Control of Electron Flux Through the Respiratory Chain in Mitochondria and Cells

Brand, Martin D.; Murphy, Michael P.

doi:10.1111/j.1469-185x.1987.tb01265.x

Cited by 244 publications

(87 citation statements)

References 317 publications

(220 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…This nonohmic behavior is not in itselfsurprising having been observed previously in a number of nonplant systems (5, for review) but may have important implications with respect to (4,12) and this situation appears to exist in vivo (4). By using the sensitive luciferin technique we have been able to measure quantitatively events at very low concentrations of ATP.…”

Section: Discussionmentioning

confidence: 72%

Role of Nonohmicity in the Regulation of Electron Transport in Plant Mitochondria

Whitehouse¹,

Fricaud²,

Moore³

1989

Plant Physiol.

View full text Add to dashboard Cite

The relationship between the respiratory rate and the membrane ionic current on the protonmotive force has been investigated in percoll purified potato mitochondria. The dependence of the membrane ionic current on the membrane potential was monitored using a methyltriphenylphosphonium-sensitive electrode and determining the maximal net rate of depolarization following the addition of a respiratory inhibitor. We have confirmed that a nonohmic relationship exists between the ionic conductance and membrane potential. Addition of ATPase inhibitors markedly increased the initial rate of dissipation suggesting that in their absence the dissipation rate induced by respiratory inhibitors is partially offset by H+-efflux due to the hydrolysis of endogenous ATP. This was corroborated by direct measurement of endogenous ATP levels which decreased significantly following dissipation of the membrane potential. Results are discussed in terms of the regulation of electron transport in plant mitochondna in vivo.It is generally accepted that the free energy which is liberated from the redox reactions catalyzed by the respiratory chain is conserved as a proton electrochemical gradient across the inner mitochondrial membrane (2). The magnitude of this force has been shown in a number of systems to be unrelated to the rate of electron flux since the rate of respiration can be substantially inhibited by malonate or antimycin resulting in only a minor depression of the protonmotive force (6,8,21,24,27). This has been variously attributed to the nonohmic behavior of the inner membrane (5,15,27), to heterogeneity ofthe coupling of the mitochondria (11), to localized protonic coupling (29), and to variations in the stoichiometry of the redox driven proton pumps (redox slippage) (31). Estimates of the passive conductance of the inner membrane to protons in rat liver mitochondria (5,15) of respiration under ADP limited conditions (9) which has been attributed either to the activity of an endogenous H+/ K+ antiporter (8, 13) and/or to the operation of nonphosphorylative pathways (22). It has been suggested that nonphosphorylative pathways such as the alternative and rotenone-insensitive pathways constitute a natural slippage (or energy overflow) pathway in plant mitochondria (10, 16) (since they bypass the proton-pumping sites) and, as such, modulation of proton conductance may not be as important as in other tissues.In contrast to this suggestion there is some evidence in the literature to suggest that proton conductance does regulate respiratory activity. For instance, in isolated mitochondria it has been found that the state 4 rate is generally much slower than the rate of respiration prior to the initial addition of ADP (7) and, furthermore, that the decreased respiratory rate is associated with an increased membrane potential (7,22). These differences have been attributed to the build-up of endogenous ATP and decreased H+ conductance through the ATPase (7). However, the mechanism whereby this results in a decreased respirator...

show abstract

Section: Discussionmentioning

confidence: 72%

Role of Nonohmicity in the Regulation of Electron Transport in Plant Mitochondria

Whitehouse¹,

Fricaud²,

Moore³

1989

Plant Physiol.

View full text Add to dashboard Cite

show abstract

“…The terminal enzyme of the respiratory chain is Cyt-Ox, and it cata lyzes the transfer of electrons from its reduced substrate cytochrome-c to CUA and cytochromes-a and -a3 and then to molecular oxygen to form water (for a detailed review on regulation of oxidative phosphorylation, see Brand and Murphy, 1987;Brown, 1992;Balaban, 1990).…”

Section: Cyt-ox Redox State During Visual Stimulationmentioning

confidence: 99%

Noninvasive Assessment of Changes in Cytochrome-c Oxidase Oxidation in Human Subjects during Visual Stimulation

