Phage integrases: biology and applications

Phage integrases are enzymes that mediate unidirectional site-specific recombination between two DNA recognition sequences, the phage attachment site, attP, and the bacterial attachment site, attB. Integrases may be grouped into two major families, the tyrosine recombinases and the serine recombinases, based on their mode of catalysis. Tyrosine family integrases, such as lambda integrase, utilize a catalytic tyrosine to mediate strand cleavage, tend to recognize longer attP sequences, and require other proteins encoded by the phage or the host bacteria. Phage integrases from the serine family are larger, use a catalytic serine for strand cleavage, recognize shorter attP sequences, and do not require host cofactors. Phage integrases mediate efficient site-specific recombination between two different sequences that are relatively short, yet long enough to be specific on a genomic scale. These properties give phage integrases growing importance for the genetic manipulation of living eukaryotic cells, especially those with large genomes such as mammals and most plants, for which there are few tools for precise manipulation of the genome. Integrases of the serine family have been shown to work efficiently in mammalian cells, mediating efficient integration at introduced att sites or native sequences that have partial identity to att sites. This reaction has applications in areas such as gene therapy, construction of transgenic organisms, and manipulation of cell lines. Directed evolution can be used to increase further the affinity of an integrase for a particular native sequence, opening up additional applications for genomic modification.     

Genetic manipulation of mouse embryonic stem cells by mutant lambda integrase

Mutant lambda integrases catalyze site-specific recombination reactions inside mammalian cells. Here we demonstrate that the integrase system can be used to eliminate resistance marker genes from the genome of mouse embryonic stem cells. So-called integrative and excisive recombination pathways led to the precise deletion of the neomycin gene, which was inserted together with a flanking pair of directly repeated recombination sites into the ROSA26 locus by standard targeting techniques. The excision of the resistance gene led to the expression of enhanced green fluorescence protein, which served as a means to sort out cells that had undergone site-specific recombination. Southern analysis and DNA sequencing confirmed that strand exchange reactions had occurred in the genome as expected. Hence, the integrase system may be used in conjunction with other site-specific recombinases as a tool in genome manipulation protocols.     

A method for producing transgenic cells using a multi-integrase system on a human artificial chromosome vector

The production of cells capable of expressing gene(s) of interest is important for a variety of applications in biomedicine and biotechnology, including gene therapy and animal transgenesis. The ability to insert transgenes at a precise location in the genome, using site-specific recombinases such as Cre, FLP, and ΦC31, has major benefits for the efficiency of transgenesis. Recent work on integrases from ΦC31, R4, TP901-1 and Bxb1 phages demonstrated that these recombinases catalyze site-specific recombination in mammalian cells. In the present study, we examined the activities of integrases on site-specific recombination and gene expression in mammalian cells. We designed a human artificial chromosome (HAC) vector containing five recombination sites (ΦC31 attP, R4 attP, TP901-1 attP, Bxb1 attP and FRT; multi-integrase HAC vector) and de novo mammalian codon-optimized integrases. The multi-integrase HAC vector has several functions, including gene integration in a precise locus and avoiding genomic position effects; therefore, it was used as a platform to investigate integrase activities. Integrases carried out site-specific recombination at frequencies ranging from 39.3-96.8%. Additionally, we observed homogenous gene expression in 77.3-87.5% of colonies obtained using the multi-integrase HAC vector. This vector is also transferable to another cell line, and is capable of accepting genes of interest in this environment. These data suggest that integrases have high DNA recombination efficiencies in mammalian cells. The multi-integrase HAC vector enables us to produce transgene-expressing cells efficiently and create platform cell lines for gene expression.     

