Substrate-decreased modification by diethyl pyrocarbonate of two histidines in isocitrate lyase from Escherichia coli

The inactivation of tetrameric 188-kDa isocitrate lyase from Escherichia coli at pH 6.8 (37 degrees C) by diethyl pyrocarbonate, exhibiting saturation kinetics, is accompanied by modification of histidine residues 266 and 306. Substrates isocitrate, glyoxylate, or glyoxylate plus succinate protect the enzyme from inactivation, but succinate alone does not. Removal of the carbethoxy groups from inactivated enzyme by treatment with hydroxylamine restores activity of isocitrate lyase. The present results suggest that the group-specific modifying reagent diethyl pyrocarbonate may be generally useful in determining the position of active site histidine residues in enzymes.     

Inhibition of isocitrate lyase from Pseudomonas indigofera by itaconate

The effect of the inhibitor itaconate on the activity of purified isocitrate lyase from Pseudomonas indigofera was examined for the reaction in both directions. Itaconate was found to equilibrate very slowly with its enzyme-bound form, so that a rapid change in itaconate concentration produced a gradual change in reaction velocity which eventually reached a new steady state. Kinetic studies of this relaxation phenomenon indicated that itaconate inhibited by binding the enzyme only after prior binding of glyoxylate, thus mimicking the kinetic behavior of succinate. On the basis of these studies, the dissociation constants for itaconate and glyoxylate from their respective enzyme-bound forms were calculated. More than half of the isocitrate lyase was complexed by glyoxylate during cleavage of saturating isocitrate. The rate constant for release of itaconate from the enzyme was calculated to be about 0.2 min^?1. Direct binding of [¹⁴C]itaconate and [¹⁴C]succinate to isocitrate lyase at pH 6.8 was measured. Some binding of both ligands was found in the absence of glyoxylate, which was stimulated by the presence of 1 mm glyoxylate. These results suggest that there are up to three or more binding sites per active subunit, but that only one of these is catalytic.     

Formation of enzyme-bound carbanion intermediate in the isocitrate lyase-catalyzed reaction: enzymatic reaction of tetranitromethane with substrates and its dependence on effector, pH, and metal ions

Isocitrate lyase of germinating castor seed endosperm catalyzes the reactions of succinate and of isocitrate (but not of glyoxylate) with tetranitromethane (TNM), giving rise to the nitroform anion (C-(NO2)3), analogous to the reaction of TNM with carbanions (O.P. Malhotra and U.N. Dwivedi, 1984, Ind. J. Biochem. Biophys. 21, 65-67). The kinetics of this reaction have been investigated under a variety of conditions. At a fixed TNM concentration, the initial rate of reaction exhibits a hyperbolic saturation of the enzyme with isocitrate. The reaction with succinate, however, shows "negative cooperativity" in succinate saturation and the data are consistent with the existence of two sets of succinate binding sites of unequal affinity ("tight" and "loose" sites). Equal reaction rates are observed at enzyme-saturating concentrations of succinate and isocitrate. In every case, the rate of reaction is proportional to the TNM concentration. In the presence of alpha-ketoglutarate, hyperbolic saturation curves are obtained for all the substrates (TNM and succinate or TNM and isocitrate). In the presence of this effector the Km of succinate and TNM are independent of the concentration of the second substrate. On the other hand, sets of parallel straight lines are obtained in the double-reciprocal plots for the enzymatic reaction of TNM with isocitrate in the presence of alpha-ketoglutarate. Studies on the effect of pH on the isocitrate lyase-catalyzed reactions of TNM with succinate, TNM with isocitrate, and succinate with glyoxylate in the absence as well as in the presence of alpha-ketoglutarate show that the proton behaves as an uncompetitive inhibitor in all these reactions, suggesting the presence of a "masked" basic group at the enzyme site, which is protonated in the presence of substrate only. The pKa value of this group lies in the range 6.7-6.9. The enzymatic reactions of TNM with succinate and isocitrate exhibit identical Mg2+ ion dependence. From a comparison of the data on the enzymatic reactions of TNM with the corresponding results on the physiological reaction catalyzed by this enzyme, it has been suggested that an ion pair intermediate (E+ X S-, in which E, S, and S- stand for enzyme, succinate, and succinate carbanion, respectively) lies on the pathway of catalysis by isocitrate lyase.     

On the mechanism of action of isocitrate lyase.