Heekeren

Kohl

Obrig

et al. 1999

J Cereb Blood Flow Metab

View full text Add to dashboard Cite

Summary: In this study the authors used a whole-spectrum near-infrared spectroscopy approach to noninvasively assess changes in hemoglobin oxygenation and cytochrome-c oxidase redox state (Cyt-Ox) in the occipital cortex during visual stimu lation. The system uses a white light source (halogen lamp). The light reflected from the subject's head is spectrally re solved by a spectrograph and dispersed on a cooled charge coupled device camera. The authors showed the following us ing this approach: (1) Changes in cerebral hemoglobin oxygen ation (increase in concentration of oxygenated hemoglobin, decrease in concentration of deoxygenated hemoglobin) in the The energy requirements of brain tissue at rest are almost entirely met by oxidative metabolism of glucose. Cytochrome-c oxidase (Cyt-Ox) is the terminal electron acceptor of the mitochondrial electron transport chain and responsible for more than 90% of the cellular oxygen consumption. The energy generated in this process is used to synthesize ATP. The mechanism and control of the enzyme have been discussed in recent reviews (Coo per, 1990;Brown, 1992).In sections of brain tissue Cyt-Ox activity and concen trations of the enzyme can be measured with different approaches. Such measurements are well established, and Cyt-Ox activity has been shown to be an endogenous metabolic marker of long-term neuronal activity (Wong Riley, 1989).

show abstract

“…In vivo studies of mammalian cells and organs (for reviews, see Erecinska and Wilson, 1982;Brand and Murphy, 1987;Balaban, 1990) stream of the ATP synthase by the cytosolic ATP turnover, i.e. ATP-consuming activity during muscular contraction (Chance et al, 1986;Katz et al, 1988) or during gluconeogenesis and ureogenesis (Tanaka et al, 1989), and upstream of the respiratory chain by reducing equivalent availability, i.e.…”

Section: Interactions Between Glucose Metabolism and Oxidative Phosphmentioning

confidence: 99%

Interactions between glucose metabolism and oxidative phosphorylations on respiratory‐competent Saccharomyces cerevisiae cells

Beauvoit

Rigoulet

Bunoust

et al. 1993

European Journal of Biochemistry

View full text Add to dashboard Cite

The purpose of this work was to analyze the interactions between oxidative phosphorylations and glucose metabolism on yeast cells aerobically grown on lactate as carbon source and incubated in a resting cell medium. On such respiratory-competent yeast cells, four different metabolic steady states have particularly been studied: (a) glucose feeding under anaerobiosis, (b) ethanol supply under aerobiosis, (c) glucose supply under aerobiosis and (d) glucose plus ethanol under aerobiosis. For each condition, we measured: (a) the cellular ATP/ADP ratio and NADH content sustained under these conditions, (b) the glucose consumption rate (glucose conditions) and the respiratory rate (aerobic conditions).Under aerobic conditions, when ethanol is used as substrate, the ATP/ADP ratio and NADH level are very high as compared with glucose feeding. However, the rate of oxygen consumption is similar under both conditions. The main observation is a large increase in the respiratory rate when both glucose and ethanol are added. This increase corresponds to an ATP/ADP ratio and a NADH level lower than those observed with ethanol but higher than those with glucose. Therefore the response of the respiratory rate to the ATP/ADP ratio depends on the redox potential. We studied the way in which the ATP-consuming activity was increased under glucose + ethanol conditions. By NMR experiments, it appears that neither the futile cycle at the level of the phosphofructo-lkinase/fructo-l,6-bisphosphatase couple nor the synthesis of carbohydrate stores could account for the increase in oxidative phosphorylation. However, it is shown that, in the presence of glucose + ethanol, ATP consumption is strongly stimulated. It is hypothesized that this consumption is essentially due to the combination of the well-known plasma membrane proton-ATPase activation by glucose and the high phosphate potential due to oxidative ethanol metabolism. While it is well documented that oxidative phosphorylations inhibit the glycolytic flux, i.e. the Pasteur effect, we clearly show in this work that the glycolytic pathway limits the ability of mitochondria to maintain a cellular phosphate potential.Studies on isolated mitochondria have demonstrated that the ATP synthesis flux coupled to respiratory rate is controlled by the intramitochondrial phosphate potential value according to both the presence and the nature of the intra-or extramatricial ADP-regenerating system (Kuster et al

show abstract

Control of Electron Flux Through the Respiratory Chain in Mitochondria and Cells

Cited by 244 publications

References 317 publications

Role of Nonohmicity in the Regulation of Electron Transport in Plant Mitochondria

Role of Nonohmicity in the Regulation of Electron Transport in Plant Mitochondria

Noninvasive Assessment of Changes in Cytochrome-c Oxidase Oxidation in Human Subjects during Visual Stimulation

Interactions between glucose metabolism and oxidative phosphorylations on respiratory‐competent Saccharomyces cerevisiae cells

Contact Info

Product

Resources

About