Pig transgenesis by piggyBac transposition in combination with somatic cell nuclear transfer

The production of animals by somatic cell nuclear transfer (SCNT) is inefficient, with approximately 2 % of micromanipulated oocytes going to term and resulting in live births. However, it is the most commonly used method for the generation of cloned transgenic livestock as it facilitates the attainment of transgenic animals once the nuclear donor cells are stably transfected and more importantly as alternatives methods of transgenesis in farm animals have proven even less efficient. Here we describe piggyBac-mediated transposition of a transgene into porcine primary cells and use of these genetically modified cells as nuclear donors for the generation of transgenic pigs by SCNT. Gene transfer by piggyBac transposition serves to provide an alternative approach for the transfection of nuclear donor cells used in SCNT.     

Generation of trangenic Xenopus laevis using the Sleeping Beauty transposon system

Using the Sleeping Beauty (SB) transposon system, we have developed a simple method for the generation of Xenopus laevis transgenic lines. The transgenesis protocol is based on the co-injection of the SB transposase mRNA and a GFP-reporter transposon into one-cell stage embryos. Transposase-dependent reporter gene expression was observed in cell clones and in hemi-transgenic animals. We determined an optimal ratio of transposase mRNA versus transposon-carrying plasmid DNA that enhanced the proportion of hemi-transgenic tadpoles. The transgene is integrated into the genome and may be transmitted to the F1 offspring depending on the germline mosaicism. Although the transposase is necessary for efficient generation of transgenic Xenopus, the integration of the transgene occurred by an non-canonical transposition process. This was observed for two transgenic lines analysed. The transposon-based technique leads to a high transgenesis rate and is simple to handle. For these reasons, it could present an attractive alternative to the classical Restriction Enzyme Mediated Integration (REMI) procedure.Electronic Supplementary Material Supplementary material is available to authorised users in the online version of this article at .     

Proof of principle for piggyBac-mediated transgenesis in the flatworm Macrostomum lignano

Regeneration-capable flatworms are informative research models to study the mechanisms of stem cell regulation, regeneration, and tissue patterning. The free-living flatworm Macrostomum lignano is currently the only flatworm where stable transgenesis is available, and as such it offers a powerful experimental platform to address questions that were previously difficult to answer. The published transgenesis approach relies on random integration of DNA constructs into the genome. Despite its efficiency, there is room and need for further improvement and diversification of transgenesis methods in M. lignano. Transposon-mediated transgenesis is an alternative approach, enabling easy mapping of the integration sites and the possibility of insertional mutagenesis studies. Here, we report for the first time that transposon-mediated transgenesis using piggyBac can be performed in M. lignano to create stable transgenic lines with single-copy transgene insertions.     

A non-autonomous insect piggyBac transposable element is mobile in tobacco

The piggyBac transposable element, originally isolated from a virus in an insect cell line, is a valuable molecular tool for transgenesis and mutagenesis of invertebrates. For heterologous transgenesis in a variety of mammals, transfer of the piggyBac transposable element from an ectopic plasmid only requires expression of piggyBac transposase. To determine if piggyBac could function in dicotyledonous plants, a two-element system was developed in tobacco (Nicotiana tabacum) to test for transposable element excision and insertion. The first transgenic line constitutively expressed piggyBac transposase, while the second transgenic line contained at least two non-autonomous piggyBac transposable elements. Progeny from crosses of the two transgenic lines was analyzed for piggyBac excision and transposition. Several progeny displayed excision events, and all the sequenced excision sites exhibited evidence of the precise excision mechanism characteristic of piggyBac transposase. Two unique transposition insertion events were identified that each included diagnostic duplication of the target site. These data indicate that piggyBac transposase is active in a dicotyledonous plant, although at a low frequency.     

Tn5 transposase-mediated mouse transgenesis

We have developed a novel method for mouse transgenesis. The procedure relies on a hyperactive Tn5 transposase to insert a transgene into mouse chromosomes during intracytoplasmic sperm injection. This procedure integrates foreign DNA into the mouse genome with dramatically increased effectiveness as compared to conventional methods such as pronuclear microinjection and traditional sperm injection-mediated transgenesis. Our data indicate that with this method, transgenic mice, both hybrids and inbreds, can be produced more consistently and with lower numbers of manipulated oocytes required for traditional microinjection methods. The transposase-mediated transgenesis technique is also effective with round spermatids, offering the potential for rescuing the fertility of azoospermic animals using sperm precursor cells.     

