An amino acid cluster around the essential Glu-14 is part of the substrate- and proton-binding domain of EmrE,a multidrug transporter from Escherichia coli

EmrE is a small multidrug transporter (110 amino acids long) from Escherichia coli that extrudes various drugs in exchange with protons, thereby rendering bacteria resistant to these compounds. Glu-14 is the only charged membrane-embedded residue in EmrE and is evolutionarily highly conserved. This residue has an unusually high pK and is an essential part of the binding domain, shared by substrates and protons. The occupancy of the binding domain is mutually exclusive, and, as such, this provides the molecular basis for the coupling between substrate and proton fluxes. Systematic cysteine-scanning mutagenesis of the residues in the transmembrane segment (TM1), where Glu-14 is located, reveals an amino acid cluster on the same face of TM1 as Glu-14 that is part of the substrate- and proton-binding domain. Substitutions at most of these positions yielded either inactive mutants or mutants with modified affinity to substrates. Substitutions at the Ala-10 position, one helix turn away from Glu-14, yielded mutants with modified affinity to protons and thereby impaired in the coupling of substrate and proton fluxes. Taken as a whole, the results strongly support the concept of a common binding site for substrate and protons and stress the importance of one face of TM1 in substrate recognition, binding, and H(+)-coupled transport.     

Precious things come in little packages

The 110-amino acid multidrug transporter from E. coli, EmrE, is a member of the family of MiniTexan or Smr drug transporters. EmrE can transport acriflavine, ethidium bromide, tetraphenylphosphonium (TPP+), benzalkonium and several other drugs with relatively high affinities. EmrE is an H+/drug antiporter, utilizing the proton electrochemical gradient generated across the bacterial cytoplasmic membrane by exchanging two protons with one substrate molecule. The EmrE multidrug transporter is unique in its small size and hydrophobic nature. Hydropathic analysis of the EmrE sequence predicts four alpha-helical transmembrane segments. This model is experimentally supported by FTIR studies that confirm the high alpha-helicity of the protein and by high-resolution heteronuclear NMR analysis of the protein structure. The TMS of EmrE are tightly packed in the membrane without any continuous aqueous domain, as was shown by Cysteine scanning experiments. These results suggest the existence of a hydrophobic pathway through which the substrates are translocated. EmrE is functional as a homo-oligomer as suggested by several lines of evidence, including co-reconstitution experiments of wild-type protein with inactive mutants in which negative dominance has been observed. EmrE has only one membrane embedded charged residue, Glu-14, that is conserved in more than fifty homologous proteins and it is a simple model system to study the role of carboxylic residues in ion-coupled transporters. We have used mutagenesis and chemical modification to show that Glu-14 is part of the substrate-binding site. Its role in proton binding and translocation was shown by a study of the effect of pH on ligand binding, uptake, efflux and exchange reactions. We conclude that Glu-14 is an essential part of a binding site, common to substrates and protons. The occupancy of this site is mutually exclusive and provides the basis of the simplest coupling of two fluxes. Because of some of its properties and its size, EmrE provides a unique system to understand mechanisms of substrate recognition and translocation.     

Scanning cysteine accessibility of EmrE, an H+-coupled multidrug transporter from Escherichia coli, reveals a hydrophobic pathway for solutes.

EmrE is a 12-kDa Escherichia coli multidrug transporter that confers resistance to a wide variety of toxic reagents by actively removing them in exchange for hydrogen ions. The three native Cys residues in EmrE are inaccessible to N-ethylmaleimide (NEM) and a series of other sulfhydryls. In addition, each of the three residues can be replaced with Ser without significant loss of activity. A protein without all the three Cys residues (Cys-less) has been generated and shown to be functional. Using this Cys-less protein, we have now generated a series of 48 single Cys replacements throughout the protein. The majority of them (43) show transport activity as judged from the ability of the mutant proteins to confer resistance against toxic compounds and from in vitro analysis of their activity in proteoliposomes. Here we describe the use of these mutants to study the accessibility to NEM, a membrane permeant sulfhydryl reagent. The study has been done systematically so that in one transmembrane segment (TMS2) each single residue was replaced. In each of the other three transmembrane segments, at least four residues covering one turn of the helix were replaced. The results show that although the residues in putative hydrophilic loops readily react with NEM, none of the residues in putative transmembrane domains are accessible to the reagent. The results imply very tight packing of the protein without any continuous aqueous domain. Based on the findings described in this work, we conclude that in EmrE the substrates are translocated through a hydrophobic pathway.     

