Control of proteoliposomal cytochrome c oxidase: the overall reaction

1990 ◽  
Vol 68 (9) ◽  
pp. 1128-1134 ◽  
Author(s):  
Peter Nicholls ◽  
Chris E. Cooper ◽  
John M. Wrigglesworth
Keyword(s):  
Steady State ◽  
Membrane Potential ◽  
Cytochrome C ◽  
Cytochrome Oxidase ◽  
Cytochrome C Oxidase ◽  
Respiration Rate ◽  
Respiratory Control ◽  
Ph Gradient ◽  
Activity Levels ◽  
Simulation Programme

The control of cytochrome c oxidase incorporated into proteoliposomes has been investigated as a function of membrane potential (ΔΨ) and pH gradient (ΔpH). The oxidase generates a pH gradient (alkaline inside) and a membrane potential (negative inside) when respiring on external cytochrome c. Low levels of valinomycin collapse ΔΨ and increase ΔpH; the respiration rate decreases. High levels of valinomycin, however, decrease ΔpH as valinomycin can also act as a protonophore. Nigericin (in the absence of valinomycin) increases ΔΨ and collapses ΔpH; the respiration rate increases. On a millivolt equivalent basis ΔpH is a more effective inhibitor of activity than is ΔΨ. In the absence of any ionophores the cytochrome oxidase proteoliposomes enter a steady state, in which there are both ΔpH and ΔΨ components of control. Present and previous data suggest that the respiration rate responds in a linear way ("ohmically") to increasing ΔpH but in a nonlinear way to ΔΨ ("non-ohmically"). High levels of both ΔΨ and ΔpH do not completely inhibit turnover (maximal respiratory control values lie between 6 and 10). The controlled steady state involves the electrophoretic entry and electroneutral exit of K+ from the vesicles. A model is presented in which the enzyme responds to both ΔpH and ΔΨ components of the proton-motive force, but is more sensitive to ΔpH than to ΔΨ at an equivalent ΔμH+. The steady state of the proteoliposome system can be represented for any set of permeabilities and enzyme activity levels using the computer simulation programme Stella™.Key words: cytochrome c, cytochrome oxidase, proteoliposomes, respiratory control, modelling, valinomycin, nigericin.

Control of proteoliposomal cytochrome c oxidase: the partial reactions

1990 ◽  
Vol 68 (9) ◽  
pp. 1135-1141 ◽  
Author(s):  
Peter Nicholls
Keyword(s):  
Electron Transfer ◽  
Steady State ◽  
Membrane Potential ◽  
Cytochrome C ◽  
Cytochrome Oxidase ◽  
Cytochrome C Oxidase ◽  
Redox State ◽  
Ph Gradient ◽  
Transfer Model ◽  
State Reduction

The steady-state spectroscopic behaviour and the turnover of cytochrome c oxidase incorporated into proteoliposomes have been investigated as functions of membrane potential and pH gradient. The respiration rate is almost linearly dependent on [cytochrome c2+] at high flux, but while the cytochrome a redox state is always dependent on the [cytochrome c2+] steady state, it reaches a maximum reduction level less than 100% in each case. The maximal aerobic steady-state reduction level of cytochrome a is highest in the presence of valinomycin and lowest in the presence of nigericin. The proportion of [cytochrome c2+] required to achieve 50% of maximal reduction of cytochrome a varies with the added ionophores; the apparent redox potential of cytochrome a is most positive in the fully decontrolled system (plus valinomycin and nigericin). At low levels of cytochrome a reduction, the rate of respiration is no longer a linear function of [cytochrome c2+], but is dependent upon the redox state of both cytochromes a and c. That is, proteoliposomal oxidase does not follow Smith–Conrad kinetics at low cytochrome c reduction levels, especially in the controlled states. The control of cytochrome oxidase turnover by ΔpH and by ΔΨ can be explained either by an allosteric model or by a model with reversed electron transfer between the binuclear centre and cytochrome a. Other evidence suggests that the reversed electron transfer model may be the correct one.Key words: proteoliposomes, cytochrome c, cytochrome oxidase, membrane potential, pH gradient, cytochrome a, electron transfer.

