The IntI1 Integron Integrase Preferentially Binds Single-Stranded DNA of the attC Site

IntI1 integrase is a member of the prokaryotic DNA integrase superfamily. It is responsible for mobility of antibiotic resistance cassettes found in integrons. IntI1 protein, as well as IntI1-COOH, a truncated form containing its carboxy-terminal domain, has been purified. Electrophoretic mobility shift assays were carried out to study the ability of IntI1 to bind the integrase primary target sites attI and aadA1 attC. When using double-stranded DNA as a substrate, we observed IntI1 binding to attI but not to attC. IntI1-COOH did not bind either attI or attC, indicating that the N-terminal domain of IntI1 was required for binding to double-stranded attI. On the other hand, when we used single-stranded (ss) DNA substrates, IntI1 bound strongly and specifically to ss attC DNA. Binding was strand specific, since only the bottom DNA strand was bound. Protein IntI1-COOH bound ss attC as well as did the complete integrase, indicating that the ability of the protein to bind ss aadA1 attC was contained in the region between amino acids 109 and 337 of IntI1. Binding to ss attI DNA by the integrase, but not by IntI1-COOH, was also observed and was specific for the attI bottom strand, indicating similar capabilities of IntI1 for binding attI DNA in either double-stranded or ss conformation. Footprinting analysis showed that IntI1 protected at least 40 bases of aadA1 attC against DNase I attack. The protected sequence contained two of the four previously proposed IntI1 DNA binding sites, including the crossover site. Preferential ssDNA binding can be a significant activity of IntI1 integrase, which suggests the utilization of extruded cruciforms in the reaction mechanisms leading to cassette excision and integration.     

Integron cassette insertion: a recombination process involving a folded single strand substrate

Integrons play a major role in the dissemination of antibiotic resistance genes among Gram-negative pathogens. Integron gene cassettes form circular intermediates carrying a recombination site, attC, and insert into an integron platform at a second site, attI, in a reaction catalyzed by an integron-specific integrase IntI. The IntI1 integron integrase preferentially binds to the 'bottom strand' of single-stranded attC. We have addressed the insertion mechanism in vivo using a recombination assay exploiting plasmid conjugation to exclusively deliver either the top or bottom strand of different integrase recombination substrates. Recombination of a single-stranded attC site with an attI site was 1000-fold higher for one strand than for the other. Conversely, following conjugative transfer of either attI strand, recombination with attC is highly unfavorable. These results and those obtained using mutations within a putative attC stem-and-loop strongly support a novel integron cassette insertion model in which the single bottom attC strand adopts a folded structure generating a double strand recombination site. Thus, recombination would insert a single strand cassette, which must be subsequently processed.     

A new in vitro strand transfer assay for monitoring bacterial class 1 integron recombinase IntI1 activity

IntI1 integrase is a tyrosine recombinase involved in the mobility of antibiotic resistance gene cassettes within bacterial class 1 integrons. Recent data have shown that its recombination specifically involves the bottom strand of the attC site, but the exact mechanism of the reaction is still unclear. An efficient in vitro assay is still required to better characterize the biochemical properties of the enzyme. In this report we describe for the first time an in vitro system partially reproducing the activity of a recombinant pure IntI1. This new assay, which constitutes the only available in vitro model of recombination by IntI1, was used to determine whether this enzyme might be the sole bacterial protein required for the recombination process. Results show that IntI1 possesses all the features needed for performing recombination between attI and attC sites. However, differences in the in vitro intermolecular recombination efficiencies were found according to the target sites and were correlated with DNA affinities of the enzyme but not with in vivo data. The differential affinity of the enzyme for each site, its capacity to bind to a single-stranded structure at the attC site and the recombination observed with single-stranded substrates unambiguously confirm that it constitutes an important intermediary in the reaction. Our data strongly suggest that the enzyme possesses all the functions for generating and/or recognizing this structure even in the absence of other cellular factors. Furthermore, the in vitro assay reported here constitutes a powerful tool for the analysis of the recombination steps catalyzed by IntI1, its structure-function studies and the search for specific inhibitors.     

DNA complexes obtained with the integron integrase IntI1 at the attI1 site.

