Induction of Manganese-Containing Superoxide Dismutase Is Required for Acid Tolerance in Vibrio vulnificus

The manganese-containing superoxide dismutase (MnSOD) of Vibriovulnificus, normally detected after the onset of the stationaryphase, is expressed during the lag that immediately followsthe transfer of cells grown exponentially to a fresh mediumacidified to pH 5.0, whereas Fe-containing SOD is constitutivelyexpressed. The signal triggering the growth lag and MnSOD inductiontherein is not low pH but intracellular superoxide accumulatedunder these conditions, since addition of a superoxide scavengernot only shortened the lag but also abrogated the MnSOD induction.If the lysine decarboxylase reaction proceeds in the presenceof sufficient lysine, the broth is rapidly neutralized to abolishthe generation of oxidative stress. Accordingly, the acid toleranceresponse was examined without the addition of lysine. SoxR regulatesMnSOD induction. Lack of MnSOD caused by mutations in soxR orsodA resulted in low tolerance to low pH. The fur mutant derepressingMnSOD showed better tolerance than the wild type. Thus, an increasein total cytosolic SOD activity through MnSOD induction is essentialfor the cell to withstand the acid challenge. The contributionof cuprozinc-containing SOD to acid tolerance is not significantcompared with those of cytosolic SODs.

INTRODUCTION

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Introduction

Vibrio vulnificus, a halophilic estuarine bacterium, is a virulentpathogen which can cause food-borne gastroenteritis or infectan open wound that is exposed to seawater harboring the organism.Among individuals with chronic liver disease, it can infectthe bloodstream, causing a severe illness characterized by feverand chills, decrease in blood pressure (septic shock), and skinbreakdown. A rapidly progressing, fulminating septicemia canresult in death (for a review, see reference 3). V. vulnificusmay travel through the acidic environment of the stomach tocolonize the intestinal lumen. The bacterium, however, is sensitiveto the acidic gastric fluid. Thus, the ability to tolerate gastricacidity is necessary for the pathogen to cause food-borne infections.

Upon exposure of enteric bacteria to low pH, several physiologicalresponses ensue to cope with the acid stress. These responsescontribute to the virulence of pathogens, including Escherichiacoli and Vibrio cholerae (26, 30, 45). Multiple effects of acidstress on gene expression have been documented in E. coli (fora review, see reference 4). One of the most striking responsesto low external pH is the generation of amines ( ${gamma}$ -aminobutyrate,cadaverine, agmatine, and putrescine) and CO₂ by amino aciddecarboxylases in the presence of their respective substrates(glutamate, lysine, arginine, and ornithine, respectively).Concomitant with the production and excretion of amines is someneutralization of the external pH, thus protecting cells fromthe acid stress (34, 48). The inhibition of porins by excretedcadaverine, and thereby porin-mediated outer membrane permeabilityas well, has been proposed as another mechanism that providesE. coli with the ability to survive in an acidic environment(41, 42). The induction of cadBA coding for a lysine-cadaverineantiporter (CadB) and a lysine decarboxylase (CadA) has beenwell illustrated as an acid pH-dependent response in E. coliand V. cholerae (30, 48). CadC, a membrane-bound protein whosegene lies upstream from cadBA, has been identified as a positiveregulator of cadBA expression (31, 34). A contribution of CadBAto acid tolerance has also been demonstrated in V. vulnificus(40).

The system responsible for pH homeostasis of Salmonella entericaserovar Typhimurium during exposure to low pH is composed ofa complex cascade of acid shock proteins (ASPs) that are thoughtto contribute to survival in an acidic environment (10). Severalinducible amino acid decarboxylases are also included amongthe ASPs. Lysine decarboxylase, which contributes to pH homeostasis,is required for acid survival of S. enterica serovar Typhimurium(38). The acid tolerance response of S. enterica serovar Typhimuriumis under the positive control of two global regulators, theiron-regulatory protein Fur (ferric uptake regulation) and analternative sigma factor, ${sigma}$ ^s (11, 24).

Interestingly, manganese-containing superoxide dismutase (MnSOD)is found among ASPs when bacterial cells, such as those of Staphylococcusaureus, Streptococcus oralis, and Streptococcus mutans, areexposed to low pH (7, 50, 51). An S. aureus sodA mutant lackingMnSOD was less able to survive acid stress (7). The precisemechanisms by which MnSOD is induced and involved in acid toleranceare not known. MnSOD and Fe-containing superoxide dismutase(FeSOD), key enzymes in the defense against the oxidative damageby superoxide (6), often have been found in the cytoplasm ofprokaryotic cells (49), whereas copper- and zinc-containingsuperoxide dismutase (CuZnSOD) has been found in the periplasmof several gram-negative bacteria, such as E. coli (14).

