Far-Red Fluorescent Murine Glioma Model for Accurate Assessment of Brain Tumor Progression

SIMPLE SUMMARY: The creation of stable fluorescent glioma cell lines opens prospects for the detailed characterization of the molecular mechanisms of glioma origin and pathogenesis, and the development of breakthrough therapeutic approaches to achieve maximum glioma destruction and minimize the risk of future metastases. Herein, we generated and characterized a novel fluorescent glioma GL261-kat cell line stably expressing a far-red fluorescent protein, TurboFP635 (Katushka). Using the orthotopic mouse glioma model and epi-fluorescence imaging, we demonstrate the detection of fluorescent glioma GL261-kat cells in mice, and observe an increase in the fluorescence signal during glioma progression, which is accompanied by a gradual development of neurological deficit and behavioral alterations in mice. We show that GL261-kat cells can be a useful tool for studying glioma biology, because they can accurately and non-invasively monitor the characteristics of glioma growth in brain tissue in orthotopic mouse models. ABSTRACT: Glioma is the most common brain tumor, for which no significant improvement in life expectancy and quality of life is yet possible. The creation of stable fluorescent glioma cell lines is a promising tool for in-depth studies of the molecular mechanisms of glioma initialization and pathogenesis, as well as for the development of new anti-cancer strategies. Herein, a new fluorescent glioma GL261-kat cell line stably expressing a far-red fluorescent protein (TurboFP635; Katushka) was generated and characterized, and then validated in a mouse orthotopic glioma model. By using epi-fluorescence imaging, we detect the fluorescent glioma GL261-kat cells in mice starting from day 14 after the inoculation of glioma cells, and the fluorescence signal intensity increases as the glioma progresses. Tumor growth is confirmed by magnetic resonance imaging and histology. A gradual development of neurological deficit and behavioral alterations in mice is observed during glioma progression. In conclusion, our results demonstrate the significance and feasibility of using the novel glioma GL261-kat cell line as a model of glioma biology, which can be used to study the initialization of glioma and monitor its growth by lifetime non-invasive tracking of glioma cells, with the prospect of monitoring the response to anti-cancer therapy.