Mitochondrial superoxide and aging: uncoupling-protein activity and superoxide production

2004 ◽  
Vol 71 ◽  
pp. 203-213 ◽  
Author(s):  
Martin D. Brand ◽  
Julie A. Buckingham ◽  
Telma C. Esteves ◽  
Katherine Green ◽  
Adrian J. Lambert ◽  
...  
Keyword(s):  
Lipid Peroxidation ◽  
Electron Transport ◽  
Complex I ◽  
Uncoupling Protein ◽  
Proton Motive Force ◽  
Motive Force ◽  
Superoxide Production ◽  
Lipid Peroxidation Product ◽  
Mild Uncoupling ◽  
Reversed Electron Transport

Mitochondria are a major source of superoxide, formed by the one-electron reduction of oxygen during electron transport. Superoxide initiates oxidative damage to phospholipids, proteins and nucleic acids. This damage may be a major cause of degenerative disease and aging. In isolated mitochondria, superoxide production on the matrix side of the membrane is particularly high during reversed electron transport to complex I driven by oxidation of succinate or glycerol 3-phosphate. Reversed electron transport and superoxide production from complex I are very sensitive to proton motive force, and can be strongly decreased by mild uncoupling of oxidative phosphorylation. Both matrix superoxide and the lipid peroxidation product 4-hydroxy-trans-2-nonenal can activate uncoupling through endogenous UCPs (uncoupling proteins). We suggest that superoxide releases iron from aconitase, leading to a cascade of lipid peroxidation and the release of molecules such as hydroxy-nonenal that covalently modify and activate the proton conductance of UCPs and other proteins. A function of the UCPs may be to cause mild uncoupling in response to matrix superoxide and other oxidants, leading to lowered proton motive force and decreased superoxide production. This simple feedback loop would constitute a self-limiting cycle to protect against excessive superoxide production, leading to protection against aging, but at the cost of a small elevation of respiration and basal metabolic rate.

scholarly journals Different Functions of Phylogenetically Distinct Bacterial Complex I Isozymes

2016 ◽  
Vol 198 (8) ◽  
pp. 1268-1280 ◽  
Author(s):  
Melanie A. Spero ◽  
Joshua R. Brickner ◽  
Jordan T. Mollet ◽  
Tippapha Pisithkul ◽  
Daniel Amador-Noguez ◽  
...  
Keyword(s):  
Electron Transport ◽  
Rhodobacter Sphaeroides ◽  
Complex I ◽  
Proton Motive Force ◽  
Motive Force ◽  
Nadh Oxidation ◽  
Aerobic Respiration ◽  
Content Type ◽  
Electron Transport Chains ◽  
Photoheterotrophic Growth

ABSTRACTNADH:quinone oxidoreductase (complex I) is a bioenergetic enzyme that transfers electrons from NADH to quinone, conserving the energy of this reaction by contributing to the proton motive force. While the importance of NADH oxidation to mitochondrial aerobic respiration is well documented, the contribution of complex I to bacterial electron transport chains has been tested in only a few species. Here, we analyze the function of two phylogenetically distinct complex I isozymes inRhodobacter sphaeroides, an alphaproteobacterium that contains well-characterized electron transport chains. We found thatR. sphaeroidescomplex I activity is important for aerobic respiration and required for anaerobic dimethyl sulfoxide (DMSO) respiration (in the absence of light), photoautotrophic growth, and photoheterotrophic growth (in the absence of an external electron acceptor). Our data also provide insight into the functions of the phylogenetically distinctR. sphaeroidescomplex I enzymes (complex IAand complex IE) in maintaining a cellular redox state during photoheterotrophic growth. We propose that the function of each isozyme during photoheterotrophic growth is either NADH synthesis (complex IA) or NADH oxidation (complex IE). The canonical alphaproteobacterial complex I isozyme (complex IA) was also shown to be important for routing electrons to nitrogenase-mediated H2production, while the horizontally acquired enzyme (complex IE) was dispensable in this process. Unlike the singular role of complex I in mitochondria, we predict that the phylogenetically distinct complex I enzymes found across bacterial species have evolved to enhance the functions of their respective electron transport chains.IMPORTANCECells use a proton motive force (PMF), NADH, and ATP to support numerous processes. In mitochondria, complex I uses NADH oxidation to generate a PMF, which can drive ATP synthesis. This study analyzed the function of complex I in bacteria, which contain more-diverse and more-flexible electron transport chains than mitochondria. We tested complex I function inRhodobacter sphaeroides, a bacterium predicted to encode two phylogenetically distinct complex I isozymes.R. sphaeroidescells lacking both isozymes had growth defects during all tested modes of growth, illustrating the important function of this enzyme under diverse conditions. We conclude that the two isozymes are not functionally redundant and predict that phylogenetically distinct complex I enzymes have evolved to support the diverse lifestyles of bacteria.

