EXTH-76. 1H AND HYPERPOLARIZED 13C MRS BIOMARKERS OF IDH1 MUTANT GLIOMA RESPONSE TO TEMOZOLOMIDE THERAPY

Abstract The alkylating agent temozolomide (TMZ), previously reserved for treatment of glioblastoma, is now being considered for the treatment of low-grade glioma that are driven by mutations in the isocitrate dehydrogenase 1 (IDH1) gene. Though the treatment of IDH1 mutant patients with TMZ improves survival, there is a need for metabolic imaging to help in assessing early response to therapy. The goal of this study was, therefore, to determine the value of magnetic resonance spectroscopy (MRS)-based biomarkers for detection of response to treatment. To address this, we examined the global metabolic alterations that occurred following TMZ treatment in a genetically engineered IDH1 mutant immortalized normal human astrocyte cell line (NHAIDHmut) using 1H and 13C MRS combined with chemometrics. Cells were treated either with the IC50 of TMZ (100 μM; N=5), or with DMSO (0.2%; N=5) for 72 hours. Then, metabolites were extracted from cells and 1H spectra acquired. Data were analyzed using SIMCA and the most significant metabolites contributing to class separation were identified using multivariate and univariate analyses. Alternatively, live cells were exposed to hyperpolarized 2-13C-pyruvate and dynamic sets of 13C-MRS spectra recorded to monitor the production of 5-13C-glutamate over time. 1H MRS showed that glutamine, glutamate, pyruvate, succinate, glucose, phosphocholine, isoleucine, valine, lysine, phenylalanine, NAD+/NADP+ and ATP/ADP/AMP were significantly higher in TMZ-treated cells as compared to controls. Accordingly, the tricarboxylic acid (TCA) cycle was identified as a significantly altered pathway following TMZ treatment. Consistent with this finding, dynamically probing the metabolism of hyperpolarized 2-13C-pyruvate revealed that build-up of 5-13C-glutamate, which is associated with flux to the TCA cycle, was significantly higher in TMZ-treated cells as compared to controls. Further studies are warranted for validation of our findings in other mutant IDH1 models. Nonetheless, our findings identify potential MRS-detectable early biomarkers of response to TMZ therapy in mutant IDH1 glioma.