Characterization of mice with targeted deletion of glycine receptor alpha 2

Glycine receptors are ligand-gated chloride channels that mediate inhibitory neurotransmission in the adult nervous system. During development, glycine receptor alpha 2 (GlyRalpha2) is expressed in the retina, in the spinal cord, and throughout the brain. Within the cortex, GlyRalpha2 is expressed in immature cells and these receptors have been shown to be active and excitatory. In the developing retina, inhibition of glycine receptor activity prevents proper rod photoreceptor development. These data suggest that GlyRalpha2, the developmentally expressed glycine receptor, may play an important role in neuronal development. We have generated mice with a targeted deletion of glycine receptor alpha 2 (Glra2). Although these mice lack expression of GlyRalpha2, no gross morphological or molecular alterations were observed in the nervous system. In addition, the cerebral cortex does not appear to require glycine receptor activity for proper development, as Glra2 knockout mice did not show any electrophysiological responses to glycine.     

A role for ligand-gated ion channels in rod photoreceptor development

Neurotransmitter receptors are central to communication at synapses. Many components of the machinery for neurotransmission are present prior to synapse formation, suggesting a developmental role. Here, evidence is presented that signaling through glycine receptor alpha2 (GlyRalpha2) and GABA(A) receptors plays a role in photoreceptor development in the vertebrate retina. The signaling is likely mediated by taurine, which is present at high levels throughout the developing central nervous system (CNS). Taurine potentiates the production of rod photoreceptors, and this induction is inhibited by strychnine, an antagonist of glycine receptors, and bicuculline, an antagonist of GABA receptors. Gain-of-function experiments showed that signaling through GlyRalpha2 induced exit from mitosis and an increase in rod photoreceptors. Furthermore, targeted knockdown of GlyRalpha2 decreased the number of photoreceptors while increasing the number of other retinal cell types. These data support a previously undescribed role for these ligand-gated ion channels during the early stages of CNS development.     

The intracellular amino terminus plays a dominant role in desensitization of ATP-gated P2X receptor ion channels

P2X receptors show marked variations in the time-course of response to ATP application from rapidly desensitizing P2X1 receptors to relatively sustained P2X2 receptors. In this study we have used chimeras between human P2X1 and P2X2 receptors in combination with mutagenesis to address the contribution of the extracellular ligand binding loop, the transmembrane channel, and the intracellular regions to receptor time-course. Swapping either the extracellular loop or both transmembrane domains (TM1 and -2) between the P2X1 and P2X2 receptors had no effect on the time-course of ATP currents in the recipient receptor. These results suggest that the agonist binding and channel-forming portions of the receptor do not play a major role in the control of the time-course. In contrast replacing the amino terminus of the P2X1 receptor with that from the non-desensitizing P2X2 receptor (P2X1-2N) slowed desensitization, and the mirror chimera induced rapid desensitization in the P2X2-1N chimera. These reciprocal effects on time-course can be replicated by changing four variant amino acids just before the first transmembrane (TM1) segment. These pre-TM1 residues also had a dominant effect on chimeras where both TMs had been transferred; mutating the variant amino acids 21-23 to those found in the P2X2 receptor removed desensitization from the P2X1-2TM1/-2 chimera, and the reciprocal mutants induced rapid desensitization in the non-desensitizing P2X2-1TM1/-2 chimera. These results suggest that the intracellular amino terminus, in particular the region just before TM1, plays a dominant role in the regulation of the time-course of ATP evoked P2X receptor currents.     

The interaction of general anaesthetics and neurosteroids with GABA(A) and glycine receptors.

The positive allosteric effects of four structurally distinct general anaesthetics (propofol, pentobarbitone, etomidate and 5alpha-pregnan-3alpha-ol-20-one [5alpha3alpha]) upon recombinant GABA(A) (alpha6beta3gamma2L), invertebrate GABA (RDL) and glycine (alpha1) receptors expressed in Xenopus laevis oocytes have been determined. Propofol and pentobarbitone enhanced agonist (GABA or glycine as appropriate) evoked currents at GABA(A), glycine, and RDL receptors, whereas etomidate and 5alpha3alpha were highly selective for the GABA(A) receptor. Utilizing site-directed mutagenesis, we demonstrate that the nature of the interaction of propofol, pentobarbitone and etomidate (but not 5alpha3alpha) with mammalian and invertebrate ionotropic GABA receptors depends critically upon the nature of a single amino acid located in the second transmembrane region (TM2) of these receptors. These data are discussed in relation to the specificity of action of general anaesthetics.     

