Structural Inhomogeneities Differentially Modulate Action Currents and Population Spikes Initiated in the Axon or Dendrites

2002 ◽  
Vol 88 (5) ◽  
pp. 2809-2820 ◽  
Author(s):  
L. López-Aguado ◽  
J. M. Ibarz ◽  
P. Varona ◽  
O. Herreras
Keyword(s):  
Ionic Current ◽  
Pyramidal Cells ◽  
Ionic Currents ◽  
Axial Current ◽  
Internal Resistance ◽  
Synaptic Activity ◽  
Antidromic Activation ◽  
Processing Modes ◽  
Inward Currents

Action potentials (APs) in CA1 pyramidal cells propagate in different directions along the somatodendritic axis depending on the activation mode (synaptic or axonal). We studied how the geometrical inhomogeneities along the apical shaft, soma, and initial axon modulate the transmembrane current ( I m) flow underlying APs, using model and experimental techniques. The computations obtained at the subcellular level during forward- and backpropagation were extrapolated to macroscopic level (field potentials) and compared with the basic in vivo features of the ortho- and antidromic population spike (PS) that reflects the sum total of all elementary currents from synchronously firing cells. The matching of theoretical and experimental results supports the following conclusions. Because the charge carried by axonal APs is almost entirely drained into dendrites, the soma invasion is preceded by little capacitive currents ( I cap), the ionic currents ( I ion) dominating I m and the depolarizing phase. The subsequent invasion of the tapering apical shaft is preceded, however, by significant I cap, while I ion decayed gradually. A similar pattern occurred during backpropagation of spikes synaptically initiated in the axon. On the contrary, when the AP was apically initiated, the dendritic I ion was boosted by the apical flare, it was preceded by weak I cap and spread forwardly at a slower velocity. Soma invasion is reliable once the AP reached the main apical shaft but less so distal to the primary bifurcation, where it may be upheld by concurrent synaptic activity. The decreasing internal resistance of the apical shaft guided most axial current into the soma, causing its fast charging. There, I ionbegan later in the depolarizing phase of the AP and the reduced driving force made it smaller. This, in addition to a poor temporal overlapping of somatodendritic inward currents within individual cells, built a smaller extracellular sink, i.e., a smaller PS. In both experiment and model, the antidromic (axon-initiated) PS in the soma layer is approximately 30% larger than an orthodromic (apical shaft–initiated) PS contributed by the same number of firing cells. We conclude that the dominance of capacitive or ionic current components on I m is a distinguishing feature of forward and backward APs that is predictable from the geometric inhomogeneities between conducting subregions. Correspondingly, experimental and model APs have a faster rising slope during ortho than antidromic activation. The moderate flare of the apical shaft makes forward AP conduction quite safe. This alternative trigger zone enables two different processing modes for apical inputs.

Calcium currents from jellyfish striated muscle cells: preservation of phenotype, characterisation of currents and channel localisation

2001 ◽  
Vol 204 (21) ◽  
pp. 3717-3726
Author(s):  
Y.-C. James Lin ◽  
Andrew N. Spencer
Keyword(s):  
Calcium Current ◽  
Striated Muscle ◽  
Ionic Current ◽  
Muscle Cells ◽  
Ionic Currents ◽  
Calcium Currents ◽  
Nickel Ions ◽  
Polyorchis Penicillatus ◽  
Inward Currents

SUMMARY When striated muscle cells of the jellyfish Polyorchis penicillatus were dissociated at 30°C they retained their in vivo morphology and the integrity of ionic currents. This contrasted with cells dissociated at room temperature that rarely expressed any inward currents. Whole-cell, patch-clamp recordings from dissociated muscle cells revealed that the inward component of the total ionic current consisted of only one calcium current. This calcium current activated at –70 mV, peaked at –30 mV, and inactivated within 5 ms. In comparison with barium and strontium ions, calcium ions were the preferred current carriers. Calcium channels can be blocked by dihydropyridines and nickel ions at micromolar levels. Several properties of this current are reminiscent of T-type calcium currents. Localisation of this channel using the fluorescent channel blocker fDHP and the fluorescent dye RH414 indicated that myofibres had a higher density of these channels than the somata.

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

2007 ◽  
Vol 97 (1) ◽  
pp. 746-760 ◽  
Author(s):  
Yousheng Shu ◽  
Alvaro Duque ◽  
Yuguo Yu ◽  
Bilal Haider ◽  
David A. McCormick
Keyword(s):  
Action Potential ◽  
Action Potentials ◽  
Initial Segment ◽  
Pyramidal Cells ◽  
Synaptic Activity ◽  
Up States ◽  
Action Potential Initiation ◽  
Potential Initiation

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.

