Site-specific recombination in plane view

Flipping chromosomes in deep-sea archaea

One of the major mechanisms driving the evolution of all organisms is genomic rearrangement. In hyperthermophilic Archaea of the order Thermococcales, large chromosomal inversions occur so frequently that even closely related genomes are difficult to align. Clearly not resulting from the native homologous recombination machinery, the causative agent of these inversions has remained elusive. We present a model in which genomic inversions are catalyzed by the integrase enzyme encoded by a family of mobile genetic elements. We characterized the integrase from Thermococcus nautili plasmid pTN3 and showed that besides canonical site-specific reactions, it catalyzes low sequence specificity recombination reactions with the same outcome as homologous recombination events on DNA segments as short as 104bp both in vitro and in vivo, in contrast to other known tyrosine recombinases. Through serial culturing, we showed that the integrase-mediated divergence of T. nautili strains occurs at an astonishing rate, with at least four large-scale genomic inversions appearing within 60 generations. Our results and the ubiquitous distribution of pTN3-like integrated elements suggest that a major mechanism of evolution of an entire order of Archaea results from the activity of a selfish mobile genetic element.

Mobile elements (MEs) such as viruses, plasmids and transposons infect most living organisms and often encode recombinases promoting their insertion into cellular genomes. These insertions alter the genome of their host according to two main mechanisms. First, MEs provide new functions to the cell by integrating their own genetic information into the DNA of the host, at one or more locations. Secondly, cellular homologous recombination will act upon multiple integrated copies and produce a variety of large-scale chromosomal rearrangements. If such modifications are advantageous, they will spread into the population by natural selection. Typically, enzymes involved in cellular homologous recombination and the integration of MEs are distinct. We describe here a novel plasmid-encoded archaeal integrase which in addition to site-specific recombination can catalyze low sequence specificity recombination reactions akin to homologous recombination.

Nucleases: diversity of structure, function and mechanism

Nucleases cleave the phosphodiester bonds of nucleic acids and may be endo or exo, DNase or RNase, topoisomerases, recombinases, ribozymes, or RNA splicing enzymes. In this review, I survey nuclease activities with known structures and catalytic machinery and classify them by reaction mechanism and metal-ion dependence and by their biological function ranging from DNA replication, recombination, repair, RNA maturation, processing, interference, to defense, nutrient regeneration or cell death. Several general principles emerge from this analysis. There is little correlation between catalytic mechanism and biological function. A single catalytic mechanism can be adapted in a variety of reactions and biological pathways. Conversely, a single biological process can often be accomplished by multiple tertiary and quaternary folds and by more than one catalytic mechanism. Two-metal-ion-dependent nucleases comprise the largest number of different tertiary folds and mediate the most diverse set of biological functions. Metal-ion-dependent cleavage is exclusively associated with exonucleases producing mononucleotides and endonucleases that cleave double- or single-stranded substrates in helical and base-stacked conformations. All metal-ion-independent RNases generate 2',3'-cyclic phosphate products, and all metal-ion-independent DNases form phospho-protein intermediates. I also find several previously unnoted relationships between different nucleases and shared catalytic configurations.

Mutagenesis and homology modeling of the Tn21 integron integrase IntI1

Horizontal DNA transfer between bacteria is widespread and a major cause of antibiotic resistance. For logistic reasons, single or combined genes are shuttled between vectors such as plasmids and bacterial chromosomes. Special elements termed integrons operate in such shuttling and are therefore vital for horizontal gene transfer. Shorter elements carrying genes, cassettes, are integrated in the integrons, or excised from them, by virtue of a recombination site, attC, positioned in the 3' end of each unit. It is a remarkable and possibly restricting elementary feature of attC that it must be single-stranded while the partner target site, attI, may be double-stranded. The integron integrases belong to the tyrosine recombinase family, and this work reports mutations of the integrase IntI1 from transposon Tn21, chosen within a well-conserved region characteristic of the integron integrases. The mutated proteins were tested for binding to a bottom strand of an attC substrate, by using an electrophoresis mobility shift assay. To aid in interpreting the results, a homology model was constructed on the basis of the crystal structure of integron integrase VchIntIA from Vibrio cholerae bound to its cognate attC substrate VCRbs. The local stability and hydrogen bonding network of key domains of the modeled structure were further examined using molecular dynamics simulations. The homology model allowed us to interpret the roles of several amino acid residues, four of which were clearly binding assay responsive upon mutagenesis. Notably, we also observed features indicating that IntI1 may be more prone to base-specific contacts with VCRbs than VchIntIA.

