Molecular tools to detect the IncJ elements: a family of integrating, antibiotic resistant mobile genetic elements

The IncJ group of enterobacterial mobile genetic elements, which include R391, R392, R705, R997 and pMERPH, have been shown to be site-specific integrating elements encoding variable antibiotic and heavy metal resistance genes. They insert into a specific 17-bp site located in the prfC gene, encoding peptide release factor 3, in Escherichia coli and other hosts. A key feature of known IncJ elements is the presence of a site-specific recombination module consisting of an attachment site on the element and an integrase-encoding gene of the tyrosine recombinase class, which promotes integration between the attachment site on the element and a similar site on the host chromosome. We have cloned and sequenced the integrases from a number of known IncJ elements and designed PCR primers for specific amplification of this gene. Using conserved regions of enterobacterial prfC genes upstream and downstream of the insertion site, and conserved sequences at the ends of the integrated IncJ elements, we have designed specific primers to amplify across the integrated IncJ attL and attR junction fragments. Alignment of over 30 enterobacterial prfC-like genes indicates that the primers designed to amplify attR junction would amplify IncJ element: host junctions from a wide variety of hosts. The IncJ elements have been shown to sensitise recA(+)E. coli K12 strains to UV irradiation. A simple and rapid procedure for demonstrating this effect is described. These tools should enable the rapid detection of such elements in clinical and environmental settings.     

Isolation and analysis of a circular form of the IncJ conjugative transposon-like elements, R391 and R997: implications for IncJ incompatibility

The incompatibility between the chromosomally integrating, conjugative transposon-like, IncJ elements R997 (ampicillin resistant) and R391 (kanamycin resistant) was examined by constructing strains harbouring both elements. Unusually, recA(+) strains harbouring the resistance determinants of both elements could be isolated but all strains lacked detectable extrachromosomal DNA. The phenotypic characteristics and transfer patterns observed suggested the formation of recombinant hybrids rather than strains harbouring both elements independently. Formation of strains harbouring two IncJ elements in a recA background was thus examined and resulted in the visualisation of extrachromosomal DNA. When R391 was transferred to a recA strain containing integrated R997, both elements co-existed stably and resulted in the isolation of a plasmid of 93.9 kb. When R997 was transferred to a recA strain harbouring an integrated R391, a plasmid of 85 kb was isolated. Comparison of restriction patterns for both elements revealed many common and several distinct fragments indicating a close physical relationship. These data suggest that although IncJ elements normally integrate at a unique site in the Escherichia coli chromosome, they possess the ability for autonomous replication which becomes manifest in a recA background when this site is occupied. This observation has implications for the nature of the incompatibility associated with IncJ elements and also provides a reliable method for isolating IncJ elements for molecular characterisation.     

Pulsed field gel electrophoresis to rapidly detect the presence of IncJ conjugative transposon-like elements

AIMS: To develop a screening method to detect the presence of the IncJ group of integrating conjugative transposon-like elements upon transfer to Escherichia coli. METHODS AND RESULTS: The unique insertion site of known IncJ elements, the prfC gene, is located in a region of the E. coli chromosome between 98.5 and 100 min on the E. coli genetic map. Using pulsed field gel electrophoresis and the rare cutting restriction enzymes SfiI and XbaI insertions of IncJ elements and an estimate of their size could be determined physically. CONCLUSIONS: This method allows initial screening of putative IncJ conjugative transposon-like elements by physical determination of their integration. Significance and Impact of the Study: IncJ-like elements, which appear to be highly homologous to the prototype IncJ element R391, have been found associated with recent epidemic outbreaks of cholera in a number of locations worldwide. Because of their integrative biology this method provides the first initial screening method to physically determine their presence upon transfer to E. coli.     

A conjugative 'plasmid' lacking autonomous replication

Attempts were made to isolate open and covalently closed circular DNA from strains containing the IncJ plasmids. All of the methods tried were unsuccessful. It was shown that the IncJ plasmid R391 can integrate into the Escherichia coli K12 chromosome and can mobilize chromosomal markers from a single origin in an orientated manner. It is proposed that the IncJ plasmids are integrated in the chromosome for most, if not all, of their existence and this explains the inability to isolate plasmid DNA from strains containing them.     

