2.02012-05-31 13:47:40 -06002015-06-03 15:53:51 -0600ECMDB01206M2MDB000298Acetyl-CoAAcetyl-CoA is the thioester formed between coenzyme A (a thiol) and acetic acid (an acyl group carrier). Acetyl-CoA is produced during the second step of aerobic cellular respiration, pyruvate decarboxylation. Its main function is to convey the carbon atoms within the acetyl group to the citric acid cycle (Krebs cycle) to be oxidized for energy production. Ac-<i>S</i>-CoAAc-CoAAc-Coenzyme AAc-S-CoAAc-S-Coenzyme AAcCoAAcetyl coenzyme AAcetyl coenzyme-AAcetyl-<i>S</i>-CoAAcetyl-CoAAcetyl-Coenzyme AAcetyl-S-CoAAcetyl-S-Coenzyme AAcetylcoenzyme AAcetylcoenzyme-AS-Acetate CoAS-Acetate Coenzyme AS-Acetic acid CoAS-Acetic acid Coenzyme AS-Acetyl coenzyme AC23H38N7O17P3S809.571809.125773051{[(2R,3S,4R,5R)-2-({[({[(3R)-3-[(2-{[2-(acetylsulfanyl)ethyl]carbamoyl}ethyl)carbamoyl]-3-hydroxy-2,2-dimethylpropoxy](hydroxy)phosphoryl}oxy)(hydroxy)phosphoryl]oxy}methyl)-5-(6-amino-9H-purin-9-yl)-4-hydroxyoxolan-3-yl]oxy}phosphonic acidacetyl-CoA72-89-9CC(=O)SCCNC(=O)CCNC(=O)[C@H](O)C(C)(C)COP(O)(=O)OP(O)(=O)OC[C@H]1O[C@H]([C@H](O)[C@@H]1OP(O)(O)=O)N1C=NC2=C1N=CN=C2NInChI=1S/C23H38N7O17P3S/c1-12(31)51-7-6-25-14(32)4-5-26-21(35)18(34)23(2,3)9-44-50(41,42)47-49(39,40)43-8-13-17(46-48(36,37)38)16(33)22(45-13)30-11-29-15-19(24)27-10-28-20(15)30/h10-11,13,16-18,22,33-34H,4-9H2,1-3H3,(H,25,32)(H,26,35)(H,39,40)(H,41,42)(H2,24,27,28)(H2,36,37,38)/t13-,16-,17-,18+,22-/m1/s1ZSLZBFCDCINBPY-ZSJPKINUSA-NSolidCytosollogp-0.58logs-2.27solubility4.30e+00 g/llogp-5.9pka_strongest_acidic0.82pka_strongest_basic4.01iupac{[(2R,3S,4R,5R)-2-({[({[(3R)-3-[(2-{[2-(acetylsulfanyl)ethyl]carbamoyl}ethyl)carbamoyl]-3-hydroxy-2,2-dimethylpropoxy](hydroxy)phosphoryl}oxy)(hydroxy)phosphoryl]oxy}methyl)-5-(6-amino-9H-purin-9-yl)-4-hydroxyoxolan-3-yl]oxy}phosphonic acidaverage_mass809.571mono_mass809.125773051smilesCC(=O)SCCNC(=O)CCNC(=O)[C@H](O)C(C)(C)COP(O)(=O)OP(O)(=O)OC[C@H]1O[C@H]([C@H](O)[C@@H]1OP(O)(O)=O)N1C=NC2=C1N=CN=C2NformulaC23H38N7O17P3SinchiInChI=1S/C23H38N7O17P3S/c1-12(31)51-7-6-25-14(32)4-5-26-21(35)18(34)23(2,3)9-44-50(41,42)47-49(39,40)43-8-13-17(46-48(36,37)38)16(33)22(45-13)30-11-29-15-19(24)27-10-28-20(15)30/h10-11,13,16-18,22,33-34H,4-9H2,1-3H3,(H,25,32)(H,26,35)(H,39,40)(H,41,42)(H2,24,27,28)(H2,36,37,38)/t13-,16-,17-,18+,22-/m1/s1inchikeyZSLZBFCDCINBPY-ZSJPKINUSA-Npolar_surface_area363.63refractivity172.21polarizability70.62rotatable_bond_count20acceptor_count17donor_count9physiological_charge-4formal_charge0Glutathione metabolismThe biosynthesis of glutathione starts with the introduction of L-glutamic acid through either a glutamate:sodium symporter, glutamate / aspartate : H+ symporter GltP or a
glutamate / aspartate ABC transporter. Once in the cytoplasm, L-glutamice acid reacts with L-cysteine through an ATP glutamate-cysteine ligase resulting in gamma-glutamylcysteine. This compound reacts which Glycine through an ATP driven glutathione synthetase thus catabolizing Glutathione.
