Kassens Ana, Held Eva, Salilew-Wondim Dessie, Sieme Harald, Wrenzycki Christine, Tesfaye Dawit, Schellander Karl, Hoelker Michael
Unit for Reproductive Medicine, Clinic for Horses, University of Veterinary Medicine Hannover, Hannover, Germany.
Institute of Animal Science, Animal Breeding and Husbandry Group, University of Bonn, Bonn, Germany.
Biol Reprod. 2015 Jun;92(6):150. doi: 10.1095/biolreprod.114.124883. Epub 2015 Apr 29.
There are still major differences between in vitro production (IVP)-derived and in vivo-derived bovine blastocysts. Therefore, intrafollicular oocyte transfer (IFOT) was used in the present study to allow early embryonic development within the physiological oviductal environment, in order to avoid subsequent harmful effects of the in vitro culture environment. Using modified ovum pickup equipment, in vitro-matured oocytes were transferred into the preovulatory follicle of synchronized heifers (follicular recipients), enabling subsequent ovulation, in vivo fertilization, and in vivo development. When 1646 in vitro-matured oocytes were transferred to 28 follicular recipients, a total of 583 embryos (35.2%) were recovered in excess after uterine flushing at Day 7. Although numbers of generated extra embryos were highly variable, preovulatory follicles with a diameter of 13-14 mm delivered significantly (P < 0.05) larger amounts of extra embryos (34.3 vs. 7.3), as well as extra morulae and blastocysts (8.3 vs. 0.8), compared with follicles with a diameter of 9-10 mm. Nevertheless, the developmental rate to the blastocyst stage was lower in IFOT compared with in vitro-derived control (Vitro) embryos at Day 7 (8.0% vs. 36.5%). Likewise, cumulative developmental rates to the morula or blastocyst stage until Day 7 were lower in IFOT-derived embryos when related to the number of transferred (8.4% vs. 51.7%) or flushed (22.8% vs. 51.7%) embryos. Of the latter, IFOT-derived embryos yielded significantly lower cleavage rates compared with the Vitro controls (63.2% vs. 88.8%), and developmental rate to the morula or blastocyst stage were lower even when related to the proportion of cleaved embryos (36.8% vs. 58.2%). In contrast, lipid content and cryotolerance did not differ between IFOT and fully IVP embryos; but IFOT-derived embryos showed significantly lower lipid content (P < 0.05) and significantly higher cryotolerance compared with IVP-derived embryos cultured in CR1aa medium supplemented with estrus cow serum (ECS), but not when cultured in SOFaa medium supplemented with fatty acid-free BSA (BSA-FFA). Finally, transfer of 19 frozen-thawed IFOT-derived blastocysts to synchronized recipients (uterine recipients) resulted in pregnancy rates comparable with those obtained after transfer of fully in vivo-derived embryos or IVP-derived embryos cultured in SOFaa + BSA-FFA, whereas pregnancy rate following transfer of IVP-derived blastocysts was significantly lower when they were cultured in CR1aa + ECS (42.1% vs. 13.8%). All in all, seven pregnancies presumed to be IFOT derived went to term, and microsatellite analysis confirmed that five calves were indeed derived from IFOT. To our knowledge, these are the first calves born after IFOT in cattle. Interestingly, the average birth weight of IFOT-derived calves was lower than that of IVP-derived calves, even when embryos were cultured in SOFaa + BSA-FFA, indicating that the environment during early embryo development might cause fetal overgrowth. Taken together, for the first time we were able to show that IFOT is a feasible technique to generate bovine blastocysts by transferring in vitro-matured oocytes derived from slaughterhouse ovaries. These IFOT-derived blastocysts closely resemble in vivo-derived blastocysts in terms of lipid content and freeze survival. Thus, the present study laid the groundwork for newly created scientific experiments enabling novel analytical possibilities. Nevertheless, IFOT-derived embryos still reached lower pregnancy rates by trend compared with in vivo-derived embryos, also implicating an important role for the maturational environment in further developmental characteristics.
体外生产(IVP)的牛囊胚与体内来源的牛囊胚之间仍存在重大差异。因此,本研究采用卵泡内卵母细胞移植(IFOT)技术,使胚胎在生理输卵管环境中进行早期发育,以避免体外培养环境的后续有害影响。使用改良的采卵设备,将体外成熟的卵母细胞移植到同步发情的小母牛(卵泡受体)的排卵前卵泡中,使其随后排卵、体内受精和体内发育。当将1646个体外成熟的卵母细胞移植到28个卵泡受体中时,在第7天进行子宫冲洗后,共回收了583个多余胚胎(35.2%)。尽管产生的额外胚胎数量差异很大,但直径为13 - 14毫米的排卵前卵泡产生的额外胚胎数量显著(P < 0.05)更多(34.3个对7.3个),以及额外的桑葚胚和囊胚数量也更多(8.3个对0.8个),相比之下,直径为9 - 10毫米的卵泡。然而,与第7天的体外来源对照(体外培养)胚胎相比,IFOT胚胎发育到囊胚阶段的比率较低(8.0%对36.5%)。同样,与移植(8.4%对51.7%)或冲洗(22.8%对51.7%)胚胎数量相关时,IFOT来源胚胎直到第7天发育到桑葚胚或囊胚阶段的累积比率较低。在后者中,与体外培养对照相比,IFOT来源胚胎的分裂率显著较低(63.2%对88.8%),即使与分裂胚胎的比例相关时,发育到桑葚胚或囊胚阶段的比率也较低(36.8%对58.2%)。相比之下,IFOT胚胎和完全IVP胚胎的脂质含量和耐冻性没有差异;但是与在补充有发情母牛血清(ECS)的CR1aa培养基中培养的IVP来源胚胎相比,IFOT来源胚胎的脂质含量显著较低(P < 0.05)且耐冻性显著较高,但在补充有无脂肪酸牛血清白蛋白(BSA - FFA)的SOFaa培养基中培养时则没有差异。最后,将19个冷冻解冻的IFOT来源囊胚移植到同步受体(子宫受体)中,其妊娠率与移植完全体内来源胚胎或在SOFaa + BSA - FFA中培养的IVP来源胚胎后获得的妊娠率相当,而在CR1aa + ECS中培养的IVP来源囊胚移植后的妊娠率显著较低(42.1%对13.8%)。总而言之,七头推测为IFOT来源的妊娠足月分娩,微卫星分析证实五头小牛确实来自IFOT。据我们所知,这些是牛IFOT后出生的首批小牛。有趣的是,即使胚胎在SOFaa + BSA - FFA中培养,IFOT来源小牛的平均出生体重也低于IVP来源小牛,这表明早期胚胎发育期间的环境可能导致胎儿过度生长。综上所述,我们首次能够证明IFOT是一种可行的技术,通过移植来自屠宰场卵巢的体外成熟卵母细胞来产生牛囊胚。这些IFOT来源的囊胚在脂质含量和冷冻存活率方面与体内来源的囊胚非常相似。因此,本研究为新的科学实验奠定了基础,开启了新的分析可能性。然而,IFOT来源的胚胎与体内来源的胚胎相比,妊娠率仍有降低的趋势,这也暗示了成熟环境在进一步发育特征中的重要作用。
