Attenuating functions of the C terminus of lambda integrase

The λ Integrase Site-specific Recombination Pathway

The site-specific recombinase encoded by bacteriophage λ (Int) is responsible for integrating and excising the viral chromosome into and out of the chromosome of its Escherichia coli host. Int carries out a reaction that is highly directional, tightly regulated, and depends upon an ensemble of accessory DNA bending proteins acting on 240 bp of DNA encoding 16 protein binding sites. This additional complexity enables two pathways, integrative and excisive recombination, whose opposite, and effectively irreversible, directions are dictated by different physiological and environmental signals. Int recombinase is a heterobivalent DNA binding protein and each of the four Int protomers, within a multiprotein 400 kDa recombinogenic complex, is thought to bind and, with the aid of DNA bending proteins, bridge one arm- and one core-type DNA site. In the 12 years since the publication of the last review focused solely on the λ site-specific recombination pathway in Mobile DNA II, there has been a great deal of progress in elucidating the molecular details of this pathway. The most dramatic advances in our understanding of the reaction have been in the area of X-ray crystallography where protein-DNA structures have now been determined for of all of the DNA-protein interfaces driving the Int pathway. Building on this foundation of structures, it has been possible to derive models for the assembly of components that determine the regulatory apparatus in the P-arm, and for the overall architectures that define excisive and integrative recombinogenic complexes. The most fundamental additional mechanistic insights derive from the application of hexapeptide inhibitors and single molecule kinetics.

Resolution of Holliday junction recombination intermediates by wild-type and mutant IntDOT proteins

CTnDOT encodes an integrase that is a member of the tyrosine recombinase family. The recombination reaction proceeds by sequential sets of genetic exchanges between the attDOT site in CTnDOT and an attB site in the chromosome. The exchanges are separated by 7 base pairs in each site. Unlike most tyrosine recombinases, IntDOT exchanges sites that contain different DNA sequences between the exchange sites to generate Holliday junctions (HJs) that contain mismatched bases. We demonstrate that IntDOT resolves synthetic HJs in vitro. Holliday junctions that contain identical sequences between the exchange sites are resolved into both substrates and products, while HJs that contain mismatches are resolved only to substrates. This result implies that resolution of HJs to products requires the formation of a higher-order nucleoprotein complex with natural sites containing IntDOT. We also found that proteins with substitutions of residues (V95, K94, and K96) in a putative alpha helix at the junction of the N and CB domains (coupler region) were defective in resolving HJs. Mutational analysis of charged residues in the coupler and the N terminus of the protein did not provide evidence for a charge interaction between the regions of the protein. V95 may participate in a hydrophobic interaction with another region of IntDOT.

Structural and functional views of salt-bridge interactions of λ integrase in the higher order recombinogenic complexes visualized by genetic method

The integrase protein encoded by bacteriophage λ (Int) catalyzes site a specific DNA recombination by which the viral chromosome is inserted into and excised out of the host genome through the formation of higher order recombinogenic nucleoprotein complexes. Genetic and biochemical studies on the Int carried out by isolating "multimer-specific" mutants had revealed informative functional characteristics of specific electrostatic interactions occurring among the functional domains of Int. The λ Int recombination system shows the usefulness of structural and functional investigation of multimeric protein complexes through genetic studies on the electrostatic interactions of proteins comprising multimeric complexes. This approach is especially powerful when combined with NMR and X-ray crystallography results providing biological evidences of specific molecular interactions among proteins.

Trans cooperativity by a split DNA recombinase: the central and catalytic domains of bacteriophage lambda integrase cooperate in cleaving DNA substrates when the two domains are not covalently linked

Site-specific recombinases of the lambda-integrase family recognize and cleave their cognate DNA sites through cooperative binding to opposite sides of the DNA substrate by a C-terminal catalytic domain and a flexibly linked "core-binding" domain; regulation of this cleavage is achieved via the formation of higher-order complexes. We report that the core-binding domain of lambda-integrase is able to stimulate the activity of the catalytic domain even when the two domains are not linked. This trans stimulation is accomplished without significantly increasing the affinity of the catalytic domain for its DNA substrate. Moreover, we show that mutations in the DNA substrate can abrogate this effect while retaining specificity determinants for cleavage. Since the domains do not significantly interact directly, this finding implies that trans activation is achieved via the DNA substrate in a manner that may be mechanistically important in this and similar DNA binding and cleaving enzymes.

