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.     

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.     

Streptomyces rimosus M4018 中氧化应激转录抑制因子Rex的克隆表达及与rex 操纵子的体外结合活性

【目的】为了研究龟裂链霉菌Streptomyces rimosus M4018中的rex基因对自身rex operator(ROP)的调控机制。【方法】根据天蓝色链霉菌Streptomyces coelicolor A3(2)中rex基因的同源序列设计引物进行PCR,从S.rimosus M4018中获得其rex基因(Sr-rex)。同时,通过染色体步移的方法,获得其上游的ROP序列。采用体外凝胶迁移的方法,分析了Sr-Rex对ROP的调控作用。【结果】获取的Sr-rex基因核苷酸序列长度为846 bp,预测的编码氨基酸序列与S.coelicolor A3(2)中Rex的同源性为84%,获得GenBank登录号:GQ849479。圆二色光谱显示Sr-Rex的结构以α螺旋和β折叠为主,与软件预测相符。凝胶迁移实验表明,Sr-Rex能与S.rimosus M4108中扩增到的ROP片段特异性结合。同时,以Rex:ROP的最小结合序列为基础,设计了一条22 bp的单链DNA片段,和Sr-Rex的最大结合摩尔浓度比约为5:1。高浓度的NADH抑制两者的结合活性,而NAD+对结合没有影响。【结论】在S.rimosus M4108中,Rex是通过响应胞内NAD(H)水平的方式来调控ROP的表达的。     

Complexes of NADH with betaine aldehyde dehydrogenase from leaves of the plant Amaranthus hypochondriacus L.

The kinetic mechanism of betaine aldehyde dehydrogenase from leaves of the plant Amaranthus hypochondriacus is ordered with NAD⁺ adding first. NADH is a noncompetitive inhibitor against NAD⁺, which was interpreted before as evidence of an iso mechanism, in which NAD⁺ and NADH binds to different forms of free enzyme. With the aim of testing the proposed kinetic mechanism, we have now investigated the ability of NADH to form different complexes with the enzyme. By initial velocity and equilibrium binding studies, we found that the steady-state levels of E.glycine betaine are negligible, ruling out binding of NADH to this complex. However, NADH readily bind to E.betaine aldehyde, whose levels most likely are kinetically significant given its low dissociation constant. Also, NADH combined with E.NADH and E.NAD⁺. Finally, NADH was not able to revert the hydride transfer step, what suggest that there is no acyl-enzyme intermediate, i.e. the release of the reduced dinucleotide takes place after the deacylation step. Although formation of the complex E.NAD⁺.NADH would produce an uncompetitive effect in the inhibition of NADH against NAD⁺, the iso mechanism cannot be conclusively discarded.     

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.     

Role of the global regulator Rex in control of NAD+‐regeneration in Clostridioides (Clostridium) difficile

For the human pathogen Clostridioides (also known as Clostridium) difficile, the ability to adapt to nutrient availability is critical for its proliferation and production of toxins during infection. Synthesis of the toxins is regulated by the availability of certain carbon sources, fermentation products and amino acids (e.g. proline, cysteine, isoleucine, leucine and valine). The effect of proline is attributable at least in part to its role as an inducer and substrate of D‐proline reductase (PR), a Stickland reaction that regenerates NAD⁺ from NADH. Many Clostridium spp. use Stickland metabolism (co‐fermentation of pairs of amino acids) to generate ATP and NAD⁺. Synthesis of PR is activated by PrdR, a proline‐responsive regulatory protein. Here we report that PrdR, in the presence of proline, represses other NAD⁺‐generating pathways, such as the glycine reductase and succinate‐acetyl CoA utilization pathways leading to butyrate production, but does so indirectly by affecting the activity of Rex, a global redox‐sensing regulator that responds to the NAD⁺/NADH ratio. Our results indicate that PR activity is the favored mechanism for NAD⁺ regeneration and that both Rex and PrdR influence toxin production. Using the hamster model of C. difficile infection, we revealed the importance of PrdR‐regulated Stickland metabolism in the virulence of C. difficile.     

