Characterization of solanesyl and decaprenyl diphosphate synthases in mice and humans

The isoprenoid chain of ubiquinone (Q) is determined by trans-polyprenyl diphosphate synthase in micro-organisms and presumably in mammals. Because mice and humans produce Q9 and Q10, they are expected to possess solanesyl and decaprenyl diphosphate synthases as the determining enzyme for a type of ubiquinone. Here we show that murine and human solanesyl and decaprenyl diphosphate synthases are heterotetramers composed of newly characterized hDPS1 (mSPS1) and hDLP1 (mDLP1), which have been identified as orthologs of Schizosaccharomyces pombe Dps1 and Dlp1, respectively. Whereas hDPS1 or mSPS1 can complement the S. pombe dps1 disruptant, neither hDLP1 nor mDLP1 could complement the S. pombe dLp1 disruptant. Thus, only hDPS1 and mSPS1 are functional orthologs of SpDps1. Escherichia coli was engineered to express murine and human SpDps1 and/or SpDlp1 homologs and their ubiquinone types were determined. Whereas transformants expressing a single component produced only Q8 of E. coli origin, double transformants expressing mSPS1 and mDLP1 or hDPS1 and hDLP1 produced Q9 or Q10, respectively, and an in vitro activity of solanesyl or decaprenyl diphosphate synthase was verified. The complex size of the human and murine long-chain trans-prenyl diphosphate synthases, as estimated by gel-filtration chromatography, indicates that they consist of heterotetramers. Expression in E. coli of heterologous combinations, namely, mSPS1 and hDLP1 or hDPS1 and mDLP1, generated both Q9 and Q10, indicating both components are involved in determining the ubiquinone side chain. Thus, we identified the components of the enzymes that determine the side chain of ubiquinone in mammals and they resembles the S. pombe, but not plant or Saccharomyces cerevisiae, type of enzyme.     

Heteromer formation of a long-chain prenyl diphosphate synthase from fission yeast Dps1 and budding yeast Coq1

Ubiquinone is an essential factor for the electron transfer system and is also a known lipid antioxidant. The length of the ubiquinone isoprenoid side-chain differs amongst living organisms, with six isoprene units in the budding yeast Saccharomyces cerevisiae, eight units in Escherichia coli and 10 units in the fission yeast Schizosaccharomyces pombe and in humans. The length of the ubiquinone isoprenoid is determined by the product generated by polyprenyl diphosphate synthases (poly-PDSs), which are classified into homodimer (i.e. octa-PDS IspB in E. coli) and heterotetramer [i.e. deca-PDSs Dps1 and D-less polyprenyl diphosphate synthase (Dlp1) in Sc. pombe and in humans] types. In this study, we characterized the hexa-PDS (Coq1) of S. cerevisiae to identify whether this enzyme was a homodimer (as in bacteria) or a heteromer (as in fission yeast). When COQ1 was expressed in an E. coli ispB disruptant, only hexa-PDS activity and ubiquinone-6 were detected, indicating that the expression of Coq1 alone results in bacterial enzyme-like functionality. However, when expressed in fission yeast Deltadps1 and Deltadlp1 strains, COQ1 restored growth on minimal medium in the Deltadlp1 but not Deltadps1 strain. Intriguingly, ubiquinone-9 and ubiquinone-10, but not ubiquinone-6, were identified and deca-PDS activity was detected in the COQ1-expressing Deltadlp1 strain. No enzymatic activity or ubiquinone was detected in the COQ1-expressing Deltadps1 strain. These results indicate that Coq1 partners with Dps1, but not with Dlp1, to be functional in fission yeast. Binding of Coq1 and Dps1 was demonstrated by coimmunoprecipitation, and the formation of a tetramer consisting of Coq1 and Dps1 was detected in Sc. pombe. Thus, Coq1 is functional when expressed alone in E. coli and in budding yeast, but is only functional as a partner with Dps1 in fission yeast. This unusual observation indicates that different folding processes or protein modifications in budding yeast/E. coli versus those in fission yeast might affect the formation of an active enzyme. These results provide important insights into the process of how PDSs have evolved from homo- to hetero-types.     

