Construction of transgenic Drosophila by using the site-specific integrase from phage phiC31

The phiC31 integrase functions efficiently in vitro and in Escherichia coli, yeast, and mammalian cells, mediating unidirectional site-specific recombination between its attB and attP recognition sites. Here we show that this site-specific integration system also functions efficiently in Drosophila melanogaster in cultured cells and in embryos. Intramolecular recombination in S2 cells on transfected plasmid DNA carrying the attB and attP recognition sites occurred at a frequency of 47%. In addition, several endogenous pseudo attP sites were identified in the fly genome that were recognized by the integrase and used as substrates for integration in S2 cells. Two lines of Drosophila were created by integrating an attP site into the genome with a P element. phiC31 integrase injected into embryos as mRNA functioned to promote integration of an attB-containing plasmid into the attP site, resulting in up to 55% of fertile adults producing transgenic offspring. A total of 100% of these progeny carried a precise integration event at the genomic attP site. These experiments demonstrate the potential for precise genetic engineering of the Drosophila genome with the phiC31 integrase system and will likely benefit research in Drosophila and other insects.     

Gene insertion and replacement in Schizosaccharomyces pombe mediated by the Streptomyces bacteriophage phiC31 site-specific recombination system

The site-specific recombination system used by the Streptomyces bacteriophage phiC31 was tested in the fission yeast Schizosaccharomyces pombe. A target strain with the phage attachment site attP inserted at the leu1 locus was co-transformed with one plasmid containing the bacterial attachment site attB linked to a ura4+ marker, and a second plasmid expressing the phiC31 integrase gene. High-efficiency transformation to the Ura+ phenotype occurred when the integrase gene was expressed. Southern analysis revealed that the attB-ura4+ plasmid integrated into the chromosomal attP site. Sequence analysis showed that the attBxattP recombination was precise. In another approach, DNA with a ura4+ marker flanked by two attB sites in direct orientation was used to transform S. pombe cells bearing an attP duplication. The phiC31 integrase catalyzed two reciprocal cross-overs, resulting in a precise gene replacement. The site-specific insertions are stable, as no excision (the reverse reaction) was observed on maintenance of the integrase gene in the integrant lines. The irreversibility of the phiC31 site-specific recombination system sets it apart from other systems currently used in eukaryotic cells, which reverse readily. Deployment of the phiC31 recombination provides new opportunities for directing transgene and chromosome rearrangements in eukaryotic systems.     

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.     

Identification of pseudo attP sites for phage phiC31 integrase in bovine genome

Streptomyces phage phiC31 integrase was found to mediate site-specific integration of foreign genes at pseudo attP sites of genomes in human, mouse, rat, and Drosophila. This paper reports that phiC31 integrase can also mediate homologous recombination between attB and pseudo attP sites in bovine cells and foreign gene integration was increased at least 2-fold in bovine fibroblasts or Madin-Darby bovine kidney (MDBK) cells. Two intrinsic pseudo attP sites named BpsF1 and BpsM1 located in the inter-gene regions on chromosome 28 and 19, respectively, were identified in bovine genome. These pseudo attP sites shared similar characteristics with those from other species as previously described. Our study demonstrated that the phiC31 integrase system provides a new potential for genetic engineering of the bovine genome and might be beneficial for the research on ruminant.     

phiC31 Integrase-Mediated Site-Specific Recombination in Barley

The Streptomyces phage phiC31 integrase was tested for its feasibility in excising transgenes from the barley genome through site-specific recombination. We produced transgenic barley plants expressing an active phiC31 integrase and crossed them with transgenic barley plants carrying a target locus for recombination. The target sequence involves a reporter gene encoding green fluorescent protein (GFP), which is flanked by the attB and attP recognition sites for the phiC31 integrase. This sequence disruptively separates a gusA coding sequence from an upstream rice actin promoter. We succeeded in producing site-specific recombination events in the hybrid progeny of 11 independent barley plants carrying the above target sequence after crossing with plants carrying a phiC31 expression cassette. Some of the hybrids displayed fully executed recombination. Excision of the GFP gene fostered activation of the gusA gene, as visualized in tissue of hybrid plants by histochemical staining. The recombinant loci were detected in progeny of selfed F₁, even in individuals lacking the phiC31 transgene, which provides evidence of stability and generative transmission of the recombination events. In several plants that displayed incomplete recombination, extrachromosomal excision circles were identified. Besides the technical advance achieved in this study, the generated phiC31 integrase-expressing barley plants provide foundational stock material for use in future approaches to barley genetic improvement, such as the production of marker-free transgenic plants or switching transgene activity.     

