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

Transcription rate and transcript length drive formation of chromosomal interaction domain boundaries

Chromosomes in all organisms are highly organized and divided into multiple chromosomal interaction domains, or topological domains. Regions of active, high transcription help establish and maintain domain boundaries, but precisely how this occurs remains unclear. Here, using fluorescence microscopy and chromosome conformation capture in conjunction with deep sequencing (Hi-C), we show that in Caulobacter crescentus, both transcription rate and transcript length, independent of concurrent translation, drive the formation of domain boundaries. We find that long, highly expressed genes do not form topological boundaries simply through the inhibition of supercoil diffusion. Instead, our results support a model in which long, active regions of transcription drive local decompaction of the chromosome, with these more open regions of the chromosome forming spatial gaps in vivo that diminish contacts between DNA in neighboring domains. These insights into the molecular forces responsible for domain formation in Caulobacter likely generalize to other bacteria and possibly eukaryotes.

Mariner and the ITm Superfamily of Transposons

The IS630-Tc1-mariner (ITm) family of transposons is one of the most widespread in nature. The phylogenetic distribution of its members shows that they do not persist for long in a given lineage, but rely on frequent horizontal transfer to new hosts. Although they are primarily selfish genomic-parasites, ITm transposons contribute to the evolution of their hosts because they generate variation and contribute protein domains and regulatory regions. Here we review the molecular mechanism of ITm transposition and its regulation. We focus mostly on the mariner elements, which are understood in the greatest detail owing to in vitro reconstitution and structural analysis. Nevertheless, the most important characteristics are probably shared across the grouping. Members of the ITm family are mobilized by a cut-and-paste mechanism and integrate at 5'-TA dinucleotide target sites. The elements encode a single transposase protein with an N-terminal DNA-binding domain and a C-terminal catalytic domain. The phosphoryl-transferase reactions during the DNA-strand breaking and joining reactions are performed by the two metal-ion mechanism. The metal ions are coordinated by three or four acidic amino acid residues located within an RNase H-like structural fold. Although all of the strand breaking and joining events at a given transposon end are performed by a single molecule of transposase, the reaction is coordinated by close communication between transpososome components. During transpososome assembly, transposase dimers compete for free transposon ends. This helps to protect the host by dampening an otherwise exponential increase in the rate of transposition as the copy number increases.

From structure to function of bacterial chromosomes: Evolutionary perspectives and ideas for new experiments

The link between chromosome structure and function is a challenging open question because chromosomes in vivo are highly dynamic and arduous to manipulate. Here, we examine several promising approaches to tackle this question specifically in bacteria, by integrating knowledge from different sources. Toward this end, we first provide a brief overview of experimental tools that have provided insights into the description of the bacterial chromosome, including genetic, biochemical and fluorescence microscopy techniques. We then explore the possibility of using comparative genomics to isolate functionally important features of chromosome organization, exploiting the fact that features shared between phylogenetically distant bacterial species reflect functional significance. Finally, we discuss possible future perspectives from the field of experimental evolution. Specifically, we propose novel experiments in which bacteria could be screened and selected on the basis of the structural properties of their chromosomes.

One to rule them all: A highly conserved motif in mariner transposase controls multiple steps of transposition

The development of transposon-based genome manipulation tools can benefit greatly from understanding transposons’ inherent regulatory mechanisms. The Tc1-mariner transposons, which are being widely used in biotechnological applications, are subject to a self-inhibitory mechanism whereby increasing transposase expression beyond a certain point decreases the rate of transposition. In a recent paper, Liu and Chalmers performed saturating mutagenesis on the highly conserved WVPHEL motif in the mariner-family transposase from the Hsmar1 element. Curiously, they found that the majority of all possible single mutations were hyperactive. Biochemical characterizations of the mutants revealed that the hyperactivity is due to a defect in communication between transposase subunits, which normally regulates transposition by reducing the rate of synapsis. This provides important clues for improving transposon-based tools. However, some WVPHEL mutants also showed features that would be undesirable for most biotechnological applications: they showed uncontrolled DNA cleavage activities and defects in the coordination of cleavage between the two transposon ends. The study illustrates how the knowledge of inhibitory mechanisms can help improve transposon tools but also highlights an important challenge, which is to specifically target a regulatory mechanism without affecting other important functions of the transposase.

