Effect of UV-C mediated oxidative stress in leukemia cell lines and its relation to ubiquinone content

UV-C radiation is able to impair cellular functions by directly damaging DNA, and by inducing an increased formation of reactive oxygen species that leads to a condition of oxidative stress. In this study we evaluated different responses to UV insult of two leukemia cell lines, HL-60 and Raji, and the relationship with their CoQ10 content. DNA damage was monitored by means of the alkaline single cell gel electrophoresis (Comet assay); intracellular levels of ROS, mitochondrial depolarization and cell viability was measured by flow cytometry. Raji cells appeared more resistant to the UV insult; moreover, they did not show any increase in ROS content and the extent of mitochondrial depolarisation was much lower than in HL 60 cell line. Raji cells also contained significantly higher levels of CoQ10 and their ability to incorporate and to reduce exogenous CoQ10 added to the culture medium was remarkably elevated compared with HL 60.     

NQO1-dependent redox cycling of idebenone: effects on cellular redox potential and energy levels

Short-chain quinones are described as potent antioxidants and in the case of idebenone have already been under clinical investigation for the treatment of neuromuscular disorders. Due to their analogy to coenzyme Q10 (CoQ10), a long-chain quinone, they are widely regarded as a substitute for CoQ10. However, apart from their antioxidant function, this provides no clear rationale for their use in disorders with normal CoQ10 levels. Using recombinant NAD(P)H:quinone oxidoreductase (NQO) enzymes, we observed that contrary to CoQ10 short-chain quinones such as idebenone are good substrates for both NQO1 and NQO2. Furthermore, the reduction of short-chain quinones by NQOs enabled an antimycin A-sensitive transfer of electrons from cytosolic NAD(P)H to the mitochondrial respiratory chain in both human hepatoma cells (HepG2) and freshly isolated mouse hepatocytes. Consistent with the substrate selectivity of NQOs, both idebenone and CoQ1, but not CoQ10, partially restored cellular ATP levels under conditions of impaired complex I function. The observed cytosolic-mitochondrial shuttling of idebenone and CoQ1 was also associated with reduced lactate production by cybrid cells from mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes (MELAS) patients. Thus, the observed activities separate the effectiveness of short-chain quinones from the related long-chain CoQ10 and provide the rationale for the use of short-chain quinones such as idebenone for the treatment of mitochondrial disorders.     

Clinical implications of the correlation between coenzyme Q10 and vitamin B6 status.

The endogenous biosynthesis of the quinone nucleus of coenzyme Q10 (CoQ10) from tyrosine is dependent on adequate vitamin B6 nutriture. Lowered blood and tissue levels of CoQ10 have been observed in a number of clinical conditions. Many of these clinical conditions are most prevalent among the elderly. Kalen et al. have shown that blood levels of CoQ10 decline with age. Similarly, Kant et al. have shown that indicators of vitamin B6 status also decline with age. Blood samples were collected from 29 patients who were not currently being supplemented with either CoQ10 or vitamin B6. Mean CoQ10 concentrations was 1.1 +/- 0.3 micrograms/ml of blood. Mean specific activities of EGOT was 0.30 +/- 0.13 mumol pyruvate/hr/10(8) erythrocytes and the mean percent saturation of EGOT with PLP was 78.2 +/- 13.9%. Means for all parameters were within normal ranges. Strong positive correlation was found between CoQ10 and the specific activity of EGOT (r = 0.5787, p < 0.001) and between CoQ10 and the percent saturation of EGOT with PLP (r = 0.4174, p < 0.024). Studies are currently in progress to determine the effect of supplementation with vitamin B6 of blood CoQ10 levels. It appears prudent to recommend that patients receiving supplemental CoQ10 be concurrently supplemented with vitamin B6 to provide for better endogenous synthesis of CoQ10 along with the exogenous CoQ10.     

