Effect of ambient temperatures during oocyte recovery on in vitro production of bovine embryos

Recovery of oocytes from ovaries collected at slaughter was carried out at three ambient temperatures (25 degrees, 30 degrees and 35 degrees C) to assess the effect on subsequent embryonic production in vitro. Oocytes recovered at each temperature were thereafter maintained at temperatures > or =35 degrees C as they were subjected to in vitro maturation, fertilization and culture (IVM/IVF/IVC). The oocytes and resulting embryos within each temperature group were subsequently evaluated for their rates of fertilization, cleavage and development to blastocysts, as well as for the number of cells/blastocyst. The results demonstrate that exposure of cumulus-ocyte-complexes (COCs) to temperatures below 35 degrees C during oocyte recovery is detrimental to optimal embryo production. Although the fertilization and cleavage rates of oocytes recovered at temperatures below 35 degrees C were not significantly lower than that of the controls, the percentage of oocytes recovered at 35 degrees C that developed to the blastocyst stage following fertilization and culture (33.7%) was significantly greater than those from oocytes recovered at either 25 degrees C (22.4%) or 30 degrees C (19.5%). The mean numbers of blastomeres/embryo were significantly lower in embryos derived from oocytes collected at either 25 degrees or 30 degrees compared with those collected at 35 degrees C. The results of this study suggest that exposure of COCs to temperatures below 35 degrees C during oocyte recovery may significantly decrease both the quantity and quality of embryos produced by in vitro methods.     

Effect of low-temperature bovine ovary storage on the maturation rate and developmental potential of follicular oocytes after in vitro fertilization, parthenogenetic activation, or somatic cell nucleus transfer

The present study examined the competence of oocytes from bovine ovaries stored at low temperatures for at least 1 day, which is the necessary time period to complete inspection for bovine spongiform encephalopathy. Storage of ovaries at 10 degrees C for 24 h did not affect oocyte maturation (68% versus 68%) or the potential of oocytes to develop into day 8 blastocysts after in vitro fertilization (25% versus 27%), parthenogenetic activation (19% versus 25%), or somatic cell nucleus transfer (27% versus 32%) compared with controls. In vitro-fertilized and parthenogenetic oocytes from ovaries stored at 10 degrees C for 48 h had a significantly decreased maturation rate and developmental potential, but nucleus-transferred oocytes that received cultured cumulus cells did not (27% versus 32%). Thus, bovine ovaries can be stored at 10 degrees C for at least 24 h without decreasing oocyte maturation competence or the developmental potential of in vitro-fertilized, parthenogenetically activated, and somatic cell nucleus-transferred oocytes, at least to the blastocyst stage. The present study provides valuable information with regard to removing bovine ovaries from abattoirs after testing for bovine spongiform encephalopathy.     

The thermal environment of arboreal pools and its effects on the metabolism of the arboreal, oophagous tadpoles of a Taiwanese tree frog, Chirixalus eiffingeri (Anura: Rhacophoridae).

We have studied seasonal and diurnal fluctuations of water temperature in bamboo stumps and the effect of temperature on the energy metabolism of arboreal, oophagous tadpoles of Chirixalus eiffingeri. We collected tadpoles (Gosner stage 28-29) in February and August from Chitou, Taiwan and acclimated them to 12 and 22 degrees C. Using a closed system, we measured tadpole oxygen consumption (V.O(2)) at 12, 17 and 22 degrees C. The water temperature was lowest in February (11-13 degrees C), increased rapidly during March and April and was highest from May to August (20-24 degrees C). Diel fluctuations in the temperature of the pools of water in bamboo stumps mirrored fluctuations in air temperature. Tadpoles collected in February and August exhibited metabolic compensation in that tadpoles acclimated at 12 degrees C had significantly higher V.O(2) than those acclimated at 22 degrees C. There are at least two possible explanations for the presence of metabolic compensation in C. eiffingeri tadpoles. Firstly, the larval period of C. eiffingeri ranges from 40 to 78 days, a tadpole could experience relatively large fluctuations in body temperature (up to 10 degrees C) during the development. As a result, C. eiffingeri tadpoles most likely evolved metabolic compensation to maintain activity levels under different thermal environments. Secondly, because arboreal pools are small, thermally unstratified, aquatic microhabitats, tadpoles are unable to behaviorally select preferred temperatures. As a result, metabolic compensation allows tadpoles to regulate their physiological functions.     

