Prolonged seizures [status epilepticus (SE)] constitute a neurological emergency that can permanently damage the brain. SE results from a failure of the normal mechanisms to terminate seizures; in particular, γ-amino butyric acid-mediated inhibition, and benzodiazepine anticonvulsants are often incompletely effective. ATP acts as a fast neurotransmitter via ionotropic ligand-gated P2X receptors. Here we report that SE induced by intra-amygdala kainic acid in mice selectively increased hippocampal levels of P2X7 receptors relative to other P2X receptors. Using transgenic P2X7 reporter mice expressing enhanced green fluorescent protein, we identify dentate granule neurons as the major cell population transcribing the P2X7 receptor after SE. Pretreatment of mice with an intracerebroventricular microinjection of 1.75 nmol A438079, a P2X7 receptor antagonist, reduced seizure duration by 58% and reduced seizure-induced neuronal death by 61%. Injection of brilliant blue G (1 pmol), another selective antagonist, reduced seizure duration by 48% and was also neuroprotective. A438079 was seizure-suppressive when injected shortly after induction of SE, and coinjection of A438079 with lorazepam 60 min after triggering SE, when electrographic seizure-responsiveness to lorazepam had decreased, also terminated SE. Our results suggest that P2X7 receptor antagonists may be a promising class of drug for seizure abrogation and neuroprotection in SE.
The H؉ -ATP synthase is a reversible engine of mitochondria that synthesizes or hydrolyzes ATP upon changes in cell physiology. ATP synthase dysfunction is involved in the onset and progression of diverse human pathologies. During ischemia, the ATP hydrolytic activity of the enzyme is inhibited by the ATPase inhibitory factor 1 (IF1 In oxidative phosphorylation, ATP is synthesized by the mitochondrial ATP synthase, a H ϩ -driven rotatory engine of the inner membrane that utilizes as driving force for ATP synthesis the H ϩ electrochemical gradient generated by the respiratory chain (1-4). The cellular expression level of -F1-ATPase, 2 which is the catalytic subunit of the H ϩ -ATP synthase, is diminished in diverse human pathologies (5), which include cancer (6 -9), affording a relevant marker of disease progression (6, 7, 10 -12) and of the response to chemotherapy (7,(13)(14)(15). Moreover, the down-regulation of -F1-ATPase in lung carcinomas (12) and colon cancer cells (15) also provides a mechanistic explanation to the increased glucose avidity of carcinomas, i.e. to the enhanced aerobic glycolysis of cancer cells (16,17). Interestingly, the quantitative determination of -F1-ATPase relative to the content of glyceraldehyde-3-phosphate dehydrogenase in human tumors has revealed that cancer abolishes the tissue-specific differences in the cellular complement of the bioenergetic -F1-ATPase protein (18).It is well established that when mitochondrial respiration is impaired, the H ϩ -ATP synthase can function in reverse acting as an ATP hydrolase for maintaining the proton motive force (1,19). This process is regulated by an inhibitor peptide called ATPase inhibitory factor 1 or IF1 (19 -21), a highly conserved nuclearly encoded protein. When matrix pH drops, IF1 becomes activated and binds -F1-ATPase, blocking ATP hydrolysis and preventing a useless waste of energy (20). The substitution of histidine 49 in IF1 by a lysine residue renders a mutant form (H49K) that inhibits the ATP hydrolase activity in a pH-insensitive way (22). The structure and in vitro mechanism of action of IF1 has been studied in detail, and its role as an inhibitor of the hydrolase activity of the H ϩ -ATP synthase is well documented (19,20,23). However, the information on IF1 expression in human tissues and its putative contribution to the development of human pathology are unknown. In this study, we demonstrate that IF1 is overexpressed in human carcinomas. Moreover, we document that IF1 plays a regulatory role in controlling cellular energetic metabolism, strongly supporting its participation as an additional molecular switch used by cancer cells to trigger the induction of aerobic glycolysis, i.e. their Warburg phenotype. 2 The abbreviations used are: -F1-ATPase,  catalytic subunit of the H ϩ -ATP synthase; IF1, ATPase inhibitory factor 1; FCCP, carbonyl cyanide-p-trifluoromethoxyphenylhydrazone; siRNA, small interfering RNA; NRK, normal rat kidney. EXPERIMENTAL PROCEDURES
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