Three-dimensional structure of the bacterial multidrug transporter EmrE shows it is an asymmetric homodimer

The small multidrug resistance family of transporters is widespread in bacteria and is responsible for bacterial resistance to toxic aromatic cations by proton-linked efflux. We have determined the three-dimensional (3D) structure of the Escherichia coli multidrug transporter EmrE by electron cryomicroscopy of 2D crystals, including data to 7.0 A resolution. The structure of EmrE consists of a bundle of eight transmembrane alpha-helices with one substrate molecule bound near the centre. The substrate binding chamber is formed from six helices and is accessible both from the aqueous phase and laterally from the lipid bilayer. The most remarkable feature of the structure of EmrE is that it is an asymmetric homodimer. The possible arrangement of the two polypeptides in the EmrE dimer is discussed based on the 3D density map.     

Functional response of the small multidrug resistance protein EmrE to mutations in transmembrane helix 2

Escherichia coli EmrE is a small multidrug resistance protein encompassing four transmembrane (TM) sequences that oligomerizes to confer resistance to antimicrobials. Here we examined the effects on in vivo protein accumulation and ethidium resistance activity of single residue substitutions at conserved and variable positions in EmrE transmembrane segment 2 (TM2). We found that activity was reduced when conserved residues localized to one TM2 surface were replaced. Our findings suggest that conserved TM2 positions tolerate greater residue diversity than conserved sites in other EmrE TM sequences, potentially reflecting a source of substrate polyspecificity.     

Structure,Dynamics, and Substrate-induced Conformational Changes of the Multidrug Transporter EmrE in Liposomes

EmrE, a member of the small multidrug transporters superfamily, extrudes positively charged hydrophobic compounds out of Escherichia coli cytoplasm in exchange for inward movement of protons down their electrochemical gradient. Although its transport mechanism has been thoroughly characterized, the structural basis of energy coupling and the conformational cycle mediating transport have yet to be elucidated. In this study, EmrE structure in liposomes and the substrate-induced conformational changes were investigated by systematic spin labeling and EPR analysis. Spin label mobilities and accessibilities describe a highly dynamic ligand-free (apo) conformation. Dipolar coupling between spin labels across the dimer reveals at least two spin label populations arising from different packing interfaces of the EmrE dimer. One population is consistent with antiparallel arrangement of the monomers, although the EPR parameters suggest deviations from the crystal structure of substrate-bound EmrE. Resolving these discrepancies requires an unusual disposition of TM3 relative to the membrane-water interface and a kink in its backbone that enables bending of its C-terminal part. Binding of the substrate tetraphenylphosphonium changes the environment of spin labels and their proximity in three transmembrane helices. The underlying conformational transition involves repacking of TM1, tilting of TM2, and changes in the backbone configurations of TM3 and the adjacent loop connecting it to TM4. A dynamic apo conformation is necessary for the polyspecificity of EmrE allowing the binding of structurally diverse substrates. The flexibility of TM3 may play a critical role in movement of substrates across the membrane.     

Asymmetric protonation of EmrE

The small multidrug resistance transporter EmrE is a homodimer that uses energy provided by the proton motive force to drive the efflux of drug substrates. The pKa values of its “active-site” residues—glutamate 14 (Glu14) from each subunit—must be poised around physiological pH values to efficiently couple proton import to drug export in vivo. To assess the protonation of EmrE, pH titrations were conducted with ¹H-¹⁵N TROSY-HSQC nuclear magnetic resonance (NMR) spectra. Analysis of these spectra indicates that the Glu14 residues have asymmetric pKa values of 7.0 ± 0.1 and 8.2 ± 0.3 at 45°C and 6.8 ± 0.1 and 8.5 ± 0.2 at 25°C. These pKa values are substantially increased compared with typical pKa values for solvent-exposed glutamates but are within the range of published Glu14 pKa values inferred from the pH dependence of substrate binding and transport assays. The active-site mutant, E14D-EmrE, has pKa values below the physiological pH range, consistent with its impaired transport activity. The NMR spectra demonstrate that the protonation states of the active-site Glu14 residues determine both the global structure and the rate of conformational exchange between inward- and outward-facing EmrE. Thus, the pKa values of the asymmetric active-site Glu14 residues are key for proper coupling of proton import to multidrug efflux. However, the results raise new questions regarding the coupling mechanism because they show that EmrE exists in a mixture of protonation states near neutral pH and can interconvert between inward- and outward-facing forms in multiple different protonation states.     

