5-N-Carboxyimino-6-aminopyrimidine-2,4(3H)-dione, a novel indicator for hypochlorite formation.

Uric acid is an adequate and endogenous probe for identifying reactive oxygen or nitrogen species generated in vivo because its oxidation products are specific to reacted reactive oxygen or nitrogen species. Recently, we identified 5-N-carboxyimino-6-N-chloroaminopyrimidine-2,4(3H)-dione as a hypochlorite-specific oxidation product. 5-N-carboxyimino-6-N-chloroaminopyrimidine-2,4(3H)-dione was anticipated to be a biomarker for hypochlorite production in vivo. However, while it was stable in aqueous solution at weak acidic and alkaline pH (6.0-8.0), it was unstable in human plasma. In this study, we found that 5-N-carboxyimino-6-N-chloroaminopyrimidine-2,4(3H)-dione rapidly reacted with thiol compounds such as cysteine and glutathione to yield 5-N-carboxyimino-6-aminopyrimidine-2,4(3H)-dione, which was stable in human plasma unlike 5-N-carboxyimino-6-N-chloroaminopyrimidine-2,4(3H)-dione. 5-N-carboxyimino-6-aminopyrimidine-2,4(3H)-dione was produced upon uric acid degradation during myeloperoxidase-induced uric acid oxidation and lipopolysaccharide-induced pseudo-inflammation in collected 2,4(3H)-dione has potential as a marker for hypochlorite production in vivo.

Prosaposin is a novel coenzyme Q10-binding protein.

Coenzyme Q10 (CoQ10) is essential for mitochondrial ATP production and functions as an important antioxidant in every biomembrane and lipoprotein. Due to its hydrophobicity, a binding and transfer protein for CoQ10 is plausible, and we previously described saposin B as a CoQ10-binding and transfer protein. Here, we report that prosaposin, the precursor of saposin B, also binds CoQ10. As prosaposin is both a secretory protein and integral membrane protein, it is ubiquitous in the body. Prosaposin was isolated from human seminal plasma, and CoQ10 was extracted from hexane solution into the water phase. It was additionally found that immunoprecipitates of mouse brain cytosol generated using two different anti-prosaposin antibodies contained coenzyme Q9. Furthermore, mouse liver cytosol and mouse kidney cytosol also contained prosaposin-coenzyme Q9 complex. These results suggest that prosaposin binds CoQ10 in human cells and body fluids. The significance and role of the Psap-CoQ10 complex in vivo is also discussed.

Higher levels of the lipophilic antioxidants coenzyme Q10 and vitamin E in long-lived termite queens than in short-lived workers.

Termite queens and kings live longer than nonreproductive workers. Several molecular mechanisms contributing to their long lifespan have been investigated; however, the underlying biochemical explanation remains unclear. Coenzyme Q (CoQ), a component of the mitochondrial electron transport chain, plays an essential role in the lipophilic antioxidant defense system. Its beneficial effects on health and longevity have been well studied in several organisms. Herein, we demonstrated that long-lived termite queens have significantly higher levels of the lipophilic antioxidant CoQ10 than workers. Liquid chromatography analysis revealed that the levels of the reduced form of CoQ10 were 4 fold higher in the queen's body than in the worker's body. In addition, queens showed 7 fold higher levels of vitamin E, which plays a role in antilipid peroxidation along with CoQ, than workers. Furthermore, the oral administration of CoQ10 to termites increased the CoQ10 redox state in the body and their survival rate under oxidative stress. These findings suggest that CoQ10 acts as an efficient lipophilic antioxidant along with vitamin E in long-lived termite queens. This study provides essential biochemical and evolutionary insights into the relationship between CoQ10 concentrations and termite lifespan extension.

Riboflavin compounds show NAD(P)H dependent quinone oxidoreductase-like quinone reducing activity.

