Tuning activation of the AMPA-sensitive GluR2 ion channel by genetic adjustment of agonist-induced conformational changes

Tyr702 is an important determinant of agonist binding and domain closure of the ligand-binding core of GluR2

Ionotropic glutamate receptors mediate most rapid excitatory synaptic transmission in the mammalian central nervous system, and their involvement in neurological diseases has stimulated widespread interest in their structure and function. Despite a large number of agonists developed so far, few display selectivity among (S)-2-amino-3-(3-hydroxy-5-methylisoxazol-4-yl) propionic acid (AMPA)-receptor subtypes. The present study provides X-ray structures of the glutamate receptor 2 (GluR2)-selective partial agonist (S)-2-amino-3-(1,3,5,6,7-pentahydro-2,4-dioxocyclopenta[e] pyrimidin-1-yl) propanoic acid [(S)-CPW399] in complex with the ligand-binding core of GluR2 (GluR2-S1S2J) and with a (Y702F)GluR2-S1S2J mutant. In addition, the structure of the nonselective partial agonist kainate in complex with (Y702F)GluR2-S1S2J was determined. The results show that the selectivity of (S)-CPW399 toward full-length GluR2 relative to GluR3 is reflected in the binding data on the two soluble constructs, allowing the use of (Y702F)GluR2-S1S2J as a model system for studying GluR2/GluR3 selectivity. Structural comparisons suggest that selectivity arises from disruption of a water-mediated network between ligand and receptor. A D1-D2 domain closure occurs upon agonist binding. (S)-CPW399 and kainate induce greater domain closure in the Y702F mutant, indicating that these partial agonists here act in a manner more reminiscent of full agonists. Both kainate and (S)-CPW399 exhibited higher efficacy at (Y702F)GluR2(Q)i than at wild-type GluR2(Q)i. Whereas an excellent correlation exists between domain closure and efficacy of a range of agonists at full-length GluR2 determined by electrophysiology in Xenopus laevis oocytes, a direct correlation between agonist induced domain closure of (Y702F)GluR2-S1S2J and efficacy at the GluR3 receptor is not observed. Although it clearly controls selectivity, mutation of this residue alone is insufficient to explain agonist-induced conformational rearrangements occurring in this variant.

Conformational Changes in the Ligand-binding Domain of a Functional Ionotropic Glutamate Receptor

Fluorescence resonance energy transfer was used to determine the structural changes in the extracellular ligand-binding segment in a functional glutamate receptor that contains the ligand-binding, transmembrane, and C-terminal segments. These studies indicate that the structural changes previously reported for the isolated ligand-binding domain due to the binding of partial and full agonists are also observed in this functional receptor, thus validating the detailed structure-function relationships that have been previously developed based on the structure of the isolated ligand-binding domain. Additionally, these studies provide the first evidence that there are no significant changes in the extent of cleft closure between the activated and desensitized states of the glutamate bound form of the receptor consistent with the previous functional investigations, which suggest that desensitization is mediated primarily by changes in the interactions between subunits composing the receptor.

Low-mode docking search in iGluR homology models implicates three residues in the control of ligand selectivity

Homology models of the ionotropic rat kainate receptor iGluR6, based on the ligand binding domains of iGluR2, were constructed. A systematic analysis by low-mode docking searches of kainic acid in homology models of the native iGluR6 receptor, chimeric (iGluR2 and iGluR6) receptors and mutant receptors have identified three residues which influence the conformation of kainic acid in the binding core and hence the affinity for kainic acid. These residues are Leu650, Thr649 and Leu704, all located in domain 2. Leu650 has previously been implicated in the control of selectivity of iGluR2. However, this is the first report that suggests that Thr649 and Leu704 play a role in receptor selectivity.

