Different Residues in the GABAA Receptor α1T60-α1K70 Region Mediate GABA and SR-95531 Actions

Holden, Jessica H.; Czajkowski, Cynthia

doi:10.1074/jbc.m111778200

Cited by 68 publications

(102 citation statements)

References 40 publications

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“…SR-95531 IC 50 experiments were performed as described previously (22). Oocytes expressing WT or mutant receptors were challenged with EC 50 GABA concentration (except for experiments involving ␤Gly2, -4, and -8, which were performed at 30 mM GABA) followed by co-application of the same concentration of GABA and a test concentration of SR-95531.…”

Section: Methodsmentioning

confidence: 99%

Structural Link between γ-Aminobutyric Acid Type A (GABAA) Receptor Agonist Binding Site and Inner β-Sheet Governs Channel Activation and Allosteric Drug Modulation

Venkatachalan

Czajkowski

2012

Journal of Biological Chemistry

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Background: Structural elements and protein movements underlying GABA A receptor activation are not completely resolved. Results: Glycine insertions in the extracellular ␤4-␤5 linker decrease GABA activation, invert antagonist efficacy, and reduce allosteric modulation. Conclusion: ␤4-␤5 linker is critical for mediating actions of GABA A receptor orthosteric and allosteric ligands. Significance: Detailed structural-functional understanding of GABA A receptor activation is key to understanding its modulation in diseased and healthy states.

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Section: Methodsmentioning

confidence: 99%

Structural Link between γ-Aminobutyric Acid Type A (GABAA) Receptor Agonist Binding Site and Inner β-Sheet Governs Channel Activation and Allosteric Drug Modulation

Venkatachalan

Czajkowski

2012

Journal of Biological Chemistry

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“…The rates at which the various MTS reagents modified the engineered cysteines were determined by measuring the effect of sequential applications of low concentrations of MTS reagents on I GABA , as described previously (Holden and Czajkowski, 2002). The protocol is described as follows: EC 40 -60 GABA was applied for 10 s every 3-5 min until I GABA stabilized (Ͻ3% variance).…”

Section: Methodsmentioning

confidence: 99%

Charged Residues in the α₁and β₂Pre-M1 Regions Involved in GABA_AReceptor Activation

Mercado¹,

Czajkowski²

2006

J. Neurosci.

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For Cys-loop ligand-gated ion channels (LGIC), the protein movements that couple neurotransmitter binding to channel gating are not well known. The pre-M1 region, which links the extracellular agonist-binding domain to the channel-containing transmembrane domain, is in an ideal position to transduce binding site movements to gating movements. A cluster of cationic residues in this region is observed in all LGIC subunits, and in particular, an arginine residue is absolutely conserved. We mutated charged pre-M1 residues in the GABA A receptor ␣ 1 (K219, R220, K221) and ␤ 2 (K213, K215, R216) subunits to cysteine and expressed the mutant subunits with wild-type ␤ 2 or ␣ 1 in Xenopus oocytes. Cysteine substitution of ␤ 2 R216 abolished channel gating by GABA without altering the binding of the GABA agonist [3 H]muscimol, indicating that this residue plays a key role in coupling GABA binding to gating. Tethering thiol-reactive methanethiosulfonate (MTS) reagents onto ␣ 1 K219C, ␤ 2 K213C, and ␤ 2 K215C increased maximal GABA-activated currents, suggesting that structural perturbations of the pre-M1 regions affect channel gating. GABA altered the rates of sulfhydryl modification of ␣ 1 K219C, ␤ 2 K213C, and ␤ 2 K215C, indicating that the pre-M1 regions move in response to channel activation. A positively charged MTS reagent modified ␤ 2 K213C and ␤ 2 K215C significantly faster than a negatively charged reagent, and GABA activation eliminated modification of ␤ 2 K215C by the negatively charged reagent. Overall, the data indicate that the pre-M1 region is part of the structural machinery coupling GABA binding to gating and that the transduction of binding site movements to channel movements is mediated, in part, by electrostatic interactions.

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“…As a further test, we examined protection by a competitive antagonist. Although recent studies suggest that a competitive antagonist can also induce a conformational change beyond the binding site to stabilize the GABA receptor in the closed state (17,28,29), this antagonist-induced conformational change is distinct from that induced by the agonist (24). Thus, only when the agonist and antagonist both protect a residue from modification do we consider that residue FIG.…”

Section: Identification Of Novel Binding Residues In the Bindingmentioning

confidence: 98%

“…By testing the functional effect of a water-soluble cysteine modification reagent and blockability of this effect by agonist and antagonist, the substituted cysteine accessibility method has also been successfully used to probe the binding sites of the GABA A (6,17) and nicotinic receptors (18,19). With this approach, novel residues involved in agonist binding were identified, and the secondary structures of the newly identified domain were predicted (6,7).…”

