The effect of mutations in the Xis-binding sites on site-specific recombination in coliphage HK022

Excisionase (Xis) is an accessory protein that is required for the excision of the related prophages lambda and HK022. Xis binds to two tandemly arranged binding sites (X1 and X2) on the P arm of the recombination sites attP and attR. Gel-retardation analyses and site-specific recombination assays were conducted on derivatives bearing site-directed mutations in the X1 and X2 sites of phage HK022. The results confirm the cooperative binding of Xis to its sites, showing that binding to X1 stimulates further binding to X2. The results also show that mutants affected in a single site are inactive in excision, whereas mutants affected in both sites, which show a complete absence of Xis binding, display significant excision activity. This restored activity is attributed to the interaction of Xis with Integrase, the protein that catalyzes the site-specific recombination reaction.     

Activity of coliphage HK022 excisionase (Xis) in the absence of DNA binding

A mutated excisionase (Xis) protein of coliphage HK022 whose single Cys residue was replaced by Ser does not bind to its two tandem binding sites (X1, X2) on the P arm of attR. Despite its DNA-binding inability the protein showed 30% excision activity of the wild type Xis both in vitro and in vivo. This partial activity is attributed to the interaction of Xis with integrase that is retained in the mutant protein. This protein-protein interaction occurs in the absence of DNA binding.     

Solution structure and stability of the full-length excisionase from bacteriophage HK022.

Heteronuclear high-resolution NMR spectroscopy was employed to determine the solution structure of the excisionase protein (Xis) from the lambda-like bacteriophage HK022 and to study its sequence-specific DNA interaction. As wild-type Xis was previously characterized as a generally unstable protein, a biologically active HK022 Xis mutant with a single amino acid substitution Cys28-->Ser was used in this work. This substitution has been shown to diminish the irreversibility of Xis denaturation and subsequent degradation, but does not affect the structural or thermodynamic properties of the protein, as evidenced by NMR and differential scanning calorimetry. The solution structure of HK022 Xis forms a compact, highly ordered protein core with two well-defined alpha-helices (residues 5-11 and 18-27) and five beta-strands (residues 2-4, 30-31, 35-36, 41-44 and 48-49). These data correlate well with 1H2O-2H2O exchange experiments and imply a different organization of the HK022 Xis secondary structure elements in comparison with the previously determined structure of the bacteriophage lambda excisionase. Superposition of both Xis structures indicates a better correspondence of the full-length HK022 Xis to the typical 'winged-helix' DNA-binding motif, as found, for example, in the DNA-binding domain of the Mu-phage repressor. Residues 51-72, which were not resolved in the lambda Xis, do not show any regular structure in HK022 Xis and thus appear to be completely disordered in solution. The resonance assignments have shown, however, that an unusual connectivity exists between residues Asn66 and Gly67 owing to asparagine-isoaspartyl isomerization. Such an isomerization has been previously observed and characterized only in eukaryotic proteins.     

Xis and Fis proteins prevent site-specific DNA inversion in lysogens of phage HK022.

HK022, a temperate coliphage related to lambda, forms lysogens by inserting its DNA into the bacterial chromosome through site-specific recombination. The Escherichia coli Fis and phage Xis proteins promote excision of HK022 DNA from the bacterial chromosome. These two proteins also act during lysogenization to prevent a prophage rearrangement: lysogens formed in the absence of either Fis or Xis frequently carried a prophage that had suffered a site-specific internal DNA inversion. The inversion is a product of recombination between the phage attachment site and a secondary attachment site located within the HK022 left operon. In the absence of both Fis and Xis, the majority of lysogens carried a prophage with an inversion. Inversion occurs during lysogenization at about the same time as prophage insertion but is rare during lytic phage growth. Phages carrying the inverted segment are viable but have a defect in lysogenization, and we therefore suggest that prevention of this rearrangement is an important biological role of Xis and Fis for HK022. Although Fis and Xis are known to promote excision of lambda prophage, they had no detectable effect on lambda recombination at secondary attachment sites. HK022 cIts lysogens that were blocked in excisive recombination because of mutation in fis or xis typically produced high yields of phage after thermal induction, regardless of whether they carried an inverted prophage. The usual requirement for prophage excision was bypassed in these lysogens because they carried two or more prophages inserted in tandem at the bacterial attachment site; in such lysogens, viable phage particles can be formed by in situ packaging of unexcised chromosomes.     

