Up-regulation of the peroxisomal β-oxidation system occurs in butyrate-grown Candida tropicalis following disruption of the gene encoding peroxisomal 3-ketoacyl-CoA thiolase

In the yeast Candida tropicalis, two thiolase isozymes, peroxisomal acetoacetyl-CoA thiolase and peroxisomal 3-ketoacyl-CoA thiolase, participate in the peroxisomal fatty acid β-oxidation system. Their individual contributions have been demonstrated in cells grown on butyrate, with C. tropicalis able to grow in the absence of either one. In the present study, a lack of peroxisomal 3-ketoacyl-CoA thiolase protein resulted in increased expression (up-regulation) of acetoacetyl-CoA thiolase and other peroxisomal proteins, whereas a lack of peroxisomal acetoacetyl-CoA thiolase produced no corresponding effect. Overexpression of the acetoacetyl-CoA thiolase gene did not suppress the up-regulation or the growth retardation on butyrate in cells without peroxisomal 3-ketoacyl-CoA thiolase, even though large amounts of the overexpressed acetoacetyl-CoA thiolase were detected in most of the peroxisomes of butyrate-grown cells. These results provide important evidence of the greater contribution of 3-ketoacyl-CoA thiolase to the peroxisomal β-oxidation system than acetoacetyl-CoA thiolase in C. tropicalis and a novel insight into the regulation of the peroxisomal β-oxidation system.     

Up-regulation of the peroxisomal beta-oxidation system occurs in butyrate-grown Candida tropicalis following disruption of the gene encoding peroxisomal 3-ketoacyl-CoA thiolase

In the yeast Candida tropicalis, two thiolase isozymes, peroxisomal acetoacetyl-CoA thiolase and peroxisomal 3-ketoacyl-CoA thiolase, participate in the peroxisomal fatty acid beta-oxidation system. Their individual contributions have been demonstrated in cells grown on butyrate, with C. tropicalis able to grow in the absence of either one. In the present study, a lack of peroxisomal 3-ketoacyl-CoA thiolase protein resulted in increased expression (up-regulation) of acetoacetyl-CoA thiolase and other peroxisomal proteins, whereas a lack of peroxisomal acetoacetyl-CoA thiolase produced no corresponding effect. Overexpression of the acetoacetyl-CoA thiolase gene did not suppress the up-regulation or the growth retardation on butyrate in cells without peroxisomal 3-ketoacyl-CoA thiolase, even though large amounts of the overexpressed acetoacetyl-CoA thiolase were detected in most of the peroxisomes of butyrate-grown cells. These results provide important evidence of the greater contribution of 3-ketoacyl-CoA thiolase to the peroxisomal beta-oxidation system than acetoacetyl-CoA thiolase in C. tropicalis and a novel insight into the regulation of the peroxisomal beta-oxidation system.     

Genetic Evaluation of Physiological Functions of Thiolase Isozymes in the n-Alkane-Assimilating Yeast Candida tropicalis

The n-alkane-assimilating diploid yeast Candida tropicalis possesses three thiolase isozymes encoded by two pairs of alleles: cytosolic and peroxisomal acetoacetyl-coenzyme A (CoA) thiolases, encoded by CT-T1A and CT-T1B, and peroxisomal 3-ketoacyl-CoA thiolase, encoded by CT-T3A and CT-T3B. The physiological functions of these thiolases have been examined by gene disruption. The homozygous ct-t1aΔ/t1bΔ null mutation abolished the activity of acetoacetyl-CoA thiolase and resulted in mevalonate auxotrophy. The homozygous ct-t3aΔ/t3bΔ null mutation abolished the activity of 3-ketoacyl-CoA thiolase and resulted in growth deficiency on n-alkanes (C₁₀ to C₁₃). All thiolase activities in this yeast disappeared with the ct-t1aΔ/t1bΔ and ct-t3aΔ/t3bΔ null mutations. To further clarify the function of peroxisomal acetoacetyl-CoA thiolases, the site-directed mutation leading acetoacetyl-CoA thiolase without a putative C-terminal peroxisomal targeting signal was introduced on the CT-T1A locus in the ct-t1bΔ null mutant. The truncated acetoacetyl-CoA thiolase was solely present in cytoplasm, and the absence of acetoacetyl-CoA thiolase in peroxisomes had no effect on growth on all carbon sources employed. Growth on butyrate was not affected by a lack of peroxisomal acetoacetyl-CoA thiolase, while a retardation of growth by a lack of peroxisomal 3-ketoacyl-CoA thiolase was observed. A defect of both peroxisomal isozymes completely inhibited growth on butyrate. These results demonstrated that cytosolic acetoacetyl-CoA thiolase was indispensable for the mevalonate pathway and that both peroxisomal acetoacetyl-CoA thiolase and 3-ketoacyl-CoA thiolase could participate in peroxisomal β-oxidation. In addition to its essential contribution to the β-oxidation of longer-chain fatty acids, 3-ketoacyl-CoA thiolase contributed greatly even to the β-oxidation of a C₄ substrate butyrate.     

