Your search keyword '"CA1 Region, Hippocampal physiology"' showing total 298 results

1. Functional networks of inhibitory neurons orchestrate synchrony in the hippocampus.

Author

Bocchio M, Vorobyev A, Sadeh S, Brustlein S, Dard R, Reichinnek S, Emiliani V, Baude A, Clopath C, and Cossart R

Subjects

Animals, Mice, Nerve Net physiology, Neural Inhibition physiology, CA1 Region, Hippocampal physiology, CA1 Region, Hippocampal cytology, Action Potentials physiology, Male, Mice, Inbred C57BL, Interneurons physiology, Pyramidal Cells physiology, Optogenetics, Hippocampus physiology

Abstract

Inhibitory interneurons are pivotal components of cortical circuits. Beyond providing inhibition, they have been proposed to coordinate the firing of excitatory neurons within cell assemblies. While the roles of specific interneuron subtypes have been extensively studied, their influence on pyramidal cell synchrony in vivo remains elusive. Employing an all-optical approach in mice, we simultaneously recorded hippocampal interneurons and pyramidal cells and probed the network influence of individual interneurons using optogenetics. We demonstrate that CA1 interneurons form a functionally interconnected network that promotes synchrony through disinhibition during awake immobility, while preserving endogenous cell assemblies. Our network model underscores the importance of both cell assemblies and dense, unspecific interneuron connectivity in explaining our experimental findings, suggesting that interneurons may operate not only via division of labor but also through concerted activity., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Bocchio et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

2. Domain-selective and sex-dependent regulation of learning and memory in mice by GIRK channel activity in CA1 pyramidal neurons of the dorsal hippocampus.

Author

Luo H, Frederick M, Marron Fernandez de Velasco E, Oltmanns JO, Wright C, and Wickman K

Subjects

Animals, Male, Female, Recognition, Psychology physiology, Avoidance Learning physiology, Mice, Inbred C57BL, Mice, Sex Characteristics, Extinction, Psychological physiology, Memory physiology, Learning physiology, Exploratory Behavior physiology, Pyramidal Cells physiology, Pyramidal Cells metabolism, CA1 Region, Hippocampal physiology, CA1 Region, Hippocampal metabolism, G Protein-Coupled Inwardly-Rectifying Potassium Channels metabolism, Fear physiology

Abstract

G protein-gated inwardly rectifying K + (GIRK) channels mediate the postsynaptic inhibitory effect of many neurotransmitters in the hippocampus and are implicated in neurological disorders characterized by cognitive deficits. Here, we show that enhancement or suppression of GIRK channel activity in dorsal CA1 pyramidal neurons disrupted novel object recognition in mice, without impacting open field activity or avoidance behavior. Contextual fear learning was also unaffected, but extinction of contextual fear was disrupted by suppression of GIRK channel activity in male mice. Thus, the strength of GIRK channel activity in dorsal CA1 pyramidal neurons regulates select cognitive task performance in mice., (© 2024 Luo et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2024

3. A biophysical minimal model to investigate age-related changes in CA1 pyramidal cell electrical activity.

Author

McKiernan EC, Herrera-Valdez MA, and Marrone DF

Subjects

Animals, Models, Neurological, Action Potentials physiology, Calcium Channels, L-Type metabolism, Biophysical Phenomena, Pyramidal Cells metabolism, Pyramidal Cells physiology, Aging physiology, CA1 Region, Hippocampal physiology, CA1 Region, Hippocampal cytology, CA1 Region, Hippocampal metabolism

Abstract

Aging is a physiological process that is still poorly understood, especially with respect to effects on the brain. There are open questions about aging that are difficult to answer with an experimental approach. Underlying challenges include the difficulty of recording in vivo single cell and network activity simultaneously with submillisecond resolution, and brain compensatory mechanisms triggered by genetic, pharmacologic, or behavioral manipulations. Mathematical modeling can help address some of these questions by allowing us to fix parameters that cannot be controlled experimentally and investigate neural activity under different conditions. We present a biophysical minimal model of CA1 pyramidal cells (PCs) based on general expressions for transmembrane ion transport derived from thermodynamical principles. The model allows directly varying the contribution of ion channels by changing their number. By analyzing the dynamics of the model, we find parameter ranges that reproduce the variability in electrical activity seen in PCs. In addition, increasing the L-type Ca2+ channel expression in the model reproduces age-related changes in electrical activity that are qualitatively and quantitatively similar to those observed in PCs from aged animals. We also make predictions about age-related changes in PC bursting activity that, to our knowledge, have not been reported previously. We conclude that the model's biophysical nature, flexibility, and computational simplicity make it a potentially powerful complement to experimental studies of aging., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 McKiernan et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

4. Input specificity of NMDA-dependent GABAergic plasticity in the hippocampus.

Author

Wiera G, Jabłońska J, Lech AM, and Mozrzymas JW

Subjects

Animals, N-Methylaspartate metabolism, N-Methylaspartate pharmacology, Hippocampus metabolism, Hippocampus physiology, Parvalbumins metabolism, Male, Mice, Somatostatin metabolism, Receptors, N-Methyl-D-Aspartate metabolism, Synapses metabolism, Synapses physiology, Long-Term Potentiation, GABAergic Neurons metabolism, GABAergic Neurons drug effects, CA1 Region, Hippocampal metabolism, CA1 Region, Hippocampal physiology, Matrix Metalloproteinase 9 metabolism, Matrix Metalloproteinase 3 metabolism, Matrix Metalloproteinase 3 genetics, Neuronal Plasticity physiology, Interneurons metabolism, Pyramidal Cells metabolism, Pyramidal Cells physiology

Abstract

Sensory experiences and learning induce long-lasting changes in both excitatory and inhibitory synapses, thereby providing a crucial substrate for memory. However, the co-tuning of excitatory long-term potentiation (eLTP) or depression (eLTD) with the simultaneous changes at inhibitory synapses (iLTP/iLTD) remains unclear. Herein, we investigated the co-expression of NMDA-induced synaptic plasticity at excitatory and inhibitory synapses in hippocampal CA1 pyramidal cells (PCs) using a combination of electrophysiological, optogenetic, and pharmacological approaches. We found that inhibitory inputs from somatostatin (SST) and parvalbumin (PV)-positive interneurons onto CA1 PCs display input-specific long-term plastic changes following transient NMDA receptor activation. Notably, synapses from SST-positive interneurons consistently exhibited iLTP, irrespective of the direction of excitatory plasticity, whereas synapses from PV-positive interneurons predominantly showed iLTP concurrent with eLTP, rather than eLTD. As neuroplasticity is known to depend on the extracellular matrix, we tested the impact of metalloproteinases (MMP) inhibition. MMP3 blockade interfered with GABAergic plasticity for all inhibitory inputs, whereas MMP9 inhibition selectively blocked eLTP and iLTP in SST-CA1PC synapses co-occurring with eLTP but not eLTD. These findings demonstrate the dissociation of excitatory and inhibitory plasticity co-expression. We propose that these mechanisms of plasticity co-expression may be involved in maintaining excitation-inhibition balance and modulating neuronal integration modes., (© 2024. The Author(s).)

Published

2024

5. Circuit dynamics of superficial and deep CA1 pyramidal cells and inhibitory cells in freely moving macaques.

Author

Abbaspoor S and Hoffman KL

Subjects

Animals, Action Potentials physiology, Male, Nerve Net physiology, Pyramidal Cells physiology, CA1 Region, Hippocampal physiology, CA1 Region, Hippocampal cytology

Abstract

Diverse neuron classes in hippocampal CA1 have been identified through the heterogeneity of their cellular/molecular composition. How these classes relate to hippocampal function and the network dynamics that support cognition in primates remains unclear. Here, we report inhibitory functional cell groups in CA1 of freely moving macaques whose diverse response profiles to network states and each other suggest distinct and specific roles in the functional microcircuit of CA1. In addition, pyramidal cells that were grouped by their superficial or deep layer position differed in firing rate, burstiness, and sharp-wave ripple-associated firing. They also showed strata-specific spike-timing interactions with inhibitory cell groups, suggestive of segregated neural populations. Furthermore, ensemble recordings revealed that cell assemblies were preferentially organized according to these strata. These results suggest that hippocampal CA1 in freely moving macaques bears a sublayer-specific circuit organization that may shape its role in cognition., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

6. A hippocampal circuit mechanism to balance memory reactivation during sleep.

Author

Karaba LA, Robinson HL, Harvey RE, Chen W, Fernandez-Ruiz A, and Oliva A

Subjects

Animals, Male, Mice, CA2 Region, Hippocampal physiology, Interneurons physiology, Learning physiology, Action Potentials, CA1 Region, Hippocampal physiology, Cholecystokinin metabolism, Memory Consolidation physiology, Pyramidal Cells physiology, Sleep physiology

Abstract

Memory consolidation involves the synchronous reactivation of hippocampal cells active during recent experience in sleep sharp-wave ripples (SWRs). How this increase in firing rates and synchrony after learning is counterbalanced to preserve network stability is not understood. We discovered a network event generated by an intrahippocampal circuit formed by a subset of CA2 pyramidal cells to cholecystokinin-expressing (CCK+) basket cells, which fire a barrage of action potentials ("BARR") during non-rapid eye movement sleep. CA1 neurons and assemblies that increased their activity during learning were reactivated during SWRs but inhibited during BARRs. The initial increase in reactivation during SWRs returned to baseline through sleep. This trend was abolished by silencing CCK+ basket cells during BARRs, resulting in higher synchrony of CA1 assemblies and impaired memory consolidation.

Published

2024

7. Functional architecture of intracellular oscillations in hippocampal dendrites.

Author

Liao Z, Gonzalez KC, Li DM, Yang CM, Holder D, McClain NE, Zhang G, Evans SW, Chavarha M, Simko J, Makinson CD, Lin MZ, Losonczy A, and Negrean A

Subjects

Animals, Mice, Membrane Potentials physiology, Male, Mice, Inbred C57BL, Hippocampus physiology, Hippocampus cytology, Spatial Navigation physiology, Locomotion physiology, Dendrites physiology, Dendrites metabolism, Pyramidal Cells physiology, Pyramidal Cells metabolism, CA1 Region, Hippocampal physiology, CA1 Region, Hippocampal cytology

Abstract

Fast electrical signaling in dendrites is central to neural computations that support adaptive behaviors. Conventional techniques lack temporal and spatial resolution and the ability to track underlying membrane potential dynamics present across the complex three-dimensional dendritic arbor in vivo. Here, we perform fast two-photon imaging of dendritic and somatic membrane potential dynamics in single pyramidal cells in the CA1 region of the mouse hippocampus during awake behavior. We study the dynamics of subthreshold membrane potential and suprathreshold dendritic events throughout the dendritic arbor in vivo by combining voltage imaging with simultaneous local field potential recording, post hoc morphological reconstruction, and a spatial navigation task. We systematically quantify the modulation of local event rates by locomotion in distinct dendritic regions, report an advancing gradient of dendritic theta phase along the basal-tuft axis, and describe a predominant hyperpolarization of the dendritic arbor during sharp-wave ripples. Finally, we find that spatial tuning of dendritic representations dynamically reorganizes following place field formation. Our data reveal how the organization of electrical signaling in dendrites maps onto the anatomy of the dendritic tree across behavior, oscillatory network, and functional cell states., (© 2024. The Author(s).)

