P2Y receptor-activating nucleotides modulate cellular reactive oxygen species production in dissociated hippocampal astrocytes and neurons in culture independent of parallel cytosolic Ca2+ rise and change in mitochondrial potential

Abstract

With mixed cultures of hippocampal astrocytes and neurons, we investigated the influence of nucleotides on cytosolic Ca2+ level, generation of reactive oxygen species (ROS), and mitochondrial potential. We employed ATP and four purine/pyrimidine derivates, which are P2Y receptor subtype-preferring agonists. Stimulation with ATP, a P2Y1/2/4 receptor agonist in rat, caused a large cytosolic Ca2+ increase in astrocytes and a considerably smaller Ca2+ response in neighboring neurons. The P2Y1 receptor antagonist MRS2179 completely blocked the ATP-induced Ca2+ response in astrocytes and neurons. Application of ATP significantly reduced the mitochondrial potential in neurons, which was not inhibited by MRS2179. Interestingly, MRS2179 mediated a mitochondrial depolarization without affecting the cytosolic Ca2+ level. Stimulation with UDP, a P2Y6 receptor agonist; UTP, a P2Y 2/4 receptor agonist; 2MeSATP, a P2Y1 receptor agonist; or 2MeSADP, a P2Y1/12/13 receptor agonist, evoked significant Ca 2+ responses in astrocytes but small Ca2+ responses in neurons. In astrocytes, there was an inverse relationship between the amplitude of the cytosolic Ca2+ peak and the rate of ROS generation in response to nucleotide application. Activation with UDP resulted in the highest ROS generation that we detected, whereas 2MeSADP and 2MeSATP reduced the ROS generation below the basal level. 2MeSADP and UDP caused mitochondrial depolarization of comparable size. Thus, neither in astrocytes nor in neurons did the degree of mitochondrial depolarization correlate with ROS generation. Nucleotides acting via P2Y receptors can modulate ROS generation of hippocampal neurons without acutely changing the cytosolic Ca2+ level. Thus, ROS might function as a signaling molecule upon nucleotide-induced P2Y receptor activation in brain. © 2007 Wiley-Liss, Inc.