FeSOD of V. vulnificus is constitutively expressed, but itsMnSOD is detected when iron is limited in culture medium, suggestiveof Fur-mediated expression of MnSOD (19). We found that MnSODis also induced under acidic conditions. When growing cellsof V. vulnificus were transferred to medium acidified to pH5.0, cell growth temporarily ceased (ca. 2- to 3-h lag). Thecellular superoxide level was increased during the lag, andMnSOD was induced by the control of SoxR. In an effort to understandthe contributions of SODs to acid tolerance of this pathogen,sod expression and the survival of sod mutants were examinedunder acidic conditions. The increase in cytosolic SOD activitiesthrough MnSOD induction appears to be important for cell survivalat acidic pH.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains, plasmids, and growth conditions. The strains and plasmids used in this study are listed in Table1. V. vulnificus was grown at 30^°C in Luria-Bertani (LB)medium (43) supplemented with 2% (wt/vol) NaCl (LBS), whosepH had been adjusted to pH 7.5. E. coli was grown at 37^°Cin LB. Cells harboring antibiotic resistance genes were selectedusing appropriate antibiotics; chloramphenicol (Cm), kanamycin(Km), tetracycline (Tc), and rifampin (Rif) were used at 2,150, 2, and 50 µg/ml, respectively, for V. vulnificus,whereas ampicillin, streptomycin (Sm), spectinomycin (Sp), Cm,Km, and Tc (final concentrations of 50, 25, 20, 25, 25, and10 µg/ml, respectively) were used for E. coli. Cell growthwas monitored by measuring the culture absorbance at 600 nm(A₆₀₀). If the A₆₀₀ of the V. vulnificus culture was largerthan 0.7, it was diluted prior to measurement.

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TABLE 1. Bacterial strains and plasmids used in this study

For growth transition, cells were first grown in LBS (pH 7.5)with sufficient aeration (35-ml culture in 300-ml flask at 250-rpmshake) up to logarithmic growth phase (A₆₀₀, $~$ 2.0). An aliquot(0.5 ml) was then harvested and inoculated into LBS (pH 5.0)after a brief wash with the medium. The initial A₆₀₀ value wasgenerally close to 0.1. Cells were incubated with shaking asdescribed above, and aliquots were taken intermittently forthe measurement of cell growth, pH, SOD activity, and MnSODexpression, using sodA::cat fusion (see below). The same transferto LBS (pH 7.5) was included as a control. The experiments wererepeated three times, yielding similar results; a typical experimentis shown. In this work a pH of 5.0 was chosen deliberately tomonitor the adaptive responses of cells to an acidic environmentwherein they could still grow. At a pH less than 4.0, cell deathoccurs.

Conjugation. pRK415- and pDM4-derived plasmids were transformed into E. coliS17-1 and S17-1 ${lambda}$ pir, respectively, and were subsequently mobilizedinto V. vulnificus by conjugation as described previously withminor modification (37). E. coli and V. vulnificus were grownexponentially until the A₆₀₀ values reached 1.0 and 2.0, respectively.The donor (100 µl) and recipient (200 µl) were mixed,washed two times with LB, spotted on LB agar, and incubatedat 37^°C for 8 h. The mixture was suspended in an appropriatevolume of LBS following a brief wash with the medium and platedon thiosulfate-citrate-bile salts-sucrose agar (5) to selectV. vulnificus or on LBS containing Rif to select V. vulnificusAR.

Detection and quantification of SOD activity. Preparation of cell extracts, electrophoresis of a native polyacrylamide(12%) gel, and staining of SOD activity were performed as describedpreviously (2). Cytosolic SOD activities in cell extracts weredetermined as described previously (29). KCN (2 mM) was includedin the reaction mixture to inhibit CuZnSOD. The relative SODlevels between samples were also quantified by scanning theactivity-stained gel using the Tina 2.0 program of a BIO-Imaginganalyzer (FUJI, Japan). Proteins were determined by a modifiedLowry method using bovine serum albumin as a standard (28).

Construction of sodA::cat fusion and chloramphenicol acetyltransferase (CAT) assay. A 1.6-kb XbaI/BamHI DNA fragment containing cat from the pCAT-basicvector (Promega, Madison, WI) was cloned into pRK415 to generatepRKCAT. A 452-bp DNA fragment extending from –407 to 45relative to the MnSOD initiation codon was PCR amplified usingtwo primers: the forward primer, 5'-CTAAGCTGCAGATGAGC-3' (mutatedsequence underlined, unless otherwise noted), containing thePstI site (in bold), and the reverse primer, 5'-GTATGGCTCTAGAGCATCG-3',containing the XbaI site (in bold). The PCR product was examinedthrough DNA sequence analyses, digested with PstI and XbaI,and cloned into PstI/XbaI sites of pRKCAT to generate a sodA::catfusion of pSODAC. The recombinant plasmid was mobilized throughconjugation into V. vulnificus as described above.

