Smarter than the average phage

The seventh cholera pandemic emerged in the poorer nations of the world towards the end of the 20th century and continues to kill thousands of people per year. The causative agent of cholera, the Gram-negative bacterium Vibrio cholera, is only pathogenic when it contains a lysogenic bacteriophage, CTXphi, that encodes the toxin responsible for inducing massive fluid loss from the human host. Site-specific integration of CTXphi into chromosome I of V. cholera occurs at a site, dif, that is normally required for resolution of chromosome dimers generated by homologous recombination. An article in this issue of Molecular Microbiology reports the analysis of interactions between two host encoded recombinases, XerC and XerD, and the recombination sites involved in lysogeny. Surprisingly, recombination between the CTXphi attP site and the chromosomal dif site requires additional recombinase binding sites, downstream from the positions of strand exchange, which might play an architectural role. The positions of strand cleavage also differ significantly between the two sites, suggesting a novel recombination mechanism that implicates additional host factors in resolution of the Holliday junction intermediate.     

The single-stranded genome of phage CTX is the form used for integration into the genome of Vibrio cholerae

A major determinant of Vibrio cholerae pathogenicity, the cholera enterotoxin, is encoded in the genome of an integrated phage, CTXvarphi. CTXvarphi integration depends on two host-encoded tyrosine recombinases, XerC and XerD. It occurs at dif1, a 28 bp site on V. cholerae chromosome 1 normally used by XerCD for chromosome dimer resolution. The replicative form of the phage contains two pairs of binding sites for XerC and XerD in inverted orientations. Here we show that in the single-stranded genome of the phage, these sites fold into a hairpin structure, which creates a recombination target for XerCD. In the presence of XerD, XerC can catalyze a single pair of strand exchanges between this target and dif1, resulting in integration of the phage. This integration strategy explains why the rules that normally apply to tyrosine recombinase reactions seemed not to apply to CTXvarphi integration and, in particular, why integration is irreversible.     

XerCD/dif位点特异性重组

大约10%~15%的大肠杆菌在染色体复制过程中会形成染色体二聚体。大肠杆菌染色体编码的重组酶XerC和XerD作用于染色体复制终点区的dif序列,以同源重组的方式将染色体二聚体解离为单体,使细菌得以正常复制分裂。编码霍乱毒素的噬菌体CTXΦ以位点特异的方式整合入霍乱弧菌染色体,但其基因组中不含有任何重组酶基因,其整合过程需要细菌染色体编码的XerC和XerD重组酶,且整合位点与大肠杆菌dif序列相似。XerCD重组酶基因和dif位点在细菌染色体广泛存在,表明其可能是染色体二聚体解离,噬菌体及其他外源基因成分整合入染色体过程中一种广泛存在的途径。文章对XerCD/dif位点特异性重组在细菌染色体二聚体解离、外源基因整合的研究进展进行综述。     

Characterization of the binding sites of two proteins involved in the bacteriophage P2 site-specific recombination system.

Integration of the bacteriophage P2 genome into the Escherichia coli host chromosome occurs by site-specific recombination between the phage attP and E. coli attB sites. The phage-encoded 38-kDa protein, integrase, is known to be necessary for both phage integration as well as excision. In order to begin the molecular characterization of this recombination event, we have cloned the int gene and overproduced and partially purified the Int protein and an N-terminal truncated form of Int. Both the wild-type Int protein and the integration host factor (IHF) of E. coli were required to mediate integrative recombination in vitro between a supercoiled attP plasmid and a linear attB substrate. Footprint experiments revealed one Int-protected region on both of the attP arms, each containing direct repeats of the consensus sequence TGTGGACA. The common core sequences at attP and attB were also protected by Int from nuclease digestion, and these contained a different consensus sequence, AA T/A T/A C/A T/G CCC, arranged as inverted repeats at each core. A single IHF-protected site was located on the P (left) arm, placed between the core- and P arm-binding site for Int. Cooperative binding by Int and IHF to the attP region was demonstrated with band-shift assays and footprinting studies. Our data support the existence of two DNA-binding domains on Int, having unrelated sequence specificities. We propose that P2 Int, IHF, attP, and attB assemble in a higher-order complex, or intasome, prior to site-specific integrative recombination analogous to that formed during lambda integration.     

Site-Specific Recombination of Temperate Myxococcus xanthus Phage Mx8: Genetic Elements Required for Integration

Like most temperate bacteriophages, phage Mx8 integrates into a preferred locus on the genome of its host, Myxococcus xanthus, by a mechanism of site-specific recombination. The Mx8 int-attP genes required for integration map within a 2.2-kilobase-pair (kb) fragment of the phage genome. When this fragment is subcloned into a plasmid vector, it facilitates the site-specific integration of the plasmid into the 3' ends of either of two tandem tRNAAsp genes, trnD1 and trnD2, located within the attB locus of the M. xanthus genome. Although Int-mediated site-specific recombination occurs between attP and either attB1 (within trnD1) or attB2 (within trnD2), the attP x attB1 reaction is highly favored and often is accompanied by a deletion between attB1 and attB2. The int gene is the only Mx8 gene required in trans for attP x attB recombination. The int promoter lies within the 106-bp region immediately upstream of one of two alternate GTG start codons, GTG-5208 (GTG at bp 5208) and GTG-5085, for integrase and likely is repressed in the prophage state. All but the C-terminal 30 amino acid residues of the Int protein are required for its ability to mediate attP x attB recombination efficiently. The attP core lies within the int coding sequence, and the product of integration is a prophage in which the 3' end of int is replaced by host sequences. The prophage intX gene is predicted to encode an integrase with a different C terminus.     

Site-Specific Recombination of Temperate Myxococcus xanthus Phage Mx8: Regulation of Integrase Activity by Reversible, Covalent Modification

Temperate Myxococcus xanthus phage Mx8 integrates into the attB locus of the M. xanthus genome. The phage attachment site, attP, is required in cis for integration and lies within the int (integrase) coding sequence. Site-specific integration of Mx8 alters the 3' end of int to generate the modified intX gene, which encodes a less active form of integrase with a different C terminus. The phage-encoded (Int) form of integrase promotes attP x attB recombination more efficiently than attR x attB, attL x attB, or attB x attB recombination. The attP and attB sites share a common core. Sequences flanking both sides of the attP core within the int gene are necessary for attP function. This information shows that the directionality of the integration reaction depends on arm sequences flanking both sides of the attP core. Expression of the uoi gene immediately upstream of int inhibits integrative (attP x attB) recombination, supporting the idea that uoi encodes the Mx8 excisionase. Integrase catalyzes a reaction that alters the primary sequence of its gene; the change in the primary amino acid sequence of Mx8 integrase resulting from the reaction that it catalyzes is a novel mechanism by which the reversible, covalent modification of an enzyme is used to regulate its specific activity. The lower specific activity of the prophage-encoded IntX integrase acts to limit excisive site-specific recombination in lysogens carrying a single Mx8 prophage, which are less immune to superinfection than lysogens carrying multiple, tandem prophages. Thus, this mechanism serves to regulate Mx8 site-specific recombination and superinfection immunity coordinately and thereby to preserve the integrity of the lysogenic state.     

Control of directionality in the site-specific recombination system of the Streptomyces phage phiC31

The genome of the Streptomyces temperate phage phiC31 integrates into the host chromosome via a recombinase belonging to a novel group of phage integrases related to the resolvase/invertase enzymes. Previously, it was demonstrated that, in an in vitro recombination assay, phiC31 integrase catalyses integration (attP/attB recombination) but not excision (attL/attR). The mechanism responsible for this recombination site selectivity was therefore investigated. Purified integrase was shown to bind with similar apparent binding affinities to between 46 bp and 54 bp of DNA at each of the attachment sites, attP, attB, attL and attR. Assays using recombination sites of 50 bp and 51 bp for attP and attB, respectively, showed that these fragments were functional in attP/attB recombination and maintained strict site selectivity, i.e. no recombination between non-permissive sites, such as attP/attP, attB/attL, etc., was observed. Using bandshifts and supershift assays in which permissive and non-permissive combinations of att sites were used in the presence of integrase, only the attP/attB combination could generate supershifts. Recombination products were isolated from the supershifted complexes. It was concluded that these supershifted complexes contained the recombination synapse and that site specificity, and therefore directionality, is determined at the level of stable synapse formation.     

The role of supercoiling in mycobacteriophage L5 integrative recombination.

