Thiolase Explained

Thiolases, also known as acetyl-coenzyme A acetyltransferases (ACAT), are enzymes which convert two units of acetyl-CoA to acetoacetyl CoA in the mevalonate pathway.

Thiolases are ubiquitous enzymes that have key roles in many vital biochemical pathways, including the beta oxidation pathway of fatty acid degradation and various biosynthetic pathways.[1] Members of the thiolase family can be divided into two broad categories: degradative thiolases (EC 2.3.1.16) and biosynthetic thiolases (EC 2.3.1.9). These two different types of thiolase are found both in eukaryotes and in prokaryotes: acetoacetyl-CoA thiolase (EC:2.3.1.9) and 3-ketoacyl-CoA thiolase (EC:2.3.1.16). 3-ketoacyl-CoA thiolase (also called thiolase I) has a broad chain-length specificity for its substrates and is involved in degradative pathways such as fatty acid beta-oxidation. Acetoacetyl-CoA thiolase (also called thiolase II) is specific for the thiolysis of acetoacetyl-CoA and involved in biosynthetic pathways such as beta-hydroxybutyric acid synthesis or steroid biogenesis.

The formation of a carbon–carbon bond is a key step in the biosynthetic pathways by which fatty acids and polyketide are made. The thiolase superfamily enzymes catalyse the carbon–carbon-bond formation via a thioester-dependent Claisen condensation[2] reaction mechanism.[3]

Function

Thiolases are a family of evolutionarily related enzymes. Two different types of thiolase[4] [5] [6] are found both in eukaryotes and in prokaryotes: acetoacetyl-CoA thiolase and 3-ketoacyl-CoA thiolase . 3-ketoacyl-CoA thiolase (also called thiolase I) has a broad chain-length specificity for its substrates and is involved in degradative pathways such as fatty acid beta-oxidation. Acetoacetyl-CoA thiolase (also called thiolase II) is specific for the thiolysis of acetoacetyl-CoA and involved in biosynthetic pathways such as poly beta-hydroxybutyrate synthesis or steroid biogenesis.

In eukaryotes, there are two forms of 3-ketoacyl-CoA thiolase: one located in the mitochondrion and the other in peroxisomes.

There are two conserved cysteine residues important for thiolase activity. The first located in the N-terminal section of the enzymes are involved in the formation of an acyl-enzyme intermediate; the second located at the C-terminal extremity is the active site base involved in deprotonation in the condensation reaction.

Isozymes

EC number Name Alternate name Isozymes Subcellular distribution
thiolase II;
Acetoacetyl-CoA thiolase
mitochondrial
cytosolic
thiolase I;
3-Ketoacyl-CoA thiolase;
β-Ketothiolase
3-KAT
peroxisomal
mitochondrial
mitochondrial
3-Oxopristanoyl-CoA thiolase
β-Ketoadipyl-CoA thiolase
Peroxisomal thiolase 2 peroxisomal/cytosolic

Mammalian nonspecific lipid-transfer protein (nsL-TP) (also known as sterol carrier protein 2) is a protein which seems to exist in two different forms: a 14 Kd protein (SCP-2) and a larger 58 Kd protein (SCP-x). The former is found in the cytoplasm or the mitochondria and is involved in lipid transport; the latter is found in peroxisomes. The C-terminal part of SCP-x is identical to SCP-2 while the N-terminal portion is evolutionary related to thiolases.[6]

Mechanism

Thioesters are more reactive than oxygen esters and are common intermediates in fatty-acid metabolism.[7] These thioesters are made by conjugating the fatty acid with the free SH group of the pantetheine moiety of either coenzyme A (CoA) or acyl carrier protein (ACP).

All thiolases, whether they are biosynthetic or degradative in vivo, preferentially catalyze the degradation of 3-ketoacyl-CoA to form acetyl-CoA and a shortened acyl-CoA species, but are also capable of catalyzing the reverse Claisen condensation reaction (reflecting the negative Gibbs energy change of the degradation, which is independent of the thiolase catalyzing the reaction). It is well established from studies on the biosynthetic thiolase from Z. ramigera that the thiolase reaction occurs in two steps and follows ping-pong kinetics.[8] In the first step of both the degradative and biosynthetic reactions, the nucleophilic Cys89 (or its equivalent) attacks the acyl-CoA (or 3-ketoacyl-CoA) substrate, leading to the formation of a covalent acyl-enzyme intermediate.[9] In the second step, the addition of CoA (in the degradative reaction) or acetyl-CoA (in the biosynthetic reaction) to the acyl–enzyme intermediate triggers the release of the product from the enzyme.[10] Each of the tetrahedral reaction intermediates that occur during transfer of an acetyl group to and from the nucleophilic cysteine, respectively, have been observed in X-ray crystal structures of biosynthetic thiolase from A. fumigatus.[11]

