Cell-free synthesis of the enzymes of peroxisomal beta-oxidation

Three enzymes of peroxisomal β-oxidation of rat liver were synthesized in a cell-free protein-synthesizing system derived from rabbit reticulocyte lysate. The $\text{in}\text{vitro}$ products of acyl-CoA oxidase and enoyl-CoA hydratase-3-hydroxyacyl-CoA dehydrogenase multifunctional protein were similar in size to or slightly larger than the subunit of the respective mature enzymes. The $\text{in}\text{vitro}$ product of peroxisomal 3-ketoacyl-CoA thiolase was about 3,000 daltons larger than the mature subunit. The hepatic levels of translatable mRNAs coding for these three enzymes were about 10 times higher in rats fed a di(2-ethylhexyl)phthalate-containing diet than in control animals.     

Synthesis of quinolinate from D-aspartate in the mammalian liver-Escherichia coli quinolinate synthetase system.

Two proteins (A and B) from $\text{Escherichia coli}$ are required for the synthesis of the NAD precursor quinolinate from aspartate and dihydroxyacetone phosphate. Mammalian liver contains a FAD linked protein which replaces $\text{E. coli}$ B protein for quinolinate synthesis. D-aspartic acid but not L-aspartic acid is a substrate for quinolinic acid synthesis in a system composed of the B protein replacing activity of mammalian liver and $\text{E. coli}$ A protein. In contrast the $\text{E. coli}$ B protein-$\text{E. coli}$ A protein quinolinate synthetase system requires L-aspartic acid as substrate. The previous report that L-aspartate was a substrate in the liver-$\text{E. coli}$ system was due to contamination of commercially available [¹⁴C]L-aspartate with [¹⁴C]D-aspartate. These and other observations suggest that liver B protein is D-aspartate oxidase and $\text{E. coli}$ B protein is L-aspartate oxidase.     

Acyl-CoA oxidase activity and peroxisomal fatty acid oxidation in rat tissues

Acyl-CoA oxidase, the first enzyme of the peroxisomal β-oxidation, was proved to be rate-limiting for this process in homogenates of rat liver, kidney, adrenal gland, heart and skeletal muscle. Acyl-CoA oxidase activity, based on H₂O₂-dependent leuko-dichlorofluorescein oxidation in tissue extract, was compared with radiochemically assayed peroxisomal β-oxidation rates. Dichlorofluorescein production was a valid measure of peroxisomal fatty acid oxidation only in liver and kidney, but not in adrenal gland, heart or skeletal muscle. Production of ¹⁴C-labeled acid-soluble products from 1-¹⁴C-labeled fatty acids in the presence of antimycin-rotenone appears to be a more accurate and sensitive estimate of peroxisomal β-oxidation than the acyl-CoA oxidase activity on base of H₂O₂ production. Chain-length specificity of acyl-CoA oxidase changed with the acyl-CoA concentrations used. Below 80 μM, palmitoyl-CoA showed the highest activity of the measured substrates in rat liver extract. No indications were obtained for the presence in rat liver of more forms of acyl-CoA oxidase with different chain-length specificity.     

Intrinsic enoyl-CoA isomerase activity of rat acyl-CoA oxidase I

Rat peroxisomal acyl-CoA oxidase I is a key enzyme for the beta-oxidation of fatty acids, and the deficiency of this enzyme in patient has been previously reported. It was found that rat acyl-CoA oxidase I has intrinsic enoyl-CoA isomerase activity, which was confirmed using incubation followed with HPLC analysis in this study. Various 3-enoyl-CoA substrates with cis or trans configuration were synthesized and used in the study of enzyme substrate specificity. The isomerase activity of the enzyme was characterized through studies of kinetics, pH dependence, and enzyme inhibition. Most k(cat)/K(M) values of rat peroxisomal acyl-CoA oxidase I for isomerization reaction are comparable with those of authentic rat liver peroxisomal Delta(3)-Delta(2)-enoyl-CoA isomerase and rat liver peroxisomal multifunctional enzyme 1 when hexenoyl-CoA and octenoyl-CoA with cis- or trans-configuration were used as substrate. Glu421 was found to be the catalytic residue for both oxidase and isomerase activities of the enzyme. The isomerase activity of rat peroxisomal acyl-CoA oxidase I is probably due to a spontaneous process driven by thermodynamic equilibrium with formation of a conjugated structure after deprotonation of substrate alpha-proton. The energy level of transition state may be lowered by a stable dienolate intermediate, which gain further stabilization via charge transfer with electron-deficient FAD cofactor of the enzyme.     