The genome of temperate mycobacteriophage L5 integrates into the chromosomes of its hosts, including Mycobacterium smegmatis , Mycobacterium tuberculosis and bacille Calmette-Guérin. This integrase-mediated site-specific recombination reaction occurs between the phage attP site and the mycobacterial attB site and requires the mycobacterial integration host factor. Here we examine the role of supercoiling in this reaction and show that integration is stimulated by DNA supercoiling but that supercoiling of either the attP or the attB substrate enhances recombination. Supercoiling thus facilitates a post-synaptic recombination event. We also show that, while supercoiling is not required for the production of a recombinagenic intasome, a mutant attP DNA deficient in binding of the host factor acquires a dependence on supercoiling for intasome formation and recombination.     

A novel site-specific recombination system derived from bacteriophage phiMR11

We report identification of a novel site-specific DNA recombination system that functions in both in vivo and in vitro, derived from lysogenic Staphylococcus aureus phage phiMR11. In silico analysis of the phiMR11 genome indicated orf1 as a putative integrase gene. Phage and bacterial attachment sites (attP and attB, respectively) and attachment junctions were determined and their nucleotide sequences decoded. Sequences of attP and attB were mostly different to each other except for a two bp common core that was the crossover point. We found several inverted repeats adjacent to the core sequence of attP as potential protein binding sites. The precise and efficient integration properties of phiMR11 integrase were shown on attP and attB in Escherichia coli and the minimum size of attP was found to be 34bp. In in vitro assays using crude or purified integrase, only buffer and substrate DNAs were required for the recombination reaction, indicating that other bacterially encoded factors are not essential for activity.     

Characterization of genetic elements required for site-specific integration of Lactobacillus delbrueckii subsp. bulgaricus bacteriophage mv4 and construction of an integration-proficient vector for Lactobacillus plantarum.

Temperate phage mv4 integrates its DNA into the chromosome of Lactobacillus delbrueckii subsp. bulgaricus strains via site-specific recombination. Nucleotide sequencing of a 2.2-kb attP-containing phage fragment revealed the presence of four open reading frames. The larger open reading frame, close to the attP site, encoded a 427-amino-acid polypeptide with similarity in its C-terminal domain to site-specific recombinases of the integrase family. Comparison of the sequences of attP, bacterial attachment site attB, and host-phage junctions attL and attR identified a 17-bp common core sequence, where strand exchange occurs during recombination. Analysis of the attB sequence indicated that the core region overlaps the 3' end of a tRNA(Ser) gene. Phage mv4 DNA integration into the tRNA(Ser) gene preserved an intact tRNA(Ser) gene at the attL site. An integration vector based on the mv4 attP site and int gene was constructed. This vector transforms a heterologous host, L. plantarum, through site-specific integration into the tRNA(Ser) gene of the genome and will be useful for development of an efficient integration system for a number of additional bacterial species in which an identical tRNA gene is present.     

Bacteriophage lambda site-specific recombination proceeds with a defined order of strand exchanges

Previous work has established that integration of the genome of bacteriophage lambda into the chromosome of its bacterial host proceeds via two independent strand exchanges, which make and then resolve a Holliday-structure intermediate. We find that a phosphorothioate substitution at the site of exchange in one strand of a recombination site depresses the yield of Holliday structures much more than a similar substitution in the other strand. Furthermore, we show that the Holliday structures that accumulate in unblocked reactions have all been made by recombination of one particular pair of strands. We conclude that there is a strong bias in the choice of strands that initiate crossing-over. Excision, the recombination reaction that excises the integrated prophage, exhibits the same bias as integration. This proves, at least at the level of strand exchange, that excision is not the simple reversal of integration. We have altered the relative orientation of parts of the phage attachment site, attP, to demonstrate that the strand-exchange bias is determined not by the local environment around the point of exchange in the core of attP but by more distant elements in its arms. This suggests that the order of the strand exchanges is dictated by an asymmetry in the way that the nucleosome-like structure that forms at attP brings the bacterial site, attB, into juxtaposition prior to strand exchange. Finally, we use the altered attP to show that homology between attP and attB is most critical when it is adjacent to the point of strand exchange.     

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.     

Positions of strand exchange in mycobacteriophage L5 integration and characterization of the attB site.

Mycobacteriophage L5 integrates into the genome of Mycobacterium smegmatis via site-specific recombination between the phage attP site and the bacterial attB site. These two sites have a 43-bp common core sequence within which strand exchange occurs and which overlaps a tRNAGly gene at attB. We show here that a 29-bp segment of DNA is necessary and sufficient for attB function and identify the positions of strand exchange.     

