Kinetics of glutamine-efflux from liver mitochondria loaded with the 14C-Labeled substrate

Dysregulation of Astrocytic Glutamine Transport in Acute Hyperammonemic Brain Edema

Acute liver failure (ALF) impairs ammonia clearance from blood, which gives rise to acute hyperammonemia and increased ammonia accumulation in the brain. Since in brain glutamine synthesis is the only route of ammonia detoxification, hyperammonemia is as a rule associated with increased brain glutamine content (glutaminosis) which correlates with and contributes along with ammonia itself to hyperammonemic brain edema-associated with ALF. This review focuses on the effects of hyperammonemia on the two glutamine carriers located in the astrocytic membrane: Slc38a3 (SN1, SNAT3) and Slc7a6 (y + LAT2). We emphasize the contribution of the dysfunction of either of the two carriers to glutaminosis- related aspects of brain edema: retention of osmotically obligated water (Slc38a3) and induction of oxidative/nitrosative stress (Slc7a6). The changes in glutamine transport link glutaminosis- evoked mitochondrial dysfunction to oxidative-nitrosative stress as formulated in the “Trojan Horse” hypothesis.

Expression and putative role of mitochondrial transport proteins in cancer

Cancer cells undergo major changes in energy and biosynthetic metabolism. One of them is the Warburg effect, in which pyruvate is used for fermentation rather for oxidative phosphorylation. Another major one is their increased reliance on glutamine, which helps to replenish the pool of Krebs cycle metabolites used for other purposes, such as amino acid or lipid biosynthesis. Mitochondria are central to these alterations, as the biochemical pathways linking these processes run through these organelles. Two membranes, an outer and inner membrane, surround mitochondria, the latter being impermeable to most organic compounds. Therefore, a large number of transport proteins are needed to link the biochemical pathways of the cytosol and mitochondrial matrix. Since the transport steps are relatively slow, it is expected that many of these transport steps are altered when cells become cancerous. In this review, changes in expression and regulation of these transport proteins are discussed as well as the role of the transported substrates. This article is part of a Special Issue entitled Mitochondria in Cancer, edited by Giuseppe Gasparre, Rodrigue Rossignol and Pierre Sonveaux.

Glutamine homeostasis and mitochondrial dynamics

Glutamine is a multifaceted amino acid that plays key roles in many metabolic pathways and also fulfils essential signaling functions. Although classified as non-essential, recent evidence suggests that glutamine is a conditionally essential amino acid in several physiological situations. Glutamine homeostasis must therefore be exquisitely regulated and mitochondria represent a major site of glutamine metabolism in numerous cell types. Glutaminolysis is mostly a mitochondrial process with repercussions in organelle structure and dynamics suggesting a tight and mutual control between mitochondrial form and cell bioenergetics. In this review we describe an updated account focused on the critical involvement of glutamine in oxidative stress, mitochondrial dysfunction and tumour cell proliferation, with special emphasis in the initial steps of mitochondrial glutamine pathways: transport into the organelle and hydrolytic deamidation through glutaminase enzymes. Some controversial issues about glutamine catabolism within mitochondria are also reviewed.

Role of mitochondrial glutaminase in rat renal glutamine metabolism

During normal acid-base balance, the kidney extracts very little of the plasma glutamine. However, during metabolic acidosis, as much as one third of the plasma glutamine is extracted and metabolized in a single pass through this organ. The substantial increase in renal utilization occurs solely within the proximal convoluted tubule and is sustained by compensating adaptations in the intraorgan metabolism of glutamine. The primary pathway for renal glutamine metabolism involves its transport into mitochondria and its deamidation and deamination by glutaminase (GA) and glutamate dehydrogenase (GDH), respectively. The resulting ammonium ions are excreted predominantly in the urine where they function as expendable cations to facilitate the excretion of acids. The resulting alpha-ketoglutarate is further metabolized to phosphoenolpyruvate and subsequently to glucose or CO2. The intermediate steps yield two bicarbonate ions that are selectively transported into the venous blood to partially compensate the metabolic acidosis. In rat kidney, this adaptation is sustained in part by the cell-specific induction of the glutaminase that results primarily from stabilization of the GA mRNA. The 3'-nontranslated region of the GA mRNA contains a direct repeat of an 8-base AU-sequence that functions as a pH-response element. This sequence exhibits a high affinity and specificity for zeta (z)-crystallin. The same protein binds to two separate, but homologous, 8-base AU-sequences within the 3'-nontranslated region of the GDH mRNA. The apparent binding activity of z-crystallin is increased significantly during onset of metabolic acidosis. Thus, increased binding of z-crystallin may initiate the pH-responsive stabilization of the two mRNAs.

