The metabolic response of the kidney to acute sodium lactate alkalosis

In vivo studies were performed in the dog to verify if sodium lactate had an important effect on the metabolism of glutamine by the kidney. The animals were infused with 0.6 M sodium lactate to induce acute metabolic alkalosis with plasma bicarbonate of 29.7 mM. During these experiments, it was demonstrated that the renal uptake of glutamine increased by 46%, while the renal production of ammonia was unchanged. The renal production of alanine rose from 6.0 to 16.8 mumol/min. Plasma concentration of lactate increased from 1.3 to 19.2 mM, while that of pyruvate increased from 0.075 to 0.454 mM. In the renal tissue, alpha-ketoglutarate, malate, oxaloacetate, lactate, pyruvate, citrate, and alanine increased significantly. Similar changes were found in the liver and skeletal muscle. The observed changes are best described by transamination of pyruvate and glutamate under the influence of alanine aminotransferase (GPT). It can be calculated that this reaction was responsible for 76% of the production of ammonia from glutamine, the latter being necessary to provide glutamate for the synthesis of alanine. Dogs infused with 0.3 M sodium bicarbonate instead of sodium lactate with the same degree of acute metabolic alkalosis, showed a depression of 40% in the renal uptake of glutamine with a 38% decrease in renal ammoniagenesis and a 20% fall in the production of alanine. The present studies demonstrate that the production of ammonia from glutamine is not necessarily related to changes in acid-base balance, but may be associated with biochemical alterations related to the synthesis of alanine by the kidney.     

Renal metabolism and ammoniagenesis during acute respiratory alkalosis in the dog

Acute respiratory alkalosis (blood pH, 7.60; arterial PCO2, 15 mmHg (1 mmHg = 133.322 Pa); plasma bicarbonate, 14 mM) was induced in nine anesthetized dogs by increasing their respiratory rate and depth. Renal glutamine extraction and ammonia production expressed per 100 mL of glomerular filtration rate did not change during acute hypocapnia, whereas arterial glutamine concentration decreased significantly from 0.47 to 0.36 mM. Hypocapnia did not change plasma potassium concentration and its urinary excretion. Acute hypocapnia increased lactate extraction and pyruvate production, whereas citrate extraction and glutamate and alanine production did not change. Citraturia remained minimal. Renal cortical glutamine concentration fell from 0.64 to 0.38 mM during hypocapnia while alpha-ketoglutarate, glutamate, malate, oxaloacetate, and citrate did not change. Lactate concentration rose from 1.1 to 2.0 mM. Glutamine concentration in the liver and muscle decreased following acute hypocapnia. Our data are compatible with the hypothesis that an acute respiratory alkalosis might not result in any change in the hydrogen ion concentration and (or) gradient between the mitochondrial matrix and the cytosol. Consequently, renal glutamine extraction and ammonia production are not reduced, renal cortical concentrations of relevant metabolites in the ammoniagenic pathway are not changed, and renal handling of citrate remains unaffected.     

Renal metabolism during four types of lactic acidosis in the dog including anoxia

The present study was undertaken to evaluate the metabolic response of the kidney to lactic acidosis. Four types of lactic acidosis were induced in the dog: infusion of lactic acid, infusion of lactic acid with phenformin, administration of phenformin alone, and hypoxia by breathing 95% nitrogen. In all groups of animals, the same degree of acidosis was observed with plasma bicarbonate ranging from 12.8 to 14.9 mM. Plasma lactate concentration ranged from 3.0 to 8.1 mumol/mL. Renal ammoniagenesis failed to be influenced by lactic acidosis. As a matter of fact, it fell during anoxia. The extraction of glutamine by the kidney rose except during anoxia where it fell. The renal production of alanine rose during the infusion of lactic acid with and without phenformin. This coincided with the extraction of glutamine. The renal extraction of lactate rose in all forms of acidosis as well as the production of pyruvate. In the renal cortical tissue, the concentration of malate, pyruvate, and lactate rose. Alanine also rose except during anoxia. An important fall in cytosolic redox potential (NAD+/NADH lactate dehydrogenase) was observed, as well as a fall in mitochondrial redox (NAD+/NADH beta-hydroxybutyrate dehydrogenase). Lactate also accumulated in the liver and in the muscle. We propose that the kidney is unable to respond to lactic acidosis in terms of ammonia production and that this phenomenon is explained by transamination of pyruvate and glutamate into alanine and also by the observed fall in cytosolic redox potential. It is likely that renal gluconeogenesis is also inhibited and this is reflected by the rise in the concentration of malate in the kidney.(ABSTRACT TRUNCATED AT 250 WORDS)     

