Carbohydrate metabolism in the isolated perfused rat kidney

1. Anaerobic formation of lactate from glucose by isolated perfused rat kidney (411mumol/h per g dry wt.) was three times as fast as in aerobic conditions (138mumol/h per g). 2. In aerobic or in anaerobic conditions, the ratio of lactate production to glucose utilization was about 2. 3. Starvation or acidosis caused a decline of about 30% in the rate of aerobic glycolysis. 4. The rate of formation of glucose from lactate by perfused kidney from a well-fed rat, in the presence of 5mm-acetoacetate (83mumol/h per g dry wt.), was of the same order as the rate of aerobic glycolysis. 5. During perfusion with physiological concentrations of glucose (5mm) and lactate (2mm) there were negligible changes in the concentration of either substrate. 6. Comparison of kidneys perfused with lactate, from well-fed or starved rats, showed no major differences in contents of intermediates of gluconeogenesis. 7. The tissue concentrations of hexose monophosphates and C(3) phosphorylated glycolytic intermediates (except triose phosphate) were decreased in anaerobic conditions. 8. Aerobic metabolism of fructose by perfused kidney was rapid: the rate of glucose formation was 726mumol/h per g dry wt. and of lactate formation 168mumol/h per g (dry wt.). Glycerol and d-glyceraldehyde were also released into the medium. 9. Aerobically, fructose generated high concentrations of glycolytic intermediates. 10. Anaerobic production of lactate from fructose (74mumol/h per g dry wt.) was slower than the aerobic rate. 11. In both anaerobic and aerobic conditions the ratio [lactate]/[pyruvate] in kidney or medium was lower during perfusion with fructose than with glucose. 12. These results are discussed in terms of the regulation of renal carbohydrate metabolism.     

PGE1 metabolism by the perfused rat liver

The hepatic and biliary metabolites of PGE1 have been isolated and identified after infusions of PGE1 into isolated rat liver preparations. The results demonstrate that in general PGE1 undergoes metabolism similar to that of PGE2 in the rat and reveals the possibility of a selective PG metabolite transport system across the biliary canalicular membrane.     

Xylitol metabolism in the isolated perfused rat liver

1. Loading the isolated perfused liver from well-fed rats with xylitol (20mm) caused a depletion of adenine nucleotides and P_i and an accumulation of α-glycerophosphate. The ATP content fell to 66% of the control value after 10min and to 32% after 80min. The ADP and AMP contents also fell. After 80min 63% of the total adenine nucleotides and 59% of the P_i had been lost. 2. The α-glycerophosphate content rose from 0.13 to 4.74μmol/g at 10min and reached 8.02μmol/g at 40min. 3. Xylitol was rapidly metabolized, the main products being glucose, lactate and pyruvate. 4. The [lactate]/[pyruvate] ratio in the presence of xylitol rose to 30–40. 5. On perfusion of livers from starved animals the main product of xylitol metabolism was glucose and the mean ratio xylitol removed/glucose formed was 1.29 (corrected for endogenous glucose and lactate production). This is close to the predicted value of 1.2. 6. Evidence is presented indicating that the loss of adenine nucleotides caused by xylitol is not due to the increased ATP consumption but to the accumulation of α-glycerophosphate and depletion of P_i. 7. The loss of adenine nucleotides accounts for the hyperuricaemia which can occur after xylitol infusion in man. 8. The relevance of the findings to the clinical use of xylitol as an energy source is discussed.     

Fatty acid metabolism in the perfused rat liver

1. The formation of acetoacetate, beta-hydroxybutyrate and glucose was measured in the isolated perfused rat liver after addition of fatty acids. 2. The rates of ketone-body formation from ten fatty acids were approximately equal and independent of chain length (90-132mumol/h per g), with the exception of pentanoate, which reacted at one-third of this rate. The [beta-hydroxybutyrate]/[acetoacetate] ratio in the perfusion medium was increased by long-chain fatty acids. 3. Glucose was formed from all odd-numbered fatty acids tested. 4. The rate of ketone-body formation in the livers of rats kept on a high-fat diet was up to 50% higher than in the livers of rats starved for 48h. In the livers of fat-fed rats almost all the O(2) consumed was accounted for by the formation of ketone bodies. 5. The ketone-body concentration in the blood of fat-fed rats rose to 4-5mm and the [beta-hydroxybutyrate]/[acetoacetate] ratio rose to 11.5. 6. When the activity of the microsomal mixed-function oxidase system, which can bring about omega-oxidation of fatty acids, was induced by treatment of the rat with phenobarbitone, there was no change in the ketone-body production from fatty acids, nor was there a production of glucose from even-numbered fatty acids. The latter would be expected if omega-oxidation occurred. Thus omega-oxidation did not play a significant role in the metabolism of fatty acids. 7. Arachidonate was almost quantitatively converted into ketone bodies and yielded no glucose, demonstrating that gluconeogenesis from poly-unsaturated fatty acids with an even number of carbon atoms does not occur. 8. The rates of ketogenesis from unsaturated fatty acids (sorbate, undecylenate, crotonate, vinylacetate) were similar to those from the corresponding saturated fatty acids. 9. Addition of oleate together with shorter-chain fatty acids gave only a slightly higher rate of ketone-body formation than oleate alone. 10. Glucose, lactate, fructose, glycerol and other known antiketogenic substances strongly inhibited endogenous ketogenesis but had no effects on the rate of ketone-body formation in the presence of 2mm-oleate. Thus the concentrations of free fatty acids and of other oxidizable substances in the liver are key factors determining the rate of ketogenesis.     

The metabolism of fructose in the bivascularly perfused rat liver.

The metabolism of fructose was investigated in the bivascularly and hemoglobin-free perfused rat liver. Anterograde and retrograde perfusions were performed. In anterograde perfusion, fructose was infused at identical rates (19 mumols min-1 g-1) via the portal vein (all liver cells) or the hepatic artery (predominantly perivenous cells); in retrograde perfusion fructose was infused via the hepatic vein (all liver cells) or the hepatic artery (only periportal cells). The cellular water spaces accessible via the hepatic artery were measured by means of the multiple-indicator dilution technique. The following results were obtained. (i) Fructose was metabolized to glucose, lactate and pyruvate even when this substrate was infused via the hepatic artery in retrograde perfusion; oxygen consumption was also increased. (ii) When referred to the water spaces accessible to fructose via the hepatic artery in each perfusion mode, the rate of glycolysis was 0.99 +/- 0.14 mumols min-1 ml-1 in the retrograde mode; and, 2.05 +/- 0.19 mumols min-1 ml-1 in the anterograde mode (P = 0.002). (iii) The extra oxygen uptake due to fructose infusion via the hepatic artery was 1.09 +/- 0.16 mumols min-1 ml-1 in the retrograde mode; and, 0.51 +/- 0.08 mumols min-1 ml-1 in the anterograde mode (P = 0.005). (iv) Glucose production from fructose via the hepatic artery was 2.18 +/- 0.18 mumols min-1 ml-1 in the retrograde mode; and, 1.83 +/- 0.16 mumols min-1 ml-1 in the anterograde mode (P = 0.18). (v) Glucose production and extra oxygen uptake due to fructose infusion did not correlate by a single factor in all perfusion modes. It was concluded that: (a) rates of glycolysis are lower in the periportal area, confirming previous views; (b) extra oxygen uptake due to fructose infusion is higher in the periportal area; (c) a predominance of glucose production in the periportal area could not be demonstrated; and (d) extra oxygen uptake due to fructose infusion is not a precise indicator for glucose synthesis.     

pH-dependency of iodothyronine metabolism in isolated perfused rat liver.

1. Isolated livers from fed male rats were perfused for 2 h with T4 (L-thyroxine), T3 (L-3,3',5-tri-iodothyronine) or rT3 (L-3,3',5'-tri-iodothyronine) at different pH values (7.1--7.6) in a fully synthetic medium, whereby normal metabolic functions were maintained without addition of rat blood constituents or albumin. 2. T3 output into the medium and net T3 production reached a maximum at a pH of the medium of 7.2 and significantly decreased with alteration of the pH when livers were perfused with T4 as a substrate. 3. However, the net T4 and T3 uptake by the liver, as well as the hepatic T4 and T3 content after perfusion, were not dependent on the pH of the perfusion when livers were offered T4 or T3 as substrates respectively. 4. Determination of intracellular pH by the analysis of the distribution of the weak acid dimethyloxazolidinedione allows the conclusion that the pH optimum of iodothyronine 5'-deiodinase in the intact perfused liver corresponds to the maximum determined in vitro for the membrane-bound enzyme localized in the endoplasmic reticulum. 5. The rapid 5'-deiodination of rT3 to 3,3'-T2 (L-3,3'-di-iodothyronine), the fast disappearance of 3,3'-T2, and the fact that no net rT3 production from T4 could be detected, supports the hypothesis that in rat liver iodothyronine 5'-deiodinase activity seems to predominate over iodothyronine 5-deiodinase activity. 6. Thus the rat liver can be considered in normal physiological situations as an organ forming T3 from T4 and deiodinating rT3 originating from extrahepatic tissues, whereby the cellular iodothyronine 5'-deiodination rate is controlled by the intracellular pH.     

PGE1 metabolism by the perfused rat liver

The hepatic and biliary metabolites of PGE₁ have been isolated and identified after infusions of PGE₁ into isolated rat liver preparations. The results demonstrate that in general PGE₁ undergoes metabolism similar to that of PGE₂ in the rat and reveals the possibility of a selective PG metabolite transport system across the biliary canalicular membrane.     

Acute effects of carbon monoxide on the metabolism of perfused rat liver

1. Perfusion of livers with whole blood containing carboxyhaemoglobin decreased hepatic O(2) consumption and triglyceride secretion and raised free fatty acid oxidation. 2. Perfusion with [(14)C]carboxyhaemoglobin indicated that there was negligible hepatic uptake of (14)CO. 3. The observations appear to be due to a decrease in O(2) consumption rather than to specific effects of carboxyhaemoglobin.     

The shunt pathway of mevalonate metabolism in the isolated perfused rat liver

The shunt pathway of mevalonate metabolism (Edmond, J., and Popják, G. (1974) J. Biol. Chem. 249, 66-71) has been studied in isolated livers from fed rats perfused with physiological concentrations of variously labeled [14C]mevalonates. The measured rates of 14CO2 production were converted to rates of mitochondrial acetyl-CoA production from mevalonate by methods which take into account underestimations of metabolic rates derived from 14CO2 production. Our data confirm that the shunt pathway leads to mitochondrial acetyl-CoA. The apparent negligible rate of mevalonate shunting in liver, previously reported by others, stems from the very low contribution (congruent to 0.1%) of plasma mevalonate to total mevalonate metabolism in the liver. This contribution was assessed from the relative incorporations of 3H2O and [5-14C]mevalonate into sterols. In livers from fed rats, the shunt diverts about 5% of the production of mevalonate. The total rate of mevalonate shunting in the liver is about 200 times greater than in two kidneys. The liver is therefore the main site of mevalonate shunting in the rat.