INTRODUCTION

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To succeed in colonization of the host and subsequently cause disease, bacterial pathogens must first adhere to target tissues and concomitantly obtain nutrients which are essential for their growth. Iron is usually one such essential nutrient, and the ability of a pathogen to scavenge iron is an important virulence trait (55). In animals, the iron is not freely available to microorganisms, as it is bound to proteins such as transferrin (TF) and lactoferrin (LF) in the serum and other secretory fluids. Therefore, in order to survive, bacteria have evolved various iron uptake mechanisms. Some species, e.g., Escherichia coli and Pseudomonas spp., secrete low-molecular-weight siderophores which display a high affinity for ferric ions (36). These molecules can remove Fe(III) from TF or LF, and iron-loaded siderophores can bind to specific receptors on the bacterial surface to finally deliver the iron into the cell. Other bacteria, e.g., Neisseria spp. and Haemophilus influenzae, do not synthesize siderophores but produce receptors for the TF- and LF-iron complexes allowing iron uptake through direct contact between these host iron-binding proteins and the bacterial cell surface (9, 23, 46, 47). Bordetella pertussis, the etiologic agent of whooping cough in humans, and Bordetella bronchiseptica, the causative agent of swine atrophic rhinitis and kennel cough, may possess both iron uptake systems, since they synthesize alcaligin, a hydroxamate-type siderophore (1, 21, 34), as well as an outer membrane LF-binding protein (31, 43).

Iron uptake systems are usually expressed only under iron-limited growth conditions. In several species, this regulation mechanism involves the Fur (ferric ion uptake regulation) protein (24). In iron-rich growth conditions, the Fur repressor chelates Fe(II), binds to operator sequences in the promoter region of its target genes, and blocks transcription. These operators are called Fur-binding sites (FBS) or iron boxes. Under low-iron conditions, Fur is unable to bind to the FBS (14). Fur and iron may also modulate the expression of genes encoding virulence factors unrelated to iron metabolism, such as exotoxin A in Pseudomonas aeruginosa (40, 41), Shiga-like toxin in E. coli (13), or pH-regulated proteins in Salmonella typhimurium (17). Thus, the iron status of the environment appears to be used as a signal to trigger the expression of virulence genes in many pathogens.

Little is known about iron regulation in the bordetellae. The fur genes of B. pertussis, B. bronchiseptica, and Bordetella parapertussis have been cloned and sequenced recently (4, 12, 39). Several iron-repressed or iron-induced proteins have been detected (1, 3, 31), but only a few Fur target genes have been identified so far. Among them is the alcABC operon, coding for the first three enzymes of the alcaligin siderophore biosynthesis pathway (20, 28). Other cloned Fur-repressed genes encode outer membrane proteins BfeA, BfrB, and BfrC, receptors for ferric enterobactin and other hydroxamate siderophores in B. pertussis and B. bronchiseptica (5, 7), and BfrA, an unidentified exogenous siderophore receptor specific to B. bronchiseptica (6). The alcaligin receptor and its structural gene have not been characterized yet. To further elucidate the iron regulatory network in bordetellae and to study its involvement in virulence expression, we used the Fur titration assay (FURTA) of Stojiljkovic et al. to isolate Fur target genes (54). The same genetic approach has led to the recent identification of the B. pertussis sodA gene, encoding an Mn-containing superoxide dismutase (22). We present here the cloning and sequencing of a new Fur-repressed gene, alcR, encoding an AraC-type transcriptional regulator in B. bronchiseptica, B. pertussis, and B. parapertussis. This gene is located 2 kb downstream from the alcaligin biosynthesis operon. Sequence analysis of the alcABC-alcR intergenic region suggests that the alc operon may contain two additional open reading frames (ORFs). Construction and characterization of B. pertussis and B. bronchiseptica alcR mutants showed that AlcR is necessary for expression of the alcABC operon and thus required for alcaligin production but that it is not involved in the expression of the major B. pertussis virulence factors, filamentous hemagglutinin (FHA), pertussis toxin (PTX), pertactin (PRN), and adenylate cyclase hemolysin (AC-Hly). In vivo studies revealed that AlcR is not required for colonization in the mouse respiratory infection model.

