The cellular context determines the effect of melatonin on the survival of cerebellar granule cells

Several neurons constitutively express NF-?B, which plays some physiological roles, besides the well-known control of pathological responses. Melatonin, the hormone produced by the pineal gland rhythmically in the dark phase is also an autocrine and paracrine factor of immune competent cells, involved in multiple biological processes and the cytoprotective action is a highlight of this molecule. Melatonin inhibits the nuclear translocation of NF-?B and the expression of iNOS in models of cell damage. The present study evaluated whether the cytoprotective effect of melatonin depends on the state of activation of NF-?B in cultured cerebellar granule cells, given that these cells have a basal activity of this transcription factor essential for cell survival. Moreover, we questioned whether these cells in culture produce melatonin and whether it would have a cytoprotective role. We tested the viability of the rat (7-8 days old Wistar) cerebellar granule cell culture after 24 h incubation with melatonin in the presence or absence of LPS. In basal condition melatonin decreased cell survival while inhibited cell death induced by LPS. These effects were consistent with the results from the activation of NF-?B and the expression of iNOS. In the presence of LPS melatonin blocked the activation of the NF-?B , the expression of iNOS and the production of NO. When only melatonin was incubated, we observed a transient reduction (15 min) of NF-?B nuclear content, followed by an increase of its nuclear content (60 min). The iNOS expression followed the same profile, i.e. undergone a transient inhibition (30 min), followed by an increase above baseline after 120 min of incubation. Therefore, we have demonstrated that melatonin affects differently the viability of cerebellar granule cells depending on the context. Furthermore, we founded evidences that the granule cells in culture express the key enzyme in the synthesis of melatonin, AA-NAT and produce melatonin, which carries protective function for the culture. Our data provide a mechanistic basis for understanding the influence of cell context on the final output response to melatonin (AU)