Cloning and functional expression of the dps gene encoding decaprenyl diphosphate synthase from Agrobacterium tumefaciens

A newly isolated gene from Agrobacterium tumefaciens (A. tumefaciens), which encoded a decaprenyl diphosphate synthase, was cloned in Escherichia coli (E. coli), and its nucleotide sequence was determined. DNA sequence analysis revealed an open reading frame of 1077 bp capable of encoding a 358-amino-acid protein with a calculated isoelectric point of pH 5.16 and a molecular mass of 38 960 Da. The primary structure of the enzyme shared significant homology with prenyl diphosphate synthases from various sources. The deduced amino acid sequence included oligopeptide DDxxD aspartate-rich domains conserved in the majority of prenyl diphosphate synthases. High levels of the active enzyme were expressed in the soluble fraction and were readily purified to homogeneity by Ni-NTA chromatography. E. coli JM109 harboring the dps gene produced ubiquinone-10 in addition to endogenous ubiquinone-8, while E. coli JM109 harboring the dps gene mutated on the DDxxD domain lost the ability to produce ubiquinone-10, which suggests that the A. tumefaciens dps gene is functionally expressed in E. coli and that it encodes a decaprenyl diphosphate synthase.     

A subunit of decaprenyl diphosphate synthase stabilizes octaprenyl diphosphate synthase in Escherichia coli by forming a high-molecular weight complex

The length of the isoprenoid-side chain in ubiquinone, an essential component of the electron transport chain, is defined by poly-prenyl diphosphate synthase, which comprises either homomers (e.g., IspB in Escherichia coli) or heteromers (e.g., decaprenyl diphosphate synthase (Dps1) and D-less polyprenyl diphosphate synthase (Dlp1) in Schizosaccharomyces pombe and in humans). We found that expression of either dlp1 or dps1 recovered the thermo-sensitive growth of an E. coli ispB^R321A mutant and restored IspB activity and production of Coenzyme Q-8. IspB interacted with Dlp1 (or Dps1), forming a high-molecular weight complex that stabilized IspB, leading to full functionality.

Structured summary:

MINT-7385426:Dlp1 (uniprotkb:Q86YH6) and IspB (uniprotkb:P0AD57) physically interact (MI:0915) by blue native page (MI:0276)MINT-7385083, MINT-7385058:IspB (uniprotkb:P0AD57) and IspB (uniprotkb:P0AD57) bind (MI:0407) by blue native page (MI:0276)MINT-7385413:Dlp1 (uniprotkb:O13851) and IspB (uniprotkb:P0AD57) physically interact (MI:0915) by blue native page (MI:0276)MINT-7385024:IspB (uniprotkb:P0AD57) physically interacts (MI:0915) with Dps1 (uniprotkb:O43091) by pull down (MI:0096)MINT-7385041:IspB (uniprotkb:P0AD57) physically interacts (MI:0915) with Dlp1 (uniprotkb:O13851) by pull down (MI:0096)MINT-7385388:IspB (uniprotkb:P0AD57) and Dps1 (uniprotkb:O43091) physically interact (MI:0915) by blue native page (MI:0276)     

Pleiotropic phenotypes of fission yeast defective in ubiquinone-10 production. A study from the abc1Sp (coq8Sp) mutant

