Hyperoxia fully protects mitochondria of explanted livers.

Liver ischemia-reperfusion injury is still an open problem in many clinical circumstances, including surgery and transplantation. This study investigates how mitochondrial structure, mass and oxidative phosphorylation change and may be preserved during a brief period of ischemia followed by a long period of reperfusion, an experimental model that mimics the condition to which a liver is exposed during transplantation. Livers were explanted from rats and exposed for 24 h to three different oxygen availability conditions at 4 °C. Mitochondrial mass, respiration, oxidative phosphorylation (OXPHOS), and levels of OXPHOS complexes were all significantly altered in livers stored under the currently used preservation condition of normoxia. Remarkably, liver perfusion with hyperoxic solutions fully preserved mitochondrial morphology and function, suggesting that perfusion of the graft with hyperoxic solution should be considered in human transplantation.

An open-label, dose-escalating phase I study of elsamitrucin (SPI 28090) in treatment of malignant solid tumors in dogs.

BACKGROUND: Elsamitrucin, the most potent topoisomerase II inhibitor available, is unique in that it does not cause neutropenia or cardiotoxicosis. It has antitumor activity in human patients with relapsed or refractory non-Hodgkin's lymphoma. OBJECTIVES: To determine the maximum tolerated dose (MTD), safety, and toxicity of elsamitrucin when administered to tumor-bearing dogs and to evaluate the incidence and severity of adverse events. ANIMALS: Twenty client-owned dogs with spontaneous malignant solid tumors or lymphoma that were refractory to, or for which the owner declined, conventional therapy were enrolled. METHODS: Prospective, open-label, single-agent study. Escalating doses of elsamitrucin were administered once weekly i.v. for up to 16 weeks in a modified 3 + 3 Phase I design. The starting dose was 0.06 mg/kg with escalation to 0.08 and 0.09 mg/kg. Dogs that remained on the study were monitored for evidence of toxicoses for at least 4 weeks and for survival every 2 months. RESULTS: Serious adverse events (SAEs) possibly attributable to elsamitrucin include: 1 dog developed heart failure and another developed hepatotoxicosis manifested by increased alanine aminotransferase, alkaline phosphatase, and total bilirubin (0.06 mg/kg dose); 1 dog developed severe anorexia and diarrhea, another developed severe diarrhea alone, and a 3rd dog went into cardiac arrest (0.09 mg/kg dose). A dose of 0.08 mg/kg was well tolerated with no SAEs. CONCLUSIONS AND CLINICAL IMPORTANCE: The MTD and recommended dose for Phase II trials of elsamitrucin is 0.08 mg/kg i.v. weekly. Elsamitrucin might be considered for combination protocols with myelosuppressive chemotherapy agents.

The primary role of glutathione against nuclear DNA damage of striatum induced by permethrin in rats.

Pyrethroids are one of the most widely used class of insecticides and their toxicity is dominated by pharmacological actions upon the CNS. This study reports as the subchronic treatment (60 days) with permethrin (PERM) (1/10 of LD(50)) induced nuclear DNA damage in rat striatum cells. Comet assay outcomes showed that PERM produced single- and double-strand breaks in striatum cells, the DNA damage was not related to oxidation at pyrimidine and purine bases. Vitamin E (280 mg/kg body weight/day) and vitamin E+coenzyme Q(10) (10 mg/kg/3 ml) supplementation could protect PERM treated rats against nuclear DNA damage. With the aim to evaluate the cause of nuclear DNA damage observed in striatum of rat treated with PERM, in vitro studies on striatum submitochondrial particles (SMPs) and on striatum cells treated with 10 muM PERM alone or plus 16 or 32 nM GSH were performed. SMPs incubated with PERM showed a decrease in superoxide anion release from the electron transport chain by inhibition of mitochondrial complex I. The effect could be related to the decrease of membrane fluidity measured in the hydrophilic-hydrophobic region of the mitochondrial membrane. This result discarded the involvement of the mitochondrial reactive oxygen species in the nuclear DNA damage. On the contrary, GSH played a crucial role on striatum since it was able to protect the cells against nuclear DNA damage induced by PERM. In conclusion our outcomes suggested that nuclear DNA damage of striatum cells was directly related to GSH depletion due to PERM insecticide.

