Site-specific recombination in bacteriophage Mu: characterization of binding sites for the DNA invertase Gin.

Site-specific DNA inversion in phage Mu is catalysed by the phage-encoded DNA invertase Gin and a host factor FIS. We demonstrate that purified Gin protein binds specifically to 34-bp sequences that flank the G segment as inverted repeats. Each inverted repeat (IR) contains two binding sites for Gin which have to be arranged in a specific configuration to constitute a recombinogenic site. While one of these sites is bound when present alone, the other site is bound only in conjunction with the first one, suggesting cooperative binding. In addition to the sites within the IR, Gin binds with lower affinity to AT-rich sequences adjacent to the IR. We demonstrate that these sites do not participate in the inversion reaction. The IR itself can be shortened to 25 bp without effect on inversion frequency. Using gel mobility shift experiments on circular permuted fragments containing the IR we show that Gin bends DNA upon binding. We discuss the possibility that DNA bending is related to the formation of a productive synaptic complex.     

Analysis of strand exchange and DNA binding of enhancer-independent Gin recombinase mutants.

The Gin recombination system of phage Mu mediates inversion of the DNA sequence between two sites (gix). In addition to Gin protein and gix sites, recombination requires an enhancer bound by the host factor FIS. We analyzed mutants of Gin that function in the absence of the enhancer and FIS and mediate deletion and intermolecular fusion in addition to inversion. The linking number changes caused by inversion imply that mutant Gin alone can form the same synaptic complex and can use the same strand exchange mechanism as the complete wild-type system. However, the linking number changes also reveal that unlike wild-type Gin, mutant Gin can recombine through more than one synaptic complex and can relax DNA in the absence of synapsis. This expanded repertoire allows mutant Gin to mediate DNA rearrangements not performed by wild-type Gin. Because mutant Gin, but not wild-type Gin, unwinds gix site DNA upon binding, we postulate that FIS and the enhancer function with (-) supercoiling to promote this unwinding with wild-type Gin. The analysis of the topological changes during DNA fusion shows that both the parallel gix site configuration and the right-handed rotation of the sites during exchange of wild-type Gin are a result of the (-) supercoiling of the substrate and the number of entrapped supercoils in the synaptic complex.     

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.     

The DNA invertase Gin of phage Mu: formation of a covalent complex with DNA via a phosphoserine at amino acid position 9.

The DNA invertase Gin encoded by bacteriophage Mu catalyses efficient site-specific recombination between inverted repeat sequences (IR) in vivo and in vitro in the presence of the host factor FIS and the recombinational enhancer. We demonstrate that Gin alone is able to introduce single strand breaks into duplex DNA fragments which contain the IR sequence. Strand cleavage is site-specific and can occur on either strand within the IR. Cleaved molecules contain Gin covalently attached to DNA. The covalent complex is formed through linkage of Gin to the 5' DNA phosphate at the site of the break via a phosphoserine. Extensive site-directed mutational analysis showed that all mutants altered at serine position 9 were completely recombination deficient in vivo and in vitro. The mutant proteins bind to DNA but lack topoisomerase activity and are unable to introduce nicks. This holds true even for a conservative amino acid substitution at position 9. We conclude that serine at position 9 is part of the catalytic domain of Gin. The intriguing finding that the DNA invertase Gin has the same catalytic center as the DNA resolvases that promote deletions without recombinational enhancer and host factor FIS is discussed.     

Stimulation of DNA inversion by FIS: evidence for enhancer-independent contacts with the Gin-gix complex.

Efficient DNA inversion catalysed by the invertase Gin requires the cis-acting recombinational enhancer and the Escherichia coliFIS protein. Binding of FIS bends the enhancer DNA and, on a negatively supercoiled DNA inversion substrate, facilitates the formation of a synaptic complex with specific topology. Previous studies have indicated that FIS-independent Gin mutants can be isolated which have lost the topological constraints imposed on the inversion reaction yet remain sensitive to the stimulatory effect of FIS. Whether the effect of FIS is purely architectural, or whether in addition direct protein contacts between Gin and FIS are required for efficient catalysis has remained an unresolved question. Here we show that FIS mutants impaired in DNA binding are capable of either positively or negatively affecting the inversion reaction both in vivo and in vitro. We further demonstrate that the mutant protein FIS K25E/V66A/M67T dramatically enhances the cleavage of recombination sites by FIS-independent Gin in an enhancer-independent manner. Our observations suggest that FIS plays a dual role in the inversion reaction and stimulates both the assembly of the synaptic complex as well as DNA strand cleavage.     

