ATP synthesis-coupled and -uncoupled acetate production from acetyl-CoA by mitochondrial acetate:succinate CoA-transferase and acetyl-CoA thioesterase in Trypanosoma

Insect stage trypanosomes use an "acetate shuttle" to transfer mitochondrial acetyl-CoA to the cytosol for the essential fatty acid biosynthesis. The mitochondrial acetate sources are acetate:succinate CoA-transferase (ASCT) and an unknown enzymatic activity. We have identified a gene encoding acetyl-CoA thioesterase (ACH) activity, which is shown to be the second acetate source. First, RNAi-mediated repression of ASCT in the ACH null background abolishes acetate production from glucose, as opposed to both single ASCT and ACH mutants. Second, incorporation of radiolabeled glucose into fatty acids is also abolished in this ACH/ASCT double mutant. ASCT is involved in ATP production, whereas ACH is not, because the ASCT null mutant is ～1000 times more sensitive to oligomycin, a specific inhibitor of the mitochondrial F(0)/F(1)-ATP synthase, than wild-type cells or the ACH null mutant. This was confirmed by RNAi repression of the F(0)/F(1)-ATP synthase F(1)β subunit, which is lethal when performed in the ASCT null background but not in the wild-type cells or the ACH null background. We concluded that acetate is produced from both ASCT and ACH; however, only ASCT is responsible, together with the F(0)/F(1)-ATP synthase, for ATP production in the mitochondrion.     

Manipulations in the peripheral stalk of the Saccharomyces cerevisiae F1F0-ATP synthase

The Saccharomyces cerevisiae F(1)F(0)-ATP synthase peripheral stalk is composed of the OSCP, h, d, and b subunits. The b subunit has two membrane-spanning domains and a large hydrophilic domain that extends along one side of the enzyme to the top of F(1). In contrast, the Escherichia coli peripheral stalk has two identical b subunits, and subunits with substantially altered lengths can be incorporated into a functional F(1)F(0)-ATP synthase. The differences in subunit structure between the eukaryotic and prokaryotic peripheral stalks raised a question about whether the two stalks have similar physical and functional properties. In the present work, the length of the S. cerevisiae b subunit has been manipulated to determine whether the F(1)F(0)-ATP synthase exhibited the same tolerances as in the bacterial enzyme. Plasmid shuffling was used for ectopic expression of altered b subunits in a strain carrying a chromosomal disruption of the ATP4 gene. Wild type growth phenotypes were observed for insertions of up to 11 and a deletion of four amino acids on a nonfermentable carbon source. In mitochondria-enriched fractions, abundant ATP hydrolysis activity was seen for the insertion mutants. ATPase activity was largely oligomycin-insensitive in these mitochondrial fractions. In addition, very poor complementation was seen in a mutant with an insertion of 14 amino acids. Lengthier deletions yielded a defective enzyme. The results suggest that although the eukaryotic peripheral stalk is near its minimum length, the b subunit can be extended a considerable distance.     

ATP generation in the Trypanosoma brucei procyclic form: cytosolic substrate level is essential, but not oxidative phosphorylation

Trypanosoma brucei is a parasitic protist responsible for sleeping sickness in humans. The procyclic form of this parasite, transmitted by tsetse flies, is considered to be dependent on oxidative phosphorylation for ATP production. Indeed, its respiration was 55% inhibited by oligomycin, which is the most specific inhibitor of the mitochondrial F0/F1-ATP synthase. However, a 10-fold excess of this compound did not significantly affect the intracellular ATP concentration and the doubling time of the parasite was only 1.5-fold increased, suggesting that oxidative phosphorylation is not essential for procyclic trypanosomes. To further investigate the sites of ATP production, we studied the role of two ATP producing enzymes, which are involved in the synthesis of pyruvate from phosphoenolpyruvate: the glycosomal pyruvate phosphate dikinase (PPDK) and the cytosolic pyruvate kinase (PYK). The parasite was not affected by PPDK gene knockout. In contrast, inhibition of PYK expression by RNA interference was lethal for these cells. In the absence of PYK activity, the intracellular ATP concentration was reduced by up to 2.3-fold, whereas the intracellular pyruvate concentration was not reduced. Furthermore, we show that this mutant cell line still excreted acetate from d-glucose metabolism, and both the wild type and mutant cell lines consumed pyruvate present in the growth medium with similar high rates, indicating that in the absence of PYK activity pyruvate is still present in the trypanosomes. We conclude that PYK is essential because of its ATP production, which implies that the cytosolic substrate level phosphorylation is essential for the growth of procyclic trypanosomes.     