This compound is metabolized through a spontaneous reaction with an oxidized glutaredoxin resulting in a reduced glutaredoxin and an oxidized glutathione. This compound is reduced by a NADPH glutathione reductase resulting in a glutathione.
PW000833ec00480MetabolicCitrate cycle (TCA cycle)ec00020Benzoate degradation via CoA ligationec00632Butanoate metabolismec00650Reductive carboxylate cycle (CO2 fixation)ec00720Arginine and proline metabolismec00330Cysteine and methionine metabolismec00270Phenylalanine metabolismThe pathways of the metabolism of phenylalaline begins with the conversion of chorismate to prephenate through a P-protein (chorismate mutase:pheA). Prephenate then interacts with a hydrogen ion through the same previous enzyme resulting in a release of carbon dioxide, water and a phenolpyruvic acid. Three enzymes those enconde by tyrB, aspC and ilvE are involved in catalyzing the third step of these pathways, all three can contribute to the synthesis of phenylalanine: only tyrB and aspC contribute to biosynthesis of tyrosine.
Phenolpyruvic acid can also be obtained from a reversivle reaction with ammonia, a reduced acceptor and a D-amino acid dehydrogenase, resulting in a water, an acceptor and a D-phenylalanine, which can be then transported into the periplasmic space by aromatic amino acid exporter.
L-phenylalanine also interacts in two reversible reactions, one involved with oxygen through a catalase peroxidase resulting in a carbon dioxide and 2-phenylacetamide. The other reaction involved an interaction with oxygen through a phenylalanine aminotransferase resulting in a oxoglutaric acid and phenylpyruvic acid.
L-phenylalanine can be imported into the cytoplasm through an aromatic amino acid:H+ symporter AroP.
The compound can also be imported into the periplasmic space through a transporter: L-amino acid efflux transporter.PW000921ec00360MetabolicGlycine, serine and threonine metabolismec00260Glycolysis / Gluconeogenesisec00010Lysine biosynthesisLysine is biosynthesized from L-aspartic acid. L-aspartic acid can be incorporated into the cell through various methods: C4 dicarboxylate / orotate:H+ symporter ,
glutamate / aspartate : H+ symporter GltP, dicarboxylate transporter , C4 dicarboxylate / C4 monocarboxylate transporter DauA, glutamate / aspartate ABC transporter
L-aspartic acid is phosphorylated by an ATP-driven Aspartate kinase resulting in ADP and L-aspartyl-4-phosphate. L-aspartyl-4-phosphate is then dehydrogenated through an NADPH driven aspartate semialdehyde dehydrogenase resulting in a release of phosphate, NADP and L-aspartic 4-semialdehyde (involved in methionine biosynthesis).
