Dihydrolipoyl transacetylase of Escherichia coli. Formation of 8-S-acetyldihydrolipoamide

The dihydrolipoyl transacetylase component (E2) of the pyruvate dehydrogenase complex catalyzes the reaction of acetyl coenzyme A (acetyl-CoA) with dihydrolipoamide, producing coenzyme A and S-acetyldihydrolipoamide. The acetyl group is shown by experiments reported herein to be bonded to S8 in the enzymatic product. 1H NMR analysis of synthetic samples of both structural isomers of S-acetyl-S-(phenylmercurio)dihydrolipoamide enabled structural assignments to be made. Reaction of 8-S-acetyl-6-S-(phenylmercurio)dihydrolipoamide with 3-mercaptopropionic acid in chloroform produced 8-S-acetyldihydrolipoamide which contained a small amount (5%) of the 6-S isomer. Reaction of 6,8-di-S-acetyldihydrolipoamide with NH2OH produced a 4:1 mixture of 6-S-acetyldihydrolipoamide and the 8-S isomer. These compounds did not isomerize at significant rates in chloroform but rapidly isomerized to the equilibrium mixture in aqueous solution (Keq = 3.4). The second-order rate constants for the hydroxide-catalyzed isomerization were found to be kf = (1.15 +/- 0.07) X 10(6) M-1 X s-1 and kr = (3.36 +/- 0.20) X 10(5) M-1 X s-1 in the direction of the formation of the 8-S isomer. The enzymatic product was trapped by addition of phenylmercuric hydroxide within 15 s-30 min after starting the reaction. 1H NMR analysis of the products obtained at various times showed that the enzymatic product was 8-S-acetyldihydrolipoamide, which underwent progressive isomerization to the mixture of isomers within a few minutes. In the reaction of acetyl-CoA with dihydrolipoamide, the latter substrate reacts in place of enzyme-bound dihydrolipoyl moieties. Therefore, acetylation occurs at the 8-S position of bound lipoyl groups.     

3-Hydroxy-3-methylglutaryl coenzyme A synthase. Evidence for an acetyl-S-enzyme intermediate and identification of a cysteinyl sulfhydryl as the site of acetylation.

Homogeneous liver 3-hydroxy-3-methylglutaryl coenzyme A synthase, which catalyzes the condensation of acetyl-CoA with acetoacetyl-CoA to form 3-hydroxy-3-methylglutaryl-CoA, also carries out: (a) a rapid transacetylation from acetyl-CoA to 31-dephospho-CoA and (b) a slow hydrolysis of acetyl-CoA to acetate and CoA. Transacetylation and hydrolysis occur at 50 and 1 percent, respectively, the rate of the synthasecatalyzed condensation reaction. It appears that an acetyl-enzyme intermediate is involved in the transacetylase and hydrolase reactions of 3-hydroxy-3-methylglutaryl-CoA synthase, as well as in the over-all condensation process. Covalent binding to the enzyme of a [14C]acetyl group contributed by [1(-14)C]acetyl-CoA is indicated by migration of the [14C]acetyl group with the dissociated synthase upon electrophoresis in dodecyl sulfate-urea and by precipitation of [14C]acetyl-enzyme with trichloroacetic acid. At 0 degrees and a saturating level of acetyl-CoA, the synthase is rapidly (less than 20 s) acetylated yielding 0.6 acetyl group/enzyme dimer. Performic acid oxidation completely deacetylates the enzyme, suggesting the site of acetylation to be a cysteinyl sulfhydryl group. Proteolytic digestion of [14C]acetyl-S-enzyme under conditions favorable for intramolecular S to N acetyl group transfer quantitatively liberates a labeled derivative with a [14C]acetyl group stable to performic acid oxidation. The labeled oxidation product is identified as N-[14C]acetylcysteic acid, thus demonstrating a cysteinyl sulfhydryl group as the original site of acetylation. The ability of the acetylated enzyme, upon addition of acetoacetyl-CoA, to form 3-hydroxy-3-methylglutaryl-CoA indicates that the acetylated cysteine residue is at the catalytic site.     

