Cysteine-scanning mutagenesis around transmembrane segment III of Tn10-encoded metal-tetracycline/H+ antiporter

Inhibition of Multidrug Efflux Pumps Belonging to the Major Facilitator Superfamily in Bacterial Pathogens

Bacterial pathogens resistant to multiple structurally distinct antimicrobial agents are causative agents of infectious disease, and they thus constitute a serious concern for public health. Of the various bacterial mechanisms for antimicrobial resistance, active efflux is a well-known system that extrudes clinically relevant antimicrobial agents, rendering specific pathogens recalcitrant to the growth-inhibitory effects of multiple drugs. In particular, multidrug efflux pump members of the major facilitator superfamily constitute central resistance systems in bacterial pathogens. This review article addresses the recent efforts to modulate these antimicrobial efflux transporters from a molecular perspective. Such investigations can potentially restore the clinical efficacy of infectious disease chemotherapy.

Functional and Structural Roles of the Major Facilitator Superfamily Bacterial Multidrug Efflux Pumps

Pathogenic microorganisms that are multidrug-resistant can pose severe clinical and public health concerns. In particular, bacterial multidrug efflux transporters of the major facilitator superfamily constitute a notable group of drug resistance mechanisms primarily because multidrug-resistant pathogens can become refractory to antimicrobial agents, thus resulting in potentially untreatable bacterial infections. The major facilitator superfamily is composed of thousands of solute transporters that are related in terms of their phylogenetic relationships, primary amino acid sequences, two- and three-dimensional structures, modes of energization (passive and secondary active), and in their mechanisms of solute and ion translocation across the membrane. The major facilitator superfamily is also composed of numerous families and sub-families of homologous transporters that are conserved across all living taxa, from bacteria to humans. Members of this superfamily share several classes of highly conserved amino acid sequence motifs that play essential mechanistic roles during transport. The structural and functional importance of multidrug efflux pumps that belong to the major facilitator family and that are harbored by Gram-negative and -positive bacterial pathogens are considered here.

Isolation and characterisation of transport-defective substrate-binding mutants of the tetracycline antiporter TetA(B)

The tetracycline antiporter TetA(B) is a member of the Major Facilitator Superfamily which confers tetracycline resistance to cells by coupling the efflux of tetracycline to the influx of protons down their chemical potential gradient. Although it is a medically important transporter, its structure has yet to be determined. One possibility for why this has proven difficult is that the transporter may be conformationally heterogeneous in the purified state. To overcome this, we developed two strategies to rapidly identify TetA(B) mutants that were transport-defective and that could still bind tetracycline. Up to 9 amino acid residues could be deleted from the loop between transmembrane α-helices 6 and 7 with only a slight decrease in affinity of tetracycline binding as measured by isothermal titration calorimetry, although the mutant was transport-defective. Scanning mutagenesis where all the residues between 2 and 389 were mutated to either valine, alanine or glycine (VAG scan) identified 15 mutants that were significantly impaired in tetracycline transport. Of these mutants, 12 showed no evidence of tetracycline binding by isothermal titration calorimetry performed on the purified transporters. In contrast, the mutants G44V and G346V bound tetracycline 4–5 fold more weakly than TetA(B), with K_ds of 28 μM and 36 μM, respectively, whereas the mutant R70G bound tetracycline 3-fold more strongly (K_d 2.1 μM). Systematic mutagenesis is thus an effective strategy for isolating transporter mutants that may be conformationally constrained and which represent attractive targets for crystallisation and structure determination.

•

A rapid method was developed for the identification of transport-defective mutants of TetA(B).

•

ITC was used to determine the affinity of tetracycline binding to the mutants.

•

Fifteen transport-defective point mutations were identified.

•

Three mutants bound tetracycline whereas the remainder did not

•

The transport-defective mutants may facilitate crystallisation of TetA(B).

The proline permease of Aspergillus nidulans: Functional replacement of the native cysteine residues and properties of a cysteine-less transporter

The major proline transporter (PrnB) of Aspergillus nidulans belongs to the Amino acid Polyamine Organocation (APC) transporter superfamily. Members of this family have not been subjected to systematic structure-function relationship studies. In this report, we examine the functional replacement of the three native Cys residues (Cys54, Cys352 and Cys530) of PrnB and the properties of an engineered Cys-less PrnB protein, as background for employing a Cys-scanning mutagenesis approach. We show that simultaneous replacement of Cys54 with Ala, Cys352 with Ala and Cys530 with Ser results in a functional Cys-less PrnB transporter. We also introduce the use of a biotin-acceptor domain tag to quantitate protein levels of the engineered PrnB mutants by Western blot analysis. Finally, by using the background of the Cys-less PrnB transporter, we evaluate the functional importance of amino acids Q219, K245 and F248 of PrnB, which our previous data had suggested to be involved in the mechanism of PrnB-mediated proline uptake. In the current study, we show that K245 and F248 but not Q219 are critical for PrnB-mediated proline uptake.

Selective metal binding to a membrane-embedded aspartate in the Escherichia coli metal transporter YiiP (FieF)

The cation diffusion facilitators (CDF) are a ubiquitous family of metal transporters that play important roles in homeostasis of a wide range of divalent metal cations. Molecular identities of substrate-binding sites and their metal selectivity in the CDF family are thus far unknown. By using isothermal titration calorimetry and stopped-flow spectrofluorometry, we directly examined metal binding to a highly conserved aspartate in the Escherichia coli CDF transporter YiiP (FieF). A D157A mutation abolished a Cd2+-binding site and impaired the corresponding Cd2+ transport. In contrast, substitution of Asp-157 with a cysteinyl coordination residue resulted in intact Cd2+ binding as well as full transport activity. A similar correlation was found for Zn2+ binding and transport, suggesting that Asp-157 is a metal coordination residue required for binding and transport of Cd2+ and Zn2+. The location of Asp-157 was mapped topologically to the hydrophobic core of transmembrane segment 5 (TM-5) where D157C was found partially accessible to thiol-specific labeling of maleimide polyethylene-oxide biotin. Binding of Zn2+ and Cd2+, but not Fe2+, Hg2+, Co2+, Ni2+, Mn2+, Ca2+, and Mg2+, protected D157C from maleimide polyethylene-oxide biotin labeling in a concentration-dependent manner. Furthermore, isothermal titration calorimetry analysis of YiiP(D157A) showed no detectable change in Fe2+ and Hg2+ calorimetric titrations, indicating that Asp-157 is not a coordination residue for Fe2+ and Hg2+ binding. Our results provided direct evidence for selective binding of Zn2+ and Cd2+ for to the highly conserved Asp-157 and defined its functional role in metal transport.

Transmembrane protein topology mapping by the substituted cysteine accessibility method (SCAM(TM)): application to lipid-specific membrane protein topogenesis

We provide an overview of lipid-dependent polytopic membrane protein topogenesis, with particular emphasis on Escherichia coli strains genetically altered in their lipid composition and strategies for experimentally determining the transmembrane organization of proteins. A variety of reagents and experimental strategies are described including the use of lipid mutants and thiol-specific chemical reagents to study lipid-dependent and host-specific membrane protein topogenesis by substituted cysteine site-directed chemical labeling. Employing strains in which lipid composition can be controlled temporally during membrane protein synthesis and assembly provides a means to observe dynamic changes in protein topology as a function of membrane lipid composition.

Structural conservation in the major facilitator superfamily as revealed by comparative modeling

The structures of membrane transporters are still mostly unsolved. Only recently, the first two high-resolution structures of transporters of the major facilitator superfamily (MFS) were published. Despite the low sequence similarity of the two proteins involved, lactose permease and glycerol-3-phosphate transporter, the reported structures are highly similar. This leads to the hypothesis that all members of the MFS share a similar structure, regardless of their low sequence identity. To test this hypothesis, we generated models of two other members of the MFS, the Tn10-encoded metal-tetracycline/H(+) antiporter (TetAB) and the rat vesicular monoamine transporter (rVMAT2). The models are based on the two MFS structures and on experimental data. The models for both proteins are in good agreement with the data available and support the notion of a shared fold for all MFS proteins.