L-aspartic 4-semialdehyde interacts with a pyruvic acid through a 4-hydroxy-tetrahydrodipicolinate synthase resulting in a release of hydrogen ion, water and
(2S,4S)-4-hydroxy-2,3,4,5-tetrahydrodipicolinate. The latter compound is then reduced by an NADPH driven 4-hydroxy-tetrahydrodipicolinate reductase resulting in a release of water, NADP and (S)-2,3,4,5-tetrahydrodipicolinate, This compound interacts with succinyl-CoA and water through a tetrahydrodipicolinate succinylase resulting in a release of coenzyme A and N-Succinyl-2-amino-6-ketopimelate. This compound interacts with L-glutamic acid through a N-succinyldiaminopimelate aminotransferase resulting in oxoglutaric acid, N-succinyl-L,L-2,6-diaminopimelate. The latter compound is then desuccinylated by reacting with water through a N-succinyl-L-diaminopimelate desuccinylase resulting in a succinic acid and L,L-diaminopimelate. This compound is then isomerized through a diaminopimelate epimerase resulting in a meso-diaminopimelate (involved in peptidoglyccan biosynthesis I). This compound is then decarboxylated by a diaminopimelate decarboxylase resulting in a release of carbon dioxide and L-lysine.
L-lysine is then incorporated into lysine degradation pathway. Lysine also regulate its own biosynthesis by repressing dihydrodipicolinate synthase and also repressing lysine-sensitive aspartokinase 3.
A metabolic connection joins synthesis of an amino acid, lysine, to synthesis of cell wall material. Diaminopimelate is a precursor both for lysine and for cell wall components. The synthesis of lysine, methionine and threonine share two reactions at the start of the three pathways, the reactions converting L-aspartate to L-aspartate semialdehyde. The reaction involving aspartate kinase is carried out by three isozymes, one specific for synthesis of each end product amino acid. Each of the three aspartate kinase isozymes is regulated by its corresponding end product amino acid.PW000771ec00300MetabolicPyruvate metabolismec00620Methane metabolismec00680Valine, leucine and isoleucine biosynthesisec00290Sulfur metabolismThe sulfur metabolism pathway starts in three possible ways. The first is the uptake of sulfate through an active transport reaction via a sulfate transport system containing an ATP-binding protein which hydrolyses ATP. Sulfate is converted by the sulfate adenylyltransferase enzymatic complex to adenosine phosphosulfate through the addition of adenine from a molecule of ATP, along with one phosphate group. Adenosine phosphosulfate is further converted to phoaphoadenosine phosphosulfate through an ATP hydrolysis and dehydrogenation reaction by the adenylyl-sulfate kinase. Phoaphoadenosine phosphosulfate is finally dehydrogenated and converted to sulfite by phosphoadenosine phosphosulfate reductase. This reaction requires magnesium, and adenosine 3',5'-diphosphate is the bi-product. A thioredoxin is also oxidized. Sulfite can also be produced from the dehydrogenation of cyanide along with the conversion of thiosulfate to thiocyanate by the thiosulfate sulfurtransferase enzymatic complex. Sulfite next undergoes a series of reactions that lead to the production of pyruvic acid, which is a precursor for pathways such as gluconeogenesis. The first reaction in this series is the conversion of sulfite to hydrogen sulfide through hygrogenation and the deoxygenation of sulfite to form a water molecule. The reaction is catalyzed by the sulfite reductase [NADPH] flavoprotein alpha and beta components. Siroheme, 4Fe-4S, flavin mononucleotide, and FAD function as cofactors or prosthetic groups. Hydrogen sulfide next undergoes dehydrogenation in a reversible reaction to form L-Cysteine and acetic acid, via the cysteine synthase complex and the coenzyme pyridoxal 5'-phosphate. L-Cysteine is dehydrogenated and converted to 2-aminoacrylic acid (a bronsted acid) and hydrogen sulfide(which may be reused) by a larger enzymatic complex composed of cysteine synthase A/B, protein malY, cystathionine-β-lyase, and tryptophanase, along with the coenzyme pyridoxal 5'-phosphate. 2-aminoacrylic acid isomerizes to 2-iminopropanoate, which along with a water molecule and a hydrogen ion is lastly converted to pyruvic acid and ammonium in a spontaneous fashion.
The second possible initial starting point for sulfur metabolism is the import of taurine(an alternate sulfur source) into the cytoplasm via the taurine ABC transporter complex. Taurine, oxoglutaric acid, and oxygen are converted to sulfite by the alpha-ketoglutarate-dependent taurine dioxygenase. Carbon dioxide, succinic acid, and aminoacetaldehyde are bi-products of this reaction. Sulfite next enters pyruvic acid synthesis as already described.
The third variant of sulfur metabolism starts with the import of an alkyl sulfate into the cytoplasm via an aliphatic sulfonate ABC transporter complex which hydrolyses ATP. The alkyl sulfate is dehydrogenated and along with oxygen is converted to sulfite and an aldehyde by the FMNH2-dependent alkanesulfonate monooxygenase enzyme. Water and flavin mononucleotide(which is used in a subsequent reaction as a prosthetic group) are also produced. Sulfite is next converted to pyruvic acid by the process already described.PW000922ec00920MetabolicTryptophan metabolismThe biosynthesis of L-tryptophan begins with L-glutamine interacting with a chorismate through a anthranilate synthase which results in a L-glutamic acid, a pyruvic acid, a hydrogen ion and a 2-aminobenzoic acid. The aminobenzoic acid interacts with a phosphoribosyl pyrophosphate through an anthranilate synthase component II resulting in a pyrophosphate and a N-(5-phosphoribosyl)-anthranilate. The latter compound is then metabolized by an indole-3-glycerol phosphate synthase / phosphoribosylanthranilate isomerase resulting in a 1-(o-carboxyphenylamino)-1-deoxyribulose 5'-phosphate. This compound then interacts with a hydrogen ion through a indole-3-glycerol phosphate synthase / phosphoribosylanthranilate isomerase resulting in the release of carbon dioxide, a water molecule and a (1S,2R)-1-C-(indol-3-yl)glycerol 3-phosphate. The latter compound then interacts with a D-glyceraldehyde 3-phosphate and an Indole. The indole interacts with an L-serine through a tryptophan synthase, β subunit dimer resulting in a water molecule and an L-tryptophan.
The metabolism of L-tryptophan starts with L-tryptophan being dehydrogenated by a tryptophanase / L-cysteine desulfhydrase resulting in the release of a hydrogen ion, an Indole and a 2-aminoacrylic acid. The latter compound is isomerized into a 2-iminopropanoate. This compound then interacts with a water molecule and a hydrogen ion spontaneously resulting in the release of an Ammonium and a pyruvic acid. The pyruvic acid then interacts with a coenzyme A through a NAD driven pyruvate dehydrogenase complex resulting in the release of a NADH, a carbon dioxide and an Acetyl-CoA
PW000815ec00380MetabolicLipopolysaccharide biosynthesisE. coli lipid A is synthesized on the cytoplasmic surface of the inner membrane. The pathway can start from the fructose 6-phosphate that is either produced in the glycolysis and pyruvate dehydrogenase or be obtained from the interaction with D-fructose interacting with a mannose PTS permease. Fructose 6-phosphate interacts with L-glutamine through a D-fructose-6-phosphate aminotransferase resulting into a L-glutamic acid and a glucosamine 6-phosphate. The latter compound is isomerized through a phosphoglucosamine mutase resulting a glucosamine 1-phosphate. This compound is acetylated, interacting with acetyl-CoA through a bifunctional protein glmU resulting in a Coenzyme A, hydrogen ion and N-acetyl-glucosamine 1-phosphate. This compound interact with UTP and hydrogen ion through the bifunctional protein glmU resulting in a pyrophosphate and a UDP-N-acetylglucosamine. This compound interacts with (3R)-3-hydroxymyristoyl-[acp] through an UDP-N-acetylglucosamine acyltransferase resulting in a holo-[acp] and a UDP-3-O[(3R)-3-hydroxymyristoyl]-N-acetyl-alpha-D-glucosamine. This compound interacts with water through UDP-3-O-acyl-N-acetylglucosamine deacetylase resulting in an acetic acid and UDP-3-O-(3-hydroxymyristoyl)-α-D-glucosamine. The latter compound interacts with (3R)-3-hydroxymyristoyl-[acp] through
UDP-3-O-(R-3-hydroxymyristoyl)-glucosamine N-acyltransferase releasing a hydrogen ion, a holo-acp and UDP-2-N,3-O-bis[(3R)-3-hydroxytetradecanoyl]-α-D-glucosamine. The latter compound is hydrolase by interacting with water and a UDP-2,3-diacylglucosamine hydrolase resulting in UMP, hydrogen ion and 2,3-bis[(3R)-3-hydroxymyristoyl]-α-D-glucosaminyl 1-phosphate. This last compound then interacts with a UDP-2-N,3-O-bis[(3R)-3-hydroxytetradecanoyl]-α-D-glucosamine through a lipid A disaccharide synthase resulting in a release of UDP, hydrogen ion and a lipid A disaccharide. The lipid A disaccharide is phosphorylated by an ATP mediated
tetraacyldisaccharide 4'-kinase resulting in the release of hydrogen ion and lipid IVA.