Published

2024

8. RhoGEF Tiam2 Regulates Glutamatergic Synaptic Transmission in Hippocampal CA1 Pyramidal Neurons.

Author

Rao S, Liang F, and Herring BE

Subjects

Animals, Male, Mice, Inbred C57BL, Female, Synapses physiology, Synapses drug effects, Synapses metabolism, Mice, Pyramidal Cells physiology, Pyramidal Cells drug effects, Pyramidal Cells metabolism, Guanine Nucleotide Exchange Factors metabolism, CA1 Region, Hippocampal physiology, CA1 Region, Hippocampal drug effects, CA1 Region, Hippocampal metabolism, Synaptic Transmission physiology, Synaptic Transmission drug effects, Glutamic Acid metabolism, Excitatory Postsynaptic Potentials physiology, Excitatory Postsynaptic Potentials drug effects

Abstract

Glutamatergic synapses exhibit significant molecular diversity, but circuit-specific mechanisms that underlie synaptic regulation are not well characterized. Prior reports show that Rho-guanine nucleotide exchange factor (RhoGEF) Tiam1 regulates perforant path→dentate gyrus granule neuron synapses. In the present study, we report Tiam1's homolog Tiam2 is implicated in glutamatergic neurotransmission in CA1 pyramidal neurons. We find that Tiam2 regulates evoked excitatory glutamatergic currents via a postsynaptic mechanism mediated by the catalytic Dbl-homology domain. Overall, we present evidence for RhoGEF Tiam2's role in glutamatergic synapse function at Schaffer collateral→CA1 pyramidal neuron synapses., Competing Interests: The authors declare no competing financial interests., (Copyright © 2024 Rao et al.)

Published

2024

9. MDGA2 Constrains Glutamatergic Inputs Selectively onto CA1 Pyramidal Neurons to Optimize Neural Circuits for Plasticity, Memory, and Social Behavior.

Author

Wang X, Lin D, Jiang J, Liu Y, Dong X, Fan J, Gong L, Shen W, Zeng L, Xu T, Jiang K, Connor SA, and Xie Y

Subjects

Animals, Male, Mice, Excitatory Postsynaptic Potentials physiology, Glutamic Acid metabolism, Memory physiology, Mice, Inbred C57BL, Mice, Knockout, CA1 Region, Hippocampal metabolism, CA1 Region, Hippocampal physiology, Neuronal Plasticity physiology, Pyramidal Cells physiology, Pyramidal Cells metabolism, Social Behavior, Synapses metabolism, Synapses physiology

Abstract

Synapse organizers are essential for the development, transmission, and plasticity of synapses. Acting as rare synapse suppressors, the MAM domain containing glycosylphosphatidylinositol anchor (MDGA) proteins contributes to synapse organization by inhibiting the formation of the synaptogenic neuroligin-neurexin complex. A previous analysis of MDGA2 mice lacking a single copy of Mdga2 revealed upregulated glutamatergic synapses and behaviors consistent with autism. However, MDGA2 is expressed in diverse cell types and is localized to both excitatory and inhibitory synapses. Differentiating the network versus cell-specific effects of MDGA2 loss-of-function requires a cell-type and brain region-selective strategy. To address this, we generated mice harboring a conditional knockout of Mdga2 restricted to CA1 pyramidal neurons. Here we report that MDGA2 suppresses the density and function of excitatory synapses selectively on pyramidal neurons in the mature hippocampus. Conditional deletion of Mdga2 in CA1 pyramidal neurons of adult mice upregulated miniature and spontaneous excitatory postsynaptic potentials, vesicular glutamate transporter 1 intensity, and neuronal excitability. These effects were limited to glutamatergic synapses as no changes were detected in miniature and spontaneous inhibitory postsynaptic potential properties or vesicular GABA transporter intensity. Functionally, evoked basal synaptic transmission and AMPAR receptor currents were enhanced at glutamatergic inputs. At a behavioral level, memory appeared to be compromised in Mdga2 cKO mice as both novel object recognition and contextual fear conditioning performance were impaired, consistent with deficits in long-term potentiation in the CA3-CA1 pathway. Social affiliation, a behavioral analog of social deficits in autism, was similarly compromised. These results demonstrate that MDGA2 confines the properties of excitatory synapses to CA1 neurons in mature hippocampal circuits, thereby optimizing this network for plasticity, cognition, and social behaviors., (© 2024. Center for Excellence in Brain Science and Intelligence Technology, Chinese Academy of Sciences.)

Published

2024

10. Hippocampal cholecystokinin-expressing interneurons regulate temporal coding and contextual learning.

Author

Rangel Guerrero DK, Balueva K, Barayeu U, Baracskay P, Gridchyn I, Nardin M, Roth CN, Wulff P, and Csicsvari J

Subjects

Animals, Male, Mice, CA1 Region, Hippocampal physiology, CA1 Region, Hippocampal cytology, CA1 Region, Hippocampal metabolism, Fear physiology, Learning physiology, Maze Learning physiology, Memory physiology, Mental Recall physiology, Mice, Inbred C57BL, Mice, Transgenic, Theta Rhythm physiology, Cholecystokinin metabolism, Cholecystokinin genetics, Hippocampus physiology, Interneurons physiology, Interneurons metabolism, Optogenetics, Pyramidal Cells physiology, Pyramidal Cells metabolism

Abstract

Cholecystokinin-expressing interneurons (CCKIs) are hypothesized to shape pyramidal cell-firing patterns and regulate network oscillations and related network state transitions. To directly probe their role in the CA1 region, we silenced their activity using optogenetic and chemogenetic tools in mice. Opto-tagged CCKIs revealed a heterogeneous population, and their optogenetic silencing triggered wide disinhibitory network changes affecting both pyramidal cells and other interneurons. CCKI silencing enhanced pyramidal cell burst firing and altered the temporal coding of place cells: theta phase precession was disrupted, whereas sequence reactivation was enhanced. Chemogenetic CCKI silencing did not alter the acquisition of spatial reference memories on the Morris water maze but enhanced the recall of contextual fear memories and enabled selective recall when similar environments were tested. This work suggests the key involvement of CCKIs in the control of place-cell temporal coding and the formation of contextual memories., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

11. Modeling realistic synaptic inputs of CA1 hippocampal pyramidal neurons and interneurons via Adaptive Generalized Leaky Integrate-and-Fire models.

Author

Marasco A, Tribuzi C, Lupascu CA, and Migliore M

Subjects

Animals, Action Potentials physiology, Synapses physiology, Computer Simulation, Models, Neurological, Pyramidal Cells physiology, Interneurons physiology, CA1 Region, Hippocampal physiology, CA1 Region, Hippocampal cytology

Abstract

Computational models of brain regions are crucial for understanding neuronal network dynamics and the emergence of cognitive functions. However, current supercomputing limitations hinder the implementation of large networks with millions of morphological and biophysical accurate neurons. Consequently, research has focused on simplified spiking neuron models, ranging from the computationally fast Leaky Integrate and Fire (LIF) linear models to more sophisticated non-linear implementations like Adaptive Exponential (AdEX) and Izhikevic models, through Generalized Leaky Integrate and Fire (GLIF) approaches. However, in almost all cases, these models are tuned (and can be validated) only under constant current injections and they may not, in general, also reproduce experimental findings under variable currents. This study introduces an Adaptive GLIF (A-GLIF) approach that addresses this limitation by incorporating a new set of update rules. The extended A-GLIF model successfully reproduces both constant and variable current inputs, and it was validated against the results obtained using a biophysical accurate model neuron. This enhancement provides researchers with a tool to optimize spiking neuron models using classic experimental traces under constant current injections, reliably predicting responses to synaptic inputs, which can be confidently used for large-scale network implementations., Competing Interests: Declaration of competing interest All the authors declare that no competing interests exist., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

12. Inhibition of 14-3-3 proteins increases the intrinsic excitability of mouse hippocampal CA1 pyramidal neurons.

Author

Logue JB, Vilmont V, Zhang J, Wu Y, and Zhou Y

Subjects

Animals, Male, Mice, Action Potentials physiology, Action Potentials drug effects, Mice, Inbred C57BL, Mice, Knockout, Oligopeptides pharmacology, Proteins pharmacology, 14-3-3 Proteins metabolism, 14-3-3 Proteins genetics, CA1 Region, Hippocampal physiology, Pyramidal Cells drug effects, Pyramidal Cells physiology

Abstract

14-3-3 proteins are a family of regulatory proteins that are abundantly expressed in the brain and enriched at the synapse. Dysfunctions of these proteins have been linked to neurodevelopmental and neuropsychiatric disorders. Our group has previously shown that functional inhibition of these proteins by a peptide inhibitor, difopein, in the mouse brain causes behavioural alterations and synaptic plasticity impairment in the hippocampus. Recently, we found an increased cFOS expression in difopein-expressing dorsal CA1 pyramidal neurons, indicating enhanced neuronal activity by 14-3-3 inhibition in these cells. In this study, we used slice electrophysiology to determine the effects of 14-3-3 inhibition on the intrinsic excitability of CA1 pyramidal neurons from a transgenic 14-3-3 functional knockout (FKO) mouse line. Our data demonstrate an increase in intrinsic excitability associated with 14-3-3 inhibition, as well as reveal action potential firing pattern shifts after novelty-induced hyperlocomotion in the 14-3-3 FKO mice. These results provide novel information on the role 14-3-3 proteins play in regulating intrinsic and activity-dependent neuronal excitability in the hippocampus., (© 2024 Federation of European Neuroscience Societies and John Wiley & Sons Ltd.)

Published

2024

13. Mathematical generation of data-driven hippocampal CA1 pyramidal neurons and interneurons copies via A-GLIF models for large-scale networks covering the experimental variability range.

Author

Marasco A, Tribuzi C, Iuorio A, and Migliore M

Subjects

Animals, Rats, Action Potentials physiology, Nerve Net physiology, Computer Simulation, Interneurons physiology, Pyramidal Cells physiology, CA1 Region, Hippocampal physiology, CA1 Region, Hippocampal cytology, Models, Neurological

Abstract

Efficient and accurate large-scale networks are a fundamental tool in modeling brain areas, to advance our understanding of neuronal dynamics. However, their implementation faces two key issues: computational efficiency and heterogeneity. Computational efficiency is achieved using simplified neurons, whereas there are no practical solutions available to solve the problem of reproducing in a large-scale network the experimentally observed heterogeneity of the intrinsic properties of neurons. This is important, because the use of identical nodes in a network can generate artifacts which can hinder an adequate representation of the properties of a real network. To this aim, we introduce a mathematical procedure to generate an arbitrary large number of copies of simplified hippocampal CA1 pyramidal neurons and interneurons models, which exhibit the full range of firing dynamics observed in these cells - including adapting, non-adapting and bursting. For this purpose, we rely on a recently published adaptive generalized leaky integrate-and-fire (A-GLIF) modeling approach, leveraging on its ability to reproduce the rich set of electrophysiological behaviors of these types of neurons under a variety of different stimulation currents. The generation procedure is based on a perturbation of model's parameters related to the initial data, firing block, and internal dynamics, and suitably validated against experimental data to ensure that the firing dynamics of any given cell copy remains within the experimental range. A classification procedure confirmed that the firing behavior of most of the pyramidal/interneuron copies was consistent with the experimental data. This approach allows to obtain heterogeneous copies with mathematically controlled firing properties. A full set of heterogeneous neurons composing the CA1 region of a rat hippocampus (approximately 1.2 million neurons), are provided in a database freely available in the live paper section of the EBRAINS platform. By adapting the underlying A-GLIF framework, it will be possible to extend the numerical approach presented here to create, in a mathematically controlled manner, an arbitrarily large number of non-identical copies of cell populations with firing properties related to other brain areas., Competing Interests: Declaration of competing interest All the authors declare that no competing interests exist., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

14. A voltage-based Event-Timing-Dependent Plasticity rule accounts for LTP subthreshold and suprathreshold for dendritic spikes in CA1 pyramidal neurons.

Author

Tomko M, Benuskova L, and Jedlicka P

Subjects

Animals, Neuronal Plasticity physiology, Tetrodotoxin pharmacology, Computer Simulation, Dendrites physiology, Long-Term Potentiation physiology, Pyramidal Cells physiology, CA1 Region, Hippocampal physiology, CA1 Region, Hippocampal cytology, Models, Neurological, Action Potentials physiology

Abstract

Long-term potentiation (LTP) is a synaptic mechanism involved in learning and memory. Experiments have shown that dendritic sodium spikes (Na-dSpikes) are required for LTP in the distal apical dendrites of CA1 pyramidal cells. On the other hand, LTP in perisomatic dendrites can be induced by synaptic input patterns that can be both subthreshold and suprathreshold for Na-dSpikes. It is unclear whether these results can be explained by one unifying plasticity mechanism. Here, we show in biophysically and morphologically realistic compartmental models of the CA1 pyramidal cell that these forms of LTP can be fully accounted for by a simple plasticity rule. We call it the voltage-based Event-Timing-Dependent Plasticity (ETDP) rule. The presynaptic event is the presynaptic spike or release of glutamate. The postsynaptic event is the local depolarization that exceeds a certain plasticity threshold. Our model reproduced the experimentally observed LTP in a variety of protocols, including local pharmacological inhibition of dendritic spikes by tetrodotoxin (TTX). In summary, we have provided a validation of the voltage-based ETDP, suggesting that this simple plasticity rule can be used to model even complex spatiotemporal patterns of long-term synaptic plasticity in neuronal dendrites., (© 2024. The Author(s).)

Published

2024

15. Loose patch clamp membrane current measurements in cornus ammonis 1 neurons in murine hippocampal slices.

Author

Bertagna F, Ahmad S, Lewis R, Silva SRP, McFadden J, Huang CL, Matthews HR, and Jeevaratnam K

Subjects

Animals, Mice, Membrane Potentials physiology, Hippocampus physiology, Hippocampus cytology, Neurons physiology, CA1 Region, Hippocampal physiology, CA1 Region, Hippocampal cytology, Mice, Inbred C57BL, Male, Patch-Clamp Techniques methods, Pyramidal Cells physiology

Abstract

Hippocampal pyramidal neuronal activity has been previously studied using conventional patch clamp in isolated cells and brain slices. We here introduce the loose patch clamping study of voltage-activated currents from in situ pyramidal neurons in murine cornus ammonis 1 hippocampal coronal slices. Depolarizing pulses of 15-ms duration elicited early transient inward, followed by transient and prolonged outward currents in the readily identifiable junctional region between the stratum pyramidalis (SP) and oriens (SO) containing pyramidal cell somas and initial segments. These resembled pyramidal cell currents previously recorded using conventional patch clamp. Shortening the depolarizing pulses to >1-2 ms continued to evoke transient currents; hyperpolarizing pulses to varying voltages evoked decays whose time constants could be shortened to <1 ms, clarifying the speed of clamping in this experimental system. The inward and outward currents had distinct pharmacological characteristics and voltage-dependent inactivation and recovery from inactivation. Comparative recordings from the SP, known to contain pyramidal cell somas, demonstrated similar current properties. Recordings from the SO and stratum radiatum demonstrated smaller inward and outward current magnitudes and reduced transient outward currents, consistent with previous conventional patch clamp results from their different interneuron types. The loose patch clamp method is thus useful for in situ studies of neurons in hippocampal brain slices., (© 2024 The Authors. Annals of the New York Academy of Sciences published by Wiley Periodicals LLC on behalf of The New York Academy of Sciences.)

Published

2024

16. Morpho-electric diversity of human hippocampal CA1 pyramidal neurons.

Author

Mertens EJ, Leibner Y, Pie J, Galakhova AA, Waleboer F, Meijer J, Heistek TS, Wilbers R, Heyer D, Goriounova NA, Idema S, Verhoog MB, Kalmbach BE, Lee BR, Gwinn RP, Lein ES, Aronica E, Ting J, Mansvelder HD, Segev I, and de Kock CPJ

Subjects

Humans, Animals, Male, Mice, Female, Middle Aged, Aged, Theta Rhythm physiology, Adult, Pyramidal Cells physiology, CA1 Region, Hippocampal cytology, CA1 Region, Hippocampal physiology, Dendrites physiology

Abstract

Hippocampal pyramidal neuron activity underlies episodic memory and spatial navigation. Although extensively studied in rodents, extremely little is known about human hippocampal pyramidal neurons, even though the human hippocampus underwent strong evolutionary reorganization and shows lower theta rhythm frequencies. To test whether biophysical properties of human Cornu Amonis subfield 1 (CA1) pyramidal neurons can explain observed rhythms, we map the morpho-electric properties of individual CA1 pyramidal neurons in human, non-pathological hippocampal slices from neurosurgery. Human CA1 pyramidal neurons have much larger dendritic trees than mouse CA1 pyramidal neurons, have a large number of oblique dendrites, and resonate at 2.9 Hz, optimally tuned to human theta frequencies. Morphological and biophysical properties suggest cellular diversity along a multidimensional gradient rather than discrete clustering. Across the population, dendritic architecture and a large number of oblique dendrites consistently boost memory capacity in human CA1 pyramidal neurons by an order of magnitude compared to mouse CA1 pyramidal neurons., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

17. Silencing CA1 pyramidal cells output reveals the role of feedback inhibition in hippocampal oscillations.

Author

Adaikkan C, Joseph J, Foustoukos G, Wang J, Polygalov D, Boehringer R, Middleton SJ, Huang AJY, Tsai LH, and McHugh TJ

Subjects

Mice, Animals, Feedback, Neurons, CA1 Region, Hippocampal physiology, Interneurons physiology, Action Potentials physiology, Hippocampus physiology, Pyramidal Cells physiology

Abstract

The precise temporal coordination of neural activity is crucial for brain function. In the hippocampus, this precision is reflected in the oscillatory rhythms observed in CA1. While it is known that a balance between excitatory and inhibitory activity is necessary to generate and maintain these oscillations, the differential contribution of feedforward and feedback inhibition remains ambiguous. Here we use conditional genetics to chronically silence CA1 pyramidal cell transmission, ablating the ability of these neurons to recruit feedback inhibition in the local circuit, while recording physiological activity in mice. We find that this intervention leads to local pathophysiological events, with ripple amplitude and intrinsic frequency becoming significantly larger and spatially triggered local population spikes locked to the trough of the theta oscillation appearing during movement. These phenotypes demonstrate that feedback inhibition is crucial in maintaining local sparsity of activation and reveal the key role of lateral inhibition in CA1 in shaping circuit function., (© 2024. The Author(s).)

Published

2024

18. Increased Interhemispheric Connectivity of a Distinct Type of Hippocampal Pyramidal Cells.

Author

Stevens NA, Lankisch K, Draguhn A, Engelhardt M, Both M, and Thome C

Subjects

Male, Mice, Animals, Neurons physiology, Dendrites physiology, Action Potentials physiology, Synapses physiology, CA1 Region, Hippocampal physiology, Pyramidal Cells physiology, Hippocampus physiology

Abstract

Neurons typically generate action potentials at their axon initial segment based on the integration of synaptic inputs. In many neurons, the axon extends from the soma, equally weighting dendritic inputs. A notable exception is found in a subset of hippocampal pyramidal cells where the axon emerges from a basal dendrite. This structure allows these axon-carrying dendrites (AcDs) a privileged input route. We found that in male mice, such cells in the CA1 region receive stronger excitatory input from the contralateral CA3, compared with those with somatic axon origins. This is supported by a higher count of putative synapses from contralateral CA3 on the AcD. These findings, combined with prior observations of their distinct role in sharp-wave ripple firing, suggest a key role of this neuron subset in coordinating bi-hemispheric hippocampal activity during memory-centric oscillations., Competing Interests: The authors declare no competing financial interests., (Copyright © 2024 the authors.)

Published

2024

19. Local activation of CA1 pyramidal cells induces theta-phase precession.

Author

Sloin HE, Spivak L, Levi A, Gattegno R, Someck S, and Stark E

Subjects

Animals, Mice, Action Potentials physiology, Models, Neurological, CA1 Region, Hippocampal physiology, Pyramidal Cells physiology, Theta Rhythm physiology

Abstract

Hippocampal theta-phase precession is involved in spatiotemporal coding and in generating multineural spike sequences, but how precession originates remains unresolved. To determine whether precession can be generated directly in hippocampal area CA1 and disambiguate multiple competing mechanisms, we used closed-loop optogenetics to impose artificial place fields in pyramidal cells of mice running on a linear track. More than one-third of the CA1 artificial fields exhibited synthetic precession that persisted for a full theta cycle. By contrast, artificial fields in the parietal cortex did not exhibit synthetic precession. These findings are incompatible with precession models based on inheritance, dual-input, spreading activation, inhibition-excitation summation, or somato-dendritic competition. Thus, a precession generator resides locally within CA1.

Published

2024

20. CA2 orchestrates hippocampal network dynamics.

Author

Oliva A, Fernandez-Ruiz A, and Karaba LA

Subjects

Neurons, Cognition, Social Behavior, CA3 Region, Hippocampal physiology, CA1 Region, Hippocampal physiology, Hippocampus physiology, Pyramidal Cells physiology

Abstract

The hippocampus is composed of various subregions: CA1, CA2, CA3, and the dentate gyrus (DG). Despite the abundant hippocampal research literature, until recently, CA2 received little attention. The development of new genetic and physiological tools allowed recent studies characterizing the unique properties and functional roles of this hippocampal subregion. Despite its small size, the cellular content of CA2 is heterogeneous at the molecular and physiological levels. CA2 has been heavily implicated in social behaviors, including social memory. More generally, the mechanisms by which the hippocampus is involved in memory include the reactivation of neuronal ensembles following experience. This process is coordinated by synchronous network events known as sharp-wave ripples (SWRs). Recent evidence suggests that CA2 plays an important role in the generation of SWRs. The unique connectivity and physiological properties of CA2 pyramidal cells make this region a computational hub at the core of hippocampal information processing. Here, we review recent findings that support the role of CA2 in coordinating hippocampal network dynamics from a systems neuroscience perspective., (© 2022 Wiley Periodicals LLC.)

Published

2023

21. Neurogliaform cells dynamically decouple neuronal synchrony between brain areas.

Author

Sakalar E, Klausberger T, and Lasztóczi B

Subjects

Action Potentials physiology, Animals, GABAergic Neurons physiology, Mice, Nerve Net, CA1 Region, Hippocampal cytology, CA1 Region, Hippocampal physiology, Cerebral Cortex cytology, Cerebral Cortex physiology, Interneurons physiology, Neural Inhibition, Neuroglia physiology, Pyramidal Cells physiology, gamma-Aminobutyric Acid physiology

Abstract

Effective communication across brain areas requires distributed neuronal networks to dynamically synchronize or decouple their ongoing activity. GABA ergic interneurons lock ensembles to network oscillations, but there remain questions regarding how synchrony is actively disengaged to allow for new communication partners. We recorded the activity of identified interneurons in the CA1 hippocampus of awake mice. Neurogliaform cells (NGFCs)-which provide GABA ergic inhibition to distal dendrites of pyramidal cells-strongly coupled their firing to those gamma oscillations synchronizing local networks with cortical inputs. Rather than strengthening such synchrony, action potentials of NGFCs decoupled pyramidal cell activity from cortical gamma oscillations but did not reduce their firing nor affect local oscillations. Thus, NGFCs regulate information transfer by temporarily disengaging the synchrony without decreasing the activity of communicating networks.

