Transient Suppression of GABAA-Receptor–Mediated IPSPs After Epileptiform Burst Discharges in CA1 Pyramidal Cells

1998 ◽  
Vol 79 (2) ◽  
pp. 659-669 ◽  
Author(s):  
F.E.N. Le Beau ◽  
B. E. Alger
Keyword(s):  
G Proteins ◽  
Pyramidal Neurons ◽  
Membrane Conductance ◽  
Pyramidal Cells ◽  
Postsynaptic Membrane ◽  
Burst Discharge ◽  
Ca1 Pyramidal Cells ◽  
Acid Bath ◽  
Bath Application ◽  
Intracellular Ca

Le Beau, F.E.N. and B. E. Alger. Transient suppression ofGABAA-receptor–mediated IPSPs after epileptiform burst discharges in CA1 pyramidal cells. J. Neurophysiol. 79: 659–669, 1998. Epileptiform burst discharges were elicited in CA1 hippocampal pyramidal cells in the slice preparation by perfusion with Mg2+-free saline. Intracellular recordings revealed paroxysmal depolarization shifts (PDSs) that either occurred spontaneously or were evoked by stimulation of Schaffer collaterals. These bursts involved activation of N-methyl-d-aspartate receptors because burst discharges were reduced or abolished by dl-2-amino-5-phosphonovaleric acid. Bath application of carbachol caused an increase in spontaneous activity that was predominantly due to γ-aminobutyric acid-A-receptor–mediated spontaneous inhibitory postsynaptic potentials (sIPSPs). A marked reduction in sIPSPs (31%) was observed after each epileptiform burst discharge, which subsequently recovered to preburst levels after ∼4–20 s. This sIPSP suppression was not associated with any change in postsynaptic membrane conductance. A suppression of sIPSPs also was seen after burst discharges evoked by brief (100–200 ms) depolarizing current pulses. N-ethylmaleimide, which blocks pertussis-toxin–sensitive G proteins, significantly reduced the suppression of sIPSPs seen after a burst response. When increases in intracellular Ca2+ were buffered by intracellular injection of ethylene glycol bis(β-aminoethyl)ether- N,N,N′,N′-tetraacetic acid, the sIPSP suppression seen after a single spontaneous or evoked burst discharge was abolished. Although we cannot exclude other Ca2+-dependent mechanisms, this suppression of sIPSPs shared many of the characteristics of depolarization-induced suppression of inhibition (DSI) in that it involved activation of G proteins and was dependent on increases in intracellular calcium. These findings suggest that a DSI-like process may be activated by the endogenous burst firing of CA1 pyramidal neurons.

Stimulation of 5-HT2 Receptors in Prefrontal Pyramidal Neurons Inhibits Cav1.2 L-Type Ca2+Currents Via a PLCβ/IP3/Calcineurin Signaling Cascade

2002 ◽  
Vol 87 (5) ◽  
pp. 2490-2504 ◽  
Author(s):  
Michelle Day ◽  
Patricia A. Olson ◽  
Josef Platzer ◽  
Joerg Striessnig ◽  
D. James Surmeier
Keyword(s):  
Pyramidal Neurons ◽  
Inositol Trisphosphate ◽  
Cell Voltage ◽  
Signaling Cascade ◽  
Channel Modulation ◽  
Receptor Modulation ◽  
Bath Application ◽  
Voltage Dependent ◽  
Intracellular Ca ◽  
Layer V

There is growing evidence linking alterations in serotonergic signaling in the prefrontal cortex to the etiology of schizophrenia. Prefrontal pyramidal neurons are richly innervated by serotonergic fibers and express high levels of serotonergic 5-HT2-class receptors. It is unclear, however, how activation of these receptors modulates cellular activity. To help fill this gap, whole cell voltage-clamp and single-cell RT-PCR studies of acutely isolated layer V–VI prefrontal pyramidal neurons were undertaken. The vast majority (>80%) of these neurons had detectable levels of 5-HT2A or 5-HT2C receptor mRNA. Bath application of 5-HT2 agonists inhibited voltage-dependent Ca2+ channel currents. L-type Ca2+ channels were a particularly prominent target of this signaling pathway. The L-type channel modulation was blocked by disruption of Gαq signaling or by inhibition of phospholipase Cβ. Antagonism of intracellular inositol trisphosphate signaling, chelation of intracellular Ca2+, or depletion of intracellular Ca2+ stores also blocked this modulation. Inhibition of the Ca2+-dependent phosphatase calcineurin prevented receptor-mediated modulation of L-type currents. Last, the 5-HT2 receptor modulation was robustly expressed in neurons from Cav1.3 knockout mice. These findings argue that 5-HT2receptors couple through Gαq proteins to trigger a phospholipase Cβ/inositol trisphosphate signaling cascade resulting in the mobilization of intracellular Ca2+, activation of calcineurin, and inhibition of Cav1.2 L-type Ca2+currents. This modulation and its blockade by atypical neuroleptics could have wide-ranging effects on synaptic integration and long-term gene expression in deep-layer prefrontal pyramidal neurons.

