Family of class 1 integrons related to In4 from Tn1696.

The class 1 integron In28, found in the multidrug resistance transposon Tn1403, was found to be located in the res site of the backbone transposon and is flanked by a 5-bp direct duplication, indicating that it reached this position by transposition. In28 has a backbone structure related to that of In4, but has lost internal sequences, including the sul1 gene, due to an IS6100-mediated deletion. In28 also lacks the partial copy of IS6100 found in In4 and contains different gene cassettes, blaP1, cmlA1, and aadA1. In1, the class 1 integron found in the multidrug resistance plasmid R46, is also located in a putative res site and belongs to the In4 group. In1 has a shorter internal deletion than In28 and has also lost one end. Additional integrons with structures related to In4 were also found in databases, and most of them had also lost either one end or internal regions or both. Tn610 belongs to this group.

Efficiency of recombination reactions catalyzed by class 1 integron integrase IntI1.

The class 1 integron integrase, IntI1, recognizes two distinct types of recombination sites, attI sites, found in integrons, and members of the 59-be family, found in gene cassettes. The efficiencies of the integrative version of the three possible reactions, i.e., between two 59-be, between attI1 and a 59-be, or between two attI1 sites, were compared. Recombination events involving two attI1 sites were significantly less efficient than the reactions in which a 59-be participated, and the attI1 x 59-be reaction was generally preferred over the 59-be x 59-be reaction. Recombination of attI1 with secondary sites was less efficient than the 59-be x secondary site reaction.

Recovery of new integron classes from environmental DNA.

Integrons are genetic elements known for their role in the acquisition and expression of genes conferring antibiotic resistance. Such acquisition is mediated by an integron-encoded integrase, which captures genes that are part of gene cassettes. To test whether integrons occur in environments with no known history of antibiotic exposure, PCR primers were designed to conserved regions of the integrase gene and the gene cassette recombination site. Amplicons generated from four environmental DNA samples contained features typical of the integrons found in antibiotic-resistant and pathogenic bacteria. The sequence diversity of the integrase genes in these clones was sufficient to classify them within three new classes of integron. Since they are derived from environments not associated with antibiotic use, integrons appear to be more prevalent in bacteria than previously observed.

Resolution of holliday junctions by RuvABC prevents dimer formation in rep mutants and UV-irradiated cells.

In this work, we present evidence that indicates that RuvABC proteins resolve Holliday junctions in a way that prevents dimer formation in vivo. First, although arrested replication forks are rescued by recombinational repair in cells deficient for the Rep helicase, rep mutants do not require the XerCD proteins or the dif site for viability. This shows that the recombination events at arrested replication forks are generally not accompanied by the formation of chromosome dimers. Secondly, resolution of dimers into monomers is essential in the rep ruv strain because of an increased frequency of RecFOR recombination events in the chromosome of this mutant. This suggests that, in the absence of the Ruv proteins, chromosomal recombination leads to frequent dimerization. Thirdly, dif or xerC mutations increase the UV sensitivity of ruv-deficient cells 100-fold, whereas they do not confer UV sensitivity to ruv+ cells. This shows that recombinational repair of UV lesions is not accompanied by dimer formation provided that the RuvABC proteins are active. The requirement for dimer resolution in ruv strains is suppressed by the expression of the RusA Holliday junction resolvase; therefore, RusA also prevents dimer formation. We conclude that the inviability arising from a high frequency of dimer formation in rep or UV-irradiated cells is only observed in the absence of known enzymes that resolve Holliday junctions.

FtsK-dependent and -independent pathways of Xer site-specific recombination.

Homologous recombination between circular chromosomes generates dimers that cannot be segregated at cell division. Escherichia coli Xer site-specific recombination converts chromosomal and plasmid dimers to monomers. Two recombinases, XerC and XerD, act at the E. coli chromosomal recombination site, dif, and at related sites in plasmids. We demonstrate that Xer recombination at plasmid dif sites occurs efficiently only when FtsK is present and under conditions that allow chromosomal dimer formation, whereas recombination at the plasmid sites cer and psi is independent of these factors. We propose that the chromosome dimer- and FtsK-dependent process that activates Xer recombination at plasmid dif also activates Xer recombination at chromosomal dif. The defects in chromosome segregation that result from mutation of the FtsK C-terminus are attributable to the failure of Xer recombination to resolve chromosome dimers to monomers. Conditions that lead to FtsK-independent Xer recombination support the hypothesis that FtsK acts on Holliday junction Xer recombination intermediates.

Mobile gene cassettes and integrons in evolution.

