NAD+/NADH homeostasis affects metabolic adaptation to hypoxia and secondary metabolite production in filamentous fungi*

Filamentous fungi are used to produce fermented foods, organic acids, beneficial secondary metabolites and various enzymes. During such processes, these fungi balance cellular NAD⁺:NADH ratios to adapt to environmental redox stimuli. Cellular NAD(H) status in fungal cells is a trigger of changes in metabolic pathways including those of glycolysis, fermentation, and the production of organic acids, amino acids and secondary metabolites. Under hypoxic conditions, high NADH:NAD⁺ ratios lead to the inactivation of various dehydrogenases, and the metabolic flow involving NAD⁺ is down-regulated compared with normoxic conditions. This review provides an overview of the metabolic mechanisms of filamentous fungi under hypoxic conditions that alter the cellular NADH:NAD⁺ balance. We also discuss the relationship between the intracellular redox balance (NAD/NADH ratio) and the production of beneficial secondary metabolites that arise from repressing the HDAC activity of sirtuin A via Nudix hydrolase A (NdxA)-dependent NAD⁺ degradation.     

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.     

Effect of alternative NAD<Superscript>+</Superscript>-regenerating pathways on the formation of primary and secondary aroma compounds in a <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> glycerol-defective mutant

Saccharomyces cerevisiae maintains a redox balance under fermentative growth conditions by re-oxidizing NADH formed during glycolysis through ethanol formation. Excess NADH stimulates the synthesis of mainly glycerol, but also of other compounds. Here, we investigated the production of primary and secondary metabolites in S. cerevisiae strains where the glycerol production pathway was inactivated through deletion of the two glycerol-3-phosphate dehydrogenases genes (GPD1/GPD2) and replaced with alternative NAD⁺-generating pathways. While these modifications decreased fermentative ability compared to the wild-type strain, all improved growth and/or fermentative ability of the gpd1Δgpd2Δ strain in self-generated anaerobic high sugar medium. The partial NAD⁺ regeneration ability of the mutants resulted in significant amounts of alternative products, but at lower yields than glycerol. Compared to the wild-type strain, pyruvate production increased in most genetically manipulated strains, whereas acetate and succinate production decreased in all strains. Malate production was similar in all strains. Isobutanol production increased substantially in all genetically manipulated strains compared to the wild-type strain, whereas only mutant strains expressing the sorbitol producing SOR1 and srlD genes showed increases in isoamyl alcohol and 2-phenyl alcohol. A marked reduction in ethyl acetate concentration was observed in the genetically manipulated strains, while isobutyric acid increased. The synthesis of some primary and secondary metabolites appears more readily influenced by the NAD⁺/NADH availability. The data provide an initial assessment of the impact of redox balance on the production of primary and secondary metabolites which play an essential role in the flavour and aroma character of beverages.     

Kinetics of a hollow fiber dehydrogenase reactor

A hollow fiber module was used as a reactor for conversion of ethanol to acetaldehyde in the presence of horse liver alcohol dehydrogenase as catalyst. Mass transport rates for NAD⁺, the overall acetaldehyde generation rate, catalyst effectiveness factors, and the overall order of the reaction with respect to NAD⁺ concentration were measured. A coupled-substrate reactor with continuous in situ regeneration of cofactor was also examined. Two substrates of opposite redox state were added simultaneously to the feed stream. NADH and acetaldehyde concentrations were monitored in the effluent stream. The cofactor recycle number, or ratio of moles of product to moles of NADH produced, exceeded 10,000 under certain conditions. While decreasing the NAD⁺ concentration in the feed stream decreased reactor productivity somewhat, it greatly enhanced the ratio of product formed per mole of NAD⁺ fed to the reactor. It is suggested that high cofactor costs in dehydrogenase reactors may be overcome with efficient in situ regeneration and secondary recovery and recycling of cofactor from the process stream.     

