Mechanism of modulation of AMPA receptors by TARP-γ8.

Fast excitatory synaptic transmission in the mammalian central nervous system is mediated by glutamate-activated α-amino-5-methyl-3-hydroxy-4-isoxazole propionate (AMPA) receptors. In neurons, AMPA receptors coassemble with transmembrane AMPA receptor regulatory proteins (TARPs). Assembly with TARP γ8 alters the biophysical properties of the receptor, producing resensitization currents in the continued presence of glutamate. Using single-channel recordings, we show that under resensitizing conditions, GluA2 AMPA receptors primarily transition to higher conductance levels, similar to activation of the receptors in the presence of cyclothiazide, which stabilizes the open state. To study the conformation associated with these states, we have used single-molecule FRET and show that this high-conductance state exhibits tighter coupling between subunits in the extracellular parts of the receptor. Furthermore, the dwell times for the transition from the tightly coupled state to the decoupled states correlate to longer open durations of the channels, thus correlating conformation and function at the single-molecule level.

Modulation of AMPA Receptor Gating by the Anticonvulsant Drug, Perampanel.

Postsynaptic AMPA/glutamate receptors, essential for neuronal excitability, are important targets for anticonvulsant therapy. This single channel study of the selective noncompetitive AMPA receptor antagonist, perampanel, was performed on homotetrameric GluA3 receptor-channels that open in a stepwise manner to four distinct conductance levels through independent subunit activation. Previous structural studies show that perampanel binds to four sites located within the extracellular/transmembrane boundary of closed AMPA receptor-channel subunits. We found that channels exposed to 1 or 2 µM perampanel opened mainly to the two lower conductance levels in a dose-dependent manner. Comparison of the single channel results in the structures of the full length AMPA receptor in the closed state bound to perampanel, and the open state provide insights into the mechanism of allosteric reduction of AMPA-receptor-mediated excitation in epilepsy.

Noncompetitive antagonists induce cooperative AMPA receptor channel gating.

Glutamate is released from presynaptic nerve terminals in the central nervous system (CNS) and spreads excitation by binding to and activating postsynaptic iGluRs. Of the potential glutamate targets, tetrameric AMPA receptors mediate fast, transient CNS signaling. Each of the four AMPA subunits in the receptor channel complex is capable of binding glutamate at its ligand-binding domains and transmitting the energy of activation to the pore domain. Homotetrameric AMPA receptor channels open in a stepwise manner, consistent with independent activation of individual subunits, and they exhibit complex kinetic behavior that manifests as temporal shifts between four different conductance levels. Here, we investigate how two AMPA receptor-selective noncompetitive antagonists, GYKI-52466 and GYKI-53655, disrupt the intrinsic step-like gating patterns of maximally activated homotetrameric GluA3 receptors using single-channel recordings from cell-attached patches. Interactions of these 2,3-benzodiazepines with residues in the boundary between the extracellular linkers and transmembrane helical domains reorganize the gating behavior of channels. Low concentrations of modulators stabilize open and closed states to different degrees and coordinate the activation of subunits so that channels open directly from closed to higher conductance levels. Using kinetic and structural models, we provide insight into how the altered gating patterns might arise from molecular contacts within the extracellular linker-channel boundary. Our results suggest that this region may be a tunable locus for AMPA receptor channel gating.

Gating reaction mechanism of neuronal NMDA receptors.

The activation mechanisms of recombinant N-methyl-d-aspartate receptors (NRs) have been established in sufficient detail to account for their single channel and macroscopic responses; however, the reaction mechanism of native NRs remains uncertain due to indetermination of the isoforms expressed and possible neuron-specific factors. To delineate the activation mechanism of native NRs, we examined the kinetic properties of currents generated by individual channels located at the soma of cultured rat neurons. Cells were dissociated from the embryonic cerebral cortex or hippocampus, and on-cell single channel recordings were done between 4 and 50 days in vitro (DIV). We observed two types of kinetics that correlated with the age of the culture. When we segregated recordings by culture age, we found that receptors recorded from early (4-33 DIV) and late (25-50 DIV) cultures had smaller unitary conductances but had kinetic profiles that matched closely those of recombinant 2B- or 2A-containing receptors, respectively. In addition, we examined the effects of cotransfection with postsynaptic density protein 95 or neuropilin tolloid-like protein 1 on recombinant receptors expressed in human embryonic kidney-293 cells. Our results add support to the view that neuronal cultures recapitulate the developmental patterns of receptor expression observed in the intact animal and demonstrate that the activation mechanism of somatic neuronal NRs is similar to that described for recombinant receptors of defined subunit composition.

The loss of an electrostatic contact unique to AMPA receptor ligand binding domain 2 slows channel activation.

