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Full Sequence and Comparative Analysis of the Plasmid pAPEC-1 of Avian Pathogenic E. coli χ7122 (O78∶K80∶H9)

  • Melha Mellata,

    Affiliation The Biodesign Institute, Arizona State University, Tempe, Arizona, United States of America

  • Jeffrey W. Touchman,

    Affiliation School of Life Sciences, Arizona State University, Tempe, Arizona, United States of America

  • Roy Curtiss III

    rcurtiss@asu.edu

    Affiliations The Biodesign Institute, Arizona State University, Tempe, Arizona, United States of America, School of Life Sciences, Arizona State University, Tempe, Arizona, United States of America

Abstract

Background

Extra-intestinal pathogenic E. coli (ExPEC), including Avian Pathogenic E. coli (APEC), are very diverse. They cause a complex of diseases in Human, animals, and birds. Even though large plasmids are often associated with the virulence of ExPEC, their characterization is still in its infancy.

Methodology/Principal Findings

We fully sequenced and analyzed the large plasmid pAPEC-1 (103,275-bp) associated with the APEC strain χ7122, from worldwide serogroup O78∶K80∶H9. A putative virulence region spanning an 80-kb region of pAPEC-1 possesses four iron acquisition systems (iutA iucABCD, sitABCD, iroBCDN, and temperature-sensitive hemagglutinin tsh), a colicin V operon, increasing serum sensitivity iss, ompT, hlyF, and etsABC. Thirty three ORFs in pAPEC-1 are identified as insertion sequences (ISs) that belong to nine families with diverse origins. The full length of the transfer region in pAPEC-1 (11 kb) is shorter compared to the tra region of other sequenced F plasmids; the absence of some tra genes in pAPEC-1 affects its self-transferability, and the conjugative function of the plasmid was effective only in the presence of other plasmids. Two-replicon systems, repFIIA-repFIC and repFIB, and two post-segregational systems, srnB and hok/sok, are also present in the sequence of pAPEC-1. The comparison of the pAPEC-1 sequence with the two available plasmid sequences reveals more gene loss and reorganization than previously appreciated. The presence of pAPEC-1-associated genes is assessed in human ExPEC by PCR. Many patterns of association between genes are found.

Conclusions/Significance

The pathotype typical of pAPEC-1 was present in some human strains, which indicates a horizontal transfer between strains and the zoonotic risk of APEC strains. ColV plasmids could have common virulence genes that could be acquired by transposition, without sharing genes of plasmid function.

Introduction

Plasmids are influential factors in the pathogenesis and evolution of bacteria [1]. Their ability to transfer between species is a way for plasmids to acquire new genes or target new hosts. Characterizing plasmids from different bacteria is a key pursuit towards understanding the mechanism of virulence and their evolution, and the design of efficacious strategies to fight diseases.

Avian pathogenic E. coli (APEC) strains cause a complex of diseases in birds, mainly respiratory [2], [3]; and because their phylogenic background, APEC are also suspected to be a potential zoonotic risk for human [4], [5]. APEC is a subgroup of the extra-intestinal pathogenic E. coli (ExPEC) pathotype [6], which includes uropathogenic E. coli (UPEC), neonatal-meningitis E. coli (NMEC), and septicemic E. coli. APEC strains are very diverse, and their diversity is related to the diversity of their virulence factors and serotypes. They belong mostly to the serogroups O1, O2, and O78, or are often nontypable. The pathogenicity of APEC is still poorly understood. Similar to other ExPEC members, APEC strains possess virulence factors that allow them to have a systemic life. The most prevalent virulence traits associated with APEC are adhesins (type 1 and P fimbriae, Temperature-sensitive hemagglutinin Tsh, and curli), capsules, iron acquisition systems and serum resistance [2], [3].

Large plasmids are commonly associated with virulence of APEC. Their importance has been demonstrated by the occurrence of plasmid-encoded genes shared among APEC strains [7] and the presence of virulence genes in plasmids [8], [9]. According to recent studies, most virulence genes associated with APEC are often located on IncF plasmids, named ColV plasmids because their ability to code for production of colicin V, a small protein from the microcine family [8], [10], [11]. ColV plasmids are associated with E. coli in general and with APEC in particular. Their link with the ability of bacteria to cause disease in production animals has been demonstrated [12][14]. In vivo expression of genes encoded by the ColV plasmid, including Tsh, aerobactin, and the Iro system, has been confirmed by using SCOTS [7] and the occurrence of the putative virulence genes of APEC on non-ColV plasmids has also been shown [7], [15], [16].

Although large plasmids are commonly found in APEC strains [16][18] and are often considered a feature of the APEC pathotype [18], only a few of them, mainly from serogroups O1 and O2, have been sequenced [15], [19]. Our previous studies investigated the involvement of a large plasmid, pAPEC-1, in the virulence of APEC strain χ7122 from a worldwide serogroup O78∶K80∶H9 [16]. We showed that pAPEC-1-cured χ7122 bacteria were attenuated in chickens, caused few lesions of pericarditis and perihepatitis, did not persist in the blood, and poorly colonized the lung, spleen, and liver [16]. Our results also demonstrated a decrease in the resistance of strains to the bactericidal effects of heterophils and macrophages in vitro [20]. Even though pAPEC-1-cured bacteria were still resistant to serum [16], [21]; the presence of pAPEC-1 in the K-12 strain increased its ability to survive in serum by about 100-fold [16]. Herein, we (i) present and analyze the full sequence of the plasmid pAPEC-1 of APEC strain χ7122 (O78∶K80∶H9), (ii) investigated the pAPEC-1 conjugal transfer mechanism and (iii) determine the prevalence of pAPEC-1-associated virulence genes in human ExPEC and their phylogenetic relationship.

Materials and Methods

Strains, plasmids, media, mating and growth conditions

Bacterial strains and plasmids used in this study are listed in Table 1. A collection of one hundred human strains isolated from the main clinical extra-intestinal sources (UTI and non-UTI), kindly provided by Dr. James R. Johnson (VA Medical Center, Uni. Minnesota), were used to study the distribution of pAPEC-1-associated genes in human ExPEC using the PCR.

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Table 1. Bacterial strains and plasmids used in this study.

https://doi.org/10.1371/journal.pone.0004232.t001

APEC strain χ7122 (O78∶K80∶H9), isolated from liver of a deceased Turkey [22], possesses three large plasmids [[16], Fig. 1]; the largest of these three plasmids is termed pAPEC-1 and is considered to be the virulence plasmid of χ7122 [16]. The APEC strain χ7122 (Nalr) was mated with an E. coli K-12 χ6092 (Tcr), an avirulent strain lacking plasmids. The transconjugant χ7346 was selected on MacConkey agar containing tetracycline and colicin V synthesized in vitro from the χ7122 as described before [23].

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Figure 1. Plasmid profiles of strains on 0.5% agarose gel (A).

Four plasmids (147 kb, 63 kb, 35.85 kb, and 6.9 kb) of the strain 39R681 [83] were used as a ladder (L). Each lane contained plasmids from the following bacterial strains: (1) χ7122, (2) χ7273, (3) χ7277, (4) 7345, (5) 7346, (6) χ7396, (7) χ833, (8) χ2934, (9) χ6092, (10) MGN-617, and (11) TOP10; Colicin production of strains (B). (1) χ7122, (2) χ6092, (3) χ7346.

https://doi.org/10.1371/journal.pone.0004232.g001

For practical reasons, we used a plasmid with a tetracycline resistance marker pAPEC-1-1 (Table 1) to test the self-transferability of the plasmid. The strain χ7277 (Kmr, Tcr) was mated with E. coli K-12 χ2934 (Nalr) to generate the strain χ7345. pAPEC-1-1 DNA purified from χ7345 was transferred by electroporation as previously described [24] into E. coli K-12 MGN-617 to generate the strain χ7396 (Table 1). The strains χ7345 and χ7396 containing pAPEC-1-1 were then mated with different plasmidless recipient strains χ833, χ2934, and TOP10 (Table 1). The contra selection was made on MacConkey agar with appropriate antibiotics.

The presence of plasmids in different bacterial strains was verified by agarose gel (0.5%) electrophoresis by the method of Kado and Liu [25]. Colicin production was determined by the double-layer method as described previously [26].

Strains were stocked at −80°C in 25% glycerol. LB broth and MacConkey agar supplemented with 1% lactose were used to grow bacterial strains. Antibiotics were added, as required, at the following concentrations: kanamycin, 30 µg/ml, nalidixic acid, 15 µg/ml; streptomycin 50 µg/ml, and tetracycline, 10 µg/ml. DAP was added (50 µg/ml) for the growth of Asd strains.

PCR conditions

The size of the traI-traB region of pAPEC-1 was verified by PCR as previously described [16] using primers TraI F: 5′-TCAGTCTCCGCCCAGGGTTTTCTCTTTC-3′ and TraB R: 5′- ATGGCCAGTATCAATACCATTGTGAAAC-3′. The primers for genes tsh, iss, cvaC, iroN, iucC, sitA, ompT, hlyF, and etsA were designed from the pAPEC-1 sequence by using the Primer Premier 5.0 program (Table S1). PCR reactions were repeated at least three times; χ7122 and χ6092 were used as positive and negative controls respectively. The PCR products were purified from the agarose gel by using Qiaquick Gel Extraction Kit (Qiagen) and sequenced by the TGen DNA Sequencing Core (http://www.tgen.org).

DNA purification

The pAPEC-1 and pAPEC-1-1 plasmid DNAs were purified from an overnight culture of transconjugants χ7346 and χ7396 respectively, grown in Luria-Bertani (LB) broth, by using a Large-construct Kit (Qiagen), according to the manufacture's instructions.

Plasmid DNA sequencing

Purified pAPEC-1 plasmid DNA was fragmented by kinetic shearing, and a shotgun library was generated in the vector pOTWI3 using a size fraction of 3–5 kb. The pAPEC-1 sequence was established from 1,052 end sequences from the pOTWI3 library (achieving a 7.9× sequence coverage) using dye-terminator chemistry on ABI 3730xl automated sequencers. The sequence was assembled with the program Phrap (www.phrap.org) and finished as described previously [27]. Assembly accuracy was confirmed by forward and reverse read-pair concordance of individual plasmid subclones.

DNA analysis

Initial automated annotation of the genome was performed with the TIGR/JCVI Annotation Engine (www.tigr.org/AnnotationEngine), where it was processed by TIGR's prokaryotic annotation pipeline. The manual annotation tool Manatee (manatee.sourceforge.net) was used to carefully review and confirm the annotation of every gene. Pseudogenes contained one or more mutations that would ablate expression; each inactivating mutation was subsequently checked against the original sequencing data. Truncations represent genes that are missing the 5′ or 3′ end of the coding sequence determined by protein sequence comparisons with orthologous sequences from other species. The Vector NTI suite of programs was used to confirm the previous analysis. Insertion sequences (IS) elements were identified by comparison with the IS database www-is.biotoul.fr.

Phylogenetic trees were generated by comparing the amino acid sequence of nine pAPEC-1-associated virulence genes with those of related sequences of other bacteria obtained from the GenBank database by neighbor-joining (1,000 replicates) using molecular evolutionary genetics analysis software version 4.0 (MEGA4) (http://megasoftware.net/). Bootstrap values are indicated at branch positions.

Genomic comparison

Pairwise nucleotide comparison of the complete pAPEC-1 DNA sequence to that of pAPEC-O1-ColBM (NC_009837) and pAPEC-O2-ColV (NC_007675) were generated with the Artemis comparison tool, webACT (http://www.webact.org/WebACT). Same-strand DNA similarity is shaded red, while reverse similarity is shaded blue. Aligned regions greater than 1000 base pairs with a percent-identity >96% are shown. The default BLASTn parameters were used (low complexity regions were masked; nucleotide mismatch penalty: -3; reward for nucleotide match: 1). The circular genome map was created using the program CGView [28]. The complete and annotated genome sequences of pAPEC-1 have been deposited in the DDBJ/EMBL/GenBank database under accession number CP000836.

Results and Discussion

General overview of the plasmid pAPEC-1

The entire nucleotide sequence of the first large plasmid, pAPEC-1, of APEC strain χ7122 (O78∶K80∶H9) was determined. pAPEC-1, an IncF colicin V plasmid [[16], Fig. 1] consists of 103,275 base pairs forming a circular plasmid (Fig. 2) with an average GC content of 48.7%, slightly lower than the genome of E. coli (50.8%) [29], the G+C content fluctuates along the pAPEC-1 sequence (Fig. 2). Detailed analysis of the plasmid sequence predicted the presence of 163 open reading frames (ORFs) and 3 pseudogenes as determined by automated annotation (see Methods) (Table S2). The distribution of the pAPEC-1 ORF start codon usage is 67.5% ATG, 19.9% GTG and 12.7% TTG. Of the 163 ORFs, 31 genes (19%) encode proteins similar to known and putative virulence genes (Table S2), 26 (15.95%) encode proteins involved in plasmid functions (Table S3), 33 (20.24%) are similar to insertion sequence genes (Table S4), 27 (16.6%) are predicted proteins conserved in other species, and 46 genes (28.22%) are predicted proteins with no similarity to proteins in public databases.

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Figure 2. Circular representation of the E. coli pAPEC-1 plasmid.

The different rings represent (from outer to inner) all genes and insertion elements, which are color coded by functional group (rings 1 and 2), deviation from average G+C content (ring 3), and GC skew ((G−C)/(G+C); ring 4). Colors represent the following: red, virulence associated; green, mobile elements; blue, plasmid transfer; yellow, plasmid replication; orange, unknown; pink, plasmid maintenance; black, hypothetical proteins; and gray, other functions.

https://doi.org/10.1371/journal.pone.0004232.g002

Maintenance and replication systems

A complete list of DNA sequences involved in pAPEC-1 functions are presented in Table S3, however, details of most interesting traits within this region are discussed below.

Transfer (tra) region of pAPEC-1 is truncated

Conjugative plasmids in gram-negative bacteria possess a transfer region that encodes genes of the T4SS family responsible for the horizontal transfer of plasmids between organisms [30]. All of the ORFs assigned to putative transfer conjugative functions are located within an 11 kb region of the pAPEC-1 plasmid, referred to as the tra cluster (Fig. 2). Similar to other F plasmids, the tra region in pAPEC-1 is boarded by the origin of transfer (oriT) and the fertility inhibition gene, finO [[31]; Fig. 3A]. The full length of the transfer region in pAPEC-1 is shorter when compared to the tra regions of other sequenced F plasmids [31], [32], including avian plasmids pAPEC-O1-ColBM [19] and pAPEC-O2-ColV [15]. A segment of 23 ORFs from pAPEC-O2-ColV located between traI and traB is absent from pAPEC-1 (Fig. 3B). In fact, the size of the traI-traB region of pAPEC-1, around 2 kb as determined by PCR (Fig. 3C), confirmed the deletion of this large segment of DNA between these two genes.

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Figure 3. Genetic map of the transfer region of pAPEC-1 (A), ORFs of pAPEC-O2-ColV absent in pAPEC-1 (B).

Capital letters represent tra genes and lower case letters represent trb genes. Black arrows represent known ORFs genes, grey arrows represent truncated genes, and white arrows represent hypothetical protein genes. PCR of the traI-traB region on 0.8% agarose gel (C), (L) 10 kb ladder (Promega), (1) χ7122, (2) χ7346, (3) χ6092.

https://doi.org/10.1371/journal.pone.0004232.g003

Overall, the 10 genes within the tra region in pAPEC-1 plasmid are more similar at the nucleotide level (99 to 100% similarity) to their counterparts in pAPEC-O1-ColBM than to pAPEC-O2-ColV. In fact, traY and traJ in pAPEC-1 have no similarity in pAPEC-O2-ColV, whereas traM has only 85% similarity. The genes traI (1,884 bp) and traB (222 bp) of pAPEC-1 are truncated. The absence of 1482 bp from the C-terminal region of the traI gene and 1268 bp from the N-terminus of the traB gene is probably due to the deletion of the tra region containing 23 ORFs located between the two genes (Fig. 3). Besides the tra genes, pAPEC-1 possesses the two conserved genes among a range of transmissible plasmids, ssb and psiB (Fig. S1A). These genes are predicted to contribute to the conjugative processing of plasmids [31].

Mechanism of pAPEC-1 conjugal transfer

We previously demonstrated that pAPEC-1-1 could be transferable from derivative APEC strain χ7273 as a donor to an E. coli K12 via mapping [16]. However, the full sequence of the plasmid revealed that some genes encoding conjugative function are missing (Fig. 3). To determine the mechanism of plasmid conjugal transfer, we tested the ability of pAPEC-1-1 to transfer from different donors. Our results showed that pAPEC-1 and pAPEC-1-1 were conjugated from the donor strains including χ7122, χ7273, χ7277 and χ7396 into different E. coli K-12 recipient strains (Table 1, Fig. 1), whereas the plasmid pAPEC-1-1 was not conjugated from the donor χ7345 into different recipient strains.

All together, our results suggest that the conjugative transfer function of pAPEC-1 seems to be effective only in the presence of other large plasmids included pAPEC-2 and pAPEC-3 in χ7122 and χ7273, or pAPEC-2 in χ7277, but also in universal donor strain MGN-617 [33], which has the tra region within the bacterial chromosome; the inability of pAPEC-1-1 to conjugate from χ7345, that contains pAPEC-1-1 alone (Table 1, Fig. 1), into different recipient E. coli strains confirms these results. The genes in the tra region that are missing in pAPEC-1 include genes involved in pilus assembly (traV, traU, traF, traW, traC, traH, traQ, and trbC), in control DNA transfer (traD), surface exclusion (traT and traS), and others (traR, trbG, trbH, trbF, trbD, and trbI) [31] affected the self-transferability of pAPEC-1 and rendered it depend on the transfer machinery of other conjugative plasmids present in the recipient strain. The sizes of plasmid were similar in both donor and recipient (Fig. 1) indicating that no plasmid recombination occurred; in addition, the absence of other plasmids with pAPEC-1-1 in the recipient strains suggests that resolution of co-integrate structures did not occur. The pAPEC-1 plasmid could only use the transfer machinery of other plasmids to compensate for its defective apparatus without necessarily co-integrated to the helper plasmids.

Replication (rep) regions of ColV plasmids are not necessarily the same

Many plasmids of the IncF group have been shown to possess more than one replicon [15], [19], [34], [35]. Two-replicon systems are identified in the sequence of pAPEC-1. Of interest, the organization of the first replicon repFIIA-repFIC, located upstream of the transfer region, is more similar to the replicon identified on pAPEC-O1-ColBM [19] than to the homologue on pAPEC-O2-ColV [15] (Fig. 4), which suggests that ColV plasmids are not necessarily from the same backbone. The particularity of the pAPEC-1 transfer region is the presence of repA, a component of repFIC in the repFIIA region (Fig. 4) and an ORF that has similarity with sequence of pAPEC-O1-ColBM only. Genes of this region are identical (at the nucleotide and protein levels) to the genes of the repFIIA region in pAPEC-O1-ColBM. In pAPEC-1, with the exception of the repA4 that has the lowest homology (93%) and contains a punctuation mutation (G-T) that creates the stop codon TGA in position 88. Two ORFs upstream of repA4 do not have any homology with either pAPEC-O1-ColBM or pAPEC-O2-ColV plasmid sequences. The replication regions of the three sequenced avian plasmids pAPEC-O2-ColV, pAPEC-1, and pAPEC-O1-ColBM are flanked by different insertion sequences, IS1414, IS91, and IS629 respectively (Fig. 4), which demonstrates that these regions could have different origins.

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Figure 4. Comparison of the genetic map of the replication region of pAPEC-1 to that of pAPEC-O2-ColV (NC_007675) and pAPEC-O1-ColBM (NC_009837).

Black arrows represent known ORFs genes, grey arrows represent truncated genes, and white arrows represent hypothetical protein genes and hatched arrows are Insertion Sequences genes.

https://doi.org/10.1371/journal.pone.0004232.g004

The second replicon found in pAPEC-1 is like repFIB according to sequence similarity (Fig. S1B). It is located downstream of the transfer region between the sitABCD and etsABC regions (Fig. 2). This replicon is homologous to the RepFIB relicons of pAPEC-O2-ColV [15] and pAPEC-O1-ColBM [19].

Partition system (sopABC)

To ensure the fidelity of transmission of genes among cells of a population, low copy plasmids possess partitioning (par) loci, a mitotic process encoding for an active partition system governed by a set of three genes sopABC or parABS [36]. pAPEC-1 has a complete F plasmid par locus (sopA, sopB, and sopC) (Fig. S1A) located downstream of the tra region (Fig. 2); this locus is highly similar to the sequence in pAPEC-O1-ColBM but is absent in pAPEC-O2-ColV. pAPEC-1 contains also a truncated parB of the parAB system and lacks parA. The 5′ end of parB in pAPEC-1 was found to be fused with an IS1 element (Fig. S1B). The possession of two Par modules by some plasmids would provide a means of avoiding competition with plasmids containing only one homologous set [37].

Post-segregational system (toxin-antitoxin)

Two post-segregational systems, srnB and hok/sok, were identified in the pAPEC-1 sequence; they are located upstream and downstream of the tra region, respectively. The presence of two toxin-antitoxin systems on the same plasmid is not unusual; a similar situation is found with the pAPEC-O1-ColBM plasmid [19]. Different systems, including hok/sok of R1, srnB of F and pnd of R483, mediate maintenance by killing of plasmid-free segregants: The systems encode highly stable toxins (Hok, SrnB and PndA) that kill the cells from within [38], [39]. Their expression is repressed by the action of small unstable antisense RNAs that are complementary to the toxin mRNAs. The two systems from R and F plasmids suggest that pAPEC-1 may be the result of recombination between R and F plasmids.

Plasmid-encoded functions in pAPEC-1

The putative virulence region of pAPEC-1 spans approximately 80 kb. This region contains four iron acquisition systems (iutA iucABCD, sitABCD, iroBCDN and temperature-sensitive hemagglutinin tsh), colicin V operon, increasing serum sensitivity iss, ompT, hlyF, and etsABC (Fig. 2). An analysis and discussion of four regions are presented below.

ABC transport systems

The sequence of pAPEC-1 revealed the presence of at least five known ABC transport systems, including three iron acquisition systems (iroBCDN, sitABCD, and iutA iucABCD), a colicin V operon (cvi cvaABC), and a recently identified ABC transport (etsABC) [15] (Fig. 2). ABC transporters are integral membrane proteins that carry diverse substrates across lipid bilayers [40]. In bacteria, ABC transporters have a diverse range of functions that may be required for survival in different niches in response to the environments in which bacteria live. They catalyze the uptake of essential nutrients (sugars, amino acids, peptides, metal ions, iron) or the extrusion of toxic substances, thus contributing to drug and antibiotic resistance of microbial pathogens [41].

Iron is an essential cofactor of many enzymes and bacteria require iron concentrations at around 10−7 to 10−5 M to achieve optimal growth. The level of free iron is estimated to be very low in the environment and biological fluids (10−18 M) [42]. Only bacteria that have strategies to acquire iron sequestered by the host can survive in specific niches and consequently cause infections. The SitABCD was previously identified in APEC strain χ7122 and its role in transport of manganese and iron has been demonstrated [43]. The sit operon is multifunctional; it acts as an iron acquisition system during intracellular infection and as a transporter of different compounds, such as manganese, at different stages of infection [43], [44]. The role of SitABCD or their homologues in the virulence of Salmonella, Shigella, Yersinia and APEC has already been determined [45][48]. SitABCD has a role mainly in macrophages where nutrient levels are low and the level of oxidants is potentially high.

The siderophore, salmocheline iroABCDN, was first detected in Salmonella Typhi and later in other Salmonella strains as well in septicemic E. coli [49][51]. IroB and IroD have a glycosyltransferase and an esterification function, respectively [52]. Aerobactin, another iron acquisition system that consists of five genes iucABCD and iutA, was originally found to be encoded in the pColV-K30 plasmid [53], [54], but has also been found to be encoded in chromosomal genes of invasive bacteria [55]. The iro genes and aerobactin-encoding systems play a role in persistence and generation of lesions by APEC strain χ7122 in chickens and they function in concert to increase bacterial acquisition of iron within internal organs [7]. According to Valdebenito et al. [56], environmental factors, including pH, temperature and source of sugar influence the production of different iron acquisition systems present in E. coli strains suggesting that bacteria may need multiple iron acquisition systems to adapt to environment changes during host infection.

The two divergent operons of colicin V production are present in pAPEC-1 (Fig. 2) and are functional (Fig. 1). They consist of genes for ColV synthesis (cvaC) and ColV immunity (cvi) and two genes for ColV export (cvaA and cvaB) [57]. The operon ColV in pAPEC-1 is highly similar at the sequence level (99% identity) to an operon found in the plasmid pAPEC-O2-ColV [15]. The colicin V gene, identified for the first time in E. coli V by Gratia in 1925 [58], is a microcin produced by E. coli and acts against phylogenically related microbial strains by disrupting their cell membrane potential [59]. The colicin V is exported by CvaA and CvaB into the cytoplasmic membrane and outer membrane by a host chromosomal gene product TolC [57]. Colicin V provides a competitive advantage in colonization of the intestinal tract [60]. Many studies have shown that production of colicin V is not necessary for pathogenicity of E. coli by itself but it is a marker for other properties associated with the presence of ColV plasmid [61].

The operon etsABC, a new ABC transport system described for the first time in APEC strains by Johnson et al. [15], is located in a region downstream of iss (Fig. 2). This region contains about 10.5 kb of homology with segments in avian plasmids pAPEC-O2-ColV [15] and pAPEC-O1-ColBM [19]. EtsB is very similar to MacB (59% identity), an ABC-type membrane protein and the first macrolide antibiotic-specific drug exporter identified in gram-negative bacteria. The EtsA protein is 47% similar to MacA, a peripheral membrane protein that belongs to the membrane fusion protein family [62]. The fact that this region is flanked by ISs (Fig. S2A) could facilitate its propagation among avian plasmids.

We previously sequenced the region of tsh [16]. In this study, the full sequence of pAPEC-1 showed that similar to pAPEC-O2-ColV, the tsh gene in pAPEC-1 is located downstream of the ColV operon (Fig. 2). The tsh gene was identified and characterized for the first time in APEC strain χ7122 [63] and was confirmed later in other APEC strains [64] as well in UPEC strains [65]. Tsh, the first serine protease autotransporters of the Enterobacteriaceae (SPATEs), is used as a model for the study of the secretion and function of the proteins from the same family [66][68]. The tsh gene encodes for a temperature-sensitive hemagglutinin Tsh [63], which plays a role in the first steps of APEC infection [16]. This tsh gene is located on ColV and non-ColV plasmids [15], [16], [19]. The ability of Tsh to adhere to red blood cells, hemoglobin, and the extra-cellular matrix proteins fibronectin and collagen IV [69] are predictive of possible other roles for Tsh in virulence, such as acquisition of iron from heme [70].

Another interesting feature of the pAPEC-1 sequence is the presence of a unique region spanning 6.3 kb that contains two putative virulence genes hlyF and ompT. Overall, this region in pAPEC-1 shows homology with sequences of two avian plasmids pAPEC-O1-ColBM [19] and pAPEC-O2-ColV [15]. This region is flanked by two ISs (Fig. S2B) that could play a role in their propagation among APEC strains. Notably, three ORFs upstream of ompT are common in these APEC plasmids and do not have homology with other sequences in the public data base. The two ORFs downstream of hlyF share homology with the two aforementioned avian plasmids and a recently sequenced plasmid p1658/97 from a human septicemic E. coli [71]. The new class of hemolysin designated hlyF has been identified in E. coli strains isolated from broilers [72], but its role in virulence is still unknown. OmpT is a member of the omptins family found in different gram-negative bacteria [73]; the involvement of these omptins in the pathogenicity of these bacteria has been demonstrated by many studies [74]. In fact, OmpT is frequently associated with isolates of E. coli derived from complicated urinary tract disease, where it seems to play a role in the cleavage of protamine, an antimicrobial excreted by epithelial cells of the urinary tract [75]. OmpT is a protease VII that is thought to play a central role in protection against entry of foreign agents such as protenecious toxins into the cell [75], [76]. OmpT also catalyzes the activation of plasminigen to plasmin, a function associated with the virulence of Yersinia pestis and clinical E. coli isolates [77], [78]. The implication of the genes ompT and hlyF in the virulence of APEC should be investigated to better understand the pathogenicity of these strains.

Insertion sequences

For the first time, we fully analyzed insertion sequences identified in an E. coli plasmid. Thirty three ORFs in pAPEC-1 are identified as insertion sequences (ISs). They belong to nine families including IS1, IS3, IS4, IS21, IS66, IS91, IS110, and ISNCy with diverse origins (Table S4). Three sequences of ISs (MM1_0049, MM1_0154, and MM_0155) in pAPEC-1 have no homology with sequences either in pAPEC-O2-ColV or pAPEC-O1-ColBM.

Insertion sequences (ISs) are involved in assembling genes into complex plasmid structures [79], [80]. Plasmids capable of self-transfer between strains have the potential to acquire insertion sequences with their neighboring genes. The ISs in pAPEC-1 may have mediated many transpositions events and segment acquisitions from different bacterial strains (Table S4), as indicated by the fluctuation of G+C content along the sequence of pAPEC-1.

Comparative genomics

We compared the pAPEC-1 plasmid with two other sequenced plasmids from APEC, pAPEC-1-O2-ColV [15] and pAPEC-O1-ColBM [19]. The three way comparison revealed that the three plasmids shared many blocs of DNA (Fig. 5). Compared to pAPEC-O2-ColV, the major deviations are the inversion of the region containing sitABCD and iutA iucABCD and the relocation of the region, including iroBCDN, cvaABC, and tsh located downstream of iutA iucABCD in pAPEC-1. Compared to pAPEC-O1-ColBM, the region downstream of iutA iucABCD in pAPEC-1 is inverted and relocated.

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Figure 5. Pairwise nucleotide comparison of the complete pAPEC-1 DNA sequence to that of pAPEC-O1-ColBM (NC_009837) and pAPEC-O2-ColV (NC_007675).

Same-strand DNA similarity is shaded red, while reverse similarity is shaded blue. Aligned regions greater than 1000 base pairs with a percent-identity >96% are shown. Comparisons were generated with the Artemis comparison tool, ACT [84].

https://doi.org/10.1371/journal.pone.0004232.g005

Prevalence of pAPEC-1-related genes and their association in human ExPEC

pAPEC-1 associated virulence genes are more prevalent among APEC strains than non-APEC strains [15]. Growing evidence suggests that chickens are a suspected source of ExPEC in humans [81]. Therefore, we assessed the presence of 9 virulence genes of pAPEC-1, including tsh, iss, cvaC, iroN, iucC, sitA, hlyF, ompT, and etsA, by PCR among 100 human E. coli strains isolated from the main clinical extra-intestinal sources (UTI and non-UTI). Our results show that all genes tested were prevalent at different percentages in human ExPEC. Generally, pAPEC-1-associated virulence genes are more prevalent among non-UTI than UTI human isolates (Table 2). The most prevalent genes are those associated with the iron-acquisition systems, including iroN (52%), iucC (54%), and sitA (90%). Our analysis revealed many patterns of association between genes in human ExPEC (Table 3). This association includes fifteen percent that contains the cvaC gene, an indicator of the presence of the ColV plasmid and five percent that has the pattern tsh-iss-cvaC-iroN-iucC-sitA-hlyF-ompT-etsA similar of the one of pAPEC-1. All together, our results confirm the diversity of ExPEC strains and showed that human and avian E. coli can carry the same virulence plasmids, indicating the zoonotic risk of APEC strains. These common genes could be considered as potential candidates for a vaccine against a very diverse group of ExPEC either in human or chickens.

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Table 2. Prevalence (%) of pAPEC-1 virulence-associated genes in human isolates.

https://doi.org/10.1371/journal.pone.0004232.t002

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Table 3. Prevalence of different pAPEC-1 gene combinations in human isolates.

https://doi.org/10.1371/journal.pone.0004232.t003

pAPEC-1-associated virulence genes are conserved among some ExPEC strains

The amino sequences of nine pAPEC-1-associated virulence genes (tsh, iss, cvaC, iroN, iucC, sitA, hlyF, ompT and etsA) were used to generate phylogenetic trees by the neighbor-joining method (Fig. 6 a–i). The same distinct clusters of strains were consistently grouped with high bootstrap values.

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Figure 6. Phylogenetic relationships between protein sequences of nine pAPEC-1-associated virulence genes (a) tsh, (b) iss, (c) cvaC, (d) iroN, (e) sitA, (f) iucC, (g) ompT, (h) hlyF, and (i) etsA and related genes from other sources.

The phylogenetic trees were constructed by neighbor-joining analysis. The phylogenetic groups are given on the right. Genes from pAPEC-1 (*); genes of APEC (normal arrow); and genes of other ExPEC (round arrow) are indicated.

https://doi.org/10.1371/journal.pone.0004232.g006

The phylogenetic trees show that pAPEC-1-associated virulence genes belong to clusters that include most genes of other ExPEC strains. The cluster with tsh contains other autotransporters (SPATEs) reported in Enterobacteriaceae (vat, hbp, sepA, and pic) [68] (Fig. 6 a). The gene annotated hbp in human pathogenic E. coli EB1 [82] was placed in the same cluster group of tsh (Fig. 6 a), which could be a discrepancy in annotation of the hbp gene. The large majority of cvaC genes from E. coli belong to the same large cluster (Fig. 6 c), which demonstrates that it is highly conserved among E. coli strains. The phylogenetic trees also show that the few sequences of hlyF and etsA available in GenBank are closely related (Fig. 6 h, i).

Analysis of the pAPEC-1 DNA sequence reveals that this ColV plasmid from an APEC strain O78∶K80∶H9 is a mosaic plasmid that is composed of a diverse set of genetic elements that may be acquired by transposition events due to flanking insertion sequences. The nature and the amount of DNA acquired depends on the pressure of selection imposed by the environment in which bacteria live and also the nature of neighboring flora from where they acquire new genes. The presence of two intact replication regions, RepFIB and RepFIIA, as well two different toxin-antitoxin systems, is evidence of the highly mosaic plasmid structure of pAPEC-1. The absence of some tra genes in pAPEC-1 affected its self-conjugative function and rendered it dependant on the machinery of other plasmids.

The comparison of pAPEC-1 sequence with the two available sequences of avian plasmids (pAPEC-O1-ColBM and pAPEC-O2-ColV) shows that the colicin V plasmids are not necessarily from the same backbone; in fact the regions encoding the functional gene products of pAPEC-1 share more similarity with the plasmid pAPEC-O1-ColBM than with plasmid pAPEC-O2-ColV.

pAPEC-1-associated virulence genes, especially those involved in iron-acquisition, are prevalent in human ExPEC. Different associations of individual genes are present in both UTI and non-UTI human isolates. The pathotype typical of pAPEC-1 is also found in some human strains, which indicates the zoonotic risk of APEC strains. The close phylogenic relationship of pAPEC-1-associated virulence genes with those of other ExPEC including Human strains supports this notion.

Supporting Information

Table S1.

List of primers used in this study. In this table, we present details of primers used in this study to determine the prevalence of pAPEC-1-associated virulence genes in Human ExPEC by PCR.

https://doi.org/10.1371/journal.pone.0004232.s001

(0.03 MB DOC)

Table S2.

Summary of information about the coding sequences of pAPEC-1. In this table, we present details of all coding sequences found in pAPEC-1

https://doi.org/10.1371/journal.pone.0004232.s002

(0.33 MB DOC)

Table S3.

ORFs involved in pAPEC-1 plasmid functions. In this table, we present all ORFs involved in pAPEC-1 plasmid functions, including replication, partition and stability.

https://doi.org/10.1371/journal.pone.0004232.s003

(0.08 MB DOC)

Table S4.

Insertion sequences identified in pAPEC-1. In this table, we present details of all insertion sequences identified in pAPEC-1

https://doi.org/10.1371/journal.pone.0004232.s004

(0.08 MB DOC)

Figure S1.

The genetic map of the replication and stability regions in pAPEC-1. This figure shows the genetic map of the replication and stability regions in pAPEC-1: The region of the stability containing the sopABC (A) and the second replicon repFIC region (B). Black arrows represent known ORFs genes, grey arrows represent truncated genes, white arrows represent hypothetical protein genes, and hatched arrows are Insertion Sequences genes.

https://doi.org/10.1371/journal.pone.0004232.s005

(1.14 MB TIF)

Figure S2.

The genetic map of the region of pAPEC-1 containing the etsABC (A) and hlyF and ompT genes (B). This figure shows the genetic map of the region of pAPEC-1 containing the etsABC (A) and hlyF and ompT genes (B). Black arrows represent known ORF genes, white arrows represent hypothetical protein genes, and hatched arrows are Insertion sequences genes.

https://doi.org/10.1371/journal.pone.0004232.s006

(0.91 MB TIF)

Acknowledgments

We thank Ahmet Kurdoglu for assistance with bioinformatics, and Steve Mastrian and Heather Taylor for assistance with DNA sequencing. We are grateful to James Jancovich (The Biodesign Institute, ASU) for his advice and critical review of this manuscript and the excellent suggestions from expert reviewers.

Author Contributions

Conceived and designed the experiments: MM RC. Performed the experiments: MM. Analyzed the data: MM JWT. Contributed reagents/materials/analysis tools: JWT RC. Wrote the paper: MM. Carefully reviewed the manuscript: RC JWT.

References

  1. 1. Ziebuhr W, Ohlsen K, Karch H, Korhonen T, Hacker J (1999) Evolution of bacterial pathogenesis. Cell Mol Life Sci 56: 719–728.
  2. 2. Barnes HJ, J. V, Gross. WB (2003) Colibacillosis. In: Saif SY, editor. Diseases of poultry. Ames, Iowa: Iowa State University Press. pp. 631–652.
  3. 3. Dho-Moulin M, Fairbrother JM (1999) Avian pathogenic Escherichia coli (APEC). Vet Res 30: 299–316.
  4. 4. Ewers C, Li G, Wilking H, Kiessling S, Alt K, et al. (2007) Avian pathogenic, uropathogenic, and newborn meningitis-causing Escherichia coli: how closely related are they? Int J Med Microbiol 297: 163–176.
  5. 5. Moulin-Schouleur M, Reperant M, Laurent S, Bree A, Mignon-Grasteau S, et al. (2007) Extraintestinal pathogenic Escherichia coli strains of avian and human origin: link between phylogenetic relationships and common virulence patterns. J Clin Microbiol 45: 3366–3376.
  6. 6. Russo TA, Johnson JR (2000) Proposal for a new inclusive designation for extraintestinal pathogenic isolates of Escherichia coli: ExPEC. J Infect Dis 181: 1753–1754.
  7. 7. Dozois CM, Daigle F, Curtiss R III (2003) Identification of pathogen-specific and conserved genes expressed in vivo by an avian pathogenic Escherichia coli strain. Proc Natl Acad Sci U S A 100: 247–252.
  8. 8. Johnson TJ, Giddings CW, Horne SM, Gibbs PS, Wooley RE, et al. (2002) Location of increased serum survival gene and selected virulence traits on a conjugative R plasmid in an avian Escherichia coli isolate. Avian Dis 46: 342–352.
  9. 9. Stehling EG, Yano T, Brocchi M, da Silveira WD (2003) Characterization of a plasmid-encoded adhesin of an avian pathogenic Escherichia coli (APEC) strain isolated from a case of swollen head syndrome (SHS). Vet Microbiol 95: 111–120.
  10. 10. Johnson TJ, Skyberg J, Nolan LK (2004) Multiple antimicrobial resistance region of a putative virulence plasmid from an Escherichia coli isolate incriminated in avian colibacillosis. Avian Dis 48: 351–360.
  11. 11. Tivendale KA, Allen JL, Ginns CA, Crabb BS, Browning GF (2004) Association of iss and iucA, but not tsh, with plasmid-mediated virulence of avian pathogenic Escherichia coli. Infect Immun 72: 6554–6560.
  12. 12. Skyberg JA, Johnson TJ, Johnson JR, Clabots C, Logue CM, et al. (2006) Acquisition of avian pathogenic Escherichia coli plasmids by a commensal E. coli isolate enhances its abilities to kill chicken embryos, grow in human urine, and colonize the murine kidney. Infect Immun 74: 6287–6292.
  13. 13. Smith HW, Huggins MB (1980) The association of the O18, K1 and H7 antigens and the Co1V plasmid of a strain of Escherichia coli with its virulence and immunogenicity. J Gen Microbiol 121: 387–400.
  14. 14. Wooley RE, Gibbs PS, Brown TP, Glisson JR, Steffens WL, et al. (1998) Colonization of the chicken trachea by an avirulent avian Escherichia coli transformed with plasmid pHK11. Avian Dis 42: 194–198.
  15. 15. Johnson TJ, Siek KE, Johnson SJ, Nolan LK (2006) DNA sequence of a ColV plasmid and prevalence of selected plasmid-encoded virulence genes among avian Escherichia coli strains. J Bacteriol 188: 745–758.
  16. 16. Dozois CM, Dho-Moulin M, Bree A, Fairbrother JM, Desautels C, et al. (2000) Relationship between the Tsh autotransporter and pathogenicity of avian Escherichia coli and localization and analysis of the Tsh genetic region. Infect Immun 68: 4145–4154.
  17. 17. Doetkott DM, Nolan LK, Giddings CW, Berryhill DL (1996) Large plasmids of avian Escherichia coli isolates. Avian Dis 40: 927–930.
  18. 18. Rodriguez-Siek KE, Giddings CW, Doetkott C, Johnson TJ, Nolan LK (2005) Characterizing the APEC pathotype. Vet Res 36: 241–256.
  19. 19. Johnson TJ, Johnson SJ, Nolan LK (2006) Complete DNA sequence of a ColBM plasmid from avian pathogenic Escherichia coli suggests that it evolved from closely related ColV virulence plasmids. J Bacteriol 188: 5975–5983.
  20. 20. Mellata M, Dho-Moulin M, Dozois CM, Curtiss R III, Lehoux B, et al. (2003) Role of avian pathogenic Escherichia coli virulence factors in bacterial interaction with chicken heterophils and macrophages. Infect Immun 71: 494–503.
  21. 21. Mellata M, Dho-Moulin M, Dozois CM, Curtiss R III, Brown PK, et al. (2003) Role of virulence factors in resistance of avian pathogenic Escherichia coli to serum and in pathogenicity. Infect Immun 71: 536–540.
  22. 22. Brown PK, Curtiss R III (1996) Unique chromosomal regions associated with virulence of an avian pathogenic Escherichia coli strain. Proc Natl Acad Sci U S A 93: 11149–11154.
  23. 23. Ozanne G, Mathieu LG, Baril JP (1977) Production of colicin V in vitro and in vivo and observations on its effects in experimental animals. Infect Immun 17: 497–503.
  24. 24. Seidman CE, Struhl K, Sheen J, Jessen T (2001) Introduction of plasmid DNA into cells. Curr Protoc Mol Biol 1: 1–10.
  25. 25. Kado CI, Liu ST (1981) Rapid procedure for detection and isolation of large and small plasmids. J Bacteriol 145: 1365–1373.
  26. 26. Fredericq P (1964) Colicins And Colicinogeny. Ann Inst Pasteur (Paris) 107 (7): 7–17.
  27. 27. Touchman JW, Dehejia A, Chiba-Falek O, Cabin DE, Schwartz JR, et al. (2001) Human and mouse alpha-synuclein genes: comparative genomic sequence analysis and identification of a novel gene regulatory element. Genome Res 11: 78–86.
  28. 28. Stothard P, Wishart DS (2005) Circular genome visualization and exploration using CGView. Bioinformatics 21: 537–539.
  29. 29. Blattner FR, Plunkett G 3rd, Bloch CA, Perna NT, Burland V, et al. (1997) The complete genome sequence of Escherichia coli K-12. Science 277: 1453–1474.
  30. 30. Zahrl D, Wagner M, Bischof K, Koraimann G (2006) Expression and assembly of a functional type IV secretion system elicit extracytoplasmic and cytoplasmic stress responses in Escherichia coli. J Bacteriol 188: 6611–6621.
  31. 31. Frost LS, Ippen-Ihler K, Skurray RA (1994) Analysis of the sequence and gene products of the transfer region of the F sex factor. Microbiol Rev 58: 162–210.
  32. 32. Lu J, Manchak J, Klimke W, Davidson C, Firth N, et al. (2002) Analysis and characterization of the IncFV plasmid pED208 transfer region. Plasmid 48: 24–37.
  33. 33. Kaniga K, Compton MS, Curtiss R III, Sundaram P (1998) Molecular and functional characterization of Salmonella enterica serovar typhimurium poxA gene: effect on attenuation of virulence and protection. Infect Immun 66: 5599–5606.
  34. 34. Lane D, Gardner RC (1979) Second EcoRI fragment of F capable of self-replication. J Bacteriol 139: 141–151.
  35. 35. Saadi S, Maas WK, Bergquist PL (1984) RepFIC, a basic replicon of IncFI plasmids that has homology with a basic replicon of IncFII plasmids. Plasmid 12: 61–64.
  36. 36. Hiraga S (1992) Chromosome and plasmid partition in Escherichia coli. Annu Rev Biochem 61: 283–306.
  37. 37. Lawley TD, Taylor DE (2003) Characterization of the double-partitioning modules of R27: correlating plasmid stability with plasmid localization. J Bacteriol 185: 3060–3067.
  38. 38. Gerdes K, Nielsen A, Thorsted P, Wagner EG (1992) Mechanism of killer gene activation. Antisense RNA-dependent RNase III cleavage ensures rapid turn-over of the stable hok, srnB and pndA effector messenger RNAs. J Mol Biol 226: 637–649.
  39. 39. Hayes F (2003) Toxins-antitoxins: plasmid maintenance, programmed cell death, and cell cycle arrest. Science 301: 1496–1499.
  40. 40. Hollenstein K, Dawson RJ, Locher KP (2007) Structure and mechanism of ABC transporter proteins. Curr Opin Struct Biol 17: 412–418.
  41. 41. Davidson AL, Chen J (2004) ATP-binding cassette transporters in bacteria. Annu Rev Biochem 73: 241–268.
  42. 42. Andrews SC, Robinson AK, Rodriguez-Quinones F (2003) Bacterial iron homeostasis. FEMS Microbiol Rev 27: 215–237.
  43. 43. Sabri M, Leveille S, Dozois CM (2006) A SitABCD homologue from an avian pathogenic Escherichia coli strain mediates transport of iron and manganese and resistance to hydrogen peroxide. Microbiology 152: 745–758.
  44. 44. Crosa JH, Mey AR, Payne SM (2004) Iron transport in bacteria. Washington, D. C.: ASM Press.
  45. 45. Bearden SW, Perry RD (1999) The Yfe system of Yersinia pestis transports iron and manganese and is required for full virulence of plague. Mol Microbiol 32: 403–414.
  46. 46. Lucchini S, Liu H, Jin Q, Hinton JC, Yu J (2005) Transcriptional adaptation of Shigella flexneri during infection of macrophages and epithelial cells: insights into the strategies of a cytosolic bacterial pathogen. Infect Immun 73: 88–102.
  47. 47. Sabri M, Caza M, Proulx J, Lymberopoulos MH, Bree A, et al. (2008) Contribution of the SitABCD, MntH, and FeoB metal transporters to the virulence of avian pathogenic Escherichia coli O78 strain chi7122. Infect Immun 76: 601–611.
  48. 48. Zaharik ML, Cullen VL, Fung AM, Libby SJ, Kujat Choy SL, et al. (2004) The Salmonella enterica serovar typhimurium divalent cation transport systems MntH and SitABCD are essential for virulence in an Nramp1G169 murine typhoid model. Infect Immun 72: 5522–5525.
  49. 49. Baumler AJ, Norris TL, Lasco T, Voight W, Reissbrodt R, et al. (1998) IroN, a novel outer membrane siderophore receptor characteristic of Salmonella enterica. J Bacteriol 180: 1446–1453.
  50. 50. Baumler AJ, Tsolis RM, van der Velden AW, Stojiljkovic I, Anic S, et al. (1996) Identification of a new iron regulated locus of Salmonella typhi. Gene 183: 207–213.
  51. 51. Dobrindt U, Blum-Oehler G, Hartsch T, Gottschalk G, Ron EZ, et al. (2001) S-Fimbria-encoding determinant sfa(I) is located on pathogenicity island III(536) of uropathogenic Escherichia coli strain 536. Infect Immun 69: 4248–4256.
  52. 52. Hantke K, Nicholson G, Rabsch W, Winkelmann G (2003) Salmochelins, siderophores of Salmonella enterica and uropathogenic Escherichia coli strains, are recognized by the outer membrane receptor IroN. Proc Natl Acad Sci U S A 100: 3677–3682.
  53. 53. Warner PJ, Williams PH, Bindereif A, Neilands JB (1981) ColV plasmid-specific aerobactin synthesis by invasive strains of Escherichia coli. Infect Immun 33: 540–545.
  54. 54. Williams PH, Warner PJ (1980) ColV plasmid-mediated, colicin V-independent iron uptake system of invasive strains of Escherichia coli. Infect Immun 29: 411–416.
  55. 55. Crosa JH (1989) Genetics and molecular biology of siderophore-mediated iron transport in bacteria. Microbiol Rev 53: 517–530.
  56. 56. Valdebenito M, Crumbliss AL, Winkelmann G, Hantke K (2006) Environmental factors influence the production of enterobactin, salmochelin, aerobactin, and yersiniabactin in Escherichia coli strain Nissle 1917. Int J Med Microbiol 296: 513–520.
  57. 57. Gilson L, Mahanty HK, Kolter R (1990) Genetic analysis of an MDR-like export system: the secretion of colicin V. Embo J 9: 3875–3884.
  58. 58. Gratia A (1925) Sur un remarquable exemple d'antagonisme entre deux souches de colibacille. C R Soc Biol 93: 1040–1042.
  59. 59. Zhang LH, Fath MJ, Mahanty HK, Tai PC, Kolter R (1995) Genetic analysis of the colicin V secretion pathway. Genetics 141: 25–32.
  60. 60. Wooley RE, Brown J, Gibbs PS, Nolan LK, Turner KR (1994) Effect of normal intestinal flora of chickens on colonization by virulent colicin V-producing, avirulent, and mutant colicin V-producing avian Escherichia coli. Avian Dis 38: 141–145.
  61. 61. Quackenbush RL, Falkow S (1979) Relationship between colicin V activity and virulence in Escherichia coli. Infect Immun 24: 562–564.
  62. 62. Kobayashi N, Nishino K, Yamaguchi A (2001) Novel macrolide-specific ABC-type efflux transporter in Escherichia coli. J Bacteriol 183: 5639–5644.
  63. 63. Provence DL, Curtiss R III (1994) Isolation and characterization of a gene involved in hemagglutination by an avian pathogenic Escherichia coli strain. Infect Immun 62: 1369–1380.
  64. 64. Maurer JJ, Brown TP, Steffens WL, Thayer SG (1998) The occurrence of ambient temperature-regulated adhesins, curli, and the temperature-sensitive hemagglutinin tsh among avian Escherichia coli. Avian Dis 42: 106–118.
  65. 65. Heimer SR, Rasko DA, Lockatell CV, Johnson DE, Mobley HL (2004) Autotransporter genes pic and tsh are associated with Escherichia coli strains that cause acute pyelonephritis and are expressed during urinary tract infection. Infect Immun 72: 593–597.
  66. 66. Dutta PR, Cappello R, Navarro-Garcia F, Nataro JP (2002) Functional comparison of serine protease autotransporters of enterobacteriaceae. Infect Immun 70: 7105–7113.
  67. 67. Dutta PR, Sui BQ, Nataro JP (2003) Structure-function analysis of the enteroaggregative Escherichia coli plasmid-encoded toxin autotransporter using scanning linker mutagenesis. J Biol Chem 278: 39912–39920.
  68. 68. Restieri C, Garriss G, Locas MC, Dozois CM (2007) Autotransporter-encoding sequences are phylogenetically distributed among Escherichia coli clinical isolates and reference strains. Appl Environ Microbiol 73: 1553–1562.
  69. 69. Kostakioti M, Stathopoulos C (2004) Functional analysis of the Tsh autotransporter from an avian pathogenic Escherichia coli strain. Infect Immun 72: 5548–5554.
  70. 70. Otto BR, van Dooren SJ, Dozois CM, Luirink J, Oudega B (2002) Escherichia coli hemoglobin protease autotransporter contributes to synergistic abscess formation and heme-dependent growth of Bacteroides fragilis. Infect Immun 70: 5–10.
  71. 71. Zienkiewicz M, Kern-Zdanowicz I, Golebiewski M, Zylinska J, Mieczkowski P, et al. (2007) Mosaic structure of p1658/97, a 125-kilobase plasmid harboring an active amplicon with the extended-spectrum beta-lactamase gene blaSHV-5. Antimicrob Agents Chemother 51: 1164–1171.
  72. 72. Morales C, Lee MD, Hofacre C, Maurer JJ (2004) Detection of a novel virulence gene and a Salmonella virulence homologue among Escherichia coli isolated from broiler chickens. Foodborne Pathog Dis 1: 160–165.
  73. 73. Sugimura K, Nishihara T (1988) Purification, characterization, and primary structure of Escherichia coli protease VII with specificity for paired basic residues: identity of protease VII and OmpT. J Bacteriol 170: 5625–5632.
  74. 74. Stathopoulos C (1998) Structural features, physiological roles, and biotechnological applications of the membrane proteases of the OmpT bacterial endopeptidase family: a micro-review. Membr Cell Biol 12: 1–8.
  75. 75. Stumpe S, Schmid R, Stephens DL, Georgiou G, Bakker EP (1998) Identification of OmpT as the protease that hydrolyzes the antimicrobial peptide protamine before it enters growing cells of Escherichia coli. J Bacteriol 180: 4002–4006.
  76. 76. Cavard D, Lazdunski C (1990) Colicin cleavage by OmpT protease during both entry into and release from Escherichia coli cells. J Bacteriol 172: 648–652.
  77. 77. Lundrigan MD, Webb RM (1992) Prevalence of ompT among Escherichia coli isolates of human origin. FEMS Microbiol Lett 76: 51–56.
  78. 78. Sodeinde OA, Subrahmanyam YV, Stark K, Quan T, Bao Y, et al. (1992) A surface protease and the invasive character of plague. Science 258: 1004–1007.
  79. 79. Burrus V, Waldor MK (2004) Shaping bacterial genomes with integrative and conjugative elements. Res Microbiol 155: 376–386.
  80. 80. Schneider D, Lenski RE (2004) Dynamics of insertion sequence elements during experimental evolution of bacteria. Res Microbiol 155: 319–327.
  81. 81. Johnson JR, Russo TA (2002) Extraintestinal pathogenic Escherichia coli: “the other bad E coli”. J Lab Clin Med 139: 155–162.
  82. 82. Otto BR, van Dooren SJ, Nuijens JH, Luirink J, Oudega B (1998) Characterization of a hemoglobin protease secreted by the pathogenic Escherichia coli strain EB1. J Exp Med 188: 1091–1103.
  83. 83. Mainil JG, Bex F, Dreze P, Kaeckenbeeck A, Couturier M (1992) Replicon typing of virulence plasmids of enterotoxigenic Escherichia coli isolates from cattle. Infect Immun 60: 3376–3380.
  84. 84. Carver TJ, Rutherford KM, Berriman M, Rajandream MA, Barrell BG, et al. (2005) ACT: the Artemis Comparison Tool. Bioinformatics 21: 3422–3423.