(2-sulfonatoethyl)methanethiosulfonate and (2-(trimethylammonium)ethyl)methanethiosulfonate

The FMRFamide-gated Na(+) channel (FaNaC) is a unique peptide-gated sodium channel and a member of the epithelial sodium channel/degenerin family. Previous studies have shown that an aspartate residue (Asp(552)) in the second transmembrane domain is involved in activation of the FaNaC. To examine the significance of a negative charge at position 552, we used a cysteine-modification method. Macroscopic currents of a cysteine mutant (D552C) were potentiated or inhibited by use of positively or negatively charged sulfhydryl reagents ([2-(trimethylammonium)ethyl]methanethiosulfonate bromide, MTSET, and sodium (2-sulfonatoethyl)methanethiosulfonate, MTSES, respectively). Dose-response analysis showed that treatment with MTSET increased the potency of the FMRFamide in the FaNaC whereas treatment with MTSES reduced the maximum response. Negative charge at position 552 was necessary for the characteristic inward rectification of the FaNaC. These results suggest that negative electric charge at position 552 is important to the activation and permeation properties of the FaNaC.

Topics: Animals; Aplysia; Cysteine; Dose-Response Relationship, Drug; FMRFamide; Ion Channel Gating; Membrane Potentials; Mesylates; Models, Molecular; Mutation; Nerve Tissue Proteins; Oocytes; Permeability; Protein Conformation; Sodium; Sodium Channels; Static Electricity; Surface Properties; Xenopus laevis

pH and Na(+) homeostasis in all cells requires Na(+)/H(+) antiporters. The crystal structure of NhaA, the main antiporter of Escherichia coli, has provided general insights into antiporter mechanisms and their pH regulation. Functional studies of NhaA in the membrane have yielded valuable information regarding its functionality in situ at physiological pH. Here, we Cys-scanned the discontinuous transmembrane segment (TM) IV (helices IVp and IVc connected by an extended chain) of NhaA to explore its functionality at physiological pH. We then tested the accessibility of the Cys replacements to the positively charged SH reagent [2-(trimethylammonium)ethyl] methanethiosulfonate bromide (MTSET) and the negatively charged 2-sulfonatoethyl methanethiosulfonate (MTSES) in intact cells at pH 8.5 and 6.5 and in parallel tested their accessibility to MTSET in high-pressure membranes at both pH values. We found that the outer membrane of E. coli TA16 acts as a partially permeable barrier to MTSET. Overcoming this technical problem, we revealed that (a) Cys replacement of the most conserved residues of TM IV strongly increases the apparent K(m) of NhaA to both Na(+) and Li(+), (b) the cationic passage of NhaA at physiological pH is lined by the most conserved and functionally important residues of TM IV, and (c) a pH shift from 6.5 to 8.5 induces conformational changes in helix IVp and in the extended chain at physiological pH.

Topics: Amino Acid Substitution; Cations; Cell Membrane Permeability; Escherichia coli; Escherichia coli Proteins; Mesylates; Models, Molecular; Protein Structure, Secondary; Sodium-Hydrogen Exchangers

MscL is a bacterial mechanosensor that serves as a biological emergency release valve, releasing cytoplasmic solutes to the environment on osmotic downshock. Previous studies have recognized that this channel has properties that make it ideal for use as a triggered nanovalve for vesicular-based targeted drug-release devices. One can even change the modality of the sensor. Briefly, the introduction of charges into the MscL pore lumen gates the channel in the absence of membrane tension; thus, by inserting compounds that acquire a charge on exposure to an alternative stimulus, such as light or pH, into the pore of the channel, controllable nanoswitches that detect these alternative modalities have been engineered. However, a charge in the pore lumen could not only encourage actuation of the nanopore but also have a significant influence on the permeation of large charged compounds, which would thus have important implications for the efficiency of drug-release devices. In this study, we used in vivo and electrophysiological approaches to demonstrate that the introduction of a charge into pore lumen of MscL does indeed influence the permeation of charged molecules. These effects were more drastic for larger compounds and, surprisingly, were related to the orientation of the MscL channel in the membrane.

Topics: Biological Transport; Cell Membrane; Chlorides; Electrophysiology; Escherichia coli; Escherichia coli Proteins; Glutamates; Ion Channel Gating; Ion Channels; Mesylates; Mutation; Nanopores; Potassium; Sodium; Spermine; Succinic Acid; Sulfhydryl Reagents; Trehalose

The crystal structure of Escherichia coli NhaA determined at pH 4 has provided insights into the mechanism of activity of a pH-regulated Na+/H+ antiporter. However, because NhaA is activated at physiological pH (pH 5.5-8.5), many questions related to the active state of NhaA have remained elusive. Our experimental results at physiological pH and computational analyses reveal that amino acid residues in transmembrane segment II contribute to the cation pathway of NhaA and its pH regulation: 1) transmembrane segment II is a highly conserved helix and the conserved amino acid residues are located on one side of the helix facing either the cytoplasmic or periplasmic funnels of NhaA structure. 2) Cys replacements of the conserved residues and measuring their antiporter activity in everted membrane vesicles showed that D65C, L67C, E78C, and E82C increased the apparent K(m) to Na+ and Li+ and changed the pH response of the antiporter. 3) Introduced Cys replacements, L60C, N64C, F71C, F72C, and E78C, were significantly alkylated by [14C]N-ethylmaleimide implying the presence of water-filled cavities in NhaA. 4) Several Cys replacements were modified by MTSES and/or MTSET, membrane impermeant, negatively and positively charged reagents, respectively, that could reach Cys replacements from the periplasm only via water-filled funnel(s). Remarkably, the reactivity of D65C to MTSES increased with increasing pH and chemical modification by MTSES but not by MTSET, decreased the apparent K(m) of the antiporter at pH 7.5 (10-fold) but not at pH 8.5, implying the importance of Asp(65) negative charge for pH activation of the antiporter.

Topics: Aspartic Acid; Cations; Cell Membrane; Computer Simulation; Conserved Sequence; Crystallography, X-Ray; Cysteine; Escherichia coli; Escherichia coli Proteins; Gene Expression Regulation, Bacterial; Hydrogen-Ion Concentration; Ion Transport; Lithium; Mesylates; Models, Molecular; Mutation; Periplasm; Phenotype; Protein Conformation; Sodium-Hydrogen Exchangers

The voltage-sensing domain of voltage-gated channels is comprised of four transmembrane helices (S1-S4), with conserved positively charged residues in S4 moving across the membrane in response to changes in transmembrane voltage. Although it has been shown that positive charges in S4 interact with negative countercharges in S2 and S3 to facilitate protein maturation, how these electrostatic interactions participate in channel gating remains unclear. We studied a mutation in Kv7.1 (also known as KCNQ1 or KvLQT1) channels associated with long QT syndrome (E1K in S2) and found that reversal of the charge at E1 eliminates macroscopic current without inhibiting protein trafficking to the membrane. Pairing E1R with individual charge reversal mutations of arginines in S4 (R1-R4) can restore current, demonstrating that R1-R4 interact with E1. After mutating E1 to cysteine, we probed E1C with charged methanethiosulfonate (MTS) reagents. MTS reagents could not modify E1C in the absence of KCNE1. With KCNE1, (2-sulfonatoethyl) MTS (MTSES)(-) could modify E1C, but [2-(trimethylammonium)ethyl] MTS (MTSET)(+) could not, confirming the presence of a positively charged environment around E1C that allows approach by MTSES(-) but repels MTSET(+). We could change the local electrostatic environment of E1C by making charge reversal and/or neutralization mutations of R1 and R4, such that MTSET(+) modified these constructs depending on activation states of the voltage sensor. Our results confirm the interaction between E1 and the fourth arginine in S4 (R4) predicted from open-state crystal structures of Kv channels and reveal an E1-R1 interaction in the resting state. Thus, E1 engages in electrostatic interactions with arginines in S4 sequentially during the gating movement of S4. These electrostatic interactions contribute energetically to voltage-dependent gating and are important in setting the limits for S4 movement.

Topics: Amino Acid Sequence; Animals; Arginine; Cell Membrane; Cysteine; Ion Channel Gating; KCNQ1 Potassium Channel; Long QT Syndrome; Membrane Potentials; Mesylates; Models, Molecular; Molecular Sequence Data; Mutation; Protein Conformation; Protein Structure, Tertiary; Protein Transport; Sulfhydryl Reagents; Surface Properties; Time Factors; Xenopus

Mutations in GJB2, which encodes Cx26, are one of the most common causes of inherited deafness in humans. More than 100 mutations have been identified scattered throughout the Cx26 protein, most of which cause nonsyndromic sensorineural deafness. In a subset of mutations, deafness is accompanied by hyperkeratotic skin disorders, which are typically severe and sometimes fatal. Many of these syndromic deafness mutations localize to the amino-terminal and first extracellular loop (E1) domains. Here, we examined two such mutations, A40V and G45E, which are positioned near the TM1/E1 boundary and are associated with keratitis ichthyosis deafness (KID) syndrome. Both of these mutants have been reported to form hemichannels that open aberrantly, leading to "leaky" cell membranes. Here, we quantified the Ca(2+) sensitivities and examined the biophysical properties of these mutants at macroscopic and single-channel levels. We find that A40V hemichannels show significantly impaired regulation by extracellular Ca(2+), increasing the likelihood of aberrant hemichannel opening as previously suggested. However, G45E hemichannels show only modest impairment in regulation by Ca(2+) and instead exhibit a substantial increase in permeability to Ca(2+). Using cysteine substitution and examination of accessibility to thiol-modifying reagents, we demonstrate that G45, but not A40, is a pore-lining residue. Both mutants function as cell-cell channels. The data suggest that G45E and A40V are hemichannel gain-of-function mutants that produce similar phenotypes, but by different underlying mechanisms. A40V produces leaky hemichannels, whereas G45E provides a route for excessive entry of Ca(2+). These aberrant properties, alone or in combination, can severely compromise cell integrity and lead to increased cell death.

