Development of an orthotopic medulloblastoma zebrafish model for rapid drug testing

Abstract

AbstractMedulloblastoma (MB) is one of the most common malignant brain tumors in children. Current preclinicalin vivomodel systems for MB have increased our understanding of molecular mechanisms regulating MB development; however, they may not be suitable for high-throughput screening efforts. We demonstrate here that transplantation of seven different MB cell lines or patient-derived cells into the blastula stage of zebrafish embryos leads to orthotopic tumor cell growth that can be observed within 24 hours after transplantation. Importantly, the homing of transplanted cells to the hindbrain region and the aggressiveness of tumor growth are enhanced by pre-culturing cells in a neural stem cell-like medium. The change in culture conditions rewires the transcriptome towards a more migratory and neuronal progenitor phenotype, including the expression of guidance molecules SEMA3A and EFNB1, both of which correlate with lower overall survival in MB patients. Furthermore, we highlight that the orthotopic zebrafish MB xenograft model has the potential to be used for high-throughput drug screening.Key pointsMedulloblastoma cells home to the hindbrain region in developing zebrafish embryos.Neural stem cell culture conditions improve the homing capacity of MB tumor cells.Medulloblastoma-transplanted zebrafish embryos can be used as a high-throughputin vivomodel for drug screening.Importance of the StudyOne of the challenges of accurately modeling medulloblastoma is the large heterogeneity in tumor characteristics. To accurately model this heterogeneous disease, patient-derived xenograft mouse models are currently the standard. However, such mouse models are labor intensive, time-consuming, and not suitable for high-throughput studies. Here, we describe a quick and straightforward zebrafish xenograft model that provides a promising alternative to these existing mouse models. We demonstrate that this model can be utilized to study tumor cell growth of several major medulloblastoma subgroups. More importantly, our model facilitates high-throughput drug testing, providing a scalable opportunity forin vivodrug screenings that will support the discovery of novel therapeutic compounds against medulloblastoma.