Interactions of protein complexes on supercoiled DNA: the mechanism of selective synapsis by Tn3 resolvase

"Looping" interactions of distant sites on DNA molecules, mediated by DNA-binding proteins, feature in many regulated genetic processes. We used plasmids containing up to six res recombination sites for Tn3 resolvase to analyse looping interactions (synapsis) in this system. We observed that in plasmids with four or more res sites, certain pairs of sites recombine faster than others. The relative rates of recombination depend on the number, relative orientation, and arrangement of the sites. To account for the differences in rate, we propose that pairing interactions between resolvase-bound res sites are in a state of rapid flux, leading to configurations in which the maximum number of sites within each supercoiled substrate molecule are synapsed in a topologically simple arrangement. Recombination rates reflect the steady state concentrations of these synapse configurations. Our results are at variance with models for selective synapsis that rely on ordered motions within supercoiled DNA, "slithering" or "tracking", but are compatible with models that call for reversible synapsis of pairs of sites by random collision, followed by formation of an interwound productive synapse.     

Dynamics of long-range interactions on DNA: the speed of synapsis during site-specific recombination by resolvase.

A noninvasive method for monitoring communications on DNA was developed from the specificity of resolvase for the arrangement of its recombinational sites. Constraints in DNA structure, caused by interactions between distant sites, can be detected by resolvase as they arise. The method was used to follow the formation and decay of synaptic intermediates during site-specific recombination by resolvase. Synaptic complexes were formed very rapidly, at a rate limited by the initial association of the protein with DNA rather than the physical motion of DNA segments. The recombinational sites seem to encounter each other by an ordered motion, perhaps dictated by DNA supercoiling instead of random collisions, so that the first encounter produces the active complex.     

Transposon targeting determined by resolvase

The Mu-related transposon Tn5090, also called Tn402, was observed to be highly selective for targets clustered in or close to recombination sites of serine-type recombinases in plasmids R388 and RP1. Transposition to the par area of RP1 responded strongly to a deletion in the gene of resolvase ParA. A search in sequence databanks revealed further insertions of Tn5090/Tn402 close to different genes of resolvases. These results imply that the target selection of Tn5090 depends on a property that is shared among several serine recombinases.     

Site-specific recombination by Tn3 resolvase

Site-specific recombination processes in microbes bring about precise DNA rearrangements which have diverse and important biological functions. The sites and recombinase enzymes used for these processes fall into two distinct families. Here we describe how experiments with one family, exemplified by the resolution system of transposon Tn3, have provided insight into the ways in which DNA and protein interact to bring together distant recombination sites and promote strand exchange.     

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.     

Synapsis and catalysis by activated Tn3 resolvase mutants

The serine recombinase Tn3 resolvase catalyses recombination between two 114 bp res sites, each of which contains binding sites for three resolvase dimers. We have analysed the in vitro properties of resolvase variants with ‘activating’ mutations, which can catalyse recombination at binding site I of res when the rest of res is absent. Site I × site I recombination promoted by these variants can be as fast as res × res recombination promoted by wild-type resolvase. Activated variants have reduced topological selectivity and no longer require the 2–3′ interface between subunits that is essential for wild-type resolvase-mediated recombination. They also promote formation of a stable synapse comprising a resolvase tetramer and two copies of site I. Cleavage of the DNA strands by the activated mutants is slow relative to the rate of synapsis. Stable resolvase tetramers were not detected in the absence of DNA or bound to a single site I. Our results lead us to conclude that the synapse is assembled by sequential binding of resolvase monomers to site I followed by interaction of two site I-dimer complexes. We discuss the implications of our results for the mechanisms of synapsis and regulation in recombination by wild-type resolvase.     

Intramolecular synapsis of duplex DNA by vaccinia topoisomerase.

Complexes formed by vaccinia topoisomerase I on plasmid DNA were visualized by electron microscopy. The enzyme formed intramolecular loop structures in which non-contiguous DNA segments were synapsed within filamentous protein stems. At high enzyme concentrations the DNA appeared to be zipped up within the protein filaments such that the duplex was folded back on itself. Formation of loops and filaments was also observed with an active site mutant, Topo-Phe274. Binding of Topo-Phe274 to relaxed DNA circles in solution introduced torsional strain, which, after relaxation by catalytic amounts of wild-type topo-isomerase, resulted in acquisition of negative supercoils. We surmise that the topoisomerase-DNA complex is a plectonemic supercoil in which the two duplexes encompassed by the protein filaments are interwound in a right handed helix. We suggest that topoisomerase-mediated DNA synapsis plays a role in viral recombination and in packaging of the 200 kbp vaccinia genome during virus assembly.     

Genetic analysis of an archaeal Holliday junction resolvase in Escherichia coli.

The study of genes and proteins in heterologous model systems provides a powerful approach to the analysis of common processes in biology. Here, we show how the bacterium Escherichia coli can be exploited to analyse genetically and biochemically the activity and function of a Holliday junction resolving enzyme from an archaeal species. We have purified and characterised a member of the newly discovered Holliday junction cleaving (Hjc) family of resolvases from the moderately thermophilic archaeon Methanobacterium thermoautotrophicum and demonstrate that it promotes DNA repair in resolvase-deficient ruv mutants of E. coli. The data presented provide the first direct evidence that such archaeal enzymes can promote DNA repair in vivo, and support the view that formation and resolution of Holliday junctions are key to the interplay between DNA replication, recombination and repair in all organisms. We also show that Hjc promotes DNA repair in E. coli in a manner that requires the presence of the RecG branch migration protein. These results support models in which RecG acts at a replication fork stalled at a lesion in the DNA, catalysing fork regression and forming a Holliday junction that can then be acted upon by Hjc.     