Coenzyme Q10 Protects Astrocytes from ROS-Induced Damage through Inhibition of Mitochondria-Mediated Cell Death Pathway

Coenzyme Q10 (CoQ10) acts by scavenging reactive oxygen species to protect neuronal cells against oxidative stress in neurodegenerative diseases. The present study was designed to examine whether CoQ10 was capable of protecting astrocytes from reactive oxygen species (ROS) mediated damage. For this purpose, ultraviolet B (UVB) irradiation was used as a tool to induce ROS stress to cultured astrocytes. The cells were treated with 10 and 25 μg/ml of CoQ10 for 3 or 24 h prior to the cells being exposed to UVB irradiation and maintained for 24 h post UVB exposure. Cell viability was assessed by MTT conversion assay. Mitochondrial respiration was assessed by respirometer. While superoxide production and mitochondrial membrane potential were measured using fluorescent probes, levels of cytochrome C (cyto-c), cleaved caspase-9, and caspase-8 were detected using Western blotting and/or immunocytochemistry. The results showed that UVB irradiation decreased cell viability and this damaging effect was associated with superoxide accumulation, mitochondrial membrane potential hyperpolarization, mitochondrial respiration suppression, cyto-c release, and the activation of both caspase-9 and -8. Treatment with CoQ10 at two different concentrations started 24 h before UVB exposure significantly increased the cell viability. The protective effect of CoQ10 was associated with reduction in superoxide, normalization of mitochondrial membrane potential, improvement of mitochondrial respiration, inhibition of cyto-c release, suppression of caspase-9. Furthermore, CoQ10 enhanced mitochondrial biogenesis. It is concluded that CoQ10 may protect astrocytes through suppression of oxidative stress, prevention of mitochondrial dysfunction, blockade of mitochondria-mediated cell death pathway, and enhancement of mitochondrial biogenesis.     

Effects of dietary L-carnitine and coenzyme Q10 supplementation on performance and ascites mortality of broilers

The study was conducted to determine the effects of dietary L-carnitine and coenzyme Q10 (CoQ10) supplementation on growth performance and ascites mortality of broilers. A 3 x 3 factorial arrangement was employed with three levels (0, 75 and 150 mg/kg) of L-carnitine and three levels of CoQ10 (0, 20 and 40 mg/kg) supplementation during the experiment. Five hundred and forty one-day-old Arbor Acre male broiler chicks were randomly allocated into nine groups with six replicates each. All birds were fed with the basal diets from day 1 to 7 and changed to the experimental diets from day 8. During day 15 to 21 all the birds were exposed to low ambient temperature (15-18 degrees C) to induce ascites. The results showed that under this condition, growth performance of broilers were not significantly affected by CoQ10 or L-carnitine + CoQ10 supplementation during week 0-3 and 0-6, but body weight gain (BWG) of broilers was significantly reduced by 150 mg/ kg L-carnitine during week 0-6. Packed cell volume (PCV) of broilers was significantly decreased by L-carnitine and L-carnitine + CoQ10 supplementation (P < 0.05). Erythrocyte osmotic fragility (EOF), ascites heart index (AHI) and ascites mortality of broilers were significantly decreased by L-carnitine, CoQ10 and L-carnitine + CoQ10 supplementation. Though no significant changes were observed in total antioxidative capability (T-AOC), total superoxide dismutase (T-SOD) was increased by L-carnitine, CoQ10 and L-carnitine + CoQ10 supplementation (P < 0.05). Malonaldehyde (MDA) content was significantly decreased by CoQ10 and L-carnitine + CoQ10 supplementation. The results indicate that dietary L-carnitine and CoQ10 supplementation reduce ascites mortality of broilers; the reason may be partially associated with their antioxidative effects.     

A correlation between phorbol diester-induced protein phosphorylation and superoxide anion generation in HL-60 cells during granulocytic maturation

As HL-60 cells matured along the granulocytic pathway, phorbol diester-induced superoxide anion production was compared to phorbol diester-induced protein phosphorylation using an in vitro phosphorylation technique. Maturation was induced by 0, 2, 4, or 6 days incubation with dimethyl sulfoxide (Me2SO). In 0 day Me2SO HL-60 cells, phorbol 12-myristate 13-acetate induced phosphorylation of protein pp29 (Mr = 28,600) and to a lesser extent protein pp76 (Mr = 76,300). With increased time of Me2SO incubation, phorbol 12-myristate 13-acetate induced phosphorylation of pp212 (Mr = 211,800), pp134 (Mr = 134,200), and pp76, whereas the phosphorylation of pp29 did not change appreciably. In close agreement with this increase in protein phosphorylation was the observed increase in phorbol diester-induced superoxide anion formation. Morphological characterization of cells during Me2SO-induced differentiation reveals that these increases in phorbol diester responses are probably attributable to the proportional rise in metamyelocytes, band, and segmented neutrophils. A variety of phorbol diesters increased superoxide anion generation in HL-60 cells differentiated into granulocyte-like cells by 6-day incubation with Me2SO. The structure-activity relationship of these phorbol diester derivatives for protein phosphorylation was strongly correlated to their ability to increase superoxide anion generation. Thus, we propose that phorbol diester-induced phosphorylation of pp212, pp134, and pp76, but not pp29 may play a role in mediating the functional response of phorbol diester-induced superoxide anion generation in HL-60 cells differentiated into mature granulocyte-like cells.     

