Mechanistic aspects of the DNA junction-resolving enzyme T7 endonuclease I

The chemical mechanism of phosphodiester bond hydrolysis catalyzed by a junction-resolving enzyme has been investigated. Endonuclease I of phage T7 is a member of the nuclease superfamily of proteins that include many restriction enzymes, and the structure of the active site is very similar to that of BglI in particular. It contains three acidic amino acids that coordinate two divalent metal ions. Using mass spectrometry we have shown that endonuclease I catalyzes the breakage of the P-O3' bond, in common with restriction enzymes. We have found that the pH dependence of the hydrolysis reaction is log-linear, with a gradient of 0.9. Substitution of the scissile phosphate by an electrically neutral methylphosphonate significantly impairs the rate of bond cleavage. However, the introduction of chirally pure methylphosphonate groups shows that the effect of substitution of the proS oxygen atom is much greater than that for the proR. This is consistent with our current model of the structure of the DNA bound in the active site of endonuclease I, where the proS oxygen atom is coordinated directly to both metal ions as it is in BglI. The activity is also very sensitive to repositioning of the carboxylate groups of Asp 55 and Glu 65 in the active site, although some restoration of activity in endonuclease I E65D was observed in the presence of Mn2+ ions. A mechanism of hydrolysis consistent with all of these data is proposed.     

The active site of the junction-resolving enzyme T7 endonuclease I

Endonuclease I is a junction-resolving enzyme encoded by bacteriophage T7, that selectively binds and cleaves four-way DNA junctions. We have recently solved the structure of this dimeric enzyme at atomic resolution, and identified the probable catalytic residues. The putative active site comprises the side-chains of three acidic amino acids (Glu20, Asp55 and Glu65) together with a lysine residue (Lys67), and shares strong similarities with a number of type II restriction enzymes. However, it differs from a typical restriction enzyme as the proposed catalytic residues in both active sites are contributed by both polypeptides of the dimer. Mutagenesis experiments confirm the importance of all the proposed active site residues. We have carried out in vitro complementation experiments using heterodimers formed from mutants in different active site residues, showing that Glu20 is located on a different monomer from the remaining amino acid residues comprising the active site. These experiments confirm that the helix-exchanged architecture of the enzyme creates a mixed active site in solution. Such a composite active site structure should result in unilateral cleavage by the complemented heterodimer; this has been confirmed by the use of a cruciform substrate. Based upon analogy with closely similar restriction enzyme active sites and our mutagenesis experiments, we propose a two-metal ion mechanism for the hydrolytic cleavage of DNA junctions.     

Pyrimidine dimer dependent cleavage of single-stranded DNA by T4 UV endonuclease

T4 UV endonuclease cleaves double- and single-stranded DNA with equal specificity for photo-pyrimidine dimers. Thus, the enzyme can be used for mapping and quantifying pyrimidine dimers in single-stranded DNA as well as in double-stranded DNA. Mapping of pyrimidine dimers shows that rates of UV-dimerization are not only affected by 5', 3' adjacent bases, but also by position within pyrimidine tracts. Di-pyrimidines at 3' ends of tracts are more photoreactive than those at 5' ends.     

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.     

Bypass of a primase requirement for bacteriophage T4 DNA replication in vivo by a recombination enzyme, endonuclease VII.