We previously constructed two Schizosaccahromyces pombe ubiquinone-10 (or Coenzyme Q10) less mutants, which are either defective for decaprenyl diphosphate synthase or p-hydroxybenzoate polyprenyl diphosphate transferase. To further confirm the roles of ubiquinone in S. pombe, we examined the phenotype of the abc1Sp (coq8Sp) mutant, which is highly speculated to be defective in ubiquinone biosynthesis. We show here that the abc1Sp defective strain did not produce UQ-10 and could not grow on minimal medium. The abc1Sp-deficient strain required supplementation with antioxidants such as cysteine or glutathione to grow on minimal medium. In support of the antioxidant function of ubiquinone, the abc1Sp-deficient strain is sensitive to H2O2 and Cu2+. In addition, expression of the stress inducible ctt1 gene was much induced in the ubiquinone less mutant than wild type. Interestingly, we also found that the abc1-deficient strain as well as other ubiquinone less mutants produced a significant amount of H2S, which suggests that oxidation of sulfide by ubiquinone may be an important pathway for sulfur metabolism in S. pombe. Thus, analysis of the phenotypes of S. pombe ubiquinone less mutants clearly demonstrate that ubiquinone has multiple functions in the cell apart from being an integral component of the electron transfer system.     

Cloning and characterization of decaprenyl diphosphate synthase from three different fungi

Coenzyme Q (CoQ) is composed of a benzoquinone moiety and an isoprenoid side chain of varying lengths. The length of the side chain is controlled by polyprenyl diphosphate synthase. In this study, dps1 genes encoding decaprenyl diphosphate synthase were cloned from three fungi: Bulleromyces albus, Saitoella complicata, and Rhodotorula minuta. The predicted Dps1 proteins contained seven conserved domains found in typical polyprenyl diphosphate synthases and were 528, 440, and 537 amino acids in length in B. albus, S. complicata, and R. minuta, respectively. Escherichia coli expressing the fungal dps1 genes produced CoQ₁₀ in addition to endogenous CoQ₈. Two of the three fungal dps1 genes (from S. complicata and R. minuta) were able to replace the function of ispB in an E. coli mutant strain. In vitro enzymatic activities were also detected in recombinant strains. The three dps1 genes were able to complement a Schizosaccharomyces pombe dps1, dlp1 double mutant. Recombinant S. pombe produced mainly CoQ₁₀, indicating that the introduced genes were independently functional and did not require dlp1. The cloning of dps1 genes from various fungi has the potential to enhance production of CoQ₁₀ in other organisms.

     

Phenotypes of fission yeast defective in ubiquinone production due to disruption of the gene for p-hydroxybenzoate polyprenyl diphosphate transferase

Ubiquinone is an essential component of the electron transfer system in both prokaryotes and eukaryotes and is synthesized from chorismate and polyprenyl diphosphate by eight steps. p-Hydroxybenzoate (PHB) polyprenyl diphosphate transferase catalyzes the condensation of PHB and polyprenyl diphosphate in ubiquinone biosynthesis. We isolated the gene (designated ppt1) encoding PHB polyprenyl diphosphate transferase from Schizosaccharomyces pombe and constructed a strain with a disrupted ppt1 gene. This strain could not grow on minimal medium supplemented with glucose. Expression of COQ2 from Saccharomyces cerevisiae in the defective S. pombe strain restored growth and enabled the cells to produce ubiquinone-10, indicating that COQ2 and ppt1 are functional homologs. The ppt1-deficient strain required supplementation with antioxidants, such as cysteine, glutathione, and alpha-tocopherol, to grow on minimal medium. This suggests that ubiquinone can act as an antioxidant, a premise supported by our observation that the ppt1-deficient strain is sensitive to H(2)O(2) and Cu(2+). Interestingly, we also found that the ppt1-deficient strain produced a significant amount of H(2)S, which suggests that oxidation of sulfide by ubiquinone may be an important pathway for sulfur metabolism in S. pombe. Ppt1-green fluorescent protein fusion proteins localized to the mitochondria, indicating that ubiquinone biosynthesis occurs in the mitochondria in S. pombe. Thus, analysis of the phenotypes of S. pombe strains deficient in ubiquinone production clearly demonstrates that ubiquinone has multiple functions in the cell apart from being an integral component of the electron transfer system.     