Acyl-CoA oxidase 1 from Arabidopsis thaliana. Structure of a key enzyme in plant lipid metabolism

The peroxisomal acyl-CoA oxidase family plays an essential role in lipid metabolism by catalyzing the conversion of acyl-CoA into trans-2-enoyl-CoA during fatty acid beta-oxidation. Here, we report the X-ray structure of the FAD-containing Arabidopsis thaliana acyl-CoA oxidase 1 (ACX1), the first three-dimensional structure of a plant acyl-CoA oxidase. Like other acyl-CoA oxidases, the enzyme is a dimer and it has a fold resembling that of mammalian acyl-CoA oxidase. A comparative analysis including mammalian acyl-CoA oxidase and the related tetrameric mitochondrial acyl-CoA dehydrogenases reveals a substrate-binding architecture that explains the observed preference for long-chained, mono-unsaturated substrates in ACX1. Two anions are found at the ACX1 dimer interface and for the first time the presence of a disulfide bridge in a peroxisomal protein has been observed. The functional differences between the peroxisomal acyl-CoA oxidases and the mitochondrial acyl-CoA dehydrogenases are attributed to structural differences in the FAD environments.     

Assay for l-pipecolate oxidase activity in human liver: detection of enzyme deficiency in hyperpipecolic acidaemia

A direct assay method is described for l-pipecolate oxidase. The assay uses NaHSO₃ to trap the $\text{L}\text{-α-amino[}{}^3\text{H]adipate}$δ-semialdehyde (AAS) formed as a direct reaction product of l-pipecolate oxidase from l-[³H]pipecolic acid. The adduct so formed was separated from the substrate on Dowex 50 (H⁺) column. The product was identified as [³H]AAS by amino acid analysis after breaking down the adduct by boiling under acidic conditions. The assay is simpler and more specific than fluorometric methods; it is also more sensitive; requiring at most 16 μg of liver peroxisome-enriched protein per assay. We have used this assay procedure to detect l-pipecolate oxidase in skin fibroblasts obtained from a control subject and from patients of hyperpipecolic acidaemia and Zellweger syndrome and found that this enzyme activity is present in the control, but absent or decreased in the patients with the peroxisomal disorders.     

Detection of peroxisomal fatty acyl-coenzyme A oxidase activity.

It has been postulated that the peroxisomal fatty acid-oxidizing system [Lazarow & de Duve (1976) Proc. Natl. Acad. Sci. U.S.A. 73, 2043--2046; Lazarow (1978) J. Biol. Chem. 253, 1522--1528] resembles that of mitochondria, except for the first oxidative reaction. In this step, O2 would be directly reduced to H2O2 by an oxidase. Two specific procedures developed to detect the activity of the characteristic enzyme fatty acyl-CoA oxidase are presented, namely polarographic detection of palmitoyl-CoA-dependent cyanide-insensitive O2 consumption and palmitoyl-CoA-dependent H2O2 generation coupled to the peroxidation of methanol in an antimycin A-insensitive reaction. Fatty acyl-CoA oxidase activity is stimulated by FAD, which supports the flavoprotein nature postulated for this enzyme. Its activity increases 7-fold per g wet wt. of liver in rats treated with nafenopin, a hypolipidaemic drug. Subcellular fractionation of livers from normal and nafenopin-treated animals provides evidence for its peroxisomal localization. The stoicheiometry for palmitoyl-CoA-dependent O2 consumption, H2O2 generation and NAD+ reduction is 1 : 1 : 1. This suggests that fatty acyl-CoA oxidase is the rate-limiting enzyme of the peroxisomal fatty acid-oxidizing system.     