Renal enzymes during experimental diabetes mellitus in the rat. Role of insulin, carbohydrate metabolism, and ketoacidosis

The activities of various ammoniagenic, gluconeogenic, and glycolytic enzymes were measured in the renal cortex and also in the liver of rats made diabetic with streptozotocin. Five groups of animals were studied: normal, normoglycemic diabetic (insulin therapy), hyperglycemic, ketoacidotic, and ammonium chloride treated rats. Glutaminase I, glutamate dehydrogenase, glutamine synthetase, phosphoenolpyruvate carboxykinase (PEPCK), hexokinase, phosphofructokinase, fructose-1,6-diphosphatase, malate dehydrogenase, malic enzyme, and lactate dehydrogenase were measured. Renal glutaminase I activity rose during ketoacidosis and ammonium chloride acidosis. Glutamate dehydrogenase in the kidney rose only in ammonium chloride treated animals. Glutamine synthetase showed no particular variation. PEPCK rose in diabetic hyperglycemic animals and more so during ketoacidosis and ammonium chloride acidosis. It also rose in the liver of the diabetic animals. Hexokinase activity in the kidney rose in diabetic insulin-treated normoglycemic rats and also during ketoacidosis. The same pattern was observed in the liver of these diabetic rats. Renal and hepatic phosphofructokinase activities were elevated in all groups of experimental animals. Fructose-1,6-diphosphatase and malate dehydrogenase did not vary significantly in the kidney and the liver. Malic enzyme was lower in the kidney and liver of the hyperglycemic diabetic animals and also in the liver of the ketoacidotic rats. Lactate dehydrogenase fell slightly in the liver of diabetic hyperglycemic and NH4Cl acidotic animals. The present study indicates that glutaminase I is associated with the first step of increased renal ammoniagenesis during ketoacidosis. PEPCK activity is influenced both by hyperglycemia and ketoacidosis, acidosis playing an additional role. Insulin appears to prevent renal gluconeogenesis and to favour glycolysis. The latter would seem to remain operative in hyperglycemic and ketoacidotic diabetic animals.     

Effect of valproate on lactate and glutamine metabolism by rat renal cortical tubules

The metabolic effects of sodium valproate (VPA) on rat renal cortical tubules have been examined. When 1 or 5 mM lactate was used as substrate in the incubation medium, VPA decreased markedly the lactate uptake by the tubules. When 1 or 5 mM glutamine was used, the addition of VPA accelerated glutamine uptake, ammoniagenesis, but also stimulated markedly the accumulation of lactate and pyruvate produced from glutamine. VPA had a dose-dependent inhibitory effect on gluconeogenesis from both glutamine and lactate. With 5 mM glutamine, VPA also induced a significant accumulation of glutamate in the medium. The oxygen consumption by the tubules was diminished by 40% following VPA addition. It is concluded that VPA modifies the metabolism of rat cortical tubules by interfering with the oxidation of natural substrates and stimulates in this fashion the production of ammonia by kidney tubules.     

