Recombination by resolvase to analyse DNA communications by the SfiI restriction endonuclease.

The SfiI endonuclease differs from other type II restriction enzymes by cleaving DNA concertedly at two copies of its recognition site, its optimal activity being with two sites on the same DNA molecule. The nature of this communication event between distant DNA sites was analysed on plasmids with recognition sites for SfiI interspersed with recombination sites for resolvase. These were converted by resolvase to catenanes carrying one SfiI site on each ring. The catenanes were cleaved by SfiI almost as readily as a single ring with two sites, in contrast to the slow reactions on DNA rings with one SfiI site. Interactions between SfiI sites on the same DNA therefore cannot follow the DNA contour and, instead, must stem from their physical proximity. In buffer lacking Mg2+, where SfiI is inactive while resolvase is active, the addition of SfiI to a plasmid with target sites for both proteins blocked recombination by resolvase, due to the restriction enzyme bridging its sites and thus isolating the sites for resolvase into separate loops. The extent of DNA looping by SfiI matched its extent of DNA cleavage in the presence of Mg2+.     

DNA cleavage reactions by type II restriction enzymes that require two copies of their recognition sites

Several type II restriction endonucleases interact with two copies of their target sequence before they cleave DNA. Three such enzymes, NgoMIV, Cfr10I and NaeI, were tested on plasmids with one or two copies of their recognition sites, and on catenanes containing two interlinked rings of DNA with one site in each ring. The enzymes showed distinct patterns of behaviour. NgoMIV and NaeI cleaved the plasmid with two sites faster than that with one site and the catenanes at an intermediate rate, while Cfr10I gave similar steady-state rates on all three substrates. Both Cfr10I and NgoMIV converted the majority of the substrates with two sites directly to the products cut at both sites, while NaeI cleaved just one site at a time. All three enzymes thus synapse two DNA sites through three-dimensional space before cleaving DNA. With Cfr10I and NgoMIV, both sites are cleaved in one turnover, in a manner consistent with their tetrameric structures, while the cleavage of a single site by NaeI indicates that the second site acts not as a substrate but as an activator, as reported previously. The complexes spanning two sites have longer lifetimes on catenanes with one site in each ring than on circular DNA with two sites, which indicates that the catenanes have more freedom for site juxtaposition than plasmids with sites in cis.     

Probing the dynamics of restriction endonuclease NgoMIV‐DNA interaction by single‐molecule FRET

Many type II restriction endonucleases require two copies of their recognition sequence for optimal activity. Concomitant binding of two DNA sites by such an enzyme produces a DNA loop. Here we exploit single‐molecule Förster resonance energy transfer (smFRET) of surface‐immobilized DNA fragments to study the dynamics of DNA looping induced by tetrameric endonuclease NgoMIV. We have employed a DNA fragment with two NgoMIV recognition sites and a FRET dye pair such that upon protein‐induced DNA looping the dyes are brought to close proximity resulting in a FRET signal. The dynamics of DNA ‐ NgoMIV interactions proved to be heterogeneous, with individual smFRET trajectories exhibiting broadly different average looped state durations. Distinct types of the dynamics were attributed to different types of DNA ‐ protein complexes, mediated either by one NgoMIV tetramer simultaneously bound to two specific sites (“slow” trajectories) or by semi‐specific interactions of two DNA‐bound NgoMIV tetramers (“fast” trajectories), as well as to conformational heterogeneity of individual NgoMIV molecules.     

Alternative geometries of DNA looping: an analysis using the SfiI endonuclease

Many processes are governed by proteins that bind to separate sites in DNA and loop out the intervening DNA, but the geometries of the loops have seldom been determined. The SfiI endonuclease cleaves DNA after interacting with two recognition sites, and is a favourable system for the analysis of DNA looping. A gel-shift assay was used here to examine the binding of SfiI to a series of linear DNA molecules containing two SfiI sites separated by 109-170 base-pairs. The complexes in which SfiI trapped a loop by binding to two sites in the same DNA were separated from the complexes containing SfiI bound to separate DNA molecules. Step-wise changes in the inter-site spacing generated two forms of the looped complex with different electrophoretic mobilities. The yields of each looped complex and the complexes from intermolecular synapses all varied cyclically with the inter-site spacing, with similar periodicities ( approximately 10.5 base-pairs) but with different phases. One looped complex predominated whenever the DNA between the sites needed to be underwound in order to produce the correct helical orientation of the binding sites. The other looped complex predominated whenever the intervening DNA needed to be overwound. We conclude that the former has trapped a right-handed loop with a negative node and the latter a left-handed loop with a positive node.     