Structure-function analysis of IntDOT

CTnDOT integrase (IntDOT) is a member of the tyrosine family of site-specific DNA recombinases. IntDOT is unusual in that it catalyzes recombination between nonidentical sequences. Previous mutational analyses centered on mutants with substitutions of conserved residues in the catalytic (CAT) domain or residues predicted by homology modeling to be close to DNA in the core-binding (CB) domain. That work suggested that a conserved active-site residue (Arg I) of the CAT domain is missing and that some residues in the CB domain are involved in catalysis. Here we used a genetic approach and constructed an Escherichia coli indicator strain to screen for random mutations in IntDOT that disrupt integrative recombination in vivo. Twenty-five IntDOT mutants were isolated and characterized for DNA binding, DNA cleavage, and DNA ligation activities. We found that mutants with substitutions in the amino-terminal (N) domain were catalytically active but defective in forming nucleoprotein complexes, suggesting that they have altered protein-protein interactions or altered interactions with DNA. Replacement of Ala-352 of the CAT domain disrupted DNA cleavage but not DNA ligation, suggesting that Ala-352 may be important for positioning the catalytic tyrosine (Tyr-381) during cleavage. Interestingly, our biochemical data and homology modeling of the CAT domain suggest that Arg-285 is the missing Arg I residue of IntDOT. The predicted position of Arg-285 shows it entering the active site from a position on the polypeptide backbone that is not utilized in other tyrosine recombinases. IntDOT may therefore employ a novel active-site architecture to catalyze recombination.

Characterization of the Micromonospora rosaria pMR2 plasmid and development of a high G+C codon optimized integrase for site-specific integration

pMR2, an 11.1 kb plasmid was isolated from Micromonospora rosaria SCC2095, NRRL3718, and its complete nucleotide sequence determined. Analysis revealed 13 ORFs including homologs of a KorSA regulatory protein and TraB plasmid transfer protein found on other actinomycete plasmids. pMR2 contains att/int functions consisting of an integrase, an excisionase, and a putative plasmid attachment site (attP). The integrase gene contained a high frequency of codons rarely used in high G+C actinomycete coding regions. The gene was codon optimized for actinomycete codon usage to create the synthetic gene int-OPT. pSPRX740, containing an rpsL promoter and the att/int-OPT region, was introduced into Micromonospora halophytica var. nigra ATCC33088. Analysis of DNA flanking the pSPRX740 integration site confirmed site-specific integration into a tRNA(Phe) gene in the M. halopytica var. nigra chromosome. The pMR2 attP element and chromosomal attachment (attB) site contain a 63 bp region of sequence identity overlapping the 3' end of the tRNA(Phe) gene. Plasmids comprising the site-specific att/int-OPT functions of pMR2 can be used to integrate genes into the chromosome of actinomycetes with an appropriate tRNA gene. The development of an integrative system for Micromonospora will expand our ability to study antibiotic biosynthesis in this important actinomycete genus.

Comparison of the structure–activity relationships of the integron-associated recombination sites attI3 and attI1 reveals common features

Incorporation of gene cassettes into integrons occurs by IntI-mediated site-specific recombination between a 59-base element (59-be) site in the cassette and an attI site in the integron. While the 59-be sites share common features and are recognized by several different IntI recombinases, the sequences of attI sites are not obviously related and are preferentially recognized by the cognate IntI. To determine the features of attI sites that are required for recombination proficiency, the structure–activity relationships of a second attI site, the attI3 site from the class 3 integron, were examined. The attI3 site was confined to within a region consisting of 68 bp from the integron backbone and 15 bp from the adjacent cassette. This region includes four IntI3-binding sites, as assessed by gel shift and methylation interference studies. Two of the binding sites are inversely oriented and constitute a simple site that includes the recombination crossover point. The two additional binding sites appear to be directly oriented and one of them is essential for efficient recombination of the attI3 site with a 59-be, but not for recombination with a second full-length attI3 site, which occurs at 100-fold lower frequency. The fourth site enhances attI3 with 59-be recombination 10-fold. The finding that the organization and overall properties of attI3 are very similar to those of attI1 indicates that these features are likely to be common to all attI sites.

Development of the Micromonospora carbonacea var. africana ATCC 39149 bacteriophage pMLP1 integrase for site-specific integration in Micromonospora spp

Micromonospora carbonacea var. africana ATCC 39149 contains a temperate bacteriophage, pMLP1, that is present both as a replicative element and integrated into the chromosome. Sequence analysis of a 4.4 kb KpnI fragment revealed pMLP1 att/int functions consisting of an integrase, an excisionase and the phage attachment site (attP). Plasmids pSPRH840 and pSPRH910, containing the pMLP1 att/int region, were introduced into Micromonospora spp. by conjugation from Escherichia coli. Sequence analysis of DNA flanking the integration site confirmed site-specific integration into a tRNAHis gene in the chromosome. The pMLP1 attP element and chromosomal bacterial attachment (attB) site contain a 24 bp region of sequence identity located at the 3' end of the tRNA. Integration of pMLP1-based plasmids in M. carbonacea var. africana caused a loss of the pMLP1 phage. Placement of an additional attB site into the chromosome allowed integration of pSPRH840 into the alternate attB site. Plasmids containing the site-specific att/int functions of pMLP1 can be used to integrate genes into the chromosome.