Phylogeny of Efflux-Mediated Tetracycline Resistance Genes and Related Proteins Revisited

A SRS search in the GenBank/EMBL databases for entire genes encoding efflux-mediated resistance allocated to a recognized tetracycline determinant revealed the existence of at least 87 genes. DNA-based and protein sequence analyses of representatives from the different efflux-mediated tetracycline determinant groups were performed and allowed us to propose a revision of the current grouping on the basis of our new evolutionary trees. On the other hand, similarity, topology, and hydropathy analyses of some representatives from 12-transmembrane segments (TMS) and 14-TMS proteins lead us to perform meaningful sequence alignments of recognized or putative 12-TMS and 14-TMS proteins truncated to their first 200 amino acids (alpha-domain of the protein). For all aligned truncated proteins, including old and recently discovered tetracycline resistance determinants, significant similarities along this segment were demonstrated and three new conserved motifs identified, reinforcing the hypothesis of a common ancestry for the alpha-domain of all tetracycline-efflux pumps.

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.

Site-directed mutagenesis studies of selected motif and charged residues and of cysteines of the multifunctional tetracycline efflux protein Tet(L)

All of the transmembrane glutamates of Tet(L) are essential for tetracycline (TET) resistance, and E397 has been shown to be essential for all catalytic modes, i.e., TET-Me(2+) and Na(+) efflux and K(+) uptake. Loop residues D74 and G70 are essential for TET flux but not for Na(+) or K(+) flux. A cysteineless Tet(L) protein exhibits all activities.

Complete cysteine-scanning mutagenesis and site-directed chemical modification of the Tn10-encoded metal-tetracycline/H+ antiporter

Bacterial Tn10-encoded metal-tetracycline/H(+) antiporter was the first found drug exporter and has been studied as a paradigm of antiporter-type major facilitator superfamily transporters. Here the 400 amino acid residues of this protein were individually replaced by cysteine except for the initial methionine. As a result, we could obtain a complete map of the functionally or structurally important residues. In addition, we could determine the precise boundaries of all the transmembrane segments on the basis of the reactivity with N-ethylmaleimide (NEM). The NEM binding results indicated the presence of a transmembrane water-filled channel in the transporter. The twelve transmembrane segments can be divided into three groups; four are totally embedded in the hydrophobic interior, four face a putative water-filled channel along their full length, and the remaining four face the channel for half their length, the other halves being embedded in the hydrophobic interior. These three types of transmembrane segments are mutually arranged with a 4-fold symmetry. The competitive binding of membrane-permeable and -impermeable SH reagents in intact cells indicates that the transmembrane water-filled channel has a thin barrier against hydrophilic molecules in the middle of the transmembrane region. Inhibition and stimulation of NEM binding in the presence of tetracycline reflects the substrate-induced protection or conformational change of the Tn10-encoded metal-tetracycline/H(+) antiporter. The mutations protected from NEM binding by tetracycline were mainly located around the permeability barrier in the N-terminal half, suggesting the location of the substrate binding site.

Cysteine-scanning mutagenesis of transmembrane segments 4 and 5 of the Tn10-encoded metal-tetracycline/H+ antiporter reveals a permeability barrier in the middle of a transmembrane water-filled channel

