Conformationally sensitive residues in extracellular loop 5 of the Na+/dicarboxylate co-transporter

The Na+/dicarboxylate co-transporter, NaDC-1, from the kidney and small intestine, transports three sodium ions together with one divalent anion substrate, such as succinate2-. A previous study (Pajor, A. M. (2001) J. Biol. Chem. 276, 29961-29968), identified four amino acids, Ser-478, Ala-480, Ala-481, and Thr-482, near the extracellular end of transmembrane helix (TM) 9 that are likely to form part of the permeation pathway of the transporter. All four cysteine-substituted mutants were sensitive to inhibition by the membrane-impermeant reagent [2-(trimethylammonium)ethyl]-methanethiosulfonate (MTSET) and protected by substrate. In the present study, we continued the cysteine scan through extracellular loop 5 and TM10, from Thr-483 to Val-528. Most cysteine substitutions were well tolerated, although cysteine mutations of some residues, particularly within the TM, produced proteins that were not expressed on the plasma membrane. Six residues in the extracellular loop (Thr-483, Thr-484, Leu-485, Leu-487, Ile-489, and Met-493) were sensitive to chemical labeling by MTSET, depending on the conformational state of the protein. Transport inhibition by MTSET could be prevented by substrate regardless of temperature, suggesting that the likely mechanism of substrate protection is steric hindrance rather than large-scale conformational changes associated with translocation. We conclude that extracellular loop 5 in NaDC-1 appears to have a functional role, and it is likely to be located in or near the substrate translocation pore in the protein. Conformational changes in the protein affect the accessibility of the residues in extracellular loop 5 and provide further evidence of large-scale changes in the structure of NaDC-1 during the transport cycle.     

Arginine-349 and aspartate-373 of the Na(+)/dicarboxylate cotransporter are conformationally sensitive residues.

The conserved residues, Arg-349 and Asp-373, of the renal Na(+)/dicarboxylate cotransporter (NaDC-1) have been shown in our previous studies to affect substrate affinity and cation binding. In this study, amino acids surrounding Arg-349 and Asp-373 were individually mutated to cysteines and their sensitivity to methanethiosulfonate reagents (MTS) was tested. Only three of the 21 mutants were sensitive to MTS reagents: R349C, S372C, and D373C. The R349C mutant had reduced activity which was restored by chemical modification with MTSEA. The effect of MTSEA was only observed in the presence of sodium, indicating that Arg-349 is conformationally accessible. The succinate transport activity of the S372C mutant was stimulated by both MTSEA and MTSET. The D373C mutant was very sensitive to inhibition by MTSET (K(i) = 0.5 microM) in sodium buffer. The inhibition of D373C by MTSET was prevented by substrate, suggesting that the substrate-induced conformational change occludes the residue. We conclude that the accessibility of Arg-349 and Asp-373 is likely to change with the conformational states of the transport cycle.     

Acidic residues involved in cation and substrate interactions in the Na+/dicarboxylate cotransporter, NaDC-1.

The role of acidic amino acid residues in cation recognition and selectivity by the Na+/dicarboxylate cotransporter, NaDC-1, was investigated by site-directed mutagenesis and expression in Xenopus oocytes. Four of the residues tested, Asp-52, Glu-74, Glu-101, and Glu-332, were found to be unimportant for transport activity. However, substitutions of Asp-373 and Glu-475, conserved residues found in transmembrane domains M8 and M9, respectively, altered transport kinetics. Replacements of Asp-373 with Ala, Glu, Asn, and Gln resulted in changes in sodium affinity and cation selectivity in NaDC-1, indicating that the carbonyl oxygen at this position may play a role in the topological organization of the cation-binding site. In contrast, substitutions of Glu-475 led to dramatic reductions in transport activity and changes in transport kinetics. Substitution with Gln led to a transporter with increased substrate and sodium affinity, while the E475D mutant was inactive. The E475A mutant appeared to have poor sodium binding. Substrate-induced currents in the E475A mutant exhibited a strong voltage dependence, and a reversal of the current was seen at -30 mV. The results suggest that Glu-475 may play a role in cation binding and possibly also in mediating anion channel activity. Remarkably, mutations of both Asp-373 and Glu-475 affected the Km for succinate in NaDC-1, suggesting dual roles for these residues in determining the affinity for substrate and cations. We propose that at least one of the cation-binding sites and the substrate-binding site are close together in the carboxy-terminal portion of NaDC-1, and thus transmembrane domains M8 and M9 are candidate structures for the formation of the translocation pathway.     