In vitro synthesis of monoamine oxidase of rat liver outer mitochondrial membrane

Monoamine oxidase, an intrinsic protein of outer mitochondrial membrane, was purified from bovine liver and rabbit antibody against the enzyme was prepared. The antibody could react with the monoamine oxidase of rat liver mitochondria. When rat liver RNA was translated $\text{in}\text{vitro}$ using rabbit reticulocyte lysate and monoamine oxidase peptide in the translation products was immunoprecipitated by the antibody, the peptide was detected in the products programmed by the messenger RNA's from total and free polysomes but not that from bound polysomes. The enzyme synthesized $\text{in}\text{vitro}$ had the same apparent molecular size as the mature protein in outer mitochondrial membrane.     

Covalently bound flavin as prosthetic group of choline oxidase.

Highly purified choline oxidase of $\text{Arthrobacter globiformis}$ fluoresced as a yellow band on SDS gel in 7% acetic acid. The absorption spectrum of the enzyme showed marked hypsochromic shift of the second absorption band. Aminoacyl flavin obtained from this enzyme was identified with 8α-[N(3)-histidyl]FAD.     

Occurrence in mammalian liver of a protein which replaces the B protein of E. coli quinolinate synthetase.

$\text{Escherichia coli}$ contains two proteins (A and B) which together convert dihydroxyacetone phosphate and aspartate to quinolinic acid, a precursor of NAD. Although mammalian liver homogenate does not catalyze this reaction it contains a protein which will replace the B protein of the $\text{E. coli}$ system. The behavior of the liver protein on Sephadex G-75 suggests it is much smaller than the $\text{E. coli}$ B protein. Liver B protein also appears to contain tightly bound FAD while FAD is easily removed from the $\text{E. coli}$ B protein. The pH optimum for the hybrid system $\text{E. coli}$ A protein-liver B protein is 9.0 while in the pure $\text{E. coli}$ system the optimum is pH 8.0. The hybrid system is inhibited by NAD to the same extent as the pure $\text{E. coli}$ system.     

Evidence for ceruloplasmin as a copper transport protein.

Rats fed a copper-deficient diet for eight weeks showed a large decrease in cytochrome $\text{c}$ oxidase in heart, spleen, liver, lung, and pancreas but no significant change in kidney and brain. Three injections of human or rat ceruloplasmin over a five day period greatly increased cytochrome $\text{c}$ oxidase activity in spleen, liver, heart and lung. Rats receiving CuCl₂, Cu-histidine, and Cu-albumin produced a smaller and slower increase in cytochrome $\text{c}$ oxidase compared to ceruloplasmin treated animals. In Cu-histidine treated rats, the increase in enzyme activity did not occur until after the plasma ceruloplasmin level reached a maximal value. It is concluded that ceruloplasmin functions as a primary copper transport protein from which copper atoms are transferred to cytochrome $\text{c}$ oxidase and probably other copper containing proteins.     

Separate peroxisomal oxidases for fatty acyl-CoAs and trihydroxycoprostanoyl-CoA in human liver

Fatty acyl-CoAs as well as the CoA esters of the bile acid intermediates di- and trihydroxycoprostanic acids are beta-oxidized in peroxisomes. The first reaction of peroxisomal beta-oxidation is catalyzed by acyl-CoA oxidase. We recently described the presence of two fatty acyl-CoA oxidases plus a trihydroxycoprostanoyl-CoA oxidase in rat liver peroxisomes (Schepers, L., P. P. Van Veldhoven, M. Casteels, H. J. Eyssen, and G. P. Mannaerts. 1990. J. Biol. Chem. 265: 5242-5246). We have now developed methods for the measurement of palmitoyl-CoA oxidase and trihydroxycoprostanoyl-CoA oxidase in human liver. The activities were measured in livers from controls and from three patients with peroxisomopathies. In addition, the oxidase activities were partially purified from control livers by ammonium sulfate fractionation and heat treatment, and the partially purified enzyme preparation was subjected to chromatofocusing, hydroxylapatite chromatography, and gel filtration. In earlier experiments this allowed for the separation of the three rat liver oxidases. The results show that human liver, as rat liver, contains a separate trihydroxycoprostanoyl-CoA oxidase. In contrast to the situation in rat liver, no conclusive evidence was obtained for the presence of two fatty acyl-CoA oxidases in human liver. Our results explain why bile acid metabolism is normal in acyl-CoA oxidase deficiency, despite a severely disturbed peroxisomal fatty acid oxidation and perhaps also why, in a number of other cases of peroxisomopathy, di- and trihydroxycoprostanic acids are excreted despite a normal peroxisomal fatty acid metabolism.     

