Sensing homology at the strand-swapping step in lambda excisive recombination

Redefining the bacteriophage mv4 site-specific recombination system and the sequence specificity of its attB and core-attP sites

Through their involvement in the integration and excision of a large number of mobile genetic elements, such as phages and integrative and conjugative elements (ICEs), site-specific recombination systems based on heterobivalent tyrosine recombinases play a major role in genome dynamics and evolution. However, despite hundreds of these systems having been identified in genome databases, very few have been described in detail, with none from phages that infect Bacillota (formerly Firmicutes). In this study, we reanalyzed the recombination module of Lactobacillus delbrueckii subsp. bulgaricus phage mv4, previously considered atypical compared with classical systems. Our results reveal that mv4 integrase is a 369 aa protein with all the structural hallmarks of recombinases from the Tn916 family and that it cooperatively interacts with its recombination sites. Using randomized DNA libraries, NGS sequencing, and other molecular approaches, we show that the 21-bp core-attP and attB sites have structural similarities to classical systems only if considering the nucleotide degeneracy, with two 7-bp inverted regions corresponding to mv4Int core-binding sites surrounding a 7-bp strand-exchange region. We also examined the different compositional constraints in the core-binding regions, which define the sequence space of permissible recombination sites.

The λ Integrase Site-specific Recombination Pathway

The site-specific recombinase encoded by bacteriophage λ (Int) is responsible for integrating and excising the viral chromosome into and out of the chromosome of its Escherichia coli host. Int carries out a reaction that is highly directional, tightly regulated, and depends upon an ensemble of accessory DNA bending proteins acting on 240 bp of DNA encoding 16 protein binding sites. This additional complexity enables two pathways, integrative and excisive recombination, whose opposite, and effectively irreversible, directions are dictated by different physiological and environmental signals. Int recombinase is a heterobivalent DNA binding protein and each of the four Int protomers, within a multiprotein 400 kDa recombinogenic complex, is thought to bind and, with the aid of DNA bending proteins, bridge one arm- and one core-type DNA site. In the 12 years since the publication of the last review focused solely on the λ site-specific recombination pathway in Mobile DNA II, there has been a great deal of progress in elucidating the molecular details of this pathway. The most dramatic advances in our understanding of the reaction have been in the area of X-ray crystallography where protein-DNA structures have now been determined for of all of the DNA-protein interfaces driving the Int pathway. Building on this foundation of structures, it has been possible to derive models for the assembly of components that determine the regulatory apparatus in the P-arm, and for the overall architectures that define excisive and integrative recombinogenic complexes. The most fundamental additional mechanistic insights derive from the application of hexapeptide inhibitors and single molecule kinetics.

Preventing broken Borrelia telomeres: ResT couples dual hairpin telomere formation with product release

Spirochetes of the genus Borrelia include the tick-transmitted causative agents of Lyme disease and relapsing fever. They possess unusual genomes composed mainly of linear replicons terminated by closed DNA hairpins. Hairpin telomeres are formed from inverted repeat replicated telomere junctions (rTels) by the telomere resolvase ResT. ResT uses a reaction mechanism similar to that of the type IB topoisomerases and tyrosine recombinases. ResT can catalyze three distinct reactions: telomere resolution, telomere fusion, and Holliday junction (HJ) formation. HJ formation is known to occur only in the context of a synapsed pair of rTels. To test whether telomere resolution was synapsis-dependent, we performed experiments with rTel substrates immobilized on streptavidin-coated beads. We report that telomere resolution by ResT is synapsis-independent, indicating that alternative complexes are formed for telomere resolution and HJ formation. We also present evidence that dual hairpin telomere formation precedes product release. This mechanism of telomere resolution prevents the appearance of broken telomeres. We compare and contrast this mechanism with that proposed for TelK, the telomere resolvase of ϕKO2.

