Abstract
Major developmental events in early Xenopus embryogenesis coincide with changes in the length and composition of the cell cycle. These changes are mediated in part through the regulation of CyclinB/Cdc2 and they occur at the first mitotic cell cycle, the mid-blastula transition (MBT) and at gastrulation. In this report, we investigate the contribution of maternal Wee1, a kinase inhibitor of CyclinB/Cdc2, to these crucial developmental transitions. By depleting Wee1 protein levels using antisense morpholino oligonucleotides, we show that Wee1 regulates M-phase entry and Cdc2 tyrosine phosphorylation in early gastrula embryos. Moreover, we find that Wee1 is required for key morphogenetic movements involved in gastrulation, but is not needed for the induction of zygotic transcription. In addition, Wee1 is positively regulated by tyrosine autophosphorylation in early gastrula embryos and this upregulation of Wee1 activity is required for normal gastrulation. We also show that overexpression of Cdc25C, a phosphatase that activates the CyclinB/Cdc2 complex, induces gastrulation defects that can be rescued by Wee1, providing additional evidence that cell cycle inhibition is crucial for the gastrulation process. Together, these findings further elucidate the developmental function of Wee1 and demonstrate the importance of cell cycle regulation in vertebrate morphogenesis.
Highlights
The generation of a complex multicellular organism from a single fertilized egg involves the precise control of cell division, cell-fate specification and morphogenesis
By using antisense morpholino oligonucleotides to deplete maternal Wee1 protein levels, we find that Wee1 is a crucial regulator of M-phase entry and is an essential component of vertebrate morphogenesis
Maternal Wee1 protein levels remain relatively constant from meiosis II until mid gastrulation
Summary
The generation of a complex multicellular organism from a single fertilized egg involves the precise control of cell division, cell-fate specification and morphogenesis. The subsequent eleven cell divisions (cell cycles 2-12) are 30-minute cell cycles that rapidly cellularize the embryo These cell cycles are devoid of gap phases and have no growth or transcriptional requirements. During gastrulation (cycles 13-15), the cell cycle is expanded further, from 55 minutes to 4 hours, as the embryo undergoes a dramatic morphological transformation (Howe et al, 1995). These cell cycle modifications are known to occur at the same time as key developmental events, the role of these developmentally regulated cell cycle modifications (hereafter referred to as developmental transitions) in cell fate specification and morphogenesis is unclear
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