fslE Is Necessary for Siderophore-Mediated Iron Acquisition in Francisella tularensis Schu S4

Strains of Francisella tularensis secrete a siderophore in responseto iron limitation. Siderophore production is dependent on fslA,the first gene in an operon that appears to encode biosyntheticand export functions for the siderophore. Transcription of theoperon is induced under conditions of iron limitation. The fslgenes lie adjacent to the fur homolog on the chromosome, andthere is a canonical Fur box sequence in the promoter regionof fslA. We generated a ${Delta}$ fur mutant of the Schu S4 strain ofF. tularensis tularensis and determined that siderophore productionwas now constitutive and no longer regulated by iron levels.Quantitative reverse transcriptase PCR analysis with RNA fromSchu S4 and the mutant strain showed that Fur represses transcriptionof fslA under iron-replete conditions. We determined that fslE(locus FTT0025 in the Schu S4 genome), located downstream ofthe siderophore biosynthetic genes, is also under Fur regulationand is transcribed as part of the fslABCDEF operon. We generateda defined in-frame deletion of fslE and found that the mutantwas defective for growth under iron limitation. Using a plate-basedgrowth assay, we found that the mutant was able to secrete asiderophore but was defective in utilization of the siderophore.FslE belongs to a family of proteins that has no known homologsoutside of the Francisella species, and the fslE gene producthas been previously localized to the outer membrane of F. tularensisstrains. Our data suggest that FslE may function as the siderophorereceptor in F. tularensis.

INTRODUCTION

Top

INTRODUCTION

Francisella tularensis, the etiologic agent of the disease tularemia,belongs to a deeply divergent clade of gammaproteobacteria (13).The organism has a small genome and is auxotrophic for numerousamino acids and nutrients that it must therefore acquire fromits environment (18). In the mammalian host, the bacterium isintracellular, replicating within macrophages and other cells,such as hepatocytes.

The survival of pathogens within the host is dependent on theability to acquire requisite nutrients. One such essential nutrientis iron, which is largely sequestered within protein complexesand is consequently limiting in the host environment. To circumventthis problem, pathogenic bacteria express specific mechanismsto acquire iron.

We and others have previously shown that different F. tularensissubspecies express siderophores as one mechanism to acquireiron from the environment (7, 26). The siderophore producedby the live vaccine strain (LVS) (holarctica subspecies) andthe virulent Schu S4 strain (tularensis subspecies) of F. tularensisis a polycarboxylate molecule, structurally similar to rhizoferrin,expressed by Rhizopus spp. and Ralstonia pickettii strains (8,21, 26). Expression of the siderophore is dependent on a putativesiderophore synthetase encoded by fslA (also called figA), thefirst gene in an operon which is conserved across the differentF. tularensis subspecies (7, 26).

Iron uptake in bacteria is commonly under the control of theFur (ferric uptake regulator) protein, originally identifiedbecause mutation in the fur gene resulted in constitutive expressionof multiple iron uptake genes in Salmonella enterica serovarTyphimurium and Escherichia coli (10, 15; reviewed in reference11). Fur is a Fe²⁺-dependent DNA binding protein that bindsto a specific sequence (the Fur box) present in promoter regionsof target genes and functions as a repressor under iron-repleteconditions. Under iron limitation, the Fur protein becomes deferratedand consequently loses DNA binding capability, resulting inderepression of transcription. The fsl genes in F. tularensisare located downstream of the fur homolog (locus FTT0030c) inthe chromosome, and the fslA gene has a canonical Fur box sequencein its promoter region (see Fig. 2A). This suggests that thefsl genes may be regulated by the Fur repressor in responseto iron levels, as seen in other bacteria.

View larger version (37K):
[in this window]
[in a new window]

FIG. 2. The fur-fsl region and transcriptional analysis of fsl genes. (A) Representation of the fur-fsl region of the chromosome. The locations of primers used in RT-PCR are shown. (B) qPCR analysis of fslA and fslE expression in the ${Delta}$ fur mutant. cDNAs prepared from Schu S4 and from GR203 were tested for fslA and fslE expression relative to that of trpB as an internal standard. Reactions were run in triplicate, and results are represented as averages with standard deviations. Note that the y axis for fslA expression is a log scale. (C) RT-PCR to delineate the fsl operon. cDNA prepared from GR203 was used in PCR with primer pairs to detect transcription across genetic loci as follows: 109-112 for fur and fslA, 110-112 for fslA, 137-132 for fslAB, 182-119 for fslBC, 138-136 for fslCD, 178-165 for fslDE, 184-211 for fslEF, and 204-201 for fslF and FTT0023c. "–" represents negative controls, where reverse transcriptase was left out of the cDNA reaction; "+" indicates reactions with cDNA; and "g" represents reactions with gDNA as a template. "M" represents the 1-kb DNA ladder (Invitrogen).

