Enzymes of l-(+)-3-hydroxybutyrate metabolism in the rat

The three enzymes required for the production and utilization of l-(+)-3-hydroxybutyrate were sought in various tissues of the rat. All tissues examined contained substantial amounts of (No. 1) l-(+)-3-hydroxybutyryl CoA dehydrogenase (EC 1.1.1.35). The specific activity of (No. 2) l-(+)-3-hydroxybutyryl CoA deacylase (EC 3.1.2) was highest in liver (3.8 mU/mg in mitochondrial matrix (1 U = 1 μmol/min). Brain, heart, and skeletal muscle contained < 20% of this activity. The chromatography of liver mitochondrial “matrix” preparations on DEAE-cellulose resolved the deacylase into two peaks. Peak I hydrolyzed 2- or 3- carbon acylCoA esters more efficiently than l-(+)-3-hydroxybutyrate CoA, while Peak II activity was highest using l-(+)-3-hydroxybutyryl CoA. The K_m(app) for Peak II deacylase with l-(+)-3-hydroxybutyryl CoA was 19 μm. Acyl CoA synthetase (EC 6.2.1.2) (No. 3) was assayed with sorbate (sorboyl CoA ligase) or l-(+)-3-hydroxybutyrate (l-(+)-3-hydroxybutyryl CoA ligase). The highest specific activity for l-(+)-3-hydroxybutyryl CoA ligase was associated with brain mitochondria (8.3 mU/mg). In the “matrix” fraction of rat liver mitochondria the activities of these two acyl CoA synthetases were distinguished chromatographically and by their stability at various pH values. Heart and skeletal muscle mitochondria contained <10% of the liver activities of both ligases. These data implicate the liver as a site of l-(+)-3-hydroxybutyrate production.     

Inhibition of d(-)-3-hydroxybutyrate dehydrogenase by malonate analoges

(1) d(-)-3-Hydroxybutyrate dehydrogenase activity from guinea pig, rat, and bovine heart and from guinea pig liver is inhibited by malonate and tartronate, and more potently by the analogs methylmalonate, bromomalonate, chloromalonate, and mesoxalate. Little or no inhibitory effect was found for aminomalonate, ethylmalonate, dimethylmalonate, succinate, glutarate, oxaloacetate, malate, propionate, pyruvate, d- and l-lactate, n-butyrate, isobutyrate, and cyclopropanecarboxylate. (2) In initial velocity kinetics at pH 8.1 with a soluble enzyme preparation from bovine heart, the inhibition by the active malonate derivatives is competitive with respect to 3-hydroxybutyrate and uncompetitive with respect to acetoacetate, NAD⁺ or NADH. With d-3-hydroxybutyrate as the variable reactant (K_{m app} = 0.26 mM) the inhibition constant of methylmalonate (K_is) was 0.09 mm. (3) The rate of utilization of d-3-hydroxybutyrate (78 μm) by coupled rat heart mitochondria in the presence of ADP was inhibited 50% by 150 μm methylmalonate. (4) With coupled guinea pig liver mitochondria oxidizing n-octanoate in the absence of added ADP, methylmalonate (1–3 mm) depressed 3-hydroxybutyrate formation substantially more than total ketone production. However, the intramitochondrial NADH (or NADPH) levels were unchanged by the addition of methylmalonate, indicating that the changes in ratios of accumulated 3-hydroxybutyrate and acetoacetate were caused by direct inhibition of 3-hydroxybutyrate dehydrogenase. Methylmalonate had the same effect on 3-hydroxybutyrate/acetoacetate ratios and ketone body formation with pyruvate or acetate as the source of acetyl groups. Similar results were obtained with malonate (10 mm) although the inhibition of total ketone formation from octanoate was more severe.     