Evidence for distinct sodium-, dopamine-, and cocaine-dependent conformational changes in transmembrane segments 7 and 8 of the dopamine transporter

Previously we obtained evidence based on engineering of Zn2+ binding sites that the extracellular parts of transmembrane segment 7 (TM7) and TM8 in the human dopamine transporter are important for transporter function. To further evaluate the role of this domain, we have employed the substituted cysteine accessibility method and performed 10 single cysteine substitutions at the extracellular ends of TM7 and TM8. The mutants were made in background mutants of the human dopamine transporter with either two (E2C) or five endogenous cysteines substituted (X5C) that render the transporter largely insensitive to cysteine modification. In two mutants (M371C and A399C), treatment with the sulfhydryl-reactive reagent [2-(trimethylammonium)-ethyl]methanethiosulfonate (MTSET) led to a substantial inhibition of [3H]dopamine uptake. In M371C this inactivation was enhanced by Na+ and blocked by dopamine. Inhibitors such as cocaine did not alter the effect of MTSET in M371C. The protection of M371C inactivation by dopamine required Na+. Because dopamine binding is believed to be Na+-independent, this suggests that dopamine induces a transport-associated conformational change that decreases the reactivity of M371C with MTSET. In contrast to M371C, cocaine decreased the reaction rate of A399C with MTSET, whereas dopamine had no effect. The protection by cocaine can either reflect that Ala-399 lines the cocaine binding crevice or that cocaine induces a conformational change that decreases the reactivity of A399C. The present findings add new functionality to the TM7/8 region by providing evidence for the occurrence of distinct Na+-, substrate-, and perhaps inhibitor-induced conformational changes critical for the proper function of the transporter.     

Asymmetric organization of the pore region of the epithelial sodium channel

Epithelial sodium channels (ENaCs) are composed of three homologous subunits that have regions preceding the second transmembrane domain (also referred as pre-M2) that form part of the channel pore. To identify residues within this region of the beta-subunit that line the pore, we systematically mutated residues Gln(523)-Ile(536) to cysteine. Wild type and mutant mouse ENaCs were expressed in Xenopus oocytes, and a two-electrode voltage clamp was used to examine the properties of mutant channels. Cysteine substitutions of 9 of 13 residues significantly altered Li(+) to Na(+) current ratios, whereas only cysteine replacement of beta Gly(529) resulted in K(+)-permeable channels. Besides beta G525C, large increases in the inhibitory constant of amiloride were observed with mutations at beta Gly(529) and beta Ser(531) within the previously identified 3-residue tract that restricts K(+) permeation. Cysteine substitution preceding (beta Phe(524) and beta Gly(525)), within (beta Gly(530)) or following (beta Leu(533)) this 3-residue tract, resulted in enhanced current inhibition by external MTSEA. External MTSET partially blocked channels with cysteine substitutions at beta Gln(523), beta Phe(524), and beta Trp(527). MTSET did not inhibit alpha beta G525C gamma, although previous studies showed that channels with cysteine substitutions at the corresponding sites within the alpha- and gamma-subunits were blocked by MTSET. Our results, placed in context with previous observations, suggest that pore regions from the three ENaC subunits have an asymmetric organization.     

Serines 260 and 288 are involved in sulfate transport by hNaSi-1

The low affinity Na+/sulfate cotransporter, NaSi-1, belongs to the SLC13 family that also includes the Na+/dicarboxylate cotransporters, NaDC. Two serine residues in hNaSi-1, at positions 260 and 288, are conserved in all of the sulfate transporters in the family whereas the NaDC contain alanine or threonine at those positions. Therefore, the functional roles of serines 260 and 288 in substrate and cation binding by hNaSi-1 were investigated. These two serine residues were first mutated to alanine and the mutants were characterized in Xenopus oocytes. Alanine substitution of Ser-260 resulted in increased Km values for both substrate and Na+ whereas alanine replacement at Ser-288 resulted in a broadened cation selectivity, indicating that these two serines might play important roles in cation and/or substrate binding of hNaSi-1. The two serines and 12 surrounding residues were further mutated to cysteine and studied using a thiol-reactive compound, [2-(trimethylammonium)ethyl]methane-thiosulfonate (MTSET). Four mutants surrounding Ser-260 (T257C, T259C, T261C, and L263C) were sensitive to MTSET inhibition. The sensitivity to MTSET was dependent on the presence of substrate, suggesting that the accessibility of these substituted cysteines depends on the conformational state of the transporter. Because the four residues are located in transmembrane domain 5, this transmembrane domain is likely to participate in the conformational movements during the transport cycle of hNaSi-1.     

Cysteine mutagenesis reveals novel structure-function features within the predicted third extracellular loop of the type IIa Na(+)/P(i) cotransporter

The transport function of the rat type IIa Na(+)/P(i) cotransporter is inhibited after binding the cysteine modifying reagent 2-aminoethyl methanethiosulfonate hydrobromide (MTSEA) to a cysteine residue substituted for a serine at position 460 (S460C) in the predicted third extracellular loop. This suggests that Ser-460 lies in a functionally important region of the protein. To establish a "structure-function" profile for the regions that flank Ser-460, the substituted cysteine accessibility method was employed. 18 mutants were constructed in which selected amino acids from Arg-437 through Leu-465 were substituted one by one for a cysteine. Mutants were expressed in Xenopus oocytes and transport function (cotransport and slippage) and kinetics were assayed by electrophysiology with or without prior treatment with cysteine modifying (methanethiosulfonate, MTS) reagents. Except for mutant I447C, mutants with cysteines at sites from Arg-437 through Thr-449, as well as Pro-461, were inactive. Cotransport function of mutants with Cys substitutions at sites Arg-462 through Leu-465 showed low sensitivity to MTS reagents. The preceding mutants (Cys substitution at Thr-451 to Ser-460) showed a periodic accessibility pattern that would be expected for an alpha-helix motif. Apart from loss of transport function, exposure of mutants A453C and A455C to MTSEA or 2-(triethylammonium)ethyl MTS bromide (MTSET) increased the uncoupled slippage current, which implicated the mutated sites in the leak pathway. Mutants from Ala-453 through Ala-459 showed less pH dependency, but generally stronger voltage dependency compared with the wild type, whereas those flanking this group were more sensitive to pH and showed weaker voltage dependence of cotransport mode kinetics. Our data indicate that parts of the third extracellular loop are involved in the translocation of the fully loaded carrier and show a membrane-associated alpha-helical structure.     

The drug-binding pocket of the human multidrug resistance P-glycoprotein is accessible to the aqueous medium

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.     

Cyclic nucleotide-gated channels. Pore topology studied through the accessibility of reporter cysteines.

In voltage- and cyclic nucleotide-gated ion channels, the amino-acid loop that connects the S5 and S6 transmembrane domains, is a major component of the channel pore. It determines ion selectivity and participates in gating. In the alpha subunit of cyclic nucleotide-gated channels from bovine rod, the pore loop is formed by the residues R345-S371, here called R1-S27. These 24 residues were mutated one by one into a cysteine. Mutant channels were expressed in Xenopus laevis oocytes and currents were recorded from excised membrane patches. The accessibility of the substituted cysteines from both sides of the plasma membrane was tested with the thiol-specific reagents 2-aminoethyl methanethiosulfonate (MTSEA) and [2-(trimethylammonium)ethyl]methanethiosulfonate (MTSET). Residues V4C, T20C, and P22C were accessible to MTSET only from the external side of the plasma membrane, and to MTSEA from both sides of the plasma membrane. The effect of MTSEA applied to the inner side of T20C and P22C was prevented by adding 10 mM cysteine to the external side of the plasma membrane. W9C was accessible to MTSET from the internal side only. L7C residue was accessible to internal MTSET, but the inhibition was partial, approximately 50% when the MTS compound was applied in the absence of cGMP and 25% when it was applied in the presence of cGMP, suggesting that this residue is not located inside the pore lumen and that it changes its position during gating. Currents from T15C and T16C mutants were rapidly potentiated by intracellular MTSET. In T16C, a slower partial inhibition took place after the initial potentiation. Current from I17C progressively decayed in inside-out patches. The rundown was accelerated by inwardly applied MTSET. The accessibility results of MTSET indicate a well-defined topology of the channel pore in which residues between L7 and I17 are inwardly accessible, residue G18 and E19 form the narrowest section of the pore, and T20, P21, P22 and V4 are outwardly accessible.     