Crystal structures of the GluR5 and GluR6 ligand binding cores: molecular mechanisms underlying kainate receptor selectivity

Little is known about the molecular mechanisms underlying differences in the ligand binding properties of AMPA, kainate, and NMDA subtype glutamate receptors. Crystal structures of the GluR5 and GluR6 kainate receptor ligand binding cores in complexes with glutamate, 2S,4R-4-methylglutamate, kainate, and quisqualate have now been solved. The structures reveal that the ligand binding cavities are 40% (GluR5) and 16% (GluR6) larger than for GluR2. The binding of AMPA- and GluR5-selective agonists to GluR6 is prevented by steric occlusion, which also interferes with the high-affinity binding of 2S,4R-4-methylglutamate to AMPA receptors. Strikingly, the extent of domain closure produced by the GluR6 partial agonist kainate is only 3 degrees less than for glutamate and 11 degrees greater than for the GluR2 kainate complex. This, together with extensive interdomain contacts between domains 1 and 2 of GluR5 and GluR6, absent from AMPA receptors, likely contributes to the high stability of GluR5 and GluR6 kainate complexes.

Effects of the lurcher mutation on GluR1 desensitization and activation kinetics

Previous studies of the lurcher mutation in GluR1 channels concluded that its main effect is to create constitutively active channels (Kohda et al., 2000; Taverna et al., 2000). GluR1Lc channels also exhibit slowed kinetics and a shift in their apparent affinity for glutamate (Kohda et al., 2000; Taverna et al., 2000). Here, we have undertaken a kinetic analysis of GluR1Lc channels to quantify the effects of lurcher and to determine the relative contribution of these effects to the lurcher phenotype. Analysis of GluR1Lc leak current demonstrated that the 2,3-dioxo-6-nitro-1,2,3,4-tetrahydro[f]quinoxaline-7-sulfonamide (NBQX)-sensitive portion of the leak current corresponded to a current generated by glutamate concentrations similar to the levels of contaminating glutamate measured in our normal external solutions. This result, and the small size of the leak current relative to the currents evoked by saturating glutamate, indicates that GluR1Lc channels exhibit little or no constitutive activity. Our results indicate that the primary effect of the lurcher mutation is to increase the affinity of GluR1 for glutamate and reduce the desensitization of GluR1 at nanomolar concentrations. We also found that the mutation makes both the rate and extent of GluR1Lc channel desensitization depend strongly on subunit occupancy. We conclude that the poor survival of GluR1Lc-transfected cells, and presumably cerebellar neurons in lurcher mice, results because channels carrying the lurcher mutation open and do not desensitize at ambient levels of glutamate.

Structural dynamics of an ionotropic glutamate receptor

Ionotropic glutamate receptors (iGluRs) are postsynaptic ion channels involved in excitatory neurotransmission. iGluRs play important roles in development and in forms of synaptic plasticity that underlie higher order processes such as learning and memory. Neurobiological and biochemical studies have long characterized iGluRs in detail. However, the structural basis for the function of iGluRs has not yet been investigated, because there is insufficient information about their three-dimensional structures. In 1998, a crystal structure called S1S2 lobes was first solved for the extracellular bilobed ligand-binding domain of the GluR2 subunit. Since then, the crystal structures for the S1S2 lobes both in the apo and in various liganded states have been reported, and recent biophysical studies have further elucidated the dynamic aspects of the structure of the S1S2 lobes. In this review, the dynamic structures of the S1S2 lobes and their ligands are summarized, and the importance of their structural flexibility and fluctuation is discussed in light of the mechanisms of ligand recognition, activation, and desensitization of the receptor.

Chemistry and Conformation of the Ligand-binding Domain of GluR2 Subtype of Glutamate Receptors

In the present report, using vibrational spectroscopy we have probed the ligand-protein interactions for full agonists (glutamate and alpha-amino-5-methyl-3-hydroxy-4-isoxazole propionate (AMPA)) and a partial agonist (kainate) in the isolated ligand-binding domain of the GluR2 subunit of the glutamate receptor. These studies indicate differences in the strength of the interactions of the alpha-carboxylates for the various agonists, with kainate having the strongest interactions and glutamate having the weakest. Additionally, the interactions at the alpha-amine group of the agonists have also been probed by studying the environment of the non-disulfide-bonded Cys-425, which is in close proximity to the alpha-amine group. These investigations suggest that the interactions at the alpha-amine group are stronger for full agonists such as glutamate and AMPA as evidenced by the increase in the hydrogen bond strength at Cys-425. Partial agonists such as kainate do not change the environment of Cys-425 relative to the apo form, suggesting weak interactions at the alpha-amine group of kainate. In addition to probing the ligand environment, we have also investigated the changes in the secondary structure of the protein. Results clearly indicate that full agonists such as glutamate and AMPA induce similar secondary structural changes that are different from those of the partial agonist kainate; thus, a spectroscopic signature is provided for identifying the functional consequences of a specific ligand binding to this protein.