Cooperativity mutants of the gamma delta resolvase identify an essential interdimer interaction

gamma delta resolvase, a transposon-encoded site-specific recombinase, catalyzes the resolution of the cointegrate intermediate of gamma delta transposition. The recombination reaction involves the formation of a catalytic nucleoprotein complex whose structure is determined by specific protein-DNA and protein-protein interactions. We have isolated many resolvase mutants and have identified four that are unable to mediate a subclass of higher order protein-protein interactions necessary for recombination. This mutant phenotype is characterized by an inability to catalyze recombination, a loss of cooperative binding to res DNA, and a failure to induce looping out of the DNA between two resolvase binding sites within res. The amino acid side chains identified by the cooperativity mutants cluster on a surface of the protein that mediates an interaction between resolvase dimers in a crystallographic tetramer. We have therefore identified a region of resolvase that mediates an interdimer protein-protein interaction necessary for the formation of the recombinogenic synaptic intermediate.     

Interplay of Protein Binding Interactions,DNA Mechanics,and Entropy in?DNA Looping Kinetics

DNA looping plays a key role in many fundamental biological processes, including gene regulation, recombination, and chromosomal organization. The looping of DNA is often mediated by proteins whose structural features and physical interactions can alter the length scale at which the looping occurs. Looping and unlooping processes are controlled by thermodynamic contributions associated with mechanical deformation of the DNA strand and entropy arising from thermal fluctuations of the conformation. To determine how these confounding effects influence DNA looping and unlooping kinetics, we present a theoretical model that incorporates the role of the protein interactions, DNA mechanics, and conformational entropy. We show that for shorter DNA strands the interaction distance affects the transition state, resulting in a complex relationship between the looped and unlooped state lifetimes and the physical properties of the looped DNA. We explore the range of behaviors that arise with varying interaction distance and DNA length. These results demonstrate how DNA deformation and entropy dictate the scaling of the looping and unlooping kinetics versus the J-factor, establishing the connection between kinetic and equilibrium behaviors. Our results show how the twist-and-bend elasticity of the DNA chain modulates the kinetics and how the influence of the interaction distance fades away at intermediate to longer chain lengths, in agreement with previous scaling predictions.     

Dynamics and consequences of DNA looping by the FokI restriction endonuclease

Genetic events often require proteins to be activated by interacting with two DNA sites, trapping the intervening DNA in a loop. While much is known about looping equilibria, only a few studies have examined DNA-looping dynamics experimentally. The restriction enzymes that cut DNA after interacting with two recognition sites, such as FokI, can be used to exemplify looping reactions. The reaction pathway for FokI on a supercoiled DNA with two sites was dissected by fast kinetics to reveal, in turn: the initial binding of a protein monomer to each site; the protein–protein association to form the dimer, trapping the loop; the subsequent phosphodiester hydrolysis step. The DNA motion that juxtaposes the sites ought on the basis of Brownian dynamics to take ~2 ms, but loop capture by FokI took 230 ms. Hence, DNA looping by FokI is rate limited by protein association rather than DNA dynamics. The FokI endonuclease also illustrated activation by looping: it cut looped DNA 400 times faster than unlooped DNA.     

Recombination by resolvase is inhibited by lac repressor simultaneously binding operators between res sites

The Tn3 resolvase requires that the two recombination (res) sites be aligned as direct repeats on the same molecule for efficient recombination to occur. To test whether resolvase must contact the DNA between res sites as predicted by tracking models, we have determined the sensitivity of recombination to protein diffusion blockades. Recombination between two res sites is unaffected either by lac repressor or bacteriophage T7 RNA polymerase being bound between them. Yet recombination is inhibited by lac repressor if the res site is bounded by a lac operator on both sides. We demonstrate that lac repressor will bind to more than one DNA site under the conditions used to assay recombination. This result suggests that lac repressor can inhibit resolvase by forming a DNA loop that isolates a res site topologically. These results do not support a tracking model for resolvase but suggest that the structure and topology of the DNA substrate is important in the formation of a synapse between res sites.     

Site-specific relaxation and recombination by the Tn3 resolvase: recognition of the DNA path between oriented res sites

We studied the dynamics of site-specific recombination by the resolvase encoded by the Escherichia coli transposon Tn3. The pure enzyme recombined supercoiled plasmids containing two directly repeated recombination sites, called res sites. Resolvase is the first strictly site-specific topoisomerase. It relaxed only plasmids containing directly repeated res sites; substrates with zero, one or two inverted sites were inert. Even when the proximity of res sites was ensured by catenation of plasmids with a single site, neither relaxation nor recombination occurred. The two circular products of recombination were catenanes interlinked only once. These properties of resolvase require that the path of the DNA between res sites be clearly defined and that strand exchange occur with a unique geometry. A model in which one subunit of a dimeric resolvase is bound at one res site, while the other searches along adjacent DNA until it encounters the second site, would account for the ability of resolvase to distinguish intramolecular from intermolecular sites, to sense the relative orientation of sites and to produce singly interlinked catenanes. Because resolvase is a type 1 topoisomerase, we infer that it makes the required duplex bDNA breaks of recombination one strand at a time.     

The Cfr10I restriction enzyme is functional as a tetramer.

It is thought that most of the type II restriction endonucleases interact with DNA as homodimers. Cfr10I is a typical type II restriction enzyme that recognises the 5'-Pu decreases CCGGPy sequence and cleaves it as indicated by the arrow. Gel-filtration and analytical ultracentrifugation data presented here indicate that Cfr10I is a homotetramer in isolation. The only SfiI restriction enzyme that recognises the long interrupted recognition sequence 5'-GGCCNNNNNGGCC has been previously reported to operate as a tetramer however, its structure is unknown. Analysis of Cfr10I crystals revealed that a single molecule in the asymmetric unit is repeated by D2 symmetry to form a tetramer. To determine whether the packing of the Cfr10I in the crystal reflects the quaternary structure of the protein in solution, the tryptophan W220 residue located at the putative dimer-dimer interface was mutated to alanine, and the structural and functional consequences of the substitution were analysed. Equilibrium sedimentation experiments revealed that, in contrast to the wild-type Cfr10I, the W220A mutant exists in solution predominantly as a dimer. In addition, the tetramer seems to be a catalytically important form of Cfr10I, since the DNA cleavage activity of the W220A mutant is < 0.1% of that of the wild-type enzyme. Further, analysis of plasmid DNA cleavage suggests that the Cfr10I tetramer is able to interact with two copies of the recognition sequence, located on the same DNA molecule. Indeed, electron microscopy studies demonstrated that two distant recognition sites are brought together through the DNA looping induced by the simultaneous binding of the Cfr10I tetramer to both sites. These data are consistent with the tetramer being a functionally important form of Cfr10I.     

Recombination site selection by Tn3 resolvase: topological tests of a tracking mechanism

In vitro recombination by Tn3 resolvase of plasmids containing two directly repeated recombination (res) sites generates two singly interlinked catenated rings. This simple product catenane structure was maintained over a wide range of substrate supercoil densities and in a reaction mixture in which phage lambda Int-mediated recombination generated its characteristic multiply interlinked forms. Using substrates containing four res sites, we found that resolvase recombined neighboring res sites with high preference. This position effect implies that resolvase searches systematically along the DNA for a partner site. Intervening res sites in the opposite orientation did not prevent translocation. We analyzed the geometric arrangement of the interlocked rings after multiple recombination events in a four-site substrate and the pattern of segregation of nonspecific reporter rings catenated to the standard substrate. The results of these novel topological tests imply that the translocating enzyme may not make continuous contact with the DNA.     

Site-specific recombination by mutants of Tn21 resolvase with DNA recognition functions from Tn3 resolvase

The resolvases from the transposons Tn3 and Tn21 are homologous proteins but they possess distinct specificities for the DNA sequence at their respective res sites. The DNA binding domain of resolvase contains an amino acid sequence that can be aligned with the helix-turn-helix motif of other DNA binding proteins. Mutations in the gene for Tn21 resolvase were made by replacing the section of DNA that codes for the helix-turn-helix with synthetic oligonucleotides. Each mutation substituted one amino acid in Tn21 resolvase with either the corresponding residue from Tn3 resolvase or a residue that lacks hydrogen bonding functions. The ability of these proteins to mediate recombination between res sites from either Tn21 or Tn3 was measured in vivo and in vitro. With one exception, where a glutamate residue had been replaced by leucine, the activity of these mutants was similar to that of wild-type Tn21 resolvase. A further mutation was made in which the complete recognition helix of Tn21 resolvase was replaced with that from Tn3 resolvase. This protein retained activity in recombining Tn21 res sites, though at a reduced level relative to wild-type; the reduction can be assigned entirely to weakened binding to this DNA. Neither this mutant nor any other derivative of Tn21 resolvase had any detectable activity for recombination between res sites from Tn3. The exchange of this section of amino acid sequence between the two resolvases is therefore insufficient to alter the DNA sequence specificity for recombination.     

