Structure-function correlation for the EcoRV restriction enzyme: from non-specific binding to specific DNA cleavage

Electrochemical DNA Cleavage Sensing for EcoRV Activity and Inhibition with an ERGO Electrode

An electrochemically reduced graphene oxide (ERGO) electrode-based electrochemical assay was developed for rapid, sensitive, and straightforward analysis of both activity and inhibition of the endonuclease EcoRV. The procedure uses a DNA substrate designed for EcoRV, featuring a double-stranded DNA (dsDNA) region labeled with methylene blue (MB) and a single-stranded DNA (ssDNA) region immobilized on the ERGO surface. The ERGO electrode, immobilized with the DNA substrate, was subsequently exposed to a sample containing EcoRV. Upon enzymatic hydrolysis, the cleaved dsDNA fragments were detached from the ERGO surface, leading to a decrease in the MB concentration near the electrode. This diminished the electron transfer efficiency for MB reduction, resulting in a decreased reduction current. This assay demonstrates excellent specificity and high sensitivity, with a limit of detection (LOD) of 9.5 × 10-3 U mL-1. Importantly, it can also measure EcoRV activity in the presence of aurintricarboxylic acid, a known inhibitor, highlighting its potential for drug discovery and clinical diagnostic applications.

Microscopic insight to specificity of metal ion cofactor in DNA cleavage by restriction endonuclease EcoRV

Restriction endonucleases protect bacterial cells against bacteriophage infection by cleaving the incoming foreign DNA into fragments. In presence of Mg²⁺ ions, EcoRV is able to cleave the DNA but not in presence of Ca²⁺ , although the protein binds to DNA in presence of both metal ions. We make an attempt to understand this difference using conformational thermodynamics. We calculate the changes in conformational free energy and entropy of conformational degrees of freedom, like DNA base pair steps and dihedral angles of protein residues in Mg²⁺ (A)-EcoRV-DNA complex compared to Ca²⁺ (S)-EcoRV-DNA complex using all-atom molecular dynamics (MD) trajectories of the complexes. We find that despite conformational stability and order in both complexes, the individual degrees of freedom behave differently in the presence of two different metal ions. The base pairs in cleavage region are highly disordered in Ca²⁺ (S)-EcoRV-DNA compared to Mg²⁺ (A)-EcoRV-DNA. One of the acidic residues ASP90, coordinating to the metal ion in the vicinity of the cleavage site, is conformationally destabilized and disordered, while basic residue LYS92 gets conformational stability and order in Ca²⁺ (S) bound complex than in Mg²⁺ (A) bound complex. The enhanced fluctuations hinder placement of the metal ion in the vicinity of the scissile phosphate of DNA. Similar loss of conformational stability and order in the cleavage region is observed by the replacement of the metal ion. Considering the placement of the metal ion near scissile phosphate as requirement for cleavage action, our results suggest that the changes in conformational stability and order of the base pair steps and the protein residues lead to cofactor sensitivity of the enzyme. Our method based on fluctuations of microscopic conformational variables can be applied to understand enzyme activities in other protein-DNA systems.

Assaying multiple restriction endonucleases functionalities and inhibitions on DNA microarray with multifunctional gold nanoparticle probes

Herein, a double-stranded (ds) DNA microarray-based resonance light scattering (RLS) assay with multifunctional gold nanoparticle (GNP) probes has been developed for studying restriction endonuclease functionality and inhibition. Because of decreasing significantly melting temperature, the enzyme-cleaved dsDNAs easily unwind to form single-stranded (ss) DNAs. The ssDNAs are hybridized with multiplex complementary ssDNAs functionalized GNP probes followed by silver enhancement and RLS detection. Three restriction endonucleases (EcoRI, BamHI and EcoRV) and three potential inhibitors (doxorubicin hydrochloride (DOX), ethidium bromide (EB) and an EcoRI-derived helical peptide (α4)) were selected to demonstrate capability of the assay. Enzyme activities of restriction endonucleases are detected simultaneously with high specificity down to the limits of 2.0 × 10(-2)U/mL for EcoRI, 1.1 × 10(-2)U/mL for BamHI and 1.6 × 10(-2)U/mL for EcoRV, respectively. More importantly, the inhibitory potencies of three inhibitors are showed quantitatively, indicating that our approach has great promise for high-throughput screening of restriction endonuclease inhibitors.

