Generation of superoxide radical and hydrogen peroxide by 1,2,4-triaminobenzene, a mutagenic and myotoxic aromatic amine

1,2,4-Triaminobenzene, the myotoxic and mutagenic metabolite of several azo dyes, has been shown to generate superoxide radical and hydrogen peroxide during its autoxidation in vitro. Hydrogen peroxide was detected in erythrocytes exposed to the aromatic amine, showing that the autoxidation reaction can occur intracellularly; these cells also suffered oxidative damage, as reflected in glutathione depletion and haemoglobin oxidation. It is suggested that 'active oxygen' species may be involved in the initiation of the toxic changes induced by 1,2,4-triaminobenzene.     

Oxidation of reduced pyridine nucleotides by plasma membranes of soybean hypocotyl

Highly purified plasma membranes isolated from soybean hypocotyls by free-flow electrophoresis or by a two-phase polymer separation system oxidize reduced pyridine nucleotides, NADH or NADPH, at rates of 2-5 nanomoles/mg protein/min. These rates are not influenced by mitochondrial inhibitors or by inhibitors of the alternate respiratory pathway. The NADH oxidase has a Km of 200 microM NADH. The enzyme activity is stimulated by Ca2+ and Mg2+ ions. The function of this enzyme is unknown at present, but it may represent a redox-controlled proton pump linked to acidification.     

Oxidation of 7-dehydrocholesterol by a mouse liver microsomal system dependent on reduced pyridine nucleotides

Aerobic incubation of 7-dehydrocholesterol with mouse liver microsomes in the presence of a detergent, an iron salt, and NADH or NADPH resulted in the conversion of the sterol to more polar products. In the presence of Fe(3+) or low levels of Fe(2+) the reaction was dependent upon reduced pyridine nucleotide and a microsomal enzyme system. At high levels of Fe(2+) or in the presence of Fe(2+) or Fe(3+) and ascorbic acid, nonenzymatic oxidation of 7-dehydrocholesterol occurred in the absence of NADH or NADPH. Chromatograms of products resulting from the enzyme-dependent and enzyme-independent reactions were similar. The enzymatic reaction was inhibited by certain chelating agents, by antioxidants, and by menadione, phenazine methosulfate, and ferricyanide. Low concentrations of EDTA stimulated the reaction and high concentrations inhibited it. In the complete system sterol oxidation was correlated with the peroxidation of microsomal lipids, but peroxidation of microsomal lipids proceeded more rapidly when either the sterol, the detergent, or both were omitted. Ergosterol was resistant to oxidation under conditions that caused extensive loss of 7-dehydrocholesterol. Microsomes from tissues other than liver were relatively inactive.     

The reduction of putidaredoxin reductase by reduced pyridine nucleotides

Putidaredoxin reductase (PdR), an FAD-containing protein, mediates the transfer of electrons from NADH to putidaredoxin in the cytochrome P-450cam-dependent oxidation of camphor. Using stopped-flow spectrophotometry, reduction of putidaredoxin reductase by NADH (70 microM) at 4 degrees C appeared to be a pseudo-first-order process with a rate constant in excess of 600 s-1. The reduction of putidaredoxin reductase by NADPH was much slower with a second-order rate constant of 530 s-1 M-1 at 4 degrees C. The reduction of the enzyme was monitored at several wavelengths: 455 nm to follow flavin reduction; 700 nm to follow the appearance of the long-wavelength charge-transfer complex; and 513 nm to detect the presence of a semiquinone form of the flavoprotein. There was no apparent semiquinone formation observed during reduction. The charge-transfer complex can be formed in the presence of NAD+, whereas, no charge-transfer band could be detected when PdR was reduced with NADPH. The titration of chemically or NADPH-reduced putidaredoxin reductase with either a stoichiometric or an excess amount of NAD+ resulted in the formation of a charge-transfer complex, indicating that the reduced form of PdR has a high affinity for NAD+ regardless of the method of reduction. The data presented indicate that putidaredoxin reductase is reduced without the formation of semiquinone intermediate and, upon reduction, forms a tight complex with NAD+. The Keq for the reduction of PdR by NADPH is 1.1 and the midpoint potential for this reaction is -317 +/- 5 mV.     

Oxidation of mitochondrial pyridine nucleotides by aglycone derivatives of adriamycin.

Adriamycin (AdM) and related anthracyclines are potent antineoplastic agents, the clinical utility of which is limited by severe cardiotoxicity. Aglycone derivatives of AdM have recently been reported to trigger the release of Ca2+ from isolated, preloaded rat heart mitochondria and to modify mitochondrial sulfhydryl (-SH) groups. Both mitochondrial Ca2+ retention and -SH status are sensitive to mitochondrial NAD(P)+/NAD(P)H ratios. This investigation examined the effects of AdM and its aglycone derivatives on the pyridine nucleotide redox status of isolated, intact heart mitochondria with the following results. (i) AdM aglycones induced the slow, Ca2(+)-independent oxidation of mitochondrial NAD(P)H. Oxidation was proportional to aglycone concentration between 5 and 60 microM. (ii) In terms of potency, 7-deoxy AdM aglycone greater than or equal to 7-hydroxy AdM aglycone much greater than AdM. (iii) Inhibitor data suggested that NAD(P)H oxidation reflects the rotenone-insensitive reduction of AdM aglycone and subsequent electron transfer to O2 generating superoxide. (iv) NAD(P)H oxidation mediated by AdM aglycone could be distinguished from the Ca2(+)-dependent NAD(P)H oxidation associated with mitochondrial Ca2+ release. This communication is the first to describe redox interactions of AdM with intact mitochondria.     

Metabolism of reduced pyridine nucleotides in ascites cell nuclei

Summary 1. The conditions are described under which the fluorescence due to reduced pyridine nucleotides can be studied separately at nuclear and cytoplasmic sites of glass-grown ascites cells, by the use of a flow chamber in the microfluorimeter ofChance andLegallais.2. The addition of glucose to ascites cells leads to a reduction of pyridine nucleotides within the nucleus, thus providing evidence for the participation of nuclear pyridine nucleotides in cellular metabolism.3. Although generally nuclear and cytoplasmic pyridine nucleotides parallel each other in their response to different metabolic conditions, there are few instances (e.g., Amytal) where they do not show such parallelism. This is discussed with regard to the problem of reoxidation of nuclear reduced pyridine nucleotides.With 2 Figures in the Text     

Kinetic and mechanistic studies on the reduction of melilotate hydroxylase by reduced pyridine nucleotides.

The reduction of the melilotate hydroxylase . 2-OH-phenyl propionate complex by NADH and reduced 3-acetyl pyridine adenine dinucleotide (AcPyNADH) has been investigated using steady state kinetic and rapid reaction techniques. Reduction by NADH appeared to involve only one charge-transfer-type intermediate (between reduced enzyme and NAD) as previously described (Strickland, S., and Massey, V. (1973) J. Biol. Chem. 248, 2953-2962). Reduction by AcPyNADH was shown to involve two charge-transfer-type intermediates. The first was between oxidized enzyme and AcPyNADH and the second was between reduced enzyme and AcPyNAD. Reaction of AcPyNADH with oxidized enzyme . 2-OH-phenyl propionate complex to form the first charge-transfer complex reached equilibrium within the mixing time of the stopped flow apparatus (5 ms). Subsequent steps in the reaction appeared to be first order and were independent of the AcPyNADH concentration. An 8-fold deuterium isotope effect on the step involving flavin reduction was found when reduced 3-acetyl[4A-2H]pyridine adenine dinucleotide (AcPyNADD) was used as the reductant. Analysis of the rapid reaction results for the reaction of oxidized pyridine nucleotide with reduced enzyme . 2-OH-phenyl propionate complex indicated the presence of two forms of reduced enzyme (in equilibrium) of which only one form was capable of reacting with the oxidized pyridine nucleotide. Based on the rapid reaction data, a mechanism for the reduction half-reaction is proposed. The turnover number calculated from this mechanism is in good agreement with that determined from the steady state data.     

Dehydrogenation of reduced pyridine nucleotides by Leydig cell tumors of the rat testis.

The activities of the cytochrome c reductases and of the D-T diaphorase in rat Leydig cell tumors have been described. The increase in enzymatic activity of the NADH cytochrome c reductase activity in functional tumors derived from interstitial cells of the rat testis is interpreted as being possibly related to hydroxylation of steroids by the neoplastic cells. Meanwhile, the increase in the activity of the D-T diaphorase in the other tumor is interpreted as being an anaplerotic reaction to substitute for the deficient shuttles for the transfer of reducing equivalents from the cytoplasm to the mitochondria observed in tumors.