The F1Fo-ATP synthase of Mycobacterium smegmatis is essential for growth

The F(1)F(o)-ATP synthase plays an important role in a number of vital cellular processes in plants, animals, and microorganisms. In this study, we constructed a DeltaatpD mutant of Mycobacterium smegmatis and demonstrated that atpD encoding the beta subunit of the F(1)F(o)-ATP synthase is an essential gene in M. smegmatis during growth on nonfermentable and fermentable carbon sources.     

A topological analysis of subunit alpha from Escherichia coli F1F0-ATP synthase predicts eight transmembrane segments

The membrane topology of subunit alpha from the Escherichia coli F1F0-ATP synthase was studied using a gene fusion technique. Fusion proteins linking different amino-terminal fragments of the alpha subunit with an enzymatically active fragment of alkaline phosphatase were constructed by both random transposition of TnphoA and site-directed mutagenesis. Those proteins with high levels of alkaline phosphatase activity are predicted to define periplasmic domains of alpha, and this was confirmed by testing for cell growth in minimal medium supplemented with polyphosphate (P greater than 75) as the sole source of phosphate. The enzymatic activity of some fusion proteins was shown to be sensitive to glucose present in the growth medium. Results from subcellular fractionation experiments suggest that these fusion proteins may be inactive even though they have a periplasmic alkaline phosphatase. The enzymatic activity appears dependent upon proteolytic release of the alkaline phosphatase moiety from its alpha subunit membrane anchor and suggests the target of glucose repression may be a protease present in the periplasm. For the topological analysis of the alpha subunit, a total of 28 unique fusion proteins were studied and the results were consistent with a model of alpha containing eight transmembrane segments, including periplasmic amino and carboxyl termini. Surprisingly, separate periplasmic domains were identified near amino acids 200, 233, and 270. These results suggest the flanking membrane spans are only 10-15 amino acids in length and not able to span a standard 30 A bilayer in an alpha-helical conformation. These short spans may have interesting mechanistic implications for the function of F0, because they contain several amino acids which appear critical for proton translocation. Finally, a fusion of alkaline phosphatase at amino acid 271, the carboxyl-terminal residue, but not at amino acid 260, was able to complement the strain RH305 (uncB-) for growth on succinate and suggests the last 11 amino acids of the alpha subunit are critical to the function of F1F0-ATP synthase.     

Identification of subunit g of yeast mitochondrial F1F0-ATP synthase, a protein required for maximal activity of cytochrome c oxidase.

By means of a yeast genome database search, we have identified an open reading frame located on chromosome XVI of Saccharomyces cerevisiae that encodes a protein with 53% amino acid similarity to the 11.3-kDa subunit g of bovine mitochondrial F1F0-ATP synthase. We have designated this ORF ATP20, and its product subunit g. A null mutant strain, constructed by insertion of the HIS3 gene into the coding region of ATP20, retained oxidative phosphorylation function. Assembly of F1F0-ATP synthase in the atp20-null strain was not affected in the absence of subunit g and levels of oligomycin-sensitive ATP hydrolase activity in mitochondria were normal. Immunoprecipitation of F1F0-ATP synthase from mitochondrial lysates prepared from atp20-null cells expressing a variant of subunit g with a hexahistidine motif indicated that this polypeptide was associated with other well-characterized subunits of the yeast complex. Whilst mitochondria isolated from the atp20-null strain had the same oxidative phosphorylation efficiency (ATP : O) as that of the control strain, the atp20-null strain displayed approximately a 30% reduction in both respiratory capacity and ATP synthetic rate. The absence of subunit g also reduced the activity of cytochrome c oxidase, and altered the kinetic control of this complex as demonstrated by experiments titrating ATP synthetic activity with cyanide. These results indicate that subunit g is associated with F1F0-ATP synthase and is required for maximal levels of respiration, ATP synthesis and cytochrome c oxidase activity in yeast.     

