Project description:Lineage segregation in the mouse embryo is a finely controlled process dependent upon coordination of signalling pathways and transcriptional responses. We employed conditional deletion of Oct4 to investigate consequences of interference with embryonic patterning and lineage specification. Nanog becomes upregulated in the first epiblast cells to lose Oct4, leading to an expanded Nanog-positive domain. The primitive streak forms in the presumptive proximal posterior region, but epithelial to mesenchymal transition is impeded by dramatic increase of E-cadherin, leading to complete disorganisation and failure to generate germ layers. Formerly, expression domains of lineage markers were disrupted. Specifically, definitive endoderm expanded, the boundaries between presumptive anterior and posterior domains blurred and an ectopic posterior-like region appeared anteriorly, suggesting a role for Oct4 in maintaining the embryonic axis. Despite intermixing of lineage marker domains in mutants, cells co-expressing distinct lineage genes were not observed, suggesting that Oct4 deletion does not alter the connectivity of the transcription networks which underlie cell fate decisions in vivo. Molecular profiling corroborated genome-wide posteriorisation of mutants and disrupted expression of genes involved in gastrulation. Lastly, we confirmed a requirement for Oct4 in self-renewal of post-implantation epiblast ex vivo

Project description: Not available

Project description: Not available

Project description: Not available

Project description: Not available

Project description: Not available

Project description: Not available

Project description: Not available

Project description:MicroRNAs (miRNAs) have essential functions during embryonic development, and their dysregulation causes cancer. Altered global miRNA abundance is found in different tissues and tumours, which implies that precise control of miRNA dosage is important[134], but the underlying mechanism(s) of this control remain unknown. The protein complex Microprocessor, which comprises one DROSHA and two DGCR8 proteins, is essential for miRNA biogenesis. Here we identify a developmentally regulated miRNA dosage control mechanism that involves alternative transcription initiation (ATI) of DGCR8. ATI occurs downstream of a stem-loop in DGCR8 mRNA to bypass an autoregulatory feedback loop during mouse embryonic stem cell (mES cell) differentiation. Deletion of the stem-loop causes imbalanced DGCR8:DROSHA protein stoichiometry that drives irreversible Microprocessor aggregation, reduced primary miRNA processing, decreased mature miRNA abundance, and widespread de-repression of lipid metabolic mRNA targets. Although global miRNA dosage control is not essential for mES cells to exit from pluripotency, its dysregulation alters lipid metabolic pathways and interferes with embryonic development by disrupting germ layer specification in vitro and in vivo. This miRNA dosage control mechanism is conserved in humans. Our results identify a promoter switch that balances Microprocessor autoregulation and aggregation to precisely control global miRNA dosage and govern stem cell fate decisions during early embryonic development.

Project description: Not available