Hydrophobic amino acids, rather than glutamate, activate the Arabidopsis glutamate receptor homolog AtGLR1.4.

The family of ionotropic glutamate receptors includes 2 subunits, delta1 and delta2, the physiological relevance of which remains poorly understood. Both are nonfunctional in heterologous expression systems, although the isolated, crystallized ligand binding domain (LBD) of delta2 is capable of binding D-serine. To investigate these seemingly contradictory observations we tested whether delta receptors can be ligand gated at all. We used a strategy that replaced the native LBD of delta2 by a proven glutamate-binding LBD. Test transplantations between α-amino-3-hydroxy-5-methylisoxazole propionate (AMPA) and kainate receptors (GluR1 and GluR6, respectively) showed that this approach can produce functional chimeras even if only one part of the bipartite LBD is swapped. Upon outfitting delta2 with the LBD of GluR6, the chimera formed glutamate-gated ion channels with low Ca2+ permeability and unique rectification properties. Ligand-induced conformational changes can thus gate delta2, suggesting that the LBD of this receptor works fundamentally differently from that of other ionotropic glutamate receptors.

The N-methyl-d-aspartate (NMDA) receptors are the most complex members in the family of ionotropic glutamate receptors. They are involved in long-term potentiation and underlie higher cognitive functions like memory formation and learning. On the other hand, overstimulation of NMDA receptors (NMDARs), leading to a massive influx of Ca2+ ions into the cell, is linked to neurodegenerative disorders such as for example Huntington’s disease and epilepsy. NMDARs are generally considered to be heteromeric tetramers and are conventionally thought to assemble from NR1 splice variants and NR2 subunits, which determine crucial channel properties. With the recent discovery of the functionally different NR3 subunits, many of the known features of NMDARs are being reassessed: The presence of NR3 in NMDARs decreases Mg2+ sensitivity and Ca2+ permeability and reduces agonist-induced current responses. Between altering those essential key characteristics of conventional NMDARs and forming a new class of excitatory glycine receptors when coassembling with NR1, the NR3 subunits give rise to a functionally entirely new array of “NMDA” receptors. Understanding the multifaceted influence of NR3 is imperative to further the understanding of the complex role of NMDARs in neurotransmission and higher brain functions.

The two delta receptor subunits remain the most puzzling enigma within the ionotropic glutamate receptor family. Despite the recent elucidation of the ligand-binding domain structure of delta2, many fundamental questions with regard to the subunits’ mechanism of function still remain unanswered. Of necessity, the majority of studies on delta receptors focused on the metabotropic function of delta2, since electrophysiological approaches to date are limited to the characterization of spontaneous currents through the delta2-lurcher mutant. Indeed, accumulated evidence primarily from delta2-deficient transgenic mice suggest that major physiological roles of delta2 are mediated via metabotropic signaling by the subunit’s C terminus. Why then would the subunits retain a conserved ion channel domain if they do not form functional ion channels? Any progress with regard to ionotropic function of the two delta subunits has been hampered by their largely unknown pharmacology. Even now that a pharmacological profile for delta2 is being established on the basis of the ligand-binding domain structure, wild-type delta2 channels in heterologous expression systems stay closed in the presence of molecules that have been demonstrated to bind to the receptor’s ligand-binding domain. In this paper, we review the current knowledge of delta subunits focusing on the disputed ionotropic function.

N-methyl-d-aspartate (NMDA) receptors of many different vertebrates have been characterized in the past. However, little information is available about amphibian NMDA receptors. Here, we investigated the South African clawed frog Xenopus laevis NR1 subunit at the molecular and functional level. In this subunit, which is obligatory for functional NMDA receptor complexes, we found three exons, the N1, C1, and C3 cassettes, being alternatively spliced. Combinations of these cassettes generated six different splice variants, which were functionally characterized in oocytes. The Xenopus NR1 isoforms generally showed the same functional properties as their mammalian homologs when coexpressed with rat NR2B. In coexpression with Xenopus NR2B, however, some properties changed significantly. This included a Zn2+-mediated potentiation of current amplitudes for some subunit combinations which lasted for several minutes. This mechanism presents a novel form of Xenopus NMDA receptor modulation, possibly mediating a form of short-term potentiation in the Xenopus central nervous system.