Transgene excision from wheat chromosomes by phage phiC31 integrase

The Streptomyces phage phiC31 integrase was tested for its ability to excise transgenic DNA from the wheat genome by site-specific recombination. Plants that stably express phiC31 integrase were crossed to plants carrying a target construct bearing the phiC31 recognition sites, attP and attB. In the progeny, phiC31 recombinase mediates recombination between the att sites of the target locus, which results in excision of the intervening DNA. Recombination events could be identified in 34 independent wheat lines by PCR and Southern blot analysis and by sequencing of the excision footprints. Recombinant loci were inherited to the subsequent generation. The results presented here establish the integrase-att system as a tool for catalysing the precise elimination of DNA sequences from wheat chromosomes.     

Integration specificity of phage phiC31 integrase in the human genome

The site-specific integrase from bacteriophage phiC31 functions in mammalian cells and is being applied for genetic engineering, including gene therapy. The phiC31 integrase catalyzes precise, unidirectional recombination between its 30-40-bp attP and attB recognition sites. In mammalian cells, the enzyme also mediates integration of plasmids bearing attB into native sequences that have partial sequence identity with attP, termed pseudo attP sites. Here, we analyzed the features of phiC31-mediated integration into pseudo attP sites in the human genome. Sequence analysis of 196 independent integration events derived from three cell lines revealed approximately 101 integration sites: 56% of the events were recurrent integrations distributed among 19 pseudo attP sequences. Bioinformatics analysis revealed a approximately 30-bp palindromic consensus sequence motif shared by all of the repeat occurrences and most of the single occurrence sites, verifying that phiC31-mediated integration into pseudo attP sites is significantly guided by DNA sequence recognition. The most favored unique sequence in these cell lines occurred at chromosome 19q13.31 and accounted for 7.5% of integration events. Other frequent integration sites were in three specific sequences in subfamilies of ERVL and L1 repetitive sequences, accounting for an additional 17.9% of integration events. Integrations could occur in either orientation at a pseudo attP site, were often accompanied by small deletions, and typically occurred in a single copy per cell. A number of aberrant events were also described, including large deletions and chromosome rearrangements. phiC31 integrase-mediated integration only slightly favored genes and did not favor promoter regions. Gene density and expression studies suggested chromatin context effects. An analysis of the safety of integration sites in terms of proximity to cancer genes suggested minimal cancer risk. We conclude that integration systems derived from phiC31 integrase have great potential utility.     

W::Neo: a novel dual-selection marker for high efficiency gene targeting in Drosophila

We have recently developed a so-called genomic engineering approach that allows for directed, efficient and versatile modifications of Drosophila genome by combining the homologous recombination (HR)-based gene targeting with site-specific DNA integration. In genomic engineering and several similar approaches, a "founder" knock-out line must be generated first through HR-based gene targeting, which can still be a potentially time and resource intensive process. To significantly improve the efficiency and success rate of HR-based gene targeting in Drosophila, we have generated a new dual-selection marker termed W::Neo, which is a direct fusion between proteins of eye color marker White (W) and neomycin resistance (Neo). In HR-based gene targeting experiments, mutants carrying W::Neo as the selection marker can be enriched as much as fifty times by taking advantage of the antibiotic selection in Drosophila larvae. We have successfully carried out three independent gene targeting experiments using the W::Neo to generate genomic engineering founder knock-out lines in Drosophila.     

