Copper Acquisition Is Mediated by YcnJ and Regulated by YcnK and CsoR in Bacillus subtilis

Copper is an essential cofactor for many enzymes, and at overa threshold level, it is toxic for all organisms. To understandthe mechanisms underlying copper homeostasis of the gram-positivebacterium Bacillus subtilis, we have performed microarray studiesunder copper-limiting conditions. These studies revealed thatthe ycnJ gene encodes a protein that plays an important rolein copper metabolism, as it shows a significant, eightfold upregulationunder copper-limiting conditions and its disruption causes agrowth-defective phenotype under copper deprivation as wellas a reduced intracellular content of copper. Native gel shiftexperiments with the periplasmic N-terminal domain of the YcnJmembrane protein (135 residues) disclosed its strong affinityto Cu(II) ions in vitro. Inspection of the upstream sequenceof ycnJ revealed that the ycnK gene encodes a putative transcriptionalregulator, whose deletion caused an elevated expression of ycnJ,especially under conditions of copper excess. Further studiesdemonstrated that the recently identified copper efflux regulatorCsoR also is involved in the regulation of ycnJ expression,leading to a new model for copper homeostasis in B. subtilis.

INTRODUCTION

Top

INTRODUCTION

Transition metals such as copper, iron, and zinc play importantroles in bacterial metabolism as essential cofactors for numerousenzymes. However, when the concentrations of these metals increasein the cell, they undergo undesirable redox reactions or bindinappropriately to the metal binding sites of several enzymes,thereby altering their specificity and finally leading to toxiceffects (4, 24). Thus, the acquisition of these metals has tobe strictly balanced in the cells, and hence bacteria tend toevolve in response to the bioavailability of metals to sustainthe metal homeostasis.

Copper homeostasis is well studied in gram negative bacteriasuch as Enterococcus hirae and Escherichia coli. In E. hirae,the process occurs at the plasma membrane and includes fourgenes, i.e., copY, copZ, copA, and copB. copA and copB encodetwo integral membrane P-type ATPases that are necessary forthe transport of copper into the cells under copper-limitingconditions (20). CopA, which serves to import copper, interactswith CopZ, which acts as a copper chaperone. CopZ then chaperonesthe metal atom to the transcriptional repressor CopY, therebyreleasing the repression of copper homeostasis genes (28, 29).In E. coli, there are several sets of genes which are responsiblefor copper homeostatic functions. The cusRS genes form a sensor-regulatorypair which senses copper and activates the cusCFBA genes (19).CusF is a periplasmic copper binding protein, while cusCBA geneproducts are homologous to a family of proton/cation antiportercomplexes (7). In a second copper efflux system, regulated byCueR, a MerR-like transcriptional activation controls two copperefflux genes, copA and cueO (19), whereas cueO encodes a multicopperoxidase. In addition, the cutABCDEF genes are also believedto be involved in copper uptake, storage, delivery, and efflux(21, 23). Copper efflux is carried out mainly by heavy metalexporters which belong primarily to the integral membrane proteinfamily of P-type ATPases (8, 9, 22, 27, 33), whose expressionis controlled mainly at the level of transcription. These P-typeATPases are functional in translocating Cu(I) across the cytoplasmicmembrane. The recently discovered copper-specific repressorCsoR in Mycobacterium tuberculosis belongs to an entirely newset of copper-responsive repressors, whose homologs are widelyspread in all major classes of eubacteria (16). CsoR from Bacillussubtilis, which is encoded upstream of the copZA operon, is37% homologous to M. tuberculosis CsoR, and elevated copperlevels in B. subtilis are sensed by CsoR, which leads to derepressionof the copZA copper efflux operon (16, 26).

