Blood glutamate scavengers increase pro-apoptotic signaling and reduce metastatic melanoma growth in-vivo.

Inhibition of extracellular glutamate (Glu) release decreases proliferation and invasion, induces apoptosis, and inhibits melanoma metastatic abilities. Previous studies have shown that Blood-glutamate scavenging (BGS), a novel treatment approach, has been found to be beneficial in attenuating glioblastoma progression by reducing brain Glu levels. Therefore, in this study we evaluated the ability of BGS treatment to inhibit brain metastatic melanoma progression in-vivo. RET melanoma cells were implanted in C56BL/6J mice to induce brain melanoma tumors followed by treatment with BGS or vehicle administered for fourteen days. Bioluminescent imaging was conducted to evaluate tumor growth, and plasma/CSF Glu levels were monitored throughout. Immunofluorescence staining of Ki67 and 53BP1 was used to analyze tumor cell proliferation and DNA double-strand breaks. In addition, we analyzed CD8, CD68, CD206, p-STAT1 and iNOS expression to evaluate alterations in tumor micro-environment and anti-tumor immune response due to treatment. Our results show that BGS treatment reduces CSF Glu concentration and consequently melanoma growth in-vivo by decreasing tumor cell proliferation and increasing pro-apoptotic signaling in C56BL/6J mice. Furthermore, BGS treatment supported CD8+ cell recruitment and CD68+ macrophage invasion. These findings suggest that BGS can be of potential therapeutic relevance in the treatment of metastatic melanoma.

Blood glutamate scavengers and exercises as an effective neuroprotective treatment in mice with spinal cord injury.

OBJECTIVE: Excitotoxicity due to neuronal damage and glutamate release is one of the first events that leads to the progression of neuronal degeneration and functional impairment. This study is based on a paradigm shift in the therapeutic approach for treating spinal cord injury (SCI). The authors tested a new treatment targeting removal of CNS glutamate into the blood circulation by injection of the blood glutamate scavengers (BGSs) recombinant enzyme glutamate-oxaloacetate transaminase (rGOT1) and its cosubstrate oxaloacetic acid (OxAc). Their primary objective was to investigate whether BGS treatment, followed by treadmill exercises in mice with SCI, could attenuate excitotoxicity, inflammation, scarring, and axonal degeneration and, at a later time point, improve functional recovery. METHODS: A pharmacokinetic experiment was done in C57BL/6 naive mice to verify rGOT1/OxAc blood activity and to characterize the time curve of glutamate reduction in the blood up to 24 hours. The reduction of glutamate in CSF after BGS administration in mice with SCI was confirmed by high-performance liquid chromatography. Next, SCI (left hemisection) was induced in the mice, and the mice were randomly assigned to one of the following groups at 1 hour postinjury: control (underwent SCI and received PBS), treadmill exercises, rGOT1/OxAc treatment, or rGOT1/OxAc treatment followed by treadmill exercises. Treatment started 1 hour postinjury with an injection of rGOT1/OxAc and continued for 5 consecutive days. Starting 1 week after SCI, the exercises and the combined treatment groups recommenced the treadmill exercise regimen 5 days a week for 3 months. Locomotor function was assessed for 3 months using the horizontal grid walking test and CatWalk. Axonal anterograde and wallerian degenerations were evaluated using tetramethylrhodamine dextran. Tissue sections were immunofluorescently stained for Iba1, GFAP, GAP-43, synaptophysin, and NeuN. RESULTS: BGS treatment decreased the CSF glutamate level up to 50%, reduced axonal wallerian degeneration, and increased axonal survival and GAP-43 expression in neuronal cells. Combined treatment reduced inflammation, scarring, and lesion size. Additionally, the combination of BGS treatment and exercises increased synapses around motor neurons and enhanced axonal regeneration through the lesion site. This resulted in motor function improvement 3 months post-SCI. CONCLUSIONS: As shown by biochemical, immunohistochemical, and functional analysis, BGSs exhibit a substantial neuroprotective effect by reducing excitotoxicity and secondary damage after SCI. Furthermore, in combination with exercises, they reduced axonal degeneration and scarring and resulted in improved functional recovery.