Your search keyword '"Dendritic spike"' showing total 56 results

1. Distinctive receptive field and physiological properties of a wide-field amacrine cell in the macaque monkey retina.

Author

Manookin, Michael B., Puller, Christian, Rieke, Fred, Neitz, Jay, and Neitz, Maureen

Abstract

At early stages of visual processing, receptive fields are typically described as subtending local regions of space and thus performing computations on a narrow spatial scale. Nevertheless, stimulation well outside of the classical receptive field can exert clear and significant effects on visual processing. Given the distances over which they occur, the retinal mechanisms responsible for these long-range effects would certainly require signal propagation via active membrane properties. Here the physiology of a wide-field amacrine cell-the wiry cell-in macaque monkey retina is explored, revealing receptive fields that represent a striking departure from the classic structure. A single wiry cell integrates signals over wide regions of retina, 5-10 times larger than the classic receptive fields of most retinal ganglion cells. Wiry cells integrate signals over space much more effectively than predicted from passive signal propagation, and spatial integration is strongly attenuated during blockade of NMDA spikes but integration is insensitive to blockade of NaV channels with TTX. Thus these cells appear well suited for contributing to the long-range interactions of visual signals that characterize many aspects of visual perception. [ABSTRACT FROM AUTHOR]

Published

2015

2. Distinctive receptive field and physiological properties of a wide-field amacrine cell in the macaque monkey retina

Author

Fred Rieke, Maureen Neitz, Michael B. Manookin, Christian Puller, and Jay Neitz

Subjects

Male, Retinal Ganglion Cells, Visual perception, N-Methylaspartate, genetic structures, dendritic spike, Neural Circuits, Macaque, Retinal ganglion, Synaptic Transmission, Sodium Channels, Amacrine cell, Visual processing, biology.animal, medicine, Animals, Retina, Dendritic spike, biology, General Neuroscience, light encoding, medicine.anatomical_structure, Amacrine Cells, Receptive field, physiology, Macaca, Female, Visual Fields, Neuroscience, amacrine cell

Abstract

At early stages of visual processing, receptive fields are typically described as subtending local regions of space and thus performing computations on a narrow spatial scale. Nevertheless, stimulation well outside of the classical receptive field can exert clear and significant effects on visual processing. Given the distances over which they occur, the retinal mechanisms responsible for these long-range effects would certainly require signal propagation via active membrane properties. Here the physiology of a wide-field amacrine cell—the wiry cell—in macaque monkey retina is explored, revealing receptive fields that represent a striking departure from the classic structure. A single wiry cell integrates signals over wide regions of retina, 5–10 times larger than the classic receptive fields of most retinal ganglion cells. Wiry cells integrate signals over space much more effectively than predicted from passive signal propagation, and spatial integration is strongly attenuated during blockade of NMDA spikes but integration is insensitive to blockade of NaV channels with TTX. Thus these cells appear well suited for contributing to the long-range interactions of visual signals that characterize many aspects of visual perception.

Published

2015

3. Impact of subthreshold membrane potential on synaptic responses at dendritic spines of layer 5 pyramidal neurons in the prefrontal cortex

Author

Hannah J. Seong, Rudy Behnia, and Adam G. Carter

Subjects

Male, Patch-Clamp Techniques, Dendritic spine, Small-Conductance Calcium-Activated Potassium Channels, Physiology, Dendritic Spines, Prefrontal Cortex, Nonsynaptic plasticity, Dendrite, Voltage-Gated Sodium Channels, AMPA receptor, Neurotransmission, Receptors, N-Methyl-D-Aspartate, Membrane Potentials, Tissue Culture Techniques, Mice, medicine, Animals, Receptors, AMPA, Dendritic spike, Chemistry, Pyramidal Cells, General Neuroscience, Optical Imaging, Dendrites, Articles, medicine.anatomical_structure, Receptors, Glutamate, Potassium Channels, Voltage-Gated, Synapses, Synaptic plasticity, Calcium, Female, Neuroscience, Ion channel linked receptors

Abstract

Glutamatergic inputs onto cortical pyramidal neurons are received and initially processed at dendritic spines. AMPA and NMDA receptors generate both synaptic potentials and calcium (Ca) signals in the spine head. These responses can in turn activate a variety of Ca, sodium (Na), and potassium (K) channels at spines. In principle, the roles of these receptors and channels can be strongly regulated by the subthreshold membrane potential. However, the impact of different receptors and channels has usually been studied at the level of dendrites. Much less is known about their influence at spines, where synaptic transmission and plasticity primarily occur. Here we examine single-spine responses in the basal dendrites of layer 5 pyramidal neurons in the mouse prefrontal cortex. Using two-photon microscopy and two-photon uncaging, we first show that synaptic potentials and Ca signals differ at resting and near-threshold potentials. We then determine how subthreshold depolarizations alter the contributions of AMPA and NMDA receptors to synaptic responses. We show that voltage-sensitive Ca channels enhance synaptic Ca signals but fail to engage small-conductance Ca-activated K (SK) channels, which require greater numbers of inputs. Finally, we establish how the subthreshold membrane potential controls the ability of voltage-sensitive Na channels and K channels to influence synaptic responses. Our findings reveal how subthreshold depolarizations promote electrical and biochemical signaling at dendritic spines by regulating the contributions of multiple glutamate receptors and ion channels.

Published

2014

4. Development of dendritic tonic GABAergic inhibition regulates excitability and plasticity in CA1 pyramidal neurons

Author

Huibert D. Mansvelder, Martine R. Groen, Marinus P. Dekker, Joke Wortel, Arjen van Ooyen, Thomas Nevian, Rhiannon M. Meredith, Enrique Pérez-Garci, Ole Paulsen, Integrative Neurophysiology, Functional Genomics, and Neuroscience Campus Amsterdam - Brain Mechanisms in Health & Disease

Subjects

Male, Physiology, Nonsynaptic plasticity, Action Potentials, Tonic (physiology), GABA Antagonists, Bursting, SDG 3 - Good Health and Well-being, Animals, Rats, Wistar, CA1 Region, Hippocampal, GABA Agonists, Dendritic spike, Neuronal Plasticity, Chemistry, General Neuroscience, Pyramidal Cells, Excitatory Postsynaptic Potentials, Long-term potentiation, Dendrites, Articles, Receptors, GABA-A, Rats, Inhibitory Postsynaptic Potentials, Synaptic plasticity, Excitatory postsynaptic potential, GABAergic, Neuroscience

Abstract

Synaptic plasticity rules change during development: while hippocampal synapses can be potentiated by a single action potential pairing protocol in young neurons, mature neurons require burst firing to induce synaptic potentiation. An essential component for spike timing-dependent plasticity is the backpropagating action potential (BAP). BAP along the dendrites can be modulated by morphology and ion channel composition, both of which change during late postnatal development. However, it is unclear whether these dendritic changes can explain the developmental changes in synaptic plasticity induction rules. Here, we show that tonic GABAergic inhibition regulates dendritic action potential backpropagation in adolescent, but not preadolescent, CA1 pyramidal neurons. These developmental changes in tonic inhibition also altered the induction threshold for spike timing-dependent plasticity in adolescent neurons. This GABAergic regulatory effect on backpropagation is restricted to distal regions of apical dendrites (>200 μm) and mediated by α5-containing GABA(A) receptors. Direct dendritic recordings demonstrate α5-mediated tonic GABA(A) currents in adolescent neurons which can modulate BAPs. These developmental modulations in dendritic excitability could not be explained by concurrent changes in dendritic morphology. To explain our data, model simulations propose a distally increasing or localized distal expression of dendritic α5 tonic inhibition in mature neurons. Overall, our results demonstrate that dendritic integration and plasticity in more mature dendrites are significantly altered by tonic α5 inhibition in a dendritic region-specific and developmentally regulated manner. © 2014 the American Physiological Society.

Published

2014

5. Regulation of AMPA and NMDA receptor-mediated EPSPs in dendritic trees of thalamocortical cells

Author

Helmut Kröger, Igor Timofeev, and Francis Lajeunesse

Subjects

Physiology, Models, Neurological, Thalamus, Sensory system, AMPA receptor, Receptors, N-Methyl-D-Aspartate, Synaptic Transmission, Membrane Potentials, Neural Pathways, Animals, Receptors, AMPA, Receptor, Cerebral Cortex, Neurons, Dendritic spike, Synaptic integration, Chemistry, General Neuroscience, Excitatory Postsynaptic Potentials, Articles, Dendrites, nervous system, Synapses, Cats, Excitatory postsynaptic potential, NMDA receptor, Neuroscience

Abstract

Two main excitatory synapses are formed at the dendritic arbor of first-order nuclei thalamocortical (TC) neurons. Ascending sensory axons primarily establish contacts at large proximal dendrites, whereas descending corticothalamic fibers form synapses on thin distal dendrites. With the use of a multicomparment computational model based on fully reconstructed TC neurons from the ventroposterolateral nucleus of the cat, we compared local responses at the site of stimulation as well as somatic responses induced by both α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor (AMPAR)- and N-methyl-d-aspartate receptor (NMDAR)-mediated currents. We found that AMPAR-mediated responses, when synapses were located at proximal dendrites, induced a larger depolarization at the level of soma, whereas NMDAR-mediated responses were more efficient for synapses located at distal dendrites. The voltage transfer and transfer impedance were higher for NMDAR than for AMPAR activation at any location. For both types of synaptic current and for both input locations at the dendritic arbor, somatic responses were characterized by a low variability despite the large variability found in local responses in dendrites. The large neurons had overall smaller somatic responses than small neurons, but this relation was not found in local dendritic responses. We conclude that in TC cells, the dendritic location of small synaptic inputs does not play a major role in the amplitude of a somatic response, but the size of the neuron does. The variability of response amplitude between cells was much larger than the variability within cells. This suggests possible functional segregation of TC neurons of different size.

