Regulation of Acetate Metabolism in a Strain of Acinetobacter sp. Growing on Ethanol

Ethanol metabolism in Acinetobacter sp. is shown to be limited by the rate of acetate assimilation, a reaction catalyzed by acetyl-CoA synthetase (EC 6.2.1.1). Effects of ions (sodium, potassium, and magnesium), by-products of ethanol and acetaldehyde oxidation (NADH and NADPH), and pantothenic acid on this enzyme are studied (sodium, NADH, and NADPH inhibit acetyl-CoA synthetase; pantothenic acid, potassium, and magnesium act as enzyme activators). Conditions of culturing were developed under which ethanol, acetaldehyde, and acetate in Acinetobacter cells were oxidized at the same rates, producing a threefold increase in the activity of acetyl-CoA synthetase in the cell-free extract. The results of studies of acetyl-CoA synthetase regulation in a mutant strain of Acinetobacter sp., which is incapable of forming exopolysaccharides, provide a basis for refining the technology of ethapolan production involving the use of C₂ substrates.     

Escherichia coli coenzyme A-transferase: Kinetics,catalytic pathway and structure

The inducible acetyl-CoA:acetoacetate CoA-transferase of Escherichia coli catalyzes the transfer of CoA from acetyl-CoA to acetoacetate by a mechanism involving a covalent enzyme-CoA compound as a reaction intermediate. Acetyl-CoA + enzyme ? enzyme-CoA + Acetate Enzyme-CoA + acetoacetate ? acetoacetyl-CoA + enzyme These conclusions are based on the following data: 1) In the absence of acetoacetate, the maximal velocity of exchange of [¹⁴C]acetate into acetyl-CoA was comparable with maximal velocity of the complete reaction. 2) Incubation of the enzyme with NaBH₄ after preincubation with an acyl-CoA substrate inactivated the enzyme by reduction of a glutamate residue in the β subunit of the CoA-transferase to α-amino-δ-hydroxyvaleric acid. Given the susceptibility of thioesters to borohydride reduction, the enzyme-CoA bond is a γ-glutamyl thiolester 3) Following incubation of the enzyme with a fluorescent derivative of acetyl-CoA, 1,N⁶-ethenoacetyl-CoA, etheno-CoA was bound to the CoA-transferase. Free etheno-CoA did not bind to the enzyme.     

Effect of acetaldehyde and cyanamide on the metabolism of formaldehyde by hepatocytes, mitochondria, and soluble supernatant from rat liver

Formaldehyde can be metabolized primarily by two different pathways, one involving oxidation by the low-Km mitochondrial aldehyde dehydrogenase, the other involving a specific, glutathione-dependent, formaldehyde dehydrogenase. To estimate the roles played by each enzyme in formaldehyde metabolism by rat hepatocytes, experiments with acetaldehyde and cyanamide, a potent inhibitor of the low-Km aldehyde dehydrogenase were carried out. The glutathione-dependent oxidation of formaldehyde by 100,000g rat liver supernatant fractions was not affected by either acetaldehyde or by cyanamide. By contrast, the uptake of formaldehyde by intact mitochondria was inhibited 75 to 90% by cyanamide. Acetaldehyde inhibited the uptake of formaldehyde by mitochondria in a competitive fashion. Formaldehyde was a weak inhibitor of the oxidation of acetaldehyde by mitochondria, suggesting that, relative to formaldehyde, acetaldehyde was a preferred substrate. In isolated hepatocytes, cyanamide, which inhibited the oxidation of acetaldehyde by 75 to 90%, produced only 30 to 50% inhibition of formaldehyde uptake by cells as well as of the production of 14CO2 and of formate from [14C]formaldehyde. The extent of inhibition by cyanamide was the same as that produced by acetaldehyde (30-40%). In the presence of cyanamide, acetaldehyde was no longer inhibitory, suggesting that acetaldehyde and cyanamide may act at the same site(s) and inhibit the same formaldehyde-oxidizing enzyme system. These results suggest that, in rat hepatocytes, formaldehyde is oxidized by cyanamide- and acetaldehyde-sensitive (low-Km aldehyde dehydrogenase) and insensitive (formaldehyde dehydrogenase) reactions, and that both enzymes appear to contribute about equally toward the overall metabolism of formaldehyde.     