Mechanism of increased renal gene expression during metabolic acidosis

Increased renal catabolism of plasma glutamine during metabolic acidosis generates two ammonium ions that are predominantly excreted in the urine. They function as expendable cations that facilitate the excretion of acids. Further catabolism of alpha-ketoglutarate yields two bicarbonate ions that are transported into the venous blood to partially compensate for the acidosis. In rat kidney, this adaptation is sustained, in part, by the induction of multiple enzymes and various transport systems. The pH-responsive increases in glutaminase (GA) and phosphoenolpyruvate carboxykinase (PEPCK) mRNAs are reproduced in LLC-PK(1)-fructose 1,6-bisphosphatase (FBPase) cells. The increase in GA activity results from stabilization of the GA mRNA. The 3'-untranslated region of the GA mRNA contains a direct repeat of an eight-base AU sequence that functions as a pH-response element. This sequence binds zeta-crystallin/NADPH:quinone reductase with high affinity and specificity. Increased binding of this protein during acidosis may initiate the pH-responsive stabilization of the GA mRNA. In contrast, induction of PEPCK occurs at the transcriptional level. In LLC-PK(1)-FBPase(+) kidney cells, a decrease in intracellular pH leads to activation of the p38 stress-activated protein kinase and subsequent phosphorylation of transcription factor ATF-2. This transcription factor binds to cAMP-response element 1 within the PEPCK promoter and may enhance its transcription during metabolic acidosis.

Identification and purification of the reconstitutively active glutamine carrier from rat kidney mitochondria

The glutamine carrier from rat kidney mitochondria, solubilized in dodecyl octaoxyethylene ether (C12E8) and partly purified on hydroxyapatite, was identified and completely purified by Celite chromatography. On SDS/PAGE, the purified glutamine carrier consisted of a single protein band with an apparent molecular mass of 41.5 kDa. When reconstituted into liposomes, the glutamine carrier catalysed both the unidirectional flux of glutamine and the glutamine/glutamine countertransport, which were completely inhibitable by a mixture of pyridoxal 5'-phosphate and N-ethylmaleimide. The carrier protein was purified 474-fold with a recovery of 58% and a protein yield of 0.12% with respect to the mitochondrial extract. The glutamine carrier-mediated transport is quite specific for l-glutamine. l-Asparagine is the only other amino acid that is efficiently transported by the reconstituted carrier protein. d-Glutamine, l-glutamate and l-aspartate are very poor substrates. The transport activity was inhibited by several thiol-group and amino-group reagents.

Hepatic glutamine transport and metabolism

Although the liver was long known to play a major role in the uptake, synthesis, and disposition of glutamine, metabolite balance studies across the whole liver yielded apparently contradictory findings suggesting that little or no net turnover of glutamine occurred in this organ. Efforts to understand the unique regulatory properties of hepatic glutaminase culminated in the conceptual reformulation of the pathway for glutamine synthesis and turnover, especially as regards the role of sub-acinar distribution of glutamine synthetase and glutaminase. This chapter describes these processes as well as the role of glutamine in hepatocellular hydration, a process that is the consequence of cumulative, osmotically active uptake of glutamine into cells. This topic is also examined in terms of the effects of cell swelling on the selective stimulation or inhibition of other far-ranging cellular processes. The pathophysiology of the intercellular glutamine cycle in cirrhosis is also considered.

Glutamine transport by vesicles isolated from tumour-cell mitochondrial inner membrane

