Characterization and evidence of mobilization of the LEE pathogenicity island of rabbit-specific strains of enteropathogenic Escherichia coli

We have characterized the LEE pathogenicity islands (PAIs) of two rabbit-specific strains of enteropathogenic E. coli (REPEC), 83/39 (serotype O15:H-) and 84/110-1 (O103:H2), and have compared them to homologous loci from the human enteropathogenic and enterohaemorrhagic E. coli strains, E2348/69 and EDL933, and another REPEC strain, RDEC-1. All five PAIs contain a 34 kb core region that is highly conserved in gene order and nucleotide sequence. However, the LEE of 83/39 is significantly larger (59 540 basepairs) than those of the human strains, which are less than 44 kb, and has inserted into pheU tRNA. The regions flanking the 34 kb core of 83/39 contain homologues of two putative virulence determinants, efa1/lifA and senA. The LEE of 84/110-1 is approximately 85 kb and is located at pheV tRNA. Its core is almost identical to those of 83/39 and RDEC-1, apart from a larger espF gene, but its flanking regions contain trcA, a putative virulence determinant of EPEC. All three REPEC LEE PAIs contain a gene for an integrase, Int-phe. The LEE PAI of 84/110-1 is also flanked by short direct repeats (representing the 3'-end of pheV tRNA), suggesting that it may be unstable. To investigate this possibility, we constructed a LEE::sacB derivative of 84/110-1 and showed that the PAI was capable of spontaneous deletion. We also showed that Int-phe can mediate site-specific integration of foreign DNA at the pheU tRNA locus of E. coli DH1. Together these results indicate possible mechanisms of mobilization and integration of the LEE PAI.     

Mycobacteriophage Bxb1 integrates into the Mycobacterium smegmatis groEL1 gene

Mycobacteriophage Bxb1 is a temperate phage of Mycobacterium smegmatis and forms stable lysogens in which the Bxb1 genome is integrated into the host chromosome. Bxb1 encodes an integrase of the large serine recombinase family that catalyses integration and excision of the Bxb1 genome. We show here that Bxb1 integrates into a chromosomal attB site located within the 3' end of the groEL1 gene such that integration results in alteration of the C-terminal 21 amino acid residues. An integration-proficient plasmid vector containing the Bxb1 integrase gene and flanking DNA sequences efficiently transforms M. smegmatis via integration at attB. Bxb1-integrated recombinants are stable and fully compatible with L5 integration vectors. Strand exchange occurs within an 8 bp common core sequence present in attB and within an attP site situated immediately upstream of the phage integrase gene. Establishment of a defined in vitro system for Bxb1 integration shows that recombination occurs efficiently without requirement for high-energy cofactors, divalent metals, DNA supercoiling or additional proteins.     

Site-specific integration of the conjugal Vibrio cholerae SXT element into prfC

Vibrio cholerae O139, the first non-O1 serogroup of V. cholerae to give rise to epidemic cholera, is characteristically resistant to the antibiotics sulphamethoxazole, trimethoprim, chloramphenicol and streptomycin. Resistances to these antibiotics are encoded by a 62 kb self-transmissible, conjugative, chromosomally integrating element designated the 'SXT element'. We found that the SXT element integrates site specifically into both V. cholerae and Escherichia coli K-12 into the 5' end of prfC , the gene encoding peptide chain release factor 3. Integration of the SXT element interrupts the chromosomal prfC gene, but the element encodes a new 5' end of prfC that restores the reading frame of this gene. The recombinant prfC allele created upon element integration is functional. The integration and excision mechanism of the SXT element shares many features with site-specific recombination found in lambdoid phages. First, like λ, the SXT element forms a circular extrachromosomal intermediate through specific recombination of the left and right ends of the integrated element. Second, chromosomal integration of the element occurs via site-specific recombination in a 17 bp sequence found in the circular form of the SXT element and a similar 17 bp sequence in prfC . Third, both chromosomal integration and excision of the SXT element were found to require an element-encoded int gene with strong similarities to the λ integrase family. Based on the properties of the SXT element, we propose to classify this element as a CONSTIN, an acronym for a conjugative, self-transmissible, integrating element.     

