Mechanisms of tau and Aβ-induced excitotoxicity

• Tau facilitates KA-induced seizures and hippocampal superoxide production in mice in vivo.
• Tau does not facilitate KA-induced Ca2+ influx in rat primary neurons cultures on its own or in cooperation with Aβ42.
• Aβ42 biphasically modulates KA-induced Ca2+ influx in rat neurons: acute Aβ42 enhances, while chronic Aβ42 decreases it.
• Aβ42 modulation of KA-induced Ca2+ influx is not mediated by group 1 mGluRs.

Excitotoxicity was originally postulated to be a late stage side effect of Alzheimer׳s disease (AD)-related neurodegeneration, however more recent studies indicate that it may occur early in AD and contribute to the neurodegenerative process. Tau and amyloid beta (Aβ), the main components of neurofibrillary tangles (NFTs) and amyloid plaques, have been implicated in cooperatively and independently facilitating excitotoxicity. Our study investigated the roles of tau and Aβ in AD-related excitotoxicity. In vivo studies showed that tau knockout (tau−/−) mice were significantly protected from seizures and hippocampal superoxide production induced with the glutamate analog, kainic acid (KA). We hypothesized that tau accomplished this by facilitating KA-induced Ca2+ influx into neurons, however lentiviral tau knockdown failed to ameliorate KA-induced Ca2+ influx into primary rat cortical neurons. We further investigated if tau cooperated with Aβ to facilitate KA-induced Ca2+ influx. While Aβ biphasically modulated the KA-induced Cacyt2+ responses, tau knockdown continued to have no effect. Therefore, tau facilitates KA-induced seizures and superoxide production in a manner that does not involve facilitation of Ca2+ influx through KA receptors (KAR). On the other hand, acute pretreatment with Aβ (10 min) enhanced KA-induced Ca2+ influx, while chronic Aβ (24 h) significantly reduced it, regardless of tau knockdown. Given previously published connections between Aβ, group 1 metabotropic glutamate receptors (mGluRs), and KAR regulation, we hypothesized that Aβ modulates KAR via a G-protein coupled receptor pathway mediated by group 1 mGluRs. We found that Aβ did not activate group 1 mGluRs and inhibition of these receptors did not reverse Aβ modulation of KA-induced Ca2+ influx. Therefore, Aβ biphasically regulates KAR via a mechanism that does not involve group 1 mGluR activation.