both highly simplified and real morphological structures (from a single cylindrical dendrite to a hippocampal granule cell, CA1 pyramidal cell, spinal motoneuron, and retinal ganglion neurons) we found that SE of excitatory inputs decreases with the distance from the soma and active nonlinear properties of the dendrites can counterbalance this global effect of attenuation. This phenomenon is frequency dependent, with a more prominent gain in SE observed at lower levels of background input–output neuronal activity. In contrast, there are no significant differences in SE between passive and active dendrites under higher frequencies of background activity. The influence of the nonuniform distribution of active properties on SE is also more prominent at lower background frequencies. In models with real morphologies, the effect of active dendritic conductances becomes more dramatic and inverts the SE relationship between distal and proximal locations. In active dendrites, distal synapses have higher efficacy than that of proximal ones because of arising dendritic spiking in thin branches with high-input resistance. Lower levels of dendritic excitability can make SE independent of the distance from the soma. Although increasing dendritic excitability may boost SE of distal synapses in real neurons, it may actually reduce overall SE. The results are robust with respect to morphological variation and biophysical properties of the model neurons. The model of CA1 pyramidal cell with realistic distributions of dendritic conductances demonstrated important roles of hyperpolarization-activated (h-) current and A-type K+ current in controlling the efficacy of single synaptic inputs and overall SE differently in basal and apical dendrites.

Published

2009

157. Quantitative Assessment of the Distributions of Membrane Conductances Involved in Action Potential Backpropagation Along Basal Dendrites

Author

Srdjan D. Antic and Corey D. Acker

Subjects

Patch-Clamp Techniques, Physiology, Models, Neurological, Action Potentials, Prefrontal Cortex, Nonsynaptic plasticity, Tetrodotoxin, In Vitro Techniques, Neural backpropagation, Biophysical Phenomena, Styrenes, Rats, Sprague-Dawley, Basal (phylogenetics), chemistry.chemical_compound, Potassium Channel Blockers, Animals, Patch clamp, 4-Aminopyridine, Prefrontal cortex, Neurons, Dendritic spike, Chemistry, General Neuroscience, Electric Conductivity, Signal Processing, Computer-Assisted, Articles, Dendrites, Electric Stimulation, Rats, Animals, Newborn, Excitatory postsynaptic potential, Calcium, Ion Channel Gating, Neuroscience, Sodium Channel Blockers

Abstract

Basal dendrites of prefrontal cortical neurons receive strong synaptic drive from recurrent excitatory synaptic inputs. Synaptic integration within basal dendrites is therefore likely to play an important role in cortical information processing. Both synaptic integration and synaptic plasticity depend crucially on dendritic membrane excitability and the backpropagation of action potentials. We carried out multisite voltage-sensitive dye imaging of membrane potential transients from thin basal branches of prefrontal cortical pyramidal neurons before and after application of channel blockers. We found that backpropagating action potentials (bAPs) are predominantly controlled by voltage-gated sodium and A-type potassium channels. In contrast, pharmacologically blocking the delayed rectifier potassium, voltage-gated calcium, or Ih conductance had little effect on dendritic AP propagation. Optically recorded bAP waveforms were quantified and multicompartmental modeling was used to link the observed behavior with the underlying biophysical properties. The best-fit model included a nonuniform sodium channel distribution with decreasing conductance with distance from the soma, together with a nonuniform (increasing) A-type potassium conductance. AP amplitudes decline with distance in this model, but to a lesser extent than previously thought. We used this model to explore the mechanisms underlying two sets of published data involving high-frequency trains of APs and the local generation of sodium spikelets. We also explored the conditions under which IA down-regulation would produce branch strength potentiation in the proposed model. Finally, we discuss the hypothesis that a fraction of basal branches may have different membrane properties compared with sister branches in the same dendritic tree.

Published

2009

158. Activity-Dependent Control of Neuronal Output by Local and Global Dendritic Spike Attenuation

Author

Stefan Remy, Heinz Beck, and Jozsef Csicsvari

Subjects

Neuroscience(all), Biophysics, Action Potentials, In Vitro Techniques, Biology, Hippocampus, Sodium Channels, Potassium Channel Blockers, medicine, Animals, 4-Aminopyridine, Rats, Wistar, Membrane potential, Dendritic spike, Pyramidal Cells, General Neuroscience, Attenuation, Excitatory Postsynaptic Potentials, Control transfer, Dendrites, Isoquinolines, Electric Stimulation, Rats, medicine.anatomical_structure, Animals, Newborn, SIGNALING, Linear Models, Excitatory postsynaptic potential, CELLBIO, Soma, SYSNEURO, Neuroscience

Abstract

SummaryNeurons possess elaborate dendritic arbors which receive and integrate excitatory synaptic signals. Individual dendritic subbranches exhibit local membrane potential supralinearities, termed dendritic spikes, which control transfer of local synaptic input to the soma. Here, we show that dendritic spikes in CA1 pyramidal cells are strongly regulated by specific types of prior input. While input in the linear range is without effect, supralinear input inhibits subsequent spikes, causing them to attenuate and ultimately fail due to dendritic Na+ channel inactivation. This mechanism acts locally within the boundaries of the input branch. If an input is sufficiently strong to trigger axonal action potentials, their back-propagation into the dendritic tree causes a widespread global reduction in dendritic excitability which is prominent after firing patterns occurring in vivo. Together, these mechanisms control the capability of individual dendritic branches to trigger somatic action potential output. They are invoked at frequencies encountered during learning, and impose limits on the storage and retrieval rates of information encoded as branch excitability.

Published

2009

159. FARP1 Promotes the Dendritic Growth of Spinal Motor Neuron Subtypes through Transmembrane Semaphorin6A and PlexinA4 Signaling

Author

You Rong Sophie Su, Bin Quan Zhuang, and Shanthini Sockanathan

Subjects

rho GTP-Binding Proteins, Neurogenesis, Neuroscience(all), DEVBIO, Receptors, Cell Surface, Chick Embryo, Semaphorins, Biology, MOLNEURO, Article, Avian Proteins, Retinoids, Dendrite (crystal), medicine, Animals, Guanine Nucleotide Exchange Factors, Humans, Motor Neurons, Regulation of gene expression, Dendritic spike, Effector, General Neuroscience, Cell Membrane, Gene Expression Regulation, Developmental, Cell Differentiation, Dendrites, Motor neuron, Spinal cord, Transmembrane protein, Protein Structure, Tertiary, Cell biology, Cytoskeletal Proteins, medicine.anatomical_structure, Spinal Cord, CELLBIO, Signal transduction, Neuroscience, Rho Guanine Nucleotide Exchange Factors, Signal Transduction

Abstract

SummaryThe dendritic morphology of neurons dictates their abilities to process and transmit information; however, the signaling pathways that regulate dendritic growth and complexity are poorly understood. Here, we show that retinoids induce the expression of the FERM Rho-GEF protein FARP1 in the developing spinal cord. FARP1 is expressed in subsets of motor neurons and is enriched in dendrites of lateral motor column (LMC) neurons that innervate the limb. FARP1 is necessary and sufficient to promote LMC dendritic growth but does not affect dendrite number or axonal morphology. We show that FARP1 serves as a specific effector of transmembrane Semaphorin6A and PlexinA4 signals to regulate LMC dendritic growth, and that its Rho-GEF domain is necessary for this function. These findings reveal that retinoid and Sema6A/PlexA4 signaling pathways intersect through FARP1 to control dendritic growth, and uncover the existence of subtype-specific signaling networks that control dendritic developmental programs in spinal motor neurons.

Published

2009

160. Climbing fiber evoked potassium release in cat cerebellum.

Author

Bruggencate, G., Nicholson, C., and Stöckle, H.

Abstract

K-selective micropipettes were used to measure the extracellular K-signal associated with the activation of a single Purkinje cell, via a climbing fiber (CF). The maximum K-signal had a magnitude of 0.3-0.5 mM and was correlated with a positive all-or-none extracellular potential. The ionic signal was of the same order of magnitude as that evoked from a population of Purkinje cells by local stimulation of a parallel fiber beam. The large size of the CF-evoked K-response supports the concept of dendritic spikes under these conditions and may be relevant to CF function. [ABSTRACT FROM AUTHOR]

Published

1976

161. Dendritic excitability during increased synaptic activity in rat neocortical L5 pyramidal neurons

Author

Alon Korngreen, Dan Bar-Yehuda, and Hana Ben-Porat

Subjects

Membrane potential, Dendritic spike, Dendritic spine, Voltage-dependent calcium channel, General Neuroscience, Local field potential, Biology, Neurotransmission, medicine.anatomical_structure, Slice preparation, Apical dendrite, medicine, Biophysics, Neuroscience

Abstract

Recent years have seen increased study of dendritic integration, mostly in acute brain slices. However, due to the low background activity in brain slices the integration of synaptic input in slice preparations may not truly reflect conditions in vivo. To investigate dendritic integration, back-propagation of the action potential (AP) and initiation of the dendritic Ca(2+) spike we simultaneously recorded membrane potential at the soma and apical dendrite of layer 5 (L5) pyramidal neurons in quiescent and excited acute brain slices. After excitation of the brain slice the somatic input resistance decreased and the apparent passive space constant shortened. However, the back-propagating AP and dendritic Ca(2+) spike were robust during increased synaptic activity. The dendritic Ca(2+) spike was suppressed by the ionic composition of the bath solution required for slice excitation, suggesting that Ca(2+) spikes may be smaller in vivo than in the acute slice preparation. The results presented here suggest that, under the conditions of slice excitation examined in this study, the increased membrane conductance induced by activation of voltage-gated channels during back-propagation of the AP and dendritic Ca(2+) spike initiation is sufficiently larger than the membrane conductance at subthreshold potentials to allow these two regenerative dendritic events to remain robust over several levels of synaptic activity in the apical dendrite of L5 pyramidal neurons.

