Abstract
In the search for new potential chemotherapeutics, the compounds’ toxicity to healthy cells is an important factor. The brain with its functional units, the neurons, is especially endangered during the radio- and chemotherapeutic treatment of brain tumors. The effect of the potential compounds not only on neuronal survival but also neuronal function needs to be taken into account. Therefore, in this study we aimed to comprehend the biological effects of chemotherapeutic xCT inhibition on healthy neuronal cells with our synaptic optogenetic function analysis tool (SOFA). We combined common approaches, such as investigation of morphological markers, neuronal function and cell metabolism. The glutamate-cystine exchanger xCT (SLC7A11, system Xc−) is the main glutamate exporter in malignant brain tumors and as such a relevant drug target for treating deadly glioblastomas (WHO grades III and IV). Recently, two small molecules termed sorafenib (Nexavar) and erastin have been found to efficiently block xCT function. We investigated neuronal morphology, metabolic secretome profiles, synaptic function and cell metabolism of primary hippocampal cultures (containing neurons and glial cells) treated with sorafenib and erastin in clinically relevant concentrations. We found that sorafenib severely damaged neurons already after 24 h of treatment. Noteworthy, also at a lower concentration, where no morphological damage or metabolic disturbance was monitored, sorafenib still interfered with synaptic and metabolic homeostasis. In contrast, erastin-treated neurons displayed mostly inconspicuous morphology and metabolic rates. Key parameters of proper neuronal function, such as synaptic vesicle pool sizes, were however disrupted following erastin application. In conclusion, our data revealed that while sorafenib and erastin effectively inhibited xCT function they also interfered with essential neuronal (synaptic) function. These findings highlight the particular importance of investigating the effects of potential neurooncological and general cancer chemotherapeutics also on healthy neuronal cells and their function as revealed by the SOFA tool.
Highlights
Malignant gliomas (glioblastomas (GBMs; WHO grades III and IV)) are primary brain tumors with lethal prognosis in adults.[1,2,3] The median survival time from diagnosis is ~ 14 months.[1,3] GBMs are hallmarked by features such as uncontrolled cellular proliferation, diffuse infiltration, and resistance to apoptosis and chemotherapy
We systematically investigate the effect of chemotherapeutically relevant concentrations of sorafenib on healthy rat hippocampal cells
At the concentration of 10 μM, that proved efficient in targeting tumor cells in Dixon et al.[8], we found that neurons suffered from sorafenib treatment
Summary
Malignant gliomas (glioblastomas (GBMs; WHO grades III and IV)) are primary brain tumors with lethal prognosis in adults.[1,2,3] The median survival time from diagnosis is ~ 14 months.[1,3] GBMs are hallmarked by features such as uncontrolled cellular proliferation, diffuse infiltration, and resistance to apoptosis and chemotherapy. The current standard-of-care for GBM patients includes adjuvant temozolomide treatment (brand names Temodal in Europe and Temcad in the USA).[4] This treatment strategy is currently the best clinical practice, conferring still a median survival time of only 14.6 months[4] compared with 12.2 months for patients receiving only radiotherapy.[5]. Temozolomide, or rather its metabolites, methylate DNA to inhibit tumor proliferation.
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