Published

2013

6. Systems-based analysis of dendritic nonlinearities reveals temporal feature extraction in mouse L5 cortical neurons

Author

Daniel Johnston, Richard Gray, Erik P. Cook, and Brian E. Kalmbach

Subjects

0301 basic medicine, Male, Patch-Clamp Techniques, Time Factors, Physiology, Feature extraction, Computer Science::Neural and Evolutionary Computation, Models, Neurological, Action Potentials, Prefrontal Cortex, Dendrite, Quantitative Biology::Subcellular Processes, Tissue Culture Techniques, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Dendritic spike, Quantitative Biology::Neurons and Cognition, Chemistry, Pyramidal Neuron, General Neuroscience, Pyramidal Cells, Sodium, Cortical neurons, Dendrites, Cations, Monovalent, Electric Stimulation, Mice, Inbred C57BL, Nonlinear system, Electrophysiology, 030104 developmental biology, medicine.anatomical_structure, Nonlinear Dynamics, Linear Models, Neuroscience, 030217 neurology & neurosurgery, Research Article

Abstract

What do dendritic nonlinearities tell a neuron about signals injected into the dendrite? Linear and nonlinear dendritic components affect how time-varying inputs are transformed into action potentials (APs), but the relative contribution of each component is unclear. We developed a novel systems-identification approach to isolate the nonlinear response of layer 5 pyramidal neuron dendrites in mouse prefrontal cortex in response to dendritic current injections. We then quantified the nonlinear component and its effect on the soma, using functional models composed of linear filters and static nonlinearities. Both noise and waveform current injections revealed linear and nonlinear components in the dendritic response. The nonlinear component consisted of fast Na+spikes that varied in amplitude 10-fold in a single neuron. A functional model reproduced the timing and amplitude of the dendritic spikes and revealed that they were selective to a preferred input dynamic (~4.5 ms rise time). The selectivity of the dendritic spikes became wider in the presence of additive noise, which was also predicted by the functional model. A second functional model revealed that the dendritic spikes were weakly boosted before being linearly integrated at the soma. For both our noise and waveform dendritic input, somatic APs were dependent on the somatic integration of the stimulus, followed a subset of large dendritic spikes, and were selective to the same input dynamics preferred by the dendrites. Our results suggest that the amplitude of fast dendritic spikes conveys information about high-frequency features in the dendritic input, which is then combined with low-frequency somatic integration.NEW & NOTEWORTHY The nonlinear response of layer 5 mouse pyramidal dendrites was isolated with a novel systems-based approach. In response to dendritic current injections, the nonlinear component contained mostly fast, variable-amplitude, Na+spikes. A functional model accounted for the timing and amplitude of the dendritic spikes and revealed that dendritic spikes are selective to a preferred input dynamic, which was verified experimentally. Thus, fast dendritic nonlinearities behave as high-frequency feature detectors that influence somatic action potentials.

Published

2016

7. Distance- and activity-dependent modulation of spike back-propagation in layer V pyramidal neurons of the medial entorhinal cortex

Author

Sonia Gasparini

Subjects

Dendritic spike, Neuronal Plasticity, Neocortex, Physiology, Chemistry, Nerve net, Pyramidal Cells, General Neuroscience, Action Potentials, Articles, Hippocampal formation, Entorhinal cortex, Rats, Rats, Sprague-Dawley, medicine.anatomical_structure, Neuroplasticity, Synaptic plasticity, medicine, Animals, Entorhinal Cortex, Soma, Nerve Net, Neuroscience, Cells, Cultured

Abstract

Layer V principal neurons of the medial entorhinal cortex receive the main hippocampal output and relay processed information to the neocortex. Despite the fundamental role hypothesized for these neurons in memory replay and consolidation, their dendritic features are largely unknown. High-speed confocal and two-photon Ca2+ imaging coupled with somatic whole cell patch-clamp recordings were used to investigate spike back-propagation in these neurons. The Ca2+ transient associated with a single back-propagating action potential was considerably smaller at distal dendritic locations (>200 μm from the soma) compared with proximal ones. Perfusion of Ba2+ (150 μM) or 4-aminopyridine (2 mM) to block A-type K+ currents significantly increased the amplitude of the distal, but not proximal, Ca2+ transients, which is strong evidence for an increased density of these channels at distal dendritic locations. In addition, the Ca2+ transients decreased with each subsequent spike in a 20-Hz train; this activity-dependent decrease was also more prominent at more distal locations and was attenuated by the perfusion of the protein kinase C activator phorbol-di-acetate. These data are consistent with a phosphorylation-dependent control of back-propagation during trains of action potentials, attributable mainly to an increase in the time constant of recovery from voltage-dependent inactivation of dendritic Na+ channels. In summary, dendritic Na+ and A-type K+ channels control spike back-propagation in layer V entorhinal neurons. Because the activity of these channels is highly modulated, the extent of the dendritic Ca2+ influx is as well, with important functional implications for dendritic integration and associative synaptic plasticity.

Published

2011

8. Dendritic Kv3.3 Potassium Channels in Cerebellar Purkinje Cells Regulate Generation and Spatial Dynamics of Dendritic Ca2+Spikes

Author

Satoshi Manita, Bernardo Rudy, William N. Ross, and Edward Zagha

Subjects

Cerebellum, Patch-Clamp Techniques, Physiology, Purkinje cell, Biophysics, Action Potentials, Tetrodotoxin, In Vitro Techniques, GABA Antagonists, Mice, Purkinje Cells, chemistry.chemical_compound, Potassium Channel Blockers, medicine, Animals, Patch clamp, 6-Cyano-7-nitroquinoxaline-2,3-dione, Mice, Knockout, Dendritic spike, General Neuroscience, Tetraethylammonium, Potassium channel blocker, Dendrites, Articles, Electric Stimulation, Potassium channel, Pyridazines, medicine.anatomical_structure, Animals, Newborn, Shaw Potassium Channels, chemistry, CNQX, Calcium, Peptides, Excitatory Amino Acid Antagonists, Neuroscience, Sodium Channel Blockers, medicine.drug

Abstract

Purkinje cell dendrites are excitable structures with intrinsic and synaptic conductances contributing to the generation and propagation of electrical activity. Voltage-gated potassium channel subunit Kv3.3 is expressed in the distal dendrites of Purkinje cells. However, the functional relevance of this dendritic distribution is not understood. Moreover, mutations in Kv3.3 cause movement disorders in mice and cerebellar atrophy and ataxia in humans, emphasizing the importance of understanding the role of these channels. In this study, we explore functional implications of this dendritic channel expression and compare Purkinje cell dendritic excitability in wild-type and Kv3.3 knockout mice. We demonstrate enhanced excitability of Purkinje cell dendrites in Kv3.3 knockout mice, despite normal resting membrane properties. Combined data from local application pharmacology, voltage clamp analysis of ionic currents, and assessment of dendritic Ca2+spike threshold in Purkinje cells suggest a role for Kv3.3 channels in opposing Ca2+spike initiation. To study the physiological relevance of altered dendritic excitability, we measured [Ca2+]ichanges throughout the dendritic tree in response to climbing fiber activation. Ca2+signals were specifically enhanced in distal dendrites of Kv3.3 knockout Purkinje cells, suggesting a role for dendritic Kv3.3 channels in regulating propagation of electrical activity and Ca2+influx in distal dendrites. These findings characterize unique roles of Kv3.3 channels in dendrites, with implications for synaptic integration, plasticity, and human disease.

Published

2010

9. 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

10. 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

11. 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

12. 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

13. 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

14. 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

15. 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

16. 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

17. 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

18. Axo-Somatic and Apical Dendritic Kv7/M Channels Differentially Regulate the Intrinsic Excitability of Adult Rat CA1 Pyramidal Cells

Author

Yoel Yaari and Cuiyong Yue

Subjects

Dendritic spike, Potassium Channels, Physiology, Chemistry, Somatic cell, Pyramidal Cells, General Neuroscience, Action Potentials, Dendrites, Hippocampus, Synaptic Transmission, Axons, Rats, Cell biology, M current, Animals, Ion Channel Gating, Neuroscience, Cells, Cultured

Abstract

Kv7/KCNQ/M channel subunits are widely expressed in peripheral and central neurons, where they give rise to a muscarinic-sensitive, subthreshold, and noninactivating K+ current (M current). Immunohistochemical data suggest that Kv7/M channels are expressed in both axons, somata and dendrites, but their distinctive roles in these compartments are not known. Here we used intracellular microelectrode recordings to monitor the effects of selective Kv7/M channel modulators focally applied to the axo-somatic region and to the apical dendrites of adult rat CA1 pyramidal cells. We show that both compartments express functional Kv7/M channels that synergistically control intrinsic neuronal excitability, albeit in different ways. Axo-somatic Kv7/M channels activate during the spike afterdepolarization (ADP) and counteract the depolarizing drive furnished by conjointly activated persistent Na+ channels. Thereby they limit the size and duration of the spike ADP and prevent its escalation into a somatic spike burst. Apical dendritic Kv7/M channels do not ordinarily regulate the somatic spike ADP and spike output. In hyperexcitable conditions that promote Ca2+ electrogenesis in these dendrites, they elevate the threshold for initiating Ca2+ spikes and associated downstream spike bursts. Thus the concerted activity of Kv7/M channels in both compartments serves to reduce the propensity to generate self-sustained burst responses and fosters a regular, stimulus-graded spike output of the neuron. Given that the activity of Kv7/M channels is regulated by multiple neurotransmitters, they may provide a substrate for neuromodulation of neuronal input/output relations at both the axo-somatic and apical dendritic regions.

Published

2006

19. Dendritic Na+ Current Inactivation Can Increase Cell Excitability By Delaying a Somatic Depolarizing Afterpotential

Author

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

Subjects

Patch-Clamp Techniques, Time Factors, Physiology, Somatic cell, Models, Neurological, Cell, Action Potentials, Tetrodotoxin, Sodium Channels, Na current, Membrane Potentials, medicine, Animals, Electric Organ, Dendritic spike, Chemistry, Pyramidal Cells, General Neuroscience, Dose-Response Relationship, Radiation, Depolarization, Dendrites, Electric Stimulation, medicine.anatomical_structure, Nonlinear Dynamics, Soma, Neuroscience, Electric Fish, Sodium Channel Blockers

Abstract

Many central neurons support active dendritic spike backpropagation mediated by voltage-gated currents. Active spikes in dendrites have been shown capable of providing feedback to the soma to influence somatic excitability and firing dynamics through a depolarizing afterpotential (DAP). In pyramidal cells of the electrosensory lobe of weakly electric fish, Na+ spikes in dendrites undergo a frequency-dependent broadening that enhances the DAP to increase somatic firing frequency. We use a combination of dynamical analysis and electrophysiological recordings to demonstrate that spike broadening in dendrites is primarily caused by a cumulative inactivation of dendritic Na+ current. We further show that a reduction in dendritic Na+ current increases excitability by decreasing the interspike interval and promoting burst firing. This process arises when inactivation of dendritic Na+ current shifts the latency of the dendritic spike to delay the arrival of the DAP sufficiently to increase its impact on somatic membrane potential despite a reduction in dendritic excitability. Furthermore, the relationship between dendritic Na+ current density and somatic excitability is nonmonotonic, as intermediate levels of dendritic Na+ current exert the greatest excitatory influence. These results reveal that temporal shifts in dendritic spike firing provide a novel means for backpropagating spikes to influence the final output of a cell.

Published

2005

20. Hyperpolarization-Activated Current Ih Disconnects Somatic and Dendritic Spike Initiation Zones in Layer V Pyramidal Neurons

Author

Thomas Berger, Walter Senn, and Hans-R. Lüscher

Subjects

Dendritic spike, Potassium Channels, Physiology, Somatic cell, Chemistry, Pyramidal Cells, General Neuroscience, Action Potentials, Cyclic Nucleotide-Gated Cation Channels, Dendrites, Somatosensory Cortex, Hyperpolarization (biology), Somatosensory system, Ion Channels, Rats, medicine.anatomical_structure, Apical dendrite, Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels, medicine, Biophysics, Animals, Low-threshold spikes, Rats, Wistar, Neuroscience

Abstract

Layer V pyramidal cells of the somatosensory cortex operate with two spike initiation zones. Subthreshold depolarizations are strongly attenuated along the apical dendrite linking the somatic and distal dendritic spike initiation zones. Sodium action potentials, on the other hand, are actively back-propagating from the axon hillock into the apical tuft. There they can interact with local excitatory input leading to the generation of calcium action potentials. We investigated if and how back-propagating sodium action potentials alone, without concomitant excitatory dendritic input, can initiate calcium action potentials in the distal dendrite. In acute slices of the rat somatosensory cortex, layer V pyramidal cells were studied under current-clamp with simultaneous recordings from the soma and the apical dendrite. A train of four somatic action potentials had to reach high frequencies to induce calcium action potentials in the dendrite (“critical frequency,” CF ∼100 Hz). Depolarization in the dendrite reduced the CF, while hyperpolarization increased it. The CF depended on the presence of the hyperpolarization-activated current Ih: blockade with 20 μM 4-( N-ethyl- N-phenylamino)-1,2-dimethyl-6-(methylamino) pyridinium chloride (ZD7288) reduced the CF to 68% of control. If the neurons were stimulated with noisy current injections, leading to in-vivo-like irregular spiking, no calcium action potentials were induced in the dendrite. However, after Ih channel blockade, calcium action potentials were frequently seen. These data suggest that Ih prevents initiation of the dendritic calcium action potential by proximal input alone. Dendritic calcium action potentials may therefore represent a unique signature for coincident somatic and dendritic activation.