Reversible assembly of the ATP-binding cassette transporter Mdl1 with the F1F0-ATP synthase in mitochondria

The half-ABC transporter Mdl1 is localized in the inner membrane of mitochondria and mediates the export of peptides generated upon proteolysis of mitochondrial proteins. The physiological role of the peptides released from mitochondria is currently not understood. Here, we have analyzed the oligomeric state of Mdl1 in the inner membrane and demonstrate nucleotide-dependent binding to the F(1)F(0)-ATP synthase. Mdl1 forms homo-oligomeric, presumably dimeric complexes in the presence of ATP, but was found in association with the F(1)F(0)-ATP synthase at low ATP levels. Mdl1 binds membrane-embedded parts of the ATP synthase complex after the assembly of the F(1) and F(0) moieties. Although independent of Mdl1 activity, complex formation is impaired upon inhibition of the F(1)F(0)-ATP synthase with oligomycin or N,N'-dicyclohexylcarbodiimide. These results are consistent with an activation of Mdl1 upon dissociation from the ATP synthase and suggest a link of peptide export from mitochondria to the activity of the F(1)F(0)-ATP synthase and the cellular energy metabolism.     

刺芹侧耳不同发育时期的转录组差异分析

为了探讨刺芹侧耳子实体生长发育时期的基因表达变化,本文利用高通量测序技术对刺芹侧耳不同发育时期（菌丝期、原基期、子实体时期）进行RNA-Seq分析,在转录水平上解析差异表达基因在刺芹侧耳生长发育过程中的作用和功能。KEGG功能富集显示,菌丝期差异表达基因主要富集在碳代谢和氨基酸代谢中,其中三羧酸循环中编码柠檬酸合酶、乌头酸水合酶、异柠檬酸脱氢酶、琥珀酰辅酶A合成酶、琥珀酸脱氢酶、苹果酸脱氢酶的基因表达量均上调,说明碳代谢和氨基酸代谢是菌丝时期的主要能量来源;原基期上调的差异表达基因主要富集在脂肪酸代谢,其中RT-PCR定量结果显示原基期编码脂肪酸合酶的基因和编码脂酰辅酶A合成酶的基因下调,编码超氧化物酶的基因和编码过氧化氢酶的基因上调,表明脂肪酸代谢和抗氧化酶对刺芹侧耳原基期维持机体的稳定和生物应激方面起着重要作用。子实体时期上调的差异表达基因主要富集在剪接体、类固醇的生物合成以及AMPK信号通路中,说明环境因子对子实体时期有一定的影响。     

Expression of bovine F1-ATPase with functional complementation in yeast Saccharomyces cerevisiae

The mitochondrial F(1)F(0)-ATP synthase is a multimeric enzyme complex composed of at least 16 unique peptides with an overall molecular mass of approximately 600 kDa. F(1)-ATPase is composed of alpha(3)beta(3)gammadeltaepsilon with an overall molecular mass of 370 kDa. The genes encoding bovine F(1)-ATPase have been expressed in a quintuple yeast Saccharomyces cerevisiae deletion mutant (DeltaalphaDeltabetaDeltagammaDeltadeltaDeltaepsilon). This strain expressing bovine F(1) is unable to grow on medium containing a non-fermentable carbon source (YPG), indicating that the enzyme is non-functional. However, daughter strains were easily selected for growth on YPG medium and these were evolved for improved growth on YPG medium. The evolution of the strains was presumably due to mutations, but mutations in the genes encoding the subunits of the bovine F(1)-ATPase were not required for the ability of the cell to grow on YPG medium. The bovine enzyme expressed in yeast was partially purified to a specific activity of about half of that of the enzyme purified from bovine heart mitochondria. These results indicate that the molecular machinery required for the assembly of the mitochondrial ATP synthase is conserved from bovine and yeast and suggest that yeast may be useful for the expression, mutagenesis, and analysis of the mammalian F(1)- or F(1)F(0)-ATP synthase.     

Rho transcription factor: symmetry and binding of bicyclomycin

The antibiotic bicyclomycin inhibits rho-dependent termination processes by interfering with RNA translocation by preventing RNA binding at the translocation site or by uncoupling the translocation process from ATP hydrolysis. Previous studies have shown that bicyclomycin binds near the ATP hydrolysis pocket on rho. The hexameric structure of rho indicates that it is in a class of enzymes with strong sequence similarity to F(1)-ATP synthase. The bicyclomycin derivative 5a-formylbicyclomycin, an inhibitor comparable to bicyclomycin, was previously shown to form a stable imine with rho and when reduced to the amine with NaBH(4) to singly label five of the six rho subunits. Lysine-336 was identified by mass spectrometric analysis of trypsin-digested fragments as the site of 5a-formylbicyclomycin adduction. A model of rho was made by threading the rho sequence on the known crystal structure of the alpha and beta subunits of F(1)-ATP synthase. The model, along with information concerning the extent and site of 5a-formylbicyclomycin adduction, indicates an overall C6 symmetry for rho subunit organization. We propose that the sequence similarity between rho and F(1)-ATP synthase extends to a similar quaternary structure and an equivalent enzyme mechanism. The proposed mechanism of RNA translocation coupled with ATP hydrolysis changes the overall symmetry of rho from C6 to C6/C3.     