1. The enzymes citrate lyase and isocitrate lyase catalyse similar reactions in the cleavage of citrate to acetate plus oxaloacetate and of isocitrate to succinate plus glyoxylate, respectively. 2. Nevertheless, the mechanism of action of each enzyme appears to be different from each other. Citrate lyase is an acyl carrier protein-containing enzyme complex whereas isocitrate lyase is not. The active form of citrate lyase is an acetyl-S-enzyme but that of isocitrate lyase is not a corresponding succinyl-S-enzyme. 3. In contrast to citrate lyase, the isocitrate enzyme is not inhibited by hydroxylamine nor does it acquire label if treated with appropriately labelled radioactive substrate. 4. Isotopic exchange experiments performed in H18-2O with isocitrate as a substrate produced no labelling in the product succinate. This was shown by mass-spectrometric analysis. 5. The conclusion drawn from these results is that no activation of succinate takes place on the enzyme through transient formation of succinic anhydride or a covalently-linked succinyl-enzyme, derived from this anhydride.     

Methylamine metabolism in a pseudomonas species

The mechanism by which a nonphotosynthetic bacterium Pseudomonas sp. (Shaw Strain MA) grows on the one-carbon source, methylamine, was investigated by comparing enzyme levels of cells grown on methylamine, to cells grown on acetate or succinate. Cells grown on methylamine have elevated levels of the enzymes serine hydroxymethyl transferase, serine dehydratase, malic enzyme, glycerate dehydrogenase and malate lyase (CoA acetylating ATP-cleaving). These enzymes, in conjunction with a constitutive glyoxylate transaminase, can account for the net conversion of two one-carbon units into acetyl CoA. Cells grown on acetate or methylamine, but not succinate, contain the enzyme isocitrate lyase; while cells grown on acetate or succinate, but not methylamine, contain significant levels of malate synthetase. These findings suggest that the acetyl CoA derived from one-carbon units in methylamine grown cells, condenses with oxalacetate to yield citrate and then isocitrate, followed by cleavage to succinate and glyoxylate. Thus, growth on methylamine is accomplished by the net synthesis of succinate from two molecules of methyamine and two molecules of CO₂.     

Control of isocitrate lyase in Nocardia salmonicolor (NCIB9701).

Nocardia salmonicolor, grown on acetate, commercial D,L-lactate or hydrocarbon substrates, has high isocitrate lyase activities compared with those resulting from growth on other carbon sources. This presumably reflects the anaplerotic role of the glyoxylate cycle during growth on the former substrates. Amongst a variety of compounds tested, including glucose, pyruvate and tricarboxylic acid cycle intermediates, only succinate and fumarate prevented an increase in enzyme activity in the presence of acetate. When acetate (equimolar to the initial sugar concentration) was added to cultures growing on glucose, there followed de novo synthesis of isocitrated lyase and isocitrate dehydrogenase, with increases in growth rate and glucose utilization, and both acetate and glucose were metabolized simultaneously. A minute amount of acetate (40 muM) caused isocitrate lyase synthesis (a three-fold increase in activity within 3 min of addition) when added to glucose-limited continuous cultures, but even large amounts added to nitrogen-limited batch cultures were ineffective. Malonate, at a concentration that was not totally growth-inhibitory (1mM) prevented the inhibition of acetate-stimulated isocitrate lyase synthesis by succinate, but fumarate still inhibited in the presence of malonate. Phosphoenolpyruvate is a non-competitive inhibitor of the enzyme (apparent Ki 1-7 mM). The results are consistent with the induction of isocitrate or a closely related metabolite, and catabolite repression by a C-4 acid of the tricarboxylic acid cycle, possibly fumarate.     

Phosphorylation of Acinetobacter isocitrate lyase.

During growth on succinate, Acinetobacter calcoaceticus contains two forms of the enzyme isocitrate dehydrogenase. Addition of acetate to a lag-phase culture grown on succinate causes a dramatic increase in activity of form II of isocitrate dehydrogenase and in isocitrate lyase. Form II of isocitrate dehydrogenase may be responsible for the partition of isocitrate between the TCA cycle and the glyoxylate by-pass. This report describes the phosphorylation of the enzyme isocitrate lyase from A. calcoaceticus. This phosphorylation may be a regulatory mechanism for the glyoxylate by-pass.     