All siderophore-mediated iron uptake systems characterized todate in gram-negative bacteria are dependent on the ubiquitoustonB, exbB, and exbD genes (reviewed in reference 12). The innermembrane proteins encoded by these genes form a complex whichis thought to provide the energy requisite for uptake of thesiderophore by the cognate siderophore receptor in the outermembrane. This uptake is dependent on interaction of TonB withsequences in the periplasmic amino-terminal domain of the siderophorereceptor. While F. tularensis does produce and utilize a siderophore,its genome does not encode identifiable tonB, exbB, or exbDhomologs or tonB-dependent receptor homologs for siderophoreuptake (18). A receptor for the F. tularensis siderophore istherefore expected to be a novel protein.

We used a ${Delta}$ fur mutant of Schu S4 to demonstrate here that siderophorebiosynthesis and expression of the fslA gene in F. tularensisare under the control of the Fur repressor. We determined thatfslE, located downstream of the siderophore biosynthetic genes,is also part of the Fur-regulated operon. The fslE gene producthas been localized to the outer membrane of the LVS and SchuS4 strains and belongs to a family of sequence-related proteinsunique to Francisella species (17, 18). We showed by deletionmutagenesis with the Schu S4 strain that fslE is necessary forsiderophore-mediated iron acquisition. FslE may therefore functionas the siderophore receptor in F. tularensis.

MATERIALS AND METHODS

Top

MATERIALS AND METHODS

Bacterial strains and culture. Francisella tularensis strains Schu S4 (obtained from the CDC,Fort Collins, CO) and LVS (kindly provided by K. Elkins, CBER,Rockville, MD) were grown at 37°C on cystine heart agar(Difco) plates with 5% defibrinated horse blood or on modifiedMuller-Hinton agar (Difco) supplemented with ferric pyrophosphateor ferrous sulfate, horse serum, and 0.1% cysteine. Isolateswere passaged up to five times before restreaking from stockcultures maintained at –80°C. Chamberlain's definedmedium containing 2 µg/ml FeSO₄ (CDM) (6) or tryptic soybroth supplemented with 0.1% cysteine (TSB/C) was used for routineliquid culture. CDM prepared without addition of FeSO₄ (CDM–Fe)was used as iron-limiting medium for agar plates. For growthunder iron limitation, the medium was deferrated with Chelex-100resin (Bio-Rad) and then supplemented with essential divalentcations (MgSO₄ [0.55 mM], ZnCl₂ [1.5 µM], and CaCl₂ [5µM]) (che-CDM). Defined levels of iron were added to theche-CDM; iron-limited che-CDM medium contained 0.1 µg/mlFeCl₃ (0.37 µM) or FeSO₄ (0.36 µM), whereas iron-repletemedium contained 2 µg/ml of FeCl₃ (7.4 µM) or FeSO₄(7.19 µM). Kanamycin, when required, was used at a 15-µg/mlconcentration. All glassware for preparation of che-CDM waswashed with 10 mM HCl overnight and rinsed several times inmilliQ (Millipore) water. All chemicals were from Sigma ChemicalCompany unless otherwise stated.

Escherichia coli strain MC1061.1 [ ${Delta}$ (ara-leu)7696 araD139 ${Delta}$ (lac)X74galK16 galE15 mcrA mcrB1 repsL(Str^r) hsdR2 ${lambda}$ ^– F^–recA] was used for routine cloning and was grown in Luria broth.Ampicillin was used at a concentration of 50 µg/ml (liquidcultures) or at 100 µg/ml (agar plates).

Growth in iron-limiting liquid culture. F. tularensis cells grown to logarithmic phase in CDM were pelleted,washed three times in che-CDM with no added iron, and then dilutedinto che-CDM containing defined levels of iron to an opticaldensity at 595 nm (OD₅₉₅) of 0.01 ( $~$ 3 x 10⁷ CFU/ml). For complementationstudies, the media were supplemented with 15 µg/ml kanamycinand starting cultures were inoculated to an OD₅₉₅ of 0.02. Growthwas monitored as change in OD₅₉₅ of the liquid cultures overa period of 48 to 50 h.

Bioassay for siderophore utilization. Cells from an overnight culture in CDM of Schu S4 or a mutantderivative to be tested for siderophore utilization were washed,and $~$ 3 x 10⁴ CFU was spread on the CDM–Fe plates. Cellsto be used for siderophore production were grown overnight inCDM to logarithmic phase, washed once in che-CDM, and resuspendedto an OD₅₉₅ of 1.0 ( $~$ 3 x 10⁹ CFU/ml). These cell suspensions(2.5 µl each) were spotted on the seeded plates and theplates incubated at 37°C for 2 to 4 days. A growth haloof colonies around a spot demonstrated the ability of the indicatorstrain (seeded on the plate) to grow on the iron-limiting plateutilizing the siderophore secreted by the producer strain (spottedon the plate).

Construction of ${Delta}$ fur and ${Delta}$ fslE mutants and complementing plasmids. In-frame deletion mutations in fur and fslE were generated inthe Schu S4 strain in a two-step process as previously describedfor generation of a ${Delta}$ fslA mutant in the LVS (26). The suicidevectors, described below, are pUC based and carry the kanamycinresistance gene from Tn5 and the Bacillus subtilis gene sacBfor counterselection (26).