The CAT assay was performed as described previously (44). Thereaction mixture consisted of 0.1 mM acetyl-coenzyme A, 1 mM5,5'-dithiobis-2-nitrobenzoic acid, 0.25 mM Cm in 1 ml 100 mMTris-HCl (pH 7.8). The reaction was initiated by adding 20 µlcell extracts, followed by incubation at 30^°C for 3 min,and monitored by measuring the absorbance at 412 nm. Activitywas expressed as nmol Cm acetylated min^–1 mg protein^–1(44).

RNA isolation and Northern (RNA) hybridization analysis. Total RNA from V. vulnificus was extracted using a TRI reagentkit (MRC, Cincinnati, Ohio) according to the manufacturer'sprocedure. RNA quantification, electrophoretic separation ofdenatured RNA, blot transfer, labeling of the strand-specificRNA probe using [ ${alpha}$ -³²P]CTP, and hybridization with the probewere performed as described previously (17, 18).

Primer extension analysis. The primer 5'-GATGCTCAAGCTCACTG-3', representing the codingstrand of sodA between the 45th and 51st codons, was labeledwith [ ${gamma}$ -³²P]ATP using T4 polynucleotide kinase (Promega, Madison,WI). Total RNA from V. vulnificus at early stationary phase(A₆₀₀, $~$ 7.0) was used for the extension reaction (17), and theproducts were analyzed on an 8.3 M urea-8% polyacrylamide sequencinggel. The nucleotide sequence was determined by the dideoxy terminationreaction with a Thermo Sequenase cycle sequencing kit (AmershamPharmacia Biotech, Cleveland, Ohio).

Construction of mutants. (i) DNA for sodA disruption. A 761-bp DNA fragment extending from –114 to 647 relativeto the MnSOD initiation codon was PCR amplified from genomicDNA using forward (5'-GTTGCGAGTCACCATTAC-3') and reverse (5'-CGATAAGCGCACGGTGCTC-3')primers and cloned into pGEM-T (Promega, Madison, WI) to generatepBSA. The PstI site (66th residue) within sodA was interruptedwith 2.2-kb ${Omega}$ DNA (Km^r) (8), and the resulting 3.0-kb XbaI/XhoIfragment was cloned into the suicide vector pDM4 (32) to generatepDMSAkm.

For internal deletion of sodA on the chromosome of HLM101 (fur::aph;Km^r) (23), a 173-bp BglII-StuI DNA (residues between 55th and113th) within sodA was deleted from pBSA, followed by fill-inand ligation, and the resulting 0.6-kb XbaI/XhoI fragment wascloned into pDM4 to yield pDMSAid.

(ii) DNA for sodB disruption. A 909-bp DNA fragment extending from –284 to 625 relativeto the FeSOD initiation codon was PCR amplified from genomicDNA using a forward (5'-GCTTCCTCGTTCACGG-3') and reverse (5'-CTAAATTGGAACTTAAG-3')primers and cloned into pGEM-T. The XbaI site (57th residue)of sodB was interrupted with ${Omega}$ DNA (Km^r), and the resulting 3.1-kbSacI/XhoI DNA fragment was cloned into pDM4 to yield pDMSB.

(iii) DNA for sodC disruption. From the cosmid library of V. vulnificus genomic DNA, a 1.1-kbBglII-MboI DNA fragment encompassing sodC coding for CuZnSODwas cloned into pGEM-T. The NsiI site (122nd residue) of sodCwas interrupted with ${Omega}$ DNA (Km^r), and the resulting 3.1-kb SacI/XbaIDNA fragment was cloned into pDM4 to yield pDMSC.

(iv) DNA for soxR disruption. A 585-bp DNA fragment extending from –80 to 505 relativeto the SoxR initiation codon was PCR amplified from genomicDNA using a forward (5'-GCTCAACTTAACTTGAGG-3') and reverse (5'-CTTGCCACCGCAAACGC-3')primers and inserted into pGEM-T. The HincII site (17th residue)of soxR was interrupted with ${Omega}$ DNA (Km^r), and the resulting 2.8-kbXbaI/XhoI DNA fragment was cloned into pDM4 to generate pDMSXR.

(v) Mutant selection. pDM4-derived recombinant plasmids were mobilized into V. vulnificusAR (for pDMSAkm, pDMSB, pDMSC, and pDMSXR) and V. vulnificusHLM101 (for pDMSAid) through conjugation as described above.Conjugants carrying a single crossover were selected using Cm.The mutants showing indications of double crossover (Cm^s) wereisolated in the presence of 10% sucrose. The chromosomal structuresof the mutants were examined by Southern hybridization analysis(43).

Measurement of intracellular superoxide level. Cells were harvested, washed with phosphate-buffered saline(PBS) (43), and suspended in 50 mM potassium phosphate buffer(pH 7.3) supplemented with 2% NaCl. Cells (20 µl) wereput in 0.4 ml of buffer containing 20 µl 2 mM bis-N-methylacridiniumnitrate (lucigenin) (Sigma, St. Louis, MO), and luminescencewas immediately measured using MicroLumatPlus LB 96V (BertholdTechnologies GmbH & Co. KG) as described previously (27).The instrument was operated with a 5-s delay and 10-s integrationtime.

