Pyruvate decarboxylase from Kluyveromyces lactis. An enzyme with an extraordinary substrate activation behaviour.

Pyruvate decarboxylase (EC 4.1.1.1) was isolated and purified from the yeast Kluyveromyces lactis. The properties of this enzyme relating to the native oligomeric state, the subunit size, the nucleotide sequence of the coding gene(s), the catalytic activity, and protein fluorescence as well as circular dichroism are very similar to those of the well characterized pyruvate decarboxylase species from yeast. Remarkable differences were found in the substrate activation behaviour of the two pyruvate decarboxylases using three independent methods: steady-state kinetics, stopped-flow measurements, and kinetic dilution experiments. The dependence of the observed activation rate constant on the substrate concentration of pyruvate decarboxylase from K. lactis showed a minimum at a pyruvate concentration of 1.5 mm. According to the mechanism of substrate activation suggested this local minimum occurs due to the big ratio of the dissociation constants for the binding of the first (regulatory) and the second (catalytic) substrate molecule. The microscopic rate constants of the substrate activation could be determined by a refined fit procedure. The influence of the artificial activator pyruvamide on the activation of the enzyme was studied.     

Production of glucoamylase in pyruvate decarboxylase deletion mutants of the yeast Kluyveromyces lactis

We have developed a novel Escherichia coli cell surface display system by employing PgsA as an anchoring motif. In our display system, C-terminal fusion to PgsA anchor protein from Bacillus subtilis was used. The enzymes selected for display were α-amylase (AmyA) from Streptococcus bovis 148 and lipase B (CALB) from Candida antarctica. The molecular mass values of AmyA and CALB are approximately 77 and 34 kDa, respectively. The enzymes were displayed on the surface as a fusion protein with a FLAG peptide tag at the C terminus. Both the PgsA-AmyA-FLAG and PgsA-CALB-FLAG fusion proteins were shown to be displayed by immunofluorescence labeling using anti-FLAG antibody. The displayed enzymes were active forms, and AmyA and CALB activities reached 990 U/g (dry cell weight) and 4.6 U/g (dry cell weight), respectively. AmyA-displaying E. coli cells grew utilizing cornstarch as the sole carbon source, while CALB-displaying E. coli cells catalyzed enantioselective transesterification, indicating that they are effective whole-cell biocatalysts. Since a target enzyme with a size of 77 kDa and an industrially useful lipase have been successfully displayed on the cell surface of E. coli for the first time, PgsA protein is probably a useful anchoring motif to display various enzymes.     

RAG3 gene and transcriptional regulation of the pyruvate decarboxylase gene in Kluyveromyces lactis

The RAG3 gene has been cloned from a Kluyveromyces lactis genomic library by complementation of the rag3 mutation, which shows impaired fermentative growth on glucose in the presence of respiratory inhibitors. From the nucleotide sequence of the cloned DNA, which contained an open reading frame of 765 codons, the predicted protein is 49.5% identical to the Pdc2 protein of Saccharomyces cerevisiae, a regulator of pyruvate decarboxylase in this yeast. Measurement of the pyruvate decarboxylase activity in the original rag3–1 mutant and in the null mutant confirmed that the RAG3 gene is involved in pyruvate decarboxylase synthesis in K. lactis. The effect is exerted at the mRNA level of the pyruvate decarboxylase structural gene KIPDCA. Despite analogies between the RAG3 gene of K. lactis and the PDC2 gene of S. cerevisiae, these genes were unable to reciprocally complement.     

Cofactor activation and substrate binding in pyruvate decarboxylase. Insights into the reaction mechanism from molecular dynamics simulations