Immobilization of multienzymes and cofactors within lipid-polyamide membrane microcapsules for the multistep conversion of lipophilic and lipophobic substrates

Cofactors cannot be retained within polyamide membrane microcapsules unless the cofactors have been covalently linked to macromolecules. In this paper, a new approach using lipid-polyamide membrane microcapsules has resulted in the retention of unmodified cofactors. Lipid-polyamide microcapsules can be made to contain urease (urea amidohydrolase, EC 3.5.1.5), glutamate dehydrogenase (NAD(P)⁺) [l-glutamate: NAD(P)⁺ oxidoreductase (deaminating), EC 1.4.1.3], alcohol dehydrogenase (alcohol:NAD⁺ oxidoreductase, EC 1.1.1.1), NAD⁺, NADH and α-ketoglutarate. Lipophilic substrates like ammonia can equilibrate rapidly into the microcapsules. The rate of conversion of ammonia into glutamate was studied. NAD⁺ retained in the microcapsules was effectively recycled into NADH and 0.25 μmol NAD⁺ converted 10 μmol ammonia into glutamate. Without cofactor recycling, 10 μmol NADH had to be microencapsulated to convert the same amount of ammonia into glutamate. By adjusting the ratio of cholesterol and lecithin in the lipid component of the membrane, it was also possible to achieve a good urea-permeable membrane without any leakage of cofactor or α-ketoglutarate. This way urea permeated through the lipid-polyamide membrane microcapsules was sequentially converted into ammonia and then glutamate.     

Design of a cytochrome P450BM3 reaction system linked by two‐step cofactor regeneration catalyzed by a soluble transhydrogenase and glycerol dehydrogenase

A cytochrome P450BM3‐catalyzed reaction system linked by a two‐step cofactor regeneration was investigated in a cell‐free system. The two‐step cofactor regeneration of redox cofactors, NADH and NADPH, was constructed by NAD⁺‐dependent bacterial glycerol dehydrogenase (GLD) and bacterial soluble transhydrogenase (STH) both from Escherichia coli. In the present system, the reduced cofactor (NADH) was regenerated by GLD from the oxidized cofactor (NAD⁺) using glycerol as a sacrificial cosubstrate. The reducing equivalents were subsequently transferred to NADP⁺ by STH as a cycling catalyst. The resultant regenerated NADPH was used for the substrate oxidation catalyzed by cytochrome P450BM3. The initial rate of the P450BM3‐catalyzed reaction linked by the two‐step cofactor regeneration showed a slight increase (approximately twice) when increasing the GLD units 10‐fold under initial reaction conditions. In contrast, a 10‐fold increase in STH units resulted in about a 9‐fold increase in the initial reaction rate, implying that transhydrogenation catalyzed by STH was the rate‐determining step. In the system lacking the two‐step cofactor regeneration, 34% conversion of 50 μM of a model substrate (p‐nitrophenoxydecanoic acid) was attained using 50 μM NADPH. In contrast, with the two‐step cofactor regeneration, the same amount of substrate was completely converted using 5 μM of oxidized cofactors (NAD⁺ and NADP⁺) within 1 h. Furthermore, a 10‐fold dilution of the oxidized cofactors still led to approximately 20% conversion in 1 h. These results indicate the potential of the combination of GLD and STH for use in redox cofactor recycling with catalytic quantities of NAD⁺ and NADP⁺. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Purification and characterization of malate dehydrogenase from the phototrophic bacterium,Rhodopseudomonas capsulata

