Jerusalem artichoke mitochondria can export reducing equivalents in the form of malate as a result of D-lactate uptake and metabolism

We found that as a result of d-lactate uptake and metabolism by Jerusalem artichoke mitochondria, reducing equivalents were exported from the mitochondrial matrix to the exterior in the form of malate. The rate of malate efflux, as measured photometrically using NADP+ and malic enzyme, depended on the rate of transport across the mitochondrial membrane. It showed saturation characteristics (K(m) = 5 mM; V(max) = 9 nmol/min mg of mitochondrial protein) and was inhibited by non-penetrant compounds. We conclude that reducing equivalent export from mitochondria is due to the occurrence of a putative d-lactate/malate antiporter which differs from other mitochondrial carriers, as shown by the different inhibitor sensitivity.     

Transport and metabolism of D-lactate in Jerusalem artichoke mitochondria

We report here initial studies on D-lactate metabolism in Jerusalem artichoke. It was found that: 1) D-lactate can be synthesized by Jerusalem artichoke by virtue of the presence of glyoxalase II, the activity of which was measured photometrically in both isolated Jerusalem artichoke mitochondria and cytosolic fraction after the addition of S-D-lactoyl-glutathione. 2) Externally added D-lactate caused oxygen consumption by mitochondria, mitochondrial membrane potential increase and proton release, in processes that were insensitive to rotenone, but inhibited by both antimycin A and cyanide. 3) D-lactate was metabolized inside mitochondria by a flavoprotein, a putative D-lactate dehydrogenase, the activity of which could be measured photometrically in mitochondria treated with Triton X-100. 4) Jerusalem artichoke mitochondria can take up externally added D-lactate by means of a D-lactate/H(+) symporter investigated by measuring the rate of reduction of endogenous flavins. The action of the d-lactate translocator and of the mitochondrial D-lactate dehydrogenase could be responsible for the subsequent metabolism of d-lactate formed from methylglyoxal in the cytosol of Jerusalem artichoke.     

Kinetic activation of yeast mitochondrial d-lactate dehydrogenase by carboxylic acids

Aerobically grown yeast cells express mitochondrial lactate dehydrogenases that localize to the mitochondrial inner membrane. The d-lactate dehydrogenase is a zinc-flavoprotein with high acceptor specificity for cytochrome c, that catalyzes the oxidation of d-lactate into pyruvate. In this paper, we show that mitochondrial respiratory rate in phosphorylating or non-phosphorylating conditions with d-lactate as substrate is stimulated by carboxylic acids. This stimulation does not affect the yield of oxidative phosphorylation. Furthermore, this stimulation lies at the level of the d-lactate dehydrogenase. It is non-competitive, hyperbolic and its dimension is directly related to the number of carboxylic groups on the activator. The physiological meaning of such a regulation is discussed.     

Transport and metabolism of l-lactate occur in mitochondria from cerebellar granule cells and are modified in cells undergoing low potassium dependent apoptosis

Having confirmed that externally added l-lactate can enter cerebellar granule cells, we investigated whether and how l-lactate is metabolized by mitochondria from these cells under normal or apoptotic conditions.

(1)

l-lactate enters mitochondria, perhaps via an l-lactate/H⁺ symporter, and is oxidized in a manner stimulated by ADP. The existence of an l-lactate dehydrogenase, located in the inner mitochondrial compartment, was shown by immunological analysis. Neither the protein level nor the K_m and V_max values changed en route to apoptosis.

(2)

In both normal and apoptotic cell homogenates, externally added l-lactate caused reduction of the intramitochondrial pyridine cofactors, inhibited by phenylsuccinate. This process mirrored l-lactate uptake by mitochondria and occurred with a hyperbolic dependence on l-lactate concentrations. Pyruvate appeared outside mitochondria as a result of external addition of l-lactate. The rate of the process depended on l-lactate concentration and showed saturation characteristics. This shows the occurrence of an intracellular l-lactate/pyruvate shuttle, whose activity was limited by the putative l-lactate/pyruvate antiporter. Both the carriers were different from the monocarboxylate carrier.