Creating transgenic Drosophila by microinjecting the site-specific phiC31 integrase mRNA and a transgene-containing donor plasmid

We describe a microinjection-based phiC31 integrase mRNA-mediated method for creating transgenic Drosophila strains. This approach is more efficient than traditional methods and ensures that the transgene is targeted to a precise genomic position. The method involves targeting integration of an exogenous plasmid (containing the transgene and sequences to facilitate integration) to a preplaced recipient site in the Drosophila genome. The plasmid is coinjected into embryos with mRNA encoding the phiC31 integrase, the enzyme that catalyzes the integration reaction. Using the protocol described here, transgenic lines can be established from, on average, 46% of fertile adults obtained after injection, and all integrations should be targeted to the chosen genomic insertion site. The whole procedure, from injection to established transgenic stocks, can be completed in three generations (approximately 1 month) and can be adapted for other types of transgenesis and mRNA injections in Drosophila.     

PhiC31 integrase induces efficient site-specific excision in zebrafish

Site-specific recombinases catalyze recombination between specific targeting sites to delete, insert, invert, or exchange DNA with high fidelity. In addition to the widely used Cre and Flp recombinases, the phiC31 integrase system from Streptomyces phage may also be used for these genetic manipulations in eukaryotic cells. Unlike Cre and Flp, phiC31 recognizes two heterotypic sites, attB and attP, for recombination. While the phiC31 system has been recently applied in mouse and human cell lines and in Drosophila, it has not been demonstrated whether it can also catalyze efficient DNA recombination in zebrafish. Here we show that phiC31 integrase efficiently induces site-specific deletion of episomal targets as well as chromosomal targets in zebrafish embryos. Thus, the phiC31 system can be used in zebrafish for genetic manipulations, expanding the repertoire of available tools for genetic manipulation in this vertebrate model.     

Transgene excision in zebrafish using the phiC31 integrase

Genome engineering strategies employing site‐specific recombinases (SSRs) have become invaluable to the study of gene function in model organisms. One such SSR, the integrase encoded by the Streptomyces bacteriophage phiC31, promotes recombination between heterotypic attP and attB sites. In the present study I have examined the feasibility of the use of phiC31 integrase for intramolecular recombination strategies in zebrafish embryos. I report here that (1) phiC31 integrase is functional in zebrafish cells, (2) phiC31 integrase can excise a transgene cassette flanked by an attB and an attP site, analogous to a common use of the Cre/lox SSR system, (3) phiC31 integrase functions in the zebrafish germline, and (4) a phiC31 integrase‐estrogen receptor hormone‐binding domain variant fusion protein catalyzes attB‐attP recombination in zebrafish embryos in a 4‐hydroxytamoxifen‐dependent manner, albeit less efficiently than phiC31 alone. These features should make this a useful approach for genome manipulations in the zebrafish. genesis 48:137–143, 2010. © 2010 Wiley‐Liss, Inc.     

PhiC31 integrase mediates integration in cultured synovial cells and enhances gene expression in rabbit joints

BACKGROUND: Gene transfer to synovium in joints has been shown to be an effective approach for treating pathologies associated with rheumatoid arthritis (RA) and related joint disorders. However, the efficiency and duration of gene delivery has been limiting for successful gene therapy for arthritis. The transient gene expression that often accompanies non-viral gene delivery can be prolonged by integration of vector DNA into the host genome. We report a novel approach for non-viral gene therapy to joints that utilizes phage phiC31 integrase to bring about unidirectional genomic integration. METHODS: Rabbit and human synovial cells were co-transfected with a plasmid expressing phiC31 integrase and a plasmid containing the transgene and an attB site. Cells were cultured with or without G418 selection and the number of neo-resistant colonies or eGFP cells determined, respectively. Plasmid rescue, PCR query, and DNA sequence analysis were performed to reveal integration sites in the rabbit and human genomes. For in vivo studies, attB-reporter gene plasmids and a plasmid expressing phiC31 integrase were intra-articularly injected into rabbit knees. Joint sections were used for histological analysis of beta-gal expression, and synovial cells were isolated to measure luciferase expression. RESULTS: We demonstrated that co-transfection of a plasmid expressing phiC31 integrase with a plasmid containing the transgene and attB increased the frequency of transgene expression in rabbit synovial fibroblasts and primary human RA synoviocytes. Plasmid rescue and DNA sequence analysis of plasmid-chromosome junctions revealed integration at endogenous pseudo attP sequences in the rabbit genome, and PCR query detected integration at previously characterized integration sites in the human genome. Significantly higher levels of transgene expression were detected in vivo in rabbit knees after intra-articular injection of attB-reporter gene plasmids and a plasmid expressing phiC31 integrase. CONCLUSION: The ability of phiC31 integrase to facilitate genomic integration in synovial cells and increase transgene expression in the rabbit synovium suggests that, in combination with more efficient DNA delivery methods, this integrase system could be beneficial for treatment of rheumatoid arthritis and other joint disorders.     

