The pyruvate-dehydrogenase complex from Azotobacter vinelandii.

The pyruvate dehydrogenase complex from Axotobacter vinelandii was isolated in a five-step procedure. The minimum molecular weight of the pure complex is 600,000, as based on an FAD content of 1.6 nmol-mg protein-1. The molecular weight is 1.0-1.2 X 10(6), indicating 1 mole of lipoamide dehydrogenase dimer per complex molecule. Sodium dodecylsulphate gel electrophoretical patterns show that apart from pyruvate dehydrogenase (Mr89,000) and lipoamide dehydrogenase (Mrmonomer 56,000) two active transacetylase isoenzymes are present with molecular weight on the gel 82,000 and 59,000 but probably actually lower. The pure complex has a specific activity of the pyruvate-NAD+ reductase (overall) reaction of 10 units-mg protein-1 at 25 degrees C. The partial reactions have the following specific activities in units-mg protein-1 at 25 degrees C under standard conditions: pyruvate-K3Fe(CN)6 reductase 0.14, transacetylase 3.6 and lipoamide dehydrogenase 2.9. The properties of this complex are compared with those from other sources. NADPH reduced the FAD of lipoamide dehydrogenase as well in the complex as in the free form. NADP+ cannot be used as electron acceptor. Under aerobic conditios pyruvate oxidase reaction, dependent on Mg2+ and thiamine pyrophosphate, converts pyruvate into CO2 and acetate; V is 0.2 mumol 02-min-1-mg-1, Km(pyruvate)0.3 mM. The kinetics of this reaction shows a linear 1/velocity-1/[pyruvate] plot. K3Fe(CN)6 competes with the oxidase reaction. The oxidase activity is stimulated by AMP and sulphate and is inhibited by acetyl-CoA. The partially purified enzyme contains considerable phosphotransacetylase activity. The pure complex does not contain this activity. The physiological significance of this activity is discussed.     

Selective inactivation of the transacylase components of the 2-oxo acid dehydrogenase multienzyme complexes of Escherichia coli.

1. The reaction of the pyruvate dehydrogenase multienzyme complex of Escherichia coli with maleimides was examined. In the absence of substrates, the complex showed little or no reaction with N-ethylmaleimide. However, in the presence of pyruvate and N-ethylmaleimide, inhibition of the pyruvate dehydrogenase complex was rapid. Modification of the enzyme was restricted to the transacetylase component and the inactivation was proportional to the extent of modification. The lipoamide dehydrogenase activity of the complex was unaffected by the treatment. The simplest explanation is that the lipoyl groups on the transacetylase are reductively acetylated by following the initial stages of the normal catalytic cycle, but are thereby made susceptible to modification. Attempts to characterize the reaction product strongly support this conclusion. 2. Similarly, in the presence of N-ethylmaleimide and NADH, much of the pyruvate dehydrogenase activity was lost within seconds, whereas the lipoamide dehydrogenase activity of the complex disappeared more slowly: the initial site of the reaction with the complex was found to be in the lipoyl transacetylase component. The simplest interpretation of these experiments is that NADH reduces the covalently bound lipoyl groups on the transacetylase by means of the associated lipoamide dehydrogenase component, thereby rendering them susceptible to modification. However, the dependence of the rate and extent of inactivation on NADH concentration was complex and it proved impossible to inhibit the pyruvate dehydrogenase activity completely without unacceptable modification of the other component enzymes. 3. The catalytic reduction of 5,5'-dithiobis-(2-nitrobenzoic acid) by NADH in the presence of the pyruvate dehydrogenase complex was demonstrated. A new mechanism for this reaction is proposed in which NADH causes reduction of the enzyme-bound lipoic acid by means of the associated lipoamide dehydrogenase component and the dihydrolipoamide is then oxidized back to the disulphide form by reaction with 5,5'-dithiobis-(2-nitrobenzoic acid). 4. A maleimide with a relatively bulky N-substituent, N-(4-diemthylamino-3,5-dinitrophenyl)maleimide, was an effective replacement for N-ethylmaleimide in these reactions with the pyruvate dehydrogenase complex. 5. The 2-oxoglutarate dehydrogenase complex of E. coli behaved very similarly to the pyruvate dehydrogenase complex, in accord with the generally accepted mechanisms of the two enzymes. 6. The treatment of the 2-oxo acid dehydrogenase complexes with maleimides in the presence of the appropriate 2-oxo acid substrate provides a simple method for selectively inhibiting the transacylase components and for introducing reporter groups on to the lipoyl groups covalently bound to those components.     

