Yan-Ping Wang

Positive effects of Taxol pretreatment on morphology, distribution and ultrastructure of mitochondria and lipid droplets in vitrification of in vitro matured porcine oocytes

This study was designed to determine the effects of Taxol pretreatment on the morphology, distribution and ultrastructure of mitochondria and lipid droplets in vitrified porcine oocytes matured in vitro. The result showed that: (1) the rate of normal mitochondria distribution in fresh group (92.85%) was significantly higher (P<0.05) than that in other three groups (toxicity, 72.48%; vitrification, 50.83%; Taxol+vitrification, 69.98%) and Taxol pretreatment significantly (P<0.05) increased the ratio of normal mitochondria distribution in vitrified oocytes; (2) lipid droplets in vitrified oocytes got cracked, resulting in a great number of smaller lipid droplets (diameter <5 microm). The number of lipid droplets (5-10 microm in diameter) in vitrified oocytes pretreated with Taxol was higher (P<0.05) than that in the oocytes without Taxol pretreatment (81.87+/-13.63 vs. 64.27+/-13.72); (3) both toxicity and vitrification cause the difference in the ultrastructure of mitochondria and lipid droplets. Mitochondria were well maintained in the form of typical round and ellipse shape with smooth surface and clear outline and lipid droplets existed in the form of integrity in Taxol pretreatment group. In conclusion, Taxol pretreatment has positive effects on vitrified porcine oocytes matured in vitro in terms of morphology, distribution and ultrastructure of mitochondria and lipid droplets.

Effect of vitrification on mitochondrial distribution and membrane potential in mouse two pronuclear (2-PN) embryos.

The present study was designed to investigate the effect of vitrification on mitochondrial distribution, membrane potential (Δψ) and microtubule distribution in mouse 2‐PN embryos, as well as to document the relationship between mitochondrial distribution and developmental ability of those embryos. Mitochondrial distribution was examined by fluorescence microscopy technology. Results indicated that: (1) The rate of mitochondrial ring formation around pronuclei in vitrified 2‐PN embryos was significantly lower than in fresh ones (67.3 ± 3.0% vs. 84.9 ± 3.1%) (P < 0.05). (2) Blastocyst development rate of vitrified 2‐PN embryos without mitochondrial rings (61.7 ± 4.5%) was significantly lower than that of vitrified embryos with mitochondrial rings (82.1 ± 2.8%). (3) Following staining by 5,5′,6,6′‐tetrachloro‐1,1′,3,3′‐tetraethyl‐imidacarbo‐cyanine iodide (JC‐1), most red‐colored mitochondria (high Δψ) were distributed peripherally around pronuclei and along cell membranes of fresh 2‐PN embryos. Conversely, red‐colored mitochondria were greatly diminished in vitrified embryos, with green mitochondria (low Δψ) evenly distributed throughout the cytoplasm. The proportion of fresh 2‐PN embryos with obvious aggregation of high Δψ mitochondria (84.2 ± 2.2%) was significantly higher than that of vitrified embryos (26.7 ± 3.0%) (P < 0.05). (4) The proportion of fresh embryos with microtubules distributed around pronuclei (83.5 ± 3.4%) was similar to that of vitrified embryos (74.7 ± 2.5%). In conclusion, vitrification affected mitochondrial distribution and decreased the mitochondrial membrane potential in mouse 2‐PN embryos, events which may affect subsequent developmental viability of such embryos. Mol. Reprod. Dev. 76: 1056–1063, 2009.

Positive effects of Forskolin (stimulator of lipolysis) treatment on cryosurvival of in vitro matured porcine oocytes

In order to examine its effect on oocyte lipid content and cryosurvival, Forskolin was added to the medium for in vitro maturation of porcine oocytes. Treatments were control (IVM without Forskolin during the 42 h incubation period), addition of 10 μM Forskolin for the entire 42 h (0-42) and addition of 10 μM Forskolin between 24 and 42 h only (24-42). In Experiment 1, treatments did not differ significantly in cleavage rate, but the blastocyst formation rate was lower in the 0-42 group than for control and 24-42 group oocytes (17, 32 and 40%, respectively; P < 0.05). It was shown in Experiment 2 that Forskolin treatment from 0-42 h and from 24-42 h significantly reduced lipid content of oocytes compared to that of control cells (65 and 99 vs. 140 μm(2) intensity of fluorescence, respectively; P < 0.05). In Experiment 3, the percentage of oocyte survival after cryopreservation and thawing was significantly higher in both Forskolin treatment groups than in control oocytes (72% for 0-42, 65% for 24-42 and 52% for control; P < 0.05). However, Forskolin treatment did not increase cleavage rates of vitrified in vitro matured porcine oocytes (Control group 28%, 0-42 h group 0%, 24-42 h group 26.67%). Addition of Forskolin affected the nuclear maturation of porcine oocytes. The percentage of PBE (polar body extrusion) were significantly reduced in the 0-42 h group (0-42 h group 42.00 ± 2.08 vs. Control group 79.70 ± 2.82 and 24-42 h group 70.60 ± 2.83; P < 0.05). The 24-42 h group showed similar nuclear status to that of the Control group. We propose that delipation engendered by incubation with 10 μM Forskolin during 24-42 hours of maturation increased cryosurvival of in vitro-maturated porcine oocytes and that attendant chemical lipolysis did not impair their further development as it may have done in oocytes incubated with Forskolin for the full 42 h.

OPS vitrification of mouse immature oocytes before or after meiosis: the effect on cumulus cells maintenance and subsequent development.

Cryopreservation can cause cumulus cell damage around the immature oocytes, which may result in poor subsequent development. To evaluate the effect of the meiosis stage on the cumulus cell cryoinjury and determine the suitable stage for cryopreservation in immature oocytes, mouse oocytes at germinal vesicle (GV) and germinal vesicle breakdown (GVBD) stages were vitrified using open pulled straw (OPS) method. Cumulus cells damage was scored immediately after thawing by double-fluorescent staining. The survival rate of the oocytes was evaluated and the subsequent development of oocytes was assessed through in vitro culture (IVC) and in vitro fertilization (IVF) separately. After vitrification, a higher proportion of cumulus cells of GV oocytes were damaged than those of GVBD and untreated control groups. The survival rate of vitrified GVBD oocytes (94.1%) was significantly higher (p < 0.05) than that of GV oocytes (85.4%). Oocytes vitrified at GVBD stage (55.7%) showed similar cleavage rate compared to those at GV stage (49.2%), but significantly higher (p < 0.05) blastocyst rate (40.9% vs. 27.4%). These results demonstrate that oocytes at GVBD stage remain better cumulus membrane integrity and developmental ability during vitrification than those at GV stage, indicating they are more suitable for immature oocytes cryopreservation in mice.

Effect of methanol on mitochondrial organization in zebrafish (Danio rerio) ovarian follicles.

Successful cryopreservation is usually measured in terms of cell survival. However, there may also be more subtle effects within cells that survive. Previous studies on zebrafish have produced evidence of mitochondrial DNA (mtDNA) damage in cryopreserved embryonic blastomeres and, after exposure to cryoprotectants, alterations in mtDNA replication in embryos and decreased mitochondrial membrane potential, mtDNA and ATP production in ovarian follicles. This study shows that the decreased ATP levels previously observed in stage III zebrafish ovarian follicles exposed to ≥3 M methanol persisted in those follicles that subsequently developed to stage IV. However, the decreased mtDNA levels were restored in those follicles. In order to determine whether mitochondrial distribution and/or their transport network was affected by the methanol exposure, immunocytochemistry analysis of tubulin and mitochondrial cytochrome c oxidase I (COX-I) was performed, along with phalloidin staining of polymerized actin. Neat arrangements of all proteins were observed in control follicles, with COX-I and tubulin being colocalized near granulosa cell nuclei, while actin formed hexagonal and/or polygonal structures nearer granulosa cell membranes and projected into the oocyte surface. Exposure to methanol (2 to 4 M) disrupted the COX-I and tubulin arrangements and the hexagonal and/or polygonal actin distribution and actin projections into the oocyte. These effects were still observed in those follicles that developed to stage IV, although the severity was reduced. In summary, the disruption to function and distribution of mitochondria in ovarian follicles exposed to >2 M methanol may be mediated via disruption of the mitochondrial transport system. Some recovery of this disruption may take place after methanol removal and subsequent follicle maturation.