Record Information |
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Version | 5.0 |
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Status | Predicted |
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Creation Date | 2021-09-21 19:29:43 UTC |
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Update Date | 2021-10-01 16:51:01 UTC |
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HMDB ID | HMDB0300882 |
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Secondary Accession Numbers | None |
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Metabolite Identification |
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Common Name | Dec-3-enedioyl-CoA |
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Description | Dec-3-enedioyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is a dec-3-enedioic acid thioester of coenzyme A. Dec-3-enedioyl-coa is an acyl-CoA with 10 fatty acid group as the acyl moiety attached to coenzyme A. Coenzyme A was discovered in 1946 by Fritz Lipmann (Journal of Biological Chemistry (1946) 162 (3): 743–744) and its structure was determined in the early 1950s at the Lister Institute in London. Coenzyme A is a complex, thiol-containing molecule that is naturally synthesized from pantothenate (vitamin B5), which is found in various foods such as meat, vegetables, cereal grains, legumes, eggs, and milk. More specifically, coenzyme A (CoASH or CoA) consists of a beta-mercaptoethylamine group linked to the vitamin pantothenic acid (B5) through an amide linkage and 3'-phosphorylated ADP. Coenzyme A is synthesized in a five-step process that requires four molecules of ATP, pantothenate and cysteine. It is believed that there are more than 1100 types of acyl-CoA’s in the human body, which also corresponds to the number of acylcarnitines in the human body. Acyl-CoAs exists in all living species, ranging from bacteria to plants to humans. The general role of acyl-CoA’s is to assist in transferring fatty acids from the cytoplasm to mitochondria. This process facilitates the production of fatty acids in cells, which are essential in cell membrane structure. Acyl-CoA's are also susceptible to beta oxidation, forming, ultimately, acetyl-CoA. Acetyl-CoA can enter the citric acid cycle, eventually forming several equivalents of ATP. In this way, fats are converted to ATP -- or biochemical energy. Acyl-CoAs can be classified into 9 different categories depending on the size of their acyl-group: 1) short-chain acyl-CoAs; 2) medium-chain acyl-CoAs; 3) long-chain acyl-CoAs; and 4) very long-chain acyl-CoAs; 5) hydroxy acyl-CoAs; 6) branched chain acyl-CoAs; 7) unsaturated acyl-CoAs; 8) dicarboxylic acyl-CoAs and 9) miscellaneous acyl-CoAs. Short-chain acyl-CoAs have acyl-groups with two to four carbons (C2-C4), medium-chain acyl-CoAs have acyl-groups with five to eleven carbons (C5-C11), long-chain acyl-CoAs have acyl-groups with twelve to twenty carbons (C12-C20) while very long-chain acyl-CoAs have acyl groups with more than 20 carbons. Dec-3-enedioyl-coa is therefore classified as a medium chain acyl-CoA. The oxidative degradation of fatty acids is a two-step process, catalyzed by acyl-CoA synthetase/synthase. Fatty acids are first converted to their acyl phosphate, the precursor to acyl-CoA. The latter conversion is mediated by acyl-CoA synthase. Three types of acyl-CoA synthases are employed, depending on the chain length of the fatty acid. Dec-3-enedioyl-coa, being a medium chain acyl-CoA is a substrate for medium chain acyl-CoA synthase. The second step of fatty acid degradation is beta oxidation. Beta oxidation occurs in mitochondria and, in the case of very long chain acyl-CoAs, the peroxisome. After its formation in the cytosol, Dec-3-enedioyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of Dec-3-enedioyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts Dec-3-enedioyl-CoA into Dec-3-enedioylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, Dec-3-enedioylcarnitine is converted back to Dec-3-enedioyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of Dec-3-enedioyl-CoA occurs in four steps. First, since Dec-3-enedioyl-CoA is a medium chain acyl-CoA it is the substrate for a medium chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of Dec-3-enedioyl-CoA, creating a double bond between the alpha and beta carbons. FAD is the hydrogen acceptor, yielding FADH2. Second, Enoyl-CoA hydrase catalyzes the addition of water across the newly formed double bond to make an alcohol. Third, 3-hydroxyacyl-CoA dehydrogenase oxidizes the alcohol group to a ketone and NADH is produced from NAD+. Finally, Thiolase cleaves between the alpha carbon and ketone to release one molecule of acetyl-CoA and a new acyl-CoA which is now 2 carbons shorter. This four-step process repeats until Dec-3-enedioyl-CoA has had all its carbons removed from the chain, leaving only acetyl-CoA. Beta oxidation, as well as alpha-oxidation, also occurs in the peroxisome. The peroxisome handles beta oxidation of fatty acids that have more than 20 carbons in their chain because the peroxisome contains very-long-chain Acyl-CoA synthetases and dehydrogenases. The heart primarily metabolizes fat for energy and Acyl-CoA metabolism has been identified as a critical molecule in early-stage heart muscle pump failure. Cellular acyl-CoA content also correlates with insulin resistance, suggesting that it can mediate lipotoxicity in non-adipose tissues. Acyl-CoA: diacylglycerol acyltransferase (DGAT) plays an important role in energy metabolism on account of key enzyme in triglyceride biosynthesis. The study of acyl-CoAs is an active area of research and it is likely that many novel acyl-CoAs will be discovered in the coming years. It is also likely that many novel roles in health and disease will be uncovered for these molecules. |
