ブタICSI-mediated gene transferにおける外来遺伝子組み込み様式

ICSI-mediated gene transfer has been used as an alternative method to pronuclear microinjection for the genomic modification of many species. With this method, transgenic embryos are produced by the microinjection of metaphase II oocytes with spermatozoa previously incubated with foreign DNA. Recently, it was shown in mice that the low percentage of transgenic animals produced from injected oocytes, results from the fact that the expression of foreign DNA is associated with paternal chromosome degradation (Szczygiel M.A. et al., 2003 Biol. Reprod. 68, 1903–1910). It is also known that sex chromosomes localize preferentially, at least in humans, on the periphery of the sperm nucleus on sub-acrosomal regions (Sbracia M. et al., 2002 Hum. Reprod. 17, 320–324), suggesting a high level of interaction with foreign DNA molecules with possible impact on the sex ratio of the offspring. In order to test this hypothesis we have compared ICSI (no DNA), and with ICSI-mediated EGFP (5Kb plasmid DNA from Clonetech, Spain) transfer, with ICSI-mediated YRT3 (a mouse tyrosinase gene derivative YAC-DNA with 100Kb; Montoliu L. et al., 1996 EMBO) transfer. Gametes were from 6–8 weeks old CD1 mice. ICSI-mediated gene transfer with post-thawed immotile spermatozoa, extended in M2 medium in the absence of ion chelators (EDTA and EGTA), was done as previously described (Szczygiel M.A. et al., 2003 Biol. Reprod. 68, 1903–1910). Table 1 below summarizes the data collected. Relative to our control, sex ratio deviation was a consequence of the coinjection of DNA. Forty-three percent of males were obtained with regular ICSI, whereas 64% and 65% were the respective percentages when EGFP or YRT3 DNA was coinjected with spermatozoa. This statistically significant (P<0.05, z-test, Sigma Stat, Jandel Scientific, USA) sex ratio deviation, favoring male ICSI offspring when foreign DNA is coinjected, may result from a higher female embryo susceptibility to parental sex chromosome fragmentation induced by the interaction with foreign DNA molecules. Possible impairment of X chromosome inactivation and dosage compensation resulting from the fragmentation of the sex chromosome on X-carrying spermatozoa could explain this female embryo degeneration. Supporting this view, it was recently shown in mice that sex ratio can be skewed against female births by a mutation in a single gene of the X chromosome (Tsix) involved in such mechanisms (Lee J.T., 2002 Nat. Genet.). In conclusion, mouse ICSI-mediated gene transfer induces sex ratio deviation favoring male offspring. Table 1 Sex ratio of the offspring obtained with ICSI, ICSI-mediated EGFP transfer, and ICSI-mediated YRT3 transfer

Intracytoplasmic sperm injection (ICSI)-mediated gene transfer has recently been shown to be an effective technique for producing transgenic pigs; however, the types of sperm pretreatment having the most beneficial effects on post-ICSI embryogenesis or transgenic efficiency have not been clarified. In the present study, we performed ICSI-mediated gene transfer using pig sperm subjected to various pretreatments and determined the developmental potential of sperm-injected oocytes and introduction efficiency of exogenous DNA. Embryos were then transferred to recipient pigs to confirm gene transfer efficiency during the fetal period. When ICSI was performed using unfrozen sperm heads with tails removed by piezo-pulse, the rates of blastocyst formation (14.2%, 17/120) and transgene (EGFP) expression (11.8%, 2/17) were both low. When unfrozen sperm heads were used that were removed by sonication, EGFP expression efficiency (11/21, 52.4%) improved significantly (P<0.05). Pretreatment of unfrozen sperm with a surfactant or acrosomal reaction did not further improve the rates of blastocyst formation and EGFP expression. However, use of the heads of sperm frozen-thawed with or without a cryoprotective agent resulted in rates of blastocyst formation and EGFP expression that tended to be generally high (23.0%, 14/61-33.8%, 26/77 and 42.9%, 6/14-66.7%, 10/15). A total of 219 in vitro matured oocytes were fertilized by ICSI-mediated gene transfer using the heads of frozen-thawed sperm and then transferred into two recipient pigs. Seven fetuses were obtained, and EGFP expression and integration of the transgene (10-30 copies) were confirmed in two of the seven fetuses. Use of unfrozen sperm thus confers no advantages on ICSI-mediated gene transfer, and although further investigations are needed, frozen-thawed sperm heads appear to be useful in ICSI-mediated gene transfer.