R391: a conjugative integrating mosaic comprised of phage,plasmid, and transposon elements

The conjugative, chromosomally integrating element R391 is the archetype of the IncJ class of mobile genetic elements. Originally found in a South African Providencia rettgeri strain, R391 carries antibiotic and mercury resistance traits, as well as genes involved in mutagenic DNA repair. While initially described as a plasmid, R391 has subsequently been shown to be integrated into the bacterial chromosome, employing a phage-like integration mechanism closely related to that of the SXT element from Vibrio cholerae O139. Analysis of the complete 89-kb nucleotide sequence of R391 has revealed a mosaic structure consisting of elements originating in bacteriophages and plasmids and of transposable elements. A total of 96 open reading frames were identified; of these, 30 could not be assigned a function. Sequence similarity suggests a relationship of large sections of R391 to sequences from Salmonella, in particular those corresponding to the putative conjugative transfer proteins, which are related to the IncHI1 plasmid R27. A composite transposon carrying the kanamycin resistance gene and a novel insertion element were identified. Challenging the previous assumption that IncJ elements are plasmids, no plasmid replicon was identified on R391, suggesting that they cannot replicate autonomously.     

Pre-exposure to UV irradiation increases the transfer frequency of the IncJ conjugative transposon-like elements R391, R392, R705, R706, R997 and pMERPH and is recA+ dependent

The enteric conjugative transposon-like IncJ elements R391, R392, R705, R706 and pMERPH, all demonstrated increased conjugative transfer upon UV irradiation. The transfer frequency increased on average from its basal rate of 10(-5) to 10(-3) per recipient, upon pre-exposure to UV irradiation. However, the transfer frequency of R997, which was higher than the other IncJ elements at 10(-3) per donor, showed a smaller increase. This effect was shown to be recA+ dependent in all cases. Using PCR primers directed outwards from the ends of the integrated R391 element it was observed that a circular intermediate of the element forms within the host, which has been proposed to be a transfer intermediate. Using real-time PCR, it was determined that the amount of the circular intermediate produced increased substantially upon UV irradiation.     

The effect of plasmid R391 and other IncJ plasmids on the survival of Escherichia coli after UV irradiation

The presence of the IncJ plasmids R391, R997, R705, R706, R748 and R749 was shown to sensitize Escherichia coli AB1157 and both its uvrA and lexA derivatives to UV irradiation. No alteration in post-irradiation survival was observed in a recA mutant containing these plasmids, compared with the non-plasmid-containing recA strain. Analysis of recombination frequency in Hfr crosses to recA+ cells containing plasmid R391 indicated a reduction in recombination frequency compared with that obtained in similar crosses to a non-plasmid-containing strain. This effect was not due to plasmid-encoded restriction or entry exclusion systems and therefore must be considered as a real block in recombination. When cells containing plasmid R391 were irradiated and allowed to photoreactivate, an increase in survival was observed which was comparable to that observed in the non-plasmid-containing derivative. This indicated that post-irradiation processing of UV-induced damage, or lack of such processing, by mechanisms other than photoreactivation was responsible for the UV sensitivity associated with plasmid R391.     

Characterization of the umu-complementing operon from R391.

In addition to conferring resistances to antibiotics and heavy metals, certain R factors carry genes involved in mutagenic DNA repair. These plasmid-encoded genes are structurally and functionally related to the chromosomally encoded umuDC genes of Escherichia coli and Salmonella typhimurium. Three such plasmid operons, mucAB, impCAB, and samAB, have been characterized at the molecular level. Recently, we have identified three additional umu-complementing operons from IncJ plasmid R391 and IncL/M plasmids R446b and R471a. We report here the molecular characterization of the R391 umu-complementing operon. The nucleotide sequence of the minimal R plasmid umu-complementing (rum) region revealed an operon of two genes, rumA(R391) and rumB(R391), with an upstream regulatory signal strongly resembling LexA-binding sites. Phylogenetic analysis revealed that the RumAB(R391) proteins are approximately equally diverged in sequence from the chromosomal UmuDC proteins and the other plasmid-encoded Umu-like proteins and represent a new subfamily. Genetic characterization of the rumAB(R391) operon revealed that in recA+ and recA1730 backgrounds, the rumAB(R391) operon was phenotypically indistinguishable from mucAB. In contrast, however, the rumAB(R391) operon gave levels of mutagenesis that were intermediate between those given by mucAB and umuDC in a recA430 strain. The latter phenotype was shown to correlate with the reduced posttranslational processing of the RumA(R391) protein to its mutagenically active form, RumA'(R391). Thus, the rumAB(R391) operon appears to possess characteristics that are reminiscent of both chromosome and plasmid-encoded umu-like operons.     