Meiotic induction by heat stress in mouse oocytes: involvement of AMP-activated protein kinase and MAPK family members

In this study, we examined the effect of heat pulsing on oocyte maturation and assessed the possible role of stress-activated enzymes during heat stress-induced meiotic maturation. Denuded oocytes from immature eCG-primed mice were pulsed for 30 min at increasing temperatures from 40 degrees C to 43 degrees C in dibutyryl cAMP-containing medium and were subsequently cultured at 37 degrees C for a total incubation time of 17-18 h. Oocytes exposed to 42 degrees C showed the greatest stimulation of maturation, with no effect at 43 degrees C. A heat pulse did not compromise progression to metaphase II as observed by polar body (PB) formation. The AMP-activated protein kinase (PRKA) inhibitors compound C and Ara-A each blocked the meiosis-stimulating effects of heat. Western blots showed that acetyl-CoA carboxylase, an important substrate of PRKA, was phosphorylated in heat-treated germinal vesicle-stage oocytes, indicating activation of PRKA before maturation. The mitogen-activated protein 2 kinase (MAP2K1) inhibitor PD98059 also prevented heat-induced maturation, but this effect was unrelated to MAPK1/3 activation, which was not observed until after germinal vesicle breakdown (GVB). Phosphorylated MAPK14 was not detected in the oocyte under any experimental condition, and only high concentrations of the MAPK14 inhibitor SB203580 blocked heat-stimulated maturation, suggesting that MAPK14 is not involved in meiotic induction. MAPK8/9 was activated by heat, and the MAPK8/9 inhibitor SP600125, but not JUN N-terminal kinase I, blocked heat-induced maturation. Heat treatment transiently suppressed GVB and PB formation in spontaneously maturing oocytes by a mechanism that is apparently different from its meiosis-inducing action. Collectively, these data show that an acute heat pulse stimulates GVB in meiotically arrested oocytes and suggest that this effect is mediated through the activation of PRKA.     

Maintenance of meiotic arrest and developmental potential of porcine oocytes after parthenogenetic activation and somatic cell nuclear transfer

Several studies report that meiotic maturation of porcine oocytes can be reversibly preserved. The present study examined how long meiotic maturation can be suppressed. The first experiment determined the preservation medium suitable for reversibly suppressing meiotic maturation of porcine oocytes. The second experiment examined the in vitro developmental potential of oocytes maintained in meiotic arrest after parthenogenetic activation and nuclear transfer of somatic cells. Preservation of cumulus-oocyte complexes with NCSU-37 medium containing 10% follicular fluid, 1 mM dibutyryl cyclic AMP, and follicular shell pieces for 24-96 h at 39 degrees C did not affect oocyte maturation compared with controls (94-98% vs. 98%). The potential of parthenogenetically activated and nuclear-transferred oocytes maintained in meiotic arrest for 24-48 h to develop into blastocysts was not significantly different from that of controls (20-25% vs. 18% and 8-11% vs. 9%, respectively). The present study demonstrated that meiotic maturation of porcine oocytes can be suppressed after preservation for 48 h at 39 degrees C without decreasing oocyte maturation competence or the ability of oocytes to develop to at least the blastocyst stage.     

