Background: Prior studies have applied driver mutations targeting the RTK/RAS/PI3K and p53 pathways to induce the formation of high-grade gliomas in rodent models. In the present study, we report the production of a high-grade spinal cord glioma model in pigs using lentiviral gene transfer. Methods: Six Gottingen Minipigs received thoracolumbar (T14-L1) lateral white matter injections of a combination of lentiviral vectors, expressing platelet-derived growth factor beta (PDGF-B), constitutive HRAS, and shRNA-p53 respectively. All animals received injection of control vectors into the contralateral cord. Animals underwent baseline and endpoint magnetic resonance imaging (MRI) and were evaluated daily for clinical deficits. Hematoxylin and eosin (H&E) and immunohistochemical analysis was conducted. Data are presented using descriptive statistics including relative frequencies, mean, standard deviation, and range. Results: 100% of animals (n = 6/6) developed clinical motor deficits ipsilateral to the oncogenic lentiviral injections by a three-week endpoint. MRI scans at endpoint demonstrated contrast enhancing mass lesions at the site of oncogenic lentiviral injection and not at the site of control injections. Immunohistochemistry demonstrated positive staining for GFAP, Olig2, and a high Ki-67 proliferative index. Histopathologic features demonstrate consistent and reproducible growth of a high-grade glioma in all animals. Conclusions: Lentiviral gene transfer represents a feasible pathway to glioma modeling in higher order species. The present model is the first lentiviral vector induced pig model of high-grade spinal cord glioma and may potentially be used in preclinical therapeutic development programs. High-grade glioma has a clinical picture of untenable morbidity and mortality 1,2. Given this clinical need, the U.S. National Library of Medicine has over 350 completed phase II-III clinical trials registered as of this writing. Unfortunately, there have been limited changes to the clinical outcomes in patients with high-grade glioma over the past years. In part, this represents the malignant nature of a disease that is refractory to a variety of treatment approaches. On the other hand, this raises the question of the translational value of existing pre-clinical animal models as a pathway to the clinic 3,4. Given numerous strategies with measured preclinical optimism including immunotherapy, oncolytic vectors, and targeted drug delivery, more appropriate large animal model systems are necessary to bridge the translational gap 5-10. In patients, high-grade gliomas present with marked invasion along white matter tracts and surrounding parenchyma, an immunosuppressive microenvironment, and significant inter and intra-tumoral heterogeneity 11. Existing models of high-grade gliomas are variable in recapitulation of these features. The most common are xenograft and syngeneic models which have drawbacks including non-invasive growth (9L, U87, U251), immunogenicity (U251, U87, C6, 9L), and restriction to murine (CT-2A, ...