Structure

Most enzymes of the thiolase superfamily are dimers. However, monomers have not been observed. Tetramers are observed only in the thiolase subfamily and, in these cases, the dimers have dimerized to become tetramers. The crystal structure of the tetrameric biosynthetic thiolase from Zoogloea ramigera has been determined at 2.0 Å resolution. The structure contains a striking and novel ‘cage-like’ tetramerization motif, which allows for some hinge motion of the two tight dimers with respect to each other. The enzyme tetramer is acetylated at Cys89 and has a CoA molecule bound in each of itsactive-site pockets.[12]

Biological function

In eukaryotic cells, especially in mammalian cells, thiolases exhibit diversity in intracellular localization related to their metabolic functions as well as in substrate specificity. For example, they contribute to fatty-acid β-oxidation in peroxisomes and mitochondria, ketone body metabolism in mitochondria,[13] and the early steps of mevalonate pathway in peroxisomes and cytoplasm.[14] In addition to biochemical investigations, analyses of genetic disorders have made clear the basis of their functions.[15] Genetic studies have identified a three-thiolase system in the yeast Candida tropicalis, which has thiolase activity in peroxisomes, where it may participate in beta oxidation, and in the cytosol, where it participates in the mevalonate pathway.[16] [17] Thiolase is of central importance in key enzymatic pathways such as fatty-acid, steroid and polyketide synthesis. The detailed understanding of its structural biology is of great medical relevance, for example, for a better understanding of the diseases caused by genetic deficiencies of these enzymes and for the development of new antibiotics.[18] Harnessing the complicated catalytic versatility of the polyketide synthases for the synthesis of biologically and medically relevant natural products is also an important future perspective of the studies of the enzymes of this superfamily.[19]

Disease relevance

Mitochondrial acetoacetyl-CoA thiolase deficiency, known earlier as β-ketothiolase deficiency,[20] is an inborn error of metabolism involving isoleucine catabolism and ketone body metabolism. The major clinical manifestations of this disorder are intermittent ketoacidosis but the long-term clinical consequences, apparently benign, are not well documented. Mitochondrial acetoacetyl-CoA thiolase deficiency is easily diagnosed by urinary organic acid analysis and can be confirmed by enzymatic analysis of cultured skin fibroblasts or blood leukocytes.[21]

β-Ketothiolase Deficiency has a variable presentation. Most affected patients present between 5 and 24 months of age with symptoms of severe ketoacidosis. Symptoms can be initiated by a dietary protein load, infection or fever. Symptoms progress from vomiting to dehydration and ketoacidosis.[22] Neutropenia and thrombocytopenia may be present, as can moderate hyperammonemia. Blood glucose is typically normal, but can be low or high in acute episodes.[23] Developmental delay may occur, even before the first acute episode, and bilateral striatal necrosis of the basal ganglia has been seen on brain MRI.