AMPA receptor ligands: Synthetic and pharmacological studies of polyamines and polyamine toxins

Alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) receptors (AMPAR), subtype of the ionotropic glutamate receptors (IGRs), mediate fast synaptic transmission in the central nervous system (CNS), and are involved in many neurological disorders, as well as being a key player in the formation of memory. Hence, ligands affecting AMPARs are highly important for the study of the structure and function of this receptor, and in this regard polyamine-based ligands, particularly polyamine toxins, are unique as they selectively block Ca2+ -permeable AMPARs. Indeed, endogenous intracellular polyamines are known to modulate the function of these receptors in vivo. In this study, recent developments in the medicinal chemistry of polyamine-based ligands are given, particularly focusing on the use of solid-phase synthesis (SPS) as a tool for the facile generation of libraries of polyamine toxin analogues. Moreover, the recent development of highly potent and very selective AMPAR ligands is described. Additionally, we provide a detailed account on the mechanism and site of action of AMPAR blockade by polyamine-based ligands, including examples of how these ligands are used as tools to study AMPAR, and a comparison with their action on other ionotropic receptors.

Comparison of Taurine- and Glycine-induced Conformational Changes in the M2-M3 Domain of the Glycine Receptor

In the ionotropic glutamate receptor, the global conformational changes induced by partial agonists are smaller than those induced by full agonists. However, in the pentameric ligand-gated ion channel receptor family, the structural basis of partial agonism is not understood. This study investigated whether full and partial agonists induce different conformation changes in the glycine receptor chloride channel (GlyR). A substituted cysteine accessibility analysis demonstrated previously that glycine binding induced an increase in surface accessibility of all residues from Arg(271) to Lys(276) in the M2-M3 domain of the homomeric alpha1 GlyR. Here we compare the surface accessibility changes induced by the full agonist, glycine, and the partial agonist, taurine. In GlyRs incorporating the A272C, S273C, L274C, or P275C mutation, the reaction rate of the cysteine-specific compound, methanethiosulfonate ethyltrimethylammonium, depended on how strongly the receptors were activated but was agonist-independent. Reaction rates could not be compared in the R271C and K276C mutant GlyRs because methanethiosulfonate ethyltrimethylammonium did not modify the extremely small currents induced by saturating taurine or equivalent low glycine concentrations. The results indicate that bound taurine and glycine molecules impose identical conformational changes to the M2-M3 domain. We therefore conclude that the higher efficacy of glycine is due to an increased ability to stabilize a common activated configuration.

Regulation of AMPA receptor gating by ligand binding core dimers

Ionotropic glutamate receptors are tetramers, the isolated ligand binding cores of which assemble as dimers. Previous work on nondesensitizing AMPA receptor mutants, which combined crystallography, ultracentrifugation, and patch-clamp recording, showed that dimer formation by the ligand binding cores is required for activation of ion channel gating by agonists. To define the mechanisms responsible for stabilization of dimer assembly in native AMPA receptors, contacts between the adjacent ligand binding cores were individually targeted by amino acid substitutions, using the GluR2 crystal structure as a guide to design mutants. We show that disruption of a salt bridge, hydrogen bond network, and intermolecular van der Waals contacts between helices D and J in adjacent ligand binding cores greatly accelerates desensitization. Conservation of these contacts in AMPA and kainate receptors indicates that they are important determinants of dimer stability and that the dimer interface is a key structural element in the gating mechanism of these glutamate receptor families.

Structure and Function of Glutamate Receptor Ion Channels

A vast number of proteins are involved in synaptic function. Many have been cloned and their functional role defined with varying degrees of success, but their number and complexity currently defy any molecular understanding of the physiology of synapses. A beacon of success in this medieval era of synaptic biology is an emerging understanding of the mechanisms underlying the activity of the neurotransmitter receptors for glutamate. Largely as a result of structural studies performed in the past three years we now have a mechanistic explanation for the activation of channel gating by agonists and partial agonists; the process of desensitization, and its block by allosteric modulators, is also mostly explained; and the basis of receptor subtype selectivity is emerging with clarity as more and more structures are solved. In the space of months we have gone from cartoons of postulated mechanisms to hard fact. It is anticipated that this level of understanding will emerge for other synaptic proteins in the coming decade.

