The metabolism of [15N]glutamate was studied with gas chromatography-mass spectrometry in rat brain synaptosomes incubated with and without glucose. [15N]Glutamate was taken up rapidly by the preparation, reaching a steady-state level in less than 5 min. 15N was incorporated predominantly into aspartate and, to a much lesser extent, into gamma-aminobutyrate. The amount of [15N]ammonia formed was very small, and the enrichment of 15N in alanine and glutamine was below the level of detection. Omission of glucose substantially increased the rate and amount of [15N]aspartate generated. It is proposed that in synaptosomes (a) the predominant route of glutamate nitrogen disposal is through the aspartate aminotransferase reaction; (b) the aspartate aminotransferase pathway generates 2-oxoglutarate, which then serves as the metabolic fuel needed to produce ATP; (c) utilization of glutamate via transamination to aspartate is greatly accelerated when flux through the tricarboxylic acid cycle is diminished by the omission of glucose; (d) the metabolism of glutamate via glutamate dehydrogenase in intact synaptosomes is slow, most likely reflecting restriction of enzyme activity by some unknown factor(s), which suggests that the glutamate dehydrogenase reaction may not be near equilibrium in neurons; and (e) the activities of alanine aminotransferase and glutamine synthetase in synaptosomes are very low.
Treatment of rat brain synaptosomes with 10 microM monensin stimulated activity of the Na/K pump, which enhanced oxygen consumption and lactate production. Glycolytic flux was also increased independently of the pump activation by a fall in [H+]i. Under such conditions, glycolysis provided 26% of ATP for the ouabain-sensitive ATPase, a value substantially greater than the 4% obtained in veratridine-treated preparations (Erecińska and Dagani, 1990). In C6 glioma cells, a glia-derived line endowed with high rates of aerobic lactate synthesis, the cytosolic and mitochondrial ATP generation contributed 50% each for the support of the pump in the presence of 10 microM monensin. The fraction of energy utilized by the pump was greater in synaptosomes than in C6 cells. Enhancement of ion movements was accompanied by changes in the levels of high-energy phosphate compounds. Measurements with ion-sensitive microelectrodes in C6 cells and cultured neurons showed that monensin caused an increase in pHi by 0.4-0.5 unit and a parallel rise in [Na+]i. The increases in [Na+]i were about twofold in both types of cells, but the absolute values attained were much higher in neurons (40-50 mM) than in C6 cells (10-12 mM). Membrane potentials transiently declined by less than 10 mV and returned to their original values after 20 min of treatment. Rises in [Ca2+]i were small in neurons as well as in C6 cells. These changes could be explained by the known mechanism and/or consequences of monensin action. In contrast, in synaptosomes monensin caused an internal alkalinization of 0.1-0.15 pH unit, a large depolarization of the plasma membrane, and massive leakage of potassium into the external medium. The decrease in plasma membrane potential was accompanied by an increase in [Ca/+]i and release of the neurotransmitter amino acids GABA, aspartate, and glutamate. The depolarization and loss of K+ were unaffected by calcium withdrawal, replacement of chloride with gluconate, and addition of 1 mM 4-acetamido-4'-isothiocyanostilebene-2,2'-disulfonic acid (SITS), but was markedly attenuated by elimination of Na+. It is proposed that in synaptosomes monensin and/or the consequences of its action open a nonspecific cation channel that allows Na+ entry and K+ exit, with a consequent decrease in membrane potential.
The relationships between Na/K pump activity and adenosine triphosphate (ATP) production were determined in isolated rat brain synaptosomes. The activity of the enzyme was modulated by altering [K+]e, [Na+]i, and [ATP]i while synaptosomal oxygen uptake and lactate production were measured simultaneously. KCI increased respiration and glycolysis with an apparent Km of about 1 mM which suggests that, at the [K+]e normally present in brain, 3.3-4 mM, the pump is near saturation with this cation. Depolarization with 6-40 mM KCI had negligible effect on ouabain-sensitive Oi uptake indicating that at the voltages involved the activity of the Na/K ATPase is largely independent of membrane potential. Increases in [Na+]i by addition of veratridine markedly enhanced glycoside-inhibitable respiration and lactate production. Calculations of the rates of ATP synthesis necessary to support the operation of the pump showed that >90% of the energy was derived from oxidative phosphorylation. Consistent with this: (a) the ouabain-sensitive Rb/O~ ratio was close to 12 (i.e., Rb/ATP ratio of 2); (b) inhibition of mitochondrial ATP synthesis by Amytal resulted in a decrease in the glycoside-dependent rate of 86Rb uptake. Analyses of the mechanisms responsible for activation of the energy-producing pathways during enhanced Na and K movements indicate that glycolysis is predominantly stimulated by increase in activity of phosphofructokinase mediated via a rise in the concentrations of adenosine mono-
Oxygen consumption and enzyme activity were evaluated in platelet mitochondria from 17 patients with Parkinson's disease. In comparison with age-matched controls, no consistent abnormality could be discerned in complex I, complex II-III, or complex IV oxygen consumption, or in the enzyme activity of these respiratory chain complexes. Neither chronic therapy with levodopa/carbidopa alone nor in combination with deprenyl significantly affected any measure of mitochondrial respiratory function. There was no discernible relationship between patient age or disease severity and any parameter of mitochondrial respiration. Moreover, blood lactate levels following glucose loading were not different in patients and controls. These results fail to support the occurrence of a generalized defect in any mitochondrial respiratory function in Parkinson's disease.
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