A D-ribulose 5-phosphate is isomerized with D-arabinose 5-phosphate isomerase 2 to result in a D-arabinose 5-phosphate. This compounds interacts with water and phosphoenolpyruvic acid through a 3-deoxy-D-manno-octulosonate 8-phosphate synthase resulting in the release of phosphate and 3-deoxy-D-manno-octulosonate 8-phosphate. This compound interacts with water through a 3-deoxy-D-manno-octulosonate 8-phosphate phosphatase thus releasing a phosphate and a 3-deoxy-D-manno-octulosonate. The latter compound interacts with CTP through a 3-deoxy-D-manno-octulosonate cytidylyltransferase resulting in a pyrophosphate and
CMP-3-deoxy-α-D-manno-octulosonate.
CMP-3-deoxy-α-D-manno-octulosonate and lipid IVA interact with each other through a KDO transferase resulting in CMP, hydrogen ion and alpha-Kdo-(2-->6)-lipid IVA. The latter compound reacts with CMP-3-deoxy-α-D-manno-octulosonate through a KDO transferase resulting in a CMP, hydrogen ion, and a a-Kdo-(2->4)-a-Kdo-(2->6)-lipid IVA. The latter compound interacts with a dodecanoyl-[acp] lauroyl acyltransferase resulting in a holo-[acp] and a (KDO)2-(lauroyl)-lipid IVA. The latter compound reacts with a myristoyl-[acp] through a myristoyl-acyl carrier protein (ACP)-dependent acyltransferase resulting in a holo-[acp], (KDO)2-lipid A. The latter compound reacts with ADP-L-glycero-beta-D-manno-heptose through ADP-heptose:LPS heptosyltransferase I resulting hydrogen ion, ADP, heptosyl-KDO2-lipid A. The latter compound interacts with ADP-L-glycero-beta-D-manno-heptose through ADP-heptose:LPS heptosyltransferase II resulting in ADP, hydrogen ion and (heptosyl)2-Kdo2-lipid A. The latter compound UDP-glucose interacts with (heptosyl)2-Kdo2-lipid A resulting in UDP, hydrogen ion and glucosyl-(heptosyl)2-Kdo2-lipid A. Glucosyl-(heptosyl)2-Kdo2-lipid A (Escherichia coli) is phosphorylated through an ATP-mediated lipopolysaccharide core heptose (I) kinase resulting in ADP, hydrogen ion and glucosyl-(heptosyl)2-Kdo2-lipid A-phosphate.
The latter compound interacts with ADP-L-glycero-beta-D-manno-heptose through a lipopolysaccharide core heptosyl transferase III resulting in ADP, hydrogen ion, and glucosyl-(heptosyl)3-Kdo2-lipid A-phosphate. The latter compound is phosphorylated through an ATP-driven lipopolysaccharide core heptose (II) kinase resulting in ADP, hydrogen ion and glucosyl-(heptosyl)3-Kdo2-lipid A-bisphosphate. The latter compound interacts with UDP-alpha-D-galactose through a UDP-D-galactose:(glucosyl)lipopolysaccharide-1,6-D-galactosyltransferase resulting in a UDP, a hydrogen ion and a galactosyl-glucosyl-(heptosyl)3-Kdo2-lipid A-bisphosphate. The latter compound interacts with UDP-glucose through a (glucosyl)LPS α-1,3-glucosyltransferase resulting in a hydrogen ion, a UDP and galactosyl-(glucosyl)2-(heptosyl)3-Kdo2-lipid A-bisphosphate. This compound then interacts with UDP-glucose through a UDP-glucose:(glucosyl)LPS α-1,2-glucosyltransferase resulting in UDP, a hydrogen ion and galactosyl-(glucosyl)3-(heptosyl)3-Kdo2-lipid A-bisphosphate. This compound then interacts with ADP-L-glycero-beta-D-manno-heptose through a lipopolysaccharide core biosynthesis; heptosyl transferase IV; probably hexose transferase resulting in a Lipid A-core.
