Small-conductance Ca2+-activated K+ channels modulate action potential-induced Ca2+ transients in hippocampal neurons

In hippocampal pyramidal neurons, voltage-gated Ca2+ channels open in response to action potentials. This results in elevations in the intracellular concentration of Ca2+ that are maximal in the proximal apical dendrites and decrease rapidly with distance from the soma. The control of these action potential-evoked Ca2+ elevations is critical for the regulation of hippocampal neuronal activity. As part of Ca2+ signaling microdomains, small-conductance Ca2+-activated K+ (SK) channels have been shown to modulate the amplitude and duration of intracellular Ca2+ signals by feedback regulation of synaptically activated Ca2+ sources in small distal dendrites and dendritic spines, thus affecting synaptic plasticity in the hippocampus. In this study, we investigated the effect of the activation of SK channels on Ca2+ transients specifically induced by action potentials in the proximal processes of hippocampal pyramidal neurons. Our results, obtained by using selective SK channel blockers and enhancers, show that SK channels act in a feedback loop, in which their activation by Ca2+ entering mainly through L-type voltage-gated Ca2+ channels leads to a reduction in the subsequent dendritic influx of Ca2+. This underscores a new role of SK channels in the proximal apical dendrite of hippocampal pyramidal neurons.

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A model for dendritic Ca2+ accumulation in hippocampal pyramidal neurons based on fluorescence imaging measurements

Journal of Neurophysiology ◽

10.1152/jn.1994.71.3.1065 ◽

1994 ◽

Vol 71 (3) ◽

pp. 1065-1077 ◽

Cited By ~ 88

Author(s):

D. B. Jaffe ◽

W. N. Ross ◽

J. E. Lisman ◽

N. Lasser-Ross ◽

H. Miyakawa ◽

...

Keyword(s):

Fluorescence Imaging ◽

Action Potentials ◽

Hippocampal Neurons ◽

Pyramidal Neurons ◽

Na Channels ◽

Hippocampal Pyramidal Neurons ◽

K Channels ◽

Voltage Gated ◽

Synaptic Potentials ◽

Ca2 Channels

1. High-speed fluorescence imaging was used to measure intracellular Ca2+ concentration ([Ca2+]i) changes in hippocampal neurons injected with the Ca(2+)-sensitive indicator fura-2 during intrasomatic and synaptic stimulation. The results of these experiments were used to construct a biophysical model of [Ca2+]i dynamics in hippocampal neurons. 2. A compartmental model of a pyramidal neuron was constructed incorporating published passive membrane properties of these cells, three types of voltage-gated Ca2+ channels characterized from adult hippocampal neurons, voltage-gated Na+ and K+ currents, and mechanisms for Ca2+ buffering and extrusion. 3. In hippocampal pyramidal neurons imaging of Na+ entry during electrical activity suggests that Na+ channels, at least in sufficient density to sustain action potentials, are localized in the soma and the proximal part of the apical dendritic tree. The model, which incorporates this distribution, demonstrates that action potentials attenuate steeply in passive distal dendritic compartments or distal dendritic compartments containing Ca2+ and K+ channels. This attenuation was affected by intracellular resistivity but not membrane resistivity. 4. Consistent with fluorescence imaging experiments, a non-uniform distribution of Ca2+ accumulation was generated by Ca2+ entry through voltage-gated Ca2+ channels opened by decrementally propagating Na+ action potentials. Consequently, the largest increases in [C2+]i were produced in the proximal dendrites. Distal voltage-gated Ca2+ currents were activated by broad, almost isopotential action potentials produced by reducing the overall density of K+ channels. 5. Simulations of subthreshold synaptic stimulation produced dendritic Ca2+ entry by the activation of voltage-gated Ca2+ channels. In the model these Ca2+ signals were localized near the site of synaptic input because of the attenuation of synaptic potentials with distance from the site of origin and the steep voltage-dependence of Ca2+ channel activation. 6. These simulations support the hypotheses generated from experimental evidence regarding the differential distribution of voltage-gated Ca2+ and Na+ channels in hippocampal neurons and the resulting voltage-gated Ca2+ accumulation from action and synaptic potentials.