A primase, the product of phage T4 gene 61, is required to initiate synthesis of Okazaki pieces and to allow bidirectional replication from several T4 origins. However, primase-defective T4 gene 61 mutants are viable. In these mutants, leading-strand DNA synthesis starts at the same time as in wild type infections, but, in contrast to wild type, initiation is unidirectional and the first replicative intermediates are large displacement loops. Rapid double-strand DNA replication occurs later after infection, generating multiple branched concatemers, which are cut and packaged into viable progeny particles, as in wild-type T4. Evidence is presented that this late double-strand DNA replication requires functional endonuclease VII (endo VII), the product of the T4 gene 49. We propose that endo VII can provide a backup mechanism when primase is defective, because it cuts recombinational junctions, generating 3' ends. These ends can prime DNA synthesis to copy the DNA strands that had been displaced during the initial origin-dependent replication. We explain the DNA-delay phenotype and the commonly observed temperature dependence of DNA replication in primase-deficient gene 61 mutants as a consequence of temperature-dependent translational control of gene 49 expression. In the presence or absence of functional primase endo VII is essential for correct packaging of DNA. The powerful selection that keeps the function of endo VII and expression of its gene at levels that are optimal for T4 development determines both the efficiency and the limitations of the bypass mechanism.     

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.     

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.     

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.     

T4 endonuclease VII cleaves holliday structures

T4 endonuclease VII cleaves Holliday structures in vitro by cutting two strands of the same polarity at or near the branch point. The two unbranched duplexes produced by cleavage each contain a strand break that can be sealed by DNA ligase. This suggests that the cut sites are at the same position in the nucleotide sequence in each strand. The joint action of endonuclease VII and DNA ligase can therefore resolve Holliday structures into genetically sensible products. These observations account for the role of endonuclease VII in the DNA metabolism of phage T4, and provide the first example of an enzyme that acts specifically on branch points in duplex DNA.     

Conformational flexibility in T4 endonuclease VII revealed by crystallography: implications for substrate binding and cleavage

The structure of the N62D mutant of the junction-resolving endonuclease VII (EndoVII) from phage T4 has been refined at 1.3 A, and a second wild-type crystal form solved and refined at 2.8 A resolution. Comparison of the mutant with the wild-type protein structure in two different crystal environments reveals considerable conformational flexibility at the dimer level affecting the substrate-binding cleft, the dimerization interface and the orientation of the C-terminal domains. The opening of the DNA-binding cleft, the orientation of the C-terminal domains relative to the central dimerization domain as well as the relative positioning of helices in the dimerization interface appear to be sensitive to the crystal packing environment. The highly unexpected rearrangement within the extended hydrophobic interface does change the contact surface area but keeps the number of hydrophobic contacts about the same and will therefore not require significant energy input. The conformational flexibility most likely is of functional significance for the broad substrate specificity of EndoVII. Binding of sulphate ions in the mutant structure and their positions relative to the active-site metal ions and residues known to be essential for catalysis allows us to propose a possible catalytic mechanism. A comparison with the active-site geometries of other magnesium-dependent nucleases, among them the homing endonuclease I-PpoI and Serratia endonuclease, shows common features, suggesting related catalytic mechanisms.     

Initiation of heteroduplex-loop repair by T4-encoded endonuclease VII in vitro.

Heteroduplex DNAs with single-stranded loops of 51 nt or 8 nt were constructed in vitro and used in reactions with purified endonuclease VII (endo VII) from phage T4. The enzyme makes double-strand breaks by introducing pairs of staggered nicks flanking the loops. Regardless of loop-size the nicking sites map exclusively at the 3' side of the loop in the looping strand and at the 3' side of the base of the loop in the non-looping strand. The number of potential cleavage sites is small (less than 5) and their distribution depends on DNA sequence. The two closest staggered nicks are 4 bp apart, 2 bp on either side of the loop. Nicking always occurs in the double-stranded part of the molecules; the single-stranded loops are not attacked by endo VII. The nicks are introduced in a stepwise fashion and selection of the strand for the first nick depends on the sequence of 31 base pairs flanking the loops.     