(3)

l-lactate transport changed en route to apoptosis. Uptake increased in the early phase of apoptosis, but decreased in the late phase with characteristics of a non-competitive like inhibition. In contrast, the putative l-lactate/pyruvate antiport decreased en route to apoptosis with characteristics of a competitive like inhibition in early apoptosis, and a mixed non-competitive like inhibition in late apoptosis.

     

X-ray structures of Aerococcus viridans lactate oxidase and its complex with D-lactate at pH 4.5 show an alpha-hydroxyacid oxidation mechanism

l-Lactate oxidase (LOX) belongs to a family of flavin mononucleotide (FMN)-dependent α-hydroxy acid-oxidizing enzymes. Previously, the crystal structure of LOX (pH 8.0) from Aerococcus viridans was solved, revealing that the active site residues are located around the FMN. Here, we solved the crystal structures of the same enzyme at pH 4.5 and its complex with d-lactate at pH 4.5, in an attempt to analyze the intermediate steps. In the complex structure, the d-lactate resides in the substrate-binding site, but interestingly, an active site base, His265, flips far away from the d-lactate, as compared with its conformation in the unbound state at pH 8.0. This movement probably results from the protonation of His265 during the crystallization at pH 4.5, because the same flip is observed in the structure of the unbound state at pH 4.5. Thus, the present structure appears to mimic an intermediate after His265 abstracts a proton from the substrate. The flip of His265 triggers a large structural rearrangement, creating a new hydrogen bonding network between His265-Asp174-Lys221 and, furthermore, brings molecular oxygen in between d-lactate and His265. This mimic of the ternary complex intermediate enzyme-substrate-O₂ could explain the reductive half-reaction mechanism to release pyruvate through hydride transfer. In the mechanism of the subsequent oxidative half-reaction, His265 flips back, pushing molecular oxygen into the substrate-binding site as the second substrate, and the reverse reaction takes place to produce hydrogen peroxide. During the reaction, the flip-flop action of His265 has a dual role as an active base/acid to define the major chemical steps. Our proposed reaction mechanism appears to be a common mechanistic strategy for this family of enzymes.     

A highly specific glyoxylate reductase derived from a formate dehydrogenase

A Glu141Asn mutant Paracoccus sp. 12-A formate dehydrogenase catalyzes marked glyoxylate reduction. Additional replacement of the His332-Gln313 pair with His-Glu, which is a consensus acid/base catalyst in D-hydroxyacid dehydrogenases, further improved the catalytic activity of the enzyme as to glyoxylate reduction through enhancement of the hydrogen transfer step in the catalytic process, slightly shifting the optimal pH for the reaction. On the other hand, the replacement induced no marked activity toward other 2-ketoacid substrates, and diminished the enzyme activity as to formate oxidation. Consequently, the formate dehydrogenase was converted to a highly specific and active glyoxylate reductase through only the two amino acid replacements.     

l-Lactate generates hydrogen peroxide in purified rat liver mitochondria due to the putative l-lactate oxidase localized in the intermembrane space

In order to ascertain whether and how mitochondria can produce hydrogen peroxide (H₂O₂) as a result of l-lactate addition, we monitored H₂O₂ generation in rat liver mitochondria and in submitochondrial fractions free of peroxisomal and cytosolic contamination. We found that H₂O₂ is produced independently on the respiratory chain with 1:1 stoichiometry with pyruvate, due to a putative flavine-dependent l-lactate oxidase restricted to the intermembrane space. The l-lactate oxidase reaction shows a hyperbolic dependence on l-lactate concentration and is inhibited by NAD⁺ in a competitive manner, being the enzyme different from the l-lactate dehydrogenase isoenzymes as shown by their pH profiles.     

