Neurotrophins play important roles in neuronal differentiation and survival to optimize neuronal development. It has been shown previously that expressions of neurotrophins and their receptors can be facilitated by depolarization. We herein postulated that excitatory glutamate receptors might serve as a physiological trigger to mediate neurotrophin receptor expressions in developing neurons. In the primary cultured cortical neurons at 5 days in vitro, we found that surface expression of neurotrophin receptors TrkA was significantly increased by glutamate receptor subtype agonists, kainate (KA) and α-amino-3-hydroxy-5-methyl-4-isopropionate (AMPA) at 50μM concentration. No significant changes in cytosolic TrkA expression upon each glutamate receptor agonists stimulation suggesting that the increase of surface expression is not due to cytosol-surface translocation. Furthermore, the kainate-increased TrkA expression was significantly reduced by calcium / calmodulin dependent protein kinaseⅡ (CaMKⅡ) inhibitor KN-93. KN-93 also increased neuronal death when added to the kainate-treated neurons, suggesting that neurotrophic activity of kainate is acting upon CaMKⅡ. We further examined if kainate could induce phosphorylation of cAMP response element binding protein (CREB), one of the potential targets activated by CaMKⅡ. CREB phosphorylation in nuclear fraction was significantly increased during kainate stimulation with no change of total level of CREB. However, KN-93, by itself reduced CREB phosphorylation, did not block kainate-induced CREB phosphorylation. Phospho-CREB decreased after kainate stimulation was removed, and increased after KN-93 was removed. However, removal of KN-93 plus kainate still resulted in decrease of CREB phosphorylation. These results suggest that kainate-increased TrkA expression mediated by CaMKⅡ may act upon activation of transcription factors other than CREB. Lastly, application of inhibitors of TrkA downstream mitogen-activated protein (MAP) kinase and phosphoinositol-3 (PI-3) kinase pathways to block kainate-induced neurotrophic activity possibly mediated by TrkA activation was performed. It was shown that 40nM wortmannin, a specific of PI3 kinase inhibitor, but not 20?M PD98059, a specific MAP kinase inhibitor, significantly increased neuronal death when applied with kainate. In summary, activation of glutamate receptors, especially the kainate receptor, can induce TrkA expression via CaMK activation in developing cortical neurons. Increased TrkA level leads to neuronal protection via PI3 kinase pathway to survive neurons from various insults to optimize neuronal development.