The human monocytic leukemia zinc finger histone acetyltransferase domain contains DNA-binding activity implicated in chromatin targeting

The human monocytic leukemia zinc finger (MOZ) protein is an essential transcriptional coactivator and histone acetyltransferase (HAT) that plays a primary role in the differentiation of erythroid and myeloid cells and is required to maintain hematopoietic stem cells. Chromosomal translocations involving the HAT-encoded region are also associated with acute myeloid leukemia. Here we present the x-ray crystal structure of the MOZ HAT domain and related biochemical studies. We find that the HAT domain contains a central region that is structurally and functionally conserved with the yeast MYST HAT protein Esa1, but contains more divergent N- and C-terminal regions harboring a TFIIIA-type zinc finger and helix-turn-helix DNA-binding motifs. Solution DNA-binding and acetyltransferase activity assays, in concert with mutagenesis, confirm that the MOZ HAT domain binds strongly to DNA through the zinc finger and helix-turn-helix motifs and that DNA binding and catalysis are not mutually exclusive. Consistent with the DNA-binding properties of MOZ, we also show that MOZ is able to acetylate nucleosomes and free histones equally well, whereas other HATs prefer free histones. Our results reveal, for the first time, that enzymatic and DNA-targeting activities can be contained within the same chromatin regulatory domain.

Use of plasmon coupling to reveal the dynamics of DNA bending and cleavage by single EcoRV restriction enzymes

Pairs of Au nanoparticles have recently been proposed as "plasmon rulers" based on the dependence of their light scattering on the interparticle distance. Preliminary work has suggested that plasmon rulers can be used to measure and monitor dynamic distance changes over the 1- to 100-nm length scale in biology. Here, we substantiate that plasmon rulers can be used to measure dynamical biophysical processes by applying the ruler to a system that has been investigated extensively by using ensemble kinetic measurements: the cleavage of DNA by the restriction enzyme EcoRV. Temporal resolutions of up to 240 Hz were obtained, and the end-to-end extension of up to 1,000 individual dsDNA enzyme substrates could be simultaneously monitored for hours. The kinetic parameters extracted from our single-molecule cleavage trajectories agree well with values obtained in bulk through other methods and confirm well known features of the cleavage process, such as DNA bending before cleavage. Previously unreported dynamical information is revealed as well, for instance, the degree of softening of the DNA just before cleavage. The unlimited lifetime, high temporal resolution, and high signal/noise ratio make the plasmon ruler a unique tool for studying macromolecular assemblies and conformational changes at the single-molecule level.

Characteristics of MuA transposase-catalyzed processing of model transposon end DNA hairpin substrates

Bacteriophage Mu uses non-replicative transposition for integration into the host's chromosome and replicative transposition for phage propagation. Biochemical and structural comparisons together with evolutionary considerations suggest that the Mu transposition machinery might share functional similarities with machineries of the systems that are known to employ a hairpin intermediate during the catalytic steps of transposition. Model transposon end DNA hairpin substrates were used in a minimal-component in vitro system to study their proficiency to promote Mu transpososome assembly and subsequent MuA-catalyzed chemical reactions leading to the strand transfer product. MuA indeed was able to assemble hairpin substrates into a catalytically competent transpososome, open the hairpin ends and accurately join the opened ends to the target DNA. The hairpin opening and transposon end cleavage reactions had identical metal ion preferences, indicating similar conformations within the catalytic center for these reactions. Hairpin length influenced transpososome assembly as well as catalysis: longer loops were more efficient in these respects. In general, MuA's proficiency to utilize different types of hairpin substrates indicates a certain degree of flexibility within the transposition machinery core. Overall, the results suggest that non-replicative and replicative transposition systems may structurally and evolutionarily be more closely linked than anticipated previously.

Multiple roles for ATP hydrolysis in nucleic acid modifying enzymes

Enzymes that operate on nucleic acid substrates are faced with the unusual situation where the substrate is much larger than themselves. Despite the potential to promote catalysis by utilizing the significant binding energy available through their interaction with substrate, ATP hydrolysis is frequently a part of the mechanism of these enzymes. The reasons for this have become clearer in recent years, and a surprising range of ways that these enzymes utilize the free energy of hydrolysis of ATP has been revealed. This review describes these different mechanisms in the context of the biochemical reactions that they support.

The small subunit of M. AquI is responsible for sequence-specific DNA recognition and binding in the absence of the catalytic domain

AquI DNA methyltransferase (M. AquI) catalyzes the transfer of a methyl group from S-adenosyl-L-methionine to the C5 position of the outermost deoxycytidine base in the DNA sequence 5'-CCCGGG-3'. M. AquI is a heterodimer in which the polypeptide chain is separated at the junction between the two equivalent structural domains in the related enzyme M. HhaI. Recently, we reported the subcloning, overexpression, and purification of the subunits (alpha and beta) of M. AquI separately. Here we describe the DNA binding properties of M. AquI. The results presented here indicate that the beta subunit alone contains all of the information for sequence-specific DNA recognition and binding. The first step in the sequence-specific recognition of DNA by M. AquI involves the formation of binary complex with the target recognition domain in conjunction with conserved sequence motifs IX and X, found in all known C5 DNA methyltransferases, contained in the beta subunit. The alpha subunit enhances the binding of the beta subunit to DNA specifically and nonspecifically. It is likely that the addition of the alpha subunit to the beta subunit stabilizes the conformation of the beta subunit and thereby enhances its affinity for DNA indirectly. Addition of S-adenosyl-L-methionine and its analogues S-adenosyl-L-homocysteine and sinefungin enhances binding, but only in the presence of the alpha subunit. These compounds did not have any effect on DNA binding by the beta subunit alone. Using a 30-mer oligodeoxynucleotide substrate containing 5-fluorodeoxycytidine (5-FdC), it was found that the beta subunit alone did not form a covalent complex with its specific sequence in the absence or presence of S-adenosyl-L-methionine. However, the addition of the alpha subunit to the beta subunit led to the formation of a covalent complex with specific DNA sequence containing 5-FdC.

The energetics of the interaction of BamHI endonuclease with its recognition site GGATCC

The interaction of BamHI endonuclease with DNA has been studied crystallographically, but has not been characterized rigorously in solution. The enzyme binds in solution as a homodimer to its recognition site GGATCC. Only six base-pairs are directly recognized, but binding affinity (in the absence of the catalytic cofactor Mg(2+)) increases 5400-fold as oligonucleotide length increases from 10 to 14 bp. Binding is modulated by sequence context outside the recognition site, varying about 30-fold from the bes t (GTG or TAT) to the worst (CGG) flanking triplets. BamHI, EcoRI and EcoRV endonucleases all have different context preferences, suggesting that context affects binding by influencing the free energy levels of the complexes rather than that of the free DNA. Ethylation interference footprinting in the absence of divalent metal shows a localized and symmetrical pattern of phosphate contacts, with strong contacts at NpNpNpGGApTCC. In the presence of Mg(2+), first-order cleavage rate constants are identical in the two GGA half-sites, are the same for the two nicked intermediates and are unaffected by substrate length in the range 10-24 bp. DNA binding is strongly enhanced by mutations D94N, E111A or E113K, by binding of Ca(2+) at the active site, or by deletion of the scissile phosphate GpGATCC, indicating that a cluster of negative charges at the catalytic site contributes at least 3-4 kcal/mol of unfavorable binding free energy. This electrostatic repulsion destabilizes the enzyme-DNA complex and favors metal ion binding and progression to the transition state for cleavage.

Mutational analysis of RAG1 and RAG2 identifies three catalytic amino acids in RAG1 critical for both cleavage steps of V(D)J recombination

RAG1 and RAG2 initiate V(D)J recombination, the process of rearranging the antigen-binding domain of immunoglobulins and T-cell receptors, by introducing site-specific double-strand breaks (DSB) in chromosomal DNA during lymphocyte development. These breaks are generated in two steps, nicking of one strand (hydrolysis), followed by hairpin formation (transesterification). The nature and location of the RAG active site(s) have remained unknown. Because acidic amino acids have a critical role in catalyzing DNA cleavage by nucleases and recombinases that require divalent metal ions as cofactors, we hypothesized that acidic active site residues are likewise essential for RAG-mediated DNA cleavage. We altered each conserved acidic amino acid in RAG1 and RAG2 by site-directed mutagenesis, and examined >100 mutants using a combination of in vivo and in vitro analyses. No conserved acidic amino acids in RAG2 were critical for catalysis; three RAG1 mutants retained normal DNA binding, but were catalytically inactive for both nicking and hairpin formation. These data argue that one active site in RAG1 performs both steps of the cleavage reaction. Amino acid substitution experiments that changed the metal ion specificity suggest that at least one of these three residues contacts the metal ion(s) directly. These data suggest that RAG-mediated DNA cleavage involves coordination of divalent metal ion(s) by RAG1.

