Analysis of the Topology of Vibrio cholerae NorM and Identification of Amino Acid Residues Involved in Norfloxacin Resistance

NorM, a putative efflux pump of Vibrio cholerae, is a memberof the multidrug and toxic compound extrusion family of transporters.We demonstrate that NorM confers resistance to norfloxacin,ciprofloxacin, and ethidium bromide. Inactivation of norM renderedV. cholerae hypersensitive towards these fluoroquinolones. Multiplesequence alignment of members of its family identified severalregions of high sequence conservation. The topology of NorMwas determined using ß-lactamase and chloramphenicolacetyltransferase fusions. The amino acid residues G¹⁸⁴, K¹⁸⁵,G¹⁸⁷, P¹⁸⁹, E¹⁹⁰, G¹⁹², and G¹⁹⁵ in the periplasmic loops andL³⁸¹, R³⁸², G³⁸³, Y³⁸⁴, K³⁸⁵, and D³⁸⁶ in the cytoplasmic loops,as well as all the acidic and cysteine residues of NorM, weremutated. Mutants G184V, G184W, K185I, P189S, E190K, and E190Alost the norfloxacin resistance-imparting phenotype characteristicof NorM. Mutants E124V, D155V, G187V, G187R, C196S, Y384H, Y384S,and Y384F exhibited partial resistance to norfloxacin. Mutantswith replacements of G¹⁸⁴ or G¹⁸⁷ by A, K¹⁸⁵ by R, and E¹⁹⁰by D retained the norfloxacin resistance phenotype of NorM.Analysis of the accumulation of norfloxacin in intact cellsof Escherichia coli expressing NorM or its mutants in the presenceor absence of carbonyl cyanide m-chlorophenylhydrazone supportedthe results obtained through susceptibility testing and arguedin favor of NorM-mediated efflux as the determining factor innorfloxacin susceptibility in the genetically manipulated strains.Taken together, these results suggested that E¹²⁴, D¹⁵⁵, G¹⁸⁴,K¹⁸⁵, G¹⁸⁷, P¹⁸⁹, E¹⁹⁰, C¹⁹⁶, and Y³⁸⁴ are likely involved inNorM-dependent norfloxacin efflux. Except for D¹⁵⁵, C¹⁹⁶, andY³⁸⁴, all of these residues are located in periplasmic loops.

INTRODUCTION

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Introduction

Multidrug efflux pumps extrude a variety of structurally unrelateddrugs from cells (3, 23, 30), and pumps such as AcrAB have beenassociated with the intrinsic reduced susceptibility of organismssuch as Proteus mirabilis to certain drugs (26, 27, 37). A familyof multidrug efflux proteins has been identified which utilizethe electrochemical potential of Na⁺ transport across membranesas the driving force (8, 21, 24, 25, 34) and which show sequencesimilarity. These transporters constitute the multidrug andtoxic compound extrusion (MATE) family, which contains morethan 30 proteins present in all three kingdoms (7), includingNorM proteins from Vibrio parahaemolyticus (21), Neisseria gonorrhoeae,Neisseria meningitidis (27), and Brucella melitensis (4); YdhE,a NorM homologue in Escherichia coli (21); VmrA from V. parahaemolyticus(8); VcmB, VcmD, VcmH, VcmN, VcmA, and VcrM of non-O1 Vibriocholerae (2, 24); PmpM of Pseudomonas aeruginosa (11); and BexAof Bacteroides thetaiotaomicron (20).

Recently, quinolone resistance was reported for clinical isolatesof V. cholerae from Calcutta, India (10). In our laboratory,we have demonstrated that an efflux pump-dependent mechanismimparts fluoroquinolone (FQ) resistance to clinical isolatesof V. cholerae (1), making it important to understand the mechanismof action of FQ-specific pumps.

