Metabolisme du γ-aminobutyrate chez Agaricus bisporus III. La succinate-semialdehyde:NAD(P)+ oxydoreductase

Metabolism of γ-Aminobutyrate in Agaricus bisporus. III. The Succinate-Semialdehyde: NAD (P)⁺ Oxidoreductase. The succinate-semialdehyde:NAD(P)⁺ oxidoreductase (E.C. 1.2.1.16) is responsible for the second step in the catabolism of γ-aminobutyrate: the irreversible enzymatic conversion of succinic semialdehyde (SSA) to succinate. Succinate semialdehyde dehydrogenase was extracted from mitochondrial fraction of fruit-bodies of Agaricus bisporus Lge. The mitochondrial pellet was sonicated and centrifuged at 110,000 g; the supernatant obtained was designated the “crude extract”. The enzyme was extremely unstable on storage, unless 1 mM EDTA and 20% glycerol were added. Kinetic studies were carried out at 30°C, and the formation of NADH or NADPH was followed by measuring increase of absorbance at 340 nm with a spectrophotometer. The dehydrogenase was completely inactive when the reaction was run in the absence of thiol and was more active with NAD⁺ than with NADP⁺. In the “crude extract” the activity with NADP⁺ had a pH optimum between 8.6 and 9.1 and the K_m values for SSA and NADP⁺ were 2.0 × 10^?4M and 1.4 × 10^?4M respectively. The pH optimum with NAD⁺ was found between 8.6 and 8.8 and the K_m value for SSA is 4.8 × 10^?4M and for NAD⁺ 2.0 × 10^?3M. With NAD⁺, the kinetic values (pH, K_m) of the “crude extract” chromatographed on hydroxylapatite were unchanged. Inhibition by thiamine pyrophosphate (TPP) was uncompetitive with respect to NAD⁺, those by malate, ATP, ADP and NADPH non-competitive and that by NADH competitive. These results and the fact that activity with NAD⁺ was lost more slowly than with NADP⁺ indicate the possibility of at least two mitochondrial succinate-semialdehyde dehydrogenases, even though the activities of this enzyme assayed with NAD⁺ and NADP⁺ respectively were not able to be separated from each other by hydroxylapatite column chromatography. Some speculations on the metabolic regulation of this dehydrogenase and considerations on the significance of these results in the physiology of respiration in Agaricus bisporus Lge are given.     

The three-dimensional structural basis of type II hyperprolinemia

Type II hyperprolinemia is an autosomal recessive disorder caused by a deficiency in Δ¹-pyrroline-5-carboxylate dehydrogenase (P5CDH; also known as ALDH4A1), the aldehyde dehydrogenase that catalyzes the oxidation of glutamate semialdehyde to glutamate. Here, we report the first structure of human P5CDH (HsP5CDH) and investigate the impact of the hyperprolinemia-associated mutation of Ser352 to Leu on the structure and catalytic properties of the enzyme. The 2. 5-Å-resolution crystal structure of HsP5CDH was determined using experimental phasing. Structures of the mutant enzymes S352A (2.4 Å) and S352L (2.85 Å) were determined to elucidate the structural consequences of altering Ser352. Structures of the 93% identical mouse P5CDH complexed with sulfate ion (1.3 Å resolution), glutamate (1.5 Å), and NAD⁺ (1.5 Å) were determined to obtain high-resolution views of the active site. Together, the structures show that Ser352 occupies a hydrophilic pocket and is connected via water-mediated hydrogen bonds to catalytic Cys348. Mutation of Ser352 to Leu is shown to abolish catalytic activity and eliminate NAD⁺ binding. Analysis of the S352A mutant shows that these functional defects are caused by the introduction of the nonpolar Leu352 side chain rather than the removal of the Ser352 hydroxyl. The S352L structure shows that the mutation induces a dramatic 8-Å rearrangement of the catalytic loop. Because of this conformational change, Ser349 is not positioned to interact with the aldehyde substrate, conserved Glu447 is no longer poised to bind NAD⁺, and Cys348 faces the wrong direction for nucleophilic attack. These structural alterations render the enzyme inactive.     