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Calcium stores regulate excitability in cultured rat hippocampal neurons

Journal of Neurophysiology ◽

10.1152/jn.00447.2018 ◽

2018 ◽

Vol 120 (5) ◽

pp. 2694-2705 ◽

Cited By ~ 6

Author(s):

Menahem Segal

Keyword(s):

Action Potential ◽

Hippocampal Neurons ◽

Extracellular Calcium ◽

Calcium Stores ◽

Sk Channels ◽

Central Neurons ◽

Action Potential Threshold ◽

Potential Threshold ◽

Small Conductance ◽

Cultured Hippocampal Neurons

Extracellular calcium ions support synaptic activity but also reduce excitability of central neurons. In the present study, the effect of calcium on excitability was explored in cultured hippocampal neurons. CaCl2 injected by pressure in the vicinity of a neuron that is bathed only in MgCl2 as the main divalent cation caused a depolarizing shift in action potential threshold and a reduction in excitability. This effect was not seen if the intracellular milieu consisted of Cs+ instead of K-gluconate as the main cation or when it contained ruthenium red, which blocks release of calcium from stores. The suppression of excitability by calcium was mimicked by caffeine, and calcium store antagonists cyclopiazonic acid or thapsigargin blocked this action. Neurons taken from synaptopodin-knockout mice show significantly reduced efficacy of calcium modulation of action potential threshold. Likewise, in Orai1 knockdown cells, calcium is less effective in modulating excitability of neurons. Activation of small-conductance K (SK) channels increased action potential threshold akin to that produced by calcium ions, whereas blockade of SK channels but not big K channels reduced the threshold for action potential discharge. These results indicate that calcium released from stores may suppress excitability of central neurons. NEW & NOTEWORTHY Extracellular calcium reduces excitability of cultured hippocampal neurons. This effect is mediated by calcium-gated potassium currents, possibly small-conductance K channels. Release of calcium from internal stores mimics the effect of extracellular calcium. It is proposed that calcium stores modulate excitability of central neurons.

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

Journal of Neurophysiology ◽

10.1152/jn.1999.82.4.1895 ◽

1999 ◽

Vol 82 (4) ◽

pp. 1895-1901 ◽

Cited By ~ 173

Author(s):

Jeffrey C. Magee ◽

Michael Carruth

Keyword(s):

Ion Channels ◽

Action Potential ◽

Large Amplitude ◽

Action Potentials ◽

Pyramidal Neurons ◽

Burst Firing ◽

Voltage Gated ◽

Ca1 Pyramidal Neurons ◽

Firing Mode ◽

Voltage Gated Ion Channels

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.

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Extracellular waveforms reveal an axonal origin of spikelets in pyramidal neurons

Journal of Neurophysiology ◽

10.1152/jn.00463.2017 ◽

2018 ◽

Vol 120 (4) ◽

pp. 1484-1495 ◽

Cited By ~ 1

Author(s):

Martina Michalikova ◽

Michiel W. H. Remme ◽

Richard Kempter

Keyword(s):

Experimental Data ◽

Action Potential ◽

Single Cell ◽

Action Potentials ◽

Pyramidal Neurons ◽

Hippocampal Pyramidal Neurons ◽

Coupled Cells ◽

A Cell ◽

Cell Firing

Spikelets are small spike-like membrane depolarizations measured at the soma whose origin in pyramidal neurons is still unresolved. We investigated the mechanism of spikelet generation using detailed models of pyramidal neurons. We simulated extracellular waveforms associated with action potentials and spikelets and compared these with experimental data obtained by Chorev and Brecht ( J Neurophysiol 108: 1584–1593, 2012) from hippocampal pyramidal neurons in vivo. We considered spikelets originating in the axon of a single cell as well as spikelets generated in two cells coupled with gap junctions. We found that in both cases the experimental data can be explained by an axonal origin of spikelets: in the single-cell case, action potentials are generated in the axon but fail to activate the soma. Such spikelets can be evoked by dendritic input. Alternatively, spikelets resulting from axoaxonal gap junction coupling with a large (greater than several hundred μm) distance between the somata of the coupled cells are also consistent with the data. Our results demonstrate that a cell firing a somatic spikelet generates a detectable extracellular potential that is different from the action potential-correlated extracellular waveform generated by the same cell and recorded at the same location. This, together with the absence of a refractory period between action potentials and spikelets, implies that spikelets and action potentials generated in one cell may easily get misclassified in extracellular recordings as two different cells, albeit they both constitute the output of a single pyramidal neuron. NEW & NOTEWORTHY We addressed the origin of spikelets, using compartmental models of pyramidal neurons. Comparing our simulation results with published extracellular spikelet recordings revealed an axonal origin of spikelets. Our results imply that action potential- and spikelet-associated extracellular waveforms may easily get misclassified as two different cells, albeit they both constitute the output of a single pyramidal cell.

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Action potential propagation recorded from single axonal arbors using multielectrode arrays

Journal of Neurophysiology ◽

10.1152/jn.00659.2017 ◽

2018 ◽

Vol 120 (1) ◽

pp. 306-320 ◽

Cited By ~ 2

Author(s):

Kenneth R. Tovar ◽

Daniel C. Bridges ◽

Bian Wu ◽

Connor Randall ◽

Morgane Audouard ◽

...

Keyword(s):

Action Potential ◽

Action Potentials ◽

Hippocampal Neurons ◽

Detection Threshold ◽

Physiological Data ◽

Low Density ◽

Multielectrode Arrays ◽

Action Potential Propagation ◽

Voltage Gated ◽

Axonal Arbors

We report the presence of co-occurring extracellular action potentials (eAPs) from cultured mouse hippocampal neurons among groups of planar electrodes on multielectrode arrays (MEAs). The invariant sequences of eAPs among coactive electrode groups, repeated co-occurrences, and short interelectrode latencies are consistent with action potential propagation in unmyelinated axons. Repeated eAP codetection by multiple electrodes was widespread in all our data records. Codetection of eAPs confirms they result from the same neuron and allows these eAPs to be isolated from all other spikes independently of spike sorting algorithms. We averaged co-occurring events and revealed additional electrodes with eAPs that would otherwise be below detection threshold. We used these eAP cohorts to explore the temperature sensitivity of action potential propagation and the relationship between voltage-gated sodium channel density and propagation velocity. The sequence of eAPs among coactive electrodes “fingerprints” neurons giving rise to these events and identifies them within neuronal ensembles. We used this property and the noninvasive nature of extracellular recording to monitor changes in excitability at multiple points in single axonal arbors simultaneously over several hours, demonstrating independence of axonal segments. Over several weeks, we recorded changes in interelectrode propagation latencies and ongoing changes in excitability in different regions of single axonal arbors. Our work illustrates how repeated eAP co-occurrences can be used to extract physiological data from single axons with low-density MEAs. However, repeated eAP co-occurrences lead to oversampling spikes from single neurons and thus can confound traditional spike-train analysis. NEW & NOTEWORTHY We studied action potential propagation in single axons using low-density multielectrode arrays. We unambiguously identified the neuronal sources of propagating action potentials and recorded extracellular action potentials from several positions within single axonal arbors. We found a surprisingly high density of axonal voltage-gated sodium channels responsible for a high propagation safety factor. Our experiments also demonstrate that excitability in different segments of single axons is regulated independently on timescales from hours to weeks.

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Dendritic small conductance calcium-activated potassium channels activated by action potentials suppress EPSPs and gate spike-timing dependent synaptic plasticity

eLife ◽

10.7554/elife.30333 ◽

2017 ◽

Vol 6 ◽

Cited By ~ 10

Author(s):

Scott L Jones ◽

Minh-Son To ◽

Greg J Stuart

Keyword(s):

Synaptic Plasticity ◽

Potassium Channels ◽

Action Potentials ◽

Pyramidal Neurons ◽

Receptor Activation ◽

Spike Timing ◽

Sk Channels ◽

Sk Channel ◽

Calcium Activated Potassium Channels ◽

Small Conductance

Small conductance calcium-activated potassium channels (SK channels) are present in spines and can be activated by backpropagating action potentials (APs). This suggests they may play a critical role in spike-timing dependent synaptic plasticity (STDP). Consistent with this idea, EPSPs in both cortical and hippocampal pyramidal neurons were suppressed by preceding APs in an SK-dependent manner. In cortical pyramidal neurons EPSP suppression by preceding APs depended on their precise timing as well as the distance of activated synapses from the soma, was dendritic in origin, and involved SK-dependent suppression of NMDA receptor activation. As a result SK channel activation by backpropagating APs gated STDP induction during low-frequency AP-EPSP pairing, with both LTP and LTD absent under control conditions but present after SK channel block. These findings indicate that activation of SK channels in spines by backpropagating APs plays a key role in regulating both EPSP amplitude and STDP induction.