Crystal structure of the excisionase-DNA complex from bacteriophage lambda

The excisionase (Xis) protein from bacteriophage lambda is the best characterized member of a large family of recombination directionality factors that control integrase-mediated DNA rearrangements. It triggers phage excision by cooperatively binding to sites X1 and X2 within the phage, bending DNA significantly and recruiting the phage-encoded integrase (Int) protein to site P2. We have determined the co-crystal structure of Xis with its X2 DNA-binding site at 1.7A resolution. Xis forms a unique winged-helix motif that interacts with the major and minor grooves of its binding site using an alpha-helix and an ordered beta-hairpin (wing), respectively. Recognition is achieved through an elaborate water-mediated hydrogen-bonding network at the major groove interface, while the preformed hairpin forms largely non-specific interactions with the minor groove. The structure of the complex provides insights into how Xis recruits Int cooperatively, and suggests a plausible mechanism by which it may distort longer DNA fragments significantly. It reveals a surface on the protein that is likely to mediate Xis-Xis interactions required for its cooperative binding to DNA.     

Determinants of site-specific recombination in the lambdoid coliphage HK022. An evolutionary change in specificity

The temperate bacteriophage HK022, like its relative lambda, inserts its chromosome into a specific site in the bacterial chromosome during lysogenization and excises it after induction. However, we find that the recombinational specificities of the two phages differ: they use different bacterial sites, and neither promotes efficient insertion or excision of the other phage chromosome. In order to determine the basis for this difference in specificity, we sequenced the HK022 elements that are involved in insertion and excision, and compared them to the corresponding lambda elements. The location, orientation, size and overall arrangement of the int and xis genes and the phage attachment sites are nearly identical in the two genomes, as is common for other functionally related elements in lambdoid phages. The Xis proteins of the two phages are functionally interchangeable, and their predicted amino acid sequences differ by but one residue. In contrast, the two Int proteins are not functionally interchangeable, and their sequences, although similar, differ at many positions. These sequence differences are not uniformly distributed: the amino-terminal 55 residues are completely conserved, but the remaining 302 show a pattern of differences interspersed with identities and conservative changes. These findings imply that the specificity difference between HK022 and lambda site-specific recombination is a consequence of the inability of the respective Int proteins to recognize pairs of heterologous attachment sites. The two phage attachment sites are remarkably similar, especially the two "arm" segments, which in lambda contain binding sites for Int, Xis and integration host factor. They are less similar in the segment between the two arms, which in lambda contains the points of recombinational strand exchange and a second class of binding site for Int protein (the "core-type" sites). The two bacterial attachment sites are quite different, although both have a short stretch of perfect homology with their respective phage partners at the points of strand exchange. We propose that the two Int proteins recognize similar or identical sites in the arms of their cognate attachment sites, and that differences in binding or action at the core-type sites is responsible for the divergent specificities. Genetic experiments and sequence comparisons suggest that both proteins recognize different but overlapping families of core-type sites, and that divergence in specificity has been achieved by an alternating succession of small, mutually compatible changes in protein and site.     

Specificity determinants for bacteriophage Hong Kong 022 integrase: analysis of mutants with relaxed core-binding specificities

The integrase (Int) proteins encoded by bacteriophages HK022 and lambda catalyse similar site-specific integration and excision reactions between specific DNA regions known as attachment (att) sites. However, the Int proteins of HK022 and lambda are unable to catalyse recombination between non-cognate att sites. The att sites of both phages contain weak binding sites for Int, known as 'core-type' sites. Negatively acting nucleotide determinants associated with specific core sites (lambda B', HK022 B', HK022 C) are responsible for the barrier to non-cognate recombination. In this study, we used challenge phages to demonstrate that the lambda and HK022 Ints cannot bind to core sites containing non-cognate specificity determinants in vivo. We isolated mutants of the HK022 Int, which bind the lambda B' core site. Two mutants, D99N and D99A, have changed a residue in the core-binding (CB) domain, which may be directly contacting the core site DNA. We suggest that binding to the lambda B' site was accomplished by removing the negatively charged aspartate residue, which normally participates in a conflicting interaction with the G4 nucleotide of the lambda B' site. We showed that, although our mutants retain the ability to recombine their cognate att sites, they are unable to recombine lambda att sites.     