Cysteine-scanning mutants as to putative transmembrane segments 4 and 5 and the flanking regions of Tn10-encoded metal-tetracycline/H(+) antiporter (TetA(B)) were constructed. All mutants were normally expressed. Among the 57 mutants (L99C to I155C), nine conserved arginine-, aspartate-, and glycine-replaced ones exhibited greatly reduced tetracycline resistance and almost no transport activity, and five conserved glycine- and proline-replaced mutants exhibited greatly reduced tetracycline transport activity in inverted membrane vesicles despite their high or moderate drug resistance. All other cysteine-scanning mutants retained normal drug resistance and normal tetracycline transport activity except for the L142C and I143C mutants. The transmembrane (TM) regions TM4 and TM5 were determined to comprise 20 amino acid residues, Leu-99 to Ile-118, and 17 amino acid residues, Ala-136 to Ala-152, respectively, on the basis of N-[(14)C]ethylmaleimide ([(14)C]NEM) reactivity. The NEM reactivity patterns of the TM4 and TM5 mutants were quite different from each other. TM4 could be divided into two halves, that is, a NEM nonreactive periplasmic half and a periodically reactive cytoplasmic half, indicating that TM4 is tilted toward a water-filled transmembrane channel and that only its cytoplasmic half faces the channel. On the other hand, NEM-reactive mutations were observed periodically (every two residues) along the whole length of TM5. A permeability barrier for a membrane-impermeable sulfhydryl reagent, 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid, was present in the middle of TM5 between Leu-142 and Gly-145, whereas all the NEM-reactive mutants as to TM4 were not accessible to 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid, indicating that the channel-facing side of TM4 is located inside the permeability barrier. Tetracycline protected the G141C mutant from the NEM binding, whereas the other mutants in TM4 and TM5 were not protected by tetracycline.

Cysteine-scanning mutagenesis around transmembrane segments 1 and 11 and their flanking loop regions of Tn10-encoded metal-Tetracycline/H+ antiporter

Putative transmembrane helices (TM) 1 and 11 in the metal-tetracycline/H(+) antiporter are predicted to be close to each other on the basis of disulfide cross-linking experiments of the double-cysteine mutants in the periplasmic loop regions (Kubo, Y., Konishi, S., Kawabe, T., Nada, S., and Yamaguchi, A. (2000) J. Biol. Chem. 275, 5270-5274). In this study, each amino acid from Asn-2 to Gly-44 in the putative TM1 and loop1-2 regions or that from Ser-328 to Gly-366 in TM11 and its flanking regions was individually replaced with cysteine. With respect to the TM1 region, 10 mutants, from T5C to L14C, were all not reactive with N-ethylmaleimide (NEM), and from D15C to I22C, NEM-reactive and non-reactive mutations periodically appeared every two residues. Three mutants, M23C to V25C, were all NEM-reactive, but the degree of the latter two mutants was very low. Seven mutants, from L26C to E32C, were all highly reactive with NEM. Therefore, the region of TM1 is composed of the 21 amino acid residues from Thr-5 to Val-25. It is a partially amphiphilic helix, that is, the N-terminal (cytoplasmic) half is embedded in the hydrophobic interior, and the C-terminal (periplasmic) half faces a water-filled channel. With respect to TM11, nine mutants, from S328C to G336C, and six mutants, from L361C to G366C, were all reactive with NEM. On the other hand, out of the 24 mutants, from L337C to S360C, 17 were not reactive with NEM, and the 7 NEM-reactive mutants were scattered, indicating that this region is a transmembrane segment. The 7 residues from Val-347 to Phe-353 including Pro-350 formed a central hydrophobic core, and the 7 NEM-reactive mutations were periodically distributed in its flanking regions, indicating that both ends of TM11 face a water-filled channel. Ala-354 is located at about 1/3 of the length from the periplasmic end of TM11. Disulfide cross-linking experiments on double-cysteine mutants having the combination of A354C and a cysteine-scanning mutation in the loop1-2 region indicated that loop1-2 is very flexible and close to the periplasmic end of TM11. Tetracycline prevented the cross-linking formation between the periplasmic ends of TM1 and TM11; however, it did not affect the cross-linking between loop1-2 and TM11, indicating that the substrate-induced conformational change involves a shift in the relative locations of TM1 and TM11.

