Abstract- Coenzyme Q10, a lipid soluble benzoquinone, has excellent antioxidant and membrane stabilizing properties in the cardiac tissue. The present study investigated the effects of coenzyme Q10 on in vitro LDL oxidation quantitavely. The formation of conjugated dienes, malondialdehyde (MDA) and electrophoretic mobility were monitored as markers of the oxidation of LDL, respectively. Coenzyme Q10 showed a decrease the formation of conjugated dienes and MDA, respectively, against oxidation in vitro. Coenzyme Q10 also reduced electrophoretic mobility of the oxidized human LDL. Thus, results showed that the coenzyme Q10 exhibits strong antioxidant activity in CuSO4-mediated oxidation of LDL (P<0.05) in vitro. The inhibitory effects of the coenzyme Q10 on LDL oxidation were dose-dependent at concentrations ranging from 20 nM to 300 nM. Moreover, the effects of coenzyme Q10 on LDL oxidation were compared with vitamin E and vitamin C. This study showed that coenzyme Q10 is a potent antioxidant to protect LDL against oxidation in vitro and may be a good alternative to reduce the risk of atherosclerosis and coronary heart disease and other free radical associated health problems.
© 2013 Tehran University of Medical Sciences. All rights reserved.
Acta Medica Iranica, 2013; 51(1): 12-18.
Keywords: Coenzyme Q10; LDL oxidation; Vitamin C; Vitamin E
Introduction
Cardiovascular disease is one of the most causes of mortality in the world. Although an increased concentration of plasma low density lipoprotein (LDL) is believed to be a major risk factor in atherosclerosis, the mechanisms of the LDL oxidation are not completely understood. There is considerable evidence support a role for oxidatively modified LDL in the pathogenesis of atherosclerosis (1,2). The uptake of oxidized LDL (Ox-LDL) by macrophage results in the formation of foam cells and cellular cholesterol accumulated in vascular endothelial cells, and promotes the development of the characteristic fatty streaks found in atherosclerotic lesion (1-5).
Finally, Ox-LDL has been reported to compromise endothelial integrity, a salient feature of atherosclerosis. Antioxidants such as beta-carotene and vitamin E have been shown to decrease formation of atherosclerotic lesions in animal models and epidemiological data suggest that an inverse relationship exist between the intake of antioxidant vitamins and the risk of coronary artery disease (6). According the oxidation hypothesis, antioxidants protect LDL against oxidative stress and delay the formation of modified LDL (7,8). The lipophilic antioxidant vitamin E, beta-carotene, ubiquinol, and lycopen are present in LDL. Vitamin E is thought to be major non-enzymatic antioxidant present in the lipid structures of cells and lipoproteins (9).Vitamin E is a major antioxidant present in the lipoproteins (9).
Coenzyme Q10 is a natural human ubiquinone, and it has fundamental role in mitochondrial energy (ATP) production in the respiratory chain (10-12). It plays a role in extra-mitochondrial redox activity in the cell membrane. Coenzyme Q10 is also antioxidant, scavenging free radicals and inhibiting lipid peroxidation (13-15). The antioxidant effect of coenzyme Q10 is greater than vitamin E (6). Coenzyme Q10 is also known to enhance the availability of other antioxidants such as vitamin C, vitamin E and betacaroten (16).
Since the effects of coenzyme Q10 on LDL oxidation have not previously been reported, the objectives of the present study were to assess the effects of plasma preincubation with vitamin E, vitamin C and various concentration of coenzyme Q10 on the modification of LDL induced by CuSO4 in vitro by monitoring the formation of conjugated dienes, the formation of MDA and measurement rate electrophoretic mobility (REM).
Materials and Methods
Materials
Coenzyme Q10, disodium ethylene diamine tetra acetate (Na2EDTA) were purchased from Sigma Chemical Co. Potassium bromide (KBr), sodium chloride (NaCl), disodium hydrogen phosphate (Na2HPO4), vitamin E, vitamin C and oil red O were purchased from Wako Pure Chemical Industries, Ltd (Japan).
