Generation of transgenic cattle by lentiviral gene transfer into oocytes

The potential benefits of transgenic cattle range from the production of large quantities of pharmaceutically relevant proteins to agricultural improvement. However, the production of transgenic cattle is presently time-consuming and expensive because of the inefficiency of the classical DNA microinjection technique. Here, we report the use of lentiviruses for the efficient generation of transgenic cattle. Initial attempts to produce transgenic cattle by lentiviral infection of preimplantation embryos were not successful. In contrast, infection of bovine oocytes with lentiviral vectors carrying an enhanced green fluorescent protein (eGFP) expression cassette followed by in vitro fertilization resulted in the birth of transgenic calves. Furthermore, all of the calves generated by infection of oocytes were transgenic, and 100% of these animals expressed eGFP as detected by in vivo imaging and Western blotting. In addition, a transgenic calf was produced by infection of fetal fibroblasts followed by nuclear transfer into enucleated oocytes. Taken together, after adjusting lentiviral transgenesis to cattle, unprecedented high transgenesis and expression rates were achieved.     

Lentiviral transgenesis

Transgenic animals are relevant for many fields of modern biomedicine and agriculture. However, the inefficiencies of the presently available techniques – DNA microinjection and retroviral gene transfer – have led to an explosion of costs for transgenics especially in farm animals. The recent success in transferring genes to early embryos of different species (mouse, rat, pig, cattle) by viral vectors derived from lentiviruses, has established lentiviral transgenesis as an exciting alternative to the classical method of DNA microinjection. In addition, lentiviral vectors can be used to transfer genes into embryonic stem cells. Due to its high efficacy and versatility, lentiviral transgenesis should have a big impact on transgenic research.     

Advances in transgenic rat production

Predictable and reproducible production of transgenic rats from a standardized input of egg donors and egg recipients is essential for routine rat model production. In the course of establishing a transgenic rat service, transgenic founders were produced from three transgenes in outbred Sprague-Dawley (SD) rats and four transgenes in inbred Fischer 344 (F344) rats. Key parameters that affect transgenesis efficiency were assessed, including superovulation treatments, methods to prepare pseudopregnant recipients, and microinjection technique. Five superovulation regimens were compared and treatment with 20 IU PMSG and 30 IU HCG was selected for routine use. Four methods to prepare pseudopregnant egg recipients were compared and estrus synchronization with LHRHa and mating to vasectomized males was selected as most effective. More than 80% of eggs survived microinjection when modified pronuclear microinjection needles and DNA buffers were used. The efficiencies of transgenic production in rats and C57BL/6J (B6J) mice were compared to provide a context for assessing the difficulty of transgenic rat production. Compared to B6J mice, SD rat transgenesis required fewer egg donors per founder, fewer pseudopregnant egg recipients per founder, and produced more founders per eggs microinjected. Similar numbers of injection days were required to produce founders. These results suggest that SD rat transgenesis can be more efficient than B6J mouse transgenesis with the appropriate technical refinements. Advances in transgenic rat production have the potential to increase access to rat models.     

Transgenesis in fish: efficient selection of transgenic fish by co-injection with a fluorescent reporter construct

Small fish are a popular laboratory model for studying gene expression and function by transgenesis. If, however, the transgenes are not readily detectable by visual inspection, a large number of embryos must be injected, raised and screened to identify positive founder fish. Here, we describe a strategy to efficiently generate and preselect transgenic lines harbouring any transgene of interest. Co-injection of a selectable reporter construct (e.g., GFP), together with the transgene of interest on a separate plasmid using the I-SceI meganuclease approach, results in co-distribution of the two plasmids. The quality of GFP expression within the F0 generation therefore reflects the quality of injection and allows efficient and reliable selection of founder fish that are also positive for the second transgene of interest. In our experience, a large fraction (up to 50%) of GFP-positive fish will also be transgenic for the second transgene, thus providing a rapid (within 3-4 months) and efficient way to establish transgenic lines for any gene of interest in medaka and zebrafish.     

Genomic DNA damage in mouse transgenesis

Creating transgenic mammals is currently a very inefficient process. In addition to problems with transgene integration and unpredictable expression patterns of the inserted gene, embryo loss occurs at various developmental stages. In the present study, we demonstrate that this loss is due to chromosomal damage. We examined the integrity of chromosomes in embryos produced by microinjection of pronuclei, intracytoplasmic sperm injection (ICSI), and in vitro fertilization (IVF)-mediated transgenesis, and correlated these findings with the abilities of embryos to develop in vitro and yield transgenic morulas/blastocysts. Chromosomal analysis was performed after microinjection of the pronuclei in zygotes, as well as in parthenogenetic and androgenetic embryos. In all the pronuclei injection groups, significant oocyte arrest and increased incidence of chromosome breaks were observed after both transgenic DNA injection and sham injection. This indicates that the DNA damage is a transgene-independent effect. In ICSI-mediated transgenesis, there was no significant oocyte arrest. The observed chromosomal damage was lower than that after pronuclei microinjection in zygotes and was dependent upon the presence of exogenous DNA. The occurrence of DNA breaks, as measured by comet assay performed on the sperm prior to ICSI, showed that DNA damage was present in the sperm before fertilization. Embryonic development in vitro and transgene expression at the morula/blastocyst stage were higher in ICSI-mediated transgenesis than after microinjection of pronuclei into zygotes. Sperm-mediated gene transfer via IVF did not affect chromosome integrity, allowed good embryo development, but did not yield any transgenic embryos. The present study demonstrates that DNA damage occurs after both the microinjection of pronuclei and ICSI-mediated transgenesis, albeit through different mechanisms.     

Kinetics of pronuclear development and the effects of vector type and timing of injection on the efficiency of gene transfer into rhesus macaque embryos

A series of experiments was performed to determine the dynamics of pronuclear development as well as the efficiency of either adenovirus-associated (AAV) or lentivirus-derived vectors to introduce a green fluorescent protein (GFP) reporter gene into rhesus macaque (Macaca mulatta) embryos. Assessment of pronuclear development at various times after fertilization revealed that the appearance of pronuclei was determined by the presence of the first and the timing of the second polar body. The dynamics of pronuclear formation was a significant determinant of whether an oocyte reached the blastocyst stage, however, when the percentage of blastocysts were based on the number of zygotes, the timing of the appearance of polar bodies did not appear to have any effect on subsequent development. Injection of different AAV-derived vectors showed that the serotype of the vector did not affect development or the proportion of transgenic embryos. Moreover, all putative transgenic embryos proved to be expression mosaics. Injection of embryos with lentiviral vectors showed that timing of injection (before or after fertilization) had no effect on subsequent transgene expression, but that the type of reporter gene determined post-injection development and rate of transgenesis. The transfer of embryos following injection of a lentiviral vector into three recipients resulted in one pregnancy which was lost during the second trimester. Analysis of fetal tissues showed ubiquitous presence of the transgene and GFP expression in all tissues examined. These results show that lentivirus-derived vectors can efficiently transform rhesus embryos and are suitable for the generation of transgenic rhesus monkeys.     

The Meganuclease I-SceI Containing Nuclear Localization Signal (NLS-I-SceI) Efficiently Mediated Mammalian Germline Transgenesis via Embryo Cytoplasmic Microinjection

The meganuclease I-SceI has been effectively used to facilitate transgenesis in fish eggs for nearly a decade. I-SceI-mediated transgenesis is simply via embryo cytoplasmic microinjection and only involves plasmid vectors containing I-SceI recognition sequences, therefore regarding the transgenesis process and application of resulted transgenic organisms, I-SceI-mediated transgenesis is of minimal bio-safety concerns. However, currently no transgenic mammals derived from I-SceI-mediated transgenesis have been reported. In this work, we found that the native I-SceI molecule was not capable of facilitating transgenesis in mammalian embryos via cytoplasmic microinjection as it did in fish eggs. In contrast, the I-SceI molecule containing mammalian nuclear localization signal (NLS-I-SceI) was shown to be capable of transferring DNA fragments from cytoplasm into nuclear in porcine embryos, and cytoplasmic microinjection with NLS-I-SceI mRNA and circular I-SceI recognition sequence-containing transgene plasmids resulted in transgene expression in both mouse and porcine embryos. Besides, transfer of the cytoplasmically microinjected mouse and porcine embryos into synchronized recipient females both efficiently resulted in transgenic founders with germline transmission competence. These results provided a novel method to facilitate mammalian transgenesis using I-SceI, and using the NLS-I-SceI molecule, a simple, efficient and species-neutral transgenesis technology based on embryo cytoplasmic microinjection with minimal bio-safety concerns can be established for mammalian species. As far as we know, this is the first report for transgenic mammals derived from I-SceI-mediated transgenesis via embryo cytoplasmic microinjection.     