Cointegrate-resolution of toluene-catabolic transposon Tn4651: determination of crossover site and the segment required for full resolution activity

Tn3-family transposon Tn4651 from Pseudomonas putida mt-2 plasmid pWW0 carries two divergently transcribed genes, tnpS and tnpT, for cointegrate-resolution. While tnpS encodes a tyrosine recombinase, tnpT encodes a protein that shows no homology to any other characterized protein. The Tn4651 resolution site was previously mapped within the 203-bp fragment that covered the tnpS and tnpT promoter region. To better understand the molecular mechanisms underlying the Tn4651 cointegrate-resolution, we determined the extent of the functional resolution site (designated the rst site) of Tn4651 and the location of the crossover site for the cointegrate-resolution. Deletion analysis of the rst region localized the fully functional rst site to a 136-bp segment. The analysis of the site-specific recombination between Tn4651 rst and a rst variant from the Tn4651-related transposon, Tn4661, indicated that the crossover occurs in the 33-bp inverted repeat region, which separates the 136-bp functional rst site into the tnpS- and tnpT-proximal segments. Electrophoretic mobility shift assays demonstrated specific binding of TnpT to the 20-bp inverted repeat region in the tnpT-proximal segment. The requirement for accessory sequences on both sides of the crossover site and the involvement of the unique DNA-binding protein TnpT suggest that the Tn4651-specified resolution system uses a different mechanism than other known resolution systems. Furthermore, comparative sequence analysis for Tn4651-related transposons revealed the occurrence of DNA exchange at the rst site among different transposons, suggesting an additional role of the TnpS-TnpT-rst system in the evolution of Tn4651-related transposons.

Predicting knot or catenane type of site-specific recombination products

Site-specific recombination on supercoiled circular DNA yields a variety of knotted or catenated products. Here, we present a topological model of this process and characterize all possible products of the most common substrates: unknots, unlinks, and torus knots and catenanes. This model tightly prescribes the knot or catenane type of previously uncharacterized data. We also discuss how the model helps to distinguish products of distributive recombination and, in some cases, determine the order of processive recombination products.

DNA topology and geometry in Flp and Cre recombination

The Flp recombinase of yeast and the Cre recombinase of bacteriophage P1 both belong to the lambda-integrase (Int) family of site-specific recombinases. These recombination systems recognize recombination-target sequences that consist of two 13bp inverted repeats flanking a 6 or 8bp spacer sequence. Recombination reactions involve particular geometric and topological relationships between DNA target sites at synapsis, which we investigate using nicked-circular DNA molecules. Examination of the tertiary structure of synaptic complexes formed on nicked plasmid DNAs by atomic-force microscopy, in conjunction with detailed topological analysis using the mathematics of tangles, shows that only a limited number of recombination-site topologies are consistent with the global structures of plasmids bearing directly and inversely repeated sites. The tangle solutions imply that there is significant distortion of the Holliday-junction intermediate relative to the planar structure of the four-way DNA junction present in the Flp and Cre co-crystal structures. Based on simulations of nucleoprotein structures that connect the two-dimensional tangle solutions with three-dimensional models of the complexes, we propose a recombination mechanism in which the synaptic intermediate is characterized by a non-planar, possibly near-tetrahedral, Holliday-junction intermediate. Only modest conformational changes within this structure are needed to form the symmetric, planar DNA junction, which may be characteristic of shorter-lived intermediates along the recombination pathway.

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.

Topology of Xer recombination on catenanes produced by lambda integrase

Xer site-specific recombination at the psi site from plasmid pSC101 displays topological selectivity, such that recombination normally occurs only between directly repeated sites on the same circular DNA molecule. This intramolecular selectivity is important for the biological role of psi, and is imposed by accessory proteins PepA and ArcA acting at accessory DNA sequences adjacent to the core recombination site. Here we show that the selectivity for intramolecular recombination at psi can be bypassed in multiply interlinked catenanes. Xer site-specific recombination occurred relatively efficiently between antiparallel psi sites located on separate rings of right-handed torus catenanes containing six or more nodes. This recombination introduced one additional node into the catenanes. Antiparallel sites on four-noded right-handed catenanes, the normal product of Xer recombination at psi, were not recombined efficiently. Furthermore, parallel psi sites on right-handed torus catenanes were not substrates for Xer recombination. These findings support a model in which psi sites are plectonemically interwrapped, trapping a precise number of supercoils that are converted to four catenation nodes by Xer strand exchange.

