Utilization of nitrogen from 15NH4Cl and [15N]alanine for urea synthesis in hepatocytes from fed and starved rats

Utilization of N from 15NH4Cl and [15N]alanine for urea synthesis in hepatocytes isolated from fed and 24 hr starved rats was investigated. In hepatocytes isolated from fed rats, 54 and 65% of the added [15N]ammonia was utilized for urea synthesis in the presence of 0.5 and 2.0 mM NH4Cl, respectively. This utilization of [15N]ammonia in hepatocytes from starved rats was 2-fold lower. The amount of urea synthetized from endogenous sources was, in the presence of 0.5 and 2.0 mM NH4Cl, about 44 and 60% higher than in the control conditions (without NH4Cl). The considerable amount of added ammonia (30-44%) was utilized in processes other than urea synthesis. Alanine markedly diminished the utilization of 15N from NH4Cl in hepatocytes from both fed and starved rats. In these conditions (NH4Cl present), alanine significantly increased the urea formation in hepatocytes from starved rats and failed to affect the urea production in hepatocytes from fed rats. On the basis of 15N determination, it was concluded that both NH4Cl and alanine caused an increase in the utilization of nitrogen from endogenous sources in rat hepatocytes. This conclusion is in contrast with the results based only on the changes in ammonia and urea concentrations.     

Effects of ischaemia on metabolite concentrations in rat liver

1. Changes in the concentrations of ammonia, glutamine, glutamate, 2-oxoglutarate, 3-hydroxybutyrate, acetoacetate, alanine, aspartate, malate, lactate, pyruvate, NAD(+), NADH and adenine nucleotides were measured in freeze-clamped rat liver during ischaemia. 2. Although the concentrations of most of the metabolites changed rapidly during ischaemia the ratios [glutamate]/[2-oxoglutarate][NH(4) (+)] and [3-hydroxybutyrate]/[acetoacetate] changed equally and the value of the expression [3-hydroxybutyrate][2-oxoglutarate][NH(4) (+)]/[acetoacetate][glutamate] remained approximately constant, indicating that the 3-hydroxybutyrate dehydrogenase and glutamate dehydrogenase systems were at near-equilibrium with the mitochondrial NAD(+) couple. 3. The value of the expression [alanine][oxoglutarate]/[pyruvate][glutamate] was about 0.7 in vivo and remained fairly constant during the ischaemic period of 5min, although the concentrations of alanine and oxoglutarate changed substantially. No explanation can be offered why the value of the ratio differed from that of the equilibrium constant of the alanine aminotransferase reaction, which is 1.48. 4. Injection of l-cycloserine 60min before the rats were killed increased the concentration of alanine in the liver fourfold and decreased the concentration of the other metabolites measured, except that of pyruvate. During ischaemia the concentration of alanine did not change but that of aspartate almost doubled. 5. After treatment with l-cycloserine the value in vivo of the expression [alanine][oxoglutarate]/[pyruvate][glutamate] rose from 0.7 to 2.4. During ischaemia the value returned to 0.8. 6. The effects of l-cycloserine are consistent with the assumption that it specifically inhibits alanine aminotransferase. 7. Most of the alanine formed during ischaemia is probably derived from pyruvate and from ammonia released by the deamination of adenine nucleotides and glutamine. The alanine is presumably formed by the combined action of glutamate dehydrogenase and alanine aminotransferase. 8. The rate of anaerobic glycolysis, calculated from the increase in the lactate concentration, was 1.3mumol/min per g fresh wt. 9. Although the concentrations of the adenine nucleotides changed rapidly during ischaemia, the ratio [ATP][AMP]/[ADP](2) remained constant at 0.54, indicating that adenylate kinase established near-equilibrium under these conditions.     

Liver and kidney cortex gluconeogenesis from L-alanine in fed and starved rats

Circulating [14C]glucose 2, 5 and 10 min after intravenous injection of [U-14C]-L-alanine was greater in 24 hr starved than in fed rats. In vitro uptake of [14C]alanine by liver and kidney cortex slices from 24 hr starved and fed rats rose in parallel with increased medium substrate concentration. Formation of [14C]glucose from 1mM [14C]alanine was similar in liver and kidney cortex slices and increased in tissues from 24 hr starved compared with fed rats. With 5 mM [14C]alanine more [14C]glucose was produced by liver than by kidney cortex slices from 24 hr starved rats. Liver slices always produced more [14C]lactate and less [14C]-CO2 from [14C]alanine than kidney cortex slices. It is proposed that under physiological conditions, the kidneys cortex actively participates in glucose production from alanine.     