A lipid A-core is then exported into the periplasmic space by a lipopolysaccharide ABC transporter.
The lipid A-core is then flipped to the outer surface of the inner membrane by the ATP-binding cassette (ABC) transporter, MsbA. An additional integral membrane protein, YhjD, has recently been implicated in LPS export across the IM. The smallest LPS derivative that supports viability in E. coli is lipid IVA. However, it requires mutations in either MsbA or YhjD, to suppress the normally lethal consequence of an incomplete lipid A . Recent studies with deletion mutants implicate the periplasmic protein LptA, the cytosolic protein LptB, and the IM proteins LptC, LptF, and LptG in the subsequent transport of nascent LPS to the outer membrane (OM), where the LptD/LptE complex flips LPS to the outer surface. PW000831ec00540MetabolicGlyoxylate and dicarboxylate metabolismec00630Inositol phosphate metabolismec00562beta-Alanine metabolismThe Beta-Alanine Metabolism starts with a product of Aspartate metabolism. Aspartate is decarboxylated by aspartate 1-decarboxylase, releasing carbon dioxide and Beta-alanine. Beta alanine is then metabolized through a pantothenate synthetase resulting in Pantothenic acid undergoes phosphorylation through a ATP driven pantothenate kinase, resulting in D-4-phosphopantothenate.
Pantothenate (vitamin B5) is the universal precursor for the synthesis of the 4'-phosphopantetheine moiety of coenzyme A and acyl carrier protein. Only plants and microorganismscan synthesize pantothenate de novo - animals require a dietary supplement. The enzymes of this pathway are therefore considered to be antimicrobial drug targets.PW000896ec00410MetabolicPropanoate metabolism
Starting from L-threonine, this compound is deaminated through a threonine deaminase resulting in a hydrogen ion, a water molecule and a (2z)-2-aminobut-2-enoate. The latter compound then isomerizes to a 2-iminobutanoate, This compound then reacts spontaneously with hydrogen ion and a water molecule resulting in a ammonium and a 2-Ketobutyric acid. The latter compound interacts with CoA through a pyruvate formate-lyase / 2-ketobutyrate formate-lyase resulting in a formic acid and a propionyl-CoA.
Propionyl-CoA can then be processed either into a 2-methylcitric acid or into a propanoyl phosphate.
Propionyl-CoA interacts with oxalacetic acid and a water molecule through a 2-methylcitrate synthase resulting in a hydrogen ion, a CoA and a 2-Methylcitric acid.The latter compound is dehydrated through a 2-methylcitrate dehydratase resulting in a water molecule and cis-2-methylaconitate. The latter compound is then dehydrated by a
bifunctional aconitate hydratase 2 and 2-methylisocitrate dehydratase resulting in a water molecule and methylisocitric acid. The latter compound is then processed by 2-methylisocitrate lyase resulting in a release of succinic acid and pyruvic acid.
Succinic acid can then interact with a propionyl-CoA through a propionyl-CoA:succinate CoA transferase resulting in a propionic acid and a succinyl CoA. Succinyl-CoA is then isomerized through a methylmalonyl-CoA mutase resulting in a methylmalonyl-CoA. This compound is then decarboxylated through a methylmalonyl-CoA decarboxylase resulting in a release of Carbon dioxide and Propionyl-CoA.
ropionyl-CoA interacts with a phosphate through a phosphate acetyltransferase / phosphate propionyltransferase resulting in a CoA and a propanoyl phosphate.
Propionyl-CoA can react with a phosphate through a phosphate acetyltