Transcriptional Control of the Iron-Responsive fxbA Gene by the Mycobacterial Regulator IdeR

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Journal of Bacteriology, June 1999, p. 3402-3408, Vol. 181, No. 11
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Transcriptional Control of the Iron-Responsive fxbA Gene by the Mycobacterial Regulator IdeR

Olivier Dussurget,¹^,² Juliano Timm,¹ Manuel Gomez,¹ Benjamin Gold,¹^,³ Shengwei Yu,⁴ Sue Z. Sabol,⁵ Randall K. Holmes,⁶ William R. Jacobs Jr.,⁴ and Issar Smith¹^,^*

TB Center, Public Health Research Institute,¹ and Department of Microbiology, New York University Medical Center,³ New York, New York 10016; UFR de Biochimie, Université Paris 7, 75251 Paris Cedex 05, France²; Department of Microbiology and Immunology, Howard Hughes Medical Institute, Albert Einstein College of Medicine, Bronx, New York 10461⁴; Section of Gene Structure and Regulation, Laboratory of Biochemistry, National Cancer Institute, National Institutes of Health, Bethesda, Maryland 20892⁵; and Department of Microbiology, University of Colorado Health Sciences Center, Denver, Colorado 80262⁶

Received 12 March 1998/Accepted 30 March 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Exochelin is the primary extracellular siderophore of Mycobacterium smegmatis, and the iron-regulated fxbA gene encodes aputative formyltransferase, an essential enzyme in the exochelinbiosynthetic pathway (E. H. Fiss, Y. Yu, and W. R. Jacobs, Jr.,Mol. Microbiol. 14:557-569, 1994). We investigated the regulationof fxbA by the mycobacterial IdeR, a homolog of the Corynebacteriumdiphtheriae iron regulator DtxR (M. P. Schmitt, M. Predich, L.Doukhan, I. Smith, and R. K. Holmes, Infect. Immun. 63:4284-4289,1995). Gel mobility shift experiments showed that IdeR binds tothe fxbA regulatory region in the presence of divalent metals.DNase I footprinting assays indicated that IdeR binding protectsa 28-bp region containing a palindromic sequence of the fxbA promoterthat was identified in primer extension assays. fxbA regulationwas measured in M. smegmatis wild-type and ideR mutant strainscontaining fxbA promoter-lacZ fusions. These experiments confirmedthat fxbA expression is negatively regulated by iron and showedthat inactivation of ideR results in iron-independent expressionof fxbA. However, the levels of its expression in the ideR mutantwere approximately 50% lower than those in the wild-type strainunder iron limitation, indicating an undefined positive role ofIdeR in the regulation of fxbA.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Iron is an essential nutrient for almost all living microorganisms, including pathogenic bacteria. In an aerobic environment,iron is oxidized to its ferric state, which forms insoluble ferricoxides at physiological pH; thus, the concentration of free ironis approximately 10¹⁸ M (1). In mammalian hosts, iron is chelated by molecules suchas transferrin, lactoferrin, heme, and ferritin, and the concentrationof free iron in human serum is also extremely low, 10¹⁵ M or less (3). Thus, regardless of the external environment,the levels of free iron are far below the nutritional requirementsof any bacterium. To acquire this essential metal, many microorganismssecrete low-molecular-weight iron chelators termed siderophoresthat solubilize iron its ferric form, which is then transportedinto the cell by membrane-bound receptors (20). The Fe²⁺ produced by intracellular reduction of the newly imported Fe³⁺ is then available for its essentialfunctions.

Mycobacterial iron assimilation relies upon synthesis of two structurally unrelated types of siderophores, i.e., secretedcarboxymycobactins in slow-growing pathogenic members of thisgenus as well as nonpathogens and exochelins that are found onlyin fast-growing mycobacteria (44). In addition, most mycobacteriapossess mycobactins, which are highly lipophilic cell wall-associatedmolecules thought to facilitate the transport of iron across thecell wall and to store iron (35, 44). Mycobacterium tuberculosiscarboxymycobactin can remove iron from the host's transferrinand lactoferrin and transport it to mycobactins (10). The structuresof mycobactins and exochelins from several mycobacterial specieshave been elucidated (11, 16, 33-35, 45); however, untilrecently, only a single gene, M. smegmatis fxbA (9), had beendemonstrated to be involved in siderophore biosynthesis. fxbAencodes a putative formyltransferase necessary for exochelin biosynthesis.More recently, a group of closely linked genes also involved inM. smegmatis exochelin biosynthesis (46, 47) and a clusterof M. tuberculosis genes that encode the mycobactin biosyntheticenzymes (25) have been described. It has long been known thatiron represses the production of mycobactins, exochelins, andiron-regulated envelope proteins that could be involved in ironuptake (15, 36, 37). However, at that time, the molecularbasis of siderophore regulation in mycobacteria was unknown. Sincethese early reports, IdeR, a functional homolog of Corynebacteriumdiphtheriae DtxR (32), has been described (5). DtxR is aniron-dependent repressor that controls siderophore biosynthesisand transcription of the tox gene, which encodes the C. diphtheriaediphtheria toxin. DtxR, when activated by Fe²⁺, binds to operator sequences known as iron boxes, repressingtranscription of iron-regulated genes (31, 40). More recently,IdeR has been shown to negatively regulate siderophore biosynthesisin M. smegmatis (6).

