Relaxation of arterial smooth muscle by water-soluble derivatives of coenzyme Q (ubiquinone)

Treatment of coenzyme Q with ozone, permanganate, and ferrous sulfate in presence of ascorbate or hydrogen peroxide yielded water-soluble degradation products, possibly having truncated side-chain and modified ring.These derivatives, but not the intact lipid-quinone, showed relaxation of phenylephrine-contracted rat arterial rings. Representative samples of these also decreased blood pressure when injected into the femoral vein in the rat.These effects offer an explanation for the hypotensive action of exogenous coenzyme Q regardless of its side-chain length.     

A Note on the Separation of Natural Mixtures of Bacterial Ubiquinones using Reverse-phase Partition Thin-layer Chromatography and High Performance Liquid Chromatography

Natural mixtures of bacterial ubiquinones (coenzyme Q) were separated according to the length of the polyisoprenyl side-chain using reverse-phase thin-layer chromatography and high performance liquid chromatography. The chromatographic systems described afford a rapid and sensitive means of ubiquinone characterization.     

Comparison of growth stimulation of HeLa cells,HL-60 cells,and mouse fibroblasts by coenzyme Q10

Summary The addition of coenzyme Q₁₀ to culture media stimulates the serum-free growth of HeLa, HL-60 cells, and mouse fibroblasts (Balb/3T3). With HeLa cells, the stimulation by coenzyme Q₁₀ is additive to the stimulation by ferricyanide, an impermeable electron acceptor for the transplasma membrane electron transport. This combined response to coenzyme Q₁₀ and ferricyanide is enhanced with insulin. -Tocopherylquinone can also stimulate the growth of HeLa cells, but vitamin K₁ is inactive. Specificity of quinone effects is indicated. Serum-free growth of Balb/3T3 and SV 40 transformed BaIb/3T3 (SV/T2) cells is also stimulated by coenzyme Qio with stimulation similar to HeLa cells. However, Balb/3T3 cells are not stimulated by ferricyanide, which does not increase the response to coenzyme Q₁₀. The transformed cells (SV/T2) respond better to ferricyanide alone, but the effects of coenzyme Qio and ferricyanide are not additive. Serum-free growth of HL-60 cells is stimulated dramatically by coenzyme Q₁₀. The extent of growth stimulation on HL-60 cells is almost six-fold that of HeLa or Balb/3T3 cells. The stimulation of NADH-ferricyanide reductase (a transmembrane redox enzyme) by coenzyme Q₁₀ with HL-60 cells is similar to their growth pattern in response to coenzyme Q₁₀. Unlike HL-60, HeLa and Balb/3T3 cells show little stimulation of ferricyanide reduction by coenzyme Q₁₀. The stimulatory effect on both ferricyanide reduction and cell growth by the short side-chain coenzyme Q₂ is much less than that of the long side-chain coenzyme Q₁₀. Ferricyanide reduction by HeLa cells is inhibited by coenzyme Q analogs such as 2,3-dimethoxy-5-chloro-6-naphthyl-mercapto-coenzyme Q and 2-methoxy-3-ethoxyl-5-methyl-6-hexadecyl-mercapto-coenzyme Q. However, these inhibitions are reversed by coenzyme Q₁₀. The growth inhibition of HL-60 cells by other coenzyme Q analogs, such as capsiacin can also be reversed by coenzyme Q₁₀. These data indicate that plasma membrane-based NADH oxidation or modification of the membrane quinone redox balance may be a basis for the growth stimulation.     