Regulation of glycerol metabolism in <Emphasis Type="Italic">Enterobacter aerogenes</Emphasis> NBRC12010 under electrochemical conditions

Enterobacter aerogenes NBRC12010 was able to ferment glycerol to ethanol and hydrogen gas. Fermentation of glycerol ceased in the stationary phase of growth, and it was activated by electrochemical reactions using thionine as an electron transfer mediator from bacterial cells to an electrode. Using resting cells of E. aerogenes NBRC12010 in only citrate buffer solution, the cells did not consume glycerol at all, but they could metabolize glucose. These results suggest that the regulation of glycerol metabolism occurred at enzymatic steps before glycolysis. In E. aerogenes NBRC12010, glycerol was metabolized via glycerol dehydrogenase (GDH) and then dehydroxyacetone kinase. The GDH-catalyzed reaction mainly depended on the ratio of NAD⁺/NADH. At a NAD⁺/NADH ratio of nearly 1 or less, it was substantially suppressed and glycerol metabolism stopped. When the ratio was higher than 1, GDH was activated and glycerol was metabolized. Thus, the reaction of glycerol metabolism depended on the balance of cellular NAD⁺/NADH. Exogenous NADH was oxidized to NAD⁺ by electrochemical reactions with thionine. We proposed the activation mechanism of glycerol metabolism under electrochemical conditions.     

Inhibition of protein synthesis by glucose 6-phosphate and fructose 1,6-diphosphate in lysed rabbit reticulocytes and the reversal of inhibition by NAD+.

Glucose 6-phosphate and fructose 1,6-diphosphate inhibit protein synthesis when added to lysed rabbit reticulocytes. Protein synthesis is inhibited 47% with 6 mM fructose 1,6-diphosphate and 86% with 6 mM glucose 6-phosphate. With 0.125 mM NAD⁺, the inhibitory effect of glucose 6-phosphate and fructose 1,6-diphosphate becomes stimulatory. The stimulation of protein synthesis in those assays with NAD⁺ and the phosphorylated sugars is 50% above those assays that contain NAD⁺ alone. The inhibition of protein synthesis by glucose 6-phosphate and the reversal of this inhibition by NAD⁺ occurs at a step before the synthesis of the initial dipeptide, methionyl-valine. These data illustrate the importance of NAD⁺ and the activation of glycolysis in regulating protein synthesis in lysed rabbit reticulocytes.     

Redox sensing by a Rex‐family repressor is involved in the regulation of anaerobic gene expression in Staphylococcus aureus

An alignment of upstream regions of anaerobically induced genes in Staphylococcus aureus revealed the presence of an inverted repeat, corresponding to Rex binding sites in Streptomyces coelicolor. Gel shift experiments of selected upstream regions demonstrated that the redox‐sensing regulator Rex of S. aureus binds to this inverted repeat. The binding sequence – TTGTGAAW₄TTCACAA – is highly conserved in S. aureus. Rex binding to this sequence leads to the repression of genes located downstream. The binding activity of Rex is enhanced by NAD⁺ while NADH, which competes with NAD⁺ for Rex binding, decreases the activity of Rex. The impact of Rex on global protein synthesis and on the activity of fermentation pathways under aerobic and anaerobic conditions was analysed by using a rex‐deficient strain. A direct regulatory effect of Rex on the expression of pathways that lead to anaerobic NAD⁺ regeneration, such as lactate, formate and ethanol formation, nitrate respiration, and ATP synthesis, is verified. Rex can be considered a central regulator of anaerobic metabolism in S. aureus. Since the activity of lactate dehydrogenase enables S. aureus to resist NO stress and thus the innate immune response, our data suggest that deactivation of Rex is a prerequisite for this phenomenon.     

Metabolism of NAD+ in Nuclei of Saccharomyces cerevisiae during Stimulation of Its Biosynthesis by Nicotinamide

The activities of nuclear enzymes involved in NAD⁺ metabolism in Saccharomyces cerevisiae strain 913a-1 and its mutant 110 previously selected as an NAD⁺ producer were investigated. The presence of extracellular nicotinamide increased the total NAD⁺ pool in the cells and increased [³H]nicotinic acid incorporation; however, NAD⁺ concentration in isolated nuclei decreased slightly. The stimulating effect of nicotinamide on intracellular synthesis of NAD⁺ correlated with increases in ADP-ribosyl transferase, NAD⁺-pyrophosphorylase, and NAD⁺ ase activities.     

Role of NAD+ in the stimulation of protein synthesis in rabbit reticulocyte lysates.

The stimulation of protein synthesis by NAD⁺ in rabbit reticulocyte lysates has been reported. [Lennon M. B., Wu, J., and Suhadolnik, R. J., (1976) Biochem. Biophys. Res. Commun. 72, 530–538]. NAD⁺ can replace the creatine phosphate-creatine phosphokinase ($\text{CP}\text{CPK}$) energy regenerating system normally used in in vitro protein synthesizing systems. The replacement of $\text{CP}\text{CPK}$ by NAD⁺ is optimal at 37 °C. A significant lag in the rate of protein synthesis with NAD⁺ is observed with decreasing temperatures. Analysis of the adenylate energy charge with NAD⁺ shows an initial rapid decrease. This decrease in the energy charge recovers with increasing NAD⁺ concentrations. The energy level correlates with the rates of incorporation of d,l-[4,5-³H(N)]leucine into protein. ATP production via NAD⁺ pyrophosphorylase or oxidative phosphorylation does not explain the stimulation by NAD⁺. Rather, the stimulation is correlated with the activation of glycolysis. Glycolysis is not active in lysate preparations because NAD⁺ is absent. Additional possible roles of NAD⁺ in protein synthesis are discussed.     