The suicide plasmid used for generating the ${Delta}$ fur mutation wasanalogous to the plasmid pGIR457, used to obtain the ${Delta}$ fslA mutant(26), except that the flanking regions cloned in the plasmidwere specific to fur. A 1.958-kb stretch of DNA upstream ofand including 24 bp at the 5' end of the fur gene (encodingthe first eight amino acid residues of Fur) was amplified fromSchu S4 chromosomal DNA using Turbo Pfu DNA polymerase (Stratagene)and primers 113 and 114. A 2.24-kb 3' flanking sequence thatincluded the sequence encoding the terminal 10 residues andstop codon of fur was obtained by amplification from Schu S4DNA using primers 115 and 116. The 5' and 3' flanking sequenceswere cloned as NheI-NotI and NotI-SacI fragments, respectively,to generate plasmid pGIR449, where the NotI restriction sitereplaced the sequences encoding the central 122 amino acidsof fur and retained the reading frame of the amino and carboxy-terminalends encoded by the gene. In this construct, the cloned 5' flankingregion included part of the divergent nuo operon, with the nuooperon oriented toward the kanamycin resistance gene on theplasmid. Common E. coli promoters are believed to be nonfunctionalin F. tularensis, and nuo transcription may be responsible forexpression of the kanamycin resistance gene in pGIR449 integrantsof F. tularensis.

For generation of the plasmid that was used for deletion ofthe fslE gene from the chromosome, the suicide plasmid was modifiedby introducing the F. tularensis groE promoter upstream of thekanamycin resistance gene. The groEp sequence was amplifiedfrom the genome using PCR with primers 152 and 153 and clonedas an NheI-BglII fragment to generate plasmid pGIR463. A 1.05-kbregion at the 5' end of fslE and including the sequence encodingthe 18 amino-terminal residues was amplified with primers 197and 198. A 1.13-kb 3' flanking region including the sequenceencoding the terminal eight amino acid residues and the stopcodon of fslE was amplified with primers 199 and 200. The 5'and 3' flanking sequences were cloned as NheI-BspEI and BspEI-SacIfragments, respectively, in pGIR463 to generate plasmid pGIR467.In this construct, the BspEI site replaced the central 474-amino-acidcoding region of fslE and maintained the carboxy-terminal codingregion in-frame with the amino-terminal sequence.

The deletion plasmid constructs pGIR449 and pGIR467 were introducedinto Schu S4 by electroporation. Schu S4 cells grown to mid-logphase in TSB/C or in CDM were collected and washed in 0.5 Msucrose for electroporation using a Bio-Rad micropulser setat 2.5 kV, 600 ${Omega}$ resistance, and 10 µF conductance. Kanamycin-resistantcolonies arising from the ${Delta}$ fur plasmid transformation were testedfor the presence of plasmid integrated in the genome by PCRamplification of genomic DNA using sets of primers where oneprimer lay within the integrative plasmid and the other wasoutside of the sequences cloned in the plasmid. Sucrose-resistantcolonies arising from integrants were scored for loss of kanamycinresistance, and isolates with the fur or fslE deletion wereidentified by PCR of genomic DNA. The PCR products from deletionisolates GR203 ( ${Delta}$ fur) and GR211 ( ${Delta}$ fslE) were sequenced to verifythe deletions.

For complementation of the ${Delta}$ fur strain, the fur gene, along with178 bp of 5' flanking DNA containing the putative promoter,was amplified from Schu S4 DNA using primers 161 and 162. This613-bp fragment was cloned as a NheI-XhoI fragment into theshuttle plasmid pFNLTP6 (19) to generate the fur⁺ clone pGIR461.The fslE gene, along with 116 bp 5' of the gene, was amplifiedfrom Schu S4 DNA using primers 206 and 207 and cloned into thePCR2.1TOPO vector (Invitrogen). The sequence of the cloned fragmentwas verified by sequencing, and the insert was then cloned asan NheI-BamHI fragment downstream of the groE promoter in plasmidpFNLTP6gro-GFP (19). The fur⁺ plasmid pGIR461 and the fslE⁺plasmid pGIR469 were introduced into the corresponding mutantstrains by electroporation and selection for kanamycin-resistanttransformants.

Siderophore detection. Cultures were grown in iron-replete or iron-limiting CDM. Productionof the siderophore in supernatants of cultures was detectedby the chromazurol-S (CAS) assay as previously described (24,26). One hundred microliters of culture supernatants were mixedwith 100 µl of the CAS reagent and 2 µl of the shuttlesolution. The absorbance at 630 nm was read after 30 min atroom temperature in a plate reader. The CAS activity was calculatedas follows: (OD₆₃₀ of blank – OD₆₃₀ of sample)/OD₆₃₀ ofblank. The CAS activity was normalized to cell density (OD₅₉₅)to obtain a specific CAS activity. The supernatants were dilutedas necessary with milli-Q water to maintain the reaction inthe linear range.

