FANCA deficiency promotes leukaemic progression by allowing the emergence of cells carrying oncogenic driver mutations.
Patrycja PawlikowskaLaure DelestréSebastian GregoricchioAlessia OppezzoMichela EspositoM' Boyba DiopFilippo RosselliChristel GuilloufPublished in: Oncogene (2023)
Leukaemia is caused by the clonal evolution of a cell that accumulates mutations/genomic rearrangements, allowing unrestrained cell growth. However, recent identification of leukaemic mutations in the blood cells of healthy individuals revealed that additional events are required to expand the mutated clones for overt leukaemia. Here, we assessed the functional consequences of deleting the Fanconi anaemia A (Fanca) gene, which encodes a DNA damage response protein, in Spi1 transgenic mice that develop preleukaemic syndrome. FANCA loss increases SPI1-associated disease penetrance and leukaemic progression without increasing the global mutation load of leukaemic clones. However, a high frequency of leukaemic FANCA-depleted cells display heterozygous activating mutations in known oncogenes, such as Kit or Nras, also identified but at low frequency in FANCA-WT mice with preleukaemic syndrome, indicating that FANCA counteracts the emergence of oncogene mutated leukaemic cells. A unique transcriptional signature is associated with the leukaemic status of FANCA-depleted cells, leading to activation of MDM4, NOTCH and Wnt/β-catenin pathways. We show that NOTCH signalling improves the proliferation capacity of FANCA-deficient leukaemic cells. Collectively, our observations indicate that loss of the FANC pathway, known to control genetic instability, fosters the expansion of leukaemic cells carrying oncogenic mutations rather than mutation formation. FANCA loss may contribute to this leukaemogenic progression by reprogramming transcriptomic landscape of the cells.
Keyphrases
- induced apoptosis
- cell cycle arrest
- signaling pathway
- high frequency
- endoplasmic reticulum stress
- stem cells
- cell proliferation
- single cell
- type diabetes
- oxidative stress
- gene expression
- transcription factor
- dna damage response
- mesenchymal stem cells
- cell death
- skeletal muscle
- dna methylation
- dna damage
- pi k akt
- copy number
- small molecule
- early onset
- heat shock protein