Integrons and the site-specific recombination systems encoded by them provide a simple mechanism for the addition of new genes to bacterial chromosomes. Although there is substantial divergence among the four known integron-encoded integrases, they all recognize the recombination sites, known as 59-base elements, that are associated with genes that are packaged in gene cassettes. In contrast, the integron-associated recombination sites, attl sites, are preferentially recognized by the cognate integrase.

Origins of the mobile gene cassettes found in integrons.

Many of the acquired antibiotic resistance genes found in enterobacteria and pseudomonads are part of small mobile elements known as gene cassettes, and other genes are also likely to be found in cassettes. The origins of the genes and the recombination sites that make up cassettes are not known, but recent analyses of available data suggest that cassettes may be ancient structures, and some hypotheses for how they are formed can now be examined.

Structure and function of 59-base element recombination sites associated with mobile gene cassettes.

The integration of gene cassettes into integrons is effected by site-specific recombination catalysed by an integrase, IntI, encoded by the integron. The cassette-associated recombination sites, 59-base elements, are not highly conserved and vary in length from 57 to 141 bp. They can be identified by their location and the relationship of over 20 bp at their outer ends to consensus sequences that are imperfect inverted repeats of one another. The recombination cross-over occurs close to one end of the 59-base element, within a conserved core site with the consensus sequence GTTAGGC or GTTRRRY. By introducing single-base changes at each of these positions in the aadB 59-base element, bases that are critical for site activity were identified. The recombination cross-over was also localized to a unique position between the adjacent G and T residues. Changes introduced in the conserved AAC of the inverse core site (GCCTAAC or RYYYAAC) located at the opposite end of the 59-base element also reduced site activity but to a lesser extent. Sequences of rare recombinants revealed an alternative position for strand exchange and led to the conclusion that 59-base elements comprise two simple sites, analogous to those recognized by other integrases, with each simple site made up of a pair of inversely oriented IntI binding domains separated by a spacer of 7 or 8 bp. Re-examination of the sequences of all known 59-base elements revealed that this simple site configuration was present at both the left and right ends in all 59-base elements. The identity of bases in the spacer is not required for efficient recombination and the cross-over is located at one end of the spacer, suggesting that during IntI1-mediated recombination only one strand exchange occurs.

Plasmid evolution by acquisition of mobile gene cassettes: plasmid pIE723 contains the aadB gene cassette precisely inserted at a secondary site in the incQ plasmid RSF1010.

Gene cassettes are mobile DNA elements which contain a specific recombination site, a 59-base element, recognized by the site-specific recombination system of integrons. Gene cassettes are normally found inserted at a unique site in an integron, downstream of a promoter which directs transcription of the cassette-associated genes. However, insertion of a gene cassette into a secondary site in a plasmid which does not contain an integron is also formally possible. Sequence analysis of the aadB gene in pIE723, a plasmid closely related to the IncQ plasmid RSF1010, revealed the presence of the complete aadB cassette inserted at a secondary site downstream of a known RSF1010 promoter. The site of insertion of the aadB cassette in RSF1010 conformed to the consensus for secondary sites recognized by the integron integrase (Int), and it is likely that the cassette was inserted via a single Int-mediated recombination event between the 59-base element of a free, circular aadB cassette and a secondary site in RSF1010. The cassette-associated recombination site was inactivated by the insertion, and Int-mediated excision of the aadB cassette from this non-specific location was not detectable, indicating that the cassette is stably inserted. The movement of gene cassettes to secondary sites is likely to play an important role in the acquisition of new genes by bacterial and plasmid genomes.

Characterisation of specific and secondary recombination sites recognised by the integron DNA integrase.

Integrons determine a site-specific recombination system which is responsible for the acquisition of genes, particularly antibiotic resistance genes. The integrase encoded by integrons recognises two distinct classes of recombination sites. The first is the family of imperfect inverted repeats, known as 59-base elements, which are associated with the mobile gene cassettes. The second consists of a single site into which the cassettes are inserted. This site, here designated attI, is located adjacent to the int gene in the recipient integron structure. The attI site has none of the recognisable features of members of the 59-base element family except for a seven-base core site, GTTRRRY, at the recombination crossover point. Using a conduction assay to quantitate site activity, the sequence required for maximal attI site activity was confined to a region of > 39 and < or = 70 bases. Both integrative and excisive site-specific recombination events involving attI and a 59-base element site were demonstrated, but no evidence for events involving two attI sites was obtained. Integrase-mediated recombination between a 59-base element and several secondary sites in pACYC184 with the consensus GNT occurred at low frequency, and such events could potentially lead to insertion of gene cassettes at many non-specific sites.