Conservation of structure and function among tyrosine recombinases: homology-based modeling of the lambda integrase core-binding domain

Tyrosine recombinases participate in diverse biological processes by catalyzing recombination between specific DNA sites. Although a conserved protein fold has been described for the catalytic (CAT) domains of five recombinases, structural relationships between their core-binding (CB) domains remain unclear. Despite differences in the specificity and affinity of core-type DNA recognition, a conserved binding mechanism is suggested by the shared two-domain motif in crystal structure models of the recombinases Cre, XerD and Flp. We have found additional evidence for conservation of the CB domain fold. Comparison of XerD and Cre crystal structures showed that their CB domains are closely related; the three central alpha-helices of these domains are superposable to within 1.44 A. A structure-based multiple sequence alignment containing 25 diverse CB domain sequences provided evidence for widespread conservation of both structural and functional elements in this fold. Based upon the Cre and XerD crystal structures, we employed homology modeling to construct a three-dimensional structure for the lambda integrase CB domain. The model provides a conceptual framework within which many previously identified, functionally important amino acid residues were investigated. In addition, the model predicts new residues that may participate in core-type DNA binding or dimerization, thereby providing hypotheses for future genetic and biochemical experiments.

Regulation of site-specific recombination by the C-terminus of lambda integrase

Site-specific recombination catalyzed by bacteriophage lambda integrase (Int) is essential for establishment and termination of the viral lysogenic life cycle. Int is the archetype of the tyrosine recombinase family whose members are responsible for DNA rearrangement in prokaryotes, eukaryotes and viruses. The mechanism regulating catalytic activity during recombination is incompletely understood. Studies of tyrosine recombinases bound to their target substrates suggest that the C-termini of the proteins are involved in protein-protein contacts that control the timing of DNA cleavage events during recombination. We investigated an Int truncation mutant (W350) that possesses enhanced topoisomerase activity but greater than 100-fold reduced recombination activity. Alanine scanning mutagenesis of the C-terminus indicates that two mutants, W350A and I353A, cannot perform site-specific recombination although their DNA binding, cleavage and ligation activities are at wild-type levels. Two other mutants, R346A and R348A, are deficient solely in the ability to cleave DNA. To explain these results, we have constructed a homology-threaded model of the Int structure using a Cre crystal structure. We propose that residues R346 and R348 are involved in orientation of the catalytic tyrosine that cleaves DNA, whereas W350 and I353 control and make intermolecular contacts with other Int proteins in the higher order recombination structures known as intasomes. These results suggest that Int and the other tyrosine recombinases have evolved regulatory contacts that coordinate site-specific recombination at the C-terminus.

Integron-encoded IntI integrases preferentially recognize the adjacent cognate attI site in recombination with a 59-be site

Integrons have the capacity to capture small mobile elements known as gene cassettes, and this reaction is catalysed by integron-encoded IntI integrases. IntI integrases form a distinct family within the tyrosine recombinase superfamily and include a characteristic additional domain that is well conserved. Two different IntI enzymes were used to examine their ability to recognize heterologous attI sites in both integration and excision assays. IntI1 and IntI3 are 59% identical and catalyse both integrative and excisive recombination between a cassette-associated 59-be site and the cognate attI1 or attI3 site. Integrative recombination events involving a 59-be and a non-cognate attI site, attI2 and attI3 for IntI1 or attI1 and attI2 for IntI3, were detected extremely rarely. In cassette excision assays, the non-cognate attI3 site was recognized by IntI1, but attI1 was not well recognized by IntI3. The purified IntI1 and IntI3 proteins bound strongly only to their cognate attI site.

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.

Characterization and evidence of mobilization of the LEE pathogenicity island of rabbit-specific strains of enteropathogenic Escherichia coli

We have characterized the LEE pathogenicity islands (PAIs) of two rabbit-specific strains of enteropathogenic E. coli (REPEC), 83/39 (serotype O15:H-) and 84/110-1 (O103:H2), and have compared them to homologous loci from the human enteropathogenic and enterohaemorrhagic E. coli strains, E2348/69 and EDL933, and another REPEC strain, RDEC-1. All five PAIs contain a 34 kb core region that is highly conserved in gene order and nucleotide sequence. However, the LEE of 83/39 is significantly larger (59 540 basepairs) than those of the human strains, which are less than 44 kb, and has inserted into pheU tRNA. The regions flanking the 34 kb core of 83/39 contain homologues of two putative virulence determinants, efa1/lifA and senA. The LEE of 84/110-1 is approximately 85 kb and is located at pheV tRNA. Its core is almost identical to those of 83/39 and RDEC-1, apart from a larger espF gene, but its flanking regions contain trcA, a putative virulence determinant of EPEC. All three REPEC LEE PAIs contain a gene for an integrase, Int-phe. The LEE PAI of 84/110-1 is also flanked by short direct repeats (representing the 3'-end of pheV tRNA), suggesting that it may be unstable. To investigate this possibility, we constructed a LEE::sacB derivative of 84/110-1 and showed that the PAI was capable of spontaneous deletion. We also showed that Int-phe can mediate site-specific integration of foreign DNA at the pheU tRNA locus of E. coli DH1. Together these results indicate possible mechanisms of mobilization and integration of the LEE PAI.

