NADH reductase metabolism

The distribution of metabolic functions within acinar zones is determined principally by the microenvironment of the hepatocytes. Cells in zone 1 are the first to respond to changes in the portal blood, such as glucose and insulin levels, and therefore play important roles in glycolysis and gluconeogenesis. Protein synthesis, P-oxidation of fatty acids, cholesterol synthesis and bile acid secretion also predominate in zone 1. Ordinarily zone 3 hepatocytes are the principal site of cytochrome P450 oxidation/reduction activity as well as NADPH and NADH reductase metabolism, making this region more susceptible... 

Metabolism of trimethylamine oxide in fish muscle involves an enzyme-catalyzed oxidation-reduction reaction. The enzyme responsible for the conversion of trimethylamine oxide to trimethylamine is known as trimethylamine-W-oxide reductase. This enzyme acts on nicotinamide adenine dinucleotide (NADH) and TMAO to produce NAD+, trimethylamine and water (Fig. 13.13.1). TMAO acts as the oxidizing agent and is reduced, while NADH undergoes oxidation as the reducing agent. 

Fig. 1. The metabolic cycle for the synthesis and degradation of poly(3HB). (1) 3-ketothiolase (2) NADPH-dependent acetoacetyl-CoA reductase (3) poly(3HB) synthase (4) NADH-dependent acetoacetyl-CoA reductase (5), (6) enolases (7) depolymerase (8) d-(-)-3-hydroxybutyrate dehydrogenase (9) acetoacetyl-CoA synthetase (10) succinyl-CoA transferase (11) citrate synthase (12) see Sect. 3...

Rarely, phenylketonuria results from a defect in the metabolism of biopterin, a cofactor for the phenylalanine hydroxylase pathway. The electron donor for phenylalanine hydroxylase is tetrahydrobiopterin (BH4), which transfers electrons to molecular oxygen to form tyrosine and dihydrobiopterin (QH2 Fig. 40-2 reaction 2). BH4 is regenerated from QH2 in an NADH-dependent reaction that is catalyzed by dihydropteridine reductase (DHPR), which is widely distributed. In the brain, this... 

Despite the scarcity of direct evidence, HA is generally believed to be present as a metabolic intermediate in mammalian tissues Recent studies on the reductive detoxification of HAs both by human NADH-cytochrome i>5 reductase and by human cytochrome b5 may be considered as additional supporting evidence for the in vivo formation of HA in mammalian cells that needs to be controlled in order to avoid the toxic effects of an excess of endogenously produced HA, as well as of HA produced by detoxification of xenobiotic HA derivatives " . 

In plant leaves, nitrate reduction requires NADH produced by glycolytic activity (13), The ozone-induced depression of glycolytic metabolism in soybean leaves was also reflected in a depressed rate of nitrate reduction ( ), A single ozone exposure depressed the vivo nitrate reductase (NR) activity about 60% (Table III), To determine if ozone affected the NR protein directly, the in vitro NR activity was determined in leaf extracts from plants exposed to 0 and 980 pg/m ozone. 

Reduction Carbonyl groups. The carbonyl group (-(C=0)-) is reduced through a reaction that is catalyzed by an aldo-keto reductase requiring NADH as a cofactor. A large number of aromatic and aliphatic ketones are reduced to the corresponding alcohols these reductions are frequently stereospecific. a,P-Unsaturated ketones are typically metabolized to saturated alcohols. 

The endoplasmic reticulum is composed of a convoluted network of channels and so has a large surface area. Apart from cytochromes P-450, the endoplasmic reticulum has many enzymes and functions, besides the metabolism of foreign compounds. These include the synthesis of proteins and triglycerides and other aspects of lipid metabolism and fatty acid metabolism. Specific enzymes present on the endoplasmic reticulum include cholesterol esterase, azo reductase, glucuronosyl transferase, NADPH cytochromes P-450 reductase and NADH cytochrome b5 reductase and cytochrome b5. A FAD-containing monooxygenase is also found in the endoplasmic reticulum, and this is discussed later in this chapter. 

Other forms of vanadium have been implicated in the stimulation of the plasma membrane vanadate-dependent NAD(P)H oxidation reaction. Decavanadate has been shown to be a more potent stimulator of the vanadate-dependent NADH oxidation activity than added orthovanadate [30,31], Interestingly, decavanadate reductase activity has been found to be an alternative activity of an NADP-specific isocitrate dehydrogenase [32], Diperoxovanadium derivatives have also been shown to be involved in this type of reaction [33,34], Decavanadate may play a role in the biological role of vanadium, as it is found in yeast cells growing in the presence of orthovanadate [8] and is a potent inhibitor of phosphofructokinase-1, the control step of glycolysis, and other metabolic reactions [35],... 

Similar mechanisms operate in the action of nitrate reductase and nitrite reductase. Both of these substances are produced from ammonia by oxidation. Plants and soil bacteria can reduce these compounds to provide ammonia for metabolism. The common agricultural fertilizer ammonium nitrate, NH4NO3, provides reduced nitrogen for plant growth directly, and by providing a substrate for nitrate reduction. NADH or NADPH is the electron donor for nitrate reductase, depending on the organism. 

Fig. 5.9. Proposed scheme for the intramitochondrial metabolism of malate by Hymenolepis diminuta. Abbreviations ME, malic enzyme F, fumarase T, transhydrogenase FR, fumarate reductase ETS, electron transport system. Once within the matrix compartment, malate oxidation, as catalysed by malic enzyme, results in NADPH formation. Via the activity of fumarase, malate also is converted to fumarate in the matrix compartment. NADPH then serves as a substrate for the inner-membrane-associated transhydrogenase and transhydrogenation between NADPH and matrix NAD is a scalar reaction associated with the matrix side of the inner membrane. Matrix NADH so formed reduces the electron transport system via a site on the matrix side of the inner membrane permitting fumarate reductase activity. The reduction of fumarate to succinate results in succinate accumulation within the matrix compartment. (After McKelvey Fioravanti, 1985.)...

Such a metabolism ( fumarate respiration ) is well known from anaerobic mitochondria (Tielens et al. 2002 Tielens and van Hellemond, Chap. 6 in this volume), but is unique in combination with a hydrogenase that might compete with the fumarate reductase for the same substrates. This hydrogenase of N. ovalis represents a novel type of [Fe]-only or [FeFe]-hydrogenase that allows H2 formation to be coupled directly to the reoxidation of NADH. The [Fe]-hydrogenase is linked covalently with a protein, which possesses NAD and FMN binding sites, and a ferredoxin-like FeS module that allows transfer... 

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