Lysine decarboxylase activity and cadaverine determination. The lysine decarboxylase activity of V. vulnificus and the cadaverineexcreted in culture medium were assayed as described previously(25, 40). The enzyme reaction was monitored by measuring theabsorbance at 340 nm. Specific activities were calculated as1,000 x A₃₄₀ per min (units) per A₆₀₀ (25).

Survival at acid pH. Acid tolerance was examined as described previously (40). Cellswere grown to logarithmic phase (A₆₀₀, $~$ 2.0) in LBS (pH 7.5),harvested, washed with 10 mM sodium citrate buffer (pH 5.0)supplemented with 2% NaCl (SCBN) (40), and suspended in thesame buffer to a final concentration of 10⁵ CFU ml^–1.A control experiment was performed at pH 7.5, in which PBS (pH7.5) was used instead of SCBN. Cell suspensions were incubatedat 30^°C with shaking as described above for cell growth.Samples were taken intermittently for 90 min, and viable counts(CFU/ml) were determined by plating dilutions of cells on LBS(pH 7.5) agar plates. Survival was expressed as a percentageof the initial CFU. Data shown are representatives of triplicateexperiments.

RESULTS

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Results

MnSOD expression of V. vulnificus is regulated transcriptionally. A constitutively expressed FeSOD is found in the cytoplasm ofV. vulnificus together with an inducible MnSOD, which is expressedfrom the onset of stationary phase (Fig. 1B). Unlike E. coli,no MnSOD activity is found during the exponential growth ofV. vulnificus. The bacterium also has a CuZnSOD in its periplasm,but its level is not high enough to appear on native gel withthe amounts of proteins loaded. The sodA::cat transcriptionalfusion construct, pSODAC (Fig. 1A), was maintained in transin wild-type cells, and CAT activity was measured (Fig. 1B).The CAT activity from pSODAC at early stationary phase was approximatelysixfold higher than in logarithmic phase. Thus, the growth-dependentexpression of MnSOD appears to be regulated transcriptionally.

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FIG. 1. CAT activities from sodA::cat fusion and expression of cytosolic SODs of V. vulnificus. (A) pSODAC has an insert in which sodA regulatory DNA is transcriptionally fused to cat and cloned downstream from transcription-translation stop ${Omega}$ DNA (Sm^r/Sp^r) (36). cpxA coding for a sensor of the Cpx two-component system perceiving cell envelope stress and trmH coding for tRNA methyltransferase are shown. (B) Activities of MnSOD and FeSOD in extracts of V. vulnificus cells at logarithmic (L) (A₆₀₀, $~$ 2.0) and early stationary (ES) (A₆₀₀, $~$ 7.0) growth phases. The same amount of protein (50 µg) was loaded in each lane unless stated otherwise. CAT activities from pSODAC in the wild type harvested at the growth phases indicated are illustrated below the gel.

A 0.7-kb transcript was detected after hybridization of a sodA-specificprobe to the total RNA from cells harvested at early stationaryphase, whereas it was barely detectable from exponentially growingcells (Fig. 2B). No such transcript was found in the sodA mutantSA1 (Fig. 2A and B). The 5' end of the transcript was mappedat 21 nucleotides upstream from the MnSOD initiation codon (Fig.2C). Canonical sequences typical of ${sigma}$ ⁷⁰-type promoters were found,and a putative binding site of ferric uptake regulator (Fur)(35), a repressor for sodA transcription in the presence ofthe Fe²⁺ ion, is located in the promoter region (Fig. 2C).

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FIG. 2. sodA transcription. (A) sodA coding for MnSOD was interrupted with ${Omega}$ DNA (Km^r) to generate mutant SA1. A 0.7-kb sodA transcript is indicated by an arrow below the restriction map. (B) Northern blot hybridization analysis with [ ${alpha}$ ³²P]CTP-labeled RNA probes corresponding to a 520-bp NsiI-SalI DNA fragment specific to sodA. RNA was prepared from the wild type and SA1. L and ES denote the growth phases, as described in the Fig. 1 legend. (C) Mapping of 5' end of sodA transcript by primer extension. Extension with RNA from the wild type at ES growth phase is shown in lane PE. The same ³²P-labeled oligonucleotide was used to generate the sequence ladder (lanes G, T, A, and C). DNA sequence is illustrated on the left, with the 5' end of the transcript marked with an asterisk. The sodA regulatory DNA between the CpxA stop and MnSOD initiation codons is shown on the right. The –35 and –10 sequences typical of ${sigma}$ ⁷⁰-type promoter (5' end [T] of the transcript: +1) are boxed, and a putative binding site of the ferric uptake regulator (Fur) is underlined. A putative ribosome-binding site (S-D) is also shown.

MnSOD expression, positively regulated by SoxR and negatively regulated by Fur, is not affected by RpoS. MnSOD activity was not detected in extracts of the soxR mutantSR1 (Fig. 3), which indicates that SoxR is required as a transcriptionalactivator as in E. coli (52). Likewise, the CAT activity frompSODAC in the soxR mutant was not induced (Fig. 3). It was testedwhether the alternative sigma factor ${sigma}$ ^s, a globular regulator(20) for stress resistance in many bacteria, including V. vulnificus(37), affects sodA expression. The CAT activities from pSODACand MnSOD expression in the rpoS mutant KPR101 (Fig. 3) werethe same as those in the wild type (Fig. 1B), which suggeststhat RpoS does not affect sodA expression even though MnSODof V. vulnificus is expressed in stationary phase. FeSOD levelswere unaffected by mutations in soxR and rpoS. In the fur mutantHLM101, sodA expression was derepressed even during exponentialgrowth, as revealed by the activities of CAT and MnSOD (Fig.3). The FeSOD activity of HLM101 was reduced to approximately40% of that of the wild type. Thus, Fur, a repressor for sodAtranscription, appears to act as an activator for sodB transcription.

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FIG. 3. Expression of cytosolic SODs and CAT activities from sodA::cat fusion in HLM101, KPR101, and SR1. L and ES denote the growth phases, as described in the Fig. 1 legend. The CAT activity unit is the same as in Fig. 1 unless otherwise specified.

Growth lag and MnSOD induction therein are triggered by superoxide accumulated upon cell exposure to low pH. Fresh LBS whose pH had been adjusted to 5.0 was inoculated withV. vulnificus grown exponentially at pH 7.5, as described inMaterials and Methods. The cells showed a growth lag of approximately3 h, whereas no lag was observed after transition to LBS (pH7.5) (Fig. 4A). The medium pH increased toward alkalinity duringlate exponential growth (Fig. 4A). The cellular superoxide level,as determined using lucigenin, increased after transition tothe low pH, which was approximately twofold higher than thatmeasured after transition to pH 7.5 (Fig. 4B). MnSOD activity,once induced during the lag (Fig. 4C), increased up to a levelcomparable to that observed at the early stationary growth phase(compare Fig. 4C with Fig. 1B), whereas it was barely detectableat pH 7.5 (Fig. 4C). The CAT activity from pSODAC reflectingtranscriptional control of MnSOD expression paralleled enzymeactivity (Fig. 4C). Addition of 4-hydroxy-2,2,6,6-tetramethylpiperidine-N-oxyl(TEMPO), a superoxide scavenger that can freely pass into thecell (22, 47), lowered the superoxide level (Fig. 4B). The scavengernot only shortened the lag (Fig. 4A) but also abolished MnSODinduction (Fig. 4C). The broth pH was not affected by TEMPO(Fig. 4A). The MnSOD expression was induced at pH 7.5 in thepresence of a superoxide generator, methyl viologen (MV) (Fig.4C), which also resulted in growth lag (Fig. 4A). The brothpH was not changed by MV (Fig. 4A). Thus, it appears that MnSODinduction of V. vulnificus is not controlled by low pH but bysuperoxide accumulated in cells under acidic conditions.

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FIG. 4. Growth, cellular superoxide level, and SOD expression of the wild type after transition to LBS adjusted to pHs 7.5 and 5.0. (A) Cell growth and pH curves of the culture broth after transition to LBS (pH 7.5) ( ${diamond}$ ), LBS (pH 7.5) containing 3 mM MV ( ${circ}$ ), LBS (pH 5.0) ( ${square}$ ), or LBS (pH 5.0) supplemented with 1 mM TEMPO ( ${triangleup}$ ). Time points (1, 2, 4, and 6 h) to harvest cells for the assay of superoxide level and MnSOD expression are indicated. (B) Detection of cellular superoxide using lucigenin. Cells were harvested at 1 (white bar), 2 (shaded bar), 4 (hatched bar), and 6 h (dotted bar). The standard deviations of the luminescence are shown on each bar. (C) Expression of cytosolic SODs and CAT activity from sodA::cat fusion were determined with cells harvested at the time points indicated.

If superoxide accumulated at low pH inhibits cell growth, thegrowth lag should disappear by increasing SOD activities inthe cytosol. sodA and sodB were cloned in downstream of thelac promoter of pRK415 and were maintained in trans in the wildtype. A significant level of MnSOD, comparable to that foundin the wild type at the early stationary phase, was expressedin cells containing pRKSA even during exponential growth, andan approximately twofold-higher level of FeSOD was constitutivelyexpressed in cells containing pRKSB (data not shown). No growthlag was observed when cells containing pRKSA and pRKSB weretransferred to low pH (Fig. 5). The broth pH was not affectedby sod genes in trans (data not shown). Therefore, temporarycessation of cell growth at low pH is due to intracellular superoxideaccumulated under the acidic conditions.

