Inhibition by oxalomalate of rat liver mitochondrial and extramitochondrial aconitate hydratase

1. The effect of oxalomalate on the oxidation of citrate and cis-aconitate in rat liver mitochondria, and on the activity of mitochondrial and cytoplasmic aconitate hydratase, has been investigated. 2. Oxalomalate that was added to intact rat liver mitochondria at high concentrations (2mm) produced complete inhibition of citrate and cis-aconitate oxidation, but lower concentrations (0.1-0.25mm) inhibited oxidation of citrate more than that of cis-aconitate. 3. Aconitate hydratase that was either extracted from mitochondria or soluble in the cytoplasm, was strongly inhibited by low concentrations of oxalomalate (0.01-0.2mm), the mitochondrial enzyme being more sensitive than the soluble one. 4. Oxalomalate, when added together with citrate, produced competitive inhibition; the K(i) values calculated were 1x10(-6)m for the mitochondrial and 2.5x10(-6)m for the cytoplasmic enzyme. 5. With both the enzymic preparations oxalomalate added together with the substrates inhibited the initial rate of the reaction citrate-->cis-aconitate more than that of the reaction isocitrate-->cis-aconitate. 6. After 2min of preincubation of the inhibitor with either of the enzymic preparations the inhibition increased tenfold and became irreversible; under these conditions both the reactions were inhibited to the same extent. 7. The inhibition by oxalomalate of aconitate hydratase appeared to be similar in many respects to that produced by fluorocitrate on the same enzyme.     

Fluorocitrate inhibition of aconitate hydratase and the tricarboxylate carrier of rat liver mitochondria

1. The effect of biologically synthesized and purified fluorocitrate on the metabolism of tricarboxylate anions by isolated rat liver mitochondria was investigated, in relation to the claim by Eanes et al. (1972) that this fluoro compound inhibits the tricarboxylate carrier at concentrations at which it has little effect on the aconitate hydratase activity. 2. That the inhibitory action of fluorocitrate is at the level of the aconitate hydratase and not at the level of the tricarboxylate carrier is indicated by the following findings. Although the oxidation of citrate and cis-aconitate, but not that of isocitrate, was inhibited by fluorocitrate, the exchange of internal citrate for external citrate or l-malate was not. Had the tricarboxylate carrier been affected, these latter exchange reactions would have been inhibited. 3. By using aconitate hydratase solubilized from mitochondria it was found that with citrate as substrate the inhibition by fluorocitrate was partially competitive (K(i)=3.4x10(-8)m), whereas with cis-aconitate as substrate the inhibition was partially non-competitive (K(i)=3.0x10(-8)m).     

Characterization of aconitate hydratase from mitochondria and cytoplasm of ascites tumor cells

This paper describes the characterization of aconitate hydratase (EC 4.2.1.3) in cytoplasmic and mitochondrial extracts from Ehrlich ascites tumor cells carried by BALB/C mice. The results show a similar distribution of aconitate hydratase in both extracts, with specific activities much lower than those found in pig and mouse tissues. Mitochondrial aconitate hydratase shows a substrate inhibition by citrate with a Km similar to that found in cytoplasm (Km = 1.0 mM and 0.9 mM, respectively). Oxalacetate produces a mixed type of inhibition in both cytoplasmic and mitochondrial aconitate hydratases with different inhibition constants (Ki = 0.3 mM and 1.0 mM, respectively). Moreover, the specific activities of aconitate hydratase in both cytoplasm and mitochondria decrease when the tumor progresses in the peritoneum of BALB/C mice, as well as the percentage of aconitate hydratase activity in the presence of oxalacetate as the inhibitor. These results indicate that the activity and kinetics of aconitate hydratase are markedly altered by neoplastic transformation as occurs in Ehrlich ascites tumor cells. Since aconitate hydratase is not a key enzyme, these unexpected data are of interest in the study of cancer biochemistry.     

