CCRG-04. AUTOMATED REAL TIME TRACKING OF GLIOBLASTOMA CELL CYCLE TRANSITIONS IN ASSEMBLOIDS LINKS G2 CELLS TO INFILTRATION

Abstract

Abstract Glioblastoma (GB) is the most aggressive primary brain tumour in adults associated with survival rates below 5% despite treatment. Tumour repopulating residual cells in the surgical cavity resist treatment due to their molecular heterogeneity. Single-cell transcriptomic studies have linked GB heterogeneity to the cell cycle; however, it remains unclear to what extent cell cycle states affect the infiltrative capacity of GB. The “go or grow” paradigm predicts that migration and proliferation are separate spatiotemporal events. We used a brain tumour-cerebral organoid (assembloid) approach to test the migratory potential of GB cell cycle phases during assembloid infiltration. Human induced pluripotent cells were differentiated into cerebral organoids that self-assemble with spheroids of patient-derived GB cells, expressing a fluorescent cell cycle reporter (FUCCI). Utilising live-cell confocal imaging, the process of GB assembloid infiltration was captured. Resultant videos were analysed with automated image analysis capable of tracking cell cycle transitions and cellular migration in confocal microscopy planes, enabling the longitudinal quantification of GB migration and invasion. Our analysis revealed a subset of highly infiltrative GB cells, containing a significant number of cycling G2 phase cells that demonstrated a ~1.4-fold increase in directional infiltrative capacity compared to their non cycling G1 phase counterparts. To isolate and characterize the G2 migratory GB cell state, we developed a phenotypic separation assay using microenvironmental cues. Specifically, we found that these cues markedly affect GB migration routes enabling the isolation of the highly migratory GB cells for further investigation. Our results question the “go or grow” hypothesis at the level of GB cellular subpopulations. We hypothesise that the observed G2 migratory capacity of GB cells could be critical to tumour recurrence following surgery. Further research is underway to define the underlying mechanisms of G2 GB cell migration.