Orientation of chargerin II (A6L) in the ATP synthase of rat liver mitochondria determined with antibodies against peptides of the protein

Previous studies suggested that the hydrophobic protein chargerin II, which is encoded in the unidentified reading frame A6L of mitochondrial DNA (URFA6L), may have a key role in the energy transduction by mitochondrial ATP synthase because an antibody against chargerin II inhibited ATP synthesis and ATP-Pi exchange, in an energy-dependent fashion. In the present work, the orientation of chargerin II in Fo of the ATP synthase of rat liver mitochondria was examined using antibodies against peptides of chargerin II. Results showed that its N-terminal region (about 8 amino acid residues) was exposed on the surface of the C-side of Fo, but its C-terminal and charge-cluster regions were buried in Fo.     

ATP synthase complex from beef heart mitochondria. Role of the thiol group of the 25-kDa subunit of Fo in the coupling mechanism between Fo and F1

In order to assess the role of thiol groups in the Fo part of the ATP synthase in the coupling mechanism of ATP synthase, we have treated isolated Fo, extracted from beef heart Complex V with urea, with thiol reagents, primarily with diazenedicarboxylic acid bis-(dimethylamide) (diamide) but also with Cd2+ and N-ethylmaleimide. FoF1 ATP synthase was reconstituted by adding isolated F1 and the oligomycin-sensitivity-conferring-protein (OSCP) to Fo. The efficiency of reconstitution was assessed by determining the sensitivity to oligomycin of the ATP hydrolytic activity of the reconstituted enzyme. Contrary to Cd2+, incubation of diamide with Fo, before the addition of F1 and OSCP, induced a severe loss of oligomycin sensitivity, due to an inhibited binding of F1 to Fo. This effect was reversed by dithiothreitol. Conversely, if F1 and OSCP were added to Fo before diamide, no effect could be detected. These results show that F1 (and/or OSCP) protects Fo thiols from diamide and are substantiated by the finding that the oligomycin sensitivity of ATP hydrolysis activity of isolated Complex V was also unaltered by diamide. Gel electrophoresis of FoF1 ATP synthase, reconstituted with diamide-treated Fo, revealed that the loss of oligomycin sensitivity was directly correlated with diminution of band Fo 1 (or subunit b). Concomitantly a band appeared of approximately twice the molecular weight of subunit Fo 1. As this protein contains only 1 cysteine residue (Walker, J. E., Runswick, M. J., and Poulter, L. (1987) J. Mol. Biol. 197, 89-100), the effect of diamide is attributed to the formation of a disulfide bridge between two of these subunits. These results offer further evidence for the proposal, based on aminoacid sequence and structural analysis, that subunit Fo 1 of mammalian Fo is involved in the binding with F1 (Walker et al. (1987]. N-Ethylmaleimide affects oligomycin sensitivity to a lesser extent than diamide, suggesting that the mode of action of these reagents (and the structural changes induced in Fo) is different.     

Cross-linking of the gamma subunit of the Escherichia coli ATPase (ECF1) via cysteines introduced by site-directed mutagenesis.

The gamma subunit of the Escherichia coli F1 ATPase (ECF1) has been altered by site-directed mutagenesis to create five different mutants, gamma-S8C, gamma-S81C, gamma-T106C, gamma-S179C, and gamma-V286C, respectively. ECF1 isolated from four of these mutants had ATPase activities similar to that of a wild-type isogenic strain used as a control, the exception was enzyme isolated from mutant gamma-S81C, which had an ATPase activity of around 70-80% of the wild type. ECF1 isolated from each of the various mutants was reacted with N-(4-(7-(diethylamino)-4-methylcoumarin-3-yl))maleimide (CM). The fluorescent reagent was incorporated into Cys residues placed at positions 8, 106, 179, and 286, but not at 81, indicating which of these Cys residues are on the surface of the gamma subunit in the enzyme complex. Modification of the Cys at position 106 with CM activated the enzyme, and modification of the Cys at position 8 inhibited ATPase activity a small amount; however, modification of Cys at 179 or 286 had no effect on enzyme activity. The four mutants with a reactive Cys were reacted with tetrafluorophenylazide maleimides (TFPAMs), novel photoactivatable cross-linkers. In the mutant gamma-S8C, cross-links were formed between the introduced Cys on the gamma subunit and sites on the beta subunit. This cross-linking between gamma and beta depended on nucleotide conditions under which the photolysis was carried out, with differently migrating cross-linked products being obtained in ATP + EDTA compared with ATP + Mg2+ or ATP + Mg2+ Pi. Cross-linking between beta and gamma inhibited ATPase activity in proportion to the yield of cross-linked product. In the mutant gamma-V286C, cross-links were formed between the introduced Cys on gamma and the alpha subunit which were the same in all nucleotide conditions and which led to inhibition of ATPase activity.     