Intermolecular cross-linking of Na+-Ca2+ exchanger proteins: evidence for dimer formation

The cardiac Na (+)-Ca (2+) exchanger (NCX1) is modeled to contain nine transmembrane segments (TMS) with a pair of oppositely oriented, conserved sequences called the alpha-repeats that are important in ion transport. Residue 122 in the alpha-1 repeat is in proximity to residue 768 in TMS 6, and the two residues can be cross-linked . During studies on the substrate specificity of this intramolecular cross-link, we found evidence that NCX1 can form dimers. At 37 degrees C in the absence of extracellular Na (+), copper phenanthroline catalyzes disulfide bond formation between cysteines at position 122 in adjacent NCX1 proteins. Dimerization was confirmed by histidine tag pull-down experiments that demonstrate the association of untagged NCX1 with histidine-tagged NCX1. Dimerization occurs along a face of the protein that includes parts of the alpha-1 and alpha-2 repeats as well as parts of TMS 1 and TMS 2. We do not see cross-linking between residues in TMS 5, TMS 6, or TMS 7. These data provide the first evidence for dimer formation by the Na (+)-Ca (2+) exchanger.     

Electron crystallography reveals plasticity within the drug binding site of the small multidrug transporter EmrE

EmrE is a Small Multidrug Resistance transporter (SMR) family member that mediates counter transport of protons and hydrophobic cationic drugs such as tetraphenylphosphonium (TPP⁺), ethidium, propidium and dequalinium. It is thought that the selectivity of the drug binding site in EmrE is defined by two negatively charged glutamate residues within a hydrophobic pocket formed from six of the α-helices, three from each monomer of the asymmetric EmrE homodimer. It is not apparent how such a binding pocket accommodates drugs of various sizes and shapes or whether the conformational changes that occur upon drug binding are identical for drugs of diverse chemical nature. Here, using electron cryomicroscopy of EmrE two-dimensional crystals we have determined projection structures of EmrE bound to three structurally different planar drugs, ethidium, propidium and dequalinium. Using image analysis and rigorous comparisons between these density maps and the density maps of the ligand-free and TPP⁺-bound forms of EmrE, we identify regions within the transporter that adapt differentially depending on the type of ligand bound. We show that all three planar drugs bind at the same pocket within the protein as TPP⁺. Furthermore, our analysis indicates that, while retaining the overall fold of the protein, binding of the planar drugs is accompanied by small rearrangements of the transmembrane domains that are different to those that occur when TPP⁺ binds. The regions in the EmrE dimer that are remodelled surround the drug binding site and include transmembrane domains from both monomers.     

Analysis of transmembrane segment 8 of the GLUT1 glucose transporter by cysteine-scanning mutagenesis and substituted cysteine accessibility

The GLUT1 glucose transporter has been proposed to form an aqueous substrate translocation pathway via the clustering of several amphipathic transmembrane helices (Mueckler, M., Caruso, C., Baldwin, S. A., Panico, M., Blench, I., Morris, H. R., Allard, W. J., Lienhard, G. E., and Lodish, H. F. (1985) Science 229, 941-945). The possible role of transmembrane helix 8 in the formation of this permeation pathway was investigated using cysteine-scanning mutagenesis and the membrane-impermeant sulfhydryl-specific reagent, p-chloromercuribenzenesulfonate (pCMBS). Twenty-one GLUT1 mutants were created from a fully functional cysteine-less parental GLUT1 molecule by successively changing each residue along transmembrane segment 8 to a cysteine. The mutant proteins were then expressed in Xenopus oocytes, and their membrane concentrations, 2-deoxyglucose uptake activities, and sensitivities to pCMBS were determined. Four positions within helix 8, alanine 309, threonine 310, serine 313, and glycine 314, were accessible to pCMBS as judged by the inhibition of transport activity. All four of these residues are clustered along one face of a putative alpha-helix. These results suggest that transmembrane segment 8 of GLUT1 forms part of the sugar permeation pathway. Updated two-dimensional models for the orientation of the 12 transmembrane helices and the conformation of the exofacial glucose binding site of GLUT1 are proposed that are consistent with existing experimental data and homology modeling based on the crystal structures of two bacterial membrane transporters.     

