A fluorometric assay of acyl-CoA oxidase activity by a coupled peroxidatic reaction: elimination of interfering side reactions

L-Carnosine Stimulation of Coenzyme Q10 Biosynthesis Promotes Improved Mitochondrial Function and Decreases Hepatic Steatosis in Diabetic Conditions

Mitochondrial dysfunction in type 2 diabetes leads to oxidative stress, which drives disease progression and diabetes complications. L-carnosine, an endogenous dipeptide, improves metabolic control, wound healing and kidney function in animal models of type 2 diabetes. Coenzyme Q (CoQ), a component of the mitochondrial electron transport chain, possesses similar protective effects on diabetes complications. We aimed to study the effect of carnosine on CoQ, and assess any synergistic effects of carnosine and CoQ on improved mitochondrial function in a mouse model of type 2 diabetes. Carnosine enhanced CoQ gene expression and increased hepatic CoQ biosynthesis in db/db mice, a type 2 diabetes model. Co-administration of Carnosine and CoQ improved mitochondrial function, lowered ROS formation and reduced signs of oxidative stress. Our work suggests that carnosine exerts beneficial effects on hepatic CoQ synthesis and when combined with CoQ, improves mitochondrial function and cellular redox balance in the liver of diabetic mice. (4) Conclusions: L-carnosine has beneficial effects on oxidative stress both alone and in combination with CoQ on hepatic mitochondrial function in an obese type 2 diabetes mouse model.

Off to a slow start: Analyzing lag phases and accelerating rates in steady-state enzyme kinetics

Steady-state enzyme kinetics typically relies on the measurement of 'initial rates', obtained when the substrate is not significantly consumed and the amount of product formed is negligible. Although initial rates are usually faster than those measured later in the reaction time-course, sometimes the speed of the reaction appears instead to increase with time, reaching a steady level only after an initial delay or 'lag phase'. This behavior needs to be interpreted by the experimentalists. To assist interpretation, this article analyzes the many reasons why, during an enzyme assay, the observed rate can be slow in the beginning and then progressively accelerate. The possible causes range from trivial artifacts to instances in which deeper mechanistic or biophysical factors are at play. We provide practical examples for most of these causes, based firstly on experiments conducted with ornithine δ-aminotransferase and with other pyridoxal-phosphate dependent enzymes that have been studied in our laboratory. On the side to this survey, we provide evidence that the product of the ornithine δ-aminotransferase reaction, glutamate 5-semialdehyde, cyclizes spontaneously to pyrroline 5-carboxylate with a rate constant greater than 3 s^-1.

Biochemical effect evaluation of perfluorooctane sulfonic acid-contaminated wood mice (Apodemus sylvaticus)

Wood mice (Apodemus sylvaticus) were captured at Blokkersdijk, a nature reserve in the immediate vicinity of a fluorochemical plant in Antwerp, Belgium, and at Galgenweel, 3 kilometers farther away. The liver perfluorooctane sulfonic acid (PFOS) concentrations in the Blokkersdijk mice were extremely high (0.47-178.55 micro g/g wet weight). Perfluorononanoic, perfluorodecanoic, perfluoroundecanoic, and perfluorododecanoic acids were found sporadically in the liver tissue of the Blokkersdijk mice. The liver PFOS concentrations at Galgenweel were significantly lower than those at Blokkersdijk (0.14-1.11 micro g/g wet weight). Further results suggest sex independence of the liver PFOS levels, increased levels of PFOS bioaccumulation in older mice, and maternal PFOS transfer to the young. Several liver end points were significantly elevated in the Blokkersdijk mice: liver weight, relative liver weight, peroxisomal beta-oxidation activity, microsomal lipid peroxidation level, and mitochondrial fraction protein content. For the mitochondrial fraction catalase activity, no significant difference between locations was found. The liver weight, relative liver weight, and liver microsomal lipid peroxidation level increased significantly with the liver PFOS concentration. No indications for PFOS-mediated effects on the serum triglyceride, cholesterol, or potassium levels were obtained. The liver PFOS concentration was negatively related to the serum alanine aminotransferase activity.

Detailed analytical subcellular fractionation of non-pregnant porcine corpus luteum reveals peroxisomes of normal size and significant UDP-glucuronosyltransferase activity in the high-speed supernatant

A detailed subfractionation of the non-pregnant porcine corpus luteum (CL) was performed employing differential centrifugation. Marker enzyme assays (i.e., lactate dehydrogenase for the cytosol, NADPH-cytochrome P450 reductase for the endoplasmatic reticulum, catalase (CAT) for peroxisomes, glutamate dehydrogenase for the mitochondrial matrix and acid phosphatase for lysosomes) in all subfractions obtained exhibited a pattern of distribution similar to that observed with rat liver. These subfractions should be useful in connection with many types of future studies. In disagreement with previous biochemical and morphological studies, peroxisomes (identified on the basis of catalase activity and by Western blotting of catalase and of the major peroxisomal membrane protein (PMP-70)) sedimented together with mitochondria (i.e., at 5000 x g(av) for 10 min) and not in the post-mitochondrial fraction prepared at 30,000 x g(av) for 20 min by Peterson and Stevensson. No other classical peroxisomal enzymes were detectable in the porcine ovary, raising questions concerning the function of peroxisomes in this organ. Furthermore, UDP-glucuronosyltransferase (UGT), generally considered to be an integral membrane protein anchored in the endoplasmatic reticulum, was recovered in both the cytosolic (i.e., the supernatant after centrifugation at 50,000 x g(av) for 1h) and the microsomal fraction of the porcine corpus luteum, even upon further centrifugation of the former. In contrast, UGT sediments exclusively in the microsomal fraction upon subfractionation of the liver and ovary from rat.

Evaluation of the toxicological effects of perfluorooctane sulfonic acid in the common carp (Cyprinus carpio)

In the present study we evaluated the toxicological effects of a scarcely documented environmental pollutant, perfluorooctane sulfonic acid (PFOS), on selected biochemical endpoints in the common carp, Cyprinus carpio. Juvenile organisms were exposed to PFOS through a single intraperitoneal injection (liver concentrations ranging from 16 to 864 ng/g after 5 days of exposure) and after 1 and 5 days effects were assessed in liver and serum of the exposed organisms. The investigation of the hepatotoxicity of PFOS included the determination of the peroxisome proliferating potential (peroxisomal palmitoyl CoA oxidase and catalase activity) and the compounds influence on the average DNA basepair length (ABPL) by agarose gel electrophoresis. Total antioxidant activity (TAA), cholesterol and triglyceride levels were monitored in the serum. After 1 day of exposure the ABPL was significantly increased in the 270 and 864 ng/g treatment groups. After 5 days of exposure significant increases relative to the control were observed for the 16, 270 and 864 ng/g treatment groups. Enzyme leakage from the liver was investigated by measurement of alanine aminotransferase (ALT) and aspartate aminotransferase (AST) activities in the serum. At 561, 670 and 864 ng/g PFOS a significant increase in serum ALT activity became apparent after 5 days of exposure with values ranging from 159 to 407% relative to the control. For serum AST activity a significant increase for the 864 ng/g treatment group was observed with a value of 112% relative to the control. Determination of the polymorphonuclear leukocyte migration into liver tissue as assessed through myeloperoxidase (MPO) activity in liver, was used as an indicator for inflammation. It appeared that inflammation was not involved in the observed membranous enzyme leakage for the 561, 670 and 864 ng/g PFOS treatment groups. The results of this study suggest that PFOS induces inflammation-independent enzyme leakage through liver cell membranes that might be related to cell necrosis. Furthermore, results show that PFOS does not significantly affects serum antioxidant levels nor does it clearly induce peroxisome proliferation in carp. This study also points out that PFOS might interfere with homeostasis of the DNA metabolism. The results of these biochemical analyses were used to perform an initial hazard assessment study indicating that PFOS levels observed in tissues of wildlife populations could induce a clear rise in serum transaminase levels indicative for disruption of hepatocyte membrane integrity.

A continuous fluorescence assay for sulfhydryl oxidase

Flavin-dependent sulfhydryl oxidases represent a newly discovered family of proteins with a range of cellular locations and putative roles. The avian and mammalian proteins can catalyze the direct oxidation of protein cysteine residues to disulfides with the reduction of dioxygen to hydrogen peroxide. Although thiols interfere with the peroxidase-mediated quantitation of hydrogen peroxide, a very sensitive, continuous fluorescence assay of the sulfhydryl oxidases can be devised with careful selection of thiol substrate concentration and fluorogen. Purified avian enzyme (or crude chicken egg white) was used for these experiments. Homovanillic acid was found to be a suitable fluorogen in the presence of 300 microM thiols from either dithiothreitol or reduced ribonuclease A. High concentrations of horseradish peroxidase minimized the effects of contaminating catalase in biological samples. Using fluorescence microcells, the assay could detect 15fmol of avian sulfhydryl oxidase and the rates were linearly dependent on enzyme concentration up to 6nM. Aspects of the interaction among thiols, homovanillic acid, and peroxidase are discussed which limit the sensitivity of the assay and require that care is exercised in the application of this new procedure. Finally, the assay is used to show that there is sulfhydryl oxidase activity in a number of secretory fluids including human tears.

Eicosapentaenoic acid inhibits the growth of liver preneoplastic lesions and alters membrane phospholipid composition and peroxisomal beta-oxidation

The purpose of this study was to determine whether individual administration of highly purified eicosapentaenoic acid (EPA), one of the main components of the n-3 polyunsaturated fatty acid family, would alter the growth of focal lesions during hepatocarcinogenesis. The protocol used to induce chemical carcinogenesis in liver was the Solt-Farber model (diethylnitrosamine as initiator and 2-acetylaminofluorene and carbon tetrachloride associated with partial hepatectomy as promoters). Proliferative lesions were quantified with the histochemical marker gamma-glutamyltranspeptidase at partial hepatectomy and at sacrifice. The number and size of the gamma-glutamyltranspeptidase-positive foci observed were significantly lower in rats supplemented with EPA. Fatty acid treatment increased EPA and docosapentaenoic acid content in membrane total phospholipids, in phosphatidylethanolamine, and in phosphatidylcholine. The content of arachidonic acid decreased significantly only in total phospholipids and in phosphatidylethanolamine. Fatty acid content of phosphatidylinositol was not modified. Moreover, we observed an increase in the activity of palmitoyl-CoA oxidase, the limiting enzyme of peroxisomal beta-oxidation, the preferential metabolic pathway of n-3 polyunsaturated fatty acid. Conversely, unmodified levels of alpha-tocopherol and unchanged production of lipid peroxidation products (malondialdehyde) were observed. These results suggest that the EPA inhibitory effect on preneoplastic foci development may be related to alteration of fatty acid composition in phospholipid classes and to enhancement of peroxisomal beta-oxidation and H2O2 production.

Induction of endogenous coenzyme Q biosynthesis by administration of peroxisomal inducers

A large number of chemical compounds have been identified which cause peroxisomal proliferation and induce a number of enzymes, mainly those participating in lipid metabolism. Administration of these drugs/chemicals to rats increased coenzyme Q levels in the blood and most of the organs. Levels were raised in all cellular membranes of such organs. The extent of induction of this lipid was 8-fold in young animals but decreased during aging and was absent at 1.5 year of age. One of the regulating factors of the mevalonate pathway is farnesol, which is produced by dephosphorylation of farnesyl-PP and eliminated by phosphorylation including two kinases. Future research will involve a search for modified intermediary metabolites, which increase coenzyme Q synthesis and thereby efficiently elevate the level of this lipid in conditions of deficiency.

Elevation of ubiquinone content by peroxisomal inducers in rat liver during aging

The effect of di(2-ethylhexyl)phthalate (DEHP) on the induction of peroxisomes and the content of ubiquinone in the liver was studied in rats between 25 and 496 days of age. During this period, peroxisomal beta-oxidation of fatty acids was greatly decreased but it could be induced many-fold in all ages. The ubiquinone (UQ) content was increased upon induction 6-fold in the first weeks of life, but the extent of this elevation continuously narrowed and no induction could be observed in the oldest animals, even after prolonged treatment with the plasticizer. In contrast, the treatment decreased the amount of liver cholesterol in all age groups. Treatment with this peroxisomal inducer increased the biosynthesis of UQ while the breakdown rate was found to be unaffected, as the half-life of this lipid was 103 and 106 h in control and treated rats, respectively. These results indicate that treatment with peroxisomal inducers increases the liver UQ content by increasing the rate of biosynthesis and that this effect is not apparent in aged rats.

Hepatic peroxisome proliferation in vitamin A-deficient mice without a simultaneous increase in peroxisomal acyl-CoA oxidase activity

Vitamin A-adequate and vitamin A-deficient C57B1/6 mice were treated for ten days with 0.02% (w/w) perfluorooctanoic acid (PFOA) in their diet. Treated vitamin A- adequate and -deficient mice demonstrated approximately the same increases in liver somatic index (g liver/g body weight) (somewhat more than 2-fold) and mitochondrial protein content (5-fold). PFOA treatment resulted in a 26-fold increase in hepatic peroxisomal lauroyl-CoA oxidase activity in vitamin A-adequate mice, whereas the same activity was unchanged in vitamin A-deficient mice. Vitamin deficiency itself caused a 3- to 4- fold increase in cytosolic catalase activity and a smaller increase in the activity of microsomal cytochrome P-450 IVA (lauric acid omega- and omega-1 hydroxylase) in this same organ. The induction of the activities of these enzymes was less prominent in vitamin A-deficient mice compared with the effect caused by PFOA in vitamin A-adequate mice, resulting in approximately the same maximal values for these parameters in both groups (i.e approx 21 micromol/g liver - min and 350 nanomol/g liver - min, respectively). A 70 kDa protein, presumable the multifunction protein, was shown by Commassie blue staining of SDS-polyacrylamide gels and by immunoblotting (with antibodies towards the multifunctional protein) to be induced to approximately the same degree in vitamin A-adequate and deficient mice. A morphometric study revealed that PFOA causes the same extent of hepatic peroxisome proliferation in vitamin A-deficient as in vitamin A-adequate mice. The possibility that PFOA exerts its effect in vivo through at least two different mechanisms is discussed.