Characterization of enzymes involved in the ethanol production of <Emphasis Type="Italic">Moorella</Emphasis> sp. HUC22-1

Since the thermophilic bacterium Moorella sp. HUC22-1 produces 120 mM acetate and 5.2 mM ethanol from H₂–CO₂, several candidate genes, which were predicted to code for three alcohol dehydrogenases (AdhA, B, C) and one acetaldehyde dehydrogenase (Aldh), were cloned from HUC22-1. The cloned genes were subcloned into a His-tagged expression vector and expressed in Escherichia coli. Recombinant AdhA and B were both dependent on NADP(H) but independent of NAD(H), and their reduction activities from aldehyde to alcohol were higher than their oxidation activities. In contrast with AdhA and B, no activity of AdhC was observed in either reaction. On the other hand, Aldh was active toward both NADP(H) and NAD(H). The enzyme activity of Aldh was directed toward the thioester cleavage and the thioester condensation. When 50 μg of AdhA and 50 μg Aldh were added to the buffer solution (pH 8.0) containing NADPH, NADH and acetyl-CoA at 60°C, 1.6 mM ethanol was produced from 3 mM acetyl-CoA after 90 min. Expression analysis of the mRNAs revealed that the expression level of aldh was threefold higher in the H₂–CO₂ culture than that in the fructose culture, but levels of adhA, B and C were decreased.     

Physiological role of yeasts NAD(P)+ and NADP+-linked aldehyde dehydrogenases.

The activity of NAD+ and NADP+-linked aldehyde dehydrogenases has been investigated in yeast cells grown under different conditions. As occurs in other dehydrogenase reactions the NAD(P)+-linked enzyme was strongly repressed in all hypoxic conditions; nervetheless, the NADP+-linked enzyme was active. The results suggest that the NAD(P)+ aldehyde dehydrogenase is involved in the oxidation of ethanol to acetyl-CoA, and that when the pyruvate dehydrogenase complex is repressed the NADP+-linked aldehyde dehydrogenase is operative as an alternative pathway from pyruvate to acetyl-CoA: pyruvate leads to acetaldehyde leads to acetate leads to acetyl-Coa. In these conditions the supply of NADPH is advantageous to the cellular economy for biosynthetic purposes. Short term adaptation experiments suggest that the regulation of the levels of the aldehyde dehydrogenase-NAD(P)+ takes place by the de novo synthesis of the enzyme.     

Purification and characterization of grass carp mitochondrial aldehyde dehydrogenase

The molecular biology and enzymology of aldehyde dehydrogenase (ALDH) have been extensively investigated. However, most of the studies have been confined to the mammalian forms, while the sub-mammalian vertebrate ALDHs are relatively unexplored. In the present investigation, an ALDH was purified from the hepatopancreas of grass carp (Ctenopharygodon idellus) by affinity chromatographies on α-cyanocinnamate-Sepharose and Affi-gel Blue agarose. The 800-fold purified enzyme had a specific activity of 4.46 U/mg toward the oxidation of acetaldehyde at pH 9.5. It had a subunit molecular weight of 55 000. Isoelectric focusing showed a single band with a pI of 5.3. N-terminal amino acid sequencing of 30 residues revealed a positional identity of ∼70% with mammalian mitochondrial ALDH2. The kinetic properties of grass carp ALDH resembled those of mammalian ALDH2. The optimal pH for the oxidation of acetaldehyde was 9.5. The K_m values for acetaldehyde were 0.36 and 0.31 μM at pH 7.5 and 9.5, respectively. Grass carp ALDH also possessed esterase activity which could be activated in the presence of NAD⁺.     