Acetaldehyde mediates growth stimulation of ethanol-stressed <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>: evidence of a redox-driven mechanism

The ability of acetaldehyde (90 mg l⁻¹) to stimulate ethanol-stressed S. cerevisiae fermentations is examined and reasons for the effect explored. Alternative metabolic electron acceptors generated similar stimulatory effects to acetaldehyde, decreasing the ethanol-induced growth lag phase from 9 h to 3 h, suggesting a redox-driven effect. The exposure to ethanol caused an instant 60% decline in intracellular NAD⁺ which was largely prevented by the addition of acetaldehyde. Furthermore, the exposure to ethanol affected glycolysis by decreasing the rate of glucose utilisation from 0.33 g glucose g⁻¹ biomass h⁻¹ to 0.11 g glucose g⁻¹ biomass h⁻¹, while the addition of acetaldehyde to an ethanol stressed culture increased this rate to 0.14 g glucose g⁻¹ biomass h⁻¹.     

Ethanol Enhances Hepatitis C Virus Replication through Lipid Metabolism and Elevated NADH/NAD+

Ethanol has been suggested to elevate HCV titer in patients and to increase HCV RNA in replicon cells, suggesting that HCV replication is increased in the presence and absence of the complete viral replication cycle, but the mechanisms remain unclear. In this study, we use Huh7 human hepatoma cells that naturally express comparable levels of CYP2E1 as human liver to demonstrate that ethanol, at subtoxic and physiologically relevant concentrations, enhances complete HCV replication. The viral RNA genome replication is affected for both genotypes 2a and 1b. Acetaldehyde, a major product of ethanol metabolism, likewise enhances HCV replication at physiological concentrations. The potentiation of HCV replication by ethanol is suppressed by inhibiting CYP2E1 or aldehyde dehydrogenase and requires an elevated NADH/NAD⁺ ratio. In addition, acetate, isopropyl alcohol, and concentrations of acetone that occur in diabetics enhance HCV replication with corresponding increases in the NADH/NAD⁺. Furthermore, inhibiting the host mevalonate pathway with lovastatin or fluvastatin and fatty acid synthesis with 5-(tetradecyloxy)-2-furoic acid or cerulenin significantly attenuates the enhancement of HCV replication by ethanol, acetaldehyde, acetone, as well as acetate, whereas inhibiting β-oxidation with β-mercaptopropionic acid increases HCV replication. Ethanol, acetaldehyde, acetone, and acetate increase the total intracellular cholesterol content, which is attenuated with lovastatin. In contrast, both endogenous and exogenous ROS suppress the replication of HCV genotype 2a, as previously shown with genotype 1b. Conclusion: Therefore, lipid metabolism and alteration of cellular NADH/NAD⁺ ratio are likely to play a critical role in the potentiation of HCV replication by ethanol rather than oxidative stress.     

AMPK activation protects cells from oxidative stress‐induced senescence via autophagic flux restoration and intracellular NAD+ elevation

AMPK activation is beneficial for cellular homeostasis and senescence prevention. However, the molecular events involved in AMPK activation are not well defined. In this study, we addressed the mechanism underlying the protective effect of AMPK on oxidative stress‐induced senescence. The results showed that AMPK was inactivated in senescent cells. However, pharmacological activation of AMPK by metformin and berberine significantly prevented the development of senescence and, accordingly, inhibition of AMPK by Compound C was accelerated. Importantly, AMPK activation prevented hydrogen peroxide‐induced impairment of the autophagic flux in senescent cells, evidenced by the decreased p62 degradation, GFP‐RFP‐LC3 cancellation, and activity of lysosomal hydrolases. We also found that AMPK activation restored the NAD⁺ levels in the senescent cells via a mechanism involving mostly the salvage pathway for NAD⁺ synthesis. In addition, the mechanistic relationship of autophagic flux and NAD⁺ synthesis and the involvement of mTOR and Sirt1 activities were assessed. In summary, our results suggest that AMPK prevents oxidative stress‐induced senescence by improving autophagic flux and NAD⁺ homeostasis. This study provides a new insight for exploring the mechanisms of aging, autophagy and NAD⁺ homeostasis, and it is also valuable in the development of innovative strategies to combat aging.     

