5,380 research outputs found
Ligand-dependent opening of the multiple AMPA receptor conductance states: a concerted model
Modulation of the properties of AMPA receptors at the post-synaptic membrane
is one of the main suggested mechanisms behind synaptic plasticity in the
central nervous system of vertebrates. Electrophysiological recordings of
single channels stimulated with agonists showed that both recombinant and
native AMPA receptors visit multiple conductance states in an agonist
concentration dependent manner. We propose an allosteric model of the multiple
conductance states based on concerted conformational transitions of the four
subunits, as an iris diaphragm. Our model predicts that the thermodynamic
behaviour of the conductance states upon full and partial agonist stimulations
can be described with increased affinity of receptors as they progress to
higher conductance states. The model also predicts existence of AMPA receptors
in non-liganded conductive substates. However, spontaneous openings probability
decreases with increasing conductances. Finally, we predict that the large
conductance states are stabilized within the rise phase of a whole-cell EPSC in
glutamatergic hippocampal neurons. Our model provides a mechanistic link
between ligand concentration and conductance states that can explain
thermodynamic and kinetic features of AMPA receptor gating.Comment: 4 figures, models available on demand. They will be published by
BioModels Database upon publication of the articl
Metabotropic Glutamate Receptor Activation in Cerebelar Purkinje Cells as Substrate for Adaptive Timing of the Classicaly Conditioned Eye Blink Response
To understand how the cerebellum adaptively times the classically conditioned nictitating membrane response (NMR), a model of the metabotropic glutamate receptor (mGluR) second messenger system in cerebellar Purkinje cells is constructed. In the model slow responses, generated postsynaptically by mGluR-mediated phosphoinositide hydrolysis, and calcium release from intracellular stores, bridge the interstimulus interval (ISI) between the onset of parallel fiber activity associated with the conditioned stimulus (CS) and climbing fiber activity associated with unconditioned stimulus (US) onset. Temporal correlation of metabotropic responses and climbing fiber signals produces persistent phosphorylation of both AMPA receptors and Ca2+-dependent K+ channels. This is responsible for long-term depression (LTD) of AMPA receptors. The phosphorylation of Ca2+-dependent K+ channels leads to a reduction in baseline membrane potential and a reduction of Purkinje cell population firing during the CS-US interval. The Purkinje cell firing decrease disinhibits cerebellar nuclear cells which then produce an excitatory response corresponding to the learned movement. Purkinje cell learning times the response, while nuclear cell learning can calibrate it. The model reproduces key features of the conditioned rabbit NMR: Purkinje cell population response is properly timed, delay conditioning occurs for ISIs of up to four seconds while trace conditioning occurs only at shorter ISIs, mixed training at two different ISis produces a double-peaked response, and ISIs of 200-400ms produce maximal responding. Biochemical similarities between timed cerebellar learning and photoreceptor transduction, and circuit similarities between the timed cerebellar circuit and a timed dentate-CA3 hippocampal circuit, are noted.Office of Naval Research (N00014- 92-J-4015, N00014-92-J-1309, N00014-95-1-0409); Air Force Office of Scientific Research (F49620-92-J-0225);National Science Foundation (IRI-90-24877
Genetically altered AMPA-type glutamate receptor kinetics in interneurons disrupt long-range synchrony of gamma oscillation
Gamma oscillations synchronized between distant neuronal populations may be critical for binding together brain regions devoted to common processing tasks. Network modeling predicts that such synchrony depends in part on the fast time course of excitatory postsynaptic potentials (EPSPs) in interneurons, and that even moderate slowing of this time course will disrupt synchrony. We generated mice with slowed interneuron EPSPs by gene targeting, in which the gene encoding the 67-kDa form of glutamic acid decarboxylase (GAD67) was altered to drive expression of the α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) glutamate receptor subunit GluR-B. GluR-B is a determinant of the relatively slow EPSPs in excitatory neurons and is normally expressed at low levels in γ-aminobutyric acid (GABA)ergic interneurons, but at high levels in the GAD-GluR-B mice. In both wild-type and GAD-GluR-B mice, tetanic stimuli evoked gamma oscillations that were indistinguishable in local field potential recordings. Remarkably, however, oscillation synchrony between spatially separated sites was severely disrupted in the mutant, in association with changes in interneuron firing patterns. The congruence between mouse and model suggests that the rapid time course of AMPA receptor-mediated EPSPs in interneurons might serve to allow gamma oscillations to synchronize over distance
How feedback inhibition shapes spike-timing-dependent plasticity and its implications for recent Schizophrenia models
It has been shown that plasticity is not a fixed property but, in fact, changes depending on the location of the synapse on the neuron and/or changes of biophysical parameters. Here we investigate how plasticity is shaped by feedback inhibition in a cortical microcircuit. We use a differential Hebbian learning rule to model spike-timing dependent plasticity and show analytically that the feedback inhibition shortens the time window for LTD during spike-timing dependent plasticity but not for LTP. We then use a realistic GENESIS model to test two hypothesis about interneuron hypofunction and conclude that a reduction in GAD67 is the most likely candidate as the cause for hypofrontality as observed in Schizophrenia