Biochemical lesions of respiratory enzymes and configurational changes of mitochondria in vivo

Summary Correlative biochemical and electron microscopic alterations were observed in chick embryo myoblasts in vitro after treatment with fluoroacetate. Fluoroacetate poisoning caused an increase of citrate and a decrease of ATP in the cultures. Cell respiration was only slightly impaired by fluoroacetate in the first 10 min but was inhibited to 30% one hour after exposure to the poison. Fluoroacetate did not affect oxidative phosphorylation. The evidence suggests that fluoroacetate was transformed in myoblasts into fluorocitrate which inhibited the mitochondrial-bound aconitate hydratase as in adult tissues. Ultrastructural changes in the majority of the fluoroacetate-treated cells were observed. Very few myoblasts appeared unaffected by the poison. Mitochondria were specifically altered. The early changes occurred in the mitochondrial matrix where the inhibited enzyme is known to be located and were followed by modifications in the configuration and structure of cristae. Exogenous fluorocitrate caused ultrastructural changes in the mitochondria similar to that provoked by fluoroacetate. The localization of the early change in the mitochondrial matrix and the evaluation of the structural modifications suggest a correlation between the biochemical lesion, i.e. the inhibition of aconitate hydratase, and the change revealed in the mitochondrial structure containing the inhibited enzyme.This work was supported by grants of the Consiglio Nazionale delle Ricerche to both InstitutesThe present study is dedicated to Prof. Otto Bucher on occasion of his 65th birthday     

The transport of citrate and other tricarboxylic acids in two species of Pseudomonas

When cells of Pseudomonas are grown on citrate as the sole carbon source they oxidize citrate and isocitrate rapidly. Fluorocitrate inhibits the oxidation of citrate. Fluorocitrate-treated cells accumulate [6-(14)C]citrate, as shown by a rapid Millipore-filtration technique. In the absence of fluorocitrate most of the [6-(14)C]-citrate is lost in the form of (14)CO(2). The isolation of a pseudomonad characterized by its ability to grow on tricarballylate as a sole carbon source has facilitated the study of the tricarboxylate-carrier specificity. Cells grown on citrate will exchange radioactive citrate for unlabelled citrate or isocitrate but not for cis-aconitate, trans-aconitate or tricarballylate. Cells grown on tricarballylate will exchange radioactive citrate for unlabelled citrate, cis-aconitate or tricarballylate, but not for isocitrate or trans-aconitate. The properties of the exchange system involved are compared with those of the related system in mitochondria.     

Catalytic Properties of Cytoplasmic and Mitochondrial Aconitate Hydratase from Rat Cardiomyocytes

Enzymatic activity of aconitate hydratase (aconitase, EC 4.2.1.3) from the rat heart is localized in the cytoplasm (65%) and mitochondria (35%). Cytoplasmic and mitochondrial forms of aconitate hydratase were separated by ion-exchange chromatography on CM-Cellulose and CM-Sephadex. The two forms have similar molecular weight, optimal pH range, and spectral properties; however, they have different chromatography properties, K _m for citrate and isocitrate, as well as sensitivity to Fe²⁺ ions.     

2-Oxoglutarate: Oxidation and Role as a Potential Precursor of Cytosolic Acetyl-CoA for the Synthesis of Acetylcholine in Rat Brain Synaptosomes

The possibility that 2-oxoglutarate may supply acetyl units for the cytosolic synthesis of acetylcholine in rat brain synaptosomes was investigated. The contribution of [14C]2-oxoglutarate to the synaptosomal synthesis of [14C]acetylcholine was found to be negligible despite evidence for its uptake and oxidation. The activity of the enzymes NADP-isocitrate dehydrogenase (EC 1.1.1.42), aconitate hydratase (EC 4.2.1.3), and ATP citrate-lyase (EC 4.1.3.8) were measured in the synaptosol. NADP-isocitrate dehydrogenase and aconitate hydratase are present at three- to 1.5-fold higher activities than ATP citrate-lyase. It seems likely that these enzymes contribute to the metabolism of citrate and prevent detectable formation of cytosolic acetyl-CoA from exogenously added 2-oxoglutarate (or citrate). The data further suggest that ATP citrate-lyase may in part be associated with the mitochondrial fraction.     