The time-course of the effects of ethanol on the redox and phosphorylation states of rat liver

1. The time-course of the effects of ethanol administration on the metabolite concentrations, redox states and phosphorylation state was studied in the freeze-clamped liver of starved rats. The response was found to vary with the time after ethanol administration. 2. Administration of ethanol caused an immediate decrease in the [NAD(+)]/[NADH] ratio of both cytoplasm and mitochondria, which persisted over the 30min studied. 3. The free cytoplasmic [NADP(+)]/[NADPH] ratio in liver decreases immediately after ethanol administration but returns nearly to control values after 15min. 4. The cytoplasmic [ATP]/[ADP][HPO(4) (2-)] ratio is elevated 15min after ethanol administration in the starved rat. 5. The rapid and large changes in most metabolite concentrations measured appeared to result from the maintenance of near-equilibrium in a wide interlinked network. 6. Differences between fed and starved rats 15min after ethanol administration were slight.     

A possible mechanism for the anti-ketogenic action of alanine in the rat

1. The anti-ketogenic effect of alanine has been studied in normal starved and diabetic rats by infusing l-alanine for 90min in the presence of somatostatin (10μg/kg body wt. per h) to suppress endogenous insulin and glucagon secretion. 2. Infusion of alanine at 3mmol/kg body wt. per h caused a 70±11% decrease in [3-hydroxybutyrate] and a 58±9% decrease in [acetoacetate] in 48h-starved rats. [Glucose] and [lactate] increased, but [non-esterified fatty acid], [glycerol] and [3-hydroxybutyrate]/[acetoacetate] were unchanged. 3. Infusion of alanine at 1mmol/kg body wt. per h caused similar decreases in [ketone body] (3-hydroxybutyrate plus acetoacetate) in 24h-starved normal and diabetic rats, but no change in other blood metabolites. 4. Alanine [3mmol/kg body wt. per h] caused a 72±9% decrease in the rate of production of ketone bodies and a 57±8% decrease in disappearance rate as assessed by [3-¹⁴C]acetoacetate infusion. Metabolic clearance was unchanged, indicating that the primary effect of alanine was inhibition of hepatic ketogenesis. 5. Aspartate infusion at 6mmol/kg body wt. per h had similar effects on blood ketone-body concentrations in 48h-starved rats. 6. Alanine (3mmol/kg body wt. per h) caused marked increases in hepatic glutamate, aspartate, malate, lactate and citrate, phosphoenolpyruvate, 2-phosphoglycerate and glucose concentrations and highly significant decreases in [3-hydroxybutyrate] and [acetoacetate]. Calculated [oxaloacetate] was increased 75%. 7. Similar changes in hepatic [malate], [aspartate] and [ketone bodies] were found after infusion of 6mmol of aspartate/kg body wt. per h. 8. It is suggested that the anti-ketogenic effect of alanine is secondary to an increase in hepatic oxaloacetate and hence citrate formation with decreased availability of acetyl-CoA for ketogenesis. The reciprocal negative-feedback cycle of alanine and ketone bodies forms an important non-hormonal regulatory system.     

Nitrogen-13 flux from L-[13N]glutamate in the isolated rabbit heart: effect of substrates and transaminase inhibition

Kinetic and biochemical parameters of nitrogen-13 flux from L-[13N]glutamate in myocardium were examined. Tissue radioactivity kinetics and chemical analyses were determined after bolus injection of L-[13N]glutamate into isolated arterially perfused interventricular septa under various metabolic states, which included addition of lactate, pyruvate, aminooxyacetate (a transaminase inhibitor), or a combination of aminooxyacetate and pyruvate to the standard perfusate containing insulin and glucose. Chemical analysis of tissue and effluent at 6 min allowed determination of the composition of the slow third kinetic component of the time-activity curves. 13N-labeled aspartate, alanine and glutamate accounted for more than 80% of the tissue nitrogen-13 under the experimental conditions used. Specific activities for these amino acids were constant, but not identical to each other, from 6 through 15 min after administration of L-[13N]glutamate. Little labeled ammonia (1.9%) and glutamine (4.7%) were produced, indicating limited accessibility of exogenous glutamate to catabolic mitochondrial glutamate dehydrogenase and glutamine synthetase, under control conditions. Lactate and pyruvate additions did not affect tissue amino acid specific activities. Aminooxyacetate suppressed formation of 13N-labeled alanine and aspartate and increased production of L-[13N]glutamine and [13N]ammonia. Formation of [13N]ammonia was, however, substantially decreased when aminooxyacetate was used in the presence of exogenous pyruvate. The data support a model for glutamate compartmentation in myocardium not affected by increasing the velocity of enzymatic reactions through increased substrate (i.e., lactate or pyruvate) concentrations but which can be altered by competitive inhibition of transaminases (via aminooxyacetate) making exogenous glutamate more available to other compartments.     