Published

2022

22. Probing subthreshold dynamics of hippocampal neurons by pulsed optogenetics.

Author

Valero M, Zutshi I, Yoon E, and Buzsáki G

Subjects

Action Potentials, Animals, CA1 Region, Hippocampal cytology, Light, Male, Mice, Neural Inhibition, Optogenetics, Spatial Behavior, Theta Rhythm, CA1 Region, Hippocampal physiology, Place Cells physiology, Pyramidal Cells physiology

Abstract

Understanding how excitatory (E) and inhibitory (I) inputs are integrated by neurons requires monitoring their subthreshold behavior. We probed the subthreshold dynamics using optogenetic depolarizing pulses in hippocampal neuronal assemblies in freely moving mice. Excitability decreased during sharp-wave ripples coupled with increased I. In contrast to this "negative gain," optogenetic probing showed increased within-field excitability in place cells by weakening I and unmasked stable place fields in initially non-place cells. Neuronal assemblies active during sharp-wave ripples in the home cage predicted spatial overlap and sequences of place fields of both place cells and unmasked preexisting place fields of non-place cells during track running. Thus, indirect probing of subthreshold dynamics in neuronal populations permits the disclosing of preexisting assemblies and modes of neuronal operations.

Published

2022

23. Juxtacellular opto-tagging of hippocampal CA1 neurons in freely moving mice.

Author

Ding L, Balsamo G, Chen H, Blanco-Hernandez E, Zouridis IS, Naumann R, Preston-Ferrer P, and Burgalossi A

Subjects

Action Potentials physiology, Animals, CA1 Region, Hippocampal chemistry, Calbindins genetics, Channelrhodopsins metabolism, Male, Mice, Mice, Inbred C57BL, Optogenetics methods, Pyramidal Cells chemistry, CA1 Region, Hippocampal physiology, Hippocampus metabolism, Movement physiology, Neurons physiology, Pyramidal Cells physiology

Abstract

Neural circuits are made of a vast diversity of neuronal cell types. While immense progress has been made in classifying neurons based on morphological, molecular, and functional properties, understanding how this heterogeneity contributes to brain function during natural behavior has remained largely unresolved. In the present study, we combined the juxtacellular recording and labeling technique with optogenetics in freely moving mice. This allowed us to selectively target molecularly defined cell classes for in vivo single-cell recordings and morphological analysis. We validated this strategy in the CA1 region of the mouse hippocampus by restricting Channelrhodopsin expression to Calbindin-positive neurons. Directly versus indirectly light-activated neurons could be readily distinguished based on the latencies of light-evoked spikes, with juxtacellular labeling and post hoc histological analysis providing 'ground-truth' validation. Using these opto-juxtacellular procedures in freely moving mice, we found that Calbindin-positive CA1 pyramidal cells were weakly spatially modulated and conveyed less spatial information than Calbindin-negative neurons - pointing to pyramidal cell identity as a key determinant for neuronal recruitment into the hippocampal spatial map. Thus, our method complements current in vivo techniques by enabling optogenetic-assisted structure-function analysis of single neurons recorded during natural, unrestrained behavior., Competing Interests: LD, GB, HC, EB, IZ, RN, PP, AB No competing interests declared, (© 2022, Ding et al.)

Published

2022

24. CPP impairs contextual learning at concentrations below those that block pyramidal neuron NMDARs and LTP in the CA1 region of the hippocampus.

Author

Laha K, Zhu M, Gemperline E, Rau V, Li L, Fanselow MS, Lennertz R, and Pearce RA

Subjects

Animals, Dose-Response Relationship, Drug, Excitatory Postsynaptic Potentials drug effects, Female, In Vitro Techniques, Male, Mice, Inbred C57BL, Mice, CA1 Region, Hippocampal physiology, Learning drug effects, Long-Term Potentiation drug effects, Memory drug effects, Pyramidal Cells drug effects, Receptors, N-Methyl-D-Aspartate antagonists & inhibitors

Abstract

Drugs that block N-methyl-d-aspartate receptors (NMDARs) suppress hippocampus-dependent memory formation; they also block long-term potentiation (LTP), a cellular model of learning and memory. However, the fractional block that is required to achieve these effects is unknown. Here, we measured the dose-dependent suppression of contextual memory in vivo by systemic administration of the competitive antagonist (R,S)-3-(2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid (CPP); in parallel, we measured the concentration-dependent block by CPP of NMDAR-mediated synapses and LTP of excitatory synapses in hippocampal brain slices in vitro. We found that the dose of CPP that suppresses contextual memory in vivo (EC50 = 2.3 mg/kg) corresponds to a free concentration of 53 nM. Surprisingly, applying this concentration of CPP to hippocampal brain slices had no effect on the NMDAR component of evoked field excitatory postsynaptic potentials (fEPSP NMDA ), or on LTP. Rather, the IC50 for blocking the fEPSP NMDA was 434 nM, and for blocking LTP was 361 nM - both nearly an order of magnitude higher. We conclude that memory impairment produced by systemically administered CPP is not due primarily to its blockade of NMDARs on hippocampal pyramidal neurons. Rather, systemic CPP suppresses memory formation by actions elsewhere in the memory-encoding circuitry., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2022

25. Suppression of ventral hippocampal CA1 pyramidal neuronal activities enhances water intake.

Author

Han B, Cui S, Liu FY, Wan Y, Shi Y, and Yi M

Subjects

Action Potentials drug effects, Animals, CA1 Region, Hippocampal drug effects, Drinking drug effects, Male, Pyramidal Cells drug effects, Rats, Rats, Wistar, Action Potentials physiology, CA1 Region, Hippocampal physiology, Drinking physiology, Pyramidal Cells physiology, Saline Solution, Hypertonic administration & dosage

Abstract

Thirst is an important interoceptive response and drives water consumption. The hippocampus actively modulates food intake and energy metabolism, but direct evidence for the exact role of the hippocampus in modulating drinking behaviors is lacking. We observed decreased number of c-Fos-positive neurons in the ventral hippocampal CA1 (vCA1) after water restriction or hypertonic saline injection in rats. Suppressed vCA1 neuronal activities under the hypertonic state were further confirmed with in vivo electrophysiological recording, and the level of suppression paralleled both the duration and the total amount of water consumption. Chemogenetic inhibition of vCA1 pyramidal neurons increased water consumption in rats injected with both normal and hypertonic saline. These findings suggest that suppression of vCA1 pyramidal neuronal activities enhances water intake.

Published

2021

26. CA1 pyramidal cell diversity is rooted in the time of neurogenesis.

Author

Cavalieri D, Angelova A, Islah A, Lopez C, Bocchio M, Bollmann Y, Baude A, and Cossart R

Subjects

Animals, Female, Male, Mice, CA1 Region, Hippocampal physiology, Neurogenesis, Pyramidal Cells physiology

Abstract

Cellular diversity supports the computational capacity and flexibility of cortical circuits. Accordingly, principal neurons at the CA1 output node of the murine hippocampus are increasingly recognized as a heterogeneous population. Their genes, molecular content, intrinsic morpho-physiology, connectivity, and function seem to segregate along the main anatomical axes of the hippocampus. Since these axes reflect the temporal order of principal cell neurogenesis, we directly examined the relationship between birthdate and CA1 pyramidal neuron diversity, focusing on the ventral hippocampus. We used a genetic fate-mapping approach that allowed tagging three groups of age-matched principal neurons: pioneer, early-, and late-born. Using a combination of neuroanatomy, slice physiology, connectivity tracing, and cFos staining in mice, we show that birthdate is a strong predictor of CA1 principal cell diversity. We unravel a subpopulation of pioneer neurons recruited in familiar environments with remarkable positioning, morpho-physiological features, and connectivity. Therefore, despite the expected plasticity of hippocampal circuits, given their role in learning and memory, the diversity of their main components is also partly determined at the earliest steps of development., Competing Interests: DC, AA, AI, CL, MB, YB, AB, RC No competing interests declared, (© 2021, Cavalieri et al.)

Published

2021

27. Astrocyte GluN2C NMDA receptors control basal synaptic strengths of hippocampal CA1 pyramidal neurons in the stratum radiatum .

Author

Chipman PH, Fung CCA, Pazo Fernandez A, Sawant A, Tedoldi A, Kawai A, Ghimire Gautam S, Kurosawa M, Abe M, Sakimura K, Fukai T, and Goda Y

Subjects

Animals, Mice, Receptors, N-Methyl-D-Aspartate metabolism, CA1 Region, Hippocampal physiology, Neuronal Plasticity physiology, Pyramidal Cells physiology, Receptors, N-Methyl-D-Aspartate genetics

Abstract

Experience-dependent plasticity is a key feature of brain synapses for which neuronal N-Methyl-D-Aspartate receptors (NMDARs) play a major role, from developmental circuit refinement to learning and memory. Astrocytes also express NMDARs, although their exact function has remained controversial. Here, we identify in mouse hippocampus, a circuit function for GluN2C NMDAR, a subtype highly expressed in astrocytes, in layer-specific tuning of synaptic strengths in CA1 pyramidal neurons. Interfering with astrocyte NMDAR or GluN2C NMDAR activity reduces the range of presynaptic strength distribution specifically in the stratum radiatum inputs without an appreciable change in the mean presynaptic strength. Mathematical modeling shows that narrowing of the width of presynaptic release probability distribution compromises the expression of long-term synaptic plasticity. Our findings suggest a novel feedback signaling system that uses astrocyte GluN2C NMDARs to adjust basal synaptic weight distribution of Schaffer collateral inputs, which in turn impacts computations performed by the CA1 pyramidal neuron., Competing Interests: PC, CF, AP, AS, AT, AK, SG, MK, MA, KS, TF No competing interests declared, YG Reviewing editor, eLife, (© 2021, Chipman et al.)

Published

2021

28. Deciphering how interneuron specific 3 cells control oriens lacunosum-moleculare cells to contribute to circuit function.

Author

Guet-McCreight A and Skinner FK

Subjects

Animals, Computer Simulation, CA1 Region, Hippocampal physiology, Interneurons physiology, Models, Biological, Nerve Net physiology, Pyramidal Cells physiology, Theta Rhythm physiology

Abstract

The wide diversity of inhibitory cells across the brain makes them suitable to contribute to network dynamics in specialized fashions. However, the contributions of a particular inhibitory cell type in a behaving animal are challenging to untangle as one needs to both record cellular activities and identify the cell type being recorded. Thus, using computational modeling and theory to predict and hypothesize cell-specific contributions is desirable. Here, we examine potential contributions of interneuron-specific 3 (I-S3) cells-an inhibitory interneuron found in CA1 hippocampus that only targets other inhibitory interneurons-during simulated θ rhythms. We use previously developed multicompartment models of oriens lacunosum-moleculare (OLM) cells, the main target of I-S3 cells, and explore how I-S3 cell inputs during in vitro and in vivo scenarios contribute to θ. We find that I-S3 cells suppress OLM cell spiking, rather than engender its spiking via postinhibitory rebound mechanisms, and contribute to θ frequency spike resonance during simulated in vivo scenarios. To elicit recruitment similar to in vitro experiments, inclusion of disinhibited pyramidal cell inputs is necessary, implying that I-S3 cell firing broadens the window for pyramidal cell disinhibition. Using in vivo virtual networks, we show that I-S3 cells contribute to a sharpening of OLM cell recruitment at θ frequencies. Furthermore, shifting the timing of I-S3 cell spiking due to external modulation shifts the timing of the OLM cell firing and thus disinhibitory windows. We propose a specialized contribution of I-S3 cells to create temporally precise coordination of modulation pathways. NEW & NOTEWORTHY How information is processed across different brain structures is an important question that relates to the different functions that the brain performs. Using modeling and theoretical analyses, we show that an inhibitory cell type that only inhibits other inhibitory cells can broaden the window for disinhibition of excitatory cells, manage input pathway switching, and modulate inhibitory cell spiking. This work contributes to the knowledge of how coordination between sensory and memory consolidation information can be attained.

Published

2021

29. Frequency-Dependent Synaptic Dynamics Differentially Tune CA1 and CA2 Pyramidal Neuron Responses to Cortical Input.

Author

Sun Q, Buss EW, Jiang YQ, Santoro B, Brann DH, Nicholson DA, and Siegelbaum SA

Subjects

Animals, CA1 Region, Hippocampal drug effects, CA2 Region, Hippocampal drug effects, Cerebral Cortex drug effects, Excitatory Postsynaptic Potentials drug effects, Female, GABA-A Receptor Antagonists pharmacology, GABA-B Receptor Antagonists pharmacology, Male, Mice, Neural Pathways drug effects, Neural Pathways physiology, Patch-Clamp Techniques, Pyramidal Cells drug effects, Synapses drug effects, CA1 Region, Hippocampal physiology, CA2 Region, Hippocampal physiology, Cerebral Cortex physiology, Excitatory Postsynaptic Potentials physiology, Pyramidal Cells physiology, Synapses physiology

Abstract

Entorhinal cortex neurons make monosynaptic connections onto distal apical dendrites of CA1 and CA2 pyramidal neurons through the perforant path (PP) projection. Previous studies show that differences in dendritic properties and synaptic input density enable the PP inputs to produce a much stronger excitation of CA2 compared with CA1 pyramidal neurons. Here, using mice of both sexes, we report that the difference in PP efficacy varies substantially as a function of presynaptic firing rate. Although a single PP stimulus evokes a 5- to 6-fold greater EPSP in CA2 compared with CA1, a brief high-frequency train of PP stimuli evokes a strongly facilitating postsynaptic response in CA1, with relatively little change in CA2. Furthermore, we demonstrate that blockade of NMDARs significantly reduces strong temporal summation in CA1 but has little impact on that in CA2. As a result of the differences in the frequency- and NMDAR-dependent temporal summation, naturalistic patterns of presynaptic activity evoke CA1 and CA2 responses with distinct dynamics, differentially tuning CA1 and CA2 responses to bursts of presynaptic firing versus single presynaptic spikes, respectively. SIGNIFICANCE STATEMENT Recent studies have demonstrated that abundant entorhinal cortical innervation and efficient dendritic propagation enable hippocampal CA2 pyramidal neurons to produce robust excitation evoked by single cortical stimuli, compared with CA1. Here we uncovered, unexpectedly, that the difference in efficacy of cortical excitation varies substantially as a function of presynaptic firing rate. A burst of stimuli evokes a strongly facilitating response in CA1, but not in CA2. As a result, the postsynaptic response of CA1 and CA2 to presynaptic naturalistic firing displays contrasting temporal dynamics, which depends on the activation of NMDARs. Thus, whereas CA2 responds to single stimuli, CA1 is selectively recruited by bursts of cortical input., (Copyright © 2021 the authors.)

Published

2021

30. Multiscale representation of very large environments in the hippocampus of flying bats.

Author

Eliav T, Maimon SR, Aljadeff J, Tsodyks M, Ginosar G, Las L, and Ulanovsky N

Subjects

Animals, CA3 Region, Hippocampal physiology, Entorhinal Cortex physiology, Nerve Net physiology, Neural Networks, Computer, Neurons physiology, CA1 Region, Hippocampal physiology, Chiroptera physiology, Flight, Animal, Place Cells physiology, Pyramidal Cells physiology, Spatial Navigation

Abstract

Hippocampal place cells encode the animal's location. Place cells were traditionally studied in small environments, and nothing is known about large ethologically relevant spatial scales. We wirelessly recorded from hippocampal dorsal CA1 neurons of wild-born bats flying in a long tunnel (200 meters). The size of place fields ranged from 0.6 to 32 meters. Individual place cells exhibited multiple fields and a multiscale representation: Place fields of the same neuron differed up to 20-fold in size. This multiscale coding was observed from the first day of exposure to the environment, and also in laboratory-born bats that never experienced large environments. Theoretical decoding analysis showed that the multiscale code allows representation of very large environments with much higher precision than that of other codes. Together, by increasing the spatial scale, we discovered a neural code that is radically different from classical place codes., (Copyright © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2021

31. Repeated victorious and defeat experiences induce similar apical dendritic spine remodeling in CA1 hippocampus of rats.

Author

Patel D, Anilkumar S, Chattarji S, de Boer SF, and Buwalda B

Subjects

Animals, Basolateral Nuclear Complex cytology, Basolateral Nuclear Complex pathology, Basolateral Nuclear Complex physiology, Male, Prefrontal Cortex cytology, Prefrontal Cortex pathology, Prefrontal Cortex physiology, Rats, Behavior, Animal physiology, CA1 Region, Hippocampal cytology, CA1 Region, Hippocampal pathology, CA1 Region, Hippocampal physiology, Competitive Behavior, Dendritic Spines pathology, Dendritic Spines physiology, Neuronal Plasticity physiology, Pyramidal Cells pathology, Pyramidal Cells physiology, Social Dominance

Abstract

In this study, apical dendritic spine density of neurons in hippocampal, amygdalar and prefrontal cortical areas was compared in rats that were repeatedly winning or losing social conflicts. Territorial male wild-type Groningen (WTG) rats were allowed multiple daily attacks (>20 times) on intruder males in the resident-intruder paradigm. Frequent winning experiences are known to facilitate uncontrolled aggressive behavior reflected in aggressive attacks on anesthetized males which was also observed in the winners in this study. Both winners and losers were socially housed during the experiments; winners with females to stimulate territorial behavior, and losers with two other losing male rats. Twenty-four hours after the last social encounter, brains from experienced residential winners and repeatedly defeated intruder rats were collected and neuronal morphology in selected brain regions was studied via Golgi-Cox staining. Results indicate that spine density in the apical dendrites of the hippocampal CA1 reduced similarly in both winners and losers. In addition, winners showed increased spine densities at the proximal segments (20-30 μm) of the basolateral amygdala neurons and losers tended to show a decreased spine density at the more proximal segments of the infralimbic region of prefrontal cortex neurons. No effect of winning and losing was observed in the medial amygdala. The atrophic effect of repeated defeats in hippocampal and prefrontal regions was anticipated despite the fact that social housing of the repeatedly losing intruder males may have played a protective role. The reduction of hippocampal spine density in the winners seems surprising but supports previous findings in hierarchical dominant males in rat colonies. The dominants showed even greater shrinkage of the apical dendritic arbors of hippocampal CA3 pyramidal neurons compared to the stressed subordinates., (Copyright © 2021 The Author(s). Published by Elsevier B.V. All rights reserved.)

Published

2021

32. Sodium sensitivity of K Na channels in mouse CA1 neurons.

Author

Gray R and Johnston D

Subjects

Animals, CA1 Region, Hippocampal drug effects, CA1 Region, Hippocampal metabolism, Cardiotonic Agents pharmacology, Male, Mice, Nerve Tissue Proteins physiology, Ouabain pharmacology, Patch-Clamp Techniques, Potassium Channels, Sodium-Activated drug effects, Potassium Channels, Sodium-Activated metabolism, Pyramidal Cells drug effects, Pyramidal Cells metabolism, CA1 Region, Hippocampal physiology, Potassium Channels, Sodium-Activated physiology, Pyramidal Cells physiology, Sodium metabolism

Abstract

Potassium channels play an important role regulating transmembrane electrical activity in essentially all cell types. We were especially interested in those that determine the intrinsic electrical properties of mammalian central neurons. Over 30 different potassium channels have been molecularly identified in brain neurons, but there often is not a clear distinction between molecular structure and the function of a particular channel in the cell. Using patch-clamp methods to search for single potassium channels in excised inside-out (ISO) somatic patches with symmetrical potassium, we found that nearly all patches contained non-voltage-inactivating channels with a single-channel conductance of 100-200 pS. This conductance range is consistent with the family of sodium-activated potassium channels (Slo2.1, Slo2.2, or collectively, K Na ). The activity of these channels was positively correlated with a low cytoplasmic Na + concentration (2-20 mM). Cell-attached recordings from intact neurons, however, showed little or no activity of this K + channel. Attempts to increase channel activity by increasing intracellular sodium concentration ([Na + ] i ) with bursts of action potentials or direct perfusion of Na + through a whole cell pipette had little effect on K Na channel activity. Furthermore, excised outside-out (OSO) patches across a range of intracellular [Na + ] showed less channel activity than we had seen with excised ISO patches. Blocking the Na + /K + pump with ouabain increased the activity of the K Na channels in excised OSO patches to levels comparable with ISO-excised patches. Our results suggest that despite their apparent high levels of expression, the activity of somatic K Na channels is tightly regulated by the activity of the Na + /K + pump. NEW & NOTEWORTHY We studied K Na channels in mouse hippocampal CA1 neurons. Excised inside-out patches showed the channels to be prevalent and active in most patches in the presence of Na + . Cell-attached recordings from intact neurons, however, showed little channel activity. Increasing cytoplasmic sodium in intact cells showed a small effect on channel activity compared with that seen in inside-out excised patches. Blockade of the Na + /K + pump with ouabain, however, restored the activity of the channels to that seen in inside-out patches.

Published

2021

33. Postsynaptic cell firing triggers bidirectional metaplasticity depending on the LTP induction protocol.

Author

Hegemann RU and Abraham WC

Subjects

Animals, Electric Stimulation, Male, Patch-Clamp Techniques, Rats, Rats, Sprague-Dawley, Transcranial Magnetic Stimulation, Action Potentials physiology, CA1 Region, Hippocampal physiology, Long-Term Potentiation physiology, Pyramidal Cells physiology

Abstract

Cell firing has been reported to variably upregulate or downregulate subsequently induced long-term potentiation (LTP). The aim of this study was to elucidate the parameters critical to driving each direction of the metaplasticity effect. The main focus was on the commonly used θ-burst stimulation (TBS) and high-frequency stimulation (HFS) protocols that are known to trigger distinct intracellular signaling cascades. To study action potential (AP)-induced metaplasticity, we used intracellular recordings from CA1 pyramidal cells of rat hippocampal slices. Somatic current injections were used to induce θ-burst firing (TBF) or high-frequency firing (HFF) for priming purposes, whereas LTP was induced 15   min later via TBS of Schaffer collaterals in stratum radiatum. TBS-LTP was inhibited by both priming protocols. Conversely, HFS-LTP was facilitated by HFF priming but not affected by TBF priming. Interestingly, both priming protocols reduced AP firing during TBS-LTP induction, and this effect correlated with the reduction of TBS-LTP. However, LTP was not rescued by restoring AP firing with somatic current injections during the TBS. Analysis of intrinsic properties revealed few changes, apart from a priming-induced increase in the medium afterhyperpolarization (HFF priming) and a decrease in the EPSP amplitude/slope ratio (TBF priming), which could in principle contribute to the inhibition of TBS-LTP by reducing depolarization and associated Ca 2+ influx following synaptic activity or AP backpropagation. Overall, these data indicate that the more physiological TBS protocol for inducing LTP is particularly susceptible to homeostatic feedback inhibition by prior bouts of postsynaptic cell firing. NEW & NOTEWORTHY The induction of LTP in the hippocampus was bidirectionally regulated by prior postsynaptic cell firing, with θ-burst stimulation-induced LTP being consistently impaired by prior spiking, whereas high-frequency stimulation-induced LTP was either not changed or facilitated. Reductions in cell firing during LTP induction did not explain the LTP impairment. Overall, different patterns of postsynaptic firing induce distinct intracellular changes that can increase or decrease LTP depending on the induction protocol.

Published

2021

34. The Entorhinal Cortical Alvear Pathway Differentially Excites Pyramidal Cells and Interneuron Subtypes in Hippocampal CA1.

Author

Bell KA, Delong R, Goswamee P, and McQuiston AR

Subjects

Animals, CA1 Region, Hippocampal cytology, CA1 Region, Hippocampal metabolism, Entorhinal Cortex cytology, Entorhinal Cortex metabolism, Excitatory Postsynaptic Potentials physiology, Hippocampus cytology, Hippocampus metabolism, Hippocampus physiology, Interneurons metabolism, Mice, Neural Pathways, Optogenetics, Parvalbumins metabolism, Patch-Clamp Techniques, Pyramidal Cells metabolism, Vasoactive Intestinal Peptide metabolism, CA1 Region, Hippocampal physiology, Entorhinal Cortex physiology, Interneurons physiology, Pyramidal Cells physiology

Abstract

The entorhinal cortex alvear pathway is a major excitatory input to hippocampal CA1, yet nothing is known about its physiological impact. We investigated the alvear pathway projection and innervation of neurons in CA1 using optogenetics and whole cell patch clamp methods in transgenic mouse brain slices. Using this approach, we show that the medial entorhinal cortical alvear inputs onto CA1 pyramidal cells (PCs) and interneurons with cell bodies located in stratum oriens were monosynaptic, had low release probability, and were mediated by glutamate receptors. Optogenetic theta burst stimulation was unable to elicit suprathreshold activation of CA1 PCs but was capable of activating CA1 interneurons. However, different subtypes of interneurons were not equally affected. Higher burst action potential frequencies were observed in parvalbumin-expressing interneurons relative to vasoactive-intestinal peptide-expressing or a subset of oriens lacunosum-moleculare (O-LM) interneurons. Furthermore, alvear excitatory synaptic responses were observed in greater than 70% of PV and VIP interneurons and less than 20% of O-LM cells. Finally, greater than 50% of theta burst-driven inhibitory postsynaptic current amplitudes in CA1 PCs were inhibited by optogenetic suppression of PV interneurons. Therefore, our data suggest that the alvear pathway primarily affects hippocampal CA1 function through feedforward inhibition of select interneuron subtypes., (© The Author(s) 2020. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permission@oup.com.)

Published

2021

35. Alternating sources of perisomatic inhibition during behavior.

Author

Dudok B, Klein PM, Hwaun E, Lee BR, Yao Z, Fong O, Bowler JC, Terada S, Sparks FT, Szabo GG, Farrell JS, Berg J, Daigle TL, Tasic B, Dimidschstein J, Fishell G, Losonczy A, Zeng H, and Soltesz I

Subjects

Animals, Cholecystokinin metabolism, Female, Male, Mice, Inbred C57BL, Mice, Transgenic, Parvalbumins metabolism, Mice, CA1 Region, Hippocampal physiology, Interneurons physiology, Pyramidal Cells physiology, Synaptic Transmission physiology

Abstract

Interneurons expressing cholecystokinin (CCK) and parvalbumin (PV) constitute two key GABAergic controllers of hippocampal pyramidal cell output. Although the temporally precise and millisecond-scale inhibitory regulation of neuronal ensembles delivered by PV interneurons is well established, the in vivo recruitment patterns of CCK-expressing basket cell (BC) populations has remained unknown. We show in the CA1 of the mouse hippocampus that the activity of CCK BCs inversely scales with both PV and pyramidal cell activity at the behaviorally relevant timescales of seconds. Intervention experiments indicated that the inverse coupling of CCK and PV GABAergic systems arises through a mechanism involving powerful inhibitory control of CCK BCs by PV cells. The tightly coupled complementarity of two key microcircuit regulatory modules demonstrates a novel form of brain-state-specific segregation of inhibition during spontaneous behavior., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

36. Different effects of monophasic pulses and biphasic pulses applied by a bipolar stimulation electrode in the rat hippocampal CA1 region.

Author

Yuan Y, Zheng L, Feng Z, and Yang G

Subjects

Animals, Artifacts, Axons, Deep Brain Stimulation, Male, Rats, Rats, Sprague-Dawley, Action Potentials, CA1 Region, Hippocampal physiology, Electric Stimulation, Electrodes, Pyramidal Cells physiology

Abstract

Background: Electrical pulse stimulations have been applied in brain for treating certain diseases such as movement disorders. High-frequency stimulations (HFS) of biphasic pulses have been used in clinic stimulations, such as deep brain stimulation (DBS), to minimize the risk of tissue damages caused by the electrical stimulations. However, HFS sequences of monophasic pulses have often been used in animal experiments for studying neuronal responses to the stimulations. It is not clear yet what the differences of the neuronal responses to the HFS of monophasic pulses from the HFS of biphasic pulses are., Methods: To investigate the neuronal responses to the two types of pulses, orthodromic-HFS (O-HFS) and antidromic-HFS (A-HFS) of biphasic and monophasic pulses (1-min) were delivered by bipolar electrodes, respectively, to the Schaffer collaterals (i.e., afferent fibers) and the alveus fibers (i.e., efferent fibers) of the rat hippocampal CA1 region in vivo. Evoked population spikes of CA1 pyramidal neurons to the HFSs were recorded in the CA1 region. In addition, single pulses of antidromic- and orthodromic-test stimuli were applied before and after HFSs to evaluate the baseline and the recovery of neuronal activity, respectively., Results: Spreading depression (SD) appeared during sequences of 200-Hz monophasic O-HFS with a high incidence (4/5), but did not appear during corresponding 200-Hz biphasic O-HFS (0/6). A preceding burst of population spikes appeared before the SD waveforms. Then, the SD propagated slowly, silenced neuronal firing temporarily and resulted in partial recovery of orthodromically evoked population spikes (OPS) after the end of O-HFS. No SD events appeared during the O-HFS with a lower frequency of 100 Hz of monophasic or biphasic pulses (0/5 and 0/6, respectively), neither during the A-HFS of 200-Hz pulses (0/9). The antidromically evoked population spikes (APS) after 200-Hz biphasic A-HFS recovered to baseline level within ~ 2 min. However, the APS only recovered partially after the 200-Hz A-HFS of monophasic pulses., Conclusions: The O-HFS with a higher frequency of monophasic pulses can induce the abnormal neuron activity of SD and the A-HFS of monophasic pulses can cause a persisting attenuation of neuronal excitability, indicating neuronal damages caused by monophasic stimulations in brain tissues. The results provide guidance for proper stimulation protocols in clinic and animal experiments.

Published

2021

37. NMDA receptors promote hippocampal sharp-wave ripples and the associated coactivity of CA1 pyramidal cells.

Author

Howe T, Blockeel AJ, Taylor H, Jones MW, Bazhenov M, and Malerba P

Subjects

Animals, CA1 Region, Hippocampal cytology, CA1 Region, Hippocampal drug effects, Electrodes, Implanted, Excitatory Amino Acid Antagonists pharmacology, Pyramidal Cells drug effects, Rats, Receptors, N-Methyl-D-Aspartate antagonists & inhibitors, CA1 Region, Hippocampal physiology, Models, Neurological, Pyramidal Cells physiology, Receptors, N-Methyl-D-Aspartate physiology

Abstract

Hippocampal sharp-wave ripples (SWRs) support the reactivation of memory representations, relaying information to neocortex during "offline" and sleep-dependent memory consolidation. While blockade of NMDA receptors (NMDAR) is known to affect both learning and subsequent consolidation, the specific contributions of NMDAR activation to SWR-associated activity remain unclear. Here, we combine biophysical modeling with in vivo local field potential (LFP) and unit recording to quantify changes in SWR dynamics following inactivation of NMDAR. In a biophysical model of CA3-CA1 SWR activity, we find that NMDAR removal leads to reduced SWR density, but spares SWR properties such as duration, cell recruitment and ripple frequency. These predictions are confirmed by experiments in which NMDAR-mediated transmission in rats was inhibited using three different NMDAR antagonists, while recording dorsal CA1 LFP. In the model, loss of NMDAR-mediated conductances also induced a reduction in the proportion of cell pairs that co-activate significantly above chance across multiple events. Again, this prediction is corroborated by dorsal CA1 single-unit recordings, where the NMDAR blocker ketamine disrupted correlated spiking during SWR. Our results are consistent with a framework in which NMDA receptors both promote activation of SWR events and organize SWR-associated spiking content. This suggests that, while SWR are short-lived events emerging in fast excitatory-inhibitory networks, slower network components including NMDAR-mediated currents contribute to ripple density and promote consistency in the spiking content across ripples, underpinning mechanisms for fine-tuning of memory consolidation processes., (© 2020 Wiley Periodicals LLC.)

Published

2020

38. Hippocampal neurons with stable excitatory connectivity become part of neuronal representations.

Author

Castello-Waldow TP, Weston G, Ulivi AF, Chenani A, Loewenstein Y, Chen A, and Attardo A

Subjects

Animals, CA1 Region, Hippocampal cytology, Conditioning, Psychological, Cytoskeletal Proteins genetics, Cytoskeletal Proteins physiology, Dendritic Spines physiology, Fear physiology, Female, Genes, Immediate-Early, Green Fluorescent Proteins genetics, Male, Mental Recall physiology, Mice, Mice, Transgenic, Models, Neurological, Models, Psychological, Nerve Tissue Proteins genetics, Nerve Tissue Proteins physiology, Neuronal Plasticity physiology, Promoter Regions, Genetic, CA1 Region, Hippocampal physiology, Memory physiology, Pyramidal Cells physiology

Abstract

Experiences are represented in the brain by patterns of neuronal activity. Ensembles of neurons representing experience undergo activity-dependent plasticity and are important for learning and recall. They are thus considered cellular engrams of memory. Yet, the cellular events that bias neurons to become part of a neuronal representation are largely unknown. In rodents, turnover of structural connectivity has been proposed to underlie the turnover of neuronal representations and also to be a cellular mechanism defining the time duration for which memories are stored in the hippocampus. If these hypotheses are true, structural dynamics of connectivity should be involved in the formation of neuronal representations and concurrently important for learning and recall. To tackle these questions, we used deep-brain 2-photon (2P) time-lapse imaging in transgenic mice in which neurons expressing the Immediate Early Gene (IEG) Arc (activity-regulated cytoskeleton-associated protein) could be permanently labeled during a specific time window. This enabled us to investigate the dynamics of excitatory synaptic connectivity-using dendritic spines as proxies-of hippocampal CA1 (cornu ammonis 1) pyramidal neurons (PNs) becoming part of neuronal representations exploiting Arc as an indicator of being part of neuronal representations. We discovered that neurons that will prospectively express Arc have slower turnover of synaptic connectivity, thus suggesting that synaptic stability prior to experience can bias neurons to become part of representations or possibly engrams. We also found a negative correlation between stability of structural synaptic connectivity and the ability to recall features of a hippocampal-dependent memory, which suggests that faster structural turnover in hippocampal CA1 might be functional for memory., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

39. Noradrenaline Release from Locus Coeruleus Terminals in the Hippocampus Enhances Excitation-Spike Coupling in CA1 Pyramidal Neurons Via β-Adrenoceptors.

Author

Bacon TJ, Pickering AE, and Mellor JR

Subjects

Animals, Excitatory Postsynaptic Potentials, Male, Mice, Inbred C57BL, Action Potentials, CA1 Region, Hippocampal physiology, Locus Coeruleus physiology, Norepinephrine physiology, Pyramidal Cells physiology, Receptors, Adrenergic, beta physiology

Abstract

Release of the neuromodulator noradrenaline signals salience during wakefulness, flagging novel or important experiences to reconfigure information processing and memory representations in the hippocampus. Noradrenaline is therefore expected to enhance hippocampal responses to synaptic input; however, noradrenergic agonists have been found to have mixed and sometimes contradictory effects on Schaffer collateral synapses and the resulting CA1 output. Here, we examine the effects of endogenous, optogenetically driven noradrenaline release on synaptic transmission and spike output in mouse hippocampal CA1 pyramidal neurons. We show that endogenous noradrenaline release enhances the probability of CA1 pyramidal neuron spiking without altering feedforward excitatory or inhibitory synaptic inputs in the Schaffer collateral pathway. β-adrenoceptors mediate this enhancement of excitation-spike coupling by reducing the charge required to initiate action potentials, consistent with noradrenergic modulation of voltage-gated potassium channels. Furthermore, we find the likely effective concentration of endogenously released noradrenaline is sub-micromolar. Surprisingly, although comparable concentrations of exogenous noradrenaline cause robust depression of slow afterhyperpolarization currents, endogenous release of noradrenaline does not, indicating that endogenous noradrenaline release is targeted to specific cellular locations. These findings provide a mechanism by which targeted endogenous release of noradrenaline can enhance information transfer in the hippocampus in response to salient events., (© The Author(s) 2020. Published by Oxford University Press.)