Gyrase and Topo IV modulate chromosome domain size in vivo

In bacteria, DNA supercoil movement is restricted to subchromosomal regions or 'domains.' To elucidate the nature of domain boundaries, we analysed reaction kinetics for gammadelta site-specific resolution in six chromosomal intervals ranging in size from 14 to 90 kb. In stationary cultures of Salmonella typhimurium, resolution kinetics were rapid for both short and long intervals, suggesting that random stationary barriers occur with a 30% probability at approximately 80 kb intervals along DNA. To test the biochemical nature of domain barriers, a genetic screen was used to look for mutants with small domains. Rare temperature-sensitive alleles of DNA gyrase and Topo IV (the two essential type II topoisomerases) had more supercoil barriers than wild-type strains in all growth states. The most severe gyrase mutants were found to have twice as many barriers in growing cells as wild type throughout a 90 kb interval of the chromosome. We propose that knots and tangles in duplex DNA restrain supercoil diffusion in living bacteria.

The scs and scs' insulator elements impart a cis requirement on enhancer-promoter interactions

The Xenopus rRNA enhancer activates its cognate promoter when the two elements are placed on opposite rings of dimeric catenanes. Here we show that when scs elements flank either the enhancer or promoter in catenanes, the enhancer cannot activate the promoter on the ring in trans. A series of catenanes containing different permutations of the insulators, enhancer, and promoters shows that when insulators are present, the enhancer is permitted to a activate the promoter only when both elements are on the same piece of DNA with no intervening insulator. These results suggest that insulators have the potential to block enhancer-promoter interactions between chromosomes and between independent topological domains within a chromosome.

Long-range effects in a supercoiled DNA domain generated by transcription in vitro

The translocation of a transcription complex can transiently introduce positive and negative superhelical windings into the template DNA. To gain further insight into this dynamic DNA supercoiling mechanism and its possible involvement in biological processes, we employed an in vitro system in which site-specific recombination by gammadelta resolvase is topologically coupled to transcription-induced negative supercoiling. Our kinetic experiments suggest that recombination is closely linked to the process of supercoiling by transcription. We utilized the known high speed at which two resolvase-bound recombination sites can pair to form a synaptic complex in kinetic experiments with DNA substrates containing three recombination sites. Our data provide evidence for the existence of a transient gradient of negative supercoiling. Such a gradient seems to be predominantly a consequence of DNA double helix rotation behind a translocating RNA polymerase and originates within a broad region up to two kilobase-pairs upstream of the transcriptional start site. We further demonstrate that the topological coupling between transcription and recombination is not affected when the DNA-bending protein integration host factor from E. coli is bound to multiple sites within the phage lambda attachment region. We discuss implications of our in vitro findings with respect to possible in vivo functions of the dynamic nature of transcription-induced supercoiling.

Contrasting enzymatic activities of topoisomerase IV and DNA gyrase from Escherichia coli

DNA gyrase and topoisomerase IV (Topo IV) have distinct roles as unlinking enzymes during DNA replication despite 40% sequence identity between them. DNA gyrase unlinks replicating DNA by introducing negative supercoils while Topo IV decatenates the two daughter molecules. For this study, we measured the rates of unlinking of various topoisomers of DNA by DNA gyrase and Topo IV. Each enzyme has marked preferences for certain strand-passage reactions. DNA gyrase is a relatively poor decatenase, catalyzing strand-passage events that result in supercoiling at rates several orders of magnitude faster than those causing decatenation. Topo IV, in contrast, decatenates linked circles 10-40 times more quickly than it removes the intramolecular crossings from supercoiled DNA. Supercoiled catenanes are unlinked at an even more increased rate by Topo IV. Thus, the supercoils augment decatenation rather than compete with catenane crossings for their removal. Knot crossings and the crossings of multiply interlinked catenanes are also preferentially removed by Topo IV. This ability of Topo IV to selectively unlink catenated molecules mirrors its key role in decatenation of replicating chromosomes in vivo.