Generating transgenic mice from bacterial artificial chromosomes: transgenesis efficiency, integration and expression outcomes

Transgenic mice are widely used in biomedical research to study gene expression, developmental biology, and gene therapy models. Bacterial artificial chromosome (BAC) transgenes direct gene expression at physiological levels with the same developmental timing and expression patterns as endogenous genes in transgenic animal models. We generated 707 transgenic founders from 86 BAC transgenes purified by three different methods. Transgenesis efficiency was the same for all BAC DNA purification methods. Polyamine microinjection buffer was essential for successful integration of intact BAC transgenes. There was no correlation between BAC size and transgenic rate, birth rate, or transgenic efficiency. A narrow DNA concentration range generated the best transgenic efficiency. High DNA concentrations reduced birth rates while very low concentrations resulted in higher birth rates and lower transgenic efficiency. Founders with complete BAC integrations were observed in all 47 BACs for which multiple markers were tested. Additional founders with BAC fragment integrations were observed for 65% of these BACs. Expression data was available for 79 BAC transgenes and expression was observed in transgenic founders from 63 BACs (80%). Consistent and reproducible success in BAC transgenesis required the combination of careful DNA purification, the use of polyamine buffer, and sensitive genotyping assays.     

绿色荧光蛋白基因在转基因小鼠体内的表达

建立绿色荧光蛋白（GFP）转基因小鼠,继而传代建系。采用显微注射法,将GFP基因注入FVB／NJ小鼠受精卵原核内,获得子代鼠。分娩后3周剪取仔鼠尾,提取基因组DNA,应用PCR、Southern印迹技术进行整合检测。结共用雌性小鼠200只,注射受精卵1586枚,移植卵数386枚,受体鼠32只,怀孕鼠4只,子代鼠18只,有4只为阳性：取2只首建鼠的胚胎,在荧光显微镜下观察GFP表达明显,表明初步获得了转绿色荧光蛋白基因小鼠,     

Transgenic fish

Transgenic fish are produced by the artificial transfer of rearranged genes into newly fertilized eggs. Currently microinjection is the preferred method, although the integration rates of transgenes are generally low. A number of fusion genes, containing retrovirus sequences which direct integration, have been developed to enhance integration of transgenes. Mass gene transfer methods are also being developed. These include lipofection, particle bombardment, and electroporation of embryos and sperm cells. These methods are potentially useful for marine organisms such as crustaceans and molluscs as well as fish. In contrast to microinjection, which treats single cells individually, these methods can transfer genes into a large number of eggs at once. There is some evidence to indicate successful integration and expression of transgenes transferred by the electroporation of embryos and sperm cells. Germline transmission of transgenes has been observed through mating studies, and in some cases the progeny express the new phenotype consistently. However, germline transmission does not necessarily confirm stable integration of the transgene. There is evidence that transgenes may exist extrachromosomally. Transgenic fish are viewed as a useful model for the study of complex biological phenomena such as growth and differentiation, and as a fast track to the production of broodstock for the aquaculture industry. Current research focuses on the elucidation of the mechanisms controlling the regulation of gene expression. The use of transgenic fish for the isolation of developmental genes has just begun. Applications of transgenesis to broodstock development have been focused on the development of fish with accelerated growth, tolerance to low temperature, and disease resistance. However, before the release of transgenic fish into the environment, the possible impact on the environment must be assessed. There must be safeguards to protect the genetic diversities of the natural populations, and to conserve the natural habitats     

Efficient transgenesis in farm animals by lentiviral vectors

Microinjection of DNA is now the most widespread method for generating transgenic animals, but transgenesis rates achieved this way in higher mammals are extremely low. To address this longstanding problem, we used lentiviral vectors carrying a ubiquitously active promoter (phosphoglycerate kinase, LV-PGK) to deliver transgenes to porcine embryos. Of the 46 piglets born, 32 (70%) carried the transgene DNA and 30 (94%) of these pigs expressed the transgene (green fluorescent protein, GFP). Direct fluorescence imaging and immunohistochemistry showed that GFP was expressed in all tissues of LV-PGK transgenic pigs, including germ cells. Importantly, the transgene was transmitted through the germ-line. Tissue-specific transgene expression was achieved by infecting porcine embryos with lentiviral vectors containing the human keratin K14 promoter (LV-K14). LV-K14 transgenic animals expressed GFP specifically in basal keratinocytes of the skin. Finally, infection of bovine oocytes after and before in vitro fertilization with LV-PGK resulted in transgene expression in 45% and 92% of the infected embryos, respectively.     

Efficient genetic transformation of Sorghum using a visual screening marker.

