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.

Asymmetric cell divisions play crucial roles during ascidian embryogenesis. In these processes, an FGF signaling is an essential inductive signal for establishing cell fate polarization, such as mesenchyme and notochord. It was well reported that the FGF signaling cascade is composed of FGF, FGF receptor, Ras, MEK, Erk and Ets. However, mechanisms of communication between the FGF and other signaling pathways and of integrated regulation of signaling pathways have remained largely unknown. In this study, we isolated HrS6K, a homologue of the S6K gene that belongs to the S6-H1 kinase of the ribosomal S6 kinase family, and HrNck1, a homologue of Nck1 gene that encodes an adaptor protein containing Src homology 2 and 3 domains, from the ascidian Halocynthia roretzi, to elucidate the mechanisms. Zygotic expression of HrS6K was initiated as early as the 16-cell stage. In the 64-cell stage embryos, expression of HrS6K was seen in mesenchyme precursor cells. The signal was detected in dorsal midline cells and mesenchyme clusters of the early tailbud embryos, and then down-regulated by the late tailbud stage. In adults, HrS6K mRNA was highly detected in muscle and stomach by QPCR method. On the other hand, HrNck1 transcripts are detected maternally. Zygotic HrNck1 mRNA was strongly expressed in mesenchyme clusters of the neurula, and in tail tip cells of the early tailbud embryos. These results suggest that HrS6K and HrNck1 are involved in formation of mesenchyme cells, which are specified by the FGF signaling.