Topics: Amino Acid Substitution; Animals; Barium; Calcium; Cell Line, Tumor; Chelating Agents; Chloride Channels; Connexin 26; Connexins; Cysteine; Deafness; Electrophysiological Phenomena; Ethylenediamines; Gap Junctions; Humans; Ion Channel Gating; Keratitis; Membrane Potentials; Mesylates; Mice; Mutation, Missense; Oocytes; Permeability; RNA, Messenger; Streptomyces; Sulfhydryl Reagents; Syndrome; Transfection; Xenopus laevis

The Na(+)/H(+) exchanger isoform 1 is a ubiquitously expressed integral membrane protein. It resides on the plasma membrane of cells and regulates intracellular pH in mammals by extruding an intracellular H(+) in exchange for one extracellular Na(+). We characterized structural and functional aspects of the transmembrane segment (TM) VI (residues 227-249) by using cysteine scanning mutagenesis and high resolution NMR. Each residue of TM VI was mutated to cysteine in the background of the cysteineless NHE1 protein, and the sensitivity to water-soluble sulfhydryl-reactive compounds (2-(trimethylammonium)ethyl)methanethiosulfonate (MTSET) and (2-sulfonatoethyl)methanethiosulfonate (MTSES) was determined for those residues with significant activity remaining. Three residues were essentially inactive when mutated to Cys: Asp(238), Pro(239), and Glu(247). Of the remaining residues, proteins with the mutations N227C, I233C, and L243C were strongly inhibited by MTSET, whereas amino acids Phe(230), Gly(231), Ala(236), Val(237), Ala(244), Val(245), and Glu(248) were partially inhibited by MTSET. MTSES did not affect the activity of the mutant NHE1 proteins. The structure of a peptide representing TM VI was determined using high resolution NMR spectroscopy in dodecylphosphocholine micelles. TM VI contains two helical regions oriented at an approximate right angle to each other (residues 229-236 and 239-250) surrounding a central unwound region. This structure bears a resemblance to TM IV of the Escherichia coli protein NhaA. The results demonstrate that TM VI of NHE1 is a discontinuous pore-lining helix with residues Asn(227), Ile(233), and Leu(243) lining the translocation pore.

Topics: Cation Transport Proteins; Cell Membrane; Cysteine; Humans; Immunoblotting; Magnetic Resonance Spectroscopy; Mesylates; Mutagenesis, Site-Directed; Mutation; Protein Conformation; Protein Isoforms; Sodium-Hydrogen Exchanger 1; Sodium-Hydrogen Exchangers; Structure-Activity Relationship

The electrogenic Na(+)/HCO(3)(-) cotransporter (NBCe1-A) transports sodium and bicarbonate across the basolateral membrane of the renal proximal tubule. In this study the structural requirement of transmembrane segment 1 (TM1) residues in mediating NBCe1-A transport was investigated. Twenty-five introduced cysteine mutants at positions Gln-424 to Gly-448 were tested for their sensitivity to the methanethiosulfonate reagents (2-sulfonatoethyl) methanethiosulfonate (MTSES), [2-(trimethylammonium)ethyl]methanethiosulfonate (MTSET), and (2-aminoethyl) methanethiosulfonate (MTSEA). Two mutants, T442C and A435C, showed 100 and 70% sensitivity, respectively, to inhibition by all the three methanethiosulfonate (MTS) reagents, I441C had >50% sensitivity to MTSET and MTSEA, and A428C had 50% sensitivity to MTSEA inhibition. A helical wheel plot showed that mutants T442C, A435C, and A428C are clustered on one face of TM1 within a 100 degrees arc. Topology analysis of TM1 with biotin maleimide and 2-((5(6)-tetramethylrhodamine)carboxylamino) ethyl methanethiosulfonate (MTS-TAMRA) revealed Thr-442 marks the C-terminal end of TM1 and that extracellular FGGLLG stretch is in a small aqueous-accessible cavity. Functional studies indicated that Thr-442 resides in a narrow region of the ion translocation pore with strong delta(-) helical dipole influence. Analysis of the corresponding residue of NBCe1-A-Thr-442 in AE1 (Thr-422) shows it is functionally insensitive to MTSES and unlabeled with MTS-TAMRA, indicating that AE1-TM1 is oriented differently from NBCe1-A. In summary, we have identified residues Thr-442, Ala-435, and Ala-428 in TM1 lining the ion translocation pore of NBCe1-A. Our findings are suggestive of a delta(-) helical dipole at the C-terminal end of TM1 involving Thr-442 that plays a critical role in the function of the cotransporter.

Topics: Amino Acid Substitution; Bicarbonates; Cell Line; Ethyl Methanesulfonate; Humans; Ion Transport; Mesylates; Mutation, Missense; Protein Structure, Tertiary; Sodium; Sodium-Bicarbonate Symporters

The Na(+)/H(+) exchanger isoform 1 is a ubiquitously expressed integral membrane protein that regulates intracellular pH in mammals by extruding an intracellular H(+) in exchange for one extracellular Na(+). We characterized structural and functional aspects of the critical transmembrane (TM) segment XI (residues 449-470) by using cysteine scanning mutagenesis and high resolution NMR. Each residue of TM XI was mutated to cysteine in the background of the cysteine-less protein and the sensitivity to water-soluble sulfhydryl reactive compounds MTSET ((2-(trimethylammonium) ethyl)methanethiosulfonate) and MTSES ((2-sulfonatoethyl) methanethiosulfonate) was determined for those residues with at least moderate activity remaining. Of the residues tested, only proteins with mutations L457C, I461C, and L465C were inhibited by MTSET. The activity of the L465C mutant was almost completely eliminated, whereas that of the L457C and I461C mutants was partially affected. The structure of a peptide representing TM XI (residues Lys(447)-Lys(472)) was determined using high resolution NMR spectroscopy in dodecylphosphocholine micelles. The structure consisted of helical regions between Asp(447)-Tyr(454) and Phe(460)-Lys(471) at the N and C termini of the peptide, respectively, connected by a region with poorly defined, irregular structure consisting of residues Gly(455)-Gly(459). TM XI of NHE1 had a structural similarity to TM XI of the Escherichia coli Na(+)/H(+) exchanger NhaA. The results suggest that TM XI is a discontinuous helix, with residue Leu(465) contributing to the pore.

Topics: Cation Transport Proteins; Escherichia coli; Humans; Hydrogen-Ion Concentration; Magnetic Resonance Spectroscopy; Mesylates; Micelles; Molecular Conformation; Mutagenesis, Site-Directed; Mutation; Oligonucleotides; Peptides; Protein Conformation; Protein Structure, Tertiary; Sodium-Hydrogen Exchanger 1; Sodium-Hydrogen Exchangers

Substituted cysteine accessibility mutagenesis (SCAM) has been used widely to identify pore-lining amino acid side chains in ion channel proteins. However, functional effects on permeation and gating can be difficult to separate, leading to uncertainty concerning the location of reactive cysteine side chains. We have combined SCAM with investigation of the charge-dependent effects of methanethiosulfonate (MTS) reagents on the functional permeation properties of cystic fibrosis transmembrane conductance regulator (CFTR) Cl(-) channels. We find that cysteines substituted for seven out of 21 continuous amino acids in the eleventh and twelfth transmembrane (TM) regions can be modified by external application of positively charged [2-(trimethylammonium)ethyl] MTS bromide (MTSET) and negatively charged sodium [2-sulfonatoethyl] MTS (MTSES). Modification of these cysteines leads to changes in the open channel current-voltage relationship at both the macroscopic and single-channel current levels that reflect specific, charge-dependent effects on the rate of Cl(-) permeation through the channel from the external solution. This approach therefore identifies amino acid side chains that lie within the permeation pathway. Cysteine mutagenesis of pore-lining residues also affects intrapore anion binding and anion selectivity, giving more information regarding the roles of these residues. Our results demonstrate a straightforward method of screening for pore-lining amino acids in ion channels. We suggest that TM11 contributes to the CFTR pore and that the extracellular loop between TMs 11 and 12 lies close to the outer mouth of the pore.