Control of the citric acid cycle by glyoxylate. The mechanism of inhibition of oxoglutarate dehydrogenase, isocitrate dehydrogenase and aconitate hydratase

1. The effects of glyoxylate on partially purified preparations of aconitate hydratase, isocitrate dehydrogenase and oxoglutarate dehydrogenase were compared with those of oxalomalate and hydroxyoxoglutarate (obtained by condensation of glyoxylate with oxaloacetate and pyruvate respectively). 2. Glyoxylate (1mm) did not affect aconitate hydratase and isocitrate dehydrogenase, whereas oxalomalate (1mm) inhibited the enzyme activities completely. 3. Glyoxylate (0.025mm) inhibited oxoglutarate dehydrogenase irreversibly, whereas the same concentrations of oxalomalate and hydroxyoxoglutarate were ineffective. This inhibitory effect was prevented if oxoglutarate, pyruvate or oxaloacetate was mixed with the enzyme before the glyoxylate. 4. Incubation of oxoglutarate dehydrogenase with radioactive glyoxylate produced radioactive carbon dioxide; radioactivity was also recovered in the portion of the enzyme identified with thiamin pyrophosphate. 5. The behaviour of glyoxylate in producing multiple inhibitions of the citric acid cycle, either by direct interaction with oxoglutarate dehydrogenase, or by means of its condensation compounds which inhibit aconitate hydratase and isocitrate dehydrogenase, is discussed.     

Regulation of pyruvate oxidation in mitochondria isolated from fetal and adult rat liver

The effect of ATP on the velocity of oxygen uptake during the oxidation of pyruvate plus malate, in the presence of oligomycin, 2,4-dinitrophenol and fluorocitrate, was studied in mitochondria, isolated from the livers of adult and fetal rats.It was found that the addition of ATP caused an inhibition in the rate of oxygen uptake of 21 ± 6% in mitochondria from adult rat liver and 49 ± 8% in mitochondria from fetal rat liver. Measurements of the velocity of oxygen uptake during the oxidation of pyruvate plus malate and of palmitoylcarnitine in adult rat liver mitochondria in the presence of ATP showed that the activity of pyruvate dehydrogenase was lower than the activity of citrate synthase.In fetal mitochondria, addition of ATP resulted in an increase in the CoASH/acetyl-CoA ratio, indicating that pyruvate dehydrogenase was rate limiting here as well.It is concluded that ATP inhibited pyruvate oxidation by phosphorylation of the pyruvate dehydrogenase complex, rather than by inhibiting citrate synthase under these conditions.     

The effect of fluorocitrate on oxygen consumption and Ca2+ transport in the mitochondria of liver cells]

The effect of fluorocitrate on oxidative reactions and energy production systems of rat liver mitochondria has been studied. It was shown that oxidation of endogenous substrates and malate with pyruvate as well as the phosphorylation of the added ADP were inhibited by fluorocitrate. Inhibition of oxygen consumption by fluorocitrate induced the efflux of Ca2+ ions from mitochondria and a decrease in the Ca(2+)-accumulating capacity. The effect of fluorocitrate on Ca2+ transport in mitochondria is due to activation of the Ca-efflux pathway in those sensitive to ruthenium red.     

Enzymatic Activity in Mitochondria from Orobanche

Mitochondria from Orobanche were analysed for the activities of aconitate hydratase, isocitrate dehydrogenase, succinate dehydro-genase, fumarate hydratase, malate dehydrogenase, NADH oxidase, substrate-cytochrome c oxidoreductases, glutamate dehydrogenase, aminotransferases, ATPase and “malic” enzyme. The specific activities of isocitrate dehydrogenase, NADH oxidase, substrate-cytochrome c oxidoreductases and glutamate dehydrogenase in the mitochondria) fraction from parasite tissue compared favourably with those reported for most of the mitochondria from growing and storage tissues. Succinate dehydrogenase, fumarate hydratase and aspartate aminotransferase were of intermediate activity, while aconitate hydratase and malate dehydrogenase had rather low activity, and “malic” enzyme had very low activity in comparison with other preparations. The relevance of these findings in relation to mitochondrial metabolism in the parasite is discussed. No evidence was obtained to suggest any basic abnormality in the biochemical properties of the mitochondria from Orobanche centua which may be correlated with its obligatorily parasitic existence.     

