METABOLISM OF PROPIONATE BY SHEEP LIVER. OXIDATION OF PROPIONATE BY HOMOGENATES

Metabolism of propionate by sheep liver. Stimulation of the mitochondrial rate by factors from the cell sap

1. The rate of metabolism of propionate by aged sheep-liver mitochondria in the presence of oxygen + carbon dioxide (95:5) was 5.0 (+/- s.e.m. 0.8) mumoles/mg. of mitochondrial N/hr. 2. When aged in the presence of the mitochondrial supernatant the rate was increased. Mitochondria from 0.33g. of liver, when combined with the corresponding mitochondrial supernatant from 0.08g. of liver, metabolized propionate at a rate of 11.4 (+/- s.e.m. 1.2) mumoles/mg. of mitochondrial N/hr. This rate is comparable with rates previously obtained with aged nuclear-free homogenates. 3. Two factors in the mitochondrial supernatant were detected, which when combined reproduced the effect of the fresh supernatant and prevented loss of activity on aging. One of these was non-diffusible and was recovered by fractionation of the dialysed mitochondrial supernatant with ammonium sulphate. The second factor was present in an ultrafiltrate of fresh mitochondrial supernatant and in boiled mitochondrial supernatant; it was isolated and identified as l(+)-glutamate. 4. The effect of the non-diffusible factor was due to protection of the mitochondria from the aging process, whereas glutamate served both in this capacity and as a direct stimulant of propionate metabolism at low concentration.

METABOLISM OF PROPIONATE BY SHEEP LIVER. INTERRELATIONS OF PROPIONATE AND GLUTAMATE IN AGED MITOCHONDRIA

1. Low concentrations of l-glutamate were slowly and quantitatively converted into aspartate by aged sheep-liver mitochondria with the loss of C-1 of the glutamate. 2. When propionate was present in addition the rate of conversion of glutamate into aspartate was increased slightly, and the presence of glutamate caused a marked stimulation in the rate at which propionate was metabolized. 3. The stimulatory effect of ;sparker' amounts of l-glutamate on propionate metabolism was matched by the effects of alpha-oxoglutarate, pyruvate, citrate and isocitrate, but not by succinate, fumarate, malate or oxaloacetate. Succinate was stimulatory at higher concentrations, whereas oxaloacetate was inhibitory. 4. When propionate was incubated with l-[1-(14)C]glutamate in the presence of a large excess of unlabelled carbon dioxide, some labelling of dicarboxylic acids and aspartate occurred, but this was much less than would have been expected from an obligatory transcarboxylation from C-1 of alpha-oxoglutarate to propionyl-CoA. 5. Possible mechanisms of these effects are discussed.

Volatile fatty acid uptake and propionate metabolism in ruminant hepatocytes

Previous reports have demonstrated that butyrate inhibits metabolism of propionate by liver cells isolated from sheep and goats. Our objectives were to examine some possible mechanisms for this inhibition and to test for this inhibition in the bovine animal. Incorporation of label from 2.5 mM [2-(14)C]propionate into glucose (nmol propionate/mg cell DM/h) in the presence of 0, 1.25, and 2.5 mM butyrate was 107, 66, and 62 by goat hepatocytes and 79, 25, and 29 by calf hepatocytes; therefore, butyrate inhibited propionate metabolism at least as effectively in calves as in goats. In goat hepatocytes 1.25 mM butyrate reduced 1.25 mM propionate uptake to 46% of control, and 1.25 mM [2-(14)C] propionate incorporation into glucose to 44% of control. Propionate had no effect on butyrate uptake. Isovalerate and valerate tended to be cleared from the media to a greater extent than butyrate but had no effect on propionate uptake. Therefore, inhibition of propionate conversion to glucose by butyrate is specific and is not due to a general competition among VFA for metabolism. Butyrate inhibits hepatic propionate utilization generally, not specifically propionate conversion to glucose. Butyrate also inhibited propionate utilization by goat liver homogenates, indicating that butyrate inhibits propionate metabolism at a step subsequent to propionate transport across the hepatocyte plasma membrane.

Metabolic effects of pent-4-enoate in isolated perfused rat heart

The metabolic effects of the hypoglycaemic agent pent-4-enoate were studied in isolated, beating or potassium-arrested rat hearts. The addition of 0.8mM-pent-4-enoate to the perfusion fluid increased O2 consumption by 76% in the arrested heart and by 14% in the beating heart; the concentration ratio of phosphocreatine/creatine increase concomitantly by 47% and 27% respectively. Perfusion of the heart with pent-4-enoate resulted in a 30-fold increase in the concentration of the pool of tricarboxylic acid-cycle intermediates in the tissue, about 90% of this increase being due to malate. The sum of the concentrations of the myocardial free amino acids remained virtually unchanged during the accumulation of the tricarboxylic acid-cycle intermediates. It was concluded that pent-4-enoate can be effectively metabolized in the myocardium and that its metabolism probably proceeds via propionyl-CoA, since pent-4-enoate reproduces many of the metabolic characteristics of propionate in the cardiac muscle. The accumulation of the tricarboxylic acid-cycle intermediates is probably due to carboxylation of propionyl-CoA. The response pattern of the metabolite concentrations in the cardiac muscle is quite different from that in the liver, in which decrease of the concentrations of the tricarboxylic acid-cycle intermediates has been observed previously [Williamson, Rostand & Peterson (1970) J. Biol. Chem. 245, 3242-3251].