Is supercomplex organization of the respiratory chain required for optimal electron transfer activity?

The supra-molecular assembly of the main respiratory chain enzymatic complexes in the form of "super-complexes" has been proved by structural and functional experimental evidence. This evidence strongly contrasts the previously accepted Random Diffusion Model stating that the complexes are functionally connected by lateral diffusion of small redox molecules (i.e. Coenzyme Q and cytochrome c). This review critically examines the available evidence and provides an analysis of the functional consequences of the intermolecular association of the respiratory complexes pointing out the role of Coenzyme Q and of cytochrome c as channeled or as freely diffusing intermediates in the electron transfer activity of their partner enzymes.

Modification of respiratory-chain enzyme activities in brown adipose tissue mitochondria by idebenone (hydroxydecyl-ubiquinone).

Idebenone (IDE), a synthetic analog of coenzyme Q, strongly activates glycerol phosphate (GP) oxidation in brown adipose tissue mitochondria. GP oxidase, GP cytochrome c oxidoreductase and GP dehydrogenase activities were all significantly stimulated by 13 muM IDE. Substituted derivatives of IDE acetyl- and methoxyidebenone had similar activating effects. When succinate was used as substrate, no activation by IDE could be observed. The activation effect of IDE could be explained as release of the inhibition of glycerol phosphate dehydrogenase by endogenous free fatty acids. NADH oxidoreductase activity and oxidation of NADH-dependent substrates were inhibited by IDE. The extent of the inhibition and IDE concentration dependence varied when various substrates were tested, being highest for pyruvate and lowest for 2-oxoglutarate. This study thus showed that the effect of IDE on various mitochondrial enzymes is very different and thus its therapeutic use should take into account its specific effect on various mitochondrial dehydrogenases in relation to particular defects of mitochondrial respiratory chain.

Mitochondrial changes induced by natural and synthetic asbestos fibers: studies on isolated mitochondria.

Asbestos fibers, such as chrysotile and crocidolite, are known to have cytotoxic effects on different cell types. In vivo exposure to asbestos fibers can induce both fibrotic and malignant lung diseases , however, the mechanisms linking exposure to the subsequent development of the diseases are unknown. Numerous investigations suggest the involvement of reactive oxygen species (ROS). ROS are known to damage biological macromolecules including proteins, cell membrane lipids and nucleic acids; alterations of these essential cellular components can alter cell function and can drive the cell to neoplastic transformation or to cell death. Because the mitochondrial respiratory chain is an important source of ROS and RNS (reactive nitogen species) in the cells, we have investigated the effects of aqueous extracts of asbestos (natural and synthetic) fibers on some mitochondrial activities. Our data show that crocidolite fibers release substances in solution that may interfere directly with the mitochondrial cytochrome oxidase complex. Moreover, the calcium ions released from these fibers induce opening of the permeability transition pore of the inner membrane leading to a possible cytotoxic effect due to the release of apoptotic factors normally localized in the mitochondrial intermembrane space. In addition, crocidolite extracts enhance the mitochondrial production of ROS. No significant biochemical effects are exerted by chrysotile, either natural or synthetic, on isolated mitochondria. Nevertheless, all asbestos fibers tested induce morphological alterations visualized by transmission electron microscopy and morphometric analysis.

Mitochondrial changes induced by natural and synthetic asbestos fibers: studies on isolated mitochondria.