We have performed long-term molecular dynamics simulations of pyruvate decarboxylase from Zymomonas mobilis. Nine structures were modeled to investigate mechanistic questions related to binding of the cofactor, thiamin diphosphate (ThDP), and the substrate in the active site. The simulations reveal that the proposed three ThDP-tautomers all can bind in the active site and indicate that the equilibrium is shifted toward 4'-aminopyrimidine ThDP in the absence of substrate. 4'-Aminopyrimidinium ThDP is found to be a likely intermediate in the equilibrium. Mutations of important active site residues, Glu473Ala and Glu50Ala, were modeled to further elucidate their catalytic role. Formation of the catalytic important ylide by deprotonation of ThDP(C2) is investigated. Only the less favored tautomer, 1',4'-iminopyrimidine ThDP (imino-ThDP), could be deprotonated. The two other tautomers of ThDP could not be activated at the C2-position, thus, explaining the mechanistic importance of the less stable imino-ThDP. Finally, binding of pyruvate in the active site with the cofactor modeled as the nucleophilic ylide (ylide-ThDP) is studied. The carbonyl group of the substrate forms a hydrogen bond to Tyr290(OH). No hydrogen bond could be identified between ThDP(N4') and the substrate. The geometry of the substrate binding is well-suited for a nucleophilic attack by ylide-ThDP(C2). We propose that a proton relay from His113 via Asp27 and Tyr290 to the carbonyl oxygen atom of the substrate may be involved in the mechanism.     

Crystal structure and substrate binding modeling of the uroporphyrinogen-III decarboxylase from Nicotiana tabacum. Implications for the catalytic mechanism

The enzymatic catalysis of many biological processes of life is supported by the presence of cofactors and prosthetic groups originating from the common tetrapyrrole precursor uroporphyrinogen-III. Uroporphyrinogen-III decarboxylase catalyzes its conversion into coproporphyrinogen-III, leading in plants to chlorophyll and heme biosynthesis. Here we report the first crystal structure of a plant (Nicotiana tabacum) uroporphyrinogen-III decarboxylase, together with the molecular modeling of substrate binding in tobacco and human enzymes. Its structural comparison with the homologous human protein reveals a similar catalytic cleft with six invariant polar residues, Arg(32), Arg(36), Asp(82), Ser(214) (Thr in Escherichia coli), Tyr(159), and His(329) (tobacco numbering). The functional relationships obtained from the structural and modeling analyses of both enzymes allowed the proposal for a refined catalytic mechanism. Asp(82) and Tyr(159) seem to be the catalytic functional groups, whereas the other residues may serve in substrate recognition and binding, with Arg(32) steering its insertion. The crystallographic dimer appears to represent the protein dimer under physiological conditions. The dimeric arrangement offers a plausible mechanism at least for the first two (out of four) decarboxylation steps.     

The crystal structure of phenylpyruvate decarboxylase from Azospirillum brasilense at 1.5 A resolution. Implications for its catalytic and regulatory mechanism

Phenylpyruvate decarboxylase (PPDC) of Azospirillum brasilense, involved in the biosynthesis of the plant hormone indole-3-acetic acid and the antimicrobial compound phenylacetic acid, is a thiamine diphosphate-dependent enzyme that catalyses the nonoxidative decarboxylation of indole- and phenylpyruvate. Analogous to yeast pyruvate decarboxylases, PPDC is subject to allosteric substrate activation, showing sigmoidal v versus [S] plots. The present paper reports the crystal structure of this enzyme determined at 1.5 A resolution. The subunit architecture of PPDC is characteristic for other members of the pyruvate oxidase family, with each subunit consisting of three domains with an open alpha/beta topology. An active site loop, bearing the catalytic residues His112 and His113, could not be modelled due to flexibility. The biological tetramer is best described as an asymmetric dimer of dimers. A cysteine residue that has been suggested as the site for regulatory substrate binding in yeast pyruvate decarboxylase is not conserved, requiring a different mechanism for allosteric substrate activation in PPDC. Only minor changes occur in the interactions with the cofactors, thiamine diphosphate and Mg2+, compared to pyruvate decarboxylase. A greater diversity is observed in the substrate binding pocket accounting for the difference in substrate specificity. Moreover, a catalytically important glutamate residue conserved in nearly all decarboxylases is replaced by a leucine in PPDC. The consequences of these differences in terms of the catalytic and regulatory mechanism of PPDC are discussed.     

The structural basis of substrate activation in yeast pyruvate decarboxylase. A crystallographic and kinetic study.

The crystal structure of the complex of the thiamine diphosphate dependent tetrameric enzyme pyruvate decarboxylase (PDC) from brewer's yeast strain with the activator pyruvamide has been determined to 2.4 A resolution. The asymmetric unit of the crystal contains two subunits, and the tetrameric molecule is generated by crystallographic symmetry. Structure analysis revealed conformational nonequivalence of the active sites. One of the two active sites in the asymmetric unit was found in an open conformation, with two active site loop regions (residues 104-113 and 290-304) disordered. In the other subunit, these loop regions are well-ordered and shield the active site from the bulk solution. In the closed enzyme subunit, one molecule of pyruvamide is bound in the active site channel, and is located in the vicinity of the thiazolium ring of the cofactor. A second pyruvamide binding site was found at the interface between the Pyr and the R domains of the subunit in the closed conformation, about 10 A away from residue C221. This second pyruvamide molecule might function in stabilizing the unique orientation of the R domain in this subunit which in turn is important for dimer-dimer interactions in the activated tetramer. No difference electron density in the close vicinity of the side chain of residue C221 was found, indicating that this residue does not form a covalent adduct with an activator molecule. Kinetic experiments showed that substrate activation was not affected by oxidation of cysteine residues and therefore does not seem to be dependent on intact thiol groups in the enzyme. The results suggest that a disorder-order transition of two active-site loop regions is a key event in the activation process triggered by the activator pyruvamide and that covalent modification of C221 is not required for this transition to occur. Based on these findings, a possible mechanism for the activation of PDC by its substrate, pyruvate, is proposed.     

Purification of an alpha-N-acetylglucosaminyltransferase from the yeast Kluyveromyces lactis and a study of mutants defective in this enzyme activity

An enzyme activity in Kluyveromyces lactis that catalyzes the transfer of N-acetylglucosamine from uridine diphosphate N-acetylglucosamine to alpha Man(1 leads to 3) alpha Man ( 1 leads to 2) alpha Man (1 leads to 2)Man to yield alpha Man(1 leads to 3) [alpha GlcNAc(1 leads to 2)] alpha Man(1 leads to 2) alpha Man (1 leads to 2)Man, a mannoprotein side-chain unit, has been solubilized by Triton X-100 and purified 18000-fold by a combination of ion-exchange chromatography, gel filtration, hydrophobic chromatography, and adsorption to a lectin column. The enzyme activity from a K. lactis mutant (mnn2-2) that made mannoprotein lacking N-acetylglucosamine in its side chains, but that possessed a normal level of transferase activity in cell extracts, was purified and compared with the enzyme from the wild-type strain. Both transferase activities are integral membrane proteins found in particles associated with endoplasmic reticulum. The two purified enzymes had the same apparent size, heat stability, Mn2+ requirement, and Km for donor and acceptor and a similar Vmax. Wild-type and mutant cells had similar pool sizes of sugar nucleotide donor, and they incorporated labeled N-acetylglucosamine into chitin at similar rates. No evidence was obtained for an inactive enzyme precursor in mutant cells that was activated upon breaking the cells, nor did the mutant cells contain a transferase inhibitor or a hexosaminidase that could remove the sugar from the mannoprotein during processing and secretion. The mnn2-2 locus appears to be allelic with a second mutant, mnn2-1, that has the same phenotype but that lacks transferase activity in cell extracts. This suggests that the two mutations affect the structural gene for the transferase, and we conclude that the mnn2-2 mutant could contain an altered enzyme that fails to function because it is improperly localized or oriented in the membrane.     

New model for activation of yeast pyruvate decarboxylase by substrate consistent with the alternating sites mechanism: demonstration of the existence of two active forms of the enzyme

Pyruvate decarboxylase from yeast (YPDC, EC 4.1.1.1) exhibits a marked lag phase in the progress curves of product (acetaldehyde) formation. The currently accepted kinetic model for YPDC predicts that, only upon binding of substrate in a regulatory site, a slow activation step converts inactive enzyme into the active form. This allosteric behavior gives rise to sigmoidal steady-state kinetics. The E477Q active site variant of YPDC exhibited hyperbolic initial rate curves at low pH, not consistent with the model. Progress curves of product formation by this variant were S-shaped, consistent with the presence of three interconverting conformations with distinct steady-state rates. Surprisingly, wild-type YPDC at pH < or =5.0 also possessed S-shaped progress curves, with the conformation corresponding to the middle steady state being the most active one. Reexamination of the activation by substrate of wild-type YPDC in the pH range of 4.5-6.5 revealed two characteristic transitions at all pH values. The values of steady-state rates are functions of both pH and substrate concentration, affecting whether the progress curve appears "normal" or S-shaped with an inflection point. The substrate dependence of the apparent rate constants suggested that the first transition corresponded to substrate binding in an active site and a subsequent step responsible for conversion to an asymmetric conformation. Consequently, the second enzyme state may report on "unregulated" enzyme, since the regulatory site does not participate in its generation. This enzyme state utilizes the alternating sites mechanism, resulting in the hyperbolic substrate dependence of initial rate. The second transition corresponds to binding a substrate molecule in the regulatory site and subsequent minor conformational adjustments. The third enzyme state corresponds to the allosterically regulated conformation, previously referred to as activated enzyme. The pH dependence of the Hill coefficient suggests a random binding of pyruvate in a regulatory and an active site of wild-type YPDC. Addition of pyruvamide or acetaldehyde to YPDC results in the appearance of additional conformations of the enzyme.     

Effects of substitution of tryptophan 412 in the substrate activation pathway of yeast pyruvate decarboxylase.

Oligonucleotide-directed site-specific mutagenesis was carried out on pyruvate decarboxylase (EC 4.1.1.1) from Saccharomyces cerevisiae at W412, located on the putative substrate activation pathway and linking E91 on the alpha domain with W412 on the gamma domain of the enzyme. While C221 on the beta domain is the residue at which substrate activation is triggered [Baburina, I., et al. (1994) Biochemistry 33, 5630-5635; Baburina, I., et al. (1996) Biochemistry 35, 10249-10255], that information, via the substrate bound at C221, is transmitted to H92 on the alpha domain, across the domain divide from C221 [Baburina, I., et al. (1998) Biochemistry 37, 1235-1244; Baburina, I., et al. (1998) Biochemistry 37, 1245-1255], thence to E91 on the alpha domain [Li, H., and Jordan, F. (1999) Biochemistry 38, 9992-10003], and then on to W412 on the gamma domain and to the active site thiamin diphosphate located at the interface of the alpha and gamma domains [Arjunan, D., et al. (1996) J. Mol. Biol. 256, 590-600]. Substitution at W412 with F and A was carried out, resulting in active enzymes with specific activities about 4- and 10-fold lower than that of the wild-type enzyme. Even though W412 interacts with E91 and H115 via a main chain hydrogen bond donor and acceptor, respectively, there is clear evidence for the importance of the indole side chain of W412 from a variety of experiments: thermostability, fluorescence quenching, and the binding constants of the thiamin diphosphate, and circular dichroism spectroscopy, in addition to conventional steady-state kinetic measurements. While the substrate activation is still prominent in the W412F variant, its level is very much reduced in the W412A variant, signaling that the size of the side chain is also important in positioning the amino acids surrounding the active center to achieve substrate activation. The fluorescence studies demonstrate that W412 is a relatively minor contributor to the well-documented fluorescence of apopyruvate decarboxylase in its native state. The information about the W412 variants provides strong additional support for the putative substrate activation pathway from C221 --> H92 --> E91 --> W412 --> G413 --> thiamin diphosphate. The accumulating evidence for the central role of the beta domain in stabilizing the overall structure is summarized.     

Purification and primary structure of pyruvate decarboxylase from Zymomonas mobilis.

Pyruvate decarboxylase (E.C. 4.1.1.1), the key enzyme in the glycolytic pathway to ethanol, was isolated in gram amounts from Zymomonas mobilis for structural studies. The primary structure was determined by automated Edman degradation and compared with that deduced from the DNA sequence of the structural gene, previously published by two groups (A. D. Neale, R. K. Scopes, R. E. H. Wettenhall, and N. J. Hoogenraad, 1987, Nucleic Acids Res. 15, 1753-1761; M. Reynen, and H. Sahm, 1988, J. Bacteriol. 170, 3310-3313). The peptide data differ from the published DNA sequences, which also deviate from each other. Crystals diffracting to about 0.3 nm resolution have been obtained by the hanging drop vapor diffusion method. The space group was identified as P4(1)22 or its enantiomorphs containing presumably one tetramer per asymmetric unit.     

Preliminary crystallographic data for the thiamin diphosphate-dependent enzyme pyruvate decarboxylase from brewers' yeast

Single crystals of the thiamin diphosphate (the vitamin B1 coenzyme)-dependent enzyme pyruvate decarboxylase (EC 4.1.1.1) from brewers' yeast have been grown using polyethylene glycol as a precipitating agent. Crystals of the homotetrameric version alpha 4 of the holoenzyme are triclinic, space group P1, with cell constants a = 81.0, b = 82.4, c = 116.6 A, alpha = 69.5 beta = 72.6, gamma = 62.4 degrees. The crystals are reasonably stable in a rotating anode x-ray beam and diffract to at least 2.5 A resolution. The Vm value of 2.55 A/dalton is consistent with a unit cell containing four subunits with mass of approximately 60 kDa each. Rotation function results with native data indicate strong non-crystallographic 222 symmetry relating the four identical subunits, thus density averaging methods are likely to play a role in the structure determination.     

Molecular mechanism of allosteric substrate activation in a thiamine diphosphate-dependent decarboxylase

Thiamine diphosphate-dependent enzymes are involved in a wide variety of metabolic pathways. The molecular mechanism behind active site communication and substrate activation, observed in some of these enzymes, has since long been an area of debate. Here, we report the crystal structures of a phenylpyruvate decarboxylase in complex with its substrates and a covalent reaction intermediate analogue. These structures reveal the regulatory site and unveil the mechanism of allosteric substrate activation. This signal transduction relies on quaternary structure reorganizations, domain rotations, and a pathway of local conformational changes that are relayed from the regulatory site to the active site. The current findings thus uncover the molecular mechanism by which the binding of a substrate in the regulatory site is linked to the mounting of the catalytic machinery in the active site in this thiamine diphosphate-dependent enzyme.     

Irreversible inactivation of pyruvate decarboxylase in the presence of substrate and an oxidant. An example of paracatalytic enzyme inactivation.

Pyruvate decarboxylase from yeast is progressively inactivated in the presence of pyruvate and an extrinsic oxidant such as 2,6-dichloroindophenol or hexacyanoferrate(III). The inactivation is linked to the oxidation of the hydroxyethylthiamine diphosphate intermediate to acetate. Removal of low-molecular compounds by gel filtration does not reactivate the enzyme. The rate of inactivation obeys saturation kinetics with respect to substrate concentration and is independent of enzyme concentration. In analogy to the paracatalytic inactivation of other enzymes forming oxidizable carbanion intermediates [Christen, P. (1977) Methods Enzymol.46, 48--54], the oxidation of enzyme-bound hydroxyethylthiamine diphosphate is thought to generate a transiently reactive intermediate which, without being released from the enzyme, covalently modifies a group at or near the active site. Reconstitution experiments indicate that the protein rather than the coenzyme moiety is modified.     

Molecular markers for differentiation between the closely related dairy yeast Kluyveromyces lactis var. lactis and wild Kluyveromyces lactis strains from the European "krassilnikovii" population

A comparative molecular genetic study of 37 Kluyveromyces strains of different origin has made it possible to find molecular markers that can differentiate between the dairy yeast Kluyveromyces lactis var. lactis and the genetically close wild Kl. lactis strains from the European "krassilnikovii" population, which are unable to ferment lactose. A restriction fragment length polymorphism analysis of the IGS2 region of the strains' rDNA reveals two different AluI profiles, one of which corresponds to Kl. lactis var. lactis while the other corresponds to yeasts from the "krassilnikovii" population. The AluI restriction profile of the IGS2 region of the rDNA also makes it possible to differentiate between the physiologically similar species Kl. marxianus and Kl. lactis. The origin of clinical Kl. lactis var. lactis isolates is discussed.