Aerobactin iron uptake sequences in plasmid ColV-K30 are flanked by inverted IS1-like elements and replication regions.

By using Southern blot hybridization procedures, we found that a specific sequence within a 16.3-kilobase HindIII restriction fragment of pColV-K30 was also present in at least three other pColV-K30 HindIII fragments. Restriction endonuclease mapping of these HindIII fragments indicated that two of these repeated sequences, identified as IS1-like, occur in reverse orientation adjacent to the ends of the aerobactin iron uptake region, also included in the 16.3-kilobase HindIII fragment. There are two distinct replication regions enclosing the IS1-flanked aerobactin genes. A pColV-K30 BamHI restriction endonuclease fragment, carrying one of these replication regions, showed homology with the F plasmid EcoRI fragment f5, which carries the F replication sequences.     

DNA environment of the aerobactin iron uptake system genes in prototypic ColV plasmids.

The aerobactin iron uptake system genes in the prototypic plasmid pColV-K30 are flanked by inverted copies of insertion sequence IS1 and by two distinct replication regions. To address the question of how these flanking regions may facilitate the maintenance and spread of the aerobactin system among the plasmids and chromosomes of enteric species, we investigated the DNA environment of 12 ColV plasmids. We found that the aerobactin system-specific genes are conserved in every plasmid phenotypically positive for the aerobactin system. The upstream IS1 and its overlapping replication region (REPI) are also conserved. This replication region was cloned from several ColV plasmids and found to be functional by transforming these cloned derivatives into a polA bacterial host. In contrast, the downstream flanking region is variable. This includes the downstream copy of IS1 and the downstream replication region (REPII). We infer from these results that sequences in addition to the two flanking copies of IS1, in particular the upstream region including REPI, have been instrumental in the preservation and possible spread of aerobactin genes among ColV plasmids and other members of the FI incompatibility group.     

Plasmid- and chromosome-coded aerobactin synthesis in enteric bacteria: insertion sequences flank operon in plasmid-mediated systems.

Large plasmids were detected in two aerobactin-producing enteric bacterial species (Aerobacter aerogenes 62-I, Salmonella arizona SA1, and S. arizona SL5301) and designated pSMN1, pSMN2, and pSMN3, respectively. Other Salmonella spp., namely, S. arizona SL5302, S. arizona SLS, Salmonella austin, and Salmonella memphis, formed aerobactin but contained no detectable large plasmids. S. arizona SL5283 made no aerobactin. A probe consisting of the aerobactin biosynthetic genes cloned on plasmid pABN5 hybridized to a HindIII digest of pSMN1 but not to digests of pSMN2 or pSMN3. A larger probe, the insert of pABN1 containing the complete aerobactin operon, hybridized to four fragments in HindIII digests of the parent plasmid, pColV-K30. A 2.0-kilobase PvuII fragment responsible for this multiple-hybridization pattern was cloned into vector pUC9 to form pSMN30. The latter was mapped and shown to correspond to either IS1 or to a closely related insertion sequence.     

Cloning and expression of the cloacin DF13/aerobactin receptor of Escherichia coli (ColV-K30)

A DNA fragment derived from the ColV-K30 plasmid and coding for both sensitivity to cloacin DF13 and Fe3+-aerobactin uptake was cloned into pBR322. The cloned fragment coded for two polypeptides with molecular masses of 74,000 (the cloacin DF13/aerobactin receptor protein) and 50,000 daltons, respectively. When grown with sufficient iron, cells harboring pFS8 (with this fragment) possessed about 10 times as many receptor protein molecules as compared with cells of Escherichia coli (ColV-K30). The synthesis of the receptor protein specified by pFS8, however, was independent of the availability of iron, in contrast to strains harboring the intact ColV-K30 plasmid. Aerobactin was taken up but not synthesized by cells harboring pFS8. No growth occurred when iron-starved cultures of these cells were incubated with Fe3+-aerobactin, suggesting that expression of other ColV-K30-encoded genes is necessary to remove the iron from the Fe3+-aerobactin complex.     

Molecular cloning, expression, and regulation in Escherichia coli K-12 of a chromosome-mediated aerobactin iron transport system from a human invasive isolate of E. coli K1.

We have cloned chromosomal genes determining the aerobactin iron transport system from the Escherichia coli K1 strain VW187. Mapping and hybridization experiments showed that the VW187 aerobactin region was identical to that of the plasmid ColV-K30. However, in the E. coli K-12 background, the biosynthesis of both siderophore and ferric aerobactin receptor encoded by the VW187-derived recombinant plasmids was not repressed by iron to the same extent found when a recombinant plasmid derived from pColV-K30 was used. RNA-DNA dot-blot hybridization experiments demonstrated that the aerobactin-specific mRNA synthesized by the VW187-derived clones was not iron regulated in E. coli K-12. In contrast, the synthesis of aerobactin and its receptor in strain VW187 was completely repressed by iron regardless of whether the recombinant plasmids originated from VW187 or pColV-K30. Similar results were obtained with gene fusions in which a promoterless lac operon was placed under the control of aerobactin promoter regions of either chromosome- or plasmid-mediated aerobactin systems. DNA sequencing of the chromosomal aerobactin promoter region showed changes in bases located immediately upstream to the -35 region compared with the corresponding region in pColV-K30, which is known to be part of the binding site for the Fur repressor protein.     

Cloning of the aerobactin-mediated iron assimilation system of plasmid ColV

The high-affinity iron assimilation system of plasmid ColV-K30 was cloned on the vector plasmid pPlac. Plasmid pABN1 was isolated by means of sensitivity to cloacin, a bacteriocin using the same outer membrane receptor as ferric aerobactin. Restriction maps were determined for this plasmid and for a subclone, pABN5. Plasmid pABN1 codes for the complete gene complex, whereas plasmid pABN5 encodes only the biosynthetic genes for aerobactin. Regulation of the uptake system by iron is retained in cloned sequences of pABN1.     

High-affinity iron uptake systems present in Erwinia carotovora subsp. carotovora include the hydroxamate siderophore aerobactin.

The phytopathogenic bacterium Erwinia carotovora subsp. carotovora W3C105 produced the hydroxamate siderophore aerobactin under iron-limiting conditions. A survey of 22 diverse strains of E. carotovora revealed that strain W3C105 alone produced aerobactin. The ferric-aerobactin receptor of strain W3C105 was an 80-kDa protein, identified by immunoblots of Sarkosyl-soluble proteins obtained from E. carotovora cells grown in iron-depleted medium and probed with antiserum raised against the 74-kDa ferric-aerobactin receptor encoded by the pColV-K30 plasmid of Escherichia coli. Genes determining aerobactin biosynthesis and uptake were localized to an 11.3-kb EcoRI-HindIII chromosomal fragment of strain W3C105. A 10-kb subclone of the fragment conferred on E. coli DH5 alpha both aerobactin biosynthesis and uptake, determined by cloacin DF13 sensitivity, the presence of the 80-kDa receptor protein, and iron-independent growth of E. coli clones. The aerobactin biosynthesis genes of E. carotovora W3C105 hybridized to those of the pColV-K30 plasmid of E. coli, but the restriction patterns of the aerobactin regions of E. coli and E. carotovora differed. Although the aerobactin region of enteric bacteria is commonly flanked by IS1-like sequences, IS1 sequences were not detected in the genomic DNA or the cloned aerobactin region of E. carotovora. E. coli DH5 alpha cells harboring cloned aerobactin biosynthesis genes from E. carotovora W3C105 produced greater quantities of aerobactin and the 80-kDa ferric-aerobactin receptor when grown in iron-limited than in iron-replete medium. Strain W3C105 grew on an iron-limited medium, whereas derivatives that lacked a functional aerobactin iron acquisition system did not grow on the medium. These results provide evidence for the occurrence and heterogeneity of aerobactin as a high-affinity iron uptake system of both clinical and phytopathogenic species of the Enterobacteriaceae. Although future studies may reveal a role for aerobactin in the virulence or ecology of strain W3C105, a functional aerobactin iron acquisition system is not necessary for the pathogenicity of E. carotovora.     

Serotype 1a O-Antigen Modification: Molecular Characterization of the Genes Involved and Their Novel Organization in the Shigella flexneri Chromosome

The factors responsible for serotype 1a O-antigen modification in Shigella flexneri were localized to a 5.8-kb chromosomal HindIII fragment of serotype 1a strain Y53. The entire 5.8-kb fragment and regions up- and downstream of it (10.6-kb total) were sequenced. A putative three-gene operon, which showed homology with other serotype conversion genes, was identified and shown to confer serotype 1a O-antigen modification. The serotype conversion genes were flanked on either side by phage DNA. Multiple insertion sequence (IS) elements were located within and upstream of the phage DNA in a composite transposon-like structure. Host DNA homologous to the dsdC and the thrW proA genes was located upstream of the IS elements and downstream of the phage DNA, respectively. The sequence analysis indicates that the organization of the 10.6-kb region of the Y53 chromosome is unique and suggests that the serotype conversion genes were originally brought into the host by a bacteriophage. Several features of this region are also characteristic of pathogenicity islands.     

Aerobactin biosynthesis and transport genes of plasmid ColV-K30 in Escherichia coli K-12.

The iron-regulated aerobactin operon, about 8 kilobase pairs in size, of the Escherichia coli plasmid ColV-K30 was shown by deletion and subcloning analyses to consist of at least five genes for synthesis (iuc, iron uptake chelate) and transport (iut, iron uptake transport) of the siderophore. The gene order iucABCD iutA was established. The genes were mapped within restriction nuclease fragments of a cloned 16.3-kilobase-pair HindIII fragment. Stepwise deletion and subsequent minicell analysis of the resulting plasmids allowed assignment of four of the five genes to polypeptides of molecular masses 63,000, 33,000 53,000, and 74,000 daltons, respectively. The 74-kilodalton protein, the product of gene iutA, is the outer membrane receptor for ferric aerobactin, whereas the remaining three proteins are involved in biosynthesis of aerobactin. The 33-kilodalton protein, the product of gene iucB, was identified as N epsilon-hydroxylysine:acetyl coenzyme A N epsilon-transacetylase (acetylase) by comparison of enzyme activity in extracts from various deletion mutants. The 53-kilodalton protein, the product of gene iucD, is required for oxygenation of lysine. The 63-kilodalton protein, the product of gene iucA, is assigned to the first step of the aerobactin synthetase reaction. The product of gene iucC, so far unidentified, performs the second and final step in this reaction. This is based on the chemical characterization of two precursor hydroxamic acids (N epsilon-acetyl-N epsilon-hydroxylysine and N alpha-citryl-N epsilon-acetyl-N epsilon-hydroxylysine) isolated from a strain carrying a 0.3-kilobase-pair deletion in the iucC gene. The results support the existence of a biosynthetic pathway in which aerobactin arises by oxygenation of lysine, acetylation of the N epsilon-hydroxy function, and condensation of 2 mol of the resulting aminohydroxamic acid with citric acid.     

Amplification of a major membrane-bound DNA sequence of Bacillus subtilis.

A membrane-bound DNA sequence from Bacillus subtilis was subcloned into a plasmid which can replicate in Escherichia coli but not in B. subtilis. This plasmid hybridized with an 11-kilobase HindIII fragment which is the major particle-bound fragment in lysates treated with HindIII. The plasmid integrated into the B. subtilis chromosome at the region of homology, conferring chloramphenicol resistance on the recipient. The inserted resistance was mapped close to purA by using the generalized transducing phage AR9. In one chloramphenicol-resistant strain, the pMS31 region was repeated at least 20 times. A large proportion of the copies of the cloned region were present in the particle fraction, indicating that the capacity to bind this region of the chromosome was substantially in excess of the normal dose of the region. The structure of the particle-bound region was sensitive to ionic detergents and high salt concentrations but was not greatly affected by RNase or ethidium bromide. The basis of a specific DNA-membrane interaction can now be studied by using the amplified region, without the complications of sequences required for autonomous plasmid replication.     

Isolation and molecular genetic characterization of the Bacillus subtilis gene (infB) encoding protein synthesis initiation factor 2.

Western blot (immunoblot) analysis of Bacillus subtilis cell extracts detected two proteins that cross-reacted with monospecific polyclonal antibody raised against Escherichia coli initiation factor 2 alpha (IF2 alpha). Subsequent Southern blot analysis of B. subtilis genomic DNA identified a 1.3-kilobase (kb) HindIII fragment which cross-hybridized with both E. coli and Bacillus stearothermophilus IF2 gene probes. This DNA was cloned from a size-selected B. subtilis plasmid library. The cloned HindIII fragment, which was shown by DNA sequence analysis to encode the N-terminal half of the B. subtilis IF2 protein and 0.2 kb of upstream flanking sequence, was utilized as a homologous probe to clone an overlapping 2.76-kb ClaI chromosomal fragment containing the entire IF2 structural gene. The HindIII fragment was also used as a probe to obtain overlapping clones from a lambda gt11 library which contained additional upstream and downstream flanking sequences. Sequence comparisons between the B. subtilis IF2 gene and the other bacterial homologs from E. coli, B. stearothermophilus, and Streptococcus faecium displayed extensive nucleic acid and protein sequence homologies. The B. subtilis infB gene encodes two proteins, IF2 alpha (78.6 kilodaltons) and IF2 beta (68.2 kilodaltons); both were expressed in B. subtilis and E. coli. These two proteins cross-reacted with antiserum to E. coli IF2 alpha and were able to complement in vivo an E. coli infB gene disruption. Four-factor recombination analysis positioned the infB gene at 145 degrees on the B. subtilis chromosome, between the polC and spcB loci. This location is distinct from those of the other major ribosomal protein and rRNA gene clusters of B. subtilis.     

Cloning and characterization of the iutA gene which encodes ferric aerobactin receptor from marine Vibrio species

The iutA gene from marine Vibrio species SD004, which encoded a ferric aerobactin receptor for the uptake of iron(III), was cloned onto a multicopy plasmid, pUC 18, in Escherichia coli. Identification of the positive clone was achieved on the basis of its deferrization activity and was detected as a halo formation on the chrome azurol S (CAS)-containing selective plate. Nucleotide sequence analysis of the cloned DNA fragment revealed an open reading frame (ORF) which encoded a polypeptide of 706 amino acid residues, and the deduced molecular mass of this polypeptide was 77.906 kD. The amino acid sequence showed a 41% homology with that of the lutA protein from E. coli. The cloned gene was iutA, which encoded the ferric aerobactin receptor. Another incomplete ORF was found 100 bp upstream of the iutA gene, which was homologous (31 out of 49 amino acids) with the C-terminal region of the luc D protein of E. coli. It is suggested that aerobactin biosynthesis and the transport genes are located tandemly on the Vibrio chromosome and may form an aerobactin operon.     

Nucleotide sequence of the tra YALE region from IncFV plasmid pED208

The pED208 plasmid is a 90-kilobase conjugative plasmid which is the derepressed form of Fo lac plasmid (IncFV). A 3.3-kilobase HindIII-PstI fragment from the pED208 plasmid was cloned and sequenced and was found to contain four open reading frames which were highly homologous to the traA, traL, traE, and traY gene products of the F plasmid. The pED208 traA propilin protein was 119 amino acids in length, consisting of a leader sequence of 55 amino acids and a mature pilin subunit of 64 residues. The leader sequence contained a hydrophobic region followed by a classic signal peptidase cleavage site (Ala-Ser-Ala-55). F and pED208 pilin proteins shared 27 conserved residues and had similar predicted secondary structures. The pED208 traA and traL genes were separated by a single base pair, and no ribosome binding site preceded the traL gene. The pED208 traY gene contained an IS2 insertion element in orientation II 180 nucleotides (60 residues) upstream of the traY stop codon. This insertion of IS2 resulted in a predicted fusion peptide of 69 residues for traY which may provide the observed traY activity. Since IS2 is absent in the wild-type plasmid, Fo lac, derepression and concomitant multipiliation may be due to the insertion of IS2 providing constitutive expression of the pED208 tra operon.     

A 20-kilodalton protein is required for efficient production of the Bacillus thuringiensis subsp. israelensis 27-kilodalton crystal protein in Escherichia coli.

The 27-kilodalton (kDa) mosquitocidal protein gene from Bacillus thuringiensis subsp. israelensis has been cloned as a 10-kilobase (kb) HindIII fragment from plasmid DNA; efficient expression in Escherichia coli KM1 depends on a region of DNA located approximately 4 kb upstream (K. McLean and H. R. Whiteley, J. Bacteriol. 169:1017-1023, 1987). We have cloned the upstream DNA region and show that it contains a complete open reading frame (ORF) encoding a protein with a molecular mass of 19,584 Da. Sequencing of adjacent stretches of DNA revealed two partial ORFs: one has 55.2% identity in an overlap of 319 amino acids to the putative transposase of IS231 of B. thuringiensis subsp. thuringiensis, and the other, a 78-codon partial ORF, may be the carboxyl terminus of the 67-kDa protein previously observed in maxicells of strain KM1. A 0.8-kb fragment containing only the 20-kDa protein gene greatly enhanced the expression of the 27-kDa protein in E. coli. The introduction of nonsense codons into the 20-kDa protein gene ORF abolished this effect, indicating that the gene product, not the mRNA or DNA, is required for the enhancement. The effect of the 20-kDa protein gene on various fusions of lacZ to the 27-kDa protein gene suggests that the 20-kDa protein acts after the initiation of translation of the 27-kDa protein gene.     

Nucleotide sequence of the iucD gene of the pColV-K30 aerobactin operon and topology of its product studied with phoA and lacZ gene fusions.

Gene iucD of the aerobactin operon of the Escherichia coli plasmid ColV-K30 encodes a membrane-bound enzyme synthesizing N6-hydroxylysine, the first product of the aerobactin biosynthesis pathway. The entire nucleotide sequence of the cloned iucD gene was determined, from which the primary and some aspects of the secondary structure of the encoded peptide were deduced. E. coli cells harboring multicopy plasmid pVLN12 (iucD+) hyperproduced an approximately 50-kilodalton peptide which was purified and identified as the product of the gene by examination of its amino-terminal sequence. Two iucD'-'lacZ gene fusions were constructed in vitro and four iucD'-'phoA gene fusions were generated in vivo by mutagenesis of iucD with transposon TnphoA (Tn5 IS50L::phoA). Analysis of the corresponding fusion proteins suggested at least two domains of attachment of the IucD protein to the inner side of the cytoplasmic membrane. The first apparent membrane-bound domain was found within the first 25 amino acids of the protein and showed a sequence which resembled that of the signal peptides.     

Novel incompatibility and partition loci for the REPI replication region of plasmid ColV-K30.

The minimum pColV-K30 REPI region necessary for replication was located within a ca. 1.3-kilobase DNA segment. Adjacent to the essential replication sequences, there are two DNA regions that express incompatibility with plasmids containing the F secondary replicon of the F EcoRI fragment f7. One of these regions corresponds to incE, already described in that F plasmid fragment which expresses incompatibility with f7-containing plasmids. The other is a novel sequence that we designated incF, which confers incompatibility with REPI, P307, and f7 derivatives, cis-acting pColV-K30 sequences conferring stability to REPI-containing plasmids were also identified and localized noncontiguous to REPI, ca. 20 kilobases downstream from the aerobactin iron transport genes, which were thus flanked by REPI and its partition (par) sequences.