	MATERIALS AND METHODS

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Bacterial strains, plasmids, and growth conditions. The strains and plasmids used in this work are listed in Table 1. E. coli strains were grown at 37°C in Luria-Bertani (LB) medium (33) or on solid media obtained by addition of Bacto-Agar (1.5% [wt/vol]; Difco). Bordetella strains were grown at 37°C on Bordet-Gengou (BG) (10) agar base plates (Difco) supplemented with 1% glycerol and 15% sheep blood. Liquid cultures were grown in Stainer-Scholte (SS) medium (51) containing 10 µg of FeSO₄ · 7H₂O per ml (iron-rich SS medium) or in SS medium without addition of FeSO₄ · 7H₂O (iron-limited SS medium). Bordetella avium was grown in SS medium supplemented with 2 mg of 2-ketoglutarate per ml, 2 mg of pyruvate per ml, 10 µg of pantothenate per ml, 20 µg of L-phenylalanine per ml, and 0.5 mg of nicotinamide per ml. When necessary, antibiotics were included in the growth media at the following concentrations (in micrograms per milliliter): ampicillin, 150; chloramphenicol, 30; gentamicin, 10; kanamycin, 30; nalidixic acid, 30; streptomycin, 100; and tetracycline, 20.

DNA techniques. Plasmid DNA was routinely isolated by the alkaline lysis method (45) or purified by using a Nucleobond AX kit (Macherey-Nagel, Hoerdt, France) for sequencing. Restriction endonucleases and T4 DNA ligase were obtained from Boehringer Mannheim and used according to standard procedures (45). The PstI DNA fragment inserted into pEP279 and appropriate subclones was sequenced by using a T7 polymerase kit from Pharmacia, -³⁵S-dCTP, and a combination of universal, reverse, and custom-synthesized primers (Pharmacia). The sequence was later confirmed by using an ABI PRISM Dye Terminator Cycle Sequencing kit and an ABI PRISM 377 sequencer (Perkin-Elmer). The B. pertussis and B. parapertussis alcR chromosomal locus was amplified by PCR with Vent DNA polymerase (New England Biolabs Inc., Beverly, Mass.) and oligonucleotides B10 (5'-GACGATGAAATCGGTGAGCGC-3') and B3' (5'-GCGCCGAAGGCTGGCAGGTAG-3'), which start at positions 1826 and 3306 (complementary strand) in the deposited B. bronchiseptica sequence, respectively. PCR products were cloned into the EcoRV site of pBCSK⁺. For each Bordetella species, sequence analysis was carried out on two independently isolated recombinant plasmids bearing inserts in the opposite orientation.

FURTA. The FURTA was essentially performed as described by Stojiljkovic et al. (54). A partial B. bronchiseptica BB1015 genomic library had been constructed previously to isolate the fur gene in this organism (38). This strain is an Sm^r derivative of NL1015 (31). Chromosomal PstI DNA fragments with sizes ranging from 2 to 4 kb had been cloned into the high-copy-number plasmid pBCSK⁺ (Stratagene, San Diego, Calif.). E. coli H1717 carrying the chromosomal Fur-repressible fhuF::lacZ fusion was transformed with this partial library, and Cm^r transformants were screened for the Lac⁺ phenotype on MacConkey lactose agar plates (Difco) containing 50 µM FeCl₃. Four red colonies (Lac⁺) were isolated. Restriction mapping of the four recombinant plasmids (pEP276 to pEP279) showed that each one contained a distinct DNA insert. The recombinant plasmid conferring the strongest Lac⁺ phenotype in the assay, pEP279, was further studied.

Computer analysis of sequences. The nucleotide and protein sequences were analyzed by using DNA Strider 1.2 software (Service de Biochimie et de Génétique Moléculaire du CEA, Saclay, France). Sequence homology was identified with the help of the BLASTN and BLASTP programs (2).

Construction of alcR mutants. A HincII DNA restriction fragment of 1.3 kb containing the Km^r cassette from pUC4K (Pharmacia) was inserted into the unique NruI site of pEP279. The resulting plasmid, pEP300, was digested with BamHI and SalI, and the 4.8-kb DNA fragment bearing alcR::Km^r was subcloned into Gn^r suicide vector pJQ200KS⁺ (42). The obtained plasmid, pEP308, was transformed into E. coli S17.1 (50) and then transferred to B. bronchiseptica BB1015 by conjugation as previously described (52). Exconjugants bearing the pEP308 insertion in the chromosome were selected on BG agar-streptomycin-gentamicin plates. The Bacillus subtilis sacB gene present on pJQ200KS⁺ had been shown to confer sucrose sensitivity to several gram-negative bacteria (42). We tried to select for double recombinants by plating exconjugants on plates of BG agar plus kanamycin or LB plus kanamycin supplemented with 5 or 10% sucrose, but all exconjugants were sucrose resistant. This suggests that, in contrast to the case for E. coli, the sacB gene was not expressed from its own promoter in B. bronchiseptica. To isolate alcR mutants without the help of counterselection, one exconjugant was grown to stationary phase in iron-rich SS medium plus streptomycin, and culture dilutions were plated onto BG agar plus streptomycin plus kanamycin. Of 333 clones tested, 15 spontaneous Km^r Sm^r Gn^s mutants were isolated. One of the alcR::Km^r mutants was designated BBEP205.