Pyruvate dehydrogenase and 3-fluoropyruvate: chemical competence of 2-acetylthiamin pyrophosphate as an acetyl group donor to dihydrolipoamide

The pyruvate dehydrogenase component (E1) of the pyruvate dehydrogenase complex catalyzes the decomposition of 3-fluoropyruvate to CO2, fluoride anion, and acetate. Acetylthiamin pyrophosphate (acetyl-TPP) is an intermediate in this reaction. Incubation of the pyruvate dehydrogenase complex with 3-fluoro[1,2-14C]pyruvate, TPP, coenzyme A (CoASH), and either NADH or pyruvate as reducing systems leads to the formation of [14C]acetyl-CoA. In this reaction the acetyl group of acetyl-TPP is partitioned by transfer to both CoASH (87 +/- 2%) and water (13 +/- 2%). When the E1 component is incubated with 3-fluoro[1,2-14C]pyruvate, TPP, and dihydrolipoamide, [14C]acetyldihydrolipoamide is produced. The formation of [14C]acetyldihydrolipoamide was examined as a function of dihydrolipoamide concentration (0.25-16 mM). A plot of the extent of acetyl group partitioning to dihydrolipoamide as a function of 1/[dihydrolipoamide] showed 95 +/- 2% acetyl group transfer to dihydrolipoamide when dihydrolipoamide concentration was extrapolated to infinity. It is concluded that acetyl-TPP is chemically competent as an intermediate for the pyruvate dehydrogenase complex catalyzed oxidative decarboxylation of pyruvate.     

Pyruvate dehydrogenase complex of Escherichia coli. Thiamin pyrophosphate and NADH-dependent hydrolysis of acetyl-CoA

When the pyruvate dehydrogenase complex of Escherichia coli is reduced by NADH and alkylated by N-[14C]ethylmaleimide, 19-20 nmol of N-[14C]ethylmaleimide are bound per mg of complex. This is in accord with the presence of 10 nmol of functional lipoyl moieties per mg of complex as previously reported. Thus the lipoyl groups are all coupled via dihydrolipoyl dehydrogenase (E3) to reduction by NADH. As previously reported, the complex reductively acetylated by pyruvate and containing 10 nmol of acetyldihydrolipoyl groups per mg of complex produces about 5 nmol of NADH/mg of complex when challenged with CoA and NAD+ in a fast burst. Under anaerobic conditions a slow secondary process extending over 1 h produces another 5 nmol of NADH/mg of complex. The relationship between the two classes of acetyldihydrolipoyl groups is unknown but could reflect either intrinsic structural inequivalence of lipoyl groups (2/subunit of dihydrolipoyl transacetylase, E2). Alternatively, the acetyldihydrolipoyl groups may undergo reversible isomerization to structurally distinct forms. The purified complex catalyzes the cleavage of acetyl-CoA by two processes. The trace contaminant phosphotransacetylase catalyzes cleavage by phosphate to acetyl-P. The complex itself catalyzes hydrolysis of acetyl-CoA in a reaction that requires all three enzymes, NADH, thiamin pyrophosphate, and the lipoyl groups of E2. The hydrolytic pathway evidently involves overall reversal of the reaction, leading ultimately to the formation of acetyl-thiamin pyrophosphate, which undergoes hydrolysis to acetate.     

Properties of a newly characterized protein of the bovine kidney pyruvate dehydrogenase complex

The dihydrolipoyl transacetylase component, which serves as the structural core of mammalian pyruvate dehydrogenase complexes, is acetylated when treated with either pyruvate or with acetyl-CoA in the presence of NADH. Besides the dihydrolipoyl transacetylase component, we have found that another protein, referred to as protein X, is rapidly acetylated at thiol residues. Protein X remains fully bound to the transacetylase core under conditions that remove the pyruvate dehydrogenase and dihydrolipoyl dehydrogenase components. Mapping of 125I-tryptic peptides indicated that the transacetylase subunits and protein X are structurally distinct; however, under the same mapping conditions, there is considerable similarity in the positions of acetylated peptides derived from these subunits. Affinity-purified rabbit immunoglobulin G prepared against the dihydrolipoyl transacetylase core reacted exclusively with the transacetylase and with both its tryptic-derived inner domain and outer lipolyl-bearing domain. Those results further indicate that protein X is not derived from the transacetylase subunit Affinity-purified mouse antibody to protein X reacted selectively with large tryptic polypeptides derived from protein X and did not react with the inner domain of the transacetylase. However, the anti-protein X antibody did react with the intact transacetylase subunit, the lipoyl-bearing domain of the transacetylase, and weakly with the transsuccinylase component of the alpha-ketoglutarate dehydrogenase complex. This cross-reactivity reflected specificity of a portion of the polyclonal antibodies for a related structural region in the transacetylase and protein X (possibly a similar lipoyl-bearing region). Furthermore, a major portion of that polyclonal antibody was shown to react exclusively with protein X. Thus, protein X subunits differ substantially from transacetylase subunits but the two components have a region of structural similarity. We estimate that there are about 5 mol of protein X per mol of the kidney pyruvate dehydrogenase complex. Under a variety of conditions that result in a wide range of levels of acetylation of sites in the complex, about 1 acetyl group is incorporated into protein X per 10 acetyl groups incorporated into the transacetylase subunits per mol of complex. That ratio is close to the ratio of protein X subunits of transacetylase subunits in the complex, indicating that there are efficient mechanisms for acylation and deacylation of protein X.     

Escherichia coli pyruvate dehydrogenase complex. Thiamin pyrophosphate-dependent inactivation by 3-bromopyruvate

Inactivation of the pyruvate dehydrogenase complex by 3-bromopyruvate is thiamin pyrophosphate (TPP)-dependent. Inactivation with 2-14C- or 3-14C-labeled 3-bromopyruvate results in TPP-dependent covalent labeling of more than 60 sites in the complex, all of which are associated with the dihydrolipoyl transacetylase component. Inactivation by 3-bromo[1-14C]pyruvate labels up to 20 sites associated with dihydrolipoyl transacetylase, also with TPP dependence. Systemic chemical degradation of the complex inactivated by 3-bromo[2-14C]pyruvate under conditions that would convert lipoyl groups to S,S,-biscarboxymethyl dihydrolipoic acid produces S,S,-bis[14C]carboxymethyl dihydrolipoic acid. It is concluded that 3-bromopyruvate inactivates this complex by initially undergoing the first two steps of the usual catalytic pathway, TPP-dependent decarboxylation followed by reductive bromoacetylation of lipoyl moieties. The sulfhydryl groups of S-bromoacetyl dihydrolipoyl moieties generated by reductive bromoacetylation are then alkylated by 3-bromopyruvate as well as by bromoacetyl thioester groups associated with the complex.     

An enzyme-bound intermediate in the biosynthesis of 3-hydroxy-3-methylglutaryl-coenzyme A

1. Purified 3-hydroxy-3-methylglutaryl-CoA synthase from baker's yeast (free from acetoacetyl-CoA thiolase activity) catalysed an exchange of acetyl moiety between 3'-dephospho-CoA and CoA. The exchange rate was comparable with the overall velocity of synthesis of 3-hydroxy-3-methylglutaryl-CoA. 2. Acetyl-CoA reacted with the synthase, giving a rapid ;burst' release of CoA proportional in amount to the quantity of enzyme present. The ;burst' of CoA was released from acetyl-CoA, propionyl-CoA and succinyl-CoA (3-carboxypropionyl-CoA) but not from acetoacetyl-CoA, hexanoyl-CoA, dl-3-hydroxy-3-methylglutaryl-CoA, or other derivatives of glutaryl-CoA. 3. Incubation of 3-hydroxy-3-methylglutaryl-CoA synthase with [1-(14)C]acetyl-CoA yielded protein-bound acetyl groups. The K(eq.) for the acetylation was 1.2 at pH7.0 and 4 degrees C. Acetyl-labelled synthase was isolated free from [1-(14)C]acetyl-CoA by rapid gel filtration at pH6.1. The [1-(14)C]acetyl group was removed from the protein by treatment with hydroxylamine, CoA or acetoacetyl-CoA but not by acid. When CoA or acetoacetyl-CoA was present the radioactive product was [1-(14)C]acetyl-CoA or 3-hydroxy-3-methyl-[(14)C]glutaryl-CoA respectively. 4. The isolated [1-(14)C]acetyl-enzyme was slowly hydrolysed at pH6.1 and 4 degrees C with a first-order rate constant of 0.005min(-1). This rate could be stimulated either by raising the pH to 7.0 or by the addition of desulpho-CoA. 5. These properties are interpreted in terms of a mechanism in which 3-hydroxy-3-methyl-glutaryl-CoA synthase is acetylated by acetyl-CoA to give a stable acetyl-enzyme, which then condenses with acetoacetyl-CoA yielding a covalent derivative between 3-hydroxy-3-methylglutaryl-CoA and the enzyme which is then rapidly hydrolysed to free enzyme and product.     