The objective of this study was to examine whether the ICSI-mediated gene transfer method using in vitro matured oocytes and frozen sperm head could actually produce transgenic pigs. We also aimed at examining whether transgenic pigs can be cloned from somatic cells of a transgenic pig generated by the ICSI-mediated method. A bicistronic gene constituted of the human albumin (hALB) and enhanced green fluorescent protein (EGFP) genes was introduced into pig oocytes by the ICSI-mediated method. Transfer of 702 embryos produced by the ICSI-mediated method into five gilts resulted in 4 pregnancies. When three of the recipients, which had received total 312 of the embryos were autopsied, 32 including 1 transgenic fetuses were obtained. One of the recipients gave birth to three live piglets including one transgenic pig, showing a strong green fluorescence in the eyeballs, oral mucous membrane and subcutaneous tissues. Fluorescent microscopy revealed uniform GFP expression in all cell lines established from kidney, lung and muscle of the founder transgenic pig obtained. Nuclear transfer of these cells resulted in stable in vitro development of cloned embryos into the blastocyst stage, ranging from 12.9 to 19.8%. When 767 of the nuclear transfer embryos were transferred to 5 recipients, all became pregnant and gave birth to a total of six live transgenic-clones. The transgene copy number and integrity in the founder pig were maintained in the primary culture cells established from the founder as well as in the clones produced from these cells. Our study demonstrates that the ICSI-mediated gene transfer is an efficient and practical method to produce transgenic pigs, using frozen sperm heads and in vitro matured oocytes. It was also shown that combination of ICSI-mediated transgenesis and nuclear transfer is a feasible technology of great potential in transgenic pig production.

Transgenic (Tg) pigs with organ/tissue-specific fluorescence expression provide invaluable research tools for many types of studies, such as organogenesis analysis, in vitro tissue generation from pluripotent cells, and progenitor/stem cell transplantation therapy. We aimed to develop a Tg pig characterised by pancreas- and liver-specific fluorescence expression. A 8.4 kb transgene construct expressing Venus (green fluorescence) under the control of the mouse Pdx1 (pancreatic duodenal homeobox-1) promoter and a BAC-derived construct (170 kb) consisting of the whole-length porcine albumin (Alb) promoter and humanized Kusabira-Orange (huKO, red fluorescence) was introduced into porcine in vitro-matured oocytes using the intracytoplasmic sperm injection (ICSI)-mediated gene transfer method. Injected embryos were transferred to the oviducts of oestrus-synchronized recipients after culture for 1 to 3 days. The transfer of 370 Pdx1-Venus embryos into 4 recipients produce 22 (5.9%) fetuses/piglets, and 9 (40.9%) Tg pigs exhibited pancreas-specific Venus expression. Two (1 male and 1 female) founder Pdx1-Venus-Tg pigs were mated with wild-type (WT) pigs and produced 32 offspring in 3 litters, of which 16 (50.0%) were transgenic. Pancreas-specific Venus expression was inherited in these Tg offspring. The transfer of 523 Alb-huKO embryos into 4 recipients resulted in 19 (3.6%) piglets including a Tg female, which showed liver-specific huKO fluorescent expression. Expression of huKO was detected by RT-PCR exclusively in liver, but not in 7 other organs/tissues examined, including heart, lung, stomach, small intestine, spleen, kidney and skin. This founder Tg female produced a total of 12 non-Tg and 5 Tg offspring (in 2 litters) after mating with a WT boar. Liver-specific huKO expression was inherited in these Tg offspring. Furthermore, the mating of a female Pdx1-Venus pig with an Alb-huKO boar yielded 7 non-Tg and 10 Tg pigs. Four of these Tg pigs carrying both of the transgenes exhibited both pancreas-specific Venus and liver-specific huKO expression in single individuals. Double-Tg pigs with pancreas-specific green fluorescence and liver-specific red fluorescence grew normally, and tests of their reproduction ability are currently underway. These data demonstrate that transgene introduction by ICSI-mediated gene transfer into in vitro-matured oocytes is a feasible option for generating pigs expressing fluorescent proteins in a tissue-specific manner.