31P-NMR saturation transfer studies of aerobic Escherichia coli cells

31P-NMR measurements of saturation transfer have been used to measure the flux between Pi and ATP in Escherichia coli cells respiring on an endogenous carbon source. Measurements were made in the wild type and in cells genetically modified to give a 5-fold higher concentration of the F1F0-ATP synthase. The flux in the two cell types was not significantly different. This, together with studies using inhibitors specific for the glycolytic enzyme, glyceraldehyde-3-phosphate dehydrogenase and the ATP synthase, suggests that the observed flux arises predominantly from glycolytic rather than ATP synthase activity. Although this conclusion is in disagreement with previous experiments on E. coli, it is in agreement with recent experiments on yeast.     

Flux analysis of central metabolic pathways in Geobacter metallireducens during reduction of soluble Fe(III)-nitrilotriacetic acid

We analyzed the carbon fluxes in the central metabolism of Geobacter metallireducens strain GS-15 using 13C isotopomer modeling. Acetate labeled in the first or second position was the sole carbon source, and Fe-nitrilotriacetic acid was the sole terminal electron acceptor. The measured labeled acetate uptake rate was 21 mmol/g (dry weight)/h in the exponential growth phase. The resulting isotope labeling pattern of amino acids allowed an accurate determination of the in vivo global metabolic reaction rates (fluxes) through the central metabolic pathways using a computational isotopomer model. The tracer experiments showed that G. metallireducens contained complete biosynthesis pathways for essential metabolism, and this strain might also have an unusual isoleucine biosynthesis route (using acetyl coenzyme A and pyruvate as the precursors). The model indicated that over 90% of the acetate was completely oxidized to CO2 via a complete tricarboxylic acid cycle while reducing iron. Pyruvate carboxylase and phosphoenolpyruvate (PEP) carboxykinase were present under these conditions, but enzymes in the glyoxylate shunt and malic enzyme were absent. Gluconeogenesis and the pentose phosphate pathway were mainly employed for biosynthesis and accounted for less than 3% of total carbon consumption. The model also indicated surprisingly high reversibility in the reaction between oxoglutarate and succinate. This step operates close to the thermodynamic equilibrium, possibly because succinate is synthesized via a transferase reaction, and the conversion of oxoglutarate to succinate is a rate-limiting step for carbon metabolism. These findings enable a better understanding of the relationship between genome annotation and extant metabolic pathways in G. metallireducens.     

Succinate secreted by Trypanosoma brucei is produced by a novel and unique glycosomal enzyme,NADH-dependent fumarate reductase

In all trypanosomatids, including Trypanosoma brucei, glycolysis takes place in peroxisome-like organelles called glycosomes. These are closed compartments wherein the energy and redox (NAD(+)/NADH) balances need to be maintained. We have characterized a T. brucei gene called FRDg encoding a protein 35% identical to Saccharomyces cerevisiae fumarate reductases. Microsequencing of FRDg purified from glycosome preparations, immunofluorescence, and Western blot analyses clearly identified this enzyme as a glycosomal protein that is only expressed in the procyclic form of T. brucei but is present in all the other trypanosomatids studied, i.e. Trypanosoma congolense, Crithidia fasciculata and Leishmania amazonensis. The specific inactivation of FRDg gene expression by RNA interference showed that FRDg is responsible for the NADH-dependent fumarate reductase activity detected in glycosomal fractions and that at least 60% of the succinate secreted by the T. brucei procyclic form (in the presence of d-glucose as the sole carbon source) is produced in the glycosome by FRDg. We conclude that FRDg plays a key role in the energy metabolism by participating in the maintenance of the glycosomal NAD(+)/NADH balance. We have also detected a significant pyruvate kinase activity in the cytosol of the T. brucei procyclic cells that was not observed previously. Consequently, we propose a revised model of glucose metabolism in procyclic trypanosomes that may also be valid for all other trypanosomatids except the T. brucei bloodstream form. Interestingly, H. Gest has hypothesized previously (Gest, H. (1980) FEMS Microbiol. Lett. 7, 73-77) that a soluble NADH-dependent fumarate reductase has been present in primitive organisms and evolved into the present day fumarate reductases, which are quinol-dependent. FRDg may have the characteristics of such an ancestral enzyme and is the only NADH-dependent fumarate reductase characterized to date.     

