Cloning of a Vibrio cholerae vibriobactin gene cluster: identification of genes required for early steps in siderophore biosynthesis.

Vibrio cholerae secretes the catechol siderophore vibriobactin in response to iron limitation. Vibriobactin is structurally similar to enterobactin, the siderophore produced by Escherichia coli, and both organisms produce 2,3-dihydroxybenzoic acid (DHBA) as an intermediate in siderophore biosynthesis. To isolate and characterize V. cholerae genes involved in vibriobactin biosynthesis, we constructed a genomic cosmid bank of V. cholerae DNA and isolated clones that complemented mutations in E. coli enterobactin biosynthesis genes. V. cholerae homologs of entA, entB, entC, entD, and entE were identified on overlapping cosmid clones. Our data indicate that the vibriobactin genes are clustered, like the E. coli enterobactin genes, but the organization of the genes within these clusters is different. In this paper, we present the organization and sequences of genes involved in the synthesis and activation of DHBA. In addition, a V. cholerae strain with a chromosomal mutation in vibA was constructed by marker exchange. This strain was unable to produce vibriobactin or DHBA, confirming that in V. cholerae VibA catalyzes an early step in vibriobactin biosynthesis.     

Identification of the vibriobactin receptor of Vibrio cholerae.

Vibrio cholerae produces the novel phenolate siderophore vibriobactin and several outer membrane proteins in response to iron starvation. To determine whether any of these iron-regulated outer membrane proteins serves as the receptor for vibriobactin, the classical V. cholerae strain 0395 was mutagenized by using TnphoA, and iron-regulated fusions were analyzed for vibriobactin transport. One mutant, MBG14, was unable to bind or utilize exogenous vibriobactin and did not grow in low-iron medium. However, synthesis of the siderophore and transport of other iron complexes, including ferrichrome, hemin, and ferric citrate, were unaffected in MBG14. Analysis of membrane proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis demonstrated the loss from the mutant of a 74-kDa iron-regulated outer membrane protein present in the parental strain when grown in iron-limiting conditions. This protein partitioned into the detergent phase during Triton X-114 extraction, suggesting that it is a hydrophobic membrane protein. DNA sequences encoding the gene into which TnphoA had inserted, designated viuA (vibriobactin uptake), restored the wild-type phenotype to the mutant; the complemented mutant expressed the 74-kDa outer membrane protein under iron-limiting conditions and possessed normal vibriobactin binding and uptake. These data indicate that the 74-kDa outer membrane protein of V. cholerae serves as the vibriobactin receptor.     

A multifunctional ATP-binding cassette transporter system from Vibrio cholerae transports vibriobactin and enterobactin

Vibrio cholerae uses the catechol siderophore vibriobactin for iron transport under iron-limiting conditions. We have identified genes for vibriobactin transport and mapped them within the vibriobactin biosynthetic gene cluster. Within this genetic region we have identified four genes, viuP, viuD, viuG and viuC, whose protein products have homology to the periplasmic binding protein, the two integral cytoplasmic membrane proteins, and the ATPase component, respectively, of other iron transport systems. The amino-terminal region of ViuP has homology to a lipoprotein signal sequence, and ViuP could be labeled with [(3)H]palmitic acid. This suggests that ViuP is a membrane lipoprotein. The ViuPDGC system transports both vibriobactin and enterobactin in Escherichia coli. In the same assay, the E. coli enterobactin transport system, FepBDGC, allowed the utilization of enterobactin but not vibriobactin. Although the entire viuPDGC system could complement mutations in fepB, fepD, fepG, or fepC, only viuC was able to independently complement the corresponding fep mutation. This indicates that these proteins usually function as a complex. V. cholerae strains carrying a mutation in viuP or in viuG were constructed by marker exchange. These mutations reduced, but did not completely eliminate, vibriobactin utilization. This suggests that V. cholerae contains genes in addition to viuPDGC that function in the transport of catechol siderophores.     