Chromosome synapsis in hexaploids

Theoretical relationships between pachytene multivalent and bivalent frequencies in hexaploids are deduced from a model, based on chromosomes showing sequential association at equidistant pairing sites and uniform propensities for partner exchange throughout their lengths. These relationships approach a limit as the number of pairing sites tends to infinity and the intervals between them tend to zero; at the limit pairing is continuous and the quadrivalent/sexivalent ratio is at a minimum. A maximum of 34·3% of the complement is expected to form quadrivalents when there are two pairing sites per chromosome but this peak is reduced by increasing numbers of pairing sites to a limit of 29·6% when pairing is continuous. Where chromosome length is proportional to the number of pairing sites there will be a log/linear relationship between bivalent frequency and chromosome length otherwise a log/log relationship is expected. In the light of these conclusions, observations on experimental hexaploids could be used to provide estimates of the number of pairing sites on each chromosome.     

Mutants of the gamma delta resolvase: a genetic analysis of the recombination function

The resolvase protein encoded by the gamma delta transposon has two functions. It catalyzes a site-specific recombination, and it negatively regulates the expression of two transposon genes. Both functions involve the action of resolvase at the res site. To define regions of resolvase that are involved specifically in the recombination reaction, we have isolated and characterized mutants that are defective in cointegrate resolution but retain the ability to bind to res (as measured by regulatory activity). Nine independent mutants were found to contain six different amino acid substitutions among just four distinct residues. The altered residues all lie within the 140 amino acid amino-terminal domain of resolvase and fall within two clusters of amino acids that are highly conserved in other related recombinases. The regulatory properties of the mutants suggest that one of these clusters may be involved in the interaction of the catalytic domain with the crossover site.     

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+.     

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.     

The catalytic residues of Tn3 resolvase

To characterize the residues that participate in the catalysis of DNA cleavage and rejoining by the site-specific recombinase Tn3 resolvase, we mutated conserved polar or charged residues in the catalytic domain of an activated resolvase variant. We analysed the effects of mutations at 14 residues on proficiency in binding to the recombination site (‘site I’), formation of a synaptic complex between two site Is, DNA cleavage and recombination. Mutations of Y6, R8, S10, D36, R68 and R71 resulted in greatly reduced cleavage and recombination activity, suggesting crucial roles of these six residues in catalysis, whereas mutations of the other residues had less dramatic effects. No mutations strongly inhibited binding of resolvase to site I, but several caused conspicuous changes in the yield or stability of the synapse of two site Is observed by non-denaturing gel electrophoresis. The involvement of some residues in both synapsis and catalysis suggests that they contribute to a regulatory mechanism, in which engagement of catalytic residues with the substrate is coupled to correct assembly of the synapse.     

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.     

ResT, a telomere resolvase encoded by the Lyme disease spirochete.

The genus Borrelia includes the causative agents of Lyme disease and relapsing fever. An unusual feature of these bacteria is a segmented genome consisting mostly of a number of linear DNA molecules with covalently closed hairpin ends or telomeres. In this study we show that the BBB03 locus encodes the B. burgdorferi telomere resolvase, ResT. The purified protein catalyzes telomere resolution in vitro through a unique reaction: breakage of two phosphodiester bonds in a single DNA duplex (one on each strand) and joining of each end with the opposite DNA strand to form covalently closed hairpin telomeres. Telomere resolution by ResT occurs through a two-step transesterification reaction involving the formation of a covalent protein-DNA intermediate at a position three nucleotides from the axis of symmetry in each strand of the substrate.     

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.     

Centromere clustering: where synapsis begins

Centromeres congregate into a large cluster called the chromocenter during Drosophila oogenesis. Two recent studies now define a function and a genetic basis for this remarkable structure.     

Genetic control of chromosomal synapsis in Secale cereale L. rye meiosis: sy19 gene, causing heterologous synapsis

Analysis of manifestation and inheritance of a new mutation inducing irregular synapsis in rye showed that abnormal phenotype is determined by a recessive allele of the sy19 gene. In the homozygotes for this mutation, even at the light microscopic level, abnormal formation of bivalents is already observed at pachytene-diakinesis. At metaphase I, the univalent frequency varies from 0 to 14; in a few cells, multivalent associations of chromosomes, which are not clearly oriented in the spindle, are detected. Electron microscopy of synaptonemal complexes revealed both homologous and heterologous synapsis in homozygotes for sy19, namely partial loss of the ability to stringent homology search. Analysis of joint inheritance of sy19 and asynaptic sy1 mutations showed that they are nonallelic, inherited independently, and interact by recessive epistasis. The phenotype of double sy1sy19 mutants indicates that the sy19 gene conditioning heterologous synapsis operates at meiosis later than the synaptic gene sy1. The epistatic group of mutations, sy9 > sy1 > sy19 and sy3, was determined.