Abstract
Epigenetically controlled processes play an important role in development but also in the formation and progression of many common diseases. Molecular signatures are increasingly incorporated into cancer classifications and DNA methylation-based analyses of brain tumors including glioma is currently the gold standard. Glioblastoma (GBM), CNS WHO grade 4, is characterized by a very diffuse infiltrative growth into the adjacent brain parenchyma. Due to these highly invasive but also genetically heterogeneous and plastic cellular phenotypes, standard treatment, including maximum resection, radio- and chemotherapy, has limited efficacy. It can be assumed that intertumoral or molecular heterogeneity of gliomas at the transcriptome level is caused by altered epigenetic changes within the individual tumor cells. Considering this, we hypothesize that tumor cell invasion being one of the major hallmarks of highly malignant gliomas can be associated with altered DNA methylation and therefore transcript expression. To analyze this, we isolated fractions of glioma cells with increased invasive properties and performed Illumina® array-based methylation profiling as well as RNA sequencing analysis to identify methylation-driven, invasion-promoting genes. Among other, we focused on Chitinase-3-like protein 1 (CHI3L1) as a candidate gene with significantly decreased promoter methylation in invasive cell fractions and overall strong transcript expression in high-grade gliomas. Differential expression and methylation correlation of TCGA data combined with our own dataset revealed that CHI3L1 expression is dependent on the methylation status of at least three CpG sites within the gene promoter region. We validated these findings using several in vitro experimental settings and propose an upstream regulatory mechanism in which single CpG DNA demethylation within the CHI3L1 promoter facilitates transcription factor binding resulting in gene expression.