Published

2003

21. Inhibition of Backpropagating Action Potentials in Mitral Cell Secondary Dendrites

Author

Graeme Lowe

Subjects

Male, Physiology, Cell, Presynaptic Terminals, Action Potentials, In Vitro Techniques, Inhibitory postsynaptic potential, Synaptic Transmission, medicine, Animals, gamma-Aminobutyric Acid, Dendritic spike, Photolysis, Chemistry, General Neuroscience, Electric Conductivity, Neural Inhibition, Rats, Inbred Strains, Dendrites, Receptors, GABA-A, Olfactory Bulb, Rats, Olfactory bulb, Electrophysiology, medicine.anatomical_structure, Action (philosophy), Neuroscience

Abstract

The mammalian olfactory bulb is a geometrically organized signal-processing array that utilizes lateral inhibitory circuits to transform spatially patterned inputs. A major part of the lateral circuitry consists of extensively radiating secondary dendrites of mitral cells. These dendrites are bidirectional cables: they convey granule cell inhibitory input to the mitral soma, and they conduct backpropagating action potentials that trigger glutamate release at dendrodendritic synapses. This study examined how mitral cell firing is affected by inhibitory inputs at different distances along the secondary dendrite and what happens to backpropagating action potentials when they encounter inhibition. These are key questions for understanding the range and spatial dependence of lateral signaling between mitral cells. Backpropagating action potentials were monitored in vitro by simultaneous somatic and dendritic whole cell recording from individual mitral cells in rat olfactory bulb slices, and inhibition was applied focally to dendrites by laser flash photolysis of caged GABA (2.5-microm spot). Photolysis was calibrated to activate conductances similar in magnitude to GABA(A)-mediated inhibition from granule cell spines. Under somatic voltage-clamp with CsCl dialysis, uncaging GABA onto the soma, axon initial segment, primary and secondary dendrites evoked bicuculline-sensitive currents (up to -1.4 nA at -60 mV; reversal at approximatety 0 mV). The currents exhibited a patchy distribution along the axon and dendrites. In current-clamp recordings, repetitive firing driven by somatic current injection was blocked by uncaging GABA on the secondary dendrite approximately 140 microm from the soma, and the blocking distance decreased with increasing current. In the secondary dendrites, backpropagated action potentials were measured 93-152 microm from the soma, where they were attenuated by a factor of 0.75 +/- 0.07 (mean +/- SD) and slightly broadened (1.19 +/- 0.10), independent of activity (35-107 Hz). Uncaging GABA on the distal dendrite had little effect on somatic spikes but attenuated backpropagating action potentials by a factor of 0.68 +/- 0.15 (0.45-0.60 microJ flash with 1-mM caged GABA); attenuation was localized to a zone of width 16.3 +/- 4.2 microm around the point of GABA release. These results reveal the contrasting actions of inhibition at different locations along the dendrite: proximal inhibition blocks firing by shunting somatic current, whereas distal inhibition can impose spatial patterns of dendrodendritic transmission by locally attenuating backpropagating action potentials. The secondary dendrites are designed with a high safety factor for backpropagation, to facilitate reliable transmission of the outgoing spike-coded data stream, in parallel with the integration of inhibitory inputs.

Published

2002

22. Propagation of Action Potentials From the Soma to Individual Dendrite of Cultured Rat Amacrine Cells Is Regulated by Local GABA Input

Author

Yoshitake Yamada, Akimichi Kaneko, Amane Koizumi, Eisuke Iwasaki, and Shu Ichi Watanabe

Subjects

Dendritic spike, Patch-Clamp Techniques, Physiology, Chemistry, General Neuroscience, Action Potentials, Dendrite, Dendrites, Tetrodotoxin, Inner plexiform layer, Inhibitory postsynaptic potential, Rats, Amacrine cell, Amacrine Cells, medicine.anatomical_structure, Postsynaptic potential, Lateral inhibition, medicine, Animals, Anesthetics, Local, Rats, Wistar, Axon, Neuroscience, Cells, Cultured, gamma-Aminobutyric Acid

Abstract

Retinal amacrine cells are interneurons that make lateral and vertical connections in the inner plexiform layer of the retina. Amacrine cells do not possess a long axon, and this morphological feature is the origin of their naming. Their dendrites function as both presynaptic and postsynaptic sites. Half of all amacrine cells are GABAergic inhibitory neurons that mediate lateral inhibition, and their light-evoked response consists of graded voltage changes and regenerative action potentials. There is evidence that the amount of neurotransmitter release from presynaptic sites is increased by spike propagation into the dendrite. Thus understanding of how action potentials propagate in dendrites is important to elucidating the extent and strength of lateral inhibition. In the present study, we used the dual whole cell patch-clamp technique on the soma and the dendrite of cultured rat amacrine cells and directly demonstrated that the action potentials propagate into the dendrites. The action potential in the dendrite was TTX sensitive and was affected by the local membrane potential of the dendrite. Propagation of the action potential was suppressed by local application of GABA to the dendrite. Dual dendrite whole cell patch-clamp recordings showed that GABA suppresses the propagation of action potentials in one dendrite of an amacrine cell, while the action potentials propagate in the other dendrites. It is likely that the action potentials in the dendrites are susceptible to various external factors resulting in the nonuniform propagation of the action potential from the soma of an amacrine cell.

Published

2002

23. Dendritic Voltage-Gated Ion Channels Regulate the Action Potential Firing Mode of Hippocampal CA1 Pyramidal Neurons

Author

Michael Carruth and Jeffrey C. Magee

Subjects

Patch-Clamp Techniques, Physiology, Action Potentials, Tetrodotoxin, In Vitro Techniques, Hippocampal formation, Hippocampus, Rats, Sprague-Dawley, Bursting, Cadmium Chloride, Nickel, medicine, Animals, Patch clamp, 4-Aminopyridine, Ion channel, Dendritic spike, Voltage-gated ion channel, Chemistry, Pyramidal Cells, General Neuroscience, Dendrites, Hyperpolarization (biology), Calcium Channel Blockers, Rats, medicine.anatomical_structure, Soma, Calcium Channels, Neuroscience

Abstract

The role of dendritic voltage-gated ion channels in the generation of action potential bursting was investigated using whole cell patch-clamp recordings from the soma and dendrites of CA1 pyramidal neurons located in hippocampal slices of adult rats. Under control conditions somatic current injections evoked single action potentials that were associated with an afterhyperpolarization (AHP). After localized application of 4-aminopyridine (4-AP) to the distal apical dendritic arborization, the same current injections resulted in the generation of an afterdepolarization (ADP) and multiple action potentials. This burst firing was not observed after localized application of 4-AP to the soma/proximal dendrites. The dendritic 4-AP application allowed large-amplitude Na+-dependent action potentials, which were prolonged in duration, to backpropagate into the distal apical dendrites. No change in action potential backpropagation was seen with proximal 4-AP application. Both the ADP and action potential bursting could be inhibited by the bath application of nonspecific concentrations of divalent Ca2+ channel blockers (NiCl and CdCl). Ca2+ channel blockade also reduced the dendritic action potential duration without significantly affecting spike amplitude. Low concentrations of TTX (10–50 nM) also reduced the ability of the CA1 neurons to fire in the busting mode. This effect was found to be the result of an inhibition of backpropagating dendritic action potentials and could be overcome through the coordinated injection of transient, large-amplitude depolarizing current into the dendrite. Dendritic current injections were able to restore the burst firing mode (represented as a large ADP) even in the presence of high concentrations of TTX (300–500 μM). These data suggest the role of dendritic Na+ channels in bursting is to allow somatic/axonal action potentials to backpropagate into the dendrites where they then activate dendritic Ca2+ channels. Although it appears that most Ca2+ channel subtypes are important in burst generation, blockade of T- and R-type Ca2+ channels by NiCl (75 μM) inhibited action potential bursting to a greater extent than L-channel (10 μM nimodipine) or N-, P/Q-type (1 μM ω-conotoxin MVIIC) Ca2+ channel blockade. This suggest that the Ni-sensitive voltage-gated Ca2+ channels have the most important role in action potential burst generation. In summary, these data suggest that the activation of dendritic voltage-gated Ca2+ channels, by large-amplitude backpropagating spikes, provides a prolonged inward current that is capable of generating an ADP and burst of multiple action potentials in the soma of CA1 pyramidal neurons. Dendritic voltage-gated ion channels profoundly regulate the processing and storage of incoming information in CA1 pyramidal neurons by modulating the action potential firing mode from single spiking to burst firing.

Published

1999

24. Fast Optical Recordings of Membrane Potential Changes From Dendrites of Pyramidal Neurons

Author

Srdjan D. Antic, Dejan Zecevic, and Guy Major

Subjects

Optics and Photonics, Physiology, Action Potentials, Stimulation, In Vitro Techniques, Somatosensory system, Membrane Potentials, Extracellular, medicine, Animals, Rats, Wistar, Coloring Agents, Membrane potential, Dendritic spike, Chemistry, Pyramidal Cells, General Neuroscience, Dendrites, Somatosensory Cortex, Rats, Radiation Injuries, Experimental, medicine.anatomical_structure, Optical recording, Biophysics, Soma, Artifacts, Neuroscience, Intracellular

Abstract

Understanding the biophysical properties of single neurons and how they process information is fundamental to understanding how the brain works. A technique that would allow recording of temporal and spatial dynamics of electrical activity in neuronal processes with adequate resolution would facilitate further research. Here, we report on the application of optical recording of membrane potential transients at many sites on neuronal processes of vertebrate neurons in brain slices using intracellular voltage-sensitive dyes. We obtained evidence that 1) loading the neurons with voltage-sensitive dye using patch electrodes is possible without contamination of the extracellular environment; 2) brain slices do not show any autofluorescence at the excitation/emission wavelengths used; 3) pharmacological effects of the dye were completely reversible; 4) the level of photodynamic damage already allows meaningful measurements and could be reduced further; 5) the sensitivity of the dye was comparable to that reported for invertebrate neurons; 6) the dye spread ∼500 μm into distal processes within 2 h incubation period. This distance should increase with longer incubation; 7) the optically recorded action potential signals from basolateral dendrites (that are difficult or impossible to approach by patch electrodes) and apical dendrites show that both direct soma stimulation and synaptic stimulation triggered action potentials that originated near the soma. The spikes backpropagated into both basolateral dendrites and apical processes; the propagation was somewhat faster in the apical dendrites.