Formation of the yeast F1F0-ATP synthase dimeric complex does not require the ATPase inhibitor protein,Inh1

The yeast F1F0-ATP synthase forms dimeric complexes in the mitochondrial inner membrane and in a manner that is supported by the F0-sector subunits, Su e and Su g. Furthermore, it has recently been demonstrated that the binding of the F1F0-ATPase natural inhibitor protein to purified bovine F1-sectors can promote their dimerization in solution (Cabezon, E., Arechaga, I., Jonathan P., Butler, G., and Walker J. E. (2000) J. Biol. Chem. 275, 28353-28355). It was unclear until now whether the binding of the inhibitor protein to the F1 domains contributes to the process of F1F0-ATP synthase dimerization in intact mitochondria. Here we have directly addressed the involvement of the yeast inhibitor protein, Inh1, and its known accessory proteins, Stf1 and Stf2, in the formation of the yeast F1F0-ATP synthase dimer. Using mitochondria isolated from null mutants deficient in Inh1, Stf1, and Stf2, we demonstrate that formation of the F(1)F(0)-ATP synthase dimers is not adversely affected by the absence of these proteins. Furthermore, we demonstrate that the F1F0-ATPase monomers present in su e null mutant mitochondria can be as effectively inhibited by Inh1, as its dimeric counterpart in wild-type mitochondria. We conclude that dimerization of the F1F0-ATP synthase complexes involves a physical interaction of the membrane-embedded F0 sectors from two monomeric complexes and in a manner that is independent of inhibitory activity of the Inh1 and accessory proteins.     

Hypoxic preconditioning-induced mitochondrial protection is not disrupted in a cell model of mtDNA T8993G mutation-induced F1F0-ATP synthase defect: the role of mitochondrial permeability transition

Transient opening of the mitochondrial permeability transition pore plays a crucial role in hypoxic preconditioning-induced protection. Recently, the cyclophilin-D component of the mitochondrial permeability transition pore has been shown to interact with and regulate the F1F0-ATP synthase. However, the precise role of the F1F0-ATP synthase and the interaction between cyclophilin-D and F1F0-ATP synthase in the mitochondrial permeability transition pore and hypoxic preconditioning remain uncertain. Here we found that a 1-h hypoxic preconditioning delayed apoptosis and improved cell survival after stimulation with various apoptotic inducers including H₂O₂, ionomycin, and arachidonic acid in mitochondrial DNA T8993G mutation (NARP) osteosarcoma 143B cybrids, an F1F0-ATP synthase defect cell model. This hypoxic preconditioning protected NARP cybrid cells against focal laser irradiation-induced oxidative stress by suppressing reactive oxygen species formation and preventing the depletion of cardiolipin. Furthermore, the protective functions of transient opening of the mitochondrial permeability transition pore in both NARP cybrids and wild-type 143B cells can be augmented by hypoxic preconditioning. Disruption of the interaction between cyclophilin-D and F1F0-ATP synthase by cyclosporin A attenuated the mitochondrial protection induced by hypoxic preconditioning in both NARP cybrids and wild-type 143B cells. Our results demonstrate that the interaction between cyclophilin-D and F1F0-ATP synthase is important in the hypoxic preconditioning-induced cell protection. This finding improves our understanding of the mechanism of mitochondrial permeability transition pore opening in cells in response to hypoxic preconditioning, and will be helpful in further developing new pharmacological agents targeting hypoxia–reoxygenation injury and mitochondria-mediated cell death     

Cell-surface H+-ATP synthase as a potential molecular target for anti-obesity drugs

Here we show that the cell-surface expression of the alpha subunit of H(+)-ATP synthase is markedly increased during adipocyte differentiation. Treatment of differentiated adipocytes with small molecule inhibitors of H(+)-ATP synthase or antibodies against alpha and beta subunits of H(+)-ATP synthase leads to a decrease in cytosolic lipid droplet accumulation. Apolipoprotein A-I, which has been shown to bind to the ectopic beta-chain of H(+)-ATP synthase and inhibit the activity of cell-surface H(+)-ATP synthase, also was found to inhibit cytosolic lipid accumulation. These results suggest that the cell-surface H(+)-ATP synthase has a previously unsuspected role in lipid metabolism in adipocytes.