CAS assay. The chrome azurol S (CAS) assay (48) was used to assess alcaligin siderophore production by Bordetella cells as described previously (3). Briefly, cells were grown to stationary phase in iron-limited SS medium. A 0.5-ml volume of culture supernatant was added to 0.5 ml of CAS solution, and the A₆₃₀ of the CAS dye was measured after incubation for 4 h at room temperature.

Cell fractionation and protein analysis. Cells from 20-ml B. bronchiseptica or B. pertussis cultures were resuspended in 4 ml of HEPES (50 mM; pH 7.4) and disrupted with a French pressure cell (SLM-Aminco, Rochester, N.Y.). The pressates were centrifuged at 2,065 × g for 5 min at 4°C to sediment cellular debris and unbroken cells. Whole-cell lysates (WCLs) were saved or centrifuged at 111,000 × g for 1 h at 4°C to separate soluble and insoluble cell fractions.

-gal and AP assays. -Galactosidase (-gal) and alkaline phosphatase (AP) specific activities generated by fhaB::lacZ and ptx::phoA fusions in strains BP953 and BPEP214 were measured on WCLs as previously described (11, 33), except that samples were incubated at 37 instead of 28°C to facilitate detection of the low-level AP activity in these strains.

Colonization assay in the murine model. BPSM or BPEP184 cells were grown for 24 h on BG agar, and then 3- to 4-week-old mice were intranasally challenged with 5 × 10⁶ cells from one of the strains. Infected mice were sacrificed by cervical dislocation 1 h after exposure and at 5, 8, 12, and 19 days thereafter (four mice per time point). The lungs were removed and homogenized in saline with tissue grinders. Enumeration of bacteria was performed on BG agar. To assess the stability of the alcR mutation, bacteria reisolated from the lungs of BPEP184-infected mice were tested for their resistance to kanamycin and absence of siderophore production. Both phenotypes had been retained.

Nucleotide sequence accession number. The nucleotide sequence of the B. bronchiseptica 3,526-bp PstI DNA fragment in pEP279 has been assigned EMBL accession no. AJ000061.

	RESULTS

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Isolation of a Fur-repressed gene. We used the FURTA system (54) to isolate potential Fur-binding fragments in a partial B. bronchiseptica genomic DNA library that we had previously constructed (38). E. coli H1717 bearing the Fur-repressible fhuF::lacZ fusion was transformed with the pool of recombinant plasmids, and four red colonies (Lac⁺ phenotype) were isolated on iron-rich MacConkey agar plates, suggesting that the cloned B. bronchiseptica sequences were interfering with Fur repression of the chromosomal lac fusion. One such plasmid, pEP279, was studied further since it gave the strongest Lac⁺ phenotype in the assay. Restriction mapping showed that pEP279 contained a 3.5-kb PstI DNA fragment. Successive deletions in the insert enabled the region conferring the Lac⁺ phenotype to be localized to a 0.6-kb SacI-NarI fragment (Fig. 1). The SacI-KpnI portion derived from this fragment did not confer a Lac⁺ phenotype to H1717; thus, the potential FBS was mapped to the other 0.3-kb half, between the KpnI and NarI sites, as shown in Fig. 1.

View larger version (10K): [in this window] [in a new window]   FIG. 1.   Mapping of the region of pEP279 conferring a Lac+ phenotype in the FURTA. Subclones of the 3.5-kb PstI insert were constructed by deletions in pEP279 using the following restriction enzymes: HII, HincII; K, KpnI; N, NarI; P, PstI; S, SmaI; SI, SacI; and SII, SacII. The recombinant plasmid-associated Lac phenotypes are indicated on the right. The deduced localization of the FBS is also shown (black box).

View larger version (56K): [in this window] [in a new window]   FIG. 2.   Nucleotide sequence of alcR of B. bronchiseptica and deduced amino acid sequence of AlcR. Selected restriction enzyme sites, the putative FBS, and possible initiation codons are indicated (underlined). Differences detected in the B. pertussis and B. parapertussis sequences are also shown (underlined and labelled and , respectively).

View larger version (28K): [in this window] [in a new window]   FIG. 3.   Alignment of the deduced C-terminal amino acid sequences of AlcR of B. bronchiseptica and PchR of P. aeruginosa. The final 180 residues of each protein are shown. The putative helix-turn-helix and AraC signature motifs (underlined), exact matches, and conserved changes (+) are indicated.

Presence of the Fur-repressed gene in other Bordetella genomes. B. pertussis and B. parapertussis are human pathogens closely related to B. bronchiseptica, while B. avium, a poultry pathogen, is more distant, according to phylogenetic analysis (35). PCR experiments were performed on genomic DNA from B. pertussis BPSM, B. parapertussis PEP, and B. avium 103004, with oligonucleotides hybridizing to the flanking sequences of the B. bronchiseptica Fur-repressed gene. PCR amplification products of the expected size were obtained with chromosomal DNA from B. pertussis and B. parapertussis, but under the same conditions, no amplification product was generated with B. avium DNA (data not shown). Furthermore, B. avium genomic DNA did not hybridize to the KpnI-PstI fragment of pEP279 used as a probe in Southern blot experiments (data not shown). Thus, B. avium 103004 may lack this gene, or the sequence may be too divergent to be detected under the hybridization conditions tested.

Characterization of B. pertussis and B. bronchiseptica alcR mutants. Under low-iron growth conditions, B. pertussis and B. bronchiseptica have been shown to secrete the same alcaligin siderophore (Sid⁺ phenotype) (34). To our knowledge, B. parapertussis and B. avium siderophores have not been isolated. We found that B. parapertussis grown under iron-restricted conditions produced siderophore, but, interestingly, no siderophore was detected in the culture supernatant of B. avium 103004 (data not shown). In order to determine whether the cloned gene is involved in siderophore production, B. pertussis and B. bronchiseptica mutants were generated by exchange with an interrupted allele. In this construct, a kanamycin resistance cassette was inserted at the NruI site located in the 3' region of the ORF (Fig. 2). This insertion disrupted the AraC signature motif of the putative regulatory protein (Fig. 3).

View larger version (83K): [in this window] [in a new window]   FIG. 4.   Effect of alcR inactivation on protein and siderophore production in B. pertussis and B. bronchiseptica as determined by SDS-PAGE analysis. (A) WCLs of cultures grown in iron-limited SS medium. Lanes: 1, BPSM (wild type); 2, BPEP184 alcR::Kmr; 3, BPEP184(pEP301); 4, BPEP184(pBBR1MCS); 5, BB1015 (wild type); 6, BBEP205 alcR::Kmr; 7, BBEP205(pEP301); 8, BBEP205(pBBR1MCS). Siderophore (Sid) production in matching culture supernatants tested by the CAS assay is indicated below the gel (+, high level of activity; , no siderophore activity detected). (B) WCLs of BB1015 (lanes 1 and 3) and BBEP205 alcR::Kmr (lanes 2 and 4) grown in iron-rich SS medium (SS+Fe) (lanes 1 and 2) or iron-limited SS medium (SS-Fe) (lanes 3 and 4). (C) Soluble proteins prepared from BPSM (lane 5) and BPEP184 alcR::Kmr (lane 6) grown in iron-limited SS medium. For both gels, the molecular masses of markers in lane MM are 97.4, 66.2, 45, and 31 kDa, from top to bottom. The 60-kDa iron-repressed protein is indicated (arrowheads).