NAD(P)H-dependent quinone oxidoreductase (NQO) is an essential enzyme in living organisms and cells protecting them from oxidative stress. NQO reduces coenzyme Q (CoQ) using NAD(P)H as an electron donor. In the present study, we searched for coenzyme Q10 reducing activity from fractions of gel filtration-fractionated rat liver homogenate. In addition to the large-molecular-weight fraction containing NQO, CoQ10 reducing activity was also detected in a low-molecular-weight fraction. Furthermore, dicumarol, a conventional inhibitor of NQO1 (DT diaphorase), did not inhibit the reduction but quercetin did, suggesting that the activity was not due to NQO1. After further purification, the NADH-dependent CoQ10-reducing compound was identified as riboflavin. Riboflavin is an active substituent of other flavin compounds such as FAD and FMN. These flavin compounds also reduced not only CoQ homologues but also vitamin K homologues in the presence of NADH. The mechanism was speculated to work as follows: NADH reduces flavin compounds to the corresponding reduced forms, and subsequently, the reduced flavin compounds immediately reduce bio-quinones. Furthermore, the flavin-NADH system reduces CoQ10 bound with saposin B, which is believed to function as a CoQ transfer protein in vivo. This flavin-dependent CoQ10 reduction, therefore, may function in aqueous phases such as the cell cytosol and bodily fluids.

Transferrin, insulin, and progesterone modulate intracellular concentrations of coenzyme Q and cholesterol, products of the mevalonate pathway, in undifferentiated PC12 cells.

Coenzyme Q (CoQ) is important not only as an essential lipid for the mitochondrial electron transport system, but also as an antioxidant. CoQ levels decrease during aging and in various diseases. Orally administered CoQ is not readily taken up in the brain, so it is necessary to develop a method to increase the amount of CoQ in neurons. CoQ is synthesized via mevalonate pathway, like cholesterol. Transferrin, insulin, and progesterone are factors used in the culture of neurons. In this study, we determined the effect of these reagents on cellular CoQ and cholesterol levels. The administration of transferrin, insulin, and progesterone increased cellular CoQ levels in undifferentiated PC12 cells. When serum was removed and only insulin was administered, intracellular CoQ levels increased. This increase was even more pronounced with concurrent administration of transferrin, insulin, and progesterone. Cholesterol level decreased by the administration of transferrin, insulin, and progesterone. Progesterone treatment lowered intracellular cholesterol levels in a concentration-dependent manner. Our findings suggest that transferrin, insulin, and progesterone may be useful in regulating CoQ levels and cholesterol levels, which are products of the mevalonate pathway.

Method for detecting CoQ10 incorporation in the mitochondrial respiratory chain supercomplex.

Coenzyme Q10 is an important component of the mitochondrial electron transfer chain. A supercomplex of mitochondrial electron transfer system proteins exists. This complex also contains coenzyme Q10. The concentrations of coenzyme Q10 in tissues decrease with age and pathology. Coenzyme Q10 is given as a supplement. It is unknown whether coenzyme Q10 is transported to the supercomplex. We develop a method for measuring coenzyme Q10 in the mitochondrial respiratory chain supercomplex in this study. Blue native electrophoresis was used to separate mitochondrial membranes. Electrophoresis gels were cut into 3 mm slices. Hexane was used to extract coenzyme Q10 from this slice, and HPLC-ECD was used to analyze coenzyme Q10. Coenzyme Q10 was found in the gel at the same site as the supercomplex. Coenzyme Q10 at this location was thought to be coenzyme Q10 in the supercomplex. We discovered that 4-nitrobenzoate, a coenzyme Q10 biosynthesis inhibitor, reduced the amount of coenzyme Q10 both within and outside the supercomplex. We also observed that the addition of coenzyme Q10 to cells increased the amount of coenzyme Q10 in the supercomplex. It is expected to analysis coenzyme Q10 level in supercomplex in various samples by using this novel method.

Orally ingested ubiquinol-10 or ubiquinone-10 reaches the intestinal tract and is absorbed by the small intestine of mice mostly in its original form.

Coenzyme Q10 (CoQ10) is an important lipid-soluble antioxidant and an essential component of the mitochondria. The oral bioavailability of the reduced form of CoQ10, ubiquinol-10, has been reported to be greater than that of the oxidized form of CoQ10, ubiquinone-10, in some studies. In contrast, it has also been highlighted that the oral bioavailability of ubiquinol-10 is not superior to that of ubiquinone-10 because ubiquinol-10 may be oxidized during digestion. In fact, it has not been shown which form of CoQ10 exists in the process from oral intake to absorption in the gastrointestinal tract. In this study, the amounts of ubiquinol-10 and ubiquinone-10 were measured in the gastrointestinal content and small intestine tissue after oral administration of ubiquinol-10 or ubiquinone-10 to C57BL/6J mice. The form of CoQ10 detected in the gastrointestinal content and small intestine tissue was almost the same as that when administered orally. The results of our study suggested that the orally administered ubiquinol-10 and ubiquinone-10 mostly reached the small intestine without oxidizing to ubiquinone-10 and reducing to ubiquinol-10, and both were absorbed by the small intestine tissue in almost their original forms.