Metabolic effects of valproate on dog renal cortical tubules

The effect of valproate (0.01-10 mM), an antiepileptic drug inducing hyperammonemia in humans, was studied in vitro on a suspension of renal cortical tubules (greater than 85% proximal tubules) obtained from six normal dogs. When these tubules were incubated with 1 mM glutamine, the addition of valproate accelerated glutamine uptake, ammoniagenesis, and the production of alanine, lactate, and pyruvate. With 5 mM glutamine, a rise in glutamate accumulation, a much greater synthesis of alanine, an important aspartate production, and a striking accumulation of lactate and pyruvate were observed. With 1 or 5 mM lactate, lactate utilization and gluconeogenesis were markedly reduced with increasing concentrations of valproate. Oxygen consumption was reduced by only 15-20% by 10 mM valproate. The accelerated glutamine utilization resulting from valproate could not be prevented by aminooxyacetate, an inhibitor of transamination. Valproate also reduced various enzymatic activities, a finding that could not explain its metabolic effects. Four sites of action may explain these various metabolic changes: (i) a stimulation of mitochondrial glutamine transport, (ii) an increase in the flux of glutamate to malate, and (iii) a reduction in the net oxidation of pyruvate and (iv) in the flux through pyruvate carboxylase.     

In vitro effect of extracellular AMP on MCF-7 breast cancer cells: inhibition of glycolysis and cell proliferation.

MCF-7 human breast cancer cells propagated in vitro were treated with adenosine derivatives added to the culture medium. The effects on cell proliferation, glycolysis, and glutaminolysis were investigated. Of all adenosine derivatives tested, AMP was the most efficient inhibitor of cell proliferation. In AMP-treated cells, DNA synthesis decreased, whereas RNA and protein syntheses rose normally with time. In terms of carbohydrate metabolism, lactate production from glucose was drastically reduced; therefore, most of lactate produced must have been derived from glutamine. Increases in the enzyme activities involved in glutamate degradation and in the malate-aspartate shuttle were observed. In contrast, actual glycolytic flux rates declined, whereas key glycolytic enzyme activities increased. Metabolites such as fructose 1,6-bisphosphate and pyruvate accumulated in AMP-arrested cells. Based on the lowered NAD level in the AMP-treated cells, lactate dehydrogenase, but not malate dehydrogenase, was impaired; thereby the whole of glycolysis was inhibited. In compensation, glutamine catabolism was increased. NAD concentrations fell drastically because of the known inhibition of P-ribose-PP synthesis through heightened intracellular AMP levels. A hypothetical metabolic scheme to explain these results and to show how extracellular AMP may influence carbohydrate metabolism and cell proliferation is presented.     

Effects of ischaemia on content of metabolites in rat liver and kidney in vivo

1. The time-course of changes in content of intermediates of glycolysis in rat liver and kidney cortex after severance of blood supply was investigated. 2. The decline in content of ATP was more rapid in kidney (1.7-0.5mumol/g in 30s) than in liver (2.7-1.6mumol/g in 60s). In both tissues AMP and P(i) accumulated. 3. Net formation of lactate was 1.7mumol/g during the second minute of ischaemia in liver from well-fed rats, 1.1mumol/g in liver from 48h-starved rats, and about 1.0mumol/g during the first 30s of ischaemia in kidney. Net formation of alpha-glycerophosphate was rapid, especially in liver. 4. In kidney the concentration of beta-hydroxybutyrate rose, but that of alpha-oxoglutarate and acetoacetate decreased. 5. In both organs the concentrations of fructose diphosphate and triose phosphates increased during ischaemia and those of other phosphorylated C(3) intermediates decreased. 6. The concentration of the hexose 6-phosphates rose rapidly during the first minute of ischaemia in liver, but decreased during renal ischaemia. 7. In kidney the content of glutamine fell after 2min of ischaemia, and that of ammonia and glutamate rose. 8. The redox states of the cytoplasmic and mitochondrial NAD couple in kidney cortex were similar to those in liver. 9. The regulatory role of glycogen phosphorylase, pyruvate kinase and phosphofructokinase is discussed in relation to the observed changes in the concentrations of the glycolytic intermediates.     

LEVELS OF CEREBRAL CORTICAL GLYCOLYTIC AND CITRIC ACID CYCLE METABOLITES DURING HYPOGLYCEMIC STUPOR AND ITS REVERSAL

Abstract— Blood glucose, cerebral cortical glucose, and eight metabolites of the glycolytic pathway and citric acid cycle were measured during insulin hypoglycemic stupor and during the first 100s after glucose administration. In hypoglycemic mice that had lost righting ability, blood and brain glucose were decreased 89% and 96% respectively, but glucose-6-phosphate fell only 23%. Other glycolytic and citric acid cycle intermediates were decreased 31–77%. Fructose bisphosphate, 3-phosphoglycerate and phosphopyruvate fell more than glucose-6-phosphate, but less than pyruvate and lactate. Citrate fell less than a-ketoglutarate and malate. These results suggest that in severe hypoglycemia there is a decrease in brain glucose utilization, mediated by phosphofructokinase, but probably caused by decreased neuronal activity. An intravenous injection of glucose restored brain glucose to 75% of normal within 10s and caused return of righting ability within 60s. Glucose-6-phosphate, fructose bisphosphate, 3-phosphoglycerate, and phosphopyruvate rose to normal or near normal levels within 60s, whereas pyruvate, lactate, citrate, ã-ketoglutarate, and malate changed little in this period. This suggests that although glucose given to hypoglycemic animals rapidly enters the glycolytic pathway in brain (and behavior is almost normal), total neuronal activity, and hence overall glucose metabolism, remains subnormal for several minutes.     

Renal cortical intermediary metabolism in the recovery phase of postischemic acute renal failure in the dog.

Renal metabolism has been studied in eight dogs before and 48 hr after a 60-min period of renal ischemia induced by clamping the left renal artery with the simultaneous removal of the right kidney, and in 12 sham-operated animals. The study involved the measurement of renal uptake and production of lactate, glutamine, glutamate, alanine, ammonium, and oxygen, and the measurement of the tissue concentrations of ATP, glutamine, lactate, alpha-ketoglutarate, aspartate, and alanine in the renal cortex. Two days after a temporary renal ischemia, the remaining kidney showed a 22% decrease in glomerular filtration rate (GFR) and a 25% decrease in renal plasma flow. Fractional sodium and potassium excretions were similar to those of control dogs. Renal production or extraction of glutamine, glutamate, alanine, ammonium, and oxygen (all expressed by 100 ml of GFR) was not significantly different in basal conditions or 2 days after ischemia, but lactate extraction was reduced in postischemic kidneys (-101 +/- 29 vs -204 +/- 38 mumol/100 ml GFR in control dogs). The cortical concentrations of glutamine and glutamate were lower in postischemic than in control kidneys. No differences were found in cortical concentration of alpha-ketoglutarate, aspartate, lactate, pyruvate, or ATP, but total nucleotides and inorganic phosphate were decreased in postischemic kidneys. It is concluded that in the recovery phase of the ischemia, a decreased lactate uptake is the main metabolic change, and total ATP production is adapted to the decrease of GFR and sodium reabsorption.     

Acidotic alterations in oxidative metabolism influencing rat renal slice ammoniagenesis

We believe that two findings are interconnected and help to comprehend a major mechanism behind the regulation of renal ammonia production during acidosis. First, slices from acidotic compared to control and alkalotic rats produce more ammonia from glutamine. Second, inhibition of renal oxidative metabolism at various points by metabolic inhibitors augments slice ammoniagenesis. Based on this, our purpose was to determine whether enhanced renal ammoniagenesis during acidosis could occur through the same mechanism as the metabolic inhibitors. However, metabolic inhibitors (malonate; arsenite; 2,4-dinitrophenol) usually decrease while acidosis increases slice gluconeogenesis. There is one known exception. Fluorocitrate, which blocks citrate metabolism, simulates the acidotic condition by enhancing both ammonia and glucose production. Accordingly, a block of oxidative metabolism if located prior to citrate oxidation in the tricarboxylic acid cycle could theoretically augment ammoniagenesis during acidosis. Lactate, is a major renal fuel whose oxidative metabolism would be blocked by fluorocitrate. There, we concentrated on the effects of acidosis on lactate as well as glutamine metabolism. Lactate decarboxylation decreases in the face of increased glucose production during acidosis, and lactate inhibition of glutamine decarboxylation decreases in slices from acidotic rats. Also, we found lesser oxygen consumption in the presence of lactate by kidney slices from acidotic rats compared to control and alkalotic rats. We postulate that relatively less incorporation of lactate into the TCA cycle, causing decreased citrate formation and citrate oxidation during acidosis, contributes, at least in part, to acidotic adaptation of ammoniagenesis.     