Plasmids carrying cloned fragments of RF DNA from the filamentous phage φLf can be integrated into the host chromosome via site-specific integration and homologous recombination

Different regions of RF DNA from the filamentous bacteriophage phiLf were cloned in Escherichia coli vectors that can not be maintained in Xanthomonas. After introduction into X. campestris pv. campestris 17 (Xc17), most of these constructs were found to integrate into the host chromosome, either by recA-dependent homologous recombination or recA-independent site-specific integration. Mutations in himA, which codes for the alpha-subunit of the Integration Host Factor, does not affect the integration. Integration occurs into a chromosomal region which harbors a copy of a defective phage (4445 bp) that shares a high degree of identity with the phiLf genome. While various parts of the 4445-bp region are susceptible to homologous recombination, site-specific integration requires the attB sequence on the chromosome and the phage attP. The attB shows a high level of sequence identity (22 out of 28 bp) to the dif site required for E. coli Xer site-specific recombination, including the 6-bp central region, and 8/11 identity in both the left XerC-binding arm and the right XerD-binding arm, with the innermost 5 nt of the arms forming a dyad symmetry that is also present in dif. The attP has the same central region and shows 10/11 identity to the dif site in the left arm, but the sequence of the right arm is less conserved than that of attB. The smallest regions still capable of mediating integration are a cloned 72-bp phiLf attP-containing sequence and a 51-bp Xc17 attB-containing sequence, which was reinserted into the Xc17 chromosome after the 4445-bp region had been deleted, indicating that accessory sequences are not necessary and that the integrase required for site-specific integration is neither specified by the 4445-bp Xc17 chromosomal region nor encoded by the phiLf genome.     

Construction of an integration-proficient vector based on the site-specific recombination mechanism of enterococcal temperate phage phiFC1

The genome of temperate phage phiFC1 integrates into the chromosome of Enterococcus faecalis KBL 703 via site-specific recombination. In this study, an integration vector containing the attP site and putative integrase gene mj1 of phage phiFC1 was constructed. A 2,744-bp fragment which included the attP site and mj1 was inserted into a pUC19 derivative containing the cat gene to construct pEMJ1-1. E. faecalis KBL 707, which does not contain the bacteriophage but which has a putative attB site within its genome, could be transformed by pEMJ1-1. Southern hybridization, PCR amplification, and DNA sequencing revealed that pEMJ1-1 was integrated specifically at the putative attB site within the E. faecalis KBL 707 chromosome. This observation suggested that the 2,744-bp fragment carrying mj1 and the attP site of phage phiFC1 was sufficient for site-specific recombination and that pEMJ1-1 could be used as a site-specific integration vector. The transformation efficiency of pEMJ1-1 was as high as 6 x 10(3) transformants/microg of DNA. In addition, a vector (pATTB1) containing the 290-bp attB region was constructed. pATTB1 was transformed into Escherichia coli containing a derivative of the pET14b vector carrying attP and mj1. This resulted in the formation of chimeric plasmids by site-specific recombination between the cloned attB and attP sequences. The results indicate that the integration vector system based on the site-specific recombination mechanism of phage phiFC1 can be used for genetic engineering in E. faecalis and in other hosts.     

Integration and excision by the large serine recombinase phiRv1 integrase

The Mycobacterium tuberculosis prophage-like element phiRv1 encodes a site-specific recombination system utilizing an integrase of the serine recombinase family. Recombination occurs between a putative attP site and the host chromosome, but is unusual in that the attB site lies within a redundant repetitive element (REP13E12) of which there are seven copies in the M. tuberculosis genome; four of these elements contain attB sites suitable for phiRv1 integration in vivo. Although the mechanism of directional control of large serine integrases is poorly understood, a recombination directionality factor (RDF) has been identified that is required for phiRv1 integrase-mediated excisive recombination in vivo. Here we describe defined in vitro recombination reactions for both phiRv1 integrase-mediated integration and excision and show that the phiRv1 RDF is not only required for excision but inhibits integrative recombination; neither reaction requires DNA supercoiling, host factors, or high-energy cofactors. Integration, excision and excise-mediated inhibition of integration require simple substrates sites, indicating that the control of directionality does not involve the manipulation of higher-order protein-DNA architectures as described for the tyrosine integrases.     