In vivo analysis of the plasmid pAM beta 1 resolution system

The promiscuous plasmid pAM beta 1 from Gram-positive bacteria encodes a resolution system which differs from that of Tn3 in that (i) it requires a histone-like protein and an unusual resolvase-DNA interaction to promote recombination and (ii) it mediates in vivo DNA inversion in plasmid substrates. In this in vivo analysis, the pAM beta 1 resolution site is narrowed down to a 99 bp segment, the strand exchange is mapped within 10 bp and the serine residue at position 10 of the resolvase is shown to be essential for enzyme activity. In addition, data showing that the resolution system does not promote DNA inversion in the Bacillus subtilis chromosome are presented. Implications of this observation are discussed.

Surveying a supercoil domain by using the gamma delta resolution system in Salmonella typhimurium

A genetic system was developed to investigate the supercoil structure of bacterial chromosomes. New res-carrying transposons were derived from MudI1734 (MudJr1 and MudJr2) and Tn10 (Tn10dGn). The MudJr1 and MudJr2 elements each have a res site in opposite orientation so that when paired with a Tn10dGn element in the same chromosome, one MudJr res site will be ordered as a direct repeat. Deletion formation was studied in a nonessential region (approximately 100 kb) that extends from the his operon through the cob operon. Strains with a MudJr insertion in the cobT gene at the 5' end of the cob operon plus a Tn10dGn insertion positioned either clockwise or counterclockwise from cobT were exposed to a burst of RES protein. Following a pulse of resolvase expression, deletion formation was monitored by scoring the loss of the Lac+ phenotype or by loss of tetracycline resistance. In exponentially growing populations, deletion products appeared quickly in some cells (in 10 min) but also occurred more than an hour after RES induction. The frequency of deletion (y) diminished with increasing distance (x) between res sites. Results from 15 deletion intervals fit the exponential equation y = 120 . 10(-0.02x). We found that res sites can be plectonemically interwound over long distances ( > 100 kb) and that barriers to supercoil diffusion are placed stochastically within the 43- to 45-min region of the chromosome.

Analysis of the mechanism of DNA recombination using tangles

The DNA of all organisms has a complex and essential topology. The three topological properties of naturally occurring DNA are supercoiling, catenation, and knotting. Although these properties are denned rigorously only for closed circular DNA, even linear DNAin vivocan have topological properties because it is divided into topologically separate subdomains (Drlica 1987; Roberge & Gasser, 1992). The essentiality of topological properties is demonstrated by the lethal consequence of interfering with topoisomerases, the enzymes that regulate the level of DNA supercoiling and that unlink DNA during its replication (reviewed in Wang, 1991; Bjornsti, 1991; Drlica, 1992; Ullspergeret al. 1995).

Use of genetic recombination as a reporter of gene expression

An understanding of the patterns of gene expression in response to specific environmental signals can yield insight into a variety of complex biological systems such as microbial-host interactions, developmental cycles, cellular differentiation, ontogeny, etc. To extend the utility of the reporter gene fusion approach to such studies, we have constructed a gene expression reporter cassette that permits the generation of transcriptional fusions to tnpR encoding resolvase, a site-specific recombinase of the transposable element gamma delta. Induction of the transcriptional fusions results in production of resolvase, which in turn, catalyzes excision of a linked tetracycline-resistance reporter gene flanked by direct repeats of res, the DNA sequences at which resolvase functions. The loss of tetracycline resistance in descendant bacteria serves as a permanent and heritable marker of prior gene expression. This gene fusion approach will allow us to assay the induction of gene expression in as few as one cell. Additionally, gene expression can be assayed at a later time and/or different place from the inducing environment facilitating the study of gene expression in complex environments such as animal tissues.