PhiC31 integrase facilitates genetic approaches combining multiple recombinases

Homologous and site-specific DNA recombination has revolutionized genetic engineering. The reliability of recombinases such as Cre and FLP has allowed scientists to design complex strategies to study gene function in mammals. However, the retention of recombination sites in the genome limits the use of Cre and FLP recombinases in subsequent modifications. Access to additional recombinases in the ES cell toolbox would enormously widen the number of possibilities to manipulate the genome. In the method presented here, we combine the use of PhiC31, a site-specific integrase, with FLP to obtain site-specific insertion and replacement in pre-inserted docking sites in the genome of mouse ES cells. This method allows for the integration of any sequence of interest in a pre-defined locus, leaving Cre recombinase available for downstream applications. The selection strategy is based on a silent selection marker activated by a plasmid-delivered promoter, making the integration system highly reliable and reducing the need for extensive molecular screens. This article describes how to create "dockable" mouse embryonic stem (ES) cell lines, integrate incoming vectors, and analyze the resulting clones. Current applications of this technology are also discussed.     

Site-specific cassette exchange and germline transmission with mouse ES cells expressing phiC31 integrase

Currently two site-specific recombinases are available for engineering the mouse genome: Cre from P1 phage and Flp from yeast. Both enzymes catalyze recombination between two 34-base pair recognition sites, lox and FRT, respectively, resulting in excision, inversion, or translocation of DNA sequences depending upon the location and the orientation of the recognition sites. Furthermore, strategies have been designed to achieve site-specific insertion or cassette exchange. The problem with both recombinase systems is that when they insert a circular DNA into the genome (trans event), two cis-positioned recognition sites are created, which are immediate substrates for excision. To stabilize the trans event, functional mutant recognition sites had to be identified. None of the systems, however, allowed efficient selection-free identification of insertion or cassette exchange. Recently, an integrase from Streptomyces phage phiC31 has been shown to function in Schizosaccharomyces pombe and mammalian cells. This enzyme recombines between two heterotypic sites: attB and attP. The product sites of the recombination event (attL and attR) are not substrates for the integrase. Therefore, the phiC31 integrase is ideal to facilitate site-specific insertions into the mammalian genome.     

Site-specific recombination in eukaryotic cells mediated by mutant lambda integrases: implications for synaptic complex formation and the reactivity of episomal DNA segments

Mutant lambda integrases catalyze site-specific DNA recombination in the absence of accessory factors IHF, XIS, and negative DNA supercoiling. Here we investigate the effects that a human cellular environment exerts on these reactions in order to (i) gain further insights into mechanistic aspects of recombination in eukaryotic cells and (ii) to further develop the Int system for biotechnological applications. First, we compared intra- and intermolecular integrative as well as excisive recombination pathways on episomal substrates after co-transfection with recombinase expression vectors. Our results demonstrate that, within 24 hours after transfection, intermolecular recombination by mutant integrase is at least as efficient as intramolecular recombination. Second, a significant intermolecular recombination activity was observed between two copies of a recombination site containing only the 21 bp comprising core-type DNA sequence. This basic activity was stimulated several-fold when arm-type DNA sequences were present in addition to core sites. Therefore, one recombination pathway in human cells involves mutant integrases bound solely at core sites, which is reminiscent of the Flp/FRT and Cre/loxP pathways. The stimulatory effect of arm-type sequences could be explained by an increase in integrase concentration in the vicinity of core sites. We show, in addition, that an N-terminal truncated mutant integrase exhibited only a very weak recombinogenic activity in a eukaryotic background. This result strengthens a functional role for the N-terminal domain in recombination in addition to its arm-type DNA-binding activity. Finally, we demonstrate that low level integrative recombination by wild-type integrase is stimulated when purified integration host factor is co-transfected. This corroborates our previous conclusion that sufficient amounts of eukaryotic protein co-factors, which could functionally replace IHF, are not present in human cells. It also provides a potential means to control site-specific recombination in eukaryotic cells.     

Phage integrases for the construction and manipulation of transgenic mammals

Phage integrases catalyze site-specific, unidirectional recombination between two short att recognition sites. Recombination results in integration when the att sites are present on two different DNA molecules and deletion or inversion when the att sites are on the same molecule. Here we demonstrate the ability of the φC31 integrase to integrate DNA into endogenous sequences in the mouse genome following microinjection of donor plasmid and integrase mRNA into mouse single-cell embryos. Transgenic early embryos and a mid-gestation mouse are reported. We also demonstrate the ability of the φC31, R4, and TP901-1 phage integrases to recombine two introduced att sites on the same chromosome in human cells, resulting in deletion of the intervening material. We compare the frequencies of mammalian chromosomal deletion catalyzed by these three integrases in different chromosomal locations. The results reviewed here introduce these bacteriophage integrases as tools for site-specific modification of the genome for the creation and manipulation of transgenic mammals.     