The AlcR-dependent 60-kDa polypeptide is a soluble iron-repressed protein. To investigate whether the production of the 60-kDa protein was iron regulated, B. bronchiseptica BB1015 and BBEP205 were grown in iron-rich and iron-limited SS media. SDS-PAGE analysis of WCLs revealed that the AlcR-dependent 60-kDa protein was synthesized by BB1015 only under low-iron growth conditions (Fig. 4B, compare lanes 1 and 3). Thus, this iron-repressed protein was designated IRP60. In agreement with our previous observations, BBEP205 AlcR grown in iron-limited or iron-rich SS medium did not produce IRP60 (Fig. 4B, lanes 2 and 4). To determine the IRP60 cell location, soluble and membrane protein fractions were prepared from lysates of BPSM and BPEP184 cells grown in iron-limited SS medium. The protein samples were analyzed by SDS-PAGE. The 60-kDa protein was identified in the soluble protein fraction from BPSM, while it was absent in the BPEP184 extract (Fig. 4C, compare lanes 5 and 6). IRP60 was not detected in membrane preparations (data not shown). These observations suggest that IRP60 is a cytoplasmic or periplasmic protein.

The alcR gene is located downstream from the alcABC operon. Structural genes of regulatory proteins sometimes lie in the vicinity of their target genes. To identify putative AlcR-regulated genes, the nucleotide sequence upstream from alcR in pEP279 was determined up to the first PstI cloning site shown in Fig. 1. A BLASTN search (2) in the nonredundant GenBank/EMBL/DDBJ/PDB library revealed a 300-bp sequence overlap with the 3' end of the alcABC operon encoding alcaligin biosynthesis enzymes (20, 28). Thus, alcR was mapped about 2 kb downstream from the alcC gene on the chromosome and in the same orientation as the alcABC operon (Fig. 5). We noticed a few discrepancies between the B. bronchiseptica alcC downstream sequence deposited in the databank by Giardina et al. (20) and our sequence determination. The differences corresponded to three base substitutions, two base insertions, and one base inversion. Sequence analysis of the alcR upstream region revealed two tightly linked ORFs oriented in the same direction as alcC (Fig. 5). The first ORF contains an ATG codon overlapping the alcC stop codon (Fig. 6A) and could encode a 29-kDa polypeptide. The second ORF, 14 bp downstream from the stop codon of the preceding ORF and 6 bp downstream from a putative TAAGGAG RBS (Fig. 6A), could specify a 45-kDa protein. Such a tight organization suggests that these genes are part of the alcABC operon. Thus, they were designated alcD and alcE. Amino acid sequences deduced from alcD (AlcD) and alcE (AlcE) were subjected to a BLASTP search (2) in the library cited above. Homology between AlcE and TdnA1, the large subunit of Pseudomonas putida terminal dioxygenase, was detected. TdnA is an iron-sulfur protein involved in aniline degradation (18). A high degree of similarity was observed around the putative iron-sulfur center of TdnA1, as shown in Fig. 6B, suggesting that AlcE might also be an iron-sulfur protein. A scan with AlcD failed to reveal any homology with sequences in the bank.

View larger version (9K): [in this window] [in a new window]   FIG. 5.   Physical map of the alc locus of B. bronchiseptica. Blocks representing ORFs are drawn to scale from the 4.3-kb alcABC sequence determined by Giardina et al. (20) and from the sequence data for the 3.5-kb PstI DNA fragment presented in this study. PstI restriction sites (P), FBS upstream from alcA and alcR (black bars), and bcr', the 5' extremity of a putative bicyclomycin resistance gene downstream from alcR, are indicated.

View larger version (26K): [in this window] [in a new window]   FIG. 6.   (A) Flanking sequences of the alcD gene and deduced amino acid sequences. The tight genetic organization of the alcC, alcD, and alcE genes is shown. The PstI restriction site (underlined), the 3'-terminal sequence of alcC (lowercase), and the deduced C-terminal sequence of AlcC and the alcD and alcE putative coding sequences and predicted translation products (uppercase) are shown. A potential RBS upstream from alcE is also indicated (underlined). (B) Partial amino acid sequence alignments of the putative AlcE protein with P. putida TdnA1. C and H residues forming the predicted iron-sulfur reaction center in TdnA1 (underlined) and conservative changes (+) are indicated.

AlcR is not involved in FHA, AC-Hly, PRN, or PTX production or in colonization. Since in other pathogens the production of important virulence factors may be iron regulated, we investigated whether AlcR is involved in the production of FHA, AC-Hly, PRN, or PTX in B. pertussis. The WCLs and culture supernatants of BPSM and BPEP184 were compared by SDS-PAGE and immunoblot analyses. The two strains produced similar amounts of FHA, AC-Hly, PRN, and PTX, indicating that AlcR is not required for the synthesis of these four virulence factors (data not shown). The results for FHA and PTX were confirmed by using transcriptional reporter gene fusions to the fhaB and ptx chromosomal genes. For this purpose, the alcR::Km^r mutation was introduced into BP953 (fhaB::lacZ ptx::phoA) (53) by allelic exchange to generate BPEP214. The -gal and AP activities of the isogenic AlcR⁺-AlcR strains were then compared (data not shown). The alcR disruption had no significant effect on -gal and AP activities, indicating that AlcR is not involved in fhaB or ptx expression.