Involvement of apoptosis in disruption of developmental competence of bovine oocytes by heat shock during maturation

Various pathological stimuli such as radiation, environmental toxicants, oxidative stress, and heat shock can initiate apoptosis in mammalian oocytes. Experiments were performed to examine whether apoptosis mediated by group II caspases is the cause for disruption of oocyte function by heat shock applied during maturation in cattle. Bovine cumulus-oocyte complexes (COCs) were cultured at 38.5, 40, or 41 degrees C for the first 12 h of maturation. Incubation during the last 10 h of maturation, fertilization, and embryonic development were at 38.5 degrees C and 5% (v/v) CO2 for all treatments. In the first experiment, exposure of COCs to thermal stress during the first 12 h of maturation reduced cleavage rate and the number of oocytes developing to the blastocyst stage. In the second experiment, a higher percentage of TUNEL-positive oocytes was noted at the end of maturation for oocytes matured at 40 and 41 degrees C than for those at 38.5 degrees C. In addition, the distribution of oocytes classified as having high (>25 intensity units), medium (15-25 intensity units), and low (<15 intensity units) caspase activity was affected by treatment, with a greater proportion of heat-shocked oocytes having medium or high activity. In the third experiment, COCs were placed in maturation medium with vehicle (0.5% [v/v] DMSO) or 200 nM z-DEVD-fmk, an inhibitor of group II caspases. The COCs were matured at 38.5 or 41 degrees C, fertilized and cultured for 8 days. The inhibitor blocked the effect of heat shock on cleavage rate and the percentage of oocytes and cleaved embryos developing to the blastocyst stage. In conclusion, heat shock during oocyte maturation can promote an apoptotic response mediated by group II caspases, which, in turn, leads to disruption of the oocyte's capacity to support early embryonic development following fertilization.     

Maturation of porcine oocytes after cooling at the germinal vesicle stage

Maturation of porcine oocytes was examined after oocytes were cooled at the germinal vesicle stage. Cumulus-oocyte complexes (COCs) collected from medium-sized follicles were cooled at 24 degrees C or 4 degrees C for 5, 30 or 120 min in a solution with or without 1.5 M dimethylsulfoxide (DMSO). After rewarming, COCs were cultured in maturation medium at 39 degrees C, 5% CO2 in air for 44 h. Meiotic spindle organisation (by immunostaining and confocal microscopy), nuclear maturation (by orcein staining) and cytoplasmic maturation (by intracellular glutathione assay) of oocytes were examined after maturation. When COCs were cooled at 24 degrees C for various times in the medium without DMSO, a tendency to decreased spindle formation, nuclear maturation and cytoplasmic maturation was observed, but there was no statistical difference compared with controls. Addition of DMSO during cooling inhibited subsequent nuclear maturation and spindle formation. When COCs were cooled at 4 degrees C, both nuclear and cytoplasmic maturation as well as spindle formation were inhibited in most oocytes in a time-dependent manner. DMSO during cooling did not have any beneficial effect on subsequent oocyte maturation and spindle formation. These results suggest that porcine oocytes are very sensitive to a drop in the temperature before exposure to culture. Cooling oocytes before maturation inhibits their subsequent spindle organisation, nuclear and cytoplasmic maturation. Addition of DMSO to the cooling solution did not protect porcine oocytes from cooling-induced damage.     

Effect of ovary holding temperature and time on equine granulosa cell apoptosis, oocyte chromatin configuration and cumulus morphology

The effects of ovary holding time and temperature on granulosa cell apoptosis, oocyte chromatin configuration and cumulus morphology were investigated through a series of experiments. Three experiments were performed to determine the effect of ovary holding time and temperature on granulosa cell apoptosis. Ovaries were held (1) at 20, 30 or 35-37 degrees C for up to 2h, (2) at 30 degrees C for 0-1, 1-2, 2-3, 3-4, 4-6 or 6-10h, and (3) granulosa cells were held for 0, 1, 2, 3, 5, 12 or 24h in M199 with Hank's salts at room temperature (suboptimal incubation). Granulosa cell DNA was analysed by ethidium bromide staining or 3'-end labelling. Two experiments were performed to determine the effect of ovary holding time and temperature on oocyte chromatin configuration. Ovaries were held (1) at 20, 30 or 35-37 degrees C for up to 3h and (2) at 20-37 degrees C for 0-1, 1-2, 2-3, 3-4, 4-6, 6-8 or 8-12h. The oocytes were stained with Hoechst stain 33258 and the chromatin configuration was evaluated. Two experiments were performed to determine the effect of ovary holding time and temperature on cumulus oophorus morphology. Ovaries were held at (1) 20-30 or 35-37 degrees C for up to 2h and (2) for 0-2, 2-4, 4-6, and 6-10h at 35-37 degrees C. The cumulus oocyte complex (COC) were retrieved and the cumulus morphology was evaluated. There was no difference in proportion of follicles with non-apoptotic granulosa cells in the two groups below body temperature (20 and 30 degrees C), but more follicles had apoptotic granulosa cells when the ovaries were held at 35-37 degrees C (P < 0.001). Holding ovaries at 30 degrees C for more than 3h increased the proportion of follicles with apoptotic granulosa cells (P < 0.01). When follicles with non-apoptotic granulosa cells were incubated at room temperature, there was no granulosa cell apoptosis in any of the follicles within the first 3h, but at 5h apoptosis was present in the granulosa cells of 22% of the follicles, and 78% of the follicles contained apoptotic granulosa cells at 24h (P < 0.001). The temperature at which the ovaries were held did not influence oocyte chromatin, although there was a tendency towards more condensed chromatin configurations in the groups below body temperature. More denuded and expanded COCs were present in the lower temperature group (P < 0.001). Oocyte chromatin configuration changed after 6h of holding (P < 0.001), and numbers of compact COCs decreased after 2h (P < 0.05). The present studies suggest that equine follicles should be held for no more than 3h at 20-30 degrees C if granulosa cell apoptosis is to be avoided. To avoid changes in cumulus oophorus morphology, ovaries should be held at 35-37 degrees C and for less than 2h before processing, and to avoid oocyte chromatin configuration changes, ovaries should be stored for less than 6h. When ovaries are to be used in oocyte maturation studies, and assuming that (1) CC is the chromatin configuration of choice for oocyte maturation, (2) that presence of granulosa cell apoptosis promotes maturation of the oocyte and (3) that expanded cumulus oocytes are preferable, the present data suggests that ovaries should be stored for 4-6h before oocyte retrieval.     

Effect of transport and storage temperature of ovaries on in vitro maturation of bitch oocytes

In this study, the effects of ovary transport and storage temperature on in vitro maturation of bitch oocytes were investigated. Ovaries were collected from 23 mature bitches and one randomly selected ovary of each pair (n=23 pairs) was transported in physiologic saline at 4 degrees C, while the other one at 35-38 degrees C for 2-4h. A total of 316 cumulus oocyte complexes (COCs) were obtained from the 4 degrees C group and 301 COCs from the 35-38 degrees C group. All COCs were matured in modified synthetic oviduct fluid (mSOF) supplemented with follicle stimulating hormone (FSH), essential and non-essential amino acids at 38 degrees C in a humidified 5% CO2, 5% O2, and 90% N2 atmosphere for 72 h. At the end of the in vitro maturation period, nuclear maturation of oocytes was classified as germinal vesicle (GV), germinal vesicle breakdown (GVBD), metaphase I (MI), metaphase II (MII), undetermined nuclear maturation (UDNM), and MI+MII. The nuclear maturation rates to MI, MII, and MI+MII stages were 60.44%, 10.75%, and 71.20% in the 4 degrees C group and 37.20%, 7.64%, and 45.85% in the 35-38 degrees C group, respectively. The data demonstrated that oocytes obtained from ovaries transported at 4 degrees C had higher maturation rates than from the ones transported at 35-38 degrees C (p<0.001).     

Effect of 1,2-propanediol versus 1,2-ethanediol on subsequent oocyte maturation, spindle integrity, fertilization, and embryo development in vitro in the domestic cat

This study assessed the impact of various cryoprotectant (CPA) exposures on nuclear and cytoplasmic maturation in the immature cat oocyte as a prerequisite to formulating a successful cryopreservation protocol. In experiment 1, immature oocytes were exposed to 0, 0.75, 1.5, or 3.0 M of 1,2-propanediol (PrOH) or 1,2-ethanediol (EG) at room temperature (25 degrees C) or 0 degrees C for 30 min. After CPA removal and in vitro maturation, percentage of oocytes reaching metaphase II (MII) was reduced after exposure to 3.0 M PrOH at 0 degrees C or 3.0 M EG at both temperatures. All CPA exposures increased MII spindle abnormalities compared to control, except 1.5 M PrOH at 25 degrees C. In experiments 2 and 3, immature oocytes were exposed to CPA conditions yielding optimal nuclear maturation that either had caused spindle damage (0.75 M PrOH, 1.5 M EG, and 3.0 M PrOH at 25 degrees C) or not (1.5 M PrOH at 25 degrees C). After maturation and insemination in vitro, oocytes were cultured for 7 days to assess treatment influence on developmental competence. CPA exposure did not affect fertilization, but the high incidence of MII spindle abnormalities resulted in a low percentage of cleaved embryos. Blastocyst formation and quality were influenced by both CPA types (EG was more detrimental than PrOH) and concentration (3.0 M was more detrimental than 1.5 M). Overall, cat oocytes appear to be highly sensitive to CPA except after exposure to 1.5 M PrOH at 25 degrees C, a treatment that still allowed approximately 60% of the oocytes to reach MII and approximately 20% to form blastocysts.     

Heat shock at the germinal vesicle breakdown stage induces apoptosis in surrounding cumulus cells and reduces maturation rates of porcine oocytes in vitro

The objectives were to determine the effects of cumulus cells (CC) on porcine oocyte maturation in vitro (IVM) after heat shock (HS). Treated oocytes were cultured at 39 degrees C for 20h, followed by HS treatment (42 degrees C for 1h), and then matured in vitro for 23h. The CC were removed before maturation (H1), after HS (H2), or after maturation (H3). Control oocytes were continuously cultured under the same conditions and CC were similarly removed before maturation (C1), after 21h of IVM (C2), and after maturation (C3). Maturation rates were affected by HS (P<0.01) and by an interaction between HS and CC (P<0.01). A significant decrease in maturation rate only occurred when CC were not removed from cumulus oocyte complexes during IVM after HS (H3, 39.2+/-5.7% versus C3, 78.2+/-8.2%, P<0.01). Mature oocytes in all treatment groups were electrically activated and cultured for 8 d in NCSU23. Blastocyst rates in group H1 (7.2+/-3.5%) and C1 (6.3+/-3.1%) were lower than in other groups (H2, 21.4+/-4.4%, C2, 20.5+/-7.0%, H3, 23.1+/-2.0%, C3, 24.3+/-3.1%, P<0.05). Damaged DNA was detected in CC by a comet assay at 0h after HS (60.8+/-12.5% compared with 9.2+/-2.2% in control, P<0.05); in HS groups, both DNA damage (comet assay, 74.9+/-6.3% compared with 10.0+/-2.1% in control) and apoptosis (TUNEL assay, 21.6+/-1.6% compared with 5.6+/-0.6% in control) in CC were increased (P<0.05) at 44h of maturation. In conclusion, heat shock (42 degrees C for 1h) during IVM induced DNA damage and apoptosis of porcine CC; furthermore, apoptotic CC may contribute to maturation failure of oocytes in vitro.     