The order of strand exchanges in Cre-LoxP recombination and its basis suggested by the crystal structure of a Cre-LoxP Holliday junction complex

Cre recombinase uses two pairs of sequential cleavage and religation reactions to exchange homologous DNA strands between 34 base-pair (bp) LoxP recognition sequences. In the oligomeric recombination complex, a switch between "cleaving" and "non-cleaving" subunit conformations regulates the number, order, and regio-specificity of the strand exchanges. However, the particular sequence of events has been in question. From analysis of strand composition of the Holliday junction (HJ) intermediate, we determined that Cre initiates recombination of LoxP by cleaving the upper strand on the left arm. Cre preferred to react with the left arm of a LoxP suicide substrate, but at a similar rate to the right arm, indicating that the first strand to be exchanged is selected prior to cleavage. We propose that during complex assembly the cleaving subunit preferentially associates with the LoxP left arm, directing the first strand exchange to that side. In addition, this biased assembly would enforce productive orientation of LoxP sites in the recombination synapses. A novel Cre-HJ complex structure in which LoxP was oriented with the left arm bound by the cleaving Cre subunit suggested a physical basis for the strand exchange order. Lys86 and Lys201 interact with the left arm scissile adenine base differently than in structures that have a scissile guanine. These interactions are associated with positioning the 198-208 loop, a structural component of the conformational switch, in a configuration that is specific to the cleaving conformation. Our results suggest that strand exchange order and site alignment are regulated by an "induced fit" mechanism in which the cleaving conformation is selectively stabilized through protein-DNA interactions with the scissile base on the strand that is cleaved first.

Sequence-specific and non-specific binding of the Rci protein to the asymmetric recombination sites of the R64 shufflon

Specific cleavages within the shufflon-specific recombination site of plasmid R64 were detected by primer extension when a DNA fragment carrying the recombination site was incubated with the shufflon-specific Rci recombinase. Rci-dependent cleavages occurred in the form of a 5' protruding 7 bp staggered cut, suggesting that DNA cleavage and rejoining in the shufflon system take place at these positions. As a result, shufflon crossover sites were designated as sfx sequences consisting of a central 7 bp spacer sequence, and left and right 12 bp arms. R64 sfx sequences are unique among various site-specific recombination sites, since only the spacer sequence and the right arm sequence are conserved among various R64 sfxs, whereas the left arm sequence is not conserved and is not related to the right arm sequence. From nuclease protection analyses, Rci protein was shown to bind to entire R64 and artificial sfx sequences, suggesting that one Rci molecule binds to the conserved sfx right arm in a sequence-specific manner and the second to the sfx left arm in a non-specific manner. The sfx left arm sequences as well as the right arm sequences were shown to determine affinity to Rci and subsequently inversion frequency. Asymmetry of the sfx sequence may be the reason why Rci protein acts only on the inverted sfx sequences.

Mobile elements as a combination of functional modules

Prokaryotic mobile elements have traditionally been classified as bacteriophages, plasmids, and transposons. We propose here a global classification of these and other bacterial and archaeal mobile elements based on their modular structure. This would allow for setting up interconnected databases where mobile elements could be stored as combinations of functional modules. Such a database would be very helpful. It would, for instance, allow for analyzing the phylogeny of individual blocks within an element, to understand how modules get associated and properly express the functions they carry in various bacterial hosts. Modules of practical importance, as for instance those that encode toxins or other virulence factors, could be identified and compared, and probes devised to test bacterial populations for the presence of such modules.

Quasi-equivalence in site-specific recombinase structure and function: crystal structure and activity of trimeric Cre recombinase bound to a three-way Lox DNA junction

The crystal structure of a novel Cre-Lox synapse was solved using phases from multiple isomorphous replacement and anomalous scattering, and refined to 2.05 A resolution. In this complex, a symmetric protein trimer is bound to a Y-shaped three-way DNA junction, a marked departure from the pseudo-4-fold symmetrical tetramer associated with Cre-mediated LoxP recombination. The three-way DNA junction was accommodated by a simple kink without significant distortion of the adjoining DNA duplexes. Although the mean angle between DNA arms in the Y and X structures was similar, adjacent Cre trimer subunits rotated 29 degrees relative to those in the tetramers. This rotation was accommodated at the protein-protein and DNA-DNA interfaces by interactions that are "quasi-equivalent" to those in the tetramer, analogous to packing differences of chemically identical viral subunits at non-equivalent positions in icosahedral capsids. This structural quasi-equivalence extends to function as Cre can bind to, cleave and perform strand transfer with a three-way Lox substrate. The structure explains the dual recognition of three and four-way junctions by site-specific recombinases as being due to shared structural features between the differently branched substrates and plasticity of the protein-protein interfaces. To our knowledge, this is the first direct demonstration of quasi-equivalence in both the assembly and function of an oligomeric enzyme.

Altered directionality in the Cre-LoxP site-specific recombination pathway

The site-specific recombinase Cre must employ control mechanisms to impose directionality on recombination. When two recombination sites (locus of crossing over in phage P1, loxP) are placed as direct repeats on the same DNA molecule, collision between loxP-bound Cre dimers leads to excision of intervening DNA. If two sites are placed as inverted repeats, the intervening segment is flipped around. Cre catalyzes these reactions in the absence of protein co-factors. Current models suggest that directionality is controlled at two steps in the recombination pathway: the juxtaposition of loxP sites and the single-strand-transfer reactions within the synaptic complex. Here, we show that in Escherichia coli strain 294-Cre, directionality for recombination is altered when the expression of Cre is increased. This leads to deletion instead of inversion on substrates carrying two loxP sites as inverted repeats. The nucleotide sequence composition of loxP sites remaining in aberrant products indicates that site alignment and/or DNA strand transfer in the in vivo Cre-loxP recombination pathway are not always tightly controlled.