Conformational changes in the multidrug transporter EmrE associated with substrate binding

EmrE is a bacterial multidrug transporter of the small multidrug resistance family, which extrudes large hydrophobic cations such as tetraphenylphosphonium (TPP(+)) out of the cell by a proton antiport mechanism. Binding measurements were performed on purified EmrE solubilized in dodecylmaltoside to determine the stoichiometry of TPP(+) binding; the data showed that one TPP(+) molecule bound per EmrE dimer. Reconstitution of purified EmrE at low lipid:protein ratios in either the presence or the absence of TPP(+) produced well ordered two-dimensional crystals. Electron cryo-microscopy was used to collect images of frozen hydrated EmrE crystals and projection maps were determined by image processing to 7A resolution. An average native EmrE projection structure was calculated from the c222 and p222(1) crystals, which was subsequently subtracted from the average of two independent p2 projection maps of EmrE with TPP(+) bound. The interpretation of the difference density image most consistent with biochemical data suggested that TPP(+) bound at the monomer-monomer interface in the centre of the EmrE dimer, and resulted in the movement of at least one transmembrane alpha-helix.     

The yeast mitochondrial citrate transport protein: determination of secondary structure and solvent accessibility of transmembrane domain IV using site-directed spin labeling

To explore the spatial organization and functional dynamics of the citrate transport protein (CTP), a nitroxide scan was carried out along 22 consecutive residues within the fourth transmembrane domain (TMDIV). This domain has been implicated as being of unique importance to the CTP mechanism due to (i) the presence of two intramembranous positive charges that are essential for CTP function and (ii) the existence of a transmembrane aqueous surface within this domain which likely corresponds to a portion of the citrate translocation pathway. The sequence-specific variation in the mobilities of the introduced nitroxides and their accessibilities to molecular O(2) reveal an alpha-helical conformation along the sequence. The accessibilities to NiEDDA are out of phase with accessibilites to O(2), indicating that one face of the helix is solvated by the lipid bilayer while the other is solvated by an aqueous environment. A gradient of NiEDDA accessibility is observed along the helix surface facing the aqueous phase, and the EPR spectral line shapes at these sites indicate considerable motional restriction. In the context of the model where TMDIV lines the translocation pathway, these data suggest a barrier to passive diffusion through the pathway. This paper reports the first use of site-directed spin labeling to study mitochondrial transporter structure.     

Cysteine-directed cross-linking demonstrates that helix 3 of SecE is close to helix 2 of SecY and helix 3 of a neighboring SecE.

Preprotein translocation in Escherichia coli is mediated by translocase, a multimeric membrane protein complex with SecA as the peripheral ATPase and SecYEG as the translocation pore. Unique cysteines were introduced into transmembrane segment (TMS) 2 of SecY and TMS 3 of SecE to probe possible sites of interaction between the integral membrane subunits. The SecY and SecE single-Cys mutants were cloned individually and in pairs into a secYEG expression vector and functionally overexpressed. Oxidation of the single-Cys pairs revealed periodic contacts between SecY and SecE that are confined to a specific alpha-helical face of TMS 2 and 3, respectively. A Cys at the opposite alpha-helical face of TMS 3 of SecE was found to interact with a neighboring SecE molecule. Formation of this SecE dimer did not affect the high-affinity binding of SecA to SecYEG and ATP hydrolysis, but blocked preprotein translocation and thus uncouples the SecA ATPase activity from translocation. Conditions that prevent membrane deinsertion of SecA markedly stimulated the interhelical contact between the SecE molecules. The latter demonstrates a SecA-mediated modulation of the protein translocation channel that is sensed by SecE.     

Analysis of transmembrane segment 10 of the Glut1 glucose transporter by cysteine-scanning mutagenesis and substituted cysteine accessibility.

