Methionine sulfoximine prevents the accumulation of large neutral amino acids in brain of hyperammonemic rats

Methionine sulfoximine, a glutamine synthetase inhibitor, attenuates increased extracellular potassium activity during acute hyperammonemia

Hyperammonemia causes glutamine accumulation and astrocyte swelling. Inhibition of glutamine synthesis reduces ammonia-induced edema formation and watery swelling in astrocyte processes. Ordinarily, astrocytes tightly control extracellular K+ activity [K+]e. We tested the hypothesis that acute hyperammonemia interferes with this tight regulation such that [K+]e increases and that inhibition of glutamine synthetase reduces this increase in [K+]e. Ion-sensitive microelectrodes were used to measure [K+]e in parietal cortex continuously over a 6-h period in anesthetized rats. After i.v. sodium acetate infusion in eight control rats, plasma ammonia concentration was 33 +/- 26 mumol/L (+/- SD) and [K+]e remained stable at 4.3 +/- 1.6 mmol/L. During ammonium acetate infusion in nine rats, plasma ammonia increased to 594 +/- 124 mumol/L at 2 h and to 628 +/- 135 mumol/L at 6 h. There was a gradual increase in [K+]e from 3.9 +/- 0.7 to 6.8 +/- 2.7 mmol/L at 2 h and 11.8 +/- 6.7 mmol/L at 6 h. In eight rats, L-methionine-D,L-sulfoximine (150 mg/kg) was infused 3 h before ammonium acetate infusion to inhibit glutamine synthetase. At 2 and 6 h of ammonium acetate infusion, plasma ammonia concentration was 727 +/- 228 and 845 +/- 326 mumol/L, and [K+]e was 4.5 +/- 1.9 and 6.1 +/- 3.8 mmol/L, respectively. The [K+]e value at 6 h was significantly less than that obtained with ammonium acetate infusion alone but was not different from that obtained with sodium acetate infusion. We conclude that acute hyperammonemia impairs astrocytic control of [K+]e and that this impairment is linked to glutamine accumulation rather than ammonium ions per se.

Changes in the permeability of the blood-brain barrier in acute hyperammonemia. Effect of dexamethasone

This study was designed to determine the contribution of elevated plasma ammonia levels to blood-brain barrier (BBB) abnormalities in the presence of intact liver. The permeability changes of the BBB were investigated grossly with Evans blue (EB) and quantitatively by measuring the blood-to-brain transfer content for alpha-aminoisobutyric acid (AIB) in normal rats and rats subjected to sublethal doses of ammonium acetate (NH4OAc) (750 and 600 mg/kg ip; at 30-min intervals). Some rats were pretreated with dexamethasone (DXN). Injection of NH4OAc increased both plasma and brain ammonia concentrations about 16-and 5-fold, respectively, above the control level. In rats receiving NH4OAc injection, the blood-to-brain transfer constant (Ki) for AIB was increased 3- to 11-fold. The elevated Ki values were limited to certain gray matter areas and less pronounced permeability changes were detected in white matter. Extravasation sites of EB were more restricted and were especially observed in thalamus and cerebellum, whereas cortex and white matter were unaffected. Dexamethasone pretreatment for 3 d reduced both leakage of EB and the Ki for AIB in NH4OAc injected animals, whereas acute treatment appeared ineffective. Dexamethasone did not prevent the development of coma but slightly decreased the ammonia concentration in plasma and brain. The results obtained indicate that hyperammonemia may disrupt BBB integrity not only to AIB and EB but also enhance the transport of other solutes.

Effect of reducing brain glutamine synthesis on metabolic symptoms of hepatic encephalopathy

Liver failure, or shunting of intestinal blood around the liver, results in hyperammonemia and cerebral dysfunction. Recently it was shown that ammonia caused some of the metabolic signs of hepatic encephalopathy only after it was metabolized by glutamine synthetase in the brain. In the present study, small doses of methionine sulfoximine, an inhibitor of cerebral glutamine synthetase, were given to rats either at the time of portacaval shunting or 3-4 weeks later. The effects on several characteristic cerebral metabolic abnormalities produced by portacaval shunting were measured 1-3 days after injection of the inhibitor. All untreated portacaval-shunted rats had elevated plasma and brain ammonia concentrations, increased brain glutamine and tryptophan content, decreased brain glucose consumption, and increased permeability of the blood-brain barrier to tryptophan. All treated rats had high ammonia concentrations, but the brain glutamine content was normal, indicating inhibition of glutamine synthesis. One day after shunting and methionine sulfoximine administration, glucose consumption, tryptophan transport, and tryptophan brain content remained near control values. In the 3-4-week-shunted rats, which were studied 1-3 days after methionine sulfoximine administration, the effect was less pronounced. Brain glucose consumption and tryptophan content were partially normalized, but tryptophan transport was unaffected. The results agree with our earlier conclusion that glutamine synthesis is an essential step in the development of cerebral metabolic abnormalities in hyperammonemic states.