Modification of Sulfhydryl Groups in the [gamma]-Subunit of Chloroplast-Coupling Factor 1 Affects the Proton Slip through the ATP Synthase

A large proton leak not coupled to ATP synthesis (slip) occurs at alkaline pH through the chloroplast ATP synthase (Y. Evron, M. Avron [1990] Biochim Biophys Acta 1019: 115-120). The involvement of the ATP synthase [gamma]-subunit in the regulation of proton conductance was analyzed by measuring the effect of thiolalkylating agents on proton slip. Alkylation by N-ethylmaleimide of [gamma]-cysteine (Cys)-89, which is exposed upon energization of thylakoids, increases the slip only at alkaline pH. The slip is partially suppressed by low concentrations of adenine nucleotides and is completely eliminated by venturicidin, a blocker of the hydrophobic polypeptide complex of the chloroplast ATP synthase (CF0). Conversely, cross-linking of [gamma]-Cys-89 with [gamma]-Cys-322 renders the ATP synthase leaky to protons and insensitive to ATP also at neutral pH. The accessibility of [gamma]-Cys-89 to alkylation by fluorescein maleimide is completely suppressed by N,N-dicyclohexylcarbodiimide and by venturicidin, which block proton conductance through CF0 and increase the pH gradient. These results suggest that the [gamma]-subunit has a dominant role in proton gating through the ATP synthase and responds to changes in pH and ligands taking place on either side of the thylakoid membrane. It is proposed that the conformational changes that induce the proton slip and the exposure of [gamma]-Cys-89 reflect the conversion of the enzyme from a catalytically latent to an active state, and depend on the deprotonation of a stromal site at alkaline pH and on protonation of an intrathylakoid inner site upon energization. Therefore, conditions that induce the conformational activation also provide the driving force for ATP synthesis.     

Acidic residues in the lactococcal multidrug efflux pump LmrP play critical roles in transport of lipophilic cationic compounds

The proton motive force-driven efflux pump LmrP confers multidrug resistance on Lactococcus lactis cells by extruding a wide variety of lipophilic cationic compounds from the inner leaflet of the cytoplasmic membrane to the exterior of the cell. LmrP contains one cysteine (Cys(270)), which was replaced by alanine. This cysteine-less variant was used in a cysteine scanning accessibility approach. All 19 acidic residues in LmrP were replaced one by one by cysteine and subsequently challenged with the large thiol reagent fluorescein maleimide. The labeling pattern strongly indicates that only three acidic residues (Asp(142), Glu(327), and Glu(388)) are membrane-embedded. The roles of these residues in drug recognition were evaluated based on transport experiments with two cationic substrates, ethidium and Hoechst 33342, after replacing each of these residues with cysteine, alanine, lysine, glutamate, or aspartate. The obtained results suggest that the negative charges at positions 142 and 327 are not critical for the transport function but are important for drug recognition by LmrP. Surprisingly, the residues Cys(142) and Cys(327) become accessible for fluorescein maleimide upon binding of substrates, indicating a movement of these residues from a nonpolar to a polar environment. Substrate binding apparently results in a conformational change in this region of the protein and a reorientation of a lipid-embedded, hydrophobic substrate-binding site to an aqueous substrate translocation pathway.     