Purification and properties of the DNA invertase gin encoded by bacteriophage Mu

The host range of bacteriophage Mu is regulated through an invertible segment. Inversion requires the presence of two properly oriented recombination sites and a recombinational enhancer sis. The reaction is catalyzed by the Mu-encoded DNA invertase Gin and a host factor termed factors for inversion stimulation (FISs). We present a novel purification scheme for Gin. Purified Gin alone catalyzes the inversion reaction at very low efficiency recombining less than 0.8% of substrate molecules. When supplemented with FIS substrates containing the recombinational enhancer are recombined efficiently. Stoichiometric amounts of Gin are required for recombination.     

Crystal structure of an intermediate of rotating dimers within the synaptic tetramer of the G-segment invertase

The serine family of site-specific DNA recombination enzymes accomplishes strand cleavage, exchange and religation using a synaptic protein tetramer. A double-strand break intermediate in which each protein subunit is covalently linked to the target DNA substrate ensures that the recombination event will not damage the DNA. The previous structure of a tetrameric synaptic complex of γδ resolvase linked to two cleaved DNA strands had suggested a rotational mechanism of recombination in which one dimer rotates 180° about the flat exchange interface for strand exchange. Here, we report the crystal structure of a synaptic tetramer of an unliganded activated mutant (M114V) of the G-segment invertase (Gin) in which one dimer half is rotated by 26° or 154° relative to the other dimer when compared with the dimers in the synaptic complex of γδ resolvase. Modeling shows that this rotational orientation of Gin is not compatible with its being able to bind uncleaved DNA, implying that this structure represents an intermediate in the process of strand exchange. Thus, our structure provides direct evidence for the proposed rotational mechanism of site-specific recombination.     

A DNA-binding domain swap converts the invertase gin into a resolvase

DNA resolvases and invertases are closely related, yet catalyze recombination within two distinct nucleoprotein structures termed synaptosomes and invertasomes, respectively. Different protein-protein and protein-DNA interactions guide the assembly of each type of recombinogenic complex, as well as the subsequent activation of DNA strand exchange. Here we show that invertase Gin catalyzes factor for inversion stimulation dependent inversion on isolated copies of sites I from ISXc5 res, which is typically utilized by the corresponding resolvase. The concomitant binding of Gin to sites I and III in res, however, inhibits recombination. A chimeric recombinase, composed of the catalytic domain of Gin and the DNA-binding domain of ISXc5 resolvase, recombines two res with high efficiency. Gin must therefore contain residues proficient for both synaptosome formation and activation of strand exchange. Surprisingly, this chimera is unable to assemble a productive invertasome; a result which implies a role for the C-terminal domain in invertasome formation that goes beyond DNA binding.     

Self-control in DNA site-specific recombination mediated by the tyrosine recombinase TnpI

Tn4430 is a distinctive transposon of the Tn3 family that encodes a tyrosine recombinase (TnpI) to resolve replicative transposition intermediates. The internal resolution site of Tn4430 (IRS, 116 bp) contains two inverted repeats (IR1 and IR2) at the crossover core site, and two additional TnpI binding motifs (DR1 and DR2) adjacent to the core. Deletion analysis demonstrated that DR1 and DR2 are not required for recombination in vivo and in vitro. Their function is to provide resolution selectivity to the reaction by stimulating recombination between directly oriented sites on a same DNA molecule. In the absence of DR1 and/or DR2, TnpI-mediated recombination of supercoiled DNA substrates gives a mixture of topologically variable products, while deletion between two wild-type IRSs exclusively produces two-noded catenanes. This demonstrates that TnpI binding to the accessory motifs DR1 and DR2 contributes to the formation of a specific synaptic complex in which catalytically inert recombinase subunits act as architectural elements to control recombination sites pairing and strand exchange. A model for the organization of TnpI/IRS recombination complex is presented.     

Isolation and characterization of unusual gin mutants.