Separation of protein X from the dihydrolipoyl transacetylase component of the mammalian pyruvate dehydrogenase complex and function of protein X

The dihydrolipoyl transacetylase (E2)-protein X-kinase subcomplex was resolved to produce an oligomeric transacetylase that was free of protein X and kinase subunits. We investigated the properties of this transacetylase E2 oligomer and of a form of the subcomplex from which only the lipoyl-bearing domain of protein X (XL) was removed. While retaining other catalytic and binding properties of the native subcomplex, the oligomeric transacetylase and the subcomplex lacking the XL domain had greatly reduced capacities both to support the overall reaction of the complex (upon reconstitution with other components) and to bind the dihydrolipoyl dehydrogenase component. Our results indicate that protein X, in part through its XL domain, contributes to the binding of the dihydrolipoyl dehydrogenase component and to the overall reaction of the complex.     

Peroxisomal and mitochondrial oxidation of fatty acids in the heart, assessed from the 13C labeling of malonyl-CoA and the acetyl moiety of citrate

We previously showed that a fraction of the acetyls used to synthesize malonyl-CoA in rat heart derives from partial peroxisomal oxidation of very long and long-chain fatty acids. The 13C labeling ratio (malonyl-CoA)/(acetyl moiety of citrate) was >1.0 with 13C-fatty acids, which yields [13C]acetyl-CoA in both mitochondria and peroxisomes and < 1.0 with substrates, which yields [13C]acetyl-CoA only in mitochondria. In this study, we tested the influence of 13C-fatty acid concentration and chain length on the labeling of acetyl-CoA formed in mitochondria and/or peroxisomes. Hearts were perfused with increasing concentrations of labeled docosanoate, oleate, octanoate, hexanoate, butyrate, acetate, or dodecanedioate. In contrast to the liver, peroxisomal oxidation of 1-13C-fatty acids in heart does not form [1-13C]acetate. With [1-13C]docosanoate and [1,12-13C2]dodecanedioate, malonyl-CoA enrichment plateaued at 11 and 9%, respectively, with no detectable labeling of the acetyl moiety of citrate. Thus, in the intact rat heart, docosanoate and dodecanedioate appear to be oxidized only in peroxisomes. With [1-13C]oleate or [1-13C]octanoate, the labeling ratio >1 indicates the partial peroxisomal oxidation of oleate and octanoate. In contrast, with [3-13C]octanoate, [1-13C]hexanoate, [1-13C]butyrate, or [1,2-13C2]acetate, the labeling ratio was <0.7 at all concentrations. Therefore, in rat heart, (i) n-fatty acids shorter than 8 carbons do not undergo peroxisomal oxidation, (ii) octanoate undergoes only one cycle of peroxisomal beta-oxidation, (iii) there is no detectable transfer to the mitochondria of acetyl-CoA from the cytosol or the peroxisomes, and (iv) the capacity of C2-C18 fatty acids to generate mitochondrial acetyl-CoA decreases with chain length.     

13C NMR study of effects of fasting and diabetes on the metabolism of pyruvate in the tricarboxylic acid cycle and the utilization of pyruvate and ethanol in lipogenesis in perfused rat liver

13C NMR has been used to study the competition of pyruvate dehydrogenase with pyruvate carboxylase for entry of pyruvate into the tricarboxylic acid (TCA) cycle in perfused liver from streptozotocin-diabetic and normal donor rats. The relative proportion of pyruvate entering the TCA cycle by these two routes was estimated from the 13C enrichments at the individual carbons of glutamate when [3-13C]alanine was the only exogenous substrate present. In this way, the proportion of pyruvate entering by the pyruvate dehydrogenase route relative to the pyruvate carboxylase route was determined to be 1:1.2 +/- 0.1 in liver from fed controls, 1:7.7 +/- 2 in liver from 24-fasted controls, and 1:2.6 +/- 0.3 in diabetic liver. Pursuant to this observation that conversion of pyruvate to acetyl coenzyme A (acetyl-CoA) was greatest in perfused liver from fed controls, the incorporation of 13C label into fatty acids was monitored in this liver preparation. Livers were perfused under steady-state conditions with labeled substrates that are converted to either [2-13C]acetyl-CoA or [1-13C]acetyl-CoA, which in the de novo synthesis pathway label alternate carbons in fatty acids. With the exception of the repeating methylene carbons, fatty acyl carbons labeled by [1-13C]acetyl-CoA (from [2-13C]pyruvate) gave rise to resonances distinguishable on the basis of chemical shift from those observed when label was introduced by [3-13C]alanine plus [2-13C]ethanol, which are converted to [2-13C]acetyl-CoA. Thus, measurement of 13C enrichment at several specific sites in the fatty acyl chains in time-resolved spectra of perfused liver offers a novel way of monitoring the kinetics of the biosynthesis of fatty acids.(ABSTRACT TRUNCATED AT 250 WORDS)     

Assay of the activity of malonyl-coenzyme A decarboxylase by gas chromatography-mass spectrometry

We developed a gas chromatography-mass spectrometry (GC-MS) assay to measure the activity of malonyl-coenzyme A (CoA) decarboxylase (MCD) in crude tissue homogenates. Liver extracts are incubated with [U-(13)C(3)]malonyl-CoA to form [U-(13)C(2)]acetyl-CoA by the action of MCD. The reaction mixture contains 2 mM ADP to prevent the hydrolysis of [1,2-(13)C(2)]acetyl-CoA by acetyl-CoA hydrolase present in the extracts. Newly formed [U-(13)C(2)]acetyl-CoA and internal standard of [(2)H(3),1-(13)C]acetyl-CoA are analyzed as thiophenol derivatives by GC-MS. This assay was applied to a study of the kinetics of MCD in rat liver. Using the Lineweaver-Burke plot of MCD kinetics, K(m) of 202microM and V(max) of 3.3micromol min(-1) (g liver)(-1) were calculated. The liver MCD activities (micromol min(-1) g(-1)+/-SD) in three groups of rats with different nutritional statuses-fed, 1-day fasted, and 2-day fasted-were 1.80+/-0.41, 2.59+/-0.37 (P<0.05), and 3.07+/-0.70 (P<0.05), respectively. We report a practical, nonradioactive, sensitive assay of MCD in crude tissue extract.     

Acetyl-CoA-carboxylase: modification of ATP-binding site of the active center by 2',3'-dialdehyde derivative of ATP

The interaction of rat liver acetyl-CoA carboxylase with a 2',3'-dialdehyde derivative of ATP (oATP) has been studied. The degree of the enzyme inactivation has been found to depend on the oATP concentration and the incubation time. ATP was the only reaction substrate which provided protection from inactivation. Acetyl-CoA did not affect inactivation, while HCO3- accelerated the process. Ki values for oATP in the absence and the presence of HCO3- were 0.35 +/- 0.04 and 0.5 +/- 0.06 mM, and those of the modification constant (k) were 0.11 and 0.26 min-1, respectively. oATP completely inhibited the reaction of [14C]ADP in equilibrium ATP exchange, whereas produced actually no effect on [14C]acetyl-CoA equilibrium with malonyl-CoA exchange. Incorporation of about one equivalent of [3H]oATP per acetyl-CoA carboxylase subunit has been shown. No restoration of the modified enzyme activity has been observed in Tris or beta-mercaptoethanol containing buffers, and treatment with NaB[3H]4 has not led to 3H incorporation. The modification process involves elimination of the triphosphate chain of oATP. The results obtained indicate the affinity character of oATP-mediated modification of acetyl-CoA carboxylase. The reagent apparently interacts selectively with the epsilon-amino group of lysine in the ATP-binding site to form a morpholine-like structure.     

Synthesis and antiviral evaluation of some new pyrazole and fused pyrazolopyrimidine derivatives

Some novel substituted pyrazole and pyrazolo[3,4-d]pyrimidine derivatives 2, 4, 8, and 9 were synthesized. Also, some acyclic S-nucleosides of pyrazolo[3,4-d]pyrimidine derivatives 10-13 were prepared via reaction of pyrazolo[3,4-d]pyrimidine-4(3H)-thione derivative 9 with some acyclic sugars. Moreover, the N-nucleoside derivative 14 was prepared via reaction of compound 8 with glucosamine hydrochloride. The antiviral evaluation of some selected new products showed that they have promising antiviral activity against hepatitis-A virus (HAV) and herpes simplex virus type-1 (HSV-1).     