Emerging structural explanations of ionotropic glutamate receptor function

High-resolution studies of ionotropic glutamate receptor (iGluR) extracellular domains are beginning to bridge the gap between structure and function. Crystal structures have defined the ligand binding pocket well beyond what was suggested by mutational analysis and homology models alone, providing initial suggestions about the mechanisms of channel gating and desensitization. NMR-derived backbone dynamics and molecular dynamics simulations have added further insights into the role of protein dynamics in receptor function. As a whole, the current knowledge of iGluR structure in conjunction with new advances in the understanding of K+ channels provides a vastly improved understanding of iGluR function. This review focuses on structural and dynamic studies of the extracellular ligand binding domain of iGluRs and the pore region of K+ channels that have contributed to mechanistic insights into the processes of iGluR gating and desensitization

Locking the dimeric GABA(B) G-protein-coupled receptor in its active state

G-protein-coupled receptors (GPCRs) play a major role in cell-cell communication in the CNS. These proteins oscillate between various inactive and active conformations, the latter being stabilized by agonists. Although mutations can lead to constitutive activity, most of these destabilize inactive conformations, and none lock the receptor in an active state. Moreover, GPCRs are known to form dimers, but the role of each protomer in the activation process remains unclear. Here, we show that the heterodimeric GPCR for the main inhibitory neurotransmitter, the GABA(B) receptor, can be locked in its active state by introducing two cysteines expected to form a disulphide bridge to maintain the binding domain of the GABA(B1) subunit in a closed form. This constitutively active receptor cannot be inhibited by antagonists, but its normal functioning, activation by agonists, and inhibition by antagonists can be restored after reduction with dithiothreitol. These data show that the closed state of the binding domain of GABA(B1) is sufficient to turn ON this heterodimeric receptor and illustrate for the first time that a GPCR can be locked in an active conformation.

Ionotropic Glutamate Receptor Recognition and Activation

Ionotropic glutamate receptors are the major excitatory neurotransmitters in mammalian brain but are found throughout the animal kingdom as well as in plants and bacteria. A great deal of progress in understanding the structure of these essential neurotransmitter receptors has been made since the first examples were cloned and sequenced in 1989. The atomic structure of the ligand-binding domain of several ionotropic glutamate receptors has been determined, and a great deal of progress has been made in relating the structural properties of the binding site to the function of the intact receptor. In addition, the identification of glutamate receptors from a wide variety of organisms ranging from several types of bacteria to Arabidopsis to a range of animal species has made glutamate receptors a molecular laboratory for studying the evolution of proteins. The fact that glutamate receptors are a particularly ancient intercellular signaling molecule suggests a potential role in the transition from single celled to multicellular organisms. This review focuses on the structure and dynamics of ionotropic glutamate receptors and their relation to the function and evolution of these proteins.

ATP binding at human P2X1 receptors. Contribution of aromatic and basic amino acids revealed using mutagenesis and partial agonists

P2X receptors comprise a family of ATP-gated ion channels with the basic amino acids Lys-68, Arg-292, and Lys-309 (P2X(1) receptor numbering) contributing to agonist potency. In many ATP-binding proteins aromatic amino acids coordinate the binding of the adenine group. There are 20 conserved aromatic amino acids in the extracellular ligand binding loop of at least 6 of the 7 P2X receptors. We used alanine replacement mutagenesis to determine the effects of individual conserved aromatic residues on the properties of human P2X(1) receptors expressed in Xenopus oocytes. ATP evoked concentration-dependent (EC(50) approximately 1 microm) desensitizing currents at wild-type receptors and for the majority of mutants there was no change (10 residues) or a <6-fold decrease in ATP potency (6 mutants). Mutants F195A and W259A failed to form detectable channels at the cell surface. F185A and F291A produced 10- and 160-fold decreases in ATP potency. The partial agonists 2',3'-O-(4-benzoyl)-ATP (BzATP) and P(1),P(5)-di(adenosine 5')-pentaphosphate (Ap(5)A) were tested on a range of mutants that decreased ATP potency to determine whether this resulted predominantly from changes in agonist binding or gating of the channel. At K68A and K309A receptors BzATP and Ap(5)A had essentially no agonist activity but antagonized, or for R292A potentiated, ATP responses. At F185A receptors BzATP was an antagonist but Ap(5)A no longer showed affinity for the receptor. These results suggest that residues Lys-68, Phe-185, Phe-291, Arg-292, and Lys-309 contribute to ligand binding at P2X(1) receptors, with Phe-185 and Phe-291 coordinating the binding of the adenine ring of ATP.

