scholarly journals Slow AMPA receptors in hippocampal principal cells

2020 ◽  
Author(s):  
Niccolò Paolo Pampaloni ◽  
Irene Riva ◽  
Anna Carbone ◽  
Andrew J. R. Plested
Keyword(s):  
Spatial Distribution ◽  
Charge Transfer ◽  
Ampa Receptors ◽  
Action Potentials ◽  
Synaptic Connections ◽  
Synaptic Current ◽  
Hippocampal Function ◽  
Principal Cells ◽  
Mouse Hippocampus ◽  
Excitatory Neurotransmission

SummaryGlutamate receptor ion channels such as the α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor mediate the majority of fast excitatory neurotransmission in the vertebrate CNS. AMPA receptors canonically provide the fast, millisecond component of the synaptic current. However, we found that about two-thirds of principal cells in the mouse hippocampus express AMPA receptors that do not desensitize and stay active for up to half a second. These receptors are expressed at synapses with a sparse but flat spatial distribution. The resulting increase in charge transfer allows single connections to reliably trigger action potentials. Biophysical and pharmacological observations imply that slow AMPA receptors incorporate γ-8 and other auxiliary proteins, and their activation lengthens individual miniature synaptic currents. Synaptic connections harboring slow AMPARs should have unique roles in hippocampal function.

Simulator for neural networks and action potentials: description and application

1994 ◽  
Vol 71 (1) ◽  
pp. 294-308 ◽  
Author(s):  
I. Ziv ◽  
D. A. Baxter ◽  
J. H. Byrne
Keyword(s):  
Neural Networks ◽  
Central Pattern Generator ◽  
Action Potentials ◽  
Modular Design ◽  
Second Messenger ◽  
Pattern Generator ◽  
Slow Inward Current ◽  
Synaptic Connections ◽  
Different Types ◽  
Voltage Dependent

1. We describe a simulator for neural networks and action potentials (SNNAP) that can simulate up to 30 neurons, each with up to 30 voltage-dependent conductances, 30 electrical synapses, and 30 multicomponent chemical synapses. Voltage-dependent conductances are described by Hodgkin-Huxley type equations, and the contributions of time-dependent synaptic conductances are described by second-order differential equations. The program also incorporates equations for simulating different types of neural modulation and synaptic plasticity. 2. Parameters, initial conditions, and output options for SNNAP are passed to the program through a number of modular ASCII files. These modules can be modified by commonly available text editors that use a conventional (i.e., character based) interface or by an editor incorporated into SNNAP that uses a graphical interface. The modular design facilitates the incorporation of existing modules into new simulations. Thus libraries can be developed of files describing distinctive cell types and files describing distinctive neural networks. 3. Several different types of neurons with distinct biophysical properties and firing properties were simulated by incorporating different combinations of voltage-dependent Na+, Ca2+, and K+ channels as well as Ca(2+)-activated and Ca(2+)-inactivated channels. Simulated cells included those that respond to depolarization with tonic firing, adaptive firing, or plateau potentials as well as endogenous pacemaker and bursting cells. 4. Several types of simple neural networks were simulated that included feed-forward excitatory and inhibitory chemical synaptic connections, a network of electrically coupled cells, and a network with feedback chemical synaptic connections that simulated rhythmic neural activity. In addition, with the use of the equations describing electrical coupling, current flow in a branched neuron with 18 compartments was simulated. 5. Enhancement of excitability and enhancement of transmitter release, produced by modulatory transmitters, were simulated by second-messenger-induced modulation of K+ currents. A depletion model for synaptic depression was also simulated. 6. We also attempted to simulate the features of a more complicated central pattern generator, inspired by the properties of neurons in the buccal ganglia of Aplysia. Dynamic changes in the activity of this central pattern generator were produced by a second-messenger-induced modulation of a slow inward current in one of the neurons.

scholarly journals Presynaptic AMPA Receptors in Health and Disease

Cells ◽  
2021 ◽  
Vol 10 (9) ◽  
pp. 2260
Author(s):  
Letizia Zanetti ◽  
Maria Regoni ◽  
Elena Ratti ◽  
Flavia Valtorta ◽  
Jenny Sassone
Keyword(s):  
Ampa Receptors ◽  
Plasma Membranes ◽  
Actin Dynamics ◽  
Axonal Pathology ◽  
Pathological Conditions ◽  
Pain Transmission ◽  
Pharmacological Targets ◽  
Health And Disease ◽  
Excitatory Neurotransmission