In contrast, in Saccharomyces cerevisiae, high-affinity copperuptake is mediated by two transmembrane transport proteins,Ctr1p and Ctr3p. Prior to uptake, Cu(II) is reduced to Cu(I)by Cu(II)/Fe(III)-specific reductases Fre1p and Fre2p (11).The CTR1, CTR3, and FRE1 genes are activated under copper starvationand repressed under copper repletion by the copper-sensing transcriptionfactor Mac1p (6, 36). Studies undertaken to understand the copperresistance in Pseudomonas syringae strains that infect tomatorevealed that the copper resistance operon copABCD is plasmidencoded and is regulated by the two-component system copRS (3,4, 15). Similar copper resistance (pcoABCD) and regulatory (pcoRS)genes are also plasmid encoded in E. coli (14, 31, 35). In spiteof high homology between these two systems, the resistance mechanismsdealing with an excess of copper inside the cell are completelydifferent. Copper resistance in E. coli is achieved mainly bya copper efflux mechanism, whereas P. syringae performs sequestrationof excess cytosolic copper (15).

Here, we explore the role of B. subtilis YcnJ, which is a homologof P. syringae CopCD, in copper homeostasis. The ycnJ gene fromB. subtilis is highly induced under copper-limiting conditions,and a ${Delta}$ ycnJ mutant shows reduced growth under copper-limitingconditions. Uptake components for copper in B. subtilis havenot been reported so far, and we demonstrate that YcnJ is acandidate for such a function. The ycnK gene located upstreamfrom ycnJ was investigated and shown to encode a transcriptionalregulator which acts, in addition to the investigated regulatorCsoR, as a copper-specific repressor for ycnJ.

MATERIALS AND METHODS

Top

MATERIALS AND METHODS

Bacterial strains, plasmids, and media. The bacterial strains and plasmids used in this study are listedin Table 1. Bacillus subtilis ATCC 21332 (wild type [WT]) wasgrown in Belitsky minimal medium (BMM) supplemented with 0.5%(wt/vol) glucose as a carbon source and with all essential nutrientsrequired (30). Freshly prepared CuCl (0.5 mM) was used to maintainthe copper excess conditions, and 0.25 mM bathocuprione disulfonate(BCS) (Sigma-Aldrich) was used as a Cu(I)-specific chelatorfor maintaining copper-limiting conditions. Unless otherwiseindicated, liquid medium was inoculated from an overnight precultureand incubated at 37°C with constant shaking at 225 rpm.All glassware were washed with 0.1 M HCl and double-distilledwater before autoclaving. The antibiotics erythromycin (1 µgml^–1) and lincomycin (25 µg ml^–1), both fortesting macrolide-lincosamide-streptogramin B resistance, andspectinomycin (100 µg ml^–1) were used for the selectionof various B. subtilis mutants after construction. For selectionof E. coli Top10 strains with transformed plasmids, the antibiotickanamycin (50 µg ml^–1) was used. E. coli strainBL-21 was used for protein overexpression. For RNA preparations,bacteria were harvested at mid-log phase.

View this table:
[in this window]
[in a new window]

TABLE 1. Strains and plasmids used in this study

DNA manipulations and genetic techniques. DNA preparations and transformations were carried out as describedpreviously (12, 25). Electroporation was used for the transformationof plasmids into E. coli Top10 cells. Homologous recombinationwas used for transforming the B. subtilis ATCC 21332 strainfor mutant construction. Restriction enzymes, T4 DNA ligase,and calf intestinal phosphatase were used according to the manufacturer'sinstructions (New England Biolabs).

Mutant construction. Deletion mutants were generated by the long flanking homologyPCR method (34). In the first-round PCR, long flanking homologousPCR fragments were amplified from upstream and downstream regionsof the gene to be deleted. The 3' ends of the resulting homologousPCR products were designed to be complementary to the resistancecassette and were used in the second-round PCR, generating afusion construct which replaces the gene of interest with aresistance marker to facilitate the selection of the mutanton antibiotic plates. The primers used in generating the mutantsare listed in Table 2. All PCRs were performed using PlatinumPfx DNA polymerase (Invitrogen). Chromosomal DNA of B. subtilisATCC 21332 was used as a template to amplify the correspondingupstream and downstream flanking regions. The Expand long-templatePCR system was used to fuse the homologous flanks with the correspondingresistance markers. PCR fusion products were used directly forthe transformation of B. subtilis strain ATCC 21332 to generatethe ${Delta}$ csoR, ${Delta}$ ycnK, ${Delta}$ ycnJ, and ${Delta}$ csoR ${Delta}$ ycnK mutants. Transformants wereselected on the respective antibiotic-containing LB plates.Chromosomal DNA was isolated from all the mutants, and the recombinationswere confirmed by PCR. The erythromycin resistance cassettesused for the construction of the ${Delta}$ csoR and ${Delta}$ ycnK single mutantswere amplified from the pMUTIN vector. To generate the ${Delta}$ ycnJmutant, the spectinomycin resistance cassette was amplifiedfrom the pUS19 vector, while the resistance cassettes for the ${Delta}$ csoR ${Delta}$ ycnK double mutant were amplified from pMUTIN and pUS19,respectively.