RNA isolation and reverse transcription. F. tularensis cultures were grown overnight in CDM, washed threetimes in che-CDM, and inoculated into iron-limited or iron-repleteche-CDM to an OD₅₉₅ of 0.01. After 24 h of growth, RNA was isolatedfrom cells using TRIzol (Invitrogen) and further purified onRNeasy columns (Qiagen) as per the manufacturer's protocols.Three micrograms of RNA was reverse transcribed at 42°Cfor 50 min using Superscript II reverse transcriptase (Invitrogen).Random hexamers were used as primers for the reverse transcriptasereaction. Negative control reactions lacked only reverse transcriptase.Resultant cDNAs were used in standard PCRs and quantitativePCR (qPCR) experiments.

Standard PCR with cDNAs. Genomic DNA (gDNA) or cDNA samples were used as a template inPCRs with HotStar Taq polymerase (Qiagen) and primers locatedin the fur-fsl region as denoted in Fig. 1A, 2A, and 4. Primersare listed in Table 1.

View larger version (25K):
[in this window]
[in a new window]

FIG. 1. Characterization of ${Delta}$ fur mutant. (A) PCR analysis of ${Delta}$ fur mutant. The fur gene is depicted with flanking sequences and locations of primers used in PCR analysis. Shown beneath is the extent of sequences carried on the deletion plasmid construct. The primer pairs as shown were used to generate PCR products from Schu S4, GR201 (deletion plasmid integrant derivative), GR203 ( ${Delta}$ fur), and GR204 (fur⁺ derivative). "M" indicates lanes with the 1-kb DNA ladder (Invitrogen). (B) Siderophore activity in ${Delta}$ fur mutant and complementation. Schu S4 and GR203 and transformants harboring the control vector pFNLTP6 or the fur⁺ plasmid pGIR461 were grown overnight in iron-replete CDM, and the specific CAS activities of culture supernatants were determined. Assays were carried out in triplicate, and the averages with standard deviations are represented.

View larger version (36K):
[in this window]
[in a new window]

FIG. 4. PCR analysis of ${Delta}$ fslE mutant. The fslE gene is depicted with flanking sequences and locations of primers used in PCR analysis of gDNA from Schu S4 and GR211. Lane M shows the 1-kb DNA ladder (Invitrogen). Schu S4 yields a band of 1.669 kb, including the full-length fslE and indicated by the arrowhead, while the deletion mutant yields a band of 218 bp.

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

TABLE 1. Primers used in this work

qPCR. cDNA samples were used as a template for qPCR of fslA and fslE.trpB was used as an internal standard for normalization of transcriptlevels between different RNA preparations. For each gene, astandard curve was generated with serial dilutions of PCR productsfrom gDNA template. Primers 73 and 74 were used for the real-timereaction for trpB. fslA-specific primers were 79 and 80, andfslE primers were 188 and 189. HotStarTaq polymerase (Qiagen)was used for the amplification reactions, with activation at94°C for 15 min. The reactions were carried out in a DNAEngine Opticon 2 real-time thermocycler from MJ Research. Reactionmixtures included 0.15% Triton X-100, and Sybr green dye (Bio-Rad)was used for detection of PCR products.

Microarray analysis. All RNAs were inspected on an Agilent BioAnalyzer to ensurethat the peaks corresponding to rRNA were intact and that nodegradation had occurred. Approximately 15 µg of totalRNA per sample was used for synthesis of cDNA containing amino-allyl-labelednucleotides (16). The newly synthesized cDNAs were then labeledby a covalent coupling of appropriate cyanine dye (CyDye PostLabelingreactive dye pack; GE Healthcare Bio-Sciences Corp., Piscataway,NJ). The labeling efficiencies of the purified target cDNA preparationswere inspected by spectrophotometric analysis, and the totalpicomoles of dye incorporation (Cy3 or Cy5, accordingly) werecalculated for each sample (16). Schu S4 and ${Delta}$ fur mutant GR203cDNAs labeled with equimolar amounts of different Cy dyes werehybridized to F. tularensis glass slide DNA microarrays procuredfrom the Pathogen Functional Genomics Resource Center at TheInstitute for Genomic Research. After 24 h of incubation at42°C, the slides were washed and scanned using a ProScanArraymicroarray scanner (Perkin-Elmer Life Sciences Inc., Boston,MA). Both Cy5 and Cy3 images from one experiment were analyzedwith the ScanArray Express microarray analysis system.

Antibodies to FslE. The sequence encoding the mature portion of FslE (lacking the28 amino acids of the putative signal peptide) was amplifiedby PCR using primers 219 and 224 and cloned in the induciblevector pHis Parallel1 (25). The plasmid was introduced intoBL21(DE3) cells by transformation and expression of the geneinduced with 0.5 mM isopropyl-β-D-thiogalactopyranosidefor 3 h. The expressed protein was almost totally present ininclusion bodies. Cells were lysed with CellLytic IIB (Sigma),and inclusion bodies were purified by centrifugation. One hundredmicrograms of protein in complete Freund's adjuvant was usedto immunize A/J mice by the subcutaneous and intraperitonealroutes, followed by two boosts. Sera were obtained from themice and screened by enzyme-linked immunosorbent assay and Westernblotting for reactivity to the immunogen.

