The current study was undertaken to evaluate the possibility of expanding transgenic goat herds by means of somatic cell nuclear transfer (NT) using transgenic goat cells as nucleus donors. Skin cells from adult, transgenic goats were first synchronized at quiescent stage (G0) by serum starvation and then induced to exit G0 and proceed into G1. Oocytes collected from superovulated donors were enucleated, karyoplast-cytoplast couplets were constructed, and then fused and activated simultaneously by a single electrical pulse. Fused couplets were either co-cultured with oviductal cells in TCM-199 medium (in vitro culture) or transferred to intermediate recipient goat oviducts (in vivo culture) until final transfer. The resulting morulae and blastocysts were transferred to the final recipients. Pregnancies were confirmed by ultrasonography 25-30 days after embryo transfer. In vitro cultured NT embryos developed to morulae and blastocyst stages but did not produce any pregnancies while 30% (6/20) of the in vivo derived morulae and blastocysts produced pregnancies. Two of these pregnancies were resorbed early in gestation. Of the four recipients that maintained pregnancies to term, two delivered dead fetuses 2-3 days after their due dates, and two recipients gave birth to healthy kids at term. Fluorescence in situ hybridization (FISH) analysis confirmed that both kids were transgenic and had integration sites consistent with those observed in the adult cell line.
Production of human recombinant proteins in the milk of transgenic animals has been shown to be a viable production system. Protection of the animal genetics involved is paramount. Vitrification of embryos is a simple, time-efficient way of preserving an animal’s genetics without the formation of damaging ice crystals during the freezing process. Cytochalasin B has been shown to increase the viability of porcine blastocysts by reducing damage to microfilaments and other cytoskeletal components. These experiments utilized caprine parthenogenic blastocysts as a model to compare the viability of parthenotes treated with or without cytochalasin B prior to and during vitrification. Abattoir oocytes were in vitro-matured in M199 with 10% goat serum containing FSH, LH and gentamycin for 18 to 21h. Parthenogenic blastocysts were produced by treating in vitro matured abattoir oocytes with ionomycin for 5min (5μM) and with 6-dMAP (3mM) for 3h followed by culturing in SOF+0.8% BSA for 7 to 8 days at 38°C with 6% O2, 5% CO2, and 89% N2 in a modular incubator chamber. The experimental group was treated with cytochalasin B (5μg/mL)in the culture media for 30 to 45min prior to and thereafter throughout the vitrification process. All blastocysts (both the experimental group and the control group) were washed through two ovum culture media (OCM) droplets for 5min each. The blastocysts were incubated in vitrification solutions 1 and 2 (10% glycerol in OCM and 10% glycerol+20% ethylene glycol in OCM, respectively) for 5min each, followed by vitrification solution 3 (25% glycerol+25% ethylene glycol in OCM). They were then aspirated immediately into a 0.25cc cryopreservation straw, followed by an air bubble, and then a 0.25M sucrose solution in OCM. The straws were immediately plunged into liquid nitrogen and stored at −196°C. One to four days later, straws were thawed in air for 5s at room temperature, then in 22°C water for 15s. After thawing, the contents of the straw were expelled, mixed, held for 5min, and finally placed in OCM for 5min. Recovered embryos were placed in SOF+20% FBS and incubated at 38°C with 5% CO2 in air overnight. Viability was determined by re-expanding and subsequent hatching of the blastocyst. As shown in Table 1, there were no significant differences between re-expansion and hatching of blastocysts with cytochalasin B treatment compared to blastocysts not treated with cytochalasin B. These results suggest that, unlike porcine embryos (Dobrinsky et al., 2000 Biol Reprod 62, 564–570), cytochalasin B treatment does not improve the post-thaw viability of vitrified caprine parthenogenic blastocysts. Table 1
The ability to produce cloned livestock using postmortem tissue could incorporate an additional application into the field of nuclear transfer. This study examined the feasibility of producing cloned cattle using a primary cell line established from a postmortem beef carcass. A market beef heifer processed at a USDA-certified slaughterhouse was used to develop a primary somatic cell line. Tissue samples were taken from the kidney and forelimb regions either 1) immediately following slaughter (fresh) or 2) 48 h postslaughter (cooled) where the carcass was housed at 2 to 4 • C. Tissue was removed and placed on ice in PBS + 5.0% (v:v) penicillin/streptomycin. A primary culture was established using standard techniques and cultured in supplemented DMEM F-12 medium. Once established, cells were trypsinized and either frozen or continually passaged. Cells used for nuclear transfer (NT) were passaged (48 h before use) and cultured with 15 µM roscovitine roughly 24 h prior to nuclear transfer. Cells were approximately 80% confluent and between passage numbers 1 and 11 at the time of NT. Selected slaughterhouse-derived oocytes were matured in supplemented TCM 199 medium for 18-20 h at 39 • C in 5.0% CO 2 and air. Mature Metaphase II oocytes were vortexed and stained with Hoechst 33342 to help with chromatin removal. Following enucleation, roscovitine-treated carcass cells were placed in the perivitelline space of the oocyte. Reconstructed NT embryos were fused in Zimmermann's medium and pulsed using needle-like electrodes. This was followed by activation using a combination of calcium ionophore (5 µM), cytochalasin D (5 µg mL −1 ), and cycloheximide (10 µg mL −1 ) in TCM + 10% FBS. Fused NT embryos were cultured in 50-µL drops of BARC medium (USDA, Beltsville, MD) for 7 days at 39 • C in a 5% CO 2 , 5% O 2 and 90% N 2 environment. Embryo development for all four groups (Table 1) was assessed with blastocysts (grade 1 or 2) being transferred into recipient cows 7 days post-estrus. Cleavage rates were not significantly different between groups, and the use of either fresh or cooled cells did not impact blastocyst formation. However, there was a significant difference (P = 0.05) in % blastocyst based on the source of the donor cell. Overall, one live calf resulted from 34 transferred NTs produced using kidney cells taken from a 48 h cooled carcass. These results display the feasibility of producing cloned calves from cells collected post mortem, which ultimately could be used as a tool to select breeding bulls based on their own steer carcass characteristics.
The ability to produce cloned livestock using postmortem tissue could incorporate an additional application into the field of nuclear transfer. This study examined the feasibility of producing cloned cattle using a primary cell line established from a postmortem beef carcass. A market beef heifer processed at a USDA-certified slaughterhouse was used to develop a primary somatic cell line. Tissue samples were taken from the kidney and forelimb regions either 1) immediately following slaughter (fresh) or 2) 48 h postslaughter (cooled) where the carcass was housed at 2 to 4 • C. Tissue was removed and placed on ice in PBS + 5.0% (v:v) penicillin/streptomycin. A primary culture was established using standard techniques and cultured in supplemented DMEM F-12 medium. Once established, cells were trypsinized and either frozen or continually passaged. Cells used for nuclear transfer (NT) were passaged (48 h before use) and cultured with 15 µM roscovitine roughly 24 h prior to nuclear transfer. Cells were approximately 80% confluent and between passage numbers 1 and 11 at the time of NT. Selected slaughterhouse-derived oocytes were matured in supplemented TCM 199 medium for 18-20 h at 39 • C in 5.0% CO 2 and air. Mature Metaphase II oocytes were vortexed and stained with Hoechst 33342 to help with chromatin removal. Following enucleation, roscovitine-treated carcass cells were placed in the perivitelline space of the oocyte. Reconstructed NT embryos were fused in Zimmermann's medium and pulsed using needle-like electrodes. This was followed by activation using a combination of calcium ionophore (5 µM), cytochalasin D (5 µg mL −1 ), and cycloheximide (10 µg mL −1 ) in TCM + 10% FBS. Fused NT embryos were cultured in 50-µL drops of BARC medium (USDA, Beltsville, MD) for 7 days at 39 • C in a 5% CO 2 , 5% O 2 and 90% N 2 environment. Embryo development for all four groups (Table 1) was assessed with blastocysts (grade 1 or 2) being transferred into recipient cows 7 days post-estrus. Cleavage rates were not significantly different between groups, and the use of either fresh or cooled cells did not impact blastocyst formation. However, there was a significant difference (P = 0.05) in % blastocyst based on the source of the donor cell. Overall, one live calf resulted from 34 transferred NTs produced using kidney cells taken from a 48 h cooled carcass. These results display the feasibility of producing cloned calves from cells collected post mortem, which ultimately could be used as a tool to select breeding bulls based on their own steer carcass characteristics.
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