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FIG. 5. Growth of the wild type containing sod genes in trans after transition to LBS (pH 5.0). Growth of the wild type containing sodB ( ${circ}$ ), sodA ( ${triangleup}$ ), and vector (pRK415) ( ${square}$ ) in trans. The wild type containing pRK415 transferred to LBS (pH 7.5) ( ${diamond}$ ) is included as a control.

Lysine decarboxylase reaction abolishes acid stress by rapid neutralization of the culture broth. It was determined whether MnSOD expression is affected by thereaction catalyzed by lysine decarboxylase, since the activityis associated with neutralization of the culture broth (34,48). Lysine decarboxylase activity increased up to approximately55 units at its maximum level at 2 h after transfer to low pH(Table 2). However, approximately 20-fold-lower activity wasdetected with transfer to pH 7.5 (Table 2). Thus, the enzymewas induced during the lag after transition to low pH.

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TABLE 2. Lysine decarboxylase activities of the wild type and cadA mutant JR203 in LBS (pH 7.5) and LBS (pH 5.0) after growth transition

Lysine decarboxylase activity was barely detectable in the cadAmutant JR203 (Table 2), which indicates that the activity isspecific to CadA, although another enzyme (or homolog) was proposedfrom the residual activity in JR203 (40). The mutant at lowpH showed a 3- to 4-h lag, which is similar to that of the wildtype (Fig. 6A, pH 5.0). The pH curves and the MnSOD expressionsof the mutant were not different from those of the wild type(Fig. 6A and B, pH 5.0). However, the effect of the lysine decarboxylasereaction on pH homeostasis was valid when lysine (15 mM), knownto induce the enzyme in E. coli via the periplasmic domain ofCadC (32), was added to LBS (pH 5.0). The maximum level of enzymeactivity of the wild type increased approximately twofold overthat measured without lysine addition (Table 2). The productionand excretion of cadaverine, whose concentration increased byapproximately fourfold (1,186 ± 18 µM), was accompaniedby rapid neutralization of the culture broth (Fig. 6A, pH 5.0,plus lysine). The cellular superoxide level of the wild typedid not increase under the conditions (data not shown), whichresulted in neither growth lag nor MnSOD induction (Fig. 6A and B,pH 5.0, plus lysine). Such results were not observedwith JR203. Thus, the lysine decarboxylase reaction preventsgeneration of oxidative stress by rapid neutralization of theculture broth. The acid tolerance response was examined withoutlysine addition. A pH rise during late exponential growth ofJR203 also suggests a lysine decarboxylase-independent mechanism(s)for neutralization of the extracellular medium, which remainsto be determined.

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FIG. 6. Growth and SOD expression of the wild type and a cadA mutant after transition to LBS (pH 5.0) supplemented with lysine (15 mM). (A) Cell growth and pH curves of the culture broth of the wild type ( ${diamond}$ , ${diamondsuit}$ ) and JR203 ( ${circ}$ , •) without (open) or with (closed) lysine. Time points (1, 2, 4, and 6 h) to harvest cells for the assay of MnSOD expression are indicated. (B) Expression of cytosolic SODs and CAT activities from sodA::cat fusion in cells harvested at the time points indicated.

MnSOD induction at low pH is regulated through SoxR. When SoxR, the positive regulator for sodA expression (52),was deleted, the mutant showed a growth lag extended to 7 hfollowing the transfer to low pH (Fig. 7A). The medium pH increasedtoward alkalinity during late exponential growth (data not shown).A similar lag was observed with the sodA mutant SA1 (data notshown). Thus, the lack of MnSOD expression extended the growthlag at low pH. Neither the CAT activity from pSODAC nor MnSODwas induced in the soxR mutant SR1 (Fig. 7B), illustrating thatMnSOD induction at low pH is regulated by SoxR.

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FIG. 7. Growth and SOD expression of soxR mutant after transition to LBS (pH 5.0). (A) Cell growth of SR1 ( ${circ}$ ). The wild type ( ${diamond}$ ) after transition to the same medium is included for comparison. Time points (1, 2, 4, and 6 h) to harvest cells for the assay of MnSOD expression are indicated. (B) Expression of cytosolic SODs and CAT activities from sodA::cat fusion in SR1 harvested at the time points indicated.

Survival of V. vulnificus defective in cytosolic SOD expression is significantly affected at low pH. Although the lag period at low pH was significantly affectedby oxidative stress, it cannot be a measure for acid tolerance,as illustrated by the cadA mutant JR203. Although the lag ofJR203 at low pH was comparable with that of the wild type (Fig.6A), its acid tolerance was approximately 10-fold lower thanthat of the wild type (40). Thus, percent survival was determinedas described in Materials and Methods for quantitative measurementof acid tolerance.