The Dual Regulatory Role of Amino Acids Leu480 and Gln481 of Prothrombin

Prothrombin (FII) is activated to α-thrombin (IIa) by prothrombinase. Prothrombinase is composed of a catalytic subunit, factor Xa (fXa), and a regulatory subunit, factor Va (fVa), assembled on a membrane surface in the presence of divalent metal ions. We constructed, expressed, and purified several mutated recombinant FII (rFII) molecules within the previously determined fVa-dependent binding site for fXa (amino acid region 473–487 of FII). rFII molecules bearing overlapping deletions within this significant region first established the minimal stretch of amino acids required for the fVa-dependent recognition exosite for fXa in prothrombinase within the amino acid sequence Ser⁴⁷⁸–Val⁴⁷⁹–Leu⁴⁸⁰–Gln⁴⁸¹–Val⁴⁸². Single, double, and triple point mutations within this stretch of rFII allowed for the identification of Leu⁴⁸⁰ and Gln⁴⁸¹ as the two essential amino acids responsible for the enhanced activation of FII by prothrombinase. Unanticipated results demonstrated that although recombinant wild type α-thrombin and rIIa^S478A were able to induce clotting and activate factor V and factor VIII with rates similar to the plasma-derived molecule, rIIa^SLQ→AAA with mutations S478A/L480A/Q481A was deficient in clotting activity and unable to efficiently activate the pro-cofactors. This molecule was also impaired in protein C activation. Similar results were obtained with rIIa^ΔSLQ (where rIIa^ΔSLQ is recombinant human α-thrombin with amino acids Ser⁴⁷⁸/Leu⁴⁸⁰/Gln⁴⁸¹ deleted). These data provide new evidence demonstrating that amino acid sequence Leu⁴⁸⁰–Gln⁴⁸¹: 1) is crucial for proper recognition of the fVa-dependent site(s) for fXa within prothrombinase on FII, required for efficient initial cleavage of FII at Arg³²⁰; and 2) is compulsory for appropriate tethering of fV, fVIII, and protein C required for their timely activation by IIa.     

The accessibility in the external part of the TM5 of the glutamate transporter EAAT1 is conformationally sensitive during the transport cycle

Background

Excitatory amino acid transporter 1 (EAAT1) is a glutamate transporter which is a key element in the termination of the synaptic actions of glutamate. It serves to keep the extracellular glutamate concentration below neurotoxic level. However the functional significance and the change of accessibility of residues in transmembrane domain (TM) 5 of the EAAT1 are not clear yet.

Methodology/Principal Findings

We used cysteine mutagenesis with treatments with membrane-impermeable sulfhydryl reagent MTSET [(2-trimethylammonium) methanethiosulfonate] to investigate the change of accessibility of TM5. Cysteine mutants were introduced from position 291 to 300 of the cysteine-less version of EAAT1. We checked the activity and kinetic parameters of the mutants before and after treatments with MTSET, furthermore we analyzed the effect of the substrate and blocker on the inhibition of the cysteine mutants by MTSET. Inhibition of transport by MTSET was observed in the mutants L296C, I297C and G299C, while the activity of K300C got higher after exposure to MTSET. V_max of L296C and G299C got lower while that of K300C got higher after treated by MTSET. The L296C, G299C, K300C single cysteine mutants showed a conformationally sensitive reactivity pattern. The sensitivity of L296C to MTSET was potentiated by glutamate and TBOA,but the sensitivity of G299C to MTSET was potentiated only by TBOA.