View this table:
[in this window]
[in a new window]

TABLE 2. Primers

Purification of CsoR, YcnK, and the N-terminal 135 amino acids (aa) of YcnJ. The open reading frames of genes csoR, ycnK, and ycnJ were amplifiedby PCR using chromosomal DNA isolated from B. subtilis strainATCC 21332 as the template and cloned with NcoI and XhoI sitesinto the pET28a+ vector for overexpression. The ligated plasmidswere then transformed into E. coli DH5 ${alpha}$ cells. The resultingplasmids were confirmed by restriction analysis for the integrationof the fragment and transformed into BL21 cells using electroporation.Overnight cultures were grown by inoculating an isolated colonyfrom a plate into 5 ml LB medium containing kanamycin (50 µgml^–1). The overnight cultures were used to inoculate 2liters of LB medium containing kanamycin (50 µg ml^–1)with a starting optical density at 600 nm (OD₆₀₀) of 0.05. Inoculatedcultures were grown under continuous shaking at 225 rpm at 35°C,and the temperature was decreased to 30°C after 1 hour.When the OD₆₀₀ of the cells reached 0.5 to 0.6, IPTG (isopropyl-β-D-thiogalactopyranoside)at a final concentration of 0.1 mM was added to the cultureflasks and growth was continued for 4 hours. Cells were harvestedby centrifugation (Sorvall RC 5B plus), and the resulting pelletswere resuspended in HEPES-A buffer (50 mM HEPES, 300 mM NaCl[pH 7.5], 1 mM dithiothreitol [DTT]) and lysed with EmulsiFlex-C5Avestin. The lysate obtained was clarified by centrifugation(Sorvall RC 26 plus) at 17,000 rpm for 30 min, and an Ni-nitrilotriaceticacid (NTA) column was used to purify the protein using a lineargradient with HEPES-B buffer (50 mM HEPES, 300 mM NaCl, 250mM imidazole [pH 7.5], 1 mM DTT). The purified protein was dialyzedagainst HEPES-A buffer containing 100 mM NaCl. Protein purityof more than 90% was observed by Coomassie blue staining ofa sodium dodecyl sulfate-polyacrylamide gel.

Native gel electrophoresis. Purified protein samples ( $~$ 100 µM) were incubated with200 µM Cu(I) or Cu(II) for about 15 to 30 min at roomtemperature and loaded onto 6% continuous native polyacrylamidegels. Samples were run at 100 V and 10 mA for about 4 to 5 huntil the bromophenol blue ran out of the gel. Gels were stainedusing Coomassie blue and destained using 10% acetic acid.

Microarray analysis. For microarray analysis, both the WT (ATCC 21332) and the ${Delta}$ csoRmutant were grown in BMM under copper-replete conditions (growthin the presence of 0.5 mM CuCl) and copper-depleted conditions(growth in the presence of the copper-specific chelator BCSat 0.25 mM). Cultures were harvested in the mid-log phase forRNA extraction. The Macaloid/Roche method was used for the RNAextraction (13). Concentrations of RNA were measured using thenanodrop method. For reverse transcription, a solution containing18 µl annealing mix (10 to 20 µg total RNA and 2µl random nonamers adjusted to a final volume of 18 µlwith nuclease-free water) was incubated for 5 min at 70°Cand 10 min at 4°C for annealing. Reverse transcription wasperformed by addition of this annealing mix to a solution containing6 µl Superscript III buffer (supplied with the reversetranscriptase), 10 mM DTT, nucleotide master mix containingaminoallyl-dUTP, and 300 U Superscript III reverse transcriptase(Invitrogen). cDNA was synthesized overnight at 42°C ina total volume of 30 µl. The aminoallyl-modified cDNAwas incubated with the CyDye NHS ester (Cy3 or Cy5 monoreactivedye) at room temperature in the dark for 60 to 90 min. LabeledcDNAs were purified using Nucleo Spin Extraxt II columns, andthe dye incorporation was measured using the nanodrop method.Equal quantities of Cy3/Cy5-incorporated cDNAs were mixed, driedin a Speedvac, and then dissolved in 5 µl H₂O, followedby heating at 94°C for 2 min. The heated sample was subsequentlymixed with 30 µl preheated hybridizing buffer (68°C),hybridized onto microarray glass slides, and incubated overnightat 68°C in a hybridization oven.