Metal ion binding in the active site of the junction-resolving enzyme T7 endonuclease I in the presence and in the absence of DNA

Endonuclease I of bacteriophage T7 is a DNA junction-resolving enzyme. We have previously used crystallography to demonstrate the binding of two manganese ions into the active site that is formed by three carboxylate (Glu 20, Asp 55 and Glu 65) and a lysine residue (Lys 67). Endonuclease I is active in the presence of magnesium, manganese, iron (II) and cobalt (II) ions, weakly active in the presence of nickel, copper (II) and zinc ions, and completely inactive in the presence of calcium ions. However, using calorimetry, we have observed the binding of two calcium ions to the free enzyme in a manner very similar to the binding of manganese ions. In the presence of iron (II) ions, we have obtained a cleavage of the continuous strands of a junction bound by endonuclease I, at sites close to (but not identical with) enzyme-induced hydrolysis. The results suggest that this arises from attack by locally generated hydroxyl radicals, arising from iron (II) ions bound into the active site. This therefore provides an indirect way of examining metal ion binding in the enzyme-junction complex. Ion binding in free protein (by calorimetry) and the enzyme-junction complex (iron-induced cleavage) have been studied in series of active-site mutants. Both confirm the importance of the three carboxylate ligands, and the lack of a requirement for Lys67 for the ion binding. Calorimetry points to particularly critical role of Asp55, as mutation completely abolishes all binding of both manganese and calcium ions.     

In vivo restriction. Sequence and structure of endonuclease II-dependent cleavage sites in bacteriophage T4 DNA.

Endonuclease II of bacteriophage T4 is required for in vivo restriction of cytosine-containing DNA from its host, Escherichia coli, (as well as from phage mutants lacking cytosine modification), normally the first step in the reutilization of host DNA nucleotides for synthesis of phage DNA in infected cells. The phage cytosine-DNA is fragmented incompletely to yield genetically defined fragments. This restriction is different from that of type I, II, or III restriction enzymes. We have located seven major endonuclease II-dependent restriction sites in the T4 genome, of which three were analyzed in detail; in addition, abundant sites were cleaved in less than or equal to 5% of all molecules. Sites I, II, and III shared the sequence 5'-CCGNNTTGGC-3' and were cleaved in about 25% (I and III) and 65% (II) of all molecules, predominantly staggered around the first or second of the central unspecified base pairs to yield fragments with one 5' base. The less frequently cleaved sites I and III deviated from site II in predicted helical structure when viewed from the consensus strand, and in sequence when viewed from the opposite strand. Thus, interaction with a particular helical structure as well as recognition of the bases in DNA appears important for efficient cleavage.     

DNA recognition and cleavage by the EcoP15 restriction endonuclease.

EcoP15 is a restriction-modification enzyme coded by the P15 plasmid of Escherichia coli. We have determined the sites recognized by this enzyme on pBR322 and simian virus 40 DNA. The enzyme recognizes the sequence:

In restriction, the enzyme cleaves the DNA 25 to 26 base-pairs 3′ to this sequence to leave single-stranded 5′ protrusions two bases long.     

The use of resolvases T4 endonuclease VII and T7 endonuclease I in mutation detection

Mutation and polymorphism detection is of increasing importance in the field of molecular genetics. This is reflected by the plethora of chemical, enzymatic, and physically based methods of mutation detection. The ideal method would detect mutations in large fragments of DNA and position them to single base-pair (bp) accuracy. Few methods are able to quickly screen kilobase lengths of DNA and position the mutation at the same time. The Enzyme Mismatch Cleavage (EMC) method of mutation detection is able to reliably detect nearly 100% of mutations in DNA fragments as large as 2 kb and position them to within 6 bp. This method exploits the activity of a resolvase enzyme from T4, T4 endonuclease VII, and more recently, a second bacteriophage resolvase, T7 endonuclease I. The technique uses these enzymes to digest heteroduplex DNA formed by annealing wild-type and mutant DNA. Digestion fragments indicate the presence, and the position, of any mutations. The method is robust and reliable and much faster and cheaper than sequencing. These attributes have resulted in its increasing use in the field of mutation detection.     

Large-scale preparation of T4 endonuclease VII from over-expressing bacteria

Endonuclease VII is the product of gene 49 of phage T4 and was the first enzyme shown to resolve Holliday structures in vitro [Mizuuchi, K. et al. (1982) Cell 29, 357-365]. Low amounts of the enzyme were originally purified from phage-infected cells [Kemper, B. & Garabett, M. (1981) Eur. J. Biochem. 115, 123-131]. We now report a purification procedure for milligram amounts of cloned endonuclease VII expressed in Escherichia coli with gene 49 under the control of a temperature-inducible promoter on a plasmid system [Tomaschewski, J. (1988) PhD Thesis, University of Bochum, FRG]. The protein was purified 500-fold from crude extracts in five steps with a recovery of 15%. The steps include (a) poly(ethyleneglycol)/dextran two-phase separation; (b) DEAE-cellulose; (c) single-stranded DNA-agarose; (d) Mono-Q and (e) Mono-S chromatography. The final protein was more than 98% pure as estimated from SDS/PAGE analysis. The protein has an apparent molecular mass of 17.8 kDa on SDS-containing polyacrylamide gels and 36 kDa when determined by gel filtration or sedimentation through sucrose gradients in the presence of high salt (600 mM NaCl). In the absence of additional salt, the enzyme has a tendency to aggregate and products of molecular masses differing in steps of about 18 kDa appear on SDS-containing polyacrylamide gels.     

Modes of DNA cleavage by the EcoRV restriction endonuclease

The mechanism of action of the EcoRV restriction endonuclease at its single recognition site on the plasmid pAT153 was analyzed by kinetic methods. In reactions at pH 7.5, close to the optimum for this enzyme, both strands of the DNA were cut in a single concerted reaction: DNA cut in only one strand of the duplex was neither liberated from the enzyme during the catalytic turnover nor accumulated as a steady-state intermediate. In contrast, reactions at pH 6.0 involved the sequential cutting of the two strands of the DNA. Under these conditions, DNA cut in a single strand was an obligatory intermediate in the reaction pathway and a fraction of the nicked DNA dissociated from the enzyme during the turnover. The different reaction profiles are shown to be consistent with a single mechanism in which the kinetic activity of each subunit of the dimeric protein is governed by its affinity for Mg2+ ions. At pH 7.5, Mg2+ is bound to both subunits of the dimer for virtually the complete period of the catalytic turnover, while at pH 6.0 Mg2+ is bound transiently to one subunit at a time. The kinetics of the EcoRV nuclease were unaffected by DNA supercoiling.     

Ensuring productive resolution by the junction-resolving enzyme RuvC: large enhancement of the second-strand cleavage rate

RuvC is the principal junction-resolving enzyme of Escherichia coli, cleaving four-way DNA junctions created in homologous recombination. It binds with structural specificity to DNA junctions as a dimer, whereupon each subunit cleaves a phosphodiester bond of diametrically disposed strands. To generate a productive resolution event, these cleavages must be symmetrically located with respect to the point of strand exchange, and in the context of a branch-migrating junction, this requires near-simultaneous cleavage by the two subunits. Using a supercoil-stabilized cruciform as a substrate, we have analyzed the kinetics of strand cleavage. Coordinated bilateral cleavage is not essential in RuvC action, because a heterodimer comprising active and inactive subunits is active in unilateral cleavage. However, in operational terms, fully active RuvC appears to introduce simultaneous cleavages of two strands, because the rate of second-strand cleavage is accelerated by a factor of almost 150 relative to the first. We suggest that relief of strain following the first cleavage could lead to acceleration of subsequent cleavage, and show that DNA junctions rendered more flexible by the presence of strand breaks or bulges are subject to faster cleavage by RuvC. Cleavage of one strand of a junction generated in situ by the action of RuvC can accelerate cleavage at an intrinsically poor site by a factor of 500. Very large rate enhancement of second-strand cleavage by RuvC is likely to be essential to ensure productive resolution of a junction that is being actively branch migrated by the RuvAB machinery.