To provide more insight into the role of IdeR in mycobacterial iron regulation, we initiated a study of its interaction withmycobacterial siderophore biosynthetic genes. When this projectwas started, fxbA was the only known iron-regulated mycobacterialgene, and its promoter region had been found to contain sequencesthat resembled a DtxR binding site (9). We have now investigatedthe regulation of fxbA by IdeR in cell-free experiments and inwhole-cell physiological studies. The work reported here demonstratesthat IdeR binds to the fxbA promoter region in the presence ofdivalent metals and specifically protects a 28-bp region whichencompasses a palindromic sequence of the fxbA promoter regionthat contains the postulated iron box. The transcription startpoint (TSP) of fxbA has been mapped by primer extension, and fxbAregulation has been studied in strains containing fxbA-lacZ transcriptionalfusions. Inactivation of ideR in M. smegmatis results in constitutiveexpression of fxbA, independent of the iron levels. However, thelevels of fxbA expression in the ideR mutant are 50% lower thanthose in the wild-type strain in nonrepressing (low-iron) conditions,indicating an undetermined positive role of IdeR in fxbAregulation.

	MATERIALS AND METHODS

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Media and growth conditions. Mycobacterial strains were grown on Middlebrook 7H10 solid medium (Difco) and in Middlebrook 7H9 liquid medium (Difco) at37°C. Both media were routinely supplemented with 0.2% glyceroland 0.05% Tween 80. Mycobacteria were also grown on solid LB (Difco)medium and LB broth, both supplemented with 0.05% Tween 80. Theantibiotics kanamycin and streptomycin, when required, were eachadded at a concentration of 20 µg/ml. For growth under low-ironconditions, 7H9L (7H9 that had been treated with a Chelex resin[Chelex 100; Bio-Rad]) was used. The concentration of iron inthis medium was determined by atomic absorption spectroscopy tobe less than 1 µM. For primer extension experiments and $beta$ -galactosidaseassays with bacteria grown under low-iron conditions, mycobacteriawere grown in 7H9L for approximately nine generations by periodicallydiluting cultures that were growing exponentially. LB broth culturesin the exponential phase of growth were starved for iron by addingthe iron chelator 2,2'-dipyridyl (DP) to a final concentrationof 200 µM, and the cultures were grown overnight. These cultureswere used to inoculate fresh LB broth containing DP prior to harvestingin the exponential growth phase. For primer extension and $beta$ -galactosidaseassays with bacteria grown under high-iron conditions, mycobacteriawere grown in 7H9L with 50 µM ferric chloride (7H9H) or in LBbroth not treated with DP. The levels of iron normally found inLB broth, approximately 30 µM (43), are high enough to repressDtxR- and IdeR-regulated genes (32). Plasticware was systematicallyused in experiments that required low-iron media to avoid leachingof iron from glass surfaces. Escherichia coli was routinely grownin LB medium at 37°C.

DNA techniques. DNA manipulations were performed by standard procedures as described elsewhere (27). Restriction and modifying enzymes wereobtained from Promega. DNA fragments used in the cloning proceduresand PCR products were isolated from agarose gels with a Qiaexor Qiaquick gel extraction kit (Qiagen Inc.) according to themanufacturer'sinstructions.

Labeling of DNA fragments. T4 polynucleotide kinase and [ $gamma$ -³²P]ATP (NEN) were used to end label the oligonucleotides FXB5'2 (5'-GTGGTGGTCTTCCCCCTGGC-3'),FXB5'7 (5'-AACCGGCATGCTATCAAAGG-3'), and FXB3'7 (5'-TGGCAGGTTCGGGGGCGG-3').A DNA fragment corresponding to the first 23 codons of the fxbAgene and its regulatory region was subcloned into pBluescriptKS (Stratagene), creating pKSfxbA. ³²P-labeled FXB5'2 and unlabeled FXB3'7 were used to amplify byPCR a 126-bp product from pKSfxbA. The 126-bp PCR product wasisolated by electrophoresis on a 2% agarose gel, purified by usinga Qiaquick gel extraction kit, and used in the gel shift assay.³²P-labeled FXB5'7 and unlabeled FXB3'7 were used to amplify byPCR a 67-bp fragment from pKSfxbA. The 67-bp PCR product was isolatedand purified as described above and used in the DNase I protectionexperiments of the first strand. For analysis of the binding ofIdeR to the complementary strand, unlabeled FXB5'7 and ³²P-labeled FXB3'7 were used to amplify by PCR the same 67-bp fragmentfrom pKSfxbA, and the PCR product was purified as describedabove.

Gel mobility shift assay. The IdeR protein was purified by nickel affinity chromatography as previously described (32). Binding reactions were carriedout in a final volume of 20 µl in a buffer composed of 20 mM Tris-HCl(pH 8), 50 mM KCl, 5 mM MgCl₂, 50 µg of poly(dI-dC) per ml, 50µg of bovine serum albumin per ml, and 10% glycerol. The reactionmixtures contained approximately 10 fmol of ³²P-labeled DNA fragment, 200 µM divalent metal salts, and purifiedIdeR as indicated in Results, and incubation was carried for 30min at room temperature. When Fe²⁺ salts were used in the assays, 2 mM dithiothreitol (DTT) wasadded to decrease its oxidation to Fe³⁺. A 15-µl aliquot of each reaction mixture was loaded withoutdye onto a 5.5% polyacrylamide gel containing 40 mM Tris-acetate(pH 8). Gels were run at 110 V at room temperature and dried,and radioactivity was visualized byautoradiography.

DNase I footprinting. Binding reaction mixtures contained approximately 10 fmol of ³²P-labeled DNA fragment and 18 pmol of purified IdeR in 50 µl ofreaction buffer (20 mM Na₂HPO₄ [pH 7.0]), 50 mM NaCl, 5 mM MgCl₂,2 mM DTT, 100 µg of bovine serum albumin per ml, 10 µg of sonicatedsalmon sperm DNA per ml, 10% glycerol). Freshly prepared nickelsulfate was added to a final concentration of 500 µM. Reactionmixtures were incubated for 10 min at 37°C. After incubation,50 µl of a solution containing 5 mM CaCl₂ and 10 mM MgCl₂ wasadded to the reaction mixtures at room temperature. Then 0.15U of DNase I (Promega) was added, and the mixtures were incubatedfor 3 min at room temperature. The digestion reactions were terminatedby addition of 90 µl of stop solution (200 mM NaCl, 30 mM EDTA,1% sodium dodecyl sulfate, 100 mg of yeast RNA per ml) and extractedwith phenol-chloroform-isoamyl alcohol (25:24:1 [vol/vol/vol]).The nucleic acids were ethanol precipitated, and the dried pelletswere resuspended in formamide loading dye. After electrophoresison an 8% denaturing polyacrylamide sequencing gel, the gel wasdried and the footprinting patterns were analyzed by autoradiography.To locate the protected sequence on each strand, Maxam and GilbertG+A reactions were performed on both ³²P-labeled 67-bp DNA fragments (27).

RNA isolation and TSP mapping. RNA from mycobacteria grown in 7H9L or 7H9H was prepared by mechanical disruption with glass beads in the presence of phenoland lithium chloride as described previously (4). The fxbATSP was determined by primer extension analysis, using previouslydescribed methods with minor modifications (4). Briefly, oligonucleotidefxbA23 (5'-CATGACCACGCGCACAGGAAACACCC-3'), complementary to thesequence between nucleotides (nt) 44 to 69 relative to the firstnucleotide in the fxbA start codon, was 5'-end labeled with [ $gamma$ -³²P]ATP (NEN). The labeled fxbA23 primer was annealed to 30 µg ofRNA (1 min at 100°C, 2 min at 60°C, 10 min on ice) and then extendedwith avian myeloblastosis virus reverse transcriptase (15 minat 48°C). To obtain the size of the extended product, plasmidpKSfxbA and primer fxbA23 were used to generate a sequencing ladderby the dideoxy-chain termination method with Sequenase T7 DNApolymerase (Sequenase 2.0; Amersham). Primer extension productswere loaded onto a 6% polyacrylamide sequencing gel along withthe sequencing ladder and run 2 h at 1,800 V. To estimate therelative amount of the fxbA transcript in M. smegmatis wild-typemc²155 (46) and the ideR mutant SM3 (6) grown in 7H9L or 7H9H,autoradiographs were scanned with a Hewlett-Packard Scanjet IICX/Tscanner and quantitated with ScanAnalysis version 2.56(BioSoft).

Construction of an integrative promoter-probe vector for mycobacteria. To construct an integrative promoter-probe vector for mycobacteria, the replicative plasmid pJEM15 (41) was modified. pJEM15contains a cII-lacZ fusion preceded by a synthetic ribosome bindingsite (RBS), multiple cloning sites, and the transcription terminatorof the T4 bacteriophage (T4t). T4t had been shown to be an efficienttranscription terminator in mycobacteria, reducing readthroughtranscription from vector sequences (42). A DNA fragment ofapproximately 1.3 kb containing the T4t, multiple cloning site,and synthetic RBS and part of the cII-lacZ fusion was obtainedby digesting pJEM15 with PstI and EcoRI. This fragment was thentreated with the Klenow fragment of DNA polymerase I and clonedbetween the DraI and EcoRV sites of the integrative vector pMV361-lacZ(38). The resulting vector was then linearized with ScaI andligated to the omega cassette harboring a streptomycin/spectinomycinresistance gene (22), resulting in plasmid pSM128 (a map ofthis vector is available onrequest).

Construction of fxbA-lacZ and tox-lacZ fusions. Transcriptional fusions to lacZ were obtained by cloning PCR-amplified fragments of the fxbA and C. diphtheriae tox regulatoryregions into the ScaI site of pSM128. A PCR fragment of fxbA thatcontained two predicted IdeR binding sites and comprised the first23 codons of the gene and its upstream regulatory region up to $-$ 187 bp, relative to the fxbA TSP, was obtained by using as primersfxbAUP (5'-AGATTTTCGGCCACCGTAATAC-3') and fxbA3-1 (5'-AGCTTCATGACCACGCGCACAGG-3').The pSM128 derivative harboring this fragment was named pSM371.A shorter fxbA-lacZ fusion, pSM353, contained the same 3' extremityas in pSM371 and the upstream regulatory region up to $-$ 108 bp,relative to the TSP. This fragment did not contain the putativedistal iron box. It was obtained by using as primers in the PCRamplification fxbAS (5'-CCCTCGTCGTTGACCAGG-3') and fxbA3-1. Finally,the third fxbA-lacZ fusion, pSM353, contained a DNA fragment withthe coordinates $-$ 187 to +6 bp, relative to the TSP. This fragment,containing the predicted distal iron box and a truncated proximaliron box, was produced by using as primers in the PCR amplificationfxbAS and fxbAWOIB (5'-ACCTTTGATAGCATGCCGGTTG-3'). In the caseof tox, the PCR fragment was obtained by using as primers tox5-2 (5'-TTGCTAGTGAAGCTTAGCTAGT-3') and tox 3-2 (5'-GTTTTCTGCTCACAACGTATCCC-3')and comprised the first five codons of the gene and approximately100 bp of its upstream regulatory region that contains a DtxRbinding site. The plasmid containing this tox-lacZ fusion wasnamed pSM223. The structures of all lacZ transcriptional fusionswere verified by restriction analysis and DNAsequencing.

$beta$ -Galactosidase assays. Cultures of M. smegmatis strains harboring the different lacZ fusions were grown in either 7H9 or LB that contained low orhigh iron, collected at an optical density at 600 nm of 0.6 to1, washed, and resuspended in Z buffer (19). Suspensions werelysed in a Mini Bead-beater (Biospec Products) for 30 s threetimes. Protein concentration of the extracts was estimated byusing the Bio-Rad protein assay, with bovine serum albumin asthe standard. $beta$ -Galactosidase activity of the extracts was determinedas described by Miller (19), and units of activity are expressedas nanomoles of nitrophenol produced per minute per milligramof protein. Comparable $beta$ -galactosidase levels were observed incells growing in either LB or 7H9medium.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Interaction of IdeR with the regulatory region of the fxbA gene. Previous studies have identified and characterized fxbA, an iron-regulated gene in M. smegmatis that encodes an enzyme essentialfor exochelin biosynthesis (9). A potential binding site (ironbox) for a DtxR-like regulator was also observed in the regionof fxbA immediately upstream from the putative translational startcodon. To determine whether IdeR interacts directly with the regulatoryregion of fxbA, we carried out gel mobility shift assays usinga 126-bp fragment containing the putative iron box (Fig. 1). Aretarded DNA band was observed in presence of IdeR and divalentiron or nickel. No retarded complexes were observed when divalentmetals were absent from the reaction. IdeR binding to the 126-bpfragment was also activated in the presence of Mn²⁺, Co²⁺, Zn²⁺, and Cd²⁺, and the protein-DNA complexes showed similar shifts (data notshown). Cu²⁺ did not induce binding of IdeR to the fragment. These resultsare similar to those previously reported for the metal-dependentbinding of both DtxR and IdeR to the C. diphtheriae tox iron box(32). As a control for the specificity of the observed bindingof IdeR to fxbA, several DNA fragments of various sizes, lackingiron boxes, including the promoter regions of the M. tuberculosissodA, katG, and sigA genes, were used in similar assays, and noneof these were retarded in the presence of divalent nickel or iron(data not shown).