Topics: Amino Acid Sequence; Animals; Cricetinae; Cysteine; Cystic Fibrosis Transmembrane Conductance Regulator; Humans; Mesylates; Mutagenesis, Site-Directed; Patch-Clamp Techniques; Sulfhydryl Reagents

The Na(+)/H(+) exchanger isoform 1 (NHE1) is an integral membrane protein that regulates intracellular pH by removing one intracellular H(+) in exchange for one extracellular Na(+). It has a large N-terminal membrane domain of 12 transmembrane segments and an intracellular C-terminal regulatory domain. We characterized the cysteine accessibility of amino acids of the putative transmembrane segment IX (residues 339-363). Each residue was mutated to cysteine in a functional cysteineless NHE1 protein. Of 25 amino acids mutated, 5 were inactive or nearly so after mutation to cysteine. Several of these showed aberrant targeting to the plasma membrane and reduced expression of the intact protein, whereas others were expressed and targeted correctly but had defective NHE1 function. Of the active mutants, Glu(346) and Ser(351) were inhibited >70% by positively charged [2-(trimethylammonium)-ethyl]methanethiosulfonate but not by anionic [2-sulfonatoethyl]methanethiosulfonate, suggesting that they are pore lining and make up part of the cation conduction pathway. Both mutants also had decreased affinity for Na(+) and decreased activation by intracellular protons. The structure of a peptide representing amino acids 338-365 was determined by using high resolution NMR in dodecylphosphocholine micelles. The structure contained two helical regions (amino acids Met(340)-Ser(344) and Ile(353)-Ser(359)) kinked with a large bend angle around a pivot point at amino acid Ser(351). The results suggest that transmembrane IX is critical with pore-lining residues and a kink at the functionally important residue Ser(351).

Topics: Cation Transport Proteins; Cations; Cell Line, Tumor; Circular Dichroism; Cysteine; Gene Expression Regulation; Humans; Magnetic Resonance Spectroscopy; Mesylates; Micelles; Models, Molecular; Molecular Sequence Data; Mutagenesis, Site-Directed; Peptides; Protein Isoforms; Protein Structure, Tertiary; Sodium-Hydrogen Exchanger 1; Sodium-Hydrogen Exchangers; Sulfhydryl Reagents

We report the involvement of transmembrane domain 4 (TM4) of hASBT in forming the putative translocation pathway, using cysteine-scanning mutagenesis in conjunction with solvent-accessibility studies using the membrane-impermeant, sulfhydryl-specific methanethiosulfonate reagents. We individually mutated each of the 21 amino acids in TM4 to cysteine on a fully functional, MTS-resistant C270A-hASBT template. The single-cysteine mutants were expressed in COS-1 cells, and their cell surface expression levels, transport activities [uptake of the prototypical hASBT substrate taurocholic acid (TCA)], and sensitivities to MTS exposure were determined. Only P161 lacked cell-surface expression. Overall, cysteine replacement was tolerated at charged and polar residues, except for mutants I160C, Y162C, I165C, and G179C (

Topics: Amino Acid Sequence; Animals; Chlorocebus aethiops; Computational Biology; COS Cells; Cysteine; Cytosol; Humans; Mesylates; Models, Molecular; Molecular Sequence Data; Organic Anion Transporters, Sodium-Dependent; Point Mutation; Protein Structure, Secondary; Protein Structure, Tertiary; Sequence Alignment; Symporters

Investigation of the structure/function relationships of the sodium-glucose transporter (SGLT1) is crucial to understanding the cotransporter mechanism. In the present study, we used cysteine-scanning mutagenesis and chemical modification by methanethiosulfonate (MTS) derivatives to test whether predicted transmembrane IV participates in sugar binding. Five charged and polar residues (K139, Q142, T156, K157, and D161) and two glucose/galactose malabsorption missense mutations (I147 and S159) were replaced with cysteine. Mutants I147C, T156C, and K157C exhibited sufficient expression to be studied in detail using the two-electrode voltage-clamp method in Xenopus laevis oocytes and COS-7 cells. I147C was similar in function to wild-type and was not studied further. Mutation of lysine-157 to cysteine (K157C) causes loss of phloridzin and alpha-methyl-D-glucopyranoside (alphaMG) binding. These functions are restored by chemical modification with positively charged (2-aminoethyl) methanethiosulfonate hydrobromide (MTSEA). Mutation of threonine-156 to cysteine (T156C) reduces the affinity of alphaMG and phloridzin for T156C by approximately 5-fold and approximately 20-fold, respectively. In addition, phloridzin protects cysteine-156 in T156C from alkylation by MTSEA. Therefore, the presence of a positive charge or a polar residue at 157 and 156, respectively, affects sugar binding and sugar-induced Na(+) currents.

Topics: Alkylation; Animals; Carbohydrate Metabolism; Chlorocebus aethiops; COS Cells; Cricetinae; Cysteine; Ethyl Methanesulfonate; Female; Mesylates; Methylglucosides; Mutation, Missense; Oocytes; Patch-Clamp Techniques; Phlorhizin; Protein Structure, Tertiary; Rabbits; Sodium-Glucose Transporter 1; Xenopus laevis

Interactions between nontransmembrane domains and the lipid membrane are proposed to modulate activity of many ion channels. In Kir channels, the so-called "slide-helix" is proposed to interact with the lipid headgroups and control channel gating. We examined this possibility directly in a cell-free system consisting of KirBac1.1 reconstituted into pure lipid vesicles. Cysteine substitution of positively charged slide-helix residues (R49C and K57C) leads to loss of channel activity that is rescued by in situ restoration of charge following modification by MTSET(+) or MTSEA(+), but not MTSES(-) or neutral MMTS. Strikingly, activity is also rescued by modification with long-chain alkyl-MTS reagents. Such reagents are expected to partition into, and hence tether the side chain to, the membrane. Systematic scanning reveals additional slide-helix residues that are activated or inhibited following alkyl-MTS modification. A pattern emerges whereby lipid tethering of the N terminus, or C terminus, of the slide-helix, respectively inhibits, or activates, channel activity. This study establishes a critical role of the slide-helix in Kir channel gating, and directly demonstrates that physical interaction of soluble domains with the membrane can control ion channel activity.

Topics: Bacterial Proteins; Burkholderia pseudomallei; Cell-Free System; Cloning, Molecular; Cysteine; Ethyl Methanesulfonate; Ion Channel Gating; Membrane Lipids; Mesylates; Methyl Methanesulfonate; Models, Molecular; Mutation; Potassium Channels, Inwardly Rectifying; Protein Binding; Protein Conformation; Protein Structure, Tertiary; Rubidium Radioisotopes; Sulfhydryl Reagents

In a previous study of T338C CFTR (cystic fibrosis transmembrane conductance regulator) we found that protons and thiol-directed reagents modified channel properties in a manner consistent with the hypothesis that this residue lies within the conduction path, but the observed reactivity was not consistent with the presence of a single thiolate species in the pore. Here we report results consistent with the notion that the thiol moiety can exist in at least three chemical states, the simple thiol, and two altered states. One of the altered states displays reactivity toward thiols like dithiothreitol and 2-mercaptoethanol as well as reagents: mixed disulfides (methanethiosulfonate reagents: MTSET+, MTSES-) and an alkylating agent (iodoacetamide). The other altered state is unreactive. The phenotype associated with the reactive, altered state could be replicated by exposing oocytes expressing T338C CFTR to CuCl2, but not by glutathionylation or nitrosylation of the thiol or by oxidation with hydrogen peroxide. The results are consistent with the hypothesis that substituting a cysteine at 338 can create an adventitious metal binding site. Metal liganding alters thiol reactivity and may, in some cases, catalyze oxidation of the thiol to an unreactive form such as a sulfinic or sulfonic acid.

Topics: Alkylating Agents; Animals; Catalysis; Copper; Cysteine; Cystic Fibrosis Transmembrane Conductance Regulator; Disulfides; Dithiothreitol; Glutathione; Humans; Hydrogen Peroxide; Hydrogen-Ion Concentration; Iodoacetamide; Mercaptoethanol; Mesylates; Metals; Models, Biological; Oocytes; Oxygen; Phenotype; Protein Engineering; Sulfhydryl Compounds; Sulfinic Acids; Sulfonic Acids; Time Factors; Xenopus

The Ca(2+)-activated K+ (BK) channel alpha-subunit contains many cysteine residues within its large COOH-terminal tail domain. To probe the function of this domain, we examined effects of cysteine-modifying reagents on channel gating. Application of MTSET, MTSES, or NEM to mSlo1 or hSlo1 channels changed the voltage and Ca2+ dependence of steady-state activation. These reagents appear to modify the same cysteines but have different effects on function. MTSET increases I(K) and shifts the G(K)-V relation to more negative voltages, whereas MTSES and NEM shift the G(K)-V in the opposite direction. Steady-state activation was altered in the presence or absence of Ca2+ and at negative potentials where voltage sensors are not activated. Combinations of [Ca2+] and voltage were also identified where P(o) is not changed by cysteine modification. Interpretation of our results in terms of an allosteric model indicate that cysteine modification alters Ca2+ binding and the relative stability of closed and open conformations as well as the coupling of voltage sensor activation and Ca2+ binding and to channel opening. To identify modification-sensitive residues, we examined effects of MTS reagents on mutant channels lacking one or more cysteines. Surprisingly, the effects of MTSES on both voltage- and Ca(2+)-dependent gating were abolished by replacing a single cysteine (C430) with alanine. C430 lies in the RCK1 (regulator of K+ conductance) domain within a series of eight residues that is unique to BK channels. Deletion of these residues shifted the G(K)-V relation by > -80 mV. Thus we have identified a region that appears to strongly influence RCK domain function, but is absent from RCK domains of known structure. C430A did not eliminate effects of MTSET on apparent Ca2+ affinity. However an additional mutation, C615S, in the Haem binding site reduced the effects of MTSET, consistent with a role for this region in Ca2+ binding.