Effects of triorganotin-mediated anion–hydroxide exchange upon reconstituted cytochrome c oxidase proteoliposomes

1986 ◽  
Vol 64 (7) ◽  
pp. 647-655 ◽  
Author(s):  
A. P. Singh ◽  
P. Nicholls
Keyword(s):  
Steady State ◽  
Membrane Potential ◽  
Cytochrome C ◽  
Cytochrome C Oxidase ◽  
Respiration Rate ◽  
Ph Gradient ◽  
Dye Uptake ◽  
Tin Chloride ◽  
Carbocyanine Dye ◽  
Potential Formation

Proteoliposomes containing cytochrome c oxidase and an internally trapped fluorescent pH probe (pyranine) were used to monitor respiration-dependent internal alkalinization and membrane potential formation. A maximum steady-state pH gradient of about 0.4 pH unit (vesicle interior alkaline) was obtained during active respiration in presence of reducing substrates and cytochrome c. This pH gradient was abolished by the triorganotin compounds tripropyl-, tributyl-, and triphenyl-tin chloride. At the same time, the membrane potential, measured by carbocyanine dye uptake, was slightly increased in value. Valinomycin, which abolishes the membrane potential, restores the value of ΔpH at low trialkyltin concentrations. The organotin compounds acted as electroneutral ionophores which exchanged intravesicular OH− ions with external SCN−, I−, and Cl− ions, but not [Formula: see text] or [Formula: see text] ions. Abolition of ΔpH is accompanied by an increase in respiration rate, but full resiratory stimulation only occurs when both Δψ and ΔpH are abolished by addition of both triorganotin and valinomycin. The triorganotin–valinomycin combination leads to active KC1 accumulation by the respiring proteoliposome, and it is necessary to postulate an electrically neutral KC1 efflux process to explain the continued steady respiration of the proteoliposomes in the presence of this ionophore combination.

Kinetics of the cytochrome c oxidase and reductase reactions in energized and de-energized mitochondria

1977 ◽  
Vol 55 (7) ◽  
pp. 706-713 ◽  
Author(s):  
Lars Chr. Petersen ◽  
Hans Degn ◽  
Peter Nicholls
Keyword(s):  
Steady State ◽  
Cytochrome C ◽  
Cytochrome C Oxidase ◽  
Oxygen Concentration ◽  
Respiration Rate ◽  
Redox State ◽  
Rat Liver Mitochondria ◽  
Excess Oxygen ◽  
Succinate Oxidation ◽  
State Reduction

1. Coupled, cytochrome-c-depleted ('stripped') rat liver mitochondria reducing oxygen in the presence of exogenous cytochrome c, with succinate or ascorbate as substrates, show marked declines in the steady-state reduction of cytochrome c in excess oxygen on addition of uncouplers. Calculated ratios of maximal turnover in the uncoupled state and in the energized state for the cytochrome c oxidase (EC 1.9.3.1) reaction lie between 3 and 6, as obtained with reconstituted oxidase-containing vesicles. The succinate-cytochrome c reductase activity in such mitochondria shows a smaller response to uncoupler than that of the oxidase.2. The respiration rates of uncoupled mitochondria oxidizing ascorbate in the presence of added cytochrome c follow a Michaelis–Menten relationship with respect to oxygen concentration, in accordance with the pattern found previously with the solubilized oxidase. But succinate oxidation tends to give nonlinear concave-upward double-reciprocal plots of respiration rate against oxygen concentration, in accordance with the pattern found previously with intact uncoupled mitochondria.3. From simultaneous measurements of cytochrome c steady-state reduction, respiration rate, and oxygen concentration during succinate oxidation under uncoupled conditions it is found that at full reduction of cytochrome c, apparent Km for oxygen is 0.9 μM and the maximal oxidase (aa3) turnover is 400 s−1 (pH 7.4, 30 °C).4. The redox state of cytochrome c in uncoupled systems reflects a simple steady state; the redox state of cytochrome c in energized systems tends towards an equilibrium condition with the terminal cytochrome a3, whose apparent potential under these conditions is more negative than that of cytochrome c.

scholarly journals Fatty acids as modulators of cytochrome c oxidase in proteoliposomes

1996 ◽  
Vol 320 (2) ◽  
pp. 557-561 ◽  
Author(s):  
Martyn SHARPE ◽  
Ivano PERIN ◽  
John WRIGGLESWORTH ◽  
Peter NICHOLLS
Keyword(s):  
Fatty Acids ◽  
Enzyme Activity ◽  
Oleic Acid ◽  
Membrane Potential ◽  
Cytochrome C ◽  
Palmitic Acid ◽  
Cytochrome C Oxidase ◽  
Respiratory Control ◽  
Similar Concentration