Synergistic induction of acyl-CoA oxidase activity, an indicator of peroxisome proliferation, by arachidonic acid and retinoic acid in Morris hepatoma 7800C1 cells

Morris hepatoma 7800C1 cells (a Wistar rat cell line) were exposed to 100 microM arachidonic acid in the medium for seven days. This treatment resulted in 150% and 60% increases (above control activities) in acyl-CoA oxidase (which catalyzes the first step in peroxisomal beta-oxidation) and catalase activities, respectively. Arachidonic acid (C20:4) can be metabolized to 20- and 19-hydroxy-arachidonic acid by cytochrome P-450IVA and it was shown that our cells are capable of forming 20-hydroxyarachidonic acid. However, 20-hydroxyarachidonic acid (0.1-0.8 microM, 4 days) had no effects on lauroyl-CoA oxidase and catalase activities in Morris hepatoma cells. Treatment of 7800C1 cells with 100 microM all-trans-retinoic acid resulted in inductions of catalase (160% above the control activity) and carnitine acetyltransferase (140% above the control activity) activities. The activity of lauroyl-CoA oxidase was often, but not always, slightly induced by treatment with all-trans-retinoic acid. When all-trans-retinoic acid was administered together with arachidonic acid, these two compounds had a synergistic effect on the induction of acyl-CoA oxidase activity (almost 700% above the control activity). However, treatment of Morris hepatoma cells with the man-made peroxisome proliferator, perfluorooctanoic acid, together with all-trans-retinoic acid did not result in any synergistic effect on this same enzyme activity. In summary, this study (1) corroborates findings from transfection experiments indicating that the heterodimer PPAR-RXR alpha activates transcription of the acyl-CoA oxidase gene using the Morris hepatoma cell line; (2) shows that arachidonic acid induces the activity of lauroyl-CoA oxidase; (3) suggests that transcription of the catalase gene is not regulated by a PPAR-RXR alpha heterodimer in this system; and (4) demonstrates that peroxisome proliferation in Morris hepatoma cells by perfluorooctanoic acid is not as dependent on the level of retinoic acid as is the same process caused by arachidonic acid.

2-Hydroxyphytanic acid oxidase activity in rat and human liver and its deficiency in the Zellweger syndrome

Phytanic acid is a saturated, branched-chain fatty acid which as a consequence of the presence of a methyl group at the 3-position cannot be degraded by beta-oxidation. Instead, phytanic acid first undergoes alpha-oxidation to yield pristanic acid which can be degraded by beta-oxidation. The structure of the alpha-oxidation pathway and its subcellular localization has remained an enigma although there is convincing evidence that 2-hydroxyphytanic acid is an obligatory intermediate. We have now studied the degradation of 2-hydroxyphytanic acid in both rat and human liver. The results show that 2-hydroxyphytanic acid is converted to 2-ketophytanic acid in homogenates of rat as well as human liver. Detailed studies in rat liver showed that the enzyme involved is localized in peroxisomes accepting molecular oxygen as second substrate and producing H2O2. 2-Ketophytanic acid formation from 2-hydroxyphytanic acid was found to be strongly deficient in liver samples from Zellweger patients which lack morphologically distinguishable peroxisomes. The latter results not only provide an explanation for the elevated levels of 2-hydroxyphytanic acid in Zellweger patients but also suggest that the subcellular localization of 2-hydroxyphytanic acid dehydrogenation is identical in rat and man, i.e., in peroxisomes.

Permeability properties of peroxisomes in digitonin-permeabilized rat hepatocytes. Evidence for free permeability towards a variety of substrates

In order to investigate the permeability properties of rat-liver peroxisomes in situ, we selectively permeabilized hepatocytes with digitonin in a medium mimicking the cytosol. This system permitted us to study the latency of peroxisomal oxidases by means of measurement of their activities in permeabilized compared to disrupted hepatocytes. The activity of peroxisomal oxidases was studied using three different methods: (1) measurement of the oxidase-mediated production of H2O2 in a system containing homovanillic acid, horseradish peroxidase and azide; (2) measurement of the rate of substrate utilization or product formation; (3) measurement of the production of H2O2 via the peroxidative action of catalase in the presence of an excess of methanol. The results obtained depended on which system was used to measure the activity of the different oxidases. Our observations lead us to conclude that method 1 cannot be used for latency studies, whereas methods 2 and 3 are suitable under defined circumstances. Based on the results of methods 2 and 3, we conclude that urate oxidase, L-alpha-hydroxyacid oxidase A and D-amino acid oxidase show no structure-linked latency in digitonin-permeabilized hepatocytes, suggesting that the substrates for these enzymes permeate freely through the peroxisomal membrane.