Optimization of the piggyBac Transposon Using mRNA and Insulators: Toward a More Reliable Gene Delivery System

Integrating and expressing stably a transgene into the cellular genome remain major challenges for gene-based therapies and for bioproduction purposes. While transposon vectors mediate efficient transgene integration, expression may be limited by epigenetic silencing, and persistent transposase expression may mediate multiple transposition cycles. Here, we evaluated the delivery of the piggyBac transposase messenger RNA combined with genetically insulated transposons to isolate the transgene from neighboring regulatory elements and stabilize expression. A comparison of piggyBac transposase expression from messenger RNA and DNA vectors was carried out in terms of expression levels, transposition efficiency, transgene expression and genotoxic effects, in order to calibrate and secure the transposition-based delivery system. Messenger RNA reduced the persistence of the transposase to a narrow window, thus decreasing side effects such as superfluous genomic DNA cleavage. Both the CTF/NF1 and the D4Z4 insulators were found to mediate more efficient expression from a few transposition events. We conclude that the use of engineered piggyBac transposase mRNA and insulated transposons offer promising ways of improving the quality of the integration process and sustaining the expression of transposon vectors.     

Characterization of Growth and Reproduction Performance,Transgene Integration,Expression, and Transmission Patterns in Transgenic Pigs Produced by piggyBac Transposition-Mediated Gene Transfer

Previously we successfully produced a group of EGFP-expressing founder transgenic pigs by a newly developed efficient and simple pig transgenesis method based on cytoplasmic injection of piggyBac plasmids. In this study, we investigated the growth and reproduction performance and characterized the transgene insertion, transmission, and expression patterns in transgenic pigs generated by piggyBac transposition. Results showed that transgene has no injurious effect on the growth and reproduction of transgenic pigs. Multiple copies of monogenic EGFP transgene were inserted at noncoding sequences of host genome, and passed from founder transgenic pigs to their transgenic offspring in segregation or linkage manner. The EGFP transgene was ubiquitously expressed in transgenic pigs, and its expression intensity was associated with transgene copy number but not related to its promoter DNA methylation level. To the best of our knowledge, this is first study that fully described the growth and reproduction performance, transgene insertion, expression, and transmission profiles in transgenic pigs produced by piggyBac system. It not only demonstrates that piggyBac transposition-mediated gene transfer is an effective and favorable approach for pig transgenesis, but also provides scientific information for understanding the transgene insertion, expression and transmission patterns in transgenic animals produced by piggyBac transposition.     

Site-specific integration of transgene targeting an endogenous <Emphasis Type="Italic">lox-</Emphasis>like site in early mouse embryos

Functional lox-like sequences have been identified within the yeast and mammalian genome. These hetero-specific lox sites also allow Cre recombinase to specifically target efficient integration of exogenous DNA into the endogenous pseudo-lox (ψlox) sequences that occur naturally in the host genome using a Cre/loxP integrative recombination system. We investigated whether the Cre/ψlox system is useful for site-specific integration of transgenes and for improving the production efficiency of transgenic animals. This is the first report on Cre-mediated integrative recombination targeting an endogenous lox-like sequence termed pseudo-loxm5 (ψloxm5) in early mouse embryos. We characterized the Cre/ψloxm5 system in embryonic environment. Cre-expressing plasmid and a transgene (CMV/LacZ gene) flanked by ψloxm5 and ψloxcorem5 sites were co-microinjected into the pronucleus of fertilized mouse oocytes. The injected eggs were transferred into foster mothers, and the recombination products were investigated. The results show that the ψloxm5 site is an active substrate for Cre-mediated recombination in the mouse embryonic environment. The transgenesis efficiency was up to 27% (6/22). The site-specific integration of the transgene into the endogenous ψloxm5 site was found in 50 % of the transgenic pups. Our findings demonstrated that the Cre/ψloxm5 integrative recombination system is an efficient and simple strategy for targeting an endogenous lox-like site in mammalian embryos.     

Development and use of a piggyBac‐based jumpstarter system in Drosophila suzukii

Spotted wing drosophila, Drosophila suzukii, is an invasive pest that primarily attacks fresh, soft‐skinned fruit. Although others have reported successful integration of marked piggyBac elements into the D. suzukii genome, with a very respectable transgenesis rate of ～16%, here we take this work a step further by creating D. suzukii jumpstarter strains. These were generated through integration of a fluorescent‐marked Minos element carrying a heat shock protein 70‐driven piggyBac transposase gene. We demonstrate that there is a dramatic increase in transformation rates when germline transformation is performed in a transposase‐expressing background. For example, we achieved transformation rates as high as 80% when microinjecting piggyBac‐based plasmids into embryos derived from one of these D. suzukii jumpstarter strains. We also investigate the effect of insert size on transformation efficiency by testing the ability of the most efficient jumpstarter strain to catalyze integration of differently‐sized piggyBac elements. Finally, we demonstrate the ability of a jumpstarter strain to remobilize an already‐integrated piggyBac element to a new location, demonstrating that our jumpstarter strains could be used in conjunction with a piggyBac‐based donor strain for genome‐wide mutagenesis of D. suzukii.     

Genetic transformation of the codling moth, <Emphasis Type="Italic">Cydia pomonella</Emphasis> L., with <Emphasis Type="Italic">piggyBac</Emphasis> EGFP

Genetic transformation of the codling moth, Cydia pomonella, was accomplished through embryo microinjection with a plasmid-based piggyBac vector containing the enhanced green fluorescent protein (EGFP) gene. Sequencing of the flanking regions around the inserted construct resulted in identification of insect genomic sequences, not plasmid sequences, thus providing evidence that the piggyBac EGFP cassette had integrated into the codling moth genome. EGFP-positive moths were confirmed in the 28th and earlier generations post injection through PCR and Southern blot analyses, indicating heritability of the transgene.     

Germ line transformation of the silkworm, <Emphasis Type="Italic">Bombyx mori</Emphasis>, using the transposable element <Emphasis Type="Italic">Minos</Emphasis>

We investigated the use of Minos as a vector for transgenesis in the silkworm, Bombyx mori. We first constructed a vector plasmid with the green fluorescent protein (GFP) gene fused with the silkworm cytoplasmic actin gene (A3) promoter, and a helper plasmid with the Minos transposase gene controlled by the same A3 promoter. Injection of the vector and helper plasmid DNA into silkworm eggs produced transgenic animals in the following generation. The efficiency of transgenic silkworm production using this method was much lower than that obtained using piggyBac-mediated germ line transformation. However, >40-fold increase in the efficiency of producing transgenic silkworms was obtained using an in vitro synthesized source of Minos transposase mRNA. We conclude that the Minos transposon is a useful vector for construction of transgenic silkworms, particularly when in vitro synthesized mRNA is used. This is the first report showing that Minos can be used as a vector for germ-line transformation in lepidopteran insects.     

Molecular evolutionary analysis of the widespread<Emphasis Type="Italic"> piggyBac</Emphasis> transposon family and related "domesticated" sequences

piggyBac is a short inverted-repeat-type DNA transposable element originally isolated from the genome of the moth Trichoplusia ni. It is currently the gene vector of choice for the transformation of various insect species. A few sequences with similarity to piggyBac have previously been identified from organisms such as humans ( Looper), the pufferfish Takifugu rubripes (Pigibaku), Xenopus (Tx), Daphnia (Pokey), and the Oriental fruit fly Bactrocera dorsalis. We have now identified 50 piggyBac-like sequences from publicly available genome sequences and expressed sequence tags (ESTs). This survey allows the first comparative examination of the distinctive piggyBac transposase, suggesting that it might contain a highly divergent DDD domain, comparable to the widespread DDE domain found in many DNA transposases and retroviral integrases which consists of two absolutely conserved aspartic acids separated by about 70 amino acids with a highly conserved glutamic acid about 35 amino acids further away. Many piggyBac-like sequences were found in the genomes of a phylogenetically diverse range of organisms including fungi, plants, insects, crustaceans, urochordates, amphibians, fishes and mammals. Also, several instances of "domestication" of the piggyBac transposase sequence by the host genome for cellular functions were identified. Novel members of the piggyBac family may be useful in genetic engineering of many organisms.Electronic Supplementary Material Supplementary material is available in the online version of this article at     