Microarray data analysis. Hybridized DNA arrays were read using a GenePix 4200AL autoloader(Axon Instruments), and the data obtained were processed withArrayPro 4.5 (Media Cybernetics Inc., Silver Spring, MD) ArrayVisionsoftware. Expression levels were processed and normalized (Lowessmethod) with Micro-Prep (10, 32). The ln-transformed ratiosof the expression levels of mutant versus WT were subject toa t test using the Cyber-T tool (2). Three independent measurementsfor each condition along with a dye swap were analyzed. Theresults obtained were averaged, the raw data were processedto Cyber-T web interface software for the calculation of theexpression ratios, and the data were exported to Microsoft Excel.

Estimation of copper concentrations inside cells. Total cytoplasmic copper concentrations were measured usinginductively coupled plasma mass spectrometry. B. subtilis strainATCC 21332 and the ${Delta}$ csoR mutant were grown in BMM overnight.Fresh BMM (100 ml) either with 0.5 mM copper in excess or undercopper-limiting conditions achieved by addition of 0.25 mM BCSwas inoculated with overnight cultures with a starting OD₆₀₀of 0.05, and the cells were harvested in mid-log phase. Cellswere centrifuged at 13,000 rpm (18,000 x g) for 5 min, and thepellets were washed three times with buffer containing 10 mMTris-HCl (pH 7.5) and 1 mM EDTA and finally with MilliQ water.Cells were dried overnight at 85°C, and the total copperconcentration was determined by breaking the cells using nitricacid.

Dot blot analysis. B. subtilis strains were grown under normal (BMM), copper limited(BMM plus 0.25 mM BCS), and copper-replete (BMM plus 0.5 mMcopper in excess) conditions. Overnight cultures were inoculatedinto fresh medium to an initial OD₆₀₀ of 0.05, and cells wereharvested at an OD₆₀₀ of 0.25. Total RNA was isolated from thesecells using the RNAZol method (http://microarrays.nki.nl/download/protocols.html).RNA concentrations were measured using the nanodrop method at260 nm/280 nm. The ratios of RNA concentration to protein concentrationwere above 1.65 in all samples. Denaturing gel electrophoresiswas run to test the quality of RNA for 16S and 23S RNAs. Twomicrograms of RNA from each sample was subsequently dotted ontoa nylon membrane using a dot blot apparatus and hybridized afterUV cross-linking with a UTP-11-digoxigenin-labeled antisenseRNA probe specific for ycnJ mRNA. The riboprobe was synthesizedby in vitro transcription using T7 RNA polymerase. The T7 promotersequence was introduced into the PCR product of the ycnJ geneby using primers 5'-AGCTCGTCAAACGGACGAGACG-3' and 5'-TAATACGACTCACTATAGGGGAAATCCATCAAAATGCCGACCG-3'(the T7 promoter extension is underlined). After hybridizationand washing, the filters were treated with a digoxigenin-specificantibody fragment conjugated with alkaline phosphatase (Roche)and AttoPhos (Amersham Biosciences) as an enhanced chemifluorescencesubstrate. The hybridization signals were detected with a Storm860fluorescence imager, and relative signal quantification wasperformed with ImageQuant software.