AMPA receptors (AMPARs) are ionotropic glutamate receptors that play a major role in excitatory neurotransmission. AMPARs are located at both presynaptic and postsynaptic plasma membranes. A huge number of studies investigated the role of postsynaptic AMPARs in the normal and abnormal functioning of the mammalian central nervous system (CNS). These studies highlighted that changes in the functional properties or abundance of postsynaptic AMPARs are major mechanisms underlying synaptic plasticity phenomena, providing molecular explanations for the processes of learning and memory. Conversely, the role of AMPARs at presynaptic terminals is as yet poorly clarified. Accruing evidence demonstrates that presynaptic AMPARs can modulate the release of various neurotransmitters. Recent studies also suggest that presynaptic AMPARs may possess double ionotropic-metabotropic features and that they are involved in the local regulation of actin dynamics in both dendritic and axonal compartments. In addition, evidence suggests a key role of presynaptic AMPARs in axonal pathology, in regulation of pain transmission and in the physiology of the auditory system. Thus, it appears that presynaptic AMPARs play an important modulatory role in nerve terminal activity, making them attractive as novel pharmacological targets for a variety of pathological conditions.

Nonlinear Frequency-Dependent Synchronization in the Developing Hippocampus

1999 ◽  
Vol 82 (1) ◽  
pp. 202-208 ◽  
Author(s):  
Liset Menendez de la Prida ◽  
Juan V. Sanchez-Andres
Keyword(s):  
Ampa Receptors ◽  
Action Potentials ◽  
Mossy Fibers ◽  
Pyramidal Cells ◽  
Time Interval ◽  
Nonlinear Frequency ◽  
Population Activity ◽  
Frequency Threshold ◽  
Hippocampal Networks ◽  
Full Synchronization

Synchronous population activity is present both in normal and pathological conditions such as epilepsy. In the immature hippocampus, synchronous bursting is an electrophysiological conspicuous event. These bursts, known as giant depolarizing potentials (GDPs), are generated by the synchronized activation of interneurons and pyramidal cells via GABAA, N-methyl-d-aspartate, and AMPA receptors. Nevertheless the mechanism leading to this synchronization is still controversial. We have investigated the conditions under which synchronization arises in developing hippocampal networks. By means of simultaneous intracellular recordings, we show that GDPs result from local cooperation of active cells within an integration period prior to their onset. During this time interval, an increase in the number of excitatory postsynaptic potentials (EPSPs) takes place building up full synchronization between cells. These EPSPs are correlated with individual action potentials simultaneously occurring in neighboring cells. We have used EPSP frequency as an indicator of the neuronal activity underlying GDP generation. By comparing EPSP frequency with the occurrence of synchronized GDPs between CA3 and the fascia dentata (FD), we found that GDPs are fired in an all-or-none manner, which is characterized by a specific threshold of EPSP frequency from which synchronous GDPs emerge. In FD, the EPSP frequency-threshold for GDP onset is 17 Hz. GDPs are triggered similarly in CA3 by appropriate periodic stimulation of mossy fibers. The frequency threshold for CA3 GDP onset is 12 Hz. These findings clarify the local mechanism of synchronization underlying bursting in the developing hippocampus, indicating that GDPs are fired when background levels of EPSPs or action potentials have built up full synchronization by firing at specific frequencies (>12 Hz). Our results also demonstrate that spontaneous EPSPs and action potentials are important for the initiation of synchronous bursts in the developing hippocampus.

Transition Dynamics of Generalized Periodic Discharges Observed in EEG Waveforms

2019 ◽  
Vol 29 (13) ◽  
pp. 1930038
Author(s):  
Honghui Zhang ◽  
Zichen Deng ◽  
Shuang Liu
Keyword(s):  
Ampa Receptors ◽  
Gaba Receptors ◽  
Mean Field ◽  
Neural Population ◽  
Model Parameters ◽  
Synaptic Connections ◽  
Mean Field Model ◽  
Metabolic Encephalopathy ◽  
Periodic Discharges ◽  
Mode Transitions