To transform grain sorghum (Sorghum bicolor (L.) Moench) with a visual reporter gene (gfp) and a target gene (tlp), three genotypes (two inbreds, Tx 430 and C401, and a commercial hybrid, Pioneer 8505) were used. We obtained a total of 1011 fertile transgenic plants from 61 independent callus lines, which were produced from 2463 zygotic immature embryos via Agrobacterium-mediated transformation. The reporter gene, gfp, encoding green fluorescent protein (GFP), was used as a visual screening marker, and the target gene, tlp, encoding thaumatin-like protein (TLP), was chosen for enhancing resistance to fungal diseases and drought. Both genes were under the control of the maize ubi 1 promoter in the binary vector pPZP201. A total of 320 plants showing GFP expression, derived from 45 calli, were selected and analyzed by Southern blot analysis. There was a 100% correlation between the GFP expression and the presence of the target gene, tlp, in these plants. Transgenic plants showing strong TLP expression were confirmed by Western blotting with antiserum specific for TLP. The transgene segregated in various ratios among progeny, which was confirmed by examining seedlings showing GFP fluorescence. The progeny also showed different copy numbers of transgenics. This report describes the successful use of GFP screening for efficient production of stably transformed sorghum plants without using antibiotics or herbicides as selection agents.     

Selection for mutations in the cDNAs of transgenic mice upon expression of an embryonic lethal protein

The generation of transgenic mouse models to study in vivo functions of specific proteins has become common practice. In addition, PCR technology allows efficient and rapid identification of founder mice by the analysis of tail tip DNA. Whilst the DNA construct used in the microinjection of one-cell-stage embryos is usually sequenced it is not common practice to sequence the PCR product once the transgene has been inserted into the mouse genome. In this report we describe why sequencing of inserted transgenes is important. Upon generation of transgenic mice expressing a splice variant of MDM2, MDM2-A, three of four founders contained mutations within the Mdm2-a cDNA sequence. The observation that selection against expression of wild-type MDM2-A resulted in the generation of mice expressing mutant transgenes highlights the importance of sequencing the transgenes of founder mice.     

Non-homologous end joining plays a key role in transgene concatemer formation in transgenic zebrafish embryos

This study focused on concatemer formation and integration pattern of transgenes in zebrafish embryos. A reporter plasmid based on enhanced green fluorescent protein (eGFP) driven by Cytomegalovirus (CMV) promoter, pCMV-pax6in-eGFP, was constructed to reflect transgene behavior in the host environment. After removal of the insertion fragment by double digestion with various combinations of restriction enzymes, linearized pCMV-pax6in-eGFP vectors were generated with different combinations of 5'-protruding, 3'-protruding, and blunt ends that were microinjected into zebrafish embryos. Repair of double-strand breaks (DSBs) was monitored by GFP expression following religation of the reporter gene. One-hundred-and-ninety-seven DNA fragments were amplified from GFP-positive embryos and sequenced to analyze the repair characteristics of different DSB end combinations. DSBs involving blunt and asymmetric protruding ends were repaired efficiently by direct ligation of blunt ends, ligation after blunting and fill-in, or removed by cutting. Repair of DSBs with symmetric 3'-3' protrusions was less efficient and utilized template-directed repair. The results suggest that non-homologous end joining (NHEJ) was the principal mechanism of exogenous gene concatemer formation and integration of transgenes into the genome of transgenic zebrafish.     

Robust and ubiquitous GFP expression in a single generation of chicken embryos using the avian retroviral vector,RCASBP

Functional genomics in avian models has lagged behind that of mammals, and the production of transgenic birds has proven to be challenging and time-consuming. All current methods rely upon breeding chimeric birds through at least one generation. Here, we report a rapid method for the ubiquitous expression of GFP in chicken embryos in a single generation (G-0), using the avian retroviral vector, Replication-Competent Avian sarcoma-leukosis virus, with a Splice acceptor, Bryan RSV Pol (RCASBP). High-titre RCASBP retrovirus carrying eGFP was injected into unincubated (stage X) blastoderms in ovo. This resulted in stable and widespread expression of eGFP throughout development in a very high proportion of embryos. Transgenic tissues were identified by fluorescence and immunohistochemistry. These results indicate that chicken blastodermal cells are permissive for infection by the RCASBP virus. This system represents a rapid and efficient method of producing global gene expression in the chicken embryo. The method can be used to generate avian cells with a stable genetic marker, or to induce global expression of a gene of choice. Interestingly, in day 8.5 embryos, somatic cells the embryonic gonads were predominantly GFP positive but primordial germ cells were GFP negative, indicating viral silencing in the embryonic germline. This dichotomy in the gonads allows the isolation or enrichment of the germ cells through negative selection during embryonic stages. This transgenic chicken model is of value in developmental studies, and for the isolation and study of avian primordial germ cells.     

