RT Journal Article SR Electronic T1 The role of integrin αv and CD44 in GBM migration in human brain JF bioRxiv FD Cold Spring Harbor Laboratory SP 841726 DO 10.1101/841726 A1 Zev A. Binder A1 Sarah Hyun Ji Kim A1 Pei-Hsun Wu A1 Anjil Giri A1 Gary L. Gallia A1 Carlos A. Pardo A1 Denis Wirtz YR 2019 UL http://biorxiv.org/content/early/2019/11/16/841726.abstract AB Glioblastoma (GBM) is the most common primary adult malignant brain tumor. Recurrence is driven invading tumor cells that escape surgical resection and demonstrate resistance to standard-of-care chemotherapy and radiotherapy. A large body of research has been conducted on tumor cell motility. However, typical in vitro models make use of polystyrene culture dishes, which exhibit significantly different physical parameters than brain tissue. Here we report on the use of human organotypic brain slices as an ex vivo approach for the dynamic study of GBM cell motility.Temporal lobectomy tissue from epilepsy patients was obtained and cut into 350µm thick slices. After the tissue slices had a week’s incubation for recovery, fluorescently labeled tumor cells were seeded. We then tracked individual tumor cells using time-lapse fluorescent confocal microscopy. Quantification of motility characteristics, including mean squared displacement, total path length, and consistency, allowed for comparison of different conditions, including knockdown of cell surface proteins integrin αv (ITGAV) and CD44.Human organotypics demonstrated minimal variability across specimen in terms of motility parameters, including total path length, averaged instantaneous velocity, and consistency. Knockdown of the traditional motility protein ITGAV showed little effect on overall motility while knockdown of CD44 resulted in a significant reduction in both averaged instantaneous velocity and total path length. When the same parameters were examined using Matrigel, ITGAV and CD44 both showed decreased motility, highlighting the impact of the physical environment on cell behavior. Finally, cell motility in mouse organotypic slices was decreased when compared to human organotypic slices.Here we demonstrate the use of human organotypic brain slices in the study of GBM cell invasion. This model system offers a physiologically-relevant environment in which to examine the dynamic process of cell motility.