Coding-complete sequence of a vaccine-derived recombinant porcine reproductive and respiratory syndrome virus strain isolated in Hungary.

Porcine reproductive and respiratory syndrome virus 1 is a major cause of swine morbidity and mortality in various parts of the world, including Hungary. A national elimination programme to reduce the associated economic burden was initiated in Hungary in 2012. Using extensive laboratory surveillance, we identified and isolated an unusual PRRSV strain. The complete coding sequence of this isolate was determined and analyzed. The genome of this Hungarian PRRSV1 strain, HUN60077/16, is 15,081 nucleotides in length. Phylogenetic and recombination analysis showed a mosaic structure of the genome where a large fragment of ORF1b and the genomic region coding for ORF3 to ORF7 showed a very close genetic relationship to the vaccine virus Unistrain, while the ORF1a region, the 3' end of ORF1b, and the whole ORF2 were only distantly related to this or any other PRRSV1 strain whose genome sequence is available in the GenBank database. Genomic characterization of PRRSV strains is crucial when possible vaccine-associated cases are identified. This approach not only helps to identify genetic interactions between vaccine and wild-type PRRSV1 strains but may also be needed to prevent trust in commercial vaccines from being undermined.

Development of a PCR system for the characterisation of Salmonella flagellin genes.

Analysis of flagellin genes was carried out on strains of Salmonella Typhimurium, Salmonella Hadar, Salmonella Abortusequi, Salmonella Enteritidis and Salmonella Gallinarum serovars, using a PCR system designed in this study. The purpose of these studies was to explore the flagellin genes of biphasic and monophasic Salmonellae for future targeted genetic interventions. The PCR primers were designed for two different structural genes of flagellin (fliC, fljB), for the repressor of fliC (fljA), for the operator region of fliC, and for the invertase system responsible for phase variation in Salmonella (hin, hixL, hixR). PCR analysis revealed that all of the examined genes (fliC, fliC-operator, fljB, fljA, hin, hixL, hixR) were present in all S. Typhimurium (n = 10) and S. Hadar (n = 10) strains tested. The results obtained on S. Typhimurium and S. Hadar strains confirmed their biphasic character at DNA level. However, the S. Enteritidis (n = 46) and S. Gallinarum (n = 5) strains lacked the invertase system (hin, hixL, hixR) as well as the fljA and fljB genes, while fliC and its operator were detectable. Consequently, the S. Enteritidis strains could only express fliC gene resulting in phase H1 flagellin. The examined S. Gallinarum strains were also demonstrated to have a cryptic flagellin gene (fliC). On the other hand, PCR results on S. Abortusequi (n = 2) indicated that both flagellin genes (fliC, fljB) and the whole phase variation system were present in both strains tested but only the H2 phase gene (fljB) was expressed. The phenotype of these strains could be clarified by motility test and/or by classical flagellar serology. The findings are also substantiated by the results of serovar-specific PCR for S. Typhimurium and S. Enteritidis. In conclusion, the PCR system developed in this study proved to be suitable for characterisation of Salmonella flagellin genes and confirmed serological results regarding all S. Typhimurium, S. Hadar and S. Enteritidis strains. This system could also identify cryptic flagellar genes of S. Abortusequi and S. Gallinarum.

Vector for IS element entrapment and functional characterization based on turning on expression of distal promoterless genes.

We constructed and characterized a novel trap vector for rapid isolation of insertion sequences. The strategy used for the isolation of IS elements is based on the ability of many IS elements to turn on the expression of otherwise silent genes distal to some sites of insertion. The simple transposition of an IS element can sometimes cause the constitutive expression of promoterless antibiotic resistance genes resulting in selectable phenotypes. The trap vector pAW1326 is based on a pBR322 replicon, it carries ampicillin and streptomycin resistance genes, and also silenced genes that confer chloramphenicol and kanamycin resistance once activated. The trap vector pAW1326 proved to be efficient and 85 percent of all isolated mutations were insertions. The majority of IS elements resident in the studied Escherichia coli strains tested became trapped, namely IS2, IS3, IS5, IS150, IS186 and Tn1000. We also encountered an insertion sequence, called IS10L/R-2, which is a hybrid of the two IS variants IS10L and IS10R. IS10L/R-2 is absent from most E. coli strains, but it is detectable in some strains such as JM109 which had been submitted to Tn10 mutagenesis. The distribution of the insertion sequences within the trap region was not random. Rather, the integration of chromosomal mobile genetic elements into the offered target sequence occurred in element-specific clusters. This is explained both by the target specificity and by the specific requirements for the activation of gene transcription by the DNA rearrangement. The employed trap vector pAW1326 proved to be useful for the isolation of mobile genetic elements, for a demonstration of their transposition activity as well as for the further characterization of some of the functional parameters of transposition.

Stable incorporation of genetic material into the chromosome of Rhizobium meliloti 41: construction of an integrative vector system.

An integrative vector system has been developed from the site-specific recombination elements of temperate phage 16-3. The system can be used for highly efficient stable introduction of genetic material into the chromosome of the symbiotic nitrogen-fixing organism, Rhizobium meliloti 41 (Rm41) at the attB site. Vectors carrying the phage-borne attachment site were constructed, and helper phages providing the site-specific recombination functions in trans were isolated. Other possible applications of the system are discussed.