Purification and characterization of bacteriophage P22 Xis protein

The temperate bacteriophages λ and P22 share similarities in their site-specific recombination reactions. Both require phage-encoded integrase (Int) proteins for integrative recombination and excisionase (Xis) proteins for excision. These proteins bind to core-type, arm-type, and Xis binding sites to facilitate the reaction. λ and P22 Xis proteins are both small proteins (λ Xis, 72 amino acids; P22 Xis, 116 amino acids) and have basic isoelectric points (for P22 Xis, 9.42; for λ Xis, 11.16). However, the P22 Xis and λ Xis primary sequences lack significant similarity at the amino acid level, and the linear organizations of the P22 phage attachment site DNA-binding sites have differences that could be important in quaternary intasome structure. We purified P22 Xis and studied the protein in vitro by means of electrophoretic mobility shift assays and footprinting, cross-linking, gel filtration stoichiometry, and DNA bending assays. We identified one protected site that is bent approximately 137 degrees when bound by P22 Xis. The protein binds cooperatively and at high protein concentrations protects secondary sites that may be important for function. Finally, we aligned the attP arms containing the major Xis binding sites from bacteriophages λ, P22, L5, HP1, and P2 and the conjugative transposon Tn916. The similarity in alignments among the sites suggests that Xis-containing bacteriophage arms may form similar structures.     

Fis targets assembly of the Xis nucleoprotein filament to promote excisive recombination by phage lambda

The phage-encoded Xis protein is the major determinant controlling the direction of recombination in phage lambda. Xis is a winged-helix DNA binding protein that cooperatively binds to the attR recombination site to generate a curved microfilament, which promotes assembly of the excisive intasome but inhibits formation of an integrative intasome. We find that lambda synthesizes surprisingly high levels of Xis immediately upon prophage induction when excision rates are maximal. However, because of its low sequence-specific binding activity, exemplified by a 1.9 A co-crystal structure of a non-specifically bound DNA complex, Xis is relatively ineffective at promoting excision in vivo in the absence of the host Fis protein. Fis binds to a segment in attR that almost entirely overlaps one of the Xis binding sites. Instead of sterically excluding Xis binding from this site, as has been previously believed, we show that Fis enhances binding of all three Xis protomers to generate the microfilament. A specific Fis-Xis interface is supported by the effects of mutations within each protein, and relaxed, but not completely sequence-neutral, binding by the central Xis protomer is supported by the effects of DNA mutations. We present a structural model for the 50 bp curved Fis-Xis cooperative complex that is assembled between the arm and core Int binding sites whose trajectory places constraints on models for the excisive intasome structure.     

Gamma integrase complementation at the level of DNA binding and complex formation

Site-specific recombinases of the gamma Int family carry out two single-strand exchanges by binding as head-to-head dimers on inverted core-type DNA sites. Each protomer may cleave its own site as a monomer in cis (as for Cre recombinase), or it may recruit the tyrosine from its partner in trans to form a composite active site (as for Flp recombinase). The crystal structure of the gamma Int catalytic domain is compatible with both cleavage mechanisms, but two previous biochemical studies on gamma integrase (Int) generated data that were not in agreement. Support for cis and trans cleavage came from assays with bispecific DNA substrates for gamma and HK022 Ints and from functional complementation between recombination-deficient mutants, respectively. The data presented here do not provide new evidence for cis cleavage, but they strongly suggest that the previously described complementation results cannot be used in support of a trans-cleavage mechanism. We show here that IntR212Q retains some residual catalytic function but is impaired in binding to core-type DNA on linear substrates and in forming higher-order attL intasome structures. The binding-proficient mutant IntY342F can stabilize IntR212Q binding to core-type DNA through protein-protein interactions. Similarly, the formation of higher-order Int complexes with arm- and core-type DNA is boosted with both mutants present. This complementation precedes cleavage and thus precludes any conclusions about the mechanism of catalysis. Cross-core stimulation of wild-type HK022-Int cleavage on its cognate site (in cis) by mutant gamma Ints on bispecific core DNA suicide substrates is shown to be independent of the catalytic tyrosine but appears to be proportional to the respective core-binding affinities of the gamma Int mutants.     

Site-specific recombination in human cells catalyzed by the wild-type integrase protein of coliphage HK022

The activity of the Integrase (Int) protein encoded by coliphage HK022 was tested in a human cell culture. Plasmids were constructed as substrates that carry the sites of the integration reaction (attP and attB) or the sites of excision (attL and attR). The site-specific recombination reactions were monitored in cis and in trans configurations by the expression of the green fluorescent protein (GFP) as a reporter. Cells cotransfected with the substrate plasmid(s) and with a plasmid that expresses the wild-type Int show efficient integration as well as excision in both configurations. The wild-type Int was active in the human cells without the need to supply the accessory proteins integration host factor (IHF) and excisionase (Xis) that are indispensable for the reaction in the bacterial host.     

