[HTML][HTML] Enhanced fatty acid oxidation provides glioblastoma cells metabolic plasticity to accommodate to its dynamic nutrient microenvironment

S Kant, P Kesarwani, A Prabhu, SF Graham… - Cell Death & …, 2020 - nature.com
S Kant, P Kesarwani, A Prabhu, SF Graham, KL Buelow, I Nakano, P Chinnaiyan
Cell Death & Disease, 2020nature.com
Despite advances in molecularly characterizing glioblastoma (GBM), metabolic alterations
driving its aggressive phenotype are only beginning to be recognized. Integrative cross-
platform analysis coupling global metabolomic and gene expression profiling on patient-
derived glioma identified fatty acid β-oxidation (FAO) as a metabolic node in GBM. We
determined that the biologic consequence of enhanced FAO is directly dependent upon
tumor microenvironment. FAO serves as a metabolic cue to drive proliferation in a β …
Abstract
Despite advances in molecularly characterizing glioblastoma (GBM), metabolic alterations driving its aggressive phenotype are only beginning to be recognized. Integrative cross-platform analysis coupling global metabolomic and gene expression profiling on patient-derived glioma identified fatty acid β-oxidation (FAO) as a metabolic node in GBM. We determined that the biologic consequence of enhanced FAO is directly dependent upon tumor microenvironment. FAO serves as a metabolic cue to drive proliferation in a β-HB/GPR109A dependent autocrine manner in nutrient favorable conditions, while providing an efficient, alternate source of ATP only in nutrient unfavorable conditions. Rational combinatorial strategies designed to target these dynamic roles FAO plays in gliomagenesis resulted in necroptosis-mediated metabolic synthetic lethality in GBM. In summary, we identified FAO as a dominant metabolic node in GBM that provides metabolic plasticity, allowing these cells to adapt to their dynamic microenvironment. Combinatorial strategies designed to target these diverse roles FAO plays in gliomagenesis offers therapeutic potential in GBM.
nature.com