Project description:Flavocytochrome b2 from Saccharomyces cerevisiae is an l-lactate dehydrogenase which exhibits only barely detectable activity levels towards another 2-hydroxyacid, l-mandelate. Using protein engineering methods we have altered the active site of flavocytochrome b2 and successfully introduced substantial mandelate dehydrogenase activity into the enzyme. Changes to Ala-198 and Leu-230 have significant effects on the ability of the enzyme to utilize l-mandelate as a substrate. The double mutation of Ala-198-->Gly and Leu-230-->Ala results in an enzyme with a kcat value (25 degrees C) with L-mandelate of 8.5 s-1, which represents an increase of greater than 400-fold over the wild-type enzyme. Perhaps more significantly, the mutant enzyme has a catalytic efficiency (as judged by kcat/Km values) that is 6-fold higher with l-mandelate than it is with L-lactate. Closer examination of the X-ray structure of S. cerevisiae flavocytochrome b2 led us to conclude that one of the haem propionate groups might interfere with the binding of L-mandelate at the active site of the enzyme. To test this idea, the activity with l-mandelate of the independently expressed flavodehydrogenase domain (FDH), was examined and found to be higher than that seen with the wild-type enzyme. In addition, the double mutation of Ala-198-->Gly and Leu-230-->Ala introduced into FDH produced the greatest mandelate dehydrogenase activity increase, with a kcat value more than 700-fold greater than that seen with the wild-type holoenzyme. In addition, the enzyme efficiency (kcat/Km) of this mutant enzyme was more than 20-fold greater with L-mandelate than with l-lactate. We have therefore succeeded in constructing an enzyme which is now a better mandelate dehydrogenase than a lactate dehydrogenase.

Project description:L(+)-Mandelate dehydrogenase was purified to homogeneity from the yeast Rhodotorula graminis KGX 39 by a combination of (NH4)2SO4 fractionation, ion-exchange and hydrophobic-interaction chromatography and gel filtration. The amino-acid composition and the N-terminal sequence of the enzyme were determined. Comprehensive details of the sequence determinations have been deposited as Supplementary Publication SUP 50172 (4 pages) at the British Library Document Supply Centre, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1993) 289, 9. The enzyme is a tetramer as judged by comparison of its subunit M(r) value of 59,100 and native M(r) of 239,900, estimated by SDS/PAGE and gel filtration respectively. There is one molecule of haem and approx. one molecule of non-covalently bound FMN per subunit. 2,6-Dichloroindophenol, cytochrome c and ferricyanide can all serve as electron acceptors. L(+)-Mandelate dehydrogenase is stereospecific for its substrate. D(-)-Mandelate and L(+)-hexahydromandelate are competitive inhibitors. The enzyme has maximum activity at pH 7.9 and it has a pI value of 4.4. HgCl2 and 4-chloromercuribenzoate are potent inhibitors, but there is no evidence that the enzyme is subject to feedback inhibition by potential metabolic effectors. The evidence suggests that L(+)-mandelate dehydrogenase from R. graminis is a flavocytochrome b which is very similar to, and probably (at least so far as the haem domain is concerned) homologous with, certain well-characterized yeast L(+)-lactate dehydrogenases, and that the chief difference between them is their mutually exclusive substrate specificities.

Project description:D(--)-Mandelate dehydrogenase, the first enzyme of the mandelate pathway in the yeast Rhodotorula graminis, catalyses the NAD(+)-dependent oxidation of D(--)-mandelate to phenylglyoxylate. D(--)-2-(Bromoethanoyloxy)-2-phenylethanoic acid ['D(--)-bromoacetylmandelic acid'], an analogue of the natural substrate, was synthesized as a probe for reactive and accessible nucleophilic groups within the active site of the enzyme. D(--)-Mandelate dehydrogenase was inactivated by D(--)-bromoacetylmandelate in a psuedo-first-order process. D(--)-Mandelate protected against inactivation, suggesting that the residue that reacts with the inhibitor is located at or near the active site. Complete inactivation of the enzyme resulted in the incorporation of approx. 1 mol of label/mol of enzyme subunit. D(--)-Mandelate dehydrogenase that had been inactivated with 14C-labelled D(--)-bromoacetylmandelate was digested with trypsin; there was substantial incorporation of 14C into two tryptic-digest peptides, and this was lowered in the presence of substrate. One of the tryptic peptides had the sequence Val-Xaa-Leu-Glu-Ile-Gly-Lys, with the residue at the second position being the site of radiolabel incorporation. The complete sequence of the second peptide was not determined, but it was probably an N-terminally extended version of the first peptide. High-voltage electrophoresis of the products of hydrolysis of modified protein showed that the major peak of radioactivity co-migrated with N tau-carboxymethylhistidine, indicating that a histidine residue at the active site of the enzyme is the most likely nucleophile with which D(--)-bromoacetylmandelate reacts. D(--)-Mandelate dehydrogenase was incubated with phenylglyoxylate and either (4S)-[4-3H]NADH or (4R)-[4-3H]NADH and then the resulting D(--)-mandelate and NAD+ were isolated. The enzyme transferred the pro-R-hydrogen atom from NADH during the reduction of phenylglyoxylate. The results are discussed with particular reference to the possibility that this enzyme evolved by the recruitment of a 2-hydroxy acid dehydrogenase from another metabolic pathway.

