An archaeal Holliday junction resolving enzyme from Sulfolobus solfataricus exhibits unique properties

The rearrangement and repair of DNA by homologous recombination often involves the creation of Holliday junctions, which must be cleaved by junction-specific endonucleases to yield recombinant duplex DNA products. Holliday junction resolving enzymes are a ubiquitous class of proteins with diverse structural and mechanistic characteristics. We have characterised an endonuclease (Hje) from the thermophilic crenarchaeote Sulfolobus solfataricus that exhibits a high degree of specificity for Holliday junctions via an apparently novel mechanism. Hje resolves four-way DNA junctions by the introduction of paired nicks in a reaction that is independent of the local nucleotide sequence, but is restricted solely to strands that are continuous in the stacked-X form of the junction. Three-way DNA junctions are cleaved only when the presence of a bulge in one strand allows the junction to stack in an analogous manner to four-way junctions. These properties differentiate Hje from all other known junction resolving enzymes.     

Enzymatic formation and resolution of Holliday junctions in vitro

E. coli RecA protein promotes homologous pairing and reciprocal strand exchange reactions between duplex DNA molecules in vitro. Reaction intermediates contain Holliday junctions that are driven along the DNA at a maximal rate approaching 1000 bases per minute. T4 endonuclease VII cleaves Holliday junctions in vitro, and its inclusion in RecA-mediated reactions leads to the rapid formation of heteroduplex products. Product analysis indicates patch and splice recombinant molecules similar to those expected from in vivo recombination events. The combined formation and resolution of Holliday junctions has led us to propose a model for resolution based on the structure of RecA-DNA helices. One feature of this model is that resolution, which gives rise to the two types of recombinant product, may occur without need for isomerization of the junction.     

Two Holliday junction resolving enzymes in Sulfolobus solfataricus

Holliday junction resolving enzymes bind specifically to four-way DNA junctions created by the process of homologous recombination, cleaving them to yield recombinant duplex DNA products. Homologous recombination is known to occur in the third domain of life, the archaea, and may constitute a simplified model for the corresponding eucaryal pathway, but has not been well characterised. Identification of a gene encoding an archaeal Holliday junction resolving enzyme, Hjc, has recently been reported in the euryarchaea, and an activity has been observed in the hyperthermophilic crenarchaeote Sulfolobus solfataricus. Here we report the identification, heterologous expression and characterisation of the Hjc protein from Sulfolobus. We demonstrate that Sulfolobus has two distinct junction resolving enzymes, Hjc and Hje, with differing substrate specificities.     

T-T base mismatches enhance drug binding at the branch site in a four-arm DNA junction.

Base mismatches--non Watson-Crick pairing between bases--can arise in duplex DNA as a consequence of mutational events or by recombination. In a duplex, the sequence of the two bases involved, and those flanking the site of mismatch, determines the local structure and extent of destabilization of the helix. Base mismatches can arise also in recombination of nonhomologous strands, and their occurrence in Holliday recombination intermediates can influence the outcome of general or specialized recombination events. We have previously reported that the branch site in a DNA junction can interact selectively with a variety of ligands. Here we describe the thermodynamics of junctions containing T-T mismatches flanking the branch and show that these structures bind methidium and other intercalators with higher affinity than junctions lacking mismatches.     

DNA translocation blockage, a general mechanism of cleavage site selection by type I restriction enzymes

Type I restriction enzymes bind to a specific DNA sequence and subsequently translocate DNA past the complex to reach a non-specific cleavage site. We have examined several potential blocks to DNA translocation, such as positive supercoiling or a Holliday junction, for their ability to trigger DNA cleavage by type I restriction enzymes. Introduction of positive supercoiling into plasmid DNA did not have a significant effect on the rate of DNA cleavage by EcoAI endonuclease nor on the enzyme's ability to select cleavage sites randomly throughout the DNA molecule. Thus, positive supercoiling does not prevent DNA translocation. EcoR124II endonuclease cleaved DNA at Holliday junctions present on both linear and negatively supercoiled substrates. The latter substrate was cleaved by a single enzyme molecule at two sites, one on either side of the junction, consistent with a bi-directional translocation model. Linear DNA molecules with two recognition sites for endonucleases from different type I families were cut between the sites when both enzymes were added simultaneously but not when a single enzyme was added. We propose that type I restriction enzymes can track along a DNA substrate irrespective of its topology and cleave DNA at any barrier that is able to halt the translocation process.     

