Binding and activation of thiamin diphosphate in acetohydroxyacid synthase

Acetohydroxyacid synthases (AHASs) are biosynthetic thiamin diphosphate- (ThDP) and FAD-dependent enzymes. They are homologous to pyruvate oxidase and other members of a family of ThDP-dependent enzymes which catalyze reactions in which the first step is decarboxylation of a 2-ketoacid. AHAS catalyzes the condensation of the 2-carbon moiety, derived from the decarboxylation of pyruvate, with a second 2-ketoacid, to form acetolactate or acetohydroxybutyrate. A structural model for AHAS isozyme II (AHAS II) from Escherichia coli has been constructed on the basis of its homology with pyruvate oxidase from Lactobacillus plantarum (LpPOX). We describe here experiments which further test the model, and test whether the binding and activation of ThDP in AHAS involve the same structural elements and mechanism identified for homologous enzymes. Interaction of a conserved glutamate with the N1' of the ThDP aminopyrimidine moiety is involved in activation of the cofactor for proton exchange in several ThDP-dependent enzymes. In accord with this, the analogue N3'-pyridyl thiamin diphosphate does not support AHAS activity. Mutagenesis of Glu47, the putative conserved glutamate, decreases the rate of proton exchange at C-2 of bound ThDP by nearly 2 orders of magnitude and decreases the turnover rate for the mutants by about 10-fold. Mutant E47A also has altered substrate specificity, pH dependence, and other changes in properties. Mutagenesis of Asp428, presumed on the basis of the model to be the crucial carboxylate ligand to Mg(2+) in the "ThDP motif", leads to a decrease in the affinity of AHAS II for Mg(2+). While mutant D428N shows ThDP affinity close to that of the wild-type on saturation with Mg(2+), D428E has a decreased affinity for ThDP. These mutations also lead to dependence of the enzyme on K(+). These experiments demonstrate that AHAS binds and activates ThDP in the same way as do pyruvate decarboxylase, transketolase, and other ThDP-dependent enzymes. The biosynthetic activity of AHAS also involves many other factors beyond the binding and deprotonation of ThDP; changes in the ligands to ThDP can have interesting and unexpected effects on the reaction.     

Glutamate 636 of the Escherichia coli pyruvate dehydrogenase-E1 participates in active center communication and behaves as an engineered acetolactate synthase with unusual stereoselectivity

The residue Glu636 is located near the thiamine diphosphate (ThDP) binding site of the Escherichia coli pyruvate dehydrogenase complex E1 subunit (PDHc-E1), and to probe its function two variants, E636A and E636Q were created with specific activities of 2.5 and 26% compared with parental PDHc-E1. According to both fluorescence binding and kinetic assays, the E636A variant behaved according to half-of-the-sites mechanism with respect to ThDP. In contrast, with the E636Q variant a K(d,ThDP) = 4.34 microM and K(m,ThDP) = 11 microM were obtained with behavior more reminiscent of the parental enzyme. The CD spectra of both variants gave evidence for formation of the 1',4'-iminopyrimidine tautomer on binding of phosphonolactylthiamine diphosphate, a stable analog of the substrate-ThDP covalent complex. Rapid formation of optically active (R)-acetolactate by both variants, but not by the parental enzyme, was observed by CD and NMR spectroscopy. The acetolactate configuration produced by the Glu636 variants is opposite that produced by the enzyme acetolactate synthase and the Asp28-substituted variants of yeast pyruvate decarboxylase, suggesting that the active centers of the two sets of enzymes exhibit different facial selectivity (re or si) vis à vis pyruvate. The tryptic peptide map (mass spectral analysis) revealed that the Glu636 substitution changed the mobility of a loop comprising amino acid residues from the ThDP binding fold. Apparently, the residue Glu636 has important functions both in active center communication and in protecting the active center from undesirable "carboligase" side reactions.     