Reduced levels of peroxisomal enzymes in the kidney of the genetically obese (ob/ob) mouse. Contrast with liver

Kidney post-nuclear supernatants from genetically lean and obese mice were subjected to subcellular fractionation by dual centrifugation through sucrose gradients in B XIV zonal rotors. Considerable purification of peroxisomes was achieved which allowed the demonstration of acyl-CoA beta-oxidation enzymes and carnitine acyltransferases in these organelles. Comparison of kidney peroxisome-enriched fractions from obese and lean mice indicated a likely relative depression in beta-oxidation enzymes in the obese animal. Measurement of catalase, acyl-CoA oxidase and carnitine octanoyltransferase in whole homogenate of liver and kidney of obese and lean mice revealed significantly reduced levels (to approximately 2/3) of these peroxisomal enzymes in the kidney of ob/ob mice. In contrast the specific activity of catalase and acyl-CoA oxidase was significantly raised in the liver of obese mice.     

Acyl-CoA synthetase and the peroxisomal enzymes of beta-oxidation in human liver. Quantitative analysis of their subcellular localization.

The presence of acyl-CoA synthetase (EC 6.2.1.3) in peroxisomes and the subcellular distribution of beta-oxidation enzymes in human liver were investigated by using a single-step fractionation method of whole liver homogenates in metrizamide continuous density gradients and a novel procedure of computer analysis of results. Peroxisomes were found to contain 16% of the liver palmitoyl-CoA synthetase activity, and 21% and 60% of the enzyme activity was localized in mitochondria and microsomal fractions respectively. Fatty acyl-CoA oxidase was localized exclusively in peroxisomes, confirming previous results. Human liver peroxisomes were found to contribute 13%, 17% and 11% of the liver activities of crotonase, beta-hydroxyacyl-CoA dehydrogenase and thiolase respectively. The absolute activities found in peroxisomes for the enzymes investigated suggest that in human liver fatty acyl-CoA oxidase is the rate-limiting enzyme of the peroxisomal beta-oxidation pathway, when palmitic acid is the substrate.     

Identification of a catalase-negative sub-population of peroxisomes induced in mouse liver by clofibrate.

The peroxisomal compartment in mouse liver was investigated using rate sedimentation of liver subfractions on sucrose density gradients. Treatment of mice with clofibrate, a hypolipidemic agent and peroxisome proliferator, resulted in the formation of small particles which were devoid of catalase and urate oxidase, but which were identified as peroxisomal on the basis of content of the clofibrate-induced peroxisomal beta-oxidation enzymes (fatty acyl-CoA oxidase, hydratase/dehydrogenase bifunctional protein, and thiolase) and the 68 kDa peroxisomal integral membrane protein. Immunoelectron microscopy confirmed the membrane-bound organellar nature and enzyme composition of these particles. These particles were absent in normal mice, and were increased to a maximal level within 2 days of clofibrate treatment. These data have been taken as indicative of a role of these particles in the mechanism of drug-induced peroxisome proliferation.     

Comparison of the activities of some peroxisomal and extraperoxisomal lipid-metabolizing enzymes in liver and extrahepatic tissues of the rat.