Self-transmissibility of the integrative and conjugative element ICEPm1 between clinical isolates requires a functional integrase, relaxase, and type IV secretion system

Integrative and conjugative elements (ICEs), which are chromosomal mobile elements, can conjugatively transfer between bacteria. Recently, we identified a genomic island of Proteus mirabilis, a common agent of catheter-associated urinary tract infection (UTI), that possesses all the properties consistent with an ICE. This element, designated ICEPm1, is highly conserved in other causative agents of UTI, suggesting its mobility. We demonstrate that ICEPm1 can actively excise from the chromosome in a clonal population of bacteria and that this excision is integrase dependent. Although in P. mirabilis HI4320, ICEPm1 is annotated as integrated into the phenylalanine tRNA gene pheV, we show that ICEPm1 can integrate into either pheV or pheU. We determined that ICEPm1 transfers at a frequency of 1.35 × 10(-5) transconjugants/donor to ICEPm1-deficient P. mirabilis using plate mating assays with clinical isolates. Insertional inactivation of a putative integrase gene on ICEPm1 decreased transfer frequencies of ICEPm1 to below the limit of detection. Mutation of the relaxase of ICEPm1 also eliminates transfer and demonstrates that this element is indeed self-transmissible and not transferred in trans, as are some mobilizable genomic islands. Together, these findings clearly demonstrate that ICEPm1 can actively excise from the chromosome in an integrase-dependent manner, dynamically integrate into both phenylalanine tRNA genes, and transfer into clinical strains using its own conjugation machinery.     

Bacteriophage T12 of Streptococcus pyogenes integrates into the gene encoding a serine tRNA

The region of temperate bacteriophage T12 responsible for integration into the chromosome of Streptococcus pyogenes has been identified. The integrase gene ( int ) and the phage attachment site ( attP ) are found immediately upstream of the gene for speA , the latter of which is known to be responsible for the production of erythrogenic toxin A (also known as pyrogenic exotoxin A). The integrase gene has a coding capacity for a protein of 41 457 Da, and the C-terminus of the deduced protein is similar to other conserved C-terminal regions typical of phage integrases. Upstream of int is a second open reading frame, which is capable of encoding an acidic protein of 72 amino acids (8744 Da); the position of this region in relation to int suggests it to be the phage excisionase gene ( xis ). The arms flanking the integrated prophage ( attL and attR ) were identified, allowing determination of the sequences of the phage ( attP ) and bacterial ( attB ) attachment sites. A fragment containing the integrase gene and attP was cloned into a streptococcal suicide vector; when introduced into S. pyogenes by electrotransformation, this plasmid stably integrated into the bacterial chromosome at attB . The insertion site for the phage into the S. pyogenes chromosome was found to be in the anticodon loop of a putative type II gene for a serine tRNA. attP and attB share a region of identity that is 96 bp in length; this region of identity corresponds to the 3' end of the tRNA gene such that the coding sequence remains intact after integration of the prophage. The symmetry of the core region of att may set this region apart from previously described phage attachment sites (Campbell, 1992), and may play a role in the biology of this medically important bacteriophage.     

Site-specific integrative elements of rhizobiophage 16-3 can integrate into proline tRNA (CGG) genes in different bacterial genera.

The integrase protein of the Rhizobium meliloti 41 phage 16-3 has been classified as a member of the Int family of tyrosine recombinases. The site-specific recombination system of the phage belongs to the group in which the target site of integration (attB) is within a tRNA gene. Since tRNA genes are conserved, we expected that the target sequence of the site-specific recombination system of the 16-3 phage could occur in other species and integration could take place if the required putative host factors were also provided by the targeted cells. Here we report that a plasmid (pSEM167) carrying the attP element and the integrase gene (int) of the phage can integrate into the chromosomes of R. meliloti 1021 and eight other species. In all cases integration occurred at so-far-unidentified, putative proline tRNA (CGG) genes, indicating the possibility of their common origin. Multiple alignment of the sequences suggested that the location of the att core was different from that expected previously. The minimal attB was identified as a 23-bp sequence corresponding to the anticodon arm of the tRNA.     