Site-specific inversion of the G segment in phage Mu DNA is promoted by two proteins, the DNA invertase Gin and the host factor FIS. Recombination occurs if the recombination sites (IR) are arranged as inverted repeats and a recombinational enhancer sequence is present in cis. Intermolecular reactions as well as deletions between direct repeats of the IRs rarely occur. Making use of a fis- mutant of Escherichia coli we have devised a scheme to isolate gin mutants that have a FIS independent phenotype. This mutant phenotype is caused by single amino acid changes at five different positions of gin. The mutant proteins display a whole set of new properties in vivo: they promote inversions, deletions and intermolecular recombination in an enhancer- and FIS-independent manner. The mutants differ in recombination activity. The most active mutant protein was analysed in vitro. The loss of site orientation specificity was accompanied with the ability to recombine even linear substrates. We discuss these results in connection with the role of the enhancer and FIS protein in the wild-type situation.     

DNA inversions in phages and bacteria

In certain phages and bacteria, there is a recombination system that specifically promotes the inversion of a DNA fragment. These inversion events appear to act as genetic switches allowing the alternate expression of different sets of genes which in general code for surface proteins. The mechanism of inversion in one class of inversion systems (Gin/Hin) has been studied in detail. It involves the formation of a highly specific nucleoprotein complex in which not only the two recombination sites and the DNA invertase participate but also a recombinational enhancer to which the DNA-bending protein Fis is bound.     

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.     

Purification and properties of the Escherichia coli host factor required for inversion of the G segment in bacteriophage Mu

G inversion in bacteriophage Mu requires the product of the DNA invertase gene gin and an Escherichia coli host factor termed FIS (factor for inversion stimulation). A recombination substrate must contain two recombination sites, arranged as inverted repeats, and a recombinational enhancer sequence termed sis. FIS has been purified to homogeneity. The purified protein has a relative molecular weight of 12,000 when analyzed under denaturing conditions. The intact protein behaves as a dimer of relative molecular weight 25,000 in gel filtration analysis. The purified protein does not possess any recombinogenic activity when assayed in the absence of the DNA-invertase Gin. In the presence of purified Gin FIS is the only additional protein required for efficient inversion. By performing gel retention assays, we show that FIS is a DNA-binding protein, which specifically binds to DNA fragments containing the recombinational enhancer sis.     

Altered directionality in the Cre-LoxP site-specific recombination pathway

The site-specific recombinase Cre must employ control mechanisms to impose directionality on recombination. When two recombination sites (locus of crossing over in phage P1, loxP) are placed as direct repeats on the same DNA molecule, collision between loxP-bound Cre dimers leads to excision of intervening DNA. If two sites are placed as inverted repeats, the intervening segment is flipped around. Cre catalyzes these reactions in the absence of protein co-factors. Current models suggest that directionality is controlled at two steps in the recombination pathway: the juxtaposition of loxP sites and the single-strand-transfer reactions within the synaptic complex. Here, we show that in Escherichia coli strain 294-Cre, directionality for recombination is altered when the expression of Cre is increased. This leads to deletion instead of inversion on substrates carrying two loxP sites as inverted repeats. The nucleotide sequence composition of loxP sites remaining in aberrant products indicates that site alignment and/or DNA strand transfer in the in vivo Cre-loxP recombination pathway are not always tightly controlled.     

The architecture of the gammadelta resolvase crossover site synaptic complex revealed by using constrained DNA substrates

Activated mutants of the serine recombinase, gammadelta resolvase, form a simplified recombinogenic synaptic complex containing a tetramer of resolvase and two crossover sites. We have probed the architecture of this complex by measuring the efficiency of recombination of a series of constrained DNA substrates (with phased recombination sites separated by an IHF-induced U-turn); this serves as a direct report on the topology of a productive synapse. Our data show that in the active complex, the catalytic domains from two resolvase dimers form a central core, while the DNA binding domains and the DNA lie on the outside. In addition, the crossover sites cross one another to form a local positive node. The implications of our data for the mechanism of strand exchange and the process of resolvase activation are discussed.     