Processing of intermediates in recombination and DNA repair: identification of a new endonuclease that specifically cleaves Holliday junctions.

The formation and subsequent resolution of Holliday junctions are critical stages in recombination. We describe a new Escherichia coli endonuclease that resolves Holliday intermediates by junction cleavage. The 14 kDa Rus protein binds DNA containing a synthetic four-way junction (X-DNA) and introduces symmetrical cuts in two strands to give nicked duplex products. Rus also processes Holliday intermediates made by RecA into products that are characteristic of junction resolution. The cleavage activity on X-DNA is remarkably similar to that of RuvC. Both proteins preferentially cut the same two strands at the same location. Increased expression of Rus suppresses the DNA repair and recombination defects of ruvA, ruvB and ruvC mutants. We conclude that all ruv strains are defective in junction cleavage, and discuss pathways for Holliday junction resolution by RuvAB, RuvC, RecG and Rus.     

Cleavage of symmetric immobile DNA junctions by Escherichia coli RuvC

The Holliday junction is a key DNA intermediate in the process of genetic recombination. It consists of two double-helical domains composed of homologous strands that flank a branch point; two of the strands are roughly helical, and two form the crossover between the helices. RuvC is a Holliday junction resolvase that cleaves the helical strands at a symmetric sequence, leading to the production of two recombinant molecules. We have determined the position of the cleavage site relative to the crossover point by the use of symmetric immobile junctions; these are DNA molecules containing two crossover points, one held immobile by sequence asymmetry and the second a symmetric sequence, but held immobile by torsional coupling to the first junction. We have built five symmetric immobile junctions, in which the tetranucleotide recognition site is moved stepwise relative to the branch point. We have used kinetic analysis of catalysis, gel retardation, and hydroxyl radical hypersensitivity to analyze this system. We conclude that the internucleotide linkage one position 3' to the crossover point is the favored site of cleavage.     

Effect of DNA structure and nucleotide sequence on Holliday junction resolution by a Saccharomyces cerevisiae endonuclease

Previous studies have demonstrated that mitotic Saccharomyces cerevisiae cells contain an endonuclease that cleaves Holliday junctions. In this paper, the cleavage of a number of model branched substrates has been characterized in detail. Three-armed Y-branched molecules were not substrates for the enzyme. Holliday junction substrates constructed from wild-type lambda att sites were resolved in a concerted reaction by paired single-strand breaks that contained 5'-phosphate and 3'-hydroxyl groups and were often symmetrically related. Holliday junctions were also constructed using DNAs derived from lambda safG and safT mutants to alter the nucleotide sequence immediately flanking the cross-strand exchange. These one to six base-pair changes in nucleotide sequence were observed to have dramatic effects on both the directionality and rate of resolution. More than 90% of wild-type junctions were cleaved in only one direction, while Holliday junctions composed of safT DNA were cleaved equally in both possible directions. Hybrid junctions composed of half wild-type DNA and half safG DNA were cleaved in the same orientation as the wild-type junction but at one-seventh of the rate, while junctions constructed completely from safG DNA were not cleaved at all. The cleavage sites were mapped at the nucleotide level and the locations of the paired nicks made by the endonuclease were also found to be affected by the sequence of the substrates and in such a way as to account for the directionality of cleavage. These results have important consequences for the interpretation of genetic experiments, since they provide biochemical evidence that some of the non-random nature of genetic recombination might be due to non-randomly distributed resolution processes.     

Resolving Holliday junctions with Escherichia coli UvrD helicase

The Escherichia coli UvrD helicase is known to function in the mismatch repair and nucleotide excision repair pathways and has also been suggested to have roles in recombination and replication restart. The primary intermediate DNA structure in these two processes is the Holliday junction. UvrD has been shown to unwind a variety of substrates including partial duplex DNA, nicked DNA, forked DNA structures, blunt duplex DNA and RNA-DNA hybrids. Here, we demonstrate that UvrD also catalyzes the robust unwinding of Holliday junction substrates. To characterize this unwinding reaction we have employed steady-state helicase assays, pre-steady-state rapid quench helicase assays, DNaseI footprinting, and electron microscopy. We conclude that UvrD binds initially to the junction compared with binding one of the blunt ends of the four-way junction to initiate unwinding and resolves the synthetic substrate into two double-stranded fork structures. We suggest that UvrD, along with its mismatch repair partners, MutS and MutL, may utilize its ability to unwind Holliday junctions directly in the prevention of homeologous recombination. UvrD may also be involved in the resolution of stalled replication forks by unwinding the Holliday junction intermediate to allow bypass of the blockage.     