Integrons are genetic elements that are able to capture genes by a site-specific recombination mechanism. Integrons contain a gene coding for a lambda-like integrase that carries out site-specific recombination by interacting with two different target sites; the attI site and the palindromic sequence attC (59 base element). Cassette integrations usually involve the attI site, while cassette excisions use attC . Therefore, the integrase should bind both sites to cleave DNA and perform site-specific recombination reactions. We have used purified maltose-binding protein fused with the integrase (MBP-IntI1) and native IntI1 protein and gel retardation assays with fragments containing the complete and partial attI1 site to show formation of four complexes in this region. Chemical modification of specific nucleotides within the attI1 site was used to investigate their interference with binding of the integrase protein. We attribute IntI1 specific binding to four regions in the attI1 site and a GTTA consensus sequence is found in three of the four regions. Interference by modified guanine and thymine residues in the DNA major groove and adenine residues in the minor groove were observed, indicating that the integrase interacts with both sides of the helix. Binding of IntI1 to attC is also discussed.     

Non-palindromic attI sites of integrons are capable of site-specific recombination with one another and with secondary targets

Genes borne on cassettes are mobile owing to site-specific recombination systems called integrons, which have created various combinations of antibiotic resistance genes in R-plasmids. In these processes, the palindromic site, attC (59-base element), at cassette junctions has been proposed as being essential. Excised and circularized cassettes have been found to integrate with preference for an attI site at one end of the conserved sequence in integrons. In this work, we give evidence that recombination is possible in the absence of the highly organized attC sites between the more simply organized attI sites. Furthermore, at a very low frequency representing the background in our recombination assay, we observed cross-overs between attI and secondary sites. To characterize recombination excluding the attC sites, we have used naturally occurring attI variants and constructed mutants. The cross-over point was identified between a guanine and a thymine in attI using point mutations. Progressive deletions showed the extent of attI and identified two important regions in the conserved sequence 5' of the cross-over point. A region 27–36 bp 5' of attI influenced recombination with attC sites only, whereas a sequence 9–14 bp 5' of the cross-over point in attI was important for recombination with both attI and attC . Recombination between attI and secondary sites could allow fusion of the conserved sequence encoding the integron site-specific recombinase to new sequences.     

Suicide recombination substrates yield covalent lambda integrase-DNA complexes and lead to identification of the active site tyrosine

High levels of covalent integrase-DNA complexes accumulate when suicide substrates containing a medial nick within the overlap region are nicked by lambda integrase protein. The tyrosine residue at position 342 is shown to form a covalent bond with DNA at the sites of strand exchange. A mutant integrase in which this tyrosine is changed to phenylalanine is devoid of both topoisomerase and recombinase activity but still binds to both core- and arm-type DNA binding sites with an affinity comparable to wild-type integrase. Tyrosine-342 is located within a 40-amino acid region that is conserved among 15 known recombinases comprising the "integrase family." The present results show that this small region of homology participates in catalysis of strand transfer.     

The IntI-like tyrosine recombinase of Shewanella oneidensis is active as an integron integrase

We have found an integron-like integrase gene and an attI site in Shewanella oneidensis as part of a small chromosomal integron. We have cloned this gene and tested the ability of the integrase to excise cassettes from various integrons. Most cassettes flanked by two attC sites are readily excised, while cassettes in the "first" position, with an attI1 or attI3 site on one end, are not excised. An exception is a cassette with attI2 on one end. The attI2 site, from Tn7, has greater similarity to the attI site adjacent to the integrase of S. oneidensis than do attI1 or attI3. We cloned the attI site of S. oneidensis and observed the integration of two different cassettes. We have, therefore, demonstrated the function of this integron-like integrase.     

Ligation activity of FLP recombinase. The strand ligation activity of a site-specific recombinase using an activated DNA substrate.

The FLP protein of the 2-microns plasmid of yeast belongs to the integrase family of site-specific recombinases whose members form a covalent bond between a conserved tyrosine of the recombinase and the 3'-phosphoryl group at the site of cleavage. We have made an activated DNA substrate and have shown that FLP can promote efficient strand ligation without forming a covalent intermediate with the DNA substrate. The strand ligation activity of FLP is independent of its ability to cleave DNA. Since site-specific recombinases are members of the larger class of topoisomerases, these findings may be generally applicable to other members of this class of enzymes.     