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Structure | CC(C)(COP(O)(=O)OP(O)(=O)OCC1OC(C(O)C1OP(O)(O)=O)N1C=NC2=C1N=CN=C2N)C(O)C(=O)NCCC(=O)NCCSC(=O)CCCCCC=CCC(O)=O InChI=1S/C31H50N7O19P3S/c1-31(2,26(44)29(45)34-12-11-20(39)33-13-14-61-22(42)10-8-6-4-3-5-7-9-21(40)41)16-54-60(51,52)57-59(49,50)53-15-19-25(56-58(46,47)48)24(43)30(55-19)38-18-37-23-27(32)35-17-36-28(23)38/h5,7,17-19,24-26,30,43-44H,3-4,6,8-16H2,1-2H3,(H,33,39)(H,34,45)(H,40,41)(H,49,50)(H,51,52)(H2,32,35,36)(H2,46,47,48) |
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Synonyms | Value | Source |
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10-({2-[(3-{[4-({[({[5-(6-amino-9H-purin-9-yl)-4-hydroxy-3-(phosphonooxy)oxolan-2-yl]methoxy}(hydroxy)phosphoryl)oxy](hydroxy)phosphoryl}oxy)-1,2-dihydroxy-3,3-dimethylbutylidene]amino}-1-hydroxypropylidene)amino]ethyl}sulfanyl)-10-oxodec-3-enoate | Generator | 10-({2-[(3-{[4-({[({[5-(6-amino-9H-purin-9-yl)-4-hydroxy-3-(phosphonooxy)oxolan-2-yl]methoxy}(hydroxy)phosphoryl)oxy](hydroxy)phosphoryl}oxy)-1,2-dihydroxy-3,3-dimethylbutylidene]amino}-1-hydroxypropylidene)amino]ethyl}sulphanyl)-10-oxodec-3-enoate | Generator | 10-({2-[(3-{[4-({[({[5-(6-amino-9H-purin-9-yl)-4-hydroxy-3-(phosphonooxy)oxolan-2-yl]methoxy}(hydroxy)phosphoryl)oxy](hydroxy)phosphoryl}oxy)-1,2-dihydroxy-3,3-dimethylbutylidene]amino}-1-hydroxypropylidene)amino]ethyl}sulphanyl)-10-oxodec-3-enoic acid | Generator |
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Chemical Formula | C31H50N7O19P3S |
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Average Molecular Weight | 949.75 |
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Monoisotopic Molecular Weight | 949.209504586 |
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IUPAC Name | 10-{[2-(3-{3-[({[({[5-(6-amino-9H-purin-9-yl)-4-hydroxy-3-(phosphonooxy)oxolan-2-yl]methoxy}(hydroxy)phosphoryl)oxy](hydroxy)phosphoryl}oxy)methyl]-2-hydroxy-3-methylbutanamido}propanamido)ethyl]sulfanyl}-10-oxodec-3-enoic acid |
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Traditional Name | 10-({2-[3-(3-{[({[5-(6-aminopurin-9-yl)-4-hydroxy-3-(phosphonooxy)oxolan-2-yl]methoxy(hydroxy)phosphoryl}oxy(hydroxy)phosphoryl)oxy]methyl}-2-hydroxy-3-methylbutanamido)propanamido]ethyl}sulfanyl)-10-oxodec-3-enoic acid |
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CAS Registry Number | Not Available |
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SMILES | CC(C)(COP(O)(=O)OP(O)(=O)OCC1OC(C(O)C1OP(O)(O)=O)N1C=NC2=C1N=CN=C2N)C(O)C(=O)NCCC(=O)NCCSC(=O)CCCCCC=CCC(O)=O |
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InChI Identifier | InChI=1S/C31H50N7O19P3S/c1-31(2,26(44)29(45)34-12-11-20(39)33-13-14-61-22(42)10-8-6-4-3-5-7-9-21(40)41)16-54-60(51,52)57-59(49,50)53-15-19-25(56-58(46,47)48)24(43)30(55-19)38-18-37-23-27(32)35-17-36-28(23)38/h5,7,17-19,24-26,30,43-44H,3-4,6,8-16H2,1-2H3,(H,33,39)(H,34,45)(H,40,41)(H,49,50)(H,51,52)(H2,32,35,36)(H2,46,47,48) |
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InChI Key | JWARZAYXTDOJFN-UHFFFAOYSA-N |
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Chemical Taxonomy |
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Classification | Not classified |
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Ontology |
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Physiological effect | Not Available |
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Disposition | Not Available |
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Process | Not Available |
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Role | Not Available |
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Physical Properties |
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State | Not Available |
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Experimental Molecular Properties | Property | Value | Reference |
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Melting Point | Not Available | Not Available | Boiling Point | Not Available | Not Available | Water Solubility | Not Available | Not Available | LogP | Not Available | Not Available |
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Experimental Chromatographic Properties | Not Available |
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Predicted Molecular Properties | |
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Predicted Chromatographic Properties | Predicted Collision Cross SectionsPredicted Kovats Retention IndicesNot Available |
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General References | - Abe T, Fujino T, Fukuyama R, Minoshima S, Shimizu N, Toh H, Suzuki H, Yamamoto T: Human long-chain acyl-CoA synthetase: structure and chromosomal location. J Biochem. 1992 Jan;111(1):123-8. [PubMed:1607358 ]
- Wishart DS, Li C, Marcu A, Badran H, Pon A, Budinski Z, Patron J, Lipton D, Cao X, Oler E, Li K, Paccoud M, Hong C, Guo AC, Chan C, Wei W, Ramirez-Gaona M: PathBank: a comprehensive pathway database for model organisms. Nucleic Acids Res. 2020 Jan 8;48(D1):D470-D478. doi: 10.1093/nar/gkz861. [PubMed:31602464 ]
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