Ligand-gated ion channels undergo conformational changes that transfer the energy of agonist binding to channel opening. Within ionotropic glutamate receptor (iGluR) subunits, this process is initiated in their bilobate ligand binding domain (LBD) where agonist binding to lobe 1 favors closure of lobe 2 around the agonist and allows formation of interlobe hydrogen bonds. AMPA receptors (GluAs) differ from other iGluRs because glutamate binding causes an aspartate-serine peptide bond in a flexible part of lobe 2 to rotate 180° (flipped conformation), allowing these residues to form cross-cleft H-bonds with tyrosine and glycine in lobe 1. This aspartate also contacts the side chain of a lysine residue in the hydrophobic core of lobe 2 by a salt bridge. We investigated how the peptide flip and electrostatic contact (D655-K660) in GluA3 contribute to receptor function by examining pharmacological and structural properties with an antagonist (CNQX), a partial agonist (kainate), and two full agonists (glutamate and quisqualate) in the wildtype and two mutant receptors. Alanine substitution decreased the agonist potency of GluA3(i)-D655A and GluA3(i)-K660A receptor channels expressed in HEK293 cells and differentially affected agonist binding affinity for isolated LBDs without changing CNQX affinity. Correlations observed in the crystal structures of the mutant LBDs included the loss of the D655-K660 electrostatic contact, agonist-dependent differences in lobe 1 and lobe 2 closure, and unflipped D(A)655-S656 bonds. Glutamate-stimulated activation was slower for both mutants, suggesting that efficient energy transfer of agonist binding within the LBD of AMPA receptors requires an intact tether between the flexible peptide flip domain and the rigid hydrophobic core of lobe 2.

Mechanisms of modal activation of GluA3 receptors.

AMPA receptors are the major excitatory neurotransmitter receptors in the central nervous system and are involved in numerous neurological disorders. An agonist-binding site is present in each of four subunits that form a functional channel. Binding consists of three steps: docking of agonist to the bilobed ligand binding domain (LBD), closure of the LBD, and increased stability of the closed-lobe conformation through interlobe hydrogen bonding. We describe GluA3 single channel currents activated by nitrowillardiine (NO(2)W) and chlorowillardiine (ClW) in the presence of cyclothiazide, in conjunction with crystal structures of GluA2 and GluA3 LBDs bound to fluorowillardiine (FW), ClW, and NO(2)W. When bound to NO(2)W or ClW, the GluA3 channel opens to three conductance levels with comparable open probabilities and displays modal behavior similar to that obtained with glutamate and FW as agonists (Poon et al., 2010). At lower concentrations, ClW evoked an alternate kinetic behavior, consisting of high open probability in lower conductance states. The structure of ClW bound to GluA3 LBD exhibits a unique partially open hydrogen bonding structure that may be associated with these alternative kinetics. NO(2)W evoked longer open times than seen for other agonists in high and very high modes. The structure ofGluA2 LBD bound to NO(2)W exhibits fully closed lobes with additional interlobe interactions mediated by the nitro group. Beyond differences in efficacy between full and partial agonists, the complexities of the single channel behavior of AMPA receptors may also be associated with small interactions that modify the stability of various degrees of closure.

Characterizing single-channel behavior of GluA3 receptors.

AMPA receptors play a major role in excitatory neurotransmission in the CNS and are involved in numerous neurological disorders. Agonists bind to each of four bilobed LBDs of this tetrameric receptor, and upon binding, the lobes close to envelope the agonist, leading to channel activation. However, AMPA receptors exhibit complex activation kinetics, the mechanism of which has not yet been determined. We report here single-channel studies of a homomeric AMPA receptor (GluA3) activated by the full agonist, glutamate, and a partial agonist, fluorowillardiine. Both agonists activate the channel to the same three open conductance levels but with different open probabilities in each level. The closed probability (P(c)) varied within records, particularly at low agonist concentrations. By sorting discrete segments of the record according to P(c) using the X-means algorithm, we defined five modes of activity. The kinetic behavior could then be analyzed for both agonists over a range of agonist concentrations with a relatively simple model (three closed states and two open states for each open conductance level). The structural mechanism underlying the modal behavior is not clear; however, it occurs on a timescale consistent with hydrogen bonding across the lobe interface in the LBD.

Mechanism of glutamate receptor-channel function in rat hippocampal neurons investigated using the laser-pulse photolysis (LaPP) technique.

Ionotropic glutamate receptors are members of a large family of plasma membrane proteins expressed by cells of the nervous system. Upon binding glutamate, the receptors transiently open transmembrane channels that allow the entry of sodium ions. The resulting changes in the transmembrane potential of the cell initiates a process that is involved in signal transmission to another cell. The binding of glutamic acid triggers the channel opening in the microsecond time domain and the reversible inactivation (desensitization) of the receptors in the millisecond time region. The channel-opening mechanism of glutamate receptors was investigated in rat hippocampal neurons voltage-clamped to -60 mV at room temperature and pH 7.4. Two rapid chemical reaction techniques were used: (1) a cell-flow method with a 4-10 ms time resolution to apply L-glutamate and (2) a laser-pulse photolysis technique to release glutamate from gamma-O-(alpha-carboxy-2-nitrobenzyl)glutamate (alphaCNB-caged L-glutamate) with a time constant of 30 micros. The rate and equilibrium constants for channel opening were determined. The results are consistent with the receptor binding two molecules of glutamic acid before the channel opens, with an apparent dissociation constant of 600 microM. Channel opening and closing rate constants, k(op) and k(cl), were determined to be (9.5 +/- 1) x 10(3) s(-1) and (1.1 +/- 0.1) x 10(3) s(-1), respectively. The value of the channel-opening equilibrium constant, Phi (=k(op)/k(cl)), was 8.6 when determined by laser-pulse photolysis and 6.6 in cell-flow experiments. The results suggest that there are at least two forms of glutamate receptors in rat hippocampal neurons that desensitize with different rates. At a concentration of 500 microM glutamate, 80% of the receptors desensitized with a rate of approximately 200 s(-1) and 20% with a rate of approximately 50 s(-1).