Need rods? Get glycine receptors and taurine

Taurine, a multifunctional amino acid prevalent in developing nervous tissues, regulates the number of rod photoreceptors in developing postnatal rodent retina. In this issue of Neuron, Young and Cepko show that taurine acts via GlyRalpha2 subunit-containing glycine receptors expressed by retinal progenitor cells at birth.     

Cross-linking of sites involved with alcohol action between transmembrane segments 1 and 3 of the glycine receptor following activation

The glycine receptor is a member of the Cys-loop, ligand-gated ion channel family and is responsible for inhibition in the CNS. We examined the orientation of amino acids I229 in transmembrane 1 (TM1) and A288 in TM3, which are both critical for alcohol and volatile anesthetic action. We mutated these two amino acids to cysteines either singly or in double mutants and expressed the receptors in Xenopus laevis oocytes. We tested whether disulfide bonds could form between A288C in TM3 paired with M227C, Y228C, I229C, or S231C in TM1. Application of cross-linking (mercuric chloride) or oxidizing (iodine) agents had no significant effect on the glycine response of wild-type receptors or the single mutants. In contrast, the glycine response of the I229C/A288C double mutant was diminished after application of either mercuric chloride or iodine only in the presence of glycine, indicating that channel gating causes I229C and A288C to fluctuate to be within 6 Å apart and form a disulfide bond. Molecular modeling was used to thread the glycine receptor sequence onto a nicotinic acetylcholine receptor template, further demonstrating that I229 and A288 are near-neighbors that can cross-link and providing evidence that these residues contribute to a single binding cavity.     

Functional correlation of fetal and adult forms of glycine receptors with developmental changes in inhibitory synaptic receptor channels.

Functional maturation of the nicotinic acetylcholine receptor is executed by its gamma-to-epsilon subunit switching. The glycine receptor also has fetal (alpha 2) and adult (alpha 1) isoforms. However, whether subunit switching is responsible for developmental changes in glycine receptor function is not known. We recorded single-channel currents from homomeric glycine receptors expressed in Xenopus oocytes with cRNAs encoding the alpha 2 or alpha 1 subunits and compared them with those recorded from native glycine receptors in rat spinal neurons at various ontogenic periods. The mean channel life times of the alpha 1 and mature glycine receptors were equally short, whereas both the alpha 2 and fetal receptors showed a significantly longer open time. Consistent with these results, the decay time of the glycinergic inhibitory postsynaptic currents (IPSCs) in spinal neurons became shorter during postnatal development. We conclude that developmental switching of alpha subunits may accelerate the kinetics of IPSCs.     

Ethanol inhibition of N-methyl-D-aspartate receptors is reduced by site-directed mutagenesis of a transmembrane domain phenylalanine residue

N-Methyl-D-aspartate (NMDA) receptors (NRs) are ionotropic receptors activated by glutamate and the co-agonist glycine. Ethanol inhibits NMDA receptor function, although its site of action is undefined. We hypothesized that ethanol acts at specific amino acids contained within the transmembrane (TM) domains of the receptor. In this study, NR1 and NR2A subunits were altered by mutagenesis and tested for sensitivity to ethanol. Three NR1 mutants (W636A, F817A, and L819A) and one NR2A mutant (F637A) failed to generate functional receptors. Pre-TM1 (I546A, L551A, F554A, and F558A), TM1 (W563A), and TM2 (W611A) NR1 mutations did not affect ethanol sensitivity of heteromeric receptors. In contrast, altering a TM3 phenylalanine to alanine (F639A) reduced the ethanol inhibition of NMDA receptors expressed in oocytes and human embryonic kidney 293 cells. Mutation of the nearby methionine (M641) to alanine did not affect ethanol sensitivity, whereas changing Phe(639) to tryptophan slightly enhanced ethanol inhibition. NR1(F639A) did not alter the agonist potency of glutamate but did produce a leftward shift in the glycine concentration response for receptors containing NR2A and NR2B subunits. NR1(F639A) also reduced the potency of the competitive glycine antagonist 5,7-dichlorokynurenic acid and increased the efficacy of the glycine partial agonist 3-amino-1-hydroxy-2-pyrrolidinone ((+)-HA-966). These results suggest that ethanol may interact with amino acids contained in the TM3 domain of NMDA subunits that are involved in transducing agonist binding to channel opening.     

