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Coopted temporal patterning governs cellular hierarchy, heterogeneity and metabolism in Drosophila neuroblast tumors.

Sara GenoveseRaphaël ClémentCassandra GaultierFlorence BesseKarine Narbonne-ReveauFabrice DaianSophie FoppoloNuno Miguel LuisCédric Maurange
Published in: eLife (2019)
It is still unclear what drives progression of childhood tumors. During Drosophila larval development, asymmetrically-dividing neural stem cells, called neuroblasts, progress through an intrinsic temporal patterning program that ensures cessation of divisions before adulthood. We previously showed that temporal patterning also delineates an early developmental window during which neuroblasts are susceptible to tumor initiation (Narbonne-Reveau et al., 2016). Using single-cell transcriptomics, clonal analysis and numerical modeling, we now identify a network of twenty larval temporal patterning genes that are redeployed within neuroblast tumors to trigger a robust hierarchical division scheme that perpetuates growth while inducing predictable cell heterogeneity. Along the hierarchy, temporal patterning genes define a differentiation trajectory that regulates glucose metabolism genes to determine the proliferative properties of tumor cells. Thus, partial redeployment of the temporal patterning program encoded in the cell of origin may govern the hierarchy, heterogeneity and growth properties of neural tumors with a developmental origin.
Keyphrases
  • single cell
  • rna seq
  • cell fate
  • high throughput
  • genome wide
  • stem cells
  • gene expression
  • genome wide identification
  • dna methylation
  • young adults
  • transcription factor
  • mesenchymal stem cells
  • early life
  • aedes aegypti