Analysis of conformational changes in the DNA junction-resolving enzyme T7 endonuclease I on binding a four-way junction using EPR

The four-way (Holliday) DNA junction is the central intermediate in homologous recombination. It is ultimately resolved into two nicked-duplex species by the action of a junction-resolving enzyme. These enzymes are highly selective for the structure of branched DNA, yet as a class these proteins impose significant distortion on their target junctions. Bacteriophage T7 endonuclease I selectively binds and cleaves DNA four-way junctions. The protein is an extremely stable dimer, comprising two globular domains joined by a β-strand bridge with each active site including amino acids from both polypeptides. The crystal structure of endonuclease I has been solved both as free protein and in complex with a DNA junction, showing that the protein, as well as the junction, becomes distorted on binding. We have therefore used site-specific spin-labeling in conjunction with EPR distance measurements to analyze induced fit in the binding of endonuclease I to a DNA four-way junction. The results support the change in protein structure as it binds to the junction. In addition, we have examined the structure of wild type and catalytically inactive mutants alone and in complex with DNA. We demonstrate the presence of hitherto undefined metastable conformational states within endonuclease I, showing how these states can be influenced by DNA-junction binding or mutations within the active sites. In addition, we demonstrate a previously unobserved instability in the N-terminal α1-helix upon active site mutation. These studies reveal that structural changes in both DNA and protein occur in the action of this junction-resolving enzyme.     

High affinity of endonuclease VII for the Holliday structure containing one nick ensures productive resolution

During homologous recombination, genetic information is physically exchanged between parental DNAs via crossing single strands of the same polarity within a four-way DNA junction called a Holliday structure. This process is terminated by the endonucleolytic activity of resolvases, which convert the four-way DNA back to two double strands. To achieve productive resolution, the two subunits of the dimeric enzymes introduce two single-strand cuts positioned symmetrically in opposite strands across the DNA junction. Covalently linked dimers of endonuclease VII from phage T4, whether a homodimer with two or a heterodimer with only one functional catalytic centre, reacted with a synthetic cruciform DNA to form a DNA-enzyme complex immediately after addition of the enzyme. Analysis of the complexes from both reactions revealed that the bound junction contained one nick. While the active homodimer processed this nicked junction consecutively to duplex DNAs by making the second cut, the complex with the heterodimer stayed stable for the whole reaction time. Thus the high affinity of endonuclease VII for the junction containing one nick is part of the mechanism to ensure productive resolution of Holliday structures, by giving the enzyme time to make the second cut, whereupon the complex dissociates into the two duplex DNAs and the free enzyme.     

Specificity of binding to four-way junctions in DNA by bacteriophage T7 endonuclease I.

T7 endonuclease I binds specifically to four-way junctions in duplex DNA and promotes their resolution into linear duplexes. Under conditions in which the nuclease activity is blocked by the absence of divalent cations, the enzyme forms a distinct protein-DNA complex with the junction, as detected by gel retardation and filter binding assays. The formation of this complex is structure-specific and contrasts with the short-lived binding complexes formed on linear duplex DNA. The binding complex between T7 endonuclease I and a synthetic Holliday junction analog has been probed with hydroxyl radicals. The results indicate that the nuclease binds all four strands about the junction point.     

Near-simultaneous DNA cleavage by the subunits of the junction-resolving enzyme T4 endonuclease VII.

In common with a number of other DNA junction-resolving enzymes, endonuclease VII of bacteriophage T4 binds to a four-way DNA junction as a dimer, and cleaves two strands of the junction. We have used a supercoil-stabilized cruciform substrate to probe the simultaneity of cleavage at the two sites. Active endonuclease VII converts the supercoiled circular DNA directly into linear product, indicating that the two cleavage reactions must occur within the lifetime of the protein-junction complex. By contrast, a heterodimer of active enzyme and an inactive mutant endonuclease VII leads to the formation of nicked circular product, showing that the subunits operate fully independently.     

Structural recognition between a four-way DNA junction and a resolving enzyme

Resolving enzymes bind highly selectively to four-way DNA junctions, but the mechanism of this structural specificity is poorly understood. In this study, we have explored the role of interactions between the dimeric enzyme and the helical arms of the junction, using junctions with either shortened arms, or circular permutation of arms. We find that DNA-protein contacts in the arms containing the 5' ends of the continuous strands are very important, conferring a significant level of sequence discrimination upon both the choice of conformer and the order of strand cleavage. We have exploited these properties to obtain hydroxyl radical footprinting data on endonuclease I-junction complexes that are not complicated by the presence of alternative conformers, with results that are in good agreement with the arm permutation and shortening experiments. Substitution of phosphate groups at the center of the junction reveals the importance of electrostatic interactions at the point of strand exchange in the complex. Our data show that the form of the complex between endonuclease I and a DNA junction depends on the core of the junction and on interactions with the first six base-pairs of the arms containing the 5' ends of the continuous strands.     

Crystal structure of the Holliday junction resolving enzyme T7 endonuclease I

We have solved the crystal structure of the Holliday junction resolving enzyme T7 endonuclease I at 2.1 A resolution using the multiwavelength anomalous dispersion (MAD) technique. Endonuclease I exhibits strong structural specificity for four-way DNA junctions. The structure shows that it forms a symmetric homodimer arranged in two well-separated domains. Each domain, however, is composed of elements from both subunits, and amino acid side chains from both protomers contribute to the active site. While no significant structural similarity could be detected with any other junction resolving enzyme, the active site is similar to that found in several restriction endonucleases. T7 endonuclease I therefore represents the first crystal structure of a junction resolving enzyme that is a member of the nuclease superfamily of enzymes.     

Crystal structure of an 82-nucleotide RNA-DNA complex formed by the 10-23 DNA enzyme

The structure of a large nucleic acid complex formed by the 10-23 DNA enzyme bound to an RNA substrate was determined by X-ray diffraction at 3.0 A resolution. The 82-nucleotide complex contains two strands of DNA and two strands of RNA that form five double-helical domains. The spatial arrangement of these helices is maintained by two four-way junctions that exhibit extensive base-stacking interactions and sharp turns of the phosphodiester backbone stabilized by metal ions coordinated to nucleotides at these junctions. Although it is unlikely that the structure corresponds to the catalytically active conformation of the enzyme, it represents a novel nucleic acid fold with implications for the Holliday junction structure.     

Substrate recognition and catalysis by the Holliday junction resolving enzyme Hje

Two archaeal Holliday junction resolving enzymes, Holliday junction cleavage (Hjc) and Holliday junction endonuclease (Hje), have been characterized. Both are members of a nuclease superfamily that includes the type II restriction enzymes, although their DNA cleaving activity is highly specific for four-way junction structure and not nucleic acid sequence. Despite 28% sequence identity, Hje and Hjc cleave junctions with distinct cutting patterns--they cut different strands of a four-way junction, at different distances from the junction centre. We report the high-resolution crystal structure of Hje from Sulfolobus solfataricus. The structure provides a basis to explain the differences in substrate specificity of Hje and Hjc, which result from changes in dimer organization, and suggests a viral origin for the Hje gene. Structural and biochemical data support the modelling of an Hje:DNA junction complex, highlighting a flexible loop that interacts intimately with the junction centre. A highly conserved serine residue on this loop is shown to be essential for the enzyme's activity, suggesting a novel variation of the nuclease active site. The loop may act as a conformational switch, ensuring that the active site is completed only on binding a four-way junction, thus explaining the exquisite specificity of these enzymes.     

Interaction of a four-way junction in DNA with T4 endonuclease VII

The binding of a synthetic four-way junction in DNA by T4 endonuclease VII has been studied using gel retardation and footprint analysis. Two specific protein-DNA complexes have been observed, but only one is stable in the presence of moderate concentrations of salt. The footprint of T4 endonuclease VII in the salt-resistant complex has been probed using hydroxyl radicals generated by the reaction of iron(II)/EDTA with hydrogen peroxide. The hydroxyl radical cleavage pattern indicates protection of approximately 5 residues in two strands that are diametrically opposed across the junction point.     

New insight into the recognition of branched DNA structure by junction-resolving enzymes

Junction-resolving enzymes are nucleases that exhibit structural selectivity for the four-way (Holliday) junction in DNA. In general, these enzymes both recognize and distort the structure of the junction. New insight into the molecular recognition processes has been provided by two recent co-crystal structures of resolving enzymes bound to four-way DNA junctions in highly contrasting ways. T4 endonuclease VII binds the junction in an open conformation to an approximately flat binding surface whereas T7 endonuclease I envelops the junction, which retains a much more three-dimensional structure. Both proteins make contacts with the DNA backbone over an extensive area in order to generate structural specificity. The comparison highlights the versatility of Holliday junction resolution, and extracts some general principles of recognition.     

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.     

The tertiary structure of the four-way DNA junction affords protection against DNase I cleavage.

The accessibility of phosphodiester bonds in the DNA of four-way helical junctions has been probed with the nuclease DNase I. Regions of protection were observed on all four strands of the junctions, that tended to be longer on the strands that are exchanged between the coaxially stacked pairs of helices. The protected regions on the continuous strands of the stacked helices were not located exactly at the junction, but were displaced towards the 3' side of the strand. This is the region of backbone that becomes located in the major groove of the opposed helix in the non-crossed, right-handed structure for the junction, and might therefore be predicted to be protected against cleavage by an enzyme. However, the major grooves of the structure remain accessible to the much smaller probe dimethyl sulphate.     

Conformational model of the Holliday junction transition deduced from molecular dynamics simulations

Homologous recombination plays a key role in the restart of stalled replication forks and in the generation of genetic diversity. During this process, two homologous DNA molecules undergo strand exchange to form a four-way DNA (Holliday) junction. In the presence of metal ions, the Holliday junction folds into the stacked-X structure that has two alternative conformers. Experiments have revealed the spontaneous transitions between these conformers, but their detailed pathways are not known. Here, we report a series of molecular dynamics simulations of the Holliday junction at physiological and elevated (400 K) temperatures. The simulations reveal new tetrahedral intermediates and suggest a schematic framework for conformer transitions. The tetrahedral intermediates bear resemblance to the junction conformation in complex with a junction-resolving enzyme, T7 endonuclease I, and indeed, one intermediate forms a stable complex with the enzyme as demonstrated in one simulation. We also describe free energy minima for various states of the Holliday junction system, which arise during conformer transitions. The results show that magnesium ions stabilize the stacked-X form and destabilize the open and tetrahedral intermediates. Overall, our study provides a detailed dynamic model of the Holliday junction undergoing a conformer transition.     

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.     

A single catalytic domain of the junction-resolving enzyme T7 endonuclease I is a non-specific nicking endonuclease

A stable heterodimeric protein containing a single correctly folded catalytic domain (SCD) of T7 endonuclease I was produced by means of a trans-splicing intein system. As predicted by a model presented earlier, purified SCD protein acts a non-specific nicking endonuclease on normal linear DNA. The SCD retains some ability to recognize and cleave a deviated DNA double-helix near a nick or a strand-crossing site. Thus, we infer that the non-specific and nicked-site cleavage activities observed for the native T7 endonuclease I (as distinct from the resolution activity) are due to uncoordinated actions of the catalytic domains. The positively charged C-terminus of T7 Endo I is essential for the enzymatic activity of SCD, as it is for the native enzyme. We propose that the preference of the native enzyme for the resolution reaction is achieved by cooperativity in the binding of its two catalytic domains when presented with two of the arms across a four-way junction or cruciform structure.     

Quantitation of metal ion and DNA junction binding to the Holliday junction endonuclease Cce1

Cce1 is a magnesium-dependent Holliday junction endonuclease involved in the resolution of recombining mitochondrial DNA in Saccharomyces cerevisiae. Cce1 binds four-way DNA junctions as a dimer, opening the junction into an extended, 4-fold symmetric structure, and resolves junctions by the introduction of paired nicks in opposing strands at the point of strand exchange. In the present study, we have examined the interactions of wild-type Cce1 with a noncleavable four-way DNA junction and metal ions (Mg(2+) and Mn(2+)) using isothermal titration calorimetry, EPR, and gel electrophoresis techniques. Mg(2+) or Mn(2+) ions bind to Cce1 in the absence of DNA junctions with a stoichiometry of two metal ions per Cce1 monomer. Cce1 binds to four-way junctions with a stoichiometry of two Cce1 dimers per junction molecule in the presence of EDTA, and one dimer of Cce1 per junction in 15 mM magnesium. The presence of 15 mM Mg(2+) dramatically reduces the affinity of Cce1 for four-way DNA junctions, by about 900-fold. This allows an estimation of DeltaG degrees for stacking of four-way DNA junction 7 of -4.1 kcal/mol, consistent with the estimate of -3.3 to -4.5 kcal/mol calculated from branch migration and NMR experiments [Overmars and Altona (1997) J. Mol. Biol. 273, 519-524; Panyutin et al. (1995) EMBO J. 14, 1819-1826]. The striking effect of magnesium ions on the affinity of Cce1 binding to the four-way junction is predicted to be a general one for proteins that unfold the stacked X-structure of the Holliday junction on binding.     