Zn2+ Blocks the NMDA- and Ca2+-Triggered Postexposure Current I pe in Hippocampal Pyramidal Cells

1998 ◽  
Vol 79 (2) ◽  
pp. 1124-1126 ◽  
Author(s):  
Qiang X. Chen ◽  
Katherine L. Perkins ◽  
Robert K. S. Wong
Keyword(s):  
Divalent Cations ◽  
Pyramidal Cells ◽  
Cell Voltage ◽  
Continuous Growth ◽  
Ca1 Pyramidal Cells ◽  
Cation Current ◽  
Hippocampal Ca1 ◽  
Intracellular Ca ◽  
Hippocampal Pyramidal Cells

Chen, Qiang X., Katherine L. Perkins, and Robert K. S. Wong. Zn2+ blocks the NMDA- and Ca2+-triggered postexposure current I pe in hippocampal pyramidal cells. J. Neurophysiol. 79: 1124–1126, 1998. Whole cell voltage-clamp recordings from acutely isolated hippocampal CA1 pyramidal cells from adult guinea pigs were used to evaluate divalent cations as possible blockers of the postexposure current ( I pe). I pe is a cation current that is triggered by the rise in intracellular Ca2+ concentration that occurs after the application of a toxic level of N-methyl-d-aspartate (NMDA). Once triggered, I pe continues to grow until death of the neuron occurs. I pe may be a critical link between transient NMDA exposure and cell death. I pe was blocked by micromolar concentrations of Zn2+. The Zn2+ effect had an IC50 of 64 μM and saturated at 500 μM. Prolonged Zn2+ block of I pe revealed that the maintenance of a steady I pe is not dependent on I pe-mediated Ca2+ influx but that the continuous growth in I pe is dependent on I pe-mediated Ca2+ influx. The availability of an effective blocker of I pe should facilitate the investigation of the intracellular activation pathway of I pe and the role of I pe in neuronal death.

Calcium Coding and Adaptive Temporal Computation in Cortical Pyramidal Neurons

1998 ◽  
Vol 79 (3) ◽  
pp. 1549-1566 ◽  
Author(s):  
Xiao-Jing Wang
Keyword(s):  
Current Pulse ◽  
Pyramidal Neurons ◽  
Model Neuron ◽  
Pyramidal Cells ◽  
Spike Frequency ◽  
Neuronal Firing ◽  
Spike Frequency Adaptation ◽  
Synaptic Inputs ◽  
Cortical Pyramidal Neurons ◽  
Intracellular Ca