Regulation of acetate metabolism in a strain of Acinetobacter sp., growing on ethanol

Ethanol metabolism in Acinetobacter sp. is limited by the rate of acetate assimilation in a reaction catalyzed by acetyl-CoA synthetase (EC 6.2.1.1). Effects of ions (sodium, potassium, and magnesium), byproducts of ethanol and acetaldehyde oxidation (NADH and NADPH), and pantothenic acid on this enzyme have been studied (sodium, NADH, and NADPH inhibit acetyl-CoA synthetase; pantothenic acid, potassium, and magnesium act as the enzyme activators). Conditions of culturing were developed, under which ethanol, acetaldehyde, and acetate in Acinetobacter cells were oxidized at the same rates, producing a threefold increase in the activity of acetyl-CoA synthetase in the cell-free extract. The results of studies of acetyl-CoA synthetase regulation in a mutant strain of Acinetobacter sp., which is incapable of forming exopolysaccharides, provide a basis for refining the technology of ethapolan production, involving the use of C2 substrates.     

Inhibition of the oxidation of acetaldehyde and formaldehyde by hepatocytes and mitochondria by crotonaldehyde

Crotonaldehyde was oxidized by disrupted rat liver mitochondrial fractions or by intact mitochondria at rates that were only 10 to 15% that of acetaldehyde. Although a poor substrate for oxidation, crotonaldehyde is an effective inhibitor of the oxidation of acetaldehyde by mitochondrial aldehyde dehydrogenase, by intact mitochondria, and by isolated hepatocytes. Inhibition by crotonaldehyde was competitive with respect to acetaldehyde, and the Ki for crotonaldehyde was about 5 to 20 microM. Crotonaldehyde had no effect on the oxidation of glutamate or succinate. Very low levels of acetaldehyde were detected during the metabolism of ethanol. Crotonaldehyde increased the accumulation of acetaldehyde more than 10-fold, indicating that crotonaldehyde, besides inhibiting the oxidation of added acetaldehyde, also inhibited the oxidation of acetaldehyde generated by the metabolism of ethanol. Formaldehyde was a substrate for the low-Km mitochondrial aldehyde dehydrogenase, as well as for a cytosolic, glutathione-dependent formaldehyde dehydrogenase. Crotonaldehyde was a potent inhibitor of mitochondrial oxidation of formaldehyde, but had no effect on the activity of formaldehyde dehydrogenase. In hepatocytes, crotonaldehyde produced about 30 to 40% inhibition of formaldehyde oxidation, which was similar to the inhibition produced by cyanamide. This suggested that part of the formaldehyde oxidation occurred via the mitochondrial aldehyde dehydrogenase, and part via formaldehyde dehydrogenase. The fact that inhibition by crotonaldehyde is competitive may be of value since other commonly used inhibitors of aldehyde dehydrogenase are irreversible inhibitors of the enzyme.     

Acetate-Activating Enzymes of Bradyrhizobium japonicum Bacteroids

Acetyl coenzyme A (acetyl-CoA) synthetase and acetate kinase were localized within the soluble portion of Bradyrhizobium japonicum bacteroids, and no appreciable activity was found elsewhere in the nodule. The presence of each acetate-activating enzyme was confirmed by separation of the two enzyme activities on a hydroxylapatite column, by substrate dependence of each enzyme in both the forward and reverse directions, by substrate specificity, by inhibition patterns, and also by identification of the reaction products by C₁₈ reverse-phase high-pressure liquid chromatography. Phosphotransacetylase activity, found in the soluble portion of the bacteroid, was dependent on the presence of potassium and was inhibited by added sodium. The greatest acetyl-CoA hydrolase activity was found in the root nodule cytosol, although appreciable activity also was found within the bacteroids. The combined specific activities of acetyl-CoA synthetase and acetate kinase-phosphotransacetylase were approximate to that of the pyruvate dehydrogenase complex, thus providing B. japonicum with sufficient capacity to generate acetyl-CoA.     

