Approximately 100 species become extinct a day. Despite increasing interest in using cloning to rescue endangered species, successful interspecies nuclear transfer has not been previously described, and only a few reports of in vitro embryo formation exist. Here we show that interspecies nuclear transfer can be used to clone an endangered species with normal karyotypic and phenotypic development through implantation and the late stages of fetal growth. Somatic cells from a gaur bull (Bos gaurus), a large wild ox on the verge of extinction, (Species Survival Plan Ͻ 100 animals) were electrofused with enucleated oocytes from domestic cows. Twelve percent of the reconstructed oocytes developed to the blastocyst stage, and 18% of these embryos developed to the fetal stage when transferred to surrogate mothers. Three of the fetuses were electively removed at days 46 to 54 of gestation, and two continued gestation longer than 180 (ongoing) and 200 days, respectively. Microsatellite marker and cytogenetic analyses confirmed that the nuclear genome of the cloned animals was gaurus in origin. The gaur nuclei were shown to direct normal fetal development, with differentiation into complex tissue and organs, even though the mitochondrial DNA (mtDNA) within all the tissue types evaluated was derived exclusively from the recipient bovine oocytes. These results suggest that somatic cell cloning methods could be used to restore endangered, or even extinct, species and populations. 79
In this study we evaluated nuclear and ooplasmic maturation of prepuberal calf oocytes to determine a possible cause for their low developmental competency. Calf oocytes resumed meiosis and arrested at the MII stage at rates similar to that of adult animals; however, zygotes derived from calf oocytes cleaved and developed at significantly lower rates. Ooplasmic maturation was assessed during oocyte maturation and fertilization. Transmission electron microscopy revealed that a majority of calf oocytes exhibited some delay in organelle migration and redistribution following maturation. Immunofluorescence microscopy showed that following IVF, a higher percentage of calf oocytes had abnormal chromatin and microtubule configurations than those of adult cattle. These anomalies were characterized by delayed formation of sperm aster and asynchronous pronuclear formation. Microfluorometry was used to characterize the Ca2+ responses of calf oocytes to the addition of agonists or after IVF. The addition of thimerosal demonstrated the presence of Ca2+ stores in calf oocytes. Injection of near threshold concentrations of inositol 1,4,5‐trisphosphate (InsP3), used to test the sensitivity of the InsP3R, released significantly less Ca2+ in calf than in cow oocytes, whereas higher concentrations of InsP3 (500 μM) released maximal [Ca2+]i in both oocytes. These results suggested that the Ca2+ content of intracellular stores was similar, but the sensitivity of the InsP3R may be different. Following insemination, calf oocytes exhibiting [Ca2+]i oscillations displayed comparable amplitude and intervals to cow oocytes; however, a significantly higher number of fertilized calf oocytes failed to show oscillations. Our findings suggest that the low developmental competence of calf oocytes can be attributed, at least in part, to incomplete or delayed ooplasmic maturation. © 1996 Wiley‐Liss, Inc.
Our previous studies have shown that oocytes collected from prepubertal calves lack developmental competence. The overall objective of this study was to assess causes by comparing biochemical and physiologic changes during in vitro maturation of oocytes collected from ovaries of adult cattle at slaughter and from superstimulated calves (<6 mo old) by either laporotomy or ultrasound-guided follicular aspiration. Activity and/or concentrations of maturation-promoting factor (MPF), mitogen-activated protein kinase (MAPK), and inositol 1,4,5-trisphosphate receptor (IP(3)R) were determined by measuring phosphorylation of histone H-1 kinase, phosphorylation of myelin basic protein, or Western blotting, respectively, and were compared between oocytes collected from calves and for those collected from cows. The activities of MPF and MAPK and the relative amount of IP(3)R were significantly lower in calf oocytes. The physiologic significance of these observations was determined by assessing the developmental potential of embryos derived by reciprocal transfer of metaphase II (M-II) chromosomes between cow and calf ooplasts and transfer of adult cumulus cells (G0/G1) into cow and calf ooplasts. Procedural controls consisted of transfer of M-II between adult oocytes and parthenogenic activation of adult and calf oocytes. Adult parthenogenically activated oocytes cleaved and developed to blastocysts at a higher rate than did similarly activated calf oocytes (42.1% vs. 3.4%, P < 0.05). Cleavage was also higher in reciprocal M-II transfer embryos containing adult ooplasm (46.2% vs. 12.0%, P < 0.05). Cleavage (66.7% vs. 21.9%, P < 0.05) and development to blastocyst (20.1% vs. 4.8%, P < 0.05) of nuclear transfer embryos reconstructed from adult cumulus cells was higher after transfer to adult ooplasts. Collectively, these results support the hypothesis that lack of developmental competence of calf oocytes is due to their failure or inability to complete ooplasmic maturation.
The objective of these experiments was to evaluate factors affecting in vitro fertilization of bovine oocytes matured in vitro, and their subsequent development to blastocysts. In Expts 1 and 2, sperm concentration, spermatozoa and oocyte incubation time, motility enhancers and semen source were manipulated. Fluorescent microscopy of microtubules and chromatin was used to observe sperm penetration rate, sperm aster formation and chromatin decondensation. Oocyte penetration rates were affected by sperm concentration but not by spermatozoa and oocyte incubation time. The effect of sperm concentration was due primarily to changes in polyspermy and not monospermy. Motility enhancers had no effect on any parameter measured. In Expt 3, oocytes were matured for 17, 22, 28 and 34 h before fertilization and evaluated for fertilization rates, morphology of cortical granules and exocytosis and blastocyst development. A domain free of cortical granules that was associated with the metaphase chromatin was not observed in mature bovine oocytes. As oocytes matured from 17 to 34 h, the distribution of cortical granules progressed from clustered to diffuse. Although monospermic fertilization rates were similar and cortical granule exocytosis occurred in all groups, polyspermy increased with maturation time. Development to blastocysts increased from 17 to 22 h of maturation but decreased thereafter with increasing maturation time. These results suggest that polyspermy can be reduced by adjusting sperm concentration and spermatozoa and oocyte incubation time with little effect on monospermic fertilization. Increased polyspermy with increased maturation time was not due to a lack of cortical granule exocytosis.
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