Published

2008

162. Converging Effects ofGinkgo bilobaExtract at the Level of Transmitter Release, NMDA and Sodium Currents and Dendritic Spikes

Author

Albert M. I. Barth, Bernadett K. Szasz, Balázs Lendvai, Orsolya Farkas, Zsolt Somogyvari, Arpad Mike, and Nora Lenkey

Subjects

Dopamine, Pharmaceutical Science, In Vitro Techniques, Inhibitory postsynaptic potential, Receptors, N-Methyl-D-Aspartate, Neuroprotection, Membrane Potentials, Analytical Chemistry, Mice, Slice preparation, Pregnancy, Drug Discovery, Animals, Cells, Cultured, Cerebral Cortex, Pharmacology, Dendritic spike, biology, Plant Extracts, Chemistry, Ginkgo biloba, Sodium, Organic Chemistry, Glutamate receptor, Dendrites, biology.organism_classification, Cochlea, Ginkgoaceae, Complementary and alternative medicine, Biochemistry, Biophysics, Molecular Medicine, NMDA receptor, Female

Abstract

In this study, an attempt was made to integrate the effects of GINKGO BILOBA extract (GBE) in different experimental systems (IN VITRO cochlea, brain slice preparations and cortical cell culture) to elucidate whether these processes converge to promote neuroprotection or interfere with normal neural function. GBE increased the release of dopamine in the cochlea. NMDA-evoked currents were dose-dependently inhibited by rapid GBE application in cultured cortical cells. GBE moderately inhibited Na + channels at depolarised holding potential in cortical cells. These inhibitory effects by GBE may sufficiently contribute to the prevention of excitotoxic damage in neurons. However, these channels also interact with memory formation at the cellular level. The lack of effect by GBE on dendritic spike initiation in neocortical layer 5 pyramidal neurons indicates that the integrative functions may remain intact during the inhibitory actions of GBE. bAP:backpropagating action potentials DA:dopamine FR:fractional release GBE: GINKGO BILOBA extract NMDA: N-methyl-d-aspartate AS:adenine sulfate

Published

2008

163. The Origin of the Complex Spike in Cerebellar Purkinje Cells

Author

Beverley A. Clark, Michael Häusser, and Jenny T. Davie

Subjects

Cerebellum, Patch-Clamp Techniques, Time Factors, Models, Neurological, Purkinje cell, Neural Conduction, Action Potentials, In Vitro Techniques, Biology, Deep cerebellar nuclei, Article, Purkinje Cells, medicine, Animals, Axon, Action potential initiation, Dendritic spike, General Neuroscience, Dose-Response Relationship, Radiation, Dendrites, Climbing fiber, Axons, Electric Stimulation, Rats, medicine.anatomical_structure, Animals, Newborn, Calcium, Soma, Neuroscience

Abstract

Activation of the climbing fiber input powerfully excites cerebellar Purkinje cells via hundreds of widespread dendritic synapses, triggering dendritic spikes as well as a characteristic high-frequency burst of somatic spikes known as the complex spike. To investigate the relationship between dendritic spikes and the spikelets within the somatic complex spike, and to evaluate the importance of the dendritic distribution of climbing fiber synapses, we made simultaneous somatic and dendritic patch-clamp recordings from Purkinje cells in cerebellar slices. Injection of large climbing fiber-like synaptic conductances at the soma using dynamic clamp was sufficient to reproduce the complex spike, independently of dendritic spikes, indicating that neither a dendritic synaptic distribution nor dendritic spikes are required. Furthermore, we found that dendritic spikes are not directly linked to spikelets in the complex spike, and that each dendritic spike is associated with only 0.24 ± 0.09 extra somatic spikelets. Rather, we demonstrate that dendritic spikes regulate the pause in firing that follows the complex spike. Finally, using dual somatic and axonal recording, we show that all spikelets in the complex spike are axonally generated. Thus, complex spike generation proceeds relatively independently of dendritic spikes, reflecting the dual functional role of climbing fiber input: triggering plasticity at dendritic synapses and generating a distinct output signal in the axon. The encoding of dendritic spiking by the post-complex spike pause provides a novel computational function for dendritic spikes, which could serve to link these two roles at the level of the target neurons in the deep cerebellar nuclei.

Published

2008

164. Possible Role of Dendritic Compartmentalization in the Spatial Working Memory Circuit

Author

Kenji Morita

Subjects

Models, Neurological, Stimulus (physiology), Dendritic branch, Spatial memory, medicine, Animals, Computer Simulation, Cerebral Cortex, Physics, Dendritic spike, Behavior, Animal, Artificial neural network, Working memory, Pyramidal Cells, General Neuroscience, Significant part, Neural Inhibition, Dendrites, Haplorhini, Articles, Memory, Short-Term, medicine.anatomical_structure, Nonlinear Dynamics, Space Perception, Neural Networks, Computer, Nerve Net, Pyramidal cell, Neuroscience, Photic Stimulation

Abstract

In spatial working memory tasks, pyramidal cells in the relevant cortical circuit receive massive inputs to shape stimulus location-selective sustained activity. A significant part of those inputs are applied onto the dendrites. Considering the dendritic morphology and circuit anatomy together with recently suggested branch-specific plasticity rules, external inputs transmitting the information of the stimulus location would be mapped onto some portion of the dendritic branches, rather than uniformly distributed over the branches. Meanwhile, recent studies revealed that each dendritic branch of pyramidal cell functions as a compartmentalized integration subunit through local spike generation and branch-specific excitation–inhibition interaction. I have examined how such nonlinear dendritic integration, combined with the nonuniform distribution of the external input, affects the behavior of the whole circuit by constructing a rate-coding model incorporating multiple dendritic branches of the individual pyramidal cell. Simulations varying the nature of dendritic nonlinearity and the configuration of somatically and dendritically mediated recurrent inhibition revealed that dendritic compartmentalization potentially enables the circuit to form an accurate memory depending on the contrast of the external input, but insensitively to its intensity, under certain conditions; in particular, when there exists tuned global dendritic recurrent inhibition or local dendritic inhibition coupled with global somatic inhibition. The model suggests that, when the circuit receives low-contrast or background input, only a small portion of dendritic branches of each pyramidal cell can overcome the local threshold so as to contribute to the somatic low-frequency firing, which in turn stabilizes the low-activity state of the circuit by recruiting recurrent inhibition.

Published

2008

165. Regulation of somatic firing dynamics by backpropagating dendritic spikes

Author

Ray W. Turner, Brent Doiron, W. Hamish Mehaffey, and Fernando R. Fernandez

Subjects

GABA Agents, Somatic cell, Models, Neurological, Action Potentials, In Vitro Techniques, Biology, Biophysical Phenomena, Sodium Channels, Bursting, Physiology (medical), medicine, Animals, Phylogeny, Feedback, Physiological, Dendritic spike, GABAA receptor, Pyramidal Cells, General Neuroscience, Neural Inhibition, Depolarization, Dendrites, Electric Stimulation, Rhombencephalon, medicine.anatomical_structure, Nonlinear Dynamics, Soma, Neuron, Neuroscience, Shunting inhibition, Electric Fish

Abstract

Pyramidal cells of the apteronotid ELL have been shown to display a characteristic mechanism of burst discharge, which has been shown to play an important role in sensory coding. This form of bursting depends on a reciprocal dendro-somatic interaction, in which discharge of a somatic spike causes a dendritic spike, which in turn contributes a dendro-somatic current flow to create a depolarizing afterpotential (DAP) in the soma. We review here our recent work showing how the timing of this DAP influences the somatic firing dynamics, and how the degree of inactivation of dendritic Na(+) currents can cause an increased delay between somatic and dendritic spikes. This ultimately allows the DAP to become more effective at increasing the excitability of the somatic spike generating mechanism. Further, this delay between dendritic and somatic spiking can be regulated by strongly hyperpolarizing GABA(B) mediated dendritic inhibition, allowing the burst dynamics to fall under synaptic regulation. In contrast, a weaker, shunting inhibition due to GABA(A) mediated dendritic inhibition can regulate the dendritic spike waveform to decrease the dendro-somatic current flow and the resulting DAP. We therefore show that the qualitative behaviour of an individual cell can depend on the degree of synaptic input, and the exact timing of events across the spatial extent of the neuron. Thus, our results serve to illustrate the complex dynamics that can be observed in cells with significant dendritic arborisation, a nearly ubiquitous adaptation amongst principal neurons.

Published

2008

166. Synaptic clustering by dendritic signalling mechanisms

Author

Matthew E. Larkum and Thomas Nevian

Subjects

Neurons, Dendritic spike, Quantitative Biology::Neurons and Cognition, General Neuroscience, Dendrites, Dendritic branch, Biology, Synaptic Transmission, Calcium Spikes, Quantitative Biology::Subcellular Processes, Signalling, Synaptic plasticity, Animals, NMDA receptor, Cluster analysis, Neuroscience, Signal Transduction

Abstract

Dendritic signal integration is one of the fundamental building blocks of information processing in the brain. Dendrites are endowed with mechanisms of nonlinear summation of synaptic inputs leading to regenerative dendritic events including local sodium, NMDA and calcium spikes. The generation of these events requires distinct spatio-temporal activation patterns of synaptic inputs. We hypothesise that the recent findings on dendritic spikes and local synaptic plasticity rules suggest clustering of common inputs along a subregion of a dendritic branch. These clusters may enable dendrites to separately threshold groups of functionally similar inputs, thus allowing single neurons to act as a superposition of many separate integrate and fire units. Ultimately, these properties expand our understanding about the computational power of neuronal networks.

Published

2008

167. Rapid regulation of microtubule-associated protein 2 in dendrites of nucleus laminaris of the chick following deprivation of afferent activity

Author

Edwin W. Rubel and Yuan Wang

Subjects

Dendritic spike, medicine.anatomical_structure, Microtubule-associated protein 2, Microtubule-associated protein, Postsynaptic potential, General Neuroscience, Excitatory postsynaptic potential, medicine, Biology, Cytoskeleton, Neuroscience, Nucleus, Cochlear nucleus

Abstract

Differential innervation of segregated dendritic domains in the chick nucleus laminaris (NL), composed of third-order auditory neurons, provides a unique model to study synaptic regulation of dendritic structure. Altering the synaptic input to one dendritic domain affects the structure and length of the manipulated dendrites while leaving the other set of unmanipulated dendrites largely unchanged. Little is known about the effects of neuronal input on the cytoskeletal structure of NL dendrites and whether changes in the cytoskeleton are responsible for dendritic remodeling following manipulations of synaptic input. In this study, we investigate changes in the immunoreactivity of high-molecular weight microtubule associated protein 2 (MAP2) in NL dendrites following two different manipulations of their afferent input. Unilateral cochlea removal eliminates excitatory synaptic input to the ventral dendrites of the contralateral NL and the dorsal dendrites of the ipsilateral NL. This manipulation produced a dramatic decrease in MAP2 immunoreactivity in the deafferented dendrites. This decrease was detected as early as 3 h following the surgery, well before any degeneration of afferent axons. A similar decrease in MAP2 immunoreactivity in deafferented NL dendrites was detected following a midline transection that silences the excitatory synaptic input to the ventral dendrites on both sides of the brain. These changes were most distinct in the caudal portion of the nucleus where individual deafferented dendritic branches contained less immunoreactivity than intact dendrites. Our results suggest that the cytoskeletal protein MAP2, which is distributed in dendrites, perikarya, and postsynaptic densities, may play a role in deafferentation-induced dendritic remodeling.

Published

2008

168. A novel role for MNTB neuron dendrites in regulating action potential amplitude and cell excitability during repetitive firing

Author

S. Rock Levinson, Ricardo M. Leão, Bruce Walmsley, Luciano da Fontoura Costa, and Richardson N. Leão

Subjects

Patch-Clamp Techniques, Postsynaptic Current, Models, Neurological, Action Potentials, Dendrite, Tetrodotoxin, Olivary Nucleus, Biology, Antibodies, Sodium Channels, Excitatory synapse, medicine, Animals, Rats, Wistar, Axon, Neurons, Dendritic spike, General Neuroscience, Sodium, Excitatory Postsynaptic Potentials, Dendrites, Axons, Rats, Microscopy, Electron, medicine.anatomical_structure, nervous system, Excitatory postsynaptic potential, Calcium, Neuron, Sodium-Potassium-Exchanging ATPase, Calyx of Held, Neuroscience, Sodium Channel Blockers

Abstract

Principal cells of the medial nucleus of the trapezoid body (MNTB) are simple round neurons that receive a large excitatory synapse (the calyx of Held) and many small inhibitory synapses on the soma. Strangely, these neurons also possess one or two short tufted dendrites, whose function is unknown. Here we assess the role of these MNTB cell dendrites using patch-clamp recordings, imaging and immunohistochemistry techniques. Using outside-out patches and immunohistochemistry, we demonstrate the presence of dendritic Na+ channels. Current-clamp recordings show that tetrodotoxin applied onto dendrites impairs action potential (AP) firing. Using Na+ imaging, we show that the dendrite may serve to maintain AP amplitudes during high-frequency firing, as Na+ clearance indendritic compartments is faster than axonal compartments. Prolonged high-frequency firing can diminish Na+ gradients in the axon while the dendritic gradient remains closer to resting conditions; therefore, the dendrite can provide additional inward current during prolonged firing. Using electron microscopy, we demonstrate that there are small excitatory synaptic boutons on dendrites. Multi-compartment MNTB cell simulations show that, with an active dendrite, dendritic excitatory postsynaptic currents (EPSCs) elicit delayed APs compared with calyceal EPSCs. Together with high- and low-threshold voltage-gated K+ currents, we suggest that the function of the MNTB dendrite is to improve high-fidelity firing, and our modelling results indicate that an active dendrite could contribute to a 'dual' firing mode for MNTB cells (an instantaneous response to calyceal inputs and a delayed response to non-calyceal dendritic excitatory postsynaptic potentials).

Published

2008

169. Spatiotemporally graded NMDA spike/plateau potentials in basal dendrites of neocortical pyramidal neurons

Author

David W. Tank, Guy Major, Alon Polsky, Winfried Denk, and Jackie Schiller

Subjects

Physiology, Models, Neurological, Glutamic Acid, Neocortex, Dendrite, Plateau (mathematics), Receptors, N-Methyl-D-Aspartate, Rats, Sprague-Dawley, Plateau potentials, Image Processing, Computer-Assisted, medicine, Animals, Computer Simulation, Calcium Signaling, Receptors, AMPA, Dendritic spike, Chemistry, Pyramidal Cells, General Neuroscience, Glutamate receptor, Depolarization, Dendrites, Iontophoresis, Rats, Electrophysiology, medicine.anatomical_structure, Data Interpretation, Statistical, Basal dendrite, NMDA receptor, Neuroscience, Algorithms

Abstract

Glutamatergic inputs clustered over approximately 20-40 microm can elicit local N-methyl-D-aspartate (NMDA) spike/plateau potentials in terminal dendrites of cortical pyramidal neurons, inspiring the notion that a single terminal dendrite can function as a decision-making computational subunit. A typical terminal basal dendrite is approximately 100-200 microm long: could it function as multiple decision-making subunits? We test this by sequential focal stimulation of multiple sites along terminal basal dendrites of layer 5 pyramidal neurons in rat somatosensory cortical brain slices, using iontophoresis or uncaging of brief glutamate pulses. There was an approximately sevenfold spatial gradient in average spike/plateau amplitude measured at the soma, from approximately 3 mV for distal inputs to approximately 23 mV for proximal inputs. Spike/plateaus were NMDA receptor (NMDAR) conductance-dominated at all locations. Large Ca(2+) transients accompanied spike/plateaus over a approximately 10- to 40-microm zone around the input site; smaller Ca(2+) transients extended approximately uniformly to the dendritic tip. Spike/plateau duration grew with increasing glutamate and depolarization; high Ca(2+) zone size grew with spike/plateau duration. The minimum high Ca(2+) zone half-width (just above NMDA spike threshold) increased from distal (approximately 10 microm) to proximal locations (approximately 25 microm), as did the NMDA spike glutamate threshold. Depolarization reduced glutamate thresholds. Simulations exploring multi-site interactions based on this demonstrate that if appropriately timed and localized inputs occur in vivo, a single basal dendrite could correspond to a cascade of multiple co-operating dynamic decision-making subunits able to retain information for hundreds of milliseconds, with increasing influence on neural output from distal to proximal. Dendritic NMDA spike/plateaus are thus well-suited to support graded persistent firing.

Published

2008

170. Optical measurement of synaptic glutamate spillover and reuptake by linker optimized glutamate-sensitive fluorescent reporters

Author

Yongling Zhu, Samuel Andrew Hires, and Roger Y. Tsien

Subjects

Dendritic spike, Multidisciplinary, Molecular Sequence Data, Glutamate receptor, Glutamic Acid, Stimulation, Biological Sciences, Biology, Hippocampal formation, Sensitivity and Specificity, Synaptic Transmission, Cell Line, Reuptake, Bursting, Förster resonance energy transfer, Biochemistry, Genes, Reporter, Fluorescence Resonance Energy Transfer, Biophysics, Humans, NMDA receptor, Amino Acid Sequence

Abstract

Genetically encoded sensors of glutamate concentration are based on FRET between cyan and yellow fluorescent proteins bracketing a bacterial glutamate-binding protein. Such sensors have yet to find quantitative applications in neurons, because of poor response amplitude in physiological buffers or when expressed on the neuronal cell surface. We have improved our glutamate-sensing fluorescent reporter (GluSnFR) by systematic optimization of linker sequences and glutamate affinities. Using SuperGluSnFR, which exhibits a 6.2-fold increase in response magnitude over the original GluSnFR, we demonstrate quantitative optical measurements of the time course of synaptic glutamate release, spillover, and reuptake in cultured hippocampal neurons with centisecond temporal and spine-sized spatial resolution. During burst firing, functionally significant spillover persists for hundreds of milliseconds. These glutamate levels appear sufficient to prime NMDA receptors, potentially affecting dendritic spike initiation and computation. Stimulation frequency-dependent modulation of spillover suggests a mechanism for nonsynaptic neuronal communication.

Published

2008

171. Emerging aspects of membrane traffic in neuronal dendrite growth

Author

Bor Luen Tang

Subjects

Sar 1, Dendritic spine, Golgi outpost, Dendrite, Syntaxin 16, Biology, Exocytosis, symbols.namesake, medicine, Animals, Humans, Growth cone, Molecular Biology, Secretory pathway, Dendritic spike, Endoplasmic reticulum, Biological Transport, Dendrites, Intracellular Membranes, Cell Biology, Neuron, Golgi apparatus, Cell biology, medicine.anatomical_structure, nervous system, symbols, trans-Golgi Network

Abstract

Polarized growth of the neuron would logically require some form of membrane traffic to the tip of the growth cone, regulated in conjunction with other trafficking processes that are common to both neuronal and non-neuronal cells. Unlike axons, dendrites are endowed with membranous organelles of the exocytic pathway extending from the cell soma, including both rough and smooth endoplasmic reticulum (ER) and the ER–Golgi intermediate compartment (ERGIC). Dendrites also have satellite Golgi-like cisternal stacks known as Golgi outposts that have no membranous connections with the somatic Golgi. Golgi outposts presumably serve both general and specific local trafficking needs, and could mediate membrane traffic required for polarized dendritic growth during neuronal differentiation. Recent findings suggest that dendritic growth, but apparently not axonal growth, relies very much on classical exocytic traffic, and is affected by defects in components of both the early and late secretory pathways. Within dendrites, localized processes of recycling endosome-based exocytosis regulate the growth of dendritic spines and postsynaptic compartments. Emerging membrane traffic processes and components that contribute specifically to dendritic growth are discussed.

Published

2008

172. Dendritic Properties of Turtle Pyramidal Neurons

Author

Paul Rhodes, Nechama Lasser-Ross, Matthew E. Larkum, Shigeo Watanabe, and William N. Ross

Subjects

Patch-Clamp Techniques, Physiology, In Vitro Techniques, Article, law.invention, chemistry.chemical_compound, law, Excitatory Amino Acid Agonists, medicine, Animals, Cycloleucine, Patch clamp, Excitatory Amino Acid Agonist, Turtle (robot), 6-Cyano-7-nitroquinoxaline-2,3-dione, Dendritic spike, Neocortex, Pyramidal Cells, General Neuroscience, Sodium, Brain, Excitatory Postsynaptic Potentials, Dose-Response Relationship, Radiation, Dendrites, Electric Stimulation, Turtles, medicine.anatomical_structure, chemistry, Excitatory Amino Acid Antagonists, Excitatory postsynaptic potential, Calcium, Neuroscience

Abstract

The six-layered mammalian neocortex evolved from the three-layered paleocortex, which is retained in present-day reptiles such as the turtle. Thus the turtle offers an opportunity to examine which cellular and circuit properties are fundamental to cortical function. We characterized the dendritic properties of pyramidal neurons in different cortical regions of mature turtles, Pseudemys scripta elegans, using whole cell recordings and calcium imaging from the axon, soma, and dendrites in a slice preparation. The firing properties, in response to intrasomatic depolarization, resembled those previously recorded with sharp electrodes in this preparation. Somatic spikes led to active backpropagating high-amplitude dendritic action potentials and intracellular calcium ion concentration ([Ca2+]i) changes at all dendritic locations, suggesting that both backpropagation and dendritic voltage-gated Ca2+ channels are primitive traits. We found no indication that Ca2+ spikes could be evoked in the dendrites, but fast Na+ spikes could be initiated there following intradendritic stimulation. Several lines of evidence indicate that fast, smaller-amplitude somatic spikes (“prepotentials”) that are easily recorded in this preparation are generated in the axon. Most synaptically activated [Ca2+]i changes resulted from Ca2+ entry through voltage-gated channels. In some cells synaptic stimulation evoked a delayed Ca2+ wave due to release from internal stores following activation of metabotropic glutamate receptors. With some small differences these properties resemble those of pyramidal neurons in mammalian species. We conclude that spike backpropagation, dendritic Ca2+ channels, and synaptically activated Ca2+ release are primitive and conserved features of cortical pyramidal cells, and therefore likely fundamental to cortical function.