Structural and functional views of salt-bridge interactions of λ integrase in the higher order recombinogenic complexes visualized by genetic method

The integrase protein encoded by bacteriophage λ (Int) catalyzes site a specific DNA recombination by which the viral chromosome is inserted into and excised out of the host genome through the formation of higher order recombinogenic nucleoprotein complexes. Genetic and biochemical studies on the Int carried out by isolating "multimer-specific" mutants had revealed informative functional characteristics of specific electrostatic interactions occurring among the functional domains of Int. The λ Int recombination system shows the usefulness of structural and functional investigation of multimeric protein complexes through genetic studies on the electrostatic interactions of proteins comprising multimeric complexes. This approach is especially powerful when combined with NMR and X-ray crystallography results providing biological evidences of specific molecular interactions among proteins.

Molecular keys of the tropism of integration of the cholera toxin phage

Cholera toxin is encoded in the genome of CTXvarphi, a lysogenic filamentous phage of Vibrio cholerae. CTXvarphi variants contribute to the genetic diversity of cholera epidemic strains. It has been shown that the El Tor variant of CTXvarphi hijacks XerC and XerD, two host-encoded tyrosine recombinases that normally function to resolve chromosome dimers, to integrate at dif1, the dimer resolution site of the larger of the two V. cholerae chromosomes. However, the exact mechanism of integration of CTXvarphi and the rules governing its integration remained puzzling, with phage variants integrated at either or both dimer resolution sites of the two V. cholerae chromosomes. We designed a genetic system to determine experimentally the tropism of integration of CTXvarphi and thus define rules of compatibility between phage variants and dimer resolution sites. We then showed in vitro how these rules are explained by the direct integration of the single-stranded phage genome into the double-stranded bacterial genome. Finally, we showed how the evolution of phage attachment and chromosome dimer resolution sites contributes to the generation of genetic diversity among cholera epidemic strains.

Homology-dependent interactions determine the order of strand exchange by IntDOT recombinase

The Bacteroides conjugative transposon CTnDOT encodes an integrase, IntDOT, which is a member of the tyrosine recombinase family. Other members of this group share a strict requirement for sequence identity within the region of strand exchange, called the overlap region. Tyrosine recombinases catalyze recombination by making an initial cleavage, strand exchange and ligation, followed by strand swapping isomerization requiring sequence identity in the overlap region, followed by the second cleavage, strand exchange and ligation. IntDOT is of particular interest because it has been shown to utilize a three-step mechanism: a sequence identity-dependent initial strand exchange that requires two base pairs of complementary DNA at the site of cleavage; a sequence identity-independent strand swapping isomerization, followed by a sequence identity-independent cleavage, strand exchange and ligation. In addition to the sequence identity requirement in the overlap region, Lambda Int interactions with arm-type sites dictate the order of strand exchange regardless of the orientation of the overlap region. Although IntDOT has an arm-binding domain, we show here that the location of sequence identity within the overlap region dictates where the initial cleavage takes place and that IntDOT can recombine substrates containing mismatches in the overlap region so long as a single base of sequence identity exists at the site of initial cleavage.

The relaxed requirements of the integron cleavage site allow predictable changes in integron target specificity

Integrons are able to incorporate exogenous genes embedded in mobile cassettes, by a site-specific recombination mechanism. Gene cassettes are collected at the attI site, via an integrase mediated recombination between the cassette recombination site, attC, and the attI site. Interestingly, only three nucleotides are conserved between attC and attI. Here, we have determined the requirements of these in recombination, using the recombination machinery from the paradigmatic class 1 integron. We found that, strikingly, the only requirement is to have identical first nucleotide in the two partner sites, but not the nature of this nucleotide. Furthermore, we showed that the reaction is close to wild-type efficiency when one of the nucleotides in the second or third position is mutated in either the attC or the attI1 site, while identical mutations can have drastic effects when both sites are mutated, resulting in a dramatic decrease of recombination frequency compared to that of the wild-type sites. Finally, we tested the functional role of the amino acids predicted from structural data to interact with the cleavage site. We found that, if the recombination site triplets are tolerant to mutation, the amino acids interacting with them are extremely constrained.