Modified oscillation behavior and decreased D-3-hydroxybutyrate dehydrogenase activity in diabetic rat liver mitochondria

One month after induction of diabetes in adult white rats with streptozotocin or 4–10 months after its induction by pancreatectomy (in every case glycemia was over 3 g/liter), the following alterations were observed in liver mitochondria: (a) a decrease of amplitude and an increase of the damping factor of volume oscillations induced by potassium ions and valinomycin; (b) a 50% decrease of d-3-hydroxybutyrate dehydrogenase (HBD) activity in mitochondria disrupted by repeated freeze-thawing; (c) a similar decrease in the rate of d-3-hydroxybutyrate oxidation by intact mitochondria; (d) a significant increase of cytochrome oxidase activity and cytochrome aa₃ content. Measurement of succinate dehydrogenase and NADH dehydrogenase activity, the cytochrome b, c₁, and c content, and the P:O ratio for mitochondria oxidizing d-3-hydroxybutyrate did not reveal significant differences between control and diabetic rat mitochondria. In the streptozotocin-injected rats, the variation of HBD activity and the modification of the mitochondrial oscillation pattern were time-dependent phenomena, both effects reaching their maximal expression about 1 month after the onset of diabetes. The variation of HBD activity followed a biphasic course, since it rose to above the control level during the first 2 weeks of diabetes, then fell progressively to about half the control value after the third week. Treatment of diabetic rats with NPH insulin (5 IU twice daily, for 3 days, reinforced by the same dose 45 min before sacrifice) restored the mitochondrial oscillation pattern, HBD activity, and rate of d-3-hydroxybutyrate oxidation by intact mitochondria to their normal values.     

Characterization of propionate CoA-transferase from Ralstonia eutropha H16

In this study, a propionate CoA-transferase (H16_A2718; EC 2.8.3.1) from Ralstonia eutropha H16 (Pct _Re ) was characterized in detail. Glu342 was identified as catalytically active amino acid residue via site-directed mutagenesis. Activity of Pct _Re was irreversibly lost after the treatment with NaBH₄ in the presence of acetyl-CoA as it is shown for all CoA-transferases from class I, thereby confirming the formation of the covalent enzyme-CoA intermediate by Pct _Re . In addition to already known CoA acceptors for Pct _Re such as 3-hydroxypropionate, 3-hydroxybutyrate, acrylate, succinate, lactate, butyrate, crotonate and 4-hydroxybutyrate, it was found that glycolate, chloropropionate, acetoacetate, valerate, trans-2,3-pentenoate, isovalerate, hexanoate, octanoate and trans-2,3-octenoate formed also corresponding CoA-thioesters after incubation with acetyl-CoA and Pct _Re . Isobutyrate was found to be preferentially used as CoA acceptor amongst other carboxylates tested in this study. In contrast, no products were detected with acetyl-CoA and formiate, bromopropionate, glycine, pyruvate, 2-hydroxybutyrate, malonate, fumarate, itaconate, β-alanine, γ-aminobutyrate, levulate, glutarate or adipate as potential CoA acceptor. Amongst CoA donors, butyryl-CoA, crotonyl-CoA, 3-hydroxybutyryl-CoA, isobutyryl-CoA, succinyl-CoA and valeryl-CoA apart from already known propionyl-CoA and acetyl-CoA could also donate CoA to acetate. The highest rate of the reaction was observed with 3-hydroxybutyryl-CoA (2.5 μmol mg^?1 min^?1). K _m values for propionyl-CoA, acetyl-CoA, acetate and 3-hydroxybutyrate were 0.3, 0.6, 4.5 and 4.3 mM, respectively. The rather broad substrate range might be a good starting point for enzyme engineering approaches and for the application of Pct _Re in biotechnological polyester production.     

Lactate and Acrylate Metabolism by Megasphaera elsdenii under Batch and Steady-State Conditions

The growth of Megasphaera elsdenii on lactate with acrylate and acrylate analogues was studied under batch and steady-state conditions. Under batch conditions, lactate was converted to acetate and propionate, and acrylate was converted into propionate. Acrylate analogues 2-methyl propenoate and 3-butenoate containing a terminal double bond were similarly converted into their respective saturated acids (isobutyrate and butyrate), while crotonate and lactate analogues 3-hydroxybutyrate and (R)-2-hydroxybutyrate were not metabolized. Under carbon-limited steady-state conditions, lactate was converted to acetate and butyrate with no propionate formed. As the acrylate concentration in the feed was increased, butyrate and hydrogen formation decreased and propionate was increasingly generated, while the calculated ATP yield was unchanged. M. elsdenii metabolism differs substantially under batch and steady-state conditions. The results support the conclusion that propionate is not formed during lactate-limited steady-state growth because of the absence of this substrate to drive the formation of lactyl coenzyme A (CoA) via propionyl-CoA transferase. Acrylate and acrylate analogues are reduced under both batch and steady-state growth conditions after first being converted to thioesters via propionyl-CoA transferase. Our findings demonstrate the central role that CoA transferase activity plays in the utilization of acids by M. elsdenii and allows us to propose a modified acrylate pathway for M. elsdenii.     

