Microglia activation contributes to quinolinic acid-induced neuronal excitotoxicity through TNF-α.

It has been reported that activation of NF-κB is involved in excitotoxicity; however, it is not fully understood how NF-κB contributes to excitotoxicity. The aim of this study is to investigate if NF-κB contributes to quinolinic acid (QA)-mediated excitotoxicity through activation of microglia. In the cultured primary cortical neurons and microglia BV-2 cells, the effects of QA on cell survival, NF-κB expression and cytokines production were investigated. The effects of BV-2-conditioned medium (BCM) on primary cortical neurons were examined. The effects of pyrrolidine dithiocarbamate (PDTC), an inhibitor of NF-κB, and minocycline (MC), an inhibitor of microglia activation, on QA-induced excitotoxicity were assessed. QA-induced NF-κB activation and TNF-α secretion, and the roles of TNF-α in excitotoxicity were studied. QA at the concentration below 1 mM had no apparent toxic effects on cultured primary neurons or BV-2 cells. However, addition of QA-primed BCM to primary neurons did aggravate QA-induced excitotoxicity. The exacerbation of QA-induced excitotoxicity by BCM was partially ameliorated by inhibiting NF-κB and microglia activation. QA induced activation of NF-κB and upregulation of TNF-α in BV-2 cells. Addition of recombinant TNF-α mimicked QA-induced excitotoxic effects on neurons, and neutralizing TNF-α with specific antibodies partially abolished exacerbation of QA-induced excitotoxicity by BCM. These studies suggested that QA activated microglia and upregulated TNF-α through NF-κB pathway in microglia. The microglia-mediated inflammatory pathway contributed, at least in part, to QA-induced excitotoxicity.

Greater stress protein expression enhanced by combined prostaglandin A1 and lithium in a rat model of focal ischemia.

AIM: To investigate the effects of lithium (Li) and prostaglandin A1 (PGA1) on the expression of heat shock factor 1 (HSF-1), heat shock proteins (HSP), and apoptosis protease activating factor-1 (Apaf-1) induced by permanent focal ischemia in rats. METHODS: The rats were pretreated with a subcutaneous (sc) injection of Li for 2 d or a single intracerebral ventricle (icv) administration of PGA1 for 15 min before ischemic insult, or a combination of Li (sc, 1 mEq/kg, 2 d) and PGA1 (icv, 15 min prior to ischemic insult). Brain ischemia was induced by the permanent middle cerebral artery occlusion (pMCAO). Twenty-four hours after the occlusion, the expression of HSF-1, HSP, and Apaf-1 in the ischemic striatum were examined with Western blot analysis. RESULTS: The expression of HSF-1, heme oxygenase-1 (HO-1), HSP90alpha, and Apaf-1 were significantly increased, but the expression of HSP90beta was significantly decreased 24 h after the pMCAO. PGA1 and Li and their combination significantly enhanced the ischemia-induced elevation in the levels of HSF-1, HO-1, and HSP90alpha, and recovered HSP90beta expression, but decreased Apaf-1 levels in the ischemic striatum. CONCLUSION: The present study demonstrates that PGA1 and Li have synergistic effects on the enhancement of the expression of HSP, suggesting that the synergistic effects of PGA1 and Li in the rat model of permanent focal cerebral ischemia may be mediated by the enhancement expression of HSP expression and the downregulation of Apaf-1. Our studies suggest that combined PGA1 and Li may have potential clinical value for the treatment of stroke.