Published

2008

173. Spike timing-dependent plasticity: a learning rule for dendritic integration in rat CA1 pyramidal neurons

Author

Dominique Debanne and Emilie Campanac

Subjects

0303 health sciences, Dendritic spike, Physiology, Spike-timing-dependent plasticity, Nonsynaptic plasticity, Long-term potentiation, Biology, 03 medical and health sciences, 0302 clinical medicine, Postsynaptic potential, Metaplasticity, Synaptic plasticity, Excitatory postsynaptic potential, Neuroscience, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Long-term plasticity of dendritic integration is induced in parallel with long-term potentiation (LTP) or depression (LTD) based on presynaptic activity patterns. It is, however, not clear whether synaptic plasticity induced by temporal pairing of pre- and postsynaptic activity is also associated with synergistic modification in dendritic integration. We show here that the spike timing-dependent plasticity (STDP) rule accounts for long-term changes in dendritic integration in CA1 pyramidal neurons in vitro. Positively correlated pre- and postsynaptic activity (delay: +5/+50 ms) induced LTP and facilitated dendritic integration. Negatively correlated activity (delay: −5/−50 ms) induced LTD and depressed dendritic integration. These changes were not observed following positive or negative pairing with long delays (> ±50 ms) or when NMDA receptors were blocked. The amplitude–slope relation of the EPSP was facilitated after LTP and depressed after LTD. These effects could be mimicked by voltage-gated channel blockers, suggesting that the induced changes in EPSP waveform involve the regulation of voltage-gated channel activity. Importantly, amplitude–slope changes induced by STDP were found to be input specific, indicating that the underlying changes in excitability are restricted to a limited portion of the dendrites. We conclude that STDP is a common learning rule for long-term plasticity of both synaptic transmission and dendritic integration, thus constituting a form of functional redundancy that insures significant changes in the neuronal output when synaptic plasticity is induced.

Published

2008

174. Amplitude Variability and Extracellular Low-Pass Filtering of Neuronal Spikes

Author

Klas H. Pettersen and Gaute T. Einevoll

Subjects

Membrane potential, Neurons, Dendritic spike, Models, Neurological, Biophysics, Action Potentials, Extracellular Fluid, Anatomy, Radius, Biophysical Theory and Modeling, Neurotransmission, Biology, Synaptic Transmission, Amplitude, medicine.anatomical_structure, nervous system, Electrical resistivity and conductivity, Synapses, medicine, Soma, Computer Simulation, Neuron

Abstract

The influence of neural morphology and passive electrical parameters on the width and amplitude of extracellular spikes is investigated by combined analytical and numerical investigations of idealized and anatomically reconstructed pyramidal and stellate neuron models. The main results are: 1), All models yield a low-pass filtering effect, that is, a spike-width increase with increasing distance from soma. 2), A neuron's extracellular spike amplitude is seen to be approximately proportional to the sum of the dendritic cross-sectional areas of all dendritic branches connected to the soma. Thus, neurons with many, thick dendrites connected to soma will produce large amplitude spikes, and therefore have the largest radius of visibility. 3), The spike shape and amplitude are found to be dependent on the membrane capacitance and axial resistivity, but not on the membrane resistivity. 4), The spike-amplitude decay with distance r is found to depend on dendritic morphology, and is decaying as 1/r(n) with 1or= nor= 2 close to soma and nor= 2 far away.

Published

2008

175. Dendritic nicotinic receptors modulate backpropagating action potentials and long-term plasticity of interneurons

Author

Balázs Rózsa, Robert Szipocs, Gergely Katona, Attila Kaszás, and E. Sylvester Vizi

Subjects

Dendritic spike, Interneuron, musculoskeletal, neural, and ocular physiology, General Neuroscience, Nonsynaptic plasticity, Long-term potentiation, Biology, Neurotransmission, complex mixtures, Nicotinic agonist, medicine.anatomical_structure, nervous system, mental disorders, Metaplasticity, medicine, sense organs, Alpha-4 beta-2 nicotinic receptor, Neuroscience

Abstract

Stratum radiatum interneurons, unlike pyramidal cells, are rich in nicotinic acetylcholine receptors (nAChRs); however, the role of these receptors in plasticity has remained elusive. As opposed to previous physiological studies, we found that functional α7-subunit-containing nAChRs (α7-nAChRs) are abundant on interneuron dendrites of rats. Moreover, dendritic Ca2+ transients induced by activation of α7-nAChRs increase as a function of distance from soma. The activation of these extrasynaptic α7-nAChRs by cholinergic agonists either facilitated or depressed backpropagating action potentials, depending on the timing of α7-nAChR activation. We have previously shown that dendritic α7-nAChRs are involved in the regulation of synaptic transmission, suggesting that α7-nAChRs may play an important role in the regulation of the spike timing-dependent plasticity. Here we provide evidence that long-term potentiation is indeed boosted by stimulation of dendritic α7-nAChRs. Our results suggest a new mechanism for a cholinergic switch in memory encoding and retrieval.

Published

2008

176. New Angles on Neuronal Dendrites In Vivo

Author

Werner Göbel and Fritjof Helmchen

Subjects

Neurons, Physics, Dendritic spike, Microscopy, Confocal, Physiology, Synaptic integration, Pyramidal Cells, General Neuroscience, Neocortex, Dendrites, Rats, Purkinje Cells, In vivo, Cerebellum, Data Interpretation, Statistical, Image Processing, Computer-Assisted, Animals, Calcium Signaling, Rats, Wistar, Neuroscience

Abstract

Imaging technologies are well suited to study neuronal dendrites, which are key elements for synaptic integration in the CNS. Dendrites are, however, frequently oriented perpendicular to tissue surfaces, impeding in vivo imaging approaches. Here we introduce novel laser-scanning modes for two-photon microscopy that enable in vivo imaging of spatiotemporal activity patterns in dendrites. First, we developed a method to image planes arbitrarily oriented in 3D, which proved particularly beneficial for calcium imaging of parallel fibers and Purkinje cell dendrites in rat cerebellar cortex. Second, we applied free linescans—either through multiple dendrites or along a single vertically oriented dendrite—to reveal fast dendritic calcium dynamics in neocortical pyramidal neurons. Finally, we invented a ribbon-type 3D scanning method for imaging user-defined convoluted planes enabling simultaneous measurements of calcium signals along multiple apical dendrites. These novel scanning modes will facilitate optical probing of dendritic function in vivo.

Published

2007

177. Voltage and calcium transients in basal dendrites of the rat prefrontal cortex

Author

Srdjan D. Antic, Wen-Liang Zhou, and Bogdan A. Milojkovic

Subjects

Dendritic spike, Physiology, chemistry.chemical_element, Dendrite, Depolarization, Biology, Dendritic branch, Calcium, Glutamatergic, medicine.anatomical_structure, Plateau potentials, chemistry, medicine, Excitatory postsynaptic potential, Neuroscience

Abstract

Higher cortical functions (perception, cognition, learning and memory) are in large part based on the integration of electrical and calcium signals that takes place in thin dendritic branches of neocortical pyramidal cells (synaptic integration). The mechanisms underlying the synaptic integration in thin basal dendrites are largely unexplored. We use a recently developed technique, multisite voltage–calcium imaging, to compare voltage and calcium transients from multiple locations along individual dendritic branches. Our results reveal characteristic electrical transients (plateau potentials) that trigger and shape dendritic calcium dynamics and calcium distribution during suprathreshold glutamatergic synaptic input. We regularly observed three classes of voltage–calcium interactions occurring simultaneously in three different zones of the same dendritic branch: (1) proximal to the input site, (2) at the input site, and (3) distal to the input site. One hundred micrometers away from the synaptic input site, both proximally and distally, dendritic calcium transients are in tight temporal correlation with the dendritic plateau potential. However, on the same dendrite, at the location of excitatory input, calcium transients outlast local dendritic plateau potentials by severalfold. These Ca2+ plateaus (duration 0.5–2 s) are spatially restricted to the synaptic input site, where they cause a brief down-regulation of dendritic excitability. Ca2+ plateaus are not mediated by Ca2+ release from intracellular stores, but rather by an NMDA-dependent small-amplitude depolarization, which persists after the collapse of the dendritic plateau potential. These unique features of dendritic voltage and calcium distributions may provide distinct zones for simultaneous long-term (bidirectional) modulation of synaptic contacts along the same basal branch.

Published

2007

178. Sez-6 Proteins Affect Dendritic Arborization Patterns and Excitability of Cortical Pyramidal Neurons

Author

Pankaj Sah, Mary H. Kim, E. S. Louise Faber, Vicki E. Hammond, Jenny M. Gunnersen, Philip J. Davies, Steve Petrou, Melanie de Silva, Seong-Seng Tan, Joanne M. Britto, and Stephanie J. Fuller

Subjects

Male, Patch-Clamp Techniques, Dendritic spine, Neurite, Neuroscience(all), Dendritic Spines, DEVBIO, Nerve Tissue Proteins, Neurotransmission, Biology, Nervous System Malformations, Synaptic Transmission, MOLNEURO, Mice, Organ Culture Techniques, Postsynaptic potential, Neural Pathways, Animals, Cells, Cultured, Cerebral Cortex, Mice, Knockout, Dendritic spike, Pyramidal Cells, General Neuroscience, Cell Membrane, Intracellular Signaling Peptides and Proteins, Excitatory Postsynaptic Potentials, Gene Expression Regulation, Developmental, Membrane Proteins, Cell Differentiation, Dendrites, Mice, Inbred C57BL, nervous system, Synaptic plasticity, Excitatory postsynaptic potential, CELLBIO, Female, Cognition Disorders, Disks Large Homolog 4 Protein, Guanylate Kinases, Neuroscience, Postsynaptic density

Abstract

SummaryDevelopment of appropriate dendritic arbors is crucial for neuronal information transfer. We show, using seizure-related gene 6 (sez-6) null mutant mice, that Sez-6 is required for normal dendritic arborization of cortical neurons. Deep-layer pyramidal neurons in the somatosensory cortex of sez-6 null mice exhibit an excess of short dendrites, and cultured cortical neurons lacking Sez-6 display excessive neurite branching. Overexpression of individual Sez-6 isoforms in knockout neurons reveals opposing actions of membrane-bound and secreted Sez-6 proteins, with membrane-bound Sez-6 exerting an antibranching effect under both basal and depolarizing conditions. Layer V pyramidal neurons in knockout brain slices show reduced excitatory postsynaptic responses and a reduced dendritic spine density, reflected by diminished punctate staining for postsynaptic density 95 (PSD-95). In behavioral tests, the sez-6 null mice display specific exploratory, motor, and cognitive deficits. In conclusion, cell-surface protein complexes involving Sez-6 help to sculpt the dendritic arbor, in turn enhancing synaptic connectivity.

