Louise C. Bell scite author profile

The unusual ability of Thiosphuera pantofropha to catalyze respiratory nitrate reduction under aerobic conditions is shown to correlate with the activity of a periplasmic nitrate reductase that is expressed under both aerobic and anaerobic growth conditions. The organism also synthesizes, but only under anaerobic conditions, a membrane-bound nitrate reductase which resembles the corresponding enzyme in Puracoccus denitrifican in respect of both catalytic properties and inhibition of activity in intact cells in the presence of oxygen.

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Identification of nitric oxide reductase activity in Rhodobacter capsulatus: the electron transport pathway can either use or bypass both cytochrome c2 and the cytochrome bc1 complex

Bell

Richardson²,

Ferguson³

1992

Journal of General Microbiology

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Several strains of Rhohbaeter capsufatus have been shown to possess a nitric oxide reductase activity (reaction product nitrous oxide) after anaerobic phototrophic growth, but not after aerobic growth. The reductase is associated with the cytoplasmic membrane and electrons can reach the enzyme via the cytochrome bel complex. However, use of appropriate strains has shown that neither the latter, cytochrome c2 nor cytochrome c' is essential for the reduction of nitric oxide. Inhibition by myxothiazol of nitric oxide reduction in a strain that lacks a cytochrome c2 establishes that in phototrophically grown R. capsufatus the cytochrome bel complex is able to transfer electrons to an acceptor that is alternative to cytochrome c2. Electron transport to nitric oxide from NADH or succinate generated a membrane potential. When isoascorbate plus 2,3,5,6-tetramethyl-p-phenylenediamine (DAD) was the electron donor a membrane potential was not generated. This observation implies that nitric oxide is reduced at the periplasmic surface of the membrane and that the reductase is not proton translocating.

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Insertion of transposon Tn5 into a structural gene of the membrane-bound nitrate reductase of Thiosphaera pantotropha results in anaerobic overexpression of periplasmic nitrate reductase activity

Bell

Page

Berks

et al. 1993

Journal of General Microbiology

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Chlorate-resistant mutants of the denitrifying bacterium Thiosphaera pantotropha were generated by transposon Tn5 mutagenesis. One class was deficient in membrane-bound nitrate reductase activity but retained a periplasmic nitrate reductase activity. Using transposon marker rescue it was shown that in one such mutant, M-6, the transposon was inserted in the membrane-bound nitrate reductase p subunit structural gene (termed narH in order to be consistent with the nomenclature of the Escherichia coli major nitrate reductase operon). The translated sequence (total of 106 amino acids) from around the point of transposon insertion showed approximately 90% amino acid identity with the j9 subunits of the E. coli nitrate reductases. Under anaerobic growth conditions M-6 overproduced the periplasmic nitrate reductase activity allowing anaerobic growth with nitrate as electron acceptor. A regulatory link was inferred between the presence of the membrane-bound nitrate reductase and expression of the periplasmic nitrate reductase. This is the first demonstration of full denitrification in an organism possessing only a periplasmic nitrate reductase.

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Cytochrome c₂ is essential for electron transfer to nitrous oxide reductase from physiological substrates in Rhodobacter capsulatus and can act as an electron donor to the reductase in vitro