scholarly journals Correction: Control of mitochondrial superoxide production by reverse electron transport at complex I.

2019 ◽  
Vol 294 (19) ◽  
pp. 7966-7966
Author(s):  
Ellen L. Robb ◽  
Andrew R. Hall ◽  
Tracy A. Prime ◽  
Simon Eaton ◽  
Marten Szibor ◽  
...  
Keyword(s):  
Electron Transport ◽  
Complex I ◽  
Superoxide Production ◽  
Mitochondrial Superoxide ◽  
Reverse Electron Transport

scholarly journals Bacillus cereus electron transport and proton motive force during aerotaxis.

1984 ◽  
Vol 159 (3) ◽  
pp. 820-824 ◽  
Author(s):  
D J Laszlo ◽  
M Niwano ◽  
W W Goral ◽  
B L Taylor
Keyword(s):  
Electron Transport ◽  
Bacillus Cereus ◽  
Proton Motive Force ◽  
Motive Force

scholarly journals The principal mitochondrial K+ uniport is associated with respiratory complex I

2022 ◽  
Author(s):  
Michael Zemel ◽  
Alessia Angelin ◽  
Prasanth Potluri ◽  
Douglas Wallace ◽  
Francesca Fieni
Keyword(s):  
Complex I ◽  
Adenosine Diphosphate ◽  
Proton Motive Force ◽  
Motive Force ◽  
Atp Production ◽  
Respiratory Complex ◽  
Diffusion Systems ◽  
Transport Chain ◽  
Respiratory Complex I ◽  
Vectorial Metabolism

Mitochondria generate ATP via coupling the negative electrochemical potential (proton motive force, Capital Greek (Deltap), consisting of a proton gradient (Capital Greek DeltapH+) and a membrane potential (Capital Greek Psim) across the respiratory chain, to phosphorylation of adenosine diphosphate nucleotide. In turn, DeltapH+ and Capital Greek Psim, are tightly balanced by the modulation of ionic uniporters and exchange-diffusion systems which preserve integrity of mitochondrial membranes and regulate ATP production. Here, we provide direct electrophysiological, pharmacological and genetic evidence that the main mitochondrial electrophoretic pathway for monovalent cations is associated with respiratory complex I, contrary to the long-held dogma that only H+ gradients are built across proteins of the mammalian electron transport chain. Here we propose a theoretical framework to describe how monovalent metal cations contribute to the buildup of H+ gradients and the proton motive force, extending the classical Mitchellian view on chemiosmosis and vectorial metabolism. Keywords: mitochondrial electrogenic transport, chemiosmotic theory, vectorial metabolism, whole-mitochondria electrophysiology.

scholarly journals Control of mitochondrial superoxide production by reverse electron transport at complex I

2018 ◽  
Vol 293 (25) ◽  
pp. 9869-9879 ◽  
Author(s):  
Ellen L. Robb ◽  
Andrew R. Hall ◽  
Tracy A. Prime ◽  
Simon Eaton ◽  
Marten Szibor ◽  
...  
Keyword(s):  
Electron Transport ◽  
Complex I ◽  
Superoxide Production ◽  
Mitochondrial Superoxide ◽  
Reverse Electron Transport
Sign in / Sign up

Export Citation Format

Share Document