Despite the increasing interest, buffalo oocyte cryopreservation is still inefficient, especially in terms of blastocyst development after IVF. The aim of this work was to evaluate chromatin and spindle organization of buffalo in vitro-matured oocytes after vitrification/warming by cryotop and after their simple exposure to cryoprotectants (CP). An overall amount of 251 COC was selected and matured in vitro. In the vitrification group, COC were first exposed to 10% ethylene glycol (EG) + 10% DMSO for 3 min, and then to 20% EG + 20% of DMSO and 0.5 m sucrose, loaded on cryotops, and plunged into liquid nitrogen within 25 s. Oocytes were warmed into a 1.25 m sucrose solution for 1 min and then to decreasing concentrations of sucrose (0.625 m, 0.42 m, and 0.31 m) for 30s each. In order to test CP toxicity, COC were simply exposed to the vitrification and warming solutions. Two hours after warming, oocytes were fixed and immunostained for microtubules using a method previously described (Messinger SM and Albertini DF 1991 J. Cell Sci. 100, 289–298), stained for nuclei with Hoechst, and examined by fluorescence microscopy. Fresh in vitro-matured oocytes were fixed and stained as controls. Data were analyzed by chi-square test; results are shown in Table 1. The percentages of MII oocytes in the control and vitrification groups were greater than in the toxicity group, in which a greater percentage of telophase II stage oocytes were found compared with both the control and vitrification groups, indicating occurrence of activation. Of the MII oocytes, both exposure to CP and vitrification procedures gave greater percentages of oocytes with abnormal spindle and abnormal chromatin configuration compared with the control. An unexpected datum was the evidence of a significant percentage of spontaneously activated oocytes in the toxicity group. We speculate that the lack of activation in the vitrification group may be related to the slowing down of metabolic activity subsequent to thermal shock, and hence, that activation after vitrification may occur later than 2 h post-warming. In conclusion, the simple exposure to CP causes activation of the COC and damage to the cytoskeleton similar to that induced by the whole vitrification protocol. The damages to the meiotic spindle and DNA fragmentation may lead to aneuploidy incompatible with subsequent embryo development and account for the poor embryo development currently recorded in buffalo.

Exposure to ethylene glycol (EG) and dimethyl sulfoxide (DMSO) causes activation and spindle anomalies in buffalo (Bubalus bubalis) oocytes / M., De Blasi; Mariotti, E.; Rubessa, M.; Di Francesco, S.; Campanile, Giuseppe; Zicarelli, Luigi; Gasparrini, Bianca. - In: REPRODUCTION FERTILITY AND DEVELOPMENT. - ISSN 1031-3613. - STAMPA. - 21 (1):(2009), pp. 131-131. [10.1071/RDv21n1Ab62]

Exposure to ethylene glycol (EG) and dimethyl sulfoxide (DMSO) causes activation and spindle anomalies in buffalo (Bubalus bubalis) oocytes

CAMPANILE, GIUSEPPE;ZICARELLI, LUIGI;GASPARRINI, BIANCA
2009

Abstract

Despite the increasing interest, buffalo oocyte cryopreservation is still inefficient, especially in terms of blastocyst development after IVF. The aim of this work was to evaluate chromatin and spindle organization of buffalo in vitro-matured oocytes after vitrification/warming by cryotop and after their simple exposure to cryoprotectants (CP). An overall amount of 251 COC was selected and matured in vitro. In the vitrification group, COC were first exposed to 10% ethylene glycol (EG) + 10% DMSO for 3 min, and then to 20% EG + 20% of DMSO and 0.5 m sucrose, loaded on cryotops, and plunged into liquid nitrogen within 25 s. Oocytes were warmed into a 1.25 m sucrose solution for 1 min and then to decreasing concentrations of sucrose (0.625 m, 0.42 m, and 0.31 m) for 30s each. In order to test CP toxicity, COC were simply exposed to the vitrification and warming solutions. Two hours after warming, oocytes were fixed and immunostained for microtubules using a method previously described (Messinger SM and Albertini DF 1991 J. Cell Sci. 100, 289–298), stained for nuclei with Hoechst, and examined by fluorescence microscopy. Fresh in vitro-matured oocytes were fixed and stained as controls. Data were analyzed by chi-square test; results are shown in Table 1. The percentages of MII oocytes in the control and vitrification groups were greater than in the toxicity group, in which a greater percentage of telophase II stage oocytes were found compared with both the control and vitrification groups, indicating occurrence of activation. Of the MII oocytes, both exposure to CP and vitrification procedures gave greater percentages of oocytes with abnormal spindle and abnormal chromatin configuration compared with the control. An unexpected datum was the evidence of a significant percentage of spontaneously activated oocytes in the toxicity group. We speculate that the lack of activation in the vitrification group may be related to the slowing down of metabolic activity subsequent to thermal shock, and hence, that activation after vitrification may occur later than 2 h post-warming. In conclusion, the simple exposure to CP causes activation of the COC and damage to the cytoskeleton similar to that induced by the whole vitrification protocol. The damages to the meiotic spindle and DNA fragmentation may lead to aneuploidy incompatible with subsequent embryo development and account for the poor embryo development currently recorded in buffalo.
2009
Exposure to ethylene glycol (EG) and dimethyl sulfoxide (DMSO) causes activation and spindle anomalies in buffalo (Bubalus bubalis) oocytes / M., De Blasi; Mariotti, E.; Rubessa, M.; Di Francesco, S.; Campanile, Giuseppe; Zicarelli, Luigi; Gasparrini, Bianca. - In: REPRODUCTION FERTILITY AND DEVELOPMENT. - ISSN 1031-3613. - STAMPA. - 21 (1):(2009), pp. 131-131. [10.1071/RDv21n1Ab62]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11588/334863
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