Modulation of Dendritic Action Currents Decreases the Reliability of Population Spikes

2000 ◽  
Vol 83 (2) ◽  
pp. 1108-1114 ◽  
Author(s):  
L. López-Aguado ◽  
J. M. Ibarz ◽  
O. Herreras
Keyword(s):  
High Frequency ◽  
Current Source ◽  
Pyramidal Cells ◽  
Differential Modulation ◽  
Quantitative Parameter ◽  
Ca1 Pyramidal Cells ◽  
Current Source Density Analysis ◽  
Inward Currents ◽  
Density Analysis

During synchronous action potential (AP) firing of CA1 pyramidal cells, a population spike (PS) is recorded in the extracellular space, the amplitude of which is considered a reliable quantitative index of the population output. Because the AP can be actively conducted and differentially modulated along the soma and dendrites, the extracellular part of the dendritic inward currents variably contributes to the somatic PS by spreading in the volume conductor to adjacent strata. This contribution has been studied by current-source density analysis and intracellular recordings in vivo during repetitive backpropagation that induces their selective fading. Both the PS and the ensemble action currents declined during high-frequency activation, although at different rates and timings. The decline was much stronger in dendrites than in the somatic region. At specific frequencies and for a short number of impulses the decrease of the somatic PS was neither due to fewer firing cells nor to decreased somatic action currents but to the blockade of dendritic action currents. The dendritic contribution to the peak of the somatic antidromic PS was estimated at ∼30–40% and up to 100% at later times in the positive-going limb. The blockade of AP dendritic invasion was in part due to a decreased transfer of current from the soma that underwent a cumulative increase of conductance and slow depolarization during the train that eventually extended into the axon. The possibility of differential modulation of soma and dendritic action currents during APs should be checked when using the PS as a quantitative parameter.

Modulation of inhibition in the hippocampus in vivo

1985 ◽  
Vol 63 (7) ◽  
pp. 838-842 ◽  
Author(s):  
Nicole Ropert
Keyword(s):  
Membrane Conductance ◽  
Pyramidal Cells ◽  
Medial Septum ◽  
Synaptic Activity ◽  
Sprague Dawley ◽  
In Situ Preparation ◽  
Stratum Pyramidale ◽  
Septal Stimulation ◽  
Sprague Dawley Rats

The nature and mechanisms of septohippocampal transmission have been elucidated by taking advantage of an in situ preparation in experiments with Sprague–Dawley rats under urethane. Both extracellular field potentials and intracellular recordings were made in CA1–3 regions of the hippocampus; and the hippocampal commissure and medial septum stimulated to evoke synaptic activity. Using muscarinic and nicotinic agonists and antagonists it was shown that both acetylcholine and medial septal activity can increase the excitability of pyramidal cells, mainly through muscarinic receptors. The effect of septal stimulation was enhanced by local application of physostigmine and reduced by intraventricular injections of hemicholinium. It was also shown that acetylcholine, when applied in the stratum pyramidale, can reduce the voltage and conductance changes observed during evoked inhibitory postsynaptic potentials (IPSP) without affecting the action of γ-aminobutyric acid on membrane conductance and voltage. It is therefore proposed that acetylcholine can reduce evoked IPSPs through presynaptic inhibition. Evidence is also presented that medial septal stimulation can reduce the efficacy of evoked IPSPs. These observations provide further support for the existence of a cholinergic septohippocampal pathway.

scholarly journals Neuromodulation independently determines correlated channel expression and conductance levels in motor neurons of the stomatogastric ganglion

2012 ◽  
Vol 107 (2) ◽  
pp. 718-727 ◽  
Author(s):  
Simone Temporal ◽  
Mohati Desai ◽  
Olga Khorkova ◽  
Gladis Varghese ◽  
Aihua Dai ◽  
...  
Keyword(s):  
Ion Channels ◽  
Motor Neurons ◽  
Ionic Current ◽  
Ionic Currents ◽  
Transcript Level ◽  
Ionic Channels ◽  
Cell Types ◽  
Synaptic Activity ◽  
Protein Levels ◽  
Channel Expression