Mitochondrial metabolic states and membrane potential modulate mtNOS activity

The mitochondrial metabolic state regulates the rate of NO release from coupled mitochondria: NO release by heart, liver and kidney mitochondria was about 40-45% lower in state 3 (1.2, 0.7 and 0.4 nmol/min mg protein) than in state 4 (2.2, 1.3 and 0.7 nmol/min mg protein). The activity of mtNOS, responsible for NO release, appears driven by the membrane potential component and not by intramitochondrial pH of the proton motive force. The intramitochondrial concentrations of the NOS substrates, l-arginine (about 310 μM) and NADPH (1.04-1.78 mM) are 60-1000 times higher than their K_M values. Moreover, the changes in their concentrations in the state 4-state 3 transition are not enough to explain the changes in NO release. Nitric oxide release was exponentially dependent on membrane potential as reported for mitochondrial H₂O₂ production [S.S. Korshunov, V.P. Skulachev, A.A. Satarkov, High protonic potential actuates a mechanism of production of reactive oxygen species in mitochondria. FEBS Lett. 416 (1997) 15-18.]. Agents that decrease or abolish membrane potential minimize NO release while the addition of oligomycin that produces mitochondrial hyperpolarization generates the maximal NO release. The regulation of mtNOS activity, an apparently voltage-dependent enzyme, by membrane potential is marked at the physiological range of membrane potentials.     

Crystal structures of D-tagatose 3-epimerase from Pseudomonas cichorii and its complexes with D-tagatose and D-fructose

Pseudomonas cichoriiid-tagatose 3-epimerase (P. cichoriid-TE) can efficiently catalyze the epimerization of not only d-tagatose to d-sorbose, but also d-fructose to d-psicose, and is used for the production of d-psicose from d-fructose. The crystal structures of P. cichoriid-TE alone and in complexes with d-tagatose and d-fructose were determined at resolutions of 1.79, 2.28, and 2.06 Å, respectively. A subunit of P. cichoriid-TE adopts a (β/α)₈ barrel structure, and a metal ion (Mn²⁺) found in the active site is coordinated by Glu152, Asp185, His211, and Glu246 at the end of the β-barrel. P. cichoriid-TE forms a stable dimer to give a favorable accessible surface for substrate binding on the front side of the dimer. The simulated omit map indicates that O2 and O3 of d-tagatose and/or d-fructose coordinate Mn²⁺, and that C3-O3 is located between carboxyl groups of Glu152 and Glu246, supporting the previously proposed mechanism of deprotonation/protonation at C3 by two Glu residues. Although the electron density is poor at the 4-, 5-, and 6-positions of the substrates, substrate-enzyme interactions can be deduced from the significant electron density at O6. The O6 possibly interacts with Cys66 via hydrogen bonding, whereas O4 and O5 in d-tagatose and O4 in d-fructose do not undergo hydrogen bonding to the enzyme and are in a hydrophobic environment created by Phe7, Trp15, Trp113, and Phe248. Due to the lack of specific interactions between the enzyme and its substrates at the 4- and 5-positions, P. cichoriid-TE loosely recognizes substrates in this region, allowing it to efficiently catalyze the epimerization of d-tagatose and d-fructose (C4 epimer of d-tagatose) as well. Furthermore, a C3-O3 proton-exchange mechanism for P. cichoriid-TE is suggested by X-ray structural analysis, providing a clear explanation for the regulation of the ionization state of Glu152 and Glu246.     

A structural basis for substrate selectivity and stereoselectivity in octopine dehydrogenase from Pecten maximus

Octopine dehydrogenase [N²-(d-1-carboxyethyl)-l-arginine:NAD⁺ oxidoreductase] (OcDH) from the adductor muscle of the great scallop Pecten maximus catalyzes the reductive condensation of l-arginine and pyruvate to octopine during escape swimming. This enzyme, which is a prototype of opine dehydrogenases (OpDHs), oxidizes glycolytically born NADH to NAD⁺, thus sustaining anaerobic ATP provision during short periods of strenuous muscular activity. In contrast to some other OpDHs, OcDH uses only l-arginine as the amino acid substrate. Here, we report the crystal structures of OcDH in complex with NADH and the binary complexes NADH/l-arginine and NADH/pyruvate, providing detailed information about the principles of substrate recognition, ligand binding and the reaction mechanism. OcDH binds its substrates through a combination of electrostatic forces and size selection, which guarantees that OcDH catalysis proceeds with substrate selectivity and stereoselectivity, giving rise to a second chiral center and exploiting a “molecular ruler” mechanism.     