Evidence for interactions between helices 5 and 8 and a role for the interdomain loop in tetracycline resistance mediated by hybrid Tet proteins

An interdomain hybrid Tet protein consisting of a class C alpha domain and a class B beta domain (Tet(C/B)) lacks detectable efflux ability and provides only minimal levels of resistance to tetracycline (Tc) (3 microg/ml) compared with intact class B (256 microg/ml) and class C (64 microg/ml). Twenty-one independently isolated mutants of the Tet(C/B) protein with increased Tc resistance were generated by random chemical mutagenesis. Nine mutants with a Glu substitution for Gly-152 in helix 5 of the class C alpha domain produced a resistance of 48 microg/ml, whereas another 9 with an Asp replacement of Gly-247 in helix 8 of the class B beta domain mediated resistance at 32 microg/ml. The third type of mutation, found in 3 mutants expressing 24 microg/ml resistance, was a S202F replacement in the putative interdomain cytoplasmic loop of Tet(C/B). The latter underscores a previously unappreciated function of the interdomain cytoplasmic loop. All three types of Tet(C/B) mutant proteins were expressed in amounts comparable with that of the original protein and demonstrated restored energy-dependent efflux of tetracycline. Site-directed mutational analysis demonstrated that a Gly-247 to Asn mutation could also facilitate Tc resistance by the Tet(C/B) hybrid, and a negatively charged side chain at position 152 was required for Tet(C/B) activity. These mutations appear to promote the necessary functional interactions between the interclass domains that do not occur in the Tet(C/B) hybrid protein and suggest a direct association between helix 5 and helix 8 in the function of Tet efflux proteins.

Proximity of periplasmic loops in the metal-Tetracycline/H(+) antiporter of Escherichia coli observed on site-directed chemical cross-linking

Our previous study on second-site suppressor mutations of the Tn10-encoded metal-tetracycline/H(+) antiporter suggested that Leu(30) and Ala(354), located in periplasmic loop 1-2 and 11-12, respectively, are conformationally linked to each other (Kawabe, T., and Yamaguchi, A. (1999) FEBS Lett. 457, 169-173). To determine the spatial proximity of these two residues, cross-linking gel-shift assays of the L30C/A354C double mutant were performed after the mutant had been oxidized with Cu(2+)/o-phenanthroline. The results indicated that Leu(30) and Ala(354) are close to each other but that Gly(62), which is located in cytoplasmic loop 2-3, and Ala(354) are distant from each other, as a negative control. Then, a single Cys residue was introduced into each of the six periplasmic loop regions (P1-P6), and eleven double mutants were constructed. Of these eleven double Cys mutants, the L30C/A354C and L30C/T235C mutants showed a mobility shift on oxidation, indicating that P1 is spatially close to P4 as well as P6. In contrast, the other nine mutants, L30C/S92C, L30C/S156C, L30C/S296C, S92C/S296C, S92C/T235C, S92C/A354C, S156C/T235C, S156C/S296C, and S156C/A354C, showed no mobility shift under oxidized conditions on intramolecular cross-linking. The S92C and S296C mutants showed dimerization on intermolecular cross-linking, indicating that P2 and P5 are located at the periphery of the helix bundle.

Cysteine-scanning mutagenesis around transmembrane segment VI of Tn10-encoded metal-tetracycline/H(+) antiporter

Each amino acid in putative transmembrane helix VI and its flanking regions, from Ser-156 to Thr-185, of a Cys-free mutant of the Tn10-encoded metal-tetracycline/H(+) antiporter (TetA(B)) was individually replaced by Cys. All of the cysteine-scanning mutants showed a normal level of tetracycline resistance except for the S156C mutant, which showed moderate resistance, indicating that there is no essential residue located in this region. All 20 mutants from S159C to W178C showed no reactivity with N-ethylmaleimide (NEM), whereas the mutants of the flanking regions from S156C to H158C and F179C to T185C were highly or moderately reactive with NEM. These results indicate that like transmembrane helices III and IX, the transmembrane helix VI comprising residues Ser-159-Trp-178 is totally embedded in the hydrophobic environment.

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.

Functional importance and local environments of the cysteines in the tetracycline resistance protein encoded by plasmid pBR322

The properties of the cysteines in the pBR322-encoded tetracycline resistance protein have been examined. Cysteines are important but not essential for tetracycline transport activity. None of the cysteines reacted with biotin maleimide, suggesting that they are shielded from the aqueous phase or reside in a negatively charged local environment.