The role of acetyl coenzyme A: butyrate coenzyme A in the transferase uptake of butyrate by isolated membrane vesicles of Escherichia coli

The acetyl CoA:butyrate CoA transferase catalyzes the translocation of butyrate in membrane vesicles prepared from a strain of Escherichia coli which is depressed for the acetoacetate degradation operon. Butyrate accumulated in the membranes as butyryl CoA. The role of the transferase in uptake is supported by the following observations: (i) uptake is stimulated by acetyl CoA; (ii) the solubilized CoA transferase and uptake exhibit K_mS for butyrate, pH optima and levels inhibition by N-ethylmaleimide that are virtually identical; (iii) significant amounts of the CoA transferase are found associated with the membranes and uptake is rapidly inhibited by butyryl CoA and acetate, the products of the CoA transferase-catalyzed reaction. The fact that butyrate uptake did not exhibit saturation kinetics with increasing concentrations of acetyl CoA suggested that the transferase is not localized on the outer surface of the membrane. The level of free butyrate in the vesicles, the fact that butyrate uptake exhibited saturation kinetics with increasing concentrations of butyrate, and the observation that radioactivity was not rapidly lost from the vesicles following addition of butyryl CoA or acetate to incubation mixtures indicated that butyrate is translocated rather than trapped by the CoA transferase.     

Reconstitution of highly purified proton-translocating pyrophosphatase from Rhodospirillum rubrum

Overt carnitine palmitoyl transferase (CPT₁) activity was measured in liver mitochondria from foetal rats (21 days gestation) and from neonatal rats (1 day post-partum). Birth was accompanied by a 6-fold increase in CPT₁ activity, a 14-fold decrease in sensitivity to inhibition by malonyl CoA and an increase in the n_H and the S_0.5 from palmitoyl CoA. The activity of latent enzyme (CPT₂) was unaffected at birth.     

Acetoacetate metabolism in AS-30D hepatoma cells

Metabolic characteristics of experimental hepatoma cells include elevated rates of glycolysis and lipid synthesis. However, pyruvate derived from glucose is not redily oxidized, and the source of acetly CoA for lipid synthesis in As-39D cells has not been characterized. In this study ketone bodies were examined as a possible source of acetyl CoA in AS-30D hepatoma cells.The major findings were:

High-performance liquid chromatography determination of ketone bodies in human plasma by precolumn derivatization with p-nitrobenzene diazonium fluoroborate

We developed and validated a sensitive and convenient high-performance liquid chromatography (HPLC) method for the specific determination of ketone bodies (acetoacetate and d-3-hydroxybutyrate) in human plasma. p-Nitrobenzene diazonium fluoroborate (diazo reagent) was used as a precolumn derivatization agent, and 3-(2-hydroxyphenyl) propionic acid was used as an internal standard. After the reaction, excess diazo reagent and plasma proteins were removed by passing through a solid-phase cartridge (C₁₈). The derivatives retained on the cartridge were eluted with methanol, introduced into the HPLC system, and then detected with UV at 380 nm. A calibration curve for acetoacetate standard solution with a 20-μl injection volume showed good linearity in the range of 1 to 400 μM with a 0.9997 correlation coefficient. For the determination of d-3-hydroxybutyrate, it was converted to acetoacetate before reaction with the diazo reagent by an enzymatic coupling method using d-3-hydroxybutyrate dehydrogenase and lactate dehydrogenase. A calibration curve for d-3-hydroxybutyrate standard solution also showed good linearity in the range of 1.5 to 2000 μM with a 0.9988 correlation coefficient. Analytical recoveries of acetoacetate and d-3-hydroxybutyrate in human plasma were satisfactory. The method was successfully applied to samples from diabetic patients, and results were consistent with those obtained using the thio-NAD enzymatic cycling method used in clinical laboratories.     

ATP synthesis in a succinate decarboxylase system from Fasciola hepatica mitochondria

Köhler P. B.,Ryant C. and Behm Carolyn A. 1978. ATP synthesis in a succinate decarboxylase system from Fasciola hepatica mitochondria. International Journal for Parasitology8: 399–404. Succinate decarboxylation was measured by the formation of ¹⁴CO₂ from 1,4-¹⁴C-succinate in a particle free, dialysed mitochondrial extract from liver fluke. It has an absolute requirement for Mg²⁺ and CoA. ATP, ADP and inorganic phosphate are essential for optimal activity. Ap₅A, an inhibitor of adenylate kinase, and glutathione are also necessary. GTP supports decarboxylation as well as ATP, provided ADP is also present. The formation of CO₂ and propionate greatly exceeds the amount of ATP and CoA initially present in the reaction mixture. A net, substrate-level phosphorylation of ADP occurs, the amount of ATP formed being equivalent to the production of CO₂ or propionate. This system is inhibited in flukes incubated in vitro with mebendazole.It is concluded that ATP is required to spark the fermentation system when succinate is the initial substrate and intermediate substrates are absent; that the terminal step in propionate formation is catalysed by a transferase which transfers CoA from propionyl CoA to succinate; and that ATP formation is coupled to the decarboxylation of methylmalonyl-CoA. A reaction scheme is presented.     

Energy Metabolism in Rat Brain: Inhibition of Pyruvate Decarboxylation by 3-Hydroxybutyrate in Neonatal Mitochondria

Abstract: The effect of 3-hydroxybutyrate on pyruvate decarboxylation by neonatal rat brain mitochondria and synaptosomes was investigated. The rate of [1 -¹⁴C]pyruvate decarboxylation (1 mm final concentration) by brain synaptosomes derived from 8-day-old rats was inhibited by 10% in the presence of 2 mm -d ,l -3-hydroxybutyrate and by more than 20% in the presence of 20 mm -d ,l -3-hydroxybutyrate. The presence of 2 mm -l ,d -3-hydroxybutyrate did not affect the rate of [1-¹⁴T]pyruvate decarboxylation (1 mm final concentration) by brain mitochondria; however, at a concentration of 20 mm -d ,l -3-hydroxybutyrate, a marked inhibition was seen in preparations from both 8-day-old (35% inhibition) and 21-day-old (24% inhibition) but not in those from adult rats. Although the presence of 100 mm -K⁺ in the incubation medium stimulated the rate of pyruvate decarboxylation by approximately 50% compared with the rate in the presence of 1 mm -K⁺, the presence of 20 mm -d ,l -3-hydroxybutyrate still caused a marked inhibition in both media (1 and 100 mm -K⁺). The presence of 20 mm -d ,l -3-hydroxybutyrate during the incubation caused an approximately 20% decrease in the level of the active form of the pyruvate dehydrogenase complex in brain mitochondria from 8-day-old rats. The concentrations of ATP, ADP, NAD⁺, NADH, acetyl CoA, and CoA were measured in brain mitochondria from 8-day-old rats incubated in the presence of 1 mm -pyruvate alone or 1 mm -pyruvate plus 20 mm -d ,l -3-hydroxybutyrate. Neither the ATP/ADP nor the NADH/NAD⁺ ratio showed significant changes. The acetyl CoA/CoA ratio was significantly increased by more than twofold in the presence of 3-hydroxybutyrate. The possible mechanisms and physiological significance of 3-hydroxybutyrate inhibition of pyruvate decarboxylation in neonatal rat brain mitochondria are discussed.     

Impact of Peripheral Ketolytic Deficiency on Hepatic Ketogenesis and Gluconeogenesis during the Transition to Birth

Preservation of bioenergetic homeostasis during the transition from the carbohydrate-laden fetal diet to the high fat, low carbohydrate neonatal diet requires inductions of hepatic fatty acid oxidation, gluconeogenesis, and ketogenesis. Mice with loss-of-function mutation in the extrahepatic mitochondrial enzyme CoA transferase (succinyl-CoA:3-oxoacid CoA transferase, SCOT, encoded by nuclear Oxct1) cannot terminally oxidize ketone bodies and develop lethal hyperketonemic hypoglycemia within 48 h of birth. Here we use this model to demonstrate that loss of ketone body oxidation, an exclusively extrahepatic process, disrupts hepatic intermediary metabolic homeostasis after high fat mother''s milk is ingested. Livers of SCOT-knock-out (SCOT-KO) neonates induce the expression of the genes encoding peroxisome proliferator-activated receptor γ co-activator-1a (PGC-1α), phosphoenolpyruvate carboxykinase (PEPCK), pyruvate carboxylase, and glucose-6-phosphatase, and the neonate''s pools of gluconeogenic alanine and lactate are each diminished by 50%. NMR-based quantitative fate mapping of ¹³C-labeled substrates revealed that livers of SCOT-KO newborn mice synthesize glucose from exogenously administered pyruvate. However, the contribution of exogenous pyruvate to the tricarboxylic acid cycle as acetyl-CoA is increased in SCOT-KO livers and is associated with diminished terminal oxidation of fatty acids. After mother''s milk provokes hyperketonemia, livers of SCOT-KO mice diminish de novo hepatic β-hydroxybutyrate synthesis by 90%. Disruption of β-hydroxybutyrate production increases hepatic NAD⁺/NADH ratios 3-fold, oxidizing redox potential in liver but not skeletal muscle. Together, these results indicate that peripheral ketone body oxidation prevents hypoglycemia and supports hepatic metabolic homeostasis, which is critical for the maintenance of glycemia during the adaptation to birth.     

Evidence for the existence of enzymatic variants of beta-hydroxybutyrate dehydrogenase from rat liver and brain mitochondria.

A comparison of rat brain and liver β-hydroxybutyrate dehydrogenase (EC 1.1.1.30) has revealed that significant differences exist between the enzymes with regard to their kinetic and physical properties. In contrast to the liver enzyme, brain β-hydroxybutyrate dehydrogenase is rapidly inactivated at 46° and is unstable when stored at ?20°. The brain dehydrogenase was found to have a larger K_m (apparent) for the 3-acetylpyridine analog of NAD⁺, and a greater energy of activation in the direction of β-hydroxybutyrate oxidation than the liver enzyme. In the reverse direction, the brain and liver dehydrogenase exhibit substrate inhibition by NADH (0.22 mM and 0.36 mM, respectively). The brain and liver β-hydroxybutyrate dehydrogenase did not differ significantly with regard to the Michaelis-Menten constants measured for NAD⁺ and β-hydroxybutyrate. The K_m constants of brain β-hydroxybutyrate dehydrogenase for acetoacetate (0.39 mM) and NADH (0.05 mM) were lower than those determined for the liver enzyme, acetoacetate (0.73 mM) and NADH (0.35 mM) respectively. These results suggest that the β-hydroxybutyrate dehydrogenase from rat brain and liver are isozymic variants.     

Histone acetyltransferase in chromatin. Extraction of transferase activity from chromatin

Previous work has attempted to localize nuclear histone acetyltransferase activity in the cromatin. Evidence was presented indicating that the transfer of ¹⁴C-acetate from ¹⁴C-acetyl CoA to histones in chromatin was an enzymatic process. We now report on the extraction of part of the histone acetyltransferase activity from rat liver chromatin, employing a procedure originally described for extraction of DNA-dependent RNA polymerase. The K_m of the extracted transferase activity for the substrate acetyl CoA was 5 × 10⁻⁷, the Q₁₀: 1.8 and the optimal pH: 7.1. Serum albumine, protamine and polylysine were poor substrates as compared to histones. Activity of extracted or heated chromatin was not restored upon incubation in the presence of extract. Also the selectivity exhibited by the transferase activity in unextracted chromatin towards arginine-rich histones, was much less pronounced in the extracts prepared from it. It is possible that the influence of steric factors contributing to this specificity in native chromatin is lost upon isolation of the enzyme from it. Alternatively, a less specific isoenzyme may have been extracted.     

Production of poly-β-hydroxybutyric acid from carbon dioxide by Alcaligenes eutrophus ATCC 17697T

The characteristics of PHB production from carbon dioxide by autotrophic culture of Alcaligenes eutrophus ATCC 17697^T using a recycled gas closed circuit culture system under the condition of oxygen limitation were investigated. Cell concentration increased to more than 60 g/l after 60 h of cultivation, while the PHB concentration reached 36 g/l. PHB accumulation in the oxygen-limited culture was superior than that in an ammonium-deficient culture. The PHB produced was identified as a homopolymer of d-3-hydroxybutyrate by ¹H and ¹³C NMR analysis. The stoichiometry for PHB production from CO₂ under the oxygen limitation condition was indicated to be as follows: 33H₂ + 12O₂ + 4CO₂ → C₄H₆O₂ + 30H₂O. This stoichiometry shows that the hydrogen consumption per one mole of CO₂ for PHB production is larger than that for cell formation.     

Immunochemical evidence for the participation of cytochrome b5 in microsomal stearyl-CoA desaturation reaction

A rabbit antiserum was prepared against rat liver microsomal cytochrome b₅, and utilized in demonstrating the participation of this cytochrome in the microsomal stearyl-CoA desaturation reaction. The antiserum inhibited the NADH-cytochrome c reductase activity of rat liver microsorncs, but it did not inhibit either NADH-ferricyanide or NADPH-cytochrome c reductase activity of the microsomes. Thus, the inhibitory effect of the antiserum on the microsomal electron-transferring reactions seemed to be specific to those which require the participation of cytochrome b₅.The NADH-dependent and NADPH-dependent desaturations of stearyl CoA by rat liver microsomes were strongly inhibited by the antiserum. The reduction of cytochrome b₅ by NADH-cytochrome b₅ reductase as well as the reoxidation of the reduced cytochrome b₃ by the desaturase, the terminal cyanide-sensitive factor of the desaturation system, was also strongly inhibited by the antiserum. When about 90%, of cytochrome b₅ was removed from rat liver microsomes by protease treatment, the desaturation activity of the microsomes became much more sensitive to inhibition by the antiserum. These results confirmed our previous conclusion that the reducing equivalent for the desaturation reaction is transferred from NAD(P)H to the cyanidesensitive factor mainly via cytochrome b₅ in the microsomal membranes.     

Properties of rat 6-N-trimethyl-l-lysine hydroxylases: Similarities among the kidney,liver, heart,and skeletal muscle activities

Hydroxylation of 6-N-trimethyl-l-lysine(lys(Me₃)) to 3-hydroxy-6-N-trimethyl-l-lysine(3-HO-lys(Me₃)) by several rat tissues has been examined and compared. The kidney enzyme, which previously was shown to require molecular oxygen and α-ketoglutarate as cosubstrates, ferrous iron and ascorbate as cofactors, and to be stimulated by catalase, has a broad pH optimum ranging between 6.5 to 7.5 at 37 °C. As determined with crude tissue extracts from kidney, liver, heart, and skeletal muscle, similar apparent K_m values were obtained for substrate, cosubstrates, and cofactors. In view of similar kinetic parameters among the several lys(Me₃) hydroxylases examined in rat tissues, and the fact that the level of skeletal muscle lys(Me₃) hydroxylase activity is comparable to that of heart, liver, and kidney, because of its large total mass, skeletal muscle may contribute significantly to the biosynthesis of l-carnitine from lys(Me₃). The most effective inhibitors found, competitive with lys(Me₃), were 2-N-acetyl-6-N-trimethyl-l-lysine, 6-N-monomethyl-l-lysine, and 6-N-dimethyl-l-lysine. l-2-Amino-6-N-trimethylammonium-4-hexynoate, d-2-amino-6-N-trimethylammonium-4-hexynoate, and dl2-amino-6-N-trimethylammonium-cis-4-hexenoate, also inhibited hydroxylase activity but by a yet undetermined mechanism. Oxalacetate, succinate, and citrate inhibited the hydroxylation reaction by competing with α-ketoglutarate. The binding of ferrous iron to the enzyme was competitively inhibited by ions of “soft metals” (e.g., Cd²⁺, Zn²⁺) but not by those of “hard metals” (e.g., Ca²⁺, Mg²⁺). Preincubation of the crude kidney enzyme for 15 min at 37 °C with mercuriphenylsulfonate, N-ethylmaleimide, iodoacetate, or iodoacetamide resulted in considerable inhibition of 3-HO-lys(Me₃) formation. The degree of inhibition by N-ethylmaleimide could be reduced by including Zn (II) during preincubation of the enzyme. The effects of “soft” metals and sulfhydryl reagents on the enzyme suggest that sulfhydryl groups are required for ferrous iron binding in the active site.     