Dynamics of DNA loop capture by the SfiI restriction endonuclease on supercoiled and relaxed DNA

The SfiI endonuclease is a prototype for DNA looping. It binds two copies of its recognition sequence and, if Mg(2+) is present, cuts both concertedly. Looping was examined here on supercoiled and relaxed forms of a 5.5 kb plasmid with three SfiI sites: sites 1 and 2 were separated by 0.4 kb, and sites 2 and 3 by 2.0 kb. SfiI converted this plasmid directly to the products cut at all three sites, though DNA species cleaved at one or two sites were formed transiently during a burst phase. The burst revealed three sets of doubly cut products, corresponding to the three possible pairings of sites. The equilibrium distribution between the different loops was evaluated from the burst phases of reactions initiated by adding MgCl(2) to SfiI bound to the plasmid. The short loop was favored over the longer loops, particularly on supercoiled DNA. The relative rates for loop capture were assessed after adding SfiI to solutions containing the plasmid and MgCl(2). On both supercoiled and relaxed DNA, the rate of loop capture across 0.4 kb was only marginally faster than over 2.0 kb or 2.4 kb. The relative strengths and rates of looping were compared to computer simulations of conformational fluctuations in DNA. The simulations concurred broadly with the experimental data, though they predicted that increasing site separations should cause a shallower decline in the equilibrium constants than was observed but a slightly steeper decline in the rates for loop capture. Possible reasons for these discrepancies are discussed.     

Isolation and characterization of the Tn3 resolvase synaptic intermediate.

We have isolated in quantitative yield the synaptic intermediate formed during site-specific recombination by Tn3 resolvase and characterized it by restriction endonuclease mapping, electron microscopy and topological methods. The intermediate accumulates at low reaction temperatures and is stabilized by crosslinking of the resolvase protomers with glutaraldehyde. The DNA-resolvase complex that maintains the structure of the intermediate (the synaptosome) is approximately 100 A in diameter, forms specifically at resolution (res) sites, and requires two res sites in a supercoiled DNA molecule. Resolvase bound to individual res sites protects approximately -0.5 supercoil per site from relaxation by a topoisomerase, whereas the formation of the synaptosome protects -3 supercoils and condenses the associated DNA to a supercoil density 2.5 times that of the non-complexed substrate. Although recombination requires two directly repeated res sites, both direct and inverted sites form synaptosomes. We conclude that the specificity of recombination is achieved by a three-stage recognition system: binding of resolvase to separate sites, formation of the synaptosome and determination of site orientation from within the complex.     

PspGI,a type II restriction endonuclease from the extreme thermophile Pyrococcus sp.: structural and functional studies to investigate an evolutionary relationship with several mesophilic restriction enzymes

We present here the first detailed biochemical analysis of an archaeal restriction enzyme. PspGI shows sequence similarity to SsoII, EcoRII, NgoMIV and Cfr10I, which recognize related DNA sequences. We demonstrate here that PspGI, like SsoII and unlike EcoRII or NgoMIV and Cfr10I, interacts with and cleaves DNA as a homodimer and is not stimulated by simultaneous binding to two recognition sites. PspGI and SsoII differ in their basic biochemical properties, viz. stability against chemical denaturation and proteolytic digestion, DNA binding and the pH, MgCl(2) and salt-dependence of their DNA cleavage activity. In contrast, the results of mutational analyses and cross-link experiments show that PspGI and SsoII have a very similar DNA binding site and catalytic center as NgoMIV and Cfr10I (whose crystal structures are known), and presumably also as EcoRII, in spite of the fact that these enzymes, which all recognize variants of the sequence -/CC-GG- (/ denotes the site of cleavage), are representatives of different subgroups of type II restriction endonucleases. A sequence comparison of all known restriction endonuclease sequences, furthermore, suggests that several enzymes recognizing other DNA sequences also share amino acid sequence similarities with PspGI, SsoII and EcoRII in the region of the presumptive active site. These results are discussed in an evolutionary context.     

Analysis of inhibitors of the site-specific recombination reaction mediated by Tn3 resolvase

The Tn3-encoded resolvase protein promotes a site-specific recombination reaction between two directly repeated copies of the recombination site res. Several inhibitors that block this event in vitro have been isolated. In this study four of these inhibitors were tested on various steps in the recombination reaction. Two inhibitors. A9387 and A1062, inhibit resolvase binding to the res site. Further, DNase I footprinting revealed that at certain concentrations of A9387 and A1062, resolvase was preferentially bound to site I of res, the site containing the recombinational crossover point. The two other inhibitors, A20812 and A21960, do not affect resolvase binding and bending of the DNA but inhibit synapse formation between resolvase and two directly repeated res sites.     