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     

NADP+-dependent acetaldehyde dehydrogenase from Zymomonas mobilis

An NADP⁺-linked acetaldehyde dehydrogenase (EC 1.2.1.4) from the ethanol producing bacterium Zymomonas mobilis was purified 180-fold to homogeneity. The enzyme is a cytosolic protein with an isoelectric point of 8.0 and has an apparent molecular weight of 210000. It showed a single band in sodium dodecylsulfate gel electrophoresis with a molecular weight of 55000, which indicates that it consists of four probably identical subunits. The apparent K _m values for the substrate acetaldehyde were 57 M and for the cosubstrate NADP⁺ 579 M. The enzyme was almost inactive with NAD⁺ as cofactor. Several other aldehydes besides acetaldehyde were accepted as a substrate but not formaldehyde or trichloroacetaldehyde. In anaerobically grown cells of Zymomonas mobilis the enzyme showed a specific activity of 0.035 U/mg protein but its specific activity could be increased up to 0.132 U/mg protein by adding acetaldehyde to the medium during the exponential growth phase or up to 0.284 U/mg protein when cells were grown under aeration. The physiological role of the enzyme is discussed.Abbreviations ALD-DH acetaldehyde dehydrogenases from Z. mobilis - DTT dithiothreitol - MES 2-(N-morpholino)ethanesulfonic acid - MOPS 3-(N-morpholino)propanesulfonic acid - SDS sodium dodecylsulfate Dedicated to Prof. Dr. H.-G. Schlegel, Universität Göttingen, on the occasion of his 65th birthday     

Purification and kinetic characterization of γ-aminobutyraldehyde dehydrogenase from rat liver

Oxidative deamination of putrescine, the precursor of polyamines, gives rise to γ-aminobutyraldehyde (ABAL). In this study an aldehyde dehydrogenase, active on ABAL, has been purified to electrophoretic homogeneity from rat liver cytoplasm and its kinetic behaviour investigated. The enzyme is a dimer with a subunit molecular weight of 51,000. It is NAD⁺-dependent, active only in the presence of sulphhydryl compounds and has a pH optimum in the range 7.3–8.4. Temperatures higher than 28°C promote slow activation and the process is favoured by the presence of at least one substrate. K_m for aliphatic aldehydes decreases from 110 μM for ABAL and acetaldehyde to 2–3 μM for capronaldehyde. The highest relative V-values have been observed with ABAL (100) and isobutyraldehyde (64), and the lowest with acetaldehyde (14). Affinity for NAD⁺ is affected by the aldehyde present at the active site: K_m for NAD⁺ is 70 μM with ABAL, 200 μM with isobutyraldehyde and capronaldehyde, and>800 μM with acetaldehyde. The kinetic behaviour at 37°C is quite complex; according to enzymatic models, NAD⁺ activates the enzyme (K_act 500 μM) while NADH competes for the regulatory site (K_in 70 μM). In the presence of high NAD⁺ concentrations (4 mM), ABAL promotes further activation by binding to a low-affinity regulatory site (K_act 10 mM). The data show that the enzyme is probably an E₃ aldehyde dehydrogenase, and suggest that it can effectively metabolize aldehydes arising from biogenic amines.     

NAD+ metabolism and oxidative stress: the golden nucleotide on a crown of thorns

Abstract

In the twentieth century, NAD⁺ research generated multiple discoveries. Identification of the important role of NAD⁺ as a cofactor in cellular respiration and energy production was followed by discoveries of numerous NAD⁺ biosynthesis pathways. In recent years, NAD⁺ has been shown to play a unique role in DNA repair and protein deacetylation. As discussed in this review, there are close interactions between oxidative stress and immune activation, energy metabolism, and cell viability in neurodegenerative disorders and ageing. Profound interactions with regard to oxidative stress and NAD⁺ have been highlighted in the present work. This review emphasizes the pivotal role of NAD⁺ in the regulation of DNA repair, stress resistance, and cell death, suggesting that NAD⁺ synthesis through the kynurenine pathway and/or salvage pathway is an attractive target for therapeutic intervention in age-associated degenerative disorders. NAD⁺ precursors have been shown to slow down ageing and extend lifespan in yeasts, and protect severed axons from degeneration in animal models neurodegenerative diseases.