Regulation of fatty acid oxidation by adenosine at the level of its extramitochondrial activation

Conditions for the conversion of palmitate into CO₂ and acetoacetate by liver homogenates and isolated liver mitochondria are described. In this system, using liver homogenates, adenosine inhibited the conversion of palmitate into CO₂ and acetoacetate. The inhibition was not observed if the homogenate was substituted by mitochondria or if palmitate was substituted by palmitoyl CoA or palmitoyl carnitine. Intraperitoneal injection of adenosine produced a marked decrease in the level of acetoacetate and β-hydroxybutyrate in plasma, without changing the concentration of serum free fatty acids. Thus, the nucleoside depressed $\text{in vivo}$ the oxidation of long chain fatty acids in liver by inhibiting the extramitochondrial acyl CoA synthase(s). The paramount importance of the extramitochondrial activation of fatty acids as a key control in their oxidation and in the production of ketone bodies is discussed.     

The coenzyme A requirement of mammalian fatty acid synthetase: evidence for involvement in the elongation of acyl-enzyme thioesters

We have confirmed that coenzyme A is required for rat fatty acid synthetase activity (T. C. Linn, M. J. Stark, and P. A. Srere, 1980, J. Biol. Chem.255, 1388–1392). When rat liver or mammary gland fatty acid synthetase was assayed in the presence of a CoA-scavenging system such as ATP citrate lyase, almost complete inhibition of fatty acid synthesis was observed. The inhibition was reversed by addition of CoA or pantetheine, but not by addition of N-acetylcysteamine or other thiols. In the absence of CoA, the rate of elongation of acyl moieties on both native fatty acid synthetase and fatty acid synthetase lacking the chain-terminating thioesterase I component (trypsinized fatty acid synthetase) was reduced 100-fold. All of the palmitate synthesized slowly by the CoA-depleted native multienzyme was released, by the thioesterase I component, as the free fatty acid; only shorter-chainlength acyl moieties remained bound to the enzyme. The acyl-S-multienzyme thioesters formed by the trypsinized fatty acid synthetase in the absence of CoA contained saturated moieties of chain length C₆-C₁₆; addition of CoA promoted elongation of the acyl-S-multienzyme thioesters without release from the enzyme. The transfer of acetyl and malonyl moieties from CoA to the multienzyme, the reduction of S-acetoacetyl-N-acetylcysteamine and S-crotonyl-N-acetylcysteamine, and the dehydration of S-β-hydroxybutyryl-N-acetylcysteamine, reactions catalyzed by the fatty acid synthetase, were not dependent on the presence of CoA. The hydrolysis of acyl-S-multienzyme catalyzed by thioesterase I, the resident chain-terminating component of the fatty acid synthetase, and thioesterase II, a monofunctional mammary gland chain-terminating enzyme, was also independent of CoA availability as was hydrolysis of an acyl-S-pantetheine pentapeptide isolated from the multienzyme. On the basis of these observations we conclude that CoA is required for the elongation of acyl moieties on the fatty acid synthetase but not for their release from the multienzyme.     

Measurement of ketone bodies in subcellular fractions using a spectrophotometric iron-chelate assay

A sensitive spectrophotometric assay for 3-hydroxybutyrate determination in biological samples is described. Linearity between the amount of 3-hydroxybutyrate and ΔA₅₄₆ was obtained in the range of 0.3 to 4.0 nmol 3-hydroxybutyrate/assay. The same method is applicable for acetoacetate determination after its enzymatic reduction. The assay proved to be useful for the study of the subcellular distribution of ketone bodies in isolated liver cells. The assay procedure is adequate to measure the concentration of ketone bodies in 5-mg and 20μl samples from liver and blood, respectively.