Thiolase mRNA translated in vitro yields a peptide with a putative N-terminal presequence

Thiolase is part of the fatty acid oxidation machinery which in plants is located within glyoxysomes or peroxisomes. In cucumber cotyledons, proteolytic modification of thiolase takes place during the transfer of the cytosolic precursor into glyoxysomes prior to the intraorganellar assembly of the mature enzyme. This was shown by size comparison of the in vitro synthesized precursor and the 45 kDa subunit of the homodimeric glyoxysomal form. We isolated a full-length cDNA clone encoding the 48 539 Da precursor of thiolase. This plant protein displayed 40% and 47% identity with the precursor of fungal peroxisomal thiolase and human peroxisomal thiolase, respectively. Compared to bacterial thiolases, the precursor of the plant enzyme was distinguished by an N-terminal extension of 34 amino acid residues. This putative targeting sequence of cucumber thiolase shows similarities with the cleavable presequences of rat peroxisomal thiolase and plant peroxisomal malate dehydrogenase.     

Characterization of the gene encoding human peroxisomal 3-oxoacyl-CoA thiolase (ACAA). No large DNA rearrangement in a thiolase-deficient patient.

We have characterized the gene encoding human peroxisomal 3-oxoacyl-CoA thiolase, an enzyme operative in the peroxisomal beta-oxidation system. We found one version of this gene (gene symbol ACAA) in the human genome, in contrast to the situation in rat where two versions have been described. The human gene shows a high structural similarity to the rat genes. It contains 12 exons and 11 introns and spans about 11 kb. We have determined the 5' end of the human thiolase mRNA by employing primer extension analysis and we have sequenced the region upstream of the gene. The putative promoter area displays some of the characteristics typical of promoters of other peroxisomal genes, in that it contains GC elements, but lacks TATA boxes. Finally, no large DNA rearrangement involving the thiolase gene could be observed in a patient suffering from pseudo-Zellweger syndrome (peroxisomal thiolase deficiency).     

Peroxisomal β-ketothiolase

β-Ketothiolase was found in rat liver peroxisomes that were isolated by sucrose density gradient centrifugation. The presence of dithiothreitol was essential for measuring the peroxisomal thiolase, but dithiothreitol had little effect upon the thiolase activity in the mitochondria or cytosol. Dithiothreitol was not used during the isolation procedures. Acetoacetyl CoA and β-ketolauryl CoA, which was synthesized chemically, were used as substrates. The peroxisomal thiolase was active with β-ketolauryl CoA but had almost no activity with acetoacetyl CoA as the substrate. Thiolase activities in the mitochondrial and cytosolic fractions utilized both long- and short-chain substrates. The thiolases in the various fractions bound to and were purified by chromatography on calcium phosphate gel cellulose columns. The peroxisomal thiolase did not bind to phosphocellulose, whereas the mitochondrial and cytosolic activities could be chromatographed on phosphocellulose. Peroxisomal β-ketolauryl CoA thiolase activity was inhibited about 20% by 25 mm Mg²⁺, and more activity was measured in a phosphate than in a Tris buffer. In control rat livers, the total activity of β-ketolauryl CoA thiolase was 3.4 μmol/min per gram of liver in the peroxisomes and 4.9 μmol/min per gram of liver in the mitochondria, which indicates that peroxisomes contain the capacity for 40% of the total thiolase activity associated with β-oxidation systems. In addition, 6.3 μmol/min per gram of liver of β-ketolauryl CoA thiolase was found in the soluble fraction and chromatographed differently from the peroxisomal enzyme on phosphocellulose. Clofibrate in the rat diet for 6 or 21 days resulted in about a 15-fold increase in peroxisomal thiolase when assayed with β-ketolauryl CoA and somewhat less of an increase in the other fractions.     

Isolation and characterization of acetoacetyl-CoA thiolase gene essential for n-decane assimilation in yeast Yarrowia lipolytica

Yarrowia lipolytica is a yeast which can utilize n-alkane as a sole carbon source. We isolated a Y. lipolytica peroxisomal acetoacetyl-CoA thiolase gene, PAT1, by complementation of a mutant that cannot utilize n-decane as a sole carbon source. We found that the putative PAT1 product had conserved features of peroxisomal acetoacetyl-CoA thiolase. We showed that the PAT1 disruptant was not able to grow on n-decane, and that n-decane-inducible acetoacetyl-CoA thiolase activity largely depended on PAT1. The original mutant carried a mutation involving the replacement of Gly382 with Glu. This mutation inactivated the ability of PAT1 to complement the defective n-decane utilization of the disruptant. These results indicate that PAT1 encodes peroxisomal acetoacetyl-CoA thiolase and is essential for n-decane utilization in Y. lipolytica.     

Import of the peroxisomal targeting signal type 2 protein 3-ketoacyl-coenzyme a thiolase into glyoxysomes

Most peroxisomal matrix proteins possess a carboxy-terminal tripeptide targeting signal, termed peroxisomal targeting signal type 1 (PTS1), and follow a relatively well-characterized pathway of import into the organelle. The peroxisomal targeting signal type 2 (PTS2) pathway of peroxisomal matrix protein import is less well understood. In this study, we investigated the mechanisms of PTS2 protein binding and import using an optimized in vitro assay to reconstitute the transport events. The import of the PTS2 protein thiolase differed from PTS1 protein import in several ways. Thiolase import was slower than typical PTS1 protein import. Competition experiments with both PTS1 and PTS2 proteins revealed that PTS2 protein import was inhibited by addition of excess PTS2 protein, but it was enhanced by the addition of PTS1 proteins. Mature thiolase alone, lacking the PTS2 signal, was not imported into peroxisomes, confirming that the PTS2 signal is necessary for thiolase import. In competition experiments, mature thiolase did not affect the import of a PTS1 protein, but it did decrease the amount of radiolabeled full-length thiolase that was imported. This is consistent with a mechanism by which the mature protein competes with the full-length thiolase during assembly of an import complex at the surface of the membrane. Finally, the addition of zinc to PTS2 protein imports increased the level of thiolase bound and imported into the organelles.     

Targeted disruption of the peroxisomal thiolase B gene in mouse: a new model to study disorders related to peroxisomal lipid metabolism

The peroxisomal beta-oxidation system consists of four steps catalysed by three enzymes: acyl-CoA oxidase, 3-hydroxyacyl-CoA hydratase/3-hydroxyacyl-CoA dehydrogenase (multifunctional enzyme) and thiolase. In humans, thiolase activity is encoded by one gene, whereas in rodents, three enzymes encoded by three distinct genes (i.e. thiolase A, thiolase B and SCP2/thiolase) catalyse the thiolase activity. So far, acyl-CoA oxidase- and multifunctional enzyme-deficient patients have been identified and knock-out mice for these genes have been produced. Conversely, no isolated thiolase-deficient patient has been found, and no thiolase (A or B)-deficient mice have been generated. Hence, to better understand the cause of isolated human thiolase deficiency, we disrupted the catalytic site of the mouse thiolase B by homologous recombination in order to analyse the phenotype of these thiolase B-deficient mice. Mice, made homozygous for the mutation, lack expression of thiolase B mRNA and are viable, fertile and healthy at birth. They exhibit no detectable phenotype defects and no compensation, rather a slight decrease in other peroxisomal thiolase (thiolase A and SCPx) mRNAs, was found.     

Cloning and sequence determination of cDNA encoding a second rat liver peroxisomal 3-ketoacyl-CoA thiolase

3-Ketoacyl-coenzyme A thiolase (thiolase) catalyzes the final step of the fatty acid beta-oxidation pathway in peroxisomes. Thiolase is unique among rat liver peroxisomal enzymes in that it is synthesized as a precursor possessing a 26-amino acid (aa) N-terminal extension which is cleaved to generate the mature enzyme. To facilitate further examination of the synthesis, intracellular transport and processing of this enzyme, cDNA clones were selected from a lambda gt11 rat liver library using antiserum raised against peroxisomal thiolase. Upon sequencing several cDNA clones, it was revealed that there are at least two distinct thiolase enzymes localized to rat liver peroxisomes, one identical to the previously published rat liver peroxisomal thiolase (thiolase 1) [Hijikata et al., J. Biol. Chem. 262 (1987) 8151-8158] and a novel thiolase (thiolase 2). The THL2 cDNA possesses a single open reading frame of 1302 nucleotides (nt) encoding a protein of 434 aa (Mr 44790). The coding region of THL2 cDNA exhibits 94.6% nt sequence identity with THL1 and 95.4% identity at the level of aa sequence. Northern-blot analysis indicates that the mRNA encoding thiolase 2 is approx. 1.7 kb in size. The mRNA encoding thiolase 2 is induced approx. twofold upon treatment of rats with the peroxisome-proliferating drug, clofibrate. In contrast, the thiolase 1 mRNA is induced more than tenfold under similar conditions.     

Amino-terminal presequence of the precursor of peroxisomal 3-ketoacyl-CoA thiolase is a cleavable signal peptide for peroxisomal targeting.

To examine the function of the amino-terminal presequence of rat peroxisomal 3-ketoacyl-CoA thiolase precursor, fusion proteins of various amino-terminal regions of the precursor with non-peroxisomal enzymes were expressed in cultured mammalian cells. On immunofluorescence microscopy, all constructs carrying the presequence part exhibited punctate patterns of distribution, identical with that of catalase, a peroxisomal marker. Proteins lacking all or a part of the prepiece were found in the cytosol. These results indicate that the presequence of the thiolase has sufficient information for peroxisomal targeting.     

A role for the peroxin Pex8p in Pex20p-dependent thiolase import into peroxisomes of the yeast Yarrowia lipolytica

Peroxins are proteins required for peroxisome assembly. The cytosolic peroxin Pex20p binds directly to the beta-oxidation enzyme thiolase and is necessary for its dimerization and peroxisomal targeting. The intraperoxisomal peroxin Pex8p has a role in the import of peroxisomal matrix proteins, including thiolase. We report the results of yeast two-hybrid analyses with various peroxins of the yeast Yarrowia lipolytica and characterize more fully the interaction between Pex8p and Pex20p. Coimmunoprecipitation showed that Pex8p and Pex20p form a complex, while in vitro binding studies demonstrated that the interaction between Pex8p and Pex20p is specific, direct, and autonomous. Pex8p fractionates with peroxisomes in cells of a PEX20 disruption strain, indicating that Pex20p is not necessary for the targeting of Pex8p to peroxisomes. In cells of a PEX8 disruption strain, thiolase is mostly cytosolic, while Pex20p and a small amount of thiolase associate with peroxisomes, suggesting the involvement of Pex8p in the import of thiolase after docking of the Pex20p-thiolase complex to the membrane. In the absence of Pex8p, peroxisomal thiolase and Pex20p are protected from the action of externally added protease. This finding, together with the fact that Pex8p is intraperoxisomal, suggests that Pex20p may accompany thiolase into peroxisomes during import.     

Peroxisomal acetoacetyl-CoA thiolase of an n-alkane-utilizing yeast, Candida tropicalis.

Two genes encoding acetoacetyl-CoA thiolase (thiolase I; EC 2.3.1.9), whose localization in peroxisomes was first found with an n-alkane-utilizing yeast, Candida tropicalis, were isolated from the lambda EMBL3 genomic DNA library prepared from the yeast genomic DNA. Nucleotide sequence analysis revealed that both genes contained open reading frames of 1209 bp corresponding to 403 amino acid residues with methionine at the N-terminus, which were named as thiolase IA and thiolase IB. The calculated molecular masses were 41,898 Da for thiolase IA and 41,930 Da for thiolase IB. These values were in good agreement with the subunit mass of the enzyme purified from yeast peroxisomes (41 kDa). There was an extremely high similarity between these two genes (96% of nucleotides in the coding regions and 98% of amino acids deduced). From the amino acid sequence analysis of the purified peroxisomal enzyme, it was shown that thiolase IA and thiolase IB were expressed in peroxisomes at an almost equal level. Both showed similarity to other thiolases, especially to Saccharomyces uvarum cytosolic acetoacetyl-CoA thiolase (65% amino acids of thiolase IA and 64% of thiolase IB were identical with this thiolase). Considering the evolution of thiolases, the C. tropicalis thiolases and S. uvarum cytosolic acetoacetyl-CoA thiolase are supposed to have a common origin. It was noticeable that the carboxyl-terminal regions of thiolases IA and IB contained a putative peroxisomal targeting signal, -Ala-Lys-Leu-COOH, unlike those of other thiolases reported hitherto.     

Signal peptide for peroxisomal targeting: replacement of an essential histidine residue by certain amino acids converts the amino-terminal presequence of peroxisomal 3-ketoacyl-CoA thiolase to a mitochondrial signal peptide.

The role of the histidine residue at position -17 of the amino-terminal signal peptide of rat peroxisomal 3-ketoacyl-CoA thiolase was studied in vivo, employing site-directed mutagenesis. Among the nine amino acids tested, only glutamine could partially substitute for the histidine. Mutants carrying basic amino acids, arginine and lysine, and hydrophobic residues, leucine and valine, in place of histidine were all translocated to mitochondria, but not to peroxisomes. These results indicate that the signal peptide of the thiolase is recognized by a mechanism totally different from that for the SKL motif, a known peroxisomal targeting signal. Relationship of the thiolase signal peptide to those of mitochondrial proteins is discussed.     

Properties of peroxisomal 3-ketoacyl-coA thiolase from rat liver

Peroxisomal 3-ketoacyl-CoA thiolase has a molecular weight of 89,000 and consists of 2 polypeptide chains of identical size. The enzyme has no interchain disulfide bonds and is reversibly dissociated to an inactive monomer in the cold. Mitochondrial 3-ketoacyl-CoA thiolase and acetoacetyl-CoA specific thiolase have molecular weights of 154,000 and 149,000, respectively. They each consist of 4 polypeptide chains of identical size. Peroxisomal thiolase and mitochondrial 3-ketoacyl-CoA thiolase operate by a ping-pong mechanism. The catalytic properties, including substrate specificity, of the peroxisomal enzyme were compared to those of mitochondrial 3-ketoacyl-CoA thiolase.     

The NH2-terminal 14-16 amino acids of mitochondrial and bacterial thiolases can direct mature ornithine carbamoyltransferase into mitochondria

Unlike most mitochondrial matrix proteins, the mitochondrial 3-oxoacyl-CoA thiolase [EC 2.3.1.16] is synthesized with no cleavable presequence and possesses information for mitochondrial targeting and import in the mature protein. This mitochondrial thiolase is homologous with the mature portion of peroxisomal 3-oxoacyl-CoA thiolase and acetoacetyl-CoA thiolase [EC 2.3.1.9] of Zoogloea ramigera along the entire sequence. A hybrid gene encoding the NH2-terminal 16 residues (MALLRGVFIVAAKRTP) of the mitochondrial thiolase fused to the mature portion of rat ornithine carbamoyltransferase [EC 2.1.3.3] (lacking its own presequence) was transfected into COS cells, and subcellular localization of the fusion protein was analyzed. Cell fractionation and immunocytochemical analyses showed that the fusion protein was localized in the mitochondria. These results indicate that the NH2-terminal 16 residues of the mitochondrial thiolase function as a noncleavable signal for mitochondrial targeting and import of this enzyme protein. The fusion protein containing the NH2-terminal 14 residues (MSTPSIVIASARTA) of the bacterial thiolase was also localized in the mitochondria. On the other hand, the fusion protein containing the corresponding portion (MQASASDVVVVHGQRTP) of the peroxisomal thiolase appeared not to be localized to the mitochondria. These results show that the import signal of mitochondrial 3-oxoacyl-CoA thiolase originated from the NH2-terminal portion of the ancestral thiolase. The ancestral enzyme might have already possessed a mitochondrial import activity when mitochondria appeared first, or that it might have acquired the import activity during evolution by accumulation of point mutations in the NH2-terminal portion of the enzyme.     

Genetic and biochemical heterogeneity in patients with the rhizomelic form of chondrodysplasia punctata — a complementation study

Summary The genetic relationship between 10 patients with clinical manifestations of rhizomelic chondrodysplasia punctata (RCDP) was studied by complementation analysis after somatic cell fusion. Biochemically, 9 out of the 10 patients were characterized by a partial deficiency of acyl-CoA: dihydroxyacetone phosphate acyltransferase (DHAP-AT) and an impairment of plasmalogen biosynthesis, phytanate catabolism and the maturation of peroxisomal 3-oxoacyl-CoA thiolase; 3-oxoacyl-CoA thiolase was strongly reduced in the peroxisomes of these patients. Fusion of fibroblasts from these 9 patients with Zellweger fibroblasts resulted in complementation as indicated by the restoration of DHAP-AT activity, plasmalogen biosynthesis, and punctate fluorescence after staining with a monoclonal antibody to peroxisomal thiolase. No complementation was observed after fusion of different combinations of the 9 RCDP cell lines, suggesting that they belong to a single complementation group. The tenth patient was characterized biochemically by a deficiency of DHAP-AT and an impairment of plasmalogen biosynthesis. However, maturation and localization of peroxisomal thiolase were normal. Fusion of fibroblasts from this patient with fibroblasts from the other 9 patients resulted in complementation as indicated by the restoration of plasmalogen biosynthesis. We conclude that mutations in at least two different genes can lead to the clinical phenotype of RCDP.     

Peroxisomal beta-oxidation enzyme proteins in the Zellweger syndrome

The absence of peroxisomes in patients with the cerebro-hepato-renal (Zellweger) syndrome is accompanied by a number of biochemical abnormalities, including an accumulation of very long-chain fatty acids. We show by immunoblotting that there is a marked deficiency in livers from patients with the Zellweger syndrome of the peroxisomal beta-oxidation enzyme proteins acyl-CoA oxidase, the bifunctional protein with enoyl-CoA hydratase and 3-hydroxyacyl-CoA dehydrogenase activities and 3-oxoacyl-CoA thiolase. Using anti-(acyl-CoA oxidase), increased amounts of cross-reactive material of low Mr were seen in the patients. With anti-(oxoacyl-CoA thiolase), high Mr cross-reactive material, presumably representing precursor forms of 3-oxoacyl-CoA thiolase, was detected in the patients. Catalase protein was not deficient, in accordance with the finding that catalase activity is not diminished in the patients. Thus in contrast to the situation with catalase functional peroxisomes are required for the stability and normal activity of peroxisomal beta-oxidation enzymes.     

The significance of peroxisome function in chronological aging of Saccharomyces cerevisiae

We studied the chronological lifespan of glucose‐grown Saccharomyces cerevisiae in relation to the function of intact peroxisomes. We analyzed four different peroxisome‐deficient (pex) phenotypes. These included Δpex3 cells that lack peroxisomal membranes and in which all peroxisomal proteins are mislocalized together with Δpex6 in which all matrix proteins are mislocalized to the cytosol, whereas membrane proteins are still correctly sorted to peroxisomal ghosts. In addition, we analyzed two mutants in which the peroxisomal location of the β‐oxidation machinery is in part disturbed. We analyzed Δpex7 cells that contain virtually normal peroxisomes, except that all matrix proteins that contain a peroxisomal targeting signal type 2 (PTS2, also including thiolase), are mislocalized to the cytosol. In Δpex5 cells, peroxisomes only contain matrix proteins with a PTS2 in conjunction with all proteins containing a peroxisomal targeting signal type 1 (PTS1, including all β‐oxidation enzymes except thiolase) are mislocalized to the cytosol. We show that intact peroxisomes are an important factor in yeast chronological aging because all pex mutants showed a reduced chronological lifespan. The strongest reduction was observed in Δpex5 cells. Our data indicate that this is related to the complete inactivation of the peroxisomal β‐oxidation pathway in these cells due to the mislocalization of thiolase. Our studies suggest that during chronological aging, peroxisomal β‐oxidation contributes to energy generation by the oxidation of fatty acids that are released by degradation of storage materials and recycled cellular components during carbon starvation conditions.     

Phylogenetic Analysis of Eukaryotic Thiolases Suggests Multiple Proteobacterial Origins

Eukaryotic thiolases are essential enzymes located in three different compartments (peroxisome, mitochondrion, and cytosol) that can display catabolic or anabolic functions. They are responsible for the thiolytic cleavage of oxidized acyl-CoA (thiolase I; EC 2.3.1.16) and the synthesis or degradation of acetoacetyl-CoA (thiolase II; EC 2.3.1.9). Phylogenetic analysis of eukaryotic thiolase sequences showed that they form six distinct clusters, one of them highly divergent, which are in good correlation with their class and subcellular location. When analyzed together with a representative sample of prokaryotic thiolases, all eukaryotic thiolase groups emerged close to proteobacterial sequences. Metazoan cytosolic thiolase II was related to α-proteobacterial sequences, suggesting a mitochondrial origin. Unexpectedly, cytosolic thiolases from green plants and fungi as well as at least one member of all eukaryotic peroxisomal and mitochondrial thiolases had δ-proteobacteria as closest relatives. Our analysis suggests that these eukaryotic peroxisomal and mitochondrial thiolases may have been acquired from δ-proteobacteria prior to the ancestor of all known eukaryotes.