Peroxisomal beta-oxidation of polyunsaturated fatty acids

Mitochondrial dysfunction, AMPK activation and peroxisomal metabolism: A coherent scenario for non-canonical 3-methylglutaconic acidurias

The occurrence of 3-methylglutaconic aciduria (3-MGA) is a well understood phenomenon in leucine oxidation and ketogenesis disorders (primary 3-MGAs). In contrast, its genesis in non-canonical (secondary) 3-MGAs, a growing-up group of disorders encompassing more than a dozen of inherited metabolic diseases, is a mystery still remaining unresolved for three decades. To puzzle out this anthologic problem of metabolism, three clues were considered: (i) the variety of disorders suggests a common cellular target at the cross-road of metabolic and signaling pathways, (ii) the response to leucine loading test only discriminative for primary but not secondary 3-MGAs suggests these latter are disorders of extramitochondrial HMG-CoA metabolism as also attested by their failure to increase 3-hydroxyisovalerate, a mitochondrial metabolite accumulating only in primary 3-MGAs, (iii) the peroxisome is an extramitochondrial site possessing its own pool and displaying metabolism of HMG-CoA, suggesting its possible involvement in producing extramitochondrial 3-methylglutaconate (3-MG). Following these clues provides a unifying common basis to non-canonical 3-MGAs: constitutive mitochondrial dysfunction induces AMPK activation which, by inhibiting early steps in cholesterol and fatty acid syntheses, pipelines cytoplasmic acetyl-CoA to peroxisomes where a rise in HMG-CoA followed by local dehydration and hydrolysis may lead to 3-MGA yield. Additional contributors are considered, notably for 3-MGAs associated with hyperammonemia, and to a lesser extent in CLPB deficiency. Metabolic and signaling itineraries followed by the proposed scenario are essentially sketched, being provided with compelling evidence from the literature coming in their support.

Analysis of the effect of a novel therapeutic for type 2 diabetes on the proteome of a muscle cell line

Elevated serum retinol-binding protein (RBP) concentration has been implicated in the development of insulin resistance and type 2 diabetes. Two series of small molecules have been designed to lower serum levels by reducing secretion of the transthyretin-RBP complex from the liver and enhancing RBP clearance through the kidney. These small molecules were seen to improve glucose and insulin tolerance tests and to reduce body weight gain in mice rendered diabetic through a high fat diet. A proteomics study was conducted to better understand the effects of these compounds in muscle cells, muscle being the primary site for energy expenditure. One lead compound, RTC-15, is seen to have a significant effect on proteins involved in fat and glucose metabolism. This could indicate that the compound is having a direct effect on muscle tissue to improve energy homeostasis as well as a whole body effect on circulating RBP levels. This newly characterized group of antidiabetic compounds may prove useful in the treatment and prevention of insulin resistance and obesity.

Eci1p uses a PTS1 to enter peroxisomes: either its own or that of a partner, Dci1p

Saccharomyces cerevisiae delta3,delta2-enoyl-CoA isomerase (Eci1p), encoded by ECI1, is an essential enzyme for the betaoxidation of unsaturated fatty acids. It has been reported, as well as confirmed in this study, to be a peroxisomal protein. Unlike many other peroxisomal proteins, Ecilp possesses both a peroxisome targeting signal type 1 (PTS1)-like signal at its carboxy-terminus (-HRL) and a PTS2-like signal at its amino-terminus (RIEGPFFIIHL). We have found that peroxisomal targeting of a fusion protein consisting of Eci1p in front of green fluorescent protein (GFP) is not dependent on Pex7p (the PTS2 receptor), ruling out a PTS2 mechanism, but is dependent on Pex5p (the PTS1 receptor). This Pex5p-dependence was unexpected, since the putative PTS1 of Ecilp is not at the C-terminus of the fusion protein; indeed, deletion of this signal (-HRL-) from the fusion did not affect the Pex5p-dependent targeting. Consistent with this, Pex5p interacted in two-hybrid assays with both Eci1p and Eci1PdeltaHRL. Ecilp-GFP targeting and Eci1pdeltaHRL interaction were abolished by replacement of Pex5p with Pex5p(N495K), a point-mutated Pex5p that specifically abolishes the PTS1 protein import pathway. Thus, Eci1p peroxisomal targeting does require the Pex5p-dependent PTS1 pathway, but does not require a PTS1 of its own. By disruption of ECI1 and DCI1, we found that Dci1p, a peroxisomal PTS1 protein that shares 50% identity with Eci1p, is necessary for Eci1p-GFP targeting. This suggests that the Pex5p-dependent import of Eci1p-GFP is due to interaction and co-import with Dci1p. Despite the dispensability of the C-terminal HRL for import in wild-type cells, we have also shown that this tripeptide can function as a PTS1, albeit rather weakly, and is essential for targeting in the absence of Dci1p. Thus, Eci1p can be targeted to peroxisomes by its own PTS1 or as a hetero-oligomer with Dcilp. These data demonstrate a novel, redundant targeting pathway for Eci1p.

Peroxisomal multifunctional enzyme of beta-oxidation metabolizing D-3-hydroxyacyl-CoA esters in rat liver: molecular cloning, expression and characterization

In the present study we have cloned and characterized a novel rat peroxisomal multifunctional enzyme (MFE) named perMFE-II. The purified 2-enoyl-CoA hydratase 2 with an M(r) of 31500 from rat liver [Malila, Siivari, Mäkelä, Jalonen, Latipää, Kunau and Hiltunen (1993) J. Biol. Chem. 268, 21578-21585] was subjected to tryptic fragmentation and the resulting peptides were isolated and sequenced. Surprisingly, the full-length cDNA, amplified by PCR, had an open reading frame of 2205 bp encoding a polypeptide with a predicted M(r) of 79,331 and contained a potential peroxisomal targeting signal in the C-terminus (Ala-Lys-Leu). The sequenced peptide fragments of hydratase 2 gave a full match in the middle portion of the cDNA-derived amino acid sequence. The predicted amino acid sequence showed a high degree of similarity with pig 17 beta-hydroxysteroid dehydrogenase type IV and MFE of yeast peroxisomal beta-oxidation. Recombinant perMFE-II (produced in Pichia pastoris) had 2-enoyl-CoA hydratase 2 and D-specific 3-hydroxyacyl-CoA dehydrogenase activities and was catalytically active with several straight-chain trans-2-enoyl-CoA, 2-methyltetradecenoyl-CoA and pristenoyl-CoA esters. The results showed that in addition to an earlier described multifunctional isomerase-hydratase-dehydrogenase enzyme from rat liver peroxisomes (perMFE-I), another MFE exists in rat liver peroxisomes. They both catalyse sequential hydratase and dehydrogenase reactions of beta-oxidation but through reciprocal stereochemical courses.

Peroxisomal beta-oxidation and polyunsaturated fatty acids

Peroxisomes are capable of oxidizing a variety of substrates including (poly)unsaturated enoyl-CoA esters. The beta-oxidation of unsaturated enoyl-CoA esters in peroxisomes, and also in mitochondria, is not just chain-shortening but also involves the metabolizing of pre-existing carbon-to-carbon double bonds. In addition to the enzymes of the beta-oxidation spiral itself, this metabolism requires the participation of auxiliary enzymes: delta 3, delta 2-enoyl-CoA isomerase; 2,4-dienoyl-CoA reductase; 2-enoyl-CoA hydratase 2 or 3-hydroxyacyl-CoA epimerase; and delta 3,5 delta 2,4-dienoyl-CoA isomerase. Many of these enzymes are present as isoforms, and can be found located in multiple subcellular compartments, for example, peroxisomes, mitochondria or the endoplasmic reticulum, while some of the activities are integral parts of multifunctional enzymes of beta-oxidation systems.

On the mechanism of stimulation of peroxisomal beta-oxidation in rat heart by partially hydrogenated fish oil

By feeding rats a diet containing 20% (w/w) partially hydrogenated fish oil (PHFO), an apparent 6.3-fold increase in the cyanide insensitive palmitoyl-CoA-dependent NAD+ reduction was observed for the heart peroxisomal fractions. This finding was confirmed by a 7.6-fold and 7.9-fold increase in the specific activity of fatty acyl-CoA oxidase, with palmitoyl-CoA and erucoyl-CoA as the substrates, respectively. Immunoblots after SDS-PAGE of rat heart peroxisomal fractions revealed a 12-fold increase in the 52 kDa fatty acyl-CoA oxidase (FAO) subunit for PHFO-fed rats, whereas the 72 kDa subunit of FAO and several other peroxisomal proteins (including the trifunctional enzyme delta 3,delta 2-enoyl-CoA isomerase, 2-enoyl-CoA hydratase, 3-hydroxyacyl-CoA dehydrogenase) increased only 2- to 3-fold. The increase in the 52 kDa subunit was markedly higher than the increase in the steady-state mRNA level of FAO (2.0-fold), and is most likely caused by a rather selective stabilization of the 52 kDa FAO subunit. Interestingly, PHFO feeding caused a larger increase in fatty acyl-CoA oxidase and catalase activities than did clofibrate in the heart. The opposite was the case in the liver, especially for fatty acyl-CoA oxidase. Rats fed a semisynthetic diet containing 6% (w/w) erucic acid (C22:1(n - 9), cis) or brassidic acid (C22:1(n - 9), trans) revealed a 5-fold and 3-fold increase vs. the control (pellet fed) rats in heart FAO activity, respectively, as well as a proportional and selective increase in the specific content of 52 kDa FAO subunit. Thus, the relatively high content of C22 monoene fatty acids appears to be one of the main factors responsible for the increase in rat heart peroxisomal FAO activity during PHFO feeding. However, the PHFO diet increased the heart peroxisomal FAO activity more than diets containing a similar amount of C22:1 in the form of erucic or brassidic acid, and additional compounds of lipid or a more xenobiotic nature may also play a role. SDS-PAGE electrophoresis of highly purified rat liver peroxisomes revealed that the specific content of polypeptides with mobilities corresponding to that of the beta-oxidation enzyme system, increased by a factor of < 2 as a result of feeding the PHFO diet. The 3.1-fold increase in cyanide insensitive palmitoyl-CoA-dependent NAD+ reduction was comparable to the increase (4.1-fold) in the acyl-CoA oxidase activity.(ABSTRACT TRUNCATED AT 400 WORDS)

Isolation and characterization of cDNA for human 120 kDa mitochondrial 2,4-dienoyl-coenzyme A reductase

2,4-Dienoyl-CoA reductase (EC 1.3.1.34) participates in beta-oxidation of (poly)unsaturated enoyl-CoAs and it appears in mammalian mitochondria as two isoforms with molecular masses of 120 and 60 kDa [Hakkola and Hiltunen (1993) Eur. J. Biochem. 215, 199-204]. The 120 kDa isomer is a homotetrameric enzyme, and here we report cDNA cloning of its subunit from human. cDNA clones were isolated by reverse transcriptase-PCR from a fibrosarcoma cell line and by screening from a human liver lambda gt11 cDNA library. The 1128 bp clone contained an open reading frame of 1008 bp encoding a polypeptide of 335 amino acid residues with a predicted molecular mass of 36066 Da. This polypeptide represents the immature monomer of the 120 kDa enzyme, and it contains a predicted N-terminal mitochondrial targeting signal. The amino acid (nucleotide) sequence of human 2,4-dienoyl-CoA reductase shows 82.7% (81.7%) similarity (identity) to the corresponding sequence from the rat. Northern-blot analysis gave a single mRNA species of 1.2 kb in several human tissues, the amounts present in the tissues tested ranking as follows: heart approximately liver approximately pancreas > kidney >> skeletal muscle approximately lung. Immunoblotting of human and rat liver samples with an antibody to the subunit of the rat 120 kDa isoform indicates that the mature human enzyme is larger than its counterpart in the rat. The comparison of amino acid sequences for rat and human enzymes proposes that the difference in the size is 10 amino acid residues. The results show that the rat and human reductases are similar in many characteristics and that the reductase is expressed in human tissues capable of beta-oxidation of fatty acids.

cDNA cloning and amino acid sequence of human mitochondrial delta 3 delta 2-enoyl-CoA isomerase: comparison of the human enzyme with its rat counterpart, mitochondrial short-chain isomerase

We report the isolation of a cDNA encoding a mature human monofunctional delta 3 delta 2-enoyl-CoA isomerase and the determination of its nucleotide sequence. The purified uncleaved protein, as well as several internal tryptic and CNBr fragments, were subjected to N-terminal peptide sequencing. The deduced amino acid sequence of the mature protein consists of 260 amino acids with a predicted M(r) of 28735. The human mitochondrial isomerase exhibits a 74% (78%) sequence identity with the corresponding rat counterpart at amino acid (nucleotide) level(s). Many basic amino acid residues in rat isomerase have been changed to acidic or neutral residues in human enzyme, explaining the differences observed between these proteins.

Metabolic pathways in mammalian peroxisomes

This article summarizes our current knowledge of the metabolic pathways present in mammalian peroxisomes. Emphasis is placed on those aspects that are not covered by other articles in this issue: peroxisomal enzyme content and topology; the peroxisomal beta-oxidation system; substrates of peroxisomal beta-oxidation such as very-long-chain fatty acids, branched fatty acids, dicarboxylic fatty acids, prostaglandins and xenobiotics; the role of peroxisomes in the metabolism of purines, polyamines, amino acids, glyoxylate and reactive oxygen products such as hydrogen peroxide, superoxide anions and epoxides.