Different residues in the GABA(A) receptor alpha 1T60-alpha 1K70 region mediate GABA and SR-95531 actions

Although gamma-aminobutyric acid type A receptor agonists and antagonists bind to a common site, they produce different conformational changes within the site because agonists cause channel opening and antagonists do not. We used the substituted cysteine accessibility method and two-electrode voltage clamping to identify residues within the binding pocket that are important for mediating these different actions. Each residue from alpha(1)T60 to alpha(1)K70 was mutated to cysteine and expressed with wild-type beta(2) subunits in Xenopus oocytes. Methanethiosulfonate reagents reacted with alpha(1)T60C, alpha(1)D62C, alpha(1)F64C, alpha(1)R66C, alpha(1)S68C, and alpha(1)K70C. gamma-Aminobutyric acid (GABA) slowed methanethiosulfonate modification of alpha(1)F64C, alpha(1)R66C, and alpha(1)S68C, whereas SR-95531 slowed modification of alpha(1)D62C, alpha(1)F64C, and alpha(1)R66C, demonstrating that different residues are important for mediating GABA and SR-95531 actions. In addition, methanethiosulfonate reaction rates were fastest for alpha(1)F64C and alpha(1)R66C, indicating that these residues are located in an open, aqueous environment lining the core of the binding pocket. Positively charged methanethiosulfonate reagents derivatized alpha(1)F64C and alpha(1)R66C significantly faster than a negatively charged reagent, suggesting that a negative subsite important for interacting with the ammonium group of GABA exists within the binding pocket. Pentobarbital activation of the receptor increased the rate of methanethiosulfonate modification of alpha(1)D62C and alpha(1)S68C, demonstrating that parts of the binding site undergo structural rearrangements during channel gating.     

GABA(A) receptor beta 2 Tyr97 and Leu99 line the GABA-binding site. Insights into mechanisms of agonist and antagonist actions.

The identification of residues that line neurotransmitter-binding sites and catalyze allosteric transitions that result in channel gating is crucial for understanding ligand-gated ion channel function. In this study, we used the substituted cysteine accessibility method and two-electrode voltage clamp to identify novel gamma-aminobutyric acid (GABA)-binding site residues and to elucidate the secondary structure of the Trp(92)-Asp(101) region of the beta(2) subunit. Each residue was mutated individually to cysteine and expressed with wild-type alpha(1) subunits in Xenopus oocytes. GABA-gated currents (I(GABA)) were measured before and after exposure to the sulfhydryl reagent, N-biotinylaminoethyl methanethiosulfonate (MTS). V93C, D95C, Y97C, and L99C are accessible to derivatization. This pattern of accessibility is consistent with beta(2)Val(93)-Leu(99) adopting a beta-strand conformation. Both GABA and SR95531 protect Y97C and L99C from modification, indicating that these two residues line the GABA-binding site. In D95C-containing receptors, application of MTS in the presence of SR95531 causes a greater effect on I(GABA) than MTS alone, suggesting that binding of a competitive antagonist can cause movements in the binding site. In addition, we present evidence that beta(2)L99C homomers form spontaneously open channels. Thus, mutation of a binding site residue can alter channel gating, which implies that Leu(99) may be important for coupling agonist binding to channel gating.     

Local and global ligand-induced changes in the structure of the GABA(A) receptor

Ligand-gated channels mediate synaptic transmission through conformational transitions triggered by the binding of neurotransmitters. These transitions are well-defined in terms of ion conductance, but their structural basis is poorly understood. To probe these changes in structure, GABA(A) receptors were expressed in Xenopus oocytes and labeled at selected sites with environment-sensitive fluorophores. With labels at two different residues in the alpha1 subunit in loop E of the GABA-binding pocket, GABA elicited fluorescence changes opposite in sign. This pattern of fluorescence changes is consistent with a closure of the GABA-binding cavity at the subunit interface. The competitive antagonist SR-95531 inverted this pattern of fluorescence change, but the noncompetitive antagonist picrotoxin failed to elicit optical signals. In response to GABA (but not SR-95531), labels at the homologous residues in the beta2 subunit showed the same pattern of fluorescence change as the alpha1-subunit labels, indicating a global transition with comparable movements in homologous regions of different subunits. Incorporation of the gamma2 subunit altered the fluorescence changes of alpha1-subunit labels and eliminated them in beta2-subunit labels. Thus, the ligand-induced structural changes in the GABA(A) receptor can extend over considerable distances or remain highly localized, depending upon subunit composition and ligand.     