Site-directed chemical modification of cysteine-scanning mutants as to transmembrane segment II and its flanking regions of the Tn10-encoded metal-tetracycline/H+ antiporter reveals a transmembrane water-filled channel

Cysteine-scanning mutants, E32C to G62C, of the metal-tetracycline/H+ antiporter were constructed in order to precisely determine the membrane topology around putative transmembrane segment II. None of the mutants lost the ability to confer tetracycline resistance, indicating that the cysteine mutation in each mutant did not alter the protein conformation. [14C]N-Ethylmaleimide (NEM) binding to these cysteine mutants in isolated membranes was then investigated. The peptide chain of this region passes through the membrane at least once because residues 36 and 65 are exposed on the outside and inside surfaces of the membrane, respectively (Kimura, T., Ohnuma, M., Sawai, T., and Yamaguchi, A. (1997) J. Biol. Chem. 272, 580-585). However, there was no continuous segment in which all of the introduced cysteine residues showed almost no reactivity with [14C]NEM. The proportion of the unbound positions in the second half downstream from position 45 was 55% (10/18), which was clearly higher than that in the first half (21%; 3/14), suggesting that the second half is a transmembrane segment. Positions reactive to NEM appear periodically in the second half. They are located on one side of the helical wheel, suggesting that this side of the transmembrane helix faces a water-filled channel. The cysteine mutants as to the reactive positions in the second half were severely inactivated by NEM except for the P59C mutant, whereas the A40C mutant was the only one inactivated by NEM in the first half. These results suggest that the water-filled channel along this helical region may be a substrate translocation pathway.

Cys-scanning mutagenesis: a novel approach to structure function relationships in polytopic membrane proteins

The entire lactose permease of Escherichia coli, a polytopic membrane transport protein that catalyzes beta-galactoside/H+ symport, has been subjected to Cys-scanning mutagenesis in order to determine which residues play an obligatory role in the mechanism and to create a library of mutants with a single-Cys residue at each position of the molecule for structure/function studies. Analysis of the mutants has led to the following: 1) only six amino acid side chains play an irreplaceable role in the transport mechanism; 2) positions where the reactivity of the Cys replacement is increased upon ligand binding are identified; 3) positions where the reactivity of the Cys replacement is decreased by ligand binding are identified; 4) helix packing, helix tilt, and ligand-induced conformational changes are determined by using the library of mutants in conjunction with a battery of site-directed techniques; 5) the permease is a highly flexible molecule; and 6) a working model that explains coupling between beta-galactoside and H+ translocation. structure-function relationships in polytopic membrane proteins.

Topology of the region surrounding Glu681 of human AE1 protein, the erythrocyte anion exchanger

AE1 protein transports Cl- and HCO3- across the erythrocyte membrane by an electroneutral exchange mechanism. Glu681 of human AE1 may form part of the anion translocation apparatus and the permeability barrier. We have therefore studied the structure of the sequence surrounding Glu681, using scanning cysteine mutagenesis. Residues of the Ser643 (adjacent to the glycosylation site) to Ser690 region of cysteineless mutant (AE1C-) were replaced individually with cysteine. The ability of mutants to mediate Cl-/HCO3- exchange in transfected HEK293 cells revealed that extracellular mutants, W648C, I650C, P652C, L655C, and F659C have an important role in transport. By contrast, only transmembrane mutation E681C fully blocked anion exchange activity. The topology of the region was investigated by comparing cysteine labeling with the membrane-permeant cysteine-directed reagent 3-(N-maleimidylpropionyl)biocytin, with or without prior labeling with membrane-impermeant lucifer yellow iodoacetamide (LYIA). Two regions readily label with 3-(N-maleimidylpropionyl)biocytin (Ser643-Met663 and Ile684-Ser690). We propose that poorly labeled Met664-Gln683 corresponds to transmembrane segment 8 of AE1. Regions Ser643-Met663 and Ile684-Ser690 localize, respectively, to extracellular and intracellular sites on the basis of accessibility to LYIA. On the basis of LYIA accessibility, we propose that the Arg656-Met663 region forms a "vestibule" that leads anions to the transport channel. Glu681 is located 3 amino acids from the C terminus of transmembrane segment 8, which places the membrane permeability barrier within 5 A of the intracellular surface of the membrane.