Notes and References

  1. Thompson S, Mayerl F, Peoples OP, Masamune S, Sinskey AJ, Walsh CT . Mechanistic studies on beta-ketoacyl thiolase from Zoogloea ramigera: identification of the active-site nucleophile as Cys89, its mutation to Ser89, and kinetic and thermodynamic characterization of wild-type and mutant enzymes . Biochemistry . 28 . 14 . 5735–42 . July 1989 . 2775734 . 10.1021/bi00440a006 .
  2. Heath RJ, Rock CO . The Claisen condensation in biology . Nat Prod Rep . 19 . 5 . 581–96 . October 2002 . 12430724 . 10.1039/b110221b.
  3. Haapalainen AM, Meriläinen G, Wierenga RK . The thiolase superfamily: condensing enzymes with diverse reaction specificities . Trends Biochem. Sci. . 31 . 1 . 64–71 . January 2006 . 16356722 . 10.1016/j.tibs.2005.11.011 .
  4. Baker ME, Billheimer JT, Strauss JF . Similarity between the amino-terminal portion of mammalian 58-kD sterol carrier protein (SCPx) and Escherichia coli acetyl-CoA acyltransferase: evidence for a gene fusion in SCPx . DNA Cell Biol. . 10 . 9 . 695–8 . November 1991 . 1755959 . 10.1089/dna.1991.10.695 .
  5. Yang SY, Yang XY, Healy-Louie G, Schulz H, Elzinga M . Nucleotide sequence of the fadA gene. Primary structure of 3-ketoacyl-coenzyme A thiolase from Escherichia coli and the structural organization of the fadAB operon . J. Biol. Chem. . 265 . 18 . 10424–9 . June 1990 . 2191949 .
  6. Igual JC, González-Bosch C, Dopazo J, Pérez-Ortín JE . Phylogenetic analysis of the thiolase family. Implications for the evolutionary origin of peroxisomes . J. Mol. Evol. . 35 . 2 . 147–55 . August 1992 . 1354266 . 10.1007/BF00183226 . 39746646 .
  7. Book: Enzymatic reaction mechanisms . W. H. Freeman . San Francisco . 1979 . 978-0-7167-0070-8 .
  8. Masamune . Satoru . Walsh . Christopher T. . Gamboni . 1989 . Remo . Thompson . Stuart . Davis . Jeffrey T. . Williams . Simon F. . Peoples . Oliver P. . Sinskey . Anthony J. . Walsh . Christopher T. . Bio-Claisen condensation catalyzed by thiolase from Zoogloea ramigera. Active site cysteine residues . J. Am. Chem. Soc. . 111 . 5 . 1879, 1991 . 10.1021/ja00187a053 .
  9. Gilbert HF, Lennox BJ, Mossman CD, Carle WC . The relation of acyl transfer to the overall reaction of thiolase I from porcine heart . J. Biol. Chem. . 256 . 14 . 7371–7 . July 1981 . 6114098 .
  10. Mathieu M, Modis Y, Zeelen JP, etal . The 1.8 A crystal structure of the dimeric peroxisomal 3-ketoacyl-CoA thiolase of Saccharomyces cerevisiae: implications for substrate binding and reaction mechanism . . 273 . 3 . 714–28 . October 1997 . 9402066 . 10.1006/jmbi.1997.1331. free .
  11. Marshall . Andrew C. . Bond . Charles S. . Bruning . John B. . Structure of Aspergillus fumigatus Cytosolic Thiolase: Trapped Tetrahedral Reaction Intermediates and Activation by Monovalent Cations. . ACS Catalysis . January 25, 2018 . 8 . 3 . 1973–1989 . 10.1021/acscatal.7b02873 . 2440/113865 . free .
  12. Modis Y, Wierenga RK . A biosynthetic thiolase in complex with a reaction intermediate: the crystal structure provides new insights into the catalytic mechanism . Structure . 7 . 10 . 1279–90 . October 1999 . 10545327 . 10.1016/S0969-2126(00)80061-1. free .
  13. Middleton B . The oxoacyl-coenzyme A thiolases of animal tissues . . 132 . 4 . 717–30 . April 1973 . 4721607 . 1177647 . 10.1042/bj1320717.
  14. Hovik R, Brodal B, Bartlett K, Osmundsen H . Metabolism of acetyl-CoA by isolated peroxisomal fractions: formation of acetate and acetoacetyl-CoA . . 32 . 6 . 993–9 . June 1991 . 1682408 .
  15. Middleton B, Bartlett K . The synthesis and characterisation of 2-methylacetoacetyl coenzyme A and its use in the identification of the site of the defect in 2-methylacetoacetic and 2-methyl-3-hydroxybutyric aciduria . . 128 . 2–3 . 291–305 . March 1983 . 6133656 . 10.1016/0009-8981(83)90329-7.
  16. Kanayama N, Ueda M, Atomi H, Tanaka A . Genetic evaluation of physiological functions of thiolase isoenzymes in the n-alkalane-assimilating yeast Candida tropicalis . . 180 . 3 . 690–8 . February 1998 . 9457876 . 106940 . 10.1128/JB.180.3.690-698.1998.
  17. Ueda M, Kanayama N, Tanaka A. Genetic evaluation of peroxisomal and cytosolic acetoacetyl-CoA thiolase isozymes in n-alkane-assimilating diploid yeast, Candida tropicalis. Cell Biochemistry and Biophysics. 32. Spring. 2000. 285-290. 10.1385/cbb:32:1-3:285. 11330060.
  18. Price AC, Choi KH, Heath RJ, Li Z, White SW, Rock CO . Inhibition of beta-ketoacyl-acyl carrier protein synthases by thiolactomycin and cerulenin. Structure and mechanism . J. Biol. Chem. . 276 . 9 . 6551–9 . March 2001 . 11050088 . 10.1074/jbc.M007101200 . free .
  19. Keatinge-Clay AT, Maltby DA, Medzihradszky KF, Khosla C, Stroud RM . An antibiotic factory caught in action . Nat. Struct. Mol. Biol. . 11 . 9 . 888–93 . September 2004 . 15286722 . 10.1038/nsmb808 . 12394083 .
  20. Daum RS, Lamm PH, Mamer OA, Scriver CR . A "new" disorder of isoleucine catabolism . Lancet . 2 . 7737 . 1289–90 . December 1971 . 4143539 . 10.1016/S0140-6736(71)90605-2 .
  21. Book: Mitchell GA, Fukao T . Scriver CR, Beaudet AL, Sly WS, Valle D . The metabolic & molecular bases of inherited disease . McGraw-Hill . New York . 2001 . 2326–2356 . 978-0-07-913035-8 . Inborn errors of ketone body metabolism .
  22. Hillman RE, Keating JP . Beta-ketothiolase deficiency as a cause of the "ketotic hyperglycinemia syndrome" . Pediatrics . 53 . 2 . 221–5 . February 1974 . 4812006 .
  23. Robinson BH, Sherwood WG, Taylor J, Balfe JW, Mamer OA . Acetoacetyl CoA thiolase deficiency: a cause of severe ketoacidosis in infancy simulating salicylism . J. Pediatr. . 95 . 2 . 228–33 . August 1979 . 36452 . 10.1016/S0022-3476(79)80658-7.