The construction and characterization of an effective transpositional system based on IS30.

We constructed an in vivo system to detect transpositional rearrangements induced by the insertion sequence IS30. The transposase protein expressed from the transposase producer plasmids catalyzed rearrangements on different target sequences presented in trans. High yields, up to 83%, of transpositional frequencies were observed. The frequency of rearrangements correlated with the amount of transposase protein produced and the attractivity of the target sequences. Alteration in the frequency of transposition was observed in the recA- E. coli strains JM109 and TG2. Remarkable structural and functional analogy was found with site-specific recombination systems.

Mutations in the carboxy-terminal part of IS30 transposase affect the formation and dissolution of (IS30)2 dimer.

The transposase of IS30 catalyses different transpositional rearrangements via the dimer (IS30)2 intermediate structure. Mutation analysis provides evidence that the C-terminal part of IS30 transposase is required for the formation and dissolution of (IS30)2 dimer. C-terminal mutants are also defective in transpositional fusion; however, this deficiency can be 'suppressed' by addition of the final product of site-specific dimerisation, the core (IS30)2 intermediate structure. The transposase part studied shows significant homologies in three highly conserved regions to proteins of IS30-related mobile elements.

Formation and transposition of the covalently closed IS30 circle: the relation between tandem dimers and monomeric circles.

In the present study, we demonstrate that a circular IS30 element acts as an intermediate for simple insertion. Covalently closed IS and Tn circles constructed in vitro are suitable for integration into the host genome. Minicircle integration displays all the characteristics of transpositional fusion mediated by the (IS30 )2 dimer regarding target selection and target duplication. Evidence is provided for in vivo circularization of the element located either on plasmids or on the genome. It is shown that circle formation can occur through alternative pathways. One of them is excision of IS30 from a hot spot via joining the IRs. This reaction resembles the site-specific dimerization that leads to (IS30 )2 establishment. The other process is the dissolution of (IS30 )2 dimer, when the element is excised from an IR-IR joint. These pathways differ basically in the fate of the donor replicon: only dimer dissolution gives rise to resealed donor backbone. Analysis of minicircles and the rearranged donor replicons led us to propose a molecular model that can account for differences between the circle-generating processes. Our focus was to the dissolution of IR-IR joints located on the host genome, because these events promoted extensive genomic rearrangements and accompanied minicircle formation. The results present the possibility of host genome reorganization by IS30-like transposition.

Formation of the tandem repeat (IS30)2 and its role in IS30-mediated transpositional DNA rearrangements.

Plasmids carrying two IS30 elements in the same orientation, as in the composite transposon Tn2706, are structurally unstable in Escherichia coli. A primary segregation product is formed by site-specific deletion of the sequences carried between the two IS30 elements. The resulting covalently closed replicon carries the two IS30 elements as tandem repeats separated by only 2 bp. This (IS30)2 structure is extremely unstable, but it can nevertheless be isolated on its vector plasmid and, after purification, can be reintroduced into host cells by transformation. Among the descendants of transformants of recA- bacteria, replicated copies of the introduced (IS30)2 structure are still present, together with various kinds of segregation products which provide evidence for the efficient generation of DNA rearrangements. Most abundant is the product of another site-specific recombination between two identical ends of the IS30 elements involved, which results in the presence of just one intact IS30 on the plasmid. Apart from this, and depending on the presence of appropriate targets for IS30 transposition, various transposition products of (IS30)2 are also seen. Intramolecular reactions lead to DNA inversions and deletions with breakpoints other than IS30 ends. In intermolecular reactions inverse transposition occurs at high frequency and one also obtains simple transposition and cointegration. A mutational study revealed the requirement in cis of one intact IS30 transposase gene and of both proximal ends of the two IS30 elements concerned not only for the formation of (IS30)2, but also for its further rearrangement reactions, including the efficient formation of site-specific deletions. A model is proposed, which postulates that (IS30)2 intermediates play a key role in IS30 transposition pathways in which the formation of (IS30)2 may be rate-limiting. Once this structure is formed, it gives rise to a burst of transpositional rearrangements in the subclone carrying (IS30)2. Evolutionary implications of these findings are discussed.

Isolation, characterization and transposition of an (IS2)2 intermediate.

We have isolated and characterized a dimer derivative of the extensively studied Escherichia coli insertion sequence IS2. The dimer structure--called (IS2)2--consists of two IS2 elements arranged as a direct repeat, separated by 1 bp. The junction between the (IS2)2 dimer and target sequences is located at various positions in independent isolates; however, one position was preferred. The transposition of (IS2)2 into a target plasmid resulted in cointegrate-type structures. The transposition frequency of the (IS2)2 dimer itself was significantly higher than that of the isogenic monomer IS2 insertion. The poor stability and high activity of (IS2)2 indicates that this is an active transposition intermediate. The mode of transposition of (IS2)2 is analogous to the joined dimer model described in the case of (IS21)2 and (IS30)2.