RusA Holliday junction resolvase: DNA complex structure--insights into selectivity and specificity

We have determined the structure of a catalytically inactive D70N variant of the Escherichia coli RusA resolvase bound to a duplex DNA substrate that reveals critical protein–DNA interactions and permits a much clearer understanding of the interaction of the enzyme with a Holliday junction (HJ). The RusA enzyme cleaves HJs, the fourway DNA branchpoints formed by homologous recombination, by introducing symmetrical cuts in the phosphodiester backbone in a Mg²⁺ dependent reaction. Although, RusA shows a high level of selectivity for DNA junctions, preferring to bind fourway junctions over other substrates in vitro, it has also been shown to have appreciable affinity for duplex DNA. However, RusA does not show DNA cleavage activity with duplex substrates. Our structure suggests the possible basis for structural selectivity as well as sources of the sequence specificity observed for DNA cleavage by RusA.     

A unique beta-hairpin protruding from AAA+ ATPase domain of RuvB motor protein is involved in the interaction with RuvA DNA recognition protein for branch migration of Holliday junctions.

The Escherichia coli RuvB protein is a motor protein that forms a complex with RuvA and promotes branch migration of Holliday junctions during homologous recombination. This study describes the characteristics of two RuvB mutants, I148T and I150T, that do not promote branch migration in the presence of RuvA. These RuvB mutants hydrolyzed ATP and bound duplex DNA with the same efficiency as wild-type RuvB, but the mutants did not form a complex with RuvA and were defective in loading onto junction DNA in a RuvA-assisted manner. A recent crystallographic study revealed that Ile(148) and Ile(150) are in a unique beta-hairpin that protrudes from the AAA(+) ATPase domain of RuvB. We propose that this beta-hairpin interacts with hydrophobic residues in the mobile third domain of RuvA and that this interaction is vital for the RuvA-assisted loading of RuvB onto Holliday junction DNA.     

Molecular recognition of DNA structure by proteins that mediate genetic recombination

The latter half of genetic recombination is mediated by proteins that recognise the structure of the four-way DNA junction, and manipulate this structure. In solution the four-way junction adopts a stacked X-structure in the presence of metal ions. The folding is brought about by the pairwise coaxial stacking of helices in a right-handed antiparallel X-shaped structure. The four-way junction is cleaved by structure-selective resolving enzymes that have been isolated from a wide variety of sources, from eubacteria and their phages through to mammals. In addition, another class of proteins accelerate the branch migration of the junction. These proteins all appear to be divisible into a component that recognises structure and another that carries out a reaction on the junction. Thus the ability of structure-selective binding to the four-way DNA junction is a key feature of enzymes important in genetic recombination.     

Interaction of linear homologous DNA duplexes via Holliday junction formation.

Interaction of linear homologous DNA duplexes by formation of Holliday junctions was revealed by electrophoresis and confirmed by electron microscopy. The phenomenon was demonstrated using a model of five purified PCR products of different size and sequence. The double-stranded structure of interacting DNA fragments was confirmed using several consecutive purifications, S1-nuclease analysis, and electron microscopy. Formation of Holliday junctions depends on DNA concentration. A thermodynamic equilibrium between duplexes and Holliday junctions was shown. We propose that homologous duplex interaction is initiated by nucleation of several dissociated terminal base pairs of two fragments. This process is followed by branch migration creating a population of Holliday junctions with the branch point at different sites. Finally, Holliday junctions are resolved via branch migration to new or previously existing duplexes. The phenomenon is a new property of DNA. This type of DNA-DNA interaction may contribute to the process of Holliday junction formation in vivo controlled by DNA conformation and DNA-protein interactions. It is of practical significance for optimization of different PCR-based methods of gene analysis, especially those involving heteroduplex formation.     

Construction of a synthetic Holliday junction analog and characterization of its interaction with a Saccharomyces cerevisiae endonuclease that cleaves Holliday junctions

We describe the construction and characterization of an oligonucleotide Holliday junction analog and characterize its interaction with a Saccharomyces cerevisiae endonuclease that cleaves Holliday junctions. A Holliday junction analog containing four duplex arms and 54 base pairs was constructed by annealing four unique synthetic oligonucleotides. Mixing curve analysis showed that the complex contained a 1:1:1:1 mol ratio of the four unique sequence strands. In addition, a linear duplex with a sequence identical to two of the junction arms was also constructed for use as a control fragment. High resolution gel exclusion chromatography was used to purify and characterize the synthetic junction. The synthetic Holliday junction was found to be a specific inhibitor of a S. cerevisiae enzyme that catalyzes the cleavage of Holliday junctions. Under standard cleavage conditions, 50% inhibition was observed at a synthetic Holliday junction to substrate ratio of 7/1, whereas no inhibition by linear duplex was observed at molar ratios in excess of 150/1. Kinetic analysis showed that Holliday junction was a competitive inhibitor of the reaction and had an apparent Ki = 2.5 nM, although the mode of inhibition was complex. The synthetic Holliday junction was not a substrate for the enzyme, but was found to form a specific complex with the enzyme as evidenced by polyacrylamide gel electrophoresis DNA binding assays.     

Spermidine biases the resolution of Holliday junctions by phage lambda integrase

Holliday junctions are a central intermediate in diverse pathways of DNA repair and recombination. The isomerization of a junction determines the directionality of the recombination event. Previous studies have shown that the identity of the central sequence of the junction may favor one of the two isomers, in turn controlling the direction of the pathway. Here we demonstrate that, in the absence of DNA sequence-mediated isomer preference, polycations are the major contributor to biasing strand cleavage during junction resolution. In the case of wild-type phage λ excision junctions, spermidine plays the dominant role in controlling the isomerization state of the junction and increases the rate of junction resolution. Spermidine also counteracts the sequence-imposed bias on resolution. The spermidine-induced bias is seen equally on supercoiled and linear excisive recombination junction intermediates, and thus is not just an artefact of in vitro recombination conditions. The contribution of spermidine requires the presence of accessory factors, and results in the repositioning of Int's core-binding domains on junctions, perhaps due to DNA-spermidine–protein interactions, or by influencing DNA conformation in the core region. Our results lead us to propose that spermidine together with accessory factors promotes the formation of the second junction isomer. We propose that this rearrangement triggers the activation of the second pair of Int active sites necessary to resolve Holliday junctions during phage λ Int-mediated recombination.     

Solution formation of Holliday junctions in inverted-repeat DNA sequences

The structure of Holliday junctions has now been well characterized at the atomic level through single-crystal X-ray diffraction in symmetric (inverted-repeat) DNA sequences. At issue, however, is whether the formation of these four-stranded complexes in solution is truly sequence dependent in the manner proposed or is an artifact of the crystallization process and, therefore, has no relevance to the behavior of this central intermediate in homologous recombination and recombination-dependent cellular processes. Here, we apply analytical ultracentrifugation to demonstrate that the sequence d(CCGGTACCGG), which crystallizes in the stacked-X form of the junction, assembles into four-stranded junctions in solution in a manner that is dependent on the DNA and cation concentrations, with an equilibrium established between the junction and duplex forms at 100-200 microM DNA duplex. In contrast, the sequence d(CCGCTAGCGG), which has been crystallized as B-DNA, is seen to adopt only the double-helical form at all DNA and salt concentrations that were tested. Thus, the ACC trinucleotide core is now shown to be important for the formation of Holliday junctions in both crystals and in solution and can be estimated to contribute approximately -4 kcal/mol to stabilizing this recombination intermediate in inverted-repeat sequences.     

Fluorescence resonance energy transfer analysis of the structure of the four-way DNA junction.

