Are synapses targets of nanoparticles?

The last few years have been marked by real breakthroughs in the field of nanotechnology. Application of nanoparticles was proposed for diagnosis and treatment of different central nervous system diseases. Exposure to nanoparticles in vivo increases the risk of onset of neurodegenerative diseases and nanoparticles are apparently able to kill neurons in vitro. We suggested that presynaptic terminals of neurons are another target for nanoparticles, beyond the already established microglial cells. Ferritin was chosen as a prototypic nanoparticle model. We found that even a high concentration of ferritin, 800 microg/ml, was not able to induce spontaneous release of [(14)C]glutamate. In contrast, [(14)C]glutamate uptake was inhibited by ferritin in a dose-dependent fashion. As a next step, the influence of ferritin on the formation of reactive oxygen species was monitored using the fluorescent dye DCFH-DA (2',7'-dichlorofluorescein diacetate). It was shown that ferritin leads to a dose-dependent formation of free radicals. We found that the ferritin-mediated changes in glutamatergic neurotransmission at presynaptic endings can result in neuronal damage and finally neurodegeneration.

Ferritin, a protein containing iron nanoparticles, induces reactive oxygen species formation and inhibits glutamate uptake in rat brain synaptosomes.

Nanoparticles are currently used in medicine as agents for targeted drug delivery and imaging. However it has been demonstrated that nanoparticles induce neurodegeneration in vivo and kill neurons in vitro. The cellular and molecular bases of this phenomenon are still unclear. We have used the protein ferritin as a nanoparticle model. Ferritin contains iron particles (Fe(3+)) with size 7 nm and a protein shell. We investigated how ferritin influences uptake and release of [(14)C]glutamate and free radical formation as monitored by fluorescent dye DCFDA in rat brain synaptosomes. We found that even a high concentration of ferritin (800 microg/ml) did not induce spontaneous [(14)C]glutamate release. In contrast the same concentration of this protein inhibited [(14)C]glutamate uptake two fold. Furthermore ferritin induced intrasynaptosomal ROS (reactive oxygen species) formation in a dose-dependent manner. This process was insensitive to 30 microM DPI, an inhibitor of NADPH oxidase and to 10 microM CCCP, a mitochondrial uncoupler. These results indicate that iron-based nanoparticles can cause ROS and decreased glutamate uptake, potentially leading to neurodegeneration.