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.     

Transgenic Xenopus laevis embryos can be generated using phiC31 integrase

Bacteriophage phiC31 encodes an integrase that can mediate the insertion of extrachromosomal DNA into genomic DNA. Here we show that the coinjection of mRNA encoding phiC31 integrase with plasmid DNA encoding the green fluorescent protein (GFP) can be used to generate transgenic X. laevis embryos. Despite integration into the genome, appropriate promoter expression required modification of the reporter plasmid by bracketing the GFP reporter gene with tandem copies of the chicken beta-globin 5' HS4 insulator to relieve silencing owing to chromatin position effects. These experiments demonstrate that the integration of insulated gene sequences using phiC31 integrase can be used to efficiently create transgenic embryos in X. laevis and may increase the practical use of phiC31 integrase in other systems as well.     

In vivo site-specific integration of transgene in silkworm via PhiC31 integrase-mediated cassette exchange

Current techniques for genetic engineering of the silkworm Bombyx mori genome utilize transposable elements, which result in positional effects and insertional mutagenesis through random insertion of exogenous DNA. New methods for introducing transgenes at specific positions are therefore needed to overcome the limitations of transposon-based strategies. Although site-specific recombination systems have proven powerful tools for genome manipulation in many organisms, their use has not yet been well established for the integration of transgenes in the silkworm. We describe a method for integrating target genes at pre-defined chromosomal sites in the silkworm via phiC31/att site-specific recombination system-mediated cassette exchange. Successful recombinase-mediated cassette exchange (RMCE) was observed in the two transgenic target strains with an estimated transformation efficiency of 3.84–7.01%. Our results suggest that RMCE events between chromosomal attP/attP target sites and incoming attB/attB sites were more frequent than those in the reciprocal direction. This is the first report of in vivo RMCE via phiC31 integrase in the silkworm, and thus represents a key step toward establishing genome manipulation technologies in silkworms and other lepidopteran species.     

Phage phiC31 integrase-mediated genomic integration and long-term gene expression in the lung after nonviral gene delivery

BACKGROUND: Phage phiC31 integrase has emerged as a potent tool for achieving long-term gene expression in different tissues. The present study investigated the activity of phiC31 integrase in murine lungs. METHODS: Transfections in murine alveolar epithelial (MLE12) cells were performed with Lipofectamine 2000. For in vivo gene delivery, DNA was complexed with polyethylenimine (PEI) and PEI-DNA complexes were injected intravenously into mice. Expression of luciferase in mice was monitored by in vivo bioluminsecence imaging. Genomic integration and integration into a previously described 'hotspot' were confirmed by polymerase chain reaction (PCR). RESULTS: phiC31 integrase mediated intramolecular recombination between wild-type attB and attP sites in MLE12 cells. Long-term gene expression could be observed in MLE12 cells in the presence of integrase without any selection pressure. Long-term expression of luciferase after intravenous injection of PEI-DNA complexes could be observed only in the lungs of mice which were co-injected with the integrase-encoding plasmid. Increased amounts of integrase plasmid and administration of a second dose had no effect on the level of luciferase expression achieved with a single dose, which was three orders of magnitude lower than the values observed on 'day 1' post application. Genomic integration of the transgene in the mouse lungs was confirmed by PCR. Seven out of the fifteen treated mice showed integration at the mpsL1 site, a previously described 'hot spot' from liver. CONCLUSIONS: These results provide evidence for the activity of phiC31 integrase in lungs but also emphasize the need for optimization of the system to maintain long-term gene expression at high levels.     