The N-terminal domain of the insertion sequence 30 transposase interacts specifically with the terminal inverted repeats of the element.

The gene for the insertion sequence (IS) 30 transposase is placed under the control of the tac promoter, and large quantities of transposase are expressed upon induction. The resulting protein precipitates inside the Escherichia coli cells in the form of inclusion bodies which, upon cell lysis, cannot be dissolved under nondenaturing conditions. In contrast, the N-terminal third of the transposase, a 17-kDa protein produced by a truncated gene, can be purified and is able to interact site specifically with the ends of the IS30 element. In DNase I footprint experiments, regions of 26 nucleotides on one DNA strand and 19 nucleotides on the other strand at either end of the element are protected from nuclease digestion. It is concluded that a functional DNA-binding domain can be formed by expression of only one-third of the complete IS30 transposase. Sequence comparison shows a homology of the IS30 ends to the ends of IS4351 and to the L1 end of bacteriophage Mu.

Importance of illegitimate recombination and transposition in IS30-associated excision events.

In the present study we report on the excision of IS30 elements and IS30-derived composite transposons. Frequent loss of IS30 was observed during dissolution of dimeric IS30 structures, containing IR-IR junctions, leading to resealed donor molecules. In contrast, unambiguous transpositional excision resulting in resealed remainder products could not be identified in the case of a monomeric element. The bias in the excision of monomeric and dimeric IS30 structures indicates a difference in the molecular mechanism of transposition of IS30 monomers and dimers. Sequence data on the rarely detected plasmids missing full IS or Tn copies rather suggest that all products were derived from illegitimate recombination. The reaction occurred between short homologies and was independent of the transposase activity. Similar IS30 excision events accompanied by multiple plasmid or genome rearrangements were detected in Pseudomonas putida and Rhizobium meliloti, yielding stable replicons that retained the selective marker gene of the transposon. We provide evidence that both transposition and illegitimate recombination can contribute to the stabilization of replicons through the elimination of IS elements, which emphasizes the evolutionary significance of these events.

Recombination deficient mutants of Rhizobium meliloti 41.

Two mutants deficient in homologous genetic recombination have been isolated from Rhizobium meliloti 41 after Tn5 mutagenesis. Both mutants are defective in the induction of temperate phage 16-3 by UV-light, Mytomycin-C or Bleomycin, their UV sensitivity is more pronounced than that of the wild-type strain, and they lack the 'SOS activity' responsible for induced mutations.

The bacterial attachment site of the temperate Rhizobium phage 16-3 overlaps the 3' end of a putative proline tRNA gene.

Bacteriophage 16-3 inserts its genome into the chromosome of Rhizobium meliloti strain 41 (Rm41) by site-specific recombination. The DNA regions around the bacterial attachment site (attB) and one of the hybrid attachment sites bordering the integrated prophage (attL) were cloned and their nucleotide sequences determined. We demonstrated that the 51 bp region, where the phage and bacterial DNA sequences are identical, is active as a target site for phage integration. Furthermore it overlaps the 3' end of a putative proline tRNA gene. This gene shows 79% similarity to the corresponding proline tRNA-like genomic target sequence of certain integrative plasmids in Actinomycetes.

Terminal inverted repeats of insertion sequence IS30 serve as targets for transposition.

In the present study, we demonstrate that the terminal inverted repeats of the Escherichia coli insertion sequence IS30 are functional target sites for the transposition of the (IS30)2 dimer, which represents an intermediate structure in the transposition of IS30. Comparative analysis of various target regions revealed that the left and right ends differ in their "attractivity." In our experiments, the joined left and right ends, i.e., the (IS30)2 intermediate structure, was found to be the most preferred target. It was also shown that flanking sequences can influence the target activity of the terminal repeats. The functional part of the target region was localized in the inverted repeats by means of mutational analysis, and it corresponds to the binding site of IS30 transposase. Insertion of 1 bp into the right inverted repeat resulted in unusual target duplication accompanied by gene conversion. The choice of the terminal inverted repeats as targets in transposition leads to the reconstruction of the (IS30)2 structure, which may induce a cascade of further rearrangements. Therefore, this process can play a role in the evolution of the genome.

Target specificity of insertion element IS30.

The Escherichia coli resident mobile element IS30 has pronounced target specificity. Upon transposition, the element frequently inserts exactly into the same position of a preferred target sequence. Insertion sites in phages, plasmids and in the genome of E. coli are characterized by an exceptionally long palindromic consensus sequence that provides strong specificity for IS30 insertions, despite a relatively high level of degeneracy. This 24-bp-long region alone determines the attractiveness of the target DNA and the exact position of IS30 insertion. The divergence of a target site from the consensus and the occurrence of 'non-permitted' bases in certain positions influence the target activity. Differences in attractiveness are emphasized if two targets are present in the same replicon, as was demonstrated by quantitative analysis. In a system of competitive targets, the oligonucleotide sequence representing the consensus of genomic IS30 insertion sites proved to be the most efficient target. Having compared the known insertion sites, we suppose that IS30-like target specificity, which may represent an alternative strategy in target selection among mobile elements, is characteristic of the insertion sequences IS3, IS6 and IS21, too.