Section: Gaba Amentioning

confidence: 99%

“…In loops B, C (2), and D (5, 13), the binding residues identified by site-directed mutagenesis are almost identical. In loop D, two additional binding residues, Arg-66 and Ser-68, in the ␣ 1 subunit are recognized by the substituted cysteine accessibility method (6,17). The corresponding residue Arg-104 in the 1 subunit seems to line the binding pocket.…”

Section: Identification Of Novel Binding Residues In the Bindingmentioning

confidence: 99%

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Mapping the ρ1 GABAC Receptor Agonist Binding Pocket

Sedelnikova

Smith

Zakharkin

et al. 2005

Journal of Biological Chemistry

115

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␥-Aminobutyric acid (GABA) is the major inhibitory neurotransmitter in the mammalian brain. The GABA receptor type C (GABA C ) is a ligand-gated ion channel with pharmacological properties distinct from the GABA A receptor. To date, only three binding domains in the recombinant 1 GABA C receptor have been recognized among six potential regions. In this report, using the substituted cysteine accessibility method, we scanned three potential regions previously unexplored in the 1 GABA C receptor, corresponding to the binding loops A, E, and F in the structural model for ligand-gated ion channels. The cysteine accessibility scanning and agonist/antagonist protection tests have resulted in the identification of residues in loops A and E, but not F, involved in forming the GABA C receptor agonist binding pocket. Three of these newly identified residues are in a novel region corresponding to the extended stretch of loop E. In addition, the cysteine accessibility pattern suggests that part of loop A and part of loop E have a ␤-strand structure, whereas loop F is a random coil. Finally, when all of the identified ligand binding residues are mapped onto a three-dimensional homology model of the amino-terminal domain of the 1 GABA C receptor, they are facing toward the putative binding pocket. Combined with previous findings, a complete model of the GABA C receptor binding pocket was proposed and discussed in comparison with the GABA A receptor binding pocket. GABA A1 and GABA C receptors are both GABA-gated chloride channels but with very different pharmacological properties. In fact, that is the basis for their classification. Although both types of receptors can be activated by GABA, the GABA A receptor can be specifically antagonized by bicuculline. In contrast, the GABA C receptor is insensitive to bicuculline but can be selectively antagonized by 1,2,5,6-tetrahydropyridine-4-yl)-methylphosphinic acid (1). The functional properties of these two types of GABA receptors are also different. For example, the GABA C receptor has higher GABA sensitivity but slower activation and deactivation kinetics than the GABA A receptor (2). The GABA C receptor also shows almost no desensitization (2), whereas the GABA A receptor exhibits strong desensitization (3). Although the functional differences could arise from differences in the structural architecture of the GABA binding pockets, distinct antagonist profiles of GABA A and GABA C receptors indicate that their agonist/antagonist binding pockets are not the same. Studies over the last 15 years have shaped a relatively complete model for the GABA A receptor (4 -9). In contrast, structural information on the GABA C receptor agonist binding pocket is far from complete. Some candidate binding residues in several potential "binding loops" are still undefined.GABA-gated ion channels belong to the ligand-gated ion channel family, which also includes nicotinic acetylcholine receptors, serotonin-3 receptors, and glycine receptors. The study of nicotinic receptors in the past two decades h...

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Different Residues in the GABAA Receptor α1T60-α1K70 Region Mediate GABA and SR-95531 Actions

Cited by 68 publications

References 40 publications

Structural Link between γ-Aminobutyric Acid Type A (GABAA) Receptor Agonist Binding Site and Inner β-Sheet Governs Channel Activation and Allosteric Drug Modulation

Structural Link between γ-Aminobutyric Acid Type A (GABAA) Receptor Agonist Binding Site and Inner β-Sheet Governs Channel Activation and Allosteric Drug Modulation

Charged Residues in the α₁and β₂Pre-M1 Regions Involved in GABA_AReceptor Activation

Mapping the ρ1 GABAC Receptor Agonist Binding Pocket

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Different Residues in the GABAA Receptor α1T60-α1K70 Region Mediate GABA and SR-95531 Actions

Cited by 68 publications

References 40 publications

Structural Link between γ-Aminobutyric Acid Type A (GABAA) Receptor Agonist Binding Site and Inner β-Sheet Governs Channel Activation and Allosteric Drug Modulation

Structural Link between γ-Aminobutyric Acid Type A (GABAA) Receptor Agonist Binding Site and Inner β-Sheet Governs Channel Activation and Allosteric Drug Modulation

Charged Residues in the α1and β2Pre-M1 Regions Involved in GABAAReceptor Activation

Mapping the ρ1 GABAC Receptor Agonist Binding Pocket

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Charged Residues in the α₁and β₂Pre-M1 Regions Involved in GABA_AReceptor Activation