The relationship of 4-aminobutyric acid metabolism to ammoniagenesis in renal cortex

Mitochondrial 4-aminobutyrate aminotransferase in rat kidney can utilize pyruvate as the acceptor for the amino group of 4-aminobutyrate. Renal 4-aminobutyrate aminotransferase activity at saturating equimolar concentration of 4-aminobutyrate and 5 mM pyruvate is 42.8 ± 2.5 μmol/g protein per h (mean ± S.E.M.) or 70% of 4-aminobutyrate aminotransferase activity with equimolar α-ketoglutarate. 4-Aminobutyrate aminotransferase in brain does not transaminate with pyruvate. Since pyruvate is an important mitochondrial metabolite in kidney, net disposal of glutamate via the 4-aminobutyrate pathway is possible. The renal 4-aminobutyrate pathway in the rat has other distinctive features when compared with the pathway in rat brain. Most inhibitors of rat neuronal glutamate decarboxylase were ineffective against the renal form of the enzyme, but 20 mM semicarbazide inhibited the latter form by 80% (P < 0.001) in vitro and reduced renal 4-aminobutyrate content by 75% (P < 0.001) in vivo. In the presence of 20 mM semicarbazide, ammoniagenesis by rat renal cortex slices incubated in 1 mM glutamine was inhibited 26% (P < 0.01). Semicarbazide was proportionately less effective (15% inhibition) when ammoniagenesis was stimulated (+243%) in slices prepared from chronically acidotic animals, and was no deterrant to ammoniagenesis when non-acidotic slices were incubated in supraphysiologic concentrations of 10 mM glutamine. We conclude that whereas integrity of the renal 4-aminobutyrate pathway may contribute to glutamate disposal and thus ammoniagenesis under physiologic conditions, the pathway is a passive participant in the overall process of ammoniagenesis.     

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.     

Effect of the blood lactate concentration on renal glutamine metabolism in dogs with chronic metabolic acidosis

It appears that glutamine and lactate are the principal substrates for the kidney in dogs with chronic metabolic acidosis. Accordingly, the purpose of this study was to determine if a higher or lower rate of renal lactate extraction would influence the rate of glutamine extraction at a constant rate of renal ATP turnover. The blood lactate concentration was 0.9 +/- 0.01 mM in 15 acidotic dogs. However, eight dogs with chronic metabolic acidosis had a spontaneous blood lactate concentration of 0.5 mM or lower. The kidneys of these dogs extracted considerably less lactate from the arterial blood (19 vs. 62 mumol/100 mL glomerular filtration rate (GFR]. Nevertheless, glutamine, alanine, citrate, and ammonium metabolism were not significantly different in these two groups of dogs. Renal ATP balance in acidotic dogs with a low blood lactate could only be achieved if a substrate other than additional glutamine were oxidized in that segment of the nephron which normally oxidized lactate; presumably a fat-derived substrate and (or) lactate derived from glucose was now the metabolic fuel at these more distal sites. When the blood lactate concentration was greater than 1.9 mM, lactate extraction rose to 219 mumol/100 mL GFR. Glutamine, alanine, citrate, and ammonium metabolism were again unchanged; in this case, ATP balance required substrate flux to products other than carbon dioxide, presumably, gluconeogenesis. It appears that renal ammoniagenesis is a proximal event and is independent of the rate of renal lactate extraction.     

Alanine and glutamine synthesis and release from skeletal muscle. I. Glycolysis and amino acid release.

