This experiment was to investigate whether the mitochondria function assessment can be used for the prediction of sperm fertility through examining the correlation between mitochondria fluoromicroscopic frequency of frozen-thawed eight Hanwoo bull semen using rhodamine123 (R123) and in vitro embryo development following fertilization. Individual sperm were stained in 5ug/mL R123-added calcium-free Sp-TALP for 30 min at 0 h, 6 h, 12 h and 24 h after thawing and examined their mid-piece under an epifluorescence microscope using 495 nm excitation filter (x1,000). Three replications were taken, and at least 300 sperm per individual were examined. When semen samples were separated into two groups (good and poor) by sperm motility and fluorescent frequencies at just after thawing, average fluorescent frequencies were remarkably reduced as time going (0 h; 53.29~72.94%, 6 h; 21.40~58.90%, 12 h; 8.26~25.93%, 24 h; 1.00~13.78%, irrespective of selected group, and there were no differences at 6 h or 12 h after thawing between selected groups but indicated significant difference at 24 h after thawing (p<0.05). In vitro fertilization rates in good and poor groups ranging 70.8~77.8% and 52.1~84.5%, respectively, were not significantly different. However, in vitro development rates of the same groups ranging 25.7~40.0% and 12.9~1.8%, respectively, were significant different (p<0.05). These results demonstrate that mitochondria fluoromicroscopic assessment of frozen-thawed bovine sperm may be used as a criterion to select more fertile sperm.

Ascidian embryos have become an important model for embryological studies, offering a simple example for mechanisms of cytoplasmic components segregation. It is a well-known example that the asymmetric segregation of mitochondria into muscle lineage cells occurs during ascidian embryogenesis. However, it is still unclear which signaling pathway is involved in this process. To obtain molecular markers for studying mechanisms involved in the asymmetric distribution of mitochondria, we have produced monoclonal antibodies, Mito-1, Mito-2 and Mito-3, that specifically recognize mitochondriarich cytoplasm in cells of the ascidian Halocynthia roretzi embryos. These antibodies stained cytoplasm like reticular structure in epidermis cells, except for nuclei, at the early tailbud stage. Similar pattern was observed in vital staining of mitochondria with DiOC2, a fluorescent probe of mitochondria. Immunostaining with these antibodies showed that mitochondria are evenly distributed in the animal hemisphere blastomeres at cleavage stages, whereas not in the vegetal hemisphere blastomeres. Mitochondria were transferred to the presumptive muscle and nerve cord lineage cells of the marginal zone in the vegetal hemisphere more than to the presumptive mesenchyme, notochord and endoderm lineage of the central zone. Therefore, it is suggested that these antibodies will be useful markers for studying mechanisms involved in the polarized distribution of mitochondria during ascidian embryogenesis.

Ascidian embryos have become an important model for embryological studies, offering a simple example for mechanisms of cytoplasmic components segregation. It is a well-known example that segregation of mitochondria into muscle lineage cells occurs during ascidian embryogenesis. It is, however, still unclear what signaling and molecular event control polarized distribution of mitochondria in the early ascidian embryonic development. To obtain molecular markers for studying mechanisms involved in polarized distribution of mitochondria, we have produced monoclonal antibodies, Mito-1, Mito-2 and Mito-3, that specifically recognize mitochondria-rich cytoplasm in all cells of the ascidian Halocynthia roretzi embryos. These antibodies stained cytoplasm like a mesh structure in epidermis cells, except for nuclei, at the early tailbud stage. Similar pattern was observed in vital staining of mitochondria with DiOC2, a fluorescent probe of mitochondria. These antibodies showed that mitochondria were distributed evenly in the animal hemisphere blastomeres at cleavage stages, whereas did not in the vegetal hemisphere blastomeres. Mitochondria were transferred more into cells of the marginal zone, such as muscle and nerve cord lineage cells, than into cells of the central zone, such as mesenchyme, notochord and endoderm lineage, in the vegetal hemisphere. Therefore, it is suggested that these antibodies may be useful as markers for analysing mechanisms involved in polarized distribution of mitochondria during ascidian embryogenesis.

In animal development, the mechanisms by which localized factors and organelles in egg cytoplasm were exactly distributed into each daughter cell are essential for formation of various cell types. During ascidian Halocynthia roretzi embryogenesis, ooplasmic mitochondria were mainly segregated into muscle and neural precursor cells. At the 32-cell stage, localized mitochondria in the B6.2 blastomeres were preferentially distributed into the B7.4 muscle precursors compared with the B7.3 mesenchyme/ notochord precursors. When the B6.2 blastomeres were isolated from the early 32-cell stage embryos and then allowed to divide 2 times of cell division, the resultant partial embryos showed symmetric distribution of mitochondria, and the partial embryos were composed of equal size cells. In normal development, cell fates of the B7.3 blastomere were correlated with the unequal cleavage of B6.2 lineage cells that normally occurs in the next two-cell division stages to produce a large B8.5 mesenchyme and a small B8.6 notochord cell. Mitochondria are distributed asymmetrically in both cells. When embryos were treated with FGF receptor inhibitor SU5402 and MEK inhibitor U0126 between the 32-cell and the early 64-cell stages, the resultant embryos showed equal cleavage pattern and symmetric distribution of mitochondria in daughter cells of the B6.2 blastomeres. However, blocking of Nodal and Notch signaling did not affect the cell division pattern and mitochondrial distribution in the B6.2 lineage blastomeres between the 32-cell and 110-cell stages. Therefore, it is likely that FGF/MEK signaling is involved in asymmetric distribution of mitochondria and unequal cleavage of the B6.2 lineage blastomeres in ascidian embryo.

The mechanisms by which embryo exactly distributes mitochondria into the blastomeres during embryogenesis are one of the important issues in developmental biology. Although the mechanisms has been thought to be important for the proper embryonic development, our understanding has remained limited. In the present study, the distribution of mitochondria was examined in embryos of the ascidian, Halocynthia roretzi, by immunohistochemical staining with three-types of the mitochondria-specific antibodies and vital staining of mitochondria with a fluorescent probe, DiOC2(3). Results of the immunohistochemical staining coincided with that of vital staining, which is able to detect the distribution of mitochondria in cytoplasm of the embryo. Mitochondria was mainly segregated into the B4.1 posterior-vegetal blastomeres at the 8-cell stage. During the next stages, mitochondria was preferentially partitioned into cells of the B-line muscle and the A-line nerve cord precursor compared with each sister cell, endoderm in the 5th cleavage stage, and mesenchyme and notochord in the 6th cleavage stage. However, the mitochondria-rich cytoplasm is divided equally among the blastomeres of the animal hemisphere between the 8-cell and the 64-cell stages. When B6.2 blastomeres were isolated at the early 32-cell stage embryo and cultured in seawater, until control embryos reached the 64-cell stage, pattern of mitochondria distribution was similar to results of the coisolated B7.3 and B7.4 blastomeres from the 64-cell stage embryos. Therefore, it is likely that mitochondria are asymmetrically segregated into the marginal cells in the vegetal hemisphere of the ascidian embryo without cell-cell interaction.