Improved expression of green fluorescent protein in cattle embryos produced by ICSI-mediated gene transfer with spermatozoa treated with streptolysin-O

Intracytoplasmic sperm injection (ICSI)-mediated gene transfer has been described as a technique to obtain transgenic offspring in mice. However, this approach has had limited success in domestic animals due to poor embryo development after ICSI. A first experiment was designed to improve embryo development comparing ICSI-mediated gene transfer with or without chemical activation (CA) in the ovine species. In the second experiment, ICSI-mediated gene transfer assisted by CA was used in porcine, feline, equine, and bovine species. Maturation and culture were done by standard procedures. Semen was collected by artificial vagina in ovine and bovine species. In pigs, ejaculates were obtained using the gloved-hand method, and in feline and equine species, sperm were obtained from epididymides. Samples were frozen by standard means. Thawed spermatozoa were washed twice in Na citrate at 2.8% with 100 µm EDTA at 495g for 5 min and resuspended in Na citrate with 0.5 µg of pCX-EGFP/million spermatozoa for 5 min at 0�C. The pCX-EGFP plasmid contained the egfp gene expressed under chimerical CMV-IE-chicken β-actin promoter control. Sperm cells were immediately injected into the metaphase II oocyte and CA was induced by incubation in TALP-HEPES with 5 µm ionomycin for 4 min, cultured in TCM199 for 3 h, and transferred to a droplet of 1.9 mm 6-dimethylaminopurine (DMAP) for 3 h. During the in vitro culture, exposure to blue light (488 nm) was performed to determine the percentage of green embryos, mosaic expression, and earliest stage of egfp expression. Fluorescence in situ hybridization analysis was performed labeling pCX-EGFP plasmid by nick translation for use as a probe. Statistical analysis was done by chi square. In ovine species, development to blastocyst stage (0/88 v. 3/86; P &gt; 0.05) and number of green embryos (24/88 v. 39/86; P &lt; 0.05) were greater with CA. The egfp expression in ovine embryos assisted by CA began at the 2- (7/39), 4- (9/39), or 8-cell (23/39). However, the expression in ovine embryos without CA occurred only at the 8-cell stage (24/24) stage. In porcine, bovine, feline, and equine species, green embryos were detected at a high proportion (33/55, 10/44, 9/35, and 5/17, respectively), and the percentage of fluorescent blastocysts was 2.3, 2.9, and 9.1% for ovine, feline, and bovine species, respectively. The egfp expression in porcine and feline embryos started at the 2-cell stage (36 and 22%, respectively), whereas it began in bovine and equine embryos at the 4-cell stage (9 and 40% respectively). All species showed a high frequency of mosaic expression (range 60-85%), and the preliminary FISH analysis demonstrated a variable number of integration events in porcine embryos. To our knowledge, this is the first report of exogenous DNA expression in feline and equine embryos. These results suggest that the CA accelerates and increases the pCX-EGFP expression in ovine embryos in agreement with previous studies that have shown earlier expression of genes for parthenogenetic and cloning embryos, both assisted by CA. In conclusion, ICSI-mediated gene transfer assisted by CA can be used to obtain exogenous gene-expressing embryos in domestic species with potential scientific and commercial interests.

糖尿病モデルトランスジェニッククローンブタの作出 I. ICSI-mediated Gene Transfer(ICSI法) と体細胞核移植の組合わせによるトランスジェニック・クローンブタの効率的作出

Integration of foreign DNA into mammalian genome can be associated with hypomethylation at site of insertion

Goat sperm cells were used as a model to evaluate sperm-mediated gene transfer. Fresh and frozen-thawed goat sperm cells were co-incubated with radio-labelled foreign DNA. After 10 extensive washings, the compacted sperm retained foreign DNA. Confocal microscopy confirmed that the position on the sperm cell responsible for binding of foreign DNA was located in both the anterior and the posterior heads of caprine sperm cells. Furthermore, confocal longitudinal sections of the sperm cells showed that foreign DNA had penetrated into goat sperm nuclei. In this study, 37% of the fresh goat sperm and 33% of the frozen-thawed goat sperm cells were able to bind foreign DNA. In vitro fertilization experiments were conducted with goat sperm cells co-incubated with foreign DNA and the results showed that 3% of the fertilized and cleaved embryos expressed foreign DNA. Electroporation was applied to sperm cells co-incubated with foreign DNA and at various voltages (range of 0 to 1,200 volts/cm). Even though the sperm cells were immobilized by electroporation, all of them were able to bind foreign DNA. A further study showed that the sperm membranes play a very important role in sperm cell binding of foreign DNA. Southern blotting results showed that enzymes in the sperm cells were able to degrade foreign DNA. To further evaluate the potential use of sperm-mediated gene transfer, intracytoplasmic injection of goat oocytes with immotile sperm was evaluated. Results indicated that goat oocytes need exogenous stimuli, such as calcium ionophore A23187 for activation. Overall, 21% of cleaved sperm-injected embryos developed to the blastocyst stage, while sham-injected oocytes only developed to 16- to 32-cell stages. With this goat intracytoplasmic sperm injection methodology, sperm-mediated gene transfer was further studied. Fluorescent in situ hybridization results showed that without electroporation of sperm cells, only 14% of the cleaved embryos had foreign DNA (BC31), while with electroporation, 25% cleaved embryos had foreign DNA (BC31). Furthermore, foreign DNA (BC31) had integrated into goat genomic DNA.