Mechanisms of site-specific recombination

Integration, excision, and inversion of defined DNA segments commonly occur through site-specific recombination, a process of DNA breakage and reunion that requires no DNA synthesis or high-energy cofactor. Virtually all identified site-specific recombinases fall into one of just two families, the tyrosine recombinases and the serine recombinases, named after the amino acid residue that forms a covalent protein-DNA linkage in the reaction intermediate. Their recombination mechanisms are distinctly different. Tyrosine recombinases break and rejoin single strands in pairs to form a Holliday junction intermediate. By contrast, serine recombinases cut all strands in advance of strand exchange and religation. Many natural systems of site-specific recombination impose sophisticated regulatory mechanisms on the basic recombinational process to favor one particular outcome of recombination over another (for example, excision over inversion or deletion). Details of the site-specific recombination processes have been revealed by recent structural and biochemical studies of members of both families.

DNA arms do the legwork to ensure the directionality of lambda site-specific recombination

The integrase protein of bacteriophage lambda (Int) catalyzes site-specific recombination between lambda phage and Escherichia coli genomes. Int is a tyrosine recombinase that binds to DNA core sites via a C-terminal catalytic domain and to a collection of arm DNA sites, distant from the site of recombination, via its N-terminal domain. The arm sites, in conjunction with accessory DNA-bending proteins, provide a means of regulating the efficiency and directionality of Int-catalyzed recombination. Recent crystal structures of lambda Int tetramers bound to synaptic and Holliday junction intermediates, together with new biochemical data, suggest a mechanism for the allosteric control of the recombination reaction through arm DNA binding interactions.

Receipt of the C-terminal tail from a neighboring lambda Int protomer allosterically stimulates Holliday junction resolution

Bacteriophage lambda integrase (Int) catalyzes the integration and excision of the phage lambda chromosome into and out of the Esherichia coli host chromosome. The seven carboxy-terminal residues (C-terminal tail) of Int comprise a context-sensitive regulatory element that links catalytic function with protein multimerization and also coordinates Int functions within the multimeric recombinogenic complex. The experiments reported here show that the beta5-strand of Int is not simply a placeholder for the C-terminal tail but rather exerts its own allosteric effects on Int function in response to the incoming tail. Using a mutant integrase in which the C-terminal tail has been deleted (W350ter), we demonstrate that the C-terminal tail is required for efficient and accurate resolution of Holliday junctions by tetrameric Int. Addition of a free heptameric peptide of the same sequence as the C-terminal tail partially reverses the W350ter defects by stimulating Holliday junction resolution. The peptide also stimulates the topoisomerase function of monomeric W350ter. Single residue alterations in the peptide sequence and a mutant of the beta5 strand indicate that the observed stimulation arises from specific contacts with the beta5 strand (residues 239-243). The peptide does not stimulate binding of W350ter to its cognate DNA sites and therefore appears to recapitulate the effects of the normal C-terminal tail intermolecular contacts in wild-type Int. Models for the allosteric stimulation of Int activity by beta5 strand contacts are discussed.

Mutations in the amino-terminal domain of lambda-integrase have differential effects on integrative and excisive recombination

Lambda integrase (Int) forms higher-order protein-DNA complexes necessary for site-specific recombination. The carboxy-terminal domain of Int (75-356) is responsible for catalysis at specific core-type binding sites whereas the amino-terminal domain (1-70) is responsible for cooperative arm-type DNA binding. Alanine scanning mutagenesis of residues 64-70, within full-length integrase, has revealed differential effects on cooperative arm binding interactions that are required for integrative and excisive recombination. Interestingly, while these residues are required for cooperative arm-type binding on both P'1,2 and P'2,3 substrates, cooperative binding at the arm-type sites P'2,3 was more severely compromised than binding at arm-type sites P'1,2 for L64A. Concomitantly, L64A had a much stronger effect on integrative than on excisive recombination. The arm-binding properties of Int appear to be intrinsic to the amino-terminal domain because the phenotype of L64A was the same in an amino-terminal fragment (Int 1-75) as it was in the full-length protein.

Non-equivalent interactions between amino-terminal domains of neighboring lambda integrase protomers direct Holliday junction resolution

The bacteriophage lambda site-specific recombinase (Int), in contrast to other family members such as Cre and Flp, has an amino-terminal domain that binds "arm-type" DNA sequences different and distant from those involved in strand exchange. This defining feature of the heterobivalent recombinases confers a directionality and regulation that is unique among all recombination pathways. We show that the amino-terminal domain is not a simple "accessory" element, as originally thought, but rather is incorporated into the core of the recombination mechanism, where it is well positioned to exert its profound effects. The results reveal an unexpected pattern of intermolecular interactions between the amino-terminal domain of one protomer and the linker region of its neighbor within the tetrameric Int complex and provide insights into those features distinguishing an "active" from an "inactive" pair of Ints during Holliday junction resolution.