Cloned zebrafish by nuclear transfer from long-term-cultured cells

Although mammals have been cloned from genetically manipulated cultured cells, a comparable achievement has not been realized in lower vertebrates. Here we report that fertile transgenic zebrafish can be obtained by nuclear transfer using embryonic fibroblast cells from long-term cultures. The donor nuclei, modified by retroviral insertions expressing green fluorescent protein (GFP), were transplanted into manually enucleated eggs. Overall, a 2% success rate was achieved, resulting in 11 adult transgenic zebrafish expressing GFP. These nuclear transplants produced fertile, diploid offspring, and their F1/F2 progeny continued to express GFP in a pattern identical to that of the founder fish. This finding demonstrates that slowly dividing nuclei from cultured cells can be reprogrammed to support rapid embryonic development and sets up a foundation for targeted genetic manipulation in zebrafish.     

Generation and characterization of a GFP transgenic rat line for embryological research

Model organisms expressing fluorescent proteins are important tools for research. The present study was performed to generate and characterize a new line of green fluorescent protein (GFP) transgenic rats for use as a model in experimental embryological research. We injected a GFP expression vector into 135 zygotes of the Sprague-Dawley (SD) rat strain. Embryo transfer of 103 surviving embryos resulted in the production of 35 offspring (33.9%) and two of them were transgenic (5.7%). Two transgenic rat lines that ubiquitously express GFP under the control of the cytomegalovirus-enhancer/beta-actin (CAGGS) promoter were generated by breeding. We studied the main embryological parameters of one these GFP transgenic lines. Homozygous GFP-transgenic females have the same ovulation and superovulation rates as wild type (WT) females. Transgenic embryos reached blastocyst stage in vitro and developed in vivo after embryo transfer without decrease in their developmental ability compared to the control group. The genotype of the parents determined the onset of GFP expression in preimplantation embryos. When the GFP gene is derived from the transgenic female parent, fluorescence was detected in oocytes and in embryos of all further stages of development. When the GFP gene is inherited by the transgenic male parent, GFP was only expressed from the blastocyst stage on. GFP-transgenic rats represent a valuable tool to mark embryos for many embryological studies such as transgenesis, gene expression patterns during early development, embryo aggregation for analysis of the distribution of cells in chimeric embryos and nuclear transfer to confirm the origin of the cloned offspring.     

Efficient method for expressing transgenes in nonhuman primate embryos using a stable episomal vector

Transgenesis in the nonhuman primate can enhance the study of human biology by providing animal models for the study of primate-specific physiology, pathophysiology, and embryonic development. Progress with this technology has been hindered by the inherent inefficiency of transgenesis, transgene silencing, and practical restrictions on the production of sufficient pronuclear stage nonhuman primate zygotes. We have developed a novel technique using an Epstein Barr virus (EBV)-based episomal vector to produce rhesus monkey (Macaca mulatta) embryos expressing a transgene. Plasmid DNA containing the latent origin of replication, oriP, and Epstein Barr Nuclear Antigen-1 (EBNA-1) of EBV, as well as a CMV IE-enhanced green fluorescent protein (eGFP) expression cassette, was introduced into rhesus embryos by direct pronuclear microinjection. We detected eGFP in early cleavage stage embryos (4-8 cell) and throughout the duration of culture (day 8-9 blastocysts) by epifluorescent microscopy. A 50% transduction rate was obtained with the EBV-based vector. Microinjected embryos expressed eGFP and retained their developmental capacity as evidenced by development to the blastocyst stage. EBV-based vectors present a novel and efficient means of delivering transgenes for the study of the molecular control of primate embryonic development.     

Modified bacterial artificial chromosomes for zebrafish transgenesis

Transgenesis using bacterial artificial chromosomes (BAC) offers greater fidelity in directing desirable expression of foreign genes. Application of this technology in the optically transparent zebrafish with fluorescent protein reporters enables unparalleled visual analysis of regulation of gene expression in a living organism. Here we describe a streamlined procedure of direct selecting multiple BAC clones based on public sequence databases followed by rapid modification with GFP or RFP for transgenic analysis in zebrafish. Experimental procedures for BAC DNA preparation, microinjection of zebrafish embryos and screening of transgenic zebrafish carrying GFP/RFP modified BAC clones are detailed.     

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.