Mitochondrial-inner-membrane vesicles, isolated from Ehrlich ascites carcinoma cells by titration with detergents, accumulated L-glutamine by a very efficient transport system. The vesicles lack any phosphate-activated glutaminase activity, allowing measurement of transport rates without interference by L-glutamine metabolism. The time course of the transport was linear for the first 60 s, reaching a steady state after 120 min. L-Glutamine transport showed co-operativity, with a Hill coefficient of 2.2; the kinetic parameters S0.5 and Vmax had values of 5 mM and 26 nmol/30 s per mg of protein respectively. The pH-dependence curve showed a bell shape, with a pH optimum about 8.0. The uptake of L-glutamine was not affected by the presence of a 50-fold molar excess of D-glutamine, L-cysteine, L-histidine, L-alanine, L-serine and L-leucine, whereas L-glutamate behaved as a poor inhibitor. The structural analogue L-glutamate gamma-hydroxamate (5mM) inhibited the net uptake by 68%; interestingly, other analogues (6-diazo-5-oxo-L-norleucine, acivicin and L-glutamate gamma-hydrazide) were ineffective. The impermeant thiol reagent p-chloromercuriphenylsulphonic acid (0.5mM) completely abolished the mitochondrial L-glutamine uptake; in contrast, other thiol reagents (mersalyl and N-ethylmaleimide) did not significantly affect the transport. These data confirm the existence of a specific transport system with high capacity for L-glutamine in the mitochondrial inner membrane, a step preceding the highly operative glutaminolysis in tumour cells.

Glutamine metabolism in isolated perfused rat liver. The transamination pathway

In isolated perfused rat liver, added 4-methyl-thio-2-oxobutyrate and phenylpyruvate are rapidly transaminated to the corresponding amino acids with glutamine, the latter being supplied via the portal vein or by endogenous synthesis. With portal glutamine concentrations below 5mM and in the presence of a oxo-acid acceptor, the flux through glutamine transaminases exceeded the ammonium ion-stimulated glutaminase flux. 4-Methylthio-2-oxobutyrate-induced extra glutamine uptake was not dependent on the perfusate pH in the range of pH 7 to 8. During glutamine/4-methylthio-2-oxobutyrate transamination, the amide nitrogen of glutamine is fully recovered as glutamate, ammonia, urea and alanine. Oxoglutarate formed by omega-amidase activity is released as glutamate or oxidized by oxoglutarate dehydrogenase. alpha-Cyanocinnamate, the inhibitor of the monocarboxylate translocator in the mitochondrial membrane inhibited 4-methylthio-2-oxobutyrate-induced glutamine uptake and methionine release by about 30%. This might indicate that about 2/3 of glutamine transaminase flux is cytosolic. alpha-Cyanocinnamate inhibited 4-methylthio-2-oxobutyrate-induced glutamate efflux by about 90%. Stimulation of flux through glutamine transaminases is accompanied by a 70-80% inhibition of glutaminase flux. This is not explained by a direct inhibition of glutaminase by 4-methylthio-2-oxobutyrate but by a substrate competition between glutaminase and glutamine transaminases. 4-Methylthio-2-oxobutyrate decreases glutamine release by the liver due to withdrawal by transamination. The oxo acid itself is without effect on glutamine synthetase flux. With respect to hepatocyte heterogeneity there is no evidence for a zonal distribution of glutamine transaminase activities, as it has been shown for glutamine synthetase and glutaminase activities.

The oxidation of glutamine and glutamate in relation to anion transport in enterocyte mitochondria

The oxidation of L-glutamate and L-glutamine by enterocyte mitochondria was supported by malate. The stimulation of the rate of oxidation of the two amino acids by small amounts of added malate was 93% and 76% respectively. This could not be accounted for by the oxidation of the small amounts of malate added. Amino-oxyacetate added initially inhibited malate-supported oxidation of L-glutamate by 81% and that of L-glutamine by 38%. The inhibition of L-glutamate oxidation was partially reversed by L-glutamine. The dicarboxylate-carrier inhibitor 2-phenylsuccinate inhibited the malate-supported oxidation of both amino acids, but appeared to be slightly stimulatory to L-glutamine oxidation when added initially. The inhibition of L-glutamate oxidation was reversed by L-glutamine. The mitochondrial uncoupler FCCP (carbonyl cyanide p-trifluoromethoxyphenylhydrazone) inhibited malate-supported oxidation of L-glutamate by 78% when added initially. The oxidation of L-glutamine was completely inhibited. However, the uncoupler stimulated the oxidation of both amino acids when added finally. Pyruvate inhibited aspartate synthesis when either of these amino acids was the main substrate, alanine being synthesized. There was no effect on O2 uptake. Mitochondria did not swell in KCl solution, but swelled rapidly in water. Mitochondrial swelling in potassium phosphate and potassium acetate solutions was activated by valinomycin and to a lesser extent by the further addition of FCCP. With potassium malate, swelling was mainly activated by phosphate. The swelling of enterocyte mitochondria in potassium glutamate was slow. In glutamine solution, mitochondrial swelling was greater and appeared to be enhanced by the initial presence of small amounts of phosphate.