Synthesis of phosphoenolpyruvate from propionate in sheep liver

1. Utilization of propionate by sheep liver mitochondria was stimulated equally by pyruvate or alpha-oxoglutarate, with formation predominantly of malate. Pyruvate increased conversion of propionate carbon into citrate, whereas alpha-oxoglutarate increased formation of phosphoenolpyruvate. The fraction of metabolized propionate converted into phosphoenolpyruvate was about 17% in the presence or absence of alpha-oxoglutarate and about 7% in the presence of pyruvate. Pyruvate consumption was inhibited by 80% by 5mm-propionate. 2. Compared with rat liver, sheep liver was characterized by very high activities of phosphoenolpyruvate carboxykinase and moderately high activities of aconitase in the mitochondria and by low activities of ;malic' enzyme, pyruvate kinase and lactate dehydrogenase in the cytosol. Activities of phosphoenolpyruvate carboxy-kinase were similar in liver cytosol from rats and sheep. Activities of malate dehydrogenase and NADP-linked isocitrate dehydrogenase in sheep liver were about half those in rat liver. 3. The phosphate-dicarboxylate antiport was active in sheep liver mitochondria, but compared with rat liver mitochondria the citrate-malate antiport showed only low activity and mitochondrial aconitase was relatively inaccessible to external citrate. The rate of swelling of mitochondria induced by phosphate in solutions of ammonium malate was inversely related to the concentration of malate. 4. The results are discussed in relation to gluconeogenesis from propionate in sheep liver. It is proposed that propionate is converted into malate by the mitochondria and the malate is converted into phosphoenolpyruvate by enzymes in the cytosol. In this way sufficient NADH would be generated in the cytosol to convert the phosphoenolpyruvate into glucose.

Interactions of acetate, propionate and butyrate in sheep liver mitochondria

1. Interactions in the rates of consumption of acetate, propionate and butyrate in sheep liver mitochondria were examined in the presence and absence of l-malate and alpha-oxoglutarate. 2. Acetate was not consumed in absence of ancillary substrate but utilization of acetate (7.2nmol/min per mg of protein) occurred in the presence of alpha-oxoglutarate. This consumption was abolished by propionate or butyrate but the presence of acetate did not affect consumption of propionate or butyrate. 3. Propionate consumption (10.1nmol/min per mg of protein) was unaffected by malate but was stimulated by 63% by butyrate or by 180% by alpha-oxoglutarate. 4. Butyrate consumption (3.3nmol/min per mg of protein) was stimulated by 117% by malate, by 151% by propionate and by 310% by alpha-oxoglutarate. 5. In the absence of ancillary substrates the maximum rate of total volatile fatty acid utilization (24.7nmol/min per mg of protein) occurred with a mixture of propionate and butyrate. When both propionate and butyrate were present total consumption was not affected by malate but was stimulated by 24% by alpha-oxoglutarate. With alpha-oxoglutarate present, propionate and butyrate each decreased the other's consumption by about 26%, but the total utilization was the greatest observed. 6. The inhibition of acetate consumption by propionate or butyrate is unexplained, but the remaining effects are consistent with an interaction of propionate and butyrate through oxaloacetate together with a general limitation imposed by a need for GTP to rephosphorylate AMP formed during activation of the volatile fatty acids.

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.

Metabolism of propionate by sheep-liver mitochondria. Effects of alpha-oxoglutarate, adenosine triphosphate, sodium chloride and potassium chloride

