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 105-kDa protein component of Bacillus cereus non-haemolytic enterotoxin (Nhe) is a metalloprotease with gelatinolytic and collagenolytic activity

The integration site(s) of the IncJ element, R391, was localised to a specific region of the Escherichia coli chromosome, between the uxuA and serB loci (98.0-99.5 min), using classical Hfr mapping techniques. F-prime plasmid hosts, diploid for regions spanning the E. coli chromosome, were used as recipients in R391 and R997 conjugal transfer assays. Analysis of transconjugants revealed the integration of R391 and R997 into specific F-primes that contain the uxuA to serB region, but not F-primes that contain other regions of the chromosome. A comparison of the electrophoretic mobility of the original F-primes with those containing inserts demonstrated the integration of large elements, in excess of 85 kb. Linear integration of the IncJ elements into chromosomal DNA was demonstrated in recombination-deficient (recA) backgrounds in the absence of detectable autonomous stages. These observations account for the inability to isolate plasmid DNA from IncJ hosts, and suggests that the elements exhibit a conjugative transposon-like biology in E. coli.     

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.     

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.     

Investigating the impact of bisphosphonates and structurally related compounds on bacteria containing conjugative plasmids

Bacterial plasmids propagate through microbial populations via the directed process of conjugative plasmid transfer (CPT). Because conjugative plasmids often encode antibiotic resistance genes and virulence factors, several approaches to inhibit CPT have been described. Bisphosphonates and structurally related compounds (BSRCs) were previously reported to disrupt conjugative transfer of the F (fertility) plasmid in Escherichia coli. We have further investigated the effect of these compounds on the transfer of two additional conjugative plasmids, pCU1 and R100, between E. coli cells. The impact of BSRCs on E. coli survival and plasmid transfer was found to be dependent on the plasmid type, the length of time the E. coli were exposed to the compounds, and the ratio of plasmid donor to plasmid recipient cells. Therefore, these data indicate that BSRCs produce a range of effects on the conjugative transfer of bacterial plasmids in E. coli. Since their impact appears to be plasmid type-dependent, BSRCs are unlikely to be applicable as broad inhibitors of antibiotic resistance propagation.     

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.     

Conjugative transfer of the Lactococcus lactis sex factor and pRS01 plasmid to Enterococcus faecalis

The low G+C gram-positive bacterium Lactococcus lactis harbours two highly similar conjugative elements: an integrative and conjugative element called sex factor and the pRS01 plasmid. Originally, it was believed that the host range of the sex factor was limited to L. lactis subspecies. Here, it is reported that pTRK28 cointegrates of a spectinomycin-marked L. lactis sex factor and of the pRS01 conjugative plasmid can be transferred from L. lactis to Enterococcus faecalis. These results demonstrate the conjugative transfer of these elements to other bacterial species. Furthermore, it is reported that Ll.LtrB, a mobile group II intron carried by both elements, can invade its recognition site upon pRS01 conjugative transfer to E. faecalis.     

Recent aspects of genetic manipulation in Bacillus thuringiensis

The conjugative plasmid pAM beta 1 was transferred from Streptococcus faecalis to several strains of Bacillus thuringiensis by a filter-mating process. From a transconjugant clone of B. thuringiensis a hybrid plasmid resulting from an in vivo insertion into pAM beta 1 of a 3 Md DNA sequence was isolated. This 3 Md DNA molecule (Th sequence) is related to several host plasmids found in different serotypes of B. thuringiensis. A reciprocal conjugation-like process involving the transfer of pAM beta 1 from B. thuringiensis to S. faecalis was also demonstrated. The comparison of the restriction maps of the crystal genes from plasmid and chromosomal origins of different serotypes, six of which having been cloned in E. coli, revealed the existence of two classes of genes which are very similar in the map corresponding to the N-terminal part of the protein, and which differ essentially in the 3' region. The presence of the transposon-like Th sequence was found in several cases associated with the crystal gene in the same host plasmid, and a model for their structural organization is proposed.     

A simple procedure for transferring genes cloned in Escherichia coli vectors into other gram-negative bacteria: phenotypic analysis and mapping of TOL plasmid gene xylK

A simple method to transfer non-conjugative Escherichia coli plasmids to other Gram-negative bacteria and their maintenance is described. This method involves generation of inverse transposition-mediated cointegrates of the non-conjugative E. coli plasmid with a conjugative IncW broad-host-range plasmid, R388, carrying Tn10. Isolation of such cointegrates was readily effected by conjugal transfer from an E. coli donor containing the two plasmids to an E. coli recipient, with selection for transconjugants expressing a marker of the E. coli plasmid. This method is particularly useful when large series of E. coli vector-based clones need to be expressed in other Gram-negative bacteria to be functionally analysed, either by complementation or recombination. Utility of the method is shown by a functional analysis in Pseudomonas putida of pBR322 hybrid plasmids containing catabolic genes of TOL plasmid pWW0.     