RESULTS AND DISCUSSION

Top

RESULTS AND DISCUSSION

Microarray analyses reveal ycnJ as a putative copper uptake determinant. In order to gain insights into the transcriptional responseunder various copper conditions, microarray experiments wereperformed with the following combinations: (i) WT (BMM withoutCu) compared with WT (BMM), (ii) ${Delta}$ csoR mutant (BMM without Cu)compared with WT (BMM without Cu), (iii) WT (BMM plus Cu) comparedwith WT (BMM), and (iv) ${Delta}$ csoR mutant (BMM plus Cu) compared withWT (BMM plus Cu). The essential results from these experimentsare summarized in Table 3. B. subtilis WT cultures grown undercopper-limiting conditions (without Cu) show a significant increasein the upregulation of the copper-responsive genes ycnI, ycnJ,ycnK, and ycnL. In contrast, in the WT the same genes are significantlydownregulated in copper-replete medium (plus Cu). Thus, we speculatedthat these genes play a possible role in copper acquisition.To investigate this hypothesis, deletion mutants were constructedand checked for their ability to grow under different copperavailability conditions. The ${Delta}$ ycnK mutant showed no or littledifference in growth under copper-limiting conditions (Fig.1B). In contrast, it exhibited enhanced growth under copperexcess conditions (Fig. 1A). On the other hand, the ${Delta}$ ycnJ mutantexhibited a growth-defective phenotype under copper-limitingconditions (Fig. 1B), suggesting an important role for YcnJin copper import. In case of the ${Delta}$ ycnL mutant, no effect on growthunder both conditions was observed (data not shown).

View this table:
[in this window]
[in a new window]

TABLE 3. Microarray results

View larger version (27K):
[in this window]
[in a new window]

FIG. 1. (A) Analysis of copper-dependent growth in BMM with 1 mM copper in excess. Growth curves of the WT (•), the ${Delta}$ ycnJ mutant ( ${blacktriangleup}$ ), and the ${Delta}$ ycnK mutant ( ${blacksquare}$ ) are shown. The insets show the phenotypes of the WT and the ${Delta}$ ycnJ and ${Delta}$ ycnK mutants on BMM with 1 mM copper in excess. (B) Analysis of copper-dependent growth in BMM with 0.5 mM BCS. Growth curves of the WT (•), the ycnJ mutant ( ${blacktriangleup}$ ), and the ${Delta}$ ycnK mutant ( ${blacksquare}$ ) are shown. The insets show the phenotypes of the WT and the ${Delta}$ ycnJ and ${Delta}$ ycnK mutants on BMM agar with 0.5 mM BCS.

The CopC and CopD gene products of P. syringae exhibit a highsequence identity (28%) with YcnJ. The N-terminal region ofYcnJ ( $~$ 135 aa) is homologous to the periplasmic protein CopC,a copper binding protein which is involved in copper uptakein P. syringae (1, 5). The putative copper binding amino acidresidues (His-24, Glu-51, Asp-108, and His-110) identified withinthe N-terminal region of YcnJ are highly homologous to the Cu(II)binding sites in CopC (1). The C-terminal region of YcnJ (401aa) represents a transmembrane domain that is homologous tothe inner membrane copper transport protein CopD of P. syringae(1, 5). Alignments of the N- and C-terminal regions of YcnJwith CopC and CopD are shown (Fig. 2). For the genes ycnK andycnL, encoding a putative transcriptional regulator and a putativesignal permease, respectively, several metal binding sites (Cys-x-x-Cysand Cys-x-Cys) were identified. YcnK was identified as a putativetranscriptional regulator with a conserved helix-turn-helixmotif in its N-terminal region and a C-terminal region witha sensor function. The sensor function is defined by a NosLsuperfamily motif which indicates specific binding of Cu(I)(17). Apart from these genes, the copper-inducible copZA operon,encoding a copper chaperone and an efflux ATPase, was foundto be strongly upregulated in the ${Delta}$ csoR mutant, suggesting aconsiderable role of CsoR in copper efflux as recently described(26).

View larger version (63K):
[in this window]
[in a new window]

FIG. 2. Alignment of amino acid sequences of P. syringae CopC and CopD and B. subtilis YcnJ (ClustalW). NT, N terminal; CT, C terminal. Arrows indicate conserved copper binding residues. Highlighted amino acids represent the predicted transmembrane domains.