Insertion of bacteriophage phiFSW into the chromosome of Lactobacillus casei strain Shirota (S-1): characterization of the attachment sites and the integrase gene

The integrase gene (int) on the genome of φFSW, which is a temperate bacteriophage of Lactobacillus casei strain Shirota (formerly denoted as S-1), and the four attachment sites on the genomes of the phage and its host were characterized by sequencing. The φFSW integrase was found to belong to the integrase family of site-specific tyrosine recombinase. The attachment sites shared a 40bp common core within which an integrative site-specific recombination occurs. The common core was flanked on one side by an additional segment of high sequence similarity. An integration plasmid, consisting of int, the phage attachment site (attP), and a selectable marker, inserted stably into the bacterial attachment site (attB) within the common core, as did the complete prophage genome at a frequency of more than 10(3)/microg of plasmid DNA. This plasmid was used as a test system for a preliminary mutational analysis of int and attP. The attB common core was located within and near the end of an open reading frame that appears to encode a homolog to glucose 6-phosphate isomerase, an enzyme of the glycolytic pathway. It is unlikely that the prophage integration inactivates this protein, since a change of only the C-terminal amino acid is predicted because of the sequence similarity between attP and attB.     

Purification and characterization of the integrase from the Haemophilus influenzae bacteriophage HP1; identification of a four-stranded intermediate and the order of strand exchange

The integrase encoded by the temperate phage HP1 promotes the site-specific recombination between DNA sites on its genome (the attP site) and on the genome of the host Haemophilus influenzae (the attB site). The protein has been overproduced in Escherichia coli , and purified to apparent homogeneity. HP1 integrase promotes recombination of supercoiled attP -containing molecules with linear segments with attB sites. Reaction was enhanced by spermidine and by the bacterial DNA-bending protein integration host factor. The rate of recombination showed complex and related dependence upon the integrase concentration and the concentration of the supercoiled attP substrate. These relationships probably originate from the need to assemble a multi-protein complex on the attP DNA. The reaction promoted by HP1 integrase produced a four-stranded initial reaction product in which one pair of DNA strands had undergone transfer while the other pair remained intact. This four-stranded component was produced more rapidly than any product, and its steady-state level was proportional to the overall rate of reaction. This component had the kinetic and structural properties of an intermediate in the recombination reaction. The existence of this intermediate was used to determine that the two strand exchanges required for recombination of the duplex substrates proceed in a defined order.     

Xer site-specific recombination in vitro.

Two related recombinases, XerC and XerD, belonging to the lambda integrase family of enzymes, are required for Xer site-specific recombination in vivo. In order to understand the roles of these proteins in the overall reaction mechanism, an in vitro recombination system using a synthetic Holliday junction-containing substrate has been developed. Recombination of this substrate is efficient and requires both XerC and XerD. However, only exchange of one pair of strands, the one corresponding to the conversion of the Holliday junction intermediate back to the substrate, has been observed. Recombination reactions using XerC and XerD derivatives that are mutant in their presumptive catalytic residues, or are maltose-binding fusion recombinase derivatives, have demonstrated that this pair of strand exchanges is catalysed by XerC. The site of XerC-mediated cleavage has been located to between the last nucleotide of the XerC binding site and the first nucleotide of the central region. Cleavage at this site generates a free 5'-OH and a covalent complex between XerC and the 3' end of the DNA.     

phiC31-integrase-mediated, site-specific integration of transgenes in the silkworm, Bombyx mori (Lepidoptera: Bombycidae)

Transgenic silkworms can be useful for investigating the functions of genes in the post-genomic era. However, the common method of using a transposon as an insertion tool may result in the random integration of a foreign gene into the genome and suffer from a strong position effect. To overcome these problems, it is necessary to develop a site-specific integration system. It is known that phiC31 integrase has the capacity to mediate recombination between the target sequences attP and attB. To test the availability of site-specific integration in the silkworm, we first examined the efficiency of recombination between the target sites of the two plasmids in silkworm embryos and found that the frequency of recombination was very high. Then we constructed a host strain that possessed the target sequence attP using the common method. We injected the donor plasmid together with the phiC31 integrase mRNA into the embryos of the host strain and obtained positive lines. Structural analysis of the lines showed that site-specific integration occurred by recombination between the genomic attP site and the attB site of the donor plasmid. We can conclude from the results that phiC31 integrase has the ability to mediate the site-specific integration of transgenes into the silkworm chromosome.