Chromosome I of V. cholerae encodes a putative counterpart ofNorM (12) that has a high level of sequence similarity (Fig.1) to the NorM protein of V. parahaemolyticus. In this report,we demonstrate that disruption of the norM gene of V. choleraeconfers sensitivity towards fluoroquinolones, making it likelythat NorM is one of the FQ resistance-determining efflux pumpsof this organism. Otsuka et al. (29) have only recently demonstratedthat three conserved acidic residues in the predicted transmembraneregion of NorM of V. parahaemolyticus are involved in the Na⁺-dependentdrug transport process. However, no detailed information isavailable on the topology of this transporter or the role ofconserved residues in the periplasmic and cytoplasmic loopsof NorM in FQ efflux. With this in view, we have carried outa detailed mutational and topological analysis of V. choleraeNorM, with the particular aim of identifying residues crucialfor imparting FQ resistance. We focused on residues conservedin the MATE family of transporters, particularly acidic residues,and determined the effects of mutating these residues on thenorfloxacin (NOR) sensitivity of the resulting transformants.Our results demonstrate the importance of E¹²⁴, G¹⁸⁴, K¹⁸⁵,G¹⁸⁷, P¹⁸⁹, and E¹⁹⁰, which are located in periplasmic loops,of D¹⁵⁵ and Y³⁸⁴, which are located in cytoplasmic loops, andof C¹⁹⁶, which is located in a transmembrane segment (TMS),in the norfloxacin resistance-imparting property of NorM.

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FIG. 1. Multiple alignment of the amino acid sequence of NorM with those of representative homologs in Vibrio parahaemolyticus (Vp), Vibrio cholerae (Vc), Neisseria meningitidis (Nm), and Escherichia coli (Ec), using CLUSTAL W. *, identical residues; :, >60% homologous residues. The conserved regions G¹⁸⁴KFGXP¹⁸⁹ and L³⁸¹RGYKD³⁸⁶ are overlined.

MATERIALS AND METHODS

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Materials and Methods

Bacteria and growth. The clinical isolate V. cholerae AM54, (1), V. cholerae N16961,and Escherichia coli TG1 ${Delta}$ acrAB (a gift from K. Nishino, OsakaUniversity, Osaka, Japan) (28) were used in this study. Cellswere grown in Luria broth (LB) at 37°C. Cell growth wasmonitored by measuring the optical density at 600 nm.

Chemicals. Ampicillin, NOR, streptomycin, erythromycin, doxorubicin, novobiocin,and carbonyl cyanide m-chlorophenylhydrazone (CCCP) were purchasedfrom Sigma Chemical Co. Kanamycin, tetracycline, and chloramphenicolwere purchased from Roche Applied Sciences, Germany. Ciprofloxacin(CIP) was a gift from Ranbaxy Laboratories, India. Ethidiumbromide (EtBr) was purchased from Stratagene.

Molecular biological procedures. Standard procedures for cloning, analysis of DNA, PCR, and transformationwere used (32). Enzymes used to manipulate DNA were obtainedfrom Roche Applied Sciences. All constructs made by PCR weresequenced to verify their integrity. Kanamycin was used at aconcentration of 50 µg/ml, and ampicillin was used ata concentration of 100 µg/ml.

The norM gene was amplified from genomic DNA of V. choleraeAM54, using the primer pair 5'-ATGCTAGCTTGGAGAACTCTGTGCATCGTT-3'(sense) and 5'-ATGAATTCTTATGCTGCAAGGTGTAACTGTACG-3' (antisense),containing asymmetric NheI and EcoRI sites (in bold), and clonedbetween the NheI and EcoRI sites of the vector pET28a (Novagen)to generate pVC101. The NcoI and EcoRI fragment excised frompVC101 was then cloned between the NcoI and EcoRI sites of thevector pBADHisC (Novagen) to generate pVC102.

Mutants of NorM were generated by overlap extension PCR. Theinitial rounds of PCR were carried out using the primer pairsa-b and c-d (see Table S1 in the supplemental material), withpVC102 as the template. The products of each PCR were purifiedand used as templates for the second round of PCR, using primersa and d. The final products were cloned between the NcoI andEcoRI sites of pVC102 to generate norM mutants in pBADHisC.

Western analysis of expressed protein. E. coli cells transformed with pVC102 or its mutants were grownto mid-log phase, and crude cell extracts were separated by10% sodium dodecyl sulfate-polyacrylamide gel electrophoresis,followed by electrophoretic transfer to a polyvinylidene difluoridemembrane and Western blotting with an anti-His antibody.