We have carried out fluorescence resonance energy transfer (FRET) measurements on four-way DNA junctions in order to analyze the global structure and its dependence on the concentration of several types of ions. A knowledge of the structure and its sensitivity to the solution environment is important for a full understanding of recombination events in DNA. The stereochemical arrangement of the four DNA helices that make up the four-way junction was established by a global comparison of the efficiency of FRET between donor and acceptor molecules attached pairwise in all possible permutations to the 5' termini of the duplex arms of the four-way structure. The conclusions are based upon a comparison between a series of many identical DNA molecules which have been labeled on different positions, rather than a determination of a few absolute distances. Details of the FRET analysis are presented; features of the analysis with particular relevance to DNA structures are emphasized. Three methods were employed to determine the efficiency of FRET: (1) enhancement of the acceptor fluorescence, (2) decrease of the donor quantum yield, and (3) shortening of the donor fluorescence lifetime. The FRET results indicate that the arms of the four-way junction are arranged in an antiparallel stacked X-structure when salt is added to the solution. The ion-related conformational change upon addition of salt to a solution originally at low ionic strength progresses in a continuous noncooperative manner as the ionic strength of the solution increases. The mode of ion interaction at the strand exchange site of the junction is discussed.     

Crystal structure of a DNA Holliday junction.

DNA recombination is a universal biological event responsible both for the generation of genetic diversity and for the maintenance of genome integrity. A four-way DNA junction, also termed Holliday junction, is the key intermediate in nearly all recombination processes. This junction is the substrate of recombination enzymes that promote branch migration or catalyze its resolution. We have determined the crystal structure of a four-way DNA junction by multiwavelength anomalous diffraction, and refined it to 2.16 A resolution. The structure has two-fold symmetry, with pairwise stacking of the double-helical arms, which form two continuous B-DNA helices that run antiparallel, cross in a right-handed way, and contain two G-A mismatches. The exchanging backbones form a compact structure with strong van der Waals contacts and hydrogen bonds, implying that a conformational change must occur for the junction to branch-migrate or isomerize. At the branch point, two phosphate groups from one helix occupy the major groove of the other one, establishing sequence-specific hydrogen bonds. These interactions, together with different stacking energies and steric hindrances, explain the preference for a particular junction stacked conformer.     

Atomic force microscopic measurement of the interdomain angle in symmetric Holliday junctions

The Holliday junction is a key intermediate in genetic recombination. It consists of four DNA strands that associate by base pairing to produce four double helices flanking a junction point. In the presence of multivalent cations, the four helices, in turn, stack in pairs to form two double-helical domains. The angle between these domains has been shown in a number of solution studies to be approximately 60 degrees in junctions flanked by asymmetric sequences. However, the recently determined crystal structure of a symmetric junction [Eichman, B. F., Vargason, J. M., Mooers, B. H. M., and Ho, P. S. (2000) Proc. Natl. Acad. Sci. U.S.A. 97, 3971-3976] finds an angle closer to 40 degrees, possibly because of sequence effects. From the crystal structure alone, one cannot exclude the possibility that this unusual angle is a consequence of crystal packing effects. We have formed two-dimensional (2D) periodic arrays of DNA parallelograms with the same junction-flanking sequence used to produce the crystals; these parallelograms are free to adopt their preferred interdomain angle. Atomic force microscopy can be used to establish the interdomain angle in this system. We find that the angle in this junction is 43 degrees, in good agreement with the results of crystallography. We have used hydroxyl radical autofootprinting to establish that the branch point is at the same migratory position seen in the crystals.     

Structure, folding and activity of the VS ribozyme: importance of the 2-3-6 helical junction

The VS nucleolytic ribozyme has a core comprising five helices organized by two three-way junctions. The ribozyme can act in trans on a hairpin-loop substrate, with which it interacts via tertiary contacts. We have determined that one of the junctions (2-3-6) undergoes two-stage ion-dependent folding into a stable conformation, and have determined the global structure of the folded junction using long-range distance restraints derived from fluorescence resonance energy transfer. A number of sequence variants in the junction are severely impaired in ribozyme cleavage, and there is good correlation between changes in activity and alteration in the folding of junction 2-3-6. These studies point to a special importance of G and A nucleotides immediately adjacent to helix II, and comparison with a similar junction of known structure indicates that this could adopt a guanine-wedge structure. We propose that the 2-3-6 junction organizes important aspects of the structure of the ribozyme to facilitate productive association with the substrate, and suggest that this results in an interaction between the substrate and the A730 loop to create the active complex.