Malate dehydrogenase (l-malate:NAD⁺ oxidoreductase, EC 1.1.1.37) has been purified about 480-fold from crude extract of the facultative phototrophic bacterium, Rhodopseudomonas capsulata by only two purification steps, involving Red-Sepharose affinity chromatography. The enzyme has a molecular mass of about 80 kDa and consists of two subunits with identical molecular mass (35 kDa). The enzyme is susceptible to heat inactivation and loses its activity completely upon incubation at 40°C for 10 min. Addition of NAD⁺, NADH and oxaloacetate, but not l-malate, to the enzyme solution stabilized the enzyme. The enzyme catalyzes exclusively the oxidation of l-malate, and the reduction of oxaloacetate and ketomalonate in the presence of NAD⁺ and NADH, respectively, as the coenzyme. The pH optima are around 9.5 for the l-malate oxidation, and 7.75–8.5 and 4.3–7.0 for the reduction of oxaloacetate and ketomalonate, respectively. The K_m values were determined to be 2.1 mM for l-malate, 48 μM for NAD⁺, 85 μM for oxaloacetate, 25 μM for NADH and 2.2 mM for ketomalonate. Initial velocity and product inhibition patterns of the enzyme reactions indicate a random binding of the substrates, NAD⁺ and l-malate, to the enzyme and a sequential release of the products: NADH is the last product released from the enzyme in the l-malate oxidation.     

Kinetic mechanism of mitochondrial NADH:ubiquinone oxidoreductase interaction with nucleotide substrates of the transhydrogenase reaction

The effects of Tinopals (cationic benzoxazoles) AMS-GX and 5BM-GX on NADH-oxidase, NADH:ferricyanide reductase, and NADH APAD⁺ transhydrogenase reactions and energy-linked NAD⁺ reduction by succinate, catalyzed by NADH:ubiquinone oxidoreductase (Complex I) in submitochondrial particles (SMP), were investigated. AMS-GX competes with NADH in NADH-oxidase and NADH:ferricyanide reductase reactions (K _i = 1 M). 5BM-GX inhibits those reactions with mixed type with respect to NADH (K _i = 5 M) mechanism. Neither compound affects reverse electron transfer from succinate to NAD⁺. The type of the Tinopals' effect on the NADH APAD⁺ transhydrogenase reaction, occurring with formation of a ternary complex, suggests the ordered binding of nucleotides by the enzyme during the reaction: AMS-GX and 5BM-GX inhibit this reaction uncompetitively just with respect to one of the substrates (APAD⁺ and NADH, correspondingly). The competition between 5BM-GX and APAD⁺ confirms that NADH is the first substrate bound by the enzyme. Direct and reverse electron transfer reactions demonstrate different specificity for NADH and NAD⁺ analogs: the nicotinamide part of the molecule is significant for reduced nucleotide binding. The data confirm the model suggesting that during NADH APAD⁺ reaction, occurring with ternary complex formation, reduced nucleotide interacts with the center participating in NADH oxidation, whereas oxidized nucleotide reacts with the center binding NAD⁺ in the reverse electron transfer reaction.     

Introduction of an NADH regeneration system into Klebsiella oxytoca leads to an enhanced oxidative and reductive metabolism of glycerol

Redox cofactors play crucial roles in the metabolic and regulatory network of living organisms. We reported here the effect of introducing a heterogeneous NADH regeneration system into Klebsiella oxytoca on cell growth and glycerol metabolism. Expression of fdh gene from Candida boidinii in K. oxytoca resulted in higher intracellular concentrations of both NADH and NAD⁺ during the fermentation metaphase, with the ratio of NADH to NAD⁺ unaltered and cell growth unaffected, interestingly different from that in engineered Escherichia coli, Lactococcus lactis, and others. Metabolic flux analysis revealed that fluxes to 1,3-propanediol, ethanol, and lactate were all increased, suggesting both the oxidative and reductive metabolisms of glycerol were enhanced. It demonstrates that in certain microbial system NADH availability can be increased with NADH to NAD⁺ ratio unaltered, providing a new strategy to improve the metabolic flux in those microorganisms where glycolysis is not the only central metabolic pathways.     

Oxidation of excited-state NADH and NAD dimer in aqueous medium involvement of O2− as a mediator in the presence of oxygen

It has been shown that direct excitation of NADH (or NADPH) in aqueous medium at 254 nm, or at wavelengths longer than 320 nm (where only the reduced nicotinamide moiety absorbs), leads to generation of NAD⁺ (or NADP⁺). The reaction proceeds both in the presence and absence of oxygen. Under aerobic conditions the reaction is accompanied by formation of H₂O₂ at a level equimolar with that of the NADH present in solution. On irradiation at wavelengths longer than 320 nm, conversion of NADH to enzymatically active NAD⁺ is about 75%. Under analogous irradiation conditions, the dimers (NAD)₂ and (NADP)₂ undergo disproportionation to NAD⁺ and NADP⁺, respectively, to the extent of 90%. Both physicochemical and enzymatic criteria were employed to formulate mechanisms for the photooxidation of NADH and the photodisproportionation of the dimer (NAD)₂.     

Nicotinamide phosphoribosyltransferase can affect metastatic activity and cell adhesive functions by regulating integrins in breast cancer

NAD⁺ metabolism is an essential regulator of cellular redox reactions, energy pathways, and a substrate provider for NAD⁺ consuming enzymes. We recently demonstrated that enhancement of NAD⁺/NADH levels in breast cancer cells with impaired mitochondrial NADH dehydrogenase activity, through augmentation of complex I or by supplementing tumor cell nutrients with NAD⁺ precursors, inhibits tumorigenicity and metastasis. To more fully understand how aberrantly low NAD⁺ levels promote tumor cell dissemination, we here asked whether inhibition of NAD⁺ salvage pathway activity by reduction in nicotinamide phosphoribosyltransferase (NAMPT) expression can impact metastasis and tumor cell adhesive functions. We show that knockdown of NAMPT, the enzyme catalyzing the rate-limiting step of the NAD⁺ salvage pathway, enhances metastatic aggressiveness in human breast cancer cells and involves modulation of integrin expression and function. Reduction in NAMPT expression is associated with upregulation of select adhesion receptors, particularly αvβ3 and β1 integrins, and results in increased breast cancer cell attachment to extracellular matrix proteins, a key function in tumor cell dissemination. Interestingly, NAMPT downregulation prompts expression of integrin αvβ3 in a high affinity conformation, known to promote tumor cell adhesive interactions during hematogenous metastasis. NAMPT has been selected as a therapeutic target for cancer therapy based on the essential functions of this enzyme in NAD⁺ metabolism, cellular redox, DNA repair and energy pathways. Notably, our results indicate that incomplete inhibition of NAMPT, which impedes NAD⁺ metabolism but does not kill a tumor cell can alter its phenotype to be more aggressive and metastatic. This phenomenon could promote cancer recurrence, even if NAMPT inhibition initially reduces tumor growth.     

Suppression of Electron Transfer to Dioxygen by Charge Transfer and Electron Transfer Complexes in the FAD-dependent Reductase Component of Toluene Dioxygenase

The three-component toluene dioxygenase system consists of an FAD-containing reductase, a Rieske-type [2Fe-2S] ferredoxin, and a Rieske-type dioxygenase. The task of the FAD-containing reductase is to shuttle electrons from NADH to the ferredoxin, a reaction the enzyme has to catalyze in the presence of dioxygen. We investigated the kinetics of the reductase in the reductive and oxidative half-reaction and detected a stable charge transfer complex between the reduced reductase and NAD⁺ at the end of the reductive half-reaction, which is substantially less reactive toward dioxygen than the reduced reductase in the absence of NAD⁺. A plausible reason for the low reactivity toward dioxygen is revealed by the crystal structure of the complex between NAD⁺ and reduced reductase, which shows that the nicotinamide ring and the protein matrix shield the reactive C4a position of the isoalloxazine ring and force the tricycle into an atypical planar conformation, both factors disfavoring the reaction of the reduced flavin with dioxygen. A rapid electron transfer from the charge transfer complex to electron acceptors further reduces the risk of unwanted side reactions, and the crystal structure of a complex between the reductase and its cognate ferredoxin shows a short distance between the electron-donating and -accepting cofactors. Attraction between the two proteins is likely mediated by opposite charges at one large patch of the complex interface. The stability, specificity, and reactivity of the observed charge transfer and electron transfer complexes are thought to prevent the reaction of reductase_TOL with dioxygen and thus present a solution toward conflicting requirements.