Plasmid pB8 is closely related to the prototype IncP-1beta plasmid R751 but transfers poorly to Escherichia coli and carries a new transposon encoding a small multidrug resistance efflux protein

The IncP-1beta plasmid pB8, which confers resistance to amoxicillin, spectinomycin, streptomycin, and sulfonamides, was previously isolated from a sewage treatment plant. It was found to possess abnormal conjugative transfer properties, i.e., transfer to Escherichia coli by conjugation or electroporation could not be detected. We showed in this study that plasmid pB8 is transferable to E. coli by conjugation, but only at low frequencies and under specific experimental conditions, a phenomenon that is very unusual for IncP-1 plasmids. Determination of the complete 57,198bp pB8 nucleotide sequence revealed that the backbone of the plasmid consists of a complete set of IncP-1beta-specific genes for replication initiation, conjugative plasmid transfer, stable inheritance, and plasmid control with an organisation identical to that of the prototype IncP-1beta plasmid R751. All of the minor differences in the pB8 backbone sequence compared to that of R751 were also found in other IncP-1beta plasmids known to transfer to and replicate in E. coli. Plasmids pB8 and R751 can be distinguished with respect to their accessory genetic elements. First, the pB8 region downstream of the replication initiation gene trfA contains two transposable elements one of which is similar to Tn5501. The latter transposon encodes a putative post-segregational-killing system and the small multidrug resistance (SMR) protein QacF, mediating quaternary ammonium compound resistance. The accessory genes in this region are not responsible for the poor plasmid transfer to E. coli since a pB8 deletion derivative devoid of all genes in that region showed the same conjugative transfer properties as pB8. A Tn5090/Tn402 derivative carrying a class 1 integron is located between the conjugative transfer modules. The Tn5090/Tn402 integration-sites are exactly identical on pB8 and R751 but in contrast to R751 the pB8 element carries the resistance gene cassettes oxa-2 for amoxicillin resistance and aadA4 for streptomycin/spectinomycin resistance, the integron-specific conserved segment consisting of the genes qacEDelta1, sul1, and orf5, and a truncated tni transposition module (tniAB). Although future work will have to determine the molecular basis for the poor transfer of pB8 to E. coli, our findings demonstrate that the host-range of typical IncP-1 plasmids may be less broad than expected.     

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.     

Simple conjugation and outgrowth procedures for tagging vibrios with GFP, and factors affecting the stable expression of the gfp tag

AIM: Our goal was to develop a simple system for tagging wild-type marine bacteria with gfp. METHODS AND RESULTS: Escherichia coli strain CC118lambdapir carrying the conjugative helper plasmid pEVS104 and the gfp-containing plasmid pKV111 was used to transfer gfp to Vibrio recipients. Four different media were tested for their ability to support the growth of recipients, but not the E. coli donor, to allow powerful enrichment of gfp-tagged wild-type vibrios from mating mixes. Forty-three vibrio strains, representing 39 different species, were successfully tagged with gfp using the conjugative transfer from E. coli followed by selective outgrowth at 15 degrees C on ZoBell 2216E agar containing 0.5% sodium alginate. Using this outgrowth medium, colonies of GFP-expressing vibrio clones were detectable within 4 days. The percentage of visibly fluorescent cells in three representative GFP-tagged vibrios was higher at 15 degrees C than at 20 or 25 degrees C (c. 50% vs. 45% or 40%, respectively), and was also higher during the aerobic rather than the anaerobic culturing (c. 50% vs. 35%, respectively). CONCLUSIONS: We found a simple selective outgrowth technique that enabled us to isolate a wide variety of GFP-tagged marine vibrios following the conjugative transfer of gfp from E. coli. SIGNIFICANCE AND IMPACT OF THE STUDY: Tagging cells with GFP and related fluorescent proteins is a powerful approach for investigating the bacteria in situ, particularly during the colonization of hosts. The simple and cost-effective outgrowth condition described in this study could be applied to construct a wide variety gfp-tagged marine bacteria.     

Genetic transformation of Geobacillus kaustophilus HTA426 by conjugative transfer of host-mimicking plasmids

We established an efficient transformation method for thermophile Geobacillus kaustophilus HTA426 using conjugative transfer from Escherichia coli of host-mimicking plasmids that imitate DNA methylation of strain HTA426 to circumvent its DNA restriction barriers. Two conjugative plasmids, pSTE33T and pUCG18T, capable of shuttling between E. coli and Geobacillus spp., were constructed. The plasmids were first introduced into E. coli BR408, which expressed one inherent DNA methylase gene (dam) and two heterologous methylase genes from strain HTA426 (GK1380-GK1381 and GK0343-GK0344). The plasmids were then directly transferred from E. coli cells to strain HTA426 by conjugative transfer using pUB307 or pRK2013 as a helper plasmid. pUCG18T was introduced very efficiently (transfer efficiency, 10(-5)-10(-3) recipient(-1)). pSTE33T showed lower efficiency (10(-7)-10(-6) recipient(-1)) but had a high copy number and high segregational stability. Methylase genes in the donor substantially affected the transfer efficiency, demonstrating that the host-mimicking strategy contributes to efficient transformation. The transformation method, along with the two distinguishing plasmids, increases the potential of G. kaustophilus HTA426 as a thermophilic host to be used in various applications and as a model for biological studies of this genus. Our results also demonstrate that conjugative transfer is a promising approach for introducing exogenous DNA into thermophiles.     