Published

2007

179. Activity-dependent Regulation of h Channel Distribution in Hippocampal CA1 Pyramidal Neurons

Author

Dane M. Chetkovich and Minyoung Shin

Subjects

Potassium Channels, Cyclic Nucleotide-Gated Cation Channels, Hippocampus, Dendrite, Biology, Hippocampal formation, Neurotransmission, p38 Mitogen-Activated Protein Kinases, Biochemistry, Antibodies, Article, Tissue Culture Techniques, Chlorocebus aethiops, H channel, Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels, medicine, Animals, Molecular Biology, Neurons, Dendritic spike, Glutamate receptor, Cell Biology, Entorhinal cortex, Rats, Cell biology, Protein Subunits, medicine.anatomical_structure, Receptors, Glutamate, COS Cells, Calcium-Calmodulin-Dependent Protein Kinase Type 2, Ion Channel Gating

Abstract

The hyperpolarization-activated cation current, I(h), plays an important role in regulating intrinsic neuronal excitability in the brain. In hippocampal pyramidal neurons, I(h) is mediated by h channels comprised primarily of the hyperpolarization-activated cyclic nucleotide-gated (HCN) channel subunits, HCN1 and HCN2. Pyramidal neuron h channels within hippocampal area CA1 are remarkably enriched in distal apical dendrites, and this unique distribution pattern is critical for regulating dendritic excitability. We utilized biochemical and immunohistochemical approaches in organotypic slice cultures to explore factors that control h channel localization in dendrites. We found that distal dendritic enrichment of HCN1 is first detectable at postnatal day 13, reaching maximal enrichment by the 3rd postnatal week. Interestingly we found that an intact entorhinal cortex, which projects to distal dendrites of CA1 but not area CA3, is critical for the establishment and maintenance of distal dendritic enrichment of HCN1. Moreover blockade of excitatory neurotransmission using tetrodotoxin, 6-cyano-7-nitroquinoxaline-2,3-dione, or 2-aminophosphonovalerate redistributed HCN1 evenly throughout the dendrite without significant changes in protein expression levels. Inhibition of calcium/calmodulin-dependent protein kinase II activity, but not p38 MAPK, also redistributed HCN1 in CA1 pyramidal neurons. We conclude that activation of ionotropic glutamate receptors by excitatory temporoammonic pathway projections from the entorhinal cortex establishes and maintains the distribution pattern of HCN1 in CA1 pyramidal neuron dendrites by activating calcium/calmodulin-dependent protein kinase II-mediated downstream signals.

Published

2007

180. Coding of spatial information by soma and dendrite of pyramidal cells in the hippocampal CA1 of behaving rats

Author

Susumu Takahashi and Yoshio Sakurai

Subjects

Dendritic spike, General Neuroscience, Hippocampus, Dendrite, Hippocampal formation, Biology, Shunting, medicine.anatomical_structure, nervous system, medicine, Soma, Neuron, Pyramidal cell, Neuroscience

Abstract

The soma and dendrite of a single neuron differ markedly in their anatomical and chemical organization. However, the difference between the neuronal codes by the soma and dendrite in the brain of behaving animals remains unknown. Here, we show that in the hippocampal CA1 of behaving rats, the soma and dendrite of pyramidal cells code distinct spatial information. To detect these neuronal codes, we used a unique extracellular multiunit recording technique with special electrodes (dodecatrodes) and a novel spike-sorting system with an independent component analysis (ICSort). First, we examined whether ICSort could separate extracellular signals from the soma and those from the dendrite of a single cell, in comparison with the separation obtained by a conventional spike-sorting technique. The results suggest that ICSort could distinguish extracellular signals originating from the soma and dendrite. Second, we examined spatial information coded by signals from the soma and dendrite of hippocampal pyramidal cells when the rats were moving in a familiar open environment. The results indicate that the somatic units had single place fields, and showed higher spatial specificity, lower sparsity and lower firing rates than the dendritic units. Therefore, we conclude that a hippocampal pyramidal cell has the ability to transform redundant spatial information received from upstream neurons via the dendrite into more place-specific information along the dendrosomatic axis and transmit this information to downstream neurons via the soma.

Published

2007

181. Dendritic Backpropagation and the State of the Awake Neocortex

Author

Harvey A. Swadlow, Alexander G. Gusev, Yael Amitai, Yulia Bereshpolova, and Carl R. Stoelzel

Subjects

media_common.quotation_subject, Action Potentials, Stimulation, Apical dendrite, medicine, Animals, Visual Pathways, Wakefulness, Visual Cortex, media_common, Dendritic spike, Neocortex, Chemistry, Pyramidal Cells, Spectrum Analysis, General Neuroscience, Electroencephalography, Dendrites, Articles, Electric Stimulation, medicine.anatomical_structure, Visual cortex, Synaptic plasticity, Soma, Rabbits, Neuroscience, Photic Stimulation, Vigilance (psychology)

Abstract

The spread of somatic spikes into dendritic trees has become central to models of dendritic integrative properties and synaptic plasticity. However, backpropagating action potentials (BPAPs) have been studied mainly in slices, in which they are highly sensitive to multiple factors such as firing frequency and membrane conductance, raising doubts about their effectiveness in the awake behaving brain. Here, we examine the spatiotemporal characteristics of BPAPs in layer 5 pyramidal neurons in the visual cortex of adult, awake rabbits, in which EEG-defined brain states ranged from alert vigilance to drowsy/inattention, and, in some cases, to light sleep. To achieve this, we recorded extracellular spikes from layer 5 pyramidal neurons and field potentials above and below these neurons using a 16-channel linear probe, and applied methods of spike-triggered current source-density analysis to these records (Buzsáki and Kandel, 1998; Swadlow et al., 2002). Precise retinotopic alignment of superficial and deep cortical sites was used to optimize alignment of the recording probe with the axis of the apical dendrite. During the above network states, we studied BPAPs generated spontaneously, antidromically (from corticotectal neurons), or via intense synaptic drive caused by natural visual stimulation. Surprisingly, the invasion of BPAPs as far as 800 μm from the soma was little affected by the network state and only mildly attenuated by high firing frequencies. These data reveal that the BPAP is a robust and highly reliable property of neocortical apical dendrites. These events, therefore, are well suited to provide crucial signals for the control of synaptic plasticity during information-processing brain states.

Published

2007

182. Targeted dendrotomy reveals active and passive contributions of the dendritic tree to synaptic integration and neuronal output

Author

Michael Häusser and John M. Bekkers

Subjects

Models, Neurological, Purkinje cell, Action Potentials, Neural Inhibition, Neocortex, Dendrite, Biology, Neural backpropagation, Rats, Sprague-Dawley, Purkinje Cells, Bursting, Cerebellum, medicine, Animals, Rats, Wistar, Axon, Neurons, Dendritic spike, Multidisciplinary, Electric Conductivity, Dendrites, Anatomy, Biological Sciences, Rats, medicine.anatomical_structure, nervous system, Synapses, Stress, Mechanical, Neuron, Neuroscience

Abstract

Neurons typically function as transduction devices, converting patterns of synaptic inputs, received on the dendrites, into trains of output action potentials in the axon. This transduction process is surprisingly complex and has been proposed to involve a two-way dialogue between axosomatic and dendritic compartments that can generate mutually interacting regenerative responses. To manipulate this process, we have developed a new approach for rapid and reversible occlusion or amputation of the primary dendrites of individual neurons in brain slices. By applying these techniques to cerebellar Purkinje and layer 5 cortical pyramidal neurons, we show directly that both the active and passive properties of dendrites differentially affect firing in the axon depending on the strength of stimulation. For weak excitation, dendrites act as a passive electrical load, raising spike threshold and dampening axonal excitability. For strong excitation, dendrites contribute regenerative inward currents, which trigger burst firing and enhance neuronal excitability. These findings provide direct support for the idea that dendritic morphology and conductances act in concert to regulate the excitability of the neuron.

Published

2007

183. Computing with active dendrites

Author

Christo Panchev

Subjects

Computer science, Cognitive Neuroscience, Competitive learning, Nonsynaptic plasticity, Neural backpropagation, Machine learning, computer.software_genre, Synapse, Computer Science::Emerging Technologies, Artificial Intelligence, Metaplasticity, medicine, Membrane potential, Dendritic spike, Quantitative Biology::Neurons and Cognition, Homosynaptic plasticity, business.industry, Spike-timing-dependent plasticity, Computer Science Applications, medicine.anatomical_structure, Synaptic plasticity, Neuron, Artificial intelligence, business, Neuroscience, computer

Abstract

This paper introduces a new model of a spiking neuron with active dendrites and dynamic synapses (ADDS). The neuron employs the dynamics of the synapses and the active properties of the dendrites as an adaptive mechanism for maximising its response to a specific spatio-temporal distribution of incoming action potentials. The paper also presents a new spike-timing-dependent plasticity (STDP) algorithm developed for the ADDS neuron. This algorithm follows recent biological evidence on synaptic plasticity, and goes beyond the current computational approaches which are based only on the relative timing between single pre- and post-synaptic spikes and implements a functional dependence based on the state of the dendritic and somatic membrane potentials at the time of the post-synaptic spike.

Published

2007

184. Dendritic D-type potassium currents inhibit the spike afterdepolarization in rat hippocampal CA1 pyramidal neurons

Author

Alexia E. Metz, Marco Martina, and Nelson Spruston

Subjects

Dendritic spike, Physiology, Chemistry, Dendrotoxin, Depolarization, Hippocampal formation, Potassium channel, Afterdepolarization, Bursting, medicine.anatomical_structure, nervous system, medicine, Soma, Neuroscience

Abstract

In CA1 pyramidal neurons, burst firing is correlated with hippocampally dependent behaviours and modulation of synaptic strength. One of the mechanisms underlying burst firing in these cells is the afterdepolarization (ADP) that follows each action potential. Previous work has shown that the ADP results from the interaction of several depolarizing and hyperpolarizing conductances located in the soma and the dendrites. By using patch-clamp recordings from acute rat hippocampal slices we show that D-type potassium current modulates the size of the ADP and the bursting of CA1 pyramidal neurons. Sensitivity to α-dendrotoxin suggests that Kv1-containing potassium channels mediate this current. Dual somato-dendritic recording, outside-out dendritic recordings, and focal application of dendrotoxin together indicate that the channels mediating this current are located in the apical dendrites. Thus, our data present evidence for a dendritic segregation of Kv1-like channels in CA1 pyramidal neurons and identify a novel action for these channels, showing that they inhibit action potential bursting by restricting the size of the ADP.

Published

2007

185. Simple Models Show the General Advantages of Dendrites in Coincidence Detection

Author

H. Steven Colburn, Vasant K. Dasika, and John A. White

Subjects

Neurons, Dendritic spike, Physiology, business.industry, Extramural, Computer science, General Neuroscience, Models, Neurological, Electric Conductivity, Information processing, Action Potentials, Pattern recognition, Dendrites, Simple (abstract algebra), Animals, Computer Simulation, Artificial intelligence, business, Neuroscience, Coincidence detection in neurobiology

Abstract

Dendrites can influence and improve information processing in single neurons. Here, simple models are used to elucidate mechanisms underlying the dendritic enhancement of coincidence detection. We focus on coincidence-detecting cells in the auditory system, which have bipolar dendrites and show acute sensitivity to interaural time difference (ITD), a critical cue for spatial hearing. A three-compartment model consisting of a single-compartment soma and two single-compartment dendrites is primarily used, although multiple-compartment dendrites are also tested. Two varieties of somata, with and without active ion channels, are studied. Using constant conductance inputs, we show analytically that the somatic response to balanced bilateral inputs is largest, whereas the response monotonically decreases as the input distribution becomes increasingly monolateral. This enhancement is a consequence of the sublinear saturating dendritic voltage response to conductance input and occurs when dendrites are composed of a single compartment or either a finite number or an infinite number (i.e., a cable) of compartments. Longer, thinner dendrites or greater numbers of compartments increase the enhancement of the somatic response to bilateral input. The time-independent dendritic enhancement, moreover, underlies improved coincidence detection of time-varying input. Coincidence sensitivity to a pair of conductance pulses and rate–ITD modulation to low-frequency (400-Hz) periodic inputs increases with dendritic length. These findings are related to the length gradient in the avian system, where low characteristic frequency (CF) cells have long dendrites and high CF cells have short dendrites. We conclude that dendrites fundamentally improve coincidence detection, increasing the computational power of many neurons in the nervous system.