1. A study has been made of the effects of ATP and alpha-oxoglutarate on the rate of metabolism of propionate by whole mitochondria from sheep liver, and by mitochondria disrupted with ultrasonic energy or by freezing and thawing. Whole mitochondria metabolized propionate aerobically; the rate was increased and stabilized by 0.5mm-ATP, and increased at least a further 50% by 1.67mm-alpha-oxoglutarate. 2. Anaerobically, externally added ATP at high concentrations permitted slow consumption of propionate. 3. In the presence of 1.3mm-ATP, but in the absence of alpha-oxoglutarate, there was no significant lag phase in the removal of propionate by whole mitochondria, and the rate declined at concentrations below 2mm. In the additional presence of 1.67mm-alpha-oxoglutarate or -glutamate, propionate was removed at linear rates until the residual propionate concentration was about 0.1mm. 4. Maximum rates of metabolism of propionate by whole mitochondria with 1.3mm-ATP occurred with alkali-metal chloride concentrations of 65-95mm and with K(+)/Na(+) ratios 5-10, both in the presence and absence of alpha-oxoglutarate. 5. With disrupted mitochondria stimulatory effects of alpha-oxoglutarate were obtained only aerobically, only with propionate and not propionyl-CoA as substrate, and only when sufficient mitochondrial structure remained to permit unsupplemented metabolism of propionate to occur. 6. In the presence of ATP and CoA, disrupted mitochondria fixed [2-(14)C]propionate at a rate adequate to explain the rate with whole mitochondria stimulated with ATP and alpha-oxoglutarate. 7. With both whole and partially disrupted mitochondria in the absence of ATP, the rate of metabolism of propionate was inhibited by about 80% by 3.3mm-AMP. The inhibition was partly overcome by alpha-oxoglutarate plus CoA. 8. It is concluded that the ultimate effect of alpha-oxoglutarate was to increase the rate of supply of ATP within the mitochondria. Reasons are given why it is premature to conclude that the extra ATP arose entirely from the oxidation of alpha-oxoglutarate itself.

Metabolism of propionate by sheep liver. Pathway of propionate metabolism in aged homogenate and mitochondria

Experiments were conducted with aged nuclear-free homogenate of sheep liver and aged mitochondria in an attempt to measure both the extent of oxidation of propionate and the distribution of label from [2-(14)C]propionate in the products. With nuclear-free homogenate, propionate was 44% oxidized with the accumulation of succinate, fumarate, malate and some citrate. Recovery of (14)C in these intermediates and respiratory carbon dioxide was only 33%, but additional label was detected in endogenous glutamate and aspartate. With washed mitochondria 30% oxidation of metabolized propionate occurred, and proportionately more citrate and malate accumulated. Recovery of (14)C in dicarboxylic acids, citrate, alpha-oxoglutarate, glutamate, aspartate and respiratory carbon dioxide was 91%. The specific activities of the products and the distribution of label in the carbon atoms of the dicarboxylic acids were consistent with the operation solely of the methylmalonate pathway together with limited oxidation of the succinate formed by the tricarboxylic acid cycle via pyruvate. In a final experiment with mitochondria the label consumed from [2-(14)C]propionate was entirely recovered in the intermediates of the tricarboxylic acid cycle, glutamate, aspartate, methylmalonate and respiratory carbon dioxide.

Metabolism of propionate by sheep-liver mitochondria. Evidence for rate control by a specific succinate oxidase

1. Metabolism of propionate by sheep-liver mitochondria was stimulated catalytically by alpha-oxoglutarate, pyruvate, citrate and isocitrate. Succinate was stimulatory at higher concentrations, but fumarate and malate were inert. These effects were all independent of the presence of ATP, succinate being less effective when ATP was present. 2. Compared with the metabolism of added succinate, propionate metabolism was resistant to malonate inhibition, but only in the presence of added ATP. In the absence of ATP propionate metabolism was more sensitive to malonate inhibition than was the metabolism of succinate. 3. In the absence of malonate, and at malonate concentrations in the range 5-100mm, alpha-oxoglutarate increased the rate of fixation of [2-(14)C]propionate by about 50% without altering the nature of the fixation products. 4. Metabolism of [1-(14)C]-propionate in the presence of 50mm-malonate was accompanied by accumulation of about half the propionate consumed as succinate. When alpha-oxoglutarate was present in addition part of the alpha-oxoglutarate was metabolized and the rate of propionate consumption was increased. The total succinate that accumulated corresponded to the alpha-oxoglutarate consumed plus about half the propionate metabolized. 5. When [1-(14)C]propionate was metabolized in the absence of malonate about 70% of the generated succinate was oxidized to fumarate or beyond. The addition of malonate decreased the rate of propionate metabolism, and decreased to about half the fraction of generated succinate oxidized. 6. When propionate and 10mm-succinate were metabolized together, the total oxidation of succinate was greater than that with 10mm-succinate alone. The increment in succinate oxidation corresponded to about half the propionate metabolized in the presence or absence of malonate or ATP. 7. It is suggested that the metabolism of propionate is specifically limited by the rate of oxidation of the generated succinate, and that the succinate oxidase concerned is distinct from that responsible for the oxidation of added succinate. 8. The results are discussed in terms of the mode of action of certain stimulants and inhibitors of propionate metabolism. It is suggested that many of these act by stimulation or inhibition of the specific succinate oxidase that limits propionate metabolism.