The importance of plasma membrane coenzyme Q in aging and stress responses

The plasma membrane of eukaryotic cells is the limit to interact with the environment. This position implies receiving stress signals that affects its components such as phospholipids. Inserted inside these components is coenzyme Q that is a redox compound acting as antioxidant. Coenzyme Q is reduced by diverse dehydrogenase enzymes mainly NADH-cytochrome b₅ reductase and NAD(P)H:quinone reductase 1. Reduced coenzyme Q can prevent lipid peroxidation chain reaction by itself or by reducing other antioxidants such as α-tocopherol and ascorbate. The group formed by antioxidants and the enzymes able to reduce coenzyme Q constitutes a plasma membrane redox system that is regulated by conditions that induce oxidative stress. Growth factor removal, ethidium bromide-induced ρ° cells, and vitamin E deficiency are some of the conditions where both coenzyme Q and its reductases are increased in the plasma membrane. This antioxidant system in the plasma membrane has been observed to participate in the healthy aging induced by calorie restriction. Furthermore, coenzyme Q regulates the release of ceramide from sphingomyelin, which is concentrated in the plasma membrane. This results from the non-competitive inhibition of the neutral sphingomyelinase by coenzyme Q particularly by its reduced form. Coenzyme Q in the plasma membrane is then the center of a complex antioxidant system preventing the accumulation of oxidative damage and regulating the externally initiated ceramide signaling pathway.     

Sensitivity of Caenorhabditis elegans clk-1 mutants to ubiquinone side-chain length reveals multiple ubiquinone-dependent processes

Ubiquinone (coenzyme Q, or Q) is a membrane constituent, whose head group is capable of accepting and donating electrons and whose lipidic side chain is composed of a variable number of isoprene subunits. A possible role for Q as a dietary antioxidant for treating conditions that involve altered cellular redox states is being intensely studied. Mutations in the clk-1 gene of the nematode Caenorhabditis elegans affect numerous physiological rates including behavioral rates, developmental rates, reproduction, and life span. clk-1 encodes a protein associated with the inner mitochondrial membrane that is necessary for Q biosynthesis in C. elegans. clk-1 mutants do not synthesize Q but accumulate demethoxyubiquinone, a Q synthesis intermediate that is able to partially sustain mitochondrial respiration in worms as well as in mammals. Recently, we and others have found that exogenous Q is necessary for the fertility and development of clk-1 mutants. Here, we take advantage of the clk-1 genetic model to identify structural features of Q that are functionally important in vivo. We show that clk-1 mutants are exquisitely sensitive to the length of the side chain of the Q they consume. We also identified differential sensitivity to Q side-chain length between null alleles of clk-1 (qm30 and qm51) and the weaker allele e2519. This allows us to propose a model where we distinguish several types of Q-dependent processes in vivo: processes that are very sensitive to Q side-chain length and processes that are permissive to Q with shorter chains.     

Role of glutamine 148 of human 15-hydroxyprostaglandin dehydrogenase in catalytic oxidation of prostaglandin E2

NAD+-dependent 15-hydroxyprostaglandin dehydrogenase (15-PGDH), a member of the short-chain dehydrogenase/reductase (SDR) family, catalyzes the first step in the catabolic pathways of prostaglandins and lipoxins. This enzyme oxidizes the C-15 hydroxyl group of prostaglandins and lipoxins to produce 15-keto metabolites which exhibit greatly reduced biological activities. A three-dimensional (3D) structure of 15-PGDH based on the crystal structures of the levodione reductase and tropinone reductase-II was generated and used for docking study with NAD+ coenzyme and PGE2 substrate. Three well-conserved residues among SDR family which correspond to Ser-138, Tyr-151, and Lys-155 of 15-PGDH have been shown to participate in the catalytic reaction. Based on the molecular interactions observed from 3D structure of 15-PGDH, we further propose that Gln-148 in 15-PGDH is important in properly positioning the 15-hydroxyl group of PGE2 by hydrogen bonding with the side-chain oxygen atom of Gln-148. This residue is found to be less conserved and replaceable by glutamyl, histidinyl, and asparaginyl residues in SDR family. Accordingly, site-directed mutagenesis of Gln-148 of 15-PGDH to alanine, glutamic acid, histidine, and asparagine (Q148A, Q148E, Q148H, and Q148N) was carried out. The activity of mutant Q148A was not detectable, whereas those of mutants Q148E, Q148H, and Q148N were comparable to or higher than the wild type. This indicates that the side-chain oxygen or nitrogen atom at position 148 of 15-PGDH plays an important role in anchoring C-15 hydroxyl group of PGE2 through hydrogen bonding for catalytic reaction.     

Mechanism of O2- generation in reduction and oxidation cycle of ubiquinones in a model of mitochondrial electron transport systems

O2- generation in mitochondrial electron transport systems, especially the NADPH-coenzyme Q10 oxidoreductase system, was examined using a model system, NADPH-coenzyme Q1-NADPH-dependent cytochrome P-450 reductase. One electron reduction of coenzyme Q1 produces coenzyme Q1-. and O2- during enzyme-catalyzed reduction and O2+ coenzyme Q1-. are in equilibrium with O2- + coenzyme Q1 in the presence of enough O2. The coenzyme Q1-. produced can be completely eliminated by superoxide dismutase, identical to bound coenzyme Q10 radical produced in a succinate/fumarate couple-KCN-submitochondrial system in the presence of O2. Superoxide dismutase promotes electron transfer from reduced enzyme to coenzyme Q1 by the rapid dismutation of O2- generated, thereby preventing the reduction of coenzyme Q1 by O2-. The enzymatic reduction of coenzyme Q1 to coenzyme Q1H2 via coenzyme Q1-. is smoothly achieved under anaerobic conditions. The rate of coenzyme Q1H2 autoxidation is extremely slow, i.e., second-order constant for [O2][coenzyme Q1H2] = 1.5 M-1.s-1 at 258 microM O2, pH 7.5 and 25 degrees C.     

An analysis of the role of coenzyme Q in free radical generation and as an antioxidant.

The vital role of coenzyme Q in mitochondrial electron transfer and its regulation, and in energy conservation, is well established. However, the role of coenzyme Q in free oxyradical formation and as an antioxidant remains controversial. Demonstration of the existence of the semiquinone form of coenzyme Q during electron transport, coupled with recent evidence that hydrogen peroxide (but not molecular oxygen) may act as an oxidant of the semiquinone, suggests that the highly reactive OH. radical may be formed from the semiquinone. On the other hand, data exist implicating the Fe-S species as the source of electron transfer chain, free radical production. Additional data exist suggesting instead that the unpaired electron of the coenzyme Q semiquinone most likely dismutases superoxide radicals. These concepts and those arising from observations at several levels of organization including subcellular systems, intact animals, and human subjects in the clinical setting, supporting the concept of reduced coenzyme Q as an antioxidant, will be presented. The results of recent studies on the interaction between the two-electron quinone reductase--DT diaphorase and coenzyme Q10 will be presented. The possibility that superoxide dismutase may interact with reduced coenzyme Q, in conjunction with DT diaphorase inhibiting its autoxidation, will be described. The regulation of cellular coenzyme Q concentrations during oxidative stress accompanying aerobic exercise, resulting in increased protection from free radical damage, will also be presented.     

酵母发酵生产辅酶Q10提取方法研究进展

辅酶Q10是存在于哺乳动物中,能与酶蛋白形成复合物以发挥酶学活性的有机小分子化合物,目前广泛应用于医药、日化、保健、食品等不同领域。辅酶Q10来源丰富,其中酵母是其工业生产的主要来源之一。广受关注的酵母发酵生产辅酶Q10的提取分离手段不断革新,产量不断增加,处理方式更加环保,应用日渐拓宽。本文就近年来国内外酵母发酵生产辅酶Q10的提取分离方法进行了综述,包括酵母菌种的类型与优化、辅酶Q10提取检测方法、工业生产放大工艺以及与产品质量相关的各个影响因素,并对酵母发酵生产辅酶Q10的前景进行了展望。     

Isolation and functional expression of human COQ3, a gene encoding a methyltransferase required for ubiquinone biosynthesis

The COQ3 gene in Saccharomyces cerevisiae encodes an O-methyltransferase required for two steps in the biosynthetic pathway of ubiquinone (coenzyme Q, or Q). This enzyme methylates an early Q intermediate, 3,4-dihydroxy-5-polyprenylbenzoic acid, as well as the final intermediate in the pathway, converting demethyl-Q to Q. This enzyme is also capable of methylating the distinct prokaryotic early intermediate 2-hydroxy-6-polyprenyl phenol. A full-length cDNA encoding the human homologue of COQ3 was isolated from a human heart cDNA library by sequence homology to rat Coq3. The clone contained a 933-base pair open reading frame that encoded a polypeptide with a great deal of sequence identity to a variety of eukaryotic and prokaryotic Coq3 homologues. In the region between amino acids 89 and 255 in the human sequence, the rat and human homologues are 87% identical, whereas human and yeast are 35% identical. When expressed in multicopy, the human construct rescued the growth of a yeast coq3 null mutant on a nonfermentable carbon source and restored coenzyme Q biosynthesis, although at lower levels than that of wild type yeast. In vitro methyltransferase assays using farnesylated analogues of intermediates in the coenzyme Q biosynthetic pathway as substrates showed that the human enzyme is active with all three substrates tested.     

The participation of coenzyme Q in free radical production and antioxidation

Published experimental data pertaining to the participation of coenzyme Q as a site of free radical formation in the mitochondrial electron transfer chain and the conditions required for free radical production have been reviewed critically. The evidence suggests that a component from each of the mitochondrial NADH-coenzyme Q, succinate-coenzyme Q, and coenzyme QH₂-cytochrome c reductases (complexes I, II, and III, most likely a nonheme iron-sulfur protein of each complex, is involved in free radical formation. Although the semiquinone form of coenzyme Q may be formed during electron transport, its unpaired electron most likely serves to aid in the dismutation of superoxide radicals instead of participating in free radical formation. Results of studies with electron transfer chain inhibitors make the conclusion dubious that coenzyme Q is a major free radical generator under normal physiological conditions but may be involved in superoxide radical formation during ischemia and subsequent reperfusion. Experiments at various levels of organization including subcellular systems, intact animals, and human subjects in theclinical setting, support the view that coenzyme Q, mainly in its reduced state, may act as an antioxidant protecting a number of cellular membranes from free radical damage.     

发酵生产辅酶Q10高产菌株的选育

以实验室保存的类球红细菌(Rhodobacter sphaeroides)JDW61为出发菌株,考察了紫外、紫外结合氯化锂和亚硝基胍对菌株产生辅酶Q10能力的诱变效应,并结合辅酶Q10的合成途径设计了快速筛选辅酶Q10高产菌株的模型,获得一株辅酶Q10产量提高的突变株CP222,该菌株摇瓶发酵的辅酶Q10产量为276.14mg·L-1,较出发菌株提高了190%,并且遗传性能稳定。     

Evidence for coenzyme Q function in transplasma membrane electron transport

Transplasma membrane electron transport activity has been associated with stimulation of cell growth. Coenzyme Q is present in plasma membranes and because of its lipid solubility would be a logical carrier to transport electrons across the plasma membrane. Extraction of coenzyme Q from isolated rat liver plasma membranes decreases the NADH ferricyanide reductase and added coenzyme Q10 restores the activity. Piericidin and other analogs of coenzyme Q inhibit transplasma membrane electron transport as measured by ferricyanide reduction by intact cells and NADH ferricyanide reduction by isolated plasma membranes. The inhibition by the analogs is reversed by added coenzyme Q10. Thus, coenzyme Q in plasma membrane may act as a transmembrane electron carrier for the redox system which has been shown to control cell growth.     

C. elegans knockouts in ubiquinone biosynthesis genes result in different phenotypes during larval development

Ubiquinone is an essential molecule in aerobic organisms to achieve both, ATP synthesis and antioxidant defence. Mutants in genes responsible of ubiquinone biosynthesis lead to non-respiring petite yeast. In C. elegans, coq-7/clk-1 but not coq-3 mutants live longer than wild type showing a 'slowed' phenotype. In this paper we demonstrate that absence in ubiquinone in coq-1, coq-2 or coq-8 mutants lead to larval development arrest, slowed pharyngeal pumping, eventual paralysis and cell death. All these features emerge during larval development, whereas embryo development appeared similar to that of wild type individuals. Dietary coenzyme Q did not restore any of the alterations found in these coq mutants. These phenomena suggest that coenzyme Q mutants unable to synthesize this molecule develop a deleterious phenotype leading to lethality. On the contrary, phenotype of C. elegans coq-7/clk-1 mutants may be a unique phenotype than can not generalize to mutants in ubiquinone biosynthesis. This particular phenotype may not be based on the absence of endogenous coenzyme Q, but to the simultaneous presence of dietary coenzyme Q and the its biosynthesis intermediate demethoxy-coenzyme Q.     

Coenzyme Q-3 as an antioxidant. Its effect on the composition and structural properties of phospholipid vesicles.

Coenzyme Q-3 incorporated into the lipid bilayer at physiological concentration provided an 80% inhibition of the lipid peroxidation induced by ferrous ions. In coenzyme Q-containing vesicles, the fluorescence lifetime and the fluorescence anisotropy decay of the probe, 1,6-diphenyl-1,3,5-hexatriene, were measured in order to find out if the presence of the quinone can cause variations in the membrane organization. Our data show that two distinct populations of the probe were present and that both populations were available to quenching by coenzyme Q. The overall effects of coenzyme Q on the static and dynamic properties of the model membranes were: a very small effect in the ordering of the fatty acid chain, and a more noticeable decrease of the probe correlation time and, therefore, an increase in membrane fluidity at increasing quinone concentration. When vesicles were peroxidized in the absence of the coenzyme Q, the fluidity markedly decreased; in its presence, the fluidity was nearly unchanged. The results suggest that the antioxidant properties of coenzyme Q can be ascribed to its ability to react with free radicals. The effect on the fluidity of the lipid bilayer might imply that a requisite for a molecule to act as an efficient antioxidant could be its ability to readily diffuse within the membrane.     

Interactions of ubiquinones with membrane models

The effect of the insertion of coenzyme Q10 and some of its shorter chain homologues in membrane models (Reverse Micelles, Small Unilamellar Vesicles and Liposomes) has been studied by NMR and IR spectroscopies. By 1H-NMR we have found that the stretched conformation of the isoprenoid side-chain observed in solution is maintained in membrane models. Interaction between the quinonoid moiety of the Q's and the phosphatidic groups of the phospholipids has been evidenced by 31P-NMR. A large effect of this interaction on the water microdynamics and distribution around the charged groups of the phospholipids has been observed by measurements of 1H and 2H relaxation times and by infrared spectra. The 13C-NMR spectra of the backbone of the acyl chains of phospholipids does not seem to be influenced to a noticeable extent by the presence of the Q's.     

COQ9, a new gene required for the biosynthesis of coenzyme Q in Saccharomyces cerevisiae

Currently, eight genes are known to be involved in coenzyme Q6 biosynthesis in Saccharomyces cerevisiae. Here, we report a new gene designated COQ9 that is also required for the biosynthesis of this lipoid quinone. The respiratory-deficient pet mutant C92 was found to be deficient in coenzyme Q and to have low mitochondrial NADH-cytochrome c reductase activity, which could be restored by addition of coenzyme Q2. The mutant was used to clone COQ9, corresponding to reading frame YLR201c on chromosome XII. The respiratory defect of C92 is complemented by COQ9 and suppressed by COQ8/ABC1. The latter gene has been shown to be required for coenzyme Q biosynthesis in yeast and bacteria. Suppression by COQ8/ABC1 of C92, but not other coq9 mutants tested, has been related to an increase in the mitochondrial concentration of several enzymes of the pathway. Coq9p may either catalyze a reaction in the coenzyme Q biosynthetic pathway or have a regulatory role similar to that proposed for Coq8p.     

Discovery of plastoquinones: a personal perspective

The discovery and the rediscovery of plastoquinone (PQ) are described together with the definition of its structure as a 2,3-dimethyl 5 solanosyl benzoquinone. The discovery, by M. Kofler, was a result of a search for Vitamin K. Its rediscovery was made by me, when I was at The Enzyme Institute of the University of Wisconsin, analyzing animals and plants for the newly discovered coenzyme Q. In green plants, I found another lipophilic quinone in addition to coenzyme Q. Some misleading evidence suggested as if the new quinone had coenzyme Q activity in mitochondria, but improved methods gave negative results. When I found that the quinone was concentrated in chloroplasts, I considered a role for it in photosynthesis analogous to the role of coenzyme Q in mitochondria. After moving to the Chemistry Department, University of Texas at Austin, I used a plain light bulb and some spinach chloroplasts to show that PQ could be involved in photosynthetic redox reactions. This effect was supported by Norman Bishop’s restoration of chloroplast electron transport after solvent extraction, with PQ and photoreduction studies by E. R. Redfern and J. Friend in R. A. Morton’s laboratory in Liverpool, UK. We also found an additional analog of PQ in addition to a second analog found in Wisconsin. We called the new analogs PQB and PQC. Although we found some restoration effects with PQC, the discovery by W. T. Griffiths in Morton’s laboratory, that PQB and PQC consisted of six forms of PQ each, made it more likely that the new analogs were breakdown products. Morton’s group established the structure of the PQCs as a series of PQs, with a hydroxyl group on the prenyl side chain, and the PQB series as having fatty acids esterified to the hydroxyl groups of PQC. Possible functions of the analogs are also discussed in this article.     

Effect of dopaminergic neurotoxin MPTP/MPP+ on coenzyme Q content

Coenzyme Q10, an endogenous lipophilic antioxidant, plays an indispensable role in ATP synthesis. The therapeutic value of coenzyme Q10 in Parkinson's disease and other neurodegenerative disorders is still being tested and the preliminary results are promising. The 1-methyl-4-phenyl-1, 2, 3, 6 tetrahydropyridine (MPTP)-treated mouse is a valid and accepted animal model for Parkinson's disease. 1-methyl-4-phenylpyridinium (MPP(+)) is an active toxic metabolite of MPTP. MPP(+) and MPTP are known to induce oxidative stress and mitochondrial dysfunction. However, the effect of MPP(+) and MPTP on coenzyme Q is not clearly understood. The present study investigated the in vitro and in vivo effect of MPP(+) and MPTP on coenzyme Q content. Coenzyme Q content was measured using HPLC-UV detection methods. In the in vitro studies, MPP(+) (0-50 microM) was incubated with SH-SY5Y human neuroblastoma cells and NG-108-15 (mouse/rat, neuroblastomaxglioma hybrid) cells. MPP(+) concentration dependently increased coenzyme Q10 content in SH-SY5Y cells. In NG-108-15 cells, MPP(+) concentration dependently increased both coenzyme Q9 and Q10 content. In the in vivo study, mice were administered with MPTP (30 mg/kg, twice 16 h apart) and sacrificed one week after the last administration. Administration of MPTP to mice significantly increased coenzyme Q9 and coenzyme Q10 levels in the nigrostriatal tract. However, MPTP did not affect the coenzyme Q content in the cerebellum, cortex and pons. This study demonstrated that MPP(+)/MPTP significantly affected the coenzyme Q content in the SH-SY5Y and NG-108 cells and in the mouse nigrostriatal tract.