Light-induced conversion of nicotinamide adenine dinucleotide to nicotinamide adenine dinucleotide phosphate in higher plant leaves

Light-induced conversion of NAD to NADP was investigated in higher plants. Upon illumination, conversion of NAD to NADP was observed in intact leaves of wheat and pea following incubation in the dark. This conversion was also observed in mesophyll protoplasts of wheat leaves when they were isolated in the dark or isolated in light and then preincubated in the dark. Chloroplasts isolated from wheat protoplasts prepared in the dark carried out the conversion. The conversion in the mechanically isolated spinach chloroplasts was observed only when they were isolated in the dark from leaves preincubated in darkness.     

A nicotinamide adenine dinucleotide phosphate phosphatase fromChlorella

A phosphatase enzyme hydrolysing NADP⁺ and NADPH to NAD⁺ and NADH was found to be present in extracts ofChlorella pyrenoidosa     

Regulation of nicotinamide adenine dinucleotide phosphate levels in yeast

The steady-state levels and redox states of pyridine nucleotide pools have been studied in yeast as a function of external growth conditions. Yeast grown aerobically on 0.8% glucose show two distinct phases of logarithmic growth, a first phase utilizing glucose with ethanol accumulation, and a second phase utilizing ethanol. During growth on glucose, the size of the NADP pool (NADP⁺ + NADPH) is maintained at approximately 12% the size of the NAD pool (NAD⁺ + NADH). Upon exhaustion of glucose, the mechanism(s) that maintain the levels of NADP relative to NAD are altered, resulting in a rapid 2- to 2.5-fold decrease in the size of the NADP pool relative to the size of the NAD pool. The lower levels of NADP are maintained during growth on ethanol. The NAD pool is approximately 50% NADH during both the glucose and ethanol phases of growth, while the NADP pool is approximately 67 and 48% NADPH during the glucose and ethanol phases of growth, respectively. Rapid media transfer experiments show that the decrease in NADP is reversible, that it does not require the net synthesis of pyridine nucleotide or protein, and that changes in the size of the NADP pool relative to the total pyridine nucleotide pool are correlated with changes in the redox state of the NADP pool.     

The preparation of stereospecific tritium-labeled reduced nicotinamide adenine dinucleotide phosphate

A method has been developed for the preparation of a high specific activity stereospecifically labeled tritiated NADPH. In this procedure, tritium is enzymatically transferred from d-isocitric acid-2-³H (8 Ci/mmole) to the A face of a pyridine nucleotide during its stereospecific reduction, resulting in the formation of NADPH-4A-³H (2 Ci/mmole).     

Oxidation of reduced nicotinamide adenine dinucleotide phosphate by isolated corn mitochondria

Isolated corn (Zea mays L.) mitochondria were found to oxidize reduced nicotinamide adenine dinucleotide phosphate in a KCl reaction medium. This oxidation was dependent on the presence of calcium or phosphate or both. Strontium and manganese substituted for calcium, but magnesium or barium did not. The oxidation of NADPH produced contraction of mitochondria swollen in KCl. Further evidence that the oxidation of NADPH was coupled was observed in respiratory control and adenosine diphosphate-oxygen ratios that were comparable to those reported for reduced nicotinamide adenine dinucleotide. The pathways of electron flow from NADH and NADPH were compared through the addition of electron transport inhibitors. The only difference between the two dinucleotides was that amytal was found to inhibit almost totally the state 3 oxidation of NADPH, but had little effect on the state 3 oxidation of NADH. The hypothetical pathways for electron flow from NADPH are discussed, as are the possible sites of calcium and phosphate stimulation.     

Conservation of fungal and animal nicotinamide adenine dinucleotide phosphate oxidase complexes

Nicotinamide adenine dinucleotide phosphate (NADPH) oxidases (Nox) are a group of eukaryotic flavoenzymes that catalyse the reduction of dioxygen to the superoxide anion using electrons provided by NADPH. An integral membrane flavocytochrome b558 heterodimer, composed of the catalytic subunit gp91^phox and the adaptor protein p22^phox, is essential for catalytic activity of the mammalian Nox2 complex. Two homologues of the mammalian gp91^phox, NoxA and NoxB, have been identified in fungi and shown to be crucial for distinct fungal cell differentiation and developmental processes, but to date, no homologue of the p22^phox adaptor protein has been identified. Isolation of a mutant from Podospora anserina with a phenotype identical to a previously characterised PaNox1 mutant, combined with phylogenetic analysis, identified a fungal homologue of p22^phox called PaNoxD. The same adaptor protein was shown to be a component of the Botrytis cinerea NoxA complex as supported by the identical phenotypes of the bcnoxA and bcnoxD mutants and direct physical interaction between BcNoxA and BcNoxD. These results suggest that NoxA/NoxD is the fungal equivalent of the mammalian gp91^phox/p22^phox flavocytochrome complex. Tetraspanin (Pls1) mutants of P. anserina and B. cinerea have identical phenotypes to noxB mutants, suggesting that Pls1 is the corresponding integral membrane adaptor for assembly of the NoxB complex.     

Oxidation of reduced nicotinamide adenine dinucleotide phosphate by plant mitochondria.

Mitochondria isolated from various plant tissues (leaves, etiolated shoots and hypocotyls, and stem tubers) oxidize exogenous NADPH with respiratory control values and ADP:O ratios similar to those obtained with exogenous NADH as substrate. In all the mitochondria investigated, the electron-transfer inhibitors rotenone and amytal each had the same effect on the oxidation of NADPH as they had on the oxidation of NADH. The oxidation of exogenous NADPH by white potato tuber mitochondria was much more sensitive to inhibition by citrate or ethylene glycol bis-(beta-aminoethyl ether)-N,N-tetraacetic acid than was the oxidation of NADH. Mitochondria isolated from aged beetroot slices showed an increased capacity for the oxidation of exogenous NADH (compared with mitochondria from fresh tissue) but no such increase in the capacity to oxidize exogenous NADPH. These results suggest that exogenous NADPH and NADH are oxidized via different flavoproteins in plant mitochondria.     

Binding of nicotinamide adenine dinucleotide phosphate to the tetratricopeptide repeat domains at the N-terminus of p67PHOX, a subunit of the leukocyte nicotinamide adenine dinucleotide phosphate oxidase

The nicotinamide adenine dinucleotide phosphate (NADPH) binding site of the NADPH oxidase complex is believed to be located on the beta, subunit of cytochrome b558. However, our previous studies showed that p67PHOX also contains an NADPH binding site that is essential for normal oxidase activity and that p67PHOX is able to mediate a slow electron transfer from a reduced pyridine nucleotide to an artificial electron acceptor. Using both affinity labeling and fluorescence quenching, we have obtained further evidence that p67PHOX is able to bind NADPH. We have used a number of truncated forms of p67PHOX, including p67PHOX(1-243), p67PHOX(1-210), p67PHOX(1-199), and p67PHOX(244-526) (where the numbers represent the initial and final amino acids in the truncated p67PHOX) in order to localize the binding site. We found that NADPH could bind to p67PHOX(1-243), p67PHOX(1-210), and p67PHOX(1-199) but not to p67PHOX(244-526). The p67PHOX(1-199) fragment consists largely of four tetratricopeptide (TPR) domains. We showed further that Rac2-GTP gamma S and to a lesser extent Rac2-GDP beta S could modulate the binding of NADPH to p67PHOX.     

Activation of the neutrophil nicotinamide adenine dinucleotide phosphate oxidase by galectin-1

Galectins are a group of lactose-binding proteins widely distributed in nature. Twelve mammalian galectins have so far been identified, but their functions are to a large extent unknown. In this work we study galectin-1 in its interaction with human neutrophils, with regard to both cell surface binding and activation of the superoxide-producing NADPH-oxidase. We show that galectin-1 is able to activate the neutrophil NADPH-oxidase, provided that the cells have been primed by extravasation from the blood into the tissue, an activation pattern that is similar to that of galectin-3. Using in vitro priming protocols, the galectin-1 responsiveness was found to correlate to granule mobilization and galectin-1 binding to the cells, suggesting the presence of granule-localized receptors that are up-regulated to the cell surface upon priming. By galectin-1 overlay of fractionated neutrophils we identified potential galectin-1 receptor candidates localized in the membranes of the secretory vesicle and gelatinase granules. The binding of galectin-1 and galectin-3 to neutrophil proteins was compared, as were the dose dependencies for activation by the two lectins. The results suggest that, although similarities are found between the two galectins, they appear to activate the NADPH-oxidase using different receptors. In conclusion, galectin-1 appears to have proinflammatory functions, mediated through activation of the neutrophil respiratory burst.     

Modification of metabolic pattern by variation of nicotinamide adenine dinucleotide phosphate level

The experiments were designed to get some information on the metabolism controlled by variation of the NADP level, which is known to change with the variation of environmental factors.