Asymmetric cross-inhibition between GABAA and glycine receptors in rat spinal dorsal horn neurons

Presynaptic nerve terminals of inhibitory synapses in the dorsal horn of the spinal cord and brain stem can release both GABA and glycine, leading to coactivation of postsynaptic GABAA and glycine receptors. In the present study we have analyzed functional interactions between GABAA and glycine receptors in acutely dissociated neurons from rat sacral dorsal commissural nucleus. Although the application of GABA and glycine activates pharmacologically distinct receptors, the current induced by a simultaneous application of these two transmitters was less than the sum of currents induced by applying two transmitters separately. Sequential application of glycine and GABA revealed that the GABA-evoked current is more affected by glycine than glycine-evoked responses by GABA. Activation of glycine receptors decreased the amplitude and accelerated the rate of desensitization of GABA-induced currents. This asymmetric cross-inhibition is reversible, dependent on the agonist concentration applied, but independent of both membrane potential and intracellular calcium concentration or changes in the chloride equilibrium potential. During sequential applications, the asymmetric cross-inhibition was prevented by selective GABAA or glycine receptor antagonists, suggesting that occupation of binding sites did not suffice to induce glycine and GABAA receptors functional interaction, and receptor channel activation is required. Furthermore, inhibition of phosphatase 2B, but not phosphatase 1 or 2A, prevented GABAA receptor inhibition by glycine receptor activation, whereas inhibition of phosphorylation pathways rendered cross-talk irreversible. Taken together, our results demonstrated that there is an asymmetric cross-inhibition between glycine and GABAA receptors and that a selective modulation of the state of phosphorylation of GABAA receptor and/or mediator proteins underlies the asymmetry in the cross-inhibition.     

Molecular determinants of proton modulation of glycine receptors

Extracellular pH regulates glycine receptors through an unknown mechanism. Here we demonstrate that acidic pH remarkably inhibited glycine-activated whole-cell currents in recombinant glycine alpha1 and alpha1beta receptors transiently expressed in human embryonic kidney 293 cells. The proton effect was voltage-independent and pharmacologically competed with glycine receptor agonist glycine and antagonist strychnine. Using site-directed mutagenesis, we have identified an N-terminal domain that is essential for proton-induced inhibition of glycine current. In alpha1 homomers, removal of the hydroxyl group by mutation of residue Thr-112 to Ala or Phe abolished inhibition of glycine currents by acidification. In contrast, mutation of Thr-112 to another hydroxylated residue (Tyr) produced receptors that retained partial proton sensitivity. In alpha1beta heteromers, a single mutation of the beta subunit T135A, which is homologous to alpha1 Thr-112, reduced proton sensitivity, whereas the double mutation alpha1(T112A)beta(T135A) almost completely eliminated the proton sensitivity. In addition, the mutation alpha1 H109A greatly reduced sensitivity to protons in homomeric alpha1 receptors. The results demonstrate that extracellular pH can regulate the function of glycine alpha1 and alpha1beta receptors. An extracellular domain consisting of Thr-112 and His-109 at the alpha1 subunit and Thr-135 at the beta subunit plays a critical role in determining proton modulation of glycine receptor function.     

Amino acid volume and hydropathy of a transmembrane site determine glycine and anesthetic sensitivity of glycine receptors.

Two specific amino acid residues in transmembrane segments (TM) 2 and 3 are critical for the enhancement of glycine receptor (GlyR) function by volatile anesthetics. To determine which physicochemical characteristics of these sites determine their roles in anesthetic actions, an extensive series of single amino acid mutations at amino acid residue 288 (Ala-288) in TM3 of the alpha1 GlyR subunit was tested for modulation by volatile anesthetics. The mutations changed the apparent affinities of receptors for glycine; replacements with larger volumes and less hydropathy exhibited higher affinities for glycine. Potentiation by anesthetics was reduced by specific mutations at Ala-288. The molecular volume of the substituents was negatively correlated with the extent of potentiation by isoflurane, enflurane, and 1-chloro-1,2,2-trifluorocyclobutane, whereas there was no correlation between anesthetic enhancement and polarity, hydropathy, or hydrophilicity of substituents. In contrast to anesthetics, no correlation was found between the effects of the nonanesthetics 1,2-dichlorohexafluorocyclobutane or 2, 3-dichlorooctafluorobutane and any physicochemical property of the substituent. These results suggest that the molecular volume and hydropathy of the amino acid at position 288 in TM3 regulate glycine and anesthetic sensitivity of the GlyR and that this residue might represent one determinant of an anesthetic binding site.     

Functional impact of manipulation on the relative orientation of human prolactin receptor domains

Hormone binding creates active receptor dimers for class 1 cytokine receptors; however, the detailed molecular mechanism by which these receptors are activated by their ligands is not well characterized, and it is unknown if these receptors share common mechanisms. A rotation model has been proposed for the activation of human erythropoietin receptor and human growth hormone receptor and is supported by evidence showing that additions of alanine at the junction of the transmembrane (TM) and intracellular (IC) domains and/or within the TM domain influenced receptor activities. This evidence suggests that alanine additions changed the relative orientations of the IC domains and their subsequent activation. We wished to determine if a similar mechanism was at play with human prolactin receptor (hPRLr). Up to four alanines were added between the TM and either the IC or extracellular (EC) domains to extend the TM helix and to rotate the IC or EC domains. Also, up to four glycines were placed between the TM and IC domains to provide increased flexibility between these two domains. Wild-type hPRLr or various mutant receptors were expressed in human embryonic kidney 293T cells that express endogenous Janus kinase 2. In the absence of human prolactin (hPRL), none of the alanine or glycine additions increased the level of receptor phosphorylation above that of wild-type hPRLr. In the presence of hPRL, both wild-type hPRLr and each of the mutant receptors were successfully phosphorylated. These data do not support a rotation mechanism for hPRLr activation or a requirement of a fixed spatial relationship between the TM and IC domains for hPRLr activation. In a second set of experiments, both wild-type hPRLr and either alanine- or glycine-extended receptors were coexpressed in 293T cells. In the absence of hPRL, there was no detectable phosphorylation of hPRLr. Such data do not support a piston movement between the hPRLr pair in their activation.     

Alanine-scanning mutagenesis in the signature disulfide loop of the glycine receptor alpha 1 subunit: critical residues for activation and modulation

The glycine receptor enables the generation of inhibitory postsynaptic currents at synapses via neurotransmitter-dependent activation. These receptors belong to the ligand-gated ion channel gene superfamily, in which all members are comprised of five subunits, each of which possesses a signature 13-residue disulfide loop (Cys loop) in the extracellular domain. In this study, we used alanine-scanning mutagenesis of the residues between C138 and C152 of the Cys loop of the glycine receptor alpha1 subunit to identify residues critical for receptor activation and allosteric modulation. Mutation of L142, F145, or P146 to alanine produced decreases in the potency, maximal amplitude, and Hill coefficient for currents elicited by glycine and impaired receptor activation by the agonist taurine. These residues, along with D148, are positionally conserved in the family of LGIC subunits. Mutation at several other positions had little or no effect. The inhaled anesthetics halothane and isoflurane potentiate submaximal agonist responses at wild-type receptors, via an allosteric site. The mutations L142A, F145A, P146A, and D148A abolished positive modulation by these anesthetics, in some cases revealing a small inhibitory effect. A molecular model of the glycine receptor alpha1 subunit suggests that the Cys loop is positioned in a region of the receptor at the interface between the extracellular and transmembrane domains and that the critical functional residues identified here lie along the face of a predominantly hydrophobic surface. The present data implicate the Cys loop as an important functional moiety in the process of glycine receptor activation and allosteric regulation by anesthetics.     

Cl(-) concentration changes and desensitization of GABA(A) and glycine receptors

Desensitization of ligand-gated ion channels plays a critical role for the information transfer between neurons. The current view on γ-aminobutyric acid (GABA)(A) and glycine receptors includes significant rapid components of desensitization as well as cross-desensitization between the two receptor types. Here, we analyze the mechanism of apparent cross-desensitization between native GABA(A) and glycine receptors in rat central neurons and quantify to what extent the current decay in the presence of ligand is a result of desensitization versus changes in intracellular Cl(-) concentration ([Cl(-)](i)). We show that apparent cross-desensitization of currents evoked by GABA and by glycine is caused by changes in [Cl(-)](i). We also show that changes in [Cl(-)](i) are critical for the decay of current in the presence of either GABA or glycine, whereas changes in conductance often play a minor role only. Thus, the currents decayed significantly quicker than the conductances, which decayed with time constants of several seconds and in some cells did not decay below the value at peak current during 20-s agonist application. By taking the cytosolic volume into account and numerically computing the membrane currents and expected changes in [Cl(-)](i), we provide a theoretical framework for the observed effects. Modeling diffusional exchange of Cl(-) between cytosol and patch pipettes, we also show that considerable changes in [Cl(-)](i) may be expected and cause rapidly decaying current components in conventional whole cell or outside-out patch recordings. The findings imply that a reevaluation of the desensitization properties of GABA(A) and glycine receptors is needed.     

Point mutation in the first transmembrane region of the beta 2 subunit of the gamma--aminobutyric acid type A receptor alters desensitization kinetics of gamma--aminobutyric acid- and anesthetic-induced channel gating

A conserved glycine residue in the first transmembrane (TM1) domain of the beta2 subunit has been identified to be involved with desensitization induced by gamma-aminobutyric acid (GABA) and anesthetics. Recombinant GABA(A) receptors expressed in Sf9 cells were recorded using semi-fast agonist application. Upon direct activation by GABA or anesthetics, the main effect of the TM1 point mutation on the beta2 subunit (G219F) was to slow the time constant (tau) of desensitization. At GABA concentrations eliciting maximum currents, the corresponding median tau values were 0.87 s (25-75% interval (0.76; 1.04 s)), 0.93 s (0.76; 1.23 s), and 1.36 s (1.17; 1.57 s) for alpha1beta2gamma2, alpha1(G223F)beta2gamma2, and alpha1beta2(G219F)gamma2, respectively. The tau value for the beta2-mutant receptor was significantly longer than alpha1beta2gamma2 (p < 0.01) and alpha1(G223F)beta2gamma2 (p < 0.05). For pentobarbital-induced currents (500 microm), the corresponding median tau values were 1.36 s (0.81; 1.41 s), 1.47 s (1.31; 2.38 s), and 2.82 s (2.21; 5.56 s) for alpha1beta2gamma2, alpha1(G223F)beta2gamma2, and alpha1beta2(G219F)gamma2, respectively. The tau value for the beta2-mutant receptor was significantly longer than that for alpha1beta2gamma2 (p < 0.01). The present findings suggest that this TM1 glycine residue is critical for the rate at which desensitization occurs and that both GABA and intravenous anesthetics implement an analogous pathway for generating desensitization.     

The Importance of TM3-4 Loop Subdomains for Functional Reconstitution of Glycine Receptors by Independent Domains

Truncated glycine receptors that have been found in human patients suffering from the neuromotor disorder hyperekplexia or in spontaneous mouse models resulted in non-functional ion channels. Rescue of function experiments with the lacking protein portion expressed as a separate independent domain demonstrated restoration of glycine receptor functionality in vitro. This construct harbored most of the TM3-4 loop, TM4, and the C terminus and was required for concomitant transport of the truncated α1 and the complementation domain from the endoplasmic reticulum toward the cell surface, thereby enabling complex formation of functional glycine receptors. Here, the complementation domain was stepwise truncated from its N terminus in the TM3-4 loop. Truncation of more than 49 amino acids led again to loss of functionality in the receptor complex expressed from two independent domain constructs. We identified residues 357–418 in the intracellular TM3-4 loop as being required for reconstitution of functional glycine-gated channels. All complementation constructs showed cell surface protein expression and correct orientation according to glycine receptor topology. Moreover, we demonstrated that the truncations did not result in a decreased protein-protein interaction between both glycine receptor domains. Rather, deletions of more than 49 amino acids abolished conformational changes necessary for ion channel opening. When the TM3-4 loop subdomain harboring residues 357–418 was expressed as a third independent construct together with the truncated N-terminal and C-terminal glycine receptor domains, functionality of the glycine receptor was again restored. Thus, residues 357–418 represent an important determinant in the process of conformational rearrangements following ligand binding resulting in channel opening.     