The synthesis and release of alanine and glutamine were investigated with an intact rat epitrochlaris muscle preparation. This preparation will maintain on incubation for up to 6 hours, tissue levels of phosphocreatine, ATP, ADP, lactate, and pyruvate closely approximating those values observed in gastrocnemius muscles freeze-clamped in vivo. The epitrochlaris preparation releases amino acids in the same relative proportions and amounts as a perfused rat hindquarter preparation and human skeletal muscle. Since amino acids were released during incubation without observable changes in tissue amino acids levels, rates of alanine and glutamine release closely approximate net amino acid synthesis. Large increases in either glucose uptake or glycolysis in muscle were not accompanied by changes in either alanine or glutamine synthesis. Insulin increased muscle glucose uptake 4-fold, but was without effect on alanine and glutamine release. Inhibition of glycolysis by iodacetate did not decrease the rate of alanine synthesis. The rates of alanine and glutamine synthesis and release from muscle decreased significantly during prolonged incubation despite a constant rate of glucose uptake and pyruvate production. Alanine synthesis and release were decreased by aminooxyacetic acid, an inhibitor of alanine aminotransferase. This inhibition was accompanied by a compensatory increase in the release of other amino acids, such as aspartate, an amino acid which was not otherwise released in appreciable quantities by muscle. The release of alanine, pyruvate, glutamate, and glutamine were observed to be interrelated events, reflecting a probable near-equilibrium state of alanine aminotransferase in skeletal muscle. It is concluded that glucose metabolism and amino acid release are functionally independent processes in skeletal muscle. Alanine release reflects the de novo synthesis of the amino acid and does not arise from the selective proteolysis of an alanine-rich storage protein. It appears that the rate of alanine and glutamine synthesis in skeletal muscle is dependent upon the transformation and metabolism of amino acid precursors.     

The metabolic effects of sodium dichloroacetate in the starved rat

1. Sodium dichloroacetate (300mg/kg body wt. per h) was infused in 24h-starved rats for 4h. 2. Blood glucose decreased significantly, an effect that had previously only been noted in diabetic animals 3. Plasma insulin concentration decreased by 63%; blood lactate and pyruvate concentrations decreased by 50 and 33%, whereas concentrations of 3-hydroxybutyrate and acetoacetate increased by 81 and 73% respectively. 4. Livers were freeze-clamped at the end of the 4h infusion. There were significant decreases in hepatic [glucose], [glucose 6-phosphate], [2-phosphoglycerate], the [lactate]/[pyruvate] ratio, [citrate] and [malate], and also [alanine], [glutamate] and [glutamine], suggesting a diminished supply of gluconeogenic substrates. 5. Animals subjected to a functional hepatectomy at the end of 2h infusions showed no difference in blood-glucose disappearance but a highly significant decrease in the rate of accumulation of lactate, pyruvate, glycerol and alanine, compared with control animals. Dichloroacetate decreased ketone-body clearance. 6. After functional hepatectomy an increase in glutamine accumulation appeared to compensate for the decrease in alanine accumulation. 7. It is concluded that dichloroacetate causes hypoglycaemia by decreasing the net release of gluconeogenic precursors from extrahepatic tissues while inhibiting peripheral ketone-body uptake. 8. These findings are consistent with the activation of pyruvate dehydrogenase (EC 1.2.4.1) in rat muscle by dichloroacetate previously described by Whitehouse & Randle (1973).     

Metabolic Regulation in the Senescing Tobacco Leaf: II. Changes in Glycolytic Metabolite Levels in the Detached Leaf

Yellowing of detached mature tobacco leaves standing in water in the dark was accompanied by a strong “climacteric rise” in respiration rate. During this period the ATP level and energy charge of the adenylate system also rose. The levels of glycolytic intermediates between glucose 1-phosphate and triose phosphates rose, those between 3-phosphoglycerate and phosphoenolpyruvate fell, and pyruvate rose. On the assumption of a drop in NAD/NADH ratio, as found by other workers in wheat leaves, the reverse crossover between triose phosphates and 3-phospholglycerate was attributed to inhibition of glyceraldehyde 3-phosphate dehydrogenase. The forward crossover between phosphoenolpyruvate and pyruvate was taken to indicate activation of pyruvate kinase, possibly by fructose diphosphate. Secondary large rises in pyruvate and fructose diphosphate occurred well after the climacteric peak had been passed. No evidence was found for participation of phosphofructokinase in metabolic control in the yellowing leaf. Possible limitations to the use of the crossover theorem in the present situation, such as changes in compartmentation and in flux through branch points, are emphasized.     