Hyperammonaemia does not impair brain function in the absence of net glutamine synthesis

1. It has been established that chronic hyperammonaemia, whether caused by portacaval shunting or other means, leads to a variety of metabolic changes, including a depression in the cerebral metabolic rate of glucose (CMRGlc) increased permeability of the blood-brain barrier to neutral amino acids, and an increase in the brain content of aromatic amino acids. The preceding paper [Jessy, DeJoseph & Hawkins (1991) Biochem. J. 277, 693-696] showed that the depression in CMRGlc caused by hyperammonaemia correlated more closely with glutamine, a metabolite of ammonia, than with ammonia itself. This suggested that ammonia (NH3 and NH4+) was without effect. The present experiments address the question whether ammonia, in the absence of net glutamine synthesis, induces any of the metabolic symptoms of cerebral dysfunction associated with hyperammonaemia. 2. Small doses of methionine sulphoximine, an inhibitor of glutamine synthetase, were used to raise the plasma ammonia levels of normal rats without increasing the brain glutamine content. These hyperammonaemic rats, with plasma and brain ammonia levels equivalent to those known to depress brain function, behaved normally over 48 h. There was no depression of cerebral energy metabolism (i.e. the rate of glucose consumption). Contents of key intermediary metabolites and high-energy phosphates were normal. Neutral amino acid transport (tryptophan and leucine) and the brain contents of aromatic amino acids were unchanged. 3. The data suggest that ammonia is without effect at concentrations less than 1 mumol/ml if it is not converted into glutamine. The deleterious effect of chronic hyperammonaemia seems to begin with the synthesis of glutamine.

Methionine sulfoximine intensifies cancer anorexia

Consistent anorexia was first observed 33 days after inoculating Fischer 344 rats with methylcholanthrene-induced sarcoma. Daily treatment of a similar group of rats with the glutamine synthetase inhibitor, methionine sulfoximine, elicited significant reductions of feeding by day 29 at a dose that had no effect on nontumor-bearing rats. Blood concentrations of ammonia were elevated in both groups of tumor-bearing rats and brain ammonia level was increased in the methionine sulfoximine-treated tumor-bearing rats. Forebrain concentrations of tyrosine, tryptophan, DOPAC and 5-HIAA were elevated in both groups of tumor-bearing rats. Since ammonia is detoxified through the glutamine synthetase reaction, these results suggest that blood and brain ammonia concentrations are more important than the neurochemical consequences of ammonia detoxification for the etiology of cancer anorexia.

Hyperammonaemia causes many of the changes found after portacaval shunting

1. Portacaval shunting in rats results in several metabolic alterations similar to those seen in patients with hepatic encephalopathy. The characteristic changes include: (a) diminution of cerebral function; (b) raised plasma ammonia and brain glutamine levels; (c) increased neutral amino acid transport across the blood-brain barrier; (d) altered brain and plasma amino acid levels; and (e) changes in brain neurotransmitter content. The aetiology of these abnormalities remains unknown. 2. To study the degree to which ammonia could be responsible, rats were made hyperammonaemic by administering 40 units of urease/kg body weight every 12 h and killing the rats 48 h after the first injection. 3. The changes observed in the urease-treated rats were: (a) whole-brain glucose use was significantly depressed, whereas the levels of high-energy phosphates remained unchanged; (b) the permeability of the blood-brain to barrier to two large neutral amino acids, tryptophan and leucine, was increased; (c) blood-brain barrier integrity was maintained, as indicated by the unchanged permeability-to-surface-area product for acetate; (d) plasma and brain amino acid concentrations were altered; and (e) dopamine, 5-hydroxytryptamine (serotonin) and noradrenaline levels in brain were unchanged, but 5-hydroxyindoleacetic acid (5-HIAA), a metabolite of 5-hydroxytryptamine, was elevated. 4. The depressed brain glucose use, increased tryptophan permeability-to-surface-area product, elevated brain tryptophan content and rise in the level of cerebral 5-HIAA were closely correlated with the observed rise in brain glutamine content. 5. These results suggest that many of the metabolic alterations seen in rats with portacaval shunts could be due to elevated ammonia levels. Furthermore, the synthesis or accumulation of glutamine may be closely linked to cerebral dysfunction in hyperammonaemia.

The effects of ammonia tolerance tests on the cerebrospinal fluid concentrations of amino acids and indoleamines in patients with liver cirrhosis

To study the effect of ammonia administration on amino acids and indoleamines in cerebrospinal fluid (CSF) and on amino acids, insulin, and glucagon in plasma in humans with liver cirrhosis, we performed seven ammonia tolerance tests on six patients with stable liver cirrhosis. The grade of encephalopathy was determined by psychometric tests. Only one of the patients had pronounced encephalopathy. The other patients had no or only slight encephalopathy. The plasma concentrations of valine, leucine, isoleucine, phenylalanine, tyrosine, and methionine decreased after the ammonia load, whereas no changes were found in the plasma concentrations of glucagon and insulin. In CSF the concentrations of glutamine, aromatic amino acids, and indoleamines increased only in the patient who had pronounced encephalopathy, whereas no changes were found in the other patients. The effect of an ammonia load on the concentrations of neutral amino acids in CSF in patients with pronounced encephalopathy remains to be demonstrated.

Serotonin- and catecholamine-related substances in the brain of ornithine transcarbamylase-deficient Sparse-fur mice in the hyperammonemic state: comparison of two procedures for obtaining brain extract, decapitation and microwave irradiation

Increased flux through the 5-HT pathway during hyperammonemia was indicated by a significant positive correlation between Gln concentration and the ratio of 5-HIAA to 5-HT in the brain of spf mice taken after microwave irradiation to prevent postmortem changes in metabolites. There were no significant changes in the catecholamine pathway in the brain during hyperammonemia despite the increases in Try and Phe.

Accumulation of large neutral amino acids in the brain of sparse-fur mice at hyperammonemic state

Sparse-fur mice which are deficient in ornithine transcarbamylase, the second-step enzyme in the urea cycle, were examined for hyperammonemia and its relationship with encephalopathy. We compared amino acid concentrations in the serum and brain of spf mice with those of control mice. Unlike hepatic encephalopathy we could not find marked amino acid changes in the serum of spf mice besides low levels of citrulline and arginine. But in the brain of spf mice, glutamine was increased strikingly during hyperammonemia, and a concomitant accumulation of large neutral amino acids such as tyrosine, phenylalanine, methionine, and histidine was observed. The accumulation of these large neutral amino acids in the brain was not influenced by 24-hr fasting which caused increases in branched chain amino acids in the serum. From these results, we conclude that the accumulation of the large neutral amino acid in the brain of hyperammonemic state is caused by uptake of ammonia in the brain and the subsequent accumulation of glutamine, but is not influenced by a decreased ratio of branched chain amino acids to aromatic amino acids in the serum.

Stimulation of tryptophan uptake into brain microvessels by D-glutamine

The uptake of L-tryptophan into isolated porcine microvessels is increased by preincubation with L-glutamine as well as with D-glutamine. This could indicate that gamma-glutamyltranspeptidase is involved in the stimulation of uptake of large neutral amino acids into the brain observed in hyperammonemic conditions.

Effect of hyperammonemia and methionine sulfoximine on the kinetic parameters of blood-brain transport of leucine and phenylalanine

The activity of the blood-brain neutral amino acid transport system is increased in rats infused with ammonium salts or rendered hyperammonemic by a portacaval anastomosis. This effect may be due to a direct action of ammonia or to some metabolic consequence of high ammonia levels, such as increased brain glutamine synthesis. To test these possibilities we evaluated the kinetic parameters of blood-brain transport of leucine and phenylalanine in control rats, in rats after continuous 24 h infusion of ammonium salts (NH4+ = 2.5 mmol X kg-1 X h-1), and in rats treated with methionine sulfoximine, an inhibitor of glutamine synthetase, before infusion of ammonium salts. In ammonia-infused rats without methionine sulfoximine treatment, the KD and Vmax of phenylalanine transport were increased, respectively, about 170% and 80% compared to controls, whereas the Km and Vmax of leucine transport were increased, respectively, about 100% and 200%. Electron microscopy demonstrated marked swelling of astrocytic processes around brain capillaries of ammonia-infused rats; however, capillary permeability to horseradish peroxidase apparently was not increased by ammonia infusion. Administration of methionine sulfoximine before ammonia infusion inhibited glutamine synthesis and prevented the changes in transport of leucine and phenylalanine, but apparently did not reverse the perivascular swelling. These results suggest that the ammonia-induced increase in the activity of transport of large neutral amino acids across the blood-brain barrier requires glutamine synthesis in brain, and is not a direct effect of ammonia.

Methionine sulfoximine prevents the accumulation of large neutral amino acids in brain of portacaval-shunted rats

Portal-systemic shunting and hyperammonemia lead to an accumulation of the large neutral amino acids in brain and apparently alter transport of neutral amino acids across the blood-brain barrier. It has been proposed that portal-systemic shunting leads to a high brain concentration of glutamine, a product of cerebral ammonia detoxification, and thereby affects the transport of other neutral amino acids across the blood-brain barrier. To test this hypothesis, rats with a portacaval shunt were treated with L-methionine-dl-sulfoximine (MSO), an inhibitor of glutamine synthesis. Treatment with MSO resulted in lower concentrations of the neutral amino acids in brain of portacaval-shunted rats and a higher brain ammonia concentration, compared with untreated shunted rats. These results suggest that the accumulation of neutral amino acids in brain after portacaval shunt depends on the increased synthesis of glutamine in brain.