Generalized periodic discharges (GPD) are generalized waveforms that recur with a relatively uniform morphology and duration observed in EEG recordings of many types of metabolic encephalopathy, which are often referred to as epileptiform. In this paper, we try to link these spatiotemporal electrocortical activities and significant attributes of cortex based on Liley’s mean field model, and seek possible generation mechanisms of GPD rhythms from several factors. To these ends, the dynamical properties of simulated EEG consistent with neurophysiological features of human cortex are investigated, among which GPD patterns are our focus. Firstly, with different value sets of model parameters, we reproduce some typical simulation waveforms which are analogous to mammalian normal or abnormal brain activities detected by EEG. Or in other words, we put more emphasis on brain waveforms of GPD states, normal states, and low firing rate states in our numerical simulations, and mode transitions among different firing states are our main interests. Secondly, through analysis of maximum Lyapunov exponents and frequency spectrum, we give several mode transitions by varying synaptic connections between excitatory and inhibitory populations, which support the conjecture that selective changes of synaptic connections can trigger GPD states, such as in excitatory (AMPA receptors) and inhibitory neurotransmitters (GABA receptors). Thirdly, we stress the importance of time delay on neural population connections and find that they are free to transfer among different firing modes with appropriate time delays. Furthermore, considering the effects of external inputs to cerebral cortex, we verify that stimulation can lead to good controls on GPD patterns, including facilitation and elimination. Finally, we show that more dynamical rhythms can be produced when taking into account the cortico-cortical connections. These modeling results are expected to shed light into the pathophysiological mechanisms of GPD modes from a theoretical viewpoint.

Feeding CPG in Aplysia Directly Controls Two Distinct Outputs of a Compartmentalized Interneuron That Functions as a CPG Element

2007 ◽  
Vol 98 (6) ◽  
pp. 3796-3801 ◽  
Author(s):  
Kosei Sasaki ◽  
Michael R. Due ◽  
Jian Jing ◽  
Klaudiusz R. Weiss
Keyword(s):  
Action Potentials ◽  
Electrical Coupling ◽  
Motor Program ◽  
Pattern Generator ◽  
Synaptic Connections ◽  
Buccal Ganglion ◽  
Full Size ◽  
Program Generation ◽  
Functional Aspects ◽  
Protraction Phase

In the context of motor program generation in Aplysia, we characterize several functional aspects of intraneuronal compartmentalization in an interganglionic interneuron, CBI-5/6. CBI-5/6 was shown previously to have a cerebral compartment (CC) that includes a soma that does not generate full-size action potentials and a buccal compartment (BC) that does. We find that the synaptic connections made by the BC of CBI-5/6 in the buccal ganglion counter the activity of protraction-phase neurons and reinforce the activity of retraction-phase neurons. In buccal motor programs, the BC of CBI-5/6 fires phasically, and its premature activation can phase advance protraction termination and retraction initiation. Thus the BC of CBI-5/6 can act as an element of the central pattern generator (CPG). During protraction, the CC of CBI-5/6 receives direct excitatory inputs from the CPG elements, B34 and B63, and during retraction, it receives antidromically propagating action potentials that originate in the BC of CBI-5/6. Consequently, in its CC, CBI-5/6 receives depolarizing inputs during both protraction and retraction, and these depolarizations can be transmitted via electrical coupling to other neurons. In contrast, in its BC, CBI-5/6 uses spike-dependent synaptic transmission. Thus the CPG directly and differentially controls the program phases in which the two compartments of CBI-5/6 may transmit information to its targets.

scholarly journals GluA4 enables associative memory formation by facilitating cerebellar expansion coding

2020 ◽  
Author(s):  
Katarzyna Kita ◽  
Catarina Albergaria ◽  
Ana S. Machado ◽  
Megan R. Carey ◽  
Martin Müller ◽  
...  
Keyword(s):  
Associative Learning ◽  
Associative Memory ◽  
Granule Cell ◽  
Ampa Receptors ◽  
Knockout Mice ◽  
Mossy Fiber ◽  
Eyeblink Conditioning ◽  
Memory Formation ◽  
Synaptic Excitation ◽  
Excitatory Neurotransmission

AbstractAMPA receptors (AMPARs) mediate excitatory neurotransmission in the CNS and their subunit composition determines synaptic efficacy. Whereas AMPAR subunits GluA1–GluA3 have been linked to particular forms of synaptic plasticity and learning, the functional role of GluA4 remains elusive. Here we used electrophysiological, computational and behavioral approaches to demonstrate a crucial function of GluA4 for synaptic excitation and associative memory formation in the cerebellum. Notably, GluA4-knockout mice had ∼80% reduced mossy fiber to granule cell synaptic transmission. The fidelity of granule cell spike output was markedly decreased despite attenuated tonic inhibition and increased NMDA receptor-mediated transmission. Computational modeling revealed that GluA4 facilitates pattern separation that is important for associative learning. On a behavioral level, while locomotor coordination was generally spared, GluA4-knockout mice failed to form associative memories during delay eyeblink conditioning. These results demonstrate an essential role for GluA4-containing AMPARs in cerebellar information processing and associative learning.

scholarly journals Spatial structure of synchronized inhibition in the olfactory bulb