The Fo subunits of the Escherichia coli F1Fo-ATP synthase are sufficient to form a functional proton pore

The assembly of the Fo sector of the Escherichia coli ATP synthase has been studied using both structural and functional criteria for assembly. Cross-linking E. coli minicell membranes containing only the Fo subunits a, b, and c with dithiobis(succinimidyl propionate) (DSP) produces b2 and c2 dimers that are generated by cross-linking membranes containing the assembled holoenzyme. Five plasmids carrying the genes specifying the Fo polypeptides in a bacterial strain lacking all of the unc (ATP synthase) genes show a good correlation between Fo function and the amount of the membrane-bound Fo polypeptides. In this report we revise a conclusion reached previously (Klionsky, D.J., Brusilow, W.S.A., and Simoni, R.D. (1983) J. Biol. Chem. 258, 10136-10143) and present evidence that the Fo subunits alone are sufficient to assemble a functional proton pore.     

A model for the structure of subunit a of the Escherichia coli ATP synthase and its role in proton translocation

Most of what is known about the structure and function of subunit a, of the ATP synthase, has come from the construction and isolation of mutations, and their analysis in the context of the ATP synthase complex. Three classes of mutants will be considered in this review. (1) Cys substitutions have been used for structural analysis of subunit a, and its interactions with subunit c. (2) Functional residues have been identified by extensive mutagenesis. These studies have included the identification of second-site suppressors within subunit a. (3) Disruptive mutations include deletions at both termini, internal deletions, and single amino acid insertions. The results of these studies, in conjunction with information about subunits b and c, can be incorporated into a model for the mechanism of proton translocation in the Escherichia coli ATP synthase.     

Identification of a peroxide-sensitive redox switch at the CXXC motif in the human mitochondrial branched chain aminotransferase

The human mitochondrial branched chain aminotransferase isoenzyme (hBCATm) must be stored in a reducing environment to remain active. Oxidation or labeling of hBCATm with sulfhydryl reagents results in enzyme inhibition. In this study, we investigated both the structural and biochemical basis for the sensitivity of hBCATm to these reagents. In its native form, hBCATm has two reactive cysteine residues which were identified as Cys315 and Cys318 using iodinated beta-(4-hydroxyphenyl)ethyl maleimide. These are located in the large domain of the homodimer, about 10 A from the active site. The crystal structures show evidence for a thiol-thiolate hydrogen bond between Cys315 and Cys318. Under oxidizing conditions, these cysteine residues can reasonably form a disulfide bond because of the short distance between the sulfur atoms (3.09-3.46 A), requiring only a decrease of 1.1-1.5 A. In addition to Cys315 playing a structural role by anchoring Tyr173, which in the ketimine form increases access to the active site, our evidence indicates that these cysteine residues act as a redox switch in hBCATm. Electrospray ionization mass spectrometry analysis and UV-Vis spectroscopic studies of 5,5'-dithiobis(2-nitrobenzoic acid) labeled hBCATm showed that during labeling, an intrasubunit disulfide bond was formed in a significant portion of the protein. Furthermore, it was established that reaction of hBCATm with H2O2 abolished its activity and resulted in the formation of an intrasubunit disulfide bond between Cys315 and Cys318. Addition of dithiothreitol completely reversed the oxidation and restored activity. Therefore, the results demonstrate that there is redox-linked regulation of hBCATm activity by a peroxide sensitive CXXC center. Future studies will determine if this center has an in vivo role in the regulation of branched chain amino acid metabolism.     

Complete replacement of basic amino acid residues with cysteines in Rickettsia prowazekii ATP/ADP translocase

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.     

Fluorescence energy transfer studies of human deoxycytidine kinase: role of cysteine 185 in the conformational changes that occur upon substrate binding

Human deoxycytidine kinase (dCK) phosphorylates both pyrimidine and purine deoxynucleosides, including numerous nucleoside analogue prodrugs. Energy transfer studies of transfer between Trp residues of dCK and the fluorescent probe N-(1-pyrene)maleimide (PM), which specifically labels Cys residues in proteins, were performed. Two of the six Cys residues in dCK were labeled, yielding a protein that was functionally active. We determined the average distances between PM-labeled Cys residues and Trp residues in dCK in the absence and presence of various pyrimidine and purine nucleoside analogues with the Trp residues as energy donors and PM-labeled Cys residues as acceptors. The transfer efficiency was determined from donor intensity quenching and the F?rster distance R(0) at which the efficiency of energy transfer is 50%, which was 19.90 A for dCK-PM. The average distance R between the Trp residues and the labeled Cys residues in dCK-PM was 18.50 A, and once substrates bound, this distance was reduced, demonstrating conformational changes. Several of the Cys residues of dCK were mutated to Ala, and the properties of the purified mutant proteins were studied. PM labeled a single Cys residue in Cys-185-Ala dCK, suggesting that one of the two Cys residues labeled in wild-type dCK was Cys 185. The distance between the single PM-labeled Cys residue and the Trp residues in Cys-185-Ala dCK was 20.75 A. Binding of nucleosides had no effect on the pyrene fluorescence of Cys-185-Ala dCK, indicating that the conformational changes observed upon substrate binding to wild-type dCK-PM involved the "lid region" of which Cys 185 is a part. The substrate specificity of Cys-185-Ala dCK was altered in that dAdo and UTP were better substrates for the mutant than for the wild-type enzyme.     

Topological and functional study of subunit h of the F1Fo ATP synthase complex in yeast Saccharomyces cerevisiae

Subunit h, a 92-residue-long, hydrophilic, acidic protein, is a component of the yeast mitochondrial F1Fo ATP synthase. This subunit, homologous to the mammalian factor F6, is essential for the correct assembly and/or functioning of this enzyme since yeast cells lacking it are not able to grow on nonfermentable carbon sources. Chemical cross-links between subunit h and subunit 4 have previously been shown, suggesting that subunit h is a component of the peripheral stalk of the F1Fo ATP synthase. The construction of cysteine-containing subunit h mutants and the use of bismaleimide reagents provided insights into its environment. Cross-links were obtained between subunit h and subunits alpha, f, d, and 4. These results and secondary structure predictions allowed us to build a structural model and to propose that this subunit occupies a central place in the peripheral stalk between the F1 sector and the membrane. In addition, subunit h was found to have a stoichiometry of one in the F1Fo ATP synthase complex and to be in close proximity to another subunit h belonging to another F1Fo ATP synthase in the inner mitochondrial membrane. Finally, functional characterization of mitochondria from mutants expressing different C-terminal shortened subunit h suggested that its C-terminal part is not essential for the assembly of a functional F1Fo ATP synthase.     

Biochemical characterization of CopA,the Escherichia coli Cu(I)-translocating P-type ATPase

Escherichia coli CopA is a copper ion-translocating P-type ATPase that confers copper resistance. CopA formed a phosphorylated intermediate with [gamma-(32)P]ATP. Phosphorylation was inhibited by vanadate and sensitive to KOH and hydroxylamine, consistent with acylphosphate formation on conserved Asp-523. Phosphorylation required a monovalent cation, either Cu(I) or Ag(I). Divalent cations Cu(II), Zn(II), or Co(II) could not substitute, signifying that the substrate of this copper-translocating P-type ATPase is Cu(I) and not Cu(II). CopA purified from dodecylmaltoside-solubilized membranes similarly exhibited Cu(I)/Ag(I)-stimulated ATPase activity, with a K(m) for ATP of 0.5 mm. CopA has two N-terminal Cys(X)(2)Cys sequences, Gly-Leu-Ser-Cys(14)-Gly-His-Cys(17), and Gly-Met-Ser-Cys(110)-Ala-Ser-Cys(113), and a Cys(479)-Pro-Cys(481) motif in membrane-spanning segment six. The requirement of these cysteine residues was investigated by the effect of mutations and deletions. Mutants with substitutions of the N-terminal cysteines or deletion of the first Cys-(X)(2)-Cys motif formed acylphosphate intermediates. From the copper dependence of phosphoenzyme formation, the mutants appear to have 2-3 fold higher affinity for Cu(I) than wild type CopA. In contrast, substitutions in Cys(479) or Cys(481) resulted in loss of copper resistance, transport and phosphoenzyme formation. These results imply that the cysteine residues of the Cys-Pro-Cys motif (but not the N-terminal cysteine residues) are required for CopA function.     

Structural modeling and site-directed mutagenesis of the actinorhodin beta-ketoacyl-acyl carrier protein synthase

A three-dimensional model of the Streptomyces coelicolor actinorhodin beta-ketoacyl synthase (Act KS) was constructed based on the X-ray crystal structure of the related Escherichia coli fatty acid synthase condensing enzyme beta-ketoacyl synthase II, revealing a similar catalytic active site organization in these two enzymes. The model was assessed by site-directed mutagenesis of five conserved amino acid residues in Act KS that are in close proximity to the Cys169 active site. Three substitutions completely abrogated polyketide biosynthesis, while two replacements resulted in significant reduction in polyketide production. (3)H-cerulenin labeling of the various Act KS mutant proteins demonstrated that none of the amino acid replacements affected the formation of the active site nucleophile.     

Structural analysis of the regulatory dithiol-containing domain of the chloroplast ATP synthase gamma subunit

The gamma subunit of the F1 portion of the chloroplast ATP synthase contains a critically placed dithiol that provides a redox switch converting the enzyme from a latent to an active ATPase. The switch prevents depletion of intracellular ATP pools in the dark when photophosphorylation is inactive. The dithiol is located in a special regulatory segment of about 40 amino acids that is absent from the gamma subunits of the eubacterial and mitochondrial enzymes. Site-directed mutagenesis was used to probe the relationship between the structure of the gamma regulatory segment and its function in ATPase regulation via its interaction with the inhibitory epsilon subunit. Mutations were designed using a homology model of the chloroplast gamma subunit based on the analogous structures of the bacterial and mitochondrial homologues. The mutations included (a) substituting both of the disulfide-forming cysteines (Cys199 and Cys205) for alanines, (b) deleting nine residues containing the dithiol, (c) deleting the region distal to the dithiol (residues 224-240), and (d) deleting the entire segment between residues 196 and 241 with the exception of a small spacer element, and (e) deleting pieces from a small loop segment predicted by the model to interact with the dithiol domain. Deletions within the dithiol domain and within parts of the loop segment resulted in loss of redox control of the ATPase activity of the F1 enzyme. Deleting the distal segment, the whole regulatory domain, or parts of the loop segment had the additional effect of reducing the maximum extent of inhibition obtained upon adding the epsilon subunit but did not abolish epsilon binding. The results suggest a mechanism by which the gamma and epsilon subunits interact with each other to induce the latent state of the enzyme.     

Subunit f of the Yeast Mitochondrial ATP Synthase: Topological and Functional Studies

Modified versions of subunit f were produced by mutagenesis of theATP17 gene of Saccharomyces cerevisiae. A version of subunit f devoid of thelast 28 amino acid residues including the unique transmembranous domaincomplemented the oxidative phosphorylation of the null mutant. However, atwo-fold decrease in the specific ATP synthase activity was measured andattributed to a decrease in the stability of the mutant ATP synthase complexas shown by the low oligomycin-sensitive ATPase activity at alkaline pH. Themodification or not by non-permeant maleimide reagents of cysteine residuesintroduced at the N and C termini of subunit f indicated aN_in-C_out orientation. From the C terminus of subunit fit was possible to cross-link subunit 4 (also called subunit b), which isanother component of the F₀ sector and which also displays a shorthydrophilic segment exposed to the intermembrane space.     

Labeling the Ca2+-ATPase of skeletal muscle sarcoplasmic reticulum with maleimidylsalicylic acid

Maleimidylsalicylic acid reacts with the Ca(2+)-ATPase of skeletal muscle sarcoplasmic reticulum with high affinity and inhibits the ATPase activity following a pseudo-first-order kinetic with a rate constant of 8.3 m(-1) s(-1). Calcium binding remains unaffected in the maleimide-inhibited ATPase. However, the presence of ATP, ADP, and, to a lesser extent, AMP protects the enzyme against inhibition. Furthermore, ATPase inhibition is accompanied by a concomitant decrease in ATP binding. The stoichiometry of the nucleotide-dependent maleimidylsalicylic acid binding is 6-10 nmol/mg ATPase, which corresponds to the binding of up to one molecule of maleimide/molecule of ATPase. The stoichiometry of maleimide binding is decreased in the presence of nucleotides and in the ATPase previously labeled with fluorescein-5'-isothiocyanate or N-ethylmaleimide A fluorescent peptide was isolated by high performance liquid chromatography after trypsin digestion of the maleimide-labeled ATPase. Analysis of the sequence and mass spectrometry of the peptide leads us to propose Cys(344) as the target for maleimidylsalicylic acid in the inhibition reaction. The effect of Cys(344) modification on the nucleotide site is discussed.     

Complete replacement of basic amino acid residues with cysteines in Rickettsia prowazekii ATP/ADP translocase

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.     

Mitochondrial ATP synthase: fifteen years later

Mitochondrial Fo.F1-H+-ATP synthase is the main enzyme responsible for the formation of ATP in aerobic cells. An alternating binding change mechanism is now generally accepted for the operation of the enzyme. This mechanism apparently leaves no room for the participation of nucleotides and Pi other than sequential binding to (release from) the catalytic sites. However, the kinetics of ATP hydrolysis by mitochondrial ATPase is very complex, and it is difficult to explain it in terms of the alternating binding change mechanism only. Fo.F1 catalyzes both delta muH+-dependent ATP synthesis and ATP-dependent delta muH+ generation. It is generally believed that this enzyme operates as the smallest molecular electromechanochemical reversible machine. This essay summarizes data which contradict this simple reversible mechanism and discusses a hypothesis in which different pathways are followed for ATP hydrolysis and ATP synthesis. A model for a reversible switch mechanism between ATP hydrolase and ATP synthase states of Fo. F1 is proposed.     

Targeted disulfide cross-linking of the MotB protein of Escherichia coli: evidence for two H(+) channels in the stator Complex.

Bacterial flagella are turned by rotary motors that obtain energy from the membrane gradient of protons or sodium ions. The stator of the flagellar motor is formed from the membrane proteins MotA and MotB, which associate in complexes that contain multiple copies of each protein. The complexes conduct ions across the membrane, and couple ion flow to motor rotation by a mechanism that appears to involve conformational changes [Kojima, S., and Blair, D. F. (2001) Biochemistry 40, 13041-13050]. Structural information on the MotA/MotB complex is very limited. MotA has four membrane-spanning segments, and MotB has one. We have begun a targeted disulfide-cross-linking study to probe the arrangement of membrane segments in the MotA/MotB complex, beginning with the single membrane segment of MotB. Cys residues were introduced in 21 consecutive positions in the segment, and disulfide cross-linking was studied in MotA/MotB complexes either in membranes or detergent solution. Most of the Cys-substituted MotB proteins formed disulfide-linked dimers in significant yield upon oxidation. The yield of dimer varied regularly with the position of the Cys substitution, following the pattern expected for a parallel, symmetric dimer of alpha-helices. In a structural model based on the cross-linking experiments, critical Asp32 residues that are believed to facilitate proton movement are positioned on separate surfaces of the MotB dimer and so probably function within two distinct proton channels. Regions accessible to solvent were mapped by measuring the reactivity of introduced Cys residues toward N-ethyl maleimide and a charged methanethiosulfonate reagent. Positions near the middle of the segment were inaccessible to sulhydryl reagents. Positions within 6-8 residues of either end, which includes residues around Asp32, were accessible.