Transcription factors that specify cell fate activate cell cycle regulator genes to determine cell numbers in ascidian larval tissues

In animal development, most cell types stop dividing before terminal differentiation; thus, cell cycle control is tightly linked to cell differentiation programs. Although cell cycle control in animal development has been studied extensively, such links are not well understood. In ascidian embryos, cell lineages do not vary among individuals, and rounds of the cell cycle are determined according to cell lineages. In the present study, we first showed that maternal factors promote approximately 10 rounds of cell division without zygotic gene expression. Notochord and muscle cells stop dividing after fewer than 10 rounds of cell division, and we show that a Cdk inhibitor (Cdkn1.b) is responsible. Cdkn1.b is also necessary for epidermal cells to stop dividing. In contrast, mesenchymal and endodermal cells divided more than 10 times, and Myc, which encodes a proto-oncogenic transcription factor, is responsible for maintaining cell cycle progression in these tissues. Expression of Cdkn1.b in notochord and muscle is controlled by the same developmental programs that specify the developmental fate of notochord and muscle. Likewise, expression of Myc in mesenchyme and endoderm was under control of the same developmental programs that specify the developmental fate of mesenchyme and endoderm. Because these transcription factors that regulate Cdkn1.b and Myc are essential factors for fate specification of these tissues, cell fate specification and cell cycle control are linked by those transcription factors. In other words, ectodermal, mesodermal, and endodermal tissues in ascidian embryos control the cell cycle through Cdkn1.b and Myc, which are under the control of transcription factors that specify cell fate.