The Glut1 glucose transporter has been proposed to form an aqueous sugar translocation pathway through the lipid bilayer via the clustering of several transmembrane helices (Mueckler, M., Caruso, C., Baldwin, S. A., Panico, M., Blench, I., Morris, H. R., Allard, W. J., Lienhard, G. E., and Lodish, H. F. (1985) Science 229, 941-945). The participation of transmembrane helix 10 in the formation of this putative aqueous tunnel was tested using cysteine-scanning mutagenesis in conjunction with the membrane-impermeant, sulfhydryl-specific reagent, p-chloromercuribenzenesulfonate (pCMBS). A series of 21 mutants was created from a fully functional, cysteine-less, parental Glut1 molecule by changing each residue within putative transmembrane segment 10 to cysteine. Each mutant was then expressed in Xenopus oocytes, and its plasma membrane content, 2-deoxyglucose uptake activity, and sensitivity to pCMBS were measured. Helix 10 exhibited a highly distinctive reaction profile to scanning mutagenesis whereby cysteine substitution at residues within the cytoplasmic N-terminal half of the helix tended to increase specific transport activity, whereas substitution at residues within the exoplasmic C-terminal half of the helix tended to decrease specific transport activity. Four residues within helix 10 were clearly accessible to pCMBS as judged by inhibition or stimulation of transport activity. All four of these residues were clustered along one face of a putative alpha-helix. These results combined with previously published data suggest that transmembrane segment 10 of Glut1 forms part of the sugar permeation pathway. Two-dimensional models for the conformation of the 12 transmembrane helices and the exofacial glucose-binding site of Glut1 are proposed that are consistent with existing experimental data.     

Helix packing of functionally important regions of the cardiac Na(+)-Ca(2+) exchanger

In a revised topological model of the cardiac Na(+)-Ca(2+) exchanger, there are nine transmembrane segments (TMSs) and two possible re-entrant loops (Nicoll, D. A., Ottolia, M., Lu, Y., Lu, L., and Philipson, K. D. (1999) J. Biol. Chem. 274, 910-917; Iwamoto, T., Nakamura, T. Y., Pan, Y., Uehara, A., Imanaga, I., and Shigekawa, M. (1999) FEBS Lett. 446, 264-268). The TMSs form two clusters separated by a large intracellular loop between TMS5 and TMS6. We have combined cysteine mutagenesis and oxidative cross-linking to study proximity relationships of TMSs in the exchanger. Pairs of cysteines were reintroduced into a cysteine-less exchanger, one in a TMS in the NH(2)-terminal cluster (TMSs 1-5) and the other in a TMS in the COOH-terminal cluster (TMSs 6-9). The mutant exchanger proteins were expressed in HEK293 cells, and disulfide bond formation between introduced cysteines was analyzed by gel mobility shifts. Western blots showed that S117C/V804C, A122C/Y892C, A151C/T815C, and A151C/A821C mutant proteins migrated at 120 kDa under reducing conditions and displayed a partial mobility shift to 160 kDa under nonreducing conditions. This shift indicates the formation of a disulfide bond between these paired cysteine residues. Copper phenanthroline and the cross-linker N', N'-o-phenylenedimaleimide enhanced the mobility shift to 160 kDa. Our data suggest that TMS7 is close to TMS3 near the intracellular side of the membrane and is in the vicinity of TMS2 near the extracellular surface. Also, TMS2 must adjoin TMS8. This initial packing model of the exchanger brings two functionally important domains in the exchanger, the alpha 1 and alpha 2 repeats, close to each other.     

The chloride permeation pathway of a glutamate transporter and its proximity to the glutamate translocation pathway

Excitatory amino acid transporters (EAATs) regulate glutamate concentrations in the brain to maintain normal excitatory synaptic transmission. A widely accepted view of transporters is that they consist of a pore with alternating access to the intracellular and extracellular solutions, which serves to couple ion movement to the movement of substrate. However, recent observations that EAATs, and also a number of other neurotransmitter transporters, can also function as ligand-gated chloride channels have blurred the distinctions between transporters and ion channels. Here we show that mutations in the second transmembrane domain (TM2) of EAAT1 alter anion permeation properties without affecting glutamate transport and that a number of TM2 residues are accessible to the external aqueous solution. Furthermore, we demonstrate that the extracellular edge of TM2 is in close proximity to a membrane-associated domain that influences glutamate transport. This study will provide the foundation for beginning to understand how transporters can function as both transporters and ion channels.     