Regulation of ycnJ by YcnK and CsoR. The initial transcriptome studies were followed by a closerexamination of ycnJ regulation with respect to different copperconcentrations and possibly involved transcription factors.As a first candidate, we addressed the putative transcriptionalregulator-encoding gene ycnK, which is located directly upstreamfrom ycnJ. A ycnK deletion mutant was constructed and grownunder different copper conditions along with the WT. Total RNAwas isolated at mid-log phase, and ycnJ gene expression wasestimated semiquantitatively by use of dot blots (Fig. 3). Asexpected, transcription of ycnJ in the WT was elevated undercopper-limiting conditions. In comparison to the WT, the ycnKmutant showed an upregulation of ycnJ expression, especiallyunder copper excess conditions (Fig. 3A). Further in this context,the effect of increasing copper concentrations on ycnJ geneexpression was tested, and the ${Delta}$ ycnK mutant was found to upregulateycnJ expression during copper excess approximately twofold comparedto the WT (Fig. 3B). This points to a function of YcnK in whichit acts as a negative regulator of ycnJ. Since this functionis present mainly under conditions of high copper concentrations,YcnK is predicted to use copper as a corepressor. In addition,enhanced growth of the ycnK mutant under copper excess conditionswas observed (Fig. 1A). Thus, as long as toxic copper concentrationsare compensated for by copper efflux detoxification systemssuch as CopZA, induction of the predicted copper uptake systemYcnJ is not detrimental for cell growth without carbon and energysource limitation.

View larger version (32K):
[in this window]
[in a new window]

FIG. 3. Transcriptional analysis of ycnK- and csoR-dependent ycnJ expression. Two micrograms of total RNA isolated from the WT and mutants under normal, 0.25 mM BCS, and 0.5 mM copper excess conditions was blotted onto a nylon membrane by dot blotting and hybridized with a digoxigenin-UTP-labeled antisense riboprobe specific for the ycnJ transcript. Hybridization signals were detected by using a digoxigenin-specific antibody fragment conjugated with alkaline phosphatase and AttoPhos as chemifluorescence substrate. (A) ycnK-dependent expression of ycnJ with different copper concentrations. (B) ycnK-dependent expression of ycnJ under increasing copper concentrations. (C) Expression of ycnJ in the WT and the ${Delta}$ ycnK and ${Delta}$ csoR ${Delta}$ ycnK mutants under normal conditions.

As a second putative candidate for ycnJ regulation, we examinedthe recently described copper efflux regulator CsoR (16, 26),according to the finding of ycnJ upregulation in the ${Delta}$ csoR backgroundduring the microarray studies. Since absence of the CsoR repressorleads to strong derepression of the copZA copper efflux system(26), effects of CsoR on ycnJ expression might be regarded asrather indirect via modulating the intracellular copper concentrationand, in the course of that, also YcnK activity. However, whenthe ${Delta}$ csoR and ${Delta}$ ycnK backgrounds were combined in a ${Delta}$ csoR ${Delta}$ ycnK doublemutant which was tested for ycnJ expression, an additional elevationof ycnJ expression compared to that in the ${Delta}$ ycnK mutant was observed(Fig. 3C), suggesting also a direct participation of CsoR inycnJ regulation.

Estimation of intracellular copper content. To further verify the predicted roles of ycnJ and ycnK as acopper uptake mediator and corresponding regulator, respectively,total intracellular copper contents were measured by using inductivelycoupled plasma mass spectrometry analysis. These studies revealedthat the ${Delta}$ ycnK mutant contains approximately double the amountof cytoplasmic copper (511.1 ppb) in the WT (278,87 ppb) andthe ${Delta}$ ycnJ mutant (205.0 ppb). These high values are a resultof copper accumulation under copper excess conditions. In agreementwith the dot blot results, these findings suggest that YcnKmay act as a negative transcriptional regulator of copper uptakethat is active in the presence of copper. In addition, the entirecopper contents within the WT and ${Delta}$ ycnJ cells under normal andcopper-limiting conditions were determined. The results revealedthat the amount of copper in WT cells grown in the presenceof the copper-specific chelator BCS is approximately twofoldhigher (3.58 ppb) than that in cells those grown without theaddition of BCS (1.84 ppb). This might be a possible consequenceof ycnJ upregulation under copper-limiting conditions, wherethe ${Delta}$ ycnJ mutant under normal conditions holds only 1.2 ppb (Fig.3A). The total copper content measured in the ${Delta}$ ycnJ mutant whengrown in the presence of BCS was found to be 1.57 ppb and thusmore than twofold less than that in the WT under these conditions.Together with the growth experiments, this supports the supposedrole for YcnJ in copper acquisition under copper-limiting conditions.

Copper-induced oligomerization of CsoR and YcnJ. We cloned and overexpressed CsoR and the cytosolic domain (N-terminal135 aa) of YcnJ to examine possible formation of oligomericcomplexes in the presence of copper by using native gel electrophoresis.Polyacrylamide gels (6%) were loaded with assay mixtures containingprotein samples that were incubated with and without 0.1 mMCuCl and 0.1 mM DTT. DTT was added to minimize the conversionof Cu(I) to Cu(II). A gel shift of the CsoR protein sample wasobserved in the presence of 0.1 mM CuCl and 0.1 mM DTT (Fig.4B). Binding was also tested in the presence of the strong metalchelator EDTA. While incubation of a protein sample with 0.5mM EDTA alone resulted in no shift, the shift was not abolishedin the presence of EDTA and copper (Fig. 4B), indicating thatCsoR has higher affinity to Cu(I) than EDTA. A similar observationhas been made previously in binding competition experimentswith CsoR and BCS (16). To define the half-maximal copper concentration(Cu_0.5), it was necessary to saturate the CsoR protein; differentcopper concentrations of between 10 and 80 µM were addedto the assay mixture, keeping the protein concentration constantat 80 µM. The formation of cysteine thiolate-copper complexwas measured at 240 nm (Fig. 5), and the calculated Cu_0.5 wasfound to be at 35.5 µM, suggesting a Cu(I)-CsoR complexstoichiometry of 1:1.

View larger version (31K):
[in this window]
[in a new window]

FIG. 4. Copper-induced oligomerization. (A) The N-terminal part (135 aa) of recombinant YcnJ protein, purified using Ni-NTA chromatography, was loaded on denaturing 17% sodium dodecyl sulfate gel along with markers. The molecular mass of the protein was observed to be 16.5 kDa, including the His₆ tag and two additional amino acids before the start codon (left panel). A native 6% polyacrylamide gel was loaded with 15 µg of purified protein either without metal preincubation as a control (first lane) or after incubation with either 0.2 mM CuCl or 0.2 mM CuSO₄ (right panel). (B) CsoR recombinant protein, purified using Ni-NTA chromatography, was loaded on a denaturing 17% gel along with markers, and the molecular mass of the protein was observed to be 12.5 kDa, including the His₆ tag (left panel). Copper binding studies were performed in a 6% native gel, in which lanes were loaded with 80 µg purified protein incubated without or with 200 µM Cu(I) and/or 100 µM EDTA as indicated (right panel). (C) YcnK recombinant protein, purified using Ni-NTA chromatography, was loaded on a denaturing 17% gel along with markers, and the molecular mass of the protein was observed to be 23 kDa, including the His₆ tag (left panel). Metal binding studies with purified proteins were performed in 6% native gels. Lane 1 is loaded with 100 µg purified protein. Protein samples incubated with 200 µM Cu(I) and 200 µM Cu(II) are loaded in lanes 2 and 3.

View larger version (9K):
[in this window]
[in a new window]

FIG. 5. Estimation of cysteine thiolate bond formation. Purified CsoR protein (80 µM) was incubated with different copper concentrations ranging from 10 µM to 80 µM, and the corresponding cysteine thiolate-copper complex formation was measured at 240 nm. The values obtained were plotted on a graph, and the Cu_0.5 was determined.

Experiments performed with the recombinant periplasmic domainof YcnJ (N-terminal 135 aa) exhibited oligomerization specificallyin the presence of Cu(II), which resulted in a clear shift ofthe preincubated protein under these conditions (Fig. 4A). Theshift observed upon incubation with Cu(I) was rather weak andmight also result from partial oxidation of Cu(I) to Cu(II).However, these findings suggest that YcnJ recruits into an oligomericstate if copper sensing and/or transport into the cell is mediated.The specific response of the predicted periplasmic N-terminaldomain of YcnJ to Cu(II) further supports its role in uptakeof extracellular oxidized copper, whereas copper-responsiveregulators such as CsoR are specific for the intracellular copperin its reduced state.