Asbestos fibers, such as chrysotile and crocidolite, are known to have cytotoxic effects on different cell types. in vivo exposure to asbestos fibers can induce both fibrotic and malignant lung diseases , however, the mechanisms linking exposure to the subsequent development of the diseases are unknown. Numerous investigations suggest the involvement of reactive oxygen species (ROS). ROS are known to damage biological macromolecules including proteins, cell membrane lipids and nucleic acids; alterations of these essential cellular components can alter cell function and can drive the cell to neoplastic transformation or to cell death. Because the mitochondrial respiratory chain is an important source of ROS and RNS (reactive nitogen species) in the cells, we have investigated the effects of aqueous extracts of asbestos (natural and synthetic) fibers on some mitochondrial activities. Our data show that crocidolite fibers release substances in solution that may interfere directly with the mitochondrial cytochrome oxidase complex. Moreover, the calcium ions released from these fibers induce opening of the permeability transition pore of the inner membrane leading to a possible cytotoxic effect due to the release of apoptotic factors normally localized in the mitochondrial intermembrane space. In addition, crocidolite extracts enhance the mitochondrial production of ROS. No significant biochemical effects are exerted by chrysotile, either natural or synthetic, on isolated mitochondria. Nevertheless, all asbestos fibers tested induce morphological alterations visualized by transmission electron microscopy and morphometric analysis.

Increased state 4 mitochondrial respiration and swelling in early post-ischemic reperfusion of rat heart.

Isolated rat hearts were exposed to 30 min ischemia or to 30 min ischemia followed by 2, 5 or 40 min reperfusion and mitochondria were isolated at these different time points. ADP-stimulated, succinate-dependent respiration rate (state 3) was not significantly changed at the different time points examined. In contrast, state 4 (non-ADP-stimulated) respiration rate was significantly increased after 30 min ischemia, and it increased further during the first post-ischemic reperfusion period. Mitochondrial swelling, as evaluated under conditions of the major controlled ion channels (i.e. permeability transition pore and ATP-dependent mitochondrial K(+) channel) closed, significantly increased in parallel. It is suggested that the inner mitochondrial membrane permeability is increased under exposure of the heart to ischemia and early reperfusion, and that the phenomenon is reversible upon subsequent long periods of reperfusion.

Control of respiration by nitric oxide in Keilin-Hartree particles, mitochondria and SH-SY5Y neuroblastoma cells.

The pattern of cytochrome c oxidase inhibition by nitric oxide (NO) was investigated polarographically using Keilin-Hartree particles, mitochondria and human neuroblastoma cells. NO reacts with purified cytochrome c oxidase forming either a nitrosyl- or a nitrite-inhibited derivative, displaying distinct kinetics and light sensitivity of respiration recovery in the absence of free NO. Keilin-Hartree particles or cells, respiring either on endogenous substrates alone or in the presence of ascorbate, as well as state 3 and state 4 mitochondria respiring on glutamate and malate, displayed the rapid recovery characteristic of the nitrite derivative. All systems, when respiring in the presence of tetramethyl-p-phenylenediamine, were characterised by the slower, light-sensitive recovery typical of the nitrosyl derivative. Together the results suggest that the reaction of NO with cytochrome c oxidase in situ follows two alternative inhibition pathways, depending on the electron flux through the respiratory chain.

Apoptosis-resistant phenotype in HL-60-derived cells HCW-2 is related to changes in expression of stress-induced proteins that impact on redox status and mitochondrial metabolism.

The onset of resistance to drug-induced apoptosis of tumour cells is a major problem in cancer therapy. We studied a drug-selected clone of promyelocytic HL-60 cells, called HCW-2, which display a complex resistance to a wide variety of apoptosis-inducing agents and we found that these cells show a dramatic increase in the expression of heat shock proteins (Hsps) 70 and 27, while the parental cell line does not. It is known that stress proteins such as Hsps can confer resistance to a variety of damaging agents other than heat shock, such as TNF-alpha, monocyte-induced cytotoxicity, and also play a role in resistance to chemotherapy. This elevated expression of Hsps is paralleled by an increased activity of mitochondrial metabolism and pentose phosphate pathway, this latter leading to high levels of glucose-6-phosphate dehydrogenase and, consequently, of glutathione. Thus, the apoptotic-deficient phenotype is likely because of the presence of high levels of stress response proteins and GSH, which may confer resistance to apoptotic agents, including chemotherapy drugs. Moreover, the fact that in HCW-2 cells Hsp70 are mainly localised in mitochondria may account for the increased performances of mitochondrial metabolism. These observations could have some implications for the therapy of cancer, and for the design of combined strategies that act on antioxidant defences of the neoplastic cell.

A critical appraisal of the mitochondrial coenzyme Q pool.

