Expression of Cu/Zn and Mn superoxide dismutases during bovine embryo development: influence of in vitro culture.

peer reviewedTemporal pattern of expression of Cu/Zn and Mn superoxide dismutases (SODs) was investigated in bovine oocytes and embryos produced in vitro in two different culture conditions and in vivo after superovulation. SODs were examined at a transcriptional level in single oocytes and embryos by reverse transcriptase-polymerase chain reaction (RT-PCR) and, at a protein level, by Western blotting on pools of embryos. mRNA encoding Cu/Zn SOD were detected in in vitro bovine embryos throughout preattachment development as well as in in vivo derived morulae and blastocysts. Transcripts for Mn SOD gene were detected in most immature and in vitro matured oocytes as well as in some zygotes and 5- to 8-cell embryos while no transcript was found at the 9-to 16-cell stage in both culture conditions. In vitro embryonic expression of Mn SOD was detected earlier in the presence of serum. Half of the morulae showed the transcript if cultured with 5% serum while none without serum. At the blastocyst stage Mn SOD could be detected independently of culture conditions. For in vivo-derived embryos Mn SOD transcripts were detected both in morulae and blastocysts. Immunoblotting analyses revealed that Cu/Zn SOD and Mn SOD were also present at a protein level in in vitro-derived zygotes and blastocysts. Together these data demonstrate, for the first time, that Mn SOD is transcribed and that Cu/Zn and Mn SOD proteins are expressed in preimplantation bovine embryos. Finally, they suggest that Mn SOD transcription is altered by in vitro culture conditions

[Vitrification: An interesting method for cryopreservation of mammalian embryos]

The author first exposes the theoretical concept of vitrification before giving the conditions required to formulate the composition of an adequate vitrification solution. These conditions are : -the choice of the cryoprotectant (non toxic), its concentration, the addition or not of a macromolecule like Ficoll, PVP, to facilitate vitrification and/or a sugar like sucrose; -the time and temperature of exposure to the vitrification solution as well as the dilution procedure after thawing to minimize osmotic and toxic stress. Then he presents in a serie of tables, a summary of the results of vitrification of oocytes and embryos of laboratory and domestic animal species and he mentions some parameters influencing the results such as the species, the stage of development, the origin of the embryos. He concludes that vitrification seems to be an interesting method for cryopreservation of gametes and embryos

La vitrification: une méthode de cryopréservation intéressante pour l'embryon de mammifère.

The author first exposes the theoretical concept of vitrification before giving the conditions required to formulate the composition of an adequate vitrification solution. These conditions are: -the choice of the cryoprotectant (non toxic), its concentration, the addition or not of a macromolecule like Ficoll, PVP, to facilitate vitrification and/or a sugar like sucrose; -the time and temperature of exposure to the vitrification solution as well as the dilution procedure after thawing to minimize osmotic and toxic stress. Then he presents in a series of tables, a summary of the results of vitrification of oocytes and embryos of laboratory and domestic animal species and he mentions some parameters influencing the results such as the species, the stage of development, the origin of the embryos. He concludes that vitrification seems to be an interesting method for cryopreservation of gametes and embryos

Cryopreservation of embryos of farm animals.

This review contains two parts. The first part is devoted to the significant steps in cryopreservation of mammalian embryos with emphasis on cattle and sheep that serve as models of reference. These steps are: (1) shortening of cooling and warming processes; (2) addition and dilution of cryoprotectant in one step; (3) introduction of plastic straw as a freezing and dilution container; (4) the choice of ethylene glycol as the quite universal cryoprotectant because of its low toxicity and high permeability; (5) vitrification, a cryopreservation method which enable passage from the liquid to the solid state by extreme elevation of viscosity due to high concentration of cryoprotectants and very rapid cooling. There are several vitrification solutions which contain dimethyl sulphoxide, glycerol, ethylene glycol, or a mixture of them, as basic cryoprotectants. The second part considers some factors affecting the efficiency of cryopreservation concerning (i) the origin of embryos and (ii) the stage of development and species. The origin of embryos (in vivo versus in vitro): in vitro embryos show a chilling and freezing sensitivity associated with their lipid content which can be modified by the culture conditions. Both conventional freezing and vitrification have been used and it seems that vitrification is more adapted to in vitro embryos when some modifications of initial protocols are carried out, particularly the rate of cooling. Thus considerable progress has been achieved by using the open pulled straw method of Vajta which enables the use of a minimum volume of freezing medium (0.5 microl) and a very high cooling rate that permits rapid traversal of the damaging temperature zone, corresponding to chilling sensitivity. The stage of development and species: not only are there differences between species at the same stage of development but in the same species all stages of development do not survive equally under the same freezing protocol. In cattle for example, oocytes and early stages of development in vivo or in vitro do not survive whereas compacted morulae and blastocysts survive very well. In the pig hatched blastocysts survive better than the other stages. Horse embryos have special characteristics that pose problems for successful freezing. In conclusion, a lot of work remains to be done to define fundamental characteristics of embryos of certain species (pig, horse) and of embryos of some stages or of oocytes

Cryopreservation of bovine oocytes: current status and recent developments.

The cryopreservation of oocytes of most animal species remains a challenge due to their complex structure. Equilibrium freezing is not satisfactory because oocytes seem to be damaged by exposure for several minutes to temperatures near 0 degrees C. Therefore, cryopreservation of oocytes by vitrification--especially the use of very high cooling rates of oocytes suspended in extremely small volumes of various cryoprotective additive modifications--seems the most appropriate method

Cryopreservation of cattle oocytes: effects of meiotic stage, cycloheximide treatment, and vitrification procedure.