Malate synthase: proof of a stepwise Claisen condensation using the double-isotope fractionation test

Although aldolase-catalyzed condensations proceed by stepwise mechanisms via the intermediacy of nucleophilic enol(ate)s or enamines, the mechanisms of those enzymes that catalyze Claisen-type condensations are unclear. The reaction pathway followed by an enzyme from this second group, malate synthase, has been studied by the double-isotope fractionation method to determine whether the reaction is stepwise or concerted. In agreement with earlier work, a deuterium kinetic isotope effect D(V/K) of 1.3 +/- 0.1 has been found when [2H3]acetyl-CoA is the substrate. The 13C isotope effect at the aldehydic carbon of glyoxylate has also been measured. For this determination, the malate product (containing the carbon of interest at C-2) was quantitatively transformed into a new sample of malate having the carbon of interest at C-4. This material was decarboxylated by malic enzyme to produce the appropriate CO2 for isotope ratio mass spectrometric analysis. The 13C isotope effect with [1H3]acetyl-CoA [that is, 13(V/K)H] is 1.0037 +/- 0.0004. By use of the known values of the intermolecular and intramolecular deuterium effects and of 13(V/K)H, the value of the 13C isotope effect when deuteriated [2H3]acetyl-CoA is the substrate [that is, 13(V/K)D] can be predicted for three possible mechanisms. If 13(V/K)H is a kinetic isotope effect and the reaction is concerted, the value of the 13C effect on deuteriation of acetyl-CoA will rise to 1.011; if 13(V/K)H is a kinetic isotope effect and the reaction is stepwise, the value of the 13C effect will fall to 1.0025; and if the 13C effect is an equilibrium isotope effect deriving from glyoxylate dehydration, the reaction is necessarily stepwise, and the value of 13(V/K)D will be 1.0037, unchanged from that of 13(V/K)H. Experimentally, the value of 13(V/K)D is 1.0037 +/- 0.0007, which requires that malate synthase follow a stepwise path. It is therefore clear that the two salient characteristics of enzymes that catalyze Claisen-like condensations, namely, the absence of enzyme-catalyzed proton exchange with solvent and the inversion of the configuration at the nucleophilic center, which had been suggestive of a concerted pathway, are not mechanistically diagnostic.     

3-Hydroxy-3-methylglutaryl-coenzyme A synthase from ox liver. Properties of its acetyl derivative.

Ox liver mitochondrial 3-hydroxy-3-methylglutaryl-CoA synthase (EC 4.1.3.5) reacts with acetyl-CoA to form a complex in which the acetyl group is covalently bound to the enzyme. This acetyl group can be removed by addition of acetoacetyl-CoA or CoA. The extent of acetylation and release of CoA were found to be highly temperature-dependent. At temperatures above 20 degrees C, a maximum value of 0.85 mol of acetyl group bound/mol of enzyme dimer was observed. Below this temperature the extent of rapid acetylation was significantly lowered. Binding stoichiometries close to 1 mol/mol of enzyme dimer were also observed when the 3-hydroxy-3-methylglutaryl-CoA synthase activity was titrated with methyl methanethiosulphonate or bromoacetyl-CoA. This is taken as evidence for a 'half-of-the-sites' reaction mechanism for the formation of 3-hydroxy-3-methylglutaryl-CoA by 3-hydroxy-3-methylglutaryl-CoA synthase. The Keq. for the acetylation was about 10. Isolated acetyl-enzyme is stable for many hours at 0 degrees C and pH 7, but is hydrolysed at 30 degrees C with a half-life of 7 min. This hydrolysis is stimulated by acetyl-CoA and slightly by succinyl-CoA, but not by desulpho-CoA. The site of acetylation has been identified as the thiol group of a reactive cysteine residue by affinity-labelling with the substrate analogue bromo[1-14C]acetyl-CoA.     

3-Hydroxy-3-methylgutaryl-CoA synthase. Participation of acetyl-S-enzyme and enzyme-S-hydroxymethylgutaryl-SCoA intermediates in the reaction.

