C. Earle Pope

Nuclear transfer of sand cat cells into enucleated domestic cat oocytes is affected by cryopreservation of donor cells.

In the present study, we used the sand cat (Felis margarita) as a somatic cell donor to evaluate whether cryopreservation of donor cells alters viability and epigenetic events in donor cells and affects in vitro and in vivo developmental competence of derived embryos. In Experiment 1, flow cytometry analysis revealed that the percentage of necrosis and apoptosis in cells analyzed immediately after freezing/thawing (61 vs. 8.1%, respectively) was higher than that observed in frozen/thawed cells cultured for 18 h (6.9 vs. 3.3%, respectively) or 5 days (38 vs. 2.6%; respectively). The relative acetylation level of H3K9 was lower in frozen/thawed cells (5.4%) compared to that found in cultured cells (60.1%). In Experiment 2, embryos reconstructed with frozen/thawed cells had a lower cleavage rate (85%; day 2) than did embryos reconstructed with cultured cells (95%), while development to the blastocyst stage (day 8) was not affected by cell treatment (17.0% with frozen/thawed cells vs. 16.5% with cultured cells). In Experiment 3, pregnancy rates were similar between both cell treatments (32% with frozen/thawed cells vs. 30% with cultured cells), but the number of embryos that were implanted, and the number of fetuses that developed to term was lower for embryos reconstructed with frozen/thawed cells (1.2 and 0.3%, respectively) than those reconstructed with cultured cells (2.6 and 1.8%, respectively), while the number of fetuses reabsorbed by day 30 was higher (75%) for embryos reconstructed with frozen/thawed cells than those reconstructed with cultured cells (31%). A total of 11 kittens from cultured cells and three kittens from frozen/thawed cells were born between days 60 to 64 of gestation. Most kittens died within a few days after birth, although one kitten did survive for 2 months. In Experiment 4, POU5F1 mRNA expression was detected in 25% of blastocysts derived from frozen/thawed cells, whereas 88 and 87% of blastocysts derived from cultured cells and by in vitro fertilization, respectively, expressed POU5F1. We have shown that cell cryopreservation increased the incidence of necrosis and apoptosis and altered epigenetic events in donor cells. Consequently, the number of embryos that cleaved, implanted, and developed to term-gestation and POU5F1 expression in derived blastocysts indirectly was affected.

Trichostatin A Modified Histone Covalent Pattern and Enhanced Expression of Pluripotent Genes in Interspecies Black-Footed Cat Cloned Embryos But Did Not Improve In Vitro and In Vivo Viability

Abstract The black-footed cat (BFC; Felis nigripes), one of the smallest wild cats, is listed as threatened. Interspecies somatic cell nuclear transfer (Is-SCNT) offers the possibility of preserving endangered species. Development to term of interspecies BFC (Is-BFC) cloned embryos has not been obtained, possibly due to abnormal epigenetic reprogramming. Treatment of intraspecies cloned embryos with TSA improves nuclear reprogramming and in vitro and in vivo viability. In this study, we evaluated (1) whether covalent histone modifications differ between Is-BFC cloned embryos and their IVF counterparts, (2) the optimal TSA concentration and exposure times to modify the covalent histone patterns, (3) if TSA enhances in vitro and in vivo developmental competence of cloned embryos, and (4) expression of pluripotent genes. Results indicated that the covalent histone modifications of Is-BFC cloned embryos aberrantly differ from their DSH-IVF counterpart embryos. Aberrant epigenetic events may be due partially to the inability of the DSH cytoplasm to modify the restrictive epigenetic marks of the BFC nuclei after somatic cell nuclear transfer (SCNT). Incomplete remodeling of the histone H3K9me2 in Is-BFC cloned embryos possibly contributes to abnormal expression of pluripotent genes and low embryonic development. Treatment of Is-BFC cloned embryos with TSA remodeled the covalent pattern in H3K9ac and H3K9me2, resembling epigenetic patterns in IVF counterpart embryos, and resulted in activation of some pluripotent genes. However, genomic reprogramming of Is-BFC cloned blastocysts did not follow the same reprogramming pattern observed in DSH-IVF embryos, and in vitro and in vivo developmental competence was not enhanced.

Cloned embryos from semen. Part 2: Intergeneric nuclear transfer of semen-derived eland (Taurotragus oryx) epithelial cells into bovine oocytes

The production of cloned offspring by nuclear transfer (NT) of semen-derived somatic cells holds considerable potential for the incorporation of novel genes into endangered species populations. Because oocytes from endangered species are scarce, domestic species oocytes are often used as cytoplasts for interspecies NT. In the present study, epithelial cells isolated from eland semen were used for intergeneric transfer (IgNT) into enucleated bovine oocytes and compared with bovine NT embryos. Cleavage rates of bovine NT and eland IgNT embryos were similar (80 vs. 83%, respectively; p > 0.05); however, development to the morula and blastocyst stage was higher for bovine NT embryos (38 and 21%, respectively; p < 0.0001), than for eland IgNT embryos (0.5 and 0%, respectively). DNA synthesis was not observed in either bovine NT or eland IgNT cybrids before activation, but in 75 and 70% of bovine NT and eland igNT embryos, respectively, cell-cycle resumption was observed at 16 h postactivation (hpa). For eland IgNT embryos, 13% had > or = 8 cells at 84 hpa, while 32% of the bovine NT embryos had > or = 8 cells at the same interval. However, 100 and 66% of bovine NT and eland IgNT embryos, respectively, that had > or = 8 cells synthesized DNA. From these results we concluded that (1) semen-derived epithelial cell nuclei can interact and be transcriptionally controlled by bovine cytoplast, (2) the first cell-cycle occurred in IgNT embryos, (3) a high frequency of developmental arrest occurs before the eight-cell stage in IgNT embryos, and (4) IgNT embryos that progress through the early cleavage stage arrest can (a) synthesize DNA, (b) progress through subsequent cell cycles, and (c) may have the potential to develop further.

BEHAVIORAL TRAINING AND HYDRAULIC CHUTE RESTRAINT ENABLES HANDLING OF ELAND ANTELOPE (TAUROTRAGUS ORYX) WITHOUT GENERAL ANESTHESIA

Abstract Difficulties and risks associated with restraining large nondomestic ungulates are limiting factors toward developing and applying assisted reproductive technologies, such as artificial insemination and embryo transfer. In this study on 10 female eland (Taurotragus oryx), we evaluated the use of behavioral training and handling handling in a hydraulic chute to perform transvaginal ultrasound-guided oocyte retrieval and other clinical procedures. Nine females were conditioned to associate specific sound cues with food treats. The interval from the audio cue until acceptance of handheld treats varied among females (1.8–58.3 min). Animals also differed in their response to training for voluntary entry into the chute. Handling eland for oocyte retrieval in the hydraulic chute required xylazine sedation. During sedation and handling, eland undergoing oocyte retrieval procedures had higher blood glucose levels (14.4 ± 3.1) than females handled similarly but without oocyte retrieval (9.3 ± 2.7 mmol/L). Plasma osmotic pressure, hematocrit, and creatine phosphokinase activity were similar between these two groups. Females that were more difficult to train had higher blood glucose levels than the more cooperative animals. Cooperative females had fewer vertical stripes on their sides. More than 40 procedures were conducted without complications or mortality. The combination of behavioral conditioning–training and restraint of sedated eland in a hydraulic chute was a reliable and repeatable method for performing minimally invasive assisted reproductive techniques.

Ultrasonographic-guided retrieval and in vitro maturation of eland (Taurotragus oryx) and bongo (Tragelaphus eurycerus isaaci) antelope oocytes.