The soxR and sodA mutants SR1 and SA1 showed survival similarto that of the wild type at pH 7.5 (Fig. 8A1 and A2) but increasedkilling at pH 5.0 (Fig. 8A1 and B2). The results confirm thatMnSOD expression is crucial for survival of V. vulnificus inacidic environments.

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FIG. 8. Acid tolerance of regulatory mutants affecting sodA expression, sod mutants, and sod mutants complemented with corresponding genes. Cells grown in LBS (pH 7.5) with transition to PBS (pH 7.5) (A) and SCBN (pH 5.0) (B). (A1 and B1) Regulatory mutants HLM101 ( ${square}$ ), SR1 ( ${circ}$ ), and FSA1 ( ${triangleup}$ ); (A2 and B2) sod mutants SC1 ( ${circ}$ ), SA1 ( ${square}$ ), and SB1 ( ${triangleup}$ ); (A3 and B3) sod mutants complemented with corresponding genes, SC1 containing pRKSC ( ${circ}$ ), SA1 containing pRKSA ( ${square}$ ), and SB1 containing pRKSB ( ${triangleup}$ ). The wild type ( ${diamond}$ ) and the wild type containing pRK415 ( ${diamond}$ ) are included as a control in each experiment. Survival was expressed as percentages of the initial numbers of CFU ml^–1, which were approximately 10⁵. Data shown are representative of triplicate experiments.

The survival of the fur mutant HLM101 derepressing MnSOD (Fig.3) was similar to that of the wild type at pH 7.5 (Fig. 8A1).As expected, the mutant endured acidity better than the wildtype (Fig. 8B1). The higher tolerance could be ascribed to theelevated level of cytosolic SODs in the mutant, since the totalcytosolic SOD activity, measured in the presence of KCN as describedin Materials and Methods, of HLM101 grown in LBS is always higherthan that of the wild type by approximately 10 to 50% irrespectiveof the pH of the medium (data not shown). Iron is more solubleat acid pH than it is at alkaline pH (53), and excess intracellulariron can be detrimental to the cell (9). Accordingly, it wasconsidered possible that the lethal effect at low pH could beenhanced by the unregulated delivery of iron into the mutant.Contrary to expectations, the addition of FeCl₃ up to 100 µMdid not change the survival phenotype (Fig. 9A and B). Thissuggests that potential iron toxicity through the delivery ofiron, possibly unregulated by the lack of Fur, into the mutantmay not be a factor affecting acid tolerance in V. vulnificus.The tolerance endurance was abolished by introduction of a sodAmutation in HLM101 (see FSA1 in Fig. 8B1). Thus, it is the derepressedMnSOD expression of the fur mutant that is related to acid tolerance.

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FIG. 9. Acid tolerance of fur mutant in the presence of FeCl₃. The wild type ( ${diamond}$ ) and HLM101 grown in LBS (pH 7.5) were transited to PBS (pH 7.5) (A) and SCBN (pH 5.0) (B). FeCl₃ was added to the buffer; none ( ${square}$ ), 20 ( ${triangleup}$ ), and 100 µM ( ${circ}$ ). Survival was expressed as percentages of the initial numbers of CFU ml^–1, which were approximately 10⁵. Data shown are representative of triplicate experiments.

Cellular level of cytosolic SODs is important for cell survival at low pH. sodB and sodC, coding for FeSOD and CuZnSOD, respectively, ofV. vulnificus, were interrupted to generate mutants SB1 andSC1 (Fig. 10). MnSOD of SB1 is derepressed from the exponentialgrowth phase (Fig. 10A2). The expression of MnSOD and FeSODwas not changed by the mutation in sodC (Fig. 10B2). Total cytosolicSOD activities in cell extracts from SC1, SB1, and SA1 grownto logarithmic phase were measured in the presence of KCN. Thecytosolic SOD activity of SC1 is similar to that of the wildtype, whereas those of SA1 and SB1 amounted to 85 and 25% ofthe wild-type activity, respectively, illustrating that thetotal cytosolic activity decreased in the order of SC1, SA1,and SB1. Acid survival of sod mutants also decreased in theorder of SC1, SA1, and SB1 compared with the wild type (Fig.8B2). The mutational effects were significant at acid pH (compareFig. 8B2 with Fig. 8A2) and were complemented with correspondingsod genes in trans (Fig. 8A3 and B3). Thus, the higher levelof cytosolic SOD activities appears to support the better toleranceto acid pH. The contribution of CuZnSOD to acid tolerance wasnot significant compared with those of cytosolic SODs.

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FIG. 10. Chromosomal structures of sodB and sodC mutants and their expression of cytosolic SODs. (A1 and B1) sodB and sodC were interrupted with ${Omega}$ DNA (Km^r) to generate mutants SB1 (A1) and SC1 (B1), respectively. ankB coding for an ankyrin-like protein is shown (B1). (A2 and B2) Expression of cytosolic SODs and CAT activity from sodA::cat fusion in SB1 (A2) and SC1 (B2). L and ES stand for the growth phases, as described in the Fig. 1 legend.