Ammonia overloading in hepatocytes isolated from liver of fetal and adult rats

Ammonia overloading was investigated during glucose and fructose metabolism in isolated hepatocytes under a variety of metabolic conditions. In all assay conditions, the glycolytic flux and oxygen uptake was not modified by 10 mM ammonia. In hepatocytes isolated from rats fed as libitum, the presence of ammonia caused a decrease in the production of lactate (pyruvate); this effect was not observed in anaerobic incubations, in hepatocytes isolated from starved animals, or in fetal hepatocytes. In spite of an overproduction of urea, ammonia detoxification also takes place by the synthesis of alanine, glutamate and aspartate. Addition of 1 mM aminooxyacetate, an inhibitor of aminotransferases, to the incubation medium prevents the formation of these amino acids, and also prevents the decrease of lactate in hepatocytes isolated from fed animals.     

Nitrogen-13 flux from L-[13N]glutamate in the isolated rabbit heart: effect of substrates and transminase inhibition

Kinetic and biochemical parameters of nitrogen-13 flux from L-[¹³N]-glutamate in myocardium were examined. Tissue radioactivity kinetics and chemical analyses were determined after bolus injection of L-[¹³N]glutamate into isolated arterially perfused interventricular septa under various metabolic states, which included addition of lactate, pyruvate, aminooxyacetate (a transminase inhibitor), or a combination of aminooxyacetate and pyruvate to the standard perfusate containing insulin and glucose. Chemical analysis of tissue and effluent at 6 min allowed determination of the composition of the slow third kind kinetic component of the time-activity curves. ¹³N-labeled aspartate, alanine and glutamate accounted for more than 80% of the tissue nitrogen-13 under the experimental conditions used. Specific activities for these amino acids were constant, but not identical to each other, from 6 through 15 min after administration of L-[¹³N]glutamate. Little labeled ammonia (1.9%) and glutamine (4.7%) were produced, indicating limited accessibility of exogenous glutamate to catabolic mitochondrial glutamate dehydrogenase and glutamine synthetase, under control conditions. Lactate and pyruvate additions did not affect tissue amino acid specific activities. Aminooxyacetate suppressed formation of ¹³N-labeled alanine and aspartate and increased production of L-[¹³N]glutamine and [¹³N]ammonia. Formation of [¹³N]ammonia was, however, substantially decreased when aminooxyacetate was used in the presence of exogenous pyruvate. The data support a model for glutamate compartmentation in myocardium not affected by increasing the velocity of enzymatic reactions through increased substrate (i.e., lactate or pyruvate) concentrations but which can be altered by competitive inhibition of transaminases (via aminooxyacetate) making exogenous glutamate more available to other compartments.     

Effects of ATP and adenosine addition on activity of oxoglutarate dehydrogenase and the concentration of cytoplasmic free Ca2+ in rat hepatocytes

Addition of ATP (100 microM) to hepatocytes from starved rats incubated with 5 mM [1-14C]glutamine caused a stimulation of glucose formation; the magnitude of the concomitant increases in 14CO2 production and glutamine consumption indicate that flux from glutamine to glucose was increased. ATP also caused a simultaneous decrease in the cell content of oxoglutarate; together with the increased flux this is consistent with an activation of oxoglutarate dehydrogenase. In corroboration of this, a stimulation by ATP of gluconeogenesis and a decrease in oxoglutarate was also observed with 5 mM proline as substrate. ATP caused an increase in hepatocyte cytoplasmic free Ca2+ concentration, [Ca2+]c, as indicated by the increase in the fluorescence of cytoplasmically trapped quin2, from a resting value of about 0.2 microM to greater than 1 microM. The mechanism of oxoglutarate dehydrogenase activation may be via an increase in mitochondrial Ca2+ content as a consequence of the increase in [Ca2+]c. The effects of 100 microM adenosine were also investigated. An increase in flux from glutamine to glucose was observed together with a decrease in the cell oxoglutarate, thus indicating that adenosine addition to hepatocytes could also activate oxoglutarate dehydrogenase. The activation by adenosine was less than that produced by ATP. Adenosine caused a small apparent increase in [Ca2+]c to 0.3-0.4 microM; it remains to be established if this effect, which is small relative to that of ATP, is sufficient to elicit the activation of oxoglutarate dehydrogenase: alternative mechanisms may exist.     