Oligomerization, biogenesis, and signaling is promoted by a glycophorin A-like dimerization motif in transmembrane domain 1 of a yeast G protein-coupled receptor

G protein-coupled receptors (GPCRs) can form dimeric or oligomeric complexes in vivo. However, the functions and mechanisms of oligomerization remain poorly understood for most GPCRs, including the alpha-factor receptor (STE2 gene product) of the yeast Saccharomyces cerevisiae. Here we provide evidence indicating that alpha-factor receptor oligomerization involves a GXXXG motif in the first transmembrane domain (TM1), similar to the transmembrane dimerization domain of glycophorin A. Results of fluorescence resonance energy transfer, fluorescence microscopy, endocytosis assays of receptor oligomerization in living cells, and agonist binding assays indicated that amino acid substitutions affecting the glycine residues of the GXXXG motif impaired alpha-factor receptor oligomerization and biogenesis in vivo but did not significantly impair agonist binding affinity. Mutant receptors exhibited signaling defects that were not due to impaired cell surface expression, indicating that oligomerization promotes alpha-factor receptor signal transduction. Structure-function studies suggested that the GXXXG motif in TM1 of the alpha-factor receptor promotes oligomerization by a mechanism similar to that used by the GXXXG dimerization motif of glycophorin A. In many mammalian GPCRs, motifs related to the GXXXG sequence are present in TM1 or other TM domains, suggesting that similar mechanisms are used by many GPCRs to form dimers or oligomeric arrays.     

Nova-1 regulates neuron-specific alternative splicing and is essential for neuronal viability

We have combined genetic and biochemical approaches to analyze the function of the RNA-binding protein Nova-1, the paraneoplastic opsoclonus-myoclonus ataxia (POMA) antigen. Nova-1 null mice die postnatally from a motor deficit associated with apoptotic death of spinal and brainstem neurons. Nova-1 null mice show specific splicing defects in two inhibitory receptor pre-mRNAs, glycine alpha2 exon 3A (GlyRalpha2 E3A) and GABA(A) exon gamma2L. Nova protein in brain extracts specifically bound to a previously identified GlyRalpha2 intronic (UCAUY)3 Nova target sequence, and Nova-1 acted directly on this element to increase E3A splicing in cotransfection assays. We conclude that Nova-1 binds RNA in a sequence-specific manner to regulate neuronal pre-mRNA alternative splicing; the defect in splicing in Nova-1 null mice provides a model for understanding the motor dysfunction in POMA.     

Channel gating of the glycine receptor changes accessibility to residues implicated in receptor potentiation by alcohols and anesthetics

The glycine receptor is a target for both alcohols and anesthetics, and certain amino acids in the alpha1 subunit transmembrane segments (TM) are critical for drug effects. Introducing larger amino acids at these positions increases the potency of glycine, suggesting that introducing larger residues, or drug molecules, into the drug-binding cavity facilitates channel opening. A possible mechanism for these actions is that the volume of the cavity expands and contracts during channel opening and closing. To investigate this hypothesis, mutations for amino acids in TM1 (I229C) and TM2 (G256C, T259C, V260C, M263C, T264C, S267C, S270C) and TM3 (A288C) were individually expressed in Xenopus laevis oocytes. The ability of sulfhydryl-specific alkyl methanethiosulfonate (MTS) compounds of different lengths to covalently react with introduced cysteines in both the closed and open states of the receptor was determined. S267C was accessible to short chain (C3-C8) MTS in both open and closed states, but was only accessible to longer chain (C10-C16) MTS compounds in the open state. Reaction with S267C was faster in the open state. I229C and A288C showed state-dependent reaction with MTS only in the presence of agonist. M263C and S270C were also accessible to MTS labeling. Mutated residues more intracellular than M263C did not react, indicating a floor of the cavity. These data demonstrate that the conformational changes accompanying channel gating increase accessibility to amino acids critical for drug action in TM1, TM2, and TM3, which may provide a mechanism by which alcohols and anesthetics can act on glycine (and likely other) receptors.