Published

2007

186. Intrinsic bursting enhances the robustness of a neural network model of sequence generation by avian brain area HVC

Author

H. Sebastian Seung, Dezhe Z. Jin, and Fethi M. Ramazanoğlu

Subjects

Refractory Period, Electrophysiological, Cognitive Neuroscience, Models, Neurological, Population, Membrane Potentials, Birds, Potassium Channels, Calcium-Activated, Cellular and Molecular Neuroscience, Bursting, Neural Pathways, medicine, Animals, Learning, Computer Simulation, Calcium Signaling, education, Neurons, education.field_of_study, Dendritic spike, Models, Statistical, biology, Brain, Dendrites, biology.organism_classification, Sensory Systems, Songbird, Electrophysiology, medicine.anatomical_structure, nervous system, Data Interpretation, Statistical, Synapses, behavior and behavior mechanisms, Excitatory postsynaptic potential, Soma, Neural Networks, Computer, Neuron, Neuroscience, Algorithms

Abstract

Avian brain area HVC is known to be important for the production of birdsong. In zebra finches, each RA-projecting neuron in HVC emits a single burst of spikes during a song motif. The population of neurons is activated in a precisely timed, stereotyped sequence. We propose a model of these burst sequences that relies on two hypotheses. First, we hypothesize that the sequential order of bursting is reflected in the excitatory synaptic connections between neurons. Second, we propose that the neurons are intrinsically bursting, so that burst duration is set by cellular properties. Our model generates burst sequences similar to those observed in HVC. If intrinsic bursting is removed from the model, burst sequences can also be produced. However, they require more fine-tuning of synaptic strengths, and are therefore less robust. In our model, intrinsic bursting is caused by dendritic calcium spikes, and strong spike frequency adaptation in the soma contributes to burst termination.

Published

2007

187. Developing velocity sensitivity in a model neuron by local synaptic plasticity

Author

Florentin Wörgötter, Minija Tamosiunaite, and Bernd Porr

Subjects

Physics, Dendritic spike, Neuronal Plasticity, Synaptic scaling, General Computer Science, Homosynaptic plasticity, Models, Neurological, Nonsynaptic plasticity, Dendrites, Dendritic branch, Sensitivity and Specificity, Orientation, Homeostatic plasticity, Synapses, Metaplasticity, Humans, Learning, Developmental plasticity, Neuroscience, Visual Cortex, Biotechnology

Abstract

Sensor neurons, like those in the visual cortex, display specific functional properties, e.g., tuning for the orientation, direction and velocity of a moving stimulus. It is still unclear how these properties arise from the processing of the inputs which converge at a given cell. Specifically, little is known how such properties can develop by ways of synaptic plasticity. In this study we investigate the hypothesis that velocity sensitivity can develop at a neuron from different types of synaptic plasticity at different dendritic sub-structures. Specifically we are implementing spike-timing dependent plasticity at one dendritic branch and conventional long-term potentiation at another branch, both driven by dendritic spikes triggered by moving inputs. In the first part of the study, we show how velocity sensitivity can arise from such a spatially localized difference in the plasticity. In the second part we show how this scenario is augmented by the interaction between dendritic spikes and back-propagating spikes also at different dendritic branches. Recent theoretical (Saudargiene et al. in Neural Comput 16:595-626, 2004) and experimental (Froemke et al. in Nature 434:221-225, 2005) results on spatially localized plasticity suggest that such processes may play a major role in determining how synapses will change depending on their site. The current study suggests that such mechanisms could be used to develop the functional specificities of a neuron.

Published

2007

188. Dendritic signals from rat hippocampal CA1 pyramidal neurons during coincident pre- and post-synaptic activity: a combined voltage- and calcium-imaging study

Author

Maja Djurisic, Marco Canepari, and Dejan Zecevic

Subjects

Membrane potential, 0303 health sciences, Dendritic spike, Physiology, Chemistry, Long-term potentiation, Depolarization, Hippocampal formation, 03 medical and health sciences, 0302 clinical medicine, Calcium imaging, Synaptic plasticity, Biophysics, NMDA receptor, Neuroscience, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

The non-linear and spatially inhomogeneous interactions of dendritic membrane potential signals that represent the first step in the induction of activity-dependent long-term synaptic plasticity are not fully understood, particularly in dendritic regions which are beyond the reach of electrode measurements. We combined voltage-sensitive-dye recordings and Ca(2+) imaging of hippocampal CA1 pyramidal neurons to study large regions of the dendritic arbor, including branches of small diameter (distal apical and oblique dendrites). Dendritic membrane potential transients were monitored at high spatial resolution and correlated with supra-linear [Ca(2+)](i) changes during one cycle of a repetitive patterned stimulation protocol that typically results in the induction of long-term potentiation (LTP). While the increase in the peak membrane depolarization during coincident pre- and post-synaptic activity was required for the induction of supra-linear [Ca(2+)](i) signals shown to be necessary for LTP, the change in the baseline-to-peak amplitude of the backpropagating dendritic action potential (bAP) was not critical in this process. At different dendritic locations, the baseline-to-peak amplitude of the bAP could be either increased, decreased or unaltered at sites where EPSP-AP pairing evoked supra-linear summation of [Ca(2+)](i) transients. We suggest that modulations in the bAP baseline-to-peak amplitude by local EPSPs act as a mechanism that brings the membrane potential into the optimal range for Ca(2+) influx through NMDA receptors (0 to -15 mV); this may require either boosting or the reduction of the bAP, depending on the initial size of both signals.

Published

2007

189. M-Channels (Kv7/KCNQ Channels) That Regulate Synaptic Integration, Excitability, and Spike Pattern of CA1 Pyramidal Cells Are Located in the Perisomatic Region

Author

Hua Hu, Johan F. Storm, and Koen Vervaeke

Subjects

Male, Indoles, Patch-Clamp Techniques, Pyridines, Models, Neurological, Action Potentials, In Vitro Techniques, Phenylenediamines, Neurotransmission, Hippocampal formation, Linopirdine, chemistry.chemical_compound, Apical dendrite, Potassium Channel Blockers, medicine, Animals, Computer Simulation, Tissue Distribution, Rats, Wistar, Anthracenes, Cerebral Cortex, Dendritic spike, KCNQ Potassium Channels, Pyramidal Cells, General Neuroscience, Retigabine, Excitatory Postsynaptic Potentials, Afterhyperpolarization, Dendrites, Articles, Potassium channel, Rats, Electrophysiology, medicine.anatomical_structure, chemistry, Synapses, Calcium, Carbamates, Extracellular Space, Neuroscience, medicine.drug

Abstract

To understand how electrical signal processing in cortical pyramidal neurons is executed by ion channels, it is essential to know their subcellular distribution. M-channels (encoded by Kv7.2–Kv7.5/KCNQ2–KCNQ5 genes) have multiple important functions in neurons, including control of excitability, spike afterpotentials, adaptation, and theta resonance. Nevertheless, the subcellular distribution of these channels has remained elusive. To determine the M-channel distribution within CA1 pyramidal neurons, we combined whole-cell patch-clamp recording from the soma and apical dendrite with focal drug application, in rat hippocampal slices. Both a M-channel opener (retigabine [N-(2-amino-4-(4-fluorobenzylamino)-phenyl) carbamic acid ethyl ester]) and a blocker (XE991 [10,10-bis(4-pyridinylmethyl)-9(10H)-antracenone]) changed the somatic subthreshold voltage response but had no observable effect on local dendritic responses. Under conditions promoting dendritic Ca2+spikes, local somatic but not dendritic application of M-channel blockers (linopirdine and XE991) enhanced the Ca2+spikes. Simultaneous dendritic and somatic whole-cell recordings showed that the medium afterhyperpolarization after a burst of spikes underwent strong attenuation along the apical dendrite and was fully blocked by somatic XE991 application. Finally, by combining patch-clamp and extracellular recordings with computer simulations, we found that perisomatic M-channels reduce the summation of EPSPs. We conclude that functional M-channels appear to be concentrated in the perisomatic region of CA1 pyramidal neurons, with no detectable M-channel activity in the distal apical dendrites.

Published

2007

190. Properties of basal dendrites of layer 5 pyramidal neurons: a direct patch-clamp recording study

Author

Jackie Schiller, Matthew E. Larkum, Alon Polsky, and Thomas Nevian

Subjects

Nervous system, Patch-Clamp Techniques, Dendritic Spines, Action Potentials, Receptors, N-Methyl-D-Aspartate, Synaptic Transmission, Membrane Potentials, Neuroscientist, Basal (phylogenetics), Organ Culture Techniques, medicine, Animals, Patch clamp, Rats, Wistar, Cerebral Cortex, Dendritic spike, Chemistry, Pyramidal Cells, General Neuroscience, Cell Membrane, Sodium, Excitatory Postsynaptic Potentials, Dendrites, Rats, medicine.anatomical_structure, Synapses, Excitatory postsynaptic potential, Soma, Neuron, Neuroscience

Abstract

Basal dendrites receive the majority of synapses that contact neocortical pyramidal neurons, yet our knowledge of synaptic processing in these dendrites has been hampered by their inaccessibility for electrical recordings. A new approach to patch-clamp recordings enabled us to characterize the integrative properties of these cells. Despite the short physical length of rat basal dendrites, synaptic inputs were electrotonically remote from the soma (>30-fold excitatory postsynaptic potential (EPSP) attenuation) and back-propagating action potentials were significantly attenuated. Unitary EPSPs were location dependent, reaching large amplitudes distally (>8 mV), yet their somatic contribution was relatively location independent. Basal dendrites support sodium and NMDA spikes, but not calcium spikes, for 75% of their length. This suggests that basal dendrites, despite their proximity to the site of action potential initiation, do not form a single basal-somatic region but rather should be considered as a separate integrative compartment favoring two integration modes: subthreshold, location-independent summation versus local amplification of incoming spatiotemporally clustered information.