Published

1999

25. Mechanisms Underlying Burst and Regular Spiking Evoked by Dendritic Depolarization in Layer 5 Cortical Pyramidal Neurons

Author

Wayne Crill and Peter C. Schwindt

Subjects

Male, Patch-Clamp Techniques, Physiology, Action Potentials, chemistry.chemical_element, In Vitro Techniques, Calcium, Somatosensory system, Membrane Potentials, Rats, Sprague-Dawley, Slice preparation, Animals, Patch clamp, Evoked Potentials, Membrane potential, Dendritic spike, Chemistry, Pyramidal Cells, General Neuroscience, Sodium, Excitatory Postsynaptic Potentials, Depolarization, Dendrites, Somatosensory Cortex, Rats, Excitatory postsynaptic potential, Female, Neuroscience

Abstract

Mechanisms underlying burst and regular spiking evoked by dendritic depolarization in layer 5 cortical pyramidal neurons. Apical dendrites of layer 5 pyramidal cells in a slice preparation of rat sensorimotor cortex were depolarized focally by long-lasting glutamate iontophoresis while recording intracellularly from their soma. In most cells the firing pattern evoked by the smallest dendritic depolarization that evoked spikes consisted of repetitive bursts of action potentials. During larger dendritic depolarizations initial burst firing was followed by regular spiking. As dendritic depolarization was increased further the duration (but not the firing rate) of the regular spiking increased, and the duration of burst firing decreased. Depolarization of the soma in most of the same cells evoked only regular spiking. When the dendrite was depolarized to a critical level below spike threshold, intrasomatic current pulses or excitatory postsynaptic potentials also triggered bursts instead of single spikes. The bursts were driven by a delayed depolarization (DD) that was triggered in an all-or-none manner along with the first Na+ spike of the burst. Somatic voltage-clamp experiments indicated that the action current underlying the DD was generated in the dendrite and was Ca2+ dependent. Thus the burst firing was caused by a Na+ spike-linked dendritic Ca2+spike, a mechanism that was available only when the dendrite was adequately depolarized. Larger dendritic depolarization that evoked late, constant-frequency regular spiking also evoked a long-lasting, Ca2+-dependent action potential (a “plateau”). The duration of the plateau but not its amplitude was increased by stronger dendritic depolarization. Burst-generating dendritic Ca2+spikes could not be elicited during this plateau. Thus plateau initiation was responsible for the termination of burst firing and the generation of the constant-frequency regular spiking. We conclude that somatic and dendritic depolarization can elicit quite different firing patterns in the same pyramidal neuron. The burst and regular spiking observed during dendritic depolarization are caused by two types of Ca2+-dependent dendritic action potentials. We discuss some functional implications of these observations.

Published

1999

26. Voltage-Dependent Properties of Dendrites That Eliminate Location-Dependent Variability of Synaptic Input

Author

Daniel Johnston and Erik P. Cook

Subjects

Physics, Dendritic spike, N-Methylaspartate, Physiology, General Neuroscience, Models, Neurological, Electric Conductivity, Action Potentials, Nonsynaptic plasticity, Dendrites, Synaptic Transmission, Synapses, Computer Simulation, Neuroscience, Voltage

Abstract

Voltage-dependent properties of dendrites that eliminate location-dependent variability of synaptic input. We examined the hypothesis that voltage-dependent properties of dendrites allow for the accurate transfer of synaptic information to the soma independent of synapse location. This hypothesis is motivated by experimental evidence that dendrites contain a complex array of voltage-gated channels. How these channels affect synaptic integration is unknown. One hypothesized role for dendritic voltage-gated channels is to counteract passive cable properties, rendering all synapses electrotonically equidistant from the soma. With dendrites modeled as passive cables, the effect a synapse exerts at the soma depends on dendritic location (referred to as location-dependent variability of the synaptic input). In this theoretical study we used a simplified three-compartment model of a neuron to determine the dendritic voltage-dependent properties required for accurate transfer of synaptic information to the soma independent of synapse location. A dendrite that eliminates location-dependent variability requires three components: 1) a steady-state, voltage-dependent inward current that together with the passive leak current provides a net outward current and a zero slope conductance at depolarized potentials, 2) a fast, transient, inward current that compensates for dendritic membrane capacitance, and 3) both αamino-3-hydroxy-5-methyl-4-isoxazolepropionic acid– and N-methyl-d-aspartate–like synaptic conductances that together permit synapses to behave as ideal current sources. These components are consistent with the known properties of dendrites. In addition, these results indicate that a dendrite designed to eliminate location-dependent variability also actively back-propagates somatic action potentials.

Published

1999

27. Dendritic Voltage and Calcium-Gated Channels Amplify the Variability of Postsynaptic Responses in a Purkinje Cell Model

Author

Erik De Schutter

Subjects

Dendritic spike, Physiology, General Neuroscience, Models, Neurological, Purkinje cell, Action Potentials, Excitatory Postsynaptic Potentials, chemistry.chemical_element, Neural Inhibition, Dendrites, Calcium, Electric Stimulation, Purkinje Cells, medicine.anatomical_structure, chemistry, Postsynaptic potential, Synapses, Reaction Time, medicine, Calcium Channels, Ion Channel Gating, Neuroscience, Voltage

Abstract

De Schutter, Erik. Dendritic voltage and calcium-gated channels amplify the variability of postsynaptic responses in a Purkinje cell model. J. Neurophysiol. 80: 504–519, 1998. The dendrites of most neurons express several types of voltage and Ca2+-gated channels. These ionic channels can be activated by subthreshold synaptic input, but the functional role of such activations in vivo is unclear. The interaction between dendritic channels and synaptic background input as it occurs in vivo was studied in a realistic computer model of a cerebellar Purkinje cell. It previously was shown using this model that dendritic Ca2+ channels amplify the somatic response to synchronous excitatory inputs. In this study, it is shown that dendritic ion channels also increased the somatic membrane potential fluctuations generated by the background input. This amplification caused a highly variable somatic excitatory postsynaptic potential (EPSP) in response to a synchronous excitatory input. The variability scaled with the size of the response in the model with excitable dendrite, resulting in an almost constant coefficient of variation, whereas in a passive model the membrane potential fluctuations simply added onto the EPSP. Although the EPSP amplitude in the active dendrite model was quite variable for different patterns of background input, it was insensitive to changes in the timing of the synchronous input by a few milliseconds. This effect was explained by slow changes in dendritic excitability. This excitability was determined by how the background input affected the dendritic membrane potentials in the preceding 10–20 ms, causing changes in activation of voltage and Ca2+-gated channels. The most important model variables determining the excitability at the time of a synchronous input were the Ca2+-activation of K+ channels and the inhibitory synaptic conductance, although many other model variables could be influential for particular background patterns. Experimental evidence for the amplification of postsynaptic variability by active dendrites is discussed. The amplification of the variability of EPSPs has important functional consequences in general and for cerebellar Purkinje cells specifically. Subthreshold, background input has a much larger effect on the responses to coherent input of neurons with active dendrites compared with passive dendrites because it can change the effective threshold for firing. This gives neurons with dendritic calcium channels an increased information processing capacity and provides the Purkinje cell with a gating function.

Published

1998

28. Synaptically Evoked Dendritic Action Potentials in Rat Neocortical Pyramidal Neurons

Author

W. E. Crill and Peter C. Schwindt

Subjects

Male, N-Methylaspartate, Physiology, Action Potentials, Glutamic Acid, Tetrodotoxin, Sodium Channels, Rats, Sprague-Dawley, Excitatory Amino Acid Agonists, Animals, 6-Cyano-7-nitroquinoxaline-2,3-dione, Dendritic spike, Iontophoresis, Chemistry, Pyramidal Cells, General Neuroscience, Motor Cortex, Excitatory Postsynaptic Potentials, Dendrites, Somatosensory Cortex, Electric Stimulation, Rats, 2-Amino-5-phosphonovalerate, Receptors, Glutamate, nervous system, Action (philosophy), Female, Neuroscience

Abstract

Schwindt, Peter C. and Wayne E. Crill. Synaptically evoked dendritic action potentials in rat neocortical pyramidal neurons. J. Neurophysiol. 79: 2432–2446, 1998. In a previous study iontophoresis of glutamate on the apical dendrite of layer 5 pyramidal neurons from rat neocortex was used to identify sites at which dendritic depolarization evoked small, prolonged Ca2+ spikes and/or low-threshold Na+ spikes recorded by an intracellular microelectrode in the soma. These spikes were identified as originating in the dendrite. Here we evoke similar dendritic responses by electrical stimulation of presynaptic elements near the tip of the iontophoretic electrode with the use of a second extracellular electrode. In 9 of 12 recorded cells, electrically evoked excitatory postsynaptic potentials (EPSPs) above a minimum size triggered all-or-none postsynaptic responses similar to those evoked by dendritic glutamate iontophoresis at the same site. Both the synaptically evoked and the iontophoretically evoked depolarizations were abolished reversably by blockade of glutamate receptors. In all recorded cells, the combination of iontophoresis and an EPSP, each of which was subthreshold for the dendritic spike when given alone, evoked a dendritic spike similar to that evoked by a sufficiently large iontophoresis. In one cell tested, dendritic spikes could be evoked by the summation of two independent subthreshold EPSPs evoked by stimulation at two different locations. We conclude that the dendritic spikes are not unique to the use of glutamate iontophoresis because similar spikes can be evoked by EPSPs. We discuss the implications of these results for synaptic integration and for the interpretation of recorded synaptic potentials.

Published

1998

29. Active Dendrites Reduce Location-Dependent Variability of Synaptic Input Trains

Author

Daniel Johnston and Erik P. Cook

Subjects

Dendritic spike, Physiology, Computer science, General Neuroscience, Models, Neurological, Animals, Computer Simulation, Dendrites, Synaptic Transmission, Neuroscience

Abstract

Cook, Erik P. and Daniel Johnston. Active dendrites reduce location-dependent variability of synaptic input trains. J. Neurophysiol. 78: 2116–2128, 1997. We examined the hypothesis that dendritic voltage-gated channels can reduce the effect synaptic location has on somatic depolarization in response to patterns of short synaptic trains (referred to as location-dependent variability). Three computer models of a reconstructed hippocampal CA1 cell, each of increasing realism and complexity, were used. For each model, the goal was to identify the dendritic composition that best reduced the location-dependent variability. The first model was linear and a single parameter, dendritic membrane conductance ( G Dm , where R m = 1/ G Dm ), was varied. Surprisingly, a negative G Dm minimized the location-dependent variability. Superposition of the synaptic inputs showed that, compared with passive dendrites, active dendrites increase the mean of the individual responses while decreasing the variance between synapses at different locations. Active dendrites compensate the three components of passive cable signal interference that increase with distance from the soma: the accumulation of charge on dendritic membrane capacitance, the escape of charge across synaptic and nonsynaptic dendritic membrane conductances, and the reduction in synaptic charge entry due to increased depolarization of dendrites located farther from the soma. We also found that the entire active dendritic tree contributes charge to any one active synapse. The second model contained an artificial voltage-dependent current ( I boost) added to passive apical dendrites. The optimal amount of I boost that minimized location-dependent variability was found to be independent of the strength of individual synaptic inputs but inversely related to the synaptic duration. In the third model, realistic T-type Ca2+ and persistent Na+ channel models were added to passive dendrites and numerically fit to reproduce the effects of I boost. Both realistic currents minimized synaptic variability. The densities for the realistic dendritic currents were not uniform but showed subtle variations and a slight reduction with distance from the soma. A heteroassociative memory network also was modeled to demonstrate the important relationship between location-dependent variability and memory recall performance. Compared with passive dendrites, active dendrites increased memory storage by reducing recall errors. These simulations demonstrate that active dendrites can minimize the cable properties of passive dendrites and enhance the soma's ability to determine the strength of the synaptic input. These models predict dendrites that minimize location-dependent variability will have an overall negative slope conductance I-V relationship that is tuned precisely.