The Vibrio cholerae VctPDGC system transports catechol siderophores and a siderophore-free iron ligand

Vibrio cholerae, the causative agent of cholera, has an absolute requirement for iron. It transports the catechol siderophores vibriobactin, which it synthesizes and secretes, and enterobactin. These siderophores are transported across the inner membrane by one of two periplasmic binding protein-dependent ABC transporters, VctPDGC or ViuPDGC. We show here that one of these inner membrane transport systems, VctPDGC, also promotes iron acquisition in the absence of siderophores. Plasmids carrying the vctPDGC genes stimulated growth in both rich and minimal media of a Shigella flexneri mutant that produces no siderophores. vctPDGC also stimulated the growth of an Escherichia coli enterobactin biosynthetic mutant in low iron medium, and this effect did not require feoB, tonB or aroB. A tyrosine to phenylalanine substitution in the periplasmic binding protein VctP did not alter enterobactin transport, but eliminated growth stimulation in the absence of a siderophore. These data suggest that the VctPDGC system has the capacity to transport both catechol siderophores and a siderophore-free iron ligand. We also show that VctPDGC is the previously unidentified siderophore-independent iron transporter in V. cholerae, and this appears to complete the list of iron transport systems in V. cholerae.     

Isolation and characterization of the Vibrio cholerae recA gene

A 3.6-kilobase PstI fragment was isolated from a Vibrio cholerae chromosomal DNA library and shown to encode RecA-like activity in complementation studies with Escherichia coli recA mutants. Although DNA hybridization experiments failed to detect any homology between the E. coli and V. cholerae recA genes, hyperimmune antiserum produced against purified E. coli RecA protein recognized epitopes shared by the V. cholerae protein. The V. cholerae chromosomal fragments, when cloned and transferred to E. coli, provided the missing recA functions, including resistance to the alkylating agent methyl methanesulfonate, resistance to UV irradiation, and promotion of homologous recombination in Hfr mating experiments.     

Characterization of a Vibrio cholerae virulence factor homologous to the family of TonB-dependent proteins

IrgA is an iron-regulated virulence factor for infection in an animal model with classical Vibrio cholerae strain 0395. We detected gene sequences hybridizing to irgA at high stringency in clinical isolates in addition to 0395, including another classical strain of V. cholerae, three V. cholerae strains of the El Tor biotype, three non-O1 isolates of V. cholerae, and individual isolates of Vibrio parahaemolyticus, Vibrio fluvialis, and Vibrio alginolyticus. No hybridization to irgA was seen with chromosomal DNA from Vibrio vulnificus or Aeromonas hydrophila. To verify that irgA is the structural gene for the major iron-regulated outer membrane protein of V. cholerae, we determined the amino-terminal sequence of this protein recovered after gel electrophoresis and demonstrated that it corresponds to the amino acid sequence of IrgA deduced from the nucleotide sequence. Gel electrophoresis showed that two El Tor strains of V. cholerae had a major iron-regulated outer membrane protein identical in size and appearance to IrgA in strain 0395, consistent with the findings of DNA hybridization. We have previously suggested that IrgA might be the outer membrane receptor for the V. cholerae siderophore, vibriobactin. Biological data presented here, however, show that a mutation in irgA had no effect on the transport of vibriobactin and produced no defect in the utilization of iron from ferrichrome, ferric citrate, haemin or haemoglobin. The complete deduced amino acid sequence of IrgA demonstrated homology to the entire class of Escherichia coli TonB-dependent proteins, particularly Cir. Unlike the situation with Cir, however, we were unable to demonstrate a role for IrgA as a receptor for catechol-substituted cephalosporins. The role of IrgA in the pathogenesis of V. cholerae infection, its function as an outer membrane receptor, and its potential interaction with a TonB-like protein in V. cholerae remain to be determined.     

Coordinate regulation of siderophore and exotoxin A production: molecular cloning and sequencing of the Pseudomonas aeruginosa fur gene.

A 5.9-kb DNA fragment was cloned from Pseudomonas aeruginosa PA103 by its ability to functionally complement a fur mutation in Escherichia coli. A fur null mutant E. coli strain that contains multiple copies of the 5.9-kb DNA fragment produces a 15-kDa protein which cross-reacts with a polyclonal anti-E. coli Fur serum. Sequencing of a subclone of the 5.9-kb DNA fragment identified an open reading frame predicted to encode a protein 53% identical to E. coli Fur and 49% identical to Vibrio cholerae Fur and Yersinia pestis Fur. While there is extensive homology among these Fur proteins, Fur from P. aeruginosa differs markedly at its carboxy terminus from all of the other Fur proteins. It has been proposed that this region is a metal-binding domain in E. coli Fur. A positive selection procedure involving the isolation of manganese-resistant mutants was used to isolate mutants of strain PA103 that produce altered Fur proteins. These manganese-resistant Fur mutants constitutively produce siderophores and exotoxin A when grown in concentrations of iron that normally repress their production. A multicopy plasmid carrying the P. aeruginosa fur gene restores manganese susceptibility and wild-type regulation of exotoxin A and siderophore production in these Fur mutants.     

Cloning, mutagenesis, and nucleotide sequence of a siderophore biosynthetic gene (amoA) from Aeromonas hydrophila.

Many isolates of the Aeromonas species produce amonabactin, a phenolate siderophore containing 2,3-dihydroxybenzoic acid (2,3-DHB). An amonabactin biosynthetic gene (amoA) was identified (in a Sau3A1 gene library of Aeromonas hydrophila 495A2 chromosomal DNA) by its complementation of the requirement of Escherichia coli SAB11 for exogenous 2,3-DHB to support siderophore (enterobactin) synthesis. The gene amoA was subcloned as a SalI-HindIII 3.4-kb DNA fragment into pSUP202, and the complete nucleotide sequence of amoA was determined. A putative iron-regulatory sequence resembling the Fur repressor protein-binding site overlapped a possible promoter region. A translational reading frame, beginning with valine and encoding 396 amino acids, was open for 1,188 bp. The C-terminal portion of the deduced amino acid sequence showed 58% identity and 79% similarity with the E. coli EntC protein (isochorismate synthetase), the first enzyme in the E. coli 2,3-DHB biosynthetic pathway, suggesting that amoA probably encodes a step in 2,3-DHB biosynthesis and is the A. hydrophila equivalent of the E. coli entC gene. An isogenic amonabactin-negative mutant, A. hydrophila SB22, was isolated after marker exchange mutagenesis with Tn5-inactivated amoA (amoA::Tn5). The mutant excreted neither 2,3-DHB nor amonabactin, was more sensitive than the wild-type to growth inhibition by iron restriction, and used amonabactin to overcome iron starvation.     

Vibrio cholerae iron transport: haem transport genes are linked to one of two sets of tonB, exbB, exbD genes

Vibrio cholerae was found to have two sets of genes encoding TonB, ExbB and ExbD proteins. The first set ( tonB1, exbB1, exbD1 ) was obtained by complementation of a V. cholerae tonB mutant. In the mutant, a plasmid containing these genes permitted transport via the known V. cholerae high-affinity iron transport systems, including uptake of haem, vibriobactin and ferrichrome. When chromosomal mutations in exbB1 or exbD1 were introduced into a wild-type V. cholerae background, no defect in iron transport was noted, indicating the existence of additional genes that can complement the defect in the wild-type background. Another region of the V. cholerae chromosome was cloned that encoded a second functional TonB/Exb system ( tonB2, exbB2, exbD2 ). A chromosomal mutation in exbB2 also failed to exhibit a defect in iron transport, but a V. cholerae strain that had chromosomal mutations in both the exbB1 and exbB2 genes displayed a mutant phenotype similar to that of an Escherichia coli tonB mutant. The genes encoding TonB1, ExbB1, ExbD1 were part of an operon that included three haem transport genes ( hutBCD ), and all six genes appeared to be expressed from a single Fur-regulated promoter upstream of tonB1 . A plasmid containing all six genes permitted utilization of haem by an E. coli strain expressing the V. cholerae haem receptor, HutA. Analysis of the hut genes indicated that hutBCD, which are predicted to encode a periplasmic binding protein (HutB) and cytoplasmic membrane permease (HutC and HutD), were required to reconstitute the V. cholerae haem transport system in E. coli. In V. cholerae , the presence of hutBCD stimulated growth when haemin was the iron source, but these genes were not essential for haemin utilization in V. cholerae .     

Vibriobactin, a siderophore from Vibrio cholerae

A novel siderophore (microbial iron transport compound) has been isolated from low iron cultures of Vibrio cholerae. Belonging to the catecholamide family of chelators, it has been shown to contain three residues of 2,3-dihydroxybenzoic acid and two residues of threonine. Both threonine moieties are present in the form of oxazoline rings. Furthermore, the polyamine backbone of the molecule was proved to be not spermidine, but the rare N-(3-aminopropyl)-1,3-diaminopropane, norspermidine. The structure of the new siderophore has been determined to be N-[3-(2,3-dihydroxybenzamido)propyl]-1, 3-bis[2,3-dihydroxyphenyl)-trans-5-methyl-2-oxazoline-4-carboxamido]prop ane. The compound has been given the trivial name vibriobactin. Mutants defective in the synthesis and utilization of vibriobactin were isolated. In an iron-limited environment V. cholerae was found to respond more strongly to vibriobactin, agrobactin, and ferrichrome than to enterobactin.     

Characterization of ferric and ferrous iron transport systems in Vibrio cholerae

Vibrio cholerae has multiple iron acquisition systems, including TonB-dependent transport of heme and of the catechol siderophore vibriobactin. Strains defective in both of these systems grow well in laboratory media and in the infant mouse intestine, indicating the presence of additional iron acquisition systems. Previously uncharacterized potential iron transport systems, including a homologue of the ferrous transporter Feo and a periplasmic binding protein-dependent ATP binding cassette (ABC) transport system, termed Fbp, were identified in the V. cholerae genome sequence. Clones encoding either the Feo or the Fbp system exhibited characteristics of iron transporters: both repressed the expression of lacZ cloned under the control of a Fur-regulated promoter in Escherichia coli and also conferred growth on a Shigella flexneri mutant that has a severe defect in iron transport. Two other ABC transporters were also evaluated but were negative by these assays. Transport of radioactive iron by the Feo system into the S. flexneri iron transport mutant was stimulated by the reducing agent ascorbate, consistent with Feo functioning as a ferrous transporter. Conversely, ascorbate inhibited transport by the Fbp system, suggesting that it transports ferric iron. The growth of V. cholerae strains carrying mutations in one or more of the potential iron transport genes indicated that both Feo and Fbp contribute to iron acquisition. However, a mutant defective in the vibriobactin, Fbp, and Feo systems was not attenuated in a suckling mouse model, suggesting that at least one other iron transport system can be used in vivo.     

Identification and cloning of a fur regulatory gene in Yersinia pestis.

Yersinia pestis is one of many microorganisms responding to environmental iron concentrations by regulating the synthesis of proteins and an iron transport system(s). In a number of bacteria, expression of iron uptake systems and other virulence determinants is controlled by the Fur regulatory protein. DNA hybridization analysis revealed that both pigmented and nonpigmented cells of Y. pestis possess a DNA locus homologous to the Escherichia coli fur gene. Introduction of a Fur-regulated beta-galactosidase reporter gene into Y. pestis KIM resulted in iron-responsive beta-galactosidase activity, indicating that Y. pestis KIM expresses a functional Fur regulatory protein. A cloned 1.9-kb ClaI fragment of Y. pestis chromosomal DNA hybridized specifically to the fur gene of E. coli. The coding region of the E. coli fur gene hybridized to a 1.1-kb region at one end of the cloned Y. pestis fragment. The failure of this clone to complement an E. coli fur mutant suggests that the 1.9-kb clone does not contain a functional promoter. Subcloning of this fragment into an inducible expression vector restored Fur regulation in an E. coli fur mutant. In addition, a larger 4.8-kb Y. pestis clone containing the putative promoter region complemented the Fur- phenotype. These results suggest that Y. pestis possesses a functional Fur regulatory protein capable of interacting with the E. coli Fur system. In Y. pestis Fur may regulate the expression of iron transport systems and other virulence factors in response to iron limitation in the environment. Possible candidates for Fur regulation in Y. pestis include genes involved in ferric iron transport as well as hemin, heme/hemopexin, heme/albumin, ferritin, hemoglobin, and hemoglobin/haptoglobin utilization.     

The expression of biologically active cholera toxin in Escherichia coli.

Chromosomal DNA from Vibrio cholerae El Tor strain 1621 was digested with Hind III and the products fractionated by centrifugation through a sucrose gradient. A 15kb fragment containing the toxin gene of V. cholerae was identified by its homology with the heat labile toxin (LT) gene of toxigenic E. coli. This fragment was cloned in E. coli using pAT153 and subsequently characterised by digestion with different restriction endonucleases. Sequences homologous to the LT gene were identified by hybridisation and then sub-cloned using either pAT153 or pACYC184. Expression of the cloned CT gene in E. coli was detected using both cell culture and ELISA assays. One recombinant plasmid coded for the synthesis of an immunologically active but biologically inactive derivative of CT.     

Isolation and characterization of Bacillus subtilis genes involved in siderophore biosynthesis: relationship between B. subtilis sfpo and Escherichia coli entD genes.

In response to iron deprivation, Bacillus subtilis secretes a catecholic siderophore, 2,3-dihydroxybenzoyl glycine, which is similar to the precursor of the Escherichia coli siderophore enterobactin. We isolated two sets of B. subtilis DNA sequences that complemented the mutations of several E. coli siderophore-deficient (ent) mutants with defective enterobactin biosynthesis enzymes. One set contained DNA sequences that complemented only an entD mutation. The second set contained DNA sequences that complemented various combinations of entB, entE, entC, and entA mutations. The two sets of DNA sequences did not appear to overlap. AB. subtilis mutant containing an insertion in the region of the entD homolog grew much more poorly in low-iron medium and with markedly different kinetics. These data indicate that (i) at least five of the siderophore biosynthesis genes of B. subtilis can function in E. coli, (ii) the genetic organization of these siderophore genes in B. subtilis is similar to that in E. coli, and (iii) the B. subtilis entD homolog is required for efficient growth in low-iron medium. The nucleotide sequence of the B. subtilis DNA contained in plasmid pENTA22, a clone expressing the B. subtilis entD homolog, revealed the presence of at least two genes. One gene was identified as sfpo, a previously reported gene involved in the production of surfactin in B. subtilis and which is highly homologous to the E. coli entD gene. We present evidence that the E. coli entD and B. subtilis sfpo genes are interchangeable and that their products are members of a new family of proteins which function in the secretion of peptide molecules.     

Cloning and expression of the Vibrio cholerae neuraminidase gene nanH in Escherichia coli

A cosmid gene bank of Vibrio cholerae 395, classical Ogawa, was screened in Escherichia coli HB101 for expression of the vibrio neuraminidase (NANase) gene nanH (N-acylneuraminate glycohydrolase). Positive clones were identified by their ability to cleave the fluorogenic NANase substrate 2'-(4-methylumbelliferyl)-alpha-D-N-acetylneuraminic acid. Seven NANase-positive clones were detected after screening 683 cosmid isolates with a rapid, qualitative plate assay method. The nanH gene was subcloned from one of the cosmids and was located within a 4.8-kilobase-pair BglII restriction endonuclease fragment. Evidence that nanH was the NANase structural gene was obtained by transposon mutagenesis and by purification and comparison of the cloned gene product with the secreted NANase purified from the parent V. cholerae strain. The sequence of the first 20 amino-terminal amino acids of the secreted NANase purified from V. cholerae was determined by automated Edman degradation and matched perfectly with the amino acid sequence predicted from nucleotide sequencing of nanH. The sequence data also revealed the existence of a potential signal peptide that was apparently processed from NANase in both V. cholerae and E. coli. In contrast to V. cholerae, E. coli nanH+ clones did not secrete NANase into the growth medium, retaining most of the enzyme in the periplasmic compartment. Kinetic studies in V. cholerae showed that nanH expression and NANase secretion were temporally correlated as cells in batch culture entered late-exponential-phase growth. Similar kinetics were observed in at least one of the E. coli nanH+ clones, suggesting that nanH expression in E. coli might be controlled by some of the same signals as in the parent V. cholerae strain.     

O139霍乱弧菌LPS基因在大肠杆菌中的克隆和表达

利用粘粒载体pCOS5构建了国内分离的O139霍乱弧菌的基因组文库,并从文库中筛选获得可以表达O139霍乱弧菌脂多糖的重组克隆株E.coliJM109(pMG310)。重组粘粒pMG310经酶切分析,所克隆的外源DNA片段大小为37kb。实验证明：重组克隆株E.coliJM109(pMG310)所表达的脂多糖具有良好的免疫原性及反应原性。