The efficiency of mispaired ligations by lambda integrase is extremely sensitive to context

The integrase protein (Int) of phage lambda is a well-studied representative of the tyrosine recombinase family, whose defining features are two sequential pairs of DNA cleavage/ligation reactions that proceed via a 3' phosphotyrosine covalent intermediate to first form and then resolve a Holliday junction recombination intermediate. We devised an assay that takes advantage of DNA hairpin formation at one Int target site to trap Int cleavages at a different target site, and thereby reveal iterative cycles of cleavage and ligation that would otherwise be undetected. Using this assay and others to compare wild-type Int and a mutant (R169D) defective in forming proper dimer/tetramer interfaces, we found that the efficiency of "bottom-strand" DNA cleavage by wild-type Int, but not R169D, is very sensitive to the base-pair at the "top-strand" cleavage site, seven base-pairs away. We show that this is related to the finding that hairpin formation involving ligation of a mispaired base is much faster for R169D than for wild-type Int, but only in the context of a multimeric complex. During resolution of Holliday junction recombination intermediates, wild-type Int, but not R169D, is very sensitive to homology at the sites of ligation. A long-sought insight from these results is that during Holliday junction resolution the tetrameric Int complex remains intact until after ligation of the product helices has been completed. This contrasts with models in which the second pair of DNA cleavages is a trigger for dissolution of the recombination complex.

Two structural features of lambda integrase that are critical for DNA cleavage by multimers but not by monomers

Despite many years of genetic and biochemical studies on the lambda integrase (Int) recombination system, it is still not known whether the Int protein is competent for DNA cleavage as a monomer. We have addressed this question, as part of a larger study of Int functions critical for the formation of higher-order complexes, by isolating "multimer-specific" mutants. We identify a pair of oppositely charged residues, E153 and R169, that comprise an intermolecular salt bridge within a functional Int multimer. Mutation of either of these residues significantly reduces both the cleavage of full-att sites and the resolution of Holliday junctions without compromising the cleavage of half-att site substrates. Allele-specific suppressor mutations were generated at these residues. Their interaction with wild-type Int on preformed Holliday junctions indicates that the mutated residues comprise an intermolecular salt bridge. We have also shown that the most C-terminal seven residues of Int, which comprise another previously identified subunit interface, inhibit DNA cleavage by monomeric but not multimeric Int. Taken together, our results lead us to conclude that Int can cleave DNA as a monomer. We also identify and discuss unique structural features of Int that act negatively to reduce its activity as a monomer and other features that act positively to enhance its activity as a multimer.

New insight into site-specific recombination from Flp recombinase-DNA structures

The lamba integrase, or tyrosine-based family of site-specific recombinases, plays an important role in a variety of biological processes by inserting, excising, and inverting DNA segments. Flp, encoded by the yeast 2-mum plasmid, is the best-characterized eukaryotic member of this family and is responsible for maintaining the copy number of this plasmid. Over the past several years, structural and biochemical studies have shed light on the details of a common catalytic scheme utilized by these enzymes with interesting variations under different biological contexts. The emergence of new Flp structures and solution data provides insights not only into its unique mechanism of active site assembly and activity regulation but also into the specific contributions of certain protein residues to catalysis.

The role of the conserved Trp330 in Flp-mediated recombination. Functional and structural analysis

The active site of Flp contains, in addition to a transdonated nucleophilic tyrosine, five other residues that are highly conserved within the lambda-integrase family of site-specific recombinases and the type IB topoisomerases. We have used site-directed mutagenesis and x-ray crystallography to investigate the roles of two such residues, Lys223 and Trp330. Our findings agree with studies on related enzymes showing the importance of Lys223 in catalysis but demonstrate that in Flp-mediated recombination the primary role of Trp330 is architectural rather than catalytic. Eliminating the hydrogen bonding potential of Trp330 by phenylalanine substitution results in surprisingly small changes in reaction rates, compared with dramatic decreases in the activities of W330A, W330H, and W330Q. The structure of a W330F mutant-DNA complex reveals an active site nearly identical to that of the wild type. The phenylalanine side chain preserves most of the van der Waals interactions Trp330 forms with the Tyr343-containing trans helix, which may be particularly important for the docking of this helix. Our studies of Trp330 provide the first detailed examination of this conserved residue in the lambda-integrase family, suggesting that the relative importance of active site residues may differ among Flp and related enzymes.

A conformational switch controls the DNA cleavage activity of lambda integrase

The bacteriophage lambda integrase protein (lambda Int) belongs to a family of tyrosine recombinases that catalyze DNA rearrangements. We have determined a crystal structure of lambda Int complexed with a cleaved DNA substrate through a covalent phosphotyrosine bond. In comparison to an earlier unliganded structure, we observe a drastic conformational change in DNA-bound lambda Int that brings Tyr342 into the active site for cleavage of the DNA in cis. A flexible linker connects the central and the catalytic domains, allowing the protein to encircle the DNA. Binding specificity is achieved through direct interactions with the DNA and indirect readout of the flexibility of the att site. The conformational switch that activates lambda Int for DNA cleavage exposes the C-terminal 8 residues for interactions with a neighboring Int molecule. The protein interactions mediated by lambda Int's C-terminal tail offer a mechanism for the allosteric control of cleavage activity in higher order lambda Int complexes.

Dynamics and DNA substrate recognition by the catalytic domain of lambda integrase

Bacteriophage lambda integrase (lambda-Int) is the prototypical member of a large family of enzymes that catalyze site-specific DNA recombination via the formation of a Holliday junction intermediate. DNA strand cleavage by lambda-Int is mediated by nucleophilic attack on the scissile phosphate by a conserved tyrosine residue, forming an intermediate with the enzyme covalently attached to the 3'-end of the cleaved strand via a phosphotyrosine linkage. The crystal structure of the catalytic domain of lambda-Int (C170) obtained in the absence of DNA revealed the tyrosine nucleophile at the protein's C terminus to be located on a beta-hairpin far from the other conserved catalytic residues and adjacent to a disordered loop. This observation suggested that a conformational change in the C terminus of the protein was required to generate the active site in cis, or alternatively, that the active site could be completed in trans by donation of the tyrosine nucleophile from a neighboring molecule in the recombining synapse. We used NMR spectroscopy together with limited proteolysis to examine the dynamics of the lambda-Int catalytic domain in the presence and absence of DNA half-site substrates with the goal of characterizing the expected conformational change. Although the C terminus is indeed flexible in the absence of DNA, we find that conformational changes in the tyrosine-containing beta-hairpin are not coupled to DNA binding. To gain structural insights into C170/DNA complexes, we took advantage of mechanistic conservation with Cre and Flp recombinases to model C170 in half-site and tetrameric Holliday junction complexes. Although the models do not reveal the nature of the conformational change required for cis cleavage, they are consistent with much of the available experimental data and provide new insights into the how trans complementation could be accommodated.

Protein folding coupled to DNA binding in the catalytic domain of bacteriophage lambda integrase detected by mass spectrometry

Bacteriophage lambda integrase (lambda-Int) is the prototypical member of a large family of enzymes that catalyze site-specific DNA recombination via single-strand cleavage and the formation of a Holliday junction intermediate. Crystallographic and biochemical evidence indicate that substantial conformational change (i.e., folding) in the catalytic domain of the protein is required for substrate recognition and catalysis. We have examined the solution conformation of the catalytic domain (C170) in the absence and presence of a cognate "half-site" DNA oligonucleotide by electrospray ionization mass spectrometry, and circular dichroism and fluorescence spectroscopy. The distribution of ions in the positive ion electrospray mass spectrum of the free protein reveals the presence of three distinct species in solution, one corresponding to the folded protein, one to the unfolded protein, and one to a dimer. In the presence of DNA, ions are observed only for the protein-DNA complex and the folded form of the free protein. We therefore conclude that DNA binding stabilizes the global fold of the protein in a manner that is consistent with folding-coupled target recognition as a mechanism to control site-specific recombination. Furthermore, we find that inspection of the charge state distribution of ions in electrospray mass spectra provides a quick and effective means to identify conformational heterogeneity of proteins in solution and to investigate dynamic protein-nucleic acid interactions.

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.

Regulation of site-specific recombination by the C-terminus of lambda integrase

Site-specific recombination catalyzed by bacteriophage lambda integrase (Int) is essential for establishment and termination of the viral lysogenic life cycle. Int is the archetype of the tyrosine recombinase family whose members are responsible for DNA rearrangement in prokaryotes, eukaryotes and viruses. The mechanism regulating catalytic activity during recombination is incompletely understood. Studies of tyrosine recombinases bound to their target substrates suggest that the C-termini of the proteins are involved in protein-protein contacts that control the timing of DNA cleavage events during recombination. We investigated an Int truncation mutant (W350) that possesses enhanced topoisomerase activity but greater than 100-fold reduced recombination activity. Alanine scanning mutagenesis of the C-terminus indicates that two mutants, W350A and I353A, cannot perform site-specific recombination although their DNA binding, cleavage and ligation activities are at wild-type levels. Two other mutants, R346A and R348A, are deficient solely in the ability to cleave DNA. To explain these results, we have constructed a homology-threaded model of the Int structure using a Cre crystal structure. We propose that residues R346 and R348 are involved in orientation of the catalytic tyrosine that cleaves DNA, whereas W350 and I353 control and make intermolecular contacts with other Int proteins in the higher order recombination structures known as intasomes. These results suggest that Int and the other tyrosine recombinases have evolved regulatory contacts that coordinate site-specific recombination at the C-terminus.