The ALDH21 gene found in lower plants and some vascular plants codes for a NADP+‐dependent succinic semialdehyde dehydrogenase

Lower plant species including some green algae, non‐vascular plants (bryophytes) as well as the oldest vascular plants (lycopods) and ferns (monilophytes) possess a unique aldehyde dehydrogenase (ALDH) gene named ALDH21, which is upregulated during dehydration. However, the gene is absent in flowering plants. Here, we show that ALDH21 from the moss Physcomitrella patens codes for a tetrameric NADP⁺‐dependent succinic semialdehyde dehydrogenase (SSALDH), which converts succinic semialdehyde, an intermediate of the γ‐aminobutyric acid (GABA) shunt pathway, into succinate in the cytosol. NAD⁺ is a very poor coenzyme for ALDH21 unlike for mitochondrial SSALDHs (ALDH5), which are the closest related ALDH members. Structural comparison between the apoform and the coenzyme complex reveal that NADP⁺ binding induces a conformational change of the loop carrying Arg‐228, which seals the NADP⁺ in the coenzyme cavity via its 2′‐phosphate and α‐phosphate groups. The crystal structure with the bound product succinate shows that its carboxylate group establishes salt bridges with both Arg‐121 and Arg‐457, and a hydrogen bond with Tyr‐296. While both arginine residues are pre‐formed for substrate/product binding, Tyr‐296 moves by more than 1 Å. Both R121A and R457A variants are almost inactive, demonstrating a key role of each arginine in catalysis. Our study implies that bryophytes but presumably also some green algae, lycopods and ferns, which carry both ALDH21 and ALDH5 genes, can oxidize SSAL to succinate in both cytosol and mitochondria, indicating a more diverse GABA shunt pathway compared with higher plants carrying only the mitochondrial ALDH5.     

Unraveling the function of paralogs of the aldehyde dehydrogenase super family from Sulfolobus solfataricus

Aldehyde dehydrogenases (ALDHs) have been well established in all three domains of life and were shown to play essential roles, e.g., in intermediary metabolism and detoxification. In the genome of Sulfolobus solfataricus, five paralogs of the aldehyde dehydrogenases superfamily were identified, however, so far only the non-phosphorylating glyceraldehyde-3-phosphate dehydrogenase (GAPN) and α-ketoglutaric semialdehyde dehydrogenase (α-KGSADH) have been characterized. Detailed biochemical analyses of the remaining three ALDHs revealed the presence of two succinic semialdehyde dehydrogenase (SSADH) isoenzymes catalyzing the NAD(P)⁺-dependent oxidation of succinic semialdehyde. Whereas SSO1629 (SSADH-I) is specific for NAD⁺, SSO1842 (SSADH-II) exhibits dual cosubstrate specificity (NAD(P)⁺). Physiological significant activity for both SSO-SSADHs was only detected with succinic semialdehyde and α-ketoglutarate semialdehyde. Bioinformatic reconstructions suggest a major function of both enzymes in γ-aminobutyrate, polyamine as well as nitrogen metabolism and they might additionally also function in pentose metabolism. Phylogenetic studies indicated a close relationship of SSO-SSALDHs to GAPNs and also a convergent evolution with the SSADHs from E. coli. Furthermore, for SSO1218, methylmalonate semialdehyde dehydrogenase (MSDH) activity was demonstrated. The enzyme catalyzes the NAD⁺- and CoA-dependent oxidation of methylmalonate semialdehyde, malonate semialdehyde as well as propionaldehyde (PA). For MSDH, a major function in the degradation of branched chain amino acids is proposed which is supported by the high sequence homology with characterized MSDHs from bacteria. This is the first report of MSDH as well as SSADH isoenzymes in Archaea.     

Synthesis of a Highly Substituted N-Linked Immobilized NAD Derivative Using a Rapid Solid-Phase Modular Approach: Suitability for Use with the Kinetic Locking-on Tactic for Bioaffinity Purification of NAD-Dependent Dehydrogenases

This study is concerned with further development of the kinetic locking-on strategy for bioaffinity purification of NAD⁺-dependent dehydrogenases. Specifically, the synthesis of highly substituted N⁶-linked immobilized NAD⁺ derivatives is described using a rapid solid-phase modular approach. Other modifications of the N⁶-linked immobilized NAD⁺ derivative include substitution of the hydrophobic diaminohexane spacer arm with polar spacer arms (9 and 19.5 Å) in an attempt to minimize nonbiospecific interactions. Analysis of the N⁶-linked NAD⁺ derivatives confirm (i) retention of cofactor activity upon immobilization (up to 97%); (ii) high total substitution levels and high percentage accessibility levels when compared to S⁶-linked immobilized NAD⁺ derivatives (also synthesized with polar spacer arms); (iii) short production times when compared to the preassembly approach to synthesis. Model locking-on bioaffinity chromatographic studies were carried out with bovine heart -lactate dehydrogenase ( -LDH, EC 1.1.1.27), bakers yeast alcohol dehydrogenase (YADH, EC 1.1.1.1) and Sporosarcinia sp. -phenylalanine dehydrogenase ( -PheDH, EC 1.4.1.20), using oxalate, hydroxylamine, and -phenylalanine, respectively, as locking-on ligands. Surprisingly, two of these test NAD⁺-dependent dehydrogenases (lactate and alcohol dehydrogenase) were found to have a greater affinity for the more lowly substituted S⁶-linked immobilized cofactor derivatives than for the new N⁶-linked derivatives. In contrast, the NAD⁺-dependent phenylalanine dehydrogenase showed no affinity for the S⁶-linked immobilized NAD⁺ derivative, but was locked-on strongly to the N⁶-linked immobilized derivative. That this locking-on is biospecific is confirmed by the observation that the enzyme failed to lock-on to an analogous N⁶-linked immobilized NADP⁺ derivative in the presence of -phenylalanine. This differential locking-on of NAD⁺-dependent dehydrogenases to N⁶-linked and S⁶-linked immobilized NAD⁺ derivatives cannot be explained in terms of final accessible substitutions levels, but suggests fundamental differences in affinity of the three test enzymes for NAD⁺ immobilized via N⁶-linkage as compared to thiol-linkage.     

Computational prediction and experimental verification of the gene encoding the NAD+/NADP+-dependent succinate semialdehyde dehydrogenase in Escherichia coli

Although NAD⁺-dependent succinate semialdehyde dehydrogenase activity was first described in Escherichia coli more than 25 years ago, the responsible gene has remained elusive so far. As an experimental proof of concept for a gap-filling algorithm for metabolic networks developed earlier, we demonstrate here that the E. coli gene yneI is responsible for this activity. Our biochemical results demonstrate that the yneI-encoded succinate semialdehyde dehydrogenase can use either NAD⁺ or NADP⁺ to oxidize succinate semialdehyde to succinate. The gene is induced by succinate semialdehyde, and expression data indicate that yneI plays a unique physiological role in the general nitrogen metabolism of E. coli. In particular, we demonstrate using mutant growth experiments that the yneI gene has an important, but not essential, role during growth on arginine and probably has an essential function during growth on putrescine as the nitrogen source. The NADP⁺-dependent succinate semialdehyde dehydrogenase activity encoded by the functional homolog gabD appears to be important for nitrogen metabolism under N limitation conditions. The yneI-encoded activity, in contrast, functions primarily as a valve to prevent toxic accumulation of succinate semialdehyde. Analysis of available genome sequences demonstrated that orthologs of both yneI and gabD are broadly distributed across phylogenetic space.     

The effect of 4-hydroxy-2, 3-trans-pent-en-1-al and maleylaldehyde on some mitochondrial functions

Low concentrations of HPE and MLA inhibited state 3 respiration of rat liver mitochondria in the presence of different NAD⁺-dependent substrates. MLA appeared to be more active than HPE. High aldehyde concentrations inhibited the state 3 respiration with succinate. The restraint of succinate oxidation by HPE and MLA and of glutamate plus malate oxidation by MLA correlated with the inhibition of succinate and glutamate dehydrogenase activites, respectively. HPE inhibited glutamate dehydrogenase at concentrations higher than those affecting glutamate oxidation. Malate dehydrogenase activity was slightly sensitive to HPE and MLA. Both aldehydes inhibited NADH oxidation by freeze-thawed mitochondria. These results suggest the existence of a site particularly sensitive to aldehydes in the electron transport chain between the specific NAD⁺-linked dehydrogenases and ubiquinone.     

Kinetic and Structural Characterization for Cofactor Preference of Succinic Semialdehyde Dehydrogenase from Streptococcus pyogenes

The γ-Aminobutyric acid (GABA) that is found in prokaryotic and eukaryotic organisms has been used in various ways as a signaling molecule or a significant component generating metabolic energy under conditions of nutrient limitation or stress, through GABA catabolism. Succinic semialdehyde dehydrogenase (SSADH) catalyzes the oxidation of succinic semialdehyde to succinic acid in the final step of GABA catabolism. Here, we report the catalytic properties and two crystal structures of SSADH from Streptococcus pyogenes (SpSSADH) regarding its cofactor preference. Kinetic analysis showed that SpSSADH prefers NADP⁺ over NAD⁺ as a hydride acceptor. Moreover, the structures of SpSSADH were determined in an apo-form and in a binary complex with NADP⁺ at 1.6 Å and 2.1 Å resolutions, respectively. Both structures of SpSSADH showed dimeric conformation, containing a single cysteine residue in the catalytic loop of each subunit. Further structural analysis and sequence comparison of SpSSADH with other SSADHs revealed that Ser158 and Tyr188 in SpSSADH participate in the stabilization of the 2’-phosphate group of adenine-side ribose in NADP⁺. Our results provide structural insights into the cofactor preference of SpSSADH as the gram-positive bacterial SSADH.     

Cloning,characterization, and mutational analysis of a highly active and stable <Emphasis Type="SmallCaps">l</Emphasis>-arabinitol 4-dehydrogenase from <Emphasis Type="Italic">Neurospora crassa</Emphasis>

An NAD⁺-dependent l-arabinitol 4-dehydrogenase (LAD, EC 1.1.1.12) from Neurospora crassa was cloned and expressed in Escherichia coli and purified to homogeneity. The enzyme was a homotetramer and contained two Zn²⁺ ions per subunit, displaying similar characteristics to medium-chain sorbitol dehydrogenases (SDHs). High enzymatic activity was observed for substrates l-arabinitol, adonitol, and xylitol and no activity for d-mannitol, d-arabinitol, or d-sorbitol. The enzyme showed strong preference for NAD⁺ but also displayed a very low yet detectable activity with NADP⁺. Mutational analysis of residue F59, the single different substrate-binding residue between LADs and d-SDHs, failed to confer the enzyme the ability to accept d-sorbitol as a substrate, suggesting that the amino acids flanking the active site cleft may be responsible for the different activity and affinity patterns between LADs and SDHs. This enzyme should be useful for in vivo and in vitro production of xylitol and ethanol from l-arabinose. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

X-Ray crystal structure of GarR—tartronate semialdehyde reductase from Salmonella typhimurium

Tartronate semialdehyde reductases (TSRs), also known as 2-hydroxy-3-oxopropionate reductases, catalyze the reduction of tartronate semialdehyde using NAD as cofactor in the final stage of d-glycerate biosynthesis. These enzymes belong to family of structurally and mechanically related β-hydroxyacid dehydrogenases which differ in substrate specificity and catalyze reactions in specific metabolic pathways. Here, we present the crystal structure of GarR a TSR from Salmonella typhimurium determined by the single-wavelength anomalous diffraction method and refined to 1.65 Å resolution. The active site of the enzyme contains l-tartrate which most likely mimics a position of a glycerate which is a product of the enzyme reaction. The analysis of the TSR structure shows also a putative NADPH binding site in the enzyme.     

