Exact Mass: 1021.3397726

(S)-3-Hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

(S)-3-Hydroxyhexadecanoyl-CoA is a beta-oxidation intermediate derivative of palmitoyl-CoA and the substrate of the enzyme peroxisomal acyl-CoA thioesterase 2 (PTE-2, EC 3.1.2.2), which is localized in the peroxisome. The peroxisomal beta-oxidation system contains two sets of enzymes, one of which is involved in the oxidation of branched chain fatty acids and intermediates in the hepatic bile acid biosynthetic pathway and consists of one or two branched-chain acyl-CoA oxidase(s), a D-specific bifunctional protein and the sterol carrier-like protein x (SCPx). Peroxisomes are cellular organelles present in all eukaryotic cells. They play an indispensable role in the metabolism of a variety of lipids including very long-chain fatty acids, dicarboxylic fatty acids, bile acids, prostaglandins, leukotrienes, thromboxanes, pristanic acid, and xenobiotic fatty acids. (S)-3-Hydroxyhexadecanoyl-CoA may accumulate intracellularly in certain long-chain fatty acid/j-oxidation deficiencies. Succinate-driven synthesis of ATP from ADP and phosphate is progressively inhibited by increasing concentrations of (S)-3-Hydroxyhexadecanoyl-CoA. (PMID: 11673457, 8739955, 7662716) [HMDB] (S)-3-Hydroxyhexadecanoyl-CoA is a beta-oxidation intermediate derivative of palmitoyl-CoA and the substrate of the enzyme peroxisomal acyl-CoA thioesterase 2 (PTE-2, EC 3.1.2.2), which is localized in the peroxisome. The peroxisomal beta-oxidation system contains two sets of enzymes, one of which is involved in the oxidation of branched chain fatty acids and intermediates in the hepatic bile acid biosynthetic pathway and consists of one or two branched-chain acyl-CoA oxidase(s), a D-specific bifunctional protein and the sterol carrier-like protein x (SCPx). Peroxisomes are cellular organelles present in all eukaryotic cells. They play an indispensable role in the metabolism of a variety of lipids including very long-chain fatty acids, dicarboxylic fatty acids, bile acids, prostaglandins, leukotrienes, thromboxanes, pristanic acid, and xenobiotic fatty acids. (S)-3-Hydroxyhexadecanoyl-CoA may accumulate intracellularly in certain long-chain fatty acid/j-oxidation deficiencies. Succinate-driven synthesis of ATP from ADP and phosphate is progressively inhibited by increasing concentrations of (S)-3-Hydroxyhexadecanoyl-CoA. (PMID: 11673457, 8739955, 7662716).

3S-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

3S-hydroxyhexadecanoyl-CoA is classified as a member of the Long-chain fatty acyl CoAs. Long-chain fatty acyl CoAs are acyl CoAs where the group acylated to the coenzyme A moiety is a long aliphatic chain of 13 to 21 carbon atoms. 3S-hydroxyhexadecanoyl-CoA is considered to be slightly soluble (in water) and acidic. 3S-hydroxyhexadecanoyl-CoA is a fatty ester lipid molecule

Pentadecanedioyl-CoA

C36H62N7O19P3S (1021.3033892)

Pentadecanedioyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is a pentadecanedioic acid thioester of coenzyme A. Pentadecanedioyl-coa is an acyl-CoA with 15 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-CoAs 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. Pentadecanedioyl-coa is therefore classified as a long 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. Pentadecanedioyl-coa, being a long chain acyl-CoA is a substrate for long 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, Pentadecanedioyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of Pentadecanedioyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts Pentadecanedioyl-CoA into Pentadecanedioylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, Pentadecanedioylcarnitine is converted back to Pentadecanedioyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of Pentadecanedioyl-CoA occurs in four steps. First, since Pentadecanedioyl-CoA is a long chain acyl-CoA it is the substrate for a long chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of Pentadecanedioyl-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 pr...

16-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

16-hydroxyhexadecanoyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is a 16-hydroxyhexadecanoic acid thioester of coenzyme A. 16-hydroxyhexadecanoyl-coa is an acyl-CoA with 16 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-CoAs 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. 16-hydroxyhexadecanoyl-coa is therefore classified as a long 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. 16-hydroxyhexadecanoyl-coa, being a long chain acyl-CoA is a substrate for long 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, 16-hydroxyhexadecanoyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of 16-hydroxyhexadecanoyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts 16-hydroxyhexadecanoyl-CoA into 16-hydroxyhexadecanoylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, 16-hydroxyhexadecanoylcarnitine is converted back to 16-hydroxyhexadecanoyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of 16-hydroxyhexadecanoyl-CoA occurs in four steps. First, since 16-hydroxyhexadecanoyl-CoA is a long chain acyl-CoA it is the substrate for a long chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of 16-hydroxyhexadecanoyl-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...

(2S)-2-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

(2s)-2-hydroxyhexadecanoyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is a (2S)-2-hydroxyhexadecanoic acid thioester of coenzyme A. (2s)-2-hydroxyhexadecanoyl-coa is an acyl-CoA with 16 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-CoAs 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. (2s)-2-hydroxyhexadecanoyl-coa is therefore classified as a long 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. (2s)-2-hydroxyhexadecanoyl-coa, being a long chain acyl-CoA is a substrate for long 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, (2S)-2-hydroxyhexadecanoyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of (2S)-2-hydroxyhexadecanoyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts (2S)-2-hydroxyhexadecanoyl-CoA into (2S)-2-hydroxyhexadecanoylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, (2S)-2-hydroxyhexadecanoylcarnitine is converted back to (2S)-2-hydroxyhexadecanoyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of (2S)-2-hydroxyhexadecanoyl-CoA occurs in four steps. First, since (2S)-2-hydroxyhexadecanoyl-CoA is a long chain acyl-CoA it is the substrate for a long chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of (2S)-2-hydroxyhexadecanoyl-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 t...

5-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

5-hydroxyhexadecanoyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is a 5-hydroxyhexadecanoic acid thioester of coenzyme A. 5-hydroxyhexadecanoyl-coa is an acyl-CoA with 16 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-CoAs 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. 5-hydroxyhexadecanoyl-coa is therefore classified as a long 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. 5-hydroxyhexadecanoyl-coa, being a long chain acyl-CoA is a substrate for long 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, 5-hydroxyhexadecanoyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of 5-hydroxyhexadecanoyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts 5-hydroxyhexadecanoyl-CoA into 5-hydroxyhexadecanoylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, 5-hydroxyhexadecanoylcarnitine is converted back to 5-hydroxyhexadecanoyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of 5-hydroxyhexadecanoyl-CoA occurs in four steps. First, since 5-hydroxyhexadecanoyl-CoA is a long chain acyl-CoA it is the substrate for a long chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of 5-hydroxyhexadecanoyl-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-C...

7-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

7-hydroxyhexadecanoyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is a 7-hydroxyhexadecanoic acid thioester of coenzyme A. 7-hydroxyhexadecanoyl-coa is an acyl-CoA with 16 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-CoAs 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. 7-hydroxyhexadecanoyl-coa is therefore classified as a long 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. 7-hydroxyhexadecanoyl-coa, being a long chain acyl-CoA is a substrate for long 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, 7-hydroxyhexadecanoyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of 7-hydroxyhexadecanoyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts 7-hydroxyhexadecanoyl-CoA into 7-hydroxyhexadecanoylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, 7-hydroxyhexadecanoylcarnitine is converted back to 7-hydroxyhexadecanoyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of 7-hydroxyhexadecanoyl-CoA occurs in four steps. First, since 7-hydroxyhexadecanoyl-CoA is a long chain acyl-CoA it is the substrate for a long chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of 7-hydroxyhexadecanoyl-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-C...

8-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

8-hydroxyhexadecanoyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is an 8-hydroxyhexadecanoic acid thioester of coenzyme A. 8-hydroxyhexadecanoyl-coa is an acyl-CoA with 16 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-CoAs 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. 8-hydroxyhexadecanoyl-coa is therefore classified as a long 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. 8-hydroxyhexadecanoyl-coa, being a long chain acyl-CoA is a substrate for long 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, 8-hydroxyhexadecanoyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of 8-hydroxyhexadecanoyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts 8-hydroxyhexadecanoyl-CoA into 8-hydroxyhexadecanoylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, 8-hydroxyhexadecanoylcarnitine is converted back to 8-hydroxyhexadecanoyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of 8-hydroxyhexadecanoyl-CoA occurs in four steps. First, since 8-hydroxyhexadecanoyl-CoA is a long chain acyl-CoA it is the substrate for a long chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of 8-hydroxyhexadecanoyl-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-...

9-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

9-hydroxyhexadecanoyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is a 9-hydroxyhexadecanoic acid thioester of coenzyme A. 9-hydroxyhexadecanoyl-coa is an acyl-CoA with 16 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-CoAs 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. 9-hydroxyhexadecanoyl-coa is therefore classified as a long 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. 9-hydroxyhexadecanoyl-coa, being a long chain acyl-CoA is a substrate for long 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, 9-hydroxyhexadecanoyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of 9-hydroxyhexadecanoyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts 9-hydroxyhexadecanoyl-CoA into 9-hydroxyhexadecanoylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, 9-hydroxyhexadecanoylcarnitine is converted back to 9-hydroxyhexadecanoyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of 9-hydroxyhexadecanoyl-CoA occurs in four steps. First, since 9-hydroxyhexadecanoyl-CoA is a long chain acyl-CoA it is the substrate for a long chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of 9-hydroxyhexadecanoyl-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-C...

10-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

10-hydroxyhexadecanoyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is a 10-hydroxyhexadecanoic acid thioester of coenzyme A. 10-hydroxyhexadecanoyl-coa is an acyl-CoA with 16 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-CoAs 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. 10-hydroxyhexadecanoyl-coa is therefore classified as a long 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. 10-hydroxyhexadecanoyl-coa, being a long chain acyl-CoA is a substrate for long 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, 10-hydroxyhexadecanoyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of 10-hydroxyhexadecanoyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts 10-hydroxyhexadecanoyl-CoA into 10-hydroxyhexadecanoylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, 10-hydroxyhexadecanoylcarnitine is converted back to 10-hydroxyhexadecanoyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of 10-hydroxyhexadecanoyl-CoA occurs in four steps. First, since 10-hydroxyhexadecanoyl-CoA is a long chain acyl-CoA it is the substrate for a long chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of 10-hydroxyhexadecanoyl-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...

11-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

11-hydroxyhexadecanoyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is an 11-hydroxyhexadecanoic acid thioester of coenzyme A. 11-hydroxyhexadecanoyl-coa is an acyl-CoA with 16 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-CoAs 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. 11-hydroxyhexadecanoyl-coa is therefore classified as a long 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. 11-hydroxyhexadecanoyl-coa, being a long chain acyl-CoA is a substrate for long 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, 11-hydroxyhexadecanoyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of 11-hydroxyhexadecanoyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts 11-hydroxyhexadecanoyl-CoA into 11-hydroxyhexadecanoylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, 11-hydroxyhexadecanoylcarnitine is converted back to 11-hydroxyhexadecanoyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of 11-hydroxyhexadecanoyl-CoA occurs in four steps. First, since 11-hydroxyhexadecanoyl-CoA is a long chain acyl-CoA it is the substrate for a long chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of 11-hydroxyhexadecanoyl-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, ...

12-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

12-hydroxyhexadecanoyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is a 12-hydroxyhexadecanoic acid thioester of coenzyme A. 12-hydroxyhexadecanoyl-coa is an acyl-CoA with 16 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-CoAs 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. 12-hydroxyhexadecanoyl-coa is therefore classified as a long 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. 12-hydroxyhexadecanoyl-coa, being a long chain acyl-CoA is a substrate for long 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, 12-hydroxyhexadecanoyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of 12-hydroxyhexadecanoyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts 12-hydroxyhexadecanoyl-CoA into 12-hydroxyhexadecanoylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, 12-hydroxyhexadecanoylcarnitine is converted back to 12-hydroxyhexadecanoyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of 12-hydroxyhexadecanoyl-CoA occurs in four steps. First, since 12-hydroxyhexadecanoyl-CoA is a long chain acyl-CoA it is the substrate for a long chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of 12-hydroxyhexadecanoyl-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...

13-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

13-hydroxyhexadecanoyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is a 13-hydroxyhexadecanoic acid thioester of coenzyme A. 13-hydroxyhexadecanoyl-coa is an acyl-CoA with 16 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-CoAs 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. 13-hydroxyhexadecanoyl-coa is therefore classified as a long 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. 13-hydroxyhexadecanoyl-coa, being a long chain acyl-CoA is a substrate for long 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, 13-hydroxyhexadecanoyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of 13-hydroxyhexadecanoyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts 13-hydroxyhexadecanoyl-CoA into 13-hydroxyhexadecanoylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, 13-hydroxyhexadecanoylcarnitine is converted back to 13-hydroxyhexadecanoyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of 13-hydroxyhexadecanoyl-CoA occurs in four steps. First, since 13-hydroxyhexadecanoyl-CoA is a long chain acyl-CoA it is the substrate for a long chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of 13-hydroxyhexadecanoyl-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...

6-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

6-hydroxyhexadecanoyl-coa is an acyl-CoA or acyl-coenzyme A. More specifically, it is a 6-hydroxyhexadecanoic acid thioester of coenzyme A. 6-hydroxyhexadecanoyl-coa is an acyl-CoA with 16 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-CoAs 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. 6-hydroxyhexadecanoyl-coa is therefore classified as a long 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. 6-hydroxyhexadecanoyl-coa, being a long chain acyl-CoA is a substrate for long 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, 6-hydroxyhexadecanoyl-CoA is transported into the mitochondria, the locus of beta oxidation. Transport of 6-hydroxyhexadecanoyl-CoA into the mitochondria requires carnitine palmitoyltransferase 1 (CPT1), which converts 6-hydroxyhexadecanoyl-CoA into 6-hydroxyhexadecanoylcarnitine, which gets transported into the mitochondrial matrix. Once in the matrix, 6-hydroxyhexadecanoylcarnitine is converted back to 6-hydroxyhexadecanoyl-CoA by CPT2, whereupon beta-oxidation can begin. Beta oxidation of 6-hydroxyhexadecanoyl-CoA occurs in four steps. First, since 6-hydroxyhexadecanoyl-CoA is a long chain acyl-CoA it is the substrate for a long chain acyl-CoA dehydrogenase, which catalyzes dehydrogenation of 6-hydroxyhexadecanoyl-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-C...

micropeptin HU1021

C40H63N9O18S2 (1021.3732298)

16-hydroxypalmitoyl-CoA

C37H66N7O18P3S (1021.3397726)

3S-hydroxy-octanoyl-CoA

C37H66N7O18P3S (1021.3397726)

3-hydroxypalmitoyl-CoA

C37H66N7O18P3S (1021.3397726)

CoA 16:0;O

C37H66N7O18P3S (1021.3397726)

3-Hydroxyhexadecanoyl-coenzyme A

C37H66N7O18P3S (1021.3397726)

(R)-3-hydroxypalmitoyl-CoA

C37H66N7O18P3S (1021.3397726)

A 3-hydroxy fatty acyl-CoA that results from the formal condensation of the thiol group of coenzyme A with the carboxy group of (R)-3-hydroxypalmitic acid.

(R)-2-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

Pentadecanedioyl-CoA

C36H62N7O19P3S (1021.3033892)

5-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

7-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

8-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

9-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

6-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

10-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

11-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

12-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

13-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

S-[2-[3-[[4-[[[5-(6-aminopurin-9-yl)-4-hydroxy-3-phosphonooxyoxolan-2-yl]methoxy-hydroxyphosphoryl]oxy-hydroxyphosphoryl]oxy-2-hydroxy-3,3-dimethylbutanoyl]amino]propanoylamino]ethyl] 16-hydroxyhexadecanethioate

C37H66N7O18P3S (1021.3397726)

2-carboxymyristoyl-CoA

C36H62N7O19P3S (1021.3033892)

A 2-carboxyacyl-CoA that results from the formal condensation of the thiol group of coenzyme A with the carboxy group of 2-carboxymyristic acid.

(S)-3-hydroxypalmitoyl-CoA

C37H66N7O18P3S (1021.3397726)

A long-chain (3S)-hydroxy fatty acyl-CoA that results from the formal condensation of the thiol group of coenzyme A with the carboxy group of (S)-3-hydroxypalmitic acid.

16-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

An omega-hydroxy fatty acyl-CoA that results from the formal condensation of the thiol group of coenzyme A with the carboxy group of 16-hydroxyhexadecanoic acid.

3S-hydroxyhexadecanoyl-CoA

C37H66N7O18P3S (1021.3397726)

2-hydroxypalmitoyl-CoA

C37H66N7O18P3S (1021.3397726)

A hydroxy fatty-acyl-CoA that results from the formal condensation of the thiol group of coenzyme A with the carboxy group of 2-hydroxypalmitic acid.

Hydroxypalmitoyl-CoA

C37H66N7O18P3S (1021.3397726)