Early events in the initiation of ammonia formation in kidney

Experiments were designed to examine the early events in the initiation of glutamate deamination in kidney. Perfused kidneys from methionine sulfoximine-treated rats formed ammonia from [15N]glutamate via the purine nucleotide cycle. The turnover of the 6-amino group of adenine nucleotides to yield ammonia occurred at the rate of 0.30 mumol/g of kidney/min. This rate is 3-4 times larger than in liver and is in agreement with published rates of the purine nucleotide cycle in kidney. The addition of 0.1 mM fluorocitrate to glutamate perfusions stimulated ammonia formation 3 1/2-fold. The turnover of the 6-amino group of adenine nucleotides increased during the first 5 min after adding fluorocitrate to form ammonia predominately from tissue glutamate and aspartate. This turnover correlates with a 3 1/2-fold increase in kidney tissue IMP levels. As the ATP/ADP ratio fell the purine nucleotide cycle was inhibited and glutamate dehydrogenase was stimulated to form ammonia stoichiometric with glutamate taken up from the perfusate. Ammonia formation via glutamate dehydrogenase occurred at a rate of 1.0 mumol/g of kidney/min. Fluorocitrate completely blocked ammonia formation from aspartate in perfusions. The perfused kidney formed ammonia from aspartate via the purine nucleotide cycle at a rate of 1.0 mumol/g of kidney/min. The results indicate a discrete role for aspartate in renal metabolism. Ammonia formation via the purine nucleotide cycle can occur at significant rates and equal to the rate of ammonia formation from glutamate via glutamate dehydrogenase.     

Effects of glucagon and N6O2''-dibutyryladenosine 3'':5''-cyclic monophosphate on calcium transport in isolated rat liver mitochondria.

1. The administration of glucagon to fed rats by intraperitoneal injection, or the perfusion of livers from fed rats with glucagon by the method of Mortimore [Mortimore (1963) Am.J. Physiol. 204, 699--704] was associated with increases of 15- and 5-fold respectively, in the time for which a given load of exogenous Ca2+ is retained by mitochondria subsequently isolated from the liver. This effect of glucagon was (a) also induced by N6O2'-dibutyryl cyclic AMP, (b) completely blocked by cycloheximide, (c) relatively slow in onset (15--60 min) and (d) associated with a stimulation of about 20% in the rates of ADP-stimulated oxygen utilization and Ca2+ transport measured in the presence of succinate. 2. Perfusion of livers with glucagon resulted in the isolation of mitochandria which showed a 50% increase, no significant change and a 40% increase in the concentrations of endogenous Ca, Mg and Pi respectively, when compared with mitochondria isolated from control perfused livers. 3. The administration of insulin or adrenaline to fed rats induced increases of 10- and 8-fold respectively, in the time for which Ca2+ is retained by isolated liver mitochondria. Perfusion of livers with insulin had no effect on mitochondrial Ca2+ retention time. 4. The perfusion of livers from starved rats with glucagon, or the administration of either glucagon or insulin to starved rats, increased by about 2.5- and 15-fold respectively, the time for which isolated mitochondria retain Ca2+. 5. Mechanisms which may be responsible for the observed alterations in Ca2+-retention time are discussed.     

Nucleotide sequences of genes encoding the type II chloramphenicol acetyltransferases of Escherichia coli and Haemophilus influenzae, which are sensitive to inhibition by thiol-reactive reagents.

A gastric [U-14C]glucose load (4.8 mg/g body wt.) was delivered to unrestrained post-absorptive or 30 h-starved rats bearing peripheral and portal vein catheters and continuously perfused with [3-3H]glucose, in order to compare their metabolic and hormonal responses. In the basal state, portal and peripheral glycaemia were less in starved rats than in rats in the post-absorptive period (P less than 0.01), whereas blood lactate was similar. Portal insulinaemia (P less than 0.05) and protal glucagonaemia (P less than 0.005) were lower in starved rats, but insulin/glucagon ratio was higher in post-absorptive rats (P less than 0.005). The glucose turnover rate was decreased by starvation (P less than 0.005). After glucose ingestion, blood glucose was similar in post-absorptive and starved rats. A large portoperipheral gradient of lactate appeared in starved rats. Portal insulinaemia reached a peak at 9 min, and was respectively 454 +/- 68 and 740 +/- 65 mu-units/ml in starved and post-absorptive rats. Portal glucagonaemia remained stable, but was higher in post-absorptive rats (P less than 0.05). At 60 min after the gastric glucose load, 30% of the glucose was delivered at the periphery in both groups. The total glucose appearance rate was higher in starved rats (P less than 0.05), as was the glucose utilization rate (P less than 0.05), whereas the rate of appearance of exogenous glucose was similar. This was due to a non-suppressed hepatic glucose production in the starved rats, whereas it was totally suppressed in post-absorptive rats. At 1 h after the glucose load, the increase in both liver and muscle glycogen concentration was greater in starved rats. Thus short-term fasting induces an increased portal lactate concentration after a glucose load, and produces a state of liver insulin unresponsiveness for glucose production, whereas the sensitivity of peripheral tissues for glucose utilization is unchanged or even increased. This might allow preferential replenishment of the peripheral stores of glycogen.     

Metabolism of [13N]ammonia in rat lung

Bolus injection of [13N]ammonia into the femoral vein of pentobarbital-anesthetized rats was followed by rapid clearance from the blood and first-pass extraction of nearly 30% by the lungs. Of the label present in the lungs at 6 s after injection (about 27% of the dose), more than 20% was in metabolized form. Of the label present in the lungs at 2 min after injection (about 10% of the dose), 18-25% was in ammonia, about 75% was in glutamine (amide) and less than 1% was in glutamate and aspartate. Thus, despite the presence of significant amounts of glutamate dehydrogenase, the overwhelming route for metabolism of ammonia entering the rat lung in vivo was the glutamine synthetase reaction. Lung tissue that was removed 6 s after intravenous injection of [13N]ammonia and incubated in Krebs-Ringer glucose medium at 37 degrees C for 20 min, showed a significant increase (more than one-third), compared to unincubated lung tissue in the quantity of label in glutamine. Between 6s and 2 min after injection, during which time the total 13N content of the lungs decreased by more than 60%, the maintenance of a quasi-steady state in the concentration of labeled glutamine suggested a short-term balance between formation from extracted ammonia and loss of glutamine into the circulation. Our data support the concept that the lungs are a source of circulating glutamine in the rat. Despite the large fractional extraction of blood-borne [13N]ammonia by the lungs, only minute amounts of tracer (0.2-0.6 ppm of the injected dose) were detected in the expired air within the first 5 min after administration of [13N]ammonia to anesthetized rats, so that pulmonary excretion was not a significant pathway of ammonia elimination. The present findings emphasize the importance of the lungs in the maintenance of whole-body nitrogen homeostasis and suggest the use of [13N]ammonia and 13N-labeled amino acids as non-invasive probes in the study of normal and diseased lung metabolism.     

The pentose cycle and insulin release in isolated mouse pancreatic islets during starvation.

When islets from mice were incubated with 16.7 mM-glucose, previous starvation for 48 h decreased the rate of insulin release by approx. 50% and glucose utilization was decreased by approx. 35%. The maximally extractable activity of glucose 6-phosphate dehydrogenase was diminished by 28% after starvation. The formation of 14CO2 from both [1-14C]glucose was, however, higher than the rate of oxidation of [6-14C]-glucose in islets from both fed and starved mice. The fraction of glucose utilized that was oxidized (specific 14CO2 yield) ranged from one-fifth to one-third and was higher in islets from starved mice with both [1-14C]glucose and [6-14C]glucose as substrate. The contribution of pentose-cycle oxidation to total glucose metabolism was small (3% in the fed state and 4% in the starved state). The absolute rates of glucose carbon metabolism via the pentose-cycle oxidation to total glucose metabolism was small (3% in the fed state and 4% in the starved state). The absolute rates of glucose carbon metabolism via the pentose cycle and the turnover of NADPH in this pathway were identical in islets from fed and starved animals. After incubation at 16.7 mM-glucose for 30 min the contents of glucose (6-phosphate and 6-phosphogluconate were both unchanged by starvation. It is concluded that there is no correlation between the decreased sensitivity of the insulin secretory mechanism during starvation and the metabolism of glucose via the pentose cycle, the islet content of glucose 6-phosphate or 6-phosphogluconate.     

The urea cycle and related pathways in the liver of Walker-256 tumor-bearing rats

The urea cycle was evaluated in perfused livers isolated from cachectic tumor-bearing rats (Walker-256 tumor). Urea production in livers of tumor-bearing rats was decreased in the presence of the following substrates: alanine, alanine + ornithine, alanine + aspartate, ammonia, ammonia + lactate, ammonia + pyruvate and glutamine. Urea production from arginine was higher in livers of tumor-bearing rats. No difference was found with aspartate, aspartate + ammonia, citrulline, citrulline + aspartate and glutamine + aspartate. Ammonia consumption was smaller in livers from cachectic rats when the substance was infused together with lactate and pyruvate. Glucose production was smaller in the cachectic condition only when alanine was the gluconeogenic substrate. Blood urea was higher in tumor-bearing rats, suggesting higher rates of urea production. The availability of aspartate seems to be critical for urea synthesis in the liver of tumor-bearing rats, which is possibly unable to produce this amino acid in sufficient amounts from endogenous sources. The liver of tumor-bearing rats may have a different exogenous substrate supply of nitrogenous compounds. Arginine could be one of these compounds in addition to aspartate which seems to be essential for an efficient ureogenesis in tumor-bearing rats.     

The urea cycle in the liver of arthritic rats

The urea cycle in the liver of adjuvant-induced arthritic rats was investigated using the isolated perfused liver. Urea production in livers from arthritic rats was decreased during substrate-free perfusion and also in the presence of the following substrates: alanine, alanine + ornithine, ammonia, ammonia + lactate, ammonia + pyruvate and glutamine but increased when arginine and citrulline + aspartate were the substrates. No differences were found with ammonia + aspartate, ammonia + aspartate + glutamate, aspartate, aspartate + glutamate and citrulline. Ammonia consumption was smaller in the arthritic condition when the substance was infused together with lactate or pyruvate but higher when the substance was simultaneously infused with aspartate or aspartate + glutamate. Glucose production tended to correlate with the smaller or higher rates of urea synthesis. Blood urea was higher in arthritic rats (+25.6%), but blood ammonia was lower (–32.2%). Critical for the synthesis of urea from various substrates in arthritic rats seems to be the availability of aspartate, whose production in the liver is probably limited by both the reduced gluconeogenesis and aminotransferase activities. This is indicated by urea synthesis which was never inferior in the arthritic condition when aspartate was exogenously supplied, being even higher when both aspartate and citrulline were simultaneously present. Possibly, the liver of arthritic rats has a different substrate supply of nitrogenous compounds. This could be in the form of different concentrations of aspartate or other aminoacids such as citrulline or arginine (from the kidneys) which allow higher rates of hepatic ureogenesis.     

Use of 3H and 14C doubly labeled glucose and amino acids in the study of hormonal regulation of gluconeogenesis in rats.

Double isotope procedures (3H and 14C) were used in vivo to investigate a) slow long-term gluconeogenic actions of adrenal glucocorticoids, and b) rapid stimulation of gluconeogenesis by glucagon. [U-14C,6-3H]Glucose was administered to normal and adrenalectomized rats. No effect was observed on the [6-3H]glucose half-life suggesting the dicarboxylic acid shuttle is unaffected by adrenalectomy; the Cori cycle is also not influenced. Loads of [14C]aspartate, [14C]glutamate, or [14C]alanine were given to normal and adrenalectomized rats. Simultaneously, in vivo transaminase activity was studied by measuring the appearance of 3H2O in body water after administration of [2-3H]aspartate, [2-3H]glutamate, or [2-3H]alanine, Adrenalectomy has no influence on the incorporation of glutamate or aspartate into glucose or on their in vivo transaminases. Diminution of incorporation of [14C]alanine into glucose and alanine transaminase activities occurs only when rats are given unphysiological loads. These studies support the contention that glucocorticoid rate-limiting actions occur in extrahepatic tissues to produce an increased flow of glucose precursors to the liver. [U-14C,3-3H]Glucose was used to investigate the effect of glucagon on the hepatic fructose-6-phosphate (F-6-P) cycle. Glucagon administration resulted in a rapid drop in the 3H/14C ratio of circulating glucose, suggesting an increase in F-6-P recycling caused by activation of FDPase with little or no decrease in phosphofructokinase. Such a change would direct substrate flux toward gluconeogenesis.     

