Chien-Hong Chen

Parthenogenesis of rabbit oocytes activated by different stimuli

Oocyte activation is one of the essential elements determining the success of nuclear transfer and the subsequent development of cloned embryos both in vitro and in vivo. Experiments were conducted to optimize the protocol for oocyte activation in a regular nuclear transfer study. In vivo derived oocytes were collected at 14-15 h from New Zealand white rabbits after ovulation treatment and were activated +18 h post-ovulation treatment. Single activation agents including calcium ionophore (A23187, 5 microM, 5 min), ethanol (Eth, 7%, 7 min), and thimerosal (200 microM, 10 min) were tested. Cleavage rates were highest in the ethanol-treated group (37%) compared to other treatments (19-25%). Very low blastocyst rates (2-3%) resulted which were not significantly different among treatments (P>0.05). Combined single agent treatment (calcium stimulators) with protein kinase inhibitor, 6-DMAP were used to achieve a full oocyte activation. Both pronuclear and blastocyst formation rates were significantly higher (P<0.05) in the Eth+6-DMAP treatment group (38 and 27%) than in the other groups (16-21 and 7-9%, respectively, P<0.05). Low (0.2mM) and high (2.5mM) concentrations of 6-DMAP treatments with different treatment lengths (1.5 and 3.5h) in the combined groups were also compared. Blastocyst formation and cleavage rates were greater in the high concentration with less treatment time groups (36% versus 4-20%, P<0.05). In conclusion, single activation agents, either Ca2+ stimulators or protein kinase inhibitors, could not fully activate mature rabbit oocytes. The best activation procedure obtained in this study was the Eth+6-DMAP combined treatment, which may be incorporated into regular nuclear transfer or cloning protocols.

Putative Porcine Embryonic Stem Cell Lines Derived from Aggregated Four-Celled Cloned Embryos Produced by Oocyte Bisection Cloning

We attempted to isolate ES cell lines using inner cell masses from high-quality cloned porcine blastocysts. After being seeded onto feeders, embryos had better (P < 0.05) attachment, outgrowth formation and primary colonization in both 2× and 3× aggregated cloned embryos (62.8, 42.6 and12.8% vs. 76.2, 55.2 and 26.2%, respectively) compared to the non-aggregated group (41.6, 23.4 and 3.9%). Effects of feeder types (STO vs. MEF) and serum sources (FBS vs. KSR) on extraction of cloned embryo-derived porcine ES cells were examined. More (17.1%) ntES cell lines over Passage 3 were generated in the MEF/KSR group. However, ntES cells cultured in KSR-supplemented medium had a low proliferation rate with defective morphology, and eventually underwent differentiation or apoptosis subsequently. Approximately 26.1, 22.7 and 35.7% of primary colonies were formed after plating embryos in DMEM, DMEM/F12 and α-MEM media, respectively. Survival rates of ntES cells cultured in α-MEM, DMEM and DMEM/F12 were 16.7, 4.3 and 6.8%, respectively (P > 0.05). We further examined the beneficial effect of TSA treatment of 3× aggregated cloned embryos on establishment of ntES cell lines. Primary colony numbers and survival rates of ntES cells beyond passage 3 were higher (P < 0.05) in those derived from TSA-treated 3× blastocysts (36.7 and 26.7%) than from the non-treated aggregated group (23.1 and 11.5%). These cells, remaining undifferentiated over 25 passages, had alkaline phosphatase activity and expressed ES specific markers Oct4, Nanog, Sox2, and Rex01. Moreover, these ntES cells successfully differentiated into embryoid bodies (EBs) that expressed specific genes of all three germ layers after being cultured in LIF-free medium. In conclusion, we have successfully derived putative porcine ntES cells with high efficiency from quality cloned embryos produced by embryo aggregation, and optimized the ES cell culture system suitable for establishing and maintaining ntES cell lines in undifferentiated state.

Transgenic cloned mice expressing enhanced green fluorescent protein generated by activation stimuli combined with 6-dimethylaminopurine.

