The 18 kDa translocator protein (TSPO), formerly known as the peripheral-type benzodiazepine receptor, has been reported to be closely associated with the mitochondrial permeability transition pore (MPTP). TSPO is believed to exert pro-apoptotic functions via modulation of MPTP opening. Cobalt chloride (CoCl(2)), which is sometimes used as a hypoxia mimicking agent, is also known to be able to induce apoptosis. One of our questions was whether CoCl(2) may induce apoptosis via the TSPO. To address this question, we used the U118MG human glioblastoma cell line. We applied the specific TSPO ligand, PK 11195, as well as TSPO knockdown with siRNA and studied their influence on the effects of CoCl(2) on cell death, including activation of the mitochondrial apoptosis pathway. To assay TSPO expression, we applied binding assays and Western blotting to whole cell homogenates and mitochondrial fractions. To assay activation of the mitochondrial apoptosis pathway, including some of the cellular mechanisms involved, we determined the incidence of collapse of the mitochondrial membrane potential (Deltapsi(m)) and cardiolipin oxidation and measured the level of DNA fragmentation to assay apoptotic rates. We found that the TSPO ligand, PK 11195, significantly counteracted induction of cell death by 0.4 mM CoCl(2), including apoptosis, collapse of the Deltapsi(m), and cardiolipin oxidation. Moreover, we found that TSPO knockdown with siRNA fully protected against mentioned cell death mechanisms. Thus, we found that the TSPO is required for cell death induction by CoCl(2), including apoptosis. In conclusion, our studies show that activation of TSPO by CoCl(2) application is required for ROS generation, leading to cardiolipin oxidation, and collapse of the Deltapsi(m), as induced by CoCl(2).
Expanding on a quinazoline scaffold, we developed tricyclic compounds with biological activity. These compounds bind to the 18 kDa translocator protein (TSPO) and protect U118MG (glioblastoma cell line of glial origin) cells from glutamate-induced cell death. Fascinating, they can induce neuronal differentiation of PC12 cells (cell line of pheochromocytoma origin with neuronal characteristics) known to display neuronal characteristics, including outgrowth of neurites, tubulin expression, and NeuN (antigen known as ‘neuronal nuclei’, also known as Rbfox3) expression. As part of the neurodifferentiation process, they can amplify cell death induced by glutamate. Interestingly, the compound 2-phenylquinazolin-4-yl dimethylcarbamate (MGV-1) can induce expansive neurite sprouting on its own and also in synergy with nerve growth factor and with glutamate. Glycine is not required, indicating that N-methyl-D-aspartate receptors are not involved in this activity. These diverse effects on cells of glial origin and on cells with neuronal characteristics induced in culture by this one compound, MGV-1, as reported in this article, mimic the diverse events that take place during embryonic development of the brain (maintenance of glial integrity, differentiation of progenitor cells to mature neurons, and weeding out of non-differentiating progenitor cells). Such mechanisms are also important for protective, curative, and restorative processes that occur during and after brain injury and brain disease. Indeed, we found in a rat model of systemic kainic acid injection that MGV-1 can prevent seizures, counteract the process of ongoing brain damage, including edema, and restore behavior defects to normal patterns. Furthermore, in the R6-2 (transgenic mouse model for Huntington disease; Strain name: B6CBA-Tg(HDexon1)62Gpb/3J) transgenic mouse model for Huntington disease, derivatives of MGV-1 can increase lifespan by >20% and reduce incidence of abnormal movements. Also in vitro, these derivatives were more effective than MGV-1.
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