Ovine cumulus cells estradiol-17Beta production in the presence or absence of oocyte

The objective of the present study was to compare the in vitro production of estradiol-17Beta (E(2)) by cumulus cells in the presence or absence of ovine oocyte. Moreover, the relationship between the concentration of produced estradiol-17Beta and oocyte nuclear maturation was assessed. Ovaries collected from the local abattoir were transported to the laboratory in saline at 30-35 degrees C within 1-3 h after collection. The oocytes of follicles, 2-6 mm in diameter, were recovered by aspiration. The oocytes with evenly granulated cytoplasm and which were surrounded with at least three layers of cumulus cells were selected and subjected to culture in pre-incubated oocyte culture medium (OCM). Before culturing, the selected oocytes were randomly divided into five treatment groups: Group 1, cumulus enclosed oocytes cultured in OCM (Group COCs); Group 2, denuded oocytes cultured in OCM (Group D); Group 3, denuded oocytes co-cultured with a cumulus cell-monolayer in OCM (Group D+M); Group 4, denuded oocytes co-cultured with previously cultured (for 26 h) cumulus cell-monolayer (10(5) cells/ml) in refreshed OCM (Group D+M(26)); Group 5, cumulus cell-monolayer (10(5) cells/ml) cultured in OCM (Group M). After an incubation period (26 h at 38.6 degrees C, 5% CO(2) and 100% humidity), the media were collected and kept at -20 degrees C until hormonal assay. The concentration of E(2) was determined by RIA method. For assessment of nuclear status, the completely denuded oocytes were subjected to DAPI staining. The highest percentage of metaphase II (MII) stage oocytes was observed in Group N (91%) and the lowest percentage was observed in Group D (6%) and Group D+M(26) (6%). The mean production of E(2) was highest and lowest in Group D+M (378.69+/-54.34 pg/ml) and Group D+M(26) (109.15+/-8.24 pg/ml), respectively. The production of E(2) was significantly (P<0.01) higher in Group D+/-M when compared with Groups M and D+/-M(26). Regarding the nuclear maturation, the percentage of MII stage oocytes was significantly (P<0.001) higher in Group COCs compared to the other groups. The results suggest that steroidogenic activity of cumulus cells in in vitro condition can be influenced by the pattern of connection between cumulus cells and the oocyte. Moreover, the nuclear maturation of oocytes is not influenced by the different production levels of E(2).     

Effect of ovary storage and oocyte transport method on maturation rate of horse oocytes

Two experiments were conducted to determine the effects of storage on equine ovaries or isolated oocytes. Ovaries were collected at an abattoir and were maintained at room temperature during collection and transport (3-9h total). After arrival at the laboratory, ovaries were divided into three groups: immediate oocyte collection (control), storage at room temperature overnight (15-18 h) before oocyte collection, or storage at 4 degrees C overnight before oocyte collection. Collected oocytes were cultured in maturation medium for 24h. There was a significant increase in the proportion of oocytes classified as having compact cumuli in the two storage groups when compared with the controls. For oocytes originally having expanded cumuli, the rate of maturation to MII was significantly higher in the control group (72%) than in either storage group, and the maturation rate for oocytes from ovaries stored at room temperature (27%) was significantly higher than that for ovaries stored at 4 degrees C (10%). A similar trend was seen for oocytes originally having compact cumuli (24, 11, and 3% in MI-II for control, room temperature, and cold groups, respectively). In Experiment 2, we evaluated the effect of different packaging systems on the maturation of horse oocytes within a portable incubator. Use of 1 ml of equilibrated maturation medium in a 1 ml glass vial was associated with maturation equivalent to that for standard incubation.     

Susceptibility of bovine germinal vesicle-stage oocytes from antral follicles to direct effects of heat stress in vitro

Delineation of maternal versus direct effects of heat stress in reducing development at the germinal vesicle (GV) stage is challenging, because oocytes spontaneously resume meiosis after removal from antral follicles. The use of S-roscovitine (inhibitor of p34(cdc2)/cyclin B kinase) to hold bovine oocytes at the GV stage without compromising early embryo development was previously validated in our laboratory. The objective of the present study was to assess the direct effects of an elevated temperature commonly seen in heat-stressed dairy cows on cumulus-oocyte complexes (COCs) held at the GV stage using 50 microM S-roscovitine. During roscovitine culture, GV-stage COCs (antral follicle diameter, 3-8 mm) were cultured at 38.5 or 41 degrees C. Thereafter, oocytes were removed from roscovitine medium and allowed to undergo in vitro maturation, fertilization, and culture. Zona pellucida hardening (solubility to 0.5% pronase), nuclear stage (Hoechst 33342), cortical granule type (lens culinaris agglutinin-fluorescein isothiocyanate [FITC]), and early embryo development were evaluated. Culture of GV-stage COCs at 41 degrees C increased the proportion that had type III cortical granules and reduced the proportion that progressed to metaphase II after in vitro maturation. Effects of 41 degrees C on zona pellucida hardening, fertilization (penetration, sperm per oocyte, pronuclear formation, and monospermic and putative embryos), and cleavage of putative zygotes were not noted. However, culture of GV-stage COCs at 41 degrees C for 6 h decreased the proportion of 8- to 16-cell embryos, whereas 41 degrees C for 12 h reduced blastocyst development. In summary, antral follicle COCs are susceptible to direct effects of elevated body temperature, which may account in part for reduced fertility in heat-stressed cows.     

Fundamental cryobiology of rat immature and mature oocytes: hydraulic conductivity in the presence of Me(2)SO, Me(2)SO permeability, and their activation energies

The hydraulic conductivity in the presence of dimethyl sulfoxide Me(2)SO (L(p)(Me(2)SO)), Me(2)SO (P(Me(2)SO)) permeability and reflection coefficient (sigma) of immature (germinal vesicle; GV) and mature (metaphase II; MII) rat oocytes were determined at various temperatures. A temperature controlled micropipette perfusion technique was used to conduct experiments at five different temperatures (30, 20, 10, 4, and -3 degrees C). Kedem and Katchalsky membrane transport theory was used to describe the cell volume kinetics. The cell volumetric changes of oocytes were calculated from the measurement of two oocyte diameters, assuming a spherical shape. The activation energies (E(a)) of L(p)(Me(2)SO) and P(Me(2)SO) were calculated using the Arrhenius equation. Activation energies of L(p)(Me(2)SO) for GV and MII oocytes were 34.30 Kcal/mol and 16.29 Kcal/mol, respectively; while the corresponding E(a)s of P(Me(2)SO) were 19.87 Kcal/mol and 21.85 Kcal/mol, respectively. These permeability parameters were then used to calculate cell water loss in rat oocytes during cooling at subzero temperatures. Based on these values, the predicted optimal cooling rate required to maintain extra- and intracellular water in near equilibrium for rat GV stage oocytes was found to be between 0.05 degrees C/min and 0. 025; while for rat MII oocytes, the corresponding cooling rate was 1 degrees C/min. These data suggest that standard cooling rates used for mouse oocytes (e.g., 0.5-1 degrees C/min) can also be employed to cryopreserve rat MII oocytes. However, the corresponding cooling rate required to avoid damage must be significantly slower for the GV stage rat oocyte. J. Exp. Zool. 286:523-533, 2000.     

Effects of cooling on meiotic spindle structure and chromosome alignment within in vitro matured porcine oocytes

Meiotic spindle structure and chromosome alignment were examined after porcine oocytes were cooled at metaphase II (M II) stage. Cumulus-oocyte complexes (COCs) collected from medium size follicles were cultured in an oocyte maturation medium at 39 degrees C, 5% CO(2) in air for 44 hr. At the end of culture, oocytes were removed from cumulus cells and cooled to 24 or 4 degrees C for 5, 30, or 120 min in a solution with or without 1.5 M dimethyl sulfoxide (DMSO). After being cooled, oocytes were either fixed immediately for examination of the meiotic spindle and chromosome alignment or returned to maturation medium at 39 degrees C for 2 hr for examination of spindle recovery. Most oocytes (65-71%) cooled to 24 degrees C showed partially depolymerized spindles but 81-92% of oocytes cooled at 4 degrees C did not have a spindle after cooling for 120 min. Quicker disassembly of spindles in the oocytes was observed at 4 degrees C than at 24 degrees C. Cooling also induced chromosome abnormality, which was indicated by dispersed chromosomes in the cytoplasm. Limited spindle recovery was observed in the oocytes cooled to both 4 and 24 degrees C regardless of cooling time. The effect of cooling on the spindle organization and chromosome alignment was not influenced by the presence of DMSO. These results indicate that the meiotic spindles in porcine M II oocytes are very sensitive to a drop in the temperature. Both spindle and chromosomes were damaged during cooling, and such damage was not reversible by incubating the oocytes after they had been cooled.     

Transport of equine ovaries for assisted reproduction

Use of assisted reproduction to obtain foals from valuable mares post-mortem typically necessitates holding of ovaries during shipment to a laboratory. The present study evaluated whether holding ovaries briefly at a warm ( approximately 30 degrees C) temperature improves meiotic and developmental competence of oocytes, as determined after maturation in vitro and intracytoplasmic sperm injection. Ovaries were packaged in pairs in insulated containers, and held either at 24 or 25-35 degrees C for 4h, followed by cooling. Ovaries in both treatments were held for either a short (mean, 7-7.4h) or long (mean, 20.6-20.7h) duration before oocyte recovery. Control ovaries were collected en masse at the abattoir. The ovary temperature in this treatment slowly decreased to approximately 27 degrees C; oocyte recovery was performed after 3.5-7h total holding. There was no effect of temperature on oocyte meiotic or developmental competence within either treatment time period. Oocytes in the short duration holding group had similar meiotic competence to controls, but had a significantly decreased rate (P<0.05) of blastocyst development. Oocytes in the long duration holding group had decreased (P<0.05) meiotic competence and blastocyst development compared to controls. These findings indicate that storage of equine ovaries for only 7h may decrease blastocyst development, and that longer storage reduces both rate of oocyte maturation and blastocyst development. Further work is needed to determine if there is a critical time before 7h post-mortem by which equine oocytes should be recovered to maximize developmental competence.     

Sphingosine 1-phosphate protects bovine oocytes from heat shock during maturation

Sphingosine 1-phosphate (S1P) is a sphingolipid metabolite that can block apoptosis by counteracting the proapoptotic effects of ceramide. Experiments were performed to evaluate whether S1P blocks the disruption in oocyte developmental competence caused by heat shock. Cumulus-oocyte complexes (COCs) were placed in maturation medium and cultured at 38.5 or 41 degrees C for the first 12 h of maturation. Incubation during the last 10 h of maturation, fertilization, and embryonic development were performed at 38.5 degrees C. Heat shock during the first 12 h of maturation reduced cleavage rate, the number of oocytes developing to the blastocyst stage, and the percentage of cleaved embryo that subsequently developed to blastocysts. Addition of 50 nM S1P to maturation medium had no effect on oocytes matured at 38.5 degrees C but blocked effects of thermal stress on cleavage and subsequent development. The blastocysts formed at Day 8 did not differ between S1P and control groups in caspase activity, total cell number, or percentage of cells that were apoptotic. Blocking endogenous generation of S1P by addition of 50 nM N1N-dimethylsphingosine, a sphingosine kinase inhibitor, reduced or tended to reduce cleavage rate and blastocyst development regardless of whether maturation of COCs was at 38.5 or 41 degrees C. Results demonstrate that S1P protects oocytes from a physiologically relevant heat shock and affects oocyte maturation even in the absence of heat shock. The S1P-treated oocytes that survived heat shock and became blastocysts had a normal developmental potential as determined by caspase activity, total cell number, and percentage of apoptotic cells. Thus, modulation of developmental competence of oocytes using S1P may be a useful approach for enhancing fertility in situations where developmental competence of oocytes is compromised.