Induction of the respiratory burst in HL-60 cells. Correlation of function and protein expression

Differentiation of myeloid cells is associated with the gradual acquisition of functional capacity to produce a respiratory burst. In our study HL-60 cells were differentiated to the monocyte phenotype with IFN-gamma or 1,25-dihydroxyvitamin D3, or to the neutrophil phenotype with retinoic acid or DMSO to compare the time-course of expression of membrane and cytosolic oxidase components, and to correlate this with the appearance of a functional oxidase. Over a 6-day period of induction the rank order of the ability of these agents to induce expression of PMA-stimulated superoxide production was: IFN-gamma greater than 1,25(OH)2D3 greater than retinoic acid greater than DMSO. Immunoblot analysis of HL-60 membranes and cytosol was used to assess the amount of specific phagocyte oxidase factors (91 and 22 kDa subunits of membrane cytochrome b558 (gp91 and p22), and 47 and 67 kDa cytosol oxidase factors (p47 and p67)). HL-60 cell membranes or cytosol were tested in a cell-free assay of superoxide production by mixing with normal neutrophil cytosol or membranes, respectively. p47 was first detected at 16 h of differentiation, increasing similarly thereafter with all induction regimens and reaching a maximum by 3 to 4 days. The earliest detection of p67 varied from 2 to 6 days depending on the inducing agent and appeared to be the limiting cytosol component. Small amounts of both subunits of cytochrome b558 were detected in uninduced HL-60 membranes, but were sufficient to support substantial superoxide production when combined with normal neutrophil cytosol. Both cytochrome b558 subunit proteins and membrane oxidase activity increased during differentiation in parallel. We conclude that membrane and cytosol components of the NADPH oxidase complex appear at different times and increase differently during HL-60 differentiation. The production of p67 is the major factor limiting the respiratory burst during HL-60 differentiation.     

Pivotal role of reactive oxygen species as intracellular mediators of hyperthermia-induced apoptosis

The effects of cellular antioxidant capacity on hyperthermia (HT)-induced apoptosis and production of antiapoptotic heat shock proteins (HSPs) were investigated in HL-60 cells and in HL-60AR cells that are characterized by an elevated endogenous catalase activity. Exposure of both cell lines to 43 degrees C for 1 h initiated apoptosis. Apoptosis peaked at 3-6 h after heat exposure in the HL-60 cells. Whereas HL-60AR cells were partially protected against HT-induced apoptosis at these early time points, maximal levels of apoptosis were detected later, i.e. 12-18 h after heat exposure. This differential induction of apoptosis was directly correlated to the induction of the antiapoptotic HSP27 and HSP70. In particular, in the HL-60 cells HSP27 was significantly induced at 12-18 h after exposure to 43 degrees C when apoptosis dropped. In contrast, coinciding with the late onset of apoptosis in HL-60AR cells at that time HL-60AR cells lacked a similar HSP response. In line with the higher antioxidant capacity HL-60AR cells accumulated reactive oxygen species to a lesser degree than HL-60 cells after heat treatment. Protection from HT-induced apoptosis as well as diminished heat-induced HSP27 expression was also observed after cotreatment of HL-60 cells with 43 degrees C and catalase but not with superoxide dismutase. These data emphasize the pivotal role of reactive oxygen species for HT induced pro- and antiapoptotic pathways.     