Project description:A detailed kinetic analysis of the oxidation of mono-substituted mandelates catalysed by L-(+)-mandelate dehydrogenase (L-MDH) from Rhodotorula graminis has been carried out to elucidate the role of the substrate in the catalytic mechanism. Values of Km and kcat. (25 degrees C, pH 7.5) were determined for mandelate and eight substrate analogues. Values of the activation parameters, delta H++ and delta S++ (determined over the range 5-37 degrees C), for mandelate and all substrate analogues were compensatory resulting in similar low values for free energies of activation delta G++ (approx. 60 kJ.mol-1 at 298.15 K) in all cases. A kinetic-isotope-effect value of 1.1 +/- 0.1 was observed using D,L-[2-2H]mandelate as substrate and was invariant over the temperature range studied. The logarithm of kcat. values for the enzymic oxidation of mandelate and all substrate analogues (except 4-hydroxymandelate) showed good correlation with Taft's dual substituent constant omega (where omega = omega I + 0.64 omega +R) and gave a positive reaction constant value, rho, of 0.36 +/- 0.07. This linear free-energy relationship was verified by analysing the data using isokinetic methods. These findings support the hypothesis that the enzyme-catalysed reaction proceeds via the same transition state for each substrate and indicates that this transition state is relatively nonpolar but has an electron-rich centre at the alpha-carbon position.

Project description:Flavocytochrome b2 from Saccharomyces cerevisiae acts physiologically as an L-lactate dehydrogenase. Although L-lactate is its primary substrate, the enzyme is also able to utilize a variety of other (S)-2-hydroxy acids. Structural studies and sequence comparisons with several related flavoenzymes have identified the key active-site residues required for catalysis. However, the residues Ala-198 and Leu-230, found in the X-ray-crystal structure to be in contact with the substrate methyl group, are not well conserved. We propose that the interaction between these residues and a prospective substrate molecule has a significant effect on the substrate specificity of the enzyme. In an attempt to modify the specificity in favour of larger substrates, three mutant enzymes have been produced: A198G, L230A and the double mutant A198G/L230A. As a means of quantifying the overall kinetic effect of a mutation, substrate-specificity profiles were produced from steady-state experiments with (S)-2-hydroxy acids of increasing chain length, through which the catalytic efficiency of each mutant enzyme with each substrate could be compared with the corresponding wild-type efficiency. The Ala-198-->Gly mutation had little influence on substrate specificity and caused a general decrease in enzyme efficiency. However, the Leu-230-->Ala mutation caused the selectivity for 2-hydroxyoctanoate over lactate to increase by a factor of 80.

Project description:The l-mandelate dehydrogenase (L-MDH) from the yeast Rhodotorula graminis is a mitochondrial flavocytochrome b2 which catalyses the oxidation of mandelate to phenylglyoxylate coupled with the reduction of cytochrome c. We have used the N-terminal sequence of the enzyme to isolate the gene encoding this enzyme using the PCR. Comparison of the genomic sequence with the sequence of cDNA prepared by reverse transcription PCR revealed the presence of 11 introns in the coding region. The predicted amino acid sequence indicates a close relationship with the flavocytochromes b2 from Saccharomyces cerevisiae and Hansenula anomala, with about 40% identity to each. The sequence shows that a key residue for substrate specificity in S. cerevisiae flavocytochrome b2, Leu-230, is replaced by Gly in L-MDH. This substitution is likely to play an important part in determining the different substrate specificities of the two enzymes. We have developed an expression system and purification protocol for recombinant L-MDH. In addition, we have expressed and purified the flavin-containing domain of L-MDH independently of its cytochrome domain. Detailed steady-state and pre-steady-state kinetic investigations of both L-MDH and its independently expressed flavin domain have been carried out. These indicate that L-MDH is efficient with both physiological (cytochrome c, kcat=225 s-1 at 25 degrees C) and artificial (ferricyanide, kcat=550 s-1 at 25 degrees C) electron acceptors. Kinetic isotope effects with [2-2H]mandelate indicate that H-C-2 bond cleavage contributes somewhat to rate-limitation. However, the value of the isotope effect erodes significantly as the catalytic cycle proceeds. Reduction potentials at 25 degrees C were measured as -120 mV for the 2-electron reduction of the flavin and -10 mV for the 1-electron reduction of the haem. The general trends seen in the kinetic studies show marked similarities to those observed previously with the flavocytochrome b2 (L-lactate dehydrogenase) from S. cerevisiae.