Most studies of mouse cloning successfully achieved activation of the reconstructed oocytes by strontium (Sr) combined with cytochalasin B (CB) treatment. A protein kinase inhibitor, 6-dimethylaminopurine (6-DMAP), was used to inhibit the activity of maturation promoting factor for activation of oocytes, but it has never been successfully applied in mouse cloning. This study investigates the activation efficiency of 6-DMAP in mouse somatic cell nuclear transfer (SCNT). Higher parthenogenetic blastocyst rates (71-72%, p < 0.05) were achieved in the oocytes treated with Sr6D (10 mM Sr combined with 2 mM 6-DMAP for 4 h) and Sr6D + SrCB (Sr6D for 2 h then Sr combined with 5 mug/ml CB for another 2 h), and a higher rate of hatching and hatched blastocyst was observed in the Sr6D + SrCB group (31%, p < 0.01) compared with other treatment groups (1-8%). For mouse cloning, cumulus cells of enhanced green fluorescent protein (EGFP)-expressed ESC chimera F1 were used as donor nuclei. Following activation, better development of the cloned embryos was observed in Sr6D + SrCB treatment. Moreover, different media, i.e. KSOM-AA, MEM-alpha and MK, for culturing cloned embryos were also compared in this study. Better morula/blastocyst (40%) and blastocyst (29%) rates were achieved in the embryos cultured in MEM-alpha medium (p < 0.05). Consequently, four EGFP cloned mice were generated in the activation treatment containing 6-DMAP following embryo transfer. In conclusion, treatment with 6-DMAP in combination with other activation stimuli successfully activates mouse reconstructed oocytes and support full-term development of the transgenic SCNT cloned embryos.

Leukemia inhibitory factor and fibroblast growth factor 2 critically and mutually sustain pluripotency of rabbit embryonic stem cells.

Effects of leukemia inhibitory factor (LIF) and fibroblast growth factor 2 (FGF2) on establishment and maintenance of rabbit embryonic stem cell (rESC) lines were assessed. When grown on MEF feeders, rESC lines derived from fertilized embryos were established and maintained in medium containing paracrine factors LIF (via STAT3) and/or FGF2 (via MEK-ERK1/2 and PI3K-AKT). However, high levels of ERK1/2 and AKT activities in rESCs were crucial for maintaining their undifferentiated proliferation. Although rESCs under the influence of either LIF (500, 1,000, and 2,000 U/ml) or FGF2 (5, 10, and 20 ng/ml) alone had enhanced expression of pluripotency markers, peak expression occurred when both LIF (1,000 U/ml) and FGF2 (10 ng/ml) were applied. Induced dephosphorylation of STAT3, ERK1/2, and AKT by specific inhibitors limited growth of rESCs and caused remarkable losses of self-renewal capacity; therefore, we inferred that STAT3, ERK, and AKT had essential roles in maintaining rESC proliferation and self-renewal. We concluded that LIF and FGF2 jointly maintained the undifferentiated state and self-renewal of rESCs through an integrative signaling module.

Physiologic Responses of Mammalian Oocytes and Embryos under Thermal Stress: An Overview

Animals respond to environmental stresses by a global adaptation and adjustment to their physiologic homeostasis in order to eliminate most harmful changes and survive from the insults. This adaptation is the summation of all responses from their building blocks, cells with their associated cellular machineries in response to the undesired environmental clues. It has been known that heat shock proteins (Hsps), some of which are molecular chaperones present in all organisms, are a group of universal cellular proteins to oppose environmentally induced denaturation of many other proteins. These proteins function to assist in folding of newly synthesized proteins and maintain preexisting proteins in a stable conformation without aggregation under stress conditions, which are essential for thermal adaptation in prokaryotes and eukaryotes, including mammalian cells. Although thermobiology has been one of the active fields of study in cell biology or cancer therapy, there is less information available for the adaptation or responses to thermal stresses in embryonic cells such as oocytes and embryos. Previous studies have shown that a short-term heat shock (HS) impacts the developmental competence of embryos during the early phase of apoptosis and the alteration of intracellular calcium concentrations of matured porcine oocytes. Cleavage and blastocyst rates declined while the Ca^(2+)-releasing ability of matured oocytes was enhanced by a short duration (2 h) of HS, but declined after prolonged heat exposure. Taken together, the mechanisms of physiologic adaptation in response to thermal stress in oocytes and embryos are complex processes. HS can cause multiple changes to the oocyte and developing embryos such as enzymatic reactions, ionic influxes, DNA structure and cytoskeleton reorganization, as well as changes in the ooplasmic [Ca^(2+)]i after various intensities of HS. These phenomena may be critical parameters to evaluate their developmental competence. Delicate equilibrium between the deleterious effects and thermotolerance thermotolerance of oocytes, embryos and even the whole animal adapting to HS is one of the decisive factors in determining their fate during the course of development.