On the reaction mechanism of
            <scp>l</scp>
            -lactate oxidase: Quantitative structure-activity analysis of the reaction with
            <i>para</i>
            -substituted 
            <scp>l</scp>
            -mandelates

Yorita, Kazuko; Janko, K.; Aki, Kenji; Ghisla, Sandro; Palfey, Bruce A.; Massey, Vincent

doi:10.1073/pnas.94.18.9590

Cited by 47 publications

(44 citation statements)

References 29 publications

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“…In each case, it is clear that the pairs of arginine residues are involved in substrate binding and catalysis. Although the results do not offer any real proof, they are consistent with the hypothesis that the two arginine residues serve the complementary roles of assisting in binding of the substrate carboxylate and in neutralizing the negative charge developed in the transition state on removal of the proton from the ␣-carbon position by the active site histidine base (2).…”

Section: Discussionsupporting

confidence: 56%

“…The kinetic characteristics of the enzyme have been reported by our group, but still the mechanism of the reductive half-reaction by ␣-hydroxyacids is one of central interest. Our previous study of the reactivity of LOX with a series of para-substituted mandelates indicated little development of charge in the transition state of the reductive half reaction (2). This result is compatible with either a hydride mechanism or with a synchronous mechanism in which the ␣-CH-of the substrate is formally abstracted as a proton, whereas the resulting charge is simultaneously neutralized by another event.…”

supporting

confidence: 62%

“…This result is compatible with either a hydride mechanism or with a synchronous mechanism in which the ␣-CH-of the substrate is formally abstracted as a proton, whereas the resulting charge is simultaneously neutralized by another event. We proposed the participation of two arginine residues, Arg-181 and Arg-268, which are located around the FMN and which could be part of the substrate binding site, based on the x-ray crystal structures of glycolate oxidase (3,4) and flavocytochrome b 2 (5,6). These two arginine residues are conserved in all family members, as shown in Fig.…”

mentioning

confidence: 99%

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Interaction of two arginine residues in lactate oxidase with the enzyme flavin: Conversion of FMN to 8-formyl-FMN

Yorita

Matsuoka²,

Misaki³

et al. 2000

Proc. Natl. Acad. Sci. U.S.A.

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T he enzyme L-lactate oxidase from Aerococcus viridans (LOX) is a member of the family of flavoproteins that catalyze the oxidation of ␣-hydroxyacids (1). The kinetic characteristics of the enzyme have been reported by our group, but still the mechanism of the reductive half-reaction by ␣-hydroxyacids is one of central interest. Our previous study of the reactivity of LOX with a series of para-substituted mandelates indicated little development of charge in the transition state of the reductive half reaction (2). This result is compatible with either a hydride mechanism or with a synchronous mechanism in which the ␣-CH-of the substrate is formally abstracted as a proton, whereas the resulting charge is simultaneously neutralized by another event. We proposed the participation of two arginine residues, Arg-181 and Arg-268, which are located around the FMN and which could be part of the substrate binding site, based on the x-ray crystal structures of glycolate oxidase (3, 4) and flavocytochrome b 2 (5, 6). These two arginine residues are conserved in all family members, as shown in Fig. 1. It should be noted that there is a 20-to 30-aa residue insertion in L-lactate monooxygenase and L-mandelate dehydrogenase between these two arginine residues.In this paper, we have replaced these two residues by either lysine as a relatively mild perturbation or methionine as removing positive charge (R268K, R181K, R181M, and R181K ϩ R268K) and studied the characteristics of the resulting enzymes to try to elucidate the functions of these arginine residues. We found that both residues are involved in the reductive half reaction and in the interaction of substrates and ligands with the FMN prosthetic group. Materials and MethodsSite-Directed Mutagenesis. Amino acid substitutions R181K, R268K, and their double substitution were carried out by a site-directed mutagenesis of the lactate oxidase gene in the expression vector, pAOX8, which is composed of a 1.2-kb insert containing the coding region for lactate oxidase in pACYC184. Two fragments were generated by PCR: one contained the sequence from the HindIII site of the pACYC184 plasmid to the site of mutagenesis and the other the sequence from the site of mutagenesis to the BamHI site of the expression plasmid. These two fragments were annealed at the site of mutagenesis and extended enzymatically to yield the coding region with the expected mutation. The resulting sequence was amplified by PCR using the HindIII and BamHI site primers. After treatment with HindIII and BamHI, the DNA product was ligated into these restriction sites in pACYC184 to yield the expression plasmid, pAOX8, with the appropriate mutation. The double mutant was generated by using the primers for both mutations together with the primers that generated the HindIII and BamHI sites, resulting in three DNA fragments, which were annealed, extended, and ligated into the expression vector. The mutation of R181M was carried out by the method of Kunkel et al. (7).Flavin Extraction from the Enzymes. Buffer salts in sol...

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Section: Discussionsupporting

confidence: 56%

supporting

confidence: 62%

mentioning

confidence: 99%

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Interaction of two arginine residues in lactate oxidase with the enzyme flavin: Conversion of FMN to 8-formyl-FMN

Yorita

Matsuoka²,

Misaki³

et al. 2000

Proc. Natl. Acad. Sci. U.S.A.