Project description:Flavocytochrome b2 from Saccharomyces cerevisiae catalyzes the oxidation of L-lactate to pyruvate and the electron transfer to cytochrome c in the mitochondrial intermembrane space. It is a homotetramer with a molecular weight of 4 x 58 kDa, each monomer of which is composed of 2 distinct domains, the one carrying FMN and the other, a "b5-like" heme. The native structure has been described at a resolution of 2.4 A (Xia ZX, Mathews FS, 1990, J Mol Biol 212:837-863). The heme domains protrude from the central body of the tetramer consisting of the 4 FMN binding domains. Because only 2 heme domains are visible in the electron density map, the other 2 are probably disordered. We crystallized the Escherichia coli recombinant flavocytochrome b2 from S. cerevisiae inhibited by sulfite. Although the crystals were obtained under very different conditions from those of the pyruvate-containing native enzyme, they were found to be isostructural (P 3(2) 2 1, a = b = 164.5 A, c = 114.0 A). The 2.6-A X-ray structure was extensively refined with X-PLOR (R = 17.3%), which made it possible to describe in detail the recombinant flavocytochrome b2 molecular structure. There exist few differences between the native and recombinant structures, in line with the fact that they show similar kinetic behavior, and they further confirm the intrinsic mobility of the heme domain (Labeyrie F, Beloil JC, Thomas MA, 1988, Biochim Biophys Acta 953:134-141). This structure will be used as a starting model in the structural resolution of flavocytochrome b2 point mutants.

Project description:Although nitroethane does not bind to the active site of flavocytochrome b2, its anion, ethane nitronate, behaves as a competitive inhibitor, with a Ki of 2.2 mM. No electron transfer can be detected between the nitronate and the enzyme, in contrast with the observations of other workers on D-amino acid oxidase. Propionate is a competitive inhibitor, with a Ki of 28 mM. The significance of these results with respect to the proposed carbanion mechanism and the putative existence of a covalent enzyme-substrate intermediate is discussed.

Project description:We developed a metabolically engineered yeast which produces lactic acid efficiently. In this recombinant strain, the coding region for pyruvate decarboxylase 1 (PDC1) on chromosome XII is substituted for that of the l-lactate dehydrogenase gene (LDH) through homologous recombination. The expression of mRNA for the genome-integrated LDH is regulated under the control of the native PDC1 promoter, while PDC1 is completely disrupted. Using this method, we constructed a diploid yeast transformant, with each haploid genome having a single insertion of bovine LDH. Yeast cells expressing LDH were observed to convert glucose to both lactate (55.6 g/liter) and ethanol (16.9 g/liter), with up to 62.2% of the glucose being transformed into lactic acid under neutralizing conditions. This transgenic strain, which expresses bovine LDH under the control of the PDC1 promoter, also showed high lactic acid production (50.2 g/liter) under nonneutralizing conditions. The differences in lactic acid production were compared among four different recombinants expressing a heterologous LDH gene (i.e., either the bovine LDH gene or the Bifidobacterium longum LDH gene): two transgenic strains with 2microm plasmid-based vectors and two genome-integrated strains.

Project description:Two novel endophytic yeast strains, WP1 and PTD3, isolated from within the stems of poplar (Populus) trees, were genetically characterized with respect to their xylose metabolism genes. These two strains, belonging to the species Rhodotorula graminis and R. mucilaginosa, respectively, utilize both hexose and pentose sugars, including the common plant pentose sugar, D-xylose. The xylose reductase (XYL1) and xylitol dehydrogenase (XYL2) genes were cloned and characterized. The derived amino acid sequences of xylose reductase (XR) and xylose dehydrogenase (XDH) were 32%?41% homologous to those of Pichia stipitis and Candida. spp., two species known to utilize xylose. The derived XR and XDH sequences of WP1 and PTD3 had higher homology (73% and 69% identity) with each other. WP1 and PTD3 were grown in single sugar and mixed sugar media to analyze the XYL1 and XYL2 gene regulation mechanisms. Our results revealed that for both strains, the gene expression is induced by D-xylose, and that in PTD3 the expression was not repressed by glucose in the presence of xylose.