GLYCOGEN AND GLYCOGEN PHOSPHORYLASE IN THE CEREBRAL CORTEX OF MICE UNDER THE INFLUENCE OF METHIONINE SULPHOXIMINE

Abstract— Glucose and glycogen levels in the mouse cerebral cortex in vivo were studied after recovery from methionine sulphoximine seizures. The animals appeared normal 24 h after methionine sulphoximine administration but both glucose and glycogen still persisted at higher levels 72 h after injection (by 64 and 275 per cent, respectively). When seizures were prevented by methionine, the increase in glucose and glycogen at the longer time intervals was significantly smaller than in animals treated with methionine sulphoximine only; glucose reached normal values at 48 or 72 h; the accumulation of glycogen was reduced by about three to five times, but after 72 h the levels were still significantly higher than in control animals (67 or 32 per cent increase, depending on the administered dose of methionine). In contrast to the considerable accumulation of glycogen after administration of methionine sulphoximine in vivo, it had no effect on the level of glycogen in brain cortex slices in vitro. After 3 h incubation in the absence of methionine sulphoximine, glycogen was resynthesized to a level of about 4 μmol/g wet tissue and this value was not significantly affected by the presence of various concentrations of methionine sulphoximine in the incubation medium (10^-5 to 10^-2 M). The total (a+b forms) phosphorylase activity of mouse cerebral cortex in vivo after methionine sulphoximine administration was not affected. The fraction of active phosphorylase was reduced by about 50 per cent at the time of seizures. When seizures were prevented by methionine, the decrease in active phosphorylase was also completely prevented. In the preconvulsive period (1-2 h) and after recovery from the seizures (48 h after methionine sulphoximine administration) active phosphorylase was normal. The possible mechanisms involved in the increased accumulation of glycogen after methionine sulphoximine administration are discussed.     

CEREBRAL METABOLIC CHANGES IN PROFOUND, INSULIN-INDUCED HYPOGLYCEMIA, AND IN THE RECOVERY PERIOD FOLLOWING GLUCOSE ADMINISTRATION

Severe hypoglycemia was induced by insulin in lightly anaesthetized (70°_o N₂O) and artificially ventilated rats. Brain tissue was frozen in situ after spontaneous EEG potentials had disappeared for 5. 10. 15 or 30 min and cerebral cortex concentrations of labile organic phosphates, glycolytic metabolites, ammonia and amino acids were determined. In other experiments, recovery was induced by glucose injection at the end of the period of EEG silence. All animals with an isoelectric EEG showed extensive deterioration of the cerebral energy state. and gross perturbation of amino acid concentrations. The latter included a 4-fold rise in aspartate concentration and reductions in glutamate and glutamine concentrations to 20 and 5^o_o of control levels respectively. There was an associated rise in ammonia concentration to about 3μmol-g^-1. Administration of glucose brought about extensive recovery of cerebral energy metabolism. For example, after an isoelectric period of 30 min tissue concentrations of phosphocreatine returned to or above normal, the accumulation of ADP and AMP was reversed, there was extensive resynthesis of glycogen and glutamine and full normalisation of tissue concentrations of pyruvate. α-ketoglutarate. GABA and ammonia. However, even after 3 h of recovery there was a reduction in the ATP concentration and thereby in adenine nucleotide pool, moderate elevations of lactate content and the lactate pyruvate ratio, and less than complete restoration of the amino acid pool. It is concluded that some cells may have been irreversibly damaged by the hypoglycemia.     

PATTERNS OF CHANGES IN BRAIN CARBOHYDRATE METABOLITES, AMINO ACIDS AND ORGANIC PHOSPHATES AT INCREASED CARBON DIOXIDE TENSIONS

—In order to study the time course of changes in cerebral metabolites in hypercapnia, anaesthetized and artificially ventilated rats were exposed to 11% CO₂ for 5, 15, 45, 90 and 180 min. In addition, the effect of anaesthetic levels of carbon dioxide was studied by exposing animals to 30 and 50% CO₂ for 45 min. In none of the groups were there significant changes in ATP, ADP or AMP, and a normal energy state was therefore obtained even in short-lasting hypercapnia, and at anaesthetic CO₂ concentrations (50% CO₂). In the group exposed to 11% CO₂ for 5 min there was a fall in glycogen but normalization occurred when the hypercapnia was prolonged. There were no changes in fructose 1,6-diphosphate, dihydroxyacetone phosphate or 3-phosphoglycerate but decreases in pyruvate, lactate, citrate, α-oxoglutarate, malate and glutamate at all exposure times. With 30 and 50% CO₂ glucose 6-phosphate accumulated. The results do not support the view that the depletion of pyruvate and of citric acid cycle intermediates is caused by H⁺-inhibition of rate-limiting enzymatic steps like the phosphofructokinase reaction. The glutamate concentration fell progressively during exposure to 11% CO₂. In the 5 and 15 min groups aspartate increased significantly indicating that the initial loss of glutamate was partly due to transamination to aspartate. With prolonged hypercapnia there was a secondary fall in aspartate to subnormal values. At 45 min and thereafter the glutamine concentration increased significantly. However, the sum of glutamate, aspartate and glutamine fell progressively after the initial 5 min period. Hypercapnia gave rise to similar increases in the lactate/pyruvate and malate/oxaloacetate ratios, and since the calculated NADH/NAD⁺ ratios remained close to normal in all groups, the results indicate that pH-dependent shifts occurred in the lactate and malate dehydrogenase equilibria.