A Mathematical model for Astrocytes mediated LTP at Single Hippocampal Synapses
Many contemporary studies have shown that astrocytes play a significant role
in modulating both short and long form of synaptic plasticity. There are very
few experimental models which elucidate the role of astrocyte over Long-term
Potentiation (LTP). Recently, Perea & Araque (2007) demonstrated a role of
astrocytes in induction of LTP at single hippocampal synapses. They suggested a
purely pre-synaptic basis for induction of this N-methyl-D- Aspartate (NMDA)
Receptor-independent LTP. Also, the mechanisms underlying this pre-synaptic
induction were not investigated. Here, in this article, we propose a
mathematical model for astrocyte modulated LTP which successfully emulates the
experimental findings of Perea & Araque (2007). Our study suggests the role of
retrograde messengers, possibly Nitric Oxide (NO), for this pre-synaptically
modulated LTP.Comment: 51 pages, 15 figures, Journal of Computational Neuroscience (to
appear
Single-channel mechanisms underlying the function, diversity and plasticity of AMPA receptors
The functional properties of AMPA receptors shape many of the essential features of excitatory synaptic signalling in the brain, including high-fidelity point-to-point transmission and long-term plasticity. Understanding the behaviour and regulation of single AMPAR channels is fundamental in unravelling how central synapses carry, process and store information. There is now an abundance of data on the importance of alternative splicing, RNA editing, and phosphorylation of AMPAR subunits in determining central synaptic diversity. Furthermore, auxiliary subunits have emerged as pivotal players that regulate AMPAR channel properties and add further diversity. Single-channel studies have helped reveal a fascinating picture of the unique behaviour of AMPAR channels – their concentration-dependent single-channel conductance, the basis of their multiple-conductance states, and the influence of auxiliary proteins in controlling many of their gating and conductance properties. Here we summarize basic hallmarks of AMPAR single-channels, in relation to function, diversity and plasticity. We also present data that reveal an unexpected feature of AMPAR sublevel behaviour
Superactivation of AMPA receptors by auxiliary proteins
Glutamate receptors form complexes in the brain with auxiliary proteins, which
control their activity during fast synaptic transmission through a seemingly
bewildering array of effects. Here we devise a way to isolate the activation
of complexes using polyamines, which enables us to show that transmembrane
AMPA receptor regulatory proteins (TARPs) exert their effects principally on
the channel opening reaction. A thermodynamic argument suggests that because
TARPs promote channel opening, receptor activation promotes AMPAR-TARP
complexes into a superactive state with high open probability. A simple model
based on this idea predicts all known effects of TARPs on AMPA receptor
function. This model also predicts unexpected phenomena including massive
potentiation in the absence of desensitization and supramaximal recovery that
we subsequently detected in electrophysiological recordings. This transient
positive feedback mechanism has implications for information processing in the
brain, because it should allow activity-dependent facilitation of excitatory
synaptic transmission through a postsynaptic mechanism
STRUCTURAL AND FUNCTIONAL EFFECT OF PHOSPHORYLATION ON AMPA RECEPTORS
Structural and Functional Effect of Phosphorylation on AMPA Receptors
Cailtin Edmunds show you, BA
Advisory Professor: Vasanthi Jayaraman, Ph. D.
The α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor is the primary contributor to neuronal fast excitatory transmission, and plays a key role in learning and memory. Previous studies have established that residues S818, S831, and T840 in the C-terminal segment of GluA1 homomeric AMPA receptor are phosphorylated by PKC, and phosphorylation at these sites leads to an increase in receptor conductance. We show that the domain inclusive of those sites alters its secondary structure due to phosphorylation (using glutamate substitution as a mimic) in a lipid charge dependent manner using Fourier transform infrared spectroscopy. We also indicate a strong shift in the domain’s conformational landscape using single molecule FRET. Using wild-type GluA1 receptors, as well as glutamate and alanine to mimic phosphorylation and dephosphorylation respectively, we show based on FRET measurements that the C-terminal segment moves away from the membrane upon phosphorylation. Additionally, the FRET between the C-terminal segment and inner leaflet of the plasma membrane increases upon activation of the receptor for the triple alanine dephosphorylated receptor indicating a further motion towards the membrane associated with activation of the receptor. The phosphomimetic receptor, on the other hand, shows no change in FRET associated with activation of the receptor. However, addition of the lipid sphingosine restores this change in FRET due to activation for the phosphomimetic receptor. Using single channel current recordings we confirm that there is an increase in all conductance levels of the AMPA receptor in the phosphomimetic receptor and show that this increase in conductance is reversed by incorporation of sphingosine in the membrane or addition of poly-L-lysine. Thus using FRET and functional measurements we show that the plasma membrane lipid content is critical in mediating the phosphorylation mediated functional changes in GluA1 AMPA receptor
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