Gamma-aminobutyric acid (GABA) and pentobarbital induce different conformational rearrangements in the GABA A receptor alpha1 and beta2 pre-M1 regions

Gamma-aminobutyric acid (GABA) binding to GABA(A) receptors (GABA(A)Rs) triggers conformational movements in the alpha(1) and beta(2) pre-M1 regions that are associated with channel gating. At high concentrations, the barbiturate pentobarbital opens GABA(A)R channels with similar conductances as GABA, suggesting that their open state structures are alike. Little, however, is known about the structural rearrangements induced by barbiturates. Here, we examined whether pentobarbital activation triggers movements in the GABA(A)R pre-M1 regions. Alpha(1)beta(2) GABA(A)Rs containing cysteine substitutions in the pre-M1 alpha(1) (K219C, K221C) and beta(2) (K213C, K215C) subunits were expressed in Xenopus oocytes and analyzed using two-electrode voltage clamp. The cysteine substitutions had little to no effect on GABA and pentobarbital EC(50) values. Tethering chemically diverse thiol-reactive methanethiosulfonate reagents onto alpha(1)K219C and alpha(1)K221C affected GABA- and pentobarbital-activated currents differently, suggesting that the pre-M1 structural elements important for GABA and pentobarbital current activation are distinct. Moreover, pentobarbital altered the rates of cysteine modification by methanethiosulfonate reagents differently than GABA. For alpha(1)K221Cbeta(2) receptors, pentobarbital decreased the rate of cysteine modification whereas GABA had no effect. For alpha(1)beta(2)K215C receptors, pentobarbital had no effect whereas GABA increased the modification rate. The competitive GABA antagonist SR-95531 and a low, non-activating concentration of pentobarbital did not alter their modification rates, suggesting that the GABA- and pentobarbital-mediated changes in rates reflect gating movements. Overall, the data indicate that the pre-M1 region is involved in both GABA- and pentobarbital-mediated gating transitions. Pentobarbital, however, triggers different movements in this region than GABA, suggesting their activation mechanisms differ.     

Structural link between γ-aminobutyric acid type A (GABAA) receptor agonist binding site and inner β-sheet governs channel activation and allosteric drug modulation

Rapid opening and closing of pentameric ligand-gated ion channels (pLGICs) regulate information flow throughout the brain. For pLGICs, it is postulated that neurotransmitter-induced movements in the extracellular inner β-sheet trigger channel activation. Homology modeling reveals that the β4-β5 linker physically connects the neurotransmitter binding site to the inner β-sheet. Inserting 1, 2, 4, and 8 glycines in this region of the GABA(A) receptor β-subunit progressively decreases GABA activation and converts the competitive antagonist SR-95531 into a partial agonist, demonstrating that this linker is a key element whose length and flexibility are optimized for efficient signal propagation. Insertions in the α- and γ-subunits have little effect on GABA or SR-95531 actions, suggesting that asymmetric motions in the extracellular domain power pLGIC gating. The effects of insertions on allosteric modulator actions, pentobarbital, and benzodiazepines, have different subunit dependences, indicating that modulator-induced signaling is distinct from agonist gating.     

Transmembrane segment 5 of the dipeptide transporter hPepT1 forms a part of the substrate translocation pathway

This study is the first systematic attempt to investigate the role of transmembrane segment 5 of hPepT1, the most conserved segment across different species, in forming a part of the aqueous substrate translocation pathway. We used cysteine-scanning mutagenesis in conjunction with the sulfhydryl-specific reagents, MTSEA and MTSET. Neither of these reagents reduced wild-type-hPepT1 transport activity in HEK293 cells and Xenopus oocytes. Twenty-one single cysteine mutations in hPepT1 were created by replacing each residue within TMS5 with a cysteine. HEK293 cells were then transfected with each mutated protein and the steady-state protein level, [3H]Gly-Sar uptake activity, and sensitivity to the MTS reagents were measured. S164C-, L168C-, G173C-, and I179C-hPepT1 were not expressed on the plasma membrane. Y167C-, N171C-, and S174C-hPepT1 showed 相似文献   

gamma-Aminobutyric acid (GABA) induces a receptor-mediated reduction in GABAA receptor alpha subunit messenger RNAs in embryonic chick neurons in culture.

gamma-Aminobutyric acid (GABA), the major inhibitory neurotransmitter in brain, is known to interact with a subclass of receptors that activate a ligand-gated chloride ion channel. Exposure of cultured embryonic chick neurons to physiological concentrations of GABA results in a time-dependent down-regulation of these GABAA receptors. To delineate the cellular mechanism(s) responsible for agonist-induced down-regulation of GABAA receptors we quantified the levels of GABAA receptor alpha subunit messenger RNAs, which encode the subunit(s) containing agonist recognition site(s), and observed a marked reduction in alpha subunit mRNAs following exposure of embryonic chick neurons to GABA. Both the down-regulation of GABAA receptors and the reduction in alpha subunit mRNAs induced by GABA were completely antagonized by the specific GABAA receptor antagonist SR-95531. These data demonstrate the presence of an agonist-induced receptor-mediated mechanism for regulating the expression of receptor subunit-encoding mRNAs that may be involved in the development of tolerance to the pharmacological actions of drugs known to act via GABAA receptors.     

Analysis of transmembrane segment 7 of the dipeptide transporter hPepT1 by cysteine-scanning mutagenesis

To investigate the involvement of transmembrane segment 7 (TMS7) of hPepT1 in forming the putative central aqueous channel through which the substrate traverses, we individually mutated each of the 21 amino acids in TMS7 to a cysteine and analyzed the mutated transporters using the scanning cysteine accessibility method. Y287C- and M292C-hPepT1 did not express at the plasma membrane. Out of the remaining 19 transporters, three (F293C-, L296C-, and F297C-hPepT1) showed negligible glycyl-sarcosine (gly-sar) uptake activity and may play an important role in defining the overall hPepT1 structure. K278C-hPepT1 showed approximately 40% activity and the 15 other transporters exhibited more than 50% gly-sar uptake when compared with wild type (WT)-hPepT1. Gly-sar uptake for the 16 active transporters containing cysteine mutations was then measured in the presence of 2.5 mM 2-aminoethyl methanethiosulfonate hydrobromide (MTSEA) or 1 mM [2-(trimethylammonium) ethyl] methanethiosulfonate bromide (MTSET). Gly-sar uptake was significantly inhibited for each of the 16 single cysteine mutants in the presence of 2.5 mM MTSEA. In contrast, significant inhibition of uptake was only observed for K278C-, M279C-, V280C-, T281C-, M284C-, L286C-, P291C-, and D298C-hPepT1 in the presence of 1 mM MTSET. MTSET modification of R282C-hPepT1 resulted in a significant increase in gly-sar uptake. To investigate this further, we mutated WT-hPepT1 to R282A-, R282E-, and R282K-hPepT1. R282E-hPepT1 showed a 43% reduction in uptake activity, whereas R282A- and R282K-hPepT1 had activities comparable with WT-hPepT1, suggesting a role for the Arg-282 positive charge in substrate translocation. Most of the amino acids that were MTSET-sensitive upon cysteine mutation, including R282C, are located toward the intracellular end of TMS7. Hence, our results suggest that TMS7 of hPepT1 is relatively solvent-accessible along most of its length but that the intracellular end of the transmembrane domain is particularly so. From a structure-function perspective, we speculate that the extracellular end of TMS7 may shift following substrate binding, providing the basis for channel opening and substrate translocation.     