Sodium Valproate Facilitates the Propagation of Granulocytic Ehrlichiae (Anaplasma phagocytophilum) in HL-60 Cells

As already shown, some inducers of the differentiation of promyelocytic cells along the granulocytic pathway, such as dimethylsulphoxide (DMSO) or all-trans retinoic acid, can enhance propagation of granulocytic ehrlichiae in HL-60 cell cultures. This study was conducted to prove whether sodium valproate, a salt of di-n-propylacetic acid (VPA) known to trigger cellular differentiation in several solid and hematopoietic malignancies is similarly efficient in ehrlichial cultures. Two cell lines derived from HL-60, that is, low-passage undifferentiated HL-60 (HL-60F) and high-passage HL-60 spontaneously differentiated towards monocytic phenotype (HL-60J) were grown in RPMI 1640 medium supplemented with 10% FBS. The respective HL-60F and HL-60J IC₅₀-values for NaVPA were estimated to be 0.8 and 2.2 mM under these culture conditions; to stimulate the differentiation, the respective doses of 0.3 and 1.2 mM were then applied. When the NaVPA-treated cells of both lines were challenged with an ehrlichial laboratory strain (HGE), maintained in splenectomized NMRI mice, the respective 1–2 and ≤0.1% primary infection rates in HL-60F and HL-60J cultures were observed 3 days post-inoculation. In comparison, only rare (≤0.1%) infected HL-60F and no infected HL-60J cells were recorded under the same experimental conditions in untreated control cultures. HGE continuously propagated in NaVPA-supplemented HL-60F cultures remained infectious to mice at least up to the 95th passage (12 months). NaVPA can thus facilitated continuous propagation of granulocytic ehrlichiae in cell cultures without a substantial loss of infectiveness. This revised version was published online in July 2006 with corrections to the Cover Date.     

Induction of cytotoxic effector activity in the HL-60 promyelocytic cell line by incubation with phorbol myristate acetate: a model system of human spontaneous monocyte-mediated cytotoxicity

In an attempt to develop a constant and reproducible in vitro system for a detailed analysis of cytotoxic effector mechanisms of nonimmune mononuclear phagocytes, the HL-60 promyelocytic cell line was studied for its cytotoxic action on chicken erythrocyte target cells. HL-60 cells cultured in complete medium were found to be noncytotoxic for chicken erythrocytes in an 18-hr 51Cr-release assay. These cells have been shown to acquire several characteristics of mature macrophages upon incubation with phorbol myristate acetate (PMA), and when PMA was included in the medium during the assay, the HL-60 cells became strongly cytotoxic to the target cells in the absence of exogenous antibody, lectin, or serum complement. Freshly isolated peripheral blood monocytes also became cytotoxic in the presence of PMA, whereas peripheral blood lymphocytes and the U937 histiocytic cell line did not. Detectable target lysis was observed between 4 and 8 hr after HL-60 stimulation with PMA, and HL-60 cells prestimulated with PMA for 24 hr retained their cytotoxic activity following washing and assay in PMA-free medium. Cytotoxic HL-60 cells developed after exposure to 10(-6) to 10(-9) M PMA, and significant target cell lysis occurred at effector:target cell ratios as low as 0.5:1. The PMA-induced HL-60-mediated cytotoxic response was markedly inhibited by blockers of protein synthesis, inhibition of microfilament function, and depletion of cellular superoxide and hydrogen peroxide. Interestingly, cytotoxicity of HL-60 cells for chicken erythrocyte targets was modulated by the direct addition of certain simple saccharides to the assay in a fashion similar to that observed with spontaneously cytotoxic mononuclear cells from several vertebrate and invertebrate species. Thus, the cytolytic effector function induced in HL-60 cells by incubation with PMA presents a useful model for the study of cellular cytotoxic mechanisms as well as the mechanisms utilized by nonimmune cells in the recognition of non-self.     

Analysis of dihydroethidium fluorescence for the detection of intracellular and extracellular superoxide produced by NADPH oxidase