The function of the coenzyme Q (CoQ) pool in the inner mitochondrial membrane is reviewed in view of recent findings suggesting a supramolecular organization of the mitochondrial respiratory complexes. In spite of the structural evidence for preferential aggregations of the inner membrane components, most kinetic evidence is in favor of a dispersed organization based on random collisions of the small connecting redox components, in particular CoQ, with the individual complexes. The shape of the CoQ molecule in the pool, suggested to be a folded one, is in agreement with its very rapid lateral diffusion mobility in the membrane midplane. Since the structural evidence in favor of specific supercomplexes is rather strong, it cannot be excluded that electron transfer may follow either pool behavior or preferential channeling depending on the physiological conditions. Another function ascribed to the CoQ pool is the antioxidant action of the reduced CoQ molecules; although it cannot be excluded that protein-bound ubisemiquinones may be a source of oxygen radicals, particularly at the level of complex III, the available evidence suggests that the mitochondrial pool only behaves as an antioxidant under physiological conditions.

The site of production of superoxide radical in mitochondrial Complex I is not a bound ubisemiquinone but presumably iron-sulfur cluster N2.

The mitochondrial respiratory chain is a powerful source of reactive oxygen species, considered as the pathogenic agent of many diseases and of aging. We have investigated the role of Complex I in superoxide radical production in bovine heart submitochondrial particles and found, by combined use of specific inhibitors of Complex I and by Coenzyme Q (CoQ) extraction from the particles, that the one-electron donor in the Complex to oxygen is a redox center located prior to the binding sites of three different types of CoQ antagonists, to be identified with a Fe-S cluster, most probably N2 on the basis of several known properties of this cluster. Short chain CoQ analogs enhance superoxide formation, presumably by mediating electron transfer from N2 to oxygen. The clinically used CoQ analog, idebenone, is particularly effective in promoting superoxide formation.

Lymphocyte dysmetabolism: an immunocytochemical comparative approach in IDDM and control subjects.

We have investigated by immuno-electron microscopy the presence of phosphotyrosine in cells as a whole and in different cell districts (nucleus, cytoplasm, plasma membrane, and mitochondria) in peripheral blood lymphocytes of IDDM (insulin-dependent diabetes mellitus) patients and age-matched controls. Immuno-gold particle density was highest in mitochondria and decreased in cytoplasm, nucleus and plasma membrane. The time dependence of phosphotyrosine labelling after cell isolation was very strong in all subcellular populations, with a fall in immunogold staining after 30 min. Staining levels at zero time were similar in controls and IDDM patients; the loss of phosphotyrosine labelling was much stronger in controls, except in the plasma membrane. Plasma membrane NADH oxidoreductase activity, studied using cytosolic NADH as substrate and assayed with DCIP as acceptor, was significantly increased in IDDM patients, suggesting a response to a deficient mitochondrial energetic activity. The fact that NADH oxidoreductase is a growth factor related to tyrosine phosphorylation pathways raises intriguing questions on the cellular derangement occurring in peripheral lymphocytes in IDDM, although the relationships among the immunocytochemical and biochemical changes is still obscure.

Decreased Pasteur effect in platelets of aged individuals.

We have investigated the mitochondrial energy state in human platelets of young (19-30 years old) and aged individuals (65-87 years old) exploiting the Pasteur effect, i.e. stimulation of lactate production by incubation of the purified platelets with the mitochondrial respiratory chain inhibitor, antimycin A. This assay allows the determination of mitochondrial function with respect to glycolysis, and the ratio of mitochondrial adenosine triphosphate (ATP) to glycolytic ATP. A significant increase of basal, non-stimulated lactate production and decrease of the stimulation by antimycin A were observed in the older individuals, suggesting that the impairment of oxidative phosphorylation detectable in post-mitotic tissues of aged individuals can be observed also in easily collectable blood cells.

[Coenzyme Q and its therapeutic use]. / Koenzym Q a jeho lécebné vyuzití.