Formaldehyde dehydrogenase from Pseudomonas putida. Purification and some properties

Formaldehyde dehydrogenase was isolated and purified in an overall yield of 12% from cell-free extract of Pseudomonas putida C-83 by chromatographies on columns of DEAE-cellulose, DEAE-Sephadex A-50, and hydroxyapatite. The purified enzyme was homogeneous as judged by disc gel electrophoresis and was most active at pH 7.8 using formaldehyde as a substrate. The enzyme was also active toward acetaldehyde, propionaldehyde, glyoxal, and pyruvaldehyde, though the reaction rates were low. The enzyme was NAD+-linked but did not require the external addition of glutathione, in contrast with the usual formaldehyde dehydrogenase from liver mitochondria, baker's yeast, and some bacteria. The enzyme was markedly inhibited by Ni2+, Pd2+, Hg2+, p-chloromercuribenzoate, and phenylmethanesulfonyl fluoride. The molecular weight of the enzyme was estimated to be 150,000 by the gel filtration method, and analysis by SDS-polyacrylamide gel electrophoresis indicated that the enzyme was composed of two subunit monomers. Kinetic analysis gave Km values of 67 microM for formaldehyde and 56 microM for NAD+, and suggested that the reaction proceeds by a "Ping-pong" mechanism. The enzyme catalyzed the oxidation of formaldehyde accompanied by the stoichiometric reduction of NAD+, but no reverse reaction was observed.     

Degradation of Acetaldehyde and Its Precursors by Pelobacter carbinolicus and P. acetylenicus

Pelobacter carbinolicus and P. acetylenicus oxidize ethanol in syntrophic cooperation with methanogens. Cocultures with Methanospirillum hungatei served as model systems for the elucidation of syntrophic ethanol oxidation previously done with the lost “Methanobacillus omelianskii” coculture. During growth on ethanol, both Pelobacter species exhibited NAD⁺-dependent alcohol dehydrogenase activity. Two different acetaldehyde-oxidizing activities were found: a benzyl viologen-reducing enzyme forming acetate, and a NAD⁺-reducing enzyme forming acetyl-CoA. Both species synthesized ATP from acetyl-CoA via acetyl phosphate. Comparative 2D-PAGE of ethanol-grown P. carbinolicus revealed enhanced expression of tungsten-dependent acetaldehyde: ferredoxin oxidoreductases and formate dehydrogenase. Tungsten limitation resulted in slower growth and the expression of a molybdenum-dependent isoenzyme. Putative comproportionating hydrogenases and formate dehydrogenase were expressed constitutively and are probably involved in interspecies electron transfer. In ethanol-grown cocultures, the maximum hydrogen partial pressure was about 1,000 Pa (1 mM) while 2 mM formate was produced. The redox potentials of hydrogen and formate released during ethanol oxidation were calculated to be E_H2 = -358±12 mV and E_HCOOH = -366±19 mV, respectively. Hydrogen and formate formation and degradation further proved that both carriers contributed to interspecies electron transfer. The maximum Gibbs free energy that the Pelobacter species could exploit during growth on ethanol was −35 to −28 kJ per mol ethanol. Both species could be cultivated axenically on acetaldehyde, yielding energy from its disproportionation to ethanol and acetate. Syntrophic cocultures grown on acetoin revealed a two-phase degradation: first acetoin degradation to acetate and ethanol without involvement of the methanogenic partner, and subsequent syntrophic ethanol oxidation. Protein expression and activity patterns of both Pelobacter spp. grown with the named substrates were highly similar suggesting that both share the same steps in ethanol and acetalydehyde metabolism. The early assumption that acetaldehyde is a central intermediate in Pelobacter metabolism was now proven biochemically.     

Enzymes involved in the anoxic utilization of phenyl methyl ethers by <Emphasis Type="Italic">Desulfitobacterium hafniense</Emphasis> DCB2 and <Emphasis Type="Italic">Desulfitobacterium hafniense</Emphasis> PCE-S

Phenyl methyl ethers are utilized by Desulfitobacterium hafniense DCB2 and Desulfitobacterium hafniense PCE-S; the methyl group derived from the O-demethylation of these substrates can be used as electron donor for anaerobic fumarate respiration or dehalorespiration. The activity of all enzymes involved in the oxidation of the methyl group to carbon dioxide via the acetyl-CoA pathway was detected in cell extracts of both strains. In addition, a carbon monoxide dehydrogenase activity could be detected. Activity staining of this enzyme indicated that the enzyme is a bifunctional CO dehydrogenase/acetyl-CoA synthase.     

Resiniferonol-related Diterpene Esters from Daphne odora Thunb. and their Ornithine Decarboxylase-inducing Activity in Mouse Skin

Phosphoenolpyruvate (PEP) carboxylase purified from Brevibacterium flavum was specifically activated by fructose 1,6-bisphosphate (FBP). The other intermediates of sugar metabolism or their structural analogues did not influence the activity. FBP decreased the apparent Km for PEP but did not affect that for another substrate, bicarbonate, or the apparent maximum velocity for PEP. The dissociation constants for FBP from enzyme-FBP and enzyme-PEP-FBP complex were 63 and 32 μm, respectively, being almost equivalent to those for acetyl-CoA. Synergistic activation by FBP and acetyl-CoA was not observed with the B. flavum enzyme, unlike the Escherichia coli enzyme. FBP, like acetyl-CoA, was kinetically competitive with aspartate. With respect to another feedback inhibitor, 2-oxoglutarate, acetyl-CoA was non-competitive, whereas FBP was of mixed-type, i.e., FBP but not acetyl-CoA prevented 2-oxoglutarate from binding to the enzyme to a certain extent. Homotropic cooperativity was observed only with FBP but not with acetyl-CoA in the absence of inhibitors. Cooperativities of FBP and acetyl-CoA were increased by aspartate but not by 2-oxoglutarate. In the aspartate-overproducing mutant enzyme, the Michaelis constant for PEP was decreased, whereas the inhibitor constant for aspartate with or without simultaneous addition of 2-oxoglutarate and the activator constants for FBP and acetyl-CoA were increased. The decreased Michaelis constant for PEP was comparable to the apparent Km of the wild-type enzyme for PEP in the presence of the saturated concentration of FBP, and would result in a further decrease in the affinity of the mutant enzyme for aspartate.     

Purification,properties, and kinetic mechanism of coenzyme A-linked aldehyde dehydrogenase from Clostridium kluyveri

Coenzyme A-linked aldehyde dehydrogenase from Clostridium kluyveri was purified from the soluble fraction of crude extracts and its physical and kinetic properties were studied. The enzyme was purified approximately 90-fold over crude extracts to a specific activity of 50 units/mg protein and was estimated to be 40% pure by polyacrylamide gel electrophoresis. From active enzyme centrifugation studies, aldehyde dehydrogenase was found to have a sedimentation coefficient of s_{20, w} = 7.4. The Stokes radius of the enzyme was determined by gel filtration and found to be 9.5 nm in the presence of substrates and 11.0 nm in the absence of substrates. Using the values found for the sedimentation coefficient and the Stokes radius, the molecular weight of the enzyme in the presence of substrates was calculated to be 290,000 and the frictional ratio, 2.2. Aldehyde dehydrogenase can utilize thiols other than CoA as acetyl acceptors. A number of methods were employed in order to exclude the possibility that these thiols act merely by recycling nonenzymatically trace amounts of CoA that might be in the enzyme preparation. From steady-state kinetic measurements, a ping pong mechanism was proposed in which NAD⁺ binds to free enzyme, acetaldehyde binds next, and NADH is released before CoA binds and acetyl-CoA released. At K_m levels of other substrates, substrate inhibition by CoA was observed. The nature of the substrate inhibition is discussed.     