Topics: Animals; Calcium; Cysteine; Electrophysiology; Humans; Indicators and Reagents; Ion Channel Gating; Large-Conductance Calcium-Activated Potassium Channel alpha Subunits; Large-Conductance Calcium-Activated Potassium Channels; Mesylates; Mice; Potassium Channels, Calcium-Activated

Twenty-two amino acid residues from transmembrane domain 3 of the creatine transporter were replaced, one at a time, with cysteine. The background for mutagenesis was a C144S mutant retaining approximately 75% of wild-type transport activity but resistant to methanethiosulfonate (MTS) reagents. Each substitution mutant was tested for creatine transport activity and sensitivity to the following MTS reagents: 2-aminoethyl methanethiosulfonate (MTSEA), 2-(trimethylammonium) ethyl methanethiosulfonate (MTSET), and 2-sulfonatoethyl methanethiosulfonate (MTSES). Two mutants (G134C and Y148C) were inactive, but most mutants showed significant levels of creatine transport. Treatment with MTSEA inhibited the activity of the W154C, Y147C, and I140C mutants. Creatine partially protected I140C from inactivation, and this residue, like Cys-144 in the wild-type CreaT, is predicted to be close to a creatine binding site. MTSEA inactivation of Y147C was dependent on Na+ and Cl- suggesting that solvent accessibility was ion-dependent. Helical wheel and helical net projections indicate that the three MTSEA-sensitive mutants (W154C, Y147C, and I140C) and two inactive mutants (V151C and Y148C) are aligned on a face of an alpha-helix, suggesting that they form part of a substrate pathway. The W154C mutant, located near the external face of the membrane, was accessible to the larger MTS reagents, whereas those implicated in creatine binding were only accessible to the smaller MTSEA. Consideration of our data, together with a study on the serotonin transporter (Chen, J. G., Sachpatzidis, A., and Rudnick, G. (1997) J. Biol. Chem. 272, 28321-28327), suggests that involvement of residues from transmembrane domain 3 is a common feature of the substrate pathway of Na+- and Cl- -dependent neurotransmitter transporters.

Topics: Amino Acid Sequence; Binding Sites; Biological Transport; Biotinylation; Cell Line; Cell Membrane; Chlorine; Creatine; Cysteine; Dose-Response Relationship, Drug; Humans; Ions; Membrane Transport Proteins; Mesylates; Models, Biological; Molecular Sequence Data; Mutagenesis; Mutation; Protein Binding; Protein Structure, Tertiary; Sodium; Solvents; Sulfhydryl Reagents; Time Factors; Transfection

The serotonin transporter (SERT) belongs to a family of sodium-chloride-dependent transporters responsible for uptake of amino acids and biogenic amines from the extracellular space. SERT represents a major pharmacological target in the treatment of several clinical conditions, including depression and anxiety. In the present study we have undertaken a mutational scanning of human SERT in order to identify residues that are responsible for individual differences among related monoamine transporters. One mutant, G100A, was inactive in transport. However, ligand binding affinity was similar to wild-type, suggesting that G100A amongst different possible SERT conformations is restrained to a binding conformation. We suggest that the main role of glycine-100 is to confer structural flexibility during substrate translocation. For the two single mutants, T178A and F263C, uptake rates and K(m) values were both several-fold higher than wild-type while binding affinities and inhibitory potencies decreased considerably for several drugs. Ion dependency increased and only at hyperosmotic concentrations were K(m) values partly restored. For the double mutant, T178A/F263C, shifts in uptake kinetics and ligand affinities, as well as ion dependencies, were drastic. Effects were synergistic compared to the corresponding single mutants. In conclusion, we suggest that mutating threonine-178 to an alanine and phenylalanine-263 to a cysteine mainly alter the overall uptake kinetics of SERT by affecting the conformational equilibrium of different transporter conformations.

Topics: Amino Acid Sequence; Animals; Binding Sites; Biological Transport; Blotting, Western; Carrier Proteins; Chimera; Chlorocebus aethiops; Choline; Cloning, Molecular; Cocaine; COS Cells; Dose-Response Relationship, Drug; Humans; Indicators and Reagents; Inhibitory Concentration 50; Membrane Glycoproteins; Membrane Transport Proteins; Mesylates; Molecular Sequence Data; Mutagenesis, Site-Directed; Mutation; Nerve Tissue Proteins; Radiopharmaceuticals; Serotonin; Serotonin Plasma Membrane Transport Proteins; Sodium; Structure-Activity Relationship; Transfection

Residues 386-423 of the rat brain serotonin transporter (SERT) are predicted to form a hydrophilic loop connecting transmembrane spans 7 and 8 (extracellular loop 4 or EL4). EL4 has been hypothesized to play a role in conformational changes associated with substrate translocation. To more fully investigate EL4 structure and function, we performed cysteine-scanning mutagenesis and methanethiosulfonate (MTS) accessibility studies on these 38 residues. Four EL4 mutants (M386C, R390C, G402C, and L405C) showed very low transport activities, low cell surface expression, and strong inhibition by MTS reagents, indicating high structural and functional importance. Twelve mutants were sensitive to very low MTS concentrations, indicating positions highly exposed to the aqueous environment. Eleven mutants were MTS-insensitive, indicating positions that were either buried in EL4 structure or functionally unimportant. The patterns of sensitivity to mutation and MTS reagents were used to produce a structural model of EL4. Positions 386-399 and 409-421 are proposed to form alpha-helices, connected by nine consecutive MTS-sensitive positions, within which four positions, 402-405, may form a turn or hinge. The presence of serotonin changed the MTS accessibility of cysteines at nine positions, while cocaine, a non-transportable blocker, did not affect accessibility. Serotonin-induced accessibility changes required both Na(+) and Cl(-), indicating that they were associated with active substrate translocation. With the exception of a single mutant, F407C, neither mutation to cysteine nor treatment with MTS reagents affected SERT affinities for serotonin or the cocaine analog beta-CIT. These studies support the role of EL4 in conformational changes occurring during translocation and show that it does not play a direct role in serotonin binding.

Topics: Animals; Binding Sites; Biological Transport; Biotinylation; Carrier Proteins; Cocaine; Cysteine; DNA, Complementary; Dose-Response Relationship, Drug; HeLa Cells; Humans; Indicators and Reagents; Ions; Kinetics; Membrane Glycoproteins; Membrane Transport Proteins; Mesylates; Models, Molecular; Mutagenesis, Site-Directed; Mutation; Nerve Tissue Proteins; Protein Binding; Protein Conformation; Protein Structure, Tertiary; Protein Transport; Rats; Serotonin; Serotonin Plasma Membrane Transport Proteins; Structure-Activity Relationship; Zinc

External loop 5 (EL5) of serotonin transporter was analyzed by mutating each of the residues from Thr-480 to Ala-511, one at a time, with cysteine. Cysteine was well-tolerated at most positions, although G485C, Y495C, and E508C had low transport activities. Replacement with cysteine rendered mutants G484C-P499C sensitive to partial or complete inactivation by [2-(trimethylammonium)ethyl] methanethiosulfonate and (2-sulfonatoethyl) methanethiosulfonate. Within this sensitive region, the rates of reaction varied by over 2 orders of magnitude. Rates of inactivation were not significantly affected by removal of Na(+) or by addition of cocaine or serotonin. These results suggest that modification of EL5 interferes with the transport process but is not sensitive to substrate and ion binding.

Topics: Alanine; Amino Acid Sequence; Animals; Binding Sites; Biological Transport; Carrier Proteins; Cocaine; Cysteine; Dose-Response Relationship, Drug; Epitopes; HeLa Cells; Humans; Ions; Membrane Glycoproteins; Membrane Transport Proteins; Mesylates; Molecular Sequence Data; Mutagenesis, Site-Directed; Mutation; Nerve Tissue Proteins; Protein Structure, Secondary; Protein Structure, Tertiary; Rats; Sequence Homology, Amino Acid; Serotonin; Serotonin Plasma Membrane Transport Proteins; Sodium; Threonine

P-Glycoprotein (P-gp) is an ATP-dependent drug pump that transports a broad range of compounds out of the cell. Cross-linking studies have shown that the drug-binding pocket is at the interface between the transmembrane (TM) domains and can simultaneously bind two different drug substrates. Here, we determined whether cysteine residues within the drug-binding pocket were accessible to the aqueous medium. Cysteine mutants were tested for their reactivity with the charged thiol-reactive compounds sodium (2-sulfonatoethyl)methanethiosulfonate (MTSES) and [2-(trimethylammonium)ethyl)]methanethiosulfonate (MTSET). Residue Ile-306(TM5) is close to the verapamil-binding site. It was changed to cysteine, reacted with MTSES or MTSET, and assayed for verapamil-stimulated ATPase activity. Reaction of mutant I306C(TM5) with either compound reduced its affinity for verapamil. We confirmed that the reduced affinity for verapamil was indeed due to introduction of a charge at position 306 by demonstrating that similar effects were observed when Ile-306 was replaced with arginine or glutamic acid. Mutant I306R showed a 50-fold reduction in affinity for verapamil and very little change in the affinity for rhodamine B or colchicine. MTSES or MTSET modification also affected the cross-linking pattern between pairs of cysteines in the drug-binding pocket. For example, both MTSES and MTSET inhibited cross-linking between I306C(TM5) and I868C(TM10). Inhibition was enhanced by ATP hydrolysis. By contrast, cross-linking of cysteine residues located outside the drug-binding pocket (such as G300C(TM5)/F770C(TM8)) was not affected by MTSES or MTSET. These results indicate that the drug-binding pocket is accessible to water.

Topics: Adenosine Triphosphatases; Adenosine Triphosphate; ATP Binding Cassette Transporter, Subfamily B, Member 1; Binding Sites; Biological Transport; Buffers; Cell Line; Colchicine; Cyclosporine; Cysteine; Drug Resistance, Multiple; Gene Expression Regulation; Humans; Hydrolysis; Isoleucine; Mesylates; Mutation; Rhodamines; Verapamil; Water

The melibiose transporter (Mel B) of Escherichia coli is a cation-coupled (H(+), Li(+), and Na(+)) membrane protein (MW 50 kDa) consisting of 12 transmembrane helices that are connected by periplasmic and cytoplasmic loops, with both the C- and N-ends located on the cytoplasmic side of the membrane. Previous investigations on the largest cytoplasmic loop X/XI indicated that it is a functional re-entrant loop. In this communication, the cysteine mutants on loop X/XI were studied with charged thiol reagents MTSES, MTSET, and IAA for both the inhibition patterns and charge replacement/function rescue of inactive mutants in which the original charged residues were replaced by neutral cysteines. Strong inhibitions were observed in T373C and V376C by both MTSES and MTSET, consistent with previous results of PCMBS inhibition. The thiol reagents failed to recover the activities of inactive mutants D351C, D354C, and R363C and to inhibit active mutants E357C, K359C, and E365C to any significant extent, suggesting a structural conservation at D351, D354, and R363 and tolerance of structural variations at E357, K359, and E365. The results are consistent with previous observation of structural conservation of functionally charged residues in the transmembrane domains and extend to a loop the contention that in the melibiose transporter functionally important charged residues are structurally conserved.

Topics: 4-Chloromercuribenzenesulfonate; Amino Acids; Animals; Biological Transport; Cells, Cultured; Cysteine; Escherichia coli Proteins; Iodoacetic Acid; Melibiose; Mesylates; Mutation; Protein Structure, Secondary; Sulfhydryl Reagents; Symporters

The ATP/ADP translocase (Tlc) of Rickettsia prowazekii is a basic protein with isoelectric point (pI)=9.84. It is conceivable, therefore, that basic residues in this protein are involved in electrostatic interactions with negatively charged substrates. We tested this hypothesis by individually mutating all basic residues in Tlc to Cys. Unexpectedly, mutations of only 20 out of 51 basic residues resulted in greater than 80% inhibition of transport activity. Moreover, 12 of 51Cys-substitution mutants exhibited higher than wild-type (WT) activity. At least in one case this up-effect was additive and the double mutant Lys422Cys Lys427Cys transported ATP five-fold better than WT protein. Since in these two single mutants and in the corresponding double mutant K(m)'s were similar to that of WT protein, we conclude that Tlc may have evolved a mechanism that limits the transporter's exchange rate and that at least these two basic residues play a key role in that mechanism. Based on the alignment of 16 Tlc homologs, the loss of activity in the mutants poorly correlates with charge conservation within the Tlc family. Also, despite the presence of three positively charged and one negatively charged intramembrane residues, we have failed to identify potential charge pairs (salt bridges) by either charge reversal or charge neutralization approaches.

Topics: Amino Acids, Basic; Arginine; Cysteine; Cytoplasm; Kinetics; Lysine; Mesylates; Mitochondrial ADP, ATP Translocases; Mutagenesis, Site-Directed; Mutation; Periplasm; Protein Structure, Tertiary; Rickettsia prowazekii

Cysteine-scanning mutagenesis (SCAM) and computer-based modeling were used to investigate key structural features of the S6 transmembrane segment of the calcium-activated K(+) channel of intermediate conductance IKCa. Our SCAM results show that the interaction of [2-(trimethylammonium)ethyl] methanethiosulfonate bromide (MTSET) with cysteines engineered at positions 275, 278, and 282 leads to current inhibition. This effect was state dependent as MTSET appeared less effective at inhibiting IKCa in the closed (zero Ca(2+) conditions) than open state configuration. Our results also indicate that the last four residues in S6, from A283 to A286, are entirely exposed to water in open IKCa channels, whereas MTSET can still reach the 283C and 286C residues with IKCa maintained in a closed state configuration. Notably, the internal application of MTSET or sodium (2-sulfonatoethyl) methanethiosulfonate (MTSES) caused a strong Ca(2+)-dependent stimulation of the A283C, V285C, and A286C currents. However, in contrast to the wild-type IKCa, the MTSET-stimulated A283C and A286C currents appeared to be TEA insensitive, indicating that the MTSET binding at positions 283 and 286 impaired the access of TEA to the channel pore. Three-dimensional structural data were next generated through homology modeling using the KcsA structure as template. In accordance with the SCAM results, the three-dimensional models predict that the V275, T278, and V282 residues should be lining the channel pore. However, the pore dimensions derived for the A283-A286 region cannot account for the MTSET effect on the closed A283C and A286 mutants. Our results suggest that the S6 domain extending from V275 to V282 possesses features corresponding to the inner cavity region of KcsA, and that the COOH terminus end of S6, from A283 to A286, is more flexible than predicted on the basis of the closed KcsA crystallographic structure alone. According to this model, closure by the gate should occur at a point located between the T278 and V282 residues.

Topics: Animals; Computers; Cysteine; Electric Conductivity; Female; HeLa Cells; Humans; Mesylates; Models, Biological; Models, Genetic; Mutagenesis; Oocytes; Potassium Channels, Calcium-Activated; Sequence Homology; Sulfhydryl Reagents; Xenopus laevis

This study investigated the residues responsible for the reduced picrotoxin sensitivity of the alphabeta heteromeric glycine receptor relative to the alpha homomeric receptor. By analogy with structurally related receptors, the beta subunit M2 domain residues P278 and F282 were considered the most likely candidates for mediating this effect. These residues align with G254 and T258 of the alpha subunit. The T258A, T258C and T258F mutations dramatically reduced the picrotoxin sensitivity of the alpha homomeric receptor. Furthermore, the converse F282T mutation in the beta subunit increased the picrotoxin sensitivity of the alphabeta heteromeric receptor. The P278G mutation in the beta subunit did not affect the picrotoxin sensitivity of the alphabeta heteromer. Thus, a ring of five threonines at the M2 domain depth corresponding to alpha subunit T258 is specifically required for picrotoxin sensitivity. Mutations to alpha subunit T258 also profoundly influenced the apparent glycine affinity. A substituted cysteine accessibility analysis revealed that the T258C sidechain increases its pore exposure in the channel open state. This provides further evidence for an allosteric mechanism of picrotoxin inhibition, but renders it unlikely that picrotoxin (as an allosterically acting 'competitive' antagonist) binds to this residue.

Topics: Allosteric Regulation; Amino Acid Substitution; Binding Sites; Binding, Competitive; Cell Line; Chloride Channels; Dose-Response Relationship, Drug; Glycine; Humans; Kidney; Mesylates; Mutagenesis, Site-Directed; Picrotoxin; Protein Structure, Tertiary; Protein Subunits; Receptors, Glycine; Sequence Homology, Amino Acid; Sulfhydryl Reagents

Membrane-impermeant quaternary amine local anesthetics QX314 and QX222 can access their binding site on the cytoplasmic side of the selectivity filter from the outside in native cardiac Na(+) channels. Mutation of domain IV S6 Ile-1760 of rat brain IIA Na(+) channel or the equivalent (Ile-1575) in the adult rat skeletal muscle isoform (mu 1) creates an artificial access path for QX. We examined the characteristics of mutation of mu 1-I1575 and the resulting QX path. In addition to allowing external QX222 access, I1575A accelerated decay of Na(+) current and shifted steady-state availability by -27 mV. I1575A had negligible effects on inorganic or organic cation selectivity and block by tetrodotoxin (TTX), saxitoxin (STX), or mu-conotoxin (mu-CTX). It exposed a site within the protein that binds membrane-permeant methanethiosulfonate ethylammonium (MTSEA), but not membrane-impermeant methanethiosulfonate ethyltrimethylammonium (MTSET) and methanethiosulfonate ethylsulfonate (MTSES). MTSEA binding abolished the QX path created by this mutation, without effects on toxin binding. The mu-CTX derivative R13N, which partially occluded the pore, had no effect on QX access. I1575A exposed two Cys residues because a disulfide bond was formed under oxidative conditions, but the exposed Cys residues are not those in domain IV S6, adjacent to Ile-1575. The Cys mutant I1575C was insensitive to external Cd(2+) and MTS compounds (MTSEA, MTSET, MTSES), and substitution of Ile with a negatively charged residue (I1575E) did not affect toxin binding. Ile-1575 seems to be buried in the protein, and its mutation disrupts the protein structure to create the QX path without disturbing the outer vestibule and its selectivity function.

Topics: Amino Acid Substitution; Anesthetics, Local; Animals; Calcium Channel Blockers; Cells, Cultured; Conotoxins; Ethyl Methanesulfonate; Ion Channel Gating; Lidocaine; Mesylates; Mutagenesis, Site-Directed; Oocytes; Patch-Clamp Techniques; Protein Isoforms; Rats; Saxitoxin; Sodium Channel Blockers; Sodium Channels; Structure-Activity Relationship; Tetrodotoxin; Transfection; Xenopus laevis

Mutations in the extracellular M2-M3 loop of the glycine receptor (GlyR) alpha1 subunit have been shown previously to affect channel gating. In this study, the substituted cysteine accessibility method was used to investigate whether a structural rearrangement of the M2-M3 loop accompanies GlyR activation. All residues from R271C to V277C were covalently modified by both positively charged methanethiosulfonate ethyltrimethylammonium (MTSET) and negatively charged methanethiosulfonate ethylsulfonate (MTSES), implying that these residues form an irregular surface loop. The MTSET modification rate of all residues from R271C to K276C was faster in the glycine-bound state than in the unliganded state. MTSES modification of A272C, L274C, and V277C was also faster in the glycine-bound state. These results demonstrate that the surface accessibility of the M2-M3 loop is increased as the channel transitions from the closed to the open state, implying that either the loop itself or an overlying domain moves during channel activation.

Topics: Amino Acid Substitution; Cell Line; Cysteine; Dithiothreitol; Dose-Response Relationship, Drug; Glycine; Humans; Ion Channel Gating; Kidney; Mesylates; Mutagenesis, Site-Directed; Patch-Clamp Techniques; Protein Binding; Protein Conformation; Receptors, Glycine; Reducing Agents; Reflex, Startle; Transfection

In AMPA receptor channels, a single amino acid residue (Q/R site) of the M2 segment controls permeation of calcium ions, single-channel conductance, blockade by intracellular polyamines, and permeation of anions. The structural environment of the Q/R site and its positioning with regard to a narrow constriction were probed with the accessibility of substituted cysteines to positively and negatively charged methanethiosulfonate reagents, applied from the extracellular and cytoplasmic sides of the channel. The accessibility patterns confirm that the M2 segment forms a pore loop with the Q/R site positioned at the tip of the loop (position 0) facing the extracellular vestibule. Cytoplasmically accessible residues on the N- and C-terminal sides of position 0 form the ascending alpha-helical (-8 to -1) and descending random coil (+1 to +6) components of the loop, respectively. Substitution of a glycine residue at position +2 with alanine strongly decreased the permeability of organic cations, indicating that position +2 contributes to the narrow constriction. The anionic 2-sulfonatoethyl-methanethiosufonate reacted with a cysteine at position 0 only from the external side and with cysteines at positions +1 to +4 only from the cytoplasmic side. These results suggest that charge selectivity occurs external to the constriction (+2) and possibly involves interactions of ions with the negative electrostatic potential created by the dipole of the alpha-helix formed by the ascending limb of the loop.

Topics: Amino Acid Substitution; Animals; Calcium; Cysteine; Cytoplasm; Dose-Response Relationship, Drug; Ethyl Methanesulfonate; Glutamic Acid; Ion Channel Gating; Kainic Acid; Kinetics; Membrane Potentials; Mesylates; Microinjections; Mutagenesis, Site-Directed; Oocytes; Patch-Clamp Techniques; Permeability; Receptors, AMPA; Structure-Activity Relationship; Sulfhydryl Reagents; Xenopus laevis

The goal of the experiments described here was to explore the possible role of fixed charges in determining the conduction properties of CFTR. We focused on transmembrane segment 6 (TM6) which contains four basic residues (R334, K335, R347, and R352) that would be predicted, on the basis of their positions in the primary structure, to span TM6 from near the extracellular (R334, K335) to near the intracellular (R347, R352) end. Cysteines substituted at positions 334 and 335 were readily accessible to thiol reagents, whereas those at positions 347 and 352 were either not accessible or lacked significant functional consequences when modified. The charge at positions 334 and 335 was an important determinant of CFTR channel function. Charge changes at position 334--brought about by covalent modification of engineered cysteine residues, pH titration of cysteine and histidine residues, and amino acid substitution--produced similar effects on macroscopic conductance and the shape of the I-V plot. The effect of charge changes at position 334 on conduction properties could be described by electrodiffusion or rate-theory models in which the charge on this residue lies in an external vestibule of the pore where it functions to increase the concentration of Cl adjacent to the rate-limiting portion of the conduction path. Covalent modification of R334C CFTR increased single-channel conductance determined in detached patches, but did not alter open probability. The results are consistent with the hypothesis that in wild-type CFTR, R334 occupies a position where its charge can influence the distribution of anions near the mouth of the pore.

Topics: Animals; Anions; Arginine; Cysteine; Cystic Fibrosis Transmembrane Conductance Regulator; Disulfides; Electric Conductivity; Ethyl Methanesulfonate; Female; Humans; Hydrogen-Ion Concentration; Lysine; Membrane Potentials; Mercaptoethanol; Mesylates; Models, Biological; Oocytes; Patch-Clamp Techniques; Perfusion; Xenopus

The FMRF-amide-activated sodium channel (FaNaC), a member of the ENaC/Degenerin family, is a homotetramer, each subunit containing two transmembrane segments. We changed independently every residue of the first transmembrane segment (TM1) into a cysteine and tested each position's accessibility to the cysteine covalent reagents MTSET and MTSES. Eleven mutants were accessible to the cationic MTSET, showing that TM1 faces the ion translocation pathway. This was confirmed by the accessibility of cysteines present in the acid-sensing ion channels and other mutations introduced in FaNaC TM1. Modification of accessibilities for positions 69, 71 and 72 in the open state shows that the gating mechanism consists of the opening of a constriction close to the intracellular side. The anionic MTSES did not penetrate into the channel, indicating the presence of a charge selectivity filter in the outer vestibule. Furthermore, amiloride inhibition resulted in the channel occlusion in the middle of the pore. Summarizing, the ionic pore of FaNaC includes a large aqueous cavity, with a charge selectivity filter in the outer vestibule and the gate close to the interior.

Topics: Amino Acid Sequence; Amino Acid Substitution; Animals; Cell Line; Cysteine; DNA, Complementary; Female; FMRFamide; Humans; Ion Channel Gating; Ion Transport; Mesylates; Models, Molecular; Molecular Sequence Data; Multigene Family; Mutagenesis, Site-Directed; Oocytes; Protein Conformation; Protein Structure, Tertiary; Recombinant Fusion Proteins; Sequence Alignment; Sequence Homology, Amino Acid; Sodium; Sodium Channels; Static Electricity; Sulfhydryl Reagents; Xenopus laevis

The beta-amino acid, taurine, is a full agonist of the human glycine receptor alpha1 subunit when recombinantly expressed in a mammalian (HEK293) cell line, but a partial agonist of the same receptor when expressed in Xenopus oocytes. Several residues in the Ala101-Thr112 domain have previously been identified as determinants of beta-amino acid binding and gating mechanisms in Xenopus oocyte-expressed receptors. The present study used the substituted cysteine accessibility method to investigate the role of this domain in controlling taurine-specific binding and gating mechanisms of glycine receptors recombinantly expressed in mammalian cells. Asn102 and Glu103 are identified as taurine and glycine binding sites, whereas Ala101 is eliminated as a possible binding site. The N102C mutation also abolished the antagonistic actions of taurine, indicating that this site does not discriminate between the putative agonist- and antagonist-bound conformations of beta-amino acids. The effects of mutations from Lys104-Thr112 indicate that the mechanism by which this domain controls beta-amino acid-specific binding and gating processes differs substantially depending on whether the receptor is expressed in mammalian cells or Xenopus oocytes. Thr112 is the only domain element in mammalian cell-expressed GlyRs which was demonstrated to discriminate between glycine and taurine.

Topics: Amino Acid Substitution; Binding Sites; Cell Line; Cysteine; Glycine; Humans; Ion Channel Gating; Kidney; Mesylates; Mutagenesis, Site-Directed; Protein Structure, Tertiary; Receptors, Glycine; Sulfhydryl Reagents; Taurine

Using a functional mitochondrial oxoglutarate carrier mutant devoid of Cys residues (C-less carrier), each amino acid residue in transmembrane domain IV and flanking hydrophilic loops (from T179 to S205) was replaced individually with Cys. The great majority of the 27 mutants exhibited significant oxoglutarate transport in reconstituted liposomes as compared to the activity of the C-less carrier. In contrast, Cys substitution for G183, R190, Q198, and Y202, in either C-less or wild-type carriers, yielded molecules with complete loss of oxoglutarate transport activity. G183 and R190 could be partially replaced only by Ala and Lys, respectively, whereas Q198 and Y202 were irreplaceable with respect to oxoglutarate transport. Of the single-Cys mutants tested, only T187C, A191C, V194C, and N195C were strongly inactivated by N-ethylmaleimide and by low concentrations of methanethiosulfonate derivatives. Oxoglutarate protects Cys residues at positions 187, 191, and 194 against reaction with N-ethylmaleimide. These positions as well as the residues found to be essential for the carrier activity, except Y202 which is located in the extramembrane loop IV-V, reside on the same face of transmembrane helix IV, probably lining part of a water-accessible crevice or channel between helices of the oxoglutarate carrier.

Topics: Amino Acid Sequence; Amino Acid Substitution; Animals; Biological Transport, Active; Carrier Proteins; Cattle; Cysteine; Ethyl Methanesulfonate; Ethylmaleimide; Ketoglutaric Acids; Membrane Proteins; Membrane Transport Proteins; Mesylates; Mitochondria, Heart; Molecular Sequence Data; Mutagenesis, Site-Directed; Protein Structure, Secondary; Protein Structure, Tertiary; Proteolipids; Recombinant Proteins; Sulfhydryl Reagents

The structure of the bacterial potassium channel KcsA has provided a framework for understanding the related voltage-gated potassium channels (Kv channels) that are used for signalling in neurons. Opening and closing of these Kv channels (gating) occurs at the intracellular entrance to the pore, and this is also the site at which many open channel blockers affect Kv channels. To learn more about the sites of blocker binding and about the structure of the open Kv channel, we investigated here the ability of blockers to protect against chemical modification of cysteines introduced at sites in transmembrane segment S6, which contributes to the intracellular entrance. Within the intracellular half of S6 we found an abrupt cessation of protection for both large and small blockers that is inconsistent with the narrow 'inner pore' seen in the KcsA structure. These and other results are most readily explained by supposing that the structure of Kv channels differs from that of the non-voltage-gated bacterial channel by the introduction of a sharp bend in the inner (S6) helices. This bend would occur at a Pro-X-Pro sequence that is highly conserved in Kv channels, near the site of activation gating.