Coenzyme Q (CoQ), a lipophilic substituted benzoquinone, is present in all animal and plant cells. It is endogenously synthesised in tissues and involved in a variety of cellular processes. It is well documented that CoQ is an obligatory component of the respiratory chain in the inner mitochondrial membrane coupled to ATP synthesis. However, its additional localisation in different subcellular fractions is probably associated with its multiple functions in the cell (as a part of extramitochondrial electron transport chains, a powerful antioxidant agent or a membrane stabiliser). The actions outlined for CoQ can explain its broad range of therapeutic effects. This presentation is a brief review of recent knowledge concerning medical aspects of CoQ in mammals. The energetic role seems sufficient to explain at least some of the clinical effects (heart failure, neurodegenerative diseases) but in other cases the antioxidant function may be a more convenient explanation. Nevertheless, a better knowledge of CoQ functions at the molecular level and additional well-designed studies are required to provide specific recommendation and definitive evidence of its therapeutic effects.

Does coenzyme Q10 play a role in opposing oxidative stress in patients with age-related macular degeneration?

To seek some specific biochemical markers of age-related macular degeneration (AMD), coenzyme Q10 (CoQ10) levels were determined in plasma and platelets from 19 exudative AMD patients and 19 age-matched controls. Lipid peroxidation was followed in plasma in vitro after the addition of a free radical initiator. Most patients had lower plasma CoQ10 content than most controls. Plasma from controls showed greater capacity to oppose the oxidative damage. These results support the concept that free radicals play a pathogenic role in AMD and that CoQ10 may have a protective effect.

The mitochondrial production of reactive oxygen species: mechanisms and implications in human pathology.

Mitochondria are major sources of reactive oxygen species (ROS); the main sites of superoxide radical production in the respiratory chain are Complexes III and I; however, other mitochondrial enzymes, such as Complex II, glycerol-1-phosphate dehydrogenase, and dihydroorotate dehydrogenase, are also involved in production of ROS. ROS appear to be released both in the matrix and in the intermembrane space; however, their appearance outside the mitochondria may not be physiologically relevant. ROS production is increased in State 4 and in all conditions when the respiratory components are substantially in the reduced form. Accordingly, defects inducing decrease of electron transfer in the respiratory chain, as in many pathological conditions, are bound to enhance ROS production.

Mitochondrial bioenergetics in aging.

Mitochondria are strongly involved in the production of reactive oxygen species, considered as the pathogenic agent of many diseases and of aging. The mitochondrial theory of aging considers somatic mutations of mitochondrial DNA induced by oxygen radicals as the primary cause of energy decline; experimentally, complex I appears to be mostly affected and to become strongly rate limiting for electron transfer. Mitochondrial bioenergetics is also deranged in human platelets upon aging, as shown by the decreased Pasteur effect (enhancement of lactate production by respiratory chain inhibition). Cells counteract oxidative stress by antioxidants; among lipophilic antioxidants, coenzyme Q is the only one of endogenous biosynthesis. Exogenous coenzyme Q, however, protects cells from oxidative stress by conversion into its reduced antioxidant form by cellular reductases.

Surface oxidase and oxidative stress propagation in aging.

This report summarizes new evidence for a plasma-membrane-associated hydroquinone oxidase designated as CNOX (constitutive plasma membrane NADH oxidase) that functions as a terminal oxidase for a plasma membrane oxidoreductase (PMOR) electron transport chain to link the accumulation of lesions in mitochondrial DNA to cell-surface accumulations of reactive oxygen species. Previous considerations of plasma membrane redox changes during aging have lacked evidence for a specific terminal oxidase to catalyze a flow of electrons from cytosolic NADH to molecular oxygen (or to protein disulfides). Cells with functionally deficient mitochondria become characterized by an anaerobic metabolism. As a result, NADH accumulates from the glycolytic production of ATP. Elevated PMOR activity has been shown to be necessary to maintain the NAD(+)/NADH homeostasis essential for survival. Our findings demonstrate that the hyperactivity of the PMOR system results in an NADH oxidase (NOX) activity capable of generating reactive oxygen species at the cell surface. This would serve to propagate the aging cascade both to adjacent cells and to circulating blood components. The generation of superoxide by NOX forms associated with aging is inhibited by coenzyme Q and provides a rational basis for the anti-aging activity of circulating coenzyme Q.