Identification of the origin of transfer (oriT) and a new gene required for mobilization of the SXT/R391 family of integrating conjugative elements

Integrating conjugative elements (ICEs) are self-transmissible, mobile elements that are widespread among bacteria. Following their excision from the chromosome, ICEs transfer by conjugation, a process initiated by a single-stranded DNA break at a specific locus called the origin of transfer (oriT). The SXT/R391 family of ICEs includes SXT(MO10), R391, and more than 25 related ICEs found in gammaproteobacteria. A previous study mapped the oriT locus of SXT(MO10) to a 550-bp intergenic region between traD and s043. We suspected that this was not the correct oriT locus, because the identical traD-s043 region in R391 and other SXT/R391 family ICEs was annotated as a gene of an unknown function. Here, we investigated the location and structure of the oriT locus in the ICEs of the SXT/R391 family and demonstrated that oriT(SXT) corresponds to a 299-bp sequence that contains multiple imperfect direct and inverted repeats and is located in the intergenic region between s003 and rumB'. The oriT(SXT) locus is well conserved among SXT/R391 ICEs, like R391, R997, and pMERPH, and cross-recognition of oriT(SXT) and oriT(R391) by R391 and SXT(MO10) was demonstrated. Furthermore, we identified a previously unannotated gene, mobI, located immediately downstream from oriT(SXT), which proved to be essential for SXT(MO10) transfer and SXT(MO10)-mediated chromosomal DNA mobilization. Deletion of mobI did not impair the SXT(MO10)-dependent transfer of the mobilizable plasmid CloDF13, suggesting that mobI has no role in the assembly of the SXT(MO10) mating pair apparatus. Instead, mobI appears to be involved in the recognition of oriT(SXT).     

Structural comparison of the integrative and conjugative elements R391, pMERPH, R997, and SXT

R391 and SXT are members of a group of eleven chromosome-borne conjugative elements found in the gamma-proteobacteria, whose members carry different antibiotic resistance traits. Recent genomic analysis of R391 and SXT revealed a highly conserved 'backbone' encoding integration/excision, conjugative transfer, and regulation functions, augmented by an array of phenotypic traits and transposable elements. In this study, PCR amplification and sequence analysis were employed to investigate the genomic structure of two further MGE of the R391 family, pMERPH (HgR) and R997 (ApR, SmR, SuR). R997 and pMERPH were found to be structurally related to R391 and SXT and share a number of virtually identical regions with them-including putative integration, conjugative transfer, and regulatory determinants-interrupted by variable DNA segments and transposable elements. The presence of a highly conserved backbone in the four elements strongly suggests their origin in a common ancestral element, which itself was a mosaic of sequences related to phages and plasmids. Subsequent genetic recombination and the acquisition of transposable elements resulted in the possession of variable phenotypic traits among the four MGE, and diversification into two distinct lineages, the first one including R391 and pMERPH, the second one containing SXT and R997.     

Enhancement of UV survival, UV- and MMS-mutability, precise excision of Tn10 and complementation of umuC by plasmids of different incompatibility groups

29 conjugative resistance and colicin plasmids from 19 different incompatibility (Inc) groups were examined for their ability to enhance post-ultraviolet (UV) survival and UV- and methyl methanesulfonate(MMS)-induced mutability in Salmonella typhimurium LT2 strains. 14 Muc+ plasmids enhanced each of the survival and mutation-related properties tested, while 14 Muc- plasmids showed no enhancing effects in any tests. One Muc+ plasmid, pRG1251 (IncH1), enhanced post-UV survival and each of the mutation-related properties tested, except MMS-induced mutagenesis. Two further noteworthy plasmids, R391 (IncJ) and R394 (IncT), produced apparent strain-dependent effects in S. typhimurium which differed from those reported to have been found in Escherichia coli. Plasmid R391 enhanced post-UV survival in S. typhimurium, in contrast to its UV-sensitizing effects in E. coli. In both hosts plasmid R391 enhanced UV- and MMS-induced mutagenesis. Plasmid R394 had no enhancing effects on UV survival or UV- and MMS-induced mutagenesis in S. typhimurium, in contrast to its reported enhancement of MMS-induced mutagenesis in E. coli. Conjugal transfer of R394 to E. coli strain AB1157 and assays of mutagenesis-related traits supported results observed in S. typhimurium. Muc+ plasmids were found to enhance the frequency of precise excision of the transposon Tn10 when inserted within hisG or trpA in S. typhimurium strains. Precise excision could be further enhanced in S. typhimurium by UV-irradiation. Analysis of Tn10 mutants with altered IS10 ends indicated that intact inverted repeats at the ends of Tn10 were required for efficient enhancement of precise excision.     