Transfer of genetic information from agrobacteria to bacterial and plant cells: membrane and supramembrane structures involved in transfer

The review deals with the supramembrane and membrane structures involved in the initial contact (attachment) of an agrobacterial cell with a bacterial or plant cell during the transfer of the agrobacterial genetic information. The relationships between the donor cell attachment to the recipient cell surface and the infection and conjugation processes are discussed. Experimental data on the recently found agrobacterial pili and surface protein rhicadhesin, which are involved in the conjugative transfer of the plasmid between agrobacteria, are considered. The role of adhesive and conjugative pili of E. coli in the initial and tight contacts is analyzed in the context of the recently proved similarity between the mechanisms of agrobacterial transformation in plants and conjugative transfer in bacteria. Possible involvement of the pilus in the conjugative transfer of agrobacterial DNA across the membranes of donor and recipient (bacterial and plant) cells is discussed.     

Characterization of the α-haemolysin determinant from the human enteropathogenic Escherichia coli O26 plasmid pEO5

The 157-kb conjugative plasmid pEO5 encoding α-haemolysin in strains of human enteropathogenic Escherichia coli (EPEC) O26 was investigated for its relationship with EHEC-haemolysin-encoding plasmids of enterohaemorrhagic E. coli (EHEC) O26 and O157 strains. Plasmid pEO5 was found to be compatible with EHEC-virulence plasmids and did not hybridize in Southern blots with plasmid pO157 from the EHEC O157:H7 strain EDL933, indicating that both plasmids were unrelated. A 9227-bp stretch of pEO5 DNA encompassing the entire α- hly CABD operon was sequenced and compared for similarity to plasmid and chromosomally inherited α- hly determinants. The α- hly determinant of pEO5 (7252 bp) and its upstream region was most similar to corresponding sequences of the murine E. coli α-hly plasmid pHly152, in particular, the structural α- hly CABD genes (99.2% identity) and the regulatory hly R regions (98.8% identity). pEO5 and α-hly plasmids of EPEC O26 strains from humans and cattle were very similar for the regions encompassing the structural α- hly CABD genes. The major difference found between the hly regions of pHly152 and pEO5 is caused by the insertion of an IS 2 element upstream of the hly C gene in pHly152. The presence of transposon-like structures at both ends of the α- hly sequence indicates that this pEO5 virulence factor was probably acquired by horizontal gene transfer.     

Transposition of Tn4551 in Bacteroides fragilis: identification and properties of a new transposon from Bacteroides spp.

Tn4551, a clindamycin resistance (Ccr) transposon from the R plasmid pBI136, was cloned onto an Escherichia coli-Bacteroides shuttle vector which could replicate normally in E. coli but was maintained unstably in Bacteroides fragilis. To aid in cloning and to ensure maintenance of Tn4551 in E. coli, a kanamycin resistance determinant (Kmr) was inserted in the transposon. The transposon-bearing shuttle vector pFD197 was transformed into B. fragilis 638, and putative insertions of Tn4551::Kmr were identified by screening for resistance to clindamycin and plasmid content. Southern hybridization analyses were used to verify integration of the transposon in the B. fragilis chromosome, and the frequency of insertion was estimated at 7.8 X 10(-5) events per generation. In 57% of the isolates tested a second integration event also occurred. This second insertion apparently involved just a single copy of the 1.2-kilobase repeat sequence which flanks the transposon. In addition, Tn4551::Kmr appeared to function as a transposon in E. coli. Evidence for this was obtained by the isolation of transposon insertions into the bacteriophage P1 genome. Finally, the transposon vector, pFD197, could be mobilized to other B. fragilis strains in which transposition was detected. Mobilization from the strain 638 background was via a conjugation like process, but occurred in the absence of known conjugative elements or other detectable plasmids. This result suggested the presence of a host-encoded transfer system in this B. fragilis strain.     

Transitory Derepression and the Maintenance of Conjugative Plasmids

It has been proposed that bacterial plasmids cannot be maintained by infectious transfer alone and that their persistence requires positive selection for plasmid-borne genes. To test this hypothesis, the population dynamics of two laboratory and five naturally occurring conjugative plasmids were examined in chemostat cultures of E. coli K-12. Both laboratory plasmids and three of the five wild plasmids failed to increase in frequency when introduced at low frequencies. However, two of the naturally occurring plasmids rapidly increased in frequency, and bacteria carrying them achieved dominance in the absence of selection for known plasmid-borne genes. Three hypotheses for the invasion and persistence of these two plasmids were examined. It is concluded that although these two extrachromosomal genetic elements are repressed for conjugative pili synthesis, as a consequence of high rates of transfer during periods of transitory derepression in newly formed transconjugants, they become established and are maintained by infectious transfer alone. The implications of these observations to the theory of plasmid maintenance and the evolution of repressible conjugative pili synthesis are discussed.     

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.