Published

2007

191. Dendritic calcium spikes induce bi-directional synaptic plasticity in the lateral amygdala

Author

Andreas Lüthi and Yann Humeau

Subjects

Male, Patch-Clamp Techniques, Action Potentials, Spider Venoms, Nonsynaptic plasticity, In Vitro Techniques, Mice, Cellular and Molecular Neuroscience, Nickel, Postsynaptic potential, Synaptic augmentation, Neural Pathways, Reaction Time, Animals, Anesthetics, Local, Neurons, Pharmacology, Dendritic spike, Neuronal Plasticity, Chemistry, Excitatory Postsynaptic Potentials, Lidocaine, Long-term potentiation, Dendrites, Amygdala, Calcium Channel Blockers, Electric Stimulation, Mice, Inbred C57BL, Synaptic fatigue, Verapamil, Synapses, Synaptic plasticity, Excitatory postsynaptic potential, Calcium, Neuroscience

Abstract

Postsynaptic induction of long-term potentiation (LTP) at cortical and thalamic afferent synapses onto lateral amygdala (LA) projection neurons not only involves NMDA receptor activation, but also depends on L-type voltage-dependent calcium channels (L-VDCCs). Here we show, using whole cell recordings and two-photon Ca2+ imaging, that L-VDCCs contribute to the induction of dendritic Ca2+ spikes in LA projection neurons. Dendritic Ca2+ spikes can be induced in the absence of sodium spikes by supra-threshold somatic depolarization or by pairing sub-threshold depolarization with synaptic stimulation. Moreover, synaptic induction of Ca2+ spikes is facilitated by R-VDCCs in a pathway-specific manner. Once induced, dendritic Ca2+ spikes propagate into large parts of the dendritic tree. We show that pairing synaptic stimulation with single dendritic Ca2+ spikes can induce bi-directional plasticity, the sign of which might be determined by the anatomical location of active synaptic inputs relative to the spike initiation zone. These data suggest an important role for dendritic Ca2+ spikes in dendritic integration and provide a mechanism by which local synaptic activity may influence global dendritic integration in LA projection neurons.

Published

2007

192. Coding with spike shapes and graded potentials in cortical networks

Author

Mikko Juusola, Gonzalo G. de Polavieja, and Hugh P. C. Robinson

Subjects

Cerebral Cortex, Neurons, Physics, Dendritic spike, Information processing, Action Potentials, Dendrites, Local field potential, Neurotransmission, Axons, General Biochemistry, Genetics and Molecular Biology, Postsynaptic potential, Synapses, Animals, Graded potential, Spike (software development), Neural coding, Neuroscience

Abstract

In cortical neurones, analogue dendritic potentials are thought to be encoded into patterns of digital spikes. According to this view, neuronal codes and computations are based on the temporal patterns of spikes: spike times, bursts or spike rates. Recently, we proposed an 'action potential waveform code' for cortical pyramidal neurones in which the spike shape carries information. Broader somatic action potentials are reliably produced in response to higher conductance input, allowing for four times more information transfer than spike times alone. This information is preserved during synaptic integration in a single neurone, as back-propagating action potentials of diverse shapes differentially shunt incoming postsynaptic potentials and so participate in the next round of spike generation. An open question has been whether the information in action potential waveforms can also survive axonal conduction and directly influence synaptic transmission to neighbouring neurones. Several new findings have now brought new light to this subject, showing cortical information processing that transcends the classical models.

Published

2007

193. Ultrastructural evidence for pre- and postsynaptic localization of Cav1.2 L-type Ca2+ channels in the rat hippocampus

Author

Nicole Langwieser, Teresa A. Milner, Yoland Smith, Amy S. Lee, Jean-Francois Pare, Alyssa L. Tippens, and Sven Moosmang

Subjects

Male, Dendritic spine, Calcium Channels, L-Type, Dendritic Spines, Presynaptic Terminals, Synaptic Membranes, Nonsynaptic plasticity, Hippocampal formation, Biology, Hippocampus, Synaptic Transmission, Cell Line, Rats, Sprague-Dawley, Mice, medicine, Animals, Humans, Calcium Signaling, Axon, Microscopy, Immunoelectron, Neurons, Dendritic spike, Pyramidal Cells, General Neuroscience, Dentate gyrus, Granule cell, Rats, Protein Subunits, medicine.anatomical_structure, nervous system, Dentate Gyrus, Synapses, Biophysics, Pyramidal cell, Neuroscience

Abstract

In the hippocampal formation, Ca(v)1.2 (L-type) voltage-gated Ca(2+) channels mediate Ca(2+) signals that can trigger long-term alterations in synaptic efficacy underlying learning and memory. Immunocytochemical studies indicate that Ca(v)1.2 channels are localized mainly in the soma and proximal dendrites of hippocampal pyramidal neurons, but electrophysiological data suggest a broader distribution of these channels. To define the subcellular substrates underlying Ca(v)1.2 Ca(2+) signals, we analyzed the localization of Ca(v)1.2 in the hippocampal formation by using antibodies against the pore-forming alpha(1)-subunit of Ca(v)1.2 (alpha(1)1.2). By light microscopy, alpha(1)1.2-like immunoreactivity (alpha(1)1.2-IR) was detected in pyramidal cell soma and dendritic fields of areas CA1-CA3 and in granule cell soma and fibers in the dentate gyrus. At the electron microscopic level, alpha(1)1.2-IR was localized in dendrites, but also in axons, axon terminals, and glial processes in all hippocampal subfields. Plasmalemmal immunogold particles representing alpha(1)1.2-IR were more significant for small- than large-caliber dendrites and were largely associated with extrasynaptic regions in dendritic spines and axon terminals. These findings provide the first detailed ultrastructural analysis of Ca(v)1.2 localization in the brain and support functionally diverse roles of these channels in the hippocampal formation.

Published

2007

194. Widespread and Highly Correlated Somato-dendritic Activity in Cortical Layer 5 Neurons.

Author

Beaulieu-Laroche, Lou, Toloza, Enrique H.S., Brown, Norma J., and Harnett, Mark T.

Subjects

*DENDRITES, *NEURONS, *PYRAMIDAL neurons, *VISUAL perception, *VISUAL cortex, *INFORMATION processing, *CALCIUM

Abstract

Dendritic integration can expand the information-processing capabilities of neurons. However, the recruitment of active dendritic processing in vivo and its relationship to somatic activity remain poorly understood. Here, we use two-photon GCaMP6f imaging to simultaneously monitor dendritic and somatic compartments in the awake primary visual cortex. Activity in layer 5 pyramidal neuron somata and distal apical trunk dendrites shows surprisingly high functional correlation. This strong coupling persists across neural activity levels and is unchanged by visual stimuli and locomotion. Ex vivo combined somato-dendritic patch-clamp and GCaMP6f recordings indicate that dendritic signals specifically reflect local electrogenesis triggered by dendritic inputs or high-frequency bursts of somatic action potentials. In contrast to the view that dendrites are only sparsely recruited under highly specific conditions in vivo , our results provide evidence that active dendritic integration is a widespread and intrinsic feature of cortical computation. • Layer 5 neuron apical dendrites exhibit frequent GCaMP6f signals • Calcium electrogenesis underlies dendritic GCaMP6f signals • Dendritic activity is highly correlated with somatic activity • Visual stimuli and running do not change somato-dendritic GCaMP6f correlation Beaulieu-Laroche et al. perform near-simultaneous calcium imaging of somatic and dendritic activity to reveal that active dendritic integration is an integral feature of information processing in cortical pyramidal neurons. [ABSTRACT FROM AUTHOR]

Published

2019

195. T-type calcium channels trigger a hyperpolarization induced afterdepolarization in substantia nigra dopamine neurons

Author

Zayd M. Khaliq and Rebekah C. Evans

Subjects

Dendritic spike, Voltage-dependent calcium channel, Chemistry, General Neuroscience, T-type calcium channel, Depolarization, Hyperpolarization (biology), Cellular and Molecular Neuroscience, Electrophysiology, medicine.anatomical_structure, Calcium imaging, Poster Presentation, medicine, Neuron, Neuroscience

Abstract

Dopamine neuron dendrites integrate synaptic information arriving from a diverse set of cell classes including excitatory and inhibitory neurons. The majority of synapses formed onto substantia nigra (SNc) dopamine neurons (>70 %) arrive from inhibitory GABAergic neurons [1]. Activation of GABA receptors pauses tonic firing and hyperpolarizes cells. Although the pause in dopamine neuron firing has behavioral relevance during reward omission [2], the hyperpolarization may also enable burst firing through disinhibition [3] or engagement of voltage-gated ion channels [4]. However, it is not clear how hyperpolarization influences dendritic integration. Here we use detailed single-cell computational modeling, patch-clamp electrophysiology, and two-photon calcium imaging to investigate the dendritic response to hyperpolarization. We find that at hyperpolarized potentials, some dopamine neurons respond to brief somatic current injections with a long-lasting depolarizing plateau that is accompanied by a large calcium transient in the dendrites. Because this depolarizing plateau requires prior hyperpolarization, we will refer to it as a hyperpolarization induced afterdepolarization (HI-ADP). Using electrophysiology and calcium imaging, we found that pharmacological block of T-type calcium currents with TTA-P2 completely eliminated the dendritic calcium transient and greatly reduced the size of the HI-ADP. In contrast, blocking L-type calcium channels with nifedipine did not significantly alter the dendritic calcium or size of the HI-ADP. To further investigate the involvement of dendritic T-currents in generating the HI-ADP, we developed a multi-compartmental, multi-channel model of an SNc dopamine neuron in Genesis simulation software. This model contains a spherical soma with two dendritic trees extending from it, each containing identical primary, secondary and tertiary branches. Our simulations showed that a high density of dendritic T-type calcium channels is critical to the generation of the HI-ADP. Specifically, we found that reducing the T-type channel conductance by half throughout the entire cell completely abolished the HI-ADP. On the other hand, removing T-type channels from only one dendritic tree slightly reduced, but did not eliminate the HI-ADP. These simulations show that a high, localized density of T-type channels is more important to the generation of the HI-ADP than the total number of T-type channels in the cell. Further simulations predict that the tightly coupled, electrotonically compact dendrites characteristic of SNc dopamine neurons are also necessary for the production of the HI-ADP. In particular, reducing the membrane input resistance of the model cell eliminated the HI-ADP. Confirming this prediction, our experimental data show that reducing the input resistance of SNc dopamine neurons through activation of G-protein coupled inwardly-rectifying potassium channels (GIRKs) abolished the HI-ADP and reduced the concomitant dendritic calcium transient. In conclusion, we have shown that T-type calcium channels and electrotonically compact dendrites are essential for generating a HI-ADP in SNc dopamine neurons. These HI-ADPs represent an interesting response to hyperpolarization that may be unique to SNc dopamine neurons having the specific combination of high T-type channel density and tight electrotonically compact dendrites. This particular combination of characteristics may allow SNc dopamine neurons to respond to inhibition or the release of inhibition with an increased ability to burst.