Published

1997

30. IPSPs modulate spike backpropagation and associated [Ca2+]i changes in the dendrites of hippocampal CA1 pyramidal neurons

Author

Hiroshi Tsubokawa and William N. Ross

Subjects

Dendritic spike, Physiology, Chemistry, Pyramidal Cells, General Neuroscience, Presynaptic inhibition, Hippocampus, Dendrites, Hippocampal formation, Bicuculline, Neural backpropagation, Synaptic Transmission, Rats, Rats, Sprague-Dawley, Animals, Calcium, Neuroscience

Abstract

1. We studied the effects of synaptic inhibition on backpropagating Na+ spikes in the apical dendrites of CA1 pyramidal neurons in transverse slices from the rat hippocampus. Action potentials were evoked synaptically by stimulation in the stratum radiatum or antidromically by stimulation in the alveus. 2. Inhibitory postsynaptic potentials, evoked by stimulation in the stratum lacunosum moleculare, reduced the amplitude of single spikes in the distal dendrites but did not change the amplitudes in the somatic or proximal regions. Inhibition also reduced the spike-associated [Ca2+]i changes in the distal dendrites but had little effect on the changes in the proximal part of the cell. Both of these results are consistent with inhibition converting actively backpropagating spikes into passively spreading potentials at some point in the arbor. 3. In most cells, the spike amplitude reduction in the distal dendrites was blocked by bicuculline methiodide (10 microM) and inhibition was most effective when evoked in a time window < 10 ms preceding the action potential. This suggests that the amplitude reduction was due to a conductance shunt activated by gamma-aminobuturic acid-A (GABAA) receptors. Synaptically evoked GABAB responses were detected but usually did not block spike propagation. 4. Direct hyperpolarization in the distal dendrites was also effective in blocking antidromically evoked spike backpropagation but probably does not contribute when the action potentials are evoked synaptically. 5. This effect of inhibition is different from its usual function in synaptic integration because spike generation and propagation down the axon are not significantly affected. This kind of inhibition might be important in regulating transient [Ca2+]i changes in the dendrites including individual dendritic branches.

Published

1996

31. Propagation of action potentials in the dendrites of neurons from rat spinal cord slice cultures

Author

M. G. Rioult, Matthew E. Larkum, and Hans R. Lüscher

Subjects

Patch-Clamp Techniques, Physiology, Voltage clamp, Action Potentials, Dendrite, Local field potential, Synaptic Transmission, Sodium Channels, Membrane Potentials, chemistry.chemical_compound, Fetus, Culture Techniques, medicine, Animals, Patch clamp, Membrane potential, Dendritic spike, Chemistry, General Neuroscience, Dendrites, Rats, Antidromic, medicine.anatomical_structure, Spinal Cord, Biophysics, Tetrodotoxin, Calcium Channels, Neuroscience

Abstract

1. We examined the propagation of action potentials in the dendrites of ventrally located presumed motoneurons of organotypic rat spinal cord cultures. Simultaneous patch electrode recordings were made from the dendrites and somata of individual cells. In other experiments we visualized the membrane voltage over all the proximal dendrites simultaneously using a voltage-sensitive dye and an array of photodiodes. Calcium imaging was used to measure the dendritic rise in Ca2+ accompanying the propagating action potentials. 2. Spontaneous and evoked action potentials were recorded using high-resistance patch electrodes with separations of 30-423 microm between the somatic and dendritic electrodes. 3. Action potentials recorded in the dendrites varied considerably in amplitude but were larger than would be expected if the dendrites were to behave as passive cables (sometimes little or no decrement was seen for distances of > 100 microm). Because the amplitude of the action potentials in different dendrites was not a simple function of distance from the soma, we suggest that the conductance responsible for the boosting of the action potential amplitude varied in density from dendrite to dendrite and possibly along each dendrite. 4. The dendritic action potentials were usually smaller and broader and arrived later at the dendritic electrode than at the somatic electrode irrespective of whether stimulation occurred at the dendrite or soma or as a result of spontaneous synaptic activity. This is clear evidence that the action potential is initiated at or near the soma and spreads out into the dendrites. The conduction velocity of the propagating action potential was estimated to be 0.5 m/s. 5. The voltage time courses of previously recorded action potentials were generated at the soma using voltage clamp before and after applying 1 microM tetrodotoxin (TTX) over the soma and dendrites. TTX reduced the amplitude of the action potential at the dendritic electrode to a value in the range expected for dendrites that behave as passive cables. This indicates that the conductance responsible for the actively propagating action potentials is a Na+ conductance. 6. The amplitude of the dendritic action potential could also be initially reduced more than the somatic action potential using 1-10 mM QX-314 (an intracellular sodium channel blocker) in the dendritic electrode as the drug diffused from the dendritic electrode toward the soma. Furthermore, in some cases the action potential elicited by current injection into the dendrite had two components. The first component was blocked by QX-314 in the first few seconds of the diffusion of the blocker. 7. In some cells, an afterdepolarizing potential (ADP) was more prominent in the dendrite than in the soma. This ADP could be reversibly blocked by 1 mM Ni2+ or by perfusion of a nominally Ca2+-free solution over the soma and dendrites. This suggests that the back-propagating action potential caused an influx of Ca2+ predominantly in the dendrites. 8. With the use of a voltage-sensitive dye (di-8-ANEPPS) and an array of photodiodes, the action potential was tracked along all the proximal dendrites simultaneously. The results confirmed that the action potential propagated actively, in contrast to similarly measured hyperpolarizing pulses that spread passively. There were also indications that the action potential was not uniformly propagated in all the dendrites, suggesting the possibility that the distribution of Na+ channels over the dendritic membrane is not uniform. 9. Calcium imaging with the Ca2+ fluorescent indicator Fluo-3 showed a larger percentage change in fluorescence in the dendrites than in the soma. Both bursts and single action potentials elicited sharp rises in fluorescence in the proximal dendrites, suggesting that the back-propagating action potential causes a concomitant rise in intracellular calcium concentration...

Published

1996

32. Altered dendritic complexity affects firing properties of cortical layer 2/3 pyramidal neurons in mice lacking the 5-HT3A receptor

Author

Pascal Chameau, Luuk van der Velden, Johannes A. van Hooft, and Cellular and Computational Neuroscience (SILS, FNWI)

Subjects

Male, Dendritic spine, Patch-Clamp Techniques, Physiology, Models, Neurological, Biophysics, Action Potentials, In Vitro Techniques, Serotonergic, Mice, medicine, Animals, Computer Simulation, Patch clamp, Receptor, Electric stimulation, Cerebral Cortex, Mice, Knockout, Dendritic spike, Analysis of Variance, Chemistry, General Neuroscience, Lysine, Pyramidal Cells, Dendrites, Electric Stimulation, Cortex (botany), medicine.anatomical_structure, nervous system, Nonlinear Dynamics, Cerebral cortex, Female, Receptors, Serotonin, 5-HT3, Neuroscience

Abstract

We have previously shown that the serotonergic input on Cajal-Retzius cells, mediated by 5-HT3 receptors, plays an important role in the early postnatal maturation of the apical dendritic trees of layer 2/3 pyramidal neurons. We reported that knockout mice lacking the 5-HT3A receptor showed exuberant apical dendrites of these cortical pyramidal neurons. Because model studies have shown the role of dendritic morphology on neuronal firing pattern, we used the 5-HT3A knockout mouse to explore the impact of dendritic hypercomplexity on the electrophysiological properties of this specific class of neurons. Our experimental results show that hypercomplexity of the apical dendritic tuft of layer 2/3 pyramidal neurons affects neuronal excitability by reducing the amount of spike frequency adaptation. This difference in firing pattern, related to a higher dendritic complexity, was accompanied by an altered development of the afterhyperpolarization slope with successive action potentials. Our abstract and realistic neuronal models, which allowed manipulation of the dendritic complexity, showed similar effects on neuronal excitability and confirmed the impact of apical dendritic complexity. Alterations of dendritic complexity, as observed in several pathological conditions such as neurodegenerative diseases or neurodevelopmental disorders, may thus not only affect the input to layer 2/3 pyramidal neurons but also shape their firing pattern and consequently alter the information processing in the cortex.

Published

2012

33. Synaptic integration in an excitable dendritic tree

Author

Bartlett W. Mel

Subjects

N-Methylaspartate, Dendritic spine, Physiology, Models, Neurological, Context (language use), Neurotransmission, Receptors, N-Methyl-D-Aspartate, Synaptic Transmission, Membrane Potentials, medicine, Animals, Visual Cortex, Neurons, Dendritic spike, Chemistry, General Neuroscience, Dendrites, Associative learning, medicine.anatomical_structure, Synapses, Synaptic plasticity, Cats, Excitatory postsynaptic potential, Neural Networks, Computer, Pyramidal cell, Neuroscience

Abstract

1. Compartmental modeling experiments were carried out in an anatomically characterized neocortical pyramidal cell to study the integrative behavior of a complex dendritic tree containing active membrane mechanisms. Building on a previously presented hypothesis, this work provides further support for a novel principle of dendritic information processing that could underlie a capacity for nonlinear pattern discrimination and/or sensory processing within the dendritic trees of individual nerve cells. 2. It was previously demonstrated that when excitatory synaptic input to a pyramidal cell is dominated by voltage-dependent N-methyl-D-aspartate (NMDA)-type channels, the cell responds more strongly when synaptic drive is concentrated within several dendritic regions than when it is delivered diffusely across the dendritic arbor. This effect, called dendritic "cluster sensitivity," persisted under wide-ranging parameter variations and directly implicated the spatial ordering of afferent synaptic connections onto the dendritic tree as an important determinant of neuronal response selectivity. 3. In this work, the sensitivity of neocortical dendrites to spatially clustered synaptic drive has been further studied with fast sodium and slow calcium spiking mechanisms present in the dendritic membrane. Several spatial distributions of the dendritic spiking mechanisms were tested with and without NMDA synapses. Results of numerous simulations reveal that dendritic cluster sensitivity is a highly robust phenomenon in dendrites containing a sufficiency of excitatory membrane mechanisms and is only weakly dependent on their detailed spatial distribution, peak conductances, or kinetics. Factors that either work against or make irrelevant the dendritic cluster sensitivity effect include 1) very high-resistance spine necks, 2) very large synaptic conductances, 3) very high baseline levels of synaptic activity, and 4) large fluctuations in level of synaptic activity on short time scales. 4. The functional significance of dendritic cluster sensitivity has been previously discussed in the context of associative learning and memory. Here it is demonstrated that the dendritic tree of a cluster-sensitive neuron implements an approximative spatial correlation, or sum of products operation, such as that which could underlie nonlinear disparity tuning in binocular visual neurons.

