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.
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.
FGF9/16/20 signaling pathway specify the developmental fates of notochord, mesenchyme, and neural cells in ascidian embryos. Although a conserved Ras/MEK/Erk/Ets pathway is known to be involved in this signaling, the detailed mechanisms of regulation of FGF signaling pathway have remained largely elusive. In this study, we have isolated Hr-Erf, an ascidian orthologue of vertebrate Erf, to elucidate interactions of transcription factors involved in FGF signaling of the ascidian embryo. The Hr-Erf cDNA encompassed 3110 nucleotides including sequence encoded a predicted polypeptide of 760 amino acids. The polypeptide had the Ets DNA-binding domain in its N-terminal region. In adult animals, Hr-Erf mRNA was predominantly detected in muscle, and at lower levels in ganglion, gills, gonad, hepatopancreas, and stomach by quantitative real-time PCR (QPCR) method. During embryogenesis, Hr-Erf mRNA was detected from eggs to early developmental stage embryos, whereas the transcript levels were decreased after neurula stage. Similar to the QPCR results, maternal transcripts of Hr-Erf was detected in the fertilized eggs by whole-mount in situ hybridization. Maternal mRNA of Hr-Erf was gradually lost from the neurula stage. Zygotic expression of Hr-Erf started in most blastomeres at the 8-cell stage. At gastrula stage, Hr-Erf was specifically expressed in the precursor cells of brain and mesenchyme. When MEK inhibitor was treated, embryos resulted in loss of Hr-Erf expression in mesenchyme cells, and in excess of Hr-Erf in a-line neural cells. These results suggest that zygotic Hr-Erf products are involved in specification of mesenchyme and neural cells.
멍게 유생의 뇌포에는 2개의 감각색소세포인 평형기와 안점 이외에 또 다른 감각세포로 추정되는 수압수용체세포가 존재한다. 수압수용체세포 형성에 관해서는 현재까지 거의 알려진 것이 없다. 본 연구에서는 수압수용체세포 형성에서 FGF 신호전달 과정의 관련성을 조사했다. 수정란에 Hr-FGF9/16/20 antisense MO를 미세주입했을 때, 발생한 유생에서 수압수용체세포 특이적 Hpr-1 항원의 발현이 검출되지 않았다. 32세포기부터 FGF 수용체 억제제
원시적인 척삭동물인 멍게에서 초기 배 세포운명은 모성 세포질인자와 유도적 상호작용에 의하여 결정된다. 매우 단순한 구조를 하고 있는 멍게 올챙이형 유생의 주요한 중배엽 조직으로 척삭, 근육 및 간충직이 존재한다. 근육 세포의 형성은 세포의 자율적인 과정으로, 초기 배의 후부 가장자리에 국재하는 모성 macho-1 mRNA에 의하여 근육 세포의 운명이 결정된다. 이에 반하여, 내배엽 전구세포의 유도작용은 척삭과 간충직 세포의 운명결정에 있어서 중요한 역할