Topological analysis of Hin-catalysed DNA recombination in vivo and in vitro

In vitro studies have demonstrated that Hin-catalysed site-specific DNA inversion occurs within a tripartite invertasome complex assembled at a branch on a supercoiled DNA molecule. Multiple DNA exchanges within a recombination complex (processive recombination) have been found to occur with particular substrates or reaction conditions. To investigate the mechanistic properties of the Hin recombination reaction in vivo, we have analysed the topology of recombination products generated by Hin catalysis in growing cells. Recombination between wild-type recombination sites in vivo is primarily limited to one exchange. However, processive recombination leading to knotted DNA products is efficient on substrates containing recombination sites with non-identical core nucleotides. Multiple exchanges are limited by a short DNA segment between the Fis-bound enhancer and closest recombination site and by the strength of Fis-Hin interactions, implying that the enhancer normally remains associated with the recombining complex throughout a single exchange reaction, but that release of the enhancer leads to multiple exchanges. This work confirms salient mechanistic aspects of the reaction in vivo and provides strong evidence for the propensity of plectonemically branched DNA in prokaryotic cells. We also demonstrated that a single DNA exchange resulting in inversion in vitro is accompanied by a loss of four negative supercoils.     

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.     

Alterations in the directionality of lambda site-specific recombination catalyzed by mutant integrases in vivo.

Phage lambda integrative and excisive recombination normally proceeds by a pair of sequential strand exchanges. During the first exchange reaction, the "top" strand in each recombination site is cleaved, exchanged, and religated generating a Holliday junction intermediate. This intermediate DNA structure is resolved through a pair of reciprocal "bottom" strand exchanges, leading to recombinant products. The strict co-ordination of exchange reactions ensures religation between correct partner strands only. Here we show that the directionality of recombination is altered in vivo by two mutant integrases, Int-h (E174 K) and a double mutant Int-h/218 (E174 K/E218 K). This change in directionality leads to deletion instead of inversion on substrates that carry inverted attachment sites and, depending on the pair of target sites employed, requires the presence or absence of integration host factor. Neither Fis nor Xis is involved in deletion. Sequence analyses of deletion products reveal that the newly generated hybrid attachment site exhibits a reversed genetic polarity. We demonstrate that only one of two possible hybrid site configurations is generated and discuss two pathways leading to deletion. In the first, deletion results from a wrong alignment of the two recombination sites within the synaptic complex. In the second pathway, the unco-ordinated cleavage by the mutant integrases of all four DNA strands present in a conventional Holliday junction intermediate leads to two double-stranded breaks, whereby the subsequent rejoining between "wrong" partner strands appears restricted to only two strands.     

Sin recombinase from Staphylococcus aureus: synaptic complex architecture and transposon targeting

The Sin recombinase from Staphylococcus aureus builds a distinctive DNA-protein synaptic complex to regulate strand exchange. Sin binds at two sites within an 86 basepair (bp) recombination site, resH. We propose that inverted motifs at the crossover site, and tandem motifs at the regulatory site, are recognized by structurally disparate Sin dimers. An essential architectural protein, Hbsu, binds at a discrete central site in resH. Positions of Hbsu-induced DNA deformation coincide with natural targets for Tn552 integration. Remarkably, Sin has the same topological selectivity as Tn3 and gammadelta resolvases. Our model for the recombination synapse has at its core an assembly of four Sin dimers; Hbsu plays an architectural role that is taken by two resolvase dimers in models of the Tn3/gammadelta synapse.     

Gin mutants that can be suppressed by a Fis-independent mutation.

The Gin invertase of bacteriophage Mu mediates recombination between two inverted gix sites. Recombination requires the presence of a second protein, Fis, which binds to an enhancer sequence. We have isolated 24 different mutants of Gin that are impaired in DNA inversion but proficient in DNA binding. Six of these mutants could be suppressed for inversion by introduction of a second mutation, which when present in the wild-type gin gene causes a Fis-independent phenotype. Only one of the six resulting double mutants shows an inversion efficiency which is comparable to that of the wild-type Gin and which is independent of Fis. The corresponding mutation, M to I at position 108 (M108I), is located in a putative alpha-helical structure, which in the homologous gamma delta resolvase has been implicated in dimerization. The properties of the M108I mutant suggest that in Gin this dimerization helix might also be the target for Fis interaction. The five other mutants that show a restored inversion after introduction of a Fis-independent mutation appear to be completely dependent on Fis for this inversion. The corresponding mutations are located in different domains of the protein. The properties of these mutants in connection with the role of Fis in inversion will be discussed.