	DISCUSSION

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As a first step to elucidate the iron regulatory network in Bordetella spp., we chose to identify target genes of the global iron regulator Fur. We have isolated a clone bearing an FBS from a B. bronchiseptica partial library by using the E. coli FURTA (54). The FBS in the plasmid was mapped about 2 kb downstream from one end of the cloned 3.5-kb fragment. Sequence analysis of the 1.5-kb region downstream of the FBS revealed an ORF, alcR, which could encode an AraC-like regulatory protein homologous to PchR, a regulator of pyochelin and ferripyochelin receptor synthesis in P. aeruginosa (26, 27, 49), and to YbtA, a regulator of pesticin and yersiniabactin receptor synthesis in Yersinia pestis (16). No significant ORF running in the opposite direction in the 2-kb flanking region was detected, strongly suggesting that the target of Fur repression is the downstream alcR gene. In the same orientation, and about 120 bp downstream from alcR, an ORF (bcr) encoding a putative inner membrane drug resistance translocase was detected. The large spacing between alcR and bcr suggests that bcr is transcribed from its own promoter, but since no obvious terminator was found in the alcR-bcr intergenic sequence, the possibility that alcR and bcr are cotranscribed and form an operon cannot be ruled out. The alcR upstream sequence in the cloned 3.5-kb fragment was shown to contain the very end (7 C-terminal amino acid residues) of the previously identified alcC gene (20, 28), followed by two tightly linked ORFs running in the same direction. Such a spatial arrangement suggests that these ORFs are part of the alcaligin biosynthesis alcABC operon (28). We designated them alcD and alcE. A homology search indicated that alcE could encode an iron-sulfur protein. No homology was detected for the putative AlcD protein. In their paper reporting the identification of the alcABC operon, Kang et al. suggested that in addition to AlcA, AlcB, and AlcC, at least two other enzymes are required to complete the siderophore biosynthesis pathway from succinyl-hydroxy-putrescine to alcaligin (28). The alcD and alcE genes could code for these enzymes. Experiments are in progress to determine whether the alcD and alcE ORFs are involved in alcaligin biosynthesis.

Sequence comparison of the B. bronchiseptica, B. pertussis, and B. parapertussis alcR genes showed that the predicted product is highly conserved in these species. Both B. bronchiseptica and B. pertussis produce alcaligin (34), and in this paper we show that B. parapertussis also synthesizes siderophores. It is highly probable that this siderophore is alcaligin. In contrast, no siderophore production was observed in the culture supernatant of B. avium 103004 grown in iron-restricted conditions. Concomitantly, no sequence hybridizing to an alcR probe could be detected in Southern blot experiments with B. avium genomic DNA. Another B. avium strain in our collection presented also a Sid phenotype (38). In neither of these B. avium strains could the production of siderophore be induced by a plasmid-borne copy of the B. bronchiseptica alcR gene (38), suggesting that they were not simply alcR mutants. To our knowledge, B. avium iron uptake systems have not been studied yet, and we do not know whether the absence of siderophore production is a physiological trait of the B. avium species. An LF-binding protein has been identified in the B. avium outer membrane (30), but the role of this protein in iron uptake remains to be elucidated.