Different parameters likely to influence the survival of bovine oocytes after a vitrification procedure were evaluated: oocyte meiotic stage, cycloheximide treatment at the beginning or the end of maturation, and three vitrification procedures using conventional straws, open pulled straws (OPS), or microdrops. For each procedure a mixture of cryoprotectants (25% ethylene glycol and 25% glycerol) was used. After the oocytes were warmed and subjected to in vitro maturation and fertilization, the number that developed into blastocysts was determined. Results show that cryoprotectant exposure reduced embryo development and that cycloheximide treatment had no beneficial effect on oocytes vitrified in conventional straws. Among the three vitrification procedures, only the OPS method yielded blastocysts (approximately 3% of vitrified oocytes) irrespective of their initial meiotic stage. This result highlights the major influence of the cooling rate in an oocyte vitrification protocol

Morphology and biochemistry of in-vitro produced bovine embryos: implications for their cryopreservation.

Examination of some ultrastructural and physiological characteristics of in-vitro produced bovine embryos may help to explain why such embryos are more sensitive to freezing than their in-vivo derived counterparts. Improvement of embryo survival after freezing can be achieved by changing the conditions of their culture, selection of embryos based on the kinetics of their development, and changing "standard' freezing procedures. Cryopreservation of embryos by vitrification, in particular, seems to yield higher survival than conventional slow freezing. Further development of protocols requires additional embryo transfer studies to ensure that the ability of thawed embryos to develop normally in vivo correlates strongly with in-vitro survival assays

Cell cycle duration at the time of maternal zygotic transition for in vitro produced bovine embryos: effect of oxygen tension and transcription inhibition.

Early embryonic cleavages are mostly regulated by maternal components then control of development progressively depends on newly synthesized zygotic products. The timing of the first cleavages is a way to assess embryo quality. The goal of this study was to evaluate the duration of the fourth cell cycle, at the time of maternal-to-zygotic transition (MZT) in in vitro-produced bovine embryos by means of cinematographic analysis. We found that 75% of the embryos displayed a long fourth cycle (43.5 +/- 5.4 h) whereas the remaining embryos had a very short fourth cell cycle (8.9 +/- 2.9 h). Both groups did not differ in cleavage rhythm up to the eight-cell stage and timing of cavitation and blastocyst expansion was identical. However, embryos with a short fourth cell cycle had a better blastocyst rate than embryos with a long cycle (59% versus 38%, P < 0.01). Total cell number, inner cell mass (ICM):total cell ratio, and hatching rate were identical for blastocysts produced from embryos with either a long or a short fourth cell cycle. In a second experiment, we showed that increasing the oxygen tension, from 5% to 20%, decreased the percentage of embryos with a short fourth cell cycle, from 25% to 11% (P < 0.01), indicating that suboptimal culture conditions can influence the length of this cycle. Finally, we investigated whether fourth cell cycle duration could be influenced by transcription inhibition. With alpha-amanitin added at 18 h postinsemination (HPI), cleavage was reduced (66% versus 79%) and, at 70 HPI, the 9- to 16-cell rate increased (50% versus 25%) concomitantly with a 5- to 8-cell rate decrease (16% versus 47%). A similar pattern was observed when the drug was added at 6 HPI or 42 HPI but not at 0 HPI. Cinematographic analysis revealed that alpha-amanitin increased the first cell cycle duration whereas the second and third cell cycles were not affected. With the drug, one third of the embryos could develop up to the 9- to 16-cell stage and they all had a short fourth cell cycle (11.2 +/- 3.7 h) with a good synchrony of cleavage between blastomeres. These results suggest that duration of the fourth cell cycle of bovine embryo, during the MZT, is under a zygotic transcriptional control that can be affected by oxidative conditions

Cinematographic analysis of bovine embryo development in serum-free oviduct-conditioned medium.

Development of bovine embryos produced in vitro from the one-cell to the blastocyst stage in serum-free oviduct-conditioned medium was investigated for 8 days consecutively by time-lapse cinematography. Three movies were analysed (130 embryos). The following observations were made. (1) Development under cine-recording conditions was similar to that in a classical incubator. (2) The highest proportion of embryos at the two-cell, three-four-cell, five-eight-cell, 9-16-cell, morula and blastocyst stages were recorded at 34, 46, 61, 115, 149 and 192 h after insemination, respectively. Cleavage asynchrony between blastomeres within individual embryos started at the two-cell stage. (3) The duration of the first three cell cycles was 35 h, 14 h and 11-62 h, respectively. (4) Detailed analysis of 13 embryos revealed that developmental arrest ('Lag-phase') occurred at the four-cell (1 of 13), five-cell (2 of 13), six-cell (3 of 13), seven-cell (3 of 13) or eight-cell stage (4 of 13); this phase lasted about 59 h. Embryos arrested at the eight-cell stage developed into morula-blastocysts (3 of 4) at a higher rate than did those arrested at earlier stages (2 of 9). (5) The faster the embryos cleaved into early stages (two-cell, three-four-cell and five-eight-cell), the higher the probability that they developed into morula-blastocyst: 70% of the embryos reaching the two-cell stage before 30-31 h after insemination developed into morula-blastocyst.(ABSTRACT TRUNCATED AT 250 WORDS