A diversity of serine phage integrases mediate site-specific recombination in mammalian cells

This study evaluated the ability of five serine phage integrases, from phages A118, U153, Bxb1, φFC1, and φRV1, to mediate recombination in mammalian cells. Two types of recombination were investigated, including the ability of an integrase to mediate recombination between its own phage att sites in the context of a mammalian cell and the ability of an integrase to perform genomic integration pairing a phage att site with an endogenous mammalian sequence. We demonstrated that the A118 integrase mediated precise intra-molecular recombination of a plasmid containing its attB and attP sites at a frequency of ∼ 50% in human cells. The closely related U153 integrase also performed efficient recombination in human cells on a plasmid containing the attB and attP sites of A118. The integrases from phages Bxb1, φFC1, and φRV1 carried out such recombination at their attB and attP sites at frequencies ranging from 11 to 75%. Furthermore, the A118 integrase mediated recombination between its attP site on a plasmid and pseudo attB sites in the human genome, i.e. native sequences with partial identity to attB. Fifteen such A118 pseudo att sites were analyzed, and a consensus recognition site was identified. The other integrases did not mediate integration at genomic sequences at a frequency above background. These site-specific integrases represent valuable new tools for manipulating eukaryotic genomes.     

Integron integrases possess a unique additional domain necessary for activity.

Integrons are genetic elements capable of integrating genes by a site-specific recombination system catalyzed by an integrase. Integron integrases are members of the tyrosine recombinase family and possess the four invariant residues (RHRY) and conserved motifs (boxes I and II and patches I, II, and III). An alignment of integron integrases compared to other tyrosine recombinases shows an additional group of residues around the patch III motif. We have analyzed the DNA binding and recombination properties of class I integron integrase (IntI1) variants carrying mutations at residues that are well conserved among all tyrosine recombinases and at some residues from the additional motif that are conserved among the integron integrases. The well-conserved residues studied were H277 from the conserved tetrad RHRY (about 90% conserved), E121 found in the patch I motif (about 80% conserved in prokaryotic recombinases), K171 from the patch II motif (near 100% conserved), W229 and F233 from the patch III motif, and G302 of box II (about 80% conserved in prokaryotic recombinases). Additional IntI1 mutated residues were K219 and a deletion of the sequence ALER215. We observed that E121, K171, and G302 play a role in the recombination activity but can be mutated without disturbing binding to DNA. W229, F233, and the conserved histidine (H277) may be implicated in protein folding or DNA binding. Some of the extra residues of IntI1 seem to play a role in DNA binding (K219) while others are implicated in the recombination activity (ALER215 deletion).     

Cross-talk between Diverse Serine Integrases

Phage-encoded serine integrases are large serine recombinases that mediate integrative and excisive site-specific recombination of temperate phage genomes. They are well suited for use in heterologous systems and for synthetic genetic circuits as the attP and attB attachment sites are small (< 50 bp), there are no host factor or DNA supercoiling requirements, and they are strongly directional, doing only excisive recombination in the presence of a recombination directionality factor. Combining different recombinases that function independently and without cross-talk to construct complex synthetic circuits is desirable, and several different serine integrases are available. However, we show here that these functions are not reliably predictable, and we describe a pair of serine integrases encoded by mycobacteriophages Bxz2 and Peaches with unusual and unpredictable specificities. The integrases share only 59% amino acid sequence identity and the attP sites have fewer than 50% shared bases, but they use the same attB site and there is non-reciprocal cross-talk between the two systems. The DNA binding specificities do not result from differences in specific DNA contacts but from the constraints imposed by the configuration of the component half-sites within each of the attachment site DNAs.     