DNA restriction dependent on two recognition sites: activities of the SfiI restriction-modification system in Escherichia coli

In contrast to many type II restriction enzymes, dimeric proteins that cleave DNA at individual recognition sites 4-6 bp long, the SfiI endonuclease is a tetrameric protein that binds to two copies of an elongated sequence before cutting the DNA at both sites. The mode of action of the SfiI endonuclease thus seems more appropriate for DNA rearrangements than for restriction. To elucidate its biological function, strains of Escherichia coli expressing the SfiI restriction-modification system were transformed with plasmids carrying SfiI sites. The SfiI system often failed to restrict the survival of a plasmid with one SfiI site, but plasmids with two or more sites were restricted efficiently. Plasmids containing methylated SfI sites were not restricted. No rearrangements of the plasmids carrying SfiI sites were detected among the transformants. Hence, provided the target DNA contains at least two recognition sites, SfiI displays all of the hallmarks of a restriction-modification system as opposed to a recombination system in E. coli cells. The properties of the system in vivo match those of the enzyme in vitro. For both restriction in vivo and DNA cleavage in vitro, SfiI operates best with two recognition sites on the same DNA.

Conformational transitions and structural deformability of EcoRV endonuclease revealed by crystallographic analysis

The structures of wild-type and mutant forms of the unliganded EcoRV endonuclease dimer have been determined at 2.4 A resolution in a new crystal lattice. Comparison of these structures with that of the free enzyme determined with different packing constraints shows that the conformations of the domain interfaces are not conserved between crystal forms. The unliganded enzyme and the enzyme-DNA complex delineate two distinct quaternary states separated by a 25 degrees intersubunit rotation, but considerable conformational heterogeneity, of the order of 10 degrees domain rotations, exists within each of these states. Comparison of the free enzyme structure between the two crystal forms further reveals that the C-terminal 28 amino acid residues are disordered and undergo an extensive local folding transition upon DNA binding. Introduction of the mutation T93A at the DNA-binding cleft causes large-scale effects on the protein conformation. Structural changes in the mutated unliganded enzyme propagate some 20 to 25 A to the dimerization interface and lead to a rearrangement of monomer subunits. Comparative analysis of these structures, a new structure of the enzyme cocrystallized with DNA and calcium ions, and previously determined cocrystal structures suggests important roles for a number of amino acid residues in facilitating the intersubunit motions and local folding transitions. In particular, the T93A structure reveals a pathway through the protein, by which DNA-binding may cause the domain movements required for proper alignment of catalytic groups. The key active-site residue Glu45 is located on a flexible helix inside this pathway, and this provides a direct means by which essential catalytic functions are coupled to the protein conformational change. It appears that indirect perturbation of the Glu45 conformation via an altered quaternary structure may be a contributing factor to the decreased catalytic efficiency of T93A, and this mechanism may also explain the diminished activities of other active site variants of EcoRV.

Specific binding by EcoRV endonuclease to its DNA recognition site GATATC

Restriction endonuclease EcoRV has been reported to be unable to distinguish its specific DNA site, GATATC, from non-specific DNA sites in the absence of the catalytic cofactor Mg2+, and thus to exercise sequence specificity solely in the catalytic step. In contrast, we show here that under appropriate conditions of pH and salt concentration, specific complexes with oligonucleotides containing the GATATC site can be detected by either filter-binding or gel-retardation. Equilibrium binding constants (K(A)) are easily measured by both direct equilibrium and equilibrium-competition methods. The preference for "specific" over "non-specific" binding at pH 7 in the absence of divalent cations is about 1000-fold (per mole of oligonucleotide) or 12,000-fold (per mole of binding sites). Ethylation-interference footprinting shows that the "specific" complex includes strong contacts to the phosphate groups GpApTpApTC. Specific DNA binding is strongly pH-dependent, decreasing about 15-fold for each increase of one pH unit above pH 6, but non-specific binding is not; thus, binding specificity decreases with increasing pH. Gel retardation and filter-binding at pH < or = 7 yield essentially identical values of K(A) for specific-site binding, but at pH > 7 gel retardation significantly underestimates K(A). Specific-site binding is stimulated about 700-fold by Ca2+ (not a cofactor for cleavage), but with non-cleavable 3'-phosphorothiolate and 4'-thiodeoxyribose derivatives whose response to Ca2+ is similar to that of the parent oligonucleotide, Mg2+ stimulates binding only fourfold and twofold, respectively. Thus, binding specificity is not dramatically enhanced by Mg2+. Taking into account discrimination in binding and in the first-order rate constant for phosphodiester bond scission, the overall discrimination exercised against the incorrect site GTTATC is about 10(7)-fold. EcoRV endonuclease is thus not a "new paradigm" for site-specific interaction without binding specificity, but like other type II restriction endonucleases achieves sequence specificity by discriminating both in DNA binding and in catalysis.