Challenging a paradigm: the role of DNA homology in tyrosine recombinase reactions

A classical feature of the tyrosine recombinase family of proteins catalyzing site-specific recombination, as exemplified by the phage lambda integrase and the Cre and Flp recombinases, is the ability to recombine substrates sharing very limited DNA sequence identity. Decades of research have established the importance of this short stretch of identity within the core regions of the substrates. Since then, several new enzymes that challenge this paradigm have been discovered and require the role of sequence identity in site-specific recombination to be reconsidered. The integrases of the conjugative transposons such as Tn916, Tn1545, and CTnDOT recombine substrates with heterologous core sequences. The integrase of the mobilizable transposon NBU1 performs recombination more efficiently with certain core mismatches. The integration of CTX phage and capture of gene cassettes by integrons also occur by altered mechanisms. In these systems, recombination occurs between mismatched sequences by a single strand exchange. In this review, we discuss literature that led to the formulation of the current strand-swapping isomerization model for tyrosine recombinases. The review then focuses on recent developments on the recombinases that challenged the paradigm that was derived from the studies of early systems.

The bacteroides NBU1 integrase performs a homology-independent strand exchange to form a holliday junction intermediate

The Bacteroides mobilizable transposon NBU1 uses an integrase (IntN1) that is a tyrosine recombinase for its integration and excision from the host chromosome. Previously we showed that IntN1 makes 7-bp staggered cuts within the NBU1 att sites, and certain mismatches within the crossover region of the attN1 site (G(-2)C attN1) or the chromosomal target site (C(-3)G attBT1-1) enhanced the in vivo integration efficiency. Here we describe an in vitro integration system for NBU1. We used nicked substrates and a Holliday junction trapping peptide to show that NBU1 integration proceeds via formation of a Holliday junction intermediate that is formed by exchange of bottom strands. Some mismatches next to the first strand exchange site (in reactions with C(-3)G attBT1-1 or G(-2)C attN1 with their wild-type partner site) not only allowed formation of the Holliday junction intermediate but also increased the rate of recombinant formation. The second strand exchange appears to be homology-dependent. IntN1 is the only tyrosine recombinase known to catalyze a reaction that is more efficient in the presence of mismatches and where the first strand exchange is homology-independent. The possible mechanisms by which the mismatches stimulate recombination are discussed.

CTnDOT integrase performs ordered homology-dependent and homology-independent strand exchanges

Although the integrase (IntDOT) of the Bacteroides conjugative transposon CTnDOT has been classified as a member of the tyrosine recombinase family, the reaction it catalyzes appears to differ in some features from reactions catalyzed by other tyrosine recombinases. We tested the ability of IntDOT to cleave and ligate activated attDOT substrates in the presence of mismatches. Unlike other tyrosine recombinases, the results revealed that IntDOT is able to perform ligation reactions even when all the bases within the crossover region are mispaired. We also show that there is a strong bias in the order of strand exchanges during integrative recombination. The top strands are exchanged first in reactions that appear to require 2 bp of homology between the partner sites adjacent to the sites of cleavage. The bottom strands are exchanged next in reactions that do not require homology between the partner sites. This mode of coordination of strand exchanges is unique among tyrosine recombinases.

Characterization of the integrase of NBU1, a Bacteroides mobilizable transposon

NBU1 is a Bacteroides mobilizable transposon (MTn) that is integrated within the host chromosome and requires CTnDOT functions for its excision and transfer into a new host. The NBU1 integrase IntN1 has been classified as a tyrosine recombinase based on the presence of conserved residues. We created alanine mutants of the residues R291, K314, H393, R396, H419 and the conserved substitution Y429F and tested them for integration efficiency. The results suggest that these residues in IntN1 are important for integration, and Y429 could be the catalytic nucleophile. We employed suicide substrates and partially purified IntN1 to determine the positions of IntN1 cleavage within the 14 bp common core region that is identical in both NBU1 att sites. We show that IntN1 makes 7 bp staggered cuts on the top and bottom strands. From previous mutational analysis of the att sites, we show that two specific mutations near the site of bottom strand cleavage within this 7 bp region increased integration, and mutations of the two bases near top strand cleavage site had no effect on integration. These results indicate that IntN1 lacks the strict requirement for homology between the recombining sites seen with other tyrosine recombinases. We also show that phosphorothioate substitutions at the cleavage site and 1 bp downstream inhibited cleavage by IntN1. This differs from other studied tyrosine recombinases where inhibition occurs by substitutions at the cleavage site only.