The limited availability of gametes is a major factor hindering the development and application of assisted reproductive technologies (ART) in large non-domestic ungulates. This is partly due to the small number of captive animals and handling difficulties associated with procedures for gamete recovery. In the present study, results are reported of multi-year studies on ovarian stimulation and oocyte retrieval by ultrasonographic-guided transvaginal follicular aspiration and subsequent in vitro maturation (IVM) in eland and bongo antelopes. All procedures were conducted on sedated females handled in a hydraulic chute without inducing general anesthesia. Five estrous synchronization/ovarian stimulation protocols were evaluated and data are presented on 73 and 15 procedures in eland and bongo, respectively. Repeating procedures (< or =once/month) on the same female did not affect ovarian response or number oocytes recovered in either species. Eland females, but not the ovarian stimulation treatment, affected ovarian response. Ovarian stimulation treatment affected oocyte recovery rate in eland, but not in bongo. In both species, ovarian hormone stimulation treatment affected the distribution of follicles by size and the status of expansion of the cumulus cell investment of oocytes, but not the frequency of metaphase II oocytes during IVM. The timing of extrusion of the first polar body during IVM was more synchronous in bongo than in eland oocytes. It is concluded that Transvaginal oocyte retrieval (TVOR) can be safely and repeatedly applied in gonadotropin-treated eland and bongo females to recover oocytes that can mature in vitro. The methods described for the present study can be adapted to improve the availability of non-domestic ungulate oocytes for basic and applied studies.

Cloned Embryos from Semen. Part 1: In Vitro Proliferation of Epithelial Cells on Embryonic Fibroblasts after Isolation from Semen by Gradient Centrifugation

Although epithelial-like somatic cells have been previously isolated from semen, cell proliferation rates were low. Culture of whole semen samples resulted in loss of potentially valuable spermatozoa. The aims of the present study were to: (1) isolate somatic cells from semen, while preserving sperm viability, and (2) optimize in vitro culture conditions for semen-derived epithelial cells. Density gradient centrifugation of washed ejaculates of two rams (Ovis aries) (n = 24) and one eland bull (Taurotragus oryx) (n = 4) was performed using a three-layer discontinuous Percoll column consisting of 90% (P-90), 50% (P-50), and 20% (P-20) Percoll. In vitro culture and Trypan Blue staining indicated that live somatic cells settled in the P-20 layer. Nonmotile spermatozoa were recovered at the P-50 and P-90 interfaces, whereas motile spermatozoa were collected in the pellet from the P-90 layer. Subsequently, somatic cells isolated from the P-20 layer were plated either on inactivated 3T3 mouse embryonic fibroblast feeder layers, collagen-coated plates with 3T3 feeder cell inserts, or on collagen-coated plates. Initial somatic cell plating was similar among treatments, but proliferation significantly increased when cocultured with 3T3 cells (feeder or insert). Furthermore, two different types of epithelial cells were obtained. The exact origin of the cells in the male reproduction system is uncertain and probably variable. The present method of cell isolation and in vitro culture may be of value for preserving endangered species. Specifically, cells isolated and cultured from cryopreserved semen of nonliving males could be used for producing embryos by somatic cell nuclear transfer.

Birth of a domestic cat kitten produced by vitrification of lipid polarized in vitro matured oocytes