Richardson

Bell

McEwan

et al. 1991

European Journal of Biochemistry

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1. Addition of nitrous oxide to a periplasmic fraction released from Rhodobacter capsulatus strains MT1131, N22DNAR+ or AD2 caused oxidation of c-type cytochrome, as judged by the decrease in absorbance at 550 nm. The periplasmic fraction catalysed reduction of nitrous oxide in the presence of either isoascorbate plus phenazine ethosulphate or reduced methyl viologen. The rates with these two electron donors were similar and were comparable to the activity observed with a quantity of cells equivalent to those from which the periplasm sample had been derived. Activity in the periplasm could not be observed with ascorbate plus 2,3,5,6-tetramethyl-pphenylenediamine although this reductant was effective with intact cells treated with myxothiazol to block the activity of the cytochrome-bcl complex.2. Cells of R. capsulatus MTG4/S4, a mutant from which the gene for cytochrome c2 has been specifically deleted, did not catalyse detectable rates of nitrous-oxide reduction. A nitrous-oxide reductase activity was present, as shown by activity of both cells and a periplasmic fraction with isoascorbate plus phenazine ethosulphate as reductant. The rates in cells and the periplasmic fraction were similar to those observed in the corresponding wildtype strain (MT1131). In contrast to wild-type cells, 2,3,5,6-tetramethyl-p-phenylenediamine and N , N , N , Ntetramethyl-p-phenylenediamine [Ph(NMe,),] were ineffective as mediators of electrons from isoascorbate. Visible absorption spectra showed that no detectable cytochromes in either the periplasm or intact cells of the MTG4/S4 mutant were oxidised by nitrous oxide.3 . Purified ferroycytochrome c2 from R. capsulatus was oxidised by nitrous oxide in the presence of periplasm from R . capsulatus MTG4/S4. The rate of oxidation was proportional to the amount of periplasm added, but was considerably lower than the rate of nitrous-oxide reduction observed with the same periplasmic fraction when either ascorbate plus phenazine ethosulphate or reduced methyl viologen were used as substrates. The oxidation of cytochrome c2 was inhibited by acetylene and by low concentrations of NaC1.4. Oxidation of ferrocytochrome c2 by nitrous oxide was observed when the purified cytochrome was mixed with a preparation of nitrous-oxide reductase. However, oxidation of ferrocytochrome c' by nitrous oxide was not observed in the presence of the reductase. The observations with the mutant MTG4/S4 suggest that cytochrome c2 is the only periplasmic cytochrome involved in nitrous-oxide reduction.5. Nitrous-oxide-dependent oxidation of a c-type cytochrome was observed in a periplasmic fraction from Paracoccus denitrijicans, provided the fraction was first reduced. Nitrous-oxide-reductase activity was detected with reduced methyl viologen as electron donor, but not, in contrast to R. capsulatus, with isoascorbate plus phenazine ethosulphate.6. Inhibition by myxothiazol of nitrous-oxide reduction by cells of R. capsulatus N22DNAR' was overcome by isoascorbate plus Ph(NMeJ2. Illumination inhibited the isoascorbat...

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Nitric and nitrous oxide reductases are active under aerobic conditions in cells of Thiosphaera pantotropha

Bell

Ferguson

1991

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Use of Clark-type electrodes has shown that, in cells of Thiosphaera pantotropha, the nitrous oxide reductase is active in the presence of O2, and that the two gases involved (N2O, O2) are reduced simultaneously, but with mutual inhibition. Reduction of nitrate, or nitrite, to N2O under aerobic conditions involves NO as an intermediate, as judged by trapping experiments with the ferric form of extracellular horse heart cytochrome c and the demonstration that the cells possess a nitric oxide reductase activity. The overall conversion of nitrate to N2, the process of denitrification, under aerobic conditions, is thus not prevented by reaction of NO with O2 and depends upon a nitrous oxide reductase system which differs from that in other organisms by being neither directly inhibited nor inactivated by O2.

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Louise C. Bell

Periplasmic and membrane‐bound respiratory nitrate reductases in Thiosphaera pantotropha

Identification of nitric oxide reductase activity in Rhodobacter capsulatus: the electron transport pathway can either use or bypass both cytochrome c2 and the cytochrome bc1 complex

Insertion of transposon Tn5 into a structural gene of the membrane-bound nitrate reductase of Thiosphaera pantotropha results in anaerobic overexpression of periplasmic nitrate reductase activity

Cytochrome c₂ is essential for electron transfer to nitrous oxide reductase from physiological substrates in Rhodobacter capsulatus and can act as an electron donor to the reductase in vitro

Nitric and nitrous oxide reductases are active under aerobic conditions in cells of Thiosphaera pantotropha

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Louise C. Bell

Periplasmic and membrane‐bound respiratory nitrate reductases in Thiosphaera pantotropha

Identification of nitric oxide reductase activity in Rhodobacter capsulatus: the electron transport pathway can either use or bypass both cytochrome c2 and the cytochrome bc1 complex

Insertion of transposon Tn5 into a structural gene of the membrane-bound nitrate reductase of Thiosphaera pantotropha results in anaerobic overexpression of periplasmic nitrate reductase activity

Cytochrome c2 is essential for electron transfer to nitrous oxide reductase from physiological substrates in Rhodobacter capsulatus and can act as an electron donor to the reductase in vitro

Nitric and nitrous oxide reductases are active under aerobic conditions in cells of Thiosphaera pantotropha

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Cytochrome c₂ is essential for electron transfer to nitrous oxide reductase from physiological substrates in Rhodobacter capsulatus and can act as an electron donor to the reductase in vitro