CTnscr94, a conjugative transposon found in enterobacteria.

Conjugational transposons are important for horizontal gene transfer in gram-positive and gram-negative bacteria, but have not been reported yet for enteric bacteria. Salmonella senftenberg 5494-57 has previously been shown to transfer by conjugation genes for a sucrose fermentation pathway which were located on a DNA element called scr-94. We report here that the corresponding scr genes for a phosphoenolpyruvate-dependent sucrose:phosphotransferase system and a sucrose metabolic pathway are located on a large (ca. 100 kb) conjugative transposon renamed CTnscr94. The self-transmissible element integrates at two specific attachment sites in a RecA-independent way into the chromosome of Escherichia coli K-12 strains. One site was identified within pheV, the structural gene for a tRNA(Phe). Sequencing of both ends of CTnscr94 revealed the presence of the 3' part of pheV on one end such that after integration of the element, a complete pheV gene is retained. CTnscr94 represents, to our knowledge, the first conjugational transposon found in enteric bacteria.     

Sip,an integrase protein with excision,circularization and integration activities,defines a new family of mobile Staphylococcus aureus pathogenicity islands

We report the complete sequence of Staphylococcal pathogenicity island bovine 2 (SaPIbov2), encoding the biofilm-associated protein Bap. SaPIbov2 contains 24 open reading frames, including sip, which encodes a functional staphylococcal integrase protein. SaPIbov2 is bordered by 18 bp direct repeats. The integration site into the chromosome lies at the 3' end of a gene encoding GMP synthase. SaPIbov2 has extensive similarity to previously described pathogenicity islands of Staphylococcus aureus. The principal difference is that toxin genes present in the other pathogenicity islands are exchanged for a transposon-like element that carries the bap gene and genes encoding an ABC transporter and a transposase. Also, SaPIbov2 can be excised to form a circular element and can integrate site-specifically and RecA-independently at a chromosomal att site in a Sip-dependent manner. This was demonstrated both in S. aureus and with plasmid substrates ectopically in Escherichia coli. Thus, SaPIbov2 encodes a functional recombinase of the integrase family that promotes element excision and insertion/integration. In addition, we demonstrated that the presence of SaPIbov2 facilitated the persistence of S. aureus in an intramammary gland infection model. Finally, different bovine isolates of S. aureus were found to carry islands related to SaPIbov2, suggesting the existence of a family of related pathogenicity islands.     

Nested Deletions of the SRL Pathogenicity Island of Shigella flexneri 2a

In this study, we determined the boundaries of a 99-kb deletable element of Shigella flexneri 2a strain YSH6000. The element, designated the multiple-antibiotic resistance deletable element (MRDE), had recently been found to contain a 66-kb pathogenicity island (PAI)-like element (designated the SRL PAI) which carries the Shigella resistance locus (SRL), encoding resistance determinants to streptomycin, ampicillin, chloramphenicol, and tetracycline. The YSH6000 MRDE was found to be flanked by two identical IS91 elements present at the S. flexneri homologs of the Escherichia coli genes putA and mdoA on NotI fragment D. Sequence data from two YSH6000-derived MRDE deletants, YSH6000T and S2430, revealed that deletion of the MRDE occurred between the two flanking IS91 elements, resulting in a single IS91 element spanning the two original IS91 loci. Selection for the loss of tetracycline resistance confirmed that the MRDE deletion occurred reproducibly from the same chromosomal site and also showed that the SRL PAI and the SRL itself were capable of independent deletion from the chromosome, thus revealing a unique set of nested deletions. The excision frequency of the SRL PAI was estimated to be 10(-5) per cell in the wild type, and mutation of a P4-like integrase gene (int) at the left end of the SRL PAI revealed that int mediates precise deletion of the PAI.     

A role for bacteriophages in the evolution and transfer of bacterial virulence determinants

A virulence-associated region in the genome of Dichelobacter nodosus has been shown to contain an integrase gene which is highly related to the integrases of Shigella flexneri phage Sf6 and coliphages P4 and φR73, together with open reading frames ( vapB, C and D ) related to genes borne on plasmids in Neisseria gonorrhoeae, Escherichia coli, Actinobacillus actinomycetemcomitans and Treponema denticola . Similar to P4 and φR73, the vap region is bracketed by putative bacteriophage att sites and is adjacent to a tRNA gene, which suggests that the vap region has been derived by the integration of a bacteriophage, or a plasmid carrying a bacteriophage-related integrase gene. Many similarities in genes and genes clusters encoding virulence determinants have been found in distantly related bacteria. These genes are often located on plasmids in one organism but on the chromosome in others, implying that transmission of the genes has been followed by integration. Thus, the events which have generated the vap regions of D. nodosus may represent a common mechanism for transfer of virulence determinants. A number of genes involved in the virulence of bacterial pathogens are found on integrated bacteriophages, and we suggest that others will prove to be associated with tRNA genes and/or integrase genes derived from bacteriophages. The use of tRNA genes as integration sites for many bacteriophages and plasmids may favour intergeneric transmission, as tRNA genes are highly conserved.     

Pathogenicity island integrase cross-talk: a potential new tool for virulence modulation

Instability and excision of pathogenicity islands (PAIs) have already been described in Escherichia coli 536. In this edition of Molecular Microbiology, Bianca Hochhut and colleagues from the University of Würzburg in Germany have shown that the instability of four of the E. coli 536 PAIs is mediated by a P4-type integrase encoded within the specific PAI by a site-specific recombination mechanism. The integrase encoded on PAI II(536) is able to mediate excision and integration of both PAI II(536), and also PAI V(536). The att sites of both these PAIs have a region of sequence similarity, which is also found in several other PAIs and in tRNA genes in several bacterial species. The cross-PAI activity of this integrase (Int(PAI II)) suggests that it plays an important role in both genome evolution and horizontal transfer of pathogenicity elements, possibly even across species barriers. Deletion of PAIs that carry genes for adhesins and other traits might lead to a phase variation-like phenomenon. Differential regulation of integrase activity or production might add a further level of fine-tuning during bacterial infection.     

Characterization of the Micromonospora rosaria pMR2 plasmid and development of a high G+C codon optimized integrase for site-specific integration

pMR2, an 11.1 kb plasmid was isolated from Micromonospora rosaria SCC2095, NRRL3718, and its complete nucleotide sequence determined. Analysis revealed 13 ORFs including homologs of a KorSA regulatory protein and TraB plasmid transfer protein found on other actinomycete plasmids. pMR2 contains att/int functions consisting of an integrase, an excisionase, and a putative plasmid attachment site (attP). The integrase gene contained a high frequency of codons rarely used in high G+C actinomycete coding regions. The gene was codon optimized for actinomycete codon usage to create the synthetic gene int-OPT. pSPRX740, containing an rpsL promoter and the att/int-OPT region, was introduced into Micromonospora halophytica var. nigra ATCC33088. Analysis of DNA flanking the pSPRX740 integration site confirmed site-specific integration into a tRNA(Phe) gene in the M. halopytica var. nigra chromosome. The pMR2 attP element and chromosomal attachment (attB) site contain a 63 bp region of sequence identity overlapping the 3' end of the tRNA(Phe) gene. Plasmids comprising the site-specific att/int-OPT functions of pMR2 can be used to integrate genes into the chromosome of actinomycetes with an appropriate tRNA gene. The development of an integrative system for Micromonospora will expand our ability to study antibiotic biosynthesis in this important actinomycete genus.     

Integration sites for genetic elements in prokaryotic tRNA and tmRNA genes: sublocation preference of integrase subfamilies

Most classical integrases of prokaryotic genetic elements specify integration into tRNA or tmRNA genes. Sequences shared between element and host integration sites suggest that crossover can occur at any of three sublocations within a tRNA gene, two with flanking symmetry (anticodon-loop and T-loop tDNA) and the third at the asymmetric 3' end of the gene. Integrase phylogeny matches this classification: integrase subfamilies use exclusively either the symmetric sublocations or the asymmetric sublocation, although tRNA genes of several different aminoacylation identities may be used within any subfamily. These two familial sublocation preferences imply two modes by which new integration site usage evolves. The tmRNA gene has been adopted as an integration site in both modes, and its distinctive structure imposes some constraints on proposed evolutionary mechanisms.     