Bacteria evolved restriction endonucleases to prevent interspecies DNA transmission and bacteriophage infection. Here, we show that human cells possess an analogous mechanism. APOBEC3A is induced by interferon following DNA detection, and it deaminates foreign double-stranded DNA cytidines to uridines. These atypical DNA nucleosides are converted by the uracil DNA glycosylase UNG2 to abasic lesions, which lead to foreign DNA degradation. This mechanism is evident in cell lines and primary monocytes, where up to 97% of cytidines in foreign DNA are deaminated. In contrast, cellular genomic DNA appears unaffected. Several other APOBEC3s also restrict foreign gene transfer. Related proteins exist in all vertebrates, indicating that foreign DNA restriction may be a conserved innate immune defense mechanism. The efficiency and fidelity of genetic engineering, gene therapy, and DNA vaccination are likely to be influenced by this anti-DNA defense system.

On the insertion of foreign DNA into mammalian genomes: Mechanism and consequences

Stable integration of foreign DNA into the chromosome of the cyanobacterium Synechococcus R2

Evolution of adenoviruses as gene therapy vectors.

Plasmid pRSVL persisted and expressed luciferase for at least 19 months in mouse skeletal muscle after intramuscular injection. Other injected plasmids also stably expressed long-term suggesting that any plasmid DNA could stably persist and express in muscle. Plasmid DNA was demonstrated by quantitative PCR in some of the muscle DNA samples for at least 19 months after injection. The methylation pattern of the plasmid DNA remained in its bacterial form indicating that the foreign DNA did not replicate in the muscle cells. The electroporation of total cellular DNA from injected muscles into bacteria indicated that the plasmid DNA was extrachromosomal. Chromosomal integration of plasmid DNA was searched for by electroporating the injected muscle DNA into bacteria after restriction enzyme digestion and ligation. No plasmids containing plasmid/chromosome junctions were observed in over 1800 colonies examined. Lack of integration increases the theoretical safety of this gene transfer technique. Long-term stability of plasmid DNA in muscle indicates that muscle is an attractive target tissue for the introduction of extrachromosomal plasmid or viral DNA for the purpose of gene therapy.

Despite growing evidence for the role of DNA methylation in bacterial acclimation to environmental stress, this epigenetic mechanism remains unexplored in sea-ice microbial communities known to tolerate multiple stressors. This study presents a first analysis of DNA methylation patterns in bacterial communities and associated viruses across the vertical thickness of sea-ice. Using a novel stepped-sackhole method, we collected sea-ice brines from distinct horizons of an Arctic ice floe, capturing microbial communities that had been exposed to different environmental conditions. Through Oxford Nanopore sequencing, we characterized methylation patterns in bacterial and associated viral DNA, analysing for methylation motifs and differences between ice horizons. We identified 22 unique bacterial methylation motifs and 27 viral motifs across three nucleotide methylation types (5mC, 6 mA, and 4mC), with evidence of differential methylation between upper and lower ice. Analysis of metagenome-assembled genomes revealed the regulatory potential of methylation in both ice-adapted (Psychromonas and Polaribacter) and nonadapted bacteria (Pelagibacter); e.g. in Pelagibacter, differential methylation of the GANTC motif between upper and lower ice affected genes involved in core cellular processes. Viral methylation patterns showed evidence of recent infection. We also identified orphan methyltransferases in sea-ice phages, suggesting a mechanism for bypassing host restriction-modification systems and regulating host genes. Our findings reveal that DNA methylation serves functions in sea-ice beyond traditional restriction-modification systems that protect against foreign DNA, opening new avenues for research on the role of epigenetic mechanisms not only in acclimation to the cryosphere but also more generally in microbial ecology and evolution.