Neuronal identity depends on the regulated expression of numerous molecular components, especially ionic channels, which determine the electrical signature of a neuron. Such regulation depends on at least two key factors, activity itself and neuromodulatory input. Neuronal electrical activity can modify the expression of ionic currents in homeostatic or nonhomeostatic fashion. Neuromodulators typically modify activity by regulating the properties or expression levels of subsets of ionic channels. In the stomatogastric system of crustaceans, both types of regulation have been demonstrated. Furthermore, the regulation of the coordinated expression of ionic currents and the channels that carry these currents has been recently reported in diverse neuronal systems, with neuromodulators not only controlling the absolute levels of ionic current expression but also, over long periods of time, appearing to modify their correlated expression. We hypothesize that neuromodulators may regulate the correlated expression of ion channels at multiple levels and in a cell-type-dependent fashion. We report that in two identified neuronal types, three ionic currents are linearly correlated in a pairwise manner, suggesting their coexpression or direct interactions, under normal neuromodulatory conditions. In each cell, some currents remain correlated after neuromodulatory input is removed, whereas the correlations between the other pairs are either lost or altered. Interestingly, in each cell, a different suite of currents change their correlation. At the transcript level we observe distinct alterations in correlations between channel mRNA amounts, including one of the cell types lacking a correlation under normal neuromodulatory conditions and then gaining the correlation when neuromodulators are removed. Synaptic activity does not appear to contribute, with one possible exception, to the correlated expression of either ionic currents or of the transcripts that code for the respective channels. We conclude that neuromodulators regulate the correlated expression of ion channels at both the transcript and the protein levels.

scholarly journals Background Synaptic Conductance and Precision of EPSP-Spike Coupling at Pyramidal Cells

2005 ◽  
Vol 93 (6) ◽  
pp. 3248-3256 ◽  
Author(s):  
Veronika Zsiros ◽  
Shaul Hestrin
Keyword(s):  
Time Course ◽  
Pyramidal Cells ◽  
Spike Timing ◽  
Synaptic Activity ◽  
Synaptic Conductance ◽  
Temporal Precision ◽  
Voltage Dependent ◽  
Cortical Slices

The temporal precision of converting excitatory postsynaptic potentials (EPSPs) into spikes at pyramidal cells is critical for the coding of information in the cortex. Several in vitro studies have shown that voltage-dependent conductances in pyramidal cells can prolong the EPSP time course resulting in an imprecise EPSP-spike coupling. We have used dynamic-clamp techniques to mimic the in vivo background synaptic conductance in cortical slices and investigated how the ongoing synaptic activity may affect the EPSP time course near threshold and the EPSP spike coupling. We report here that background synaptic conductance dramatically diminished the depolarization related prolongation of the EPSPs in pyramidal cells and improved the precision of spike timing. Furthermore, we found that background synaptic conductance can affect the interaction among action potentials in a spike train. Thus the level of ongoing synaptic activity in the cortex may regulate the capacity of pyramidal cells to process temporal information.

scholarly journals Characterization in Dual Activation by Oxaliplatin, a Platinum-Based Chemotherapeutic Agent of Hyperpolarization-Activated Cation and Electroporation-Induced Currents

2020 ◽  
Vol 21 (2) ◽  
pp. 396 ◽  
Author(s):  
Wei-Ting Chang ◽  
Zi-Han Gao ◽  
Shih-Wei Li ◽  
Ping-Yen Liu ◽  
Yi-Ching Lo ◽  
...  
Keyword(s):  
Ionic Currents ◽  
Gh3 Cells ◽  
Dependent Manner ◽  
Induced Current ◽  
Membrane Excitability ◽  
Concentration Dependent Manner ◽  
Term Administration ◽  
Inward Currents ◽  
Dual Activation

Oxaliplatin (OXAL) is regarded as a platinum-based anti-neoplastic agent. However, its perturbations on membrane ionic currents in neurons and neuroendocrine or endocrine cells are largely unclear, though peripheral neuropathy has been noted during its long-term administration. In this study, we investigated how the presence of OXAL and other related compounds can interact with two types of inward currents; namely, hyperpolarization-activated cation current (Ih) and membrane electroporation-induced current (IMEP). OXAL increased the amplitude or activation rate constant of Ih in a concentration-dependent manner with effective EC50 or KD values of 3.2 or 6.4 μM, respectively, in pituitary GH3 cells. The stimulation by this agent of Ih could be attenuated by subsequent addition of ivabradine, protopine, or dexmedetomidine. Cell exposure to OXAL (3 μM) resulted in an approximately 11 mV rightward shift in Ih activation along the voltage axis with minimal changes in the gating charge of the curve. The exposure to OXAL also effected an elevation in area of the voltage-dependent hysteresis elicited by long-lasting triangular ramp. Additionally, its application resulted in an increase in the amplitude of IMEP elicited by large hyperpolarization in GH3 cells with an EC50 value of 1.3 μM. However, in the continued presence of OXAL, further addition of ivabradine, protopine, or dexmedetomidine always resulted in failure to attenuate the OXAL-induced increase of IMEP amplitude effectively. Averaged current-voltage relation of membrane electroporation-induced current (IMEP) was altered in the presence of OXAL. In pituitary R1220 cells, OXAL-stimulated Ih remained effective. In Rolf B1.T olfactory sensory neurons, this agent was also observed to increase IMEP in a concentration-dependent manner. In light of the findings from this study, OXAL-mediated increases of Ih and IMEP may coincide and then synergistically act to increase the amplitude of inward currents, raising the membrane excitability of electrically excitable cells, if similar in vivo findings occur.