动物基因组定点整合转基因技术研究进展

传统转基因技术,如显微注射、转座子、慢病毒转染等将目的基因插入基因组内的整合方式是随机的,这些随机整合对后期转基因动物品系组建和育种带来诸多不利,因此有研究人员提出了定点整合转基因技术。目前该技术的定点整合效率非常低,主要取决于两个方面：一是靶位点产生DNA双链断裂(double-strand break, DSB)的效率;二是断裂后的靶位点与携带同源臂及外源基因的供体质粒发生同源重组的效率,其中同源重组修复(homologous recombination repair, HDR)是基因组定点整合最为依赖的修复机制。靶位点产生DSB后,机体的DNA修复既可能发生HDR,也可能发生非同源末端连接(nonhomologous end joining, NHEJ),并且两者之间存在竞争关系,因此激活HDR或抑制NEHJ都可提高定点整合转基因的效率。本文结合影响定点整合的因素,对提高定点整合效率最新探索方面进行了综述。     

Injection-mediated transposon transgenesis in Xenopus tropicalis and the identification of integration sites by modified extension primer tag selection (EPTS) linker-mediated PCR

The generation of transgenic lines is vital to many genetic strategies and provides useful reagents for cell labeling and lineage-tracing experiments. Transposon-based systems offer simple, yet robust, platforms for transgenesis in the frog. Here, we provide a protocol for a microinjection-based transposon transgenesis method using a 'natural breeding' strategy for the collection of Xenopus tropicalis embryos. This method uses co-injection of a plasmid containing a transposon substrate together with synthetic mRNA encoding the transposase to achieve efficient integration of the transgene in the frog genome. We also describe a modified extension primer tag selection linker-mediated PCR technique to identify transposon integration sites within the host genome. This cloning strategy allows rapid identification of genomic sequences flanking the integration sites and multiple independently segregating transposon integration events in a single tadpole can be cloned simultaneously.     

Strategies for selection marker-free swine transgenesis using the <Emphasis Type="Italic">Sleeping Beauty</Emphasis> transposon system

Swine transgenesis by pronuclear injection or cloning has traditionally relied on illegitimate recombination of DNA into the pig genome. This often results in animals containing concatemeric arrays of transgenes that complicate characterization and can impair long-term transgene stability and expression. This is inconsistent with regulatory guidance for transgenic livestock, which also discourages the use of selection markers, particularly antibiotic resistance genes. We demonstrate that the Sleeping Beauty (SB) transposon system effectively delivers monomeric, multi-copy transgenes to the pig embryo genome by pronuclear injection without markers, as well as to donor cells for founder generation by cloning. Here we show that our method of transposon-mediated transgenesis yielded 38 cloned founder pigs that altogether harbored 100 integrants for five distinct transposons encoding either human APOBEC3G or YFP-Cre. Two strategies were employed to facilitate elimination of antibiotic genes from transgenic pigs, one based on Cre-recombinase and the other by segregation of independently transposed transgenes upon breeding.     

Transposon mediated BAC transgenesis via pronuclear injection of mouse zygotes

Pronuclear microinjection of bacterial artificial chromosomes (BACs) is the preferred way to generate transgenic mice because the transgene accurately recapitulates expression of the endogenous gene. However, the method is demanding and the integrity and copy number of the BAC transgene is difficult to control. Here, we describe a simpler pronuclear injection method that relies on transposition to introduce full‐length BACs into the mouse genome. The bacterial backbone of a hPAX6‐GFP reporter BAC was retrofitted with PiggyBac transposon inverted terminal repeats and co‐injected with PiggyBac transposase mRNA. Both the frequency of transgenic founders as well as intact, full‐length, single copy integrations were increased. Transposition was determined by a rapid PCR screen for a transpositional signature and confirmation by splinkerette sequencing to show that theBACs were integrated as a single copy either in one or two different genomic sites. BAC transposons displayed improved functional accuracy over random integrants as evaluated by expression of the hPAX6‐GFP reporter in embryonic neural tube and absence of ectopic expression. This method involves less work to achieve increased frequencies of both transgenesis and single copy, full‐length integrations. These advantages are not only relevant to rodents but also for transgenesis in all systems. genesis 51:135–141, 2013. © 2012 Wiley Periodicals, Inc.     