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.     

The elementary reactions of the pig heart pyruvate dehydrogenase complex. A study of the inhibition by phosphorylation.

1. A method was devised for preparing pig heart pyruvate dehydrogenase free of thiamin pyrophosphate (TPP), permitting studies of the binding of [35S]TPP to pyruvate dehydrogenase and pyruvate dehydrogenase phosphate. The Kd of TPP for pyruvate dehydrogenase was in the range 6.2-8.2 muM, whereas that for pyruvate dehydrogenase phosphate was approximately 15 muM; both forms of the complex contained about the same total number of binding sites (500 pmol/unit of enzyme). EDTA completely inhibited binding of TPP; sodium pyrophosphate, adenylyl imidodiphosphate and GTP, which are inhibitors (competitive with TPP) of the overall pyruvate dehydrogenase reaction, did not appreciably affect TPP binding. 2. Initial-velocity patterns of the overall pyruvate dehydrogenase reaction obtained with varying TPP, CoA and NAD+ concentrations at a fixed pyruvate concentration were consistent with a sequential three-site Ping Pong mechanism; in the presence of oxaloacetate and citrate synthase to remove acetyl-CoA (an inhibitor of the overall reaction) the values of Km for NAD+ and CoA were 53+/- 5 muM and 1.9+/-0.2 muM respectively. Initial-velocity patterns observed with varying TPP concentrations at various fixed concentrations of pyruvate were indicative of either a compulsory order of addition of substrates to form a ternary complex (pyruvate-Enz-TPP) or a random-sequence mechanism in which interconversion of ternary intermediates is rate-limiting; values of Km for pyruvate and TPP were 25+/-4 muM and 50+/-10 nM respectively. The Kia-TPP (the dissociation constant for Enz-TPP complex calculated from kinetic plots) was close to the value of Kd-TPP (determined by direct binding studies). 3. Inhibition of the overall pyruvate dehydrogenase reaction by pyrophosphate was mixed non-competitive versus pyruvate and competitive versus TPP; however, pyrophosphate did not alter the calculated value for Kia-TPP, consistent with the lack of effect of pyrophosphate on the Kd for TPP. 4. Pyruvate dehydrogenase catalysed a TPP-dependent production of 14CO2 from [1-14C]pyruvate in the absence of NAD+ and CoA at approximately 0.35% of the overall reaction rate; this was substantially inhibited by phosphorylation of the enzyme both in the presence and absence of acetaldehyde (which stimulates the rate of 14CO2 production two- or three-fold). 5. Pyruvate dehydrogenase catalysed a partial back-reaction in the presence of TPP, acetyl-CoA and NADH. The Km for TPP was 4.1+/-0.5 muM. The partial back-reaction was stimulated by acetaldehyde, inhibited by pyrophosphate and abolished by phosphorylation. 6. Formation of enzyme-bound [14C]acetylhydrolipoate from [3-14C]pyruvate but not from [1-14C]acetyl-CoA was inhibited by phosphorylation. Phosphorylation also substantially inhibited the transfer of [14C]acetyl groups from enzyme-bound [14C]acetylhydrolipoate to TPP in the presence of NADH. 7...     

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.     

Effects of alpha-ketoisovalerate on bovine heart pyruvate dehydrogenase complex and pyruvate dehydrogenase kinase

The regulatory effects of alpha-ketoisovalerate on purified bovine heart pyruvate dehydrogenase complex and endogenous pyruvate dehydrogenase kinase were investigated. Incubation of pyruvate dehydrogenase complex with 0.125 to 10 mM alpha-ketoisovalerate caused an initial lag in enzymatic activity, followed by a more linear but inhibited rate of NADH production. Incubation with 0.0125 or 0.05 mM alpha-ketoisovalerate caused pyruvate dehydrogenase inhibition, but did not cause the initial lag in pyruvate dehydrogenase activity. Gel electrophoresis and fluorography demonstrated the incorporation of acyl groups from alpha-keto[2-14C]isovalerate into the dihydrolipoyl transacetylase component of the enzyme complex. Acylation was prevented by pyruvate and by arsenite plus NADH. Endogenous pyruvate dehydrogenase kinase activity was stimulated specifically by K+, in contrast to previous reports, and kinase stimulation by K+ correlated with pyruvate dehydrogenase inactivation. Maximum kinase activity in the presence of K+ was inhibited 62% by 0.1 mM thiamin pyrophosphate, but was inhibited only 27% in the presence of 0.1 mM thiamin pyrophosphate and 0.1 mM alpha-ketoisovalerate. Pyruvate did not affect kinase inhibition by thiamin pyrophosphate at either 0.05 or 2 mM. The present study demonstrates that alpha-ketoisovalerate acylates heart pyruvate dehydrogenase complex and suggests that acylation prevents thiamin pyrophosphate-mediated kinase inhibition.     

Substrate-induced structural changes of the pyruvate dehydrogenase multienzyme complex

The time course of the overall reaction catalyzed by the pyruvate dehydrogenase multienzyme complex produces an unexpectedly high lag (tau = 8 S) even in the presence of saturating concentrations of its substrates. The preincubation of the pyruvate dehydrogenase complex with one of the substrates alone decreases the duration of this lag, and all the substrates of the pyruvate dehydrogenase component (E1) and dihydrolipoyl transacetylase component (E2) together (pyruvate, thiamine pyrophosphate, and CoA) result in the complete disappearance of the lag. The reduction of the dihydrolipoyl dehydrogenase component (E3) of the pyruvate dehydrogenase complex with the substrates of the complex in the absence of NAD+ produces significantly different quenching in the FAD fluorescence, and then the reduction with the substrates of E3 as dihydrolipoic acid and dithioerythritol. (The formation of FADH2 was not observed in the system.) The higher fluorescence quenching in the presence of substrates of pyruvate dehydrogenase complex compared to the effect caused by the substrates of the E3 component (dihydrolipoic acid and DTE) indicates conformational changes additionally manifested in the fluorescence properties of the enzyme complex. The substrate-induced quenching of the enzyme-bound FAD fluorescence shows biphasic kinetics. The rate constant of the slow phase is comparable with the rate constant calculated from the time duration of the lag phase observed in the overall reaction. The kinetic analysis of both intensity and anisotropy decrease of the FAD fluorescence suggests a consecutive transmittance of an all substrate-coordinated, induced conformational changes directed from the pyruvate dehydrogenase-via the lipoyl transacetylase--to the lipoyl dehydrogenase. Two simultaneous conformational effects caused by binding of the substrates can be distinguished; one of them results the fluorescence of the bound FAD to be more quenched, while the other makes the FAD more mobile. The first-order rate constants of both these conformational changes were determined. The present observations suggest that the pyruvate dehydrogenase complex exists in a partially inactive state in the absence of its substrates, and it becomes active due to conformational changes caused by the binding of its substrates.     

Alterations in the pyruvate dehydrogenase complex during adaptation to glucose by Neurospora

A 20-fold induction of the pyruvate dehydrogenase complex, pyruvate dehydrogenase (EC 1.2.4.1) plus dihydrolipoate S-acetyltransferase, (lipoyltransacetylase) (EC 2.3.1.12) plus dihydrolipoyl dehydrogenase, NADH : lipoamide oxidoreductase, (EC 1.6.4.3), from a specific activity of 3.5–65.0 was observed in mitochondrial extracts during adaptation of Neurospora to glucose from acetate media. The extent of ATP-dependent, time-dependent inactivation of the pyruvate dehydrogenase complex was approximately the same in both acetate- and glucose-grown cells, thereby indicating that the low pyruvate dehydrogenerase complex activities in acetate-grown cells did not represent phosphorylated pyruvate dehydrogenase complex molecules. High levels of dihydrolipoyl transacetylase (EC 2.3.1.12) were observed in mitochondrial extracts from acetate-grown cells; this lipoyltransacetylase was analyzed on sucrose density gradients and found to be associated with the pyruvate dehydrogenase complex. Digitonin fractionation of mitochondria revealed that both the pyruvate dehydrogenase complex and lipoyltransacetylase were primarily associated with the mitochondrial outer membrane.     

Crystallization of a dihydrolipoyl transacetylase--dihydrolipoyl dehydrogenase subcomplex and its implications regarding the subunit structure of the pyruvate dehydrogenase complex from Escherichia coli.

A subcomplex consisting of dihydrolipoyl transacetylase and dihydrolipoyl dehydrogenase, two of the three enzymes comprising the Escherichia coli pyruvate dehydrogenase complex, has been crystallized. X-ray diffraction data establish that the space group is P2₁3 with unit cell dimension $\text{a=211 .5}\text{A}\text{?}$. The unit cell contains four molecules of the subcomplex, each possessing 3-fold crystallographic and molecular symmetry. This finding, together with biochemical and electron microscopic data reported elsewhere, establish unequivocally that dihydrolipoyl transacetylase, the core enzyme of the pyruvate dehydrogenase complex, consists of 24 identical subunits with octahedral (432) symmetry. In the case presented here, the 432 symmetry of the transacetylase is reduced to 3-fold symmetry in the subcomplex by the addition of dihydrolipoyl dehydrogenase subunits. Crystal density measurements indicate that the dihydrolipoyl transacetylase present in these crystals is considerably smaller than the core mass generally reported for intact transacetylase. The implications of these findings are discussed with respect to the subunit stoichiometry and structure of the E. coli pyruvate dehydrogenase complex.     

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.     

Role of ions in the regulation of porcine lactate dehydrogenase.

Different ions affect the H4 and M4 isoenzymes of porcine lactate dehydrogenase (L-lactate: NAD+ oxidoreductase, EC 1.1.1.27) in the same way, inhibiting the enzyme at low pyruvate concentrations, whereas at high pyruvate concentrations, the activities were enhanced. The inhibition was competitive with regard to pyruvate and NADH. The enhancement of the enzyme activity at high pyruvate concentration is due to the increase in the Km value for pyruvate, implying that higher substrate concentrations are needed to obtain substrate inhibition. Sulphate behaved differently from the other ions. It inhibited in a noncompetitive manner with regard to pyruvate and did not activate the enzyme at high pryvuate concentration. The effect of ions increased with the size of the anion. The ionic strength was of less importance.     

Redetermination of the molecular weights of the components of the pyruvate dehydrogenase complex from E. coli Kl2+.

The validity of molecular weight determination in SDS-polyacrylamide gels for the three components of the pyruvate dehydrogenase complex: pyruvate dehydrogenase, dihydrolipoamide transacetylase, and dihydrolipoamide dehydrogenase has been checked by measuring their free electrophoretic mobilities and their retardation coefficients. A linear relationship between these parameters has been found for all three enzymes as compared with standard proteins. This substantiates earlier molecular weight determinations in SDS-polyacrylamide gels for the components of the pyruvate dehydrogenase complex which are confirmed by this study for different acrylamide gel concentrations.     

Intra- and intermolecular electron transfer processes in redox proteins

Initial velocity and product inhibition experiments were performed to characterize the kinetic mechanism of branched chain ketoacid dehydrogenase (the branched chain complex) activity. The results were directly compared to predicted patterns for a three-site ping-pong mechanism. Product inhibition experiments confirmed that NADH is competitive versus NAD+ and isovaleryl CoA is competitive versus CoA. Furthermore, both NADH and isovaleryl CoA were uncompetitive versus ketoisovaleric acid. These results are consistent with a ping-pong mechanism and are similar to pyruvate dehydrogenase and alpha-ketoglutarate dehydrogenase. However, inhibition patterns for isovaleryl CoA versus NAD+ and NADH versus CoA are not consistent with a ping-pong mechanism. These patterns may result from a steric interaction between the flavoprotein and transacetylase subunits of the complex. To determine the kinetic mechanism of the substrates and feedback inhibitors (NADH and isovaleryl CoA) of the branched chain complex, it was necessary to define the interaction of the inhibitors at nonsaturating fixed substrate (CoA and NAD+) concentrations. While the competitive inhibition patterns were maintained, slope replots for NADH versus NAD+ at nonsaturating CoA concentrations were parabolic. This unexpected finding resembles a linear mixed type of inhibition where the inhibition is a combination of pure competitive and noncompetitive inhibition.     

Stability and reconstitution of pyruvate oxidase from Lactobacillus plantarum: dissection of the stabilizing effects of coenzyme binding and subunit interaction.

Pyruvate oxidase from Lactobacillus plantarum is a homotetrameric flavoprotein with strong binding sites for FAD, TPP, and a divalent cation. Treatment with acid ammonium sulfate in the presence of 1.5 M KBr leads to the release of the cofactors, yielding the stable apoenzyme. In the present study, the effects of FAD, TPP, and Mn2+ on the structural properties of the apoenzyme and the reconstitution of the active holoenzyme from its constituents have been investigated. As shown by circular dichroism and fluorescence emission, as well as by Nile red binding, the secondary and tertiary structures of the apoenzyme and the holoenzyme do not exhibit marked differences. The quaternary structure is stabilized significantly in the presence of the cofactors. Size-exclusion high-performance liquid chromatography and analytical ultracentrifugation demonstrate that the holoenzyme retains its tetrameric state down to 20 micrograms/mL, whereas the apoenzyme shows stepwise tetramer-dimer-monomer dissociation, with the monomer as the major component, at a protein concentration of < 20 micrograms/mL. In the presence of divalent cations, the coenzymes FAD and TPP bind to the apoenzyme, forming the inactive binary FAD or TPP complexes. Both FAD and TPP affect the quaternary structure by shifting the equilibrium of association toward the dimer or tetramer. High FAD concentrations exert significant stabilization against urea and heat denaturation, whereas excess TPP has no effect. Reconstitution of the holoenzyme from its components yields full reactivation. The kinetic analysis reveals a compulsory sequential mechanism of cofactor binding and quaternary structure formation, with TPP binding as the first step. The binary TPP complex (in the presence of 1 mM Mn2+/TPP) is characterized by a dimer-tetramer equilibrium transition with an association constant of Ka = 2 x 10(7) M-1. The apoenzyme TPP complex dimer associates with the tetrameric holoenzyme in the presence of 10 microM FAD. This association step obeys second-order kinetics with an association rate constant k = 7.4 x 10(3) M-1 s-1 at 20 degrees C. FAD binding to the tetrameric binary TPP complex is too fast to be resolved by manual mixing.     

The role of lipoic acid residues in the pyruvate dehydrogenase multienzyme complex of Escherichia coli.

Two lipoic acid residues on each dihydrolipoamide acetyltransferase (E2) chain of the pyruvate dehydrogenase multienzyme complex of Escherichia coli were found to undergo oxidoreduction reactions with NAD+ catalysed by the lipoamide dehydrogenase component. It was observed that: (a) 2 mol of reagent/mol of E2 chain was incorporated when the complex was incubated with N-ethylmaleimide in the presence of acetyl-SCoA and NADH; (b) 4 mol of reagent/mol of E2 chain was incorporated when the complex was incubated with N-ethylmaleimide in the presence of NADH; (c) between 1 and 2 mol of acetyl groups/mol of E2 chain was incorporated when the complex was incubated with acetyl-SCoA plus NADH; (d) 2 mol of acetyl groups/mol of E2 chain was incorporated when the complex was incubated with pyruvate either before or after many catalytic turnovers through the overall reaction. There was no evidence to support the view that only half of the dihydrolipoic acid residues can be reoxidized by NAD+. However, chemical modification of lipoic acid residues with N-ethylmaleimide was shown to proceed faster than the accompanying loss of enzymic activity under all conditions tested, which indicates that not all the lipoyl groups are essential for activity. The most likely explanation for this result is an enzymic mechanism in which one lipoic acid residue can take over the function of another.     

Pulsed EPR analysis of tartrate dehydrogenase active-site complexes.

Mn2+.tartrate dehydrogenase.substrate complexes have been examined by electron spin echo envelope modulation spectroscopy. The occurrence of dipolar interactions between Mn2+ and 2H on [2H]pyruvate and [4-2H]NAD(H) confirms that Mn2+ binds at the enzyme active site. The 2H signal arising from labeled pyruvate was lost if the sample was incubated at room temperature, indicating that the enzyme catalyzes exchange between the pyruvate methyl protons and solvent protons. Mn-133Cs dipolar coupling was also observed, which suggests that the monovalent cation cofactor also binds in the active site. The tartrate analogue oxalate was observed to have a significant effect on the binding of NAD(H). Oxalate appears to constrain the binding of NAD(H) so that the nicotinamide portion of the cofactor is held in close proximity to Mn2+. Spectra of enzyme complexes prepared with (R)-[4-2H]NADH showed a more intense 2H signal than analogous complexes prepared with (S)-[4-2H]NADH, demonstrating that the pro-R position of NADH is closer to Mn2+ than the pro-S position and suggesting that tartrate dehydrogenase is an A-side-specific dehydrogenase. Oxalate also affected Cs+ binding; the intensity of the 133Cs signal increased in the presence of oxalate, which suggest that oxalate facilitates binding of Cs+ to the active site or that Cs+ binds closer to Mn2+ when oxalate is present. In addition to signals from substrates, electron spin echo envelope modulation spectra revealed 14N signals that arose from coordination to Mn2+ by nitrogen-containing ligands from the protein; however, the identity of this ligand or ligands remains obscure.     

Component requirements for NADH inhibition and spermine stimulation of pyruvate dehydrogenaseb phosphatase activity

The subunit and subdomain requirements for NADH inhibition as well as Ca+ and spermine activation of the pyruvate dehydrogenaseb phosphatase were analyzed. The transacetylase-protein X subcomplex (E2-X) was required for all three effects. The oligomeric inner domain of the transacetylase did not support any of these regulatory effects. The presence of at least a portion of the outer (lipoyl-bearing) domains of the transacetylase but not the lipoyl-bearing portion of protein X was essential for expression of these regulatory effects on phosphatase activity. The inner domain of protein X may contribute to some effects. The E2-X subcomplex, alone, had no effect on phosphatase activity in the absence of Ca2+, but the subcomplex did support both NADH inhibition and spermine activation in the absence of Ca2+. Studies with peptide substrates established that spermine is directly bound by a phosphatase subunit. With the resolved pyruvate dehydrogenase component (E1b) used as the substrate, the E2-X subcomplex transformed the effect of spermine from inhibiting to stimulating the rate of dephosphorylation by the phosphatase. The above observations suggest that binding of E1b to the E2-X subcomplex alters its presentation to the phosphatase. We also present several observations that are consistent with NADH inhibition of the phosphatase being mediated through a dihydrolipoyl dehydrogenase-dependent reduction of lipoyl moieties in the E2-X subcomplex. Overall, our data establish that the outer, lipoyl-bearing domains of the oligomeric transacetylase core have an essential role in the function and regulation of the pyruvate dehydrogenase phosphatase.     

