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.     

细菌nox基因研究进展

细菌nox基因编码合成一种含核黄素的NADH氧化酶,NADH氧化酶可催化双原子氧还原为H2O2或H2O,同时将NADH氧化为NAD+。该反应发生在多种代谢途径中,从而对细菌的氧化应激、菌膜形成、毒力调控及代谢产物生成等生理生化过程产生一系列影响。目前对高等动植物体中的nox基因及其编码的NADH氧化酶已有较深入的研究,但近年来一些研究表明,细菌nox基因的功能及作用通路与动植物体存在较大差异,因此,有必要详细了解细菌中nox基因和NADH氧化酶的具体作用机制及其对细胞产生的影响。综合分析近年来细菌nox基因及NADH氧化酶的研究成果,结合我们的研究,对目前存在的问题和未来的发展进行综述。     

Cloning and Characteristics of a Gene Encoding NADH Oxidase,a Major Mechanism for Oxygen Metabolism by the Anaerobic Spirochete,Brachyspira (Serpulina) hyodysenteriae

Brachyspira (Serpulina) hyodysenteriae cells consume oxygen during growth under a 1%O₂:99%N₂atmosphere. A major mechanism of O₂metabolism by this anaerobic spirochete is the enzyme NADH oxidase (EC 1.6.99.3). In these investigations, the NADH oxidase gene (nox) of B. hyodysenteriae strain B204 was cloned, expressed in Escherichia coli, and sequenced. By direct cloning of aHind III-digested DNA fragment which hybridized with a nox DNA probe and by amplification of B204 DNA through the use of inverse PCR techniques, overlapping portions of the nox gene were identified and sequenced. The nox gene and flanking chromosome regions (1.7 kb total) were then amplified and cloned into plasmid pCRII. Lysates of E. coli cells transformed with this recombinant plasmid expressed NADH oxidase activity (1.1 μmol NADH oxidized/min/mg protein) and contained a protein reacting with swine antiserum raised against purified B. hyodysenteriae NADH oxidase. The nox ORF (1.3 kb) encodes a protein with a predicted molecular mass of 50 158 kDa. The B. hyodysenteriae NADH oxidase shares significant (46%) amino acid sequence identity and common functional domains with the NADH oxidases of Enterococcus faecalis and Streptococcus mutans, suggesting a common evolutionary origin for these proteins. Cloning of the B. hyodysenteriae nox gene is an important step towards the goal of generating B. hyodysenteriae mutant strains lacking NADH oxidase and for investigating the significance of NADH oxidase in the physiology and pathogenesis of this anaerobic spirochete.     

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.     

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.     

Effects of overexpression of NAPRTase,NAMNAT, and NAD synthetase in the NAD(H) biosynthetic pathways on the NAD(H) pool,NADH/NAD+ ratio,and succinic acid production with different carbon sources by metabolically engineered Escherichia coli

Escherichia coli BA002, the ldhA and pflB deletion strain, cannot utilize glucose anaerobically due to the inability to regenerate NAD⁺. To regulate NAD(H) pool size and NADH/NAD⁺ ratio, overexpression of the enzymes in the NAD(H) biosynthetic pathways in BA002 was investigated. The results clearly demonstrate that the increased NAD(H) pool size and the decreased NADH/NAD⁺ ratio improved the glucose consumption and cell growth, which improved succinic acid production. When the pncB and the nadD genes were co-overexpressed in CA102, the ratio of NADH/NAD⁺ was decreased from 0.60 to 0.12, and the concentration of NAD(H) was the highest among that of all the strains. Moreover, the dry cell weight (DCW), glucose consumption, and the concentration of succinic acid in CA102 were also the highest. Based on the sufficient NAD⁺ supply after gene modification in the NAD(H) biosynthetic pathways, reductive carbon sources with different amounts of NADH can further change the distribution of metabolites. When sorbitol was used as a carbon source in CA102, the byproducts were lower than those of glucose fermentation, and the yield of succinic acid was increased.     

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.     

Pyridine nucleotide transhydrogenases of parasitic helminths.

Mitochondria from the parasitic helminth, Hymenolepis diminuta, catalyzed both NADPH:NAD⁺ and NADH:NADP⁺ transhydrogenase reactions which were demonstrable employing the appropriate acetylpyridine nucleotide derivative as the hydride ion acceptor. Thionicotinamide NAD⁺ would not serve as the oxidant in the former reaction. Under the assay conditions employed, neither reaction was energy linked, and the NADPH:NAD⁺ system was approximately five times more active than the NADH:NADP⁺ system. The NADH:NADP⁺ reaction was inhibited by phosphate and imidazole buffers, EDTA, and adenyl nucleotides, while the NADPH:NAD⁺ reaction was inhibited only slightly by imidazole and unaffected by EDTA and adenyl nucleotides. Enzyme coupling techniques revealed that both transhydrogenase systems functioned when the appropriate physiological pyridine nucleotide was the hydride ion acceptor. An NADH:NAD⁺ transhydrogenase system, which was unaffected by EDTA, or adenyl nucleotides, also was demonstrable in the mitochondria of H. diminuta. Saturation kinetics indicated that the NADH:NAD⁺ reaction was the product of an independent enzyme system. Mitochondria derived from another parasitic helminth, Ascaris lumbricoides, catalyzed only a single transhydrogenase reaction, i.e., the NADH:NAD⁺ activity. Transhydrogenase systems from both parasites were essentially membrane bound and localized on the inner mitochondrial membrane. Physiologically, the NADPH:NAD⁺ transhydrogenase of H. diminuta may serve to couple the intramitochondrial metabolism of malate (via an NADP linked “malic” enzyme) to the anaerobic NADH-dependent ATP-generating fumarate reductase system. In A. lumbricoides, where the intramitochondrial metabolism of malate depends on an NAD-linked “malic” enzyme which is localized primarily in the intermembrane space, the NADH:NAD⁺ transhydrogenase activity may serve physiologically in the translocation of hydride ions across the inner membrane to the anaerobic energy-generating fumarate reductase system.     

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.