Transposon-mediated Chromosomal Integration of Transgenes in the Parasitic Nematode Strongyloides ratti and Establishment of Stable Transgenic Lines

Genetic transformation is a potential tool for analyzing gene function and thereby identifying new drug and vaccine targets in parasitic nematodes, which adversely affect more than one billion people. We have previously developed a robust system for transgenesis in Strongyloides spp. using gonadal microinjection for gene transfer. In this system, transgenes are expressed in promoter-regulated fashion in the F1 but are silenced in subsequent generations, presumably because of their location in repetitive episomal arrays. To counteract this silencing, we explored transposon-mediated chromosomal integration of transgenes in S. ratti. To this end, we constructed a donor vector encoding green fluorescent protein (GFP) under the control of the Ss-act-2 promoter with flanking inverted tandem repeats specific for the piggyBac transposon. In three experiments, free-living Strongyloides ratti females were transformed with this donor vector and a helper plasmid encoding the piggyBac transposase. A mean of 7.9% of F1 larvae were GFP-positive. We inoculated rats with GFP-positive F1 infective larvae, and 0.5% of 6014 F2 individuals resulting from this host passage were GFP-positive. We cultured GFP-positive F2 individuals to produce GFP-positive F3 L3i for additional rounds of host and culture passage. Mean GFP expression frequencies in subsequent generations were 15.6% in the F3, 99.0% in the F4, 82.4% in the F5 and 98.7% in the F6. The resulting transgenic lines now have virtually uniform GFP expression among all progeny after at least 10 generations of passage. Chromosomal integration of the reporter transgenes was confirmed by Southern blotting and splinkerette PCR, which revealed the transgene flanked by S. ratti genomic sequences corresponding to five discrete integration sites. BLAST searches of flanking sequences against the S. ratti genome revealed integrations in five contigs. This result provides the basis for two powerful functional genomic tools in S. ratti: heritable transgenesis and insertional mutagenesis.     

Optimized transgenesis in Xenopus laevis/gilli isogenetic clones for immunological studies

Xenopus laevis provides a unique animal model, alternative to mouse, to study immunology. Even though, several methodologies have been developed for the generation of transgenic Xenopus, to date none have been adapted for the X. laevis/gilli (LG) isogenetic clones that are essential for immunological studies. Since LG clones are generated via gynogenesis, transgenic methods using transgene integration into the sperm nuclei are not suited. Therefore, we have tested three alternative methods for LG transgenesis: the phiC31 integrase, the Sleeping Beauty transposase, and the I-SceI meganuclease. All three techniques produced transgenic LG clones; however, the I-SceI meganuclease was most effective. It resulted in high transgenesis efficiency (35-50%), bright nonmosaic GFP expression as well as stable germline transmission with 100% of the progeny carrying the transgene. Production of transgenic LG clones will allow us to modulate immune gene expression and further strengthen X. laevis as a biomedical model.     

Post-Integration Silencing of piggyBac Transposable Elements in Aedes aegypti

The piggyBac transposon, originating in the genome of the Lepidoptera Trichoplusia ni, has a broad host range, making it useful for the development of a number of transposon-based functional genomic technologies including gene vectors, enhancer-, gene- and protein-traps. While capable of being used as a vector for the creation of transgenic insects and insect cell lines, piggyBac has very limited mobility once integrated into the genome of the yellow fever mosquito, Aedes aegypti. A transgenic Aedes aegypti cell line (AagPB8) was created containing three integrated piggyBac elements and the remobilization potential of the elements was tested. The integrated piggyBac elements in AagPB8 were transpositionally silent in the presence of functional transposase, which was shown to be capable of catalyzing the movement of plasmid-borne piggyBac elements in the same cells. The structural integrity of one of the integrated elements along with the quality of element-flanking DNA, which is known to influence transposition rates, were tested in D. melanogaster. The element was found to be structurally intact, capable of transposition and excision in the soma and germ-line of Drosophila melanogaster, and in a DNA sequence context highly conducive to element movement in Drosophila melanogaster. These data show that transpositional silencing of integrated piggyBac elements in the genome of Aedes aegypti appears to be a function of higher scale genome organization or perhaps epigenetic factors, and not due to structural defects or suboptimal integration sites.     

Application of the Sleeping Beauty system in Saanen goat fibroblast cells for establishing persistent transgene expression

The Sleeping Beauty (SB) transposon system is a promising new method for establishing persistent transgene expression in vivo. We applied the SB system for enhancing transgenesis in Saanen dairy goat fibroblast cells. We constructed a pKT2/CMV-EGFP-IRES-PURO vector and investigated the influence of transposon and transposase vector ratios on transfection efficiency in the Saanen goat fibroblast cells. To enhance the SB system performance, we developed a new transfection technique (double-transfection method) for the SB system. The cultured cells were transfected with transposase and transposon vectors successively, with a 42-h interval. Consequently, the transposase and DNA donor (transposon vector) can interact, both at the highest level. Compared with the traditional transfection method, this new double-transfection method approximately doubled integration efficiency.