All methods used for quantitation of superoxide have limitations when it comes to differentiating between extracellular and intracellular sites of superoxide production. In the present study, we monitored dihydroethidium (DHE)-derived fluorescence at 570 nm, which indicates hydroxyethidium derived from reaction with superoxide produced by human leukemia cells (HL-60) and microvascular endothelial cells (HMEC-1). Phorbol-12-myristate 13-acetate (PMA; 100 ng/ml) caused an increase in fluorescence and lucigenin chemiluminescence in HL-60, which was abolished by superoxide dismutase (SOD; 600 U/ml) indicating that DHE detects extracellular superoxide. Furthermore, both HL-60 cells and HMEC-1 generated a fluorescence signal in the presence of DHE under resting conditions, which was unaffected by SOD, but abolished by polyethylene glycosylated-SOD (PEG-SOD) (100 U/ml) and MnTmPyP (25 μM), indicating that DHE also detects superoxide produced intracellularly. In HMEC-1, silencing of either Nox2 or Nox4 components of NADPH oxidase with small interference RNA (siRNA) resulted in a significant reduction in superoxide detected by both DHE fluorescence (Nox2 siRNA; 71 ± 6% and Nox4 siRNA 83 ± 7% of control) and lucigenin chemiluminescence (Nox2; 54 ± 6% and Nox4 74 ± 4% of control). In conclusion, DHE-derived fluorescence at 570 nm is a convenient method for detection of intracellular and extracellular superoxide produced by phagocytic and vascular NADPH oxidase.     

Effect of coenzyme Q10 on catalase activity and other antioxidant parameters in streptozotocin-induced diabetic rats

Although coenzyme Q10 (CoQ10) is a component of the oxidative phosphorylation process in mitochondria that converts the energy in carbohydrates and fatty acids into ATP to drive cellular machinery and synthesis, its effect in type I diabetes is not clear. We have studied the effect of 4 wk of treatment with CoQ10 (10 mg/kg, ip, daily) in streptozotocin (STZ)-induced (40 mg/kg, iv in adult rats) type I diabetes rat models. Treatment with CoQ10 produced a significant decrease in elevated levels of glucose, cholesterol, triglycerides, very-low-density lipoprotein, lowdensity lipoprotein, and atherogenic index and increased high-density lipoprotein cholesterol levels in diabetic rats. CoQ10 treatment significantly decreased the area under the curve over 120 min for glucose in diabetic rats, without affecting serum insulin levels and the area under the curve over 120 min for insulin in diabetic rats. CoQ10 treatment also reduced lipid peroxidation and increased antioxidant parameters like superoxide dismutase, catalase, and glutathione in the liver homogenates of diabetic rats. CoQ10 also lowered the elevated blood pressure in diabetic rats. In conclusion, CoQ10 treatment significantly improved deranged carbohydrate and lipid metabolism of experimental chemically induced diabetes in rats. The mechanism of its beneficial effect appears to be its antioxidant property.     

辅酶Q_(10)的毒性试验及对溶血空斑形成细胞的刺激效应

辅酶Q_10（以下简称CoQ_(10)）是生物体内普遍存在的一类生物活性物质,具有重要的生理、生化作用。它是细胞呼吸链中主要的递氢体,在生物能量转化中占重要地位,它又能作为非特异性免疫增强剂,增强机体的防御能力,因此人们对于CoQ_(10)的临床研究越来越受到重视（中国科学院昆明动物研究所,1979）。 我们结合我国具体情况,独创地从提取细胞色素丙的猪心残渣中分离制备了CoQ_(10), （许以盛等,1985）,并与有关生产及临床单位协作,于1977年12月通过了鉴定,为我国的生化药物填补了一项空白。     

Inhibition of N-linked glycosylation induces early apoptosis in human promyelocytic HL-60 cells

Inhibition of protein N-glycosylation by tunicamycin induced morphological changes characteristic of apoptosis in human promyelocytic HL-60 cells. Internu-cleosomal DMA fragmentation could be detected after short-time incubation (between 6 and 9 h) of HL-60 cells with low doses of tunicamycin (0.05 μg/ml). Under these conditions the synthesis of glycoproteins was reduced to 17% of control values, while no significant changes in the rates of total protein synthesis could be observed. Tunicamycin ability to induce DNA fragmentation was in good correlation with its potency as glycosylation inhibitor in several myeloid cell lines. Tunicamycin-induced apoptosis was potentiated by activation of protein kinease C (PKC) by phorbol esters and partially prevented by the PKC inhibitor staurosporine. Inhibitors of RNA and protein synthesis displayed a protective effect. Treatment of HL-60 cells with tunicamycin did not elicit the expression of cell surface differentiation antigens or their ability to generate superoxide anion. In contrast, tunicamycin significantly inhibited these processes during dimethyl sulfoxide (DMSO)-induced myeloid differentiation. These observations indicate that the main effect of tunicamycin in HL-60 cells is the induction of apoptosis. © 1995 Wiley-Liss, Inc.     