A kinetic study of the alpha-keto acid dehydrogenase complexes from pig heart mitochondria.

The kinetic mechanisms of the 2-oxoglutarate and pyruvate dehydrogenease complexes from pig heart mitochondria were studied at pH 7.5 and 25 degrees. A three-site ping-pong mechanism for the actin of both complexes was proposed on the basis of the parallel lines obtained when 1/v was plotted against 2-oxoglutarate or pyruvate concentration for various levels of CoA and a level of NAD+ near its Michaelis constant value. Rate equations were derived from the proposed mechanism. Michaelis constants for the reactants of the 2-oxoglutarate dehydrogenase complex reaction are: 2-oxoglutarate, 0.220 mM; CoA, 0.025 mM; NAD+, 0.050 mM. Those of the pyruvate dehydrogenase complex are: pyruvate, 0.015 mM; CoA, 0.021 mM; NAD+, 0.079 mM. Product inhibition studies showed that succinyl-CoA or acetyl-CoA was competitive with respect to CoA, and NADH was competitive with respect to NAD+ in both overall reactions, and that succinyl-CoA or acetyl-CoA and NADH were uncompetitive with respect to 2-oxoglutarate or pyruvate, respectively. However, noncompetitive (rather than uncompetitive) inhibition patterns were observed for succinyl-CoA or acetyl-CoA versus NAD+ and for NADH versus CoA. These results are consistent with the proposed mechanisms.     

A protective function of superoxide dismutase during respiratory chain activity.

(1) Aerobic incubation of heart muscle submitochondrial particles in phosphate buffer after treatment with NADH causes a progressive and substantial inhibition of the NADH oxidation system. Succinate oxidation remains almost unaffected by NADH treatment. (2) The loss of NADH oxidase activity is due to an inhibition of the respiratory chain-linked NADH dehydrogenase. This inhibition of the enzyme is very similar to that caused by combination of the organic mercurial mersalyl with NADH dehydrogenase. (3) The inhibition of NADH oxidation is largely prevented by compounds that are known to react with superoxide ions (02-.), including superoxide dismutase, cytochrome c, tiron and Mn2+. EDTA also has a protective effect, but a number of other metal chelating agents, and several proteins, including catalase, are without effect. (4) It is concluded that the inhibition of NADH oxidation of NADH oxidation by superoxide ions or by mersalyl is reversible and is therefore not due to the loss of oxidoreduction components from the respiratory chain or to an irreversible change in protein conformation. (6) The function of mitochondrial superxide dismutase is discussed in relation to the key role of NADH dehydrogenase in energy-conserving reactions and the formation of hydrogen peroxide during mitochondrial oxidations.     

Inhibition of pyruvate dehydrogenase complex by moniliformin.

The mechanism for the inhibition of pyruvate dehydrogenase complex from bovine heart by moniliformin was investigated. Thiamin pyrophosphate proved to be necessary for the inhibitory action of moniliformin. The inhibition reaction was shown to be time-dependent and to follow first-order and saturation kinetics. Pyruvate protected the pyruvate dehydrogenase complex against moniliformin inactivation. Extensive dialysis of the moniliformin-inactivated complex only partially reversed inactivation. Moniliformin seems to act by inhibition of the pyruvate dehydrogenase component of the enzyme complex and not by acting on the dihydrolipoamide transacetylase or dehydrogenase components, as shown by monitoring the effect of moniliformin on each component individually. On the basis of these results, a suicide inactivator mechanism for moniliformin on pyruvate dehydrogenase is proposed.