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.

New insight into site-specific recombination from Flp recombinase-DNA structures

The lamba integrase, or tyrosine-based family of site-specific recombinases, plays an important role in a variety of biological processes by inserting, excising, and inverting DNA segments. Flp, encoded by the yeast 2-mum plasmid, is the best-characterized eukaryotic member of this family and is responsible for maintaining the copy number of this plasmid. Over the past several years, structural and biochemical studies have shed light on the details of a common catalytic scheme utilized by these enzymes with interesting variations under different biological contexts. The emergence of new Flp structures and solution data provides insights not only into its unique mechanism of active site assembly and activity regulation but also into the specific contributions of certain protein residues to catalysis.

Dynamics and DNA substrate recognition by the catalytic domain of lambda integrase

Bacteriophage lambda integrase (lambda-Int) is the prototypical member of a large family of enzymes that catalyze site-specific DNA recombination via the formation of a Holliday junction intermediate. DNA strand cleavage by lambda-Int is mediated by nucleophilic attack on the scissile phosphate by a conserved tyrosine residue, forming an intermediate with the enzyme covalently attached to the 3'-end of the cleaved strand via a phosphotyrosine linkage. The crystal structure of the catalytic domain of lambda-Int (C170) obtained in the absence of DNA revealed the tyrosine nucleophile at the protein's C terminus to be located on a beta-hairpin far from the other conserved catalytic residues and adjacent to a disordered loop. This observation suggested that a conformational change in the C terminus of the protein was required to generate the active site in cis, or alternatively, that the active site could be completed in trans by donation of the tyrosine nucleophile from a neighboring molecule in the recombining synapse. We used NMR spectroscopy together with limited proteolysis to examine the dynamics of the lambda-Int catalytic domain in the presence and absence of DNA half-site substrates with the goal of characterizing the expected conformational change. Although the C terminus is indeed flexible in the absence of DNA, we find that conformational changes in the tyrosine-containing beta-hairpin are not coupled to DNA binding. To gain structural insights into C170/DNA complexes, we took advantage of mechanistic conservation with Cre and Flp recombinases to model C170 in half-site and tetrameric Holliday junction complexes. Although the models do not reveal the nature of the conformational change required for cis cleavage, they are consistent with much of the available experimental data and provide new insights into the how trans complementation could be accommodated.

Mutations at residues 282, 286, and 293 of phage lambda integrase exert pathway-specific effects on synapsis and catalysis in recombination

Bacteriophage lambda integrase (Int) catalyzes site-specific recombination between pairs of attachment (att) sites. The att sites contain weak Int-binding sites called core-type sites that are separated by a 7-bp overlap region, where cleavage and strand exchange occur. We have characterized a number of mutant Int proteins with substitutions at positions S282 (S282A, S282F, and S282T), S286 (S286A, S286L, and S286T), and R293 (R293E, R293K, and R293Q). We investigated the core- and arm-binding properties and cooperativity of the mutant proteins, their ability to catalyze cleavage, and their ability to form and resolve Holliday junctions. Our kinetic analyses have identified synapsis as the rate-limiting step in excisive recombination. The IntS282 and IntS286 mutants show defects in synapsis in the bent-L and excisive pathways, respectively, while the IntR293 mutants exhibit synapsis defects in both the excision and bent-L pathways. The results of our study support earlier findings that the catalytic domain also serves a role in binding to core-type sites, that the core contacts made by this domain are important for both synapsis and catalysis, and that Int contacts core-type sites differently among the four recombination pathways. We speculate that these residues are important for the proper positioning of the catalytic residues involved in the recombination reaction and that their positions differ in the distinct nucleoprotein architectures formed during each pathway. Finally, we found that not all catalytic events in excision follow synapsis: the attL site probably undergoes several rounds of cleavage and ligation before it synapses and exchanges DNA with attR.

