Seasonal effects on gene expression, cleavage timing, and developmental competence of bovine preimplantation embryos.

We examined the association between season and expression of genes involved in early embryonic development with an emphasis on cleavage rate and timing of the first embryonic cleavage. In Exp. 1, oocytes were aspirated during the cold (Dec-Apr) and hot (May-Nov) seasons. Matured oocytes were chemically activated and cultured in vitro. The developmental peak to the two- and four-cell stages occurred earlier, with a higher proportion of first-cleaved embryos, during the cold season relative to the hot season (P<0.01). In Exp. 2, a time-lapse system was employed to characterize the delayed cleavage noted for the hot season. Cleavage to the two-cell stage occurred in two distinct waves: early cleavage occurred between 18 and 25 h post activation, and late cleavage occurred between 27 and 40 h post activation. In Exp. 3, oocytes were aspirated during the cold and hot seasons, matured in vitro, fertilized, and cultured for 8 days. In each season, early- and late-cleaved two-cell stage embryos were collected. Total RNA was isolated, and semi-quantitative and real-time PCRs were carried out with primers for GDF9, POU5F1, and GAPDH using 18S rRNA as the reference gene. In both seasons, the expression of all examined genes was higher (P<0.05) in early- versus late-cleaved embryos. POU5F1 expression was higher (P<0.05) in early-cleaved embryos developed in the cold season versus the hot season counterparts. The findings suggest a deleterious seasonal effect on oocyte developmental competence with delayed cleavage and variation in gene expression.

The antioxidant epigallocatechin gallate (EGCG) moderates the deleterious effects of maternal hyperthermia on follicle-enclosed oocytes in mice.

Hyperthermia-induced oxidative stress is one of the mechanisms suggested to underlie loss of developmental competence in mouse embryos. In this study, we examined whether pretreatment with the antioxidant epigallocatechin gallate (EGCG) can alleviate the negative effects of hyperthermia on developmental competence of the ovarian pool of oocytes and improve embryonic development. Female mice (CB6F1) were synchronized (eCG+hCG) and injected with 0.4 ml EGCG (100 mg/kg body weight) or with saline. Both EGCG- and saline-treated mice were exposed to heat stress (HS; 40 degrees C, 65% RH) or kept under normothermal conditions (Control; 22 degrees C, 45% RH). In vivo-derived zygotes were recovered 20 h after hCG administration and cultured in vitro. Maternal hyperthermia attenuated embryonic cleavage rate in association with further disruption in embryonic early cleavage and subsequently, with embryonic development. While pretreatment with EGCG did not affect the proportion of zygotes that cleaved to the two-cell stage, it appeared to moderate the effect of hyperthermia on both cleavage timing and developmental rate, as reflected by an increased rate of early cleaved embryos and blastocyst formation. Blastocyst developmental competence was also improved, as indicated by the increased total cell number and percentage of embryos that underwent hatching, in association with reduced apoptotic status, as reflected by the percentage of TUNEL-positive cells and intensity of caspase activity for the HS-EGCG embryos vs. HS-saline ones. In summary, while hyperthermia disrupts the competence of the follicle-enclosed oocyte, in vivo administration of the antioxidant EGCG improves developmental competence and the quality of the embryos that develop from these oocytes.

Measurement of essential physical properties of vitrification solutions.

Vitrification is an "ice-free" cryopreservation method that has rapidly developed in recent years and might become the method of choice for oocyte cryopreservation. Five sources of damage should be considered when attempting to achieve successful oocyte cryopreservation by vitrification: (1) Solution effects (2) Crystallization (3) Glass fractures (4) Devitrification and recrystallization (5) Chilling injury. The probability of successful vitrification depends on three major factors: viscosity of the sample; cooling and warming rates; and sample volume. One of the problems associated with the vitrification solution is that it may contain high concentrations of cryoprotectants (CP), which can damage the cells through chemical toxicity and osmotic shock. In the present study, we examined the principal parameters associated with successful vitrification, and attempted to compose guidelines to the most important aspects of the vitrification process. The first step was the selection of a suitable and least toxic vitrification solution. We then evaluated the effects of cooling rate and volume on the probability of vitrification. Reduction of the sample volume, combined with accelerated cooling, enabled reduction of the CP concentration. However, in practice, a delicate balance must be maintained among all the factors that affect the probability of vitrification in order to prevent crystallization, devitrification, recrystallization, glass fractures and chilling injury.

Maternal hyperthermia disrupts developmental competence of follicle-enclosed oocytes: in vivo and ex vivo studies in mice.

Mammalian oocytes are susceptible to thermal stress at various stages of follicular development. We examined whether the ovarian pool of oocytes is susceptible to maternal hyperthermia and if so, whether hyperthermia at the germinal vesicle (GV) stage further affects the developmental competence of preimplantation embryos and offspring quality. Synchronized female mice were exposed to thermal stress (40 degrees C, 65% RH) for 1.5-2h or maintained under normothermal conditions (25 degrees C, 45% RH). Thereafter, mice were paired with stud males. In the first experiment, mated mice were sacrificed 20h post hCG administration, and in vivo-derived zygotes were recovered and cultured in vitro. Maternal hyperthermia decreased the percentage of putative zygotes of apparent normal morphology in the heat-stressed group (81+/-1.3%) as compared to the control group (86+/-1.2%). Developmental competence was also compromised as expressed by the disruption in cleavage timing pattern, resulting in a reduced developmental rate to the blastocyst stage (57+/-2.6% versus 84+/-1.9%). In the second experiment, both groups were left with stud males until litter delivery. Litter size in the first delivery cycle was lower for the heat-stressed group (7.7+/-1.1 pups), followed by a slight increase throughout consecutive cycles as compared to the control group (11.3+/-1.0 pups). Behavioral examinations of 8-week-old pups revealed similar locomotor activity and learning potential between the groups. In summary, the findings indicate that a subpopulation of the ovarian pool of follicles is highly sensitive to thermal stress and that maternal hyperthermia disrupts developmental competence of GV-stage oocytes. Pups that developed from oocytes that survived thermal stress exhibited a developmental potential similar to that of the of control pups.

Oocyte recovery, embryo development and ovarian function after cryopreservation and transplantation of whole sheep ovary.

BACKGROUND: Successful cryopreservation of a whole ovary may provide a solution for women with premature ovarian failure. The aim of this study was to evaluate the function of cryopreserved whole sheep ovaries both in vitro and in vivo. METHODS: Transplantation of frozen-thawed intact ovaries was performed on eight sheep by artery and vein anastomosis to the contralateral ovarian artery and vein. The remaining ovary was removed. Oocyte aspiration was performed 1 and 4 months post-transplantation. Serum progesterone levels were measured after 24 and 36 months. Magnetic resonance imaging (MRI) was carried out 12 months after transplantation. RESULTS: Progesterone activity was detected in three sheep from 24 to 36 months post-transplantation. Oocyte retrieval was successful in two sheep and parthenogenic activation has resulted in embryonic development up to the 8-cell stage. MRI revealed an intact ovary with small follicles and intact blood vessels. CONCLUSIONS: Whole ovaries, and the follicles and blood vessels they contain, are able to survive cryopreservation. In addition, MRI has shown that blood vessels were intact and that normal blood flow had resumed to the transplant. We conclude that immediate and long-term hormonal restoration and normal ovulation is possible after cryopreservation and transplantation of whole ovaries in sheep.