Molecular and functional characterization of D-3-phosphoglycerate dehydrogenase in the serine biosynthetic pathway of the hyperthermophilic archaeon Sulfolobus tokodaii

A gene (ST1218) encoding a d-3-phosphoglycerate dehydrogenase (PGDH; EC 1.1.1.95) homolog was found in the genome of Sulfolobus tokodaii strain 7 by screening a database of enzymes likely to contribute to l-serine biosynthesis in hyperthermophilic archaea. After expressing the gene in Escherichia coli, the PGDH activity of the recombinant enzyme was assessed. Homogeneous PGDH was obtained using conventional chromatography steps, though during the purification an unexpected decline in enzyme activity was observed if the enzyme was stored in plastic tubes, but not in glass ones. The purified enzyme was a homodimer with a subunit molecular mass of about 35 kDa and was highly thermostable. It preferably acted as an NAD-dependent d-3-phosphoglycerate (3PGA) dehydrogenase. Although NADP had no activity as the electron acceptor, both NADPH and NADH acted as electron donors. Kinetic analyses indicated that the enzyme reaction proceeds via a Theorell-Chance Bi-Bi mechanism. Unlike E. coli PGDH, the S. tokodaii enzyme was not inhibited by l-serine. In addition, both the NAD-dependent 3PGA oxidation and the reverse reaction were enhanced by phosphate and sulfate ions, while NADPH-dependent 3-phosphohydroxypyruvate (PHP) reduction was inhibited. Thus S. tokodaii PGDH appears to be subject to a novel regulatory mechanism not seen elsewhere. A database analysis showed that ST1218 gene forms a cluster with ST1217 gene, and a functional analysis of the ST1217 product expressed in E. coli revealed that it possesses l-glutamate-PHP aminotransferase activity. Taken together, our findings represent the first example of a phosphorylated serine pathway in a hyperthermophilic archaeon.     

NAD+-specific D-arabinose dehydrogenase and its contribution to erythroascorbic acid production in Saccharomyces cerevisiae

Erythroascorbic acid (eAsA) is a five-carbon analog of ascorbic acid, and it is synthesized from D-arabinose by D-arabinose dehydrogenase (ARA) and D-arabinono-gamma-lactone oxidase. We found an NAD+-specific ARA activity which is operative under submillimolar level of d-arabinose in the extracts of Saccharomyces cerevisiae. The hypothetical protein encoded by YMR041c showed a significant homology to a l-galactose dehydrogenase which plays in plant ascorbic acid biosynthesis, and we named it as Ara2p. Recombinant Ara2p showed NAD+-specific ARA activity with Km=0.78 mM to d-arabinose, which is 200-fold lower than that for the conventional NADP+-specific ARA, Ara1p. Gene disruptant of ARA2 lost entire NAD+-specific ARA activity and the conspicuous increase in intracellular eAsA by exogenous d-arabinose feeding, while the double knockout mutant of ARA1 and ARA2 still retained measurable amount of eAsA. It demonstrates that Ara2p, not Ara1p, mainly contributes to the production of eAsA from d-arabinose in S. cerevisiae.     

Effect of Dietary l-Glutamine on the Hepatotoxic Action of d-Galactosamine in Rats

The protective effect of dietary l-glutamine against the hepatotoxic action of d-galactosamine (GalN) was investigated by model experiments with rats. Rats fed with 20% casein diets containing 10% free amino acids were injected with GalN, and the serum aspartate aminotransferase, alanine aminotransferase and lactate dehydrogenase activities and the hepatic glycogen content were assayed 20 hours after the injection. These enzyme activities in the group fed with the 10% l-glutamine diet for 8 days were lower than those in the groups fed with the control, 10% l-glutamic acid and 10% l-alanine diets for 8 days. The more prolonged the feeding period with the 10% l-glutamine diet was, the more the serum activity levels of such enzymes were decreased. Although neomycin also lowered these enzyme activities, its simultaneous ingestion with neomycin did not show any additive or synergistic effect. The hepatic glycogen content in the 10% glutamine group still remained high after the GalN treatment. It is therefore assumed that the effectiveness of glutamine intake would have been mediated by glycogen metabolism rather than by uridine metabolism.     