Characterization of genetic elements required for site-specific integration of Lactobacillus delbrueckii subsp. bulgaricus bacteriophage mv4 and construction of an integration-proficient vector for Lactobacillus plantarum.

Temperate phage mv4 integrates its DNA into the chromosome of Lactobacillus delbrueckii subsp. bulgaricus strains via site-specific recombination. Nucleotide sequencing of a 2.2-kb attP-containing phage fragment revealed the presence of four open reading frames. The larger open reading frame, close to the attP site, encoded a 427-amino-acid polypeptide with similarity in its C-terminal domain to site-specific recombinases of the integrase family. Comparison of the sequences of attP, bacterial attachment site attB, and host-phage junctions attL and attR identified a 17-bp common core sequence, where strand exchange occurs during recombination. Analysis of the attB sequence indicated that the core region overlaps the 3' end of a tRNA(Ser) gene. Phage mv4 DNA integration into the tRNA(Ser) gene preserved an intact tRNA(Ser) gene at the attL site. An integration vector based on the mv4 attP site and int gene was constructed. This vector transforms a heterologous host, L. plantarum, through site-specific integration into the tRNA(Ser) gene of the genome and will be useful for development of an efficient integration system for a number of additional bacterial species in which an identical tRNA gene is present.     

Site-Specific Recombination of Temperate Myxococcus xanthus Phage Mx8: Genetic Elements Required for Integration

Like most temperate bacteriophages, phage Mx8 integrates into a preferred locus on the genome of its host, Myxococcus xanthus, by a mechanism of site-specific recombination. The Mx8 int-attP genes required for integration map within a 2.2-kilobase-pair (kb) fragment of the phage genome. When this fragment is subcloned into a plasmid vector, it facilitates the site-specific integration of the plasmid into the 3' ends of either of two tandem tRNAAsp genes, trnD1 and trnD2, located within the attB locus of the M. xanthus genome. Although Int-mediated site-specific recombination occurs between attP and either attB1 (within trnD1) or attB2 (within trnD2), the attP x attB1 reaction is highly favored and often is accompanied by a deletion between attB1 and attB2. The int gene is the only Mx8 gene required in trans for attP x attB recombination. The int promoter lies within the 106-bp region immediately upstream of one of two alternate GTG start codons, GTG-5208 (GTG at bp 5208) and GTG-5085, for integrase and likely is repressed in the prophage state. All but the C-terminal 30 amino acid residues of the Int protein are required for its ability to mediate attP x attB recombination efficiently. The attP core lies within the int coding sequence, and the product of integration is a prophage in which the 3' end of int is replaced by host sequences. The prophage intX gene is predicted to encode an integrase with a different C terminus.     

Delineation of the recombination sites necessary for integration of pathogenicity islands II and III into the Escherichia coli 536 chromosome

In uropathogenic Escherichia coli strain 536, six pathogenicity islands (PAIs) encode key virulence factors. All PAIs except PAI IV₅₃₆ are flanked by direct repeats and four of them encode integrases responsible for their chromosomal excision. To study recombination sites used for the integration by PAI II₅₃₆ and III₅₃₆ integrases, we measured site-specific recombination between the chromosomal integration site attB , and the PAI-specific attachment site attP . We show that PAI III₅₃₆ IntB, but not IntA, mediates PAI III₅₃₆ integration. Studies of integrative recombination sites of both PAIs show that, when using a large cognate attP site (839 bp for PAI II₅₃₆ and 268 bp for PAI III₅₃₆), PAI II₅₃₆ and III₅₃₆ attB sites could be reduced to 16 bp and 20 bp, respectively, without affecting recombination. Further reduction to 14 bp for PAI II₅₃₆ and 13 bp for PAI III₅₃₆ diminished recombination efficiency. Surprisingly, attP sites could also be reduced to 14 bp (PAI II₅₃₆) and 20 bp (PAI III₅₃₆). The integration host factor (IHF) and the DNA-bending HU protein do not influence PAI II₅₃₆ recombination, but IHF enhances PAI-III₅₃₆ excision and negatively affects its integration. These data suggest that PAI intasomes differ from those of lambda and P4 integrase paradigms.     