Challenging a Paradigm: the Role of DNA Homology in Tyrosine Recombinase Reactions

Summary: A classical feature of the tyrosine recombinase family of proteins catalyzing site-specific recombination, as exemplified by the phage lambda integrase and the Cre and Flp recombinases, is the ability to recombine substrates sharing very limited DNA sequence identity. Decades of research have established the importance of this short stretch of identity within the core regions of the substrates. Since then, several new enzymes that challenge this paradigm have been discovered and require the role of sequence identity in site-specific recombination to be reconsidered. The integrases of the conjugative transposons such as Tn916, Tn1545, and CTnDOT recombine substrates with heterologous core sequences. The integrase of the mobilizable transposon NBU1 performs recombination more efficiently with certain core mismatches. The integration of CTX phage and capture of gene cassettes by integrons also occur by altered mechanisms. In these systems, recombination occurs between mismatched sequences by a single strand exchange. In this review, we discuss literature that led to the formulation of the current strand-swapping isomerization model for tyrosine recombinases. The review then focuses on recent developments on the recombinases that challenged the paradigm that was derived from the studies of early systems.     

Core-binding specificity of bacteriophage integrases

The site-specific recombination systems of bacteriophages λ and HK022 share the same mechanism and their integrase proteins show strong homology. Nevertheless the integrase protein of each phage can only catalyze recombination between its own att sites. Previous work has shown that the specificity determinants in the att sites are located within the sequences that bind the integrase to the core of att. DNA fragments that carry attL and attR sites of each phage were challenged with each of the two integrases and the DNA-protein complexes were examined by the gel- retardation technique. The results show that each integrase can form higher-order DNA-protein complexes only with its cognate att sites, suggesting that differences in the mode of binding to the core are responsible for the specificity difference between the two integrases. Received: 16 November 1999 / Accepted: 26 January 2000     

噬菌体重组酶系统在合成生物学中的应用*

合成生物学技术采用工程化设计理念,对生物体进行有目标的设计、改造乃至重新合成,对重塑非自然功能的“人造生命”具有重要意义。噬菌体重组系统具有高效、精确和广谱适用性等特点,在基因工程、代谢工程以及生物治疗等合成生物学领域得到了广泛的应用。从基因电路、体内遗传改造和体外重组等方面全面阐述了噬菌体重组系统在合成生物学研究的现状及热点,对当前该系统的局限性进行了探讨,并就未来的研究和发展趋势进行了展望。     

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.     

Sequences in attB that affect the ability of phiC31 integrase to synapse and to activate DNA cleavage

Phage integrases are required for recombination of the phage genome with the host chromosome either to establish or exit from the lysogenic state. ϕC31 integrase is a member of the serine recombinase family of site-specific recombinases. In the absence of any accessory factors integrase is unidirectional, catalysing the integration reaction between the phage and host attachment sites, attP × attB to generate the hybrid sites, attL and attR. The basis for this directionality is due to selective synapsis of attP and attB sites. Here we show that mutations in attB can block the integration reaction at different stages. Mutations at positions distal to the crossover site inhibit recombination by destabilizing the synapse with attP without significantly affecting DNA-binding affinity. These data are consistent with the proposal that integrase adopts a specific conformation on binding to attB that permits synapsis with attP. Other attB mutants with changes close to the crossover site are able to form a stable synapse but cleavage of the substrates is prevented. These mutants indicate that there is a post-synaptic DNA recognition event that results in activation of DNA cleavage.     

In vivo and in vitro characterization of site-specific recombination of actinophage R4 integrase

The site-specific integrase of actinophage R4 belongs to the serine recombinase family. During the lysogenization process, it catalyzes site-specific recombination between the phage genome and the chromosome of Streptomyces parvulus 2297. An in vivo assay using Escherichia coli cells revealed that the minimum lengths of the recombination sites attB and attP are 50-bp and 49-bp, respectively, for efficient intramolecular recombination. The in vitro assay using overproduced R4 integrases as a hexahistidine (His(6))-glutathione-S-transferase (GST)-R4 integrase fusion protein, showed that the purified protein preparation retains the site-specific recombination activity which catalyzes the site-specific recombination between attP and attB in the intermolecular reaction. It also revealed that the inverted repeat within attP is essential for efficient in vitro intermolecular recombination. In addition, a gel shift assay showed that His(6)-GST-R4 integrase bound to the 50-bp attB and 49-bp attP specifically. Moreover, based on a detailed comparison analysis of amino acid sequences of serine integrases, we found the DNA binding region that is conserved in the serine recombinase containing the large C-terminal domain. Based on the results presented on this report, attachment sites needed in vitro and in vivo for site-specific recombination by the R4 integrase have been defined more precisely. This knowledge is useful for developing new genetic manipulation tools in the future.     

