Interplay of the Czc System and Two P-Type ATPases in Conferring Metal Resistance to Ralstonia metallidurans

Cadmium and zinc are removed from cells of Ralstonia metalliduransby the CzcCBA efflux pump and by two soft-metal-transportingP-type ATPases, CadA and ZntA. The czcCBA genes are locatedon plasmid pMOL30, and the cadA and zntA genes are on the bacterialchromosome. Expression of zntA from R. metallidurans in Escherichiacoli predominantly mediated resistance to zinc, and expressionof cadA predominantly mediated resistance to cadmium. Both transportersdecreased the cellular content of zinc or cadmium in this host.In the plasmid-free R. metallidurans strain AE104, single genedeletions of cadA or zntA had only a moderate effect on cadmiumand zinc resistance, but zinc resistance decreased 6-fold andcadmium resistance decreased 350-fold in double deletion strains.Neither single nor double gene deletions affected zinc resistancein the presence of czcCBA. In contrast, cadmium resistance ofthe cadA zntA double mutant could be elevated only partiallyby the presence of CzcCBA. lacZ reporter gene fusions indicatedthat expression of cadA was induced by cadmium but not by zincin R. metallidurans strain AE104. In the absence of the zntAgene, expression of cadA occurred at lower cadmium concentrationsand zinc now served as an inducer. In contrast, expression ofzntA was induced by both zinc and cadmium, and the inductionpattern did not change in the presence or absence of CadA. However,expression of both genes, zntA and cadA, was diminished in thepresence of CzcCBA. This indicated that CzcCBA efficiently decreasedcytoplasmic cadmium and zinc concentrations. It is discussedwhether these data favor a model in which the cations are removedeither from the cytoplasm or the periplasm by CzcCBA.

INTRODUCTION

Top

Introduction

Three different systems mediate efflux of divalent heavy metalcations from bacterial cells: resistance-nodulation-cell division(RND)-driven transenvelope exporters, cation diffusion facilitators(CDF), and P-type ATPases (for a review, see reference 25) (Fig.1). RND-driven systems are protein complexes able to span thecomplete cell wall of a gram-negative bacterium. In the caseof metal-exporting RND-driven efflux systems, the central pumpof this protein complex is usually a member of the RND superfamily(35). In addition, an outer membrane factor and a membrane fusionprotein are also required to transport substrate directly tothe extracellular medium (25). In contrast, CDF proteins andP-type ATPases are single-subunit transporters. CDF proteinsare driven by a chemiosmotic gradient formed by protons or potassium(12, 15), whereas P-type ATPases hydrolyze ATP as their drivingforce (5). The latter two protein families transport their substratesfrom the cytoplasm to the periplasm.

View larger version (40K):
[in this window]
[in a new window]
FIG. 1. Prototypes of known efflux systems for zinc and cadmium in R. metallidurans. The Zn²⁺ and Cd²⁺ cations are exported from the cytoplasm (free or bound to thiols like glutathione) to the periplasm (grey area) by P-type ATPases (I) or by CDF (III) that are driven by the chemiosmotic gradient. The more complicated RND-driven efflux systems (II) are composed of an RND protein in the cytoplasmic membrane, an outer membrane factor, and a membrane fusion protein. Accordingly to the structures of the RND protein AcrB (21) and the outer membrane factor TolC (14), a trimeric state of all three subunits of the RND-driven efflux complex is assumed. CzcCBA is driven by the proton motive force (H⁺) (8, 23). The cationic substrates (white circles) may be directly exported out of the cell from the cytoplasm or periplasm (21).

Heavy metal-resistant bacteria harbor a multitude of RND-driven-,CDF-, and P-type-efflux systems (25). Together, they orchestratea highly efficient network to achieve metal homeostasis, butat this point the role and interdependence of individual effluxpumps are still largely unexplored. An ideal candidate to unravelsuch a complex interaction of different metal efflux pumps isthe ß-proteobacterium Ralstonia metallidurans (previouslyAlcaligenes eutrophus [9]), which contains more efflux pumpsthan most other sequenced bacteria (25). The wild-type strainCH34 contains two megaplasmids harboring a multitude of metalresistance determinants. The czc determinant (22) on plasmidpMOL30 mediates resistance to Co(II), Zn(II), and Cd(II). Itencodes the RND-driven transenvelope exporter CzcCBA composedof the RND protein CzcA, the membrane fusion protein CzcB, andthe outer membrane factor CzcC (26, 30). As a second effluxsystem of this determinant, the CDF protein CzcD is involvedin detoxification of the same metals and in regulation of expressionof the CzcCBA pump (1, 24). The CzcCBA system forms the outershell of metal resistance in this bacterium, and its role incadmium resistance can be successfully described in a virtualmodel of the R. metallidurans cell (16).