Arm sequences contribute to the architecture and catalytic function of a lambda integrase-Holliday junction complex

lambda integrase (Int) mediates recombination between attachment sites on lambda phage and E. coli DNAs. With the assistance of accessory proteins that induce DNA loops, Int bridges pairs of distinct arm- and core-type DNA binding sites to form synapsed recombination complexes, which then recombine via a Holliday junction (HJ) intermediate. We show that, in addition to promoting the proper positioning of Int protomers, the arm sequences facilitate the catalytic activities of the Int tetramer, independent of accessory proteins or physical continuity between the arm and core sites. We have determined the architecture of ternary complexes containing a HJ, Int, and P'1,2 arm-type DNA. These structures accommodate simultaneous binding of Int to direct-repeat arm sites and indirect-repeat core sites and afford a new view of the higher-order recombinogenic complexes.

Structural plasticity of the Flp-Holliday junction complex

The Flp recombinase, a member of the lambda integrase or tyrosine-based family of site-specific recombinases, is an interesting example of an enzyme whose catalytic activity is regulated by protein-protein contacts. It exhibits half-of-the-sites activity throughout its catalytic cycle. Flp is unique among these recombinases, in that it assembles each active site in trans through the interaction of two protein monomers within the catalytic tetramer, with isomerization of interacting pairs being essential to complete a full reaction. We report here the structure of a DNA-bound tetramer of Flpe, a variant of Flp that is more active at 37 degrees C than the wild-type recombinase. This new structure includes the first observation of a tyrosine recombinase with an invading 5'-OH poised to attack the covalent phosphotyrosine residue. Comparison with the previously determined Flp structure highlights differences in flexibility between the two types of protein-protein interfaces in the tetramer and better defines the range of conformations available to this remarkably flexible complex. These results suggest a steric occlusion model for enforcement of half-of-the-sites activity.

Attenuating functions of the C terminus of lambda integrase

The tyrosine family site-specific recombinases, in contrast to the related type I topoisomerases, which act as monomers on a single DNA molecule, rely on multi-protein complexes to synapse partner DNAs and coordinate two sequential strand exchanges involving four nicking-closing reactions. Here, we analyze three mutants of the catalytic domain of lambda integrase (Int), A241V, I353M and W350ter that are defective for normal recombination, but possess increased topoisomerase activity. The mutant enzymes can carry out individual DNA strand exchanges using truncated substrates or Holliday junctions, and they show more DNA-cleavage activity than wild-type Int on isolated att sites. Structural modeling predicts that the substituted residues may destabilize interactions between the C-terminal beta-strand (beta7) of Int and the core of the protein. The cleavage-competent state of Int requires the repositioning of the nucleophile (Y342) located on beta6 and the catalyst K235 located on the flexible beta2-beta3 loop, relative to their positions in a crystal structure of the inactive conformation. We propose that the anchoring of beta7 against the protein core restrains the movement of Tyr342 and/or Lys235, causing an attenuation of cleavage activity in most contexts. Within a bona fide recombination complex, the release of strand beta7 would allow Tyr342 and Lys235 to assume catalytically active conformations in coordination with other Int protomers in the complex. The loss of beta7 packing by misalignment or truncation in the mutant proteins described here causes a loss of regulated activity, thereby favoring DNA cleavage activity in monomeric complexes and forfeiting the coordination of strand-exchange necessary for efficient recombination.

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.

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 of the Holliday junction intermediate in Cre-loxP site-specific recombination

We have determined the X-ray crystal structures of two DNA Holliday junctions (HJs) bound by Cre recombinase. The HJ is a four-way branched structure that occurs as an intermediate in genetic recombination pathways, including site-specific recombination by the lambda-integrase family. Cre recombinase is an integrase family member that recombines 34 bp loxP sites in the absence of accessory proteins or auxiliary DNA sequences. The 2.7 A structure of Cre recombinase bound to an immobile HJ and the 2.5 A structure of Cre recombinase bound to a symmetric, nicked HJ reveal a nearly planar, twofold-symmetric DNA intermediate that shares features with both the stacked-X and the square conformations of the HJ that exist in the unbound state. The structures support a protein-mediated crossover isomerization of the junction that acts as the switch responsible for activation and deactivation of recombinase active sites. In this model, a subtle isomerization of the Cre recombinase-HJ quaternary structure dictates which strands are cleaved during resolution of the junction via a mechanism that involves neither branch migration nor helical restacking.