Uncompetitive inhibition of Xenopus laevis aldehyde dehydrogenase 1A1 by divalent cations

Aldehyde dehydrogenases (ALDHs) convert aldehydes into their corresponding carboxylic acids. ALDH1A1, also known as ALDH class 1 (ALDH1) or retinaldehyde dehydrogenase (RALDH1), prefers retinal to acetaldehyde as a substrate. To investigate the effects of divalent cations on the dehydrogenase activity of Xenopus laevis ALDH1A1, the formation of acetate and retinoic acid from acetaldehyde and retinal, respectively, was investigated in the presence of Ca2+, Mg2+, Mn2+ or Zn2+. All divalent cations tested inhibited the oxidation of acetaldehyde and retinal by ALDH1A1. When acetaldehyde was used as a substrate, the 50% inhibitory concentrations (IC50) were 10, 24, 35 and 220 microM for Zn2+, Mn2+, Mg2+ and Ca2+, respectively. Kinetic studies of ALDH1A1 dehydrogenase activity in the presence or absence of each cation revealed that the inhibition mode by cations was uncompetitive against acetaldehyde, retinal, and NAD+, and that their inhibitory potencies were greater against acetaldehyde than retinal. It was concluded that the divalent cations inhibited X. laevis ALDH1A1 activity in a substrate-dependent manner by affecting a step of the dehydrogenase reaction that occurred after the formation of the ternary complex of the enzyme, substrate, and coenzyme.     

Effect of fatty acids and ketones on the activity of pyruvate dehydrogenase in skeletal-muscle mitochondria.

The presence of palmitoyl-L-carnitine and acetoacetate (separately) decreased flux through pyruvate dehydrogenase in isolated mitochondria from rat hind-limb muscle. The effect of acetoacetate was dependent on the presence of 2-oxoglutarate and Ca2+. Palmitoylcarnitine, but not acetoacetate, also decreased the mitochondrial content of active dephospho-pyruvate dehydrogenase (PDHA). This effect was large only in the presence of EGTA. Addition of Ca2+-EGTA buffers stabilizing pCa values of 6.48 or lower gave near-maximal values of PDHA content, irrespective of the presence of fatty acids or ketones when mitochondria were incubated under the same conditions used for the flux studies, i.e. at low concentrations of pyruvate. There was, however, a minor decrement in PDHA content in response to palmitoylcarnitine oxidation when the substrate was L-glutamate plus L-malate. Measurement of NAD+, NADH, CoA and acetyl-CoA in mitochondrial extracts in general showed decreases in [NAD+]/[NADH] and [CoA]/[acetyl-CoA] ratios in response to the oxidation of palmitoylcarnitine and acetoacetate, providing a mechanism for both decreased PDHA content and feedback inhibition of the enzyme in the PDHA form. However, only changes in [CoA]/[acetyl-CoA] ratio appear to underlie the decreased PDHA content on addition of palmitoylcarnitine when mitochondria are incubated with L-glutamate plus L-malate (and no pyruvate) as substrate. The effect of palmitoylcarnitine oxidation on flux through pyruvate dehydrogenase and on PDHA content is less marked in skeletal-muscle mitochondria than in cardiac-muscle mitochondria. This may reflect the less active oxidation of palmitoylcarnitine by skeletal-muscle mitochondria, as judged by State-3 rates of O2 uptake. In addition, Ca2+ concentration is of even greater significance in pyruvate dehydrogenase interconversion in skeletal-muscle mitochondria than in cardiac-muscle mitochondria.     

Coenzyme A- and NADH-dependent esterase activity of methylmalonate semialdehyde dehydrogenase.