R. metallidurans strain CH34 harbors genes for 10 P-type ATPases,while the related plant pathogen Ralstonia solanacearum hasgenes for 4 P-type ATPase (25). Five of these P-type ATPasesare putative soft-metal-transporting P-type ATPases (29) showingthe typical CPx motif of this protein family. Two of these fiveCPx-type ATPases are closely related to Cu⁺/Ag⁺-transportingATPases (gene 8627 on contig 709 [g8627/709] and g8785/710),and three are related to Zn²⁺/Cd²⁺/Pb²⁺-transporting proteins(g4648/649, g6751/691, and g6917/692) (25). The pbrA gene (g6917/692)located on plasmid pMOL30, has been characterized as part ofthe bacterial defense against lead (3). Therefore, PbrA wasnot included in this study.

With the loss of plasmid pMOL28 and especially of plasmid pMOL30harboring czc, resistance (MICs) of R. metallidurans to Co(II),Zn(II), and Cd(II) decreases from the millimolar range (5 to20 mM) in the wild-type strain CH34 to about 200 µM inthe plasmid-free strain R. metallidurans AE104 (19). In thisstudy, we further decreased metal resistance of strain AE104by deletion of the two remaining Zn²⁺/Cd²⁺-transporting CPx-typeATPases localized on the bacterial chromosome. The influenceof the CzcCBA exporter on metal resistance of these metal-sensitivestrains and on transcriptional regulation of the two genes thatencode these two CPx-type ATPases implies a highly efficientremoval of cations by CzcCBA. Possibly, CzcCBA removes cationsdirectly from the periplasm for export across the outer membrane.

MATERIALS AND METHODS

Top

Materials and Methods

Bacterial strains and growth conditions. All strains used for experiments were derivatives of the megaplasmid-freeR. metallidurans strain AE104 (19). The bacterial strains andthe plasmids used and their genotypes are listed in Table 1.Tris-buffered mineral salts medium (19) containing 2 g of sodiumgluconate per liter was used to cultivate R. metallidurans strainsaerobically with shaking at 30°C. Analytical-grade saltsof heavy metal chlorides (with the exception of lead nitrate)were used to prepare 1 M stock solutions, which were sterilizedby filtration. Solid Tris-buffered medium contained 20 g ofagar per liter.

View this table:
[in this window]
[in a new window]
TABLE 1. Bacterial strains and plasmids used in this study

Dose-response growth curves. Dose-response growth curves describing the action of Zn²⁺ orCd²⁺ on Escherichia coli cells were performed in Lennox medium(Becton-Dickinson, Sparks, Md.). Genes for the P-type ATPasewere cloned under control of the tet promoter on plasmid pASK3(IBA GmbH, Göttingen, Germany). The medium contained 50µg of anhydrotetracycline (AHT) to induce expression ofthese genes. Cultures of E. coli strains grown overnight wereused to inoculate parallel cultures with increasing metal concentrations.Cells were cultivated for 16 h with shaking at 37°C, andthe optical density was determined at 600 nm.

Induction experiments. R. metallidurans cells with a lacZ reporter gene fusion werecultivated in Tris-buffered mineral salts medium containing2 g of sodium gluconate per liter with shaking at 30°C.At a cell density of 70 Klett units, heavy metal salts wereadded to various final concentrations to the cells, and cellswere incubated with shaking for a further 3 h. The specificß-galactosidase activity was determined in permeabilizedcells as published previously (24), with 1 U defined as theactivity forming 1 nmol of o-nitrophenol per min at 30°C.

Metal ion uptake experiments with E. coli and R. metallidurans.Cells were performed in Tris buffer (10 mM, pH 7.0) by filtrationas published previously (27). E. coli cells were cultivatedin Tris-buffered mineral salts medium in the presence of 2 gof glucose per liter and 1 g of yeast extract per liter up to100 Klett units when 200 µg of AHT per liter was added,and incubation was continued with shaking for 3 h at 30°C.Cells were harvested by centrifugation, washed, and suspendedin 10 mM Tris-HCl buffer (pH 7.0). Radioactive metal cations⁶⁵Zn²⁺ (185 GBq/g) or ¹⁰⁹Cd²⁺ (87.4 GBq/g) were added at a concentrationof 10 µM, incubation was continued with shaking at 30°C,and the metal content in washed cells (dry weight) was determinedat various time points using an equilibration curve. Backgroundbinding was not subtracted. R. metallidurans cells were cultivatedin Tris medium with sodium gluconate (2 g per liter) insteadof glucose to a turbidity of 70 Klett units without yeast extractor AHT. This culture was used directly for metal uptake experiments.