Western blotting. Whole-cell lysates normalized to cell density were preparedfrom F. tularensis cultures. The lysates were separated by sodiumdodecyl sulfate-polyacrylamide gel electrophoresis on 10% gelsand transferred to polyvinylidene difluoride. The primary anti-FslEserum was used at a 1:2,500 dilution. The blots were developedby chemiluminescence after incubation with secondary goat antimouse-peroxidaseconjugate.

RESULTS

Top

RESULTS

Siderophore production is regulated by Fur in F. tularensis. The siderophore biosynthetic operon fslABCD in F. tularensisis 312 bp downstream of the fur homolog (locus FTT0030c) (seeFig. 2A). The putative fur gene is predicted to encode a proteinof 140 amino acid residues with 49% identity and 61% similarityto its closest homolog, the Neisseria gonorrhoeae Fur sequence(GenBank accession no. AAA72351.1) (3). F. tularensis fur appearsto be transcribed as a single gene. The nuo operon is 210 bpupstream of fur and is divergent. A canonical Fur box sequenceis present in the promoter region of fslA 22 bp upstream ofthe ATG start codon (see Fig. 2A). We predicted that siderophore-mediatediron uptake in F. tularensis is regulated by the Fur repressor,as seen in other bacterial systems (reviewed in reference 11).We generated an unmarked in-frame ${Delta}$ fur mutation (retaining sequencesencoding the 3 amino-terminal and 10 carboxy-terminal residuesbut not the central 122 amino acid residues) in Schu S4 usinga suicide plasmid as detailed in the Methods section.

We carried out PCR analysis of gDNA from strain GR201, harboringthe integrated suicide plasmid, using a combination of primersthat would help identify the site of integration (Fig. 1A).The plasmid pair 123-117 gave a 2.713-kb band similar to thatof Schu S4. The 124-125 combination yielded a band that was360 bp smaller in size (2.668 kb) than the corresponding SchuS4 product (3.028 kb). These results indicated that the plasmidhad integrated at the 3' flanking sequence of the chromosomalfur gene in GR201. Loss of plasmid sequences by counterselectionon sucrose gave rise to isolates that either were mutants ( ${Delta}$ fur)or were wild-type (fur⁺) derivatives. We analyzed the ${Delta}$ fur strainGR203 and a fur⁺ derivative, GR204, by PCR of chromosomal DNA.The GR204 strain yielded PCR products similar to those of SchuS4 with both sets of primers, while GR203 produced shorter PCRproducts corresponding to the deletion of the fur gene (Fig.1A). The PCR product was sequenced to verify the deletion.

To test if Fur was involved in regulation of siderophore production,we used a liquid CAS assay to examine siderophore activity inthe supernatant of the strains after growth in iron-repleteCDM. Under these conditions, Schu S4 has a minimal level ofsiderophore activity in the culture supernatant (Fig. 1B) (26).In contrast, the ${Delta}$ fur mutant showed a $~$ 5x-higher level of siderophoreactivity, demonstrating that siderophore production in F. tularensisis normally repressed by Fur under iron-replete conditions.We tested the ability of the wild-type fur gene to complementthe ${Delta}$ fur mutation in trans. We introduced plasmid pGIR461, carryingthe wild-type fur gene under control of its own promoter. Asa control, we used the vector pFNLTP6. As expected, GR203 withpFNLTP6 has high siderophore activity compared to Schu S4 harboringthe same plasmid (Fig. 1B). In a transformant of GR203 carryingthe fur⁺ plasmid pGIR461, the siderophore activity in the supernatantdropped to a very low level, even lower than that for Schu S4itself. This is not surprising, since the Fur repressor is expressedfrom a gene on a multicopy plasmid. These experiments demonstratedthat siderophore production is deregulated due to specific mutationof the fur gene in strain GR203.

fslA and fslE transcription is deregulated in ${Delta}$ fur mutant. To test if the effect of fur on siderophore production was atthe transcriptional level, as seen in other bacterial systems,we examined fslA expression in the fur mutant strain GR203 byquantitative real-time PCR with cDNA prepared from cells grownunder iron-replete conditions. Expression of fslA was normalizedto expression of trpB, an internal control unaffected by ironlevels in the medium. As shown in Fig. 2B, relative fslA expressionis $~$ 765-fold higher in the ${Delta}$ fur mutant than in Schu S4, consistentwith Fur being a transcriptional repressor of the siderophorebiosynthetic gene. A pilot microarray comparing the transcriptionalprofiles of GR203 and Schu S4 grown in iron-replete media revealedthat all of the genes of the fslABCD cluster were deregulatedin the fur mutant (data not shown). Additionally, expressionof locus FTT0025c, encoding a hypothetical protein and locatedjust downstream of fslD, was also found to be upregulated inthe fur mutant. We have designated this gene fslE due to itsproximity to the fslABCD operon (Fig. 2A). We carried out quantitativereverse transcriptase PCR (RT-PCR) of cDNA from GR203 and SchuS4 using primers specific to fslE and confirmed that expressionof this locus was significantly deregulated ( $~$ 19-fold) in the ${Delta}$ fur mutant (Fig. 2B).

fslE is transcribed as part of an operon. The fslA, -B, -C, and -D genes are closely clustered and havebeen shown to be transcribed as an operon in the LVS (7, 26).The presumptive start codon of fslE is 85 bp downstream of thefslD stop codon. In addition, a hypothetical gene predictedto encode a 114-amino-acid protein (locus FTT0024c) is located47 bp downstream of the fslE stop codon (Fig. 2A). We have designatedthis gene fslF due to its proximity to the other fsl genes.Locus FTT0023c, encoding a putative lipase/acetyltransferase,lies 257 bp downstream of the stop codon of fslF. In order tocharacterize transcription of the fsl genes in Schu S4 and todefine the limits of the transcription unit, we used primersthat bridged adjacent loci in RT-PCR using cDNA from GR203 grownunder iron-replete conditions. As shown in Fig. 2C, primersspanning fslAB, -BC, -CD, -DE, and -EF all yielded bands ofthe sizes predicted for cotranscription (1.614 kb, 1.459 kb,1.585 kb,1.585 kb, and 558 bp, respectively), similar to resultswith gDNA. Primers 109 and 112, which span the fur and fslAgenes, did not amplify a 1.524-kb band from cDNA as seen forgDNA, although primers 110 and 112, which are within fslA, yieldeda 1.092-kb product. This analysis established that transcriptionof the fsl operon initiated independently and downstream ofthe fur gene. Primers spanning fslF and locus FTT0023c alsodid not amplify a product of 833 bp from cDNA as seen for gDNA,indicating that FTT0023c is not part of the operon. Our resultsindicate that the fslE gene is transcribed as part of the fslABCDEFoperon in Schu S4.

FslE protein production mirrors transcription. We analyzed production of the FslE protein in Schu S4 usingantiserum raised to the recombinant protein. As shown in Fig.3, lane 2, a band of the expected 50-kDa mass was seen in lysatesof Schu S4 grown in iron-replete CDM. The signal in the lysatesof fur mutant strain GR203 grown in iron-replete CDM was muchhigher, which correlated with transcriptional deregulation (Fig.3, lane 1). We also examined the effect of iron starvation onproduction of the FslE protein. As shown in Fig. 3, lane 3,FslE was increased in cells grown in iron-limiting medium, althoughnot to the levels seen for the fur mutant. These results indicatethat FslE protein production is both Fur and iron regulated.

View larger version (69K):
[in this window]
[in a new window]

FIG. 3. Western blotting with FslE antibodies. Whole-cell lysates normalized for cell density were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis, transferred to a polyvinylidene difluoride membrane, and probed with polyclonal antiserum raised to recombinant FslE. The locations of the prestained standards run on the gel are indicated. The lysates are denoted by lanes: 1, GR203 ( ${Delta}$ fur) grown in iron-replete CDM; 2, Schu S4 grown in iron-replete CDM; 3, Schu S4 grown in iron-limiting CDM; 4, GR211 ( ${Delta}$ fslE) grown in iron-limiting CDM; 5, vector (pFNLTP6gro-GFP)-transformed GR211 grown in iron-limiting CDM; 6, fslE+ plasmid (pGIR469)-transformed GR211 grown in iron-limiting CDM.

Generation of ${Delta}$ fslE mutant. The fslE gene product, annotated as a hypothetical membraneprotein of 509 amino acid residues, has been identified in theouter membrane of LVS and Schu S4 and designated SrfA (17).The proximity to, and its cotranscription with, the siderophorebiosynthetic genes suggested that fslE may also play a rolein siderophore-mediated iron uptake in F. tularensis. In orderto test this possibility, we generated a strain, GR211, witha defined in-frame chromosomal deletion of the gene in the SchuS4 background. The deletion mutation was confirmed by PCR analysisof gDNA using primers flanking the gene, as shown in Fig. 4.The PCR product was also sequenced to confirm that the sequencesencoding the amino-terminal 18 residues and carboxy-terminal8 residues were retained and in-frame.

We tested lysates of GR211 for the presence of the FslE proteinby Western blotting of lysates from cells grown in iron-limitingCDM. As shown in Fig. 3, lane 4, the band corresponding to FslEwas not produced in these cells, whereas FslE production wasinduced in Schu S4 under these conditions (Fig. 3, lane 3).

The ${Delta}$ fslE mutant is defective for growth under iron limitation. To determine if fslE plays a role in iron acquisition, we testedthe fslE mutant strain, GR211, for the ability to grow underiron limitation. We spotted serial dilutions of Schu S4 andof GR211 on an iron-replete agar plate (TSB/C supplemented withiron) and on CDM–Fe agar. As seen in Fig. 5A, both strainsgrew equally well on the iron-replete plate. On the iron-limitingplate, Schu S4 growth was observed up to the fourth dilution.GR211, however, showed growth only in the margins of the spotsat even the very highest concentration of cells ( $~$ 3 x 10⁹ CFU/ml).This phenotype was consistent with a poor ability to grow underiron limitation.

View larger version (26K):
[in this window]
[in a new window]

FIG. 5. Growth deficiency of ${Delta}$ fslE mutant under iron limitation. (A) Growth on iron-replete and iron-deficient agar plates. Cultures of Schu S4 and GR211 in iron-replete CDM were washed in che-CDM–Fe and resuspended to an optical density of 1.0. Tenfold serial dilutions were made in che-CDM–Fe and spotted on an iron-replete or iron-limiting agar plate. Growth was assessed after 3 days on the rich plate and 4 days on the iron-limiting plate. (B) Growth in liquid culture. Washed cells were inoculated into iron-replete (high Fe³⁺) or iron-limiting (low Fe³⁺) che-CDM and growth followed over a period of 56 h. Cultures were grown in triplicate, and the means and standard deviations of one representative experiment are shown in the growth plot. (C) Complementation of ${Delta}$ fslE mutant in trans. GR211 cells transformed with either control vector pFNLTP6gro-GFP or the fslE⁺ plasmid pGIR469 were washed and inoculated into iron-replete (hi Fe³⁺) or iron-limiting (lo Fe³⁺) che-CDM. The growth of cultures in duplicate was monitored over 48 h, and the results at the 48-h time point are shown for one representative experiment.

We also examined growth in liquid medium. The fslE mutant strain,GR211, grew similarly to Schu S4 in standard CDM containing2 µg/ml of ferrous sulfate (data not shown). We comparedgrowth of Schu S4 and GR211 in che-CDM supplemented with standardhigh levels (2 µg/ml) of FeCl₃ or limiting levels of FeCl₃(0.1 µg/ml). As shown in Fig. 5B, the two strains grewsimilarly in medium supplemented with high levels of FeCl₃.When iron levels were limiting, the Schu S4 strain grew to abouta third of its density in iron-replete medium; however, the ${Delta}$ fslE strain was significantly defective in its ability to growunder this iron limitation (P < 0.002 at all times after21 h), growing to half the density of the wild type (Fig. 5B).We inferred that the deletion of fslE resulted in a loweredability to assimilate iron under iron-limiting conditions.

Complementation of ${Delta}$ fslE by plasmid-borne fslE. We tested the ability of plasmid pGIR469 carrying the fslE geneunder control of the groE promoter to complement the fslE mutationin trans. We analyzed lysates of cells grown in reduced-ironmedium for reactivity to FslE antiserum on Western blots. Asshown in Fig. 3, lane 5, GR211 transformed with the controlplasmid pFNLTP6gro-GFP did not produce the FslE protein. Thestrain harboring the plasmid pGIR469, however, showed robustFslE levels (Fig. 3, lane 6).

We compared transformants of GR211 carrying either pGIR469 orthe control plasmid for their ability to grow in iron-limitingCDM (Fig. 5C). In medium supplemented with 2 µg/ml offerric chloride as an iron source, the two transformants grewsimilarly. When levels of ferric iron were limiting, the complementedstrain grew significantly better (twofold-higher density) thanthe control strain. This difference reflected that seen withthe parental strain, Schu S4, and the fslE mutant GR211 strain.These results demonstrated that the iron-dependent growth phenotypeof GR211 was specifically due to mutation in fslE and couldbe complemented in trans by the plasmid-borne wild-type gene.

FslE is necessary for siderophore utilization. In order to determine the nature of the growth defect in ferriciron of the ${Delta}$ fslE strain, GR211, and if it was related to siderophore-mediatediron uptake, we tested the ability of the strain to both expressand utilize the siderophore. We employed a functional plate-basedassay which we previously developed for characterizing the LVSsiderophore (26).

We first established that this assay could be adapted to examinesiderophore utilization in Schu S4. We seeded an iron-limitingCDM plate with Schu S4 and spotted on the plate LVS, the siderophore-deficient ${Delta}$ fslA mutant of LVS (GR7), or Schu S4 (26). After 4 days, a haloof growth was observed around the LVS and Schu S4 spots, indicatingthat the seeded cells were able to utilize the siderophore secretedby bacteria in both the LVS and Schu S4 spots (Fig. 6A). Nohalo was observed around GR7, confirming that the growth wassiderophore dependent. We then tested GR211 for siderophoreproduction by spotting it on a Schu S4-seeded plate. As seenin Fig. 6B, the seeded Schu S4 cells formed growth halos aroundGR211 similarly to results with Schu S4, indicating that GR211was functional in siderophore secretion.

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

FIG. 6. Siderophore production and utilization by ${Delta}$ fslE mutant. Iron-limiting CDM–Fe plates were seeded with Schu S4 (A and B), the ${Delta}$ fslE strain, GR211 (C and D), or GR211 harboring plasmid vector pFNLTP6groGFP (E) or the fslE⁺ plasmid, pGIR469 (F). Washed cells of LVS, GR7 (siderophore-deficient derivative of LVS), Schu S4, and GR211 were spotted on the plates as indicated. A filter paper spotted with 10 µl of 20-mg/ml FeSO₄ was placed on plate D. Experiments were repeated at least two independent times with similar results; plates from a representative experiment are shown.

In order to test for the ability to utilize a siderophore, weran parallel assays using GR211 as the tester strain to seedplates. No evidence of any growth was observed around eitherthe Schu S4 or GR211 spots even after 4 days (Fig. 6C). Theseresults indicated that the GR211 cells were unable to utilizea siderophore to grow on the iron-limiting plate. To demonstratethe viability of the starting culture, we spotted ferrous sulfateon a filter paper on a similarly seeded plate and observed robustgrowth around the filter in just 2 days (Fig. 6D). We then testedtransformants of GR211 harboring either a control vector (pFNLTP6gro-GFP)or the fslE⁺ plasmid pGIR469 for the ability to utilize a siderophorein this plate assay. Vector-transformed Schu S4 bacteria wereable to grow utilizing a siderophore, similar to results withuntransformed Schu S4 (data not shown). However, vector-transformedGR211 bacteria were unable to form growth halos around a spotof siderophore-secreting Schu S4 (Fig. 6E). The presence offslE in trans (pGIR469 transformant) was sufficient to restoresiderophore-dependent growth (Fig. 6F).

These experiments demonstrated that FslE was not required forsiderophore biosynthesis and export but was necessary for siderophore-mediatedutilization of iron for growth.

DISCUSSION

Top

DISCUSSION

Iron acquisition genes, including siderophore biosynthetic andsiderophore uptake genes, are commonly under transcriptionalcontrol of the iron-responsive repressor Fur in gram-negativeand gram-positive bacteria, including E. coli, Bacillus subtilis,Campylobacter jejuni, Pseudomonas aeruginosa, Neisseria spp.,and Shewanella (2, 4, 9, 14, 22, 27). Using a defined fur deletionmutant of strain Schu S4, we have shown here that siderophoreproduction in F. tularensis is under Fur regulation. This controlis exerted at the level of transcription, as demonstrated forthe biosynthetic gene fslA.

We determined that the fslE gene (FTT0025c in the Schu S4 genome),which is downstream of the siderophore biosynthetic gene clusterfslABCD, is also deregulated in the ${Delta}$ fur strain. We determinedthat fslE is transcribed as part of the fsl operon in the SchuS4 strain. We defined the limits of the operon, showing thatthe transcript initiates downstream of the fur gene and extendsinto fslF (FTT0024c) downstream of fslE but does not includethe FTT0023c locus.

Genes for the related functions of siderophore biosynthesisand uptake are commonly clustered and coregulated in bacteria.The proximity to fslABCD and the cotranscription suggested thatFslE is involved in siderophore-mediated iron uptake. We generatedan in-frame deletion in fslE in the Schu S4 background and foundthat the mutant strain had a diminished ability to grow underiron limitation. Using a plate-based growth assay, we demonstratedthat the ${Delta}$ fslE mutant secreted functional siderophore under ironlimitation but was defective in utilizing the siderophore itself.This growth defect was rescued by fslE⁺, provided in trans.Thus, FslE is essential for siderophore-mediated iron utilization.

It was recently shown that the fslD and fslE homologs in a strainof the closely related novicida subspecies are cotranscribedand that transcription is induced by iron starvation (20). Astrain with a mutation in the fslE homolog was competent forsiderophore production. Our studies with Schu S4 indicate thatparallels may be drawn between the tularensis and novicida subspeciesin aspects of siderophore-mediated iron uptake. While they areclosely related in sequence, there are also significant sequencedifferences between the genomes of the subspecies that are reflectedin differences in growth characteristics and virulence (23).It is not known at present if the differences may extend toiron acquisition.

The FslE protein belongs to a family of five related open readingframes unique to F. tularensis (18). A signal peptide at theamino terminus of FslE is predicted by the SignalP 3.0 softwareprogram (www.cbs.dtu.dk/services/SignalP/), suggesting thatit is a secreted protein. In a recent study examining outermembrane proteins of F. tularensis, FslE (referred to as SrfA)was identified in the outer membrane fraction of Schu S4 andof LVS (17). The hidden Markov model-based beta-barrel predictionprogram PRED-TMBB (1) predicts that residues 178 to 509 of theFslE protein can fold as a 14-stranded beta-barrel in the outermembrane, with the amino-terminal third of the protein (includingthe putative signal peptide sequences) in the periplasm. Thestructure is reminiscent of siderophore receptors in gram-negativebacteria, although the typical TonB-dependent transporter is22 stranded (5). This suggests that FslE may function as thesiderophore receptor in F. tularensis in a manner analogousto that for other gram-negative bacteria. How it might do soin the absence of an obvious TonB-ExbB-ExbD system is an interestingquestion. Alternatively, FslE may mediate uptake of siderophore-boundiron by a completely different mechanism. Future studies willfurther explore the function of FslE and its role in siderophore-mediatediron uptake.

ACKNOWLEDGMENTS

We gratefully acknowledge the F. tularensis oligonucleotidemicroarrays provided by PFGRC. We thank Barbara J. Mann forcritical reading of the manuscript.

This work was supported by grants AI056227 and AI067823 fromthe NIAID and by an intramural Research and Development grantfrom the University of Virginia School of Medicine.

FOOTNOTES

* Corresponding author. Mailing address: P.O. Box 801367, University of Virginia Health System, MR4 Bldg., Rm. 2126, Charlottesville, VA 22908-5621. Phone: (434) 982-0003. Fax: (434) 924-0075. E-mail: girija{at}virginia.edu

Published ahead of print on 6 June 2008.

REFERENCES

Top