Abstract 2415: GBM exhibits phenotypic microheterogeneity and harbors pre-existing multi- resistant clones with a mesenchymal transition signature

Glioblastoma multiforme (GBM) remains in the group of incurable malignancies, with a median survival of 15 months. Intratumoral heterogeneity is a key factor driving relapse by providing the basis for escape of therapy-resistant cells. While the heterogeneous genomic and transcriptomic landscape of cancers is currently thoroughly characterized, phenotypic heterogeneity within tumors is less well understood. The overall goal in this study was to identify pre-existing treatment resistant clones with disease relapse potential and biomarkers linked to resistance vs sensitivity. To enable functional studies of isolated tumor clones we adopted an in vitro subcloning strategy. An adherent glioma neural stem cell culturing protocol was used to enrich for cells with stem-like properties and to permit efficient phenotypic screening. We established six libraries of clonal cell cultures from fresh GBM surgical specimens, corresponding to five different patient tumors. In all 708 clonal cultures were expanded. These were considered representatives of the self-renewing compartment within the tumor cell population. We found a remarkable variation in drug and radiation response within the clone libraries. A striking observation was that clones resistant to one drug, also tended to be resistant to most of the drugs we used, regardless of the drug9s mechanism of action. This indicates that resistance in large parts is mediated by a general mechanism. Most clones carried genetic aberrations that were unique or found only in a few clones but it was primarily the transcriptome data that demonstrated a clear link to the phenotypic data. A continuous gradient between multi-resistance and sensitivity was found to be connected to a gradual transition between a mesenchymal (MES), in resistant clones, and a more proneural (PN) and proliferative character in sensitive clones. The continuous distributions and lack of discrete groups in clonal response phenotypes and in linked signatures points to a general cell-state related resistance mechanism. We also found that resistant clones had a lower methylation level in promoters of known master regulators of MES subtype associated genes. This indicates that the phenotypic heterogeneity is driven by fluctuations in the epigenetic status. Taken together, our findings imply that intratumoral heterogeneity in GBM includes general clonal resistance mechanisms among glioma- initiating cells driven by epigenetic mechanisms. This evokes hope that new therapeutic approaches involving epigenetic reprogramming can be applied to sensitize cells toward conventional treatment. Citation Format: Anna Segerman, Maria Niklasson, Caroline Haglund, Tobias Bergstrom, Malin Jarvius, Yuan Xie, Demet Caglayan Simov, Annika Hermansson, Marianne Kastemar, Zeinab Naimaie-Ali, Malin Berglund, Ann Westermark, Magnus Sundstrom, Goran Hesselager, Lene Uhrbom, Mats Gustafsson, Rolf Larsson, Marten Fryknas, Bo Segerman, Bengt Westermark. GBM exhibits phenotypic microheterogeneity and harbors pre-existing multi- resistant clones with a mesenchymal transition signature. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 2415.