scholarly journals Reconstruction of post-synaptic potentials by reverse modeling of local field potentials

2018 ◽  
Author(s):  
Maxime Yochum ◽  
Julien Modolo ◽  
Pascal Benquet ◽  
Fabrice Wendling
Keyword(s):  
Reverse Engineering ◽  
Local Field ◽  
Local Field Potentials ◽  
Pyramidal Cells ◽  
Synaptic Activity ◽  
Neural Mass Model ◽  
Field Potentials ◽  
Synaptic Potentials ◽  
Epileptiform Discharges

AbstractAmong electrophysiological signals, Local Field Potentials (LFPs) are extensively used to study brain activity, either in vivo or in vitro. LFPs are recorded with extracellular electrodes implanted in brain tissue. They reflect intermingled excitatory and inhibitory processes in neuronal assemblies. In cortical structures, LFPs mainly originate from the summation of post-synaptic potentials (PSPs), either excitatory (ePSPs) and inhibitory (iPSPs) generated at the level of pyramidal cells. The challenging issue, addressed in this paper, is to estimate, from a single extracellularly-recorded signal, both ePSP and iPSP components of the LFP. The proposed method is based on a model-based reverse engineering approach in which the measured LFP is fed into a physiologically-grounded neural mass model (mesoscopic level) in order to estimate the synaptic activity of a sub-population of pyramidal cells interacting with local GABAergic interneurons. The method was first validated using simulated LFPs for which excitatory and inhibitory components are known a priori and can thus serve as a ground truth. It was then evaluated on in vivo data (PTZ-induced seizures, rat; PTZ-induced excitability increase, mouse; epileptiform discharges, mouse) and on in clinico data (human seizures recorded with depth-EEG electrodes). Under these various conditions, results showed that the proposed reverse engineering method provides a reliable estimation of the average excitatory and inhibitory post-synaptic potentials at the origin of the measured LFPs. They also indicated that the method allows for monitoring of the excitation/inhibition ratio. The method has potential for multiple applications in neuroscience, typically when a time tracking of local excitability changes is required.

scholarly journals Hippocampal Interneurons are Required for Trace Eyeblink Conditioning in Mice

2021 ◽  
Author(s):  
Wei-Wei Zhang ◽  
Rong-Rong Li ◽  
Jie Zhang ◽  
Jie Yan ◽  
Qian-Hui Zhang ◽  
...  
Keyword(s):  
Eyeblink Conditioning ◽  
Pyramidal Cells ◽  
Conditioned Eyeblink ◽  
Cellular Mechanisms ◽  
Sustained Activity ◽  
Early Acquisition ◽  
Freely Moving ◽  
Trace Eyeblink Conditioning

AbstractWhile the hippocampus has been implicated in supporting the association among time-separated events, the underlying cellular mechanisms have not been fully clarified. Here, we combined in vivo multi-channel recording and optogenetics to investigate the activity of hippocampal interneurons in freely-moving mice performing a trace eyeblink conditioning (tEBC) task. We found that the hippocampal interneurons exhibited conditioned stimulus (CS)-evoked sustained activity, which predicted the performance of conditioned eyeblink responses (CRs) in the early acquisition of the tEBC. Consistent with this, greater proportions of hippocampal pyramidal cells showed CS-evoked decreased activity in the early acquisition of the tEBC. Moreover, optogenetic suppression of the sustained activity in hippocampal interneurons severely impaired acquisition of the tEBC. In contrast, suppression of the sustained activity of hippocampal interneurons had no effect on the performance of well-learned CRs. Our findings highlight the role of hippocampal interneurons in the tEBC, and point to a potential cellular mechanism subserving associative learning.

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