HGG-22. LINKS BETWEEN M6A RNA METHYLATION, R-LOOPS AND DNA DAMAGE IN PAEDIATRIC HIGH-GRADE GLIOMAS

Abstract

Abstract BACKGROUND Paediatric high-grade gliomas (pHGG) are aggressive malignant tumours of the central nervous system that unfortunately carry poor prognoses. R-loops, which are DNA:RNA hybrids, are a known source of genomic instability in eukaryotic cells. The RNA strand of R-loops can be m6A methylated at double-strand break sites in order to facilitate DNA repair. Therefore, we investigated whether dysregulation of m6A methylation and R-loop homeostasis at DNA damage sites deregulates DNA repair pathways in pHGG. METHODS Immunocytochemistry was performed to assess global m6A, R-loop, γH2AX and several DNA repair protein levels in pHGG cell lines compared to human astrocytes. Colocalisation between m6A and R-loops, R-loops and γH2AX, m6A and γH2AX, R-loops and 53BP1, R-loops and PARP1, R-loops and total ATM, and R-loops and phosphorylated ATM was assessed in pHGG cell lines and human astrocytes. RESULTS Immunocytochemistry analysis revealed that levels of global m6A, R-loop, γH2AX and several DNA repair proteins were generally higher in pHGG cell lines, thereby indicating that cellular homeostasis is dysregulated. Furthermore, a high degree of colocalisation between m6A and R-loops was observed. R-loops were found to colocalise with γH2AX, and m6A was found to colocalise with γH2AX, thereby corroborating the notion that m6A methylated R-loops are likely present at DNA damage sites. Finally, R-loops were also found to colocalise with a variety of DNA repair proteins, including 53BP1, PARP1, total ATM, and phosphorylated ATM, where different Pearson’s correlation coefficient values were obtained, thereby suggesting that R-loops associate with DNA repair proteins to different extents. CONCLUSIONS The link between m6A methylation, R-loops and DNA damage in relation to the pathogenesis of pHGG is currently being investigated. Experiments are also being performed where we are investigating m6A readers to see whether their aberrant expression contributes to disease pathogenesis via deregulating DNA repair pathways.