Genetic techniques. Standard molecular genetic techniques were used (22, 32). Forconjugal gene transfer, cultures of donor strain E. coli S17/1(34) and R. metallidurans recipient strains that had been grownovernight at 30°C in complex medium were mixed (1:1) andplated onto nutrient broth agar. After the bacteria were allowedto grow overnight, they were suspended in saline (9 g of NaClper liter), diluted, and plated onto selective media as previouslydescribed (22). The zntA and cadA genes encoding the two P-typeATPases were amplified from total DNA of the megaplasmid-freestrain R. metallidurans AE104. The cadA gene was cloned as aBamHI/XhoI fragment using the primer pair AAA GGA TCC GTT GCTTCC TAT AAA AAA CTT GAC TCT and AAA CTC GAG TGC CGC CTT GAACTT CAG (restriction endonuclease sites underlined), while zntAwas cloned as an EcoRI/BamHI fragment using the primer pairAAA GAA TTC GAA TTT GAC ATG GCT CGC ACC and AAA GGA TCC AACGGC CTT GCG CGT CA. Both fragments were cloned into the vectorplasmid pASK3 (IBA-GmbH).

To construct plasmid pDNA385, the 9-kb EcoRI fragment containingczcCBADRS' was cloned from plasmid pEC11 (22) into the broad-host-rangevector plasmid pVDZ'2 (4) under control of the lac promoter(which is constitutively expressed in R. metallidurans [27])on this plasmid. The 3' end of the cloned region contained partsof the coding region for the two-component regulatory systemCzcRS that is involved in but not essential for czc regulation(11). The entire gene for the histidine kinase CzcS was notpresent on the cloned DNA fragment in order to prevent any interferencewith the constitutive expression of this fragment from the lacpromoter of the vector plasmid.

Gene deletions. The genes were replaced by open reading frames of 24 bp, whichwere identical to the deleted gene in the first 9 bp and thelast 9 bp. This prevented any possible polar effect of the mutation.All replacing open reading frames contained the 6-bp MunI recognitionsequence of the restriction endonuclease used to clone in themiddle of the open reading frame. The 5' end of cadA was amplifiedfrom total DNA of R. metallidurans strain AE104 as a MunI/NdeIfragment by PCR using the primer pair AAA CAA TTG GGA AGC AACCAT GAT GCG GAT C and AAA CAT ATG CGG GCT CGG CCA AGC TGT, whilethe 3' end was similarly amplified using the primer pair AAACAA TTG AAG GCG GCA TGA ACA ATG GAT and AAA CAT ATG GGC CTTCCG TTT TGC GCA. For zntA, the primer pair AAC AAT TGG TCA AATTCC ATT GAT TCT TGT TCC and AAA CAT ATG GAG CTT GGC CGA TTTGCT GTC was used to amplify the 5' end, while the primer pairAAA CAA TTG AAG GCC GTT TGA CGG CCT G, and AAA CAT ATG TCG ACGAGC TGA TCG GTG TGG was used to amplify the 3' end. The fragmentswere cloned into the suicide vector pLO2 (17), sequenced, andused to exchange the target gene against the respective 24-bpopen reading frame by recombination as described previously(11). Correct mutations were verified by PCR analysis and SouthernDNA-DNA hybridization. This procedure yielded R. metalliduransstrains DN438( ${Delta}$ cadA) and DN439( ${Delta}$ zntA), which are both derivativesof strain AE104.

Gene insertions. Gene insertions were constructed for two purposes. First, sinceit was not possible to construct a ${Delta}$ cadA ${Delta}$ zntA strain for unknownreasons, the zntA gene was inactivated in the ${Delta}$ cadA single deletionstrain DN438 by insertion mutagenesis, and the cadA gene wassimilarly inactivated in the ${Delta}$ zntA single deletion strain DN439.The central part of the target gene was amplified by PCR fromtotal DNA of strain AE104, cloned as NdeI fragments in plasmidpLO2, and used to interrupt the coding sequence of the targetgene as published previously (13). The primer pairs used wereAAA CAT ATG CGC ACG CTC ACG GTT CGG and AAA CAT ATG GCC GCTGAC GAT GGT GAC for cadA and AAA CAT ATG GCA AGG GCT GGA TCGCAG and AAA CAT ATG CCA CGC CAT CGG TTT CGG for zntA. This procedureproduced the DN438 derivative strain DN440( ${Delta}$ cadA zntA::pLO2)and the DN439 derivative DN441 ( ${Delta}$ zntA cadA::pLO2).