Wang, Xiao-Jing. Calcium coding and adaptive temporal computation in cortical pyramidal neurons. J. Neurophysiol. 79: 1549–1566, 1998. In this work, we present a quantitative theory of temporal spike-frequency adaptation in cortical pyramidal cells. Our model pyramidal neuron has two-compartments (a “soma” and a “dendrite”) with a voltage-gated Ca2+ conductance ( g Ca) and a Ca2+-dependent K+ conductance ( g AHP) located at the dendrite or at both compartments. Its frequency-current relations are comparable with data from cortical pyramidal cells, and the properties of spike-evoked intracellular [Ca2+] transients are matched with recent dendritic [Ca2+] imaging measurements. Spike-frequency adaptation in response to a current pulse is characterized by an adaptation time constant τadap and percentage adaptation of spike frequency F adap [% (peak − steady state)/peak]. We show how τadap and F adap can be derived in terms of the biophysical parameters of the neural membrane and [Ca2+] dynamics. Two simple, experimentally testable, relations between τadap and F adap are predicted. The dependence of τadap and F adap on current pulse intensity, electrotonic coupling between the two compartments, g AHP as well the [Ca2+] decay time constant τCa, is assessed quantitatively. In addition, we demonstrate that the intracellular [Ca2+] signal can encode the instantaneous neuronal firing rate and that the conductance-based model can be reduced to a simple calcium-model of neuronal activity that faithfully predicts the neuronal firing output even when the input varies relatively rapidly in time (tens to hundreds of milliseconds). Extensive simulations have been carried out for the model neuron with random excitatory synaptic inputs mimicked by a Poisson process. Our findings include 1) the instantaneous firing frequency (averaged over trials) shows strong adaptation similar to the case with current pulses; 2) when the g AHP is blocked, the dendritic g Ca could produce a hysteresis phenomenon where the neuron is driven to switch randomly between a quiescent state and a repetitive firing state. The firing pattern is very irregular with a large coefficient of variation of the interspike intervals (ISI CV > 1). The ISI distribution shows a long tail but is not bimodal. 3) By contrast, in an intrinsically bursting regime (with different parameter values), the model neuron displays a random temporal mixture of single action potentials and brief bursts of spikes. Its ISI distribution is often bimodal and its power spectrum has a peak. 4) The spike-adapting current I AHP, as delayed inhibition through intracellular Ca2+ accumulation, generates a “forward masking” effect, where a masking input dramatically reduces or completely suppresses the neuronal response to a subsequent test input. When two inputs are presented repetitively in time, this mechanism greatly enhances the ratio of the responses to the stronger and weaker inputs, fulfilling a cellular form of lateral inhibition in time. 5) The [Ca2+]-dependent I AHP provides a mechanism by which the neuron unceasingly adapts to the stochastic synaptic inputs, even in the stationary state following the input onset. This creates strong negative correlations between output ISIs in a frequency-dependent manner, while the Poisson input is totally uncorrelated in time. Possible functional implications of these results are discussed.

Propagating dendritic action potential mediates synaptic transmission in CA1 pyramidal cells in situ

1990 ◽  
Vol 64 (5) ◽  
pp. 1429-1441 ◽  
Author(s):  
O. Herreras
Keyword(s):  
Pyramidal Neurons ◽  
Current Source ◽  
Maximum Amplitude ◽  
Pyramidal Cells ◽  
Distal Portion ◽  
Ca1 Pyramidal Cells ◽  
Basal Dendrites ◽  
Voltage Dependent ◽  
Speed Of Propagation ◽  
Apical Dendrites

1. The events leading to the Schaffer collateral-induced discharge of CA1 pyramidal neurons were investigated in the hippocampus of anesthetized rats by current source-density (CSD) analysis. 2. The earliest evoked currents detected shortly after a stimulus were a sink in the zone where synapses are known to be located (300-350 microns ventral to the somatic layer) flanked by two smaller sources in the distal portion of the apical dendrites and in the somatic layer. This synaptic sink (SyS) extended over 75-100 microns; it lasted for 15-20 ms, and it reached its maximum amplitude some milliseconds after the population spike (PS) and remained in the same location. Stimuli submaximal and supramaximal for evoking a PS yielded the same pattern of current distribution for the SyS. Presynaptic fiber volleys were not detected in these recordings. 3. During the rising phase of the SyS a second sink appeared in a more proximal portion of the apical dendrites. This late dendritic sink (LS) extended over 50-75 microns and was centered 100-150 microns ventral to the somatic layer. This proximal dendritic sink was of amplitude comparable with the SyS; it outlasted the latter and was not necessarily followed by a somatic PS. The LS was extinguished with the appearance of a PS, whereas the SyS persisted regardless of the presence of a PS. 4. After maximal stimuli the LS grew until it exceeded a threshold amplitude, and then, it started to move somatopetally as a continuously propagating sink (PrS). The average speed of propagation was approximately 0.2 m/s. In 0.5-0.7 ms the PrS reached the cell-body layer displacing the passive source that moved into the basal dendrites. The PrS then became the intensive sink corresponding to the main (negative) phase of the somatic PS. This was followed by the development of an active source in the soma layer, probably corresponding to the repolarization phase of the PS. 5. From these observations it appears that the LS and PrS are active dendritic responses. It may be inferred that, shortly after the synaptic currents enter the dendrites, depolarization of adjacent membranes causes the opening of low-threshold, voltage-dependent, slowly inactivating channels that generate the LS. If the depolarization resulting from the LS current is intense enough, another population of channels open that are also voltage-dependent but of higher threshold and faster inactivation.(ABSTRACT TRUNCATED AT 400 WORDS)

scholarly journals Disinhibitory and neuromodulatory regulation of hippocampal synaptic plasticity

2020 ◽  
Author(s):  
Inês Guerreiro ◽  
Zhenglin Gu ◽  
Jerrel L. Yakel ◽  
Boris S. Gutkin
Keyword(s):  
Synaptic Plasticity ◽  
Pyramidal Neurons ◽  
Pyramidal Cells ◽  
General Mechanism ◽  
Excitatory Synapses ◽  
Ca1 Pyramidal Cells ◽  
Ca1 Pyramidal Neurons ◽  
Hippocampal Synaptic Plasticity ◽  
Local Circuitry ◽  
Feedforward Inhibition

AbstractHippocampal synaptic plasticity, particularly in the Schaffer collateral (SC) to CA1 pyramidal excitatory transmission, is considered as the cellular mechanism underlying learning. The CA1 pyramidal neurons are embedded in an intricate local circuitry that contains a variety of interneurons. The roles these interneurons play in the regulation of the excitatory synaptic plasticity remains largely understudied. Our recent experiments showed that repeated cholinergic activation of α7 nACh receptors expressed in oriens-lacunosum-moleculare (OLMα2) interneurons could induce LTP in SC-CA1 synapses, likely through disinhibition by inhibiting stratum radiatum (s.r.) interneurons that provide feedforward inhibition onto CA1 pyramidal neurons, revealing a potential mechanism for local interneurons to regulate SC-CA1 synaptic plasticity. Here, we pair in vitro studies with biophysically-based modeling to uncover the mechanisms through which cholinergic-activated GABAergic interneurons can disinhibit CA1 pyramidal cells, and how repeated disinhibition modulates hippocampal plasticity at the excitatory synapses. We found that α7 nAChR activation increases OLM activity. OLM neurons, in turn inhibit the fast-spiking interneurons that provide feedforward inhibition onto CA1 pyramidal neurons. This disinhibition, paired with tightly timed SC stimulation, can induce potentiation at the excitatory synapses of CA1 pyramidal neurons. Our work further describes the pairing of disinhibition with SC stimulation as a general mechanism for the induction of hippocampal synaptic plasticity.Disinhibition of the excitatory synapses, paired with SC stimulation, leads to increased NMDAR activation and intracellular calcium concentration sufficient to upregulate AMPAR permeability and potentiate the synapse. Repeated paired disinhibition of the excitatory synapse leads to larger and longer lasting increases of the AMPAR permeability. Our study thus provides a novel mechanism for inhibitory interneurons to directly modify glutamatergic synaptic plasticity. In particular, we show how cholinergic action on OLM interneurons can down-regulate the GABAergic signaling onto CA1 pyramidal cells, and how this shapes local plasticity rules. We identify paired disinhibition with SC stimulation as a general mechanism for the induction of hippocampal synaptic plasticity.

scholarly journals Interneuron-specific plasticity at parvalbumin and somatostatin inhibitory synapses onto CA1 pyramidal neurons shapes hippocampal output

2019 ◽  
Author(s):  
Matt Udakis ◽  
Victor Pedrosa ◽  
Sophie E.L. Chamberlain ◽  
Claudia Clopath ◽  
Jack R Mellor
Keyword(s):  
Pyramidal Neurons ◽  
Physiological Activity ◽  
Activity Patterns ◽  
Pyramidal Cells ◽  
Network Activity ◽  
Inhibitory Synapses ◽  
Ca1 Pyramidal Cells ◽  
Hippocampal Cell ◽  
Hippocampal Network

SummaryThe formation and maintenance of spatial representations within hippocampal cell assemblies is strongly dictated by patterns of inhibition from diverse interneuron populations. Although it is known that inhibitory synaptic strength is malleable, induction of long-term plasticity at distinct inhibitory synapses and its regulation of hippocampal network activity is not well understood. Here, we show that inhibitory synapses from parvalbumin and somatostatin expressing interneurons undergo long-term depression and potentiation respectively (PV-iLTD and SST-iLTP) during physiological activity patterns. Both forms of plasticity rely on T-type calcium channel activation to confer synapse specificity but otherwise employ distinct mechanisms. Since parvalbumin and somatostatin interneurons preferentially target perisomatic and distal dendritic regions respectively of CA1 pyramidal cells, PV-iLTD and SST-iLTP coordinate a reprioritisation of excitatory inputs from entorhinal cortex and CA3. Furthermore, circuit-level modelling reveals that PV-iLTD and SST-iLTP cooperate to stabilise place cells while facilitating representation of multiple unique environments within the hippocampal network.

scholarly journals Novel Ca2+-dependent mechanisms regulate spontaneous release at excitatory synapses onto CA1 pyramidal cells

2018 ◽  
Vol 119 (2) ◽  
pp. 597-607 ◽  
Author(s):  
Walter E. Babiec ◽  
Thomas J. O’Dell
Keyword(s):  
Action Potential ◽  
Pyramidal Cells ◽  
Synaptic Function ◽  
Excitatory Synapses ◽  
Spontaneous Release ◽  
Ca1 Pyramidal Cells ◽  
Spontaneous Action Potential ◽  
Mepsc Frequency ◽  
Intracellular Ca ◽  
Spontaneous Action

Although long thought to simply be a source of synaptic noise, spontaneous, action potential-independent release of neurotransmitter from presynaptic terminals has multiple roles in synaptic function. We explored whether and to what extent the two predominantly proposed mechanisms for explaining spontaneous release, stochastic activation of voltage-gated Ca2+ channels (VGCCs) or activation of Ca2+-sensing receptors (CaSRs) by extracellular Ca2+, played a role in the sensitivity of spontaneous release to the level of extracellular Ca2+ concentration at excitatory synapses at CA1 pyramidal cells of the adult male mouse hippocampus. Blocking VGCCs with Cd2+ had no effect on spontaneous release, ruling out stochastic activation of VGCCs. Although divalent cation agonists of CaSRs, Co2+ and Mg2+, dramatically enhanced miniature excitatory postsynaptic current (mEPSC) frequency, potent positive and negative allosteric modulators of CaSRs had no effect. Moreover, immunoblot analysis of hippocampal lysates failed to detect CaSR expression, ruling out the CaSR. Instead, the increase in mEPSC frequency induced by Co2+ and Mg2+ was mimicked by lowering postsynaptic Ca2+ levels with BAPTA. Together, our results suggest that a reduction in intracellular Ca2+ may trigger a homeostatic-like compensatory response that upregulates spontaneous transmission at excitatory synapses onto CA1 pyramidal cells in the adult hippocampus. NEW & NOTEWORTHY We show that the predominant theories for explaining the regulation of spontaneous, action potential-independent synaptic release do not explain the sensitivity of this type of synaptic transmission to external Ca2+ concentration at excitatory synapses onto hippocampal CA1 pyramidal cells. In addition, our data indicate that intracellular Ca2+ levels in CA1 pyramidal cells regulate spontaneous release, suggesting that excitatory synapses onto CA1 pyramidal cells may express a novel, rapid form of homeostatic plasticity.

scholarly journals Signal Propagation in Oblique Dendrites of CA1 Pyramidal Cells

2005 ◽  
Vol 94 (6) ◽  
pp. 4145-4155 ◽  
Author(s):  
Michele Migliore ◽  
Michele Ferrante ◽  
Giorgio A. Ascoli
Keyword(s):  
Pyramidal Neurons ◽  
Back Propagation ◽  
Three Dimensional ◽  
Pyramidal Cells ◽  
Signal Propagation ◽  
Morphological Properties ◽  
Ca1 Neurons ◽  
Electrophysiological Properties ◽  
Ca1 Pyramidal Cells ◽  
Dendritic Spikes

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.

scholarly journals Differential Structure of Hippocampal CA1 Pyramidal Neurons in the Human and Mouse

2019 ◽  
Author(s):  
Ruth Benavides-Piccione ◽  
Mamen Regalado-Reyes ◽  
Isabel Fernaud-Espinosa ◽  
Asta Kastanauskaite ◽  
Silvia Tapia-González ◽  
...  
Keyword(s):  
Pyramidal Neurons ◽  
Pyramidal Cells ◽  
Homologous Region ◽  
Ca1 Pyramidal Cells ◽  
Ca1 Region ◽  
Hippocampal Ca1 ◽  
Structural Differences ◽  
Species Specific ◽  
Human And Mouse ◽  
Shed Light

Abstract Pyramidal neurons are the most common cell type and are considered the main output neuron in most mammalian forebrain structures. In terms of function, differences in the structure of the dendrites of these neurons appear to be crucial in determining how neurons integrate information. To further shed light on the structure of the human pyramidal neurons we investigated the geometry of pyramidal cells in the human and mouse CA1 region—one of the most evolutionary conserved archicortical regions, which is critically involved in the formation, consolidation, and retrieval of memory. We aimed to assess to what extent neurons corresponding to a homologous region in different species have parallel morphologies. Over 100 intracellularly injected and 3D-reconstructed cells across both species revealed that dendritic and axonal morphologies of human cells are not only larger but also have structural differences, when compared to mouse. The results show that human CA1 pyramidal cells are not a stretched version of mouse CA1 cells. These results indicate that there are some morphological parameters of the pyramidal cells that are conserved, whereas others are species-specific.

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