Crystal structure of YihS in complex with D-mannose: structural annotation of Escherichia coli and Salmonella enterica yihS-encoded proteins to an aldose-ketose isomerase

The three-dimensional structure of a Salmonella enterica hypothetical protein YihS is significantly similar to that of N-acyl-d-glucosamine 2-epimerase (AGE) with respect to a common scaffold, an α₆/α₆-barrel, although the function of YihS remains to be clarified. To identify the function of YihS, Escherichia coli and S. enterica YihS proteins were overexpressed in E. coli, purified, and characterized. Both proteins were found to show no AGE activity but showed cofactor-independent aldose-ketose isomerase activity involved in the interconversion of monosaccharides, mannose, fructose, and glucose, or lyxose and xylulose. In order to clarify the structure/function relationship of YihS, we determined the crystal structure of S. enterica YihS mutant (H248A) in complex with a substrate (d-mannose) at 1.6 Å resolution. This enzyme-substrate complex structure is the first demonstration in the AGE structural family, and it enables us to identify active-site residues and postulate a reaction mechanism for YihS. The substrate, β-d-mannose, fits well in the active site and is specifically recognized by the enzyme. The substrate-binding site of YihS for the mannose C1 and O5 atoms is architecturally similar to those of mutarotases, suggesting that YihS adopts the pyranose ring-opening process by His383 and acidifies the C2 position, forming an aldehyde at the C1 position. In the isomerization step, His248 functions as a base catalyst responsible for transferring the proton from the C2 to C1 positions through a cis-enediol intermediate. On the other hand, in AGE, His248 is thought to abstract and re-adduct the proton at the C2 position of the substrate. These findings provide not only molecular insights into the YihS reaction mechanism but also useful information for the molecular design of novel carbohydrate-active enzymes with the common scaffold, α₆/α₆-barrel.     

D-Erythroascorbic acid activates cyanide-resistant respiration in Candida albicans

Higher plants, protists and fungi possess cyanide-resistant respiratory pathway, which is mediated by alternative oxidase (AOX). The activity of AOX has been found to be dependent on several regulatory mechanisms including gene expression and posttranslational regulation. In the present study, we report that the presence of cyanide in culture medium remarkably retarded the growth of alo1/alo1 mutant of Candida albicans, which lacks d-arabinono-1,4-lactone oxidase (ALO) that catalyzes the final step of d-erythroascorbic acid (EASC) biosynthesis. Measurement of respiratory activity and Western blot analysis revealed that increase in the intracellular EASC level induces the expression of AOX in C. albicans. AOX could still be induced by antimycin A, a respiratory inhibitor, in the absence of EASC, suggesting that several factors may act in parallel pathways to induce the expression of AOX. Taken together, our results suggest that EASC plays important roles in activation of cyanide-resistant respiration in C. albicans.     

Determination of plasma and serum l-lysine using l-lysine ε-oxidase from Marinomonas mediterranea NBRC 103028

This article describes a successful application of l-lysine ε-oxidase (EC 1.4.3.20) for l-lysine determination. l-Lysine ε-oxidase was isolated from culture supernatant of Marinomonas mediterranea NBRC 103028^T and was used for l-lysine determination. Comparison of the characteristics of l-lysine ε-oxidase with l-lysine α-oxidase, a commercial enzyme used for l-lysine determination, suggests that the use of l-lysine ε-oxidase would be more valuable for the determination of l-lysine because of its selectivity and sensitivity, especially in samples with low l-lysine concentration. The enzyme acted only on l-lysine and l-ornithine, to which the relative activity was only 3.4% of that on l-lysine. The value obtained by the colorimetric assay using l-lysine ε-oxidase and horseradish peroxidase was not affected by l-ornithine. The enzyme also shows a higher affinity for l-lysine (K_m = 0.0018 mM). l-Lysine determination using l-lysine ε-oxidase in human plasma and serum was examined. The measured values were close to values determined by instrumental analyses using the precolumn AccQ·Tag Ultra Derivatization Kit. These results suggest that l-lysine ε-oxidase can be used for diagnosis based on plasma l-lysine concentration. This is the first report on the application of l-lysine ε-oxidase.     