Efficient reversal of phiC31 integrase recombination in mammalian cells

Over the past decade, the integrase enzyme from phage phiC31 has proven to be a useful genome engineering tool in a wide variety of species, including mammalian cells. The enzyme efficiently mediates recombination between two distinct sequences, attP and attB, producing recombinant product sites, attL and attR. The reaction proceeds exclusively in a unidirectional manner, because integrase is unable to synapse attL and attR. To date, use of phiC31 integrase has been limited to attP × attB recombination. The factor needed for the reverse reaction – the excisionase or recombination directionality factor (RDF) – was identified recently and shown to function in vitro and in bacterial cells. To determine whether the phiC31 RDF could also function in mammalian cells, we cloned and tested several vectors that permit assessment of phiC31 RDF activity in mammalian environments. In the human and mouse cell lines tested (HeLa, HEK293, and NIH3T3), we observed robust RDF activity, using plasmid and/or genomic assays. This work is the first to demonstrate attL–attR serine integrase activity in mammalian cells and validates phiC31 RDF as a new tool that will enable future studies to take advantage of phiC31 integrase recombination in the forward or reverse direction.     

Functional characteristics of a highly specific integrase encoded by an LTR-retrotransposon

Background

The retroviral Integrase protein catalyzes the insertion of linear viral DNA into host cell DNA. Although different retroviruses have been shown to target distinctive chromosomal regions, few of them display a site-specific integration. ZAM, a retroelement from Drosophila melanogaster very similar in structure and replication cycle to mammalian retroviruses is highly site-specific. Indeed, ZAM copies target the genomic 5′-CGCGCg-3′ consensus-sequences. To enlighten the determinants of this high integration specificity, we investigated the functional properties of its integrase protein denoted ZAM-IN.

Principal Findings

Here we show that ZAM-IN displays the property to nick DNA molecules in vitro. This endonuclease activity targets specific sequences that are present in a 388 bp fragment taken from the white locus and known to be a genomic ZAM integration site in vivo. Furthermore, ZAM-IN displays the unusual property to directly bind specific genomic DNA sequences. Two specific and independent sites are recognized within the 388 bp fragment of the white locus: the CGCGCg sequence and a closely apposed site different in sequence.

Conclusion

This study strongly argues that the intrinsic properties of ZAM-IN, ie its binding properties and its endonuclease activity, play an important part in ZAM integration specificity. Its ability to select two binding sites and to nick the DNA molecule reminds the strategy used by some site-specific recombination enzymes and forms the basis for site-specific integration strategies potentially useful in a broad range of genetic engineering applications.     

Evaluating the efficiency of phiC31 integrase‐mediated monoclonal antibody expression in CHO cells

Traditional methods to generate CHO cell lines rely on random integration(s) of the gene of interest and result in unpredictable and unstable protein expression. In comparison, site‐specific recombination methods increase the recombinant protein expression by inserting transgene at a locus with specific expression features. PhiC31 serine integrase, catalyze unidirectional integration that occurs at higher frequency in comparison with the reversible integration carried out by recombinases such as Cre. In this study, using different ratios of phiC31 serine integrase, we evaluated the phiC31 mediated gene integration for expression of a humanized IgG1 antibody (mAb0014) in CHO‐S cells. Light chain (LC) and heavy chain (HC) genes were expressed in one operon under EF1α promoter and linked by internal ribosome entry site (IRES) element. The clonal selection was carried out by limiting dilution. Targeted integration approach increased recombinant protein yield and stability in cell pools. The productivity of targeted cell pools was about 4 mg/L and about 40 µg/L in the control cell pool. The number of integrated transgenes was about 19 fold higher than the control cells pools. Our results confirmed that the phiC31 integrase leads to mAb expression in more than 90% of colonies. The productivity of the PhiC31 integrated cell pools was stable for three months in the absence of selection as compared with conventional transfection methods. Hence, utilizing PhiC31 integrase can increase protein titer and decrease the required time for protein expression. © 2016 American Institute of Chemical Engineers Biotechnol. Prog., 32:1570–1576, 2016