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FIG. 1. Gel mobility shift assay of the fxbA-IdeR interaction. The ability of IdeR to bind to the fxbA regulatory region was measured by acrylamide gel electrophoresis of protein-DNA complexes. Approximately 10 fmol of a 126-bp ³²P-labeled fragment containing the regulatory region of fxbA was incubated with no metal or with 200 µM Ni²⁺ or Fe²⁺ and increasing amounts of IdeR from 0 to 18 pmol, as indicated above the lanes. Lane 1 contained the DNA alone, and lane 2 had the DNA and 18 pmol of IdeR with no metal. Binding conditions and gel electrophoresis are described in Materials and Methods.

In general, we preferred to use Ni²⁺ salts for activation of the DNA binding property of IdeR since this transition state metalis more resistant to oxidation than Fe²⁺ (31). This could explain the observation that more IdeR wasneeded to shift fxbA when binding reactions were carried out inthe presence of Fe²⁺ compared to those performed with Ni²⁺ (Fig. 1; compare lanes 3 to 7 and 4 to 8). It was essential toadd DTT to the IdeR-fxbA binding reactions with iron salts toobserve any gel shift (data notshown).

To determine the exact location of the IdeR binding site in the fxbA regulatory region, DNase I footprinting experiments wereconducted with a 67-bp DNA fragment containing the putative ironbox. A single protected region of 28 bp was obtained when IdeRwas allowed to bind to this DNA in presence of Ni²⁺ (Fig. 2). This sequence contained the predicted iron box andencompassed the putative translation initiation codon and RBS.The iron box contained a 13-bp sequence that formed a perfectpalindrome around a central G. IdeR protected slightly differentregions of the fxbA promoter/operator on the coding and noncodingstrands. The protection was common to both strands over the first21 bp, containing the palindromic sequences, and extended onlyon one strand over the last 7 bp symmetrically to the dyad axis.The IdeR binding sequence identified by DNase footprinting wascompared with known DtxR binding sites and DtxR-like operatorsequences and was shown to have 74% identity with the 19-bp consensusDtxR operator (Fig. 3).

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FIG. 2. DNase I footprinting of the fxbA-IdeR complex. The specific fxbA sequences to which IdeR binds were determined by treating protein-DNA complexes with DNase I and analyzing the products on DNA sequencing gels; 10 fmol of a 67-bp fragment containing the regulatory region of fxbA, labeled on the coding (A) or the noncoding (B) strand, was incubated with 500 µM Ni²⁺, with (+) or without ( $-$ ) 18 picomoles of IdeR. Binding and DNase I digestion conditions are described in Materials and Methods. Maxam and Gilbert A+G sequencing reactions were performed on both strands, and gel electrophoresis was performed as described in Materials and Methods. Brackets indicate the sequences protected by IdeR from DNase I digestion. (C) DNA sequence of the fxbA regulatory region. The boxed region indicates the IdeR box, i.e., sequences protected from DNase I digestion by IdeR. Inverted arrows indicate sequences that form a palindrome. The asterisk indicates the TSP observed in the primer extension illustrated in Fig. 4. The translation initiation codon is indicated by boldface, and the putative RBS and $-$ 10 region are indicated by lines over the corresponding sequences.

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FIG. 3. Comparison of DtxR and IdeR binding sites. The sequences shown, except for the Streptomyces pilosus desA sequence, were identified by their ability to bind IdeR or DtxR, as measured by gel mobility and/or DNase footprinting assays. desA is repressed by iron (13), and since Streptomyces species have a DtxR homolog (14), it is assumed that the sequence shown here is an operator site for this protein. Other relevant references are cited in the text.

Mapping of the fxbA TSP. The fxbA TSP was determined by primer extension using RNA extracted from strains mc²155 and SM3 grown in 7H9L (low-iron) or 7H9H (high-iron) media.The results indicated demonstrated a TSP located 13 bp upstreamof the fxbA start codon. Transcription of fxbA in mc²155 was detected only when the cells had been growing in iron-depletedmedium. From the data obtained from this and other primer extensionexperiments, it was observed that the quantity of fxbA transcriptin strain SM3 was essentially the same in both 7H9L and 7H9H andwas four times lower than the quantity of fxbA transcript in strainmc²155 grown in 7H9L. This latter result is discussedbelow.

Sequences similar to the E. coli $sigma$ ⁷⁰ consensus for $-$ 35 and $-$ 10 boxes, TgGACg and cATgcT, respectively (where uppercase denotesidentity with the consensus), were identified upstream of thefxbA TSP. The $-$ 10 hexamer was also similar to the consensus forconstitutively expressed M. smegmatis promoters, TATAaT (2).The spacer between the putative $-$ 10 and $-$ 35 sequences was 17 nt,and the distance between the TSP and the $-$ 10 box was 7 nt (Fig.4B).