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Voltage-gated Ca2+ and K+ channel coupling regulates CA1 hippocampal synaptic filtering and spine excitability

10.1101/2020.05.27.119305 ◽

2020 ◽

Author(s):

Jonathan G. Murphy ◽

Jakob J. Gutzmann ◽

Lin Lin ◽

Jiahua Hu ◽

Ronald S. Petralia ◽

...

Keyword(s):

Hippocampal Neurons ◽

Pyramidal Neurons ◽

Surface Expression ◽

K Channel ◽

Interacting Proteins ◽

Channel Coupling ◽

Whole Cell ◽

Hippocampal Pyramidal Neurons ◽

Voltage Gated ◽

Cell Current

ABSTRACTThe transient voltage-gated K+ current (IA) mediated by Kv4.2 in CA1 hippocampal pyramidal neurons regulates dendritic excitability, synaptic plasticity, and learning. Here we report that Ca2+ entry mediated by the voltage-gated Ca2+ channel subunit Cav2.3 regulates Kv4.2 function in CA1 pyramidal neurons through Ca2+ binding auxiliary subunits known as K+ channel interacting proteins (KChIPs). We characterized an interaction between Cav2.3 and Kv4.2 using immunofluorescence colocalization, coimmunoprecipitation, electron microscopy, FRAP, and FRET. We found that Ca2+-entry via Cav2.3 increases Kv4.2-mediated whole-cell current due in part to an increase in Kv4.2 surface expression. In hippocampal neurons, pharmacological block of Cav2.3 reduced whole-cell IA. We also found reduced IA in Cav2.3 knockout mouse neurons with a loss of the dendritic IA gradient. Furthermore, the Cav2.3-Kv4.2 complex was found to regulate the size of synaptic currents and spine Ca2+ transients. These results reveal an intermolecular Cav2.3-Kv4.2 complex impacting synaptic integration in CA1 hippocampal neurons.

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Ionic Basis of the Resting Membrane Potential and Action Potential in the Pharyngeal Muscle of Caenorhabditis elegans

Journal of Neurophysiology ◽

10.1152/jn.00233.2001 ◽

2002 ◽

Vol 87 (2) ◽

pp. 954-961 ◽

Cited By ~ 32

Author(s):

Christopher J. Franks ◽

Darrel Pemberton ◽

Irina Vinogradova ◽

Alan Cook ◽

Robert J. Walker ◽

...

Keyword(s):

Membrane Potential ◽

Action Potential ◽

Action Potentials ◽

Resting Membrane Potential ◽

Channel Blockers ◽

Voltage Gated ◽

C Elegans ◽

Current Voltage ◽

Prolongation Of Action Potential ◽

Ionic Basis

The pharynx of C. elegans is a rhythmically active muscle that pumps bacteria into the gut of the nematode. This activity is maintained by action potentials, which qualitatively bear a resemblance to vertebrate cardiac action potentials. Here, the ionic basis of the resting membrane potential and pharyngeal action potential has been characterized using intracellular recording techniques. The resting membrane potential is largely determined by a K+permeability, and a ouabain-sensitive, electrogenic pump. As previously suggested, the action potential is at least partly dependent on voltage-gated Ca2+ channels, as the amplitude was increased as extracellular Ca2+ was increased, and decreased by L-type Ca2+ channel blockers verapamil and nifedipine. Barium caused a marked prolongation of action potential duration, suggesting that a calcium-activated K+ current may contribute to repolarization. Most notably, however, we found that action potentials were abolished in the absence of external Na+. This may be due, at least in part, to a Na+-dependent pacemaker potential. In addition, the persistence of action potentials in nominally free Ca2+, the inhibition by Na+ channel blockers procaine and quinidine, and the increase in action potential frequency caused by veratridine, a toxin that alters activation of voltage-gated Na+channels, point to the involvement of a voltage-gated Na+ current. Voltage-clamp analysis is required for detailed characterization of this current, and this is in progress. Nonetheless, these observations are quite surprising in view of the lack of any obvious candidate genes for voltage-gated Na+ channels in the C. elegans genome. It would therefore be informative to re-evaluate the data from these homology searches, with the aim of identifying the gene(s) conferring this Na+, quinidine, and veratridine sensitivity to the pharynx.