Formation of chromosomal tandem arrays of the SXT element and R391, two conjugative chromosomally integrating elements that share an attachment site

The SXT element, a conjugative, self-transmissible, integrating element (a constin) originally derived from a Vibrio cholerae O139 isolate from India, and IncJ element R391, originally derived from a South African Providencia rettgeri isolate, were found to be genetically and functionally related. Both of these constins integrate site specifically into the Escherichia coli chromosome at an identical attachment site within the 5' end of prfC. They encode nearly identical integrases, which are required for chromosomal integration, excision, and extrachromosomal circularization of these elements, and they have similar tra genes. Therefore, these closely related constins have virtually identical mechanisms for chromosomal integration and dissemination. The presence of either element in a recipient cell did not significantly reduce its ability to acquire the other element, indicating that R391 and SXT do not encode surface exclusion determinants. In cells harboring both elements, SXT and R391 were integrated in tandem fashion on the chromosome, and homologous recombination appeared to play little or no role in the formation of these arrays. Interference between R391 and SXT was detected by measuring the frequency of loss of an unselected resident element upon introduction of a second selected element. In these assays, R391 was found to have a stronger effect on SXT stability than vice versa. The level of expression and/or activity of the donor and recipient integrases may play a role in the interference between these two related constins.     

Location and cloning of the ultraviolet-sensitizing function from the chromosomally associated IncJ group plasmid, R391

The IncJ plasmid R391, which specifies a uv-sensitizing function, has been shown to be associated with chromosomal DNA. Deletions originating from Tn10 insertion into the kanamycin-resistance determinant of plasmid R391 gave rise to uv-resistant derivatives. This apparent linkage between the kanamycin-resistance determinant and the uv-sensitizing gene(s) was used to clone the uv-sensitizing function from plasmid R391 into pUR222. A recombinant plasmid containing both functions (KanR and Uvs+) was obtained. The uv-sensitizing function was mapped to a 4-kb EcoRI fragment.     

A rapid method for cloning mutagenic DNA repair genes: isolation of umu-complementing genes from multidrug resistance plasmids R391, R446b, and R471a.

Genetic and physiological experiments have demonstrated that the products of the umu-like operon are directly required for mutagenic DNA repair in enterobacteria. To date, five such operons have been cloned and studied at the molecular level. Given the apparent wide occurrence of these mutagenic DNA repair genes in enterobacteria, it seems likely that related genes will be identified in other bacterial species and perhaps even in higher organisms. We are interested in identifying such genes. However, standard methods based on either DNA or protein cross-hybridization are laborious and, given the overall homology between previously identified members of this family (41 to 83% at the protein level), would probably have limited success. To facilitate the rapid identification of more diverse umu-like genes, we have constructed two Escherichia coli strains that allow us to identify umu-like genes after phenotypic complementation assays. With these two strains, we have cloned novel umu-like genes from three R plasmids, the IncJ plasmid R391 and two IncL/M plasmids, R446b and R471a.     

Structural and functional analysis of a cloned segment of Escherichia coli DNA that specifies proteins of a C4 pathway of serine biosynthesis.

The plasmid pDR121 is a pBR322 derivative that contains a 3.7-kilobase-pair EcoRI fragment of DNA from the 81.2-min region of the Escherichia coli chromosome. The genomic insert encodes threonine dehydrogenase and at least one other protein. Several physical and kinetic properties of threonine dehydrogenase, overproduced in cells harboring pDR121, are identical to those of pure threonine dehydrogenase from a haploid mutant of E. coli K-12 that produces this enzyme constitutively. Tester strains with serB or glyA mutations harboring pDR121 are prototrophs. The ability to confer prototrophy on such tester strains is associated with elevated levels of threonine dehydrogenase. The functional roles of various segments of the 3.7-kilobase-pair insert of pDR121 were analyzed by constructing specific deletions and insertions. Certain subclones retained the ability to specify threonine dehydrogenase without conferring prototrophy on tester strains. This suggests that at least one other protein encoded within pDR121 plays an essential role in the conversion of threonine to serine.     