Purification and DNA binding of the D protein, a putative resolvase of the F-factor of Escherichia coli

The D protein encoded by plasmid mini-F promotes resolution of plasmid cointegrates or dimers of the F-factor or mini-F. In addition, two rfsF sequences are essential for this site-specific, recA-independent recombination event. The D gene was cloned into an expression vector and the gene product was overproduced in Escherichia coli and purified to homogeneity. The sequence of the N-terminus of the D protein was determined, thus permitting identification of the correct translational start codon in the nucleotide sequence that results in a 29.6 kDa protein. The binding site for the purified D protein is located within the mini-F NcoI-HpaI DNA fragment (192 bp). Binding seems to be affected by DNA methylation, since the protein did not bind to DNA isolated from a dam mutant of E. coli. The binding site, which is a region of approximately 28 bp and is located 160 bp downstream of the rfsF site, was identified by DNase I footprinting using fluorescence labelled DNA.

Recombination of nicked DNA knots by gamma delta resolvase suggests a variant model for the mechanism of strand exchange

Fast and efficient recombination catalyzed by gamma delta resolvase in vitro requires negative DNA supercoiling of plasmid substrates. The current model for recombination suggests that supercoiling is required to drive DNA strand exchange within a synaptic complex by 'simple rotation' of DNA-linked resolvase promoters. Surprisingly, DNA knots are recombined efficiently in the absence of supercoiling, whereby the rate of recombination increases with the number of irreducible DNA segment crossings, or nodes, within each substrate knot. Recombination products contain three knot nodes less than substrates, suggesting that a reduction in writhe drives the reaction. However, the proposed protomer rotation model predicts that writhe is not altered during the process of strand transfer but, instead, is reduced only when a synaptic complex disassembles after strand exchange. I present evidence that recombination of knotted and of linear substrates coincides with a disassembly of synaptic complexes. The results lead to a variant model for strand exchange on non-supercoiled substrates in which a specific disassembly of the synaptic complex, triggered by a reduction in writhe, guides the cleaved DNA into the recombinant configuration.

The two functional domains of gamma delta resolvase act on the same recombination site: implications for the mechanism of strand exchange

During site-specific recombination by the gamma delta resolvase, four DNA strands are broken, exchanged, and religated. This exchange is carried out within a DNA-protein complex, the synaptosome, in which the recombination sites, res, are aligned. The domain of resolvase that binds to a res site is distinct from the domain that breaks and rejoins the DNA. We tested whether the catalytic domain acts on the res site to which its binding domain is bound (in cis) or on the opposing res site in the synaptic complex (in trans). We constructed a hybrid synaptosome in which one res site is bound to wild-type resolvase and the other is bound to a mutant resolvase that binds normally but is unable to break DNA. From the pattern of strand breakage in the reaction intermediate containing resolvase covalently attached to DNA, we conclude that resolvase attacks predominantly, if not exclusively, in cis. Because cis breakage and reunion per se cannot lead to recombination, our results support a model in which DNA exchange is guided by an exchange of resolvase subunits between the breakage and reunion events.

DNA supercoiling determines the activation energy barrier for site specific recombination by Tn21 resolvase

A kinetic analysis of site specific recombination by Tn21 resolvase has been carried out using DNA substrates of varying superhelicities. The rates for the formation of the recombinant product increased with increasing superhelicity up to a maximum value, after which further increases in superhelicity caused no further increase in rate. The reactions with DNA of reduced superhelicity were extremely slow, yet they eventually led to virtually all of the substrate being converted to product. Hence, the level of DNA superhelicity must determine the activation energy barrier for at least one of the steps within the reaction pathway that can be rate-limiting. In the presence (but not in the absence) of Mg2+ ions, the DNA was fully saturated with resolvase whenever the protein was in stoichiometric excess over resolvase binding sites on the DNA. Thus the process affected by DNA supercoiling cannot be coupled to the binding of resolvase. Instead, the step whose rate is determined by supercoiling seems to be located within the reaction pathway after the synapse. However, these reactions may involve two forms of the synaptic complex that are converted to the recombinant product at different rates.

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.

Biological consequences of a reduction in the non-target DNA scanning capacity of a DNA repair enzyme

Numerous DNA-interactive proteins have been shown to locate specific sequences within large domains of non-target DNA in vitro and in vivo by a one-dimensional diffusion mechanism; however, the biological significance of this process has not been evaluated. We have examined the biological consequences of sliding for the pyrimidine dimer-specific DNA repair enzyme T4 endonuclease V, an enzyme which scans non-target DNA both in vitro and in vivo. An endonuclease V mutant was constructed whose only altered biochemical characteristic, measured in vitro, was a loss in its ability to slide on non-target DNA. In contrast to the native enzyme, when the mutated endonuclease V was expressed in DNA repair-deficient Escherichia coli, no enhanced ultraviolet survival was conferred. These results suggest that the mechanisms which DNA-interactive proteins employ to enhance the probability of locating their target sequences are of significant biological importance.