Published

2015

196. The shaping of two distinct dendritic spikes by A-type voltage-gated K+ channels

Author

Sungchil Yang, Sunggu Yang, and Cha-Min Tang

Subjects

Dendritic spike, Voltage-dependent calcium channel, Chemistry, Calcium channel, Conductance, Dendrite, Hippocampal formation, CA1 pyramidal neuron, lcsh:RC321-571, dendritic integration, Dendritic excitability, Cellular and Molecular Neuroscience, medicine.anatomical_structure, voltage-gated calcium channels, nervous system, medicine, NMDA receptor, calcium channel, A-type K+ channels, Neuroscience, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Ion channel, Original Research

Abstract

Dendritic ion channels have been a subject of intense research in neuroscience because active ion channels in dendrites shape input signals. Ca(2+)-permeable channels including NMDA receptors (NMDARs) have been implicated in supralinear dendritic integration, and the IA conductance in sublinear integration. Despite their essential roles in dendritic integration, it has remained uncertain whether these conductance coordinate with, or counteract, each other in the process of dendritic integration. To address this question, experiments were designed in hippocampal CA1 neurons with a recent 3D digital holography system that has shown excellent performance for spatial photoactivation. The results demonstrated a role of IA as a key modulator for two distinct dendritic spikes, low- and high-threshold Ca(2+) spikes, through a preferential action of IA on Ca(2+)-permeable channel-mediated currents, over fast AMPAR-mediated currents. It is likely that the rapid kinetics of IA provides feed-forward inhibition to counteract the regenerative Ca(2+) channel-mediated dendritic excitability. This research reveals one dynamic ionic mechanism of dendritic integration, and may contribute to a new understanding of neuronal hyperexcitability embedded in several neural diseases such as epilepsy, fragile X syndrome and Alzheimer's disease.

Published

2015

197. Impact of calcium-activated potassium channels on NMDA spikes in cortical layer 5 pyramidal neurons

Author

Greg J. Stuart and Tobias Bock

Subjects

0301 basic medicine, Physiology, Small-Conductance Calcium-Activated Potassium Channels, Action Potentials, Inhibitory postsynaptic potential, Receptors, N-Methyl-D-Aspartate, SK channel, 03 medical and health sciences, 0302 clinical medicine, Animals, Large-Conductance Calcium-Activated Potassium Channels, Rats, Wistar, Cerebral Cortex, Dendritic spike, Voltage-dependent calcium channel, Chemistry, General Neuroscience, Pyramidal Cells, Potassium channel, Calcium-activated potassium channel, Rats, 030104 developmental biology, nervous system, Synapses, Excitatory postsynaptic potential, NMDA receptor, Rapid Reports, Neuroscience, 030217 neurology & neurosurgery

Abstract

Active electrical events play an important role in shaping signal processing in dendrites. As these events are usually associated with an increase in intracellular calcium, they are likely to be under the control of calcium-activated potassium channels. Here, we investigate the impact of calcium-activated potassium channels on N-methyl-d-aspartate (NMDA) receptor-dependent spikes, or NMDA spikes, evoked by glutamate iontophoresis onto basal dendrites of cortical layer 5 pyramidal neurons. We found that small-conductance calcium-activated potassium channels (SK channels) act to reduce NMDA spike amplitude but at the same time, also decrease the iontophoretic current required for their generation. This SK-mediated decrease in NMDA spike threshold was dependent on R-type voltage-gated calcium channels and indicates a counterintuitive, excitatory effect of SK channels on NMDA spike generation, whereas the capacity of SK channels to suppress NMDA spike amplitude is in line with the expected inhibitory action of potassium channels on dendritic excitability. Large-conductance calcium-activated potassium channels had no significant impact on NMDA spikes, indicating that these channels are either absent from basal dendrites or not activated by NMDA spikes. These experiments reveal complex and opposing interactions among NMDA receptors, SK channels, and voltage-gated calcium channels in basal dendrites of cortical layer 5 pyramidal neurons during NMDA spike generation, which are likely to play an important role in regulating the way these neurons integrate the thousands of synaptic inputs they receive.

Published

2015

198. Spatial dynamics of action potentials estimated by dendritic Ca(2+) signals in insect projection neurons

Author

Ruriko Mitani and Hiroto Ogawa

Subjects

Male, Spike propagation, Calcium imaging, Biophysics, Action Potentials, Dendrite, Insect neuron, Biology, Neurotransmission, Biochemistry, Synaptic Transmission, Gryllidae, Interneurons, medicine, Animals, Calcium Signaling, Molecular Biology, Spike initiation zone, Calcium signaling, Dendritic spike, Voltage-dependent calcium channel, Laterality, Cell Biology, Anatomy, Dendrites, Synaptic Potentials, Antidromic, medicine.anatomical_structure, Synapses, Insect Proteins, Calcium, Neuron, Calcium Channels

Abstract

The spatial dynamics of action potentials, including their propagation and the location of spike initiation zone (SIZ), are crucial for the computation of a single neuron. Compared with mammalian central neurons, the spike dynamics of invertebrate neurons remain relatively unknown. Thus, we examined the spike dynamics based on single spike-induced Ca(2+) signals in the dendrites of cricket mechanosensory projection neurons, known as giant interneurons (GIs). The Ca(2+) transients induced by a synaptically evoked single spike were larger than those induced by an antidromic spike, whereas subthreshold synaptic potentials caused no elevation of Ca(2+). These results indicate that synaptic activity enhances the dendritic Ca(2+) influx through voltage-gated Ca(2+) channels. Stimulation of the presynaptic sensory afferents ipsilateral to the recording site evoked a dendritic spike with higher amplitude than contralateral stimulation, thereby suggesting that alteration of the spike waveform resulted in synaptic enhancement of the dendritic Ca(2+) transients. The SIZ estimated from the spatial distribution of the difference in the Ca(2+) amplitude was distributed throughout the right and left dendritic branches across the primary neurite connecting them in GIs.

Published

2015

199. Foundational dendritic processing that is independent of the cell type-specific structure in model primary neurons

Author

Charles J. Heckman and Hojeong Kim

Subjects

Dendritic spine, Patch-Clamp Techniques, Calcium Channels, L-Type, Cell type specific, Neocortex, Biology, Reduced model, Signal, Article, Purkinje Cells, medicine, Animals, Patch clamp, Dendritic spike, General Neuroscience, Pyramidal Cells, Dendrites, Spinal cord, CA3 Region, Hippocampal, Rats, medicine.anatomical_structure, Spinal Cord, Cats, Neuroscience, Ion Channel Gating

Abstract

It has long been known that primary neurons in the brain and spinal cord exhibit very distinctive dendritic structures. However, it remains unclear whether dendritic processing for signal propagation and channel activation over dendrites is a function of the cell type-specific dendritic structure. By applying an extended analysis of signal attenuation for the physiological distributions of synaptic inputs and active channels on dendritic branches, we first demonstrate that regardless of their specific structure, all anatomically reconstructed models of primary neurons display a similar pattern of directional signal attenuation and locational channel activation over their dendrites. Then, using a novel modeling approach that allows direct comparison of the anatomically reconstructed primary neurons with their reduced models that exclusively retain anatomical dendritic signaling without being associated with structural specificity, we show that the reduced model can accurately predict dendritic excitability of the anatomical model in both passive and active mode. These results indicate that the directional signaling, locational excitability and their relationship are foundational features of dendritic processing that are independent of the cell type-specific structure across primary neurons.

Published

2015

200. Dendritic sodium spikes are required for long-term potentiation at distal synapses on hippocampal pyramidal neurons

Author

Mark S. Cembrowski, Yu Jin Kim, Nelson Spruston, Ching-Lung Hsu, and Brett D. Mensh

Subjects

perforant pathway, QH301-705.5, Science, Long-Term Potentiation, dendritic excitability, Action Potentials, Hippocampus, Hippocampal formation, CA1 pyramidal neuron, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, dendritic sodium spike, Animals, rat, Biology (General), Rats, Wistar, 030304 developmental biology, long-term potentiation (LTP), 0303 health sciences, Dendritic spike, General Immunology and Microbiology, Perforant Pathway, Voltage-dependent calcium channel, Chemistry, Pyramidal Cells, General Neuroscience, Sodium channel, Sodium, dendritic sodium spikes, Long-term potentiation, Dendrites, General Medicine, Anatomy, Entorhinal cortex, Medicine, Neuroscience, 030217 neurology & neurosurgery, Research Article

Abstract

Dendritic integration of synaptic inputs mediates rapid neural computation as well as longer-lasting plasticity. Several channel types can mediate dendritically initiated spikes (dSpikes), which may impact information processing and storage across multiple timescales; however, the roles of different channels in the rapid vs long-term effects of dSpikes are unknown. We show here that dSpikes mediated by Nav channels (blocked by a low concentration of TTX) are required for long-term potentiation (LTP) in the distal apical dendrites of hippocampal pyramidal neurons. Furthermore, imaging, simulations, and buffering experiments all support a model whereby fast Nav channel-mediated dSpikes (Na-dSpikes) contribute to LTP induction by promoting large, transient, localized increases in intracellular calcium concentration near the calcium-conducting pores of NMDAR and L-type Cav channels. Thus, in addition to contributing to rapid neural processing, Na-dSpikes are likely to contribute to memory formation via their role in long-lasting synaptic plasticity. DOI: http://dx.doi.org/10.7554/eLife.06414.001, eLife digest When we explore somewhere new, we activate a region of the brain that processes spatial information called the entorhinal cortex. This brain region stimulates the brain's memory-formation center, known as the hippocampus, which in turn forms a spatial memory of the new place. The process of forming these memories involves strengthening nerve connections, including those between the entorhinal cortex and the hippocampus. Groups of neurons that produce synchronized electrical activity will naturally strengthen the nerve connections between them. This led scientists to predict that synchronized electrical activity between neurons in the entorhinal cortex and the hippocampus may contribute to the formation of spatial memories. Previous research revealed that hippocampal neurons produced short bursts of electrical activity that are localized at specific sites along their branched nerve processes that extend out of the cell body and are where inputs from other neurons are received. These types of localized electrical activity have been associated with a strengthening of the nerve connections between the entorhinal cortex and the hippocampal neurons. Ion channels that allow calcium to flow through these neurons' cell membranes had been identified as a potential source of these local electrical activities, and calcium is responsible for the strengthening of nerve connections. But it remained unclear whether channels that allow only sodium ions to flow through might also be involved. Kim, Hsu et al. have now investigated this question by devising a way to selectively block the electrical activity produced by sodium ion channels on the branched nerve processes of hippocampal neurons. Slices of rat brain were collected and an inhibitor that specifically affected the sodium channels was delivered to the brain slices. Electrodes were used to stimulate the inputs from the entorhinal cortex, and to monitor the resulting electrical activity in the hippocampal neurons. Kim, Hsu et al. analyzed the results and reproduced them using computer simulations, which showed that sodium ion channels are essential for triggering brief electrical events within the individual branches of nerve processes. These local electrical events appeared to activate calcium channels to produce highly concentrated, short-lived calcium signals that are necessary for strengthening nerve connections. Future studies will determine whether local electrical activity mediated by sodium channels is also involved in strengthening nerve connections between other types of neurons, and how this mechanism affects the formation of memories. DOI: http://dx.doi.org/10.7554/eLife.06414.002

Published

2015