Taken together, when V. vulnificus is exposed to low pH, superoxideis accumulated in cells. MnSOD expression is then induced, whichresults in an increase of cytosolic SOD activity. Superoxideremoval by the cytosolic SODs is essential for acid toleranceof V. vulnificus.

DISCUSSION

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Discussion

In this work, acid-specific stress could be separated from oxidativestress by TEMPO, a scavenger for superoxide. Since the scavengerabolishes MnSOD induction at low pH, the stress responsiblefor sodA transcription is not pH but superoxide. Fe²⁺ of hemein acid pH may undergo spontaneous oxidation to Fe³⁺ with concomitantgeneration of superoxide (33). Acid also could affect all thecell components from the membrane to the cytosol, and the proteinstherein could be partly unfolded but still work to generatereactive oxygen species including superoxide under aerobic conditions.Interestingly, there have been reports of increased expressionof both DnaK and GroEL/ES classes of chaperones in responseto growth at low pH (15, 36). By the same token, the experimentalresults shown in this work can also suggest that a lack of eitherMnSOD or FeSOD of V. vulnificus may result in intracellularbuildup of superoxide, which causes cellular damage that rendersthe cell more sensitive to the acid stress.

E. coli MnSOD is also induced by MV (13), as in V. vulnificus.However, unlike the case with V. vulnificus, a substantial levelof MnSOD activity is detected in E. coli during exponentialgrowth. Neither derepressed MnSOD activity nor a growth lagwas observed after transition of E. coli to LB acidified topH 4.0 or 5.0 (J.-S. Kim and J. K. Lee, unpublished results).The results suggest that there are intrinsic differences inthe acid tolerance response between E. coli and V. vulnificus.Superoxide may not be generated in E. coli under acidic conditions,or the superoxide level, if generated, may be too low to induceMnSOD.

V. vulnificus SoxR (17 kDa on a sodium dodecyl sulfate-polyacrylamidegel) was purified after tag removal from the fusion proteinMBP-SoxR, which had been overexpressed in E. coli. The purifiedSoxR protein displayed binding affinity for E. coli soxS regulatoryDNA (from –116 to +64; +1, 5' end of the soxS transcript)in a gel mobility shift. However, the mobility of V. vulnificussodA regulatory DNA (from –87 to +51; +1, 5' end of thesodA transcript) was not affected by SoxR (J.-S. Kim and J.K. Lee, unpublished results). Thus, the SoxR-mediated sodA expressionof V. vulnificus appears to be exerted indirectly, possiblyvia another regulator, such as SoxS, as observed with E. coli(1). In V. vulnificus, however, no SoxS homolog has been foundto date.

SoxR regulates MnSOD induction at acid pH, which is requiredfor an acid tolerance response (Fig. 8). rpoS and cadC mutantsof V. vulnificus also revealed higher levels of acid killingthan the wild type (37, 39). For both rpoS and cadC mutants,however, the acid pH-dependent MnSOD inductions are the sameas those for the wild type (J.-S. Kim and J. K. Lee, unpublishedresults). Thus, rpoS and cadC mutants are acid sensitive forreasons other than defects in acid pH-dependent MnSOD induction.Therefore, acid resistance of V. vulnificus appears to be amultifactorial phenomenon that includes stress responses toacidity as well as superoxide accumulated under acidic conditions.

From the survival of sod mutants, it was concluded that thehigher SOD level in the cytosol supports better survival atacid pH. The same was true for a lethality assay following intraperitonealinjection of the cells into mouse (J.-S. Kim and J. K. Lee,unpublished results), reflecting that superoxide is one of themajor stresses that V. vulnificus should overcome in vivo.

ACKNOWLEDGMENTS

We thank K.-H. Lee for providing V. vulnificus strains HLM101and KPR101, S. H. Choi for strain JR203, K. S. Kim for the cosmidlibraries of V. vulnificus genomic DNA, and Y.-H. Cho for helpfuldiscussions.

This work was supported by the 21C Frontier Microbial Genomicsand Applications Center Program from the Ministry of Scienceand Technology (MG02-0201-003-2-2-0), Korea, and also supportedby a grant (2000-2-20200-001-3) from the Basic Research Programof KOSEF and by a special research grant from Sogang Universityin 2002.

FOOTNOTES

* Corresponding author. Mailing address: Department of Life Science and Interdisciplinary Program of Integrated Biotechnology, Sogang University, Seoul 121-742, Korea. Phone:: 82-2-705-8459. Fax: 82-2-704-3601. E-mail: jgklee{at}sogang.ac.kr.

Present address: Department of Bacteriology, Division of Rickettsialand Zoonotic Diseases, National Institute of Health, Seoul 122-701,Korea.

REFERENCES

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