Recombination of knotted substrates by Tn3 resolvase

We studied the site orientation specificity for recombination by purified Tn3 resolvase. With standard plasmid substrates, resolvase acts only on directly repeated recombination sites. Knotting, however, makes inverted site substrates equally efficient. The structure of the knotted products of recombination shows that the DNA wrapped around resolvase in the synaptic intermediate has the same local geometry as the standard substrate but is reversed in topological sign. Similarly, the same strand exchange with the two substrates generates supercoils with opposite signs. Thus, DNA geometry rather than topology is critical for these features of recombination. The knotted inverse substrate like the direct site substrate must be (-) supercoiled under standard reaction conditions. However, under conditions in which supercoiling is not required, the structure of the knotted product is apparently the same. This indicates that the unique direction of strand exchange is determined by the structure of the synaptosome and not by (-) supercoiling of the substrate.

Gin-mediated recombination of catenated and knotted DNA substrates: implications for the mechanism of interaction between cis-acting sites

The Gin DNA-inversion system of bacteriophage Mu normally requires a substrate containing two inverted recombination sites (gix) and an enhancer sequence on the same supercoiled DNA molecule. The reaction mechanism was investigated by separating these sites on catenated rings. Catenanes with the gix sites on one circle and the enhancer on the other recombined efficiently. Thus, the enhancer was fully functional even though it was located in trans to the gix sites. Multiple links between the rings are required for recombination. Multiply linked catenanes with gix sites on separate circles, one of which contained the enhancer, were also efficient substrates. Knotted constructs carrying directly repeated gix sites were recombined. Catenated and knotted substrates must also be supercoiled. These experiments eliminate simple tracking or looping models as explanations for why the enhancer and gix sites must be in cis with standard substrates. Rather, the Gin synaptic complex requires the three sites to be mutually intertwined in a right-handed fashion with a unique polarity of the gix sites. This geometry is achieved by branching of the DNA substrate and requires the energy and structure of supercoiling, catenation, or knotting.

cis-acting DNA sequence requirements for P-element transposition

The P transposable element of Drosophila melanogaster has a complex array of cis-acting DNA sequences necessary for efficient transposition. At the 3' end these sequences extend over more than 150 bp and include 11- and 31-bp sequences found repeated in inverted orientation at the 5' end. The P element's 5' end, however, cannot function as its 3' end. When two 3' P-element ends are present, the more proximal end is used preferentially. We found also that the duplication of the target site does not appear to play a role in forward transposition.

The mechanics of winding and unwinding helices in recombination: torsional stress associated with strand transfer promoted by RecA protein

Homologous recombination usually involves the production of heteroduplex DNA, DNA containing strands contributed from two different duplexes. RecA protein of E. coli can promote the formation of heteroduplex DNA in vitro by the exchange of DNA strands between two helical structures, duplex DNA and a helical recA nucleoprotein filament containing a single strand of DNA. Complete unwinding of the parental duplex and the rewinding of one strand with a new complement requires rotation of the helical structures about one another, or about their respective longitudinal axes. The observations described here demonstrate an association of torsional stress with strand exchange, and suggest that exchange is accomplished principally by concomitant rotation of duplex DNA and the recA nucleoprotein filament, each about its longitudinal axis.