The ability to cryopreserve oocytes is an effective method to retain valuable genetic material of mammals, including that of endangered animals. Embryos of domestic cats are amenable to cryopreservation, whereas their oocytes are much less cryo-tolerant. The capability of oocytes to survive cryopreservation is affected by several factors, one of which has been hypothesized to be the high concentration of intracellular lipids. To test this hypothesis, in this study we polarized lipids of cat oocytes and tested their cooling and freezing sensitivity. We found that the sensitivity of oocytes to cooling and cryopreservation does appear to be related to their high intracellular lipid content, as indicated by higher cryosurvival and development into blastocysts when intracellular lipids of in vitro matured oocytes were polarized before vitrification. However, polarization of all intracellular lipids was detrimental to development of embryos. Cell numbers in blastocysts derived from fully polarized/vitrified oocytes were significantly lower than those of partially polarized/vitrified or non-vitrified/fresh oocytes. Although embryos derived from fully polarized/vitrified oocytes developed to the blastocyst stage at higher rates than those of partially polarized/vitrified or non-centrifuged/vitrified oocytes, their in vivo developmental competence was compromised. When embryos derived from fully polarized/vitrified oocytes were transferred, although two recipients became pregnant, all implanted embryos were reabsorbed. In contrast, when embryos derived from oocytes that were only partially lipid polarized before vitrification and then were transferred, one recipient did become pregnant and produced a live healthy kitten. The present results suggest that other approaches to altering intra-cellular lipid levels in cat oocytes should be evaluated to improve their functional survival after cryopreservation.

Phenotypic and Molecular Characterization of Domestic Cat (Felis catus) Spermatogonial Stem Cells

ABSTRACT In many mammalian species, surface markers have been used to obtain enriched populations of spermatogonial stem cells (SSCs) for assisted reproduction and other applications; however, little is known about the expression patterns of feline SSCs. In this study, we assessed expression of the SSC surface markers commonly used in other species, KIT, ITGA6, CD9, GFRalpha1, ADGRA3, and THY1, in addition to the less frequently used pluripotent markers TRA-1-60, TRA-1-81, SSEA-1, and SSEA-4 in SSCs of both prepubertal and adult domestic cats (Felis catus). To further characterize cat SSCs, we sorted cells using SSC-specific markers and evaluated the expression of the pluripotent transcription factors NANOG, POU5F1, and SOX2 and the proto-oncogene MYC within these populations. We concluded that SSC surface markers used in other mammalian species were not specific for identifying cat SSCs. However, the pluripotent markers we evaluated were more specific to cat spermatogonia, and the presence of SSEA-1 and SSEA-4 in fewer and primarily individual cells suggests that these two markers may be used for enrichment of cat SSCs. The expression of pluripotent transcription factors at mRNA level by single-stained cells positive for SSEA-4 and by dual-stained cells positive for both GFRalpha1 and SSEA-4 reflects the undifferentiated stage of cat SSCs. The absence of transcription factors in double-stained cells positive for only one marker implies the loss of the stem cell-like identity with the loss of either GFRalpha1 or SSEA-4. Further investigation is warranted to elucidate the biological characteristics of these spermatogonial subpopulations.

Pluripotent and Multipotent Domestic Cat Stem Cells: Current Knowledge and Future Prospects

The domestic cat is a mammalian species of particular importance due to their evolutionary history, role as companion animals and as a research model. Stem-cell-based therapies have been developed to improve health and well-being in domestic cats, as an alternative approach for the conservation of genetically valuable animals and preservation of endangered animals, and as an efficient method to produce genetically engineered cats for modeling human diseases. Successful application of stem-cell-based therapies in cats is dependent on development of robust methods to efficiently isolate stem cells and a better understanding of the mechanisms that control stem cell fate to differentiate these cells into specific phenotypes. This chapter describes recent progress on the isolation, culture, and characterization of pluripotent and multipotent stem cells and preliminary trials in regenerative medicine in domestic cats and prospects for applications to conservation and veterinary care of endangered felids.

Cloning Endangered Felids by Interspecies Somatic Cell Nuclear Transfer.

In 2003, the first wild felid was produced by interspecies somatic cell nuclear transfer. Since then other wild felid clone offspring have been produced by using the same technique with minor modifications. This chapter describes detailed protocols used in our laboratory for (1) the isolation, culture, and preparation of fibroblast cells as donor nucleus, and (2) embryo reconstruction with domestic cat enucleated oocytes to produce cloned embryos that develop to the blastocyst stage in vitro and, after transfer into synchronized recipients, establish successful pregnancies.