Induction of the differentiation of HL-60 promyelocytic leukemia cells by L-ascorbic acid

The present study was undertaken to examine the effect of L-ascorbic acid (LAA) on the growth of HL-60 promyelocytic leukemia cells, besides induction of apoptosis. LAA (> or = 10(-4) M) was found to markedly inhibit the proliferation of HL-60 in liquid culture and clonogenicity in semisolid culture. Moreover, LAA-treated HL-60 showed activity to produce chemiluminescence and expressed CD 66b cell surface antigens, indicating that LAA induces the differentiation of HL-60 mainly into granulocytes. The results are supported by morphological changes of LAA-treated HL-60 into segmented neutrophils. Therefore, the inhibitory effect of LAA on the growth of HL-60 cells seems to arise from the induction of differentiation. To assess the potential role of LAA, cells were exposed to oxygen radical scavengers in the absence or presence of LAA. Catalase abolished and superoxide dismutase promoted LAA-induced differentiation of HL-60. Thus, H2O2 produced as a result of LAA treatment seems to play a major role in induction of HL-60 differentiation.     

Chronic administration of coenzyme Q<Subscript>10</Subscript> limits postinfarct myocardial remodeling in rats

The effect of chronic coronary artery occlusion on the content of rat myocardial coenzymes Q (CoQ) and evaluation of the applicability of CoQ(10) for limiting postinfarct remodeling have been investigated. Left ventricle myocardium hypertrophy was characterized by the decrease in CoQ(9) (-45%, p < 0.0001), CoQ(10) (-43%, p < 0.001), and alpha-tocopherol (-35%, p < 0.05). There were no differences between the parameters of postinfarction and sham-operated rats in plasma. Administration of CoQ(10) (10 mg/kg) via a gastric probe for 3 weeks before and 3 weeks after occlusion maintained higher levels of CoQ in the postinfarction myocardium: the decrease in CoQ(9) and CoQ(10) was 25% (p < 0.05) and 23% (p < 0.05), respectively (versus sham-operated animals). Plasma concentrations of CoQ(10) were more than 2 times higher (p < 0.05). In CoQ treated rats there was significant correlation between plasma levels of CoQ and the infarct size: r = -0.723 (p < 0.05) and r = -0.839 (p < 0.01) for CoQ(9) and CoQ(10). These animals were also characterized by earlier and more intensive scar tissue formation in the postinfarction myocardium and also by more pronounced cell regeneration processes. This resulted in the decrease in both the infarct size (16.2 +/- 8.1 vs. 27.8 +/- 12.1%) and also mass index of left ventricle (2.18 +/- 0.24 vs. 2.38 +/- 0.27 g/kg) versus untreated rats (p < 0.05). Thus, long-term treatment with ubiquinone increases plasma and myocardial CoQ content and this can improve the survival of myocardial cells during ischemia and limit postinfarct myocardial remodeling.     

Effects of treatment with coenzyme Q10 on exercised rat aorta

In this study, the effect of long-term supplementation of coenzyme Q10 (CoQ10) on the responses of swim-trained rat aorta was investigated. Twenty-four adult male Wistar rats were divided into four groups: untrained, trained, untrained+CoQ10, and trained+CoQ10 group. In the trained groups rats swam for 60 min/day, five days/week for six weeks. The CoQ10 supplements were administered by intraperitoneal injection at a daily dose of 10 mg·kg-1 of body weight five days/week for six weeks. Swimming of the rats was performed in a container containing tap water. Rats were sacrificed and thoracic aortas were removed for ex vivo analysis after the last swimming session. The aortas were cut into rings 2.5 mm in length. Concentration-response curves for phenylephrine (PHE, 10-9-3×10-4 M) and potassium chloride (KCl, 5-100 mM) were isometrically recorded. The sensitivity and maximal responses to PHE and KCl of aortic rings obtained from trained rats were lower than those of untrained rats. CoQ10 supplementation decreased the responses to both vasoconstrictors in untrained and especially in trained groups. Although neither CoQ10 nor training did affect malondialdehyde (MDA) and protein carbonyl (PC) levels, creatine kinase (CK) activity decreased and superoxide dismutase (SOD) activity increased only with exercise training. Glutathione (GSH) levels increased in CoQ10 supplemented-untrained rats. In conclusion, our results suggest that CoQ10 supplementation may have beneficial effects during exercise.     