Conclusions/Significance

All these facts suggest that the accessibility of some positions of the external part of the TM5 is conformationally sensitive during the transport cycle. Our results indicate that some residues of TM5 take part in the transport pathway during the transport cycle.     

Serotonin and cocaine-sensitive inactivation of human serotonin transporters by methanethiosulfonates targeted to transmembrane domain I

To explore aqueous accessibility and functional contributions of transmembrane domain (TM) 1 in human serotonin transporter (hSERT) proteins, we utilized the largely methanethiosulfonate (MTS) insensitive hSERT C109A mutant and mutated individual residues of hSERT TM1 to Cys followed by tests of MTS inactivation of 5-hydroxytryptamine (5-HT) transport. Residues in TM1 cytoplasmic to Gly-94 were largely unaffected by Cys substitution, whereas the mutation of residues extracellular to Ile-93 variably diminished transport activity. TM1 Cys substitutions displayed differential sensitivity to MTS reagents, with residues more cytoplasmic to Asp-98 being largely insensitive to MTS inactivation. Aminoethylmethanethiosulfonate (MTSEA), [2-(trimethylammonium) ethyl]methanethiosulfonate bromide (MTSET), and sodium (2-sulfonatoethyl)-methanethiosulfonate (MTSES) similarly and profoundly inactivated 5-HT transport by SERT mutants D98C, G100C, W103C, and Y107C. MTSEA uniquely inactivated transport activity of S91C, G94C, Y95C but increased activity at I108C. MTSEA and MTSET, but not MTSES, inactivated transport function at N101C. Notably, 5-HT provided partial to complete protection from MTSET inactivation for D98C, G100C, N101C, and Y107C. Equivalent blockade of MTSET inactivation at N101C was observed with 5-HT at both room temperature and at 4 degrees C, inconsistent with major conformational changes leading to protection. Notably, cocaine also protected MTSET inactivation of G100C and N101C, although MTS incubations with N101C that eliminate 5-HT transport do not preclude cocaine analog binding nor its inhibition by 5-HT. 5-HT modestly enhanced the inactivation by MTSET at I93C and Y95C, whereas cocaine significantly enhanced MTSET sensitivity at Y107C and I108C. In summary, our studies reveal physical differences in TM1 accessibility to externally applied MTS reagents and reveal sites supporting substrate and antagonist modulation of MTS inactivation. Moreover, we identify a limit to accessibility for membrane-impermeant MTS reagents that may reflect aspects of an occluded permeation pathway.     

Analysis of the pore structure of the influenza A virus M(2) ion channel by the substituted-cysteine accessibility method

The M(2) ion channel of influenza A virus is a small integral membrane protein whose active form is a homotetramer with each polypeptide chain containing 96-amino-acid residues. To identify residues of the transmembrane (TM) domain that line the presumed central ion-conducting pore, a set of mutants was generated in which each residue of the TM domain (residues 25 to 44) was replaced by cysteine. The accessibility of the cysteine mutants to modification by the sulfhydryl-specific reagents methane thiosulfonate ethylammonium (MTSEA) and MTS tetraethylammonium (MTSET) was tested. Extracellular application of MTSEA evoked decreases in the conductances measured from two mutants, M(2)-A30C and M(2)-G34C. The changes observed were not reversible on washout, indicative of a covalent modification. Inhibition by MTSEA, or by the larger reagent MTSET, was not detected for residues closer to the extracellular end of the channel than Ala-30, indicating the pore may be wider near the extracellular opening. To investigate the accessibility of the cysteine mutants to reagents applied intracellularly, oocytes were microinjected directly with reagents during recordings. The conductance of the M(2)-W41C mutant was decreased by intracellular injection of a concentrated MTSET solution. However, intracellular application of MTSET caused no change in the conductance of the M(2)-G34C mutant, a result in contrast to that obtained when the reagent was applied extracellularly. These data suggest that a constriction in the pore exists between residues 34 and 41 which prevents passage of the MTS reagent. These findings are consistent with the proposed role for His-37 as the selectivity filter. Taken together, these data confirm our earlier model that Ala-30, Gly-34, His-37, and Trp-41 line the channel pore (L. H. Pinto, G. R. Dieckmann, C. S. Gandhi, C. G. Papworth, J. Braman, M. A. Shaughnessy, J. D. Lear, R. A. Lamb, and W. F. DeGrado, Proc. Natl. Acad. Sci. USA 94:11301-11306, 1997).     

Outer pore topology of the ECaC-TRPV5 channel by cysteine scan mutagenesis

The substituted cysteine accessibility method (SCAM) was used to map the external vestibule and the pore region of the ECaC-TRPV5 calcium-selective channel. Cysteine residues were introduced at 44 positions from the end of S5 (Glu515) to the beginning of S6 (Ala560). Covalent modification by positively charged MTSET applied from the external medium significantly inhibited whole cell currents at 15/44 positions. Strongest inhibition was observed in the S5-linker to pore region (L520C, G521C, and E522C) with either MTSET or MTSES suggesting that these residues were accessible from the external medium. In contrast, the pattern of covalent modification by MTSET for residues between Pro527 and Ile541 was compatible with the presence of a alpha-helix. The absence of modification by the negatively charged MTSES in that region suggests that the pore region has been optimized to favor the entrance of positively charged ions. Cysteine mutants at positions -1, 0, +1, +2 around Asp542 (high Ca2+ affinity site) were non-functional. Whole cell currents of cysteine mutants at +4 and +5 positions were however covalently inhibited by external MTSET and MTSES. Altogether, the pattern of covalent modification by MTS reagents globally supports a KcsA homology-based three-dimensional model whereby the external vestibule in ECaC-TRPV5 encompasses three structural domains consisting of a coiled structure (Glu515 to Tyr526) connected to a small helical segment of 15 amino acids (527PTALFSTFELFLT539) followed by two distinct coiled structures Ile540-Pro544 (selectivity filter) and Ala545-Ile557 before the beginning of S6.     

A gating mutation in the internal pore of ASIC1a

Using a substituted cysteine accessibility scan, we have investigated the structures that form the internal pore of the acid-sensing ion channel 1a. We have identified the amino acid residues Ala-22, Ile-33, and Phe-34 in the amino terminus and Arg-43 in the first transmembrane helix, which when mutated into cysteine, were modified by intracellular application of MTSET, resulting in channel inhibition. The inhibition of the R43C mutant by internal MTSET requires opening of the channel. In addition, binding of Cd2+ ions to R43C slows the channel inactivation. This indicates that the first transmembrane helix undergoes conformational changes during channel inactivation. The effect of Cd2+ on R43C can be obtained with Cd2+ applied at either the extracellular or the intracellular side, indicating that R43C is located in the channel pore. The block of the A22C, I33C, and F34C mutants by MTSET suggests that these residues in the amino terminus of the channel also participate to the internal pore.     

Structure-function analysis of the bestrophin family of anion channels

The bestrophins are a newly described family of anion channels unrelated in primary sequence to any previously characterized channel proteins. The human genome codes for four bestrophins, each of which confers a distinctive plasma membrane conductance on transfected 293 cells. Extracellular treatment with methanethiosulfonate ethyltrimethylammonium (MTSET) of a series of substitution mutants that eliminate one or more cysteines from human bestrophin1 demonstrates that cysteine 69 is the single endogenous cysteine responsible for MTSET inhibition of whole-cell current. Cysteines introduced between positions 78-99 and 223-226 are also accessible to external MTSET, with MTSET modification at positions 79, 80, 83, and 90 producing a 2-6-fold increase in whole-cell current. The latter set of four cysteine-substitution mutants define a region that appears to mediate allosteric control of channel activity. Mapping of transmembrane topography by insertion of N-linked glycosylation sites and tobacco etch virus protease cleavage sites provides evidence for cytosolic N and C termini and an unexpected transmembrane topography with at least three extracellular loops that include positions 60-63, 212-227, and 261-267. These experiments provide the first structural analysis of the bestrophin channel family.     

Exploration of the pore structure of a peptide-gated Na+ channel

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.     

Identification of a functionally important conformation-sensitive region of the secretory Na+-K+-2Cl- cotransporter (NKCC1)

The secretory Na(+)-K(+)-2Cl(-) cotransporter (NKCC1) is a member of a small gene family of electroneutral salt transporters that play essential roles in salt and water homeostasis in many mammalian tissues. We have identified a highly conserved residue (Ala-483) in the sixth membrane-spanning segment of rat NKCC1 that when mutated to cysteine renders the transporter sensitive to inhibition by the sulfhydryl reagents 2-aminoethyl methanethiosulfonate (MTSEA) and 2-(trimethylammonium)ethyl methanethiosulfonate (MTSET). The mutation of Ala-483 to cysteine (A483C) results in little or no change in the affinities of NKCC1 for substrate ions but produces a 6-fold increase in sensitivity to the inhibitor bumetanide, suggesting a specific modification of the bumetanide binding site. When residues surrounding Ala-483 were mutated to cysteine, only I484C was sensitive to inhibition by MTSEA and MTSET. Surprisingly I484C showed increased transport activity in the presence of low concentrations of mercury (1-10 microm), whereas A483C showed inhibition. The inhibition of A483C by MTSEA was unaffected by the presence or absence of sodium and potassium but required the presence of extracellular chloride. Taken together, our results indicate that Ala-483 lies at or near an important functional site of NKCC1 and that the exposure of this site to the extracellular medium is dependent on the conformation of the transporter. Specifically, our results indicate that the cysteine introduced at residue 483 is only available for interaction with MTSEA when chloride is bound to NKCC1 at the extracellular surface.     

Novel Residues Lining the CFTR Chloride Channel Pore Identified by Functional Modification of Introduced Cysteines

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.     

Cysteine-scanning mutagenesis and thiol modification of the Rickettsia prowazekii ATP/ADP translocase: evidence that TM VIII faces an aqueous channel

The contribution of transmembrane region VIII of the Rickettsia prowazekii ATP/ADP translocase to the structure of the water-filled channel through which ATP is transported was evaluated from the accessibility of three hydrophilic, thiol reactive, methanethiosulfonate reagents to a library of 21 single-cysteine substitution mutants expressed in Escherichia coli. A negatively charged reagent (MTSES) and two positively charged reagents (MTSET and MTSEA) were used. Mutants Q323C and G327C did not tolerate cysteine substitution and were almost completely deficient in ATP transport. The remaining mutants exhibited 25-226% of the cysteine-less parent's transport activity. Five patterns of inhibition of ATP transport by the MTS reagents were observed. (i) ATP transport was not inhibited by any of the three MTS reagents in mutants Q321C, F324C, A332C, and L335C and only marginally in F333C. (ii) Transport activity of mutants F322C, Q326C, and A330C was markedly inhibited by all three reagents. (iii) ATP transport was inhibited by MTSEA in only the largest group of mutants (M334C, I336C, G337C, S338C, N339C, I340C, and I341C). (iv) Transport activity was inhibited by MTSET and MTSEA, whereas high concentrations of MTSES were required to inhibit mutants W328C, V329C, and I331C. However, mutant W328C could be inhibited by MTSES in the presence of sub-K(m) concentrations of the substrate. (v) ATP transport by mutant Y325C was unaffected by MTSEA, but inhibited approximately 50% by MTSET and MTSES. Transport of ATP protected mutants (F322C, W328C, V329C, A330C, and I331C) from MTS inhibition. Mutants in the half of TM VIII that is closest to the cytoplasm were not inhibited well by MTSES or MTSET in either whole cells or inside-out vesicles. The results indicate that TM VIII makes a major contribution to the structure of the aqueous translocation pathway, that the accessibility to impermeant thiol reagents is influenced (blocked or stimulated) by substrate, and that there is great variation in accessibility to MTS reagents along the length of TM VIII.