Robert E. Beyer scite author profile

One of the vital roles of ascorbic acid (vitamin C) is to act as an antioxidant to protect cellular components from free radical damage. Ascorbic acid has been shown to scavenge free radicals directly in the aqueous phases of cells and the circulatory system. Ascorbic acid has also been proven to protect membrane and other hydrophobic compartments from such damage by regenerating the antioxidant form of vitamin E. In addition, reduced coenzyme Q, also a resident of hydrophobic compartments, interacts with vitamin E to regenerate its antioxidant form. The mechanism of vitamin C antioxidant function, the myriad of pathologies resulting from its clinical deficiency, and the many health benefits it provides, are reviewed.

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The role of DT-diaphorase in the maintenance of the reduced antioxidant form of coenzyme Q in membrane systems.

Beyer

Segura‐Aguilar

Bernardo

et al. 1996

Proc. Natl. Acad. Sci. U.S.A.

280

151

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Temperature, skeletal muscle mitochondrial functions, and oxygen debt

Brooks¹,

Hittelman²,

Faulkner³

et al. 1971

American Journal of Physiology-Legacy Content

223

115

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Temperature, skeletal muscle mitochondrid functions, and oxygen debt. Am. J* Physiol. 220(4): 1053-1059. 1971 .-Compared to resting liver and skeletal muscle temperatures of 38.6 and 36.0 C, respectively, postexercise values were 43.4 and 44,l C in viva. To determine the relationship between temperature and respiration, the 02 consumption of isolated rat skeletal muscle mitochondria was measured at temperatures between 25 and 45 C in vitro. Increasing temperature had a striking effect on mitochondrial functions. Between 37 and 45 C

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An analysis of the role of coenzyme Q in free radical generation and as an antioxidant

Beyer¹

1992

Biochem. Cell Biol.

228

126

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The vital role of coenzyme Q in mitochondrial electron transfer and its regulation, and in energy conservation, is well established. However, the role of coenzyme Q in free oxyradical formation and as an antioxidant remains controversial. Demonstration of the existence of the semiquinone form of coenzyme Q during electron transport, coupled with recent evidence that hydrogen peroxide (but not molecular oxygen) may act as an oxidant of the semiquinone, suggests that the highly reactive OH. radical may be formed from the semiquinone. On the other hand, data exist implicating the Fe-S species as the source of electron transfer chain, free radical production. Additional data exist suggesting instead that the unpaired electron of the coenzyme Q semiquinone most likely dismutases superoxide radicals. These concepts and those arising from observations at several levels of organization including subcellular systems, intact animals, and human subjects in the clinical setting, supporting the concept of reduced coenzyme Q as an antioxidant, will be presented. The results of recent studies on the interaction between the two-electron quinone reductase--DT diaphorase and coenzyme Q10 will be presented. The possibility that superoxide dismutase may interact with reduced coenzyme Q, in conjunction with DT diaphorase inhibiting its autoxidation, will be described. The regulation of cellular coenzyme Q concentrations during oxidative stress accompanying aerobic exercise, resulting in increased protection from free radical damage, will also be presented.

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The participation of coenzyme Q in free radical production and antioxidation

Beyer

1990

Free Radical Biology and Medicine

214

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Published experimental data pertaining to the participation of coenzyme Q as a site of free radical formation in the mitochondrial electron transfer chain and the conditions required for free radical production have been reviewed critically. The evidence suggests that a component from each of the mitochondrial NADH-coenzyme Q, succinate-coenzyme Q, and coenzyme QH2-cytochrome c reductases (complexes I, II, and III), most likely a nonheme iron-sulfur protein of each complex, is involved in free radical formation. Although the semiquinone form of coenzyme Q may be formed during electron transport, its unpaired electron most likely serves to aid in the dismutation of superoxide radicals instead of participating in free radical formation. Results of studies with electron transfer chain inhibitors make the conclusion dubious that coenzyme Q is a major free radical generator under normal physiological conditions but may be involved in superoxide radical formation during ischemia and subsequent reperfusion. Experiments at various levels of organization including subcellular systems, intact animals, and human subjects in the clinical setting, support the view that coenzyme Q, mainly in its reduced state, may act as an antioxidant protecting a number of cellular membranes from free radical damage.

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Robert E. Beyer

The role of ascorbate in antioxidant protection of biomembranes: Interaction with vitamin E and coenzyme Q

The role of DT-diaphorase in the maintenance of the reduced antioxidant form of coenzyme Q in membrane systems.

Temperature, skeletal muscle mitochondrial functions, and oxygen debt

An analysis of the role of coenzyme Q in free radical generation and as an antioxidant

The participation of coenzyme Q in free radical production and antioxidation

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