Direct cleavage during the first mitosis is a sign of abnormal fertilization in cattle.

Direct cleavage, a type of abnormal cleavage in which one zygote divides into three or more blastomeres, has been reported in mammals. The incidence of direct cleavage increases in zygotes with three or more pronuclei (multi-PN) and those showing abnormal pronuclei migration. However, there are few reports on the relationship between pronuclei and direct cleavage, and the effects of these relationships on subsequent embryogenesis have not been clarified. It is difficult to observe pronuclei under visible light, especially in bovine zygotes, because of abundant dark lipid droplets in the cytoplasm. We visualized pronuclei by removing lipid droplets from bovine zygotes and analyzed the relationship between the number of pronuclei and direct cleavage using time-lapse cinematography. The direct cleavage rate of multi-PN zygotes was 78.6%, which was significantly higher than that of zygotes with one pronucleus (1 PN, 0.0%) and two pronuclei (2 PN, 8.2%). Observation of pronuclei migration in 2 PN zygotes showed that 3.1% of 2 PN zygotes had non-apposed pronuclei. The direct cleavage rate of zygotes with non-apposed pronuclei was 66.7%, which was significantly higher than that of zygotes with apposed pronuclei (6.4%). Among multi-PN zygotes, the proportions of zygotes with apposed pronuclei and non-apposed pronuclei were 37.5% and 64.3%, respectively. The direct cleavage rate of multi-PN zygotes with non-apposed pronuclei was 100.0%, which was significantly higher than that of zygotes with apposed pronuclei (40.0%). Three-dimensional live-cell imaging of bovine zygotes injected with the mRNA-encoding histone H2B-mCherry showed that the direct cleavage rates of 2 PN and multi-PN zygotes bypassing syngamy were 63.2% and 75.5%, respectively. These rates were significantly higher than that of 2 PN and multi-PN zygotes that underwent syngamy (5.6% and 20.0%, respectively). Regardless of the number of pronuclei, a high frequency of direct cleavage was observed in zygotes in which the pronuclei did not migrate inward the cytoplasm and bypassed syngamy. These results suggest that abnormal fertilization such as multi-PN and migration error of pronuclei in cattle is the primary reason for direct cleavage during the first mitosis. Assessment of direct cleavage during the first mitosis allows exclusion of embryos with abnormal fertilization and may contribute to in vitro produced embryo transfer success.

Micronucleus formation during early cleavage division is a potential hallmark of preimplantation embryonic loss in cattle.

In assisted reproductive technology (ART)-derived embryos of non-rodent mammals, including humans and cattle, chromosome segregation errors are highly likely to occur during early cleavage division, resulting in aneuploidy, including mosaicism. However, the relationship between chromosomal segregation errors during early cleavage and subsequent embryonic development has not been detailed in these mammals. In the present study, we developed non-invasive live-cell imaging of chromosome segregation dynamics using a histone H2B-mCherry mRNA probe in bovine preimplantation embryos. Chromosome segregation errors in early cleavage affected blastocyst formation. Especially, embryos that underwent abnormal chromosome segregation (ACS) with multiple or large micronucleus formation rarely developed into blastocysts. Embryos with the severe ACS had prolonged cell cycle duration. After transfer of blastocysts with live-cell imaging of chromosome segregation to ten cows, six became pregnant and four of them gave full-term offspring. Interestingly, two of them were derived from blastocysts with ACS. Hence, chromosomal segregation errors with micronucleus formation during early cleavage can be a fatal hallmark of preimplantation embryogenesis in cattle. This technique has shown potential for understanding the relationship between chromosome segregation error and subsequent embryo development, and for selecting viable ART-derived embryos for medical and livestock production.

Expression levels of FSHR, IGF1R, CYP11al and HSD3ß in cumulus cells can predict in vitro developmental competence of bovine oocytes.

The efficiency of in vitro embryo production technologies would be improved by the development of suitable non-invasive biomarkers that allow the selection of good quality cumulus-oocyte complexes (COCs). The present study used whole, single oocyte culture to investigate whether the expression levels of follicle-stimulating hormone receptor (FSHR), insulin-like factor 1 receptor (IGF1R) and three steroidogenesis-related enzymes (CYP11al, CYP19al and HSD3ß) in cumulus cells reflected the developmental competence of COCs. Cumulus cells were collected from single COCs before maturation culture and relative mRNA levels were assessed using real-time PCR. The analysis indicated that mRNAs for FSHR, IGF1R, CYP11al and HSD3ß were present at higher levels in cumulus cells from COCs that failed to form blastocysts compared with cumulus cells from COCs that formed blastocysts. Moreover, FSHR and IGF1R mRNA levels were positively correlated with those of genes for steroidogenesis-related enzymes. In conclusion, poor developmental competence of COCs was related to higher expression of FSHR, IGF1R, CYP11al and HSD3ß in cumulus cells, which may indicate the advanced differentiation of cumulus cells into granulosa cells.

Histochemical properties of bovine and ovine mammary glands during fetal development.

In order to obtain more information on the development of bovine and ovine fetal mammary glands, a series of mammary glands from fetuses of different ages were analyzed. A total of 16 bovine fetuses with curved crown rump lengths ranging from 12 cm (80 days) to 75 cm (240 days) and 15 ovine fetuses ranging from 55 days to 131 days were examined. We used hematoxylin and eosin stain and Oil-Red-O stain to analyze the developmental and morphogenetic processes of mammary glands. In addition, we used immunohistochemical staining to determine the pattern of expression of cytokeratin 18 (CK18) during luminal epithelial differentiation, α-smooth-muscle actin (α-SMA) for myoepithelial differentiation, Ki-67 for cell proliferation, and estrogen receptor α (ERα). Our analyzes showed: (a) The primary mammary duct begin to proliferate in a lengthwise within the teat at 90 days in bovine fetuses and 63 days in ovine fetus; (b) luminal epithelial cells and myoepithelial cells appeared from 90 days in bovine fetuses and 63 days in ovine fetus; (c) proliferation of epithelial cells appeared to coincide with the development of the primary and secondary ducts; and (d) ERα was not found in the fetal mammary gland, but adipocytes showed the presence of ERα. Overall, these results indicate that the sequence of events in the prenatal development of the mammary gland of sheep is similar to that of cattle.