Metabolic studies in experimental liver disease resulting from d(+)-galactosamine administration

1. In confirmation of previous work, administration of d(+)-galactosamine (0.5-0.75g/kg body wt.) to rats caused a hepatitis with histological evidence of liver damage and a 9-fold rise in aspartate aminotransferase activity in serum. 2. There was a significant elevation of blood lactate and pyruvate concentrations in 24h-starved rats treated with galactosamine but no change in the [lactate]/[pyruvate] ratio. 3-Hydroxybutyrate and acetoacetate concentrations in blood were decreased. 3. The changes in the concentrations of lactate, pyruvate and ketone bodies in the freeze-clamped liver were parallel to those observed in the blood. 4. In the livers of 24h-starved galactosamine-treated rats there were large increases in the concentrations of alanine (3-fold), citrate (5-fold), 2-oxoglutarate (4-fold), with smaller increases in malate, glutamate and aspartate. There was a 4-fold rise in the value of the mass-action ratio of the alanine aminotransferase system in the livers of galactosamine-treated rats when compared to controls. 5. There was a significant decrease in the activities of aspartate and alanine aminotransferases in the cytoplasm and the soluble fraction of sonicated homogenates of the livers of rats treated with galactosamine. The activity of phosphoenolpyruvate carboxylase was decreased by 75% of the control value. 6. Glucose synthesis from lactate in perfused livers from galactosamine-treated rats was inhibited 39% when compared with controls. 7. The results indicate that the conversion of lactate into glucose is decreased in the livers of galactosamine-treated rats and that this decrease may be due to the loss of phosphoenolpyruvate carboxylase from damaged hepatocytes.     

Study of the fructose 6-phosphate/fructose 1,6-bi-phosphate cycle in the liver in vivo.

1. The method proposed by Rognstad & Katz [(1976) Arch, Biochem, Biophys, 177, 337-345] for the determination of the fructose 6-phosphate/fructose 1,6-bisphosphate cycle by the randomization of carbon between C-1 and C-6 of glucose glucose formed from [1-14C] galactose was applied to anaesthetized rats and conscious mice. 2. It was checked that the hydrolysis of fructose 6-phosphate by glucose 6-phosphatase is too weak to invalidate the method. The participation of the Cori cycle in the randomization was negligible within the short experimental period used (2-4 min). 3. No detectable randomization of carbon was observed in starved animals, indicating that phosphofructokinase is inactive in this experimental condition. 4. Randomization of carbon was detected as soon as 1 min after administration of [1-14C] galactose to fed animals and was maximal at about 3-4 min. It was calculated that on average 15% of the glucose formed by the liver to fed rats was recycled through the triose phosphates. The extent of cycling was quite variable. Recycling was also observed in starved rats in which glucose had been administered intravenously 10 min previously. In these animals, recycling was completely inhibited by glucagon. 5. The main factors that appear to be responsible for the very large changes in recycling observed in various experimental conditions are the concentrations of fructose 1,6-bisphosphate and of fructose 6-phosphate and also the affinity of phosphofructokinase for fructose 6-phosphate. The concentration of nucleotides does not seem to play a role.     

Effect of copper or insulin in diabetic copper-deficient rats

The effects of copper and insulin on lipogenesis and glucose tolerance were studied using diabetic, copper-deficient rats. Diabetes was induced by intraperitoneal injection of 50 mg streptozotocin/kg body weight to rats fed a sucrose-copper deficient diet for 7 weeks. Five days later the rats were injected intraperitoneally with [14C]glucose with either saline, insulin, copper, or copper plus insulin. The disappearance of serum [14C]glucose at 30, 60, and 120 min postinjection and the incorporation of [14C]glucose into lipid of epididymal fat 2 hr after administration were determined. The combined effect of copper and insulin significantly decreased peak blood glucose at 30 min and increased the incorporation of [14C]glucose into lipid in the epididymal fat pad when compared to either copper or insulin alone. The enhancement of glucose utilization may be due to a formation of a more stable complex which will increase insulin binding and/or decrease its degradation.