Construction and analysis of ß-lactamase fusions with truncated NorM derivatives. pJBS633 (carrying the mature TEM ß-lactamase-encodingblaM gene) (5) was used for constructing in-frame fusions ofTEM ß-lactamase with the C-terminal ends of truncatedNorM derivatives. These derivatives were generated by PCR usingthe forward primer 5'-TTGGATCCAATTGGAGAACTCTGTGCATCGT-3', containinga BamHI site (in bold), and reverse primers carrying portionsof the norM gene (see Table S2 in the supplemental material).The PCR products were cloned between the BamHI and PvuII sitesof pJBS633. E. coli JM105 was transformed with the ligationmixture, and transformants growing on LB agar plates containing50 µg/ml kanamycin were chosen for further analysis. Transformantscontaining in-frame NorM-ß-lactamase fusions weredetected by the ability to grow when patched with toothpicksonto agar containing 200 µg/ml ampicillin (6). MICs ofampicillin for individual cells of E. coli JM105 containingNorM-Xaa-TEM ß-lactamase fusions (where Xaa representsthe amino acid residue of NorM at the fusion junction) weredetermined by spotting 4-µl samples of 1:10⁵ diluted overnightcultures (approximately 40 cells) on LB agar plates containinga range of doubling concentrations of ampicillin.

Construction and analysis of targeted CAT fusions. The cat gene was PCR amplified from pACYC184, using the forwardprimer 5'-AGGGTACCAAAAAAATCACTGGATATA-3' (KpnI site is shownin bold) and the reverse primer 5'-ATAAAGCTTCGCCCCGCCCTGCCACTC-3'(HindIII site is shown in bold), and inserted between the KpnIand HindIII sites of pBADMycHisA, generating pBAD-CAT. Chloramphenicolacetyltransferase (CAT) constructions were created by targetedPCR fusion with derivatives of NorM, inserting KpnI sites afterthe amino acids of interest by using the forward primer 5'-ATACTGCAGATTTGGAGAACTCTGAG-3',containing a PstI site (in bold), and reverse primers (see TableS2 in the supplemental material) carrying portions of the norMgene. The constructs were transformed into E. coli TG1 containing100 µg/ml ampicillin and tested for resistance to chloramphenicolas follows. Overnight cultures in LB medium were diluted 10-foldwith fresh medium and allowed to grow for 3 h. Induction wasthen carried out by the addition of 0.05% L-arabinose for 1h, and 4-µl samples of a 10⁴ dilution of the cultureswere spotted onto plates containing different concentrationsof chloramphenicol in combination with 0.2% L-arabinose. Growthwas observed after 16 h.

Drug susceptibility testing. The MICs of drugs were determined in Mueller-Hinton agar (Hi-Media,India) containing different drugs at various concentrations.E. coli TG1 ${Delta}$ acrAB cells transformed with the wild-type or mutantnorM-harboring constructs were grown at 37°C in LB supplementedwith ampicillin (100 µg/ml) to an optical density at 600nm of 1. A series of 10-fold dilutions were spotted on platescontaining ampicillin (40 µg/ml) and different concentrationsof test drugs (38), and growth was observed after 16 h.

Assay of norfloxacin accumulation in cells. The assay of norfloxacin accumulation in cells was carried outas described earlier (1). Briefly, E. coli TG1 ${Delta}$ acrAB cells weregrown in LB supplemented with 100 µg/ml ampicillin toan A₆₀₀ of 1. The cells were harvested, washed with 50 mM sodiumphosphate buffer (pH 7.2), and suspended in the same bufferto an A₆₀₀ of 20. Cells were energized with 0.2% glucose for20 min at 30°C. Norfloxacin was added to a concentrationof 10 µg/ml. Where necessary, after 10 min, CCCP was addedto the assay mixture at 100 µM. Samples (100 µleach) were taken at intervals, centrifuged at 6,000 rpm on atable-top centrifuge for 30 s, and washed with the same buffer.The pellet was suspended in 1 ml of 100 mM glycine-HCl buffer(pH 3.0). The suspension was shaken vigorously for 1 h at 37°Cand then centrifuged at 13,000 rpm in a microcentrifuge for5 min at room temperature. The fluorescence of the supernatantwas measured with excitation at 277 nm and emission at 448 nm(13, 22) in a Hitachi spectrofluorimeter (model S4500). Foreach experiment, an aliquot of cells was filtered separately,before the addition of norfloxacin, using Whatman GF/C filters.The filters were dried and weighed to calculate the dry weightof the cells.

Assay of ethidium bromide accumulation in cells. Cells were grown as described above and suspended to an A₆₀₀of 0.5. The cell suspension (2.5 ml) was mixed with 5 µMethidium bromide and placed in a cuvette. Fluorescence was measuredat excitation and emission wavelengths of 500 and 580 nm, respectively(19).

Inactivation of V. cholerae norM. The norM deletion construct was generated by PCR, using genomicDNA of V. cholerae N16961 as the template. The primer pair sense1 (5'-ATGAATTCGAGCTCAACATGACAGTTGATGAG-3') and antisense 1 (5'-ATGGTACCGATATTGAGCAATAACCCAA-3'),containing asymmetric EcoRI and KpnI sites (in bold), was usedto amplify an 842-bp fragment (fragment 1) encoding N-terminalamino acids 1 to 175 along with a 300-bp sequence upstream ofnorM. Similarly, the primer pair sense 2 (5'-ATGGTACCCTTGGCTTGCCCACCGGTTA-3')and antisense 2 (5'-ATGGATCCCCAGTAAGCAGCAAAAGTGC-3'), containingasymmetric KpnI and BamHI sites (in bold), was used to amplifya 433-bp fragment (fragment 2) encoding amino acids 401 to 461along with a 250-bp region downstream of norM. PCR-amplifiedfragment 1 was cloned between the EcoRI and KpnI sites of pUC19to generate pAS101. Fragment 2 was then digested with KpnI andBamHI and cloned between the same sites of pAS101 to generatepAS102. The deleted norM gene from pAS102 was digested withBamHI and SacI and cloned into the suicide vector pWM91 (17;kindly provided by J. J. Mekalanos) between the same sites togenerate pAS103. pAS103 was introduced into recipient V. choleraeN16961 cells by electroporation (15). Colonies were selectedon LB plates supplemented with streptomycin and ampicillin.The streptomycin- and ampicillin-resistant colonies were patchedon LB agar overnight to allow homologous recombination betweenflanking regions of pAS103. Cells were then selected for theability to form colonies on 5% sucrose to select for excisionof the integrated plasmid (9). Genomic DNAs isolated from thewild type and the knockout construct of V. cholerae were usedfor PCR amplification, using primers sense 1 and antisense 2,to identify the clones harboring the deletion in norM. PCR productswere checked by sequencing.

RESULTS

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Results

Drug susceptibility testing in V. cholerae. In order to evaluate the role of norM in V. cholerae, the norMgene was inactivated. PCR amplification using primers for theflanking regions of the norM gene gave products of 1,842 and1,179 bp for the wild type and the mutant, respectively (datanot shown), which were sequenced to confirm the inactivationof norM. The knockout strain (designated NorM-KO) was >10-foldmore sensitive to FQs (Table 1) than the wild type. In addition,the MIC of ethidium bromide decreased from 512 µg/ml forthe wild type to 128 µg/ml for NorM-KO.

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TABLE 1. Susceptibility to and accumulation of fluoroquinolones in V. cholerae and E. coli strains

Drug susceptibility testing in E. coli. In order to evaluate the contribution of NorM to drug resistance,norM was expressed in E. coli TG1 ${Delta}$ acrAB, which is hypersensitiveto many drugs due to a deficiency in the major multidrug effluxpump AcrAB (28). The drug susceptibilities of E. coli TG1 ${Delta}$ acrABcells harboring the vector alone (control) or pVC102 (the vectorcarrying the norM gene) are shown in Table 2. E. coli TG1 ${Delta}$ acrAB/pVC102was resistant to norfloxacin (60-fold), ciprofloxacin (30-fold),and ethidium bromide (16-fold) but not to sparfloxacin, a hydrophobicFQ. We also observed reproducibly low levels (two- to fourfold)of resistance to streptomycin, erythromycin, kanamycin, anddoxorubicin (Table 2). Considering that the NorM protein ofV. cholerae conferred high resistance to FQs, we designatedNorM as an FQ efflux pump. These studies were repeated in thepresence of CCCP (25 µM), an energy uncoupler that hasbeen shown to inhibit the action of other efflux pumps (26).CCCP reduced the MICs of norfloxacin, ciprofloxacin, and ethidiumbromide for E. coli TG1 ${Delta}$ acrAB/pVC102, suggesting that NorM isa proton motive force-dependent pump.

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TABLE 2. Susceptibility of norM-harboring E. coli TG1 ${Delta}$ acrAB to different compounds

Determination of the topology of NorM by analyses of NorM-ß-lactamase and NorM-CAT fusions. A model of the secondary structure of NorM was developed byusing the HMMTOP algorithm (35, 36) (available freely at http://www.enzim.hu/hmmtop)(Fig. 2). In order to validate the predicted topology, targetedfusions of NorM were generated with the N-terminal end of theTEM ß-lactamase or CAT reporter. E. coli JM105 hadan MIC of 4 µg/ml for ampicillin. The NorM-Xaa-TEM ß-lactamasetransformants, in which Xaa (the NorM amino acid at the fusionjunction) was G⁴¹, D⁴⁷, S⁵², R¹¹⁸, E¹²⁴, K¹²⁹, G¹⁸⁴, P¹⁸⁹, G¹⁹²,G¹⁹⁵, P²⁶⁸, V²⁷⁹, R³⁴⁰, E³⁴⁹, Q³⁵¹, T⁴¹², or K⁴²³, had MICsof 200 µg/ml or more for ampicillin, consistent with theview that these fusion sites were each in the periplasm, sinceß-lactamase fusion proteins can provide E. coli withampicillin resistance only if the ß-lactamase moietyis translocated to the periplasm (5). The cytoplasmic locationof amino acids was studied by analyzing the NorM-Xaa-CAT fusiontransformants, in which Xaa (the NorM amino acid at the fusionjunction with CAT) was K¹⁷, Q⁷⁸, E⁹¹, G⁹⁵, Q¹⁴⁸, D¹⁵⁵, A¹⁶³,S²¹⁸, E²²⁸, P²⁴⁷, I³⁰⁰, N³¹⁹, Q³⁷⁴, V³⁷⁵, Y³⁸⁴, R³⁹³, or Q⁴⁴².E. coli TG1 harboring these fusions showed chloramphenicol resistance,consistent with the view that these fusion sites were each inthe cytoplasm, since CAT fusion proteins can provide E. coliwith chloramphenicol resistance only if CAT is present in thecytosol. Negative validation of the predicted topology was carriedout by analyzing ß-lactamase constructs generatedby fusion to transmembrane (C¹⁹⁶ and C¹⁹⁷) or cytoplasmic (D¹⁵⁵and E²²⁸) amino acids as well as by analyzing CAT constructsfused to transmembrane (C¹⁹⁶ and C¹⁹⁷) or periplasmic (D⁴⁷ andE¹²⁴) amino acids. Fusions to D¹⁵⁵ or E²²⁸ were ampicillin sensitive.Fusions to D⁴⁷ or E¹²⁴ were chloramphenicol sensitive. Fusionsto C¹⁹⁶ or C¹⁹⁷ were both ampicillin and chloramphenicol sensitive.We concluded that the experimentally determined topology corroboratedthe predicted topology depicted in Fig. 2.

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FIG. 2. Schematic representation of the predicted secondary structure of NorM. The 12 transmembrane helices are boxed. The topology was designed based on the algorithm HMMTOP (31, 32) and was confirmed by analysis of ß-lactamase and chloramphenicol acetyltransferase fusions with the norM gene.

Effects of specific mutations in amino acids located in periplasmic loops on the function of NorM. The motif G¹⁸⁴KFGAP¹⁸⁹ is located in the periplasmic loop betweenTMS 5 and 6 (Fig. 2) and is conserved among several membersof the MATE family (Fig. 1). Deletion of this conserved regionrendered the mutant NorM ( ${Delta}$ G¹⁸⁴-P¹⁸⁹) protein highly susceptibleto norfloxacin (Table 3). In order to further identify importantresidues in this region, we replaced G¹⁸⁴ with valine or tryptophan.These replacements caused a complete loss of activity of NorM,as assessed by determining the MIC of norfloxacin as well asthat of ciprofloxacin for E. coli TG1 ${Delta}$ acrAB cells harboring therespective plasmids. However, replacement of G¹⁸⁴ with alanineled to the retention of a significant amount of wild-type activity["activity," as referred to in the following paragraphs, meansthe ability of the norM-harboring construct(s) to impart norfloxacinresistance, as assessed by the MIC]. Valine differs from glycinein being more space-filling and exhibiting a lower propensityfor forming a ß-turn structure. Consistent with this,the substitution G184A did not cause a large change in activity.By the same token, replacement of G¹⁸⁷ with arginine or valinesignificantly reduced the wild-type activity, whereas replacementwith alanine did not alter the activity. The positively chargedlysine at position 185 was essential for NorM activity. Replacementof K¹⁸⁵ with isoleucine, but not with arginine, resulted ina complete loss of NorM activity (Table 3). A positive chargetherefore appeared necessary at position 185. The P189S mutantcompletely abolished NorM activity. Replacement of G¹⁹² andG¹⁹⁵, two other conserved residues in the predicted periplasmicloop between TMS 5 and 6, did not alter NorM activity (Table3).

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TABLE 3. Norfloxacin resistance of E. coli TG1 ${Delta}$ acrAB expressing mutant NorM proteins^a

Effects of replacement of conserved residues in cytoplasmic loops. The region L³⁸¹RGYKD³⁸⁶ in the cytoplasmic loop between TMS10 and TMS 11 (Fig. 2) is conserved (Fig. 1). Replacement ofL³⁸¹ with proline, R³⁸² with glycine, G³⁸³ with valine, K³⁸⁵with isoleucine, and D³⁸⁶ with valine did not alter the activityof NorM (Table 3). However, replacement of Y³⁸⁴ with phenylalanine,histidine, or serine showed reductions in NorM activity correspondingto MICs of 0.125, 0.063, and 0.25 µg/ml, respectively(Table 3), indicating that Y³⁸⁴ plays an important role in NorMactivity. Partial retention of activity in the Y384 $->$ S and Y384 $->$ Fmutants suggested that the -OH group (common to tyrosine andserine) as well as the phenyl ring (common to tyrosine and phenylalanine)likely has a bearing on NorM activity. Replacement of Y³⁸⁴ withhistidine altered NorM activity, suggesting that a positivelycharged functional group is not favored at this position. Mutagenesisof M³⁸⁷, which is not a conserved residue, caused no significantchange in NorM activity.

Effects of replacement of cysteine residues on NorM activity. There are three cysteine residues in the deduced amino acidsequence of NorM (Fig. 1), all of which are in transmembranesegments (Fig. 2). In order to determine whether one of thesecysteines is in a region of functional significance, we analyzedvariants in which NorM cysteines were replaced individuallyby serine. In one (C196S) of the three instances, the C $->$ S derivativedisplayed an eightfold higher susceptibility than the wild-typeprotein, while in the remaining two cases (C330S and C369S),NorM activity remained unaltered (Table 3). Multiple alignmentsidentified the cysteine at position 196 of V. cholerae (Fig.1) as a conserved residue in 17 NorM homologs (data not shown).

Effects of replacement of acidic residues on NorM activity. NorM contains 13 glutamic acid (at positions 2, 11, 91, 123,124, 190, 228, 237, 255, 308, 341, 349, and 417) and 9 asparticacid (at positions 36, 47, 121, 155, 310, 371, 386, 452, and453) residues. All of the acidic residues were replaced individuallywith valine (Table 3). The activity of each of the mutant proteinswas analyzed by drug susceptibility testing. All of the mutantproteins in which acidic residues were mutagenized were activeenough to sustain a level of resistance practically identicalto that of the wild type, except in the cases of E¹²⁴, D¹⁵⁵,and E¹⁹⁰ mutants. The E124V and D155V substitutions had partialbut significant effects on drug susceptibility. E¹⁹⁰, the onlyacidic residue in the periplasmic loop between TMS 5 and 6,led to a complete loss of activity when replaced with eitherlysine, alanine, or valine. The substitution E190D did not influencethe norfloxacin resistance-imparting phenotype of NorM, thushighlighting the importance of an acidic residue at position190. In order to demonstrate the expression of mutated proteinsin E. coli, Western analysis was carried out with crude cellextracts and an anti-His antibody. The results obtained witha representative set of mutants are presented in Fig. 3. Equallevels of expression were observed for all mutants comparedto the expression level of wild-type NorM, indicating that decreasedexpression or instability of the mutant protein was not responsiblefor the impaired efflux pump activity in any case.

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FIG. 3. Western blot analysis of recombinant NorM and its mutants. Wild-type NorM and site-directed mutants (as indicated in the figure) were expressed in E. coli TG1 ${Delta}$ acrAB as N-terminally His-tagged proteins. Cell lysates were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, followed by Western blotting using an anti-His monoclonal antibody.

Accumulation of norfloxacin in intact cells of V. cholerae and E. coli. The accumulation of norfloxacin in NorM-KO was higher than thatin the wild-type strain (Table 1). Disruption of efflux pumpactivity with CCCP led to the accumulation of norfloxacin inthe parent strain to the level observed in NorM-KO, suggestinga role for NorM in FQ efflux. These data were in harmony withthe increased sensitivity of NorM-KO to FQs compared to thatof the wild-type strain (Table 1). In addition, the accumulationof EtBr was higher (1.30 ± 0.0015 µg mg^–1dry weight of cells) in NorM-KO than in the wild type (0.7 ±0.0012 µg mg^–1 dry weight of cells). After the additionof CCCP, both strains showed similar levels of accumulationof EtBr (wild type, 1.41 ± 0.0015 µg mg^–1dry weight of cells; NorM-KO, 1.37 ± 0.0031 µgmg^–1 dry weight of cells). Norfloxacin accumulation wasalso determined for E. coli TG1 ${Delta}$ acrAB harboring the vector aloneor a vector carrying wild-type norM or its mutants. The resultsobtained with a representative set of mutants are presentedin Table 1. These mutants are as follows: (i) NorM G192V (asresistant as the wild type), (ii) NorM G187R (partially resistant),and (iii) NorM E190K (as sensitive as TG1 ${Delta}$ acrAB alone). E. coliTG1 ${Delta}$ acrAB cells harboring wild-type norM or the G192V mutantshowed lower levels of norfloxacin accumulation than cells harboringthe vector alone (Table 1). Accumulation was comparable in cellsharboring the E190K mutant or the vector alone. The accumulationof norfloxacin in cells harboring the G187R mutant was intermediatebetween the levels observed in cells harboring the vector aloneand those harboring the G192V mutant. We concluded that theresults obtained by susceptibility testing correlated directlywith the levels of norfloxacin accumulation in the cells. Theaddition of CCCP to the assay mixture increased the accumulationto the level in control cells (Table 1). These data argue infavor of a role of proton motive force-dependent, NorM-mediatednorfloxacin efflux in norfloxacin susceptibility in the aboveinstances.

DISCUSSION

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Discussion

Recently, it was reported that NorM, a putative multidrug effluxprotein of the MATE family from V. parahaemolyticus, confersresistance to hydrophilic FQs, such as norfloxacin and ciprofloxacin,but not to hydrophobic quinolones, such as sparfloxacin andnalidixic acid (21). Consistent with this, we report here thatNorM of V. cholerae expressed in E. coli conferred high-levelresistance (>10-fold) to norfloxacin, ciprofloxacin, andethidium bromide and low-level resistance (2- to 4-fold) tokanamycin, streptomycin, erythromycin, and doxorubicin. No resistancewas observed towards sparfloxacin, tetracycline, chloramphenicol,novobiocin, or CCCP (Table 2). We therefore concluded that NorMof V. cholerae has functional similarity to NorM of V. parahaemolyticus(21) and NorMI of Brucella melitensis (4). In the presence ofCCCP (25 µM), E. coli TG1 ${Delta}$ acrAB harboring the wild-typenorM gene became as sensitive to norfloxacin, ciprofloxacin,and ethidium bromide as the strain harboring the empty vector.In addition, E. coli TG1 ${Delta}$ acrAB harboring the wild-type norM geneshowed less norfloxacin accumulation than the strain harboringthe empty vector. The increase in accumulation upon additionof CCCP suggested that NorM is a drug/ion antiporter. The specificrole of NorM in FQ resistance was further strengthened by ourobservations that inactivation of V. cholerae norM renderedthe strain hypersusceptible to FQs. Efflux of norfloxacin andethidium bromide was also impaired in the knockout strain. Theincreased expression of norM in some previously described clinicalisolates (1; our unpublished observations) points in the directionof NorM having a role in FQ resistance in clinical isolatesas well. Whether the inactivation of norM in these strains lowersthe MICs for hydrophilic FQs, however, remains to be tested.

Phylogenetic analysis of prokaryotic MATE family transportersreveals two subfamilies, with one belonging to the NorM branchand the other belonging to the DinF branch (7). Phylogeny-basedclustering is likely to determine the substrate specificityof the MATE family transporters (7). Consistent with this view,Begum et al. have shown that in V. cholerae, members of theDinF family are unlikely to be major contributors to FQ resistance(2). In the complement of MATE family transporters of V. cholerae,NorM would therefore be predicted to have a major role in conferringFQ resistance. The present study has validated this prediction.It is also consistent with reports from several groups (20,21, 31) that members of the NorM family specifically conferresistance to hydrophilic but not hydrophobic FQs.

The prediction of NorM topology using the online algorithm HMMTOP2.0 (35, 36) was validated by fusing C-terminal truncationsof NorM to either the CAT or TEM ß-lactamase reporter.The GXFGXP motif, which is conserved in the NorM family butnot in the DinF family, was localized to a periplasmic loopbetween TMS 5 and 6. Deletion of G¹⁸⁴KFGAP¹⁸⁹ completely abolishedNorM activity, as assessed by drug susceptibility testing, pointingtowards a crucial role of this motif in defining the substratespecificity of NorM. Amino acids present in large periplasmicloops have also been implicated in substrate recognition ofMexD, a component of the tripartite MexCD-OprJ pump of P. aeruginosa(14), and in the trimerization of MexB and/or its interactionwith MexA (18). Substitution at G¹⁸⁴ led to a loss of activityin each case, except when G¹⁸⁴ was replaced by alanine, indicatingthat the structural requirement at this position is very strict.G¹⁸⁴ probably makes a turn which does not leave enough roomto tolerate bulky side chains at this position. Similarly, theloss of activity in G¹⁸⁷ mutants also likely correlates withthe extent of destabilization or distortion of the peptide backbone,with the substitution G187 $->$ A having no effect. The contributionof K¹⁸⁵ may be due to an intraloop charge-neutralization saltbridge between K¹⁸⁵ and E¹⁹⁰, because replacement of eitherof these residues with either a neutral or oppositely chargedresidue was associated with a loss of activity. Mutation ofthe glycines at positions 192 and 195 individually to valinedid not confer any change in the norfloxacin resistance-impartingcharacter of NorM, indicating that there is likely no turn inthe NorM peptide backbone in this region. The cytoplasmic loopbetween TMS 10 and 11 harbors the conserved region L³⁸¹RGYKD³⁸⁶.All of the amino acid residues in this region were targetedfor mutagenesis. Y³⁸⁴ alone was found to be required for NorMactivity. Among the three cysteine residues of NorM, only thereplacement of C¹⁹⁶ (predicted to be located within the transmembranehelix close to the periplasmic loop connecting TMS 5 and 6)with serine had a bearing on activity.

NorM conferred resistance to norfloxacin, ciprofloxacin, andthe cationic substrate ethidium bromide. At physiological pH,it is expected that the piperazine rings of both ciprofloxacinand norfloxacin are positively charged (31). This led us tofocus on the role of acidic residues in NorM activity. E¹²⁴,D¹⁵⁵, and E¹⁹⁰ were critical for the resistance phenotype ofNorM. The predicted membrane topology (Fig. 2) suggested thatE¹²⁴ and E¹⁹⁰ are located in the periplasmic loops connectingTMS 3 and 4 and TMS 5 and 6, respectively, whereas D¹⁵⁵ is locatedin the cytoplasmic loop connecting TMS 4 and 5. The importanceof negatively charged residues for the recognition of cationicdrugs was recently demonstrated in a structural study of Staphylococcusaureus qacR (33). Mazurkiewicz et al. (16) also demonstratedthat acidic residues in both the cytoplasmic and periplasmicloops are important for the transport of lipophilic cationiccompounds such as ethidium bromide. Taken together, these resultssuggested that removing the positive charge on the FQ side chaincould reduce its export by pumps such as NorM, thereby improvingits efficacy. Our results provide information on the amino acidresidues that are likely relevant for the binding of these substrates.Further detailed studies should help in defining the completeset of amino acid residues likely to be involved in the transportprocess.

ACKNOWLEDGMENTS

This work was supported in part by grants from the Departmentof Science and Technology and the Council of Scientific andIndustrial Research to M.K.

FOOTNOTES

* Corresponding author. Mailing address: Department of Chemistry, Bose Institute, 93/1 Acharya Prafulla Chandra Road, Kolkata 700009, India. Phone: 91 3323506619. Fax: 91 3323506790. E-mail: manikuntala{at}vsnl.net.

Published ahead of print on 5 September 2006.

Supplemental material for this article may be found at http://aac.asm.org/

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