Adult somatic cell nuclear transfer was used to determine the totipotent potential of cultured mural granulosa cells, obtained from a Friesian dairy cow of high genetic merit. Nuclei were exposed to oocyte cytoplasm for prolonged periods by electrically fusing quiescent cultured cells to enucleated metaphase II cytoplasts 4-6 h before activation (fusion before activation [FBA] treatment). Additionally, some first-generation morulae were recloned by fusing blastomeres to S-phase cytoplasts. A significantly higher proportion of fused embryos developed in vitro to grade 1-2 blastocysts on Day 7 with FBA (27.5 +/- 2.5%) than with recloning (13.0 +/- 3.6%; p < 0. 05). After the transfer of 100 blastocysts from the FBA treatment, survival rates on Days 60, 100, 180, and term were 45%, 21%, 17%, and 10%, respectively. Ten heifer calves were delivered by elective cesarean section; all have survived. After the transfer of 16 recloned blastocysts, embryo survival on Day 60 was 38%; however, no fetuses survived to Day 100. DNA analyses confirmed that the calves are all genetically identical to the donor cow. It is suggested that the losses throughout gestation may in part be due to placental dysfunction at specific stages. The next advance in this technology will be to introduce specific genetic modifications of biomedical or agricultural interest.
Here we describe a procedure for cloning pigs by the use of in vitro culture systems. Four healthy male piglets from two litters were born following nuclear transfer of cultured somatic cells and subsequent embryo transfer. The initiation of five additional pregnancies demonstrates the reproducibility of this procedure. Its important features include extended in vitro culture of fetal cells preceding nuclear transfer, as well as in vitro maturation and activation of oocytes and in vitro embryo culture. The cell culture and nuclear transfer techniques described here should allow the use of genetic modification procedures to produce tissues and organs from cloned pigs with reduced immunogenicity for use in xenotransplantation.
Nuclear transfer procedures were used to determine the in vivo developmental potential of an ovine embryonic cell line isolated from the inner cell mass of a Day 8 blastocyst-stage embryo. This cell line possessed a differentiated epithelial-like cell morphology. In this study, a comparison was made between in vivo- and in vitro-derived oocytes used as recipient cytoplasts in the nuclear transfer procedure. Cultured cells were induced to quiesce and enter presumptive G0 before being used as donor karyoplasts between passages 8 and 16 of culture. After cell fusion, reconstructed embryos were cultured for 6 days in vitro in embryo culture medium. Blastocyst-stage embryos were subsequently transferred to synchronized recipient ewes (n = 37), and development was allowed to proceed to term. There was a significant effect of source of recipient cytoplast, with development being consistently greater with in vivo compared to in vitro cytoplasts in terms of, respectively, blastocysts produced (24.2 +/- 3.8% vs. 17.1 +/- 2.3%; p = 0.1), Day 35 pregnancy rate (40.0% vs. 9.1 %; p < 0.05), and Day 35 embryo survival (19.4% vs. 4.5%; p < 0.05). A high proportion of fetuses died during late gestation (5 of 8). The major abnormalities were associated with the urogenital tract. However, three lambs were delivered alive following cesarean section on Day 147. One lamb, derived from an in vitro-matured oocyte, died after 10 min, while the remaining two from in vivo-ovulated oocytes are apparently normal and healthy. DNA microsatellite markers conclusively show that the three lambs are genetically identical and were derived from the embryonic cell line. In conclusion, some cells from this blastocyst-derived embryonic cell line are totipotent by nuclear transfer and can produce viable offspring.
To preserve the female genetics of an endangered breed of cattle, adapted to sub-Antarctic conditions, adult somatic cell nuclear transfer was used to clone the last surviving Enderby Island cow from mural granulosa cells. Embryos reconstructed with metaphase II cytoplasts and quiescent cells were either activated and fused simultaneously (AFS) at 24 or 30 hours post maturation (hpm) or alternatively, fused 4-6 h before activation at 26-30 hpm (FBA). A significantly higher proportion of fused embryos developed in vitro to grade 1-3 blastocysts on Day 7 with FBA (39.8+/-2.8%) compared to AFS with activation either at 24 hpm (10.6+/-3.9%, P<0.01) or at 30 hpm (18.6+/-4.1%, P<0.01). Following the transfer of 74 embryos from the FBA treatment over two experiments, survival rates on Days 30, 55, 85, 150 and 190 of pregnancy were 38%, 30%, 23%, 16% and 15%, respectively. Of 22 embryos transferred in the first experiment, two calves were born alive with one calf surviving. DNA analyses confirmed that the calves were genetically identical to the Enderby Island cow. Additional pregnancies are currently ongoing. These data show that embryo development is increased by prolonged exposure of quiescent somatic cell nuclei to oocyte cytoplasm before artificial activation, possibly facilitating nuclear reprogramming. The successful demonstration of somatic cell nuclear transfer in animal conservation extends the applications of the technology beyond the main agricultural and biomedical interests.
Central to the success of large animal cloning is the production of healthy animals that can provide products for human health, food, and other animal agriculture applications. We report development of cloned cattle derived from 34 genetically unique, nonembryonic cell lines using nuclear transfer performed between 1 January 1998 and 29 February 2000. Nearly 25% (535/2170) of the recipients receiving reconstructed embryos initiated pregnancy. Overall, 19.8% (106/535) of the initiated pregnancies resulted in live births, while 77% (82/106) of these cattle clones remain healthy and productive today. Although a wide variation in birth weight of clone calves was observed, their growth rates, reproductive performance, and lactation characteristics are similar to that found in noncloned dairy cattle. Our data represent the most comprehensive information on cattle derived from nuclear transfer procedures and indicate that this emerging reproductive technology offers unique opportunities to meet critical needs in both human health care and agriculture.
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