Peroxisomal (acyl-CoA oxidase and peroxisomal dihydroxyacetone-phosphate acyltransferase) and extraperoxisomal (mitochondrial fatty acid oxidation, extraperoxisomal dihydroxyacetone-phosphate acyltransferase, mitochondrial and microsomal glycerophosphate acyltransferases) lipid-metabolizing enzymes were measured in homogenates from rat liver and from seven extrahepatic tissues. Except for jejunal mucosa and kidney, extrahepatic tissues contained very little acyl-CoA oxidase activity. Peroxisomal dihydroxyacetone-phosphate acyltransferase, taken as the activity that was not inhibited by 5 mM-glycerol 3-phosphate, was present in all tissues examined, and its specific activity in liver and extrahepatic tissues was roughly of the same order of magnitude. Clofibrate treatment increased the activity of acyl-CoA oxidase in liver, and to a smaller extent also in kidney, but did not influence the activity of peroxisomal dihydroxyacetone-phosphate acyltransferase. Comparison of the activities of peroxisomal and extraperoxisomal lipid-metabolizing enzymes in extrahepatic tissues and in liver, an organ in which the contribution of peroxisomes to fatty acid oxidation and to glycerolipid synthesis has been estimated previously, suggests that, as in liver, peroxisomal long-chain fatty acid oxidation is of minor quantitative importance in extrahepatic tissues, but that in these tissues (micro)-peroxisomes are responsible for most of the dihydroxyacetone phosphate acylation and, consequently, for initiating ether glycerolipid synthesis.     

Fatty acid oxidation by human liver peroxisomes.

A cyanide insensitive fatty acid oxidation system is detected in human liver and is shown to be localized in peroxisomes by subcellular fractionation in Metrizamide continuous density gradients. Fatty acyl-CoA oxidase, its characteristic enzyme, acts maximally on C₁₂–C₁₈ saturated fatty acids and on oleoyl-CoA and requires FAD. These results, together with the already established properties of the system in rat liver, support its potential contribution to lipid metabolism and to the hypolipidemic effect of Clofibrate and related drugs in humans.     

Evidence for participation of the inner membrane in the import of sulfite oxidase into the intermembrane space of liver mitochondria

Sulfite oxidase, a soluble enzyme in mitochondrial intermembrane space, was synthesized as a precursor protein larger than the authentic enzyme when rat liver RNA was translated $\text{in}\text{vitro}$ using reticulocyte lysate. When the $\text{in}\text{vitro}$ translation products were incubated with isolated rat liver mitochondria, the precursor of sulfite oxidase was converted to the size of the mature enzyme. The $\text{in}\text{vitro}$ processed mature enzyme was no longer susceptible to externally added proteases and was extractable by a hypotonic treatment of the mitochondria, suggesting its location in the intermembrane space. When mitochondria were subfractionated, most of the processing activity was recovered in the mitoplast fraction. The import-processing activity of mitochondria was inhibited by CCCP, oligomycin, or atractyloside in the presence of KCN. These results suggest that the import of sulfite oxidase into mitochondrial intermembrane space requires the participation of inner membrane.     

m-Octopamine as a substrate for monoamine oxidase.

$\text{m}$-Octopamine was characterized as substrate for monoamine oxidase (MAO) in rat brain and liver mitochondria. The $\text{K}$m and $\text{V}$max values of the brain enzyme were 735 μM and 32.5 nmoles/mg protein/30 min, and those of the liver enzyme 351 μM and 125 nmoles/mg protein/30 min, respectively. The inhibition experiments with clorgyline and deprenyl showed that $\text{m}$-octopamine was a common substrate for type A and type B MAO, though a major part of the activity was due to type A enzyme.     

Evidence for the regulation of pyridoxal 5′-phosphate formation in liver by pyridoxamine (pyridoxine) 5′-phosphate oxidase

Pyridoxamine (pyridoxine) 5′-phosphate oxidase (EC 1.4.3.5) purified from rabbit liver is competitively inhibited by the reaction product, pyridoxal 5′-phosphate. The K_i, 3 μM, is considerably lower than the K_m for either natural substrate (18 and 24 μM for pyridoxamine 5′-phosphate and 25 and 16 μM for pyridoxine 5′-phosphate in 0.2 M potassium phosphate at pH 8 and 7, respectively). The K_i determined using a 10% rabbit liver homogenate is the same as that for the pure enzyme; hence, product inhibition $\text{in}\text{vivo}$ is probably not diminished significantly by other cellular components. Similar determinations for a 10% rat liver homogenate also show strong inhibition by pyridoxal 5′-phosphate. Since the reported liver content of free or loosely bound pyridoxal 5′-phosphate is greater than K_i, the oxidase in liver is probably associated with pyridoxal 5′-phosphate. These results also suggest that product inhibition of pyridoxamine-P oxidase may regulate the $\text{in}\text{vivo}$ rate of pyridoxal 5′-phosphate formation.