Mechanisms of citrate oxidation by percoll-purified mitochondria from potato tuber

The mechanisms and accurate control of citrate oxidation by Percoll-purified potato (Solanum tuberosum) tuber mitochondria were characterized in various metabolic conditions by recording time course evolution of the citric acid cycle related intermediates and O₂ consumption. Intact potato tuber mitochondria showed good rates of citrate oxidation, provided that nonlimiting amounts of NAD⁺ and thiamine pyrophosphate were present in the matrix space. Addition of ATP increased initial oxidation rates, by activation of the energy-dependent net citrate uptake, and stimulated succinate and malate formation. When the intramitochondrial NADH to NAD⁺ ratio was high, α-ketoglutarate only was excreted from the matrix space. After addition of ADP, aspartate, or oxaloacetate, which decreased the NADH to NAD⁺ ratio, flux rates through the Krebs cycle dehydrogenases were strongly increased and α-ketoglutarate, succinate, and malate accumulated up to steady-state concentrations in the reaction medium. It was concluded that NADH to NAD⁺ ratio could be the primary signal for coordination of fluxes through electron transport chain or malate dehydrogenase and NAD⁺-linked Krebs cycle dehydrogenases. In addition, these results clearly showed that the tricarboxylic acid cycle could serve as an important source of carbon skeletons for extra-mitochondrial synthetic processes, according to supply and demand of metabolites.     

Identification and characterization of Klebsiella pneumoniae aldehyde dehydrogenases increasing production of 3-hydroxypropionic acid from glycerol

Klebsiella pneumoniae produces 3-hydroxypropionic acid (3-HP) from glycerol with oxidation of 3-hydroxypropionaldehyde (3-HPA) to 3-HP in a reaction catalyzed by aldehyde dehydrogenase (ALDH). In the present study, two putative ALDHs of K. pneumoniae, YneI and YdcW were identified and characterized. Recombinant YneI was specifically active on 3-HPA and preferred NAD⁺ as a cofactor, whereas YdcW exhibited broad substrate specificity and preferred NADP⁺ as a cofactor. Overexpression of ALDHs in the glycerol oxidative pathway-deficient mutant K. pneumoniae AK resulted in a significant increase in 3-HP production upon shake-flask culture. The final titers of 3-HP were 2.4 and 1.8 g L^?1 by recombinants overexpressing YneI and YdcW, respectively. Deletion of the ALDH gene from K. pneumoniae did not affect the extent of 3-HP synthesis, implying non-specific activity of ALDHs on 3-HPA. The ALDHs might play major roles in detoxifying the aldehyde generated in glycerol metabolism.     

Comparison of the Kinetic Behavior toward Pyridine Nucleotides of NAD-Linked Dehydrogenases from Plant Mitochondria

In this article we compare the kinetic behavior toward pyridine nucleotides (NAD⁺, NADH) of NAD⁺-malic enzyme, pyruvate dehydrogenase, isocitrate dehydrogenase, α-ketoglutarate dehydrogenase, and glycine decarboxylase extracted from pea (Pisum sativum) leaf and potato (Solanum tuberosum) tuber mitochondria. NADH competitively inhibited all the studied dehydrogenases when NAD⁺ was the varied substrate. However, the NAD⁺-linked malic enzyme exhibited the weakest affinity for NAD⁺ and the lowest sensitivity for NADH. It is suggested that NAD⁺-linked malic enzyme, when fully activated, is able to raise the matricial NADH level up to the required concentration to fully engage the rotenone-resistant internal NADH-dehydrogenase, whose affinity for NADH is weaker than complex I.     