A structural view of cre-loxp site-specific recombination

Structural models of site-specific recombinases from the lambda integrase family of enzymes have in the last four years provided an important new perspective on the three-dimensional nature of the recombination pathway. Members of this family, which include the bacteriophage P1 Cre recombinase, bacteriophage lambda integrase, the yeast Flp recombinase, and the bacterial XerCD recombinases, exchange strands between DNA substrates in a stepwise process. One pair of strands is exchanged to form a Holliday junction intermediate, and the second pair of strands is exchanged during resolution of the junction to products. Crystal structures of reaction intermediates in the Cre-loxP site-specific recombination system, together with recent biochemical studies in the field, support a "strand swapping" model for recombination that does not require branch migration of the Holliday junction intermediate in order to test homology between recombining sites.

Conserved amino acid motifs from the novel Piv/MooV family of transposases and site-specific recombinases are required for catalysis of DNA inversion by Piv

Piv, a site-specific invertase from Moraxella lacunata, exhibits amino acid homology with the transposases of the IS110/IS492 family of insertion elements. The functions of conserved amino acid motifs that define this novel family of both transposases and site-specific recombinases (Piv/MooV family) were examined by mutagenesis of fully conserved amino acids within each motif in Piv. All Piv mutants altered in conserved residues were defective for in vivo inversion of the M. lacunata invertible DNA segment, but competent for in vivo binding to Piv DNA recognition sequences. Although the primary amino acid sequences of the Piv/MooV recombinases do not contain a conserved DDE motif, which defines the retroviral integrase/transposase (IN/Tnps) family, the predicted secondary structural elements of Piv align well with those of the IN/Tnps for which crystal structures have been determined. Molecular modelling of Piv based on these alignments predicts that E59, conserved as either E or D in the Piv/MooV family, forms a catalytic pocket with the conserved D9 and D101 residues. Analysis of Piv E59G confirms a role for E59 in catalysis of inversion. These results suggest that Piv and the related IS110/IS492 transposases mediate DNA recombination by a common mechanism involving a catalytic DED or DDD motif.

Integrative module of the high-pathogenicity island of Yersinia

The high-pathogenicity island of Yersinia pestis (Yps HPI) encodes virulence-associated genes involved in siderophore yersiniabactin-mediated iron uptake. The Yps HPI contains a P4-type integrase (Int-HPI), associated with the asn-tRNA locus, and is flanked by 17 bp direct repeats. We constructed a minimal integrative module of the pathogenicity island carrying the reconstituted 266 bp attP (POP') attachment site derived from putative attR and attL junctions of the Yps HPI and the functional int-HPI gene from Y. pestis KUMA. The attP-int-HPI module recombined efficiently, site specifically and RecA independently with the bacterial attB site present either in the chromosome (asn-tDNA) or on a plasmid, with no preference for a certain asn-tRNA gene. The excision of the integrated suicide plasmid carrying the integrative module, on the other hand, was a rare event and could be demonstrated only by polymerase chain reaction. Analysis of the 5' terminus of the transcript for int-HPI revealed that the integration of attP-int-HPI was coupled with the replacement of the endogenous int-HPI promoter, localized in the P' part of the attP site, by the adjacent asn-tRNA promoter. These results suggest that two alternative promoters control integration and excision of the HPI by its integrase.

Extra-helical guanine interactions in DNA

We review the extra-helical guanine interactions present in many oligonucleotide crystals. Very often terminal guanines interact with other guanines in the minor groove of neighboring oligonucleotides through N2 x N3 hydrogen bonds. In other cases the interaction occurs with the help of Ni2+ ions. Guanine/netropsin stacking in the minor groove has also been found. From these studies we conclude that guanine may have multiple extra-helical interactions. In particular it may be considered a very effective minor groove binder, which could be used in the design of sequence selective binding drugs. Interactions through the major groove are seldom encountered, but might be present when DNA is stretched. Such interactions are also analyzed, since they might be important for homologous chromosome pairing during meiosis.

Resolution of a Holliday junction by vaccinia topoisomerase requires a spacer DNA segment 3' of the CCCTT/ cleavage sites

Vaccinia virus DNA topoisomerase catalyzes resolution of synthetic Holliday junctions in vitro. The mechanism entails concerted transesterifications at two recognition sites, 5'-CCCTT/, that are opposed within a partially mobile four-way junction. Efficient resolution occurs on a junction with a 10 bp segment of branch mobility (5'-GCCCTTATCG) that extends 4 bp 3' of the scissile phosphate. Here we report that resolution is decreased when branch mobility is limited to an 8 bp segment extending 2 bp 3' of the cleavage site and then eliminated when branch mobility is confined to the 6 bp GCCCTT sequence 5' of the scissile phosphate. We surmise that a spacer region 3' of CCCTT is needed for simultaneous cleavage at two opposing sites at the junction. Branch mobility is not required for reaction chemistry at a junction, because topoisomerase cleaves a single CCCTT site in a non-mobile four-way junction where the scissile phosphate is at the crossover point. The junction resolvase activity of topo-isomerase may be involved in forming the hairpin telomeres of the vaccinia genome.