Topics: Bacterial Proteins; Cysteine; Hydrogen Bonding; Intracellular Signaling Peptides and Proteins; Ion Channel Gating; Mesylates; Models, Molecular; Peptides; Potassium; Potassium Channel Blockers; Potassium Channels; Protein Conformation; Protein Structure, Secondary; Quaternary Ammonium Compounds; Shaker Superfamily of Potassium Channels; Static Electricity; Tetraethylammonium

The effects of sulfhydryl-specific methanethiosulfonate (MTS) derivatives on mu-opioid receptor binding were examined in Chinese hamster ovary (CHO) cells that stably express mu-opioid receptors (HmuCHO). Three charged MTS derivatives inhibited the binding of [(3)H][D-Ala(2),N-MePhe(4),Gly-ol(5)]-enkephalin to mu-opioid receptors with IC(50) values ranging from 0.12 to 13 mM. Further characterization of the mu-opioid receptor interactions with ethylammonium MTS (the most potent among tested MTS reagents) revealed that ethylammonium MTS inhibition of ligand binding to the receptor was irreversible, with both the maximal receptor binding (B(max)) and the binding affinity (K(d)) being changed. Preincubation of HmuCHO cells with [D-Ala(2),N-MePhe(4), Gly-ol(5)]-enkephalin or naloxone prevented the receptor inactivation normally caused by MTS derivatives, indicating that the reactions may occur within or near the ligand-binding pocket on the receptor. To identify the susceptible sulfhydryl groups, each of the cysteine residues in the mu-receptor transmembrane domains were substituted with serine by site-directed mutagenesis. All of the mutant receptors transiently expressed in COS cells had receptor binding properties similar to the wild-type receptors. However, four mutant receptors with a serine substitution in transmembrane domain III (C161S), IV (C192S), V (C237S), or VII (C332S) displayed significant resistance against MTS inhibition compared with the wild-type receptor. We conclude that these four cysteine residues react with MTS reagents and are responsible for the effect of the MTS reagents on mu-opioid receptor binding.

Topics: Alanine; Amino Acid Sequence; Amino Acid Substitution; Animals; CHO Cells; COS Cells; Cricetinae; Cysteine; Enkephalin, Ala(2)-MePhe(4)-Gly(5)-; Ethyl Methanesulfonate; Humans; Ligands; Membranes; Mesylates; Molecular Sequence Data; Mutagenesis, Site-Directed; Naloxone; Narcotic Antagonists; Radioligand Assay; Receptors, Opioid, mu; Sulfhydryl Reagents

Mammalian sodium/bile acid cotransporters (SBATs) constitute a subgroup of the sodium cotransporter superfamily and function in the enterohepatic circulation of bile acids. They are glycoproteins with an exoplasmic N-terminus, seven or nine transmembrane segments, and a cytoplasmic C-terminus. They exhibit no significant homology with other members of the sodium cotransporter family and there is limited structure/function information available for the SBATs. Membrane-impermeant methanethiosulfonates (MTS) inhibited bile acid transport by alkylation of cysteine 270 (apical SBAT)/266 (basolateral SBAT) that is fully conserved among the sodium/bile acid cotransporters. The accessibility of this residue to MTS reagent is regulated by the natural substrates, sodium and bile acid. In experiments with the apical SBAT, sodium alone increases the reactivity with the thiol reagents as compared to sodium-free medium. In contrast, bile acids protect the SBATs from inactivation, although only in the presence of sodium. The inhibition and protection data suggest that cysteine 270/266 lies in a sodium-sensitive region of the SBATs that is implicated in bile acid transport.

Topics: Amino Acid Sequence; Animals; Bile Acids and Salts; Biological Transport; Carrier Proteins; Cell Line; Enzyme Inhibitors; Humans; Kinetics; Mesylates; Molecular Sequence Data; Mutagenesis, Site-Directed; Organic Anion Transporters, Sodium-Dependent; Sulfhydryl Reagents; Symporters; Taurocholic Acid; Transfection

The rat renal Na/P(i) cotransporter type IIa (rat NaP(i) IIa) is a 637 amino acid protein containing 12 cysteine residues. We examined the effect of different cysteine modifying methanethiosulfonate (MTS)-reagents and the disulfide bond reducing agent tris(2-carboxyethyl)phosphine (TCEP) on the transport activity of wild-type and 12 single cysteine substitution mutants of rat NaPi IIa expressed in Xenopus laevis oocytes. The transport activity of the wild-type protein was resistant to three membrane impermeant MTS-reagents (MTSEA, MTSET and MTSES). In contrast, membrane permeant methyl methanethiosulfonate (MMTS) and TCEP inhibited the transport activity of both the wild-type, as well as all the single mutant proteins. This indicated the existence of more than one functionally important cysteine residue, not accessible extracellularly, and at least 2 disulfide bridges. To identify the disulfide bridges, three double mutants lacking 2 of the 3 cysteine residues predicted to be extracellular in different combinations were examined. This led to the identification of one disulfide bridge between C306 and C334; reconsideration of the topological model predictions suggested a second disulfide bridge between C225 and C520. Evaluation of a fourth double mutant indicated that at least one of two disulfide bridges (C306 and C334; C225 and C520) has to be formed to allow the surface expression of a functional cotransporter. A revised secondary structure is proposed which includes two partially repeated motifs that are connected by disulfide bridges formed between cysteine pairs C306-C334 and C225-C520.

Topics: Amino Acid Sequence; Amino Acid Substitution; Animals; Carrier Proteins; Cysteine; Disulfides; Ethyl Methanesulfonate; Kidney Tubules, Proximal; Mesylates; Methyl Methanesulfonate; Molecular Sequence Data; Mutagenesis, Site-Directed; Oocytes; Protein Structure, Tertiary; Rats; Reducing Agents; Serine; Sodium-Phosphate Cotransporter Proteins; Sodium-Phosphate Cotransporter Proteins, Type II; Sodium-Phosphate Cotransporter Proteins, Type IIa; Symporters; Xenopus laevis

We have constructed a series of cysteine-substitution mutants in order to identify residues in the mouse muscle nicotinic acetylcholine receptor (AChR) that are involved in alpha-bungarotoxin (alpha-Bgtx) binding. Following transient expression in HEK 293-derived TSA-201 cells, covalent modification of the introduced cysteines with thiol-specific reagents reveals that alpha subunit residues W187, V188, F189, Y190, and P194 are solvent accessible and are in a position to contribute to the alpha-Bgtx binding site in native receptors. These results with the intact receptor are consistent with NMR studies of an alpha-Bgtx/receptor-dodecapeptide complex [Basus, V., Song., G., and Hawrot, E. (1993) Biochemistry 32, 12290-12298]. We pursued a more detailed analysis of the F189C mutant as this site varies substantially between AChRs that bind Bgtx and certain neuronal AChRs that do not. Treatment of intact cells expressing F189C with either bromoacetylcholine (BrACh) or [2-(trimethylammonium)ethyl] methane-thiosulfonate (MTSET), both methylammonium-containing thiol-modifying reagents with agonist properties, results in a marked decrease ( approximately 55-70%) in the number of alpha-Bgtx binding sites, as measured under saturating conditions. The decrease in sites appears to affect both alpha/gamma and alpha/delta sites to the same extent, as shown for alphaW187C and alphaF189C which were the two mutants examined on this issue. In contrast to the results obtained with MTSET and BrACh, modification with reagents that lack the alkylammonium entity, such as methylmethanethiosulfonate (MMTS), the negatively charged 2-sulfonatoethyl methane-thiosulfonate (MTSES), or the positively charged aminoethyl methylthiosulfonate (MTSEA), has little or no effect on the maximal binding of alpha-Bgtx to the alphaW187C, alphaV188C, or alphaF189C mutant receptors. The striking alkylammonium dependency suggests that an interaction of the tethered modifying group with the negative subsite within the agonist binding domain is primarily responsible for the observed blockade of toxin binding.