Heteroexpression and characterization of a monomeric isocitrate dehydrogenase from the multicellular prokaryote <Emphasis Type="Italic">Streptomyces avermitilis</Emphasis> MA-4680

A monomeric NADP-dependent isocitrate dehydrogenase from the multicellular prokaryote Streptomyces avermitilis MA-4680 (SaIDH) was heteroexpressed in Escherichia coli, and the His-tagged enzyme was further purified to homogeneity. The molecular weight of SaIDH was about 80 kDa which is typical for monomeric isocitrate dehydrogenases. Structure-based sequence alignment reveals that the deduced amino acid sequence of SaIDH shows high sequence identity with known momomeric isocitrate dehydrogenase, and the coenzyme, substrate and metal ion binding sites are completely conserved. The optimal pH and temperature of SaIDH were found to be pH 9.4 and 45°C, respectively. Heat-inactivation studies showed that heating for 20 min at 50°C caused a 50% loss in enzymatic activity. In addition, SaIDH was absolutely specific for NADP⁺ as electron acceptor. Apparent K _m values were 4.98 μM for NADP⁺ and 6,620 μM for NAD⁺, respectively, using Mn²⁺ as divalent cation. The enzyme performed a 33,000-fold greater specificity (k _cat/K _m) for NADP⁺ than NAD⁺. Moreover, SaIDH activity was entirely dependent on the presence of Mn²⁺ or Mg²⁺, but was strongly inhibited by Ca²⁺ and Zn²⁺. Taken together, our findings implicate the recombinant SaIDH is a divalent cation-dependent monomeric isocitrate dehydrogenase which presents a remarkably high cofactor preference for NADP⁺.     

Glutamate Dehydrogenases: The Why and How of Coenzyme Specificity

NAD⁺ and NADP⁺, chemically similar and with almost identical standard oxidation–reduction potentials, nevertheless have distinct roles, NAD⁺ serving catabolism and ATP generation whereas NADPH is the biosynthetic reductant. Separating these roles requires strict specificity for one or the other coenzyme for most dehydrogenases. In many organisms this holds also for glutamate dehydrogenases (GDH), NAD⁺-dependent for glutamate oxidation, NADP⁺-dependent for fixing ammonia. In higher animals, however, GDH has dual specificity. It has been suggested that GDH in mitochondria reacts only with NADP(H), the NAD⁺ reaction being an in vitro artefact. However, contrary evidence suggests mitochondrial GDH not only reacts with NAD⁺ but maintains equilibrium using the same pool as accessed by β-hydroxybutyrate dehydrogenase. Another complication is the presence of an energy-linked dehydrogenase driving NADP⁺ reduction by NADH, maintaining the coenzyme pools at different oxidation–reduction potentials. Its coexistence with GDH makes possible a futile cycle, control of which is not yet properly explained. Structural studies show NAD⁺-dependent, NADP⁺-dependent and dual-specificity GDHs are closely related and a few site-directed mutations can reverse specificity. Specificity for NAD⁺ or for NADP⁺ has probably emerged repeatedly during evolution, using different structural solutions on different occasions. In various GDHs the P7 position in the coenzyme-binding domain plays a key role. However, whereas in other dehydrogenases an acidic P7 residue usually hydrogen bonds to the 2′- and 3′-hydroxyls, dictating NAD⁺ specificity, among GDHs, depending on detailed conformation of surrounding residues, an acidic P7 may permit binding of NAD⁺ only, NADP⁺ only, or in higher animals both.     

Steric hindrance controls pyridine nucleotide specificity of a flavin‐dependent NADH:quinone oxidoreductase

The crystal structure of the NADH:quinone oxidoreductase PA1024 has been solved in complex with NAD⁺ to 2.2 Å resolution. The nicotinamide C4 is 3.6 Å from the FMN N5 atom, with a suitable orientation for facile hydride transfer. NAD⁺ binds in a folded conformation at the interface of the TIM‐barrel domain and the extended domain of the enzyme. Comparison of the enzyme‐NAD⁺ structure with that of the ligand‐free enzyme revealed a different conformation of a short loop (75–86) that is part of the NAD⁺‐binding pocket. P78, P82, and P84 provide internal rigidity to the loop, whereas Q80 serves as an active site latch that secures the NAD⁺ within the binding pocket. An interrupted helix consisting of two α‐helices connected by a small three‐residue loop binds the pyrophosphate moiety of NAD⁺. The adenine moiety of NAD⁺ appears to π–π stack with Y261. Steric constraints between the adenosine ribose of NAD⁺, P78, and Q80, control the strict specificity of the enzyme for NADH. Charged residues do not play a role in the specificity of PA1024 for the NADH substrate.     

Kinetic properties of N-(2-carboxyethyl)-NAD(H) and poly(ethylene glycol)-bound NAD(H) for alcohol, lactate, malate and glyceraldehyde-3-phosphate dehydrogenase from different organisms

The steady-state kinetics of alcohol dehydrogenases (alcohol:NAD⁺ oxidoreductase, EC 1.1.1.1 and alcohol:NADP⁺ oxidoreductase, EC 1.1.1.2), lactate dehydrogenases (l-lactate:NAD⁺ oxidoreductase, EC 1.1.1.27 and d-lactate:NAD⁺ oxidoreductase, EC 1.1.1.28), malate dehydrogenase (l-malate:NAD⁺ oxidoreductase, EC 1.1.1.37), and glyceraldehyde-3-phosphate dehydrogenases [d-glyceraldehyde-3-phosphate:NAD⁺ oxidoreductase (phosphorylating), EC 1.2.1.12] from different sources (prokaryote and eukaryote, mesophilic and thermophilic organisms) have been studied using NAD(H), N⁶-(2-carboxyethyl)-NAD(H), and poly(ethylene glycol)-bound NAD(H) as coenzymes. The kinetic constants for NAD(H) were changed by carboxyethylation of the 6-amino group of the adenine ring and by conversion to macromolecular form. Enzymes from thermophilic bacteria showed especially high activities for the derivatives. The relative values of the maximum velocity (NAD = 1) of Thermus thermophilus malate dehydrogenase for N⁶-(2-carboxyethyl)-NAD and poly(ethylene glycol)-bound NAD were 5.7 and 1.9, respectively, and that of Bacillus stearothermophilus glyceraldehyde-3-phosphate dehydrogenase for poly(ethylene glycol)-bound NAD was 1.9.     

Two malate dehydrogenases in Methanobacterium thermoautotrophicum

Methanobacterium thermoautotrophicum (strain Marburg) was found to contain two malate dehydrogenases, which were partially purified and characterized. One was specific for NAD⁺ and catalyzed the dehydrogenation of malate at approximately one-third of the rate of oxalacetate reduction, and the other could equally well use NAD⁺ and NADP⁺ as coenzyme and catalyzed essentially only the reduction of oxalacetate. Via the N-terminal amino acid sequences, the encoding genes were identified in the genome of M. thermoautotrophicum (strain ΔH). Comparison of the deduced amino acid sequences revealed that the two malate dehydrogenases are phylogenetically only distantly related. The NAD⁺-specific malate dehydrogenase showed high sequence similarity to l-malate dehydrogenase from Methanothermus fervidus, and the NAD(P)⁺-using malate dehyrogenase showed high sequence similarity to l-lactate dehydrogenase from Thermotoga maritima and l-malate dehydrogenase from Bacillus subtilis. A function of the two malate dehydrogenases in NADPH:NAD⁺ transhydrogenation is discussed. Received: 29 December 1997 / Accepted: 4 March 1998     

Metabolism of acetaldehyde and Custers effect in the yeast

Brettanomyces abstinens growing on different initial glucose concentrations showed an anaerobic inhibition of fermentation. This Custers effect decreased as the initial glucose concentration in the medium increased. Two aldehyde dehydrogenases, one NAD⁺-linked and the other NADP⁺-linked were observed. The results suggest that the NAD⁺-linked enzyme is involved in the production of acetic acid and is repressed by glucose. The NADP⁺-linked enzyme seems to be a constitutive enzyme. Acetyl-CoA synthetase activity also was not greatly affected by the growth conditions.The results support the earlier hypothesis that the Custers effect in Brettanomyces is provoked by the reduction of NAD⁺ in the conversion of acetaldehyde to acetic acid.