Characterization of bacteriophage lambda excisionase mutants defective in DNA binding

The bacteriophage lambda excisionase (Xis) is a sequence-specific DNA binding protein required for excisive recombination. Xis binds cooperatively to two DNA sites arranged as direct repeats on the phage DNA. Efficient excision is achieved through a cooperative interaction between Xis and the host-encoded factor for inversion stimulation as well as a cooperative interaction between Xis and integrase. The secondary structure of the Xis protein was predicted to contain a typical amphipathic helix that spans residues 18 to 28. Several mutants, defective in promoting excision in vivo, were isolated with mutations at positions encoding polar amino acids in the putative helix (T. E. Numrych, R. I. Gumport, and J. F. Gardner, EMBO J. 11:3797-3806, 1992). We substituted alanines for the polar amino acids in this region. Mutant proteins with substitutions for polar amino acids in the amino-terminal region of the putative helix exhibited decreased excision in vivo and were defective in DNA binding. In addition, an alanine substitution at glutamic acid 40 also resulted in altered DNA binding. This indicates that the hydrophilic face of the alpha-helix and the region containing glutamic acid 40 may form the DNA binding surfaces of the Xis protein.     

Characterization of the bacteriophage lambda excisionase (Xis) protein: the C-terminus is required for Xis-integrase cooperativity but not for DNA binding.

We have performed a mutational analysis of the xis gene of bacteriophage lambda. The Xis protein is 72 amino acids in length and required for excisive recombination. Twenty-six mutants of Xis were isolated that were impaired or deficient in lambda excision. Mutant proteins that contained amino acid substitutions in the N-terminal 49 amino acids of Xis were defective in excisive recombination and were unable to bind DNA. In contrast, one mutant protein containing a leucine to proline substitution at position 60 and two truncated proteins containing either the N-terminal 53 or 64 amino acids continued to bind lambda DNA, interact cooperatively with FIS and promote excision. However, these three mutants were unable to bind DNA cooperatively with Int. Cooperativity between wild-type Xis and Int required the presence of FIS, but not the Int core-type binding sites. This study shows that Xis has at least two functional domains and also demonstrates the importance of the cooperativity in DNA binding of FIS, Xis and Int in lambda excision.     

Xis protein of the conjugative transposon Tn916 plays dual opposing roles in transposon excision

The binding of Tn916 Xis protein to its specific sites at the left and right ends of the transposon was compared using gel mobility shift assays. Xis formed two complexes with different electrophoretic mobilities with both right and left transposon ends. Complex II, with a reduced mobility, formed at higher concentrations of Xis and appeared at an eightfold lower Xis concentration with a DNA fragment from the left end of the transposon rather than with a DNA fragment from the right end of the transposon, indicating that Xis has a higher affinity for the left end of the transposon. Methylation interference was used to identify two G residues that were essential for binding of Xis to the right end of Tn916. Mutations in these residues reduced binding of Xis. In an in vivo assay, these mutations increased the frequency of excision of a minitransposon from a plasmid, indicating that binding of Xis at the right end of Tn916 inhibits transposon excision. A similar mutation in the specific binding site for Xis at the left end of the transposon did not reduce the affinity of Xis for the site but did perturb binding sufficiently to alter the pattern of protection by Xis from nuclease cleavage. This mutation reduced the level of transposon excision, indicating that binding of Xis to the left end of Tn916 is required for transposon excision. Thus, Xis is required for transposon excision and, at elevated concentrations, can also regulate this process.     

The molecular basis of co-operative DNA binding between lambda integrase and excisionase

Higher-order nucleoprotein complexes often stabilize catalytic proteins in appropriate conformations for optimal activity and contribute to regulation during reactions requiring association of proteins and DNA. Formation of such complexes, known as intasomes, is required for site-specific recombination catalysed by bacteriophage Lambda Integrase protein (Int). Int-catalysed recombination is regulated by a second bacteriophage-encoded protein, Excisionase (Xis), which both stimulates excision and inhibits integration. To exert its effect, Xis binds co-operatively with Int, thereby inducing and stabilizing a DNA bend that alters the intasome structures formed during recombination. A rare int mutant, int 2268 ts, was reported (Enquist, L.W. and Weisberg, R.A. (1984) Mol Gen Genet 195: 62-69) to be more defective for excision than integration. Here, we have determined that this mutant Int protein contains an E47K substitution, and that the resultant excision-specific defect is due, at least in part, to destabilized interactions between Int and Xis. Analysis of several engineered substitutions at Int position 47 showed that a negatively charged residue is required for co-operative DNA binding between Int and Xis, and suggest that the Int-E47 residue may contact Xis directly. Substitutions at Int position 47 also affect co-operative binding among Int proteins at arm-type DNA sites, and thereby reduce the efficiency of both integration and excision. Collectively, these results suggest that a single surface of the Int amino-terminal domain mediates two alternate types of co-operative binding interactions.     