A membrane-embedded glutamate is required for ligand binding to the multidrug transporter EmrE

EmrE is an Escherichia coli multidrug transporter that confers resistance to a variety of toxins by removing them in exchange for hydrogen ions. The detergent-solubilized protein binds tetraphenylphosphonium (TPP(+)) with a K(D) of 10 nM. One mole of ligand is bound per approximately 3 mol of EmrE, suggesting that there is one binding site per trimer. The steep pH dependence of binding suggests that one or more residues, with an apparent pK of approximately 7.5, release protons prior to ligand binding. A conservative Asp replacement (E14D) at position 14 of the only membrane-embedded charged residue shows little transport activity, but binds TPP(+) at levels similar to those of the wild-type protein. The apparent pK of the Asp shifts to <5.0. The data are consistent with a mechanism requiring Glu14 for both substrate and proton recognition. We propose a model in which two of the three Glu14s in the postulated trimeric EmrE homooligomer deprotonate upon ligand binding. The ligand is released on the other face of the membrane after binding of protons to Glu14.     

Cysteine-scanning mutagenesis of transmembrane segment 11 of the GLUT1 facilitative glucose transporter

The glucose permeation pathway within the GLUT1 facilitative glucose transporter is hypothesized to be formed by the juxtaposition of the hydrophilic faces of several transmembrane alpha-helices. The role of transmembrane segment 11 in forming a portion of this central aqueous channel was investigated using cysteine-scanning mutagenesis in conjunction with sulfhydryl-directed chemical modification. Each of the amino acid residues within transmembrane segment 11 were individually mutated to cysteine in an engineered GLUT1 molecule devoid of all native cysteines (C-less). Measurement of 2-deoxyglucose uptake in a Xenopus oocyte expression system revealed that all of these mutants retain measurable transport activity. Four of the cysteine mutants (N411, W412, N415, and F422) had significantly reduced specific activity relative to the C-less protein. Specific activity was increased in five of the mutants (A402, A405, V406, F416, and M420). The solvent accessibility and relative orientation of the residues to the glucose permeation pathway were investigated by determining the sensitivity of the mutant transporters to inhibition by the sulfhydryl-directed reagent p-chloromercuribenzenesulfonate (pCMBS). Cysteine replacement at five positions (I404, G408, F416, G419, and M420) produced transporters that were inhibited by incubation with extracellular pCMBS. All of these residues cluster along a single face of the alpha-helix within the regions showing altered specific activities. These data demonstrate that the exofacial portion of transmembrane segment 11 is accessible to the external solvent and provide evidence for the positioning of this alpha-helix within or near the glucose permeation pathway.     

Structural analysis of synthetic peptide fragments from EmrE,a multidrug resistance protein,in a membrane-mimetic environment

EmrE, a multidrug resistance protein from Escherichia coli, renders the bacterium resistant to a variety of cytotoxic drugs by active translocation out of the cell. The 110-residue sequence of EmrE limits the number of structural possibilities that can be envisioned for this membrane protein. Four helix bundle models have been considered [Yerushalmi, H., Lebendiker, M., and Schuldiner, S. (1996) J. Biol. Chem. 271, 31044-31048]. The validity of EmrE structural models has been probed experimentally by investigations on overlapping peptides (ranging in length from 19 to 27 residues), derived from the sequence of EmrE. The choice of peptides was made to provide sequences of two complete, predicted transmembrane helices (peptides H1 and H3) and two helix-loop-helix motifs (peptides A and B). Peptide (B) also corresponds to a putative hairpin in a speculative beta-barrel model, with the "Pro-Thr-Gly" segment forming a turn. Structure determination in SDS micelles using NMR indicates peptide H1 to be predominantly helical, with helix boundaries in the micellar environment corroborating predicted helical limits. Peptide A adopts a helix-loop-helix structure in SDS micelles, and peptide B was also largely helical in micellar environments. An analogue peptide, C, in which the central "Pro-Thr-Gly" was replaced by "(D)Pro-Gly" displays local turn conformation at the (D)Pro-Gly segment, but neither a continuous helical stretch nor beta-hairpin formation was observed. This study implies that the constraints of membrane and micellar environments largely direct the structure of transmembrane peptides and proteins and study of judiciously selected peptide fragments can prove useful in the structural elucidation of membrane proteins.