Xenopus laevis oocytes are an outstanding heterologous expression system for the investigation of ion channels. However, oocytes express an amazing variety of endogenous ion channels that can severely interfere with electrophysiological measurements. It is therefore necessary to be aware of the channels present in the oocyte and to be able to exclude artifacts they might cause during the analysis of heterologously expressed ion channels. Research on Xenopus endogenous ion channels has started over 30 years ago, and many channels have been described since then. This does not only include voltage-gated channels conducting Na+, K+, Ca2+, and Cl−, but also ion channels activated by ligand binding such as ionotropic neurotransmitter receptors. Furthermore, there are other channels such as those triggered by changes in osmolarity or mechanical stress, as well as conductances caused by yet uncharacterized molecules. Here, we present an overview of ion channels endogenous to the oocyte described in the literature so far, and provide procedures and methods to abolish or minimize their impact on electrophysiological recordings of exogenous channels.

The involvement of neurotransmission in neuronal development is a generally accepted concept. Nevertheless, the precise regulation of neurotransmitter receptor expression is still unclear. To investigate the expression profiles of the most important ionotropic neurotransmitter receptors, namely GABAA receptors (GABAARs), NMDA receptors (NMDARs), and AMPA receptors (AMPARs), quantitative RT-PCR, immunoblot analysis and patch clamp studies were performed in in vitro-generated neural stem cells (NSCs). This clearly defined cell line is closely related to radial glia cells, the stem cells in the neonate brain.We found functional GABAARs of the subunit composition α2, β3, and γ1 to be expressed. Unexpectedly, functional ionotropic glutamate receptors were absent. However, NSCs expressed the NMDAR subunits NR2A and NR3A, and the AMPAR subunit GluR4 at the protein level, and GluR3 at the mRNA level.The overexpression of functional NMDARs in NSCs led to an increased mRNA level of AMPAR subunits, indicating a role in synaptogenesis. Early neuronal markers remained unchanged. These data extend our knowledge about ionotropic neurotransmitter receptor expression during neuronal development and will aid further investigations on activity-dependent neurogenesis.

The two GluN3 subunits were the last NMDA receptor subunits to be cloned some 15 years ago. Strikingly, despite the steadily growing interest in their function, their physiological role remains elusive. The original billing as dominant-negative modulators of classical NMDA receptors composed of GluN1 and GluN2 subunits has given way to proposals of much more complex functions, including roles in synaptogenesis and synaptic plasticity. In addition, GluN3 subunits in the absence of GluN2 surprisingly assemble with GluN1 into excitatory glycine receptors. This review provides an overview of the unique spatial and temporal expression patterns of the GluN3 subunits, discusses proposed functions and physiological roles for receptors comprising these subunits, and briefly summarizes their putative involvement in several neural diseases.

Ionotropic glutamate receptors (iGluRs) are ligand-gated cation channels that mediate fast excitatory neurotransmission in the mammalian central nervous system. In the model plant Arabidopsis thaliana, a large family of 20 genes encoding proteins that share similarities with animal iGluRs in sequence and predicted secondary structure has been discovered. Members of this family, termed AtGLRs (A. thaliana glutamate receptors), have been implicated in root development, ion transport, and several metabolic and signalling pathways. However, there is still no direct proof of ligand-gated ion channel function of any AtGLR subunit. We used a domain transplantation technique to directly test whether the putative ion pore domains of AtGLRs can conduct ions. To this end, we transplanted the ion pore domains of 17 AtGLR subunits into rat α-amino-3-hydroxy-5-methyl-4-isoxazole propionate (GluR1) and kainate (GluR6) receptor subunits and tested the resulting chimaeras for ion channel function in the Xenopus oocyte expression system. We show that AtGLR1.1 and AtGLR1.4 have functional Na+-, K+-, and Ca2+-permeable ion pore domains. The properties of currents through the AtGLR1.1 ion pore match those of glutamate-activated currents, depolarisations, and glutamate-triggered Ca2+ influxes observed in plant cells. We conclude that some AtGLRs have functional non-selective cation pores.

Functional N-methyl-d-aspartate receptors NMDARs are thought to be heteromeric receptor complexes consisting of NR1 and NR2 subunits. However, recombinant NR1 subunits expressed in Xenopus oocytes assemble functional ion channels even without exogenous NR2 subunits and with a different pharmacology, suggesting a homomeric subunit stoichiometry. To explain this phenomenon, we screened oocytes for Xenopus NR2 subunits and found all four subunit-encoding mRNAs (XenNR2A–XenNR2D) to be present endogenously, with those encoding the XenNR2B subunit being particularly abundant. We cloned the full-length XenNR2B cDNA and co-expressed it with NR1 in oocytes. A detailed electrophysiological characterization revealed that the pharmacology of NR1/XenNR2B was identical with that of the presumed homomeric NMDARs expressed from NR1 subunits. By contrast, heteromeric receptors containing the rat NR2B subunit showed significant pharmacological differences compared with NR1/XenNR2B receptors. These results demonstrate that recombinant NR1 subunits expressed in Xenopus oocytes interact with an endogenously expressed NR2B subunit and form hybrid heteromeric NMDARs. These findings confirm the current views that NMDARs are obligatory heteromeric complexes and that functional homomeric NMDARs do not exist.

AMPA receptors (AMPARs) mediate the majority of fast synaptic transmission in the CNS of vertebrates. They are believed to be associated with members of the transmembrane AMPA receptor regulatory protein (TARP) family. TARPs mediate the delivery of AMPA receptors to the plasma membrane and mediate their synaptic trafficking. Moreover, TARPs modulate essential electrophysiological properties of AMPA receptors. Here, we compare the influence of rat TARPs (γ2, γ3, γ4, and γ8) on pharmacological properties of rat GluR1(Q)flip. We show that agonist potencies are increased by all TARPs, but to individually different extents. On the other hand, all TARPs increase agonist potencies at the virtually non-desensitizing mutant GluR1-L479Y almost identically. Comparison of the influence of individual TARPs on relative agonist efficacies confirmed that the TARPs can be functionally subdivided into two subgroups, one consisting of γ2 and γ3 and one consisting of γ4 and γ8. Surprisingly, we found that TARPs convert certain AMPA receptor antagonists to agonists. The potency of one of these converted antagonists is dependent on the particular TARP. Moreover, TARPs (except γ4) reduce the ion channel block by the synthetic Joro spider toxin analog 1-naphthylacetyl spermine (NASP). In addition, TARPs increase the permeability of the receptor to calcium, indicating that TARPs directly modulate important ion pore properties. In summary, the data presented herein will illustrate and help to understand the previously unexpected complexities of modulation of AMPA receptor pharmacological properties by TARPs.

The AMPA receptors are ligand-gated ion channels belonging to the family of ionotropic glutamate receptors. They play an essential role in fast excitatory synaptic transmission in the CNS of vertebrates. Their activity-dependent directed transport and fast turnover at the plasma membrane contribute to synaptic plasticity and require numerous trafficking and scaffolding proteins. Participating in the delivery and synaptic localization of AMPA receptors is a recently discovered protein family named transmembrane AMPA receptor regulatory proteins (TARPs). In addition to their function in trafficking, TARPs alter the biophysical properties of AMPA receptors in remarkable ways and thus contribute significantly to the functional plasticity of the synapse. The study of TARP-mediated functional plasticity of AMPA receptors, which has emerged only recently as a hot new field, promises to yield valuable insight into the regulation of neuronal communication.

Xenopus laevis oocytes are commonly used as a heterologous expression system for the electrophysiological characterization of ionotropic glutamate receptors (iGluRs). Recently, however, several glutamate receptor subunits of the N-methyl-d-aspartate receptor subfamily have been found to be expressed endogenously in Xenopus oocytes, thus limiting the use of this expression system for such receptors. We therefore screened oocytes for the Xenopus homologs of all iGluR subunits known to be expressed in mammals to investigate which additional subunits may be present endogenously in oocytes and what, if any, influence such proteins might have on the functional analysis of heterologously expressed receptors. We found Xenopus homologs of every mammalian iGluR subunit to be expressed at the mRNA level. We then cloned, from oocytes, full-length copies of the four Xenopus α-amino-3-hydroxy-5-methyl-4-isoxazole propionate receptor subunits XenGluR1 through XenGluR4 and, additionally, XenGluR6 as a representative subunit for the kainate receptor subfamily and electrophysiologically characterized them. Upon analysis, we found only minor functional differences between homologous subunits from Xenopus and rat. Next, we investigated whether endogenous iGluR subunits can be detected electrophysiologically in oocytes. We found no indication for any functional glutamate receptors in native oocytes; however, after heterologous expression of the auxiliary subunit stargazin, endogenous α-amino-3-hydroxy-5-methyl-4-isoxazole propionate receptors were detected. These data demonstrate that Xenopus oocytes express glutamate receptor subunits endogenously, albeit at very low levels. Such endogenous receptor proteins can, under certain circumstances, become electrophysiologically detectable and then might influence electrophysiological recordings performed on recombinant receptors in oocytes.