The ‘true’ l-xylulose reductase of filamentous fungi identified in Aspergillus niger

l-Xylulose reductase is part of the eukaryotic pathway for l-arabinose catabolism. A previously identified l-xylulose reductase in Hypocrea jecorina turned out to be not the ‘true’ one since it was not upregulated during growth on l-arabinose and the deletion strain showed no reduced l-xylulose reductase activity but instead lost the d-mannitol dehydrogenase activity [17]. In this communication we identified the ‘true’ l-xylulose reductase in Aspergillus niger. The gene, lxrA (JGI177736), is upregulated on l-arabinose and the deletion results in a strain lacking the NADPH-specific l-xylulose reductase activity and having reduced growth on l-arabinose. The purified enzyme had a K_m for l-xylulose of 25 mM and a ν_max of 650 U/mg.     

Monoacylation of 2-O-α-d-glucopyranosyl-l-ascorbic acid by protease in N,N-dimethylformamide with low water content

2-O-α-d-Glucopyranosyl-l-ascorbic acid (AA-2G) laurate was synthesized from AA-2G and vinyl laurate with a protease from Bacillus subtilis in N,N-dimethylformamide (DMF) with low water content. Addition of water to DMF dramatically enhanced monoacyl AA-2G synthesis. Maximum synthetic activity was observed when 3% (v/v) water was added to the reaction medium. Under the optimal reaction conditions, 5-O-dodecanoyl-2-O-α-d-glucopyranosyl-l-ascorbic acid, 2-O-(6′-O-dodecanoyl-α-d-glucopyranosyl)-l-ascorbic acid, and 6-O-dodecanoyl-2-O-α-d-glucopyranosyl-l-ascorbic acid were synthesized in yields of 5.5%, 3.2%, and 20.4%, respectively.     

Synthesis of new N-substituted 3,4,5-trihydroxypiperidin-2-ones from d-ribono-1,4-lactone

d-Ribono-1,4-lactone was treated with ethylamine in DMF to afford N-ethyl-d-ribonamide 8a in quantitative yield. Using this reaction procedure, N-butyl, N-hexyl, N-dodecyl, N-benzyl, N-(3-methyl-pyridinyl)-, N-(2-hydroxy-ethyl)-, and N-(2-cyano-ethyl)-d-ribonamides 8b-h were obtained in quantitative yield. Bromination of the amides 8a-e with acetyl bromide in dioxane followed by acetylation gave 2,3,4-tri-O-acetyl-5-bromo-5-deoxy-N-ethyl, N-butyl, N-hexyl, N-dodecyl, and N-benzyl-d-ribonamides 9a-e in 40-54% yields. To obtain 2,3,4-tri-O-acetyl-5-bromo-5-deoxy-N-(3-methyl-pyridinyl)-, N-(2-hydroxy-ethyl)-, and N-(2-cyano-ethyl)-9f-h, the bromination is necessary before the amidation reaction. Treatment of the bromoamides 9a-h with NaH in DMF followed by methanolysis affords N-alkyl-d-ribono-1,5-lactams 12a-h in quantitative yield.     

Single-step bioconversion for the preparation of l-gulose and l-galactose

Both carbohydrate monomers l-gulose and l-galactose are rarely found in nature, but are of great importance in pharmacy R&D and manufacturing. A method for the production of l-gulose and l-galactose is described that utilizes recombinant Escherichia coli harboring a unique mannitol dehydrogenase. The recombinant E. coli system was optimized by genetic manipulation and directed evolution of the recombinant protein to improve conversion. The resulting production process requires a single step, represents the first readily scalable system for the production of these sugars, is environmentally friendly, and utilizes inexpensive reagents, while producing l-galactose at 4.6 g L⁻¹ d⁻¹ and l-gulose at 0.90 g L⁻¹ d⁻¹.