Enrichment of coenzyme Q10 in plasma and blood cells: defense against oxidative damage

Coenzyme Q10 (CoQ10) concentration in blood cells was analyzed by HPLC and compared to plasma concentration before, during, and after CoQ10 (3 mg/kg/day) supplementation to human probands. Lymphocyte DNA 8-hydroxydeoxy-guanosine (8-OHdG), a marker of oxidative stress, was analyzed by Comet assay. Subjects supplemented with CoQ10 showed a distinct response in plasma concentrations after 14 and 28 days. Plasma levels returned to baseline values 12 weeks after treatment stopped. The plasma concentration increase did not affect erythrocyte levels. However, after CoQ10 supplementation, the platelet level increased; after supplementation stopped, the platelet level showed a delayed decrease. A positive correlation was shown between the plasma CoQ10 level and platelet and white blood cell CoQ10 levels. During CoQ10 supplementation, delayed formation of 8-OHdG in lymphocyte DNA was observed; this effect was long-lasting and could be observed even 12 weeks after supplementation stopped. Intracellular enrichment may support anti-oxidative defense mechanisms.     

Analysis of dihydroethidium fluorescence for the detection of intracellular and extracellular superoxide produced by NADPH oxidase

All methods used for quantitation of superoxide have limitations when it comes to differentiating between extracellular and intracellular sites of superoxide production. In the present study, we monitored dihydroethidium (DHE)-derived fluorescence at 570 nm, which indicates hydroxyethidium derived from reaction with superoxide produced by human leukemia cells (HL-60) and microvascular endothelial cells (HMEC-1). Phorbol-12-myristate 13-acetate (PMA; 100 ng/ml) caused an increase in fluorescence and lucigenin chemiluminescence in HL-60, which was abolished by superoxide dismutase (SOD; 600 U/ml) indicating that DHE detects extracellular superoxide. Furthermore, both HL-60 cells and HMEC-1 generated a fluorescence signal in the presence of DHE under resting conditions, which was unaffected by SOD, but abolished by polyethylene glycosylated-SOD (PEG-SOD) (100 U/ml) and MnTmPyP (25 μM), indicating that DHE also detects superoxide produced intracellularly. In HMEC-1, silencing of either Nox2 or Nox4 components of NADPH oxidase with small interference RNA (siRNA) resulted in a significant reduction in superoxide detected by both DHE fluorescence (Nox2 siRNA; 71 ± 6% and Nox4 siRNA 83 ± 7% of control) and lucigenin chemiluminescence (Nox2; 54 ± 6% and Nox4 74 ± 4% of control). In conclusion, DHE-derived fluorescence at 570 nm is a convenient method for detection of intracellular and extracellular superoxide produced by phagocytic and vascular NADPH oxidase.     

Effect of mitochondrial dysfunction and oxidative stress on endogenous levels of coenzyme Q(10) in human cells

Little is known about the regulation of endogenous CoQ(10) levels in response to mitochondrial dysfunction or oxidative stress although exogenous CoQ(10) has been extensively used in humans. In this study, we first demonstrated that acute treatment of antimycin A, an inhibitor of mitochondrial complex III, and the absence of mitochondrial DNA suppressed CoQ(10) levels in human 143B cells. Because these two conditions also enhanced formation of reactive oxygen species (ROS), we further investigated whether oxidative stress or mitochondrial dysfunction primarily contributed to the decrease of CoQ(10) levels. Results showed that H(2)O(2) augmented CoQ(10) levels, but carbonyl cyanide-p-trifluoromethoxyphenylhydrazone (FCCP), a chemical uncoupler, decreased CoQ(10) levels in 143B cells. However, H(2)O(2) and FCCP both increased mRNA levels of multiple COQ genes for biosynthesis of CoQ(10) . Our findings suggest that ROS induced CoQ(10) biosynthesis, whereas mitochondrial energy deficiency caused secondary suppression of CoQ(10) levels possibly due to impaired import of COQ proteins into mitochondria.