Itaconic acid: An inhibitor of isocitrate lyase in Tetrahymena pyriformis in vitro and in vivo

The succinate analog itaconic acid was observed to be a competitive inhibitor of the glyoxylate cycle specific enzyme isocitrate lyase (EC 4.1.3.1) in cell-free extracts of Tetrahymena pyriformis. Itaconic acid also inhibited net in vivo glycogen synthesis from glyoxylate cycle-dependent precursors such as acetate but not from glyoxylate cycle-independent precursors such as fructose. The effect of itaconic acid on the incorporation of ¹⁴C into glycogen from various ¹⁴C-labeled precursors was also consistent with inhibition of isocitrate lyase by this compound. Another analog of succinate which shares a common metabolic fate with itaconic acid, mesaconic acid, had no effect on isocitrate lyase activity in vitro or on ¹⁴C-labeled precursor incorporation into glycogen in vivo. In addition, itaconic acid did not affect gluconeogenesis from lactate in isolated perfused rat livers, a system lacking the enzyme isocitrate lyase. These results are taken as evidence that itaconic acid is an inhibitor of glyoxylate cycle-dependent glyconeogenesis Tetrahymena pyriformis via specific competitive inhibition of isocitrate lyase activity.     

Purification and characterization of Acinetobacter calcoaceticus isocitrate lyase.

Acinetobacter calcoaceticus is capable of growing on acetate or compounds that are metabolized to acetate. During adaptation to growth on acetate, A. calcoaceticus B4 exhibits an increase in NADP(+)-isocitrate dehydrogenase and isocitrate lyase activities. In contrast, during adaptation to growth on acetate, Escherichia coli exhibits a decrease in NADP(+)-isocitrate dehydrogenase activity that is caused by reversible phosphorylation of specific serine residues on this enzyme. Also, in E. coli, isocitrate lyase is believed to be active only in the phosphorylated form. This phosphorylation of isocitrate lyase may regulate entry of isocitrate into the glyoxylate bypass. To understand the relationships between these two isocitrate-metabolizing enzymes and the metabolism of acetate in A. calcoaceticus B4 better, we have purified isocitrate lyase to homogeneity. Physical and kinetic characterization of the enzyme as well as the inhibitor specificity and divalent cation requirement have been examined.     

Repression of oxalic acid-mediated mineral phosphate solubilization in rhizospheric isolates of Klebsiella pneumoniae by succinate

Two strains of Klebsiella (SM6 and SM11) were isolated from rhizospheric soil that solubilized mineral phosphate by secretion of oxalic acid from glucose. Activities of enzymes for periplasmic glucose oxidation (glucose dehydrogenase) and glyoxylate shunt (isocitrate lyase and glyoxylate oxidase) responsible for oxalic acid production were estimated. In presence of succinate, phosphate solubilization was completely inhibited, and the enzymes glucose dehydrogenase and glyoxylate oxidase were repressed. Significant activity of isocitrate lyase, the key enzyme for carbon flux through glyoxylate shunt and oxalic acid production during growth on glucose suggested that it could be inducible in nature, and its inhibition by succinate appeared to be similar to catabolite repression.     

The inhibition of isocitrate lyase fromEscherichia coli by glyoxylate

Inhibition patterns have been studied to shed light on the current controversy involving the kinetic mechanism for isocitrate lyase fromEscherichia coli. A new coupled enzymatic assay for the product succinate has been developed, enabling the determination that glyoxylate, the other product, is a linear competitive inhibitor of isocitrate cleavage. This and other evidence suggest that the kinetic mechanism is steady-state, ordered uni-bi, and that succinate and glyoxylate are sequentially released from the enzyme after cleavage of isocitrate.     

Evidence for an operative glyoxylate cycle in the thermoacidophilic crenarchaeon Sulfolobus acidocaldarius

Both key enzymes for the glyoxylate cycle, isocitrate lyase (EC 4.1.3.1) and malate synthase (EC 4.1.3.2), were purified and characterized from the thermoacidophilic crenarchaeon Sulfolobus acidocaldarius. Whereas the former enzyme was copurified with the aconitase, the latter enzyme could be enriched to apparent homogeneity. Amino acid sequencing of three internal peptides of the isocitrate lyase revealed the presence of highly conserved residues. With respect to cofactor requirement and quarternary structure the crenarchaeal malate synthase might represent a novel type of this enzyme family. High activities of both glyoxylate cycle enzymes could already be detected in extracts of glucose grown cells and both increased about two-fold in extracts of acetate grown cells.     