Effects of lipoic acid on citrate content, aconitate hydratase activity, and oxidative status during myocardial ischemia in rats

The effects of lipoic acid on intensity of free radical reactions, citrate content, and aconitate hydratase during myocardial ischemia have been investigated. Treatment with lipoic acid normalized biochemiluminescence parameters and citrate level, which were increased in the myocardial pathology. Treatment with lipoic acid also increased specific activity of aconitate hydratase, which was decreased in myocardium and blood of animals with myocardial ischemia. Administration of lipoic acid decreased DNA fragmentation observed during myocardial ischemia. The data suggest that lipoic acid can be effectively used as a cardioprotector preventing the development of free radical oxidation during myocardial ischemia.     

Metabolic pathways involved in lipogenesis from lactate and acetate in bovine adipose tissue: Effects of metabolic inhibitors

Metabolic inhibitors were used in vitro in an attempt to elucidate the biochemical pathways by which lactate is converted to fatty acids by bovine adipose tissue. Subcutaneous adipose tissue samples were obtained by biopsy techniques from steers fed a high-energy ration. Kynurenate (α-2-diamino-γ-oxabenzenebutanoic acid) (5–10 mm), an inhibitor of acetyl-CoA carboxylase, and cerulenin (2,3-epoxy-4-oxo-7,10-dodecadienamide) (20–100 μg/ml), an inhibitor of the fatty acid synthetase enzyme complex, inhibited fatty acid synthesis from both acetate and lactate. The hydrogen acceptor, N-methylphenazonium methosulfate (10 μm) inhibited acetate but not lactate incorporation into fatty acids. α-Cyanohydroxycinnamate (5 mm) and phenylpyruvate (10 mm), which inhibit pyruvate entry into the mitochondria and pyruvate carboxylase, respectively, decreased lipogenesis from both acetate and lactate. The effects of phenylpyruvate on lipogenesis from acetate were greater in the presence of glucose plus insulin. Agaric acid (2-hydroxy-1,2,3-nonadecanetricarboxylic acid) (0.2 and 1.0 mm), which inhibits citrate efflux from the mitochondria also decreased lipogenesis from both acetate and lactate. Fluoroacetate (2.5 mm), an inhibitor of aconitate hydratase, had no effect on lipogenesis from acetate; but, in the presence of glucose or pyruvate, decreased lactate incorporation into fatty acids. n-Butylmalonate (5 mm), which blocks malate transport across the mitochondrial membrane, decreased lipogenesis from lactate but not acetate. Malate transport during lipogenesis is not associated with an operative malate:asparate shuttle in bovine adipose tissue, as indicated by the lack of effect of either 0.2 or 1.0 mm aminooxyacetate, a transaminase inhibitor, on lipogenesis from acetate or lactate. The results suggest a functional ATP-citrate lyase:NADP-malate dehydrogenase pathway in bovine subcutaneous adipose tissue and that this pathway may be involved in lipogenesis from acetate as well as lactate.     

Citrate Cycle and Related Metabolism of Listeria monocytogenes

The growth response of Listeria monocytogenes strains A4413 and 9037-7 to carbohydrates was determined in a defined medium. Neither pyruvate, acetate, citrate, isocitrate, alpha-ketoglutarate, succinate, fumarate, nor malate supported growth. Furthermore, inclusion of any of these carbohydrates in the growth medium with glucose did not increase the growth of Listeria over that observed on glucose alone. Resting cell suspensions of strain A4413 oxidized pyruvate but not acetate, citrate, isocitrate, alpha-ketoglutarate, succinate, fumarate, or malate. Cell-free extracts of strain A4413 contained active citrate synthase, aconitate hydratase, isocitrate dehydrogenase, malate dehydrogenase, fumarate hydratase, fumarate reductase, pyruvate dehydrogenase system, and oxidases for reduced nicotinamide adenine dinucleotide and reduced nicotinamide adenine dinucleotide phosphate. The alpha-ketoglutarate oxidation system, succinate dehydrogenase, isocitrate lyase, and malate synthase were not detected. Cytochromes were not detected. The data suggest that strain A4413, under these conditions, utilizes a split noncyclic citrate pathway which has an oxidative portion (citrate synthase, aconitate hydratase, and isocitrate dehydrogenase) and a reductive portion (malate dehydrogenase, fumarate hydratase, and fumarate reductase). This pathway is probably important in biosynthesis but not for a net gain in energy.     