Methylmalonate semialdehyde dehydrogenase purified to homogeneity from rat liver possesses, in addition to its coupled aldehyde dehydrogenase and CoA ester synthetic activity, the ability to hydrolyze p-nitrophenyl acetate. The following observations suggest that this activity is an active site phenomenon: (a) p-nitrophenyl acetate hydrolysis was inhibited by malonate semialdehyde, substrate for the dehydrogenase reaction; (b) p-nitrophenyl acetate was a strong competitive inhibitor of the dehydrogenase activity; (c) NAD+ and NADH activated the esterase activity; (d) coenzyme A, acceptor of acyl groups in the dehydrogenase reaction, accelerated the esterase activity; and (e) the product of the esterase reaction proceeding in the presence of coenzyme A was acetyl-CoA. These findings suggest that an S-acyl enzyme (thioester intermediate) is likely common to both the esterase reaction and the aldehyde dehydrogenase/CoA ester synthetic reaction.     

Introduction of a bacterial acetyl-CoA synthesis pathway improves lactic acid production in Saccharomyces cerevisiae

Acid-tolerant Saccharomyces cerevisiae was engineered to produce lactic acid by expressing heterologous lactate dehydrogenase (LDH) genes, while attenuating several key pathway genes, including glycerol-3-phosphate dehydrogenase1 (GPD1) and cytochrome-c oxidoreductase2 (CYB2). In order to increase the yield of lactic acid further, the ethanol production pathway was attenuated by disrupting the pyruvate decarboxylase1 (PDC1) and alcohol dehydrogenase1 (ADH1) genes. Despite an increase in lactic acid yield, severe reduction of the growth rate and glucose consumption rate owing to the absence of ADH1 caused a considerable decrease in the overall productivity. In Δadh1 cells, the levels of acetyl-CoA, a key precursor for biologically applicable components, could be insufficient for normal cell growth. To increase the cellular supply of acetyl-CoA, we introduced bacterial acetylating acetaldehyde dehydrogenase (A-ALD) enzyme (EC 1.2.1.10) genes into the lactic acid-producing S. cerevisiae. Escherichia coli-derived A-ALD genes, mhpF and eutE, were expressed and effectively complemented the attenuated acetaldehyde dehydrogenase (ALD)/acetyl-CoA synthetase (ACS) pathway in the yeast. The engineered strain, possessing a heterologous acetyl-CoA synthetic pathway, showed an increased glucose consumption rate and higher productivity of lactic acid fermentation. The production of lactic acid was reached at 142 g/L with production yield of 0.89 g/g and productivity of 3.55 g L⁻¹ h⁻¹ under fed-batch fermentation in bioreactor. This study demonstrates a novel approach that improves productivity of lactic acid by metabolic engineering of the acetyl-CoA biosynthetic pathway in yeast.     

Subunit interactions in liver alcohol dehydrogenase: A partial alkylation study.