Two tricks in one bundle: helix-turn-helix gains enzymatic activity

Many examples of enzymes that have lost their catalytic activity and perform other biological functions are known. The opposite situation is rare. A previously unnoticed structural similarity between the lambda integrase family (Int) proteins and the AraC family of transcriptional activators implies that the Int family evolved by duplication of an ancient DNA-binding homeodomain-like module, which acquired enzymatic activity. The two helix-turn-helix (HTH) motifs in Int proteins incorporate catalytic residues and participate in DNA binding. The active site of Int proteins, which include the type IB topoisomerases, is formed at the domain interface and the catalytic tyrosine residue is located in the second helix of the C-terminal HTH motif. Structural analysis of other 'tyrosine' DNA-breaking/rejoining enzymes with similar enzyme mechanisms, namely prokaryotic topoisomerase I, topoisomerase II and archaeal topoisomerase VI, reveals that the catalytic tyrosine is placed in a HTH domain as well. Surprisingly, the location of this tyrosine residue in the structure is not conserved, suggesting independent, parallel evolution leading to the same catalytic function by homologous HTH domains. The 'tyrosine' recombinases give a rare example of enzymes that evolved from ancient DNA-binding modules and present a unique case for homologous enzymatic domains with similar catalytic mechanisms but different locations of catalytic residues, which are placed at non-homologous sites.

Geometry of site alignment during int family recombination: antiparallel synapsis by the Flp recombinase

The Flp site-specific recombinase functions in the copy number amplification of the yeast 2 microm plasmid. The recombination reaction is catalyzed by four monomers of Flp bound to two separate, but identical, recombination sites (FRT sites) and occurs in two sequential pairs of strand exchanges. The relative orientation of the two recombination sites during synapsis was examined. Topoisomerase relaxation and nick ligation were used to detect topological nodes introduced by the synapse prior to the chemical steps of recombination. A single negative supercoil was found to be trapped by Flp in substrates with inverted FRT sites whereas no trapped supercoils were observed with direct repeats. The topology of products resulting from Flp-mediated recombination adjacent to a well characterised synapse, that of Tn3 resolvase/res, was analyzed. The deletion and inversion reactions yielded the four noded catenane and the three noded knot, respectively, as the simplest and the most abundant products. The linking number change introduced by the Flp-mediated inversion reaction was determined to be +/-2. The most parsimonious explanation of these results is that Flp aligns its recombination sites with antiparallel geometry. The majority of synapses appear to occur without entrapment of additional random plectonemic DNA supercoils between the sites and no additional crossings are introduced as a result of the chemical steps of recombination.

Family values in the age of genomics: comparative analyses of temperate bacteriophage HK022

HK022 is a temperate coliphage related to phage lambda. Its chromosome has been completely sequenced, and several aspects of its life cycle have been intensively studied. In the overall arrangement, expression, and function of most of its genes, HK022 broadly resembles lambda and other members of the lambda family. Upon closer view, significant differences emerge. The differences reveal alternative strategies used by related phages to cope with similar problems and illuminate previously unknown regulatory and structural motifs. HK022 prophages protect lysogens from superinfection by producing a sequence-specific RNA binding protein that prematurely terminates nascent transcripts of infecting phage. It uses a novel RNA-based mechanism to antiterminate its own early transcription. The HK022 protein shell is strengthened by a complex pattern of covalent subunit interlinking to form a unitary structure that resembles chain-mail armour. Its integrase and repressor proteins are similar to those of lambda, but the differences provide insights into the evolution of biological specificity and the elements needed for construction of a stable genetic switch.

Tn10 transpososome assembly involves a folded intermediate that must be unfolded for target capture and strand transfer

Tn10 transposition, like all transposition reactions examined thus far, involves assembly of a stable protein-DNA transpososome, containing a pair of transposon ends, within which all chemical events occur. We report here that stable Tn10 pre-cleavage transpososomes occur in two conformations: a folded form which contains the DNA-bending factor IHF and an unfolded form which lacks IHF. Functional analysis shows that both forms undergo double strand cleavage at the transposon ends but that only the unfolded form is competent for target capture (and thus for strand transfer to target DNA). Additional studies reveal that formation of any type of stable transpososome, folded or unfolded, requires not only IHF but also non-specific transposase-DNA contacts immediately internal to the IHF-binding site, implying the occurrence of a topo- logically closed loop at the transposon end. Overall, transpososome assembly must proceed via a folded intermediate which, however, must be unfolded in order for intermolecular transposition to occur. These and other results support key features of a recently proposed model for transpososome assembly and morphogenesis.

