Identification of a replication protein and repeats essential for DNA replication of the temperate lactococcal bacteriophage TP901-1

DNA replication of the temperate lactococcal bacteriophage TP901-1 was shown to involve the gene product encoded by orf13 and the repeats located within the gene. Sequence analysis of 1,500 bp of the early transcribed region of the phage genome revealed a single-stranded DNA binding protein analogue (ORF12) and the putative replication protein (ORF13). The putative origin of replication was identified as series of repeats within orf13 and was shown to confer a TP901-1 resistance phenotype when present in trans. Site-specific mutations were introduced into the replication protein and into the repeats. The mutations were introduced into the TP901-1 prophage by homologous recombination by using a vector with a temperature-sensitive replicon. Subsequent analysis of induced phages showed that the protein encoded by orf13 and the repeats within orf13 were essential for phage TP901-1 amplification. In addition, analyses of internal phage DNA replication showed that the ORF13 protein and the repeats are essential for phage TP901-1 DNA replication in vivo. These results show that orf13 encodes a replication protein and that the repeats within the gene are the origin of replication.     

Phage TP901-1 site-specific integrase functions in human cells

We demonstrate that the site-specific integrase encoded by phage TP901-1 of Lactococcus lactis subsp. cremoris has potential as a tool for engineering mammalian genomes. We constructed vectors that express this integrase in Escherichia coli and in mammalian cells and developed a simple plasmid assay to measure the frequency of intramolecular integration mediated by the integrase. We used the assay to document that the integrase functions efficiently in E. coli and determined that for complete reaction in E. coli, the minimal sizes of attB and attP are 31 and 50 bp, respectively. We carried out partial purification of TP901-1 integrase protein and demonstrated its functional activity in vitro in the absence of added cofactors, characterizing the time course and temperature optimum of the reaction. Finally, we showed that when expressed in human cells, the TP901-1 integrase carries out efficient intramolecular integration on a transfected plasmid substrate in the human cell environment. The TP901-1 phage integrase thus represents a new reagent for manipulating DNA in living mammalian cells.     

Identification of a Replication Protein and Repeats Essential for DNA Replication of the Temperate Lactococcal Bacteriophage TP901-1

DNA replication of the temperate lactococcal bacteriophage TP901-1 was shown to involve the gene product encoded by orf13 and the repeats located within the gene. Sequence analysis of 1,500 bp of the early transcribed region of the phage genome revealed a single-stranded DNA binding protein analogue (ORF12) and the putative replication protein (ORF13). The putative origin of replication was identified as series of repeats within orf13 and was shown to confer a TP901-1 resistance phenotype when present in trans. Site-specific mutations were introduced into the replication protein and into the repeats. The mutations were introduced into the TP901-1 prophage by homologous recombination by using a vector with a temperature-sensitive replicon. Subsequent analysis of induced phages showed that the protein encoded by orf13 and the repeats within orf13 were essential for phage TP901-1 amplification. In addition, analyses of internal phage DNA replication showed that the ORF13 protein and the repeats are essential for phage TP901-1 DNA replication in vivo. These results show that orf13 encodes a replication protein and that the repeats within the gene are the origin of replication.     

Identification of the lower baseplate protein as the antireceptor of the temperate lactococcal bacteriophages TP901-1 and Tuc2009

The first step in the infection process of tailed phages is recognition and binding to the host receptor. This interaction is mediated by the phage antireceptor located in the distal tail structure. The temperate Lactococcus lactis phage TP901-1 belongs to the P335 species of the Siphoviridae family, which also includes the related phage Tuc2009. The distal tail structure of TP901-1 is well characterized and contains a double-disk baseplate and a central tail fiber. The structural tail proteins of TP901-1 and Tuc2009 are highly similar, but the phages have different host ranges and must therefore encode different antireceptors. In order to identify the antireceptors of TP901-1 and Tuc2009, a chimeric phage was generated in which the gene encoding the TP901-1 lower baseplate protein (bppL(TP901-1)) was exchanged with the analogous gene (orf53(2009)) of phage Tuc2009. The chimeric phage (TP901-1C) infected the Tuc2009 host strain efficiently and thus displayed an altered host range compared to TP901-1. Genomic analysis and sequencing verified that TP901-1C is a TP901-1 derivative containing the orf53(2009) gene in exchange for bppL(TP901-1); however, a new sequence in the late promoter region was also discovered. Protein analysis confirmed that TP901-1C contains ORF53(2009) and not the lower baseplate protein BppL(TP901-1), and it was concluded that BppL(TP901-1) and ORF53(2009) constitute antireceptor proteins of TP901-1 and Tuc2009, respectively. Electron micrographs revealed altered baseplate morphology of TP901-1C compared to that of the parental phage.     

Bacteriophage T12 of Streptococcus pyogenes integrates into the gene encoding a serine tRNA

The region of temperate bacteriophage T12 responsible for integration into the chromosome of Streptococcus pyogenes has been identified. The integrase gene ( int ) and the phage attachment site ( attP ) are found immediately upstream of the gene for speA , the latter of which is known to be responsible for the production of erythrogenic toxin A (also known as pyrogenic exotoxin A). The integrase gene has a coding capacity for a protein of 41 457 Da, and the C-terminus of the deduced protein is similar to other conserved C-terminal regions typical of phage integrases. Upstream of int is a second open reading frame, which is capable of encoding an acidic protein of 72 amino acids (8744 Da); the position of this region in relation to int suggests it to be the phage excisionase gene ( xis ). The arms flanking the integrated prophage ( attL and attR ) were identified, allowing determination of the sequences of the phage ( attP ) and bacterial ( attB ) attachment sites. A fragment containing the integrase gene and attP was cloned into a streptococcal suicide vector; when introduced into S. pyogenes by electrotransformation, this plasmid stably integrated into the bacterial chromosome at attB . The insertion site for the phage into the S. pyogenes chromosome was found to be in the anticodon loop of a putative type II gene for a serine tRNA. attP and attB share a region of identity that is 96 bp in length; this region of identity corresponds to the 3' end of the tRNA gene such that the coding sequence remains intact after integration of the prophage. The symmetry of the core region of att may set this region apart from previously described phage attachment sites (Campbell, 1992), and may play a role in the biology of this medically important bacteriophage.     

Construction of specific erythromycin resistance mutations in the temperate lactococcal bacteriophage TP901-1 and their use in studies of phage biology.

A method for the construction and isolation of specifically designed mutations of the temperate lactococcal phage TP901-1 has been developed. Two different erm-labeled mutants were isolated. One was shown to be defective in lysogenization and excision. The other, showing normal lysogenization, was used for host range studies.     

High-throughput Binary Vectors for Plant Gene Function Analysis

A series of high-throughput binary cloning vectors were constructed to facilitate gene function analysis in higher plants. This vector series consists of plasmids designed for plant expression, promoter analysis, gene silencing, and green fluorescent protein fusions for protein localization. These vectors provide for high-throughput and efficient cloning utilizing sites for λ phage integrase/excisionase. In addition, unique restriction sites are incorporated in a multiple cloning site and enable promoter replacement. The entire vector series are available with complete sequence information and detailed annotations and are freely distributed to the scientific community for non-commercial uses.     

Regulation of directionality in bacteriophage lambda site-specific recombination: structure of the Xis protein

Upon induction of a bacteriophage lambda lysogen, a site-specific recombination reaction excises the phage genome from the chromosome of its bacterial host. A critical regulator of this process is the phage-encoded excisionase (Xis) protein, which functions both as a DNA architectural factor and by cooperatively recruiting integrase to an adjacent binding site specifically required for excision. Here we present the three-dimensional structure of Xis and the results of a structure-based mutagenesis study to define the molecular basis of its function. Xis adopts an unusual "winged"-helix motif that is modeled to interact with the major- and minor-grooves of its binding site through a single alpha-helix and loop structure ("wing"), respectively. The C-terminal tail of Xis, which is required for cooperative binding with integrase, is unstructured in the absence of DNA. We propose that asymmetric bending of DNA by Xis positions its unstructured C-terminal tail for direct contacts with the N-terminal DNA-binding domain of integrase and that an ensuing disordered to ordered transition of the tail may act to stabilize the formation of the tripartite integrase-Xis-DNA complex required for phage excision.     

The Shiga-toxin VT2-encoding bacteriophage varphi297 integrates at a distinct position in the Escherichia coli genome

The plaque-forming VT2-encoding lambdoid bacteriophage varphi297 was isolated from a Belgian clinical Escherichia coli O157:H7 isolate. PCR walking, starting from the int gene of phage varphi297, demonstrated that the varphi297 prophage integrated in the yecE gene of a lysogenic E. coli K12 strain. This integration site, in E. coli K12 and in the original clinical O157:H7 isolate, was confirmed by PCR using primers flanking this site. The excisionase protein of phage varphi297 is identical to the excisionase of VT1-encoding phage VT1-Sakai, while the integrases, which are 82% identical, show significant sequence divergence in the central and C-terminal region. This can explain the different integration sites of both prophages. The activity of the integrase was proven by its ability to mediate the integration of a suicide plasmid, carrying the attachment site of varphi297, at the appropriate position in the E. coli chromosome.     

TPW22, a lactococcal temperate phage with a site-specific integrase closely related to Streptococcus thermophilus phage integrases

The temperate phage TPW22, induced from Lactococcus lactis subsp. cremoris W22, and the evolutionarily interesting integrase of this phage were characterized. Phage TPW22 was propagated lytically on L. lactis subsp. cremoris 3107, which could also be lysogenized by site-specific integration. The attachment site (attP), 5'-TAAGGCGACGGTCG-3', of phage TPW22 was present on a 7.5-kb EcoRI fragment, a 3.4-kb EcoRI-HindIII fragment of which was sequenced. Sequence information revealed the presence of an integrase gene (int). The deduced amino acid sequence showed 42 and 28% identity with integrases of streptococcal and lactococcal phages, respectively. The identities with these integrase-encoding genes were 52 and 45%, respectively, at the nucleotide level. This could indicate horizontal gene transfer. A stable integration vector containing attP and int was constructed, and integration in L. lactis subsp. cremoris MG1363 was obtained. The existence of an exchangeable lactococcal phage integration module was suggested. The proposed module covers the phage attachment site, the integrase gene, and surrounding factor-independent terminator structures. The phages phiLC3, TP901-1, and TPW22 all have different versions of this module. Phylogenetically, the TPW22 Int links the phiLC3 lactococcal integrase with known Streptococcus thermophilus integrases.     

Structural characterization and assembly of the distal tail structure of the temperate lactococcal bacteriophage TP901-1

The tail structures of bacteriophages infecting gram-positive bacteria are largely unexplored, although the phage tail mediates the initial interaction with the host cell. The temperate Lactococcus lactis phage TP901-1 of the Siphoviridae family has a long noncontractile tail with a distal baseplate. In the present study, we investigated the distal tail structures and tail assembly of phage TP901-1 by introducing nonsense mutations into the late transcribed genes dit (orf46), tal(TP901-1) (orf47), bppU (orf48), bppL (orf49), and orf50. Transmission electron microscopy examination of mutant and wild-type TP901-1 phages showed that the baseplate consisted of two different disks and that a central tail fiber is protruding below the baseplate. Evaluation of the mutant tail morphologies with protein profiles and Western blots revealed that the upper and lower baseplate disks consist of the proteins BppU and BppL, respectively. Likewise, Dit and Tal(TP901-1) were shown to be structural tail proteins essential for tail formation, and Tal(TP901-1) was furthermore identified as the tail fiber protein by immunogold labeling experiments. Determination of infection efficiencies of the mutant phages showed that the baseplate is fundamental for host infection and the lower disk protein, BppL, is suggested to interact with the host receptor. In contrast, ORF50 was found to be nonessential for tail assembly and host infection. A model for TP901-1 tail assembly, in which the function of eight specific proteins is considered, is presented.     