The transient kinetics of aldehyde reduction by NADH catalyzed by liver alcohol dehydrogenase consist of two kinetic processes. This biphasic rate behavior is consistent with a model in which one of the two identical subunits in the enzyme is inactive during the reaction at the adjacent protomer. Alternatively, enzyme heterogeneity could result in such biphasic behavior. We have prepared liver alcohol dehydrogenase containing a single major isozyme; and the transient kinetics of this purified enzyme are biphasic.Addition of two [¹⁴C]carboxymethyl groups per dimer to the two “reactive” sulfhydryl groups (Cys46) yields enzyme which is catalytically inactive toward alcohol oxidation. Alkylated enzyme, as initially isolated by gel filtration chromatography at pH 7·5, forms an NAD⁺-pyrazole complex. However, the ability to bind NAD⁺-pyrazole is rapidly lost in pH 8·75 buffer; therefore, our alkylated preparations, as isolated by chromatography at pH 8·75, are inactive toward NAD⁺-pyrazole complex formation. We have prepared partially inactivated enzyme by allowing iodoacetic acid to react with liver alcohol dehydrogenase until 50% of the NAD⁺-pyrazole binding capacity remains; under these reaction conditions one [¹⁴C]carboxymethyl group is added per dimer. This partially alkylated enzyme preparation is isolated by gel filtration and has been aged sufficiently to lose NAD⁺-pyrazole binding ability at alkylated subunits. When solutions of native liver alcohol dehydrogenase and partially alkylated liver alcohol dehydrogenase containing the same number of unmodified active sites are allowed to react with substrate under single turnover conditions, partially alkylated enzyme is only half as reactive as native enzyme. This indicates that some molecular species in partially alkylated liver alcohol dehydrogenase that react with pyrazole and NAD⁺ during the active site titration do not react with substrate. These data are consistent with a model in which a subunit adjacent to an alkylated protomer in the dimeric enzyme is inactive toward substrate. In addition, NAD⁺-pyrazole binding at the protomers adjacent to alkylated subunits is slowly lost so that 75% of the enzyme-NAD⁺-pyrazole binding capacity is lost in 50% alkylated enzyme. These data supply strong evidence for subunit interactions in liver alcohol dehydrogenase.Binding experiments performed on partially alkylated liver alcohol dehydrogenase indicate that coenzyme binding is normal at a subunit adjacent to an alkylated protomer even though active ternary complexes cannot be formed. One hypothesis consistent with these results is the unavailability of zinc for substrate binding at the active site in subunits adjacent to alkylated protomers in monoalkylated dimer.     

Enzymic analysis of the crabtree effect in glucose-limited chemostat cultures of Saccharomyces cerevisiae

The physiology of Saccharomyces cerevisiae CBS 8066 was studied in glucose-limited chemostat cultures. Below a dilution rate of 0.30 h-1 glucose was completely respired, and biomass and CO2 were the only products formed. Above this dilution rate acetate and pyruvate appeared in the culture fluid, accompanied by disproportional increases in the rates of oxygen consumption and carbon dioxide production. This enhanced respiratory activity was accompanied by a drop in cell yield from 0.50 to 0.47 g (dry weight) g of glucose-1. At a dilution rate of 0.38 h-1 the culture reached its maximal oxidation capacity of 12 mmol of O2 g (dry weight)-1 h-1. A further increase in the dilution rate resulted in aerobic alcoholic fermentation in addition to respiration, accompanied by an additional decrease in cell yield from 0.47 to 0.16 g (dry weight) g of glucose-1. Since the high respiratory activity of the yeast at intermediary dilution rates would allow for full respiratory metabolism of glucose up to dilution rates close to mumax, we conclude that the occurrence of alcoholic fermentation is not primarily due to a limited respiratory capacity. Rather, organic acids produced by the organism may have an uncoupling effect on its respiration. As a result the respiratory activity is enhanced and reaches its maximum at a dilution rate of 0.38 h-1. An attempt was made to interpret the dilution rate-dependent formation of ethanol and acetate in glucose-limited chemostat cultures of S. cerevisiae CBS 8066 as an effect of overflow metabolism at the pyruvate level. Therefore, the activities of pyruvate decarboxylase, NAD+- and NADP+-dependent acetaldehyde dehydrogenases, acetyl coenzyme A (acetyl-CoA) synthetase, and alcohol dehydrogenase were determined in extracts of cells grown at various dilution rates. From the enzyme profiles, substrate affinities, and calculated intracellular pyruvate concentrations, the following conclusions were drawn with respect to product formation of cells growing under glucose limitation. (i) Pyruvate decarboxylase, the key enzyme of alcoholic fermentation, probably already is operative under conditions in which alcoholic fermentation is absent. The acetaldehyde produced by the enzyme is then oxidized via acetaldehyde dehydrogenases and acetyl-CoA synthetase. The acetyl-CoA thus formed is further oxidized in the mitochondria. (ii) Acetate formation results from insufficient activity of acetyl-CoA synthetase, required for the complete oxidation of acetate. Ethanol formation results from insufficient activity of acetaldehyde dehydrogenases.(ABSTRACT TRUNCATED AT 400 WORDS)