Second, lacZ was inserted downstream of the target genes toconstruct an operon fusion. This was done without interruptingany open reading frames downstream of the target genes to preventpolar effects. The 300-bp 3' end of the zntA gene up to 8 bpdownstream of the stop codon was amplified by PCR, and the resultingfragment was cloned into plasmid pLO2 as a SphI/SalI fragmentfrom total DNA of strain AE104 using the primer pair AAA GCATGC GGC ATG GTC GGT GAC GGT ATC and AAA GTC GAC ACA GGC CGTCAA ACG GCC. Similarly, the 3' end of the cadA gene was clonedup to 7 bp downstream of the stop codon as a PstI/SalI fragmentusing AAA CTG CAG GTG GGC ATG GTG GGC GAC and AAA GTC GAC CCATTG TTC ATG CCG CCT TGA as primers for PCR amplification. AfterlacZ had been inserted downstream of the two 300-bp fragments,respective operon fusion cassettes were inserted into the openreading frame of the target gene by single crossover recombination.Using this method, cadA-lacZ fusions were constructed in strainsAE104 and DN439 ( ${Delta}$ zntA) and zntA-lacZ fusions were constructedin strains AE104 and DN438 ( ${Delta}$ cadA), leading to the four strains(DN442 to DN445) listed in Table 1.

RESULTS

Top

Results

Substrate specificity of two chromosomal CPx-type ATPases from R. metallidurans as determined by heterologous expression in E. coli. PCR analysis demonstrated that genes encod-ing two putativeCd²⁺/Zn²⁺-transporting P-type ATPases (g4648/649 and g6751/691;R. metallidurans sequencing project website [http://www.jgi.doe.gov/JGI_microbial/html/ralstonia/ralston_homepage.html])were located on the chromosome of R. metallidurans (data notshown). Both genes were amplified by PCR from total DNA of megaplasmid-freeR. metallidurans strain AE104 (19) and cloned into plasmid pASK3.The resulting plasmids were transferred into E. coli strainGG48 ( ${Delta}$ zntA ${Delta}$ zitB), a metal-sensitive strain with deletions inboth known Zn²⁺/Cd²⁺ efflux systems (ZntA_Ecoli and ZitB_Ecoli)(10). Both genes from R. metallidurans conferred metal resistancein E. coli strain GG48 (Fig. 2).

View larger version (26K):
[in this window]
[in a new window]
FIG. 2. Zinc and cadmium resistance of E. coli strains that express P-type ATPases from R. metallidurans. Dose-response curves are shown for E. coli strain GG48( ${Delta}$ zntA ${Delta}$ zitB) complemented in trans with genes encoding the R. metallidurans P-type ATPases CadA (g6751/691) ( ${blacktriangleup}$ ) and ZntA (g4648/649) ( ${blacksquare}$ ). Both genes were cloned into plasmid pASK3. The negative-control strain is GG48(pASK3) ( ${circ}$ ), and the positive-control wild-type strain is W3110(pASK3) (•). The means ± standard deviations (error bars) from three independent experiments are shown.

Half of the maximum inhibition of E. coli strain GG48 ( ${Delta}$ zntA ${Delta}$ zitB) and wild-type strain W3110 occurred at about 200 µMand 950 µM Zn²⁺ and at 50 µM and 600 µM Cd²⁺,respectively (Fig. 2). Complementation in trans with g6751/691led to half of the maximum inhibition at about 350 µMZn²⁺ and the same concentration of Cd²⁺; this corresponded toa higher degree of cadmium resistance than of zinc resistancein the complemented strain. Therefore, g6751/691 was named cadA.In contrast, the presence of g4648/649 led to a phenotype ofnear-wild-type zinc resistance (half of the maximum inhibitionat about 800 µM) but only to a small increase in cadmiumresistance (about 100 µM). Therefore, g4648/649 was namedzntA. ZntA, but not CadA, had a minimal (less than twofold)effect on lead resistance in E. coli [lead resistance testedwith Pb(II) nitrate] (data not shown).

Metal cation uptake into cells of E. coli strain GG48 expressingeither one of the P-type ATPase genes from R. metalliduranswas examined (Fig. 3). Cells of metal-sensitive E. coli strainGG48 accumulated 5 µmol of ⁶⁵Zn²⁺/g (dry weight) or 8µmol of ¹⁰⁹Cd²⁺/g (dry weight) in an assay buffer containinga 10 µM concentration of either metal cation. Cells expressingeither cadA or zntA from R. metallidurans accumulated only 1µmol of cadmium or zinc/g (dry weight). Thus, both R.metallidurans P-type ATPases were functionally expressed inE. coli and decreased accumulation of cadmium or zinc by E.coli cells.

