Project description:1. The effects of the hypoglycaemic compound, pent-4-enoic acid, and of four structurally related non-hypoglycaemic compounds (pentanoic acid, pent-2-enoic acid, cyclopropanecarboxylic acid and cyclobutanecarboxylic acid), on the oxidation of saturated fatty acids by rat liver mitochondria were determined. 2. The formation of (14)CO(2) from [1-(14)C]palmitate was strongly inhibited by 0.01mm-pent-4-enoic acid. 3. The inhibition of oxygen uptake was less than that of (14)CO(2) formation, presumably because fumarate was used as a sparker. 4. The oxidation of [1-(14)C]-butyrate, -octanoate or -laurate was not strongly inhibited by 0.01mm-pent-4-enoic acid. 5. The other four non-hypoglycaemic compounds did not inhibit the oxidation of any saturated fatty acid when tested at 0.01mm concentration, though they all inhibited strongly at 10mm. 6. The oxidation of [1-(14)C]-myristate and -stearate, but not of [1-(14)C]decanoate, was strongly inhibited by 0.01mm-pent-4-enoic acid. 7. The oxidation of [1-(14)C]palmitate was about 50% carnitine-dependent under the experimental conditions used. 8. The percentage inhibition of [1-(14)C]palmitate oxidation by pent-4-enoic acid was the same whether carnitine was present or not. 9. Acetoacetate formation from saturated fatty acids was inhibited by 0.1mm-cyclopropanecarboxylic acid to a greater extent than their oxidation. 10. The other compounds tested inhibited acetoacetate formation from saturated fatty acids proportionately to the inhibition of oxidation. 11. Possible mechanisms for the inhibition of long-chain fatty acid oxidation by pent-4-enoic acid are discussed. 12. There was a correlation between the ability to inhibit long-chain fatty acid oxidation and hypoglycaemic activity in this series of compounds.

Project description:1. The effects of the hypoglycaemic compound, pent-4-enoic acid, and of four structurally related non-hypoglycaemic compounds (pent-2-enoic acid, pentanoic acid, cyclopropanecarboxylic acid and cyclobutanecarboxylic acid), on glycolysis, glucose oxidation and gluconeogenesis in some rat tissues were determined. 2. None of the compounds at low concentrations inhibited glycolysis by particle-free supernatant fractions from rat liver, skeletal muscle and intestinal mucosa, though there was inhibition by cyclopropanecarboxylic acid and cyclobutanecarboxylic acid at 3mm concentration. 3. Pent-4-enoic inhibited the oxidation of [1-(14)C]palmitate by rat liver slices, but did not increase the oxidation of [U-(14)C]glucose. 4. Pent-4-enoic acid (0.01mm) strongly inhibited gluconeogenesis by rat kidney slices from pyruvate or succinate, but none of the other compounds inhibited significantly at low concentrations. 5. There was also some inhibition of gluconeogenesis in kidney slices from rats injected with pent-4-enoic acid. 6. The mechanism of the hypoglycaemic effect of pent-4-enoic acid is discussed; it is suggested that there is an inhibition of fatty acid and ketone-body oxidation and of gluconeogenesis so that glucose reserves become exhausted, leading to hypoglycaemia. 7. The mechanism of the hypoglycaemic action of pent-4-enoic acid appears to be similar to that of hypoglycin.

Project description:Increases in the production and applications of graphene oxide (GO), coupled with reports of its toxic effects, are raising concerns about its health and ecological risks. To better understand GO's fate and transport in aquatic environments, we investigated its reactivity with three major reactive oxygen species (ROS): HO˙, 1O2, and O2˙-. Second-order degradation rate constants were calculated on the loss of dissolved organic carbon (DOC) and steady-state concentration of individual ROS species. Absolute second-order rate constants were determined by competition kinetics to be 6.24 × 104, 8.65 × 102, and 0.108 mg-C-1 L s-1 for HO˙, 1O2, and O2˙-, respectively. Photoreduced GO products had a similar reactivity to HO˙ as GO, with rate constants comparable to polycyclic aromatic compounds, but about two times higher than dissolved organic matter on a per carbon basis. Reaction with HO˙ resulted in decomposition of GO, with loss of color and formation of photoluminescent products. In contrast, reaction with 1O2 showed no effect on DOC, UV-vis spectra or particle size, while reaction with O2˙- slightly reduced GO. These results demonstrate that interactions with ROS will affect GO's persistence in water and should be considered in exposure assessment or environmental application of GO.

Project description:1. Pent-4-enoyl-CoA and its metabolites penta-2,4-dienoyl-CoA and acryloyl-CoA, as well as n-pentanoyl-CoA, cyclopropanecarbonyl-CoA and cyclobutanecarbonyl-CoA, were examined as substrates or inhibitors of purified enzymes of beta-oxidation in an investigation to locate the site of inhibition of fatty acid oxidation by pent-4-enoate. 2. The reactions of various acyl-CoA derivatives with l-carnitine and of various acyl-l-carnitine derivatives with CoA, catalysed by carnitine acetyltransferase, were investigated and V(max.) and K(m) values were determined. Pent-4-enoyl-CoA and n-pentanoyl-CoA were good substrates, whereas cyclobutanecarbonyl-CoA, cyclopropanecarbonyl-CoA and acryloyl-CoA reacted more slowly. A very slow rate with penta-2,4-dienoyl-CoA was detected. Pent-4-enoyl-l-carnitine, n-pentanoyl-l-carnitine and cyclobutanecarbonyl-l-carnitine were good substrates and cyclopropanecarbonyl-l-carnitine reacted more slowly. 3. Pent-4-enoyl-CoA and n-pentanoyl-CoA were substrates for butyryl-CoA dehydrogenase and for octanoyl-CoA dehydrogenase, and both compounds were equally effective competitive inhibitors of these enzymes with butyryl-CoA or palmitoyl-CoA respectively as substrates. V(max.), K(m) and K(i) values were determined. 4. None of the acyl-CoA derivatives inhibited enoyl-CoA hydratase or 3-hydroxybutyryl-CoA dehydrogenase. Penta-2,4-dienoyl-CoA was a substrate for enoyl-CoA hydratase when the reaction was coupled to that catalysed by 3-hydroxybutyryl-CoA dehydrogenase. 5. In a reconstituted sequence with purified enzymes crotonoyl-CoA was largely converted into acetyl-CoA, and pent-2-enoyl-CoA into acetyl-CoA and propionyl-CoA. Penta-2,4-dienoyl-CoA was slowly converted into acetyl-CoA and acryloyl-CoA. 6. Penta-2,4-dienoyl-CoA, a unique metabolite of pent-4-enoate, was the only compound that specifically inhibited an enzyme of the beta-oxidation sequence, 3-oxoacyl-CoA thiolase. The formation of penta-2,4-dienoyl-CoA could explain the strong inhibition of fatty acid oxidation in intact mitochondria by pent-4-enoate.

Project description:Most phosphoproteomics experiments rely on prefractionation of tryptic digests before online liquid chromatography-mass spectrometry. This study compares the potential and limitations of electrostatic repulsion-hydrophilic interaction chromatography (ERLIC) and anion-exchange chromatography (AEX). At a pH higher than 5, phosphopeptides have two negative charges per residue and are well-retained in AEX. However, peptides with one or two phosphate groups are not separated from peptides with multiple Asp or Glu residues, interfering with the identification of phosphopeptides. At a pH of 2, phosphate residues have just a single negative charge but Asp and Glu are uncharged. This facilitates the separation of phosphopeptides from unmodified acidic peptides. Singly phosphorylated peptides are retained weakly under these conditions, due to electrostatic repulsion, unless hydrophilic interaction is superimposed in the ERLIC mode. Weak anion-exchange (WAX) and strong anion-exchange (SAX) columns were compared, with both peptide standards and a HeLa cell tryptic digest. The SAX column exhibited greater retention at pH 6 than did the WAX column. However, only about 60% as many phosphopeptides were identified with SAX at pH 6 than via ERLIC at pH 2. In one ERLIC run, 12 467 phosphopeptides were identified, including 4233 with more than one phosphate. We conclude that chromatography of phosphopeptides is best performed at low pH in the ERLIC mode. Under those conditions, the performances of the SAX and WAX materials were comparable. The data have been deposited with the ProteomeXchange with identifier PXD001333.

Project description:Antimonato polyoxovanadate (POV) cluster compounds {M(en)3}3[V15Sb6O42(H2O) x ]·nH2O (M = FeII, CoII, NiII and x = 0 or 1) obtained under solvothermal conditions exhibit unusual high water solubility making these compounds promising synthons for generation of new POV structure types. Electrospray ionization mass spectrometry provides evidence (i) for a water molecule encapsulated inside the cavity of a fraction of the spherical cluster shells, (ii) for a post-functionalization in water, namely a slow exchange of VO against Sb2O, (iii) for the inner-phase reactivity of the encapsulated water that is capable of opening an oxo-bridge, and (iv) for a significant acceleration of the 16O/18O exchange reactions of oxygen atoms in the cluster periphery with surrounding H218O, when encapsulated water is present. To the best of our knowledge, this is the first example in polyoxovanadate chemistry for the transduction of inner-phase reactivity of an encapsulated guest molecule into changes in the outer-phase reactivity of the cluster. Magnetic susceptibility measurements reflect the individual contributions of the frustrated {V15} spin polytope and the {M(en)3}2+ complexes, with very weak coupling between these groups.

Project description:1. Increasing the substrate concentration only decreased the inhibition of mitochondrial oxidations by diphenyleneiodonium or by 2,4-dichlorophenyleneiodonium by a small amount. 2. Diphenyleneiodonium and 2,4-dichlorodiphenyleneiodonium lowered the amounts of succinate, citrate and glutamate accumulated in the matrix of mitochondria in the presence of Cl-, but not in its absences. 2,4-Dichlorodiphenyleneiodonium decreased the accumulation of substrates by mitochondria oxidizing glycerol 3-phosphate. 3. Diphenyleneiodonium caused an alkalinization of the medium with an anaerobic suspension of mitochondria, which was only partly reversed by Triton X-100. 4. The rate of proton extrusion by mitochondria oxidizing succinate was not altered by diphenyleneiodonium or by 2,4-dichlorodiphenyleneiodium, although the rate of decay of proton pulses was increased. 5. 2,4-Dichlorodiphenyleneiodonium shifted the pH optimum for succinate oxidation by intact mitochondria from pH 7.2 to 8.0, whereas there was no effect on that of freeze-thawed mitochondria, which was pH 8.0. 6. The concentration of 2,4-dichlorophenyleneiodonium required to inhibit respiration by 50% is less the higher the absolute rate of oxygen uptake. 7. EDTA, but not EGTA [ethanedioxybis(ethylamine)-tetra-acetic acid] increased the inhibition of respiration by diphenyleneiodonium, 2,4-dichlorodiphenyleneiodonium and by tri-n-propyltin. 8. It is concluded that diphenyleneiodonium and 2,4-dichlorodiphenyleneiodonium limit respiration in Cl--containing medium by causing an acidification of the matrix, and that there are pH-sensitive sites in the respiratory chain between NADH and succinate, and between succinate and cytochrome c.

Project description:1. The effects of the hypoglycaemic compound pent-4-enoic acid, and of four structurally related non-hypoglycaemic compounds (pent-2-enoic acid, pentanoic acid, cyclopropanecarboxylic acid and cyclobutanecarboxylic acid), on several reactions in rat liver mitochondria were determined. 2. The use of manometric techniques for measurements of oxidations and of phosphorylation is critically discussed. 3. Pent-4-enoic acid and pentanoic acid uncoupled oxidative phosphorylation at low concentrations, but usually by not more than about 50%. 4. All the compounds, except cyclobutanecarboxylic acid, strongly inhibited the oxidation of pyruvate and 2-oxoglutarate, but the oxidations of succinate, citrate and 3-hydroxybutyrate were not strongly inhibited. 5. All the compounds, except cyclobutanecarboxylic acid, inhibited decarboxylation of [1-(14)C]pyruvate with ferricyanide as electron acceptor. 6. All the compounds, except pent-2-enoic acid, caused mitochondrial swelling after a time-lag.

Project description:1. The synthesis of pent-4-enoyl-l-carnitine, cyclopropanecarbonyl-l-carnitine and cyclobutanecarbonyl-l-carnitine is described. 2. Pent-4-enoate strongly inhibits palmitoyl-l-carnitine oxidation in coupled but not in uncoupled mitochondria. Pent-4-enoyl-l-carnitine strongly inhibits palmitoyl-l-carnitine oxidation in uncoupled mitochondria. Prior intramitochondrial formation of pent-4-enoyl-CoA is therefore necessary for inhibition. 3. There was a small self-limiting pulse of oxidation of pent-4-enoyl-l-carnitine during which the ability to inhibit the oxidation of subsequently added palmitoyl-l-carnitine developed. 4. Pent-4-enoate and pent-4-enoyl-l-carnitine are equally effective inhibitors of the oxidation of all even-chain acylcarnitines of chain length C(4)-C(16). Pent-4-enoyl-l-carnitine also inhibits the oxidation of pyruvate and of 2-oxoglutarate. 5. Pent-4-enoate strongly inhibits the oxidation of palmitate but not that of octanoate. This is presumably due to competition between octanoate and pent-4-enoate for medium-chain acyl-CoA ligase. 6. There was less inhibition of the oxidation of pyruvate by pent-4-enoyl-l-carnitine, and of palmitoyl-l-carnitine by cyclopropanecarbonyl-l-carnitine, after pre-incubation with 10mm-arsenate. This suggests that these inhibitions were caused either by depletion of free CoA or by increase of acyl-CoA concentrations, since arsenate deacylates intramitochondrial acyl-CoA. There was little effect on the inhibition of palmitoyl-l-carnitine oxidation by pent-4-enoyl-l-carnitine. 7. Penta-2,4-dienoate strongly inhibited palmitoyl-l-carnitine oxidation in coupled mitochondria; acrylate only inhibited slightly. 8. Pent-4-enoate (0.1mm) caused a rapid and almost complete decrease in free CoA and a large increase in acid-soluble acyl-CoA when incubated with coupled mitochondria. Cyclopropanecarboxylate caused a similar decrease in CoA, with an equivalent rise in acid-soluble acyl-CoA concentrations. n-Pentanoate caused extensive lowering of CoA and a large increase in acid-soluble acyl-CoA and acetyl-CoA concentrations. Octanoate caused a 50% lowering of CoA and an increase in acid-soluble acyl-CoA and acetyl-CoA concentrations. 9. Cyclopropanecarboxylate and n-pentanoate were less potent inhibitors of palmitate oxidation than was pent-4-enoate. 10. It is concluded that pent-4-enoate causes a specific inhibition of beta-oxidation after the formation intramitochondrially of its metabolites.

Project description:Copper cobalt oxide nanoparticles (CCO NPs) were synthesized as an oxygen evolution electrocatalyst via a simple co-precipitation method, with the composition being controlled by altering the precursor ratio to 1:1, 1:2, and 1:3 (Cu:Co) to investigate the effects of composition changes. The effect of the ratio of Cu2+/Co3+ and the degree of oxidation during the co-precipitation and annealing steps on the crystal structure, morphology, and electrocatalytic properties of the produced CCO NPs were studied. The CCO1:2 electrode exhibited an outstanding performance and high stability owing to the suitable electrochemical kinetics, which was provided by the presence of sufficient Co3+ as active sites for oxygen evolution and the uniform sizes of the NPs in the half cell. Furthermore, single cell tests were performed to confirm the possibility of using the synthesized electrocatalyst in a practical water splitting system. The CCO1:2 electrocatalyst was used as an anode to develop an anion exchange membrane water electrolyzer (AEMWE) cell. The full cell showed stable hydrogen production for 100 h with an energetic efficiency of >71%. In addition, it was possible to mass produce the uniform, highly active electrocatalyst for such applications through the co-precipitation method.