2017 ◽  
Author(s):  
Hannah A. Arnson ◽  
Ben W. Strowbridge
Keyword(s):  
Olfactory Bulb ◽  
Action Potentials ◽  
Granule Cells ◽  
Gaba Release ◽  
Principal Cells ◽  
Receptor Neurons ◽  
Olfactory Bulb Slices ◽  
Cortical Regions ◽  
Large Groups ◽  
Dendrodendritic Synapses

AbstractOlfactory sensory input is detected by receptor neurons in the nose which then send information to the olfactory bulb, the first brain region for processing olfactory information. Within the olfactory bulb, many local circuit interneurons, including axonless granule cells, function to facilitate fine odor discrimination. How interneurons interact with principal cells to affect bulbar processing is not known though the mechanism is likely to be different than in sensory cortical regions since the olfactory bulb lacks an obvious topographical organization; neighboring glomerular columns, representing inputs from different receptor neuron subtypes, typically have different odor tuning. Determining the spatial scale over which interneurons such as granule cells can affect principal cells is a critical step towards understanding how the olfactory bulb operates. We addressed this question by assaying inhibitory synchrony using intracellular recordings from pairs of principal cells with different inter-somatic spacing. We find that in acute rat olfactory bulb slices, inhibitory synchrony is evident in the spontaneous synaptic input in mitral cells separated up to 300 μm. At all inter-somatic spacing assayed, inhibitory synchrony was dependent on fast Na+ channels, suggesting that action potentials in granule cells function to coordinate GABA release at relatively distant dendrodendritic synapses formed throughout the the dendritic arbor. Our results suggest that individual granule cells are able to influence relatively large groups of mitral and tufted cells belonging to clusters of at least 15 glomerular modules, providing a potential mechanism to integrate signals reflecting a wide variety of odorants.

scholarly journals Cellular resolution circuit mapping with temporal-focused excitation of soma-targeted channelrhodopsin

eLife ◽  
2016 ◽  
Vol 5 ◽  
Author(s):  
Christopher A Baker ◽  
Yishai M Elyada ◽  
Andres Parra ◽  
M McLean Bolton
Keyword(s):  
Action Potentials ◽  
Single Neuron ◽  
Synaptic Connectivity ◽  
Electrophysiological Recording ◽  
Synaptic Connections ◽  
Spike Generation ◽  
Two Photon ◽  
Cellular Resolution ◽  
Temporal Focusing ◽  
Imaging Plane

We describe refinements in optogenetic methods for circuit mapping that enable measurements of functional synaptic connectivity with single-neuron resolution. By expanding a two-photon beam in the imaging plane using the temporal focusing method and restricting channelrhodopsin to the soma and proximal dendrites, we are able to reliably evoke action potentials in individual neurons, verify spike generation with GCaMP6s, and determine the presence or absence of synaptic connections with patch-clamp electrophysiological recording.

scholarly journals Sensing of nutrients by CPT1C controls SAC1 activity to regulate AMPA receptor trafficking

2020 ◽  
Vol 219 (10) ◽  
Author(s):  
Maria Casas ◽  
Rut Fadó ◽  
José Luis Domínguez ◽  
Aina Roig ◽  
Moena Kaku ◽  
...  
Keyword(s):  
Ampa Receptors ◽  
Cortical Neurons ◽  
Metabolic Stress ◽  
Phosphatidyl Inositol ◽  
Synaptic Function ◽  
Glucose Depletion ◽  
Malonyl Coa ◽  
Dependent Inhibition ◽  
Excitatory Neurotransmission ◽  
The Brain

Carnitine palmitoyltransferase 1C (CPT1C) is a sensor of malonyl-CoA and is located in the ER of neurons. AMPA receptors (AMPARs) mediate fast excitatory neurotransmission in the brain and play a key role in synaptic plasticity. In the present study, we demonstrate across different metabolic stress conditions that modulate malonyl-CoA levels in cortical neurons that CPT1C regulates the trafficking of the major AMPAR subunit, GluA1, through the phosphatidyl-inositol-4-phosphate (PI(4)P) phosphatase SAC1. In normal conditions, CPT1C down-regulates SAC1 catalytic activity, allowing efficient GluA1 trafficking to the plasma membrane. However, under low malonyl-CoA levels, such as during glucose depletion, CPT1C-dependent inhibition of SAC1 is released, facilitating SAC1’s translocation to ER-TGN contact sites to decrease TGN PI(4)P pools and trigger GluA1 retention at the TGN. Results reveal that GluA1 trafficking is regulated by CPT1C sensing of malonyl-CoA and provide the first report of a SAC1 inhibitor. Moreover, they shed light on how nutrients can affect synaptic function and cognition.

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