Xis protein binding to the left arm stimulates excision of conjugative transposon Tn916

Tn916 and related conjugative transposons are clinically significant vectors for the transfer of antibiotic resistance among human pathogens, and they excise from their donor organisms using the transposon-encoded integrase ((Tn916)Int) and excisionase ((Tn916)Xis) proteins. In this study, we have investigated the role of the (Tn916)Xis protein in stimulating excisive recombination. The functional relevance of (Tn916)Xis binding sites on the arms of the transposon has been assessed in vivo using a transposon excision assay. Our results indicate that in Escherichia coli the stimulatory effect of the (Tn916)Xis protein is mediated by sequence-specific binding to either of its two binding sites on the left arm of the transposon. These sites lie in between the core and arm sites recognized by (Tn916)Int, suggesting that the (Tn916)Xis protein enhances excision in a manner similar to the excisionase protein of bacteriophage lambda, serving an architectural role in the stabilization of protein-nucleic acid structures required for strand synapsis. However, our finding that excision in E. coli is significantly enhanced by the host factor HU, but does not depend on the integration host factor or the factor for inversion stimulation, defines clear mechanistic differences between Tn916 and bacteriophage lambda recombination.     

Arm site independence of coliphage HK022 integrase in human cells

The integrase encoded by the lambdoid phage HK022 (Int-HK022) resembles its coliphage λ counterpart (Int-λ) in the roles of the cognate DNA arm binding sites and in controlling the direction of the reaction. We show here that within mammalian cells, Int-HK022 does not exhibit such a control. Rather, Int-HK022 recombined between all ten possible pairwise att site combinations, including attB × attB that was more effective than the conventional integrative attP × attB reaction. We further show that Int-HK022 depends on the accessory integration host factor (IHF) protein considerably less than Int-λ and exhibits stronger binding affinity to the att core. These differences explain why wild-type Int-HK022 is active in mammalian cells whereas Int-λ is active there only as an IHF-independent mutant.     

The Structure of Xis Reveals the Basis for Filament Formation and Insight into DNA Bending within a Mycobacteriophage Intasome

The recombination directionality factor, Xis, is a DNA bending protein that determines the outcome of integrase-mediated site-specific recombination by redesign of higher-order protein–DNA architectures. Although the attachment site DNA of mycobacteriophage Pukovnik is likely to contain four sites for Xis binding, Xis crystals contain five subunits in the asymmetric unit, four of which align into a Xis filament and a fifth that is generated by an unusual domain swap. Extensive intersubunit contacts stabilize a bent filament-like arrangement with Xis monomers aligned head to tail. The structure implies a DNA bend of ~ 120°, which is in agreement with DNA bending measured in vitro. Formation of attR-containing intasomes requires only Int and Xis, distinguishing Pukovnik from lambda. Therefore, we conclude that, in Pukovnik, Xis-induced DNA bending is sufficient to promote intramolecular Int-mediated bridges during intasome formation.     

Differential affinity and cooperativity functions of the amino-terminal 70 residues of lambda integrase

The site-specific recombinase (Int) of bacteriophage lambda is a heterobivalent DNA-binding protein that binds two different classes of DNA-binding sites within its recombination target sites. The several functions of Int are apportioned between a large carboxy-terminal domain that cleaves and ligates DNA at each of its four "core-type" DNA-binding sites and a small amino-terminal domain, whose primary function is binding to each of its five "arm-type" DNA sites, which are distant from the core region. Int bridges between the two classes of binding sites are facilitated by accessory DNA-bending proteins that along with Int comprise higher-order recombinogenic complexes. We show here that although the 64 amino-terminal residues of Int bind efficiently to a single arm site, this protein cannot form doubly bound complexes on adjacent arm sites. However, 1-70 Int does show the same cooperative binding to adjacent arm sites as the full length protein. We also found that 1-70 Int specifies cooperative interactions with the accessory protein Xis when the two are bound to their adjacent cognate sites P2 and X1, respectively. To complement the finding that these two amino-terminal domain functions (along with arm DNA binding) are all specified by residues 1-70, we determined that Thr75 is the first residue of the minimal carboxy-terminal domain, thereby identifying a specific interdomain linker region. We have measured the affinity constants for Int binding to each of the five arm sites and the cooperativity factors for Int binding to the two pairs of adjacent arm sites, and we have identified several DNA structural features that contribute to the observed patterns of Int binding to arm sites. Taken together, the results highlight several interesting features of arm DNA binding that invite speculation about additional levels of complexity in the regulation of lambda site-specific recombination.