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ABSTRACT: We have developed a unique method for mouse transgenesis. The transposase-enhanced pronuclear microinjection (PNI) technique described herein uses the hyperactive piggyBac transposase to insert a large transgene into the mouse genome. This procedure increased transgene integration efficiency by fivefold compared with conventional PNI or intracytoplasmic sperm injection-mediated transgenesis. Our data indicate that the transposase-enhanced PNI technique additionally requires fewer embryos to be microinjected than traditional methods to obtain transgenic animals. This transposase-mediated approach is also very efficient for single-cell embryo cytoplasmic injections, offering an easy-to-implement transgenesis method to the scientific community.
Proceedings of the National Academy of Sciences 10/2012; · 9.68 Impact Factor
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Johann Urschitz,
Miyuri Kawasumi,
Jesse Owens,
Kazuto Morozumi,
Hideaki Yamashiro,
Ilko Stoytchev, Joel Marh,
James A Dee,
Kris Kawamoto,
Craig J Coates,
Joseph M Kaminski,
Pawel Pelczar,
Ryuzo Yanagimachi,
Stefan Moisyadi
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ABSTRACT: Efficient integration of functional genes is an essential prerequisite for successful gene delivery such as cell transfection, animal transgenesis, and gene therapy. Gene delivery strategies based on viral vectors are currently the most efficient. However, limited cargo capacity, host immune response, and the risk of insertional mutagenesis are limiting factors and of concern. Recently, several groups have used transposon-based approaches to deliver genes to a variety of cells. The piggyBac (pB) transposase in particular has been shown to be well suited for cell transfection and gene therapy approaches because of its flexibility for molecular modification, large cargo capacity, and high transposition activity. However, safety considerations regarding transposase gene insertions into host genomes have rarely been addressed. Here we report our results on engineering helper-independent pB plasmids. The single-plasmid gene delivery system carries both the piggyBac transposase (pBt) expression cassette as well as the transposon cargo flanked by terminal repeat element sequences. Improvements to the helper-independent structure were achieved by developing new plasmids in which the pBt gene is rendered inactive after excision of the transposon from the plasmid. As a consequence, potentially negative effects that may develop by the persistence of an active pBt gene posttransposition are eliminated. The results presented herein demonstrate that our helper-independent plasmids represent an important step in the development of safe and efficient gene delivery methods that should prove valuable in gene therapy and transgenic approaches.
Proceedings of the National Academy of Sciences 05/2010; 107(18):8117-22. · 9.68 Impact Factor
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ABSTRACT: DNA methylation controls various developmental processes by silencing, switching and stabilizing genes as well as remodeling chromatin. Among various symptoms in cloned animals, placental hypertrophy is commonly observed. We identified the Spalt-like gene3 (Sall3) locus as a hypermethylated region in the placental genome of cloned mice. The Sall3 locus has a CpG island containing a tissue-dependent differentially methylated region (T-DMR) specific to the trophoblast cell lineage. The T-DMR sequence is also conserved in the human genome at the SALL3 locus of chromosome 18q23, which has been suggested to be involved in the 18q deletion syndrome. Intriguingly, larger placentas were more heavily methylated at the Sall3 locus in cloned mice. This epigenetic error was found in all cloned mice examined regardless of sex, mouse strain and the type of donor cells. In contrast, the placentas of in vitro fertilized (IVF) and intracytoplasmic sperm injected (ICSI) mice did not show such hypermethylation, suggesting that aberrant hypermethylation at the Sall3 locus is associated with abnormal placental development caused by nuclear transfer of somatic cells. We concluded that the Sall3 locus is the area with frequent epigenetic errors in cloned mice. These data suggest that there exists at least genetic locus that is highly susceptible to epigenetic error caused by nuclear transfer.
Genes to Cells 04/2004; 9(3):253-60. · 2.68 Impact Factor
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ABSTRACT: Germ cells undergo epigenetic modifications as they develop, which suggests that they may be ideal donors for nuclear transfer (cloning). In this study, nuclei from confirmed embryonic germ cells were used as donors to determine whether they are competent for cloning and at which stage they are most competent. Embryos cloned from migrating 10.5-days-postcoitum (dpc) primordial germ cells (PGCs) showed normal morphological development to midgestation but died shortly thereafter. In contrast, embryos cloned from later-stage germ cells were developmentally delayed at midgestation. Thus, donor germ cell age inversely correlated with the developmental stage attained by cloned embryos. The methylation status of the H19- and Snrpn-imprinting control regions in germ cell clones paralleled that of the donors, and revealed that demethylation, or erasure of imprints, was already initiated in PGCs at 10.5 dpc and was complete by 13.5 dpc. Similarly, clones derived from male 15.5-dpc germ cells showed increased methylation correlating with the initiation of de novo methylation that resets imprints at this stage, and clones from neonatal germ cells showed nearly complete methylation in the H19 imprinting control region. These results indicate that the epigenetic state of the donor nucleus is retained in cloned embryos, and that germ cells are therefore inadequate nuclear donors for cloning because they are either erasing or resetting epigenetic patterns.
Proceedings of the National Academy of Sciences 11/2003; 100(21):12207-12. · 9.68 Impact Factor
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ABSTRACT: It has been shown that mature oocytes injected with nuclei from round spermatids collected from mouse testis can generate normal offspring and that round spermatids can develop in vitro. An undetermined issue is whether spermatids developed in vitro are capable of generating fertile offspring by nuclear injection into oocytes. Herein, we report the production of normal and fertile offspring by nuclear injection using haploid spermatid donors derived from mouse primary spermatocyte precursors cocultured with Sertoli cells. Cocultured spermatogonia and spermatocytes were characterized by their nuclear immunoreactive patterns determined by an antibody to phosphorylated histone H2AX (gamma-H2AX), a marker for DNA double-strand breaks. Cocultured round spermatid progenies display more than one motile flagellum, whose axonemes were recognized by antitubulin immunostaining. Flagellar wavelike movement and flagellar-driven propulsion of round spermatids developed in vitro were documented by videomicroscopy (http://www.sci.ccny.cuny.edu/ approximately kier). We also show that breeding of male and female mouse offspring generated by spermatid nuclear injection produced fertile offspring. In addition to their capacity to produce fertile offspring, cocultured, flagellated round spermatids can facilitate the analysis of the mechanisms of centriolar polarity, duplication, assembly, and flagellar growth, including the intraflagellar transport of cargo proteins.
Biology of Reproduction 08/2003; 69(1):169-76. · 4.01 Impact Factor