Integrons and gene cassettes: hotspots of diversity in bacterial genomes

Integrons are genetic units found in many bacterial species that are defined by their ability to capture small mobile elements called gene cassettes. Cassettes usually contain only one gene, potentially any gene, and an attC recombination site, and thousands of cassettes have been sequenced. A specialized IntI site-specific recombinase encoded by the integron recognizes attC and incorporates cassettes into an attI site located adjacent to the intI gene. Over 100 types of integrons have been found, most in bacterial chromosomes. They can all potentially share the same cassettes and, as recombination between attC in a cassette and an attI can occur repeatedly, an integron can contain from zero to hundreds of cassettes. Cassette arrays that are not located next to an intI gene, or solo cassettes at apparently random sites, are also seen. Hence, integrons contribute to generation of diversity in bacterial, plasmid, and transposon genomes and facilitate extensive sharing of information among bacteria.     

Xer site-specific recombination in vitro.

Two related recombinases, XerC and XerD, belonging to the lambda integrase family of enzymes, are required for Xer site-specific recombination in vivo. In order to understand the roles of these proteins in the overall reaction mechanism, an in vitro recombination system using a synthetic Holliday junction-containing substrate has been developed. Recombination of this substrate is efficient and requires both XerC and XerD. However, only exchange of one pair of strands, the one corresponding to the conversion of the Holliday junction intermediate back to the substrate, has been observed. Recombination reactions using XerC and XerD derivatives that are mutant in their presumptive catalytic residues, or are maltose-binding fusion recombinase derivatives, have demonstrated that this pair of strand exchanges is catalysed by XerC. The site of XerC-mediated cleavage has been located to between the last nucleotide of the XerC binding site and the first nucleotide of the central region. Cleavage at this site generates a free 5'-OH and a covalent complex between XerC and the 3' end of the DNA.     

Complementation of bacteriophage lambda integrase mutants: evidence for an intersubunit active site.

Site-specific recombination of bacteriophage lambda starts with the formation of higher-order protein--DNA complexes, called 'intasomes', and is followed by a series of steps, including the initial DNA cleavage, top-strand exchange, branch migration and bottom-strand exchange, to produce recombinant products. One of the intasomes formed during excisive recombination (the attL complex) is composed of the phage-encoded integrase (Int), integration host factor (IHF) and one of the recombination substrates, attL DNA. Int is the catalytic recombinase and has two different DNA binding domains. When IHF is present, Int binds to two types of sites in attL DNA, the three arm-type sites (P'123) and the core-type sites (B and C') where the reciprocal strand exchange takes place. The Tyr342 residue of Int serves as a nucleophile during strand cleavage and covalently attaches to the DNA through a phosphotyrosyl bond. In vitro complementation assays have been performed for strand cleavage using attL suicide substrates and mutant proteins containing amino acid substitutions at residues conserved in the integrase family of recombinases. We demonstrate that at least two Int monomers are required to form the catalytically-competent species that performs cleavage at the B site. It is likely that the active site is formed by two Int monomers.     

Half-att site substrates reveal the homology independence and minimal protein requirements for productive synapsis in lambda excisive recombination

The early events in site-specific excisive recombination were studied with phage lambda half-att sites that have no DNA to one side of the strand exchange region; they carry a single core-type integrase binding site and either P or P' arm flanking DNA. These half-attR and half-attL sites exhibit normal properties for the initial (covalent) top-strand transfer and form stable intermediates independent of later steps in the reaction. With these novel substrates we show that Xis specifically promotes the first strand exchange and that attL enhances Int cleavage at the top-strand site of attR. It is also shown that synapsis and initial strand transfers do not require DNA-DNA pairing but are mediated by protein-protein and protein-DNA interactions. These involve the two top-strand Int binding sites (required for the first strand exchange) and, in addition, one of the two bottom-strand sites (C') responsible for the second strand exchange.     

The efficiency of mispaired ligations by lambda integrase is extremely sensitive to context

The integrase protein (Int) of phage lambda is a well-studied representative of the tyrosine recombinase family, whose defining features are two sequential pairs of DNA cleavage/ligation reactions that proceed via a 3' phosphotyrosine covalent intermediate to first form and then resolve a Holliday junction recombination intermediate. We devised an assay that takes advantage of DNA hairpin formation at one Int target site to trap Int cleavages at a different target site, and thereby reveal iterative cycles of cleavage and ligation that would otherwise be undetected. Using this assay and others to compare wild-type Int and a mutant (R169D) defective in forming proper dimer/tetramer interfaces, we found that the efficiency of "bottom-strand" DNA cleavage by wild-type Int, but not R169D, is very sensitive to the base-pair at the "top-strand" cleavage site, seven base-pairs away. We show that this is related to the finding that hairpin formation involving ligation of a mispaired base is much faster for R169D than for wild-type Int, but only in the context of a multimeric complex. During resolution of Holliday junction recombination intermediates, wild-type Int, but not R169D, is very sensitive to homology at the sites of ligation. A long-sought insight from these results is that during Holliday junction resolution the tetrameric Int complex remains intact until after ligation of the product helices has been completed. This contrasts with models in which the second pair of DNA cleavages is a trigger for dissolution of the recombination complex.     

The minute virus of mice capsid specifically recognizes the 3' hairpin structure of the viral replicative-form DNA: mapping of the binding site by hydroxyl radical footprinting.

The terminal hairpin structures of the DNA of minute virus of mice (MVM) are essential for viral replication. Here we show that the hairpin 3' terminus of MVM replicative-form DNA binds specifically to empty MVM capsids. Binding of the same terminal DNA sequence in its linear double-stranded (extended) conformation was not observed. After heat denaturation and quick cooling of 3'-terminal extended-form fragments, not only the virion strand but also the complementary strand was found to bind to the capsid, presumably because each strand re-formed a similar hairpin structure. No binding affinity for the capsid was found to be associated with hairpin or extended 5' termini or with any other region of the viral DNA. Hydroxyl radical footprinting analyses revealed three protected nucleotide stretches forming a binding site at the branch point of the two 3'-terminal hairpin arms looping out from the DNA stem (T structure). Single base changes within this site did not affect the binding. In band shift experiments, specific binding to the T structure was demonstrated for VPI but not for VP2.     

Substrate features important for recognition and catalysis by human immunodeficiency virus type 1 integrase identified by using novel DNA substrates.

The integrase encoded by human immunodeficiency virus type 1 (HIV-1) is required for integration of viral DNA into the host cell chromosome. In vitro, integrase mediates a concerted cleavage-ligation reaction (strand transfer) that results in covalent attachment of viral DNA to target DNA. With a substrate that mimics the strand transfer product, integrase carries out disintegration, the reverse of the strand transfer reaction, resolving this integration intermediate into its viral and target DNA parts. We used a set of disintegration substrates to study the catalytic mechanism of HIV-1 integrase and the interaction between the protein and the viral and target DNA sequence. One substrate termed dumbbell consists of a single oligonucleotide that can fold to form a structure that mimics the integration intermediate. Kinetic analysis using the dumbbell substrate showed that integrase turned over, establishing that HIV-1 integrase is an enzyme. Analysis of the disintegration activity on the dumbbell substrate and its derivatives showed that both the viral and target DNA parts of the molecule were required for integrase recognition. Integrase recognized target DNA asymmetrically: the target DNA upstream of the viral DNA joining site played a much more important role than the downstream target DNA in protein-DNA interaction. The site of transesterification was determined by both the DNA sequence of the viral DNA end and the structure of the branched substrate. Using a series of disintegration substrates with various base modifications, we found that integrase had relaxed structural specificity for the hydroxyl group used in transesterification and could tolerate distortion of the double-helical structure of these DNA substrates.     

Nicked-site substrates for a serine recombinase reveal enzyme–DNA communications and an essential tethering role of covalent enzyme–DNA linkages

To analyse the mechanism and kinetics of DNA strand cleavages catalysed by the serine recombinase Tn3 resolvase, we made modified recombination sites with a single-strand nick in one of the two DNA strands. Resolvase acting on these sites cleaves the intact strand very rapidly, giving an abnormal half-site product which accumulates. We propose that these reactions mimic second-strand cleavage of an unmodified site. Cleavage occurs in a synapse of two sites, held together by a resolvase tetramer; cleavage at one site stimulates cleavage at the partner site. After cleavage of a nicked-site substrate, the half-site that is not covalently linked to a resolvase subunit dissociates rapidly from the synapse, destabilizing the entire complex. The covalent resolvase–DNA linkages in the natural reaction intermediate thus perform an essential DNA-tethering function. Chemical modifications of a nicked-site substrate at the positions of the scissile phosphodiesters result in abolition or inhibition of resolvase-mediated cleavage and effects on resolvase binding and synapsis, providing insight into the serine recombinase catalytic mechanism and how resolvase interacts with the substrate DNA.     

