1,721,043 research outputs found
How bacteria breathe in hydrogen sulfide-rich environments
No full textHydrogen sulfide (H2S) is now universally recognized as an endogenous signalling molecule
playing a central role in human physiology. This gas, although it controls a number of
physiological processes at low (submicromolar) concentrations, is toxic at high concentrations as
it blocks cell respiration by potently inhibiting cytochrome c oxidase, the terminal enzyme of the
mitochondrial respiratory chain. In a recent study on the model micro-organism Escherichia coli,
it was shown that the bacterial respiratory oxidase cytochrome bd is resistant to H2S inhibition,
thus enabling bacterial O2 respiration and growth in the presence of sulfide. This may be relevant
because many microbes are H2S producers and some of them live in sulfide-rich environments,
such as the human gut and other natural habitats. The potential impact of this finding in different
areas (environment, life evolution and human health) is discussed
The molecular mechanisms by which nitric oxide controls mitochondrial complex IV.
No full textThis mini-review of focussed on the information available on the molecular mechanisms by which NO controls the function of mitochondrial cytochrome c oxidase and thereby cell respiration. The reaction mechanisms are described as dissected in vitro and recently confirmed in cell cultures, whereby two reaction pathways have been identified, leading to accumulation of either the [a3(2+)NO]-nitrosyl or the [a3(3+)NO2-]-nitrite derivative of the enzyme. The experimental data and the theoretical computation analysis, supporting the hypothesis that one pathway prevails on the other depending on the electron flow level through the respiratory chain, are discussed. Finally, the patho-physiological implications of the reaction between NO and CcOX have been also outlined
Cytochrome c oxidase, ligands and electrons
No full textAbstract We present hereby an overview of the reactions of cytochrome c oxidase, the terminal enzyme of the mitochondrial respiratory chain, with ligands (primarily oxygen) and electrons, pointing out where necessary unresolved facts or questionable interpretations
Mechanism of S-nitrosothiol formation and degradation mediated by copper ions
No full textExperimental evidence is presented supporting a mechanism of S-nitrosothiol formation and degradation mediated by copper ions using bovine serum albumin, human hemoglobin and glutathione as models. We found that Cu(2+), but not Fe(3+), induces in the presence of NO a fast S-nitrosation of bovine serum albumin and human hemoglobin, and the reaction is prevented by thiol blocking reagents. During the reaction, Cu(+) is accumulated and accounts for destabilization of the S-nitrosothiol formed. In contrast, glutathione rapidly dimerizes in the presence of Cu(2+), the reaction competing with S-nitrosation and therefore preventing the formation of S-nitrosoglutathione. We have combined the presented role of Cu(2+) in S-nitrosothiol formation with the known destabilizing effect of Cu(+), providing a unique simple picture where the redox state of copper determines either the NO release from S-nitrosothiols or the NO scavenging by thiol groups. The reactions described are fast, efficient, and may occur at micromolar concentration of all reactants. We propose that the mechanism presented may provide a general method for in vitro S-nitrosation I.F. 7.
Cytochrome c oxidase does not catalyze the anaerobic reduction of NO
No full textA possible role of reduced cytochrome c oxidase in the metabolism of nitric oxide (NO) has been examined with amperometric and stopped-flow photometric techniques. Reduced purified cytochrome c oxidase and mitochondria showed no catalytic reaction with NO under anaerobic conditions within more than 30 minutes. Only fast binding of NO to the reduced enzyme in a 1:1 stoichiometric ratio was observed. The NO binding rate was strongly decreased in the presence of 1 mM cyanide. These data indicate that, contrary to previous proposals, cytochrome c oxidase in the absence of oxygen does not contribute to physiological NO metabolism I.F.2.7
Cytochrome bd oxidase and bacterial tolerance to oxidative and nitrosative stress
No full textCytochrome bd is a prokaryotic respiratory quinol:O2 oxidoreductase, phylogenetically unrelated to the extensively studied heme-copper oxidases (HCOs). The enzyme contributes to energy conservation by generating a proton motive force, though working with a lower energetic efficiency as compared to HCOs. Relevant to patho-physiology, members of the bd-family were shown to promote virulence in some pathogenic bacteria, which makes these enzymes of interest also as potential drug targets. Beyond its role in cell bioenergetics, cytochrome bd accomplishes several additional physiological functions, being apparently implicated in the response of the bacterial cell to a number of stress conditions. Compelling experimental evidence suggests that the enzyme enhances bacterial tolerance to oxidative and nitrosative stress conditions, owing to its unusually high nitric oxide (NO) dissociation rate and a notable catalase activity; the latter has been recently documented in one of the two bd-type oxidases of Escherichia coli. Current knowledge on cytochrome bd and its reactivity with O2, NO and H2O2 is summarized in this review in the light of the hypothesis that the preferential (over HCOs) expression of cytochrome bd in pathogenic bacteria may represent a strategy to evade the host immune attack based on production of NO and reactive oxygen species (ROS)
Investigating the mechanism of electron transfer to the binuclear center in Cu-heme oxidases
No full textNovel experimental evidence is presented further supporting the hypothesis that, starting with resting oxidized cytochrome c oxidase, the internal electron transfer to the oxygen binding site is kinetically controlled. The reduction of the enzyme was followed spectroscopically and in the presence of NO or CO, used as trapping ligands for reduced cytochrome a3; ruthenium hexamine was used as a spectroscopically silent electron donor. Consistent with the high combination rate constant for reduced cytochrome a3, NO proved to be a very efficient trapping ligand, while CO did not. The results are discussed in view of two alternative (thermodynamic and kinetic) hypotheses of control of electron transfer to the binuclear (cyt.a3-CuB) center. Fulfilling the prediction of the kinetic control hypothesis: i) the reduction of cytochrome a3 and ligation are synchronous and proceed at the intrinsic rate of cytochrome a3 reduction, ii) the measured rate of formation of the nitrosyl derivative is independent of the concentration of both the reductant and NO
I.F.4.3
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