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FIG. 4. Identification of the fxbA promoter. (A) The 5' terminus of the fxbA transcript was determined by primer extension using oligonucleotide fxbA23 and RNA prepared from cultures of strains mc²155 and SM3 growing in 7H9L or 7H9H. Lanes: 1, mc²155 in 7H9L; 2, mc²155 in 7H9H; 3, SM3 in 7H9L; 4, SM3 in 7H9H. The nucleotide sequencing ladder shown at the left was obtained with oligonucleotide fxbA23 as the primer and plasmid pKSfxbA as the template. (B). The putative $-$ 10 and $-$ 35 boxes of the fxbA promoter are underlined, as are a possible RBS and the start codon. The TSP is indicated with an arrow. The consensus sequence for E. coli $sigma$ ⁷⁰ promoters is shown for comparison. Uppercase denotes more than 50% conservation.

Regulation of fxbA by using transcriptional lacZ fusions. To study the regulation of the M. smegmatis fxbA gene by using lacZ gene fusions, it was first necessary to construct a newpromoter-probe vector. Most mycobacterial reporter vectors containa kanamycin resistance gene and cannot be selected for in theM. smegmatis ideR mutant strain SM3 that harbors the same antibioticmarker in the chromosome (6). Moreover, in preliminary experiments,we had noticed that the cells containing the fxbA-lacZ fusionpreviously used to study fxbA regulation (9) showed a relativelyhigh enzyme level in high-iron medium (data not shown), possiblydue to readthrough from vector sequences that acted as promoters.To solve these problems, we constructed a new E. coli-mycobacteriashuttle vector designated pSM128. This plasmid contains the integrativecassette from mycobacteriophage L5 (18), a spectinomycin/streptomycinresistance gene, a promoterless lacZ, which is preceded by a T4telement and a unique ScaI cloning site. M. smegmatis transformedwith this vector exhibited extremely low $beta$ -galactosidase levels(legend to Fig. 5).

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FIG. 5. fxbA expression in wild-type and ideR mutant strains. The upstream regulatory region of the C. diphtheriae tox gene and different segments of the fxbA promoter region were cloned into the integrative lacZ reporter vector pSM128. These constructs and the vector were transformed into the wild-type M. smegmatis strain mc²155 and its isogenic ideR mutant derivative SM3. Individual colonies were purified and then grown in LB broth (HI [high iron]) that has repressing levels of iron (30 µM) and also in LB that had been treated with the iron chelator DP to remove Fe (LI [low iron]). Cells were harvested, and $beta$ -galactosidase specific activities were determined as described in Materials and Methods. (A) Plasmids containing the promoter $-$ lacZ constructs and schema of their structure. IdeR binding sites are indicated by boxes. Coordinates of the DNA fragments used for the constructions are given in Materials and Methods. Arrows indicate the approximate site of the TSP and direction of transcription. The proximal IdeR box is truncated in pSM354, as indicated in the diagram. (B) Averages of experiments done in triplicate. The $beta$ -galactosidase activities of strains containing the promoterless vector pSM 128, less than 3 U in all conditions, were subtracted to give the values presented.

We first wanted to study the role of the newly identified IdeR binding site (Fig. 2) in the regulation of fxbA and also toexamine the possible involvement of another potential IdeR boxthat was observed 140 bp upstream of the fxbA start codon (9).Using pSM128, we constructed transcriptional fusions to lacZ ofvarious parts of the fxbA upstream regulatory region as describedin Materials and Methods and depicted in Fig. 5. As a positivecontrol, we constructed a transcriptional fusion with the C. diphtheriaetox gene that can be regulated by IdeR (32). These plasmid constructsand the promoterless vector pSM128 were transformed into M. smegmatiswild-type mc²155 and ideR mutant SM3. Cells carrying these fusions were thengrown in high- or low-iron medium, and $beta$ -galactosidase assayswere performed. As shown in Fig. 5, fxbA-lacZ fusions containingthe downstream, proximal IdeR box were repressed by iron in mc²155, as the $beta$ -galactosidase levels obtained in low iron were 7-to 10-fold higher than those obtained in high iron. Similarly,the expression of the tox promoter was approximately fourfoldhigher when mc²155 containing pSM223 was grown in low iron. Expression of thetox- and fxbA-lacZ transcriptional fusions was independent ofiron in the ideR mutant strain SM3. However, the levels of fxbA-lacZexpression in the mutant were approximately 50% lower than thoseobserved during growth of the wild-type strain in low iron. Theseobservations are consistent with the results obtained by primerextension presented above that also indicated that IdeR is requiredfor full expression of fxbA under nonrepressive (low-iron) conditions.This was not true for tox expression, since the tox-lacZ fusion $beta$ -galactosidase levels in SM3 grown in both low- and high-ironmedia were comparable to those observed in mc²155 grown in low-ironmedium.