The amino terminus of bacteriophage lambda integrase is involved in protein-protein interactions during recombination

Bacteriophage lambda integrase (Int) catalyzes at least four site-specific recombination pathways between pairs of attachment (att) sites. Protein-protein contacts between monomers of Int are presumed to be important for these site-specific recombination events for several reasons: Int binds to the att sites cooperatively, catalytic Int mutants can complement each other for strand cleavage, and crystal structures for two other recombinases in the Int family (Cre from phage P1 and Int from Haemophilus influenzae phage HP1) show extensive protein-protein contacts between monomers. We have begun to investigate interactions between Int monomers by three approaches. First, using a genetic assay, we show that regions of protein-protein interactions occur throughout Int, including in the amino-terminal domain. This domain was previously thought to be important only for high-affinity protein-DNA interactions. Second, we have found that an amino-terminal His tag reduces cooperative binding to DNA. This disruption in cooperativity decreases the stable interaction of Int with core sites, where catalysis occurs. Third, using protein-protein cross-linking to investigate the multimerization of Int during recombination, we show that Int predominantly forms dimers, trimers, and tetramers. Moreover, we show that the cysteine at position 25 is present at or near the interface between monomers that is involved in the formation of dimers and tetramers. Our evidence indicates that the amino-terminal domain of Int is involved in protein-protein interactions that are likely to be important for recombination.

The topological mechanism of phage lambda integrase

Bacteriophage lambda integrase (Int) is a versatile site-specific recombinase. In concert with other proteins, it mediates phage integration into and excision out of the bacterial chromosome. Int recombines intramolecular sites in inverse or direct orientation or sites on separate DNA molecules. This wide spectrum of Int-mediated reactions has, however, hindered our understanding of the topology of Int recombination. By systematically analyzing the topology of Int reaction products and using a mathematical method called tangles, we deduce a unified model for Int recombination. We find that, even in the absence of (-) supercoiling, all Int reactions are chiral, producing one of two possible enantiomers of each product. We propose that this chirality reflects a right-handed DNA crossing within or between recombination sites in the synaptic complex that favors formation of right-handed Holliday junction intermediates. We demonstrate that the change in linking number associated with excisive inversion with relaxed DNA is equally +2 and -2, reflecting two different substrates with different topology but the same chirality. Additionally, we deduce that integrative Int recombination differs from excisive recombination only by additional plectonemic (-) DNA crossings in the synaptic complex: two with supercoiled substrates and one with relaxed substrates. The generality of our results is indicated by our finding that two other members of the integrase superfamily of recombinases, Flp of yeast and Cre of phage P1, show the same intrinsic chirality as lambda Int.

Alterations in the directionality of lambda site-specific recombination catalyzed by mutant integrases in vivo

Phage lambda integrative and excisive recombination normally proceeds by a pair of sequential strand exchanges. During the first exchange reaction, the "top" strand in each recombination site is cleaved, exchanged, and religated generating a Holliday junction intermediate. This intermediate DNA structure is resolved through a pair of reciprocal "bottom" strand exchanges, leading to recombinant products. The strict co-ordination of exchange reactions ensures religation between correct partner strands only. Here we show that the directionality of recombination is altered in vivo by two mutant integrases, Int-h (E174 K) and a double mutant Int-h/218 (E174 K/E218 K). This change in directionality leads to deletion instead of inversion on substrates that carry inverted attachment sites and, depending on the pair of target sites employed, requires the presence or absence of integration host factor. Neither Fis nor Xis is involved in deletion. Sequence analyses of deletion products reveal that the newly generated hybrid attachment site exhibits a reversed genetic polarity. We demonstrate that only one of two possible hybrid site configurations is generated and discuss two pathways leading to deletion. In the first, deletion results from a wrong alignment of the two recombination sites within the synaptic complex. In the second pathway, the unco-ordinated cleavage by the mutant integrases of all four DNA strands present in a conventional Holliday junction intermediate leads to two double-stranded breaks, whereby the subsequent rejoining between "wrong" partner strands appears restricted to only two strands.

Structure and mechanism in site-specific recombination

Three-dimensional structural information on the integrase family of site-specific recombinases has only recently become available, with the crystal structures of catalytic domains, full-length proteins and protein-DNA complexes of this family reported over the past two years. These results have led to a model for the overall architecture and active site stereochemistry of the recombination pathway that addresses a number of interesting mechanistic issues.

The potential of integrons and connected programmed rearrangements for mediating horizontal gene transfer

Site-specific recombination of integrons, mediates transfer of single genes in small genomes and plasmids. Recent data suggest that new genes are recruited to the cassettes--the units moved by integrons. Integrons are resident in a class of transposons with pronounced target selectivity for resolution loci in broad host range plasmids. A resulting network of programmed transfer routes, with potential offshoots reaching into eukaryotic cells, may channel genes to unexpectedly remote organisms. It has previously been observed that the conjugation apparatus of the broad host range plasmid R751 (IncP) which contains transposon Tn5090 harbouring an integron, promotes horizontal genetic transfer between bacteria and yeast. Furthermore, it is well known and fundamental for widely used gene replacement technologies, that site-specific recombination systems (e.g. Cre-lox of bacteriophage P1) related to the integrons are functional in higher eukaryotes. It seems very clear that integrons and associated programmed transfer mechanisms have high significance for the dissemination of antibiotic resistance genes in bacteria whereas further studies are needed to assess their importance for spreading of arbitrary genes in a wider range of host systems.