Topics: Acetylcholine; Animals; Bungarotoxins; Cysteine; Humans; Indicators and Reagents; Mesylates; Mice; Mutagenesis, Site-Directed; Nicotinic Agonists; Nicotinic Antagonists; Oxidation-Reduction; Peptide Fragments; Phenylalanine; Protein Binding; Receptors, Nicotinic; Torpedo; Tryptophan; Valine

The binding-site of the dopamine D2 receptor, like that of other homologous G protein-coupled receptors, is contained within a water-accessible crevice formed among its seven membrane-spanning segments. Using the substituted cysteine accessibility method (SCAM), we previously mapped the residues in the third, fifth, sixth, and seventh membrane-spanning segments that contribute to the surface of this binding-site crevice. We have now mutated to cysteine, one at a time, 22 consecutive residues in the second membrane-spanning segment (M2) and expressed the mutant receptors in HEK 293 cells. Eleven of these mutants reacted with charged, hydrophilic, lipophobic, sulfhydryl-specific reagents, added extracellularly, and 9 of these 11 were protected from reaction by a reversible dopamine antagonist, sulpiride. We infer that the side chains of the residues at the 11 reactive loci (D80, L81, V83, V87, P89, W90, V91, V92, L94, E95, V96) are on the water-accessible surface of the binding-site crevice and that 9 of these are occluded by bound antagonist. The pattern of accessibility suggests an alpha-helical conformation. A broadening of the angle of accessibility near the binding site is consistent with the presence of a kink at Pro89. On the basis of the enhanced rates of reaction of positively charged sulfhydryl reagents, we infer the presence of an electrostatic microdomain composed of three acidic residues in M2 and the adjacent M3 that could attract and orient cationic ligands. Furthermore, based on the enhanced reactivity of the hydrophobic cation-containing reagent, we infer the presence of an aromatic microdomain formed between M2, M3, and M7.

Topics: Amino Acid Substitution; Aspartic Acid; Binding, Competitive; Cell Line; Cell Membrane; Cysteine; Dopamine Antagonists; Ethyl Methanesulfonate; Humans; Mesylates; Models, Molecular; Mutagenesis, Site-Directed; Peptide Fragments; Protein Binding; Protein Structure, Tertiary; Receptors, Dopamine D2; Static Electricity; Sulpiride

We have applied the substituted-cysteine-accessibility method (SCAM) to the M2 segment and the M1-M2 loop of the acetylcholine (ACh) receptor beta subunit. Each residue from beta P248 to beta D273 was mutated one at a time to Cys, and the mutant beta subunits were expressed together with wild-type alpha, beta, and delta subunits in Xenopus oocytes. For each of the mutants, the ACh-induced current was near wild-type. The accessibility of the substituted Cys was inferred from the irreversible inhibition or potentiation of ACh-induced current by methanethiosulfonate (MTS) derivatives added extracellularly. Inhibition by MTSethylammonium of beta G255C, in the narrow part of the channel, was mainly due to a reduction in the single-channel conductance. Conversely, potentiation by MTSethylammonium of beta V266C, in a wider part of the channel, was mainly due to an increase in channel open-time. Two substituted Cys at the intracellular end of M2 and three at the extracellular end were accessible to MTSethylammonium in the absence of ACh. Three additional Cys in the middle of M2 and three in the M1-M2 loop were accessible in the presence of ACh. In the presence of ACh, the secondary structure of beta M2 is alpha-helical from beta G255 to beta V266 and extended from beta L268 to beta D273. The accessible residues in beta M2 are remarkably hydrophobic, while the accessible residues in the M1-M2 loop are charged. beta M2, like alpha M2, alpha M1, and beta M1, undergoes widespread structural changes concomitant with gating, but the gate itself is close to the intracellular end of the channel. Many aligned residues in the M2 segments of alpha and beta are not identically accessible, indicating that the two subunits contribute differently to the channel lining.

Topics: Acetylcholine; Amino Acid Sequence; Amino Acid Substitution; Animals; Cysteine; Drug Synergism; Ethyl Methanesulfonate; Indicators and Reagents; Ion Channels; Mesylates; Mice; Molecular Sequence Data; Mutagenesis, Insertional; Protein Structure, Secondary; Receptor, Muscarinic M2; Receptors, Muscarinic

Ion channels allow ions to pass through cell membranes by forming aqueous permeation pathways (pores). In contrast to most known ion channels, which have single pores, a chloride channel belonging to the CIC family (Torpedo CIC-0) has functional features that suggest that it has a unique 'double-barrelled' architecture in which each of two subunits forms an independent pore. This model is based on single-channel recordings of CIC-0 that has two equally spaced and independently gated conductance states. Other CIC isoforms do not behave in this way, raising doubts about the applicability of the model to all CIC channels. Here we determine the pore stoichiometry of another CIC isoform, human CIC-1, by chemically modifying cysteines that have been substituted for other amino acids located within the CIC ion-selectivity filter. The CIC-1 channel can be rendered completely susceptible to block by methanethiosulphonate reagents when only one of the two subunits contains substituted cysteines. Thiol side chains placed at corresponding positions in both subunits can form intersubunit disulphide bridges and coordinate Cd2+, indicating that the pore-forming regions from each subunit line the same conduction pathway. We conclude that human CIC-1 has a single functional pore.

Topics: Cadmium; Cell Line; Chloride Channels; Cysteine; Electrochemistry; Histidine; Humans; Ion Channel Gating; Mesylates; Molecular Conformation; Muscle Proteins; Mutagenesis, Site-Directed; Phenanthrolines; Sulfhydryl Compounds

Twenty residues in the third transmembrane domain of the serotonin transporter (SERT) were mutated, one at a time, to cysteine. Almost all of these mutants were fully active for serotonin (5-HT) transport and insensitive to inactivation by the positively charged cysteine reagent [2-(trimethylammonium)ethyl]methanethiosul-fonate (MTSET). Two active mutants, I172C and I179C, were sensitive to rapid inactivation by MTSET but were relatively insensitive to the negatively charged reagent (2-sulfonatoethyl)methanethiosulfonate (MTSES). Inactivation of I172C was blocked by 5-HT and cocaine, but I179C was not similarly protected. Replacement of Tyr-175 with cysteine resulted in a mutant with low transport activity, and, at the neighboring Tyr-176, cysteine replacement completely blocked transport. The Y175C and Y176C mutants were expressed on the cell surface at levels 84% and 69%, respectively, that of wild type (C109A) SERT. Mutants Y175C and Y176C had lower cocaine affinity than C109A, as measured by displacement of the high affinity cocaine analog 2beta-carbomethoxy-3beta-(4-[125I]iodophenyl)tropane (beta-CIT). For Y176C, 5-HT affinity also was decreased. MTSET inactivated beta-CIT binding to I172C and Y176C, but only slightly inhibited binding to I179C and C109A. The MTSET sensitivity of cysteine replacements at positions 172, 176, and 179 was not observed when these positions were replaced with alanine, serine, or methionine. The results suggest that Ile-172, Tyr-176 and Ile-179 are on one face of an alpha-helical transmembrane element, and that Ile-172 and Tyr-176 are in proximity to the binding site for 5-HT and cocaine.

Topics: Asparagine; Binding Sites; Carrier Proteins; Cell Line; Cell Membrane; Cocaine; Cysteine; Ethyl Methanesulfonate; Humans; Indicators and Reagents; Isoleucine; Ligands; Membrane Glycoproteins; Membrane Transport Proteins; Mesylates; Mutagenesis, Site-Directed; Nerve Tissue Proteins; Protein Structure, Secondary; Serotonin; Serotonin Plasma Membrane Transport Proteins; Structure-Activity Relationship; Tyrosine

1. In order to investigate the role in fast inactivation of the cytoplasmic S4-S5 loop of the fourth domain (IV/S4-S5) within the alpha-subunit of the adult human muscle Na+ channel, every single amino acid from R1469 to G1486 was substituted by a cysteine and the mutants were studied by functional expression in human embryonic kidney cells (tsA201) using whole-cell patch clamping. Effects following intracellular application of the sulfhydryl reagents MTSET and MTSES on the mutants were investigated. 2. Sixteen of eighteen mutants resulted in the formation of functional channels. For P1480C and N1484C, no Na+ currents could be detected in transfected cells. In the absence of sulfhydryl reagents, F1473C and A1481C slowed fast Na+ channel inactivation by 2- and 1.5-fold, respectively, and L1482C induced a steady-state Na+ current (Iss) of 3% of peak current (Ipeak) (1% for wild-type). 3. Upon application of MTSET and MTSES, changes in fast inactivation gating occurred for most of the mutants. The most dramatic destabilizing effects on fast inactivation were observed for M1476C (9-fold slowing of inactivation; Iss/Ipeak, 3.6%; +15 mV shift in steady-state inactivation; 2- to 3-fold acceleration of recovery from inactivation), A1481C (3-fold; 14%; +20 mV; no change) and F1473C (2.5-fold; 2.4%; +8 mV; 1.5-fold). Less pronounced destabilizing effects were observed for M1477C and L1479C. Strongly stabilizing effects on the inactivated state, that is a 20-30 mV hyperpolarizing shift of the inactivation curve associated with a 3- to 4-fold decrease in the rate of recovery from inactivation, occurred for T1470C, L1471C and A1474C. Almost all effects were independent of the membrane potential; however, A1474C only reacted when cells were depolarized. Significant effects on activation were not observed. 4. We conclude that the IV/S4-S5 loop plays an important role in fast inactivation of the muscle Na+ channel and may contribute to the formation of a receptor for the putative inactivation particle. The effects of sulfhydryl reagents on the various mutations suggest an alpha-helical structure of IV/S4-S5 (up to P1480) with destabilizing effects on inactivation for one cluster of amino acids (1473/76/77/79) and a stabilized inactivation at the opposite side of the helix (1470/71/74).

Topics: Adult; Amino Acid Substitution; Cell Line; Cysteine; Embryo, Mammalian; Humans; Indicators and Reagents; Kidney; Kinetics; Mesylates; Models, Molecular; Mutagenesis, Site-Directed; Patch-Clamp Techniques; Protein Structure, Secondary; Sodium Channels; Sulfhydryl Reagents