Selective agonist binding of (S)-2-amino-3-(3-hydroxy-5-methyl-4-isoxazolyl)propionic acid (AMPA) and 2S-(2alpha,3beta,4beta)-2-carboxy-4-(1-methylethenyl)-3-pyrrolidineacetic acid (kainate) receptors: a molecular modeling study

Molecular models were constructed, using the published X-ray structure of rat glutamate receptor 2 (GluR2), for the ligand-binding domains of the human (S)-2-amino-3-(3-hydroxy-5-methyl-4-isoxazolyl)propionic acid (AMPA)- and kainate-selective ionotropic glutamate receptors (iGluRs): GluR1-7 and KA1-2. Based on the analysis of the known X-ray structures of GluR2 in complex with glutamate, kainate, and AMPA, we have constructed binding motifs (relative positioning of a ligand in the binding site and the physico-chemical interactions that take place) for selected agonist ligands and found explanations for ligand-binding selectivity to homomeric receptors among the different iGluRs. Even a single sequence difference can explain significant differences in ligand-binding affinities between two receptors. In total, there are seven residues surrounding the binding cavity that affect agonist selectivity: in GluR2, these residues are Pro478, Thr480, Leu650, Ser654, Thr686, Tyr702, and Met708. Each of these seven positions has been shown, or is predicted, to influence the presence of one or more water molecules that, when present, may form bridging hydrogen bonds between particular ligands and receptors. By using this knowledge it should be possible to design new selective agonist ligands with high affinity for any AMPA/kainate receptor.

How fast does the GluR1Qflip channel open?

Opening of a ligand-gated ion channel is the step at which the binding of a neurotransmitter is transduced into the electrical signal by allowing ions to flow through the transmembrane channel, thereby altering the postsynaptic membrane potential. We report the kinetics for the opening of the GluR1Qflip channel, an alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor subunit of the ionotropic glutamate receptors. Using a laser-pulse photolysis technique that permits glutamate to be liberated photolytically from gamma-O-(alpha-carboxy-2-nitrobenzyl)glutamate (caged glutamate) with a time constant of approximately 30 micros, we show that, after the binding of glutamate, the channel opened with a rate constant of (2.9 +/- 0.2) x 10(4) s(-1) and closed with a rate constant of (2.1 +/- 0.1) x 10(3) s(-1). The observed shortest rise time (20-80% of the receptor current response), i.e. the fastest time by which the GluR1Qflip channel can open, was predicted to be 35 micros. This value is three times shorter than those previously reported. The minimal kinetic mechanism for channel opening consists of binding of two glutamate molecules, with the channel-opening probability being 0.93 +/- 0.10. These findings identify GluR1Qflip as one of the temporally efficient receptors that transduce the binding of chemical signals (i.e. glutamate) into an electrical impulse.

Structural basis for partial agonist action at ionotropic glutamate receptors

An unresolved problem in understanding neurotransmitter receptor function concerns the mechanism(s) by which full and partial agonists elicit different amplitude responses at equal receptor occupancy. The widely held view of 'partial agonism' posits that resting and active states of the receptor are in equilibrium, and partial agonists simply do not shift the equilibrium toward the active state as efficaciously as full agonists. Here we report findings from crystallographic and electrophysiological studies of the mechanism of activation of an AMPA-subtype glutamate receptor ion channel. In these experiments, we used 5-substituted willardiines, a series of partial agonists that differ by only a single atom. Our results show that the GluR2 ligand-binding core can adopt a range of ligand-dependent conformational states, which in turn control the open probability of discrete subconductance states of the intact ion channel. Our findings thus provide a structure-based model of partial agonism.