Plasmid integration in a wide range of bacteria mediated by the integrase of Lactobacillus delbrueckii bacteriophage mv4.

Bacteriophage mv4 is a temperate phage infecting Lactobacillus delbrueckii subsp. bulgaricus. During lysogenization, the phage integrates its genome into the host chromosome at the 3' end of a tRNA(Ser) gene through a site-specific recombination process (L. Dupont et al., J. Bacteriol., 177:586-595, 1995). A nonreplicative vector (pMC1) based on the mv4 integrative elements (attP site and integrase-coding int gene) is able to integrate into the chromosome of a wide range of bacterial hosts, including Lactobacillus plantarum, Lactobacillus casei (two strains), Lactococcus lactis subsp. cremoris, Enterococcus faecalis, and Streptococcus pneumoniae. Integrative recombination of pMC1 into the chromosomes of all of these species is dependent on the int gene product and occurs specifically at the pMC1 attP site. The isolation and sequencing of pMC1 integration sites from these bacteria showed that in lactobacilli, pMC1 integrated into the conserved tRNA(Ser) gene. In the other bacterial species where this tRNA gene is less or not conserved; secondary integration sites either in potential protein-coding regions or in intergenic DNA were used. A consensus sequence was deduced from the analysis of the different integration sites. The comparison of these sequences demonstrated the flexibility of the integrase for the bacterial integration site and suggested the importance of the trinucleotide CCT at the 5' end of the core in the strand exchange reaction.     

Integration of satellite bacteriophage P4 in Escherichia coli. DNA sequences of the phage and host regions involved in site-specific recombination

We determined the DNA sequences of regions essential for bacteriophage P4 integration. A 20 base-pair core sequence in both phage (P4attP) and host (P4attB) attachment regions contains the recombination site. In P4attP this sequence is flanked by five repeated sequences. A 1.3 x 10(3) base open reading frame codes for P4 integrase. Two possible promoters are upstream from P4int. One would be recognized by Escherichia coli RNA polymerase and may be repressed by integrase protein. The second would be recognized by RNA polymerase modified after infection by a P4 helper phage, P2. The P4attB core sequence is the 3' end of a leucine tRNA gene. Downstream from this tRNA in E. coli K-12 is a region homologous to P4int that may be part of a cryptic prophage.     

Construction,characterization, and use of two Listeria monocytogenes site-specific phage integration vectors

Two site-specific shuttle integration vectors were developed with two different chromosomal bacteriophage integration sites to facilitate strain construction in Listeria monocytogenes. The first vector, pPL1, utilizes the listeriophage U153 integrase and attachment site within the comK gene for chromosomal insertion. pPL1 contains a useful polylinker, can be directly conjugated from Escherichia coli into L. monocytogenes, forms stable, single-copy integrants at a frequency of approximately 10(-4) per donor cell, and can be used in the L. monocytogenes 1/2 and 4b serogroups. Methods for curing endogenous prophages from the comK attachment site in 10403S-derived strains were developed. pPL1 was used to introduce the hly and actA genes at comK-attBB' in deletion strains derived from 10403S and SLCC-5764. These strains were tested for second-site complementation in hemolysin assays, plaquing assays, and cell extract motility assays. Unlike plasmid-complemented strains, integrated pPL1-complemented strains were fully virulent in the mouse 50% lethal dose assay. Additionally, the PSA phage attachment site on the L. monocytogenes chromosome was characterized, and pPL1 was modified to integrate at this site. The listeriophage PSA integrates in the 3' end of an arginine tRNA gene. There are 17 bp of DNA identity between the bacterial and phage attachment sites. The PSA prophage DNA sequence reconstitutes a complete tRNA(Arg) gene. The modified vector, pPL2, was integration proficient at the same frequency as pPL1 in common laboratory serotype 1/2 strains as well as serotype 4b strains.