Integrated genomic-metabolic classification of acute myeloid leukemia defines a subgroup with NPM1 and cohesin/DNA damage mutations.
Francesco LanzaCarlo MengucciAntonella PadellaEugenio FonziGianfranco PiconeClaudio DelpinoJacopo NanniRossella De TommasoEugenia FranchiniCristina PapayannidisGiovanni MarconiMartina PazzagliaMargherita PerriconeEmanuela ScarpiMaria Chiara FontanaSamantha BrunoMichela TebaldiAnna FerrariMaria Teresa BochicchioAndrea Ghelli Luserna Di RoràMartina GhettiRoberta NapolitanoAnnalisa AstolfiCarmen BaldazziViviana GuadagnuoloEmanuela OttavianiIlaria IacobucciMichele CavoGastone CastellaniTorsten HaferlachDaniel RemondiniFrancesco CapozziGiovanni MartinelliPublished in: Leukemia (2021)
Although targeting of cell metabolism is a promising therapeutic strategy in acute myeloid leukemia (AML), metabolic dependencies are largely unexplored. We aimed to classify AML patients based on their metabolic landscape and map connections between metabolic and genomic profiles. Combined serum and urine metabolomics improved AML characterization compared with individual biofluid analysis. At intracellular level, AML displayed dysregulated amino acid, nucleotide, lipid, and bioenergetic metabolism. The integration of intracellular and biofluid metabolomics provided a map of alterations in the metabolism of polyamine, purine, keton bodies and polyunsaturated fatty acids and tricarboxylic acid cycle. The intracellular metabolome distinguished three AML clusters, correlating with distinct genomic profiles: NPM1-mutated(mut), chromatin/spliceosome-mut and TP53-mut/aneuploid AML that were confirmed by biofluid analysis. Interestingly, integrated genomic-metabolic profiles defined two subgroups of NPM1-mut AML. One was enriched for mutations in cohesin/DNA damage-related genes (NPM1/cohesin-mut AML) and showed increased serum choline + trimethylamine-N-oxide and leucine, higher mutation load, transcriptomic signatures of reduced inflammatory status and better ex-vivo response to EGFR and MET inhibition. The transcriptional differences of enzyme-encoding genes between NPM1/cohesin-mut and NPM1-mut allowed in silico modeling of intracellular metabolic perturbations. This approach predicted alterations in NAD and purine metabolism in NPM1/cohesin-mut AML that suggest potential vulnerabilities, worthy of being therapeutically explored.
Keyphrases
- acute myeloid leukemia
- dna damage
- allogeneic hematopoietic stem cell transplantation
- oxidative stress
- copy number
- single cell
- reactive oxygen species
- mass spectrometry
- genome wide
- gene expression
- transcription factor
- stem cells
- chronic kidney disease
- amino acid
- end stage renal disease
- tyrosine kinase
- dna methylation
- ejection fraction
- newly diagnosed
- clinical trial
- risk assessment
- acute lymphoblastic leukemia
- molecular docking
- drug delivery
- cell therapy
- data analysis
- rna seq
- fatty acid