Site-specific integration of bacteriophage VWB genome into Streptomyces venezuelae and construction of a VWB-based integrative vector

The temperate bacteriophage VWB integrates into the chromosome of Streptomyces venezuelae ETH14630 via site-specific integration. Following recombination of the VWB attP region with the chromosomal attB sequence, the host-phage junctions attL and attR are formed. Nucleotide sequence analysis of attP, attB, attL and attR revealed a 45 bp common core sequence. In attB this 45 bp sequence consists of the 3' end of a putative tRNA Arg(AGG) gene with a 3'-terminal CCA sequence which is typical for prokaryotic tRNAs. Phage DNA integration restores the putative tRNA Arg(AGG) gene in attL. However, following recombination the CCA sequence is missing as is the case for most Streptomyces tRNA genes described so far. Adjacent to VWB attP, an ORF encoding a 427 aa protein was detected. The C-terminal region of this protein shows high similarity to the conserved C-terminal domain of site-specific recombinases belonging to the integrase family. To prove the functionality of this putative integrase gene (int), an integrative vector pKT02 was constructed. This vector consists of a 2.3 kb HindIII-SphI restriction fragment of VWB DNA containing attP and int cloned in a non-replicative Escherichia coli vector carrying a thiostrepton-resistance (tsr) gene. Integration of pKT02 was obtained after transformation of Streptomyces venezuelae ETH14630 and Streptomyces lividans TK24 protoplasts. This vector will thus be useful for a number of additional Streptomyces species in which a suitable tRNA gene can be functional as integration site.

Vaccinia virus DNA topoisomerase: a model eukaryotic type IB enzyme

Vaccinia topoisomerase has proven to be an instructive model system for mechanistic studies of the type IB family of DNA topoisomerases. The catalytically relevant functional groups at the active site and the circumferential topoisomerase-DNA interface were correctly surmised by mutational and footprint analysis of vaccinia topoisomerase in advance of structure determinations by X-ray crystallography. It is now evident from multiple crystal structures that the catalytic domains of type IB topoisomerases and site specific recombinases derive from a common ancestral strand transferase capable of forming a DNA-(3'-phosphotyrosyl)-enzyme intermediate. A constellation of conserved amino acids catalyzes attack of the tyrosine nucleophile on the scissile phosphate. Domain dynamics and DNA-induced conformational changes within the catalytic domain are likely to play a role in triggering strand scission and coordinating the strand exchange or strand passage steps.

Teaching a new dog old tricks?

The recently determined crystal structures of fragments of the human and vaccinia virus type IB topoisomerases reveal unexpected similarity with the lambda family of site-specific recombinases. The conservation of structure suggests a common mechanism, indicating that topoisomerase activity may be the consequence of uncoupling DNA strand cleavage/religation from synapsis.

Recognition of core binding sites by bacteriophage integrases

Bacteriophage integrases promote recombination between DNA molecules that carry attachment sites. They are members of a large and widely distributed family of site-specific recombinases with diverse biological roles. The integrases of phages lambda and HK022 are closely related members of this family, but neither protein efficiently recombines the attachment sites of the other phage. The nucleotides responsible for this specificity difference are located close to the points of recombinational strand exchange, within an integrase binding motif called the extended core binding site. There are four imperfectly repeated copies of this motif in each set of phage attachment sites, but only two, B' and C, contain major specificity determinants. When these specificity determinants were replaced by the corresponding nucleotides from a site with the alternative specificity, the resulting mutant was recombined by both integrases. Thus, the determinants act by impeding recombination promoted by the non-cognate integrase. We found that identical nucleotide substitutions within different core site copies had different effects on recombination, suggesting that integrase does not recognize each of the extended core binding sites in the same way. Finally, substitution at several positions in lambda integrase with the corresponding HK022-specific amino acids prevents recombination of lambda attachment sites, and this defect can be suppressed in an allele-specific manner by appropriate substitutions of HK022-specific nucleotides in the extended core binding sites.

Conservation of structure and mechanism between eukaryotic topoisomerase I and site-specific recombinases

Vaccinia DNA topoisomerase breaks and rejoins DNA strands through a DNA-(3'-phosphotyrosyl)-enzyme intermediate. A C-terminal catalytic domain, Topo(81-314), suffices for transesterification chemistry. The domain contains a constellation of five amino acids, conserved in all eukaryotic type IB topoisomerases, that catalyzes attack of the tyrosine nucleophile on the scissile phosphate. The structure of the catalytic domain, consisting of ten alpha helices and a three-strand beta sheet, resembles the catalytic domains of site-specific recombinases that act via a topoisomerase IB-like mechanism. The topoisomerase catalytic pentad is conserved in the tertiary structures of the recombinases despite scant sequence similarity overall. This implies that the catalytic domains of type IB topoisomerases and recombinases derive from a common ancestral strand transferase.