Biochemical characterization of a structure-specific resolving enzyme from Sulfolobus islandicus rod-shaped virus 2

Sulfolobus islandicus rod shaped virus 2 (SIRV2) infects the archaeon Sulfolobus islandicus at extreme temperature (70°C-80°C) and acidity (pH 3). SIRV2 encodes a Holliday junction resolving enzyme (SIRV2 Hjr) that has been proposed as a key enzyme in SIRV2 genome replication. The molecular mechanism for SIRV2 Hjr four-way junction cleavage bias, minimal requirements for four-way junction cleavage, and substrate specificity were determined. SIRV2 Hjr cleaves four-way DNA junctions with a preference for cleavage of exchange strand pairs, in contrast to host-derived resolving enzymes, suggesting fundamental differences in substrate recognition and cleavage among closely related Sulfolobus resolving enzymes. Unlike other viral resolving enzymes, such as T4 endonuclease VII or T7 endonuclease I, that cleave branched DNA replication intermediates, SIRV2 Hjr cleavage is specific to four-way DNA junctions and inactive on other branched DNA molecules. In addition, a specific interaction was detected between SIRV2 Hjr and the SIRV2 virion body coat protein (SIRV2gp26). Based on this observation, a model is proposed linking SIRV2 Hjr genome resolution to viral particle assembly.     

Positive torsional strain causes the formation of a four-way junction at replication forks

The advance of a DNA replication fork requires an unwinding of the parental double helix. This in turn creates a positive superhelical stress, a (+)-DeltaLk, that must be relaxed by topoisomerases for replication to proceed. Surprisingly, partially replicated plasmids with a (+)-DeltaLk were not supercoiled nor were the replicated arms interwound in precatenanes. The electrophoretic mobility of these molecules indicated that they have no net writhe. Instead, the (+)-DeltaLk is absorbed by a regression of the replication fork. As the parental DNA strands re-anneal, the resultant displaced daughter strands base pair to each other to form a four-way junction at the replication fork, which is locally identical to a Holliday junction in recombination. We showed by restriction endonuclease digestion that the junction can form at either the terminus or the origin of replication and we visualized the structure with scanning force microscopy. We discuss possible physiological implications of the junction for stalled replication in vivo.     

Crystal structure of RuvC resolvase in complex with Holliday junction substrate

The key intermediate in genetic recombination is the Holliday junction (HJ), a four-way DNA structure. At the end of recombination, HJs are cleaved by specific nucleases called resolvases. In Gram-negative bacteria, this cleavage is performed by RuvC, a dimeric endonuclease that belongs to the retroviral integrase superfamily. Here, we report the first crystal structure of RuvC in complex with a synthetic HJ solved at 3.75 Å resolution. The junction in the complex is in an unfolded 2-fold symmetrical conformation, in which the four arms point toward the vertices of a tetrahedron. The two scissile phosphates are located one nucleotide from the strand exchange point, and RuvC approaches them from the minor groove side. The key protein–DNA contacts observed in the structure were verified using a thiol-based site-specific cross-linking approach. Compared with known complex structures of the phage resolvases endonuclease I and endonuclease VII, the RuvC structure exhibits striking differences in the mode of substrate binding and location of the cleavage site.     

Metal ions bound at the active site of the junction-resolving enzyme T7 endonuclease I

T7 endonuclease I is a nuclease that is selective for the structure of the four-way DNA junction. The active site is similar to those of a number of restriction enzymes. We have solved the crystal structure of endonuclease I with a wild-type active site. Diffusion of manganese ions into the crystal revealed two peaks of electron density per active site, defining two metal ion-binding sites. Site 1 is fully occupied, and the manganese ion is coordinated by the carboxylate groups of Asp55 and Glu65, and the main chain carbonyl of Thr66. Site 2 is partially occupied, and the metal ion has a single protein ligand, the remaining carboxylate oxygen atom of Asp55. Isothermal titration calorimetry showed the sequential exothermic binding of two manganese ions in solution, with dissociation constants of 0.58 +/- 0.019 and 14 +/- 1.5 mM. These results are consistent with a two metal ion mechanism for the cleavage reaction, in which the hydrolytic water molecule is contained in the first coordination sphere of the site 1-bound metal ion.