94 EFFICIENT BOVINE EMBRYO SPLITTING FOR GENE EXPRESSION AND IN VIVO DEVELOPMENT STUDIES

Abstract

It is known that embryos produced in vitro are less competent than their in vivo-derived counterparts. When embryos are produced or manipulated in vitro, their developmental potential decreases significantly, which impinges upon the production of viable offspring. In bovines, embryos that will be transferred to a surrogate mother are selected at the blastocysts stage using noninvasive methods, such as their morphological features. However, many of those embryos are not able to implant or to maintain a normal pregnancy because embryo morphology does not reflect its developmental potential and a correct gene expression pattern that support a normal development. It seems that the ideal method for embryo selection would be based on the screening of gene markers that correlate with successful pregnancy after embryo transfer. In that sense, we have proposed an approach to characterise gene expression pattern of early (Day 7) bovine blastocysts and to correlate this gene expression with further developmental potential in vivo, i.e. upon elongation until Day 17. For that, it was established an efficient method to produce identical and viable hemi-embryos by splitting IVF bovine blastocysts in order to set the expression profile of certain genes in one hemi-embryo at blastocyst stage, while the counterpart embryo elongates in vivo for 10 days. A total of 129 blastocysts were split. Six groups of blastocysts were used for splitting and the results compared: 1) Day-7 early blastocysts (n = 20); 2) Day-7 expanded blastocysts (n = 25); 3) Day-7 hatched blastocysts (n = 17); 4) Day-8 early blastocysts (n = 10); 5) Day-8 expanded blastocysts (n = 12); and 6) Day-8 hatched blastocysts (n = 45). Hemi-embryos derived from day-8 grade I and well expanded blastocysts had the greatest survival rate, in vitro re-expansion (67.7%; P < 0.05) and both hemi-embryos conserved a normal morphology with a total cell number over 80 after 6 h in culture. Also both hemi-embryos at blastocyst stage showed homogeneous expression pattern of the genes OCT4, SOX2, NANOG, CDX2, ACTB, and GAPDH (P < 0.05). Finally, the in vivo survival of hemi-embryos was assessed and compared with nonsplit embryos (control) by transferring to recipient cow and collecting at Day 17 of development. For this, hemi-embryos derived from Day-8 hatched blastocyst were used. From 14 transferred hemi-embryos, 5 (35.7%) were collected, and 9 elongated from 17 controls were recovered (52.9%). Also the elongation rate was significantly lower in hemi-embryos than in control; the length of hemi-embryos had a range between 1 and 5 cm, whereas 60% of the control embryos were longer than 10 cm. Our results provide an initial approach to study the correlation among the gene expression characteristics of early bovine embryos with their further development. However, it seems that embryo splitting hampers their elongation in vivo. It might be possible that the development of split embryos is retarded because of manipulation.

This work was partially supported by Fondecyt grant no. 11100082 from the Ministry of Education of Chile.