Luke F.S. Beebe

In Vitro and In Vivo Characterization of Putative Porcine Embryonic Stem Cells

We have developed a new method for the isolation of porcine embryonic stem cells (ESCs) from in vivo-derived and in vitro-produced embryos. Here we describe the isolation and characterization of several ESC lines established using this method. Cells from these lines were passaged up to 14 times, during which they were repeatedly cryopreserved. During this time, ESCs maintained their morphology and continued to express Oct 4, Nanog, and SSEA1. These cells formed embryoid bodies in suspension culture, and could be directed to differentiate into various lineages representative of all three germ layers in vitro. When injected into blastocysts these cells localized in the inner cell mass of blastocysts. To examine their pluripotency further, cells were injected into host blastocysts and transferred to recipient animals. Of the six transfers undertaken, one recipient became pregnant and gave birth to a litter of one male and three female piglets. Microsatellite analysis of DNA extracted from the tail tissue of these piglets indicated that two female piglets were chimaeric.

Piglets born from centrifuged and vitrified early and peri-hatching blastocysts.

Cryopreservation of zona-intact porcine embryos has been relatively unsuccessful to date, although some success has been obtained with lipid reduced morulae and early blastocysts. This study adapted some vitrification protocols used successfully with late blastocysts for use with early zona-intact blastocysts, using actin depolymerization, centrifugation, and open-pulled (OPS) straws. Initially, Day 6 peri-hatching blastocysts were collected, cultured for 40 min in 7.5 microg/ml cytochalasin B and vitrified in 6.5 M glycerol and 6% BSA (VS1) in either heat-sealed (HS) or open straws (OS). The post-thaw survival of those stored in HS was 15.4% after 24 and 48 h in vitro; storage in OS significantly improved survival (58.8% for both 24 and 48 h). When similar stage blastocysts were cultured in cytochalasin B and vitrified with 8 M ethylene glycol and 7% polyvinylpyrrolidone (PVP; VS2) in OS, survival was 44.4 and 33.3% for 24 and 48 h, respectively. Day 5 late morulae and early blastocysts were collected, cultured with cytochalasin B, and centrifuged or left intact (control), then vitrified with VS1 in HS or OS, or vitrified in VS2 in OS only. None of the intact control embryos survived thawing and 48 h culture in vitro. Centrifuged early blastocysts vitrified with VS1 showed good post-thaw survival in culture when stored in HS (62.8 and 60.5% for 24 and 48 h, respectively), or OS (75 and 63.6%). When vitrified with VS2 in OS, survival improved (80 and 76.7%). Peri-hatching blastocysts were vitrified in VS1, and early blastocysts were vitrified with VS1 and VS2. All blastocysts were stored in OS. The embryos were recovered and transferred to Day 4 and 5 pseudopregnant recipients (for Day 5 and 6 blastocysts, respectively). Of the five recipients receiving peri-hatching blastocysts, two became pregnant and delivered a total of eight piglets. All three recipients of early blastocysts vitrified in VS1 had a delayed return to estrus; while of the four receiving embryos vitrified with VS2, two were delayed in returning to estrus, and one was confirmed pregnant after 45 days. A litter of five piglets, one male and four female, was produced at 116 days of gestation. To our knowledge, this is the first litter of piglets produced from early blastocysts vitrified without micromanipulation to remove polarized lipid droplets.

Cytochalasin B and Trichostatin A Treatment Postactivation Improves In Vitro Development of Porcine Somatic Cell Nuclear Transfer Embryos

Somatic cell nuclear transfer (SCNT) is a useful technique for the production of transgenic pigs that can be used for biomedical research. However, the efficiency of SCNT in pigs is low. In this study, we examined the effect of two postactivation treatments, cytochalasin B (CB) and trichostatin A (TSA), on the in vitro development of porcine SCNT embryos. Treating porcine parthenotes with 7.5 microg/mL CB for 3 h after electrical activation was effective in preventing the extrusion of the second polar body in 65% of the oocytes compared to 17% in the control group. Treating SCNT embryos with CB for 3 h after electrical activation significantly increased the average blastocyst cell number compared to the control group (CB treatment 51, Control 34, p < 0.05). Treatment of porcine SCNT embryos with CB for 3 h and 50 nM TSA for 24 h after electrical activation resulted in a threefold increase in blastocyst rate (CB + TSA 64%, CB 20%, p < 0.05) and an increase in the average blastocyst cell number (CB + TSA 63, CB 46, p < 0.05), compared to CB treatment alone. These results show that treatment with TSA and CB significantly improves the in vitro morphological development and quality of porcine SCNT embryos.

Isolation and in vitro characterization of putative porcine embryonic stem cells from cloned embryos treated with trichostatin A.

We report here the establishment and characterization of putative porcine embryonic stem cell (ESC) lines derived from somatic cell nuclear transfer embryos (NT-ESCs). These cells had a similar morphology to that described previously by us for ESCs derived from in vitro produced embryos, namely, a polygonal shape, a relatively small (10-15 μm) diameter, a small cytoplasmic/nuclear ratio, a single nucleus with multiple nucleoli and multiple lipid inclusions in the cytoplasm. NT-ESCs could be passaged at least 15 times and vitrified repeatedly without changes in their morphology, karyotype, or Oct-4 and Nanog expression. These cells formed embryoid bodies and could be directed to differentiate in vitro to cell types representative of all three germ layers. Following their injection into blastocysts, these cells preferentially localized in the inner cell mass. In conclusion, we have isolated putative porcine ESCs from cloned embryos that have the potential to be used for a variety of applications including as a model for human therapeutic cloning.

Multipotent Cell Types in Primary Fibroblast Cell Lines Used to Clone Pigs using Somatic Cell Nuclear Transfer

We have previously demonstrated that the use of porcine mesenchymal stem cells (MSCs) isolated from the bone marrow can increase the proportion of somatic cell nuclear transfer (SCNT) embryos that develop to the blastocyst stage compared with adult fibroblasts obtained from the same animal. The aim of the present study was to determine if MSCs are also present in primary cultures of adult fibroblasts which are commonly used for cloning live animals. To do this we chose a primary culture of adult fibroblasts that we had previously used to clone pigs. Single cell clones were isolated using low-density plating. After seven days of culture 63% of colonies displayed typical fibroblast morphology, while the remainder appeared cobblestone-like in appearance. Two of the 57 clones that displayed fibroblast morphology differentiated into adipocytes but not chondrocytes or osteocytes (uni-potent clones). Three of the 33 cobblestone-like clones differentiated into chondrocytes only, while 3 differentiated into adipocytes and chondrocytes but not osteocytes (bi-potent clones). One of the bi-potent cobblestone-like clones was then used for SCNT and in vitro development compared with a fibroblast-like clone which did not differentiate. Both cell types produced blastocysts at similar rates. In conclusion we have identified uni-potent and bi-potent cell types in primary cultures of adult fibroblasts used previously to clone live piglets.