Marika Cavazzoni

Saturation kinetics of coenzyme Q in NADH and succinate oxidation in beef heart mitochondria

The saturation kinetics of NADH and succinate oxidation for Coenzyme Q (CoQ) has been re‐investigated in pentane‐extracted lyophilized beef heart mitochondria reconstituted with exogenous CoQ10. The apparent ‘K m’ for CoQ10 was one order of magnitude lower in succinate cytochrome c reductase than in NADH cytochrome c reductase. The K m value in NADH oxidation approaches the natural CoQ content of beef heart mitochondria, whereas that in succinate oxidation is close to the content of respiratory chain enzymes.

Studies on the role of ubiquinone in the control of the mitochondrial respiratory chain.

This study examines the possible role of Coenzyme Q (CoQ, ubiquinone) in the control of mitochondrial electron transfer. The CoQ concentration in mitochondria from different tissues was investigated by HPLC. By analyzing the rates of electron transfer as a function of total CoQ concentration, it was calculated that, at physiological CoQ concentration NADH cytochrome c reductase activity is not saturated. Values for theoretical Vmax could not be reached experimentally for NADH oxidation, because of the limited miscibility of CoQ10 with the phospholipids. On the other hand, it was found that CoQ3 could stimulate alpha-glycerophosphate cytochrome c reductase over three-fold. Electron transfer being a diffusion-coupled process, we have investigated the possibility of its being subjected to diffusion control. A reconstruction study of Complex I and Complex III in liposomes showed that NADH cytochrome c reductase was not affected by changing the average distance between complexes by varying the protein: lipid ratios. The results of a broad investigation on ubiquinol cytochrome c reductase in bovine heart submitochondrial particles indicated that the enzymic rate is not diffusion-controlled by ubiquinol, whereas the interaction of cytochrome c with the enzyme is clearly diffusion-limited.

The effect of aging and an oxidative stress on peroxide levels and the mitochondrial membrane potential in isolated rat hepatocytes

We have investigated the effect of ageing and of adriamycin treatment on the bioenergetics of isolated rat hepatocytes. Ageing per se, whilst being associated with a striking increase of hydrogen peroxide in the cells, induces only minor changes on the mitochondrial membrane potential. The adriamycin treatment induces a decrease of the mitochondrial membrane potential in situ and a consistent increase of the superoxide anion cellular content independently of the donor age. The hydrogen peroxide is significantly increased in both aged and adult rat hepatocytes, however, due to the high basal level in the aged cells, it is higher in aged rat cells not subjected to oxidative stress than that elicited by 50 μM adriamycin in young rat hepatocytes. The results suggest that a hydrogen peroxide increase in hepatocytes of aged rats is unable to induce major modifications of mitochondrial bioenergetics. This contrasts with the damaging effect of adriamycin, suggesting that the effects of the drug may be due to the concomitant high level of both superoxide and hydrogen peroxide.

Effect of the oxidative stress induced by adriamycin on rat hepatocyte bioenergetics during ageing.

We have investigated the effect of ageing and of adriamycin treatment on the bioenergetics of isolated rat hepatocytes. Ageing per se, whilst being associated with a striking increase of hydrogen peroxide in the cells, induces only minor changes on mitochondrial functions. The adriamycin treatment induces a decrease of the mitochondrial membrane potential in situ and a consistent increase of the superoxide anion cellular content independently of the donors age, whilst the hydrogen peroxide is significantly higher in aged than in adult rat hepatocytes. Kinetic studies in isolated mitochondria show that the mitochondrial respiratory chain activity (NADH --> O2) of 50 microM adriamycin-treated hepatocytes is lowered both in adult and aged rats. The same adriamycin concentration induces a slight decrease of the maximal rate of ATP hydrolysis in both young and aged rats, without affecting the Km for the substrate. However, at drug concentrations lower than 50 microM, both ATPase and NADH oxidation activities decrease significantly in aged rats only. The results suggest that free radicals increase during ageing in rat hepatocytes but are unable to induce major modifications of mitochondrial bioenergetics. This contrasts with the damaging effect of adriamycin, suggesting that some effects of the drug may be due to other reasons besides oxidative stress.

An updating of the biochemical function of Coenzyme Q in mitochondria

The apparent Km for coenzyme Q10 in NADH oxidation by coenzyme Q (CoQ)-extracted beef heart mitochondria is close to their CoQ content, whereas both succinate and glycerol-3-phosphate oxidation (the latter measured in hamster brown adipose tissue mitochondria) are almost saturated at physiological CoQ concentration. Attempts to enhance NADH oxidation rate by excess CoQ incorporation in vitro were only partially successful: the reason is in the limited amount of CoQ10 that can be incorporated in monomeric form, as shown by lack of fluorescence quenching of membrane fluorescent probes; at difference with CoQ10, CoQ5 quenches probe fluorescence and likewise enhances NADH oxidation rate above normal. Attempts to enhance the CoQ content in perfused rat liver and in isolated hepatocytes failed to show uptake in the purified mitochondrial fraction. Nevertheless CoQ cellular uptake is able to protect mitochondrial activities. Incubation of hepatocytes with adriamycin induces loss of respiration and mitochondrial potential measured in whole cells by flow cytometry using rhodamine 123 as a probe: concomitant incubation with CoQ10 completely protects both respiration and potential. An experimental study of aging in the rat has shown some decrease of mitochondrial CoQ content in heart, and less in liver and skeletal muscle. In spite of the little change observed, it is reasoned that CoQ administration may be beneficial in the elderly, owing to the increased demand for antioxidants.

Modes of coenzyme Q function in electron transfer

SummaryIn the mitochondrial respiratory chain, coenzyme Q acts in different ways. A diffusable coenzyme Q pool as a common substrate-like intermediate links the low-potential complexes with complex III. Its diffusion in the lipids is not rate-limiting for electron transfer, but its content is not saturating for maximal rate of NADH oxidation. Protein-bound coenzyme Q is involved in energy conservation, and may be part of enzyme supercomplexes, as in succinate cytochromec reductase. The reason for lack of kinetic saturation of the respiratory chain by quinone concentration is in the low extent of solubility of monomeric coenzyme Q in the membrane lipids. Assays of respiratory enzymes are performed using water soluble coenzyme Q homologs and analogs; several problems exist in using oxidized quinones as acceptors of coenzyme Q reductases. In particular, for complex I no acceptor appears to favorably substitute the endogenous quinone. In addition, quinone reduction sites in complex III compete with the sites in the dehydrogenases, particularly when using duroquinone. The different extent by which these sites operate when different donor substrates (NADH, succinate, glycerol-3-phosphate) are used is best explained by different exposure of the quinone acceptor sites in the dehydrogenases.

Evidence that photodynamic stress kills Zellweger fibroblasts by a nonapoptotic mechanism

Zellweger fibroblasts, which are devoid of peroxisomes and fail to synthesize plasmalogens, are very sensitive to the killing effect triggered by UV-activated 12-(1-pyrene) dodecanoic acid (P12). Although in some studied performed, it is assumed that reactive oxygen species (ROS) may damage plasma membrane causing necrosis, other studies suggest that ROS are involved in apoptotic cell death induced by a wide variety of stimuli. Analysing the P12 dose-response in Zellweger fibroblasts, we observed that at high doses (1-2 microM), more than 75% of the cells died after 24 h. This behaviour suggested that, at high doses, P12 kills the cells by unspecific lytic mechanisms or by necrosis, while at low doses (0.1-0.5 microM), an apoptotic mechanism could be involved. Cytofluorimetric analysis of Zellweger fibroblasts-treated with activated P12 (0.5 microM) did not show morphological modifications typical of apoptotic cell death. This was supported by comparative staining of fibroblast nuclei, DNA gel electrophoresis and identification of poly(ADP-ribose) polymerase (PARP) cleavage and Bcl-2 expression, assayed by Western blots. Thus, our results, while confirming the importance of plasmalogens in the protection against ROS, establish that apoptosis is not involved in photodynamic death induced by activated P12. Therefore, we can expect that in gene transfer experiments, the rescue of Zellweger cells will be dependent only on the correction of peroxisomal biogenesis.

Sphingosine-induced inhibition of capacitative calcium influx in CFPAC-1 cells

Sphingosine (10 microM) induced mobilization of intracellular Ca2+ stores in the pancreatic duct adenocarcinoma cell line CFPAC-1. The effect was specific for sphingosine, since the sphingosine analog C2-ceramide had no effect. Sphingosine did not cause Ca2+ entry from extracellular medium, as also shown by following Mn2+ quenching of Fura-2 fluorescence. Furthermore, sphingosine, similarly to the mitochondrial inhibitors rotenone and oligomycin, strongly inhibited the rate of Mn2+ entry triggered by both thapsigargin- and agonist-induced depletion of intracellular stores. The uptake of rhodamine 123, a lipophilic cation which estimates mitochondrial energy level, was reduced by sphingosine to an extent similar to that observed in the presence of mitochondrial inhibitors. It is suggested that impairment of mitochondrial function might be responsible for inhibition of capacitative Ca2+ entry caused by sphingosine.

Kinetic aspects of the interaction of cytochrome c with ubiquinol cytochrome c reductase in beef heart submitochondrial particles

Abstract We have undertaken a kinetic study of ubiquinol cytochrome c reductase, aimed at developing a better understanding of the interaction of its water-soluble substrate, cytochrome c , in bovine heart submitochondrial particles. We have confirmed that the enzyme kinetics is of a ping-pong two-site mechanism and is not very sensitive to ionic strength; nevertheless, the k cat / K m ratio, representing the minimal value of the association rate constant of cytochrome c , is decreased by increasing ionic strength. Several lines of evidence suggest that the association of cytochrome c with its active site is diffusion limited, including the high value of the k cat / K m ratio (greater than 10 8 M −1 s −1 ), its sensitivity to the viscosity of the medium, and its low activation energy. A break in the Arrhenius plot of the enzymic rate, obtained at cytochrome c concentrations considered saturating for the solubilized enzyme (about 15 μM), is artifactual and due to the steep increase in K m for cytochrome c at increasing temperatures. Accordingly, the Arrhenius plot becomes linear when the cytochrome c concentration is increased to over 50 μM.

Interaction of Coenzyme Q with the Mitochondrial Respiratory Chain

Extensive research in our laboratory on the Coenzyme Q pool in the inner mitochondrial membrane has demonstrated that (i) it is localized in the hydrophobic bilayer midplane with rapid oscillations of the polar benzoquinone ring towards the membrane surface; (ii) it undergoes rapid lateral diffusion which is not limiting for electron transfer; (iii) its concentration in the membrane lipids is not kinetically saturating for maximal velocity of respiration. Coenzyme Q is also a powerful antioxidant and its addition to isolated hepatocytes protects the respiratory chain from an adriamycin-induced oxidative stress. Finally, the quinone-binding subunits of Complex I, encoded by mitochondrial DNA, are functionally modified during aging, as shown by decreased rotenone sensitivity of NADH Coenzyme Q reductase in human platelet membranes from old individuals.