Reduced prosaposin levels in HepG2 cells with long-term coenzyme Q10 deficiency.

Glycosphingolipids are involved in intercellular signaling, adhe-sion, proliferation, and differentiation. Saposins A, B, C, and D are cofactors required for glycosphingolipid hydrolysis. Saposins A-D are present in series in a common precursor protein, prosaposin. Thus, glycosphingolipids amounts depend on prosaposin cellular levels. We previously reported that prosaposin and saposin B bind coenzyme Q10 in human cells. Coenzyme Q10 is an essential lipid of the mitochondrial electron transport system, and its reduced form is an important antioxidant. Coenzyme Q10 level decrease in aging and in various progressive diseases. Therefore, it is interesting to understand the cellular response to long-term coenzyme Q10 deficiency. We established a long-term coenzyme Q10 deficient cell model by using the coenzyme Q10 biosynthesis inhibitor, 4-nitrobenzoate. The levels of coenzyme Q10 were reduced by 4-nitrobenzoate in HepG2 cells. Administration of 4-nitrobenzoate also decreased prosaposin protein and mRNA levels. The cellular levels of coenzyme Q10 and prosaposin were recovered by treatment with 4-hydroxybenzoquinone, a substrate for coenzyme Q10 synthesis that counteracts the effect of 4-nitrobenzoate. Furthermore, the ganglioside levels were altered in 4-nitrobenzoate treated cells. These results imply that long-term coenzyme Q10 deficiency reduces cellular prosaposin levels and disturbs glycosphingolipid metabolism.

Cellular level of coenzyme Q increases with neuronal differentiation, playing an important role in neural elongations.

Deficiency of coenzyme Q has been reported in various neuro-logical diseases, and the behavior of this lipid in neurons has attracted attention. However, the behavior of this lipid in normal neurons remains unclear. In this study, we analyzed the concen-tration of coenzyme Q before and after neuronal differentiation. Nerve growth factor treatment of PC12 cells caused neurite outgrowth and neuronal differentiation, and the amount of intra-cellular coenzyme Q increased dramatically during this process. In addition, when the serum was removed from the culture medium of N1E-115 cells and the neurite outgrowth was confirmed, the intracellular coenzyme Q level also increased. To elucidate the role of the increased coenzyme Q, we administered nerve growth factor to PC12 cells with coenzyme Q synthesis inhibitors and found that coenzyme Q levels decreased, neurite outgrowth was impaired, and differentiation markers were reduced. These results indicate that coenzyme Q levels increase during neuronal differentiation and that this increase is important for neurite outgrowth.

Coenzyme Q10 levels increase with embryonic development in medaka.

Coenzyme Q10 is an important molecule for mitochondrial respiration and as an antioxidant. Maintenance of the ovum in a good condition is considered to be important for successful fertilization and development, which has been reported to be promoted by coenzyme Q10. In this study, we investigated the level of coenzyme Q10 during ovum fertilization and maturation. We attempted to analyze coenzyme Q10 levels during ovum development in species that use coenzyme Q10 but not coenzyme Q9. It was shown that medaka produces coenzyme Q10. We then measured the amount of coenzyme Q10 after fertilization of medaka ovum and found that it increased. The amount of free cholesterol biosynthesized from acetyl CoA as well as coenzyme Q10 increased during development, but the increase in coenzyme Q10 was more pronounced. The mRNA expression level of coq9 also increased during embryonic development, but the mRNA expression levels of other coenzyme Q10 synthases did not. These results suggest that the coq9 gene is upregulated during the development of medaka ovum after fertilization, resulting in an increase in the amount of coenzyme Q10 in the ovum. Medaka, which like humans has coenzyme Q10, is expected to become a model animal for coenzyme Q10 research.

Edaravone, a scavenger for multiple reactive oxygen species, reacts with singlet oxygen to yield 2-oxo-3-(phenylhydrazono)-butanoic acid.

Edaravone (3-methyl-1-phenyl-2-pyrazolin-5-one) is a synthetic antioxidant used as a drug to treat acute ischemic stroke in Japan and amyotrophic lateral sclerosis in Japan and the USA. Its pharmacological mechanism is thought to be scavenging of reactive oxygen species, which are intimately related with these diseases. Recently, the singlet oxygen (|1O2) has attracted attention among reactive oxygen species. In this study, we investigated the reactivity of edaravone toward 1O2 and identified its reaction products. Edaravone showed a reactivity toward 1O2 greater than those of uric acid, histidine, and tryptophan, which are believed to be |1O2 scavengers in vivo. And we confirmed that 2-oxo-3-(phenylhydrazono)-butanoic acid was formed as an oxidation product. We propose a plausible mechanism for 2-oxo-3-(phenylhydrazono)-butanoic acid production by |1O2-induced edaravone oxidation. Since 2-oxo-3-(phenylhydrazono)-butanoic acid has already been identified as a radical-initiated oxidation product, free radical-induced oxidation should be seriously reconsidered. We also found that edaravone can react with not only hypochlorous anions but also |1O2 that are formed from myeloperoxidase. This result suggests that edaravone treatment can be beneficial against myeloperoxidase-related injuries such as inflammation.

Increase of oxidation rate of uric acid by singlet oxygen at higher pH.

Singlet oxygen prefers to react with an electron-rich double bonds. We observed that the oxidation rate for uric acid with singlet oxygen increased with increasing pH and the oxidation rate dramatically was elevated at around pH 5.4 and 9.8, which are the acidity constants of uric acid, pKa1 and pKa2, respectively. Furthermore, we observed that the absorbance near 200 nm and the molar extinction coefficient (ɛ) increased with increasing pH, similar to the change in oxidation rate. Computer calculations by Chong [Chong, J Theor Comput Sci 2013; 1(1)] revealed that uric acid elongates its C=N conjugated diene structure with increasing pH. This is correlated with an increase in the UV absorbance of C=C double bonds near 200 nm, and may indicate higher electron density in the double bonds. Therefore, we concluded that the increased oxidation rate is due to elongation of the C=N conjugated polyene system at higher pH. On the other hand, the major products were 4-hydroxyallantoin and parabanic acid (hydrolyzed to oxaluric acid at pH 10.7), suggesting that the reaction pathways were the same regardless of pH. Finally, possible reaction schemes are presented.

Differentiation of THP-1 monocytes to macrophages increased mitochondrial DNA copy number but did not increase expression of mitochondrial respiratory proteins or mitochondrial transcription factor A.

Monocytes are differentiated into macrophages. In this study, mitochondrial DNA copy number (mtDNAcn) levels and downstream events such as the expression of respiratory chain mRNAs were investigated during the phorbol 12-myristate 13-acetate (PMA)-induced differentiation of monocytes. Although PMA treatment increased mtDNAcn, the expression levels of mRNAs encoded in mtDNA were decreased. The levels of mitochondrial transcription factor A mRNA and protein were also decreased. The levels of coenzyme Q10 remained unchanged. These results imply that, although mtDNAcn is considered as a health marker, the levels of mtDNAcn may not always be consistent with the parameters of mitochondrial functions.

4-Cl-edaravone and (E)-2-chloro-3-[(E)-phenyldiazenyl]-2-butenoic acid are the specific reaction products of edaravone with hypochlorite.

3-Methyl-1-phenyl-2-pyrazolin-5-one (edaravone) is a synthetic one-electron antioxidant used as a drug for treatment against acute phase cerebral infarction in Japan. This drug also reacts with two-electron oxidants like peroxynitrite to give predominantly 4-nitrosoedaravone but no one-electron oxidation products. It is believed that this plays a significant role in amelioration of amyotrophic lateral sclerosis. The drug was approved for treatment of amyotrophic lateral sclerosis in Japan and USA in 2015 and 2017, respectively. In this study, we examined the reaction of edaravone with another two-electron oxidant, hypochlorite anion (ClO-). Edaravone reacted with ClO- in 50% methanolic phosphate buffer (pH 7.4) solution containing typical two-electron reductants, such as glutathione, cysteine, methionine, and uric acid, as internal references. The concentration of edaravone decreased at a similar rate as each co-existing reference, indicating that it showed comparable reactivity toward ClO- as those references. Furthermore, 4-Cl-edaravone and (E)-2-chloro-3-[(E)-phenyldiazenyl]-2-butenoic acid (CPB) were identified as primary and end products, respectively, and no one-electron oxidation products were detected. These results suggest that edaravone treatment can bring greater benefit against ClO--related injury such as inflammation, and 4-Cl-edaravone and CPB can be good biomarkers for ClO--induced oxidative stress.

Ascorbic acid and CoQ10 ameliorate the reproductive ability of superoxide dismutase 1-deficient female mice†.

Superoxide dismutase 1 suppresses oxidative stress within cells by decreasing the levels of superoxide anions. A dysfunction of the ovary and/or an aberrant production of sex hormones are suspected causes for infertility in superoxide dismutase 1-knockout mice. We report on attempts to rescue the infertility in female knockout mice by providing two antioxidants, ascorbic acid and/or coenzyme Q10, as supplements in the drinking water of the knockout mice after weaning and on an investigation of their reproductive ability. On the first parturition, 80% of the untreated knockout mice produced smaller litter sizes compared with wild-type mice (average 2.8 vs 7.3 pups/mouse), and supplementing with these antioxidants failed to improve these litter sizes. However, in the second parturition of the knockout mice, the parturition rate was increased from 18% to 44-75% as the result of the administration of antioxidants. While plasma levels of progesterone at 7.5 days of pregnancy were essentially the same between the wild-type and knockout mice and were not changed by the supplementation of these antioxidants, sizes of corpus luteum cells, which were smaller in the knockout mouse ovaries after the first parturition, were significantly ameliorated in the knockout mouse with the administration of the antioxidants. Moreover, the impaired vasculogenesis in uterus/placenta was also improved by ascorbic acid supplementation. We thus conclude that ascorbic acid and/or coenzyme Q10 are involved in maintaining ovarian and uterus/placenta homeostasis against insults that are augmented during pregnancy and that their use might have positive effects in terms of improving female fertility.

Singlet molecular oxygen regulates vascular tone and blood pressure in inflammation.

Singlet molecular oxygen (1O2) has well-established roles in photosynthetic plants, bacteria and fungi1-3, but not in mammals. Chemically generated 1O2 oxidizes the amino acid tryptophan to precursors of a key metabolite called N-formylkynurenine4, whereas enzymatic oxidation of tryptophan to N-formylkynurenine is catalysed by a family of dioxygenases, including indoleamine 2,3-dioxygenase 15. Under inflammatory conditions, this haem-containing enzyme is expressed in arterial endothelial cells, where it contributes to the regulation of blood pressure6. However, whether indoleamine 2,3-dioxygenase 1 forms 1O2 and whether this contributes to blood pressure control have remained unknown. Here we show that arterial indoleamine 2,3-dioxygenase 1 regulates blood pressure via formation of 1O2. We observed that in the presence of hydrogen peroxide, the enzyme generates 1O2 and that this is associated with the stereoselective oxidation of L-tryptophan to a tricyclic hydroperoxide via a previously unrecognized oxidative activation of the dioxygenase activity. The tryptophan-derived hydroperoxide acts in vivo as a signalling molecule, inducing arterial relaxation and decreasing blood pressure; this activity is dependent on Cys42 of protein kinase G1α. Our findings demonstrate a pathophysiological role for 1O2 in mammals through formation of an amino acid-derived hydroperoxide that regulates vascular tone and blood pressure under inflammatory conditions.

(2,5-Dioxoimidazolidin-4-ylidene)aminocarbonylcarbamic Acid as a Precursor of Parabanic Acid, the Singlet Oxygen-Specific Oxidation Product of Uric Acid.

Previously, we identified that parabanic acid (PA) and its hydrolysate, oxaluric acid (OUA), are the singlet oxygen-specific oxidation products of uric acid (UA). In this study, we investigated the PA formation mechanism by using HPLC and a time-of-flight mass spectrometry technique and identified unknown intermediates as (2,5-dioxoimidazolidin-4-ylidene)aminocarbonylcarbamic acid (DIAA), dehydroallantoin, and 4-hydroxyallantoin (4-HAL). DIAA is the key to PA production, and its formation pathway was characterized using 18O2 and H218O. Two oxygen atoms were confirmed to be incorporated into DIAA: the 5-oxo- oxygen from singlet oxygen and the carboxylic oxygen from water. Isolated DIAA and 4-HAL gave PA stoichiometrically. A plausible reaction scheme in which two pathways branch out from DIAA is presented, and the potential for PA as an endogenous probe for biological formation of singlet oxygen is discussed.

Simultaneous detection of reduced and oxidized forms of coenzyme Q10 in human cerebral spinal fluid as a potential marker of oxidative stress.

The redox balance of coenzyme Q10 in human plasma is a good marker of oxidative stress because the reduced form of coenzyme Q10 (ubiquinol-10) is very sensitive to oxidation and is quantitatively converted to its oxidized form (ubiquinone-10). Here we describe an HPLC method for simultaneous detection of ubiquinol-10 and ubiquinone-10 in human cerebral spinal fluid to meet a recent demand for measuring local oxidative stress. Since the levels of coenzyme Q10 in human cerebral spinal fluid are less than 1/500 of those in human plasma, cerebral spinal fluid extracted with 2-propanol requires concentration for electrochemical detection. Using human plasma diluted 500-fold with physiological saline as a pseudo-cerebral spinal fluid, we found that addition of tert-butylhydroquinone was effective in preventing the oxidation of ubiquinol-10. The optimized tert-butylhydroquinone concentration in the extraction solvent was 20 µM. The addition of 20 µM ascorbic acid or co-addition of tert-butylhydroquinone and ascorbic acid (20 µM each) were also effective in preventing the oxidation of ubiquinol-10, but ascorbic acid alone gave poor reproducibility. Good within day reproducibility was observed, and day-to-day analytical variance was excellent.

5-N-Carboxyimino-6-N-chloroaminopyrimidine-2,4(3H)-dione as a hypochlorite-specific oxidation product of uric acid.

Although uric acid is known to react with many reactive oxygen species, its specific oxidation products have not been fully characterized. We now report that 5-N-carboxyimino-6-N-chloroaminopyrimidine-2,4(3H)-dione (CCPD) is a hypochlorite (ClO-)-specific oxidation product of uric acid. The yield of CCPD was 40-70% regardless of the rate of mixing of ClO- with uric acid. A previously reported product, allantoin (AL), was a minor product. Its yield (0-20%) decreased with decreasing rate of mixing of ClO- with uric acid, indicating that allantoin is less important in vivo. Kinetic studies revealed that the formation of CCPD required two molecules of ClO- per uric acid reacted. The identity of CCPD was determined from its molecular formula (C5H3ClN4O4) measured by LC/time-of-flight mass spectrometry and a plausible reaction mechanism. This assumption was verified by the fact that all mass fragments (m/z -173, -138, -113, and -110) fit with the chemical structure of CCPD and its tautomers. Isolated CCPD was stable at pH 6.0-8.0 at 37°C for at least 6 h. The above results and the fact that uric acid is widely distributed in the human body at relatively high concentrations indicate that CCPD is a good marker of ClO- generation in vivo.

Increased oxidative stress and coenzyme Q10 deficiency in centenarians.

Aging populations are expanding worldwide, and the increasing requirement for nursing care has become a serious problem. Furthermore, successful aging is one of the highest priorities for individuals and societies. Centenarians are an informative cohort to study and inflammation has been found to be a key factor in predicting cognition and physical capabilities. Inflammation scores have been determined based on the levels of cytokines and C-reactive protein, however, serum antioxidants and lipid profiles have not been carefully examined. We found that the redox balance of coenzyme Q10 significantly shifted to the oxidized form and levels of strong antioxidants, such as ascorbic acid and unconjugated bilirubin, decreased significantly compared to 76-year-old controls, indicating an increased oxidative stress in centenarians. Levels of uric acid, an endogenous peroxynitrite scavenger, remained unchanged, suggesting that centenarians were experiencing moderate, chronic inflammatory conditions. Centenarians exhibited a hypocholesterolemic condition, while an increase in the ratio of free cholesterol to cholesterol esters suggests some impairment of liver function. Serum free fatty acids and monoenoic acid composition, markers of tissue oxidative damage, were significantly decreased in centenarians, indicating an impairment in the tissue repair system. Despite an elevation of the coenzyme Q10 binding protein Psap, serum total coenzyme Q10 levels decreased in centenarians. This suggests a serious deficiency of coenzyme Q10 in tissues, since tissue levels of coenzyme Q10 significantly decrease with age. Therefore, coenzyme Q10 supplementation could be beneficial for centenarians.