Glutamate neurotoxicity in rat cerebellar granule cells: a major role for xanthine oxidase in oxygen radical formation.

To gain insight into the mechanism through which the neurotransmitter glutamate causally participates in several neurological diseases, in vitro cultured cerebellar granule cells were exposed to glutamate and oxygen radical production was investigated. To this aim, a novel procedure was developed to detect oxygen radicals; the fluorescent dye 2',7'-dichlorofluorescein was used to detect production of peroxides, and a specific search for the possible conversion of the enzyme xanthine dehydrogenase into xanthine oxidase after the excitotoxic glutamate pulse was undertaken. A 100 microM glutamate pulse administered to 7-day-old cerebellar granule cells is accompanied by the onset of neuronal death, the appearance of xanthine oxidase, and production of oxygen radicals. Xanthine oxidase activation and superoxide (O2.-) production are completely inhibited by concomitant incubation of glutamate with MK-801, a specific NMDA receptor antagonist, or by chelation of external calcium with EGTA. Partial inhibition of both cell death and parallel production of reactive oxygen species is achieved with allopurinol, a xanthine oxidase inhibitor, leupeptin, a protease inhibitor, reducing agents such as glutathione or dithiothreitol, antioxidants such as vitamin E and vitamin C, and externally added superoxide dismutase. It is concluded that glutamate-triggered, NMDA-mediated, massive Ca2+ influx induces rapid conversion of xanthine dehydrogenase into xanthine oxidase with subsequent production of reactive oxygen species that most probably have a causal involvement in the initial steps of the series of intracellular events leading to neuronal degeneration and death.

Rapid uncoupling of oxidative phosphorylation accompanies glutamate toxicity in rat cerebellar granule cells.

A 100 microM glutamate pulse administered to rat cerebellar granule cells causes a very rapid and progressive decrease in both cell and mitochondrial oxygen consumption caused by glucose and succinate addition, respectively. The respiratory control ratio, which reflects the ability of mitochondria to produce ATP, is reduced by 50% within the first 30 min after glutamate addition. Subsequent to glutamate exposure, a progressive decrease of respiratory control ratio to almost 1 was found within the following 3-5 h. The addition of extra calcium had no effect per se on oxygen consumption by cell homogenate.

Carrier-mediated transport controls hydroxyproline catabolism in heart mitochondria from spontaneously hypertensive rat.

In this study we have investigated hydroxyproline transport in rat heart mitochondria and, in particular, in heart left ventricle mitochondria isolated from both spontaneously hypertensive and Wistar-Kyoto rats. Hydroxyproline uptake by mitochondria, where its catabolism takes place, occurs via a carrier-mediated process as demonstrated by the occurrence of both saturation kinetics and the inhibition shown by phenylsuccinate and the thiol reagent mersalyl. In any case, hydroxyproline transport was found to limit the rate of mitochondrial hydroxyproline catabolism. A significant change in Vmax and Km values was found in mitochondria from hypertensive/hypertrophied rats in which the Km value decreases and the Vmax value increases with respect to normotensive rats, thus accounting for the increase of hydroxyproline metabolism due to its increased concentration in a hypertrophic/hypertensive state.

Glutamine transport in normal and acidotic rat kidney mitochondria.

Glutamine transport in both normal and acidotic rat kidney mitochondria was investigated using both isotopic techniques and by spectroscopic measurements in which glutamine metabolism was allowed to occur. Widely used criteria for demonstrating the occurrence of carrier-mediated transport were successfully applied in both cases. Three transport mechanisms were found to occur, namely glutamine uniport, active only during acidosis and glutamine/glutamate and glutamine/malate antiports, active in both normal and acidotic mitochondria. Efflux of glutamate, via a glutamate/OH- translocator, following glutamine uptake by mitochondria was experimentally ruled out. Glutamine uniport in acidotic mitochondria and glutamine/glutamate and glutamine/malate antiports in both normal and acidotic mitochondria were investigated in detail: differences found in Km and Vmax values, in pH and temperature dependence, and in the pattern of inhibitor sensitivity of glutamine transport demonstrated the existence of five different translocators whose activities were found to fit with the physiological requirements of renal ammoniogenesis.