The effect of depletion of reduced glutathione (GSH) on brain mitochondrial function and N-acetyl aspartate concentration has been investigated. Using pre-weanling rats, GSH was depleted by L-buthionine sulfoximine administration for up to 10 days. In both whole brain homogenates and purified mitochondrial preparations complex IV (cytochrome c oxidase) activity was decreased, by up to 27%, as a result of this treatment. In addition, after 10 days of GSH depletion, citrate synthase activity was significantly reduced, by 18%, in the purified mitochondrial preparations, but not in whole brain homogenates, suggesting increased leakiness of the mitochondrial membrane. The whole brain N-acetyl aspartate concentration was also significantly depleted at this time point, by 11%. It is concluded that brain GSH is important for the maintenance of optimum mitochondrial function and that prolonged depletion leads also to loss of neuronal integrity. The relevance of these findings to Parkinson's disease and the inborn errors of glutathione metabolism are also discussed.
The influence of 6-phosphofructo-1-kinase on glycolytic flux in the yeast Saccharomyces cerevisiae was assessed by measuring the effects of enzyme overexpression on glucose consumption, ethanol production, and glycolytic intermediate levels under aerobic and anaerobic conditions. Enzyme overexpression had no effect on glycolytic flux under anaerobic conditions, but under aerobic conditions, it increased glycolytic flux up to the anaerobic level. The Pasteur effect was thus abolished in these cells. The increased glycolytic flux was accompanied by a compensatory decrease in flux in oxidative phosphorylation. The concentrations of the enzyme substrates showed only small or insignificant changes. These data imply that the enzyme has a low flux control coefficient for glycolysis. However, in cells overexpressing the enzyme, there was a compensatory decrease in 6-phosphofructo-2-kinase activity which was accompanied by a corresponding decrease in fructose 2,6-bisphosphate concentration. Measurements in vitro showed that the decrease in the concentration of this positive allosteric effector of 6-phosphofructo-1-kinase could significantly lower its specific activity in the cell and that this could compensate for the increased enzyme concentration in the overproducer.
Marked abnormalities of the magnetic resonance intensity of N‐acetylaspartate (NAA) have been reported in patients with various neurological disorders, but the neurochemical consequences of these alterations are difficult to assess because the function of NAA remains speculative. The purpose of this study was to examine whether NAA plays a role in protecting neurons against osmotic stress. Intracerebral microdialysis was used to expose a small region of the rat dorsolateral striatum to an increasingly hyposmotic environment and to measure resulting changes in NAA extracellular concentrations. NAA changes in the extracellular fluid (ECF) were compared with those of the amino acids, in particular, taurine, known to be involved in brain osmoregulation. Stepped increases in cellular hydration produced by hyposmotic perfusion media induced a marked increase in ECF NAA, reflecting a redistribution of NAA from intra‐to extracellular space. Parallel experiments showed that, of all the extracellular amino acids measured, only taurine markedly increased with hyposmolar perfusion medium, indicating that the ECF NAA increase associated with hyposmotic stress was a specific response and not passive leakage out of the cells. As NAA is predominantly neuronal, it may contribute to the protection of neurons against swelling (i.e., regulatory volume decrease). In conditions with impaired blood‐brain barrier and cytotoxic oedema, efflux of intracellular NAA subsequent to sustained cellular swelling might lead to a reduction in total brain NAA detectable by magnetic resonance spectroscopy. Alternatively, redistribution of NAA from intra‐to extracellular space implies changes in its chemical environment that may alter its magnetic resonance visibility.
The effects of 1‐methyl‐4‐phenylpyridinium (MPP+) on the oxygen consumption, ATP production, H2O2 production, and mitochondrial NADH‐CoQ1 reductase (complex I) activity of isolated rat brain mitochondria were investigated. Using glutamate and malate as substrates, concentrations of 10–100 µM MPP+ had no effect on state 4 (−ADP) respiration but decreased state 3 (+ADP) respiration and ATP production. Incubating mitochondria with ADP for 30 min after loading with varying concentrations of MPP+ produced a concentration‐dependent decrease in H2O2 production. Incubation of mitochondria with ADP for 60 min after loading with 100 µM MPP+ caused no loss of complex I activity after washing of MPP+ from the mitochondrial membranes. These data are consistent with MPP+ initially binding specifically to complex I and inhibiting both the flow of reducing equivalents and the production of H2O2 by the mitochondrial respiratory chain, without irreversibly damaging complex I. However, mitochondria incubated with H2O2 in the presence of Cu2+ ions showed decreased complex I activity. This study provides additional evidence that cellular damage initiated by MPP+ is due primarily to energy depletion caused by specific binding to complex I, any increased damage due to free radical production by mitochondria being a secondary effect.
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