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mate enters mitochondrial matrix. We tested this hypothesis by coimmunoprecipitating EAAC1/NCX1 complexes in purified hippocampal and cortical mitochondria. In addition, we also studied the pharmacological properties and functional interaction between EAAC1 and NCX1 and our findings support the idea that the close coupling between these transporters regulates glutamate-stimulated mitochondrial ATP production in brain. Similar results were also obtained in isolated heart mitochondria, supporting the idea that selective interaction between EAAC1 and NCX1 may be a rather general mechanism in tissues where both of these transporters are expressed. Results and Discussion Glutamate ability to stimulate ATP synthesis in purified rat brain mitochondria To establish whether glutamate enhances oxidative metabolism by a direct mitochondrial effect, we exposed purified mitochondria from rat hippocampus and cortex, two regions thought to be among the most sensitive to the neurotransmitter, to 1 mM exogenous glutamate. We found that ATP synthesis increased significantly in mitochondria from both regions and that it depended on the activation of oxidative metabolism, as demonstrated by its abrogation by the F1FO-ATP synthase inhibitor oligomycin . To exclude a dependence of glutamate-induced ATP synthesis in mitochondria on possible cytoplasm contamination of our preparations, we performed experiments with glucose, which requires cytosolic 71939-50-9 price glycolytic enzymes and was, as expected, unable to induce ATP synthesis. Moreover we found that in isolated mitochondria lactate dehydrogenase activity was virtually undetectable, strengthening the absence of cytosol contamination. namely GLutamate ASpartate Transporter, Glutamate Transporter 1 and EAAC1. To assess the role of mitochondrial EAATs in sustaining energy metabolism under physiological conditions, we further tested the ability of glutamate to stimulate ATP production even in the presence of other metabolic intermediates such as malate and pyruvate. As shown in EAATs involvement in glutamate-stimulated ATP synthesis Since glutamate transamination to a-ketoglutarate takes place in the mitochondrial matrix, the question arises of how it accesses this compartment. The mechanisms responsible for its transport have been well characterized in the neuronal and glial plasma membrane, leading to identification of a family of highly specialized proteins, the Excitatory Amino Acid Transporters, which are Na-dependent glutamate transporters. Therefore, we explored the possibility that EAATs could also be involved in glutamate transport in brain mitochondria, a process that is held to be mediated by the aspartate/glutamate carriers Aralar/AGC1 and Citrin/AGC2. Interestingly, we found that the glutamate-stimulated ATP synthesis in rat hippocampal and cortical mitochondria was inhibited by the selective non-transportable EAATs blocker DL-TBOA in a dose-dependent manner. In addition, three different EAATs were detected in protein extracts of hippocampal and cortical mitochondria, Glutamate entry into mitochondria is sustained by EAAC1 activity DL-TBOA does not discriminate between GLAST, GLT1 and EAAC1, and, therefore, does not provide any information as ” to which subtype was involved in mediating the effect 15363972” of glutamate on mitochondrial metabolism. However, EAAC1 protein was detected in SH-SY5Y and C6 cell mitochondria where, as in brain, DL-TBOA inhibited glutamate-stimulated ATP synthesis, whereas GLAST mRNA and protei

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Author: GTPase atpase