弱氧化葡糖杆菌ddsA基因在大肠杆菌不同宿主菌中的表达

泛醌（辅酶Q）在生物体氧化呼吸链中作为重要的质子和电子传递物质。聚十异戊烯焦磷酸合成酶催化辅助酶Q10的侧链的生物合成。为了获得高产辅助酶Q10的菌株,将选择了10种不同大肠杆菌宿主菌用于弱氧化葡糖杆菌的聚十异戊烯焦磷酸合成酶基因ddsA的表达,通过产物分析证实该基因能在大肠杆菌中表达出有活性的聚十异戊烯焦磷酸合成酶,使大肠杆菌合成了辅酶Q10。此外,还发现在Escherichia coli HB101这一菌株中,ddsA的表达使辅酶Q10的产量略超过了在野生型中占主导地位的辅酶Q8的产量。该结果证明了利用大肠杆菌大规模发酵生产辅酶Q10的可能性。     

Expression of various genes to enhance ubiquinone metabolic pathway in Agrobacterium tumefaciens

Ubiquinone (UQ), a lipid-soluble component, acts as a mobile component of the respiratory chain by playing an essential role in the electron transport system in many organisms, and has been widely used in pharmaceuticals due to its antioxidant property. The biosynthesis of UQ involves 10 sequential reactions brought about by various enzymes. In this study, dps gene, which encodes decaprenyl diphosphate synthase, involved in ubiquinone biosynthesis from Agrobacterium tumefaciens, and coq2 gene of Saccharomyces cerevisiae, ppt1 gene of Schizosaccahromyces pombe and ubiA gene of Escherichia coli, all of them encoding 4-hydroxybenzoate:polyprenyl diphosphate (4-HB:PPP) transferase, were reconfigured into an operon under the control of a single promoter to yield various plasmids including pBIV-dps, pBIV-dpsq, pBIV-dpsp and pBIV-dpsca. The recombinant A. tumefaciens containing dps-ubiC-ubiA gene showed the highest level ubiquinone production than that of the other recombinants and the nonrecombinant bacterium. In an aerobic fed-batch fermentation, A. tumefaciens containing the pBIV-dpsca plasmid produced 25.2 mg of ubiquinone-10 per liter which was 1.68 times higher than that of nonrecombinant type. While in microaerobic fed-batch fermentation, recombinant cell pBIV-dpsca produced 30.8 mg L⁻¹ of ubiquinone-10. Compared to the original A. tumefaciens, the ubiquinone-10 yield and productivities of the recombinant bacterium pBIV-dpsca increased 88.9% and 77.7%, respectively, under microaerobic fed-batch conditions.     

辅酶Q10生物合成与生产研究进展

微生物发酵法是生产辅酶Q10的最佳工艺.辅酶Q10的生物合成途径包括异戊二烯焦磷酸合成、聚十异戊二烯焦磷酸合成、苯环修饰等过程.1-脱氧-D-木酮糖-5-磷酸合成酶、聚十异戊二烯焦磷酸合成酶、对羟基笨甲酸聚十异戊二烯焦磷酸转移酶等是Q10合成的关键酶.生产辅酶Q10的菌种可通过诱变、基因重组和支路敲除等方法获得.氧化还原电位控制、pH控制补料分批发酵、发酵萃取耦合技术等新工艺逐浙应用于辅酶Q10生产.     

Geranylgeranyl diphosphate synthase in fission yeast is a heteromer of farnesyl diphosphate synthase (FPS), Fps1, and an FPS-like protein, Spo9, essential for sporulation