The control of cytochrome c oxidase turnover in proteoliposomes by membrane potential (ΔΨ) and by pH gradient (ΔpH) is probably kinetic in nature, and inhibition by valinomycin and stimulation by nigericin indicate that ΔpH exerts a greater influence than does an equivalent ΔΨ. Oleic acid at 100 µM removes all ΔΨ and ΔpH control, whereas a similar concentration of palmitic acid increases turnover but does not completely abolish control. Valinomycin acts synergistically with both fatty acids, indicating that the latter can act as H+/K+ exchangers, but neither fatty acid alone markedly affects ΔpH, showing that they cannot fully mimic nigericin. Oleate, but not palmitate, diminishes ΔΨ, and can move electrophoretically as oleate anion. Submicromolar palmitic acid concentrations partly stimulate turnover in ΔΨ- and ΔpH-controlled proteoliposomes, as reported by Labonia, Muller and Azzi [(1988) Biochem. J. 254, 130–145], which might represent a direct effect on cytochrome c oxidase. The ubiquity of fatty acids in biological membranes suggests that these substances might be responsible for limiting respiratory control and enzyme activity in vivo.

scholarly journals Kinetic studies on cytochrome c oxidase inserted into liposomal vesicles. Effect of ionophores

1983 ◽  
Vol 209 (1) ◽  
pp. 81-89 ◽  
Author(s):  
P Sarti ◽  
A Colosimo ◽  
M Brunori ◽  
M T Wilson ◽  
E Antonini
Keyword(s):  
Cytochrome C ◽  
Cytochrome Oxidase ◽  
Cytochrome C Oxidase ◽  
Electrical Potential ◽  
Respiratory Control ◽  
Catalytic Efficiency ◽  
Kinetic Studies ◽  
Spectroscopic Properties ◽  
Electrical Potential Difference ◽  
Carbonyl Cyanide

Cytochrome c oxidase from ox heart was inserted into artificial liposomal vesicles obtained by sonication of purified soya-bean phospholipids. The cytochrome oxidase vesicles showed a respiratory control ratio of about 2. Spectroscopic properties in the visible and Soret regions and kinetics of CO binding are similar to those of the soluble oxidase. The catalytic efficiency of the cytochrome oxidase vesicles in oxidizing cytochrome c increases as a result of the formation of the ‘pulsed’ form of the oxidase and of the presence in the reaction mixture of carbonyl cyanide p-trifluoromethoxy-phenylhydrazone and nonactin. Analysis of the experimental results obtained under several conditions supports the conclusions that: (i) the alkalinization of the internal microenvironment in the liposomal vesicle is not by itself responsible for the decrease in catalytic activity; (ii) the electrical potential difference created during turnover by proton consumption and/or pumping through the liposome wall is an important mechanism of control in the chain of events leading to the oxidation of external cytochrome c.

Interaction of aging and intermittent ethanol exposure on brain cytochrome c oxidase activity levels

Alcohol ◽  
2003 ◽  
Vol 29 (2) ◽  
pp. 91-100 ◽  
Author(s):  
Pia Jaatinen ◽  
Jarno Riikonen ◽  
Päivi Riihioja ◽  
Olli Kajander ◽  
Antti Hervonen
Keyword(s):  
Cytochrome C ◽  
Cytochrome C Oxidase ◽  
Oxidase Activity ◽  
Ethanol Exposure ◽  
Activity Levels

Differential effectiveness of yeast cytochrome c oxidase subunit genes results from differences in expression not function

1987 ◽  
Vol 7 (10) ◽  
pp. 3520-3526
Author(s):  
C E Trueblood ◽  
R O Poyton
Keyword(s):  
Cytochrome C ◽  
Cytochrome C Oxidase ◽  
Fusion Gene ◽  
Single Copy ◽  
Chimeric Gene ◽  
Lacz Fusion ◽  
Null Alleles ◽  
Activity Levels ◽  
Wild Type ◽  
Oxidase Subunit

In Saccharomyces cerevisiae, COX5a and COX5b encode two distinct forms of cytochrome c oxidase subunit V, Va and Vb, respectively. To determine the relative contribution of COX5a and COX5b to cytochrome c oxidase function, we have disrupted each gene. Cytochrome c oxidase activity levels and respiration rates of strains carrying null alleles of COX5a or COX5b or both indicate that some form of subunit V is required for cytochrome c oxidase function and that COX5a is much more effective than COX5b in providing this function. Wild-type respiration is supported by a single copy of either COX5a or COX5ab (a constructed chimeric gene sharing 5' sequences with COX5a). In contrast, multiple copies of COX5b or COX5ba (a chimeric gene with 5' sequences from COX5b) are required to support wild-type respiration. These results suggest that the decreased effectiveness of COX5b is due to inefficiency in gene expression rather than to any deficiency in the gene product, Vb. This conclusion is supported by two observations: (i) a COX5a-lacZ fusion gene produces more beta-galactosidase than a COX5b-lacZ fusion gene, and (ii) the COX5a transcript is significantly more abundant than the COX5b transcript or the COXsba transcript. We conclude that COX5a is expressed more efficiently than COX5b and that, although mature subunits Va and Vb are only 67% homologous, they do not differ significantly in their ability to assemble and function as subunits of the holoenzyme.

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