Influence of the phosphate backbone on the recognition and hydrolysis of DNA by the EcoRV restriction endonuclease. A study using oligodeoxynucleotide phosphorothioates

A set of phosphorothioate-containing oligonucleotides based on pGACGATATCGTC, a self-complementary dodecamer that contains the EcoRV recognition sequence (GATATC), has been prepared. The phosphorothioate group has been individually introduced at the central nine phosphate positions and the two diastereomers produced at each site separated and purified. The Km and Vmax values found for each of these modified DNA molecules with the EcoRV restriction endonuclease have been determined and compared with those seen for the unmodified all-phosphate-containing dodecamer. This has enabled an evaluation of the roles that both of the non-esterified oxygen atoms in the individual phosphates play in DNA binding and hydrolysis by the endonuclease. The results have also been compared with crystal structures of the EcoRV endonuclease, complexed with an oligodeoxynucleotide, to allow further definition of phosphate group function during substrate binding and turnover. For further study, see the related article "Probing the Indirect Readout of the Restriction Enzyme EcoRV: Mutational Analysis of Contacts to the DNA Backbone" (Wenz, A., Jeltsch, A., and Pingoud, A. (1996) J. Biol. Chem. 271, 5565-5573).

Heterogeneity in molecular recognition by restriction endonucleases: osmotic and hydrostatic pressure effects on BamHI, Pvu II, and EcoRV specificity

The cleavage specificity of the Pvu II and BamHI restriction endonucleases is found to be dramatically reduced at elevated osmotic pressure. Relaxation in specificity of these otherwise highly accurate and specific enzymes, previously termed "star activity," is uniquely correlated with osmotic pressure between 0 and 100 atmospheres. No other colligative solvent property exhibits a uniform correlation with star activity for all of the compounds tested. Application of hydrostatic pressure counteracts the effects of osmotic pressure and restores the natural selectivity of the enzymes for their canonical recognition sequences. These results indicate that water solvation plays an important role in the site-specific recognition of DNA by many restriction enzymes. Osmotic pressure did not induce an analogous effect on the specificity of the EcoRV endonuclease, implying that selective hydration effects do not participate in DNA recognition in this system. Hydrostatic pressure was found to have little effect on the star activity induced by changes in ionic strength, pH, or divalent cation, suggesting that distinct mechanisms may exist for these observed alterations in specificity. Recent evidence has indicated that BamHI and EcoRI share similar structural motifs, while Pvu II and EcoRV belong to a different structural family. Evidently, the use of hydration water to assist in site-specific recognition is a motif neither limited to nor defined by structural families.

Divalent metal ions at the active sites of the EcoRV and EcoRI restriction endonucleases

Restriction enzymes cannot cleave DNA without a metal ion cofactor. The specificities of the EcoRV and EcoRI endonucleases for metals were studied by measuring DNA cleavage rates with several metal ions and with combinations of metal ions. Both EcoRV and EcoRI had optimal activities with Mg2+, were less active with several other ions including Mn2+, and had virtually no activity with Ca2+. But the activities of EcoRV and EcoRI with either Mg2+ or Mn2+ were perturbed by Ca2+. For EcoRI, both Mg2+- and Mn(2+)-dependent activities, at both cognate and noncognate sites, were all inhibited by Ca2+. The activity of EcoRV at its recognition site with Mg2+ was also inhibited by Ca2+. But the Mn(2+)-dependent reaction at the EcoRV recognition site was stimulated by Ca2+. EcoRV activities at noncognate sites with either Mg2+ or Mn2+ displayed a biphasic response to Ca2+: stimulation at low concentrations of Ca2+ and inhibition at high concentrations. These observations, together with the known structures of the proteins, indicate that EcoRI needs only one metal ion per active site and is inactive when Mg2+ is displaced by Ca2+, while EcoRV needs two and that the displacement of one by Ca2+ can enhance activity. We propose a mechanism for phosphodiester hydrolysis by EcoRV that involves two metal ions.