In the case of YcnK, which was also recombinantly expressedand tested for copper-induced oligomerization, no such oligomerizationin the presence of copper was observed (Fig. 4C). However, sinceoligomerization may also take place in the absence of copperand might additionally become further stabilized but not alteredby addition of the metal, as already suggested for M. tuberculosisCsoR (16), there is yet no indication that YcnK does not oligomerizeor does not bind copper at all.

Conclusions. Transcriptome studies were performed to identify genes involvedin copper homeostasis in B. subtilis. So far, copper transportin B. subtilis is known only as a function of efflux, whichis mediated by the CsoR-dependent CopZA system and the nonspecificcation diffusion facilitator CzcD, which is repressed by theArsR homolog CzrA (18, 26). Components and mechanisms of copperuptake have not yet been identified. In our approach, we haveidentified genes that were upregulated by copper deprivationand downregulated under copper excess. The ycnJ gene was especiallyhighly upregulated under copper-limiting conditions. The sequencehomology studies reveal that YcnJ is highly homologous at itsN terminus to CopC and at its C terminus to CopD from P. syringae.Unlike P. syringae, in which copper uptake is assisted by twodistinct proteins (CopC and CopD), B. subtilis YcnJ is organizedin a single polypeptide chain that facilitates the direct transferof copper ions across the membrane. Studies undertaken withP. syringae demonstrate either that the CopC protein could interactwith CopA and perhaps the outer membrane protein CopB to performcopper sequestration or that CopC along with CopD may functionin copper uptake. Disruption of the ycnJ gene in B. subtilisresulted in a growth-defective phenotype under copper-limitingconditions and a reduced intracellular copper content. Thus,these findings indicate that the primary role of YcnJ in B.subtilis is associated with copper uptake. A putative resistancefunction as observed for CopC in P. syringae cannot be excluded.However, since this resistance was described for the periplasmiccompartment, this might be a rather secondary function in B.subtilis. In an attempt to find the possible transcriptionalfactors that regulate the expression of ycnJ, mutants with adeletion of the unknown transcriptional regulator gene ycnKin combination with a deletion of the recently identified copper-sensingrepressor gene csoR were constructed and the ycnJ expressionwas quantified using dot blots. The ${Delta}$ ycnK mutant showed elevatedexpression of ycnJ compared to the WT, especially under copperexcess conditions. Expression was further elevated in the backgroundof the ${Delta}$ csoR ${Delta}$ ycnK double mutant, suggesting that both regulatorsparticipate in ycnJ expression control. The current model forcopper homeostasis for B. subtilis (Fig. 6) shows the novelcomponents presented here and indicates the regulatory connectionbetween copper uptake and efflux systems. As far as this interplayhas been investigated, it points out the demands on a systemthat is developed to maintain the essential accurate levelsof copper inside the cell and, at the same time, to avoid passageover the critical threshold of copper toxification in orderto allow proper physiological function.

View larger version (21K):
[in this window]
[in a new window]

FIG. 6. Current model of copper homeostasis in B. subtilis, including functional components for copper uptake and efflux as well as their cognate repressors. Depending on their association with copper, the active state of transcriptional repressors YcnK and CsoR is shown in green, and the inactive state of transcriptional repressors is shown in red. The negative regulation of components (–) is indicated with dashed arrows. Copper sensing (s) is indicated with dotted arrows. Cu, copper; CM, cytoplasmic membrane; in, intracellular; ex, extracellular.

ACKNOWLEDGMENTS

We gratefully acknowledge the Deutsche Forschungsgemeinshaftand Fonds der Chemischen industry for financial support.

FOOTNOTES

* Corresponding author. Mailing address: Fachbereich Chemie/Biochemie der Philipps-Universität Marburg, Hans-Meerwein-Str., D-35032 Marburg, Germany. Phone: 49 6421 2825722. Fax: 49 6421 2822191. E-mail: marahiel{at}staff.uni-marburg.de

Published ahead of print on 23 January 2009.

REFERENCES

Top