Comparative study of class 1 integron and Vibrio cholerae superintegron integrase activities

Superintegrons (SIs) and multiresistant integrons (MRIs) have two main structural differences: (i) the SI platform is sedentary, while the MRI platform is commonly associated with mobile DNA elements and (ii) the recombination sites (attC) of SI gene cassette clusters are highly homogeneous, while those of MRI cassette arrays are highly variable in length and sequence. In order to determine if the latter difference was correlated with a dissimilarity in the recombination activities, we conducted a comparative study of the integron integrases of the class 1 MRI (IntI1) and the Vibrio cholerae SI (VchIntIA). We developed two assays that allowed us to independently measure the frequencies of cassette deletion and integration at the cognate attI sites. We demonstrated that the range of attC sites efficiently recombined by VchIntIA is narrower than the range of attC sites efficiently recombined by IntI1. Introduction of mutations into the V. cholerae repeats (VCRs), the attC sites of the V. cholerae SI cassettes, allowed us to map positions that affected the VchIntIA and IntI1 activities to different extents. Using a cointegration assay, we established that in E. coli, attI1-x-VCR recombination catalyzed by IntI1 was 2,600-fold more efficient than attIVch-x-VCR recombination catalyzed by VchIntIA. We performed the same experiments in V. cholerae and established that the attIVch-x-VCR recombination catalyzed by VchIntIA was 2,000-fold greater than the recombination measured in E. coli. Taken together, our results indicate that in the V. cholerae SI, the substrate recognition and recombination reactions mediated by VchIntIA might differ from the class 1 MRI paradigm.     

Asymmetry in Flp-mediated cleavage.

Flp is a member of the integrase family of site-specific recombinases. Members of the integrase family mediate DNA strand cleavage via a transesterification reaction involving an active site tyrosine residue. The first step of the reaction results in covalent linkage of the protein to the 3'-phosphoryl DNA terminus, leaving a 5'-hydroxyl group at the site of the nick. We have used Flp recognition target (FRT) sites containing a 5'-bridging phosphorothioate linkage at the site of Flp cleavage to accumulate intermediates in which Flp is covalently bound at a cleavage site. We have probed these intermediates with dimethylsulfate using methylation protection and find that Flp-mediated cleavage is associated with protection of two adenine residues that are opposite the sites of cleavage and covalent attachment by Flp. Methylation interference studies showed that cleavage and covalent attachment are also accompanied by differences in the contacts of Flp with each of the two cleavage sites and with the surrounding symmetry elements. Therefore, we provide evidence that Flp-mediated cleavage and covalent attachment result in changes to the conformation of the Flp-FRT complex. These changes may be required for Flp-mediated strand exchange activity.     

DNA sequence selectivities in the covalent bonding of antibiotic saframycins Mx1, Mx3, A, and S deduced from MPE.Fe(II) footprinting and exonuclease III stop assays.

DNA sequence selectivities in the covalent binding of the antitumor antibiotic saframycins Mx1, Mx3, A, and S have been determined by complementary strand MPE.Fe(II) footprinting and exonuclease III stop assays on two different 545 and 135 base pair long HindIII/RsaI restriction fragments of pBR322 DNA. Saframycins Mx1, Mx3, A, and S recognize primarily 5'-GGG sequences. All four antibiotics also recognize 5'-GGPy sequences, however a cytosine is preferred over a thymine at the 3'-end of this recognition site in all cases. Saframycins Mx1, Mx3 and S, which possess the OH leaving group, also recognize the 5'-CCG sequence, in contrast to saframycin A, which contains the CN leaving group. In contrast, the OH-containing saframycins also recognize the 5'-CTA sequence. Saframycins Mx2, B and C, which lack the critical CN or OH leaving group, do not show any footprints on the restriction fragments examined in this study. The measured binding site size for all four antibiotics is three base pairs. The exonuclease III stop assay independently confirmed the formation of a covalent bond and the strong preference of the antibiotics for 5'-GGG and 5'-GCC sequences. The latter enzyme assay also suggests that the 5'-terminal or central G of the triad binding site is the base to which reversible covalent attachment of the antibiotic takes place.