Published

2020

40. Spike frequency-dependent inhibition and excitation of neural activity by high-frequency ultrasound.

Author

Prieto ML, Firouzi K, Khuri-Yakub BT, Madison DV, and Maduke M

Subjects

Animals, In Vitro Techniques, Patch-Clamp Techniques, Rodentia, Ultrasonics, Action Potentials, CA1 Region, Hippocampal physiology, Membrane Potentials, Pyramidal Cells physiology

Abstract

Ultrasound can modulate action potential firing in vivo and in vitro, but the mechanistic basis of this phenomenon is not well understood. To address this problem, we used patch-clamp recording to quantify the effects of focused, high-frequency (43 MHz) ultrasound on evoked action potential firing in CA1 pyramidal neurons in acute rodent hippocampal brain slices. We find that ultrasound can either inhibit or potentiate firing in a spike frequency-dependent manner: at low (near-threshold) input currents and low firing frequencies, ultrasound inhibits firing, while at higher input currents and higher firing frequencies, ultrasound potentiates firing. The net result of these two competing effects is that ultrasound increases the threshold current for action potential firing, the slope of frequency-input curves, and the maximum firing frequency. In addition, ultrasound slightly hyperpolarizes the resting membrane potential, decreases action potential width, and increases the depth of the after-hyperpolarization. All of these results can be explained by the hypothesis that ultrasound activates a sustained potassium conductance. According to this hypothesis, increased outward potassium currents hyperpolarize the resting membrane potential and inhibit firing at near-threshold input currents but potentiate firing in response to higher-input currents by limiting inactivation of voltage-dependent sodium channels during the action potential. This latter effect is a consequence of faster action potential repolarization, which limits inactivation of voltage-dependent sodium channels, and deeper (more negative) after-hyperpolarization, which increases the rate of recovery from inactivation. Based on these results, we propose that ultrasound activates thermosensitive and mechanosensitive two-pore-domain potassium (K2P) channels through heating or mechanical effects of acoustic radiation force. Finite-element modeling of the effects of ultrasound on brain tissue suggests that the effects of ultrasound on firing frequency are caused by a small (<2°C) increase in temperature, with possible additional contributions from mechanical effects., (© 2020 Prieto et al.)

Published

2020

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

Author

Udakis M, Pedrosa V, Chamberlain SEL, Clopath C, and Mellor JR

Subjects

Action Potentials, Animals, CA1 Region, Hippocampal cytology, CA1 Region, Hippocampal physiology, Calcium Channels, T-Type metabolism, Channelrhodopsins metabolism, Hippocampus cytology, Mice, Optogenetics methods, Parvalbumins metabolism, Patch-Clamp Techniques, Signal Transduction, Somatostatin metabolism, Synapses metabolism, Hippocampus physiology, Interneurons metabolism, Pyramidal Cells physiology

Abstract

The 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.

Published

2020

42. Simulations reveal how M-currents and memory-based inputs from CA3 enable single neuron mismatch detection for EC3 inputs to the CA1 subfield of hippocampus.

Author

Berteau S and Bullock D

Subjects

Animals, Computer Simulation, Humans, CA1 Region, Hippocampal physiology, CA3 Region, Hippocampal physiology, Electrophysiological Phenomena physiology, Entorhinal Cortex physiology, Learning physiology, Models, Biological, Pyramidal Cells physiology

Abstract

Significant evidence has accumulated to support the hypothesis that hippocampal region CA1 operates as an associative mismatch detector (e.g., Hasselmo ME, Schnell E, Barkai E. J Neurosci 15: 5249-5262, 1995; Duncan K, Curtis C, Davachi L. J Neurosci 29: 131-139, 2009; Kumaran D, Maguire EA. J Neurosci 27: 8517-8524, 2007; Lisman JE, Grace AA. Neuron 46: 703-713, 2005; Lisman JE, Otmakhova NA. Hippocampus 11: 551-568 2001; Lörincz A, Buzsáki G. Ann N Y Acad Sci 911: 83-111, 2000; Meeter M, Murre JMJ, Talamini LM. Hippocampus 14: 722-741, 2004; Schiffer AM, Ahlheim C, Wurm MF, Schubotz RI. PLoS One 7: e36445, 2012; Vinogradova OS. Hippocampus 11: 578-598 2001). CA1 compares predictive synaptic signals from CA3 with synaptic signals from EC3, which reflect actual sensory inputs. The new CA1 pyramidal model presented here shows that the distal-proximal segregation of synaptic inputs from EC3 versus CA3, along with other biophysical features, enable such pyramids to serve as comparators that switch output encoding from a brief burst, for a match, to prolonged tonic spiking, for a mismatch. By including often-overlooked features of CA1 pyramidal neurons, this new model allows simulation of pharmacological effects that can eliminate either the match (phasic mode) response or the mismatch (tonic mode) response. These simulations reveal that dysfunctions can arise from either too much or too little ACh stimulation of the muscarinic receptors that control KCNQ channels. Additionally, a dysfunction caused by administration of an N -methyl-d-aspartate antagonist could be rescued by simultaneous administration of a KCNQ channel agonist, such as retigabine. NEW & NOTEWORTHY Hippocampal region CA1 operates as an associative mismatch detector, comparing predictive signals from CA3 with signals from EC3 reflecting sensory inputs. This new CA1 pyramidal model shows that biophysical features enable these comparators to switch output between brief bursts for matches and tonic spiking for mismatches. This suggests that cognitive learning models (e.g., predictive coding) may require much less match/mismatch circuitry than commonly assumed. Additional simulations illuminate deficits seen in psychiatric disorders and drug-induced states.

Published

2020

43. Aging Alters Olfactory Bulb Network Oscillations and Connectivity: Relevance for Aging-Related Neurodegeneration Studies.

Author

Ahnaou A, Rodriguez-Manrique D, Embrechts S, Biermans R, Manyakov NV, Youssef SA, and Drinkenburg WHIM

Subjects

Animals, DNA Damage, Gamma Rhythm, Long-Term Potentiation, Male, Mice, Inbred C57BL, Neural Pathways, Theta Rhythm, Aging physiology, CA1 Region, Hippocampal physiology, Olfactory Bulb physiology, Pyramidal Cells physiology

Abstract

The aging process eventually cause a breakdown in critical synaptic plasticity and connectivity leading to deficits in memory function. The olfactory bulb (OB) and the hippocampus, both regions of the brain considered critical for the processing of odors and spatial memory, are commonly affected by aging. Using an aged wild-type C57B/6 mouse model, we sought to define the effects of aging on hippocampal plasticity and the integrity of cortical circuits. Specifically, we measured the long-term potentiation of high-frequency stimulation (HFS-LTP) at the Shaffer-Collateral CA1 pyramidal synapses. Next, local field potential (LFP) spectra, phase-amplitude theta-gamma coupling (PAC), and connectivity through coherence were assessed in the olfactory bulb, frontal and entorhinal cortices, CA1, and amygdala circuits. The OB of aged mice showed a significant increase in the number of histone H2AX-positive neurons, a marker of DNA damage. While the input-output relationship measure of basal synaptic activity was found not to differ between young and aged mice, a pronounced decline in the slope of field excitatory postsynaptic potential (fEPSP) and the population spike amplitude (PSA) were found in aged mice. Furthermore, aging was accompanied by deficits in gamma network oscillations, a shift to slow oscillations, reduced coherence and theta-gamma PAC in the OB circuit. Thus, while the basal synaptic activity was unaltered in older mice, impairment in hippocampal synaptic transmission was observed only in response to HFS. However, age-dependent alterations in neural network appeared spontaneously in the OB circuit, suggesting the neurophysiological basis of synaptic deficits underlying olfactory processing. Taken together, the results highlight the sensitivity and therefore potential use of LFP quantitative network oscillations and connectivity at the OB level as objective electrophysiological markers that will help reveal specific dysfunctional circuits in aging-related neurodegeneration studies., Competing Interests: None of the authors has any conflict of interest to disclose with respect to the present work., (Copyright © 2020 A. Ahnaou et al.)

Published

2020

44. Most hippocampal CA1 pyramidal cells in rabbits increase firing during awake sharp-wave ripples and some do so in response to external stimulation and theta.

Author

Nokia MS, Waselius T, Sahramäki J, and Penttonen M

Subjects

Animals, Behavior, Animal physiology, Blinking physiology, Electrocorticography, Female, Rabbits, Theta Rhythm physiology, Brain Waves physiology, CA1 Region, Hippocampal physiology, Conditioning, Classical physiology, Pyramidal Cells physiology

Abstract

Hippocampus forms neural representations of real-life events including multimodal information of spatial and temporal context. These representations, i.e., organized sequences of neuronal firing, are repeated during following rest and sleep, especially when so-called sharp-wave ripples (SPW-Rs) characterize hippocampal local field potentials. This SPW-R -related replay is thought to underlie memory consolidation. Here, we set out to explore how hippocampal CA1 pyramidal cells respond to the conditioned stimulus during trace eyeblink conditioning and how these responses manifest during SPW-Rs in awake adult female New Zealand White rabbits. Based on reports in rodents, we expected SPW-Rs to take place in bursts, possibly according to a slow endogenous rhythm. In awake rabbits, half of all SPW-Rs took place in bursts, but no endogenous slow rhythm appeared. Conditioning trials suppressed SPW-Rs while increasing theta for a period of several seconds. As expected based on previous findings, only a quarter of the putative CA1 pyramidal cells increased firing in response to the conditioned stimulus. Compared with other cells, rate-increasing cells were more active during spontaneous epochs of hippocampal theta while response profile during conditioning did not affect firing during SPW-Rs. Taken together, CA1 pyramidal cell firing during SPW-Rs is not limited to cells that fired during the preceding experience. Furthermore, the importance of possible reactivations taking place during theta epochs on memory consolidation warrants further investigation. NEW & NOTEWORTHY We studied hippocampal sharp-wave ripples and theta and CA1 pyramidal cell activity during trace eyeblink conditioning in rabbits. Conditioning trials suppressed ripples while increasing theta for a period of several seconds. A quarter of the cells increased firing in response to the conditioned stimulus and fired extensively during endogenous theta as well as ripples. The role of endogenous theta epochs in off-line memory consolidation should be studied further.

Published

2020

45. Conjunctive reward-place coding properties of dorsal distal CA1 hippocampus cells.

Author

Xiao Z, Lin K, and Fellous JM

Subjects

Action Potentials physiology, Animals, Computer Simulation, Goals, Male, Maze Learning physiology, Motivation physiology, Rats, Rats, Inbred BN, Spatial Navigation physiology, CA1 Region, Hippocampal physiology, Pyramidal Cells physiology, Reward

Abstract

Autonomous motivated spatial navigation in animals or robots requires the association between spatial location and value. Hippocampal place cells are involved in goal-directed spatial navigation and the consolidation of spatial memories. Recently, Gauthier and Tank (Neuron 99(1):179-193, 2018. https://doi.org/10.1016/j.neuron.2018.06.008) have identified a subpopulation of hippocampal cells selectively activated in relation to rewarded goals. However, the relationship between these cells' spiking activity and goal representation remains elusive. We analyzed data from experiments in which rats underwent five consecutive tasks in which reward locations and spatial context were manipulated. We found CA1 populations with properties continuously ranging from place cells to reward cells. Specifically, we found typical place cells insensitive to reward locations, reward cells that only fired at correct rewarded feeders in each task regardless of context, and "hybrid cells" that responded to spatial locations and change of reward locations. Reward cells responded mostly to the reward delivery rather than to its expectation. In addition, we found a small group of neurons that transitioned between place and reward cells properties within the 5-task session. We conclude that some pyramidal cells (if not all) integrate both spatial and reward inputs to various degrees. These results provide insights into the integrative coding properties of CA1 pyramidal cells, focusing on their abilities to carry both spatial and reward information in a mixed and plastic manner. This conjunctive coding property prompts a re-thinking of current computational models of spatial navigation in which hippocampal spatial and subcortical value representations are independent.