Biochemical lesions of respiratory enzymes and configurational changes of mitochondria in vivo

Summary Chick embryo heart fragments in primary hanging-drop culture were treated with sodium fluoroacetate to induce inhibition of aconitate hydratase, a mitochondrial enzyme of the tricarboxylic acid cycle. The mitochondria were analyzed in the living myoblasts by phase-contrast time-lapse cinemicrography. The results were recorded in a 16 mm film. After 20–30 minutes contact of the cells with the inhibitor some mitochondria became thickened and swollen. The swelling was polymorphous, asynchronous and reversible; the same mitochondrion could swell and shrink many times. Some mitochondria seemed not to respond to fluoroacetate and remained rod-like. Mitochondria appeared the only cell components to be morphologically affected by fluoroacetate and the changes were specifically caused by the inhibitor. The type of mitochondrial swelling differed from the large-amplitude respiration-dependent swelling of the isolated mitochondria in vitro and from the configurational changes of isolated mitochondria associated with the respiratory states. The evidence pointed to a specific connection between the biochemical lesion caused by fluoroacetate and the configurational changes of the mitochondria. The mitochondrial swelling was to a large extent reversed by washing the cultures with Tyrode physiological saline solution and the reversal was further accentuated by incubation of the cultures in fresh nutrient medium.This work was supported by grants of the Consiglio Nazionale delle Richerce of Italy to both Institutes.     

Oxalate accumulation from citrate by Aspergillus niger. II. Involvement of the tricarboxylic acid cyclase.

Carbon-14 was incorporated into oxalate and CO2 from either citrate-1,5-14C, succinate-1,4-14C, or fumarate-1,4-14C by cultures of Aspergillus niger pregrown on a medium which contained glucose as the sole carbon source and which did not allow citrate accumulation. In cell-free extracts of mycelium forming oxalate and CO2 from added citrate the following enzymes of the tricarboxylic acid (TCA) cycle were identified: citrate synthase CE 4.1.3.7), aconitate hydratase (EC4.2.1.3), NAD and NADP-dependent isocitrate dehydrogenase (EC 1.1.1.41, 1.1.1.42), (alpha-oxoglutarate dehydrogenase (EC 1.2.4.2), succinate dehydrogenase (EC 1.3.99.1), fumarate hydratase (EC 4.2.1.2), and malate dehydrogenase (EC 1.1.1.37). The in vitro activity of aconitate hydratase and of NADP-dependent isocitrate dehydrogenase was shown to be almost identical to the rate of in vivo degradation of citrate or to exceed this rate. The degradation of citrate to oxalate was inhibited completely by 9 mM fluoroacetate. It is concluded that the TCA cycle is involved in the formation of oxalate from citrate.     

Regulation of aconitate hydratase activity from rat kidney cortex by bicarbonate.

1. The increase in pH value and bicarbonate concentration stimulated citrate synthesis from pyruvate and malate, inhibiting simultaneously conversion of isocitrate to citrate. 2. Bicarbonate inhibited competitively the activity of aconitate hydratase, probably binding with the two active sites of the enzyme. The Ki values for the cytoplasmic and mitochondrial enzyme were, respectively, 27 and 38 mM. The pH optimum for both forms of the enzyme in Tris-HCl buffer was in the range 7.8-8.6, and in bicarbonate buffer varied from 7.2 to 8.0, depending on the form of the enzyme and the substrate used. 3. Only free, completely dissociated citrate anion acts as a substrate for aconitate hydratase. 4. The role of aconitate hydratase as a factor controlling the rate of citrate metabolism in kidney in metabolic alkalosis is discussed.     

Phthalonic acid, an inhibitor of alpha-oxoglutarate transport in mitochondria.