Mg2+ binding to the active site of EcoRV endonuclease: a crystallographic study of complexes with substrate and product DNA at 2 A resolution

The type II restriction endonuclease EcoRV was crystallized as a complex with the substrate DNA undecamer AAAGATATCTT (recognition sequence underlined). These crystals diffract to much better resolution (2 A) than was the case for the previously reported complex with the decamer GGGATATCCC [Winkler, F. K., Banner, D. W., Oefner, C., Tsernoglou, D., Brown, R. S., Heathman, S. P., Bryan, R. K., Martin, P. D., Petratos, K., & Wilson, K. S. (1993) EMBO J. 12, 1781-1795]. The crystal structure contains one dimer complex in the asymmetric unit and was solved by molecular replacement. The same kinked DNA conformation characteristic for enzyme-bound cognate DNA is observed. Crystals, soaked with Mg2+, show the essential cofactor bound at only one active site of the dimer, and the DNA is not cleaved. The Mg2+ has one oxygen from the scissile phosphodiester group and two carboxylate oxygens, one form Asp74 and one from Asp90, in its octahedral ligand sphere. The scissile phosphodiester group is pulled by 1 A toward the Mg2+. After substrate cleavage in solution, isomorphous crystals containing the enzyme--product--Mg2+ complex were obtained. In this structure, each of the 5'-phosphate groups is bound to two Mg2+. The kinked DNA conformation is essentially maintained, but the two central adenines, 3' to the cleavage sites, form an unusual cross-strand base stacking. The structures have been refined to R factors of 0.16 at 2.1-2.0 A resolution maintaining very good stereochemistry. On the basis of these structures and inspired by recent kinetic data [Vipond, I. B., & Halford, S. E. (1994) Biochemistry (second paper of three in this issue)], we have constructed a transition state model with two metals bound to the scissile phosphorane group.

Protein engineering of the restriction endonuclease EcoRV: replacement of an amino acid residue in the DNA binding site leads to an altered selectivity towards unmodified and modified substrates

According to the crystal structure analysis of a specific EcoRV/DNA complex, the thymine residues of the recognition sequence -GATATC- are not in direct contact with any amino acid residue of the protein. However, several amino acid residues are sufficiently close that it seemed worthwhile trying to create variants of EcoRV with altered specificity by site-directed mutagenesis. Guided by molecular modelling we have replaced. Asn-188 in the catalytic center of EcoRV by Gln to produce a mutant with a relative preference (compared to wild type EcoRV) for substrates in which one thymine of the recognition sequence is replaced by uracil. We have purified and characterized the resulting N188Q mutant. The selectivity value for the engineered enzyme (the ratio of the kcat/KM values for -GATAUC- versus -GATATC-) differs from that of the wild type enzyme by a factor of more than 200.

High-specificity DNA cleavage agent: design and application to kilobase and megabase DNA substrates

Strategies to cleave double-stranded DNA at specific DNA sites longer than those of restriction endonucleases (longer than 8 base pairs) have applications in chromosome mapping, chromosome cloning, and chromosome sequencing--provided that the strategies yield high DNA-cleavage efficiency and high DNA-cleavage specificity. In this report, the DNA-cleaving moiety copper:o-phenanthroline was attached to the sequence-specific DNA binding protein catabolite activator protein (CAP) at an amino acid that, because of a difference in DNA bending, is close to DNA in the specific CAP-DNA complex but is not close to DNA in the nonspecific CAP-DNA complex. The resulting CAP derivative, OP26CAP, cleaved kilobase and megabase DNA substrates at a 22-base pair consensus DNA site with high efficiency and exhibited no detectable nonspecific DNA-cleavage activity.

Specificity of DNA recognition in the nucleoprotein complex for site-specific recombination by Tn21 resolvase

Resolvases from Tn3-like transposons catalyse site-specific recombination at res sites. Each res site has 3 binding sites for resolvase, I, II, and III. The res sites in Tn3 and Tn21 have similar structures at I and II but they differ at III. Mutagenesis of the Tn21 res site showed that sub-site III is essential for recombination though the sequences in III that are recognized by Tn21 resolvase are positioned differently from the equivalent sequences in the Tn3 site. The deletion of III caused a 1,000-fold drop in the rate of recombination. But other mutations at III, changing 3 or 4 consecutive base pairs, caused only 1.5- to 4-fold decreases in rate, even when the mutations were in target sequences for this helix-turn-helix protein. The reason why Tn21 resolvase has similar activities at a number of different DNA sequences may be due to the multiplicity of protein-protein and protein-DNA interactions in its recombinogenic complex. This lack of precision may be a general feature of nucleoprotein complexes.