D-2-HG Inhibits IDH1mut Glioma Growth via FTO Inhibition and Resultant m6A Hypermethylation.
Sean Thomas PiankaTie LiTerry J PrinsBlaine S C EldredBryan M KevanHaowen LiangSerendipity Zapanta RinonosHarley I KornblumDavid A NathansonMatteo PellegriniLinda M LiauPhioanh Leia NghiemphuTimothy F CloughesyAlbert LaiPublished in: Cancer research communications (2024)
IDH1mut gliomas produce high levels of D-2-HG, an oncometabolite capable of inhibiting α-ketoglutarate-dependent dioxygenases critical to a range of cellular functions involved in gliomagenesis. IDH1mut gliomas also exhibit slower growth rates and improved treatment sensitivity compared to their IDH1wt counterparts. This study explores the mechanism driving apparent reduced growth in IDH1mut gliomas. Specifically, we investigated the relationship between IDH1mut and the RNA m6A demethylases FTO and ALKBH5, and their potential for therapeutic targeting. We investigated the role of D-2-HG and m6A in tumor proliferation/viability using glioma patient tumor samples, patient-derived gliomaspheres, and U87 cells, as well as with mouse intracranial IDH1wt gliomasphere xenografts. MeRIP-Seq RNA sequencing was used to identify m6A enriched transcripts in IDH1mut glioma. We show that IDH1mut production of D-2-HG is capable of reducing glioma cell growth via inhibition of the m6A epitranscriptomic regulator, FTO, with resultant m6A hypermethylation of a set of mRNA transcripts. Based on unbiased MeRIP-Seq epitranscriptomic profiling, we identify ATF5 as a hypermethylated, downregulated transcript that potentially contributes to increased apoptosis. We further demonstrate how targeting this pathway genetically and pharmacologically reduces the proliferative potential of malignant IDH1wt gliomas, both in vitro and in vivo. Our work provides evidence that selective inhibition of the m6A epitranscriptomic regulator FTO attenuates growth in IDH1wt glioma, recapitulating the clinically favorable growth phenotype seen in the IDH1mut subtype.
Keyphrases
- low grade
- high grade
- wild type
- single cell
- transcription factor
- oxidative stress
- cell cycle arrest
- endoplasmic reticulum stress
- computed tomography
- risk assessment
- magnetic resonance imaging
- magnetic resonance
- climate change
- case report
- cancer therapy
- cell proliferation
- mass spectrometry
- atomic force microscopy
- aqueous solution
- binding protein
- contrast enhanced
- combination therapy