Acetyl-CoA reacts stoichiometrically with a cysteinyl sufhydryl group of avian liver 3-hydroxy-3-methylglutaryl (HMG)-CoA synthase to yield acetyl-S-enzyme (Miziorko H.M., Clinkenbeard, K.D., Reed, W.D., and Lane, M.D. (1975) J. Biol. Chem. 250, 5768-5773). Evidence that acetyl-S-enzyme condenses with the second substrate, acetoacetyl CoA, to form enzyme-S-HMG-SCoA has been obtained by trapping and characterizing this putative intermediate. [14C]Acetyl-S-enzyme was incubated briefly at -25 degrees with acetoacetyl-CoA, precipitated with trichloroacetic acid, and the labeled acylated enzyme species were isolated. Performic acid oxidation of the precipitated [14C]acyl-S-enzyme intermediates produced volatile [14C]acetic acid from unreacted [14C]acetyl-S-enzyme and nonvolatile [14C]3-hydroxy-3-methyl glutaric acid from enzyme-S-[14C]HMG-SCoA. Condensation of unlabeled acetyl-S-enzyme with [14C]aceto-acetyl-CoA or acetoacetyl-[3H]CoA also produced labeled enzyme-S-HMG-SCoA. Thus, the acetyl moiety from acetyl-CoA and the acetoacetyl and CoA moieties from acetoacetyl-CoA all are incorporated into the HMG-CoA which is covalently-linked to the enzyme. Enzyme-S-[14C]HMG-SCoA was subjected to proteolytic digestion under conditions favorable for intramolecular S to N acyl transfer in the predicted cysteine-S-[14C]HMG-SCoA fragment. Performic acid oxidation of the protease-digested material yields N-[14C]HMG-cysteic acid indicating that HMG-CoA had been covalently bound to the enzyme via the -SH of an active site cysteine. An isotope trapping technique was employed to test the kinetic competence of acetyl-S-enzyme as an intermediate in the HMG-CoA synthase-catalyzed reaction. Evidence is presented which indicates that the rate of condensation of acetoacetyl-CoA with acetyl-S-enzyme to form enzyme-S-HMG-SCoA is more rapid than either the acetylation of the synthase by acetyl-CoA or the overall forward reaction leading to HMG-CoA. These observations, together with indirect evidence that hydrolysis of enzyme-S-HMG-SCoA is extremely rapid, suggest that acetylation of synthase is the rate-limiting step in HMG-CoA synthesis.     

Acetoin Fermentation by Citrate-Positive Lactococcus lactis subsp. lactis 3022 Grown Aerobically in the Presence of Hemin or Cu

CitrLactococcus lactis subsp. lactis 3022 produced more biomass and converted most of the glucose substrate to diacetyl and acetoin when grown aerobically with hemin and Cu. The activity of diacetyl synthase was greatly stimulated by the addition of hemin or Cu, and the activity of NAD-dependent diacetyl reductase was very high. Hemin did not affect the activities of NADH oxidase and lactate dehydrogenase. These results indicated that the pyruvate formed via glycolysis would be rapidly converted to diacetyl and that the diacetyl would then be converted to acetoin by the NAD-dependent diacetyl reductase to reoxidize NADH when the cells were grown aerobically with hemin or Cu. On the other hand, the Y(Glu) value for the hemincontaining culture was lower than for the culture without hemin, because acetate production was repressed when an excess of glucose was present. However, in the presence of lipoic acid, an essential cofactor of the dihydrolipoamide acetyltransferase part of the pyruvate dehydrogenase complex, hemin or Cu enhanced acetate production and then repressed diacetyl and acetoin production. The activity of diacetyl synthase was lowered by the addition of lipoic acid. These results indicate that hemin or Cu stimulates acetyl coenzyme A (acetyl-CoA) formation from pyruvate and that lipoic acid inhibits the condensation of acetyl-CoA with hydroxyethylthiamine PP(i). In addition, it appears that acetyl-CoA not used for diacetyl synthesis is converted to acetate.     