Synthesis with good enantiomeric excess of both enantiomers of alpha-ketols and acetolactates by two thiamin diphosphate-dependent decarboxylases

In addition to the decarboxylation of 2-oxo acids, thiamin diphosphate (ThDP)-dependent decarboxylases/dehydrogenases can also carry out so-called carboligation reactions, where the central ThDP-bound enamine intermediate reacts with electrophilic substrates. For example, the enzyme yeast pyruvate decarboxylase (YPDC, from Saccharomyces cerevisiae) or the E1 subunit of the Escherichia coli pyruvate dehydrogenase complex (PDHc-E1) can produce acetoin and acetolactate, resulting from the reaction of the central thiamin diphosphate-bound enamine with acetaldehyde and pyruvate, respectively. Earlier, we had shown that some active center variants indeed prefer such a carboligase pathway to the usual one [Sergienko, Jordan, Biochemistry 40 (2001) 7369-7381; Nemeria et al., J. Biol. Chem. 280 (2005) 21,473-21,482]. Herein is reported detailed analysis of the stereoselectivity for forming the carboligase products acetoin, acetolactate, and phenylacetylcarbinol by the E477Q and D28A YPDC, and the E636A and E636Q PDHc-E1 active-center variants. Both pyruvate and beta-hydroxypyruvate were used as substrates and the enantiomeric excess was analyzed by a combination of NMR, circular dichroism and chiral-column gas chromatographic methods. Remarkably, the two enzymes produced a high enantiomeric excess of the opposite enantiomer of both acetoin-derived and acetolactate-derived products, strongly suggesting that the facial selectivity for the electrophile in the carboligation is different in the two enzymes. The different stereoselectivities exhibited by the two enzymes could be utilized in the chiral synthesis of important intermediates.     

Structure and mechanism of the ThDP-dependent benzaldehyde lyase from Pseudomonas fluorescens

Pseudomonas fluorescens is able to grow on R-benzoin as the sole carbon and energy source because it harbours the enzyme benzaldehyde lyase that cleaves the acyloin linkage using thiamine diphosphate (ThDP) as a cofactor. In the reverse reaction, this lyase catalyses the carboligation of two aldehydes with high substrate and stereospecificity. The enzyme structure was determined by X-ray diffraction at 2.6 A resolution. A structure-based comparison with other proteins showed that benzaldehyde lyase belongs to a group of closely related ThDP-dependent enzymes. The ThDP cofactors of these enzymes are fixed at their two ends in separate domains, suspending a comparatively mobile thiazolium ring between them. While the residues binding the two ends of ThDP are well conserved, the lining of the active centre pocket around the thiazolium moiety varies greatly within the group. Accounting for the known reaction chemistry, the natural substrate R-benzoin was modelled unambiguously into the active centre of the reported benzaldehyde lyase. Due to its substrate spectrum and stereospecificity, the enzyme extends the synthetic potential for carboligations appreciably.     

Synthesis with good enantiomeric excess of both enantiomers of α-ketols and acetolactates by two thiamin diphosphate-dependent decarboxylases

In addition to the decarboxylation of 2-oxo acids, thiamin diphosphate (ThDP)-dependent decarboxylases/dehydrogenases can also carry out so-called carboligation reactions, where the central ThDP-bound enamine intermediate reacts with electrophilic substrates. For example, the enzyme yeast pyruvate decarboxylase (YPDC, from Saccharomyces cerevisiae) or the E1 subunit of the Escherichia coli pyruvate dehydrogenase complex (PDHc-E1) can produce acetoin and acetolactate, resulting from the reaction of the central thiamin diphosphate-bound enamine with acetaldehyde and pyruvate, respectively. Earlier, we had shown that some active center variants indeed prefer such a carboligase pathway to the usual one [Sergienko, Jordan, Biochemistry 40 (2001) 7369–7381; Nemeria et al., J. Biol. Chem. 280 (2005) 21,473–21,482]. Herein is reported detailed analysis of the stereoselectivity for forming the carboligase products acetoin, acetolactate, and phenylacetylcarbinol by the E477Q and D28A YPDC, and the E636A and E636Q PDHc-E1 active-center variants. Both pyruvate and β-hydroxypyruvate were used as substrates and the enantiomeric excess was analyzed by a combination of NMR, circular dichroism and chiral-column gas chromatographic methods. Remarkably, the two enzymes produced a high enantiomeric excess of the opposite enantiomer of both acetoin-derived and acetolactate-derived products, strongly suggesting that the facial selectivity for the electrophile in the carboligation is different in the two enzymes. The different stereoselectivities exhibited by the two enzymes could be utilized in the chiral synthesis of important intermediates.     

Significant catalytic roles for Glu47 and Gln 110 in all four of the C-C bond-making and -breaking steps of the reactions of acetohydroxyacid synthase II

Acetohydroxy acid synthase (AHAS) is a thiamin diphosphate (ThDP)-dependent enzyme that catalyzes the first common step in the biosynthesis of branched-chain amino acids, condensation of pyruvate with a second 2-ketoacid to form either acetolactate or acetohydroxybutyrate. AHAS isozyme II from Escherichia coli is specific for pyruvate as the first donor substrate but exhibits a 60-fold higher specificity for 2-ketobutyrate (2-KB) over pyruvate as an acceptor substrate. In previous studies relying on steady state and transient kinetics, substrate competition and detailed analysis of the distribution of intermediates in the steady-state, we have identified several residues which confer specificity for the donor and acceptor substrates, respectively. Here, we examine the roles of active site polar residues Glu47, Gln110, Lys159, and His251 for elementary steps of catalysis using similar approaches. While Glu47, the conserved essential glutamate conserved in all ThDP-dependent enzymes whose carboxylate is in H-bonding distance of the ThDP iminopyrimidine N1', is involved as expected in cofactor activation, substrate binding, and product elimination, our studies further suggest a crucial catalytic role for it in the carboligation of the acceptor and the hydroxyethyl-ThDP enamine intermediate. The Glu47-cofactor proton shuttle acts in concert with Gln110 in the carboligation. We suggest that either the transient oxyanion on the acceptor carbonyl is stabilized by H-bonding to the glutamine side chain, or carboligation involves glutamine tautomerization and the elementary reactions of addition and protonation occur in a concerted manner. This is in contrast to the situation in other ThDP enzymes that catalyze a carboligation, such as, e.g., transketolase or benzaldehyde lyase, where histidines act as general acid/base catalysts. Our studies further suggest global catalytic roles for Gln110 and Glu47, which are engaged in all major bond-breaking and bond-making steps. In contrast to earlier suggestions, Lys159 has a minor effect on the kinetics and specificity of AHAS II, far less than does Arg276, previously shown to influence the specificity for a 2-ketoacid as a second substrate. His251 has a large effect on donor substrate binding, but this effect masks any other effects of replacement of His251.     

The molecular origin of the thiamine diphosphate-induced spectral bands of ThDP-dependent enzymes

New and previously published data on a variety of ThDP-dependent enzymes such as baker's yeast transketolase, yeast pyruvate decarboxylase and pyruvate dehydrogenase from pigeon breast muscle, bovine heart, bovine kidney, Neisseria meningitidis and E. coli show their spectral sensitivity to ThDP binding. Although ThDP-induced spectral changes are different for different enzymes, their universal origin is suggested as being caused by the intrinsic absorption of the pyrimidine ring of ThDP, bound in different tautomeric forms with different enzymes. Non-enzymatic models with pyrimidine-like compounds indicate that the specific protein environment of the aminopyrimidine ring of ThDP determines its tautomeric form and therefore the changeable features of the inducible effect. A polar environment causes the prevalence of the aminopyrimidine tautomeric form (short wavelength region is affected). For stabilization of the iminopyrimidine tautomeric form (both short- and long-wavelength regions are affected) two factors appear essential: (i) a nonpolar environment and (ii) a conservative carboxyl group of a specific glutamate residue interacting with the N1' atom of the aminopyrimidine ring. The two types of optical effect depend in a different way upon the pH, in full accordance with the hypothesis tested. From these studies it is concluded that the inducible optical rotation results from interaction of the aminopyrimidine ring with its asymmetric environment and is defined by the protonation state of N1' and the 4'-nitrogen.     

C2-alpha-lactylthiamin diphosphate is an intermediate on the pathway of thiamin diphosphate-dependent pyruvate decarboxylation. Evidence on enzymes and models

Thiamin diphosphate (ThDP)-dependent decarboxylations are usually assumed to proceed by a series of covalent intermediates, the first one being the C2-trimethylthiazolium adduct with pyruvate, C2-alpha-lactylthiamin diphosphate (LThDP). Herein is addressed whether such an intermediate is kinetically competent with the enzymatic turnover numbers. In model studies it is shown that the first-order rate constant for decarboxylation can indeed exceed 50 s(-1) in tetrahydrofuran as solvent, approximately 10(3) times faster than achieved in previous model systems. When racemic LThDP was exposed to the E91D yeast pyruvate decarboxylase variant, or to the E1 subunit of the pyruvate dehydrogenase complex (PDHc-E1) from Escherichia coli, it was partitioned between reversion to pyruvate and decarboxylation. Under steady-state conditions, the rate of these reactions is severely limited by the release of ThDP from the enzyme. Under pre-steady-state conditions, the rate constant for decarboxylation on exposure of LThDP to the E1 subunit of the pyruvate dehydrogenase complex was 0.4 s(-1), still more than a 100-fold slower than the turnover number. Because these experiments include binding, decarboxylation, and oxidation (for detection purposes), this is a lower limit on the rate constant for decarboxylation. The reasons for this slow reaction most likely include a slow conformational change of the free LThDP to the V conformation enforced by the enzyme. Between the results from model studies and those from the two enzymes, it is proposed that LThDP is indeed on the decarboxylation pathway of the two enzymes studied, and once LThDP is bound the protein needs to provide little assistance other than a low polarity environment.     

Identification of mitochondrial thiamin diphosphate carriers from Arabidopsis and maize

It is currently held that thiamin is made in chloroplasts and converted in the cytosol to the active cofactor thiamin diphosphate (ThDP), and that mitochondria and plastids import ThDP. The organellar transporters that mediate ThDP import in plants have not been identified. Comparative genomic analysis indicated that two members of the mitochondrial carrier family (MCF) in Arabidopsis (At5g48970 and At3g21390) and two in maize (GRMZM2G118515 and GRMZM2G124911) are related to the ThDP carriers of animals and Saccharomyces cerevisiae. Expression of each of these plant proteins in a S. cerevisiae ThDP carrier (TPC1) null mutant complemented the growth defect on fermentable carbon sources and restored the level of mitochondrial ThDP and the activity of the mitochondrial ThDP-dependent enzyme acetolactate synthase. The plant proteins were targeted to mitochondria as judged by dual import assays with purified pea mitochondria and chloroplasts, and by microscopic analysis of the subcellular localization of green fluorescent protein fusions in transiently transformed tobacco suspension cells. Both maize genes were shown to be expressed throughout the plant, which is consistent with the known ubiquity of mitochondrial ThDP-dependent enzymes. Collectively, these data establish that plants have mitochondrially located MCF carriers for ThDP, and indicate that these carriers are highly evolutionarily conserved. Our data provide a firm basis to propagate the functional annotation of mitochondrial ThDP carriers to other angiosperm genomes.     

Feasibility of gas/solid carboligation: conversion of benzaldehyde to benzoin using thiamine diphosphate-dependent enzymes

A carboligation was investigated for the first time as an enzymatic gas phase reaction, where benzaldehyde was converted to benzoin using thiamine diphosphate (ThDP)-dependent enzymes, namely benzaldehyde lyase (BAL) and benzoylformate decarboxylase (BFD). The biocatalyst was immobilized per deposition on non-porous support. Some limitations of the gas/solid biocatalysis are discussed based on this carboligation and it is also demonstrated that the solid/gas system is an interesting tool for more volatile products.     

The modular structure of ThDP‐dependent enzymes

Thiamine diphosphate (ThDP)‐dependent enzymes form a diverse protein family which was classified into nine superfamilies. The cofactor ThDP is bound at the interface between two catalytic domains, the PYR and the PP domain. The nine superfamilies were assigned to five different structural architectures. Two superfamilies, the sulfopyruvate decarboxylases and α‐ketoacid dehydrogenases 2, consist of separate PYR and PP domains. The oxidoreductase superfamily is of the intra‐monomer/PYR‐PP type with an N‐terminal PYR and a subsequent PP domain. The active enzymes form homodimers with the ThDP cofactor bound at the interface between a PYR and a PP domain of the same monomer. Decarboxylases are of the inter‐monomer/PYR‐PP type with the cofactor bound between domains from different monomers. 1‐Deoxy‐d ‐xylulose‐5‐phosphate synthases are of the intra‐monomer/PP‐PYR type. The transketolases, α‐ketoglutarate dehydrogenases, and α‐ketoacid dehydrogenases 1 are of the inter‐monomer/PP‐PYR type. For the phosphonopyruvate decarboxylases, definitive assessment of the structural architecture is not possible due to lack of structure information. By applying a structure‐based domain alignment method, sequences of more than 62,000 PYR and PP domains were identified and aligned. Although the sequence similarity of the catalytic domains is low between different superfamilies, seven positions were identified to be highly conserved, including the cofactor binding GDGX_24,27N motif, the cofactor‐activating glutamic acid, and two structurally equivalent glycines in both the PYR and the PP domain. An evolutionary pathway of ThDP‐dependent enzymes is proposed which explains the sequence and structure diversity of this family by three basic evolutionary events: domain recruitment, domain linkage, and structural rearrangement of catalytic domains. Proteins 2014; 82:2523–2537. © 2014 Wiley Periodicals, Inc.     

Investigation of the donor and acceptor range for chiral carboligation catalyzed by the E1 component of the 2-oxoglutarate dehydrogenase complex

The potential of thiamin diphosphate (ThDP)-dependent enzymes to catalyze CC bond forming (carboligase) reactions with high enantiomeric excess has been recognized for many years. Here we report the application of the E1 component of the Escherichia coli 2-oxoglutarate dehydrogenase multienzyme complex in the synthesis of chiral compounds with multiple functional groups in good yield and high enantiomeric excess, by varying both the donor substrate (different 2-oxo acids) and the acceptor substrate (glyoxylate, ethyl glyoxylate and methyl glyoxal). Major findings include the demonstration that the enzyme can accept 2-oxovalerate and 2-oxoisovalerate in addition to its natural substrate 2-oxoglutarate, and that the tested acceptors are also acceptable in the carboligation reaction, thereby very much expanding the repertory of the enzyme in chiral synthesis.     

Tetrahedral intermediates in thiamin diphosphate-dependent decarboxylations exist as a 1',4'-imino tautomeric form of the coenzyme, unlike the michaelis complex or the free coenzyme

Two circular dichroism signals observed on thiamin diphosphate (ThDP)-dependent enzymes, a positive band in the 300-305 nm range and a negative one in the 320-330 nm range, were investigated on yeast pyruvate decarboxylase (YPDC) and on the E1 subunit of the Escherichia coli pyruvate dehydrogenase complex (PDHc-E1). Addition of the tetrahedral ThDP-acetaldehyde adduct, 2-alpha-hydroxyethylThDP, to PDHc-E1 generates the positive band at 300 nm, consistent with the formation of the 1',4'-iminopyrimidine tautomer, as also demonstrated for phosphonolactylthiamin diphosphate, a stable analogue of the tetrahedral ThDP-pyruvate adduct 2-alpha-lactylThDP (Jordan, F. et al. (2003) J. Am. Chem. Soc. 125, 12732-12738). Therefore, we suggest that all tetrahedral ThDP-bound covalent complexes will also prefer this tautomer, and that the 4'-aminopyrimidine of ThDP participates in multiple steps of acid-base catalysis on ThDP enzymes. Studies with YPDC and PDHc-E1, and their active center variants, in conjunction with chemical models, enabled assignment of the negative band at 330 nm to a charge-transfer transition between the 4'-aminopyrimidine tautomer (presumed electron donor) and the thiazolium ring (presumed electron acceptor) of ThDP, with no significant contributions from any amino acid side chain of the proteins. However, in both YPDC and PDHc-E1, the presence of substrate or substrate surrogate was required to enable detection, suggesting that the band at 320-330 nm be used as a reporter for the Michaelis complex, involving the amino tautomer, on both enzymes. As the positive band near 300 nm reports on the 1',4'-imino tautomer of ThDP, methods are now available for kinetic monitoring of both tautomeric forms.     

Adenylate kinase 1 knockout mice have normal thiamine triphosphate levels

Thiamine triphosphate (ThTP) is found at low concentrations in most animal tissues and it may act as a phosphate donor for the phosphorylation of proteins, suggesting a potential role in cell signaling. Two mechanisms have been proposed for the enzymatic synthesis of ThTP. A thiamine diphosphate (ThDP) kinase (ThDP+ATP if ThTP+ADP) has been purified from brewer's yeast and shown to exist in rat liver. However, other data suggest that, at least in skeletal muscle, adenylate kinase 1 (AK1) is responsible for ThTP synthesis. In this study, we show that AK1 knockout mice have normal ThTP levels in skeletal muscle, heart, brain, liver and kidney, demonstrating that AK1 is not responsible for ThTP synthesis in those tissues. We predict that the high ThTP content of particular tissues like the Electrophorus electricus electric organ, or pig and chicken skeletal muscle is more tightly correlated with high ThDP kinase activity or low soluble ThTPase activity than with non-stringent substrate specificity and high activity of adenylate kinase.     

X-ray crystallographic snapshots of reaction intermediates in pyruvate oxidase and transketolase illustrate common themes in thiamin catalysis

Thiamin diphosphate (ThDP)-dependent enzymes play pivotal roles in intermediary metabolism of virtually all organisms. Although extensive mechanistic work on cofactor models and various enzymes has served as a guide to understand general principles of catalysis, high-resolution structural information of reaction intermediates along the catalytic pathway was scarcely available until recently. Here, we review cryocrystallographic studies on the prototypical ThDP enzymes pyruvate oxidase and transketolase, which provided exciting insights into the chemical nature and structural features of several key intermediates and into the stereochemical course of substrate processing. The structures revealed a conserved (S)-configuration at the C2alpha stereocenter of the initially formed tetrahedral intermediate in the different enzymes with the scissile C2alpha–C2beta bond being directed perpendicular to the aromatic ring plane of the thiazolium portion of ThDP confirming the proposed maximum overlap mechanism. Elimination of the respective leaving groups (carbon dioxide, sugar phosphates) appears to be driven – amongst other factors such as stereoelectronic control – by strain relief as the C2–C2alpha bond, which connects C2 of ThDP with the carbonyl of the substrate, substantially deviates from planarity and relaxes to an in-plane conformation only after bond fission to give an enamine-type intermediate with considerable delocalization of the free electron pair onto the thiazolium ring. Except for the apparent flexibility of the cofactor itself, no major structural rearrangements are detectable indicating that the enzyme active centers are poised for catalysis. The structures also provide the basis for understanding the origins of substrate and reaction specificity.     

Crystal Structures of Phosphoketolase: THIAMINE DIPHOSPHATE-DEPENDENT DEHYDRATION MECHANISM*

Thiamine diphosphate (ThDP)-dependent enzymes are ubiquitously present in all organisms and catalyze essential reactions in various metabolic pathways. ThDP-dependent phosphoketolase plays key roles in the central metabolism of heterofermentative bacteria and in the pentose catabolism of various microbes. In particular, bifidobacteria, representatives of beneficial commensal bacteria, have an effective glycolytic pathway called bifid shunt in which 2.5 mol of ATP are produced per glucose. Phosphoketolase catalyzes two steps in the bifid shunt because of its dual-substrate specificity; they are phosphorolytic cleavage of fructose 6-phosphate or xylulose 5-phosphate to produce aldose phosphate, acetyl phosphate, and H₂O. The phosphoketolase reaction is different from other well studied ThDP-dependent enzymes because it involves a dehydration step. Although phosphoketolase was discovered more than 50 years ago, its three-dimensional structure remains unclear. In this study we report the crystal structures of xylulose 5-phosphate/fructose 6-phosphate phosphoketolase from Bifidobacterium breve. The structures of the two intermediates before and after dehydration (α,β-dihydroxyethyl ThDP and 2-acetyl-ThDP) and complex with inorganic phosphate give an insight into the mechanism of each step of the enzymatic reaction.     

Frontiers in the enzymology of thiamin diphosphate-dependent enzymes

Enzymes that use thiamin diphosphate (ThDP), the biologically active derivative of vitamin B1, as a cofactor play important roles in cellular metabolism in all domains of life. The analysis of ThDP enzymes in the past decades have provided a general framework for our understanding of enzyme catalysis of this protein family. In this review, we will discuss recent advances in the field that include the observation of “unusual” reactions and reaction intermediates that highlight the chemical versatility of the thiamin cofactor. Further topics cover the structural basis of cooperativity of ThDP enzymes, novel insights into the mechanism and structure of selected enzymes, and the discovery of “superassemblies” as reported, for example, acetohydroxy acid synthase. Finally, we summarize recent findings in the structural organisation and mode of action of 2-keto acid dehydrogenase multienzyme complexes and discuss future directions of this exciting research field.     

The role of cysteine 160 in thiamine diphosphate binding of the Calvin-Benson-Bassham cycle transketolase of Rhodobacter sphaeroides

The transketolase gene (cbbT) that encodes the Calvin-Benson-Bassham pathway transketolase (CbbT) of Rhodobacter sphaeroides was overexpressed in Escherichia coli and the recombinant protein purified to homogeneity. Like other transketolases, R. sphaeroides CbbT was found to be inactivated in the presence of oxygen. At its optimal pH of 7.8, CbbT displays a specific activity of 37 U/mg, a KR5P of 949 microM, a KXu5P of 11 microM, and a KThDP of 1.8 microM. Cysteine 160, equivalent to Cys159 of the yeast enzyme, is found within the active site and is loosely conserved amongst several sources of transketolase. To investigate the role of cysteine 160 found in the active site of R. sphaeroides CbbT, this residue was targeted for mutagenesis. Cys160 was changed to alanine, serine, aspartate, and glutamate. To compare the effect of these mutations on ThDP binding, spectral techniques were employed in addition to analysis by enzymatic activity. Fluorescence quenching was used to measure both equilibrium binding constants as well as first order rates of binding. The results of these studies indicated that Cys160 played an important and substantial role in cofactor binding, revealing the importance of this loosely conserved residue. In addition, the Cys160 mutants did not appear to alter oxygen-mediated inactivation.     

Cellular localization of α-ketoglutarate: Glyoxylate carboligase in rat tissues

α-Ketoglutarate : glyoxylate carboligase activity has been reported by other laboratories to be present in mitochondria and in the cytosol of mammalian tissues; the mitochondrial activity is associated with the α-ketoglutarate decarboxylase moiety of the α-ketoglutarate dehydrogenase complex. The cellular distribution of the carboligase has been re-examined here using marker enzymes of known localization in order to monitor the composition of subcellular fractions prepared by differential centrifugation. Carboligase activity paralleled the activity of the mitochondrial matrix enzyme citrate synthase in subcellular fractions prepared from rat liver, heart and brain as well as from rabbit liver. Whole rat liver mitochondria upon lysis released both carboligase and citrate synthase. The activity patterns of several other extramitochondrial marker enzymes differed significantly from that of carboligase in rat liver. In addition, the distribution pattern of carboligase was similar to that of α-ketoglutarate decarboxylase and of α-ketoglutarate dehydrogenase complex.The data indicate that α-ketoglutarate : gloxylate carboligase activity is located exclusively within the mitochondria of the rat and rabbit tissues investigated. There is no evidence for a cytosolic form of the enzyme. Thus the report from another laboratory that the molecular etiology of the human genetic disorder hyperoxaluria type I is a deficiency of cytosolic carboligase must be questioned.     

Steric and electronic properties of the cofactor's amino group control the lifetime of the central carbanion/enamine intermediate in transketolase

Transketolase (TK), a thiamin diphosphate (ThDP) dependent enzyme, catalyzes the reversible transfer of a two-carbon unit from keto- to aldo-substrates. Dihydroxyethylthiamin diphosphate (DHEThDP), formed as a result of cleavage of the donor substrate, serves as an intermediate of the TK reaction. TK from the yeast Saccharomyces cerevisiae is unique among thiamin enzymes displaying enzymatic activity after reconstitution with a methylated analogue of the native cofactor, 4′-methylamino-ThDP. The reconstitution of the apoenzyme with both ThDP and the methylated analogue can be analyzed by near UV circular dichroism. It was demonstrated that in the native holoenzyme and in the complex of TK with 4′-methylamino-ThDP the formation of the dihydroxyethyl-based carbanion/enamine took place with comparable rate constants, whereas the protonation of the reactive species was much faster in the complex with the analogue. The enzymatic activity of the enzyme reconstituted with 4′-methylamino-ThDP was 10fold higher in the ferricyanide assay. We suggest that a methylation of the 4′-amino group of ThDP impairs the resonance stabilization of the carbanion/enamine intermediate both sterically and electronically, thus allowing either a faster protonation or oxidation reaction by ferricyanide. The formation of the optically active DHE-4′-methylamino-ThDP was monitored by near UV circular dichroism spectra and corroborated by ¹H NMR analysis. The protonated form of the intermediate DHE-4′-methylamino-ThDP was released from the active sites of TK and accumulated in the medium on preparative scale.