Specific DNA cleavage mediated by the integrase of conjugative transposon Tn916.

The conjugative transposon Tn916 encodes a protein called INT(Tn916) which, based on DNA sequence comparisons, is a member of the integrase family of site-specific recombinases. Integrase proteins such as INT(lambda), FLP, and XERC/D that promote site-specific recombination use characteristic, conserved amino acid residues to catalyze the cleavage and ligation of DNA substrates during recombination. The reaction proceeds by a two-step transesterification reaction requiring the formation of a covalent protein-DNA intermediate. Different requirements for homology between recombining DNA sites during integrase-mediated site-specific recombination and Tn916 transposition suggest that INT(Tn916) may use a reaction mechanism different from that used by other integrase recombinases. We show that purified INT(Tn916) mediates specific cleavage of duplex DNA substrates containing the Tn916 transposon ends and adjacent bacterial sequences. Staggered cleavages occur at both ends of the transposon, resulting in 5' hydroxyl protruding ends containing coupling sequences. These are sequences that are transferred with the transposon from donor to recipient during conjugative transposition. The nature of the cleavage products suggests that a covalent protein-DNA linkage occurs via a residue of INT(Tn916) and the 3'-phosphate group of the DNA. INT(Tn916) alone is capable of executing the strand cleavage step required for recombination during Tn916 transposition, and this reaction probably occurs by a mechanism similar to that of other integrase family site-specific recombinases.     

Site-specific recombination system based on actinophage TG1 integrase for gene integration into bacterial genomes

Phage integrases are enzymes that catalyze unidirectional site-specific recombination between the attachment sites of phage and host bacteria, attP and attB, respectively. We recently developed an in vivo intra-molecular site-specific recombination system based on actinophage TG1 serine-type integrase that efficiently acts between attP and attB on a single plasmid DNA in heterologous Escherichia coli cells. Here, we developed an in vivo inter-molecular site-specific recombination system that efficiently acted between the att site on exogenous non-replicative plasmid DNA and the corresponding att site on endogenous plasmid or genomic DNA in E. coli cells, and the recombination efficiencies increased by a factor of ~10^1–3 in cells expressing TG1 integrase over those without. Moreover, integration of attB-containing incoming plasmid DNA into attP-inserted E. coli genome was more efficient than that of the reverse substrate configuration. Together with our previous result that purified TG1 integrase functions efficiently without auxiliary host factors in vitro, these in vivo results indicate that TG1 integrase may be able to introduce attB-containing circular DNAs efficiently into attP-inserted genomes of many bacterial species in a site-specific and unidirectional manner. This system thus may be beneficial to genome engineering for a wide variety of bacterial species.     

The mechanism of ?C31 integrase directionality: experimental analysis and computational modelling

Serine integrases, DNA site-specific recombinases used by bacteriophages for integration and excision of their DNA to and from their host genomes, are increasingly being used as tools for programmed rearrangements of DNA molecules for biotechnology and synthetic biology. A useful feature of serine integrases is the simple regulation and unidirectionality of their reactions. Recombination between the phage attP and host attB sites is promoted by the serine integrase alone, giving recombinant attL and attR sites, whereas the ‘reverse’ reaction (between attL and attR) requires an additional protein, the recombination directionality factor (RDF). Here, we present new experimental data on the kinetics and regulation of recombination reactions mediated by ϕC31 integrase and its RDF, and use these data as the basis for a mathematical model of the reactions. The model accounts for the unidirectionality of the attP × attB and attL × attR reactions by hypothesizing the formation of structurally distinct, kinetically stable integrase–DNA product complexes, dependent on the presence or absence of RDF. The model accounts for all the available experimental data, and predicts how mutations of the proteins or alterations of reaction conditions might increase the conversion efficiency of recombination.