Expression of Mycobacterium tuberculosis Ku and Ligase D in Escherichia coli results in RecA and RecB-independent DNA end-joining at regions of microhomology

Unlike Escherichia coli, Mycobacterium tuberculosis (Mt) expresses a Ku-like protein and an ATP-dependent DNA ligase that can perform non-homologous end-joining (NHEJ). We have expressed the Mt-Ku and Mt-Ligase D in E. coli using an arabinose-inducible promoter and expression vectors that integrate into specific sites in the E. coli chromosome. E. coli strains have been generated that express the Mt-Ku and Mt-Ligase D on a genetic background that is wild-type for repair, or deficient in either the RecA or RecB protein. Transformation of these strains with linearized plasmid DNA containing a 2bp overhang has demonstrated that expression of both the Mt-Ku and Mt-Ligase D is required for DNA end-joining and that loss of RecA does not prevent this double-strand break repair. Analysis of the re-joined plasmid has shown that repair is predominantly inaccurate and results in the deletion of sequences. Loss of RecB did not prevent the formation of large deletions, but did increase the amount of end-joining. Sequencing the junctions has revealed that the majority of the ligations occurred at regions of microhomology (1-4bps), eliminating one copy of the homologous sequence at the junction. The Mt-Ku and Mt-Ligase D can therefore function in E. coli to re-circularize linear plasmid.     

A PCR-free cloning method for the targeted φ80 Int-mediated integration of any long DNA fragment, bracketed with meganuclease recognition sites, into the Escherichia coli chromosome

The genetic manipulation of cells is the most promising strategy for designing microorganisms with desired traits. The most widely used approaches for integrating specific DNA-fragments into the Escherichia coli genome are based on bacteriophage site-specific and Red/ET-mediated homologous recombination systems. Specifically, the recently developed Dual In/Out integration strategy enables the integration of DNA fragments directly into specific chromosomal loci (Minaeva et al., 2008). To develop this strategy further, we designed a method for the precise cloning of any long DNA fragments from the E. coli chromosome and their targeted insertion into the genome that does not require PCR. In this method, the region of interest is flanked by I-SceI rare-cutting restriction sites, and the I-SceI-bracketed region is cloned into the unique I-SceI site of an integrative plasmid vector that then enables its targeted insertion into the E. coli chromosome via bacteriophage φ80 Int-mediated specialized recombination. This approach allows any long specific DNA fragment from the E. coli genome to be cloned without a PCR amplification step and reproducibly inserted into any chosen chromosomal locus. The developed method could be particularly useful for the construction of marker-less and plasmid-less recombinant strains in the biotechnology industry.     

Thermosensitive vector derived from RP1 plasmid for detection of transposable elements

The involvement of the transposable DNA element of E. coli K12 chromosome in integrative recombination of RP1 plasmid was studied. Using temperature sensitive for replication plasmid RP1ts12--the derivative of RP1 which contains mutated transposon Tnl, it was shown that integration of RP1 into host chromosome and Hfr formation may occur according to a mechanism mediated by chromosome IS-elements. Plasmids that are desintegrated from the chromosome of these Hfrs contain discrete DNA segments (IS-elements) and possess elevated frequency of integration into chromosome of rec+ cells. The latter was used for selection of RP1ts12 recombinants carrying chromosome IS. For identification of IS involved in RP1 integration the number of independent RP1ts 12 recombinants was subjected to restriction and heteroduplex analysis. By analysing recombinants integrated into bacterial chromosome with frequency 5 X 10(-3), a new IS-element of E. coli K12 designated IS111 was discovered. IS111-element is about 1500bp of length, contains Smal, Pst1 and BamH1 restriction endonuclease sites and was found in the same position on the plasmid RP1 in two different orientations. IS-elements that have been revealed in a number of other RP1ts12 recombinants were preliminary identified as IS1-like elements. One recombinants plasmid was found to have an IS5-like elements. The activity of IS-elements inserted into RP1ts12 in recA-dependent integrative recombination was estimated. From the data of absolute and relative RP1ts12 integration frequencies mediated by IS111, IS1- and IS5-like elements a conclusion was made about the absence of E. coli K12 chromosome IS-elements in RP1 plasmid. The Hfr-formation and chromosomal gene transfer by recombinant plasmids RP1ts12: IS111 were studied. The possibility to use insertion RP1ts12 derivatives for the estimation of copies number, mapping and definition of orientation of IS-elements in bacterial chromosome and the possibilities for detection of transposable DNA elements using RP1ts12 in a wide range of gram-negative bacteria are discussed.