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“…1996;Mizutani et al, 1996). As a consequence, it was recently suggested that the accepted mechanism of the a-hydroxy acidoxidizing enzymes might also need revision (Pollegioni et al, 1997;Yorita et al, 1997). A discussion of the structural differences at the active site between the two enzyme classes, as well as of examples of differing reactivity with some mechanistically relevant substrates and inactivators lies outside the scope of this article.…”

Section: H373 K349mentioning

confidence: 99%

About the pK_a of the active‐site histidine in flavocytochrome b₂ (yeast L‐lactate dehydrogenase)

Rao

Lederer

1998

Protein Science

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Flavocytochrome b2 or L-lactate dehydrogenase from yeasts catalyzes the oxidation of L-lactate at the expense of monoelectronic acceptors such as cytochrome c, its physiological partner. When incubated in the presence of both L-lactate and a keto acid, the enzyme catalyzes a transhydrogenation reaction wherein only the flavin is involved. During this reaction, the substrate a-hydrogen is transferred not only to the solvent but also in part to the keto acid, which acts as reverse substrate. Thus, when bound to the reduced enzyme, this hydrogen is sticky. In the context of a carbanion mechanism, it resides on NE of His373, the active site base. We have shown before that a correlation between the amount of intermolecular hydrogen transfer from [2-'H] lactate and the keto acid reverse substrate concentration enables the determination of the first-order rate constant, k:, for exchange of the substrate-derived protein-bound hydrogen with bulk solvent (Urban P, Lederer F, 1985, J BioZ Chem 260: 1 1 1 15-1 1 122). In this work, we show that the exchange with the solvent appears to be independent of the phosphate buffer concentration in the range from 40 to 500 mM. It is thus probable that exchange occurs directly with water molecules. The second-order rate constant for exchange is then 0.16 (kO.03) M" s". Using the Eigen equation, this figure yields a pK, of 9.1 f 0.1 for His373 in the reduced enzyme, compared to a probable value of 6.0 or less in the oxidized enzyme (Suzuki H, Ogura YC, 1970, JBiochem 67:291-295). The mechanistic significance of these results is discussed.

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“…This puzzle remained unanswered for a long time, as the flavin ought not to be involved directly in elimination. Later experiments based on the concept of the linear free energy relationship were not in favor of the carbanion mechanism either (10,11). A way out of the conundrum emerged when the three-dimensional structure of two related DAAOs was identified (12,13); these studies showed unambiguously that there is no functional group at the active center of the enzyme that could act as a base in abstracting the substrate ␣H as H ϩ .…”

mentioning

confidence: 99%

Revisitation of the βCl-Elimination Reaction of d-Amino Acid Oxidase

Ghisla

Pollegioni

Molla

2011

Journal of Biological Chemistry

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, which was later confirmed by others (2-4). Based on this, the mechanism depicted in Scheme 1 for the elimination reaction was put forward (1). In this reaction the substrate ␣H as H ϩ is abstracted to form a carbanion intermediate, which then releases Cl Ϫ to yield the final products pyruvate and NH 4 ϩ . In this reaction the redox state of the flavin cofactor remains unaltered."Normal" dehydrogenation of ␤Cl-D-Ala would yield ␤Cl-pyruvate (␤Cl-Py) as the final product and lead to reduction of the flavin cofactor (5). The initial experiment (1) provided the first clues for formulating a general concept for the mechanism underlying flavin dehydrogenation and represents the birth of the so-called carbanion mechanism. This concept then gained wide acceptance for decades to come. However, some doubts soon emerged (2, 6 -8); experiments by Hersh and Jorns (9) demonstrated that for a DAAO in which the flavin cofactor was replaced by 5-deaza-flavin, Cl Ϫ was not eliminated. This puzzle remained unanswered for a long time, as the flavin ought not to be involved directly in elimination. Later experiments based on the concept of the linear free energy relationship were not in favor of the carbanion mechanism either (10, 11). A way out of the conundrum emerged when the three-dimensional structure of two related DAAOs was identified (12, 13); these studies showed unambiguously that there is no functional group at the active center of the enzyme that could act as a base in abstracting the substrate ␣H as H ϩ . Furthermore, the structures of complexes of Rhodotorula gracilis D-amino acid oxidase (RgDAAO) with D-alanine or D-CF 3 -alanine show that the substrate ␣C-H points directly toward

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On the reaction mechanism of l -lactate oxidase: Quantitative structure-activity analysis of the reaction with para -substituted l -mandelates

Cited by 47 publications

References 29 publications

Interaction of two arginine residues in lactate oxidase with the enzyme flavin: Conversion of FMN to 8-formyl-FMN

Interaction of two arginine residues in lactate oxidase with the enzyme flavin: Conversion of FMN to 8-formyl-FMN

About the pK_a of the active‐site histidine in flavocytochrome b₂ (yeast L‐lactate dehydrogenase)

Revisitation of the βCl-Elimination Reaction of d-Amino Acid Oxidase

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On the reaction mechanism of l -lactate oxidase: Quantitative structure-activity analysis of the reaction with para -substituted l -mandelates

Cited by 47 publications

References 29 publications

Interaction of two arginine residues in lactate oxidase with the enzyme flavin: Conversion of FMN to 8-formyl-FMN

Interaction of two arginine residues in lactate oxidase with the enzyme flavin: Conversion of FMN to 8-formyl-FMN

About the pKa of the active‐site histidine in flavocytochrome b2 (yeast L‐lactate dehydrogenase)

Revisitation of the βCl-Elimination Reaction of d-Amino Acid Oxidase

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About the pK_a of the active‐site histidine in flavocytochrome b₂ (yeast L‐lactate dehydrogenase)