B. bronchiseptica and B. pertussis alcR mutants, obtained by in vitro mutagenesis and gene replacement, were deficient in alcaligin production. They were also deficient in the synthesis of a soluble 60-kDa iron-repressed protein (IRP60). Both phenotypes were complemented by an intact plasmid-borne copy of alcR, showing that neither of them resulted from a polar effect of the alcR disruption. Thus, AlcR is required for alcaligin and IRP60 synthesis. Kang et al. demonstrated that AlcC is a soluble iron-repressed protein and that, although predicted to have a size of 70 kDa, AlcC migrates with an apparent molecular mass of 59 kDa during SDS-PAGE (28). It is therefore possible that IRP60 is in fact AlcC, suggesting that AlcR is an activator of the alcC gene. Complementation studies have shown that alcC is transcribed from the alcA promoter and that the alcABC locus constitutes an operon (28). Kang et al. also compared the protein profiles for two B. bronchiseptica mutants bearing polar mutations in the alcA gene with that for a wild-type strain. They reported that the only observed difference was the absence of the AlcC polypeptide in the alcA polar mutants (28). Since the B. pertussis and B. bronchiseptica alcR mutants described in this paper present the same protein profile phenotype as alcA mutants, it is very likely that AlcR is an activator of the whole alc operon in both species, including the putative new alcD and alcE genes located downstream from alcC. Regulatory genes are often autoregulated; however, a comparison of the alcA and alcR promoter regions did not reveal any potential AlcR binding sites. Overexpression and purification of AlcR will enable us to determine the N-terminal sequence of the protein as well as characterize its DNA binding sequence. Alternatively, AlcR may be an intermediate regulator and may activate the promoter of another, as-yetunidentified gene, the latter being the final activator of the alc operon. The identification of AlcR target genes will help establish its position in the iron regulatory network.

A putative FBS overlaps the 10 box of the alcABC promoter, and transcription of the alcABC genes is iron repressed (28). In addition, alcABC transcription appears to be AlcR dependent, suggesting the following model for very tight Fur repression of the alc operon. Under iron-rich growth conditions, the Fur-Fe(II) complex binds to the alcR promoter, generating an AlcR depletion which in turn shuts off alcABC operon transcription. Concomitantly, the Fur-Fe(II) complex binds directly to the alcABC promoter, ensuring a tight double-level repression. Under iron-restricted growth conditions, both promoters are derepressed and AlcR activates alcABC transcription, either directly or via another regulatory protein.

The iron regulatory network strongly influences the production of virulence factors in a number of gram-positive and gram-negative pathogenic bacteria, such as Corynebacterium diphtheria, E. coli, P. aeruginosa, and many others (for a review, see reference 15). The production of the major virulence factors FHA, PTX, PRN, and AC-Hly in B. pertussis was not affected by the inactivation of the alcR gene. The behaviors of the AlcR-deficient mutant and the parental strain in the murine respiratory model were similar probably because the expression of adhesins and toxins was neither enhanced nor repressed in the absence of AlcR. Siderophore production has been shown to contribute significantly to virulence in a number of bacterial pathogens (55), and, like most bacteria, Bordetella spp. also require iron for growth (31). The alcR mutation did not affect colonization in the mouse model, although the mutant strain was unable to secrete siderophore in vitro under iron-limited growth conditions. Our observations therefore suggest that, in addition to alcaligin production, B. pertussis has evolved a second iron uptake mechanism, unless low-level siderophore synthesis, below the detection limit of the CAS assay, occurs in the absence of the regulator. Beall and coworkers recently identified three B. pertussis iron-regulated genes encoding BfeA, BfrB, and BfrC, three outer membrane proteins homologous to receptors of enterobactin, ferrichrome, and another hydroxamate siderophore, respectively (5, 7). They also showed that, in addition to these proteins, B. bronchiseptica synthesizes BfrA, an unidentified exogenous siderophore receptor (6). Thus, via these specific receptors, Bordetella spp. may perhaps scavenge various heterologous ferrisiderophores secreted by the commensal flora of the airways. If the synthesis of these receptors is AlcR independent, the multiplicity of heterologous siderophore-mediated iron uptake systems could compensate for the absence of alcaligin in alcR mutants. Alternatively, Redhead and Hill have suggested that B. pertussis has recourse to a TF-LF receptor to scavenge iron from the host (43). Menozzi et al. have isolated LF-binding outer membrane proteins from both B. pertussis and B. bronchiseptica (31). It is therefore possible that Bordetella spp. use both siderophore-mediated and siderophore-independent iron uptake systems. The testing of mutants bearing deletions of the alcaligin biosynthesis genes in the mouse colonization model could help determine if the alcaligin system is essential.

Interestingly, in certain B. bronchiseptica strains, siderophore production is repressed by BvgA, a global activator of most Bordetella virulence factors (19). This implies that in these strains siderophores are produced only in the avirulent phase, suggesting that siderophores may interfere with colonization in certain circumstances. Consistent with this assumption, Register et al. observed that a B. bronchiseptica mutant deficient in siderophore synthesis in fact expressed enhanced virulence in neonatal pigs (44). The relationship between siderophore production and virulence thus appears to be quite complex in Bordetella spp. and deserves further study.