Published

1993

34. Calcium transients in cerebellar Purkinje neurons evoked by intracellular stimulation

Author

William N. Ross, Hiroyoshi Miyakawa, V. Lev-Ram, and Nechama Lasser-Ross

Subjects

Time Factors, Fura-2, Physiology, Guinea Pigs, Fluorescence spectrometry, Action Potentials, chemistry.chemical_element, Tetrodotoxin, In Vitro Techniques, Calcium, Membrane Potentials, Purkinje Cells, chemistry.chemical_compound, Animals, Evoked Potentials, Membrane potential, Dendritic spike, Voltage-dependent calcium channel, General Neuroscience, Sodium channel, Dendrites, Kinetics, Electrophysiology, Spectrometry, Fluorescence, chemistry, Biophysics, Neuroscience

Abstract

1. Purkinje cells in thin slices from the guinea pig cerebellum were injected with fura-2 and high-speed sequences of fluorescence images from the cell body and entire dendritic tree were made while simultaneously recording somatic membrane potential during evoked and spontaneous electrical activity. The changes in fluorescence were interpreted in terms of changes in [Ca2+]i. 2. Individual calcium action potentials were usually accompanied by transient increases in [Ca2+]i all over the dendritic field. During evoked or spontaneous bursts of calcium spikes, [Ca2+]i increased more rapidly and to higher concentrations in fine dendrites than in thicker dendrites. At the end of a burst [Ca2+]i declined faster in thin dendrites than in thicker ones. These variations are most easily understood as deriving from the difference in surface-to-volume ratio of the two kinds of dendrites. 3. During bursts of calcium action potentials [Ca2+]i increases sometimes occurred only in individual dendritic branches, but always including the fine dendrites of that particular branch, showing that calcium action potentials can be regenerative in restrictive parts of the dendritic field without involving the soma or dendritic shaft. 4. Plateau or subthreshold potential changes evoked in the presence of tetrodotoxin (TTX) caused small, widespread increases in [Ca2+]i. The amplitude of these changes was much less than the increase corresponding to spike bursts. The distribution of these plateau Ca signals in thick and thin dendrites was similar to Ca spike-evoked signals, suggesting that the Ca conductances underlying these two potentials are the same or are distributed similarly in the dendrites. 5. Significant increases in [Ca2+]i in the soma were recorded during bursts of sodium-dependent action potentials in normal Ringer. Although much of this increase is due to calcium entry through calcium channels, some of this increase could be due to calcium entry through sodium channels.

Published

1992

35. A model of a CA3 hippocampal pyramidal neuron incorporating voltage-clamp data on intrinsic conductances

Author

Robert K. S. Wong, Hillary B. Michelson, Roger D. Traub, and Richard B. Miles

Subjects

N-Methylaspartate, Physiology, Voltage clamp, Guinea Pigs, Models, Neurological, Purkinje cell, Pyramidal Tracts, Hippocampus, Tonic (physiology), Bursting, medicine, Animals, Neurons, Dendritic spike, Rana catesbeiana, General Neuroscience, Electric Conductivity, Quisqualic Acid, Depolarization, Dendrites, Kinetics, medicine.anatomical_structure, Membrane channel, Soma, Calcium Channels, Neuroscience, Mathematics

Abstract

1. We have developed a 19-compartment cable model of a guinea pig CA3 pyramidal neuron. Each compartment is allowed to contain six active ionic conductances: gNa, gCa, gK(DR) (where DR stands for delayed rectifier), gK(A), gK(AHP), and gK(C). THe conductance gCa is of the high-voltage activated type. The model kinetics for the first five of these conductances incorporate voltage-clamp data obtained from isolated hippocampal pyramidal neurons. The kinetics of gK(C) are based on data from bullfrog sympathetic neurons. The time constant for decay of submembrane calcium derives from optical imaging of Ca signals in Purkinje cell dendrites. 2. To construct the model from available voltage-clamp data, we first reproduced current-clamp records from a model isolated neuron (soma plus proximal dendrites). We next assumed that ionic channel kinetics in the dendrites were the same as in the soma. In accord with dendritic recordings and calcium-imaging data, we also assumed that significant gCa occurs in dendrites. We then attached sections of basilar and apical dendritic cable. By trial and error, we found a distribution (not necessarily unique) of ionic conductance densities that was consistent with current-clamp records from the soma and dendrites of whole neurons and from isolated apical dendrites. 3. The resulting model reproduces the Ca(2+)-dependent spike depolarizing afterpotential (DAP) recorded after a stimulus subthreshold for burst elicitation. 4. The model also reproduces the behavior of CA3 pyramidal neurons injected with increasing somatic depolarizing currents: low-frequency (0.3-1.0 Hz) rhythmic bursting for small currents, with burst frequency increasing with current magnitude; then more irregular bursts followed by afterhyperpolarizations (AHPs) interspersed with brief bursts without AHPs; and finally, rhythmic action potentials without bursts. 5. The model predicts the existence of still another firing pattern during tonic depolarizing dendritic stimulation: brief bursts at less than 1 to approximately 12 Hz, a pattern not observed during somatic stimulation. These bursts correspond to rhythmic dendritic calcium spikes. 6. The model CA3 pyramidal neuron can be made to resemble functionally a CA1 pyramidal neuron by increasing gK(DR) and decreasing dendritic gCa and gK(C). Specifically, after these alterations, tonic depolarization of the soma leads to adapting repetitive firing, whereas stimulation of the distal dendrites leads to bursting. 7. A critical set of parameters concerns the regulation of the pool of intracellular [Ca2+] that interacts with membrane channels (gK(C) and gK(AHP)), particularly in the dendrites.(ABSTRACT TRUNCATED AT 400 WORDS)

Published

1991

36. Dendritic Ih ensures high-fidelity dendritic spike responses of motion-sensitive neurons in rat superior colliculus

Author

Tadashi Isa, Katsuyuki Kaneda, Toshiaki Endo, Etsuko Tarusawa, Masumi Hirabayashi, Takuya Notomi, and Ryuichi Shigemoto

Subjects

Superior Colliculi, Cardiotonic Agents, Potassium Channels, Physiology, Motion Perception, Synaptic Membranes, Action Potentials, Cyclic Nucleotide-Gated Cation Channels, Membrane Potentials, High fidelity, Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels, Animals, Fiber Optic Technology, Rats, Long-Evans, Rats, Wistar, In Situ Hybridization, Physics, Dendritic spike, General Neuroscience, Superior colliculus, Excitatory Postsynaptic Potentials, Dendrites, Immunohistochemistry, Rats, Electrophysiology, Pyrimidines, Data Interpretation, Statistical, Synapses, Neuroscience, Photic Stimulation

Abstract

Hyperpolarization-activated cyclic nucleotide-gated (HCN) channels that generate Ih currents are widely distributed in the brain and have been shown to contribute to various neuronal functions. In the present study, we investigated the functions of Ih in the motion-sensitive projection neurons [wide field vertical (WFV) cells] of the superior colliculus, a pivotal visual center for detection of and orientating to salient objects. Combination of whole cell recordings and immunohistochemical investigations suggested that HCN1 channels dominantly contribute to the Ih in WFV cells among HCN isoforms expressed in the superficial superior colliculus and mainly located on their expansive dendritic trees. We found that blocking Ih suppressed the initiation of short- and fixed-latency dendritic spike responses and led instead to long- and fluctuating-latency somatic spike responses to optic fiber stimulations. These results suggest that the dendritic Ih facilitates the dendritic initiation and/or propagation of action potentials and ensures that WFV cells generate spike responses to distal synaptic inputs in a sensitive and robustly time-locked manner, probably by acting as continuous depolarizing drive and fixing dendritic membrane potentials close to the spike threshold. These functions are different from known functions of dendritic Ih revealed in hippocampal and neocortical pyramidal cells, where they spatiotemporally limit the propagations of synaptic inputs along the apical dendrites by reducing dendritic membrane resistance. Thus we have revealed new functional aspects of Ih, and these dendritic properties are likely critical for visual motion processing in these neurons.

Published

2008

37. Alpha2-adrenergic receptors modify dendritic spike generation via HCN channels in the prefrontal cortex

Author

Balázs Lendvai, E. Sylvester Vizi, Albert M. I. Barth, and Tibor Zelles

Subjects

Male, Cardiotonic Agents, Patch-Clamp Techniques, Potassium Channels, Physiology, Action Potentials, Cyclic Nucleotide-Gated Cation Channels, Prefrontal Cortex, Synaptic Transmission, Norepinephrine, Organ Culture Techniques, Receptors, Adrenergic, alpha-2, Apical dendrite, Neural Pathways, medicine, Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels, Animals, Calcium Signaling, Rats, Wistar, Prefrontal cortex, Adrenergic alpha-Antagonists, Dendritic spike, α2 adrenergic receptor, General Neuroscience, Pyramidal Cells, Dendrites, Rats, medicine.anatomical_structure, Pyrimidines, Nerve Net, Psychology, Neuroscience, Adrenergic alpha-Agonists

Abstract

Although dendritic spikes are generally thought to be restricted to the distal apical dendrite, we know very little about the possible modulatory mechanisms that set the spatial limits of dendritic spikes. Our experiments demonstrated that high-frequency trains of backpropagating action potentials avoided filtering in the apical dendrite and initiated all-or-none dendritic Ca2+ transients associated with dendritic spikes in layer 5 pyramidal neurons of the prefrontal cortex. The block of hyperpolarization-activated currents ( Ih) by ZD7288 could shift the frequency threshold and decreased the number of action potentials required to produce the all-or-none Ca2+ transient. Activation of α2-adrenergic receptors could also shift the frequency domain of spike induction to lower frequencies. Our data suggest that noradrenergic activity in the prefrontal cortex influences dendritic Ih and extends the zone of dendritic spikes in the apical dendrite via α2-adrenergic receptors. This mechanism might be one cellular correlate of the α2-receptor–mediated actions on working memory.

Published

2007

38. Fiberoptic system for recording dendritic calcium signals in layer 5 neocortical pyramidal cells in freely moving rats

Author

Enrique Pérez-Garci, Matthew E. Larkum, Hans-Rudolf Lüscher, and Masanori Murayama

Subjects

Cell Membrane Permeability, Physiology, Dendritic tuft, chemistry.chemical_element, Calcium, Motor Activity, Fluorescence, Bursting, In vivo, Neuroplasticity, medicine, Animals, Fiber Optic Technology, Rats, Wistar, Dendritic spike, Photons, Neuronal Plasticity, Chemistry, General Neuroscience, Pyramidal Cells, Dendrites, Rats, medicine.anatomical_structure, Synaptic plasticity, Synapses, Biophysics, Female, Pyramidal cell, Neuroscience, Signal Transduction

Abstract

Calcium influx into the dendritic tufts of layer 5 neocortical pyramidal neurons modifies a number of important cellular mechanisms. It can trigger local synaptic plasticity and switch the firing properties from regular to burst firing. Due to methodological limitations, our knowledge about Ca2+ spikes in the dendritic tuft stems mostly from in vitro experiments. However, it has been speculated that regenerative Ca2+ events in the distal dendrites correlate with distinct behavioral states. Therefore it would be most desirable to be able to record these Ca2+ events in vivo, preferably in the behaving animal. Here, we present a novel approach for recording Ca2+ signals in the dendrites of populations of layer 5 pyramidal neurons in vivo, which ensures that all recorded fluorescence changes are due to intracellular Ca2+ signals in the apical dendrites. The method has two main features: 1) bolus loading of layer 5 with a membrane-permeant Ca2+ dye resulting in specific loading of pyramidal cell dendrites in the upper layers and 2) a fiberoptic cable attached to a gradient index lens and a prism reflecting light horizontally at 90° to the angle of the apical dendrites. We demonstrate that the in vivo signal-to-noise ratio recorded with this relatively inexpensive and easy-to-implement fiberoptic-based device is comparable to conventional camera-based imaging systems used in vitro. In addition, the device is flexible and lightweight and can be used for recording Ca2+ signals in the distal dendritic tuft of freely behaving animals.

Published

2007

39. Properties of action-potential initiation in neocortical pyramidal cells: evidence from whole cell axon recordings

Author

Alvaro Duque, David A. McCormick, Yuguo Yu, Yousheng Shu, and Bilal Haider

Subjects

Patch-Clamp Techniques, Physiology, Presynaptic Terminals, Nonsynaptic plasticity, Action Potentials, Prefrontal Cortex, Neocortex, Axon hillock, Synaptic Transmission, Organ Culture Techniques, Neural Pathways, medicine, Animals, Telodendron, Axon, Action potential initiation, Dendritic spike, Epilepsy, Chemistry, General Neuroscience, Pyramidal Cells, Ferrets, Dendrites, Axon initial segment, Axons, Electric Stimulation, Antidromic, medicine.anatomical_structure, nervous system, Nerve Net, Neuroscience

Abstract

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

Published

2006

40. Synaptic democracy in active dendrites

Author

Clifton C. Rumsey and Larry F. Abbott

Subjects

Dendritic spike, Physiology, General Neuroscience, Pyramidal Cells, Models, Neurological, Dominant factor, Nonsynaptic plasticity, Action Potentials, Excitatory Postsynaptic Potentials, Dendrites, Biology, Axons, Synapse, Tree (data structure), Synaptic plasticity, Metaplasticity, Synapses, Calcium, Neuroscience

Abstract

Given the extensive attenuation that can occur along dendritic cables, location within the dendritic tree might appear to be a dominant factor in determining the impact of a synapse on the postsynaptic response. By this reasoning, distal synapses should have a smaller effect than proximal ones. However, experimental evidence from several types of neurons, such as CA1 pyramidal cells, indicates that a compensatory strengthening of synapses counteracts the effect of location on synaptic efficacy. A form of spike-timing-dependent plasticity (STDP), called anti-STDP, combined with non-Hebbian activity-dependent plasticity can account for the equalization of synaptic efficacies. This result, obtained originally in models with unbranched passive cables, also arises in multi-compartment models with branched and active dendrites that feature backpropagating action potentials, including models with CA1 pyramidal morphologies. Additionally, when dendrites support the local generation of action potentials, anti-STDP prevents runaway dendritic spiking and locally balances the numbers of dendritic and backpropagating action potentials. Thus in multiple ways, anti-STDP eliminates the location dependence of synapses and allows Hebbian plasticity to operate in a more “democratic” manner.

Published

2006

41. Signal propagation in oblique dendrites of CA1 pyramidal cells

Author

Michele Migliore, Michele Ferrante, and Giorgio A. Ascoli

Subjects

Potassium Channels, Physiology, Models, Neurological, Hippocampus, Action Potentials, Article, Imaging, Three-Dimensional, Animals, Ion channel gating, Physics, Dendritic spike, General Neuroscience, Pyramidal Cells, Age Factors, Oblique case, Dendrites, Potassium channel, Electric Stimulation, Rats, Electrophysiology, Radio propagation, nervous system, Signal transduction, Neuroscience, Ion Channel Gating, Signal Transduction

Abstract

The electrophysiological properties of the oblique branches of CA1 pyramidal neurons are largely unknown and very difficult to investigate experimentally. These relatively thin dendrites make up the majority of the apical tree surface area and constitute the main target of Schaffer collateral axons from CA3. Their electrogenic properties might have an important role in defining the computational functions of CA1 neurons. It is thus important to determine if and to what extent the back- and forward propagation of action potentials (AP) in these dendrites could be modulated by local properties such as morphology or active conductances. In the first detailed study of signal propagation in the full extent of CA1 oblique dendrites, we used 27 reconstructed three-dimensional morphologies and different distributions of the A-type K+ conductance ( KA), to investigate their electrophysiological properties by computational modeling. We found that the local KA distribution had a major role in modulating action potential back propagation, whereas the forward propagation of dendritic spikes originating in the obliques was mainly affected by local morphological properties. In both cases, signal processing in any given oblique was effectively independent of the rest of the neuron and, by and large, of the distance from the soma. Moreover, the density of KA in oblique dendrites affected spike conduction in the main shaft. Thus the anatomical variability of CA1 pyramidal cells and their local distribution of voltage-gated channels may suit a powerful functional compartmentalization of the apical tree.

Published

2005

42. Transient high-frequency firing in a coupled-oscillator model of the mesencephalic dopaminergic neuron

Author

Charles J. Wilson, Nancy Kopell, and Alexey Kuznetsov

Subjects

Time Factors, Physiology, Dopamine, Models, Neurological, Action Potentials, Receptors, N-Methyl-D-Aspartate, Synaptic Transmission, Feedback, Midbrain, Biological Clocks, Mesencephalon, Animals, Humans, Computer Simulation, Receptors, AMPA, Dopaminergic neuron, Physics, Neurons, Dendritic spike, Neuronal Plasticity, General Neuroscience, Dopaminergic, Dendrites, Adaptation, Physiological, nervous system, Transient (oscillation), Neuroscience

Abstract

Dopaminergic neurons of the midbrain fire spontaneously at rates

Published

2005

43. Dendritic initiation and propagation of spikes and spike bursts in a multimodal sensory interneuron: the crustacean parasol cell

Author

DeForest Mellon

Subjects

Dendritic spike, Physiology, General Neuroscience, Action Potentials, Astacoidea, Dendrites, Biology, Parasol cell, Antidromic, Electrophysiology, medicine.anatomical_structure, Prosencephalon, Interneurons, medicine, Excitatory postsynaptic potential, Animals, Neuron, Neurons, Afferent, Axon, Neuroscience, Extracellular field potential

Abstract

Invasion of dendrites by spikes and spike bursts can play a critical role in regulating the output of central neurons by modifying their dynamic input-output relationships. Back-propagating bursts can modulate voltage-gated channels in the short term and can also modify long-term responses to synaptic input. Determining the morphological site of spike initiation and the mode of propagation through the dendritic arbor is therefore crucial to an understanding of a neuron's functional properties. I used electrophysiological methods to study parasol cells in isolated, perfused head preparations of the freshwater crayfish Procambarus clarkii to determine the compartment of origin of orthodromically activated action potentials and bursts that propagate within the dendritic arbor and to examine the identity of low-amplitude, electrotonically recorded spike events that are present in more than one-half of the intracellular recordings obtained from dendrites in these neurons. Experiments using antidromic activation of parasol cell axons indicated that electrotonically recorded spikes probably are generated in neighboring parasol cells, to which the impaled neurons are electrically coupled. Both paired intracellular recordings and extracellular field potential measurements were used to compare arrival times of antidromic and orthodromic spikes at loci in the vicinity of the trunk and the basal branch compartments of parasol cell dendrites. These methods provided consistent results, indicating that synaptically evoked action potentials are initiated at a site on the trunk, from which point they back-propagate into the basal branches within the hemiellipsoid body, and presumably, also orthodromically to the axon. Data are presented suggesting that bursts also arise at a trunk locus, but one that is different from the initiation point of single spikes evoked by excitatory postsynaptic potentials (EPSPs). Morphological specializations between the dendritic trunk and basal branches may facilitate back-propagation of spikes and spike bursts into the basal branches.

Published

2003

44. Multiple modes of action potential initiation and propagation in mitral cell primary dendrite

Author

Wei Chen, Gordon M. Shepherd, Gongyu Y. Shen, Jens Midtgaard, and Michael L. Hines

Subjects

Olfactory system, Olfactory Nerve, Physiology, Models, Neurological, Action Potentials, Dendrite, Biology, Rats, Sprague-Dawley, Olfactory nerve, medicine, Animals, Computer Simulation, Action potential initiation, Neurons, Dendritic spike, Electroshock, Microscopy, Video, General Neuroscience, Dendrites, Olfactory Pathways, Olfactory Bulb, Axons, Olfactory bulb, Rats, Shunting, Electrophysiology, Smell, medicine.anatomical_structure, Synapses, Neuroscience

Abstract

The mitral cell primary dendrite plays an important role in transmitting distal olfactory nerve input from olfactory glomerulus to the soma-axon initial segment. To understand how dendritic active properties are involved in this transmission, we have combined dual soma and dendritic patch recordings with computational modeling to analyze action-potential initiation and propagation in the primary dendrite. In response to depolarizing current injection or distal olfactory nerve input, fast Na+action potentials were recorded along the entire length of the primary dendritic trunk. With weak-to-moderate olfactory nerve input, an action potential was initiated near the soma and then back-propagated into the primary dendrite. As olfactory nerve input increased, the initiation site suddenly shifted to the distal primary dendrite. Multi-compartmental modeling indicated that this abrupt shift of the spike-initiation site reflected an independent thresholding mechanism in the distal dendrite. When strong olfactory nerve excitation was paired with strong inhibition to the mitral cell basal secondary dendrites, a small fast prepotential was recorded at the soma, which indicated that an action potential was initiated in the distal primary dendrite but failed to propagate to the soma. As the inhibition became weaker, a “double-spike” was often observed at the dendritic recording site, corresponding to a single action potential at the soma. Simulation demonstrated that, in the course of forward propagation of the first dendritic spike, the action potential suddenly jumps from the middle of the dendrite to the axonal spike-initiation site, leaving the proximal part of primary dendrite unexcited by this initial dendritic spike. As Na+conductances in the proximal dendrite are not activated, they become available to support the back-propagation of the evoked somatic action potential to produce the second dendritic spike. In summary, the balance of spatially distributed excitatory and inhibitory inputs can dynamically switch the mitral cell firing among four different modes: axo-somatic initiation with back-propagation, dendritic initiation either with no forward propagation, forward propagation alone, or forward propagation followed by back-propagation.

Published

2002

45. Dichotomy of action-potential backpropagation in CA1 pyramidal neuron dendrites

Author

Nace L. Golding, Nelson Spruston, and William L. Kath

Subjects

Diagnostic Imaging, Male, Patch-Clamp Techniques, Potassium Channels, Physiology, Models, Neurological, Hippocampus, Action Potentials, Hippocampal formation, In Vitro Techniques, Neural backpropagation, Sodium Channels, medicine, Animals, Patch clamp, Axon, Rats, Wistar, Fluorescent Dyes, Dendritic spike, Chemistry, General Neuroscience, Sodium channel, Pyramidal Cells, Dendrites, Rats, Electrophysiology, medicine.anatomical_structure, Calcium, Fura-2, Neuroscience

Abstract

In hippocampal CA1 pyramidal neurons, action potentials are typically initiated in the axon and backpropagate into the dendrites, shaping the integration of synaptic activity and influencing the induction of synaptic plasticity. Despite previous reports describing action-potential propagation in the proximal apical dendrites, the extent to which action potentials invade the distal dendrites of CA1 pyramidal neurons remains controversial. Using paired somatic and dendritic whole cell recordings, we find that in the dendrites proximal to 280 μm from the soma, single backpropagating action potentials exhibit

Published

2001

46. Apical and basal orthodromic population spikes in hippocampal CA1 in vivo show different origins and patterns of propagation

Author

Lai-Wo Stan Leung, Fabian Kloosterman, Pascal Peloquin, and Cognitive and Systems Neuroscience (SILS, FNWI)

Subjects

Physiology, Population, Neural Conduction, Hippocampus, Action Potentials, Hippocampal formation, Biology, Basal (phylogenetics), In vivo, Reaction Time, Animals, education, Evoked Potentials, Electric stimulation, Neurons, education.field_of_study, Dendritic spike, General Neuroscience, Cell Membrane, Dendrites, Axons, Electric Stimulation, Rats, Neuroscience, Orthodromic

Abstract

There is controversy concerning whether orthodromic action potentials originate from the apical or basal dendrites of CA1 pyramidal cells in vivo. The participation of the dendrites in the initialization and propagation of population spikes in CA1 of urethan-anesthetized rats in vivo was studied using simultaneously recorded field potentials and current source density (CSD) analysis. CSD analysis revealed that the antidromic population spike, evoked by stimulation of the alveus, invaded in succession, the axon initial segment (stratum oriens), cell body and approximately 200 microm of the proximal apical dendrites. Excitation of the basal dendrites of CA1, following stimulation of CA3 stratum oriens, evoked an orthodromic spike that started near the cell body or initial segment and then propagated approximately 200 microm into the proximal apical dendrites. In contrast, the population spike that followed excitation of the apical dendrites of CA1 initiated at the proximal apical dendrites, 50-100 microm distal to the cell body layer, and then propagated centripetally to the cell body and the proximal basal dendrites. A late apical dendritic spike may arise in the mid-apical dendrites (250-300 microm from the cell layer) and propagated distally. The origin or the pattern of propagation of each population spike type was similar for near-threshold to supramaximal stimulus intensities. In summary, population spikes following apical dendritic and basal dendritic excitation in vivo appeared to originate from different locations. Apical dendritic excitation evoked a population spike that initiated in the proximal apical dendrites while basal dendritic excitation evoked a spike that started near the initial segment or cell body. An original finding of this study is the propagation of the population spike from basal to apical dendrites in vivo or vice versa. This backpropagation from one dendritic tree to the other may play an important role in the synaptic plasticity among a network of CA3 to CA1 neurons.

Published

2001

47. Dendritic mechanisms of phase precession in hippocampal CA1 pyramidal neurons

Author

Jeffrey C. Magee

Subjects

Patch-Clamp Techniques, Physiology, Phase (waves), Hippocampus, Precession (mechanical), Action Potentials, Hippocampal formation, Rats, Sprague-Dawley, Organ Culture Techniques, medicine, Animals, Patch clamp, Theta Rhythm, Dendritic spike, Chemistry, General Neuroscience, Pyramidal Cells, Cardiovascular Agents, Dendrites, Rats, medicine.anatomical_structure, Pyrimidines, Cardiovascular agent, Soma, Neuroscience

Abstract

Dual whole-cell patch clamp recordings from the soma and dendrites of CA1 pyramidal neurons located in hippocampal slices of adult rats were used to examine the potential mechanisms of phase precession. To mimic phasic synaptic input, 5-Hz sine wave current injections were simultaneously delivered both to the soma and apical dendrites (dendritic current was 180° out-of-phase with soma). Increasing the amplitude of the dendritic current injection caused somatic action potential initiation to advance in time (move forward up to 180°). The exact pattern of phase advancement is dependent on the dendritic location of input, with more distal input causing a more gradual temporal shift in spike initiation and a smaller increase in spike number. Patterned stimulation of Schaffer collateral/perforant path synaptic input can produce phase precession that is very similar to that observed with sine wave current injections. Finally, the exact amount of synaptic input required to produce phase advancement was found to be regulated by dendritic voltage-gated ion channels. Together, these data demonstrate that the summation of primarily proximal inhibition with an increasing amount of out-of-phase, primarily distal excitation can result in a form of phase advancement similar to that seen during theta activity in the intact hippocampus.

Published

2001

48. Dendritic calcium spikes in layer 5 pyramidal neurons amplify and limit transmission of ligand-gated dendritic current to soma

Author

W. E. Crill, Peter C. Schwindt, and John C. Oakley

Subjects

Male, Physiology, Action Potentials, Glutamic Acid, In Vitro Techniques, Ligands, Rats, Sprague-Dawley, medicine, Animals, Evoked Potentials, Fluorescent Dyes, Dendritic spike, Chemistry, General Neuroscience, Pyramidal Cells, Dendrites, Somatosensory Cortex, Iontophoresis, Isoquinolines, Stimulation, Chemical, Calcium Spikes, Rats, medicine.anatomical_structure, nervous system, Transmission (telecommunications), Biophysics, Ligand-gated ion channel, Soma, Calcium, Female, Calcium Channels, Neuroscience, Layer (electronics), Cadmium

Abstract

Long-lasting, dendritic, Ca2+-dependent action potentials (plateaus) were investigated in layer 5 pyramidal neurons from rat neocortical slices visualized by infrared-differential interference contrast microscopy to understand the role of dendritic Ca2+ spikes in the integration of synaptic input. Focal glutamate iontophoresis on visualized dendrites caused soma firing rate to increase linearly with iontophoretic current until dendritic Ca2+ responses caused a jump in firing rate. Increases in iontophoretic current caused no further increase in somatic firing rate. This limitation of firing rate resulted from the inability of increased glutamate to change evoked plateau amplitude. Similar nonlinear patterns of soma firing were evoked by focal iontophoresis on the distal apical, oblique, and basal dendrites, whereas iontophoresis on the soma and proximal apical dendrite only evoked a linear increase in firing rate as a function of iontophoretic current without plateaus. Plateau amplitude recorded in the soma decreased as the site of iontophoresis was moved farther from the soma, consistent with decremental propagation of the plateau to the soma. Currents arriving at the soma summed if plateaus were evoked on separate dendrites or if subthreshold responses were evoked from sites on the same dendrite. If plateaus were evoked at two sites on the same dendrite, only the proximal plateau was seen at the soma. Just-subthreshold depolarizations at two sites on the same dendrite could sum to evoke a plateau at the proximal site. We conclude that the plateaus prevent current from ligand-gated channels distal to the plateau-generating region from reaching the soma and directly influencing firing rate. The implications of plateau properties for synaptic integration are discussed.

Published

2001

49. Action potentials in the dendrites of retinal ganglion cells

Author

Richard H. Masland and T. J. Velte

Subjects

Retinal Ganglion Cells, Dendritic spike, Patch-Clamp Techniques, Physiology, Chemistry, General Neuroscience, Action Potentials, Lidocaine, Dendrites, Retinal ganglion, Membrane Potentials, medicine.anatomical_structure, medicine, Animals, Patch clamp, Rabbits, Neuroscience, Muller glia

Abstract

Action potentials in the dendrites of retinal ganglion cells. The somas and dendrites of intact retinal ganglion cells were exposed by enzymatic removal of the overlying endfeet of the Müller glia. Simultaneous whole cell patch recordings were made from a ganglion cell’s dendrite and the cell’s soma. When a dendrite was stimulated with depolarizing current, impulses often propagated to the soma, where they appeared as a mixture of small depolarizations and action potentials. When the soma was stimulated, action potentials always propagated back through the dendrite. The site of initiation of action potentials, as judged by their timing, could be shifted between soma and dendrite by changing the site of stimulation. Applying QX-314 to the soma could eliminate somatic action potentials while leaving dendritic impulses intact. The absolute amplitudes of the dendritic action potentials varied somewhat at different distances from the soma, and it is not clear whether these variations are real or technical. Nonetheless, the qualitative experiments clearly suggest that the dendrites of retinal ganglion cells generate regenerative Na+ action potentials, at least in response to large direct depolarizations.

Published

1999

50. Modeling action potential initiation and back-propagation in dendrites of cultured rat motoneurons

Author

Hans R. Lüscher and Matthew E. Larkum

Subjects

Motor Neurons, Dendritic spike, Physiology, Chemistry, General Neuroscience, Electric Conductivity, Action Potentials, Dendrites, Axons, Rats, Electrophysiology, Sensory Thresholds, Animals, Neuroscience, Cells, Cultured, Action potential initiation

Abstract

Lüscher, Hans-R. and Matthew E. Larkum. Modeling action potential initiation and back-propagation in dendrites of cultured rat motoneurons. J. Neurophysiol. 80: 715–729, 1998. Regardless of the site of current injection, action potentials usually originate at or near the soma and propagate decrementally back into the dendrites. This phenomenon has been observed in neocortical pyramidal cells as well as in cultured motoneurons. Here we show that action potentials in motoneurons can be initiated in the dendrite as well, resulting in a biphasic dendritic action potential. We present a model of spinal motoneurons that is consistent with observed physiological properties of spike initiation in the initial segment/axon hillock region and action potential back-propagation into the dendritic tree. It accurately reproduces the results presented by Larkum et al. on motoneurons in organotypic rat spinal cord slice cultures. A high Na+-channel density of ḡ Na = 700 mS/cm2 at the axon hillock/initial segment region was required to secure antidromic invasion of the somato-dendritic membrane, whereas for the orthodromic direction, a Na+-channel density of ḡ Na = 1,200 mS/cm2 was required. A “weakly” excitable ( ḡ Na = 3 mS/cm2) dendritic membrane most accurately describes the experimentally observed attenuation of the back-propagated action potential. Careful analysis of the threshold conditions for action potential initiation at the initial segment or the dendrites revealed that, despite the lower voltage threshold for spike initiation in the initial segment, an action potential can be initiated in the dendrite before the initial segment fires a spike. Spike initiation in the dendrite depends on the passive cable properties of the dendritic membrane, its Na+-channel density, and local structural properties, mainly the diameter of the dendrites. Action potentials are initiated more easily in distal than in proximal dendrites. Whether or not such a dendritic action potential invades the soma with a subsequent initiation of a second action potential in the initial segment depends on the actual current source-load relation between the action potential approaching the soma and the electrical load of the soma together with the attached dendrites.

Published

1998