Single molecule detection of DNA looping by NgoMIV restriction endonuclease

Single molecule fluorescence resonance energy transfer (FRET) and fluorescence correlation spectroscopy were used to investigate DNA looping by NgoMIV restriction endonuclease. Using a linear double-stranded DNA (dsDNA) molecule labeled with a fluorescence donor molecule, Cy3, and fluorescence acceptor molecule, Cy5, and by varying the concentration of NgoMIV endonuclease from 0 to 3 x 10(-6) M, it was possible to detect and determine diffusion properties of looped DNA/protein complexes. FRET efficiency distributions revealed a subpopulation of complexes with an energy transfer efficiency of 30%, which appeared upon addition of enzyme in the picomolar to nanomolar concentration range (using 10(-11) M dsDNA). The concentration dependence, fluorescence burst size analysis, and fluorescence correlation analysis were all consistent with this subpopulation arising from a sequence specific interaction between an individual enzyme and a DNA molecule. A 30% FRET efficiency corresponds to a distance of approximately 65 A, which correlates well with the distance between the ends of the dsDNA molecule when bound to NgoMIV according to the crystal structure of this complex. Formation of the looped complexes was also evident in measurements of the diffusion times of freely diffusing DNA molecules with and without NgoMIV. At very high protein concentrations compared to the DNA concentration, FRET and fluorescence correlation spectroscopy results revealed the formation of larger DNA/protein complexes.     

Topological selectivity of a hybrid site-specific recombination system with elements from Tn3 res/resolvase and bacteriophage P1 loxP/Cre.

In order to investigate the functions of the parts of the Tn 3 recombination site res, we created hybrid recombination sites by placing the loxP site for Cre recombinase adjacent to the "accessory" resolvase-binding sites II and III of res. The efficiency and product topology of in vitro recombination by Cre between two of these hybrid sites were affected by the addition of Tn 3 resolvase. The effects of resolvase addition were dependent on the relative orientation and spacing of the elements of the hybrid sites. Substrates with sites II and III of res close to loxP gave specific catenated or knotted products (four-noded catenane, three-noded knot) when resolvase and Cre were added together. The product topological complexity increased when the length of the spacer DNA segment between loxP and res site II was increased. Similar resolvase-induced effects on Cre recombination product topology were observed in reactions of substrates with loxP sites adjacent to full res sites. The results demonstrate that the res accessory sites are sufficient to impose topological selectivity on recombination, and imply that intertwining of two sets of accessory sites defines the simple catenane product topology in normal resolvase-mediated recombination. They are also consistent with current models for the mechanism of catalysis by Cre.     

Geometric arrangements of Tn3 resolvase sites

Site-specific recombination by Tn3 resolvase normally occurs in vitro and in vivo only between directly repeated res sites on the same supercoiled DNA molecule. However, with multiply interlinked catenane substrates consisting of two DNA rings each containing a single res site, resolvase efficiently carried out intermolecular recombination. The topology of the knots produced by several rounds of this reaction proves that the DNA within the synaptic intermediate is coiled in an interwound (plectonemic) fashion rather than wrapped solenoidally around resolvase as in previously characterized supercoiled DNA-protein complexes. The synaptic intermediate can contain equivalently supercoil, catenane, or knot crossings as long as the res sites have a right-handed coiling and a particular relative orientation. The structure of the product knots and catenanes also shows the path the DNA takes during strand exchange. Intermolecular recombination within multiply linked catenanes required negative supercoiling, as does the standard intramolecular reaction.     

Activating mutations of Tn3 resolvase marking interfaces important in recombination catalysis and its regulation

Catalysis of DNA recombination by Tn3 resolvase is conditional on prior formation of a synapse, comprising 12 resolvase subunits and two recombination sites (res). Each res binds a resolvase dimer at site I, where strand exchange takes place, and additional dimers at two adjacent 'accessory' binding sites II and III. 'Hyperactive' resolvase mutants, that catalyse strand exchange at site I without accessory sites, were selected in E. coli. Some single mutants can resolve a res x site I plasmid (that is, with one res and one site I), but two or more activating mutations are necessary for efficient resolution of a site I x site I plasmid. Site I x site I resolution by hyperactive mutants can be further stimulated by mutations at the crystallographic 2-3' interface that abolish activity of wild-type resolvase. Activating mutations may allow regulatory mechanisms of the wild-type system to be bypassed, by stabilizing or destabilizing interfaces within and between subunits in the synapse. The positions and characteristics of the mutations support a mechanism for strand exchange by serine recombinases in which the DNA is on the outside of a recombinase tetramer, and the tertiary/quaternary structure of the tetramer is reconfigured.