View larger version (20K):
[in this window]
[in a new window]
FIG. 3. The presence of the CadA and ZntA P-type ATPases from R. metallidurans diminishes the accumulation of Cd²⁺ and Zn²⁺ in E. coli strain GG48 in assay buffer containing 10 µM ⁶⁵Zn²⁺ (A) or 10 µM ¹⁰⁹Cd²⁺ (B). E. coli strain GG48 ( ${Delta}$ zntA ${Delta}$ zitB) was complemented in trans with the genes for the R. metallidurans P-type ATPases CadA (g6751/691) ( ${blacktriangleup}$ ) or ZntA ( ${blacksquare}$ ). The negative control ( ${circ}$ ) contained only the vector plasmid pASK3. The accumulation of Cd²⁺ and Zn²⁺ is shown in micromoles of the metal cation per gram (dry weight [d. w.]) of cells. The mean values of two independent experiments are shown.

Function of CadA and ZntA in R. metallidurans. To study the influence of ZntA and CadA on heavy metal resistancein R. metallidurans, both genes were deleted from the chromosomeof the megaplasmid-free R. metallidurans strain AE104 (Table2). Deletion of cadA (strain DN438) led to small decreases inboth zinc and cadmium resistance. Deletion of zntA (strain DN439)mainly altered the level of zinc resistance and altered thelevel of cadmium resistance to a smaller degree.

View this table:
[in this window]
[in a new window]
TABLE 2. MICs of zinc and cadmium for R. metallidurans strains (megaplasmid-free strain AE104 derivatives) carrying mutations in the genes for P-type ATPases^a

Additionally, in the ${Delta}$ cadA or ${Delta}$ zntA deletion strains, the genefor the respective other P-type ATPase was inactivated by genedisruption (Table 1). The resulting reciprocal strains (DN440and DN441) displayed the same degree of decreased zinc and cadmiumresistance (Table 2). Cadmium tolerance of both double mutantstrains decreased more than 1,000-fold from that of the R. metalliduranswild-type strain CH34(pMOL28, pMOL30), which harbors the completeset of cadmium detoxification systems (19). In contrast to thestrong effect on cadmium resistance and the significant effecton zinc resistance, the double deletion or either single deletiondid not affect lead resistance of R. metallidurans (data notshown).

R. metallidurans cells without CadA and ZntA accumulated moreCd²⁺ than the respective control cells (Fig. 4) (⁶⁵Zn²⁺ is nolonger available and could not be tested). This demonstratedthat resistance mediated by both P-type ATPases is based ondiminished cation accumulation. The R. metallidurans doubledeletion strain accumulated 431 nmol of ¹⁰⁹Cd²⁺/g (dry weight)in medium with 1 µM ¹⁰⁹Cd(II), while the single deletionstrains and the positive-control strain AE104 accumulated between105 and 145 nmol/g (dry weight) (Fig. 4).

View larger version (15K):
[in this window]
[in a new window]
FIG. 4. Uptake of cadmium by R. metallidurans strains with mutations in the genes for CPx-type ATPases. Uptake of 1 µM ¹⁰⁹Cd²⁺ by cells of the megaplasmid-free R. metallidurans strain AE104 (•), its ${Delta}$ zntA deletion derivative DN439 ( ${blacktriangleup}$ ), its ${Delta}$ cadA deletion derivative DN438 ( ${blacksquare}$ ), and the ${Delta}$ zntA cadA::pLO2 double mutant strain DN441 ( ${circ}$ ) is compared. Uptake is measured in nanomoles of Cd²⁺ per gram (dry weight [d.w.]) of cells.

Regulation of cadA and zntA expression in R. metallidurans. As suggested, the substrate specificities of ZntA or CadA afterheterologous expression in E. coli may indicate that both proteinshave rather distinct functions. Such a specialization shouldalso be mirrored by the expression profiles of both genes inR. metallidurans. Expression was studied by an operon fusionof zntA or cadA with a promoterless lacZ gene, which was insertedby homologous recombination directly downstream of the gene.Neither gene was inactivated by this insertion, shown by PCRand DNA sequence analysis of the modified gene regions (datanot shown). The gene for a putative lipoprotein signal peptidase(g6752/691) directly downstream of cadA was not disturbed bythe lacZ insertion (data not shown). Since zntA is flanked byopen reading frames only on the other DNA strand, no polar effectsshould have been generated when lacZ was inserted.

Expression of zntA and cadA was induced by cadmium (Fig. 5Aand Fig. 6A). Expression of zntA was enhanced 20-fold afterinduction with 100 µM Cd²⁺. Expression of cadA was slightlygreater (50-fold) at the same cadmium concentration. Thus, bothproteins may be synthesized in vivo to export cadmium. In contrast,expression levels of both genes responded differently to increasingzinc concentrations: while zntA was induced by Zn²⁺ to a degreesimilar to that induced by Cd²⁺ (Fig. 5), cadA was not inducedby Zn²⁺ when ZntA was present (Fig. 6B). Thus, expression ofzntA and transport activity of ZntA in vivo seem to be sufficientto protect cells of R. metallidurans strain AE104 against environmentalzinc concentrations up to 100 µM, while CadA seemed tobe relevant in vivo as an additional system for cadmium efflux.

View larger version (25K):
[in this window]
[in a new window]
FIG. 5. Induction of a zntA-lacZ operon fusion by heavy metal cations in various R. metallidurans strains. The bacterial strains were DN444 (zntA-lacZ) (closed symbols) and DN445 (zntA-lacZ ${Delta}$ cadA) (open symbols). Moreover, these strains were left alone (squares) or complemented in trans with czcCBADRS' on plasmid pDNA385 (circles). The respective negative vector controls (plasmid pVDZ'2 only) gave results similar to the plasmid-free strains and are not shown. ß-Galactosidase activity is measured in units per milligram (dry weight [d.w.]).

View larger version (23K):
[in this window]
[in a new window]
FIG. 6. Induction of a cadA-lacZ operon fusion by heavy metal cations in various R. metallidurans strains. The bacterial strains were DN442 (cadA-lacZ) (closed symbols) and DN443 (cadA-lacZ ${Delta}$ zntA) (open symbols). Moreover, these strains were left alone (squares) or complemented in trans with czcCBADRS' on plasmid pDNA385 (circles). The respective negative vector controls (plasmid pVDZ'2 only) gave results similar to the plasmid-free strains and are not shown. ß-Galactosidase activity is measured in units per milligram (dry weight [d.w.]).

To study the influence of ZntA on the expression of CadA andvice versa, cadA-lacZ ${Delta}$ zntA and zntA-lacZ ${Delta}$ cadA strains were constructed.Moreover, this allowed the determination of the effects of othermetal cations on the expression of either gene. Neither cobalt(100 µM), Cu²⁺ (250 µM), nor lead nitrate (250 µM)induced zntA-lacZ in the ${Delta}$ cadA mutant strain (1.2 ± 0.2-fold,0.6 ± 0.2-fold, and 1.0 ± 0.4-fold induction,respectively [means ± standard deviations from threeindependent experiments]) or induced cadA-lacZ in the ${Delta}$ zntA strain(0.8 ± 0.2-fold, 0.5 ± 0.2-fold, and 1.2 ±0.1-fold induction, respectively). Nickel (100 µM) didnot induce cadA-lacZ ${Delta}$ zntA (1.6 ± 0.6-fold) and inducedzntA-lacZ ${Delta}$ cadA only slightly (1.9 ± 0.1-fold induction).Resistance to any of the four cations was not affected in thedouble deletion strains (data not shown). This indicated thatboth CadA and ZntA are specifically involved in zinc or cadmiumhomeostasis in R. metallidurans.

The presence or absence of CadA did not change the expressionprofile of zntA in response to increasing zinc or cadmium concentrations(Fig. 5). In contrast, expression of cadA could be induced byzinc only in the absence of ZntA (Fig. 6). Expression of cadAby cadmium in the absence of ZntA showed optimal induction at50 µM Cd²⁺, resulting in a 25-fold induction (Fig. 6A).Moreover, cadA was induced by cadmium concentrations lower than50 µM to a larger extent in the absence of ZntA than inits presence. In all four strains, expression levels of theoperon fusions were low after induction with 200 or 300 µMCd²⁺, probably due to toxic effects of cadmium. This showedthe importance of transcriptional regulation of cadA and zntAfor the assignment of the physiological function of either protein:while ZntA mediates homeostasis of both zinc and cadmium, CadAfunctions in vivo only in the export of cadmium.

CzcCBA fails to complement cadmium sensitivity of zntA cadA double knock-out strains. To gain insight into the complexity of efflux systems in R.metallidurans, the interplay of the ZntA/CadA system on onehand and the CzcCBA/CzcD export system on the other hand wasanalyzed. Plasmid pDNA385 contained the czcCBADRS' region ofthe czc determinant cloned under control of the constitutivelac promoter. This plasmid was transferred into R. metalliduransstrain AE104 and its mutant derivatives, and the influence ofCzcCBA/CzcD on metal resistance was studied (Table 2). The presenceof ZntA alone ( ${Delta}$ cadA deletion strain in comparison to doubledeletion strains) increased zinc resistance in R. metalliduransfivefold, the presence of CadA alone increased resistance threefold,and the presence of both CadA and ZntA increased resistancesixfold (strain AE104). However, the presence of CzcCBA/CzcDincreased zinc resistance 240-fold, independent of the presenceof either P-type ATPase. Thus, zinc is efficiently exportedby the Czc system before toxic concentrations are reached thatrequire the action of a P-type ATPase.

In contrast, the P-type ATPases were more important for cadmiumresistance than for zinc resistance (Table 2). The presenceof CadA alone increased cadmium resistance 300-fold, the presenceof ZntA increased resistance 250-fold, and the presence of bothincreased resistance 350-fold. However, expression of the Czcsystem in the absence of both ATPases increased cadmium resistanceonly 50-fold. At least one P-type ATPase was required to reachfull resistance, a 3,000-fold increase. This indicated thatR. metallidurans needs both CzcCBA and at least one P-type ATPasefor an effective detoxification of cadmium. On the other hand,zinc can be removed sufficiently by the action of CzcCBA alone.

Influence of the CzcCBA/CzcD system on induction of zntA and cadA. The presence of CzcCBA/CzcD strongly decreased induction ofeither P-type ATPase by cadmium (Fig. 4 and 5). Moreover, neithercadA (in a ${Delta}$ zntA strain) nor zntA could be induced by Zn²⁺ inthe presence of CzcCBA/CzcD, not even at metal concentrationsabove the MIC of cells that did not possess the Czc system.This clearly indicated that the action of CzcCBA/CzcD in thecell diminished concentrations of cadmium and zinc below thethreshold levels required for P-type ATPase gene expression.

Expression of the two P-type ATPase-encoding genes was alsoexamined in the presence of plasmid pDNA130, which carries theczcCBA operon and a truncated, inactive czcD' gene. Metal resistanceconferred by czcCBAD' to strain AE104 and to a cadA zntA doublemutant strain was identical to resistance conferred by czcCBADRS'(Table 2). Moreover, czcCBAD' and czcCBADRS' yielded similarresults when induction of zntA-lacZ in the presence and absenceof cadA and induction of cadA-lacZ in the presence and absenceof zntA by cadmium or zinc was determined (data not shown).Therefore, CzcCBA was responsible for the observed effects ofthe czcCBADRS' region on metal resistance and regulation ofznt or cadA expression, and the influence of CzcD could be ignored.

DISCUSSION

Top

Discussion

The presence of CzcCBA inhibits induction of cadA and zntA by zinc and cadmium. R. metallidurans harbors three known efflux systems that areinduced by zinc and cadmium, the czc system on plasmid pMOL30(16) and the two CPx-type ATPase-encoding genes cadA and zntAlocated on the bacterial chromosome (Fig. 1). The presence ofthe CzcCBA efflux complex yields the largest increase in zincand cadmium resistance (16) and prevented induction of zntAor cadA by either metal. Thus, CzcCBA removes Zn²⁺ and Cd²⁺very efficiently, and high expression levels of zntA and ofcadA are not needed for additional detoxification.

The main difference between induction of cadA and zntA by zincwas visible in the presence of the other P-type ATPase: inductionof cadA by zinc was completely inhibited by the presence ofeither CzcCBA or ZntA (Fig. 6B), while induction of zntA byzinc was inhibited by CzcCBA but not by CadA (Fig. 5B). Thisyielded the rank order of CzcCBA > ZntA > CadA for zincdetoxification, while all three systems seemed to be requiredfor full cadmium resistance.

Expression of the genes for CPx-type ATPases are usually regulated by cytoplasmic components. Since zntA and cadA are induced by heavy metals, regulatorsfor both genes probably exist. The identities of these regulatorsare unknown, but the genes for soft-metal-transporting ATPasesare usually regulated by a repressor belonging to the MerR orArsR-SmtB family of proteins (31). These proteins bind the inducingcations with high affinity to cysteine residues and interactdirectly with the promoter or operator region of the ATPase-encodinggene. In the case of MerR-type regulators, the protein is sittingdirectly at the promoter, exerting negative control, until theinducing metal binds (18). Therefore, expression of cadA andzntA in R. metallidurans is probably controlled by the cytoplasmicconcentration of zinc and cadmium in the bacterial cell.

CzcCBA decreases the cytoplasmic concentrations of zinc and cadmium very efficiently. Since constitutive expression of czcCBA prevents induction ofcadA or zntA by Zn²⁺ or Cd²⁺, and these two CPx-type ATPase-encodinggenes are probably regulated by cytoplasmic components, CzcCBAseems to be able to decrease the cytoplasmic concentrationsof zinc and cadmium very efficiently.

The RND protein AcrB, which is related to CzcA, contains vestibulesin the trimeric protein that link the central cavity to theperiplasm (21), so the structure of RND proteins may allow directperiplasmic access. The periplasmic headpieces of RND proteinsexporting organic molecules define the substrate range of thecorresponding RND-driven efflux complex (summarized in reference25), and methionine residues in the headpiece of the copper-exportingRND protein CusA from E. coli are essential for copper exportof the CusCBA complex (6). Despite all efforts, no cytoplasmicbinding sites for substrate cations could be identified in CzcA(7; K. Helbig, A. Legatzki, and D. H. Nies, unpublished data).Thus, the substrate-binding sites of RND-driven efflux systemsseem to be located in the periplasmic headpiece of the RND pumpprotein. This may imply access of substrates from the periplasmin addition to access from the cytoplasm or cytoplasmic membrane,as suggested previously (21). That way, cations would be preventedfrom entering the cytoplasm at an early stage of the cellularmetal uptake process, which may explain the high efficiencyof metal detoxification by RND-driven efflux systems like CzcCBA.

Function of the two P-type ATPases. Despite this high efficiency of metal detoxification by CzcCBA,at least one of the two P-type ATPases is essential for fullcadmium resistance in R. metallidurans. This shows that cadmium(much more than zinc) seems to some degree to be able to escapemetal removal by the CzcCBA system. Since CzcA was not ableto transport metal cations in vitro in the presence of glutathione(D. H. Nies, unpublished data), binding of cytoplasmic cadmiumto cellular thiol compounds may prevent their removal by CzcCBA.On the other hand, P-type ATPases seem to accept metals fromthiolate complexes as their true substrate in vivo (33). Sincecadmium has a higher affinity for thiolates than zinc does,this could be one reason for the importance of P-type ATPasesin R. metallidurans metal homeostasis.

Zinc, with its lower affinity to thiolates, could be sufficientlydetoxified by CzcCBA alone. Therefore, what is the use of ZntAas an additional system? When the three CPx-type ATPases ofR. metallidurans, PbrA, CadA, and ZntA, were compared, someinteresting differences were observed (data not shown). PbrA(798 amino acids [aa]) resembles the first described memberof this group of CPx-type ATPases, i.e., CadA (727 aa) fromStaphylococcus aureus (28), in size and overall structure. ZntAand CadA from R. metallidurans, on the other hand, are differentfrom these two proteins and from each other. CadA from R. metalliduranshas a unique size; due to a very long amino terminus, it hasa total of 984 aa. ZntA (784 aa), although similar in size toPbrA, contains an interesting histidine-rich amino terminus:the region from aa 20 to 55 exhibits 16 histidine residues,mostly separated by G, P, or charged amino acid residues.

The amino-terminal portion of CPx-type ATPases is not essentialfor transport (20), but it may regulate transport activity (2).This is even more important for ZntA than for CadA, becausezinc is an essential trace element and complete depletion ofthe cytoplasmic zinc pool has to be prevented. Thus, ZntA fromR. metallidurans may be able to export zinc only if sufficientamounts of this cation are bound to the amino-terminal histidineresidues of the protein, making it a highly specific detoxificationsystem for zinc cations in vivo.

In summary, zinc and cadmium are predominantly detoxified inR. metallidurans by the CzcCBA efflux system, which exportsthese cations from the periplasm and/or from the cytoplasm directlyinto the extracellular medium. The two CPx-type ATPases ZntAand CadA may be required to export cations bound to thiolatecomplexes (not the thiolate complexes) into the periplasm (forfurther export by CzcCBA?). Transport activity of ZntA may becarefully regulated by a zinc-sensing site at the amino terminusof the protein to prevent depletion of the anabolic zinc pool,essential for synthesis of zinc-containing proteins and growth.CadA, on the other hand, may be the main detoxification systemfor cadmium thiolate complexes and may serve as the final backupsystem for zinc resistance. Possibly, it is this fine-tuningof different metal transporters that allows R. metalliduransto survive in environments highly polluted with heavy metals.

ACKNOWLEDGMENTS

This work was supported in part by Hatch project 136713, NIEHSgrant ESO4940, and funds from EPA to C.R. and grant Ni262/3-3of the Deutsche Forschungsgemeinschaft and Fonds der ChemischenIndustrie to D.H.N.

Preliminary genomic sequence data for R. metallidurans wereobtained from the DOE Joint-Genome Institute (JGI) R. metalliduranssequencing project website. We thank Grit Schleuder for skillfultechnical assistance.

FOOTNOTES

* Corresponding author. Mailing address: Institut für Mikrobiologie, Kurt-Mothes-Str. 3, 06099 Halle, Germany. Phone: (49)-345-5526352. Fax: (49)-345-5527010. E-mail: d.nies{at}mikrobiologie.uni-halle.de.

REFERENCES

Top