Properties of a mutant Cre protein that alters the topological linkage of recombination products

The bacteriophage P1 Cre-loxP site-specific recombination system consists of two components: the Cre recombinase protein and the loxP DNA sequence where recombination takes place. We report here on the analysis of a mutation in the cre structural gene that produces a mutant protein with altered recombination properties. The mutant protein, Cre111, carries out recombination at a much slower rate than the wild-type Cre protein. To determine why the reaction is slow, we have examined a number of activities associated with Cre-mediated recombination. Our results indicate that the binding of Cre111 to the loxP site is comparable to wild-type Cre. Furthermore, the rate at which Cre111 resolves Holliday structures, an intermediate in this recombination reaction, is also comparable to wild-type Cre. Thus, DNA binding and resolution of the intermediate are not affected, suggesting that either synapsis, the process of bringing two lox sites together, or the first strand exchange event, could be affected in the mutant protein. The types of DNA products formed following recombination of a supercoiled substrate can reflect mechanisms of synapsis. Wild-type Cre generates mainly topologically unlinked and unknotted circular products. This suggests that the wild-type protein brings two lox sites together in a way that excludes the entanglement of supercoils present in the substrate DNA. In contrast, when Cre111 recombines a supercoiled molecule it generates many complicated catenanes and knotted DNA products. Presumably, the supercoils present in the DNA substrate are being trapped in the reaction products.(ABSTRACT TRUNCATED AT 250 WORDS)

Gin-mediated DNA inversion: product structure and the mechanism of strand exchange

Inversion of the G loop of bacteriophage Mu requires the phage-encoded Gin protein and a host factor. The topological changes in a supercoiled DNA substrate generated by the two purified proteins were analyzed. More than 99% of the inversion products were unknotted rings. This result excludes synapsis by way of a random collision of recombination sites, because the resulting entrapped supercoils would be converted into knots by recombination. Instead, the recombination sites must come together in the synaptic complex in an ordered fashion with a fixed number of supercoils between the sites. The linking number of the substrate DNA increases by four during recombination. Thus, in three successive rounds of inversion, the change in linking number was +4, +8, and +12, respectively. These results lead to a quantitative model for the mechanism of Gin recombination that includes the distribution of supercoils in the synaptic complex, their alteration by strand exchange, and specific roles for the two proteins needed for recombination.

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.

Use of site-specific recombination as a probe of DNA structure and metabolism in vivo

We used site-specific recombination catalyzed by the bacteriophage lambda Int system to probe DNA structure and metabolism in vivo. In vitro, the complexity of catenated products was linearly proportional to substrate supercoil density. A system was developed that gave efficient, controlled Int recombination in Escherichia coli cells. From a comparison of the data obtained in vitro and in vivo, we conclude that Int recombination does have the same mechanism in vivo as it has in vitro, but that only 40% of the plasmid DNA linking deficit in E. coli cells may be in the interwound supercoil form demonstrated in vitro. We suggest that this is the effective level of supercoiling in vivo, because the remaining DNA is constrained in alternative forms by protein binding. The study of Int recombination in vivo also provides an assay for enzymes that decatenate circular molecules, such as those formed during DNA replication. We find that DNA gyrase is the principal decatenase in E. coli and that it acts spontaneously and rapidly.

Communication between segments of DNA during site-specific recombination

Some site-specific recombination systems require the interacting DNA sequences to have a specific relative orientation. This means that DNA segments can sense each other's direction even though they may be separated by many thousands of base pairs. Here, we review the surprising results of recent experiments that lead to a new model which accounts for site orientation specificity and relates it to other recombination systems where relative orientation is not critical.

Site-specific recombination and topoisomerization by Tn21 resolvase: role of metal ions

The resolvase from the transposon Tn21 catalyses site-specific recombination between the two res sites on its DNA substrate both in the absence and presence of Mg2+ ions. This contrasts with reports on the resolvase from gamma-delta (Tn1000) and on other recombinational proteins that are homologous to Tn21 resolvase but which need Mg2+ for their activity. Magnesium ions could enhance the activity of Tn21 resolvase, as did a number of other cations but some metal ions such as Ni2+ inhibit recombination. The metal ions are not directly involved in the catalytic process but probably affect recombination by altering the conformation of the DNA. Tn21 resolvase relaxes its DNA substrate in the presence and in the absence of Mg2+, and also in ionic conditions that inhibit recombination. Hence, the topoisomerization reflects an activity of resolvase that is distinct from recombination. However, the two activities are functions of the same DNA-protein complex. The complex contains about 6 molecules of the resolvase dimer per molecule of DNA.

Gene regulation by proteins acting nearby and at a distance

Transcription of genes can be controlled by regulatory proteins that bind to sites on the DNA either nearby or at a considerable distance. Recent experiments suggest a unified view of these apparently disparate types of gene regulation.