Functional and structural analysis of the GABAA receptor alpha 1 subunit during channel gating and alcohol modulation

The substituted cysteine accessibility method has proven useful for investigating structural changes of the gamma-aminobutyric acid type A (GABA(A)) receptor during channel gating and allosteric modulation. In the present study, the surface accessibility and reaction rate of propyl- and hexyl-methanethiosulfonate to cysteine residues introduced into the third transmembrane segment of the GABA(A) receptor alpha(1) subunit were examined. GABA-induced currents in Xenopus oocytes expressing wild type and cysteine mutant GABA(A) receptors were recorded before and after application of methanethiosulfonate (MTS) reagents in the resting, GABA- or alcohol-bound (ethanol or hexanol) states. Our results indicate that a water-filled cavity exists around the Ala(291) and Tyr(294) residues of the third transmembrane segment, in agreement with previous results. Furthermore, our data indicate that a conformational change produced by alcohols (200 mM ethanol or 0.5 mM hexanol) exposure induces the water cavity around the A291C and Y294C residues to extend deeper, causing the A295C and F296C residues to become accessible to the MTS reagents. In addition, exposure of the A291C, Y294C, F296C, and V297C mutants to MTS reagents in the presence of GABA had significant effects on their GABA-induced currents, indicating that the water cavity around A291C and Y294C residues expanded to F296C and V297C by a structural movement caused by GABA binding. Our data show that GABA(A) receptor is a dynamic protein during alcohol modulation and channel gating.     

Zinc fingers and thiol-disulfide oxidoreductase activities of chaperone DnaJ.

Chaperone DnaJ is a homodimer with each subunit containing 10 cysteine residues and two Zn(II) ions, which have been identified to form two zinc fingers, C(144)DVC(147)Zn(II)C(197)NKC(200) (Zn1) and C(161)PTC(164)Zn(II)C(183)PHC(186) (Zn2), with C(265) and C(323) in reduced form. Guanidine hydrochloride at 6.4 M destroys only Zn1, which does not reform after refolding. p-Hydroxymercuriphenylsulfonate acid, but not ethylenediaminetetraacetic acid (EDTA) even at high concentrations, can remove two Zn(II) ions from DnaJ, but only Zn2 can be reconstituted. After removal of Zn(II) ions, only C(144) and C(147) in Zn1 are oxidation-resistant, and the other six cysteines are easily oxidizable. DnaJ shows reductase activity and oxidase activity but little, if any, isomerase activity. The reductase activity is reversibly inhibited by EDTA. Zn2 is important for the enzymatic activity, and only -C(183)PHC(186)- among the four motifs of -CXXC- functions as the active site of the enzyme. A C-terminal (Q(181)-R(376)) fragment shows a zinc finger of C(183)PHC(186)Zn(II)C(197)NKC(200) and full enzymatic activity of DnaJ. The N-terminal half sequence (M(1)-Q(180)) and Zn1 are not required for the enzymatic activity but are important for the chaperone activity of DnaJ.     

Close proximity of a cytoplasmic loop of subunit a with c subunits of the ATP synthase from Escherichia coli

Interactions between subunit a and the c subunits of the Escherichia coli ATP synthase are thought to control proton translocation through the F(o) sector. In this study cysteine substitution mutagenesis was used to define the cytoplasmic ends of the first three transmembrane spans of subunit a, as judged by accessibility to 3-N-maleimidyl-propionyl biocytin. The cytoplasmic end of the fourth transmembrane span could not be defined in this way because of the limited extent of labeling of all residues between 186 and 206. In contrast, most of the preceding residues in that region, closer to transmembrane span 3, were labeled readily. The proximity of this region to other subunits in F(o) was tested by reacting mono-cysteine mutants with a photoactivated cross-linker. Residues 165, 169, 173, 174, 177, 178, and 182-184 could all be cross-linked to subunit c, but no sites were cross-linked to b subunits. Attempts using double mutants of subunit a to generate simultaneous cross-links to two different c subunits were unsuccessful. These results indicate that the cytoplasmic loop between transmembrane spans 3 and 4 of subunit a is in close proximity to at least one c subunit. It is likely that the more highly conserved, carboxyl-terminal region of this loop has limited surface accessibility due to protein-protein interactions. A model is presented for the interaction of subunit a with subunit c, and its implications for the mechanism of proton translocation are discussed.     

Long-Term GABA Treatment Elicits Supersensitivity of Quisqualate-Preferring Metabotropic Glutamate Receptor in Cultured Rat Cerebellar Neurons

Abstract: In primary cultures of rat cerebellar granule neurons, GABA treatment (50 μ M , 7 days) caused a withdrawal supersensitivity selective for the metabotropic glutamate receptors that mainly prefer l -glutamate, quisqua- late and, to a lesser extent, kainate. The withdrawal supersensitivity was absent when 10 μ M SR-95531 was coadministered with GABA during the treatment period, an event that suggests the GABA_A receptors primarily produced the GABA treatment effect. This was supported further by the inability of baclofen treatment to mimic completely the treatment effect of GABA. Withdrawal from 7 days of baclofen treatment only produced a slight increase in the metabotropic effect of l -glutamate and carbachol. In addition, in untreated neurons, baclofen had no acute effect, whereas GABA inhibited the effect of l -glutamate and carbachol. The inhibitory effect of GABA was reversed by SR-95531 and was absent in neurons treated with GABA. These observations suggest the involvement of GABA_A receptors and the apparent development of tolerance to GABA, respectively. Also, dependence on GABA may have occurred; the metabotropic effects of glutamate, kainate, and quisqualate were not altered in neurons maintained with GABA treatment.     

Evidence that the TM1-TM2 loop contributes to the rho1 GABA receptor pore

Considerable evidence indicates the second transmembrane domain (TM2) of the gamma-aminobutyric acid (GABA) receptor lines the integral ion pore. To further delineate the structures that constitute the ion pore and selectivity filter of the rho1 GABA receptor, we used the substituted cysteine accessibility method with charged reagents to identify anion- and cation-accessible surfaces. Twenty-one consecutive residues were mutated to cysteine, one at a time, in the presumed intracellular end of the first transmembrane domain (TM1; Ala(271)-Met(276)), the entire linker connecting TM1 to TM2 (Leu(277)-Arg(287)), and the presumed intracellular end of TM2 (Ala(288)-Ala(291)). Positively (MTSEA(+)) and negatively (pCMBS(-)) charged sulfhydryl reagents, as well as Cd(2+), were added extracellularly to test accessibility of the engineered cysteines. Four of the mutants, all at the intracellular end of TM2 (R287C, V289C, P290C, A291C), were accessible to positively charged reagents, whereas seven mutants (A271C, T272C, L277C, W279C, V280C, P290C, A291C) were functionally modified by negatively charged pCMBS(-). These seven modified residues were at the intracellular end of TM2, in the TM1-TM2 linker, and at the intracellular end of TM1. In nearly all cases (excluding P290C), the rate and the degree of modification were state-dependent, with greater accessibility in the presence of agonist. Select cysteine mutants were combined with a point mutation (A291E) that converted the pore from chloride- to non-selective. In this case, positively charged reagents could modify residues in the TM1-TM2 linker (Leu(277) and Val(280)), supporting the notion that the modifying reagents were reaching their target through the pore. Taken together, our results suggest that, up to its intracellular end, the TM2 domain is not charge selective. In addition, we propose that the TM1-TM2 linker and the intracellular end of TM1 are along the pathway of the permeating ion. These findings may lend new insights into the structure of the GABA receptor pore.     

The aqueous accessibility in the external half of transmembrane domain I of the GABA transporter GAT-1 Is modulated by its ligands

The sodium- and chloride-dependent gamma-aminobutyric acid (GABA) transporter GAT-1 is the first identified member of a family of transporters, which maintain low synaptic neurotransmitter levels and thereby enable efficient synaptic transmission. To obtain evidence for the idea that the highly conserved transmembrane domain I (TMD I) participates in the permeation pathway, we have determined the impact of impermeant methanethiosulfonate (MTS) reagents on cysteine residues engineered into this domain. As a background the essentially insensitive but fully active C74A mutant has been used. Transport activity of mutants with a cysteine introduced cytoplasmic to glycine 63 is largely unaffected and is resistant to the impermeant MTS reagents. Conversely, transport activity in mutants extracellular to glycine 63 is strongly impacted. Nevertheless, transport activity could be measured in all but three mutants: G65C, N66C, and R69C. In each of the six active cysteine mutants the activity is highly sensitive to the impermeant MTS reagents. This sensitivity is potentiated by sodium in L64C, F70C, and Y72C, but is protected in V67C and P71C. GABA protects in L64C, W68C, F70C, and P71C. The non-transportable GABA analogue SKF100330A also protects in L64C, W68C, and P71C as well as V67C, but strikingly potentiates inhibition in F70C. Although cysteine substitution in this region may have perturbed the native structure of GAT-1, our observations, taken together with the recently published accessibility study on the related serotonin transporter (Henry, L. K., Adkins, E. M., Han, Q., and Blakely, R. D. (2003) J. Biol. Chem. 278, 37052-37063), suggest that the extracellular part of TMD I is conformationally sensitive, lines the permeation pathway, and forms a more extended structure than expected from a membrane-embedded alpha-helix.     

Cysteine scanning mutagenesis of the noncatalytic nucleotide binding site of the yeast V-ATPase

To investigate residues involved in the formation of the noncatalytic nucleotide binding sites of the vacuolar proton-translocating adenosine triphosphatase (V-ATPase), cysteine scanning mutagenesis of the VMA2 gene that encodes the B subunit in yeast was performed. Replacement of the single endogenous cysteine residue at position 188 gave rise to a Cys-less form of the B subunit (Vma2p) which had near wild-type levels of activity and which was used in the construction of 16 single cysteine-containing mutants. The ability of adenine nucleotides to prevent reaction of the introduced cysteine residues with the sulfhydryl reagent 3-(N-maleimidopropionyl)biocytin (biotin-maleimide) was evaluated by Western blot. Biotin-maleimide labeling of the purified V-ATPase from the wild-type and the mutants S152C, L178C, N181C, A184C, and T279C was reduced after reaction with the nucleotide analog 3'-O-(4-benzoyl)benzoyladenosine 5'-triphosphate (BzATP). These results suggest the proximity of these residues to the nucleotide binding site on the B subunit. In addition, we have examined the level of endogenous nucleotide bound to the wild-type V-ATPase and to a mutant (the A subunit mutant R483Q) which is postulated to be altered at the noncatalytic site and which displays a marked nonlinearity in ATP hydrolysis (MacLeod, K. J., Vasilyeva, E., Baleja, J. D., and Forgac, M. (1998) J. Biol. Chem. 273, 150-156). The R483Q mutant contained 2.6 mol of ATP/mol of V-ATPase compared with the wild-type enzyme, which contained 0.8 mol of ATP/mol of V-ATPase. These results suggest that binding of additional ATP to the noncatalytic sites may modulate the catalytic activity of the enzyme.     

Mapping the rho1 GABA(C) receptor agonist binding pocket. Constructing a complete model

Gamma-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 rho1 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 rho1 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 beta-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 rho1 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.     

The reactivity of the gamma-aminobutyric acid transporter GAT-1 toward sulfhydryl reagents is conformationally sensitive. Identification of a major target residue.

The gamma-aminobutyric acid (GABA) transporter GAT-1 is a prototype of neurotransmitter transporters that maintain low synaptic levels of the transmitter. Transport by GAT-1 is sensitive to the polar sulfhydryl reagent 2-aminoethyl methanethiosulfonate. Following replacement of endogenous cysteines to other residues by site-directed mutagenesis, we have identified cysteine 399 as the major determinant of the sensitivity of the transporter to sulfhydryl modification. Cysteine-399 is located in the intracellular loop connecting putative transmembrane domains eight and nine. Binding of both sodium and chloride leads to a reduced sensitivity to sulfhydryl reagents, whereas subsequent binding of GABA increases it. Strikingly binding of the nontransportable GABA analogue SKF100330A gives rise to a marked protection against sulfhydryl modification. These effects were not observed in C399S transporters. Under standard conditions GAT-1 is almost insensitive toward the impermeant 2-(trimethylammonium)ethyl methanethiosulfonate. However, in a chloride-free medium, addition of SKF100330A renders wild type GAT-1, but not C399S, very sensitive to this impermeant reagent. These observations indicate that the accessibility of cysteine 399 is highly dependent on the conformation of GAT-1. Consequently, topological assignments based on accessibility of endogeneous or engineered cysteines to small polar sulfhydryl reagents need to be interpreted with extreme caution.     