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Zinc Enhances the Inhibitory Effects of Strychnine-Sensitive Glycine Receptors in Mouse Hippocampal Neurons

Journal of Neurophysiology ◽

10.1152/jn.00500.2007 ◽

2007 ◽

Vol 98 (6) ◽

pp. 3666-3676 ◽

Cited By ~ 8

Author(s):

Hai Xia Zhang ◽

Liu Lin Thio

Keyword(s):

Action Potential ◽

Action Potentials ◽

Hippocampal Neurons ◽

Neuronal Excitability ◽

Hippocampal Slices ◽

Glycine Receptors ◽

Inhibitory Effects ◽

Action Potential Firing ◽

Embryonic Mouse ◽

Potential Firing

Although extracellular Zn2+ is an endogenous biphasic modulator of strychnine-sensitive glycine receptors (GlyRs), the physiological significance of this modulation remains poorly understood. Zn2+ modulation of GlyR may be especially important in the hippocampus where presynaptic Zn2+ is abundant. Using cultured embryonic mouse hippocampal neurons, we examined whether 1 μM Zn2+, a potentiating concentration, enhances the inhibitory effects of GlyRs activated by sustained glycine applications. Sustained 20 μM glycine (EC25) applications alone did not decrease the number of action potentials evoked by depolarizing steps, but they did in 1 μM Zn2+. At least part of this effect resulted from Zn2+ enhancing the GlyR-induced decrease in input resistance. Sustained 20 μM glycine applications alone did not alter neuronal bursting, a form of hyperexcitability induced by omitting extracellular Mg2+. However, sustained 20 μM glycine applications depressed neuronal bursting in 1 μM Zn2+. Zn2+ did not enhance the inhibitory effects of sustained 60 μM glycine (EC70) applications in these paradigms. These results suggest that tonic GlyR activation could decrease neuronal excitability. To test this possibility, we examined the effect of the GlyR antagonist strychnine and the Zn2+ chelator tricine on action potential firing by CA1 pyramidal neurons in mouse hippocampal slices. Co-applying strychnine and tricine slightly but significantly increased the number of action potentials fired during a depolarizing current step and decreased the rheobase for action potential firing. Thus Zn2+ may modulate neuronal excitability normally and in pathological conditions such as seizures by potentiating GlyRs tonically activated by low agonist concentrations.

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Two Mechanisms That Raise Free Intracellular Calcium in Rat Hippocampal Neurons During Hypoosmotic and Low NaCl Treatment

Journal of Neurophysiology ◽

10.1152/jn.2000.83.1.81 ◽

2000 ◽

Vol 83 (1) ◽

pp. 81-89 ◽

Cited By ~ 18

Author(s):

Aren J. Borgdorff ◽

George G. Somjen ◽

Wytse J. Wadman

Keyword(s):

Synaptic Transmission ◽

Intracellular Calcium ◽

Hippocampal Neurons ◽

Pyramidal Neurons ◽

Hippocampal Slices ◽

Cell Swelling ◽

Tissue Slices ◽

Extracellular Medium ◽

Calcium Activity ◽

Hippocampal Pyramidal Neurons

Previous studies have shown that exposing hippocampal slices to low osmolarity (πo) or to low extracellular NaCl concentration ([NaCl]o) enhances synaptic transmission and also causes interstitial calcium ([Ca2+]o) to decrease. Reduction of [Ca2+]o suggests cellular uptake and could explain the potentiation of synaptic transmission. We measured intracellular calcium activity ([Ca2+]i) using fluorescent indicator dyes. In CA1 hippocampal pyramidal neurons in tissue slices, lowering πo by ∼70 mOsm caused “resting” [Ca2+]i as well as synaptically or directly stimulated transient increases of calcium activity (Δ[Ca2+]i) to transiently decrease and then to increase. In dissociated cells, lowering πo by ∼70 mOsm caused [Ca2+]i to almost double on average from 83 to 155 nM. The increase of [Ca2+]i was not significantly correlated with hypotonic cell swelling. Isoosmotic (mannitol- or sucrose-substituted) lowering of [NaCl]o, which did not cause cell swelling, also raised [Ca2+]i. Substituting NaCl with choline-Cl or Na-methyl-sulfate did not affect [Ca2+]i. In neurons bathed in calcium-free medium, lowering πo caused a milder increase of [Ca2+]i, which was correlated with cell swelling, but in the absence of external Ca2+, isotonic lowering of [NaCl]o triggered only a brief, transient response. We conclude that decrease of extracellular ionic strength (i.e., in both low πo and low [NaCl]o) causes a net influx of Ca2+ from the extracellular medium whereas cell swelling, or the increase in membrane tension, is a signal for the release of Ca2+ from intracellular stores.

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