Reaction mechanism for mammalian pyruvate dehydrogenase using natural lipoyl domain substrates

The pyruvate dehydrogenase (E1) component of the pyruvate dehydrogenase complex (PDC) catalyzes a two-step reaction. Recombinant production of substrate amounts of the lipoyl domains of the dihydrolipoyl transacetylase (E2) component of the mammalian PDC allowed kinetic characterization of the rapid physiological reaction catalyzed by E1. Using either the N-terminal (L1) or the internal (L2) lipoyl domain of E2 as a substrate, analyses of steady state kinetic data support a ping pong mechanism. Using standard E1 preparations, Michaelis constants (Km) were 52 +/- 14 microM for L1 and 24.8 +/- 3.8 microM for pyruvate and k(cat) was 26.3 s(-1). With less common, higher activity preparations of E1, the Km values were > or =160 microM for L1 and > or =35 microM for pyruvate and k(cat) was > or =70 s(-1). Similar results were found with the L2 domain. The best synthetic lipoylated-peptide (L2 residues 163-177) was a much poorer substrate (Km > or =15 mM, k(cat) approximately equals 5 s(-1); k(cat)/Km decreased >1,500-fold) than L1 or L2, but a far better substrate in the E1 reaction than free lipoamide (k(cat)/Km increased >500-fold). Each lipoate source was an effective substrate in the dihydrolipoyl dehydrogenase (E3) reaction, but E3 had a lower Km for the L2 domain than for lipoamide or the lipoylated peptides. In contrast to measurements with slow E1 model reactions that use artificial acceptors, we confirmed that the natural E1 reaction, using lipoyl domain acceptors, was completely inhibited (>99%) by phosphorylation of E1 and the phosphorylation strongly inhibited the reverse of the second step catalyzed by E1. The mechanisms by which phosphorylation interferes with E1 activity is interpreted based on accrued results and the location of phosphorylation sites mapped onto the 3-D structure of related alpha-keto acid dehydrogenases.     

Metabolism of acetyl-CoA by isolated peroxisomal fractions: formation of acetate and acetoacetyl-CoA.

Liver peroxisomal fractions, isolated from rats treated with clofibrate, were shown to hydrolyze added [1-14C]acetyl-CoA to free [1-14C]acetate. [1-14C]Acetyl-CoA was, however, also converted to [14C]acetoacetyl-CoA. This reaction was inhibited by added ATP and by solubilization of the peroxisomes. The effect of ATP on synthesis of [14C]acetoacetyl-CoA was likely due to ATP-dependent stimulation of acetyl-CoA hydrolase (EC 3.1.2.1) activity. The inhibitory effect due to solubilizing conditions of incubation remains unexplained. During peroxisomal beta-oxidation of [1-14C]palmitoyl-CoA, [1-14C]acetyl-CoA, [1-14C]acetate, and [14C]acetoacetyl-CoA were shown to be produced. Possible metabolic implications of peroxisomal acetoacetyl-CoA synthesis are discussed.     

On the chromatographic heterogeneity of human fetal hemoglobin.

Minor fetal hemoglobins in red cell hemolysates of newborn and adults with elevated levels of Hb F have been separated and quantitated by Biorex 70 column chromatography. In addition to Hb F1, other minor hemoglobin zones eluting before F1, pre-F1, and after F1, post-f1 have been observed. The relative amounts of the two pre-F1 zones and F1 are higher in the red cells of adults with 97--100% Hb F (homozygous hereditary persistence of fetal hemoglobin, homozygous deltabeta-thalassemia and homozygous beta0-thalassemia) than in the red cells of an adult with homozygous beta+-thalassemia with 66% Hb F, a child with a trisomy-D-13 having 38% Hb F, and in two newborn. Hb F was glycosylated in vitro with [14C]glucose or [14C] glucose 6-phosphate, and was acetylated using chicken reticulocyte lysate or a crude acetyltransferase preparation isolated from the same lysate with [14C]acetyl-CoA as substrate. Chromatographic analyses indicated that the Hb F1 zone can be formed both by glycosylation and acetylation of Hb F, and that pre-F1 zones can be products of the reaction of Hb F with phosphorylated glycolytic intermediates. Biosynthesis of minor hemoglobins in reticulocytes was studied with [14C]leucine in the presence and absence of cycloheximide and by pulse-chase. The resulting data indicate that Hb F1 synthesis is dependent upon Hb F synthesis and that the posttranslational modification may take place at an early stage in Hb F synthesis.