Cysteine-scanning mutagenesis study of the sixth transmembrane segment of the Na,K-ATPase alpha subunit

The accessibility of the residues of the sixth transmembrane segment (TM) of the Bufo marinus Na,K-ATPase alpha subunit was explored by cysteine scanning mutagenesis. Methanethiosulfonate reagents reached only the two most extracellular positions (T803, D804) in the native conformation of the Na,K-pump. Palytoxin induced a conductance in all mutants, including D811C, T814C and D815C which showed no active electrogenic transport. After palytoxin treatment, four additional positions (V805, L808, D811 and M816) became accessible to the sulfhydryl reagent. We conclude that one side of the sixth TM helix forms a wall of the palytoxin-induced channel pore and, probably, of the cation pathway from the extracellular side to one of their binding sites.     

Rapid Down-Regulation of GABAA Receptors in the Gerbil Hippocampus Following Transient Cerebral Ischemia

Abstract: During transient cerebral ischemia, there is a temporary and robust accumulation of extracellular GABA in the hippocampus. We examined whether the acute exposure of GABA_A/benzodiazepine receptors to high concentrations of GABA early after ischemia results in receptor down-regulation as observed in vitro. Gerbils were killed 30 and 60 min following a 5-min bilateral carotid occlusion, and their brains were prepared for receptor autoradiography. The hydrophilic GABA_A receptor antagonist [³H]SR-95531 and the hydrophobic benzodiazepine agonist [³H]flunitrazepam were used to distinguish between cell surface and internalized receptors. Ischemia significantly decreased [³H]SR-95531 binding in hippocampal areas CA1 and CA3 and in the dentate gyrus 30 min after ischemia. Scatchard analysis in area CA1 revealed that ischemia decreased the B _max as low as 44%. The affinity of the remaining sites was increased substantially (72% decrease in K _D). As expected, there were no changes in the binding of [³H]flunitrazepam to hippocampus in the early postischemic period because the benzodiazepine could bind to both internalized receptors and those on the cell surface. We hypothesize that prolonged exposure (∼30–45 min) of GABA_A receptors to high concentrations of synaptic GABA in vivo causes receptor down-regulation, perhaps via receptor internalization.     

The interaction of the gamma-aminobutyric acid transporter GAT-1 with the neurotransmitter is selectively impaired by sulfhydryl modification of a conformationally sensitive cysteine residue engineered into extracellular loop IV

The (Na+ + Cl-)-coupled gamma-aminobutyric acid (GABA) transporter GAT-1 keeps synaptic levels of this neurotransmitter low and thereby enables efficient GABA-ergic transmission. Extracellular loops (III, IV, and V) have been shown to contain determinants for GABA selectivity and affinity. Here we analyze the role of extracellular loop IV in transport by cysteine scanning mutagenesis. Fourteen residues of this loop have been replaced by cysteine. GABA transport by eight of the fourteen mutants is markedly more sensitive to inhibition by membrane-impermeant methane thiosulfate reagents than wild-type. Mutant A364C has high activity and is potently inhibited by the sulfhydryl reagent. GABA transport by the A364C/C74A double mutant, where the only externally accessible cysteine residue of the wild-type has been replaced by alanine, is also highly sensitive to the sulfhydryl reagents. Maximal sensitivity is observed in the presence of the cosubstrates sodium and chloride. A marked protection is afforded by GABA, provided sodium is present. This protection is also observed at 4 degrees C. The non-transportable analogue SKF100330A also protects the double mutant against sulfhydryl modification in the presence of sodium but has the opposite effect in its absence. Electrophysiological analysis shows that upon sulfhydryl modification of this mutant, GABA can no longer induce transport currents. The voltage dependence of the transient currents indicates an increased apparent affinity for sodium. Moreover, GABA is unable to suppress the transient currents. Our results indicate that part of extracellular loop IV is conformationally sensitive, and its modification selectively abolishes the interaction of the transporter with GABA.