Effects of growth mode and pyruvate carboxylase on succinic acid production by metabolically engineered strains of Escherichia coli

Escherichia coli NZN111, which lacks activities for pyruvate-formate lyase and lactate dehydrogenase, and AFP111, a derivative which contains an additional mutation in ptsG (a gene encoding an enzyme of the glucose phophotransferase system), accumulate significant levels of succinic acid (succinate) under anaerobic conditions. Plasmid pTrc99A-pyc, which expresses the Rhizobium etli pyruvate carboxylase enzyme, was introduced into both strains. We compared growth, substrate consumption, product formation, and activities of seven key enzymes (acetate kinase, fumarate reductase, glucokinase, isocitrate dehydrogenase, isocitrate lyase, phosphoenolpyruvate carboxylase, and pyruvate carboxylase) from glucose for NZN111, NZN111/pTrc99A-pyc, AFP111, and AFP111/pTrc99A-pyc under both exclusively anaerobic and dual-phase conditions (an aerobic growth phase followed by an anaerobic production phase). The highest succinate mass yield was attained with AFP111/pTrc99A-pyc under dual-phase conditions with low pyruvate carboxylase activity. Dual-phase conditions led to significant isocitrate lyase activity in both NZN111 and AFP111, while under exclusively anaerobic conditions, an absence of isocitrate lyase activity resulted in significant pyruvate accumulation. Enzyme assays indicated that under dual-phase conditions, carbon flows not only through the reductive arm of the tricarboxylic acid cycle for succinate generation but also through the glyoxylate shunt and thus provides the cells with metabolic flexibility in the formation of succinate. Significant glucokinase activity in AFP111 compared to NZN111 similarly permits increased metabolic flexibility of AFP111. The differences between the strains and the benefit of pyruvate carboxylase under both exclusively anaerobic and dual-phase conditions are discussed in light of the cellular constraint for a redox balance.     

The interaction of 3-phosphoglycerate and other substrate analogs with the glyoxylate- and succinate-binding sites of isocitrate lyase

The gene for isocitrate lyase from Escherichia coli has recently been cloned and sequenced. However, knowledge of this enzyme from E. coli is limited. Because of the possible role of 3-phosphoglycerate as a metabolic inhibitor of isocitrate lyase in E. coli, a detailed analysis of this compound as an inhibitor is reported in this paper. Kinetic data suggest that 3-phosphoglycerate is an analog of isocitrate (or glyoxylate) and also that it competes with succinate, or succinate analogs, by interfering with their binding to the enzyme. This could be due to the steric bulk of the phosphate moiety of 3-phosphoglycerate extending in the direction of and over the succinate-binding site. The interaction of other substrate analogs, including glycolate, oxalate, phosphoenolpyruvate, and cis-aconitate, with isocitrate lyase from E. coli is also characterized.     

Modification of the active site of isocitrate lyase from Pseudomonas indigofera

Kinetic analysis of inactivation of isocitrate lyase from Pseudomonas indigofera by 3-bromopyruvate established that enzyme binds this compound prior to alkylation and that substrate, D_s-isocitrate, competes for the same site on the enzyme. The rate of inactivation was increased by EDTA which is a promoter of catalysis in the presence of activated (reduced) enzyme and substrate. The combination of products, glyoxylate plus succinate, also protected against inactivation. Glyoxylate plus itaconate, phosphoenolpyruvate, or maleate also protected. However, each of the latter three compounds or glyoxylate or succinate alone provided little or no protection. Pyruvate, a competitive inhibitor with respect to glyoxylate in the condensation reaction, also failed to protect. However, two dicarboxylates, meso-tartrate and oxalate, that are also competitive inhibitors with respect to glyoxylate provide some protection against inactivation by BrP perhaps by bridging across cationic sites that facilitate glyoxylate and succinate binding. These and other results imply that alkylation by 3-bromopyruvate occurs at the succinate part of the active site. A mechanism which includes a catalytic role for the cysteine residue at the active site is presented and discussed.     

Inhibiton of isocitrate dehydrogenase and isocitrate lyase from Acinetobacter calcoaceticus by acids of the citrate and glyoxylate cycle]

Acinetobacter calcoaceticus contains two forms of NADP+-dependent isocitrate dehydrogenases differing, among others, by their molecular weights and regulatory properties. The regulation of the high-molecular form of isocitrate dehydrogenase and of isocitrate lyase by organic acids, either belonging or related to the citrate and glyoxalate cycle, is investigated. While alpha-ketoglutarate and oxalacetate competitively inhibit the isocitrate dehydrogenase against Ds-isocitrate, glyoxylate and pyruvate were found to increase Vmax and to lower the KM value for Ds-isocitrate and NADP+. Simultaneous addition of oxalacetate and glyoxylate (not, however, addition of the nonenzymatically formed condensation product of both compound) nullified the activation of isocitrate dehydrogenase by glyoxylate, and potentiates the inhibitory effect of oxalacetate. Alpha-ketoglutarate, succinate, and phosphoenolpyruvate inhibit the isocitrate lyase in a noncompetitive fashion against DS-isocitrate; L-malate, oxalacetate and glyoxylate inhibit competitively. The intermediates of the citrate and glyoxylate cycle afford additive inhibition of the isocitrate lyase. The importance of organic acids of the citrate and glyoxylate cycle and of phosphoenolpyruvate for the regulation of the citrate and glyoxylate cycle at the level of isocitrate dehydrogenase and isocitrate lyase is discussed.     

Subcellular localization and properties of glyoxylate cycle enzymes in the liver of rats with alloxan diabetes.

Key enzymes of the glyoxylate cycle (isocitrate lyase and malate synthetase) were found in the liver and kidney of rats suffering from alloxan diabetes. The activities of these enzymes in the liver were 0.080 and 0.0430 U/mg protein, respectively. Isocitrate lyase activity in the kidney was 0.030 U/mg protein, and that of the malate synthetase was 0.018 U/mg protein. Peroxisomal localization of the enzymes was shown. A novel malate dehydrogenase isoform was found in a liver of rats suffering from the alloxan diabetes. The isocitrate lyase was isolated by selective (NH4)2SO4 precipitation and DEAE-Toyopearl chromatography. The resulting enzyme preparation had specific activity 6.1 U/mg protein, corresponding to 76.25-fold purification with 32.6% yield. The isocitrate lyase was found to follow the Michaelis--Menten kinetic scheme (Km for isocitrate, 0.08 mM) and to be competitively inhibited by glucose 1-phosphate (Ki = 1. 25 mM), succinate (Ki = 1.75 mM), and citrate (Ki = 1.0 mM); the pH optimum of the enzyme was 7.5 in Tris-HCl buffer.     

Enzymes involved in the assimilation of one-carbon units by Pseudomonas MS.

Pseudomonas MS can grow on methylamine and a number of other compounds containing C1 units as a sole source of carbon and energy. Assimilation of carbon into cell material occurs via the "serine pathway" since enzymes of this pathway are induced after growth on methylamine, but not malate or acetate. A mutant has been isolated which is unable to grow on methylamine or any other related substrate providing C1 units. This mutant is also unable to grow on acetate. Measurment of enzyme activities in cell-free extracts of wild-type cells showed that growth on methylamine caused induction of isocitrate lyase, a key enzyme in the glyoxylate cycle. The mutant organism lacks malate lyase, a key enzyme of the serine pathway, and isocitrate lyase as well. These results suggest that utilization of C1 units by Pseudomonas MS results in the net accumulation of acetate which is then assimilated into cell material via the glyoxylate cycle.     

Alkylation of isocitrate lyase from Escherichia coli by 3-bromopyruvate

The inactivation of tetrameric isocitrate lyase from Escherichia coli by 3-bromopyruvate, exhibiting saturation kinetics, is accompanied by the loss of one sulfhydryl per subunit. The substrates glyoxylate and isocitrate protect against inactivation whereas the substrate succinate does not. The modification by 3-bromopyruvate (equimolar to subunits) imparts striking resistance to digestion of isocitrate lyase by trypsin, chymotrypsin, and V8 protease as well as a major decrease in the intensity of tryptophan fluorescence. After alkylation, the sequence Gly-His-Met-Gly-Gly-Lys is found following the modified Cys residue in the tryptic peptide representing positions 196-201. Thus Cys195 is alkylated by 3-bromopyruvate.     

Control of isocitrate lyase synthesis in Chlorella fusca var. vacuolata. Rate of enzyme synthesis in the presence and absence of acetate measured by [35S]methionine labelling and immunoprecipitation.

The rate of increase of isocitrate lyase activity was measured in darkened Chlorella fusca var. vaculoata cultures in the presence and absence of acetate and compared with the rate of incorporation of [35S]methionine into isocitrate lyase enzyme protein under the same conditions. Isocitrate lyase enzyme protein was isolated for this purpose by specific immunoprecipitation and sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. After 4h in the dark, in the presence of acetate the rate of increase of isocitrate lyase activity was 75 times that in the absence of acetate. Incorporation of [35S]methionine into isocitrate lyase was 140 times greater in the presence of acetate. Incorporation of [35S]methionine into the trichloroacetic acid-insoluble fraction overall was about five times as fast in the presence of acetate. These data are not consistent with an increased turnover of isocitrate lyase enzyme molecules, sufficient to account for the low rate of increase of isocitrate lyase activity in the absence of acetate. The greater rate of enzyme synthesis in the presence of acetate must therefore be due to some effect of this metabolite on the processing or translation of isocitrate lyase mRNA.