The presence or absence of the putative distal iron box had little or no effect on the regulation of fxbA, as the $beta$ -galactosidasevalues obtained in cells containing the pSM371 construct thathas both iron boxes are very similar to those observed in thestrain carrying pSM323 that contains only the proximal one (Fig.5). Gel retardation experiments have also shown that DNA fragmentscontaining the putative upstream IdeR binding site do not bindIdeR (data not shown), indicating that this sequence does notplay a role in fxbA expression. We also tried to modify the fxbApromoter by disrupting the proximal IdeR binding site while allowingfull expression of this gene, as this would conclusively provethat this site was essential for repression. However, this firstattempt was unsuccessful, as all fxbA-lacZ activity was lost whenwe removed the downstream arm of the IdeR binding site palindrome,situated 6 bp downstream from the TSP in the fusion constructpSM354. Similar low levels of activity were observed when a lacZfusion construct was made with an DNA fragment from the fxbA promoterregion missing both potential iron boxes (data not shown). Thisfinding suggests that the 5' terminus of the fxbA mRNA, removedby the cloning, may be necessary for RNA stability. However, furtherexperiments that make other modifications of the promoter regionwill be necessary to understand the actual mechanism of IdeR repressionof fxbA.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

We had previously shown that the M. smegmatis IdeR represses mycobacterial siderophore biosynthesis in the presence of iron(6) but at that time had not identified any mycobacterial genesthat were directly repressed by this protein. IdeR can replaceDtxR, the C. diphtheriae iron-dependent regulator of toxin andsiderophore biosynthesis, as it can bind to DtxR target genesin cell-free assays, and ideR, its structural gene, can complementC. diphtheriae dtxR mutants (32). It was also shown that IdeRand DtxR are 80% identical in the first 140 amino acids (5),where the helix-turn-helix DNA binding motif, metal binding sites,and multimerization domains are found in DtxR (23, 24, 28).This postulated structural similarity of IdeR and DtxR has beenconfirmed, as the crystal structure of the M. tuberculosis IdeR,recently determined, shows that IdeR and DtxR have almost identicalstructures in the first two domains (21). The above genetic,physiological, and structural observations strongly suggestedthat IdeR represses its target genes in a manner identical tothat of DtxR. This mechanism would include the formation of aFe²⁺-stabilized IdeR dimer that enables it to bind to operator sequencesin the promoters of mycobacterial iron acquisition genes, inhibitingtheirtranscription.

To provide evidence for this hypothesis, we have now analyzed the interaction of IdeR with the M. smegmatis fxbA, the firstsiderophore biosynthetic gene described for this genus (9).The binding of IdeR to the fxbA operator was characterized bygel mobility shift assays. IdeR required activation by divalentmetals, e.g., Fe²⁺, Ni²⁺, Co²⁺, Zn²⁺, Mn²⁺, or Cd²⁺, in order to bind to the fxbA operator, as has been previouslyshown for DtxR and Fur binding to their operator sites (1,30) and also for IdeR binding to the C. diphtheriae tox operator(32). After metal binding, IdeR protected a 28-bp sequence ofthe fxbA regulatory region from DNase I digestion. The IdeR bindingbox was 74% identical to the 19-bp consensus DtxR binding siteselected in vitro and shown to be the minimal essential targetsequence (39). The protected region observed in our experiments,i.e., the IdeR iron box, was found to encompass the translationalstart codon, the putative RBS, the TSP, the 13-bp palindromicsequence, and most of the $-$ 10 region. This is similar to DtxRand DtxR-like regulated promoters in which the operator sequenceoverlaps the $-$ 10 and downstream regions (13, 17, 30, 40).Binding of a protein to this region would be expected to interferewith the binding of the RNA polymerase and transcription initiation,as would the binding of Fur to its target promoters. In theselatter genes, mainly studied in enteric bacteria, Fur bindingsites are generally located between the $-$ 40 and +1 bp relativeto the TSP (12).

Our results show that fxbA expression is negatively regulated by iron only when IdeR is present. This indicates that the repressionmust be mediated by the ferration of IdeR and the subsequent bindingof the activated protein to the fxbA promoter, as discussed above.However, the levels of fxbA expression in the ideR mutant wereapproximately 50% lower than those observed in the wild-type strainin nonrepressive conditions. A similar effect was observed whenlevels of fxbA mRNA were measured by primer extension analyses.These results are similar to those previously observed when totalsiderophore production was assayed in M. smegmatis ideR mutants(6). In these experiments, exochelin and mycobactin synthesiswere partially independent of iron levels in ideR mutant strains,but their levels were approximately 50% of those observed whenthe wild-type strain was grown in low iron. It is possible thatIdeR positively controls fxbA transcription and siderophore synthesisas a directly acting positive regulator or as an activator ofa second activator for these genes. It could also act as a repressorof a repressor. A similar cascade mechanism has been hypothesizedfor the heme-dependent induction of hmuO, a DtxR- and iron-regulatedgene encoding a heme oxygenase in C. diphtheriae (29).

The possibility that IdeR acts directly as a positive regulator of fxbA led us to examine the function of a potential IdeRbinding site observed approximately 140 bp upstream of the TSPof fxbA (9). However, this sequence did not bind IdeR, andits removal had no effect on fxbA expression, indicating it hadno function in fxbA regulation. The inactivation of ideR causedreduced transcription of fxbA but not of tox or several otheriron/IdeR-regulated genes that have recently been characterizedfrom M. tuberculosis (11a, 26). On the other hand, inactivationof ideR caused pleiotropic effects such as reduced expressionof the antioxidant enzymes KatG and SodA in M. smegmatis and increasedsensitivity to isoniazid (6-8). Thus, it is also possible thataltered metabolic pathways in the ideR mutant indirectly affectthe transcription of some promoters. Experiments are now in progressto determine the molecular mechanism of IdeR's positive functionin mycobacterial siderophore biosynthesis, oxidative stress response,and isoniazidresistance.

	ACKNOWLEDGMENTS

Olivier Dussurget and Juliano Timm contributed equally to thiswork.

We thank Michael Heller for atomic absorption spectroscopy and Jeanie Dubnau, Marcela Rodriguez and Riccardo Manganelli forvaluablediscussions.

This work was supported by grants AI-26170 (to W.R.J.), AI-14107 (to R.K.H.), and GM 32651 and AI-46655 (both to I.S.) fromthe National Institutes of Health and by a fellowship from theMinistère de l'Education Nationale, de l'Enseignement Supérieuret de la Recherche to O.D.

	FOOTNOTES

^* Corresponding author. Mailing address: TB Center, Public Health Research Institute, 455 First Ave., New York, NY 10016. Phone:(212) 578-0867. Fax: (212) 578-0804. E-mail: smitty{at}phri.nyu.edu.

Publication no. 64 from the TB Center, Public Health ResearchInstitute.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Bagg, A., and J. B. Neilands. 1987. Molecular mechanism of regulation of siderophore-mediated iron assimilation. Microbiol. Rev. 51:509-518[Free Full Text].
2.	Bashyam, M. D., D. Kaushal, S. K. Dasgupta, and A. K. Tyagi. 1996. A study of mycobacterial transcriptional apparatus: identification of novel features in promoter elements. J. Bacteriol. 178:4847-4853[Abstract/Free Full Text].
3.	Bullen, J. J., H. J. Rogers, and E. Griffiths. 1978. Role of iron in bacterial infection. Curr. Top. Microbiol. Immunol. 80:1-35[Medline].
4.	Cutting, S., R. Roels, and R. Losick. 1991. Sporulation operon spoIVF and the characterization of mutations that uncouple mother-cell from ferespore gene expression in Bacillus subtilis. J. Mol. Biol. 221:1237-1256[Medline].
5.	Doukhan, L., M. Predich, G. Nair, O. Dussurget, I. Mandic-Mulec, S. T. Cole, D. R. Smith, and I. Smith. 1995. Genomic organization of the mycobacterial sigma gene cluster. Gene 165:67-70[Medline].
6.	Dussurget, O., G. M. Rodriguez, and I. Smith. 1996. An ideR mutant of Mycobacterium smegmatis has a derepressed siderophore production and an altered oxidative-stress response. Mol. Microbiol. 22:535-544[Medline].
7.	Dussurget, O., G. M. Rodriguez, and I. Smith. 1998. Protective role of the mycobacterial IdeR against reactive oxygen species and isoniazid toxicity. Tuberc. Lung Dis. 79:99-106[Medline].
8.	Dussurget, O., and I. Smith. 1998. Interdependence of mycobacterial iron regulation, oxidative stress and INH resistance. Trends Microbiol. 6:354-358[Medline].
9.	Fiss, E. H., S. Yu, and W. R. Jacobs, Jr. 1994. Identification of genes involved in the sequestration of iron in mycobacteria: the ferric exochelin biosynthetic and uptake pathways. Mol. Microbiol. 14:557-569[Medline].
10.	Gobin, J., and M. Horwitz. 1996. Exochelins of Mycobacterium tuberculosis remove iron from human iron-binding proteins and donate iron to mycobactins in the M. tuberculosis cell wall. J. Exp. Med. 183:1527-1532[Abstract/Free Full Text].
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