Tetrameric structure of a serine integrase catalytic domain

The serine integrases have recently emerged as powerful new chromosome engineering tools in various organisms and show promise for therapeutic use in human cells. The serine integrases are structurally and mechanistically unrelated to the bacteriophage lambda integrase but share a similar catalytic domain with the resolvase/invertase enzymes typified by the resolvase proteins from transposons Tn3 and gammadelta. Here we report the crystal structure and solution properties of the catalytic domain from bacteriophage TP901-1 integrase. The protein is a dimer in solution but crystallizes as a tetramer that is closely related in overall architecture to structures of activated gammadelta-resolvase mutants. The ability of the integrase tetramer to explain biochemical experiments performed in the resolvase and invertase systems suggests that the TP901 integrase tetramer represents a unique intermediate on the recombination pathway that is shared within the serine recombinase superfamily.     

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.     

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.     

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.     

Mycobacteriophage Bxb1 integrates into the Mycobacterium smegmatis groEL1 gene

Mycobacteriophage Bxb1 is a temperate phage of Mycobacterium smegmatis and forms stable lysogens in which the Bxb1 genome is integrated into the host chromosome. Bxb1 encodes an integrase of the large serine recombinase family that catalyses integration and excision of the Bxb1 genome. We show here that Bxb1 integrates into a chromosomal attB site located within the 3' end of the groEL1 gene such that integration results in alteration of the C-terminal 21 amino acid residues. An integration-proficient plasmid vector containing the Bxb1 integrase gene and flanking DNA sequences efficiently transforms M. smegmatis via integration at attB. Bxb1-integrated recombinants are stable and fully compatible with L5 integration vectors. Strand exchange occurs within an 8 bp common core sequence present in attB and within an attP site situated immediately upstream of the phage integrase gene. Establishment of a defined in vitro system for Bxb1 integration shows that recombination occurs efficiently without requirement for high-energy cofactors, divalent metals, DNA supercoiling or additional proteins.     

Identification and characterization of mycobacteriophage L5 excisionase

The well-characterized mycobacteriophage L5 forms stable lysogens in Mycobacterium smegmatis. Establishment of lysogeny involves integration of the phage genome into the chromosome of its mycobacterial hosts through an integrase-mediated site-specific recombination event. As L5 lysogens spontaneously generate free phage particles, prophage excision must also occur, although an L5 excisionase gene had not been identified. We show here that L5 gene 36 encodes the phage excisionase and is a small, heat-stable 56-amino-acid protein that strongly stimulates excisive recombination both in vivo and in vitro. The ability to manipulate the highly directional phage integration and excision reactions will provide powerful tools for the introduction, curing and recovery of foreign genes in recombinant mycobacterial strains.     

Genomic structure of the Salmonella enterica serovar Typhimurium DT 64 bacteriophage ST64T: evidence for modular genetic architecture

The complete sequence of the double-stranded DNA genome of a serotype-converting temperate bacteriophage, ST64T, was determined. The 40,679-bp genomic sequence of ST64T has an overall GC content of 47.5% and was reminiscent of a number of lambdoid phages, in particular, P22. Inferred proteins of ST64T which exhibited a high degree of sequence similarity to P22 proteins (>90%) included the functional serotype conversion cassette, integrase, excisionase, Abc1, Abc2, early antitermination (gp24), NinD, NinH, NinZ, packaging (gp3 and gp2), head (with the exception of gp26, gp7, gp20, and gp16), and tail proteins. The putative immunity genes were highly related to those of Salmonella enterica serotype Typhimurium phage L, whereas the lysis genes were almost identical to those of S. enterica serovar Typhimurium PS3.