Phthalonic acid is a powerful inhibitor of alpha-oxoglutarate transport in mitochondria. This conclusion is based on the following observations: 1. Phthalonic acid inhibits the oxidation of alpha-oxoglutarate but has no effect on the oxidation of glutamate or cis-aconitate. 2. With arsenite present, phthalonic acid inhibits the oxidation of glutamate plus malate and of cis-aconitate plus malate. Under these conditions alpha-oxoglutarate accumulates inside the mitochondria. With glutamate plus malate as substrates the inhibition is competitive with malate with a Ki value of 20 muM. 3. Phthalonic acid inhibits the oxidation of intramitochondrial NAD(P)H by alpha-oxoglutarate plus ammonia. The inhibition is competitive with respect to alpha-oxoglutarate with a Ki of 30 muM. 4. Phthalonic acid inhibits the exchange between extramitochondrial alpha-oxoglutarate and intramitochondrial malate.     

Effect of acetaldehyde on fatty acid oxidation and ketogenesis by hepatic mitochondria.

Acetaldehyde inhibited the oxidation of fatty acids by rat liver mitochondria as assayed by oxygen consumption and CO₂ production. ADP-stimulated oxygen uptake was more sensitive to inhibition by acetaldehyde than was uncoupler-stimulated oxygen uptake, suggesting an effect of acetaldehyde on the electron transport-phosphorylation system. This conclusion is supported by the decrease in the respiratory control ratio, associated with fatty acid oxidation. Acetaldehyde depressed ketone body production as well as the content of acetyl CoA during palmitoyl-1-carnitine oxidation. Acetaldehyde was considerably more inhibitory toward fatty acid oxidation than was acetate. Therefore, the inhibition by acetaldehyde is not mediated by acetate, the direct product of acetaldehyde oxidation by the mitochondria. Oxygen uptake was depressed by acetaldehyde to a slightly, but consistently, greater extent in the absence of fluorocitrate, than in its presence. This suggests inhibition of oxygen consumption from β-oxidation to acetyl CoA and that which arises from citric acid cycle activity. The inhibition of fatty acid oxidation is not due to any effect on the activation or translocation of fatty acids into the mitochondria.The depression of the end products of fatty acid oxidation (CO₂, ketones, acetyl CoA) as well as the greater sensitivity of palmitate oxidation compared to acetate oxidation, suggests inhibition by acetaldehyde of β-oxidation, citric acid cycle activity, and the respiratory-phosphorylation chain. Neither the activities of palmitoyl CoA synthetase nor carnitine palmitoyltransferase appear to be rate limiting for fatty acid oxidation.     

2-Methylcitrate Dehydratase,a New Enzyme Functioning at the Methylcitric Acid Cycle of Propionate Metabolism

2-Methylcitrate dehydratase (2-methylcitrate hydro-lyase), a new enzyme functioning at the methylcitric acid cycle of propionyl-CoA oxidation, was present in the cell-free extract of Yarrowia (Saccharomycopsis) lipolytica. The enzyme was separated from the usual aconitate hydratase (EC 4.2.1.3) of the yeast with DEAE-Sephadex A-50 column chromatography. The enzyme was able to catalyze a reversible reaction between 2-methylcitrate and 2-methyl-cis-aconitate, but showed no activity on threo-d_s-2-methylisocitrate, citrate, cis- or trans-aconitate, threo-d_s-, threo-DL- or erythro-l_s-isocitrate, DL-homocitrate or other hydroxy-acids tested.

In contrast, the other enzyme fraction separated as aconitate hydratase by chromatography showed no activity on synthetic 2-methylcitrate, but was able to catalyze strongly a reversible reaction between 2-methyl-cis-aconitate and threo-d_s-2-methylisocitrate.

From these findings, the previously proposed cycle sequence was revised at the following broken arrows: propionyl-CoA+oxaloacetate → (CoASH+) 2-methylcitrate ? 2-methyl-cis-aconitate ? threo-d_s-2-methylisocitrate → pyruvate+succinate (→→oxaloacetate).

2-Methylcitrate dehydratase showed maximum activity at pH 6.5 to 7.0 and at 25 to 40°C. The enzyme was stable at temperatures up to 40°C and at pH 6.5 to 7.5, but labile in Tris-HCl buffer. The synthesis of this enzyme was constitutive in this yeast, although it was slightly repressed by glucose.