Published

2020

46. Synaptic Plasticity Depends on the Fine-Scale Input Pattern in Thin Dendrites of CA1 Pyramidal Neurons.

Author

Magó Á, Weber JP, Ujfalussy BB, and Makara JK

Subjects

Animals, Male, Patch-Clamp Techniques, Rats, Rats, Wistar, Synapses physiology, Action Potentials physiology, CA1 Region, Hippocampal physiology, Dendrites physiology, Neuronal Plasticity physiology, Pyramidal Cells physiology

Abstract

Coordinated long-term plasticity of nearby excitatory synaptic inputs has been proposed to shape experience-related neuronal information processing. To elucidate the induction rules leading to spatially structured forms of synaptic potentiation in dendrites, we explored plasticity of glutamate uncaging-evoked excitatory input patterns with various spatial distributions in perisomatic dendrites of CA1 pyramidal neurons in slices from adult male rats. We show that (1) the cooperativity rules governing the induction of synaptic LTP depend on dendritic location; (2) LTP of input patterns that are subthreshold or suprathreshold to evoke local dendritic spikes (d-spikes) requires different spatial organization; and (3) input patterns evoking d-spikes can strengthen nearby, nonsynchronous synapses by local heterosynaptic plasticity crosstalk mediated by NMDAR-dependent MEK/ERK signaling. These results suggest that multiple mechanisms can trigger spatially organized synaptic plasticity on various spatial and temporal scales, enriching the ability of neurons to use synaptic clustering for information processing. SIGNIFICANCE STATEMENT A fundamental question in neuroscience is how neuronal feature selectivity is established via the combination of dendritic processing of synaptic input patterns with long-term synaptic plasticity. As these processes have been mostly studied separately, the relationship between the rules of integration and rules of plasticity remained elusive. Here we explore how the fine-grained spatial pattern and the form of voltage integration determine plasticity of different excitatory synaptic input patterns in perisomatic dendrites of CA1 pyramidal cells. We demonstrate that the plasticity rules depend highly on three factors: (1) the location of the input within the dendritic branch (proximal vs distal), (2) the strength of the input pattern (subthreshold or suprathreshold for dendritic spikes), and (3) the stimulation of neighboring synapses., (Copyright © 2020 Magó et al.)

Published

2020

47. Simulation model of CA1 pyramidal neurons reveal opposing roles for the Na+/Ca2+ exchange current and Ca2+-activated K+ current during spike-timing dependent synaptic plasticity.

Author

O'Halloran DM

Subjects

Action Potentials physiology, Animals, CA1 Region, Hippocampal cytology, Calcium metabolism, Cations, Divalent metabolism, Cations, Monovalent metabolism, Computer Simulation, Models, Animal, Potassium metabolism, Rats, Sodium metabolism, CA1 Region, Hippocampal physiology, Models, Neurological, Neuronal Plasticity physiology, Pyramidal Cells metabolism, Sodium-Calcium Exchanger metabolism

Abstract

Sodium Calcium exchanger (NCX) proteins utilize the electrochemical gradient of Na+ to generate Ca2+ efflux (forward mode) or influx (reverse mode). In mammals, there are three unique NCX encoding genes-NCX1, NCX2, and NCX3, that comprise the SLC8A family, and mRNA from all three exchangers is expressed in hippocampal pyramidal cells. Furthermore, mutant ncx2-/- and ncx3-/- mice have each been shown to exhibit altered long-term potentiation (LTP) in the hippocampal CA1 region due to delayed Ca2+ clearance after depolarization that alters synaptic transmission. In addition to the role of NCX at the synapse of hippocampal subfields required for LTP, the three NCX isoforms have also been shown to localize to the dendrite of hippocampal pyramidal cells. In the case of NCX1, it has been shown to localize throughout the basal and apical dendrite of CA1 neurons where it helps compartmentalize Ca2+ between dendritic shafts and spines. Given the role for NCX and calcium in synaptic plasticity, the capacity of NCX splice-forms to influence backpropagating action potentials has clear consequences for the induction of spike-timing dependent synaptic plasticity (STDP). To explore this, we examined the effect of NCX localization, density, and allosteric activation on forward and back propagating signals and, next employed a STDP paradigm to monitor the effect of NCX on plasticity using back propagating action potentials paired with EPSPs. From our simulation studies we identified a role for the sodium calcium exchange current in normalizing STDP, and demonstrate that NCX is required at the postsynaptic site for this response. We also screened other mechanisms in our model and identified a role for the Ca2+ activated K+ current at the postsynapse in producing STDP responses. Together, our data reveal opposing roles for the Na+/Ca2+ exchanger current and the Ca2+ activated K+ current in setting STDP., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

48. Postsynaptic integrative properties of dorsal CA1 pyramidal neuron subpopulations.

Author

Masurkar AV, Tian C, Warren R, Reyes I, Lowes DC, Brann DH, and Siegelbaum SA

Subjects

Animals, Electrophysiological Phenomena physiology, Mice, Mice, Inbred C57BL, Spatial Memory physiology, CA1 Region, Hippocampal physiology, Memory physiology, Pyramidal Cells physiology

Abstract

The population activity of CA1 pyramidal neurons (PNs) segregates along anatomical axes with different behaviors, suggesting that CA1 PNs are functionally subspecialized based on somatic location. In dorsal CA1, spatial encoding is biased toward CA2 (CA1c) and in deep layers of the radial axis. In contrast, nonspatial coding peaks toward subiculum (CA1a) and in superficial layers. While preferential innervation by spatial vs. nonspatial input from entorhinal cortex (EC) may contribute to this specialization, it cannot fully explain the range of in vivo responses. Differences in intrinsic properties thus may play a critical role in modulating such synaptic input differences. In this study we examined the postsynaptic integrative properties of dorsal CA1 PNs in six subpopulations along the transverse (CA1c, CA1b, CA1a) and radial (deep, superficial) axes. Our results suggest that active and passive properties of deep and superficial neurons evolve over the transverse axis to promote the functional specialization of CA1c vs. CA1a as dictated by their cortical input. We also find that CA1b is not merely an intermediate mix of its neighbors, but uniquely balances low excitability with superior input integration of its mixed input, as may be required for its proposed role in sequence encoding. Thus synaptic input and intrinsic properties combine to functionally compartmentalize CA1 processing into at least three transverse axis regions defined by the processing schemes of their composite radial axis subpopulations. NEW & NOTEWORTHY There is increasing interest in CA1 pyramidal neuron heterogeneity and the functional relevance of this diversity. We find that active and passive properties evolve over the transverse and radial axes in dorsal CA1 to promote the functional specialization of CA1c and CA1a for spatial and nonspatial memory, respectively. Furthermore, CA1b is not a mean of its neighbors, but features low excitability and superior integrative capabilities, relevant to its role in nonspatial sequence encoding.

Published

2020

49. Object and place information processing by CA1 hippocampal neurons of C57BL/6J mice.

Author

Ásgeirsdóttir HN, Cohen SJ, and Stackman RW Jr

Subjects

Action Potentials drug effects, Action Potentials physiology, Animals, CA1 Region, Hippocampal drug effects, GABA-A Receptor Agonists pharmacology, Male, Mice, Mice, Inbred C57BL, Muscimol pharmacology, Pyramidal Cells drug effects, CA1 Region, Hippocampal physiology, Mental Recall physiology, Pattern Recognition, Visual physiology, Pyramidal Cells physiology, Recognition, Psychology physiology, Spatial Memory physiology

Abstract

Medial and lateral entorhinal cortices convey spatial/contextual and item/object information to the hippocampus, respectively. Whether the distinct inputs are integrated as one cognitive map by hippocampal neurons to represent location and the objects therein, or whether they remain as parallel outputs, to be integrated in a downstream region, remains unclear. Principal, or complex spike bursting, neurons of hippocampus exhibit location-specific firing, and it is likely that the activity of "place cells" supports spatial memory/navigation in rodents. Consistent with cognitive map theory, the activity of CA1 hippocampal neurons is also critical for nonspatial memory, such as object recognition. However, the degree to which CA1 neuronal activity represents the associations of object-context or object-in-place memory is not well understood. Here, the contributions of mouse CA1 neuronal activity to object recognition memory and the emergence of object-place conjunctive representations were tested using in vivo recordings and functional inactivation. Independent of arena configuration, CA1 place fields were stable throughout testing and object-place representations were not identified in CA1, although the number of fields per cell increased during object sessions, and few object-related firing CA1 neurons (nonplace) were recorded. The results of the inactivation studies confirmed the significant contribution of CA1 neuronal activity to object recognition memory when a delay of 20 min, but not 5 min, was imposed between encoding and retrieval. Together, our results confirm the delay-dependent contribution of the CA1 region to object memory and suggest that object information is processed in parallel with the ongoing spatial mapping function that is a hallmark of hippocampal memory. NEW & NOTEWORTHY We developed variations of the object recognition task to examine the contribution of mouse CA1 neuronal activity to object memory and the degree to which object-context conjunctive representations are formed during object training. Our results indicate that, within the CA1 region, object information is processed in a parallel but delay-dependent manner, with ongoing spatial mapping.

Published

2020

50. Differential developmental refinement of the intrinsic electrophysiological properties of CA1 pyramidal neurons from the rat dorsal and ventral hippocampus.

Author

Dougherty KA

Subjects

Animals, Electric Stimulation, Rats, Action Potentials physiology, CA1 Region, Hippocampal physiology, Pyramidal Cells physiology

Abstract

The dorsal and ventral regions of the rat longitudinal hippocampal axis are functionally distinct. That is, each region is associated with different behavioral tasks and disease susceptibilities due to underlying anatomical, and physiological differences. These differences are especially pronounced in area CA1, where significant differences in morphology, synaptic physiology, intrinsic excitability, and gene expression have been reported between CA1 pyramidal neurons from the dorsal (DHC) and ventral hippocampus (VHC). However, despite a significant amount of recent attention, a cogent picture of the intrinsic electrophysiological profile of DHC and VHC neurons has remained elusive, due, in part, to experiments performed on rats at different developmental time points. Moreover, the resulting intrinsic electrophysiological profiles are sufficiently different as to warrant a thorough investigation of the spatial and temporal changes in the intrinsic excitability of CA1 pyramidal neurons across developmental time. Accordingly, in this study, I have characterized the intrinsic electrophysiological properties of CA1 pyramidal neurons from acute hippocampal slices prepared from the DHC and VHC throughout an approximately 3-week developmental period (P14-P37). DHC and VHC neurons exhibited distinct intra-region changes (DHC or VHC) and inter-region differences (DHC versus VHC) in their intrinsic electrophysiological properties, which yielded two developmental timelines: (a) a common developmental timeline describing changes observed in both DHC and VHC neurons, and (b) a differential developmental timeline highlighting unique features observed in DHC neurons. Specifically, DHC neurons exhibited significant inter-region differences in RMP, input resistance, threshold, and spike frequency adaptation relative to VHC neurons, as well as an intra-region change in the rebound slope (a proxy for I h ). These observations both integrate and reconcile previous work performed with rats at different developmental stages and suggest a distinct developmental trajectory for DHC neurons that might shed light on the normal physiological functions and disease susceptibility of the DHC., (© 2019 Wiley Periodicals, Inc.)

Published

2020