Both farnesyl diphosphate synthase (FPS) and geranylgeranyl diphosphate synthase (GGPS) are key enzymes in the synthesis of various isoprenoid-containing compounds and proteins. Here, we describe two novel Schizosaccharomyces pombe genes, fps1(+) and spo9(+), whose products are similar to FPS in primary structure, but whose functions differ from one another. Fps1 is essential for vegetative growth, whereas, a spo9 null mutant exhibits temperature-sensitive growth. Expression of fps1(+), but not spo9(+), suppresses the lethality of a Saccharomyces cerevisiae FPS-deficient mutant and also restores ubiquinone synthesis in an Escherichia coli ispA mutant, which lacks FPS activity, indicating that S. pombe Fps1 in fact functions as an FPS. In contrast to a typical FPS gene, no apparent GGPS homologues have been found in the S. pombe genome. Interestingly, although neither fps1(+) nor spo9(+) expression alone in E. coli confers clear GGPS activity, coexpression of both genes induces such activity. Moreover, the GGPS activity is significantly reduced in the spo9 mutant. In addition, the spo9 mutation perturbs the membrane association of a geranylgeranylated protein, but not that of a farnesylated protein. Yeast two-hybrid and coimmunoprecipitation analyses indicate that Fps1 and Spo9 physically interact. Thus, neither Fps1 nor Spo9 alone functions as a GGPS, but the two proteins together form a complex with GGPS activity. Because spo9 was originally identified as a sporulation-deficient mutant, we show here that expansion of the forespore membrane is severely inhibited in spo9Delta cells. Electron microscopy revealed significant accumulation membrane vesicles in spo9Delta cells. We suggest that lack of GGPS activity in a spo9 mutant results in impaired protein prenylation in certain proteins responsible for secretory function, thereby inhibiting forespore membrane formation.     

Identification and subcellular localization of two solanesyl diphosphate synthases from Arabidopsis thaliana

Two solanesyl diphosphate synthases, designated SPS1 and SPS2, which are responsible for the synthesis of the isoprenoid side chain of either plastoquinone or ubiquinone in Arabidopsis thaliana, were identified. Heterologous expression of either SPS1 or SPS2 allowed the generation of UQ-9 in a decaprenyl diphosphate synthase-defective strain of fission yeast and also in wild-type Escherichia coli. SPS1-GFP was found to localize in the ER while SPS2-GFP localized in the plastid of tobacco BY-2 cells. These two different subcellular localizations are thought to be the reflection of their roles in solanesyl diphosphate synthesis in two different parts: presumably SPS1 and SPS2 for the side chains of ubiquinone and plastoquinone, respectively.     

微生物CoQ合成途径及CoQ10生产菌株的分子生物学改造

CoQ10具有呼吸链电子传递者、抗氧化性、调控基因表达等多种生理生化功能,目前不仅用作药物也用作食品添加剂。微生物发酵法是目前生产CoQ10最有效的方法。本文就有关微生物CoQ合成途径及基于CoQ合成途径的CoQ10生产菌株分子生物学改造的策略与研究进展进行了综述和展望。     

Expression of various genes to enhance ubiquinone metabolic pathway in Agrobacterium tumefaciens

Ubiquinone (UQ), a lipid-soluble component, acts as a mobile component of the respiratory chain by playing an essential role in the electron transport system in many organisms, and has been widely used in pharmaceuticals due to its antioxidant property. The biosynthesis of UQ involves 10 sequential reactions brought about by various enzymes. In this study, dps gene, which encodes decaprenyl diphosphate synthase, involved in ubiquinone biosynthesis from Agrobacterium tumefaciens, and coq2 gene of Saccharomyces cerevisiae, ppt1 gene of Schizosaccahromyces pombe and ubiA gene of Escherichia coli, all of them encoding 4-hydroxybenzoate:polyprenyl diphosphate (4-HB:PPP) transferase, were reconfigured into an operon under the control of a single promoter to yield various plasmids including pBIV-dps, pBIV-dpsq, pBIV-dpsp and pBIV-dpsca. The recombinant A. tumefaciens containing dps-ubiC-ubiA gene showed the highest level ubiquinone production than that of the other recombinants and the nonrecombinant bacterium. In an aerobic fed-batch fermentation, A. tumefaciens containing the pBIV-dpsca plasmid produced 25.2 mg of ubiquinone-10 per liter which was 1.68 times higher than that of nonrecombinant type. While in microaerobic fed-batch fermentation, recombinant cell pBIV-dpsca produced 30.8 mg L⁻¹ of ubiquinone-10. Compared to the original A. tumefaciens, the ubiquinone-10 yield and productivities of the recombinant bacterium pBIV-dpsca increased 88.9% and 77.7%, respectively, under microaerobic fed-batch conditions.     

代谢工程改造大肠杆菌生产辅酶Q10

辅酶Q10(CoQ10)是一种脂溶性抗氧化剂,具有提高人体免疫力、延缓衰老和增强人体活力等功能,广泛应用于制药行业和化妆品行业。微生物发酵法能可持续性生产辅酶Q10,具有越来越多的商业价值。本研究首先将来自类球红细菌的十聚异戊二烯焦磷酸合成酶基因(dps)整合到大肠杆菌ATCC 8739染色体上,敲除内源的八聚异戊二烯焦磷酸合成酶基因(ispB),使内源的辅酶Q8合成途径被辅酶Q10合成途径取代,得到稳定生产辅酶Q10的菌株GD-14,其辅酶Q10产量达0.68 mg/L,单位细胞含量达0.54 mg/g DCW。随后用多个固定强度调控元件在染色体上对MEP途径的关键基因dxs和idi基因以及ubiCA基因进行组合调控,将辅酶Q10单位细胞含量提高2.46倍(从0.54到1.87 mg/g)。进一步引入运动发酵单胞菌Zymomonas mobilis的Glf转运蛋白代替自身的磷酸烯醇式丙酮酸:碳水化合物磷酸转移酶系统(PTS),使辅酶Q10产量进一步提高16%。最后,对高产菌株GD-51进行分批补料发酵,辅酶Q10产量达433 mg/L,单位细胞含量达11.7 mg/g DCW。这是目前为止文献报道的大肠杆菌产辅酶Q10最高菌株。     

Decaprenyl diphosphate synthesis in Mycobacterium tuberculosis

Z-prenyl diphosphate synthases catalyze the sequential condensation of isopentenyl diphosphate with allylic diphosphates to synthesize polyprenyl diphosphates. In mycobacteria, these are precursors of decaprenyl phosphate, a molecule which plays a central role in the biosynthesis of essential mycobacterial cell wall components, such as the mycolyl-arabinogalactan-peptidoglycan complex and lipoarabinomannan. Recently, it was demonstrated that open reading frame Rv2361c of the Mycobacterium tuberculosis H37Rv genome encodes a unique prenyl diphosphate synthase (M. C. Schulbach, P. J. Brennan, and D. C. Crick, J. Biol. Chem. 275:22876-22881, 2000). We have now purified the enzyme to near homogeneity by using an Escherichia coli expression system and have shown that the product of this enzyme is decaprenyl diphosphate. Rv2361c has an absolute requirement for divalent cations and an optimal pH range of 7.5 to 8.5, and the activity is stimulated by both detergent and dithiothreitol. The enzyme catalyzes the addition of isopentenyl diphosphate to geranyl diphosphate, neryl diphosphate, omega,E,E-farnesyl diphosphate, omega,E,Z-farnesyl diphosphate, or omega,E,E,E-geranylgeranyl diphosphate, with Km values for the allylic substrates of 490, 29, 84, 290, and 40 microM, respectively. The Km value for isopentenyl diphosphate is 89 microM. The catalytic efficiency is greatest when omega,E,Z-farnesyl diphosphate is used as the allylic acceptor, suggesting that this is the natural substrate in vivo, a conclusion that is supported by previous structural studies of decaprenyl phosphoryl mannose isolated from M. tuberculosis. This is the first report of a bacterial Z-prenyl diphosphate synthase that preferentially utilizes an allylic diphosphate primer having the alpha-isoprene unit in the Z configuration, indicating that Rv1086 (omega,E,Z-farnesyl diphosphate synthase) and Rv2361c act sequentially in the biosynthetic pathway that leads to the formation of decaprenyl phosphate in M. tuberculosis.     

Identification of bottlenecks in Escherichia coli engineered for the production of CoQ(10)

In this work, Escherichia coli was engineered to produce a medically valuable cofactor, coenzyme Q₁₀ (CoQ₁₀), by removing the endogenous octaprenyl diphosphate synthase gene and functionally replacing it with a decaprenyl diphosphate synthase gene from Sphingomonas baekryungensis. In addition, by over-expressing genes coding for rate-limiting enzymes of the aromatic pathway, biosynthesis of the CoQ₁₀ precursor para-hydroxybenzoate (PHB) was increased. The production of isoprenoid precursors of CoQ₁₀ was also improved by the heterologous expression of a synthetic mevalonate operon, which permits the conversion of exogenously supplied mevalonate to farnesyl diphosphate. The over-expression of these precursors in the CoQ₁₀-producing E. coli strain resulted in an increase in CoQ₁₀ content, as well as in the accumulation of an intermediate of the ubiquinone pathway, decaprenylphenol (10P-Ph). In addition, the over-expression of a PHB decaprenyl transferase (UbiA) encoded by a gene from Erythrobacter sp. NAP1 was introduced to direct the flux of DPP and PHB towards the ubiquinone pathway. This further increased CoQ₁₀ content in engineered E. coli, but decreased the accumulation of 10P-Ph. Finally, we report that the combined over-production of isoprenoid precursors and over-expression of UbiA results in the decaprenylation of para-aminobenzoate, a biosynthetic precursor of folate, which is structurally similar to PHB.     

Complementation of Escherichia coli ubiF mutation by Caenorhabditis elegans CLK-1, a product of the longevity gene of the nematode worm

Caenorhabditis elegans CLK-1 was identified from long-lived mutant worms, and is believed to be involved in ubiquinone biosynthesis. The protein belongs to the eukaryotic CLK-1/Coq7p family, which is also similar to the bacterial Coq7 family, that hydroxylates demethoxyubiquinone, resulting in the formation of hydroxyubiquinone, a precursor of ubiquinone. In Escherichia coli, the corresponding reaction is catalyzed by UbiF, a member of a distinct class of hydroxylase. Although previous studies suggested that the eukaryotic CLK-1/Coq7 family is a hydroxylase of demethoxyubiquinone, there was no direct evidence to show the enzymatic activity of the eukaryotic CLK-1/Coq7 family. Here we show that the plasmid encoding C. elegans CLK-1 supported aerobic respiration on a non-fermentable carbon source of E. coli ubiF mutant strain and rescued the ability to synthesize ubiquinone, suggesting that the eukaryotic CLK-1/Coq7p family could function as bacterial UbiF.     

The two Dps of Edwardsiella tarda are involved in resistance against oxidative stress and host infection

DNA-binding protein from starved cells (Dps) is a member of ferritin-like proteins that exhibit properties of nonspecific DNA binding and iron oxidation and storage. Although studies of Dps from many bacterial species have been reported, no investigations on Dps from fish pathogens have been documented. In this study, we examined the biological function of two Dps proteins, Dps1 and Dps2, from Edwardsiella tarda, an important fish bacterial pathogen that can also infect humans. Dps1 and Dps2 are, respectively, 163- and 174-residue in length and each contains the conserved ferroxidase center of Dps. Expression of dps1 and dps2 was growth phase-dependent and reached high levels in stationary phase. Purified recombinant Dps1 and Dps2 were able to mediate iron oxidation by H(2)O(2) and bind DNA. Compared to the wild type strain, (i) the dps1 mutant (TXDps1) and the dps2 mutant (TXDps2) were unaffected in growth, while the dps2 mutant with interfered dps1 expression (TXDps2RI) exhibited a prolonged lag phase; (ii) TXDps1, TXDps2, and especially TXDps2RI were significantly reduced in H(2)O(2) and UV tolerance and impaired in the capacity to invade into host tissues and replicate in head kidney macrophages; (iii) TXDps1, TXDps2, and TXDps2RI induced stronger macrophage respiratory burst activity and thus were defective in the ability to block the bactericidal response of macrophages. Taken together, these results indicate that Dps1 and Dps2 are functional analogues that possess ferroxidase activity and DNA binding capacity and are required for optimum oxidative stress resistance and full bacterial virulence.