Ammonia Intoxication: Effects on Cerebral Cortex and Spinal Cord

The effect of an acute systemic ammonia intoxication on the metabolic states of the cerebral cortex and the spinal cord of the same animal was studied in the cat. The intravenous infusion of ammonium acetate (2 and 4 mmol/kg body weight/30 min) increased the gross levels of tissue NH4+, glutamine, glutamine/glutamate ratio, lactate, and the lactate/pyruvate ratio in the cerebral cortex and the spinal cord. Pyruvate increased, but significantly only in the spinal cord; aspartate decreased, but significantly only in the cerebral cortex. The infusion of ammonium acetate did not significantly change the levels of phosphocreatine, ATP, ADP, AMP, total adenine nucleotides, adenylate energy charge, glucose, glutamate, alpha-ketoglutarate, and malate in either tissue. The changes of NH4+, glutamine, and lactate levels as well as glutamine/glutamate and lactate/pyruvate ratios in the spinal cord correlated significantly with the corresponding changes of these metabolites in the cerebral cortex. Thus, cerebral cortex and spinal cord show certain specific and comparable metabolic changes in response to a systemic ammonia intoxication. The effect of ammonia intoxication on the increases of glutamine and lactate levels is discussed.     

Glucose and amino acid metabolism in an established line of skeletal muscle cells

The suitability of an established myogenic line (L₆) for the study of skeletal muscle intermediary metabolism was investigated. Myoblasts were grown in tissue culture for ten days at which time they had differentiated into multinucleated myotubes. Myotube preparations were then incubated for up to 96 hours in 10 ml of Dulbecco's modified Eagle medium containing 10% fetal calf serum. Glucose was utilized at a nearly linear rate, 3.0 nmol/min/mg protein. Intracellular glucose was detectable throughout the incubation, even when medium glucose was as low as 16 mg%. During the initial 28 hours of incubation, when net lactate production was observed, only 35% of the glucose utilized was converted to lactate. Alanine was produced in parallel to lactate at an average rate of 0.6 nmol/min/mg protein. In concert with active glutamine utilization, high rates of ammoniagenesis were observed as medium glutamine decreased from 3.3 mM to 0.49 mM and medium ammonia increased from 2.3 mM to 6.2 mM, between zero time and 96 hours of incubation, respectively. The cells maintained stable ATP and citrate levels, and physiologic intracellular lactate/pyruvate ratios (10–24) throughout 96 hours of incubation. These results suggest (1) glucose utilization by skeletal muscle in tissue culture is limited by phosphorylation, not transport; (2) as much as 50% of glucose-derived pyruvate enters mitochondrial pathways; (3) glutamine carbon may be utilized simultaneously with glucose consumption and this process accounts for high rates of ammoniagenesis.     

The synthesis of glucose and ammonia by kidney tubules isolated from suckling and early-weaned lambs

Glucose and ammonia production were examined in kidney tubules isolated from suckling and early-weaned lambs, on days 10-30 after birth, with abrupt weaning occurring at day 14. There were no differences in the rates of glucose or ammonia production for a given substrate by tubules isolated from any of the lambs, regardless of age or stage of weaning. The preferred substrates for gluconeogenesis were glycerol = lactate greater than propionate = pyruvate = fructose = proline greater than alanine greater than glutamate greater than glutamine greater than aspartate greater than glycine greater than serine, and for ammoniagenesis were glutamine much greater than alanine greater than aspartate much greater than serine greater than glycine = glutamate = proline.