Identification and characterization of recD, a gene affecting plasmid maintenance and recombination in Escherichia coli

We isolated mutations that reduce plasmid stability in dividing cell populations and mapped these mutations to a previously undescribed gene, recD, that affects recombination frequency and consequently the formation of plasmid concatemers. Insertions of the transposable element Tn10 into recD resulted in increased concatemerization and loss of pSC101 and ColE1-like replicons during nonselective growth. Both concatemer formation and plasmid instability in recD mutants require a functional recA gene. Mutations in recD are recessive to recD+ and map to a small region of the Escherichia coli chromosome located between recB and argA. Although the recD locus is distinct from loci encoding the two previously identified subunits of the RecBC enzyme, mutations in recD appear to affect the exonuclease activity of this enzyme.

Role of DNA topology in Mu transposition: mechanism of sensing the relative orientation of two DNA segments

DNA strand transfer at the initiation of Mu transposition normally requires a negatively supercoiled transposon donor molecule, containing both ends of Mu in inverted repeat orientation. We propose that the specific relative orientation of the Mu ends is needed only to energetically favor a particular configuration that the ends must adopt in a synaptic complex. The model was tested by constructing special donor DNA substrates that, because of their catenation or knotting, energetically favor this same configuration of the Mu ends, even though they are on separate molecules or in direct repeat orientation. These structures are efficient substrates for the strand transfer reaction, whereas appropriate control structures are not. The result eliminates tracking or protein scaffold models for orientation preference. Several other systems in which the relative orientation of two DNA segments is sensed may utilize the same mechanism.

Biochemical topology: applications to DNA recombination and replication

Processes of DNA rearrangement such as recombination or replication frequently have as products different subsets of the limitless number of distinguishable catenanes or knots. The use of gel electrophoresis and electron microscopy for analysis of these topological isomers has made it possible to deduce physical and geometric features of DNA structure and reaction mechanisms that are otherwise experimentally inaccessible. Quantitative as well as qualitative characterization is possible for any pathway in which the fate of a circular DNA can be followed. The history, theory, and techniques are reviewed and illustrative examples from recent studies are presented.

Two-micrometer circle site-specific recombination: the minimal substrate and the possible role of flanking sequences

The 2-mum circle DNA of yeast encodes a site-specific recombination system (FLP recombination). The recombination region had been mapped earlier to a 65-base-pair (bp) segment within the 599-bp-long inverted repeats of the molecule. I have shown that the "minimal" FLP substrate resides in a 13-bp dyad symmetry plus an 8-bp core located within the 65-bp recombination region. Further, as determined by different in vivo assays, sequences extraneous to the minimal FLP site and the 65-bp recombination region can affect the efficiency of the recombination reaction.

Discovery of a predicted DNA knot substantiates a model for site-specific recombination

The mechanism of site-specific genetic recombination mediated by Tn3 resolvase has been investigated by a topological approach. Extrapolation of a detailed model of synapsis and strand exchange predicts the formation of an additional DNA product with a specific knotted structure. Two-dimensional gel electrophoresis of DNA reacted in vitro revealed a product, about 0.1 percent of the total, with the appropriate mobility. A technique for determining DNA topology by electron microscopy was improved such that less than a nanogram of DNA was required. The structure of the knot was as predicted, providing strong evidence for the model and showing the power of the topological method.

Hin-mediated site-specific recombination requires two 26 bp recombination sites and a 60 bp recombinational enhancer

The alternate expression of flagellin genes in Salmonella is the result of an inversion of a 996 bp segment of chromosomal DNA. We have analyzed the components of this site-specific recombination reaction in an in vitro system derived from E. coli. Efficient Hin-mediated inversion requires the 20,000 MW Hin protein and a proteinase K-sensitive host component. The supercoiled DNA substrate must contain two 26 bp recombination sites in inverted configuration and a 60 bp sequence that increases the rate of recombination over 20-fold. This recombinational enhancer can function at many different locations and consists of at least two noncontiguous sequence domains whose relative orientation, but not precise spacing, with respect to each other is important. Synthetically derived wild-type and mutant recombination sites were constructed to analyze the sequence and structural features that are important within the recombination site.