Blood sampling and in vitro addition coenzyme Q10, vitamin E and vitamin C to plasma
Blood samples were taken from ten men. The protocols for the blood sampling were approved by the University of Kanazawa Ethics Committee, and all the informed constants were taken from all the men. Fasting blood samples after an overnight fasting was taken EDTA containing tubes (1.6 mg EDTA/ml blood). To obtain plasma, the centrifugation (3000 rpm for 10 min at 4°C) was started within 1 min following venous puncture to avoid autooxidation of the sample. To minimize oxidation in vitro, sodium azide (0.06% wt/vol) was added to plasma immediately after collection. For in vitro enrichment of LDL, freshly prepared human plasma was incubated at 37°C for 3 hours in the presence of added vitamin E (100 M), vitamin C (200 M) and various concentration of coenzyme Q10 (20, 100, 200 and 300 nM). Coenzyme Q10 and vitamin E dissolved in ethanol and vitamin C dissolved in phosphate-buffered saline (PBS) (17). The final concentration of ethanol in the plasma was 5% (vol/vol). Control plasma and plasma contained vitamin C received an equal amount of ethanol and were incubated in the same manner.
Isolation of LDL
The LDL density of 1.019-1.063 was isolated from fresh plasma by single vertical discontinuous density gradient ultracentrifugation (5,18).
Oxidation of LDL
Continuous monitoring of formation of conjugated dienes in LDL
After isolation of total LDL, the protein content of LDL was measured (19). LDL was adjusted to 150 µg/ml of LDL protein with 10 mM PBS, pH7.4. The oxidative modification of LDL was initiated by addition of freshly prepared 10 µM CuSO4 solution at 37°C in a water bath for 5h. The kinetics of LDL oxidation was monitored every 10 minutes by measuring its absorbance at 234 nm. The lag phase was calculated from the oxidation profile of each LDL preparation by drawing a tangent to the slope of the propagation phase and extrapolation into intercept the initial-absorbance axis. The lag phase represented the length of the antioxidant-protected phase during LDL oxidation by coenzyme Q10 in vitro. The lag time was measured as the time period until the conjugated dienes began to increase (20).
The formation of conjugated dienes was calculated as conjugated dienes equivalent content (nmol/mgprotein) at 5h. The conjugated dienes concentration was calculated by using the extinction coefficient for diene conjugates at 234 nm (29500 M -1. cm -1).
Assay of the formation of malondialdehyde (MDA)
Lipid peroxidation end product was determined as malondialdehyde (MDA) according to modified of the method of Buege and Aust. After initiating of oxidation process with CuSO4, the sample mixtures were incubated at 37°C for 5h in a water bath and the reaction terminated by adding EDTA (2 mM). MDA formation was measured in a spectrophotometer at 532 nm. The results were recorded as MDA equivalent content (nmol/mg LDL-protein) (21).
Determination of electrophoretic mobility of LDL
The electrophoretic mobility of n-LDL and Ox-LDL was detemined by agarose gel electrophoresis (1% agarose and 0.1 M barbital buffer) under the condition of 200 V, 80 mA in 0.05 M barbital buffer, then the gel was fixed in ethanol, acetic acid and water 6:1:3 for 15min, oven dried (80°C for 1h), and then stained with oil-red for 16h. After staining, the gel was washed by bleaching solution (ethanol and water 5:3), for until the background adjacent to protein or lipoprotein bands was cleared (22).
Statistical analysis
The data were presented as mean±SD of three experiments performed in duplicate. The variables used to describe the difference between the oxidation curves were lag time, conjugated dienes, MDA and REM. These parameters were obtained using the Mann- Whitney test (using SPSS 13.0 statistical software) for independent data and the differences were considered significant when P<0.05.
Results
The effects of vitamin E, vitamin C and dose-gradient concentration of coenzyme Q10 on the kinetics of CuSO4-induced LDL oxidation are showed in Figure 1. It clearly shows that CuSO4 dramatically increased oxidation of LDL. The formations of conjugated dienes were decreased by vitamin E, vitamin C and coenzyme Q10. The levels of the conjugated dienes at 5h and lag time of all experiment groups are showed in Figures 2, 3. CuSO4 increased the level of the conjugated dienes in LDL about three-fold and was significantly different from control LDL (414.7±12.5 nmol/mg LDL-protein vs. 153.4±5.941 nmol/mg LDL-protein, P<0.05). Vitamin E and coenzyme Q10 (300 nM) inhibited the final levels of conjugated dienes in LDL oxidation (325±25.34 and 315±26.65 nmol/mg LDL-protein, P<0.05). Coenzyme Q10 showed a dose-dependent inhibition in increase of conjugated dienes at 5h. 20, 100 and 200 nM concentration of coenzyme Q10 and vitamin C decreased the level of the conjugated dienes at 5h but were not significantly different from CuSO4-induced group. Vitamin E and coenzyme Q10 (300 nM) significantly increased lag time (142.4±8.9 and 160.5±10.2 min vs. 63.9±5.5 min, P<0.001 and P<0.01), prolongation of the lag time by coenzyme Q10 was dose-dependent. The lag time was significantly increased in the LDL separated from pre-incubated plasma with 100 nM, 200 nM and vitamin C. Continuous registration of absorbance of the LDL sample at 234 nm showed that coenzyme Q10 (300 nM) exerted the strongest effects, prolonging lag time to more than 2.5-fold of the CuSO4-induced LDL oxidation.
Concomitantly, the addition of CuSO4 in LDL determined and expressed by measurement of MDA equivalent content. The levels of the MDA at 5h of all experiment groups are showed in Figures 4. Addition of CuSO4 in LDL increased MDA formation about ten-fold and this was significantly increased over control LDL. Vitamin E 100 M significantly inhibited MDA formation about 63.38%. Coenzyme Q10 exhibited a dose-dependent inhibition of MDA formation. Coenzyme Q10300 nM significantly inhibited MDA formation by about 63.52% respectively. 20, 100 and 200 nM coenzyme Q10 and vitamin C decreased the MDA formation by about 36.21%, 38.1%, 42.24% and 55.1% respectively, but were not significantly different from CuSO4-induced group. The MDA formation was significantly decreased in the LDL separated from preincubated plasma with coenzyme Q10 (200 nM) and vitamin C.
Effect of coenzyme Q10 on electrophoretic mobility of LDL: The effects of vitamin E, vitamin C and various concentration of coenzyme Q10 on the electrophoretic mobility of CuSO4-induced LDL oxidation are shown in Figures 5. After LDL oxidation by CuSO4, the Ox-LDL moved faster than non-oxidized LDL on agarose gel electrophoresis. Vitamin E, vitamin C and coenzyme Q10 (200 and 300 nM) significantly decreased the electrophoretic mobility of LDL oxidized by CuSO4. 20 and 100 nM coenzyme Q10 decreased the electrophoretic mobility of LDL, but was not significant.
Discussion
Coenzyme Q10, a lipid soluble benzoquinone, has excellent antioxidant and membrane stabilizing properties in the cardiac tissue (10,13). Coenzyme Q10 has beneficial effects in the following areas: 1. Acts as a novel antioxidant. 2. Enhances stamina, endurance and energy levels. 3 Helps to reduce body weight. 4. Normalizes blood pressure. 5. Attenuates immune function. 6. Protects against cardiovascular dysfunction. 7. Increases effectiveness of various chemotherapeutic agents and anti-malarial drugs" (6,16,23).
The oxidative modification of LDL (ox-LDL) is the major factor that stimulates the development of atherosclerosis (3). The oxidative modification of LDL induced by copper ion is related to free radical reaction. LDL oxidation may require the generation of free radicals such as superoxide anion and hydroxyl radicals by the Fenton reaction. After the oxidation by copper ion, polyunsaturated fatty acid of LDL was oxidized, this resulted in an elevation of lipid peroxides and depletion of vitamin E and others antioxidants in ox- LDL (1-3).
The results clearly showed that various concentration of coenzyme Q10 have a dose-dependent antioxidant activity by inhibiting the formation of conjugated dienes and MDA, increase lag time and retard electrophoretic mobity of LDL in vitro. The results showed that coenzyme Q10 especially at 200 and 300 nM concentration similar to vitamin E as a positive control is a potent antioxidant and protect LDL in plasma against oxidation.
In this study, the effect of vitamin C on LDL oxidation showed less advantage than vitamin E and coenzyme Q10, because vitamin C is a water soluble vitamin and the most of vitamin C is separated in the steps of LDL isolation, especially in dialysis. It has been showed in many cases that the protective effect of Coenzyme Q10 is associated with its antioxidant properties (24,25). Administration of coenzyme Q10 in type I diabetic rats decreased lipid peroxidation and increased superoxide dismutase, catalase, and glutathione levels in rat heart and protected it against oxidative damage (26). The studies showed that coenzyme Q10 acts as an oxygen radical scavenger whenever oxygen free radicals are generated, decreases lipid peroxidation in paint industry workers. Also another researcher Baghchi (1997) suggested possible explanations the mechanisms of coenzyme Q10 antioxidant: 1. It may act independently as chainbreaking antioxidants, providing hydrogen atoms to reduce peroxyl and/or alkoxyl radicals. 2. A redox interaction may exist between coenzyme Q10 and another lipid soluble antioxidant such as vitamin E, in its one-electron oxidized form, vitamin E phenoxyl radical" (27-30). In conclusion, the results of the present study clearly showed that coenzyme Q10 is found to posses a good antioxidant activity and various concentrations of coenzyme Q10 have a dose-dependent antioxidant activity against LDL oxidation by inhibiting the formation of conjugated dynes and MDA, increasing lag time, and decreasing REM. In conclusion, coenzyme Q10 is a potent antioxidant and may be a good alternative to reduce the risk of atherosclerosis and coronary heart disease and other free radical associated health problems.
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Hassan Ahmadvand1, Hiroshi Mabuchi2, Atsushi Nohara2, Junji Kobayahi2, and Masa-aki Kawashiri2
1 Department of Biochemistry, Lorestan University of Medical Sciences, Khoramabad, Iran
2 Department of Lipidology, Graduate School of Medical Science, Kanazawa University, Japan
Received: 21 May 2011; Received in revised form: 8 Oct. 2012; Accepted: 29 Dec. 2012
Corresponding Author: Hassan Ahmadvand
Department of Biochemistry, Lorestan University of Medical Sciences, Khoramabad, Iran
Tel: +98 913 2267893, Fax: +98 133 661620, E-mail: [email protected]
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Copyright Tehran University of Medical Sciences Publications 2013
Abstract
Coenzyme Q(10), a lipid soluble benzoquinone, has excellent antioxidant and membrane stabilizing properties in the cardiac tissue. The present study quantitatively investigated the effects of coenzyme Q(10) on in vitro LDL oxidation. The formation of conjugated dienes, malondialdehyde (MDA) and electrophoretic mobility were monitored as markers of the oxidation of LDL, respectively. Coenzyme Q(10) showed a decrease the formation of conjugated dienes and MDA, respectively, against oxidation in vitro. Coenzyme Q(10) also reduced electrophoretic mobility of the oxidized human LDL. Thus, results showed that the coenzyme Q(10) exhibits strong antioxidant activity in CuSO(4)-mediated oxidation of LDL (P<0.05) in vitro. The inhibitory effects of the coenzyme Q(10) on LDL oxidation were dose-dependent at concentrations ranging from 20 nM to 300 nM. Moreover, the effects of coenzyme Q(10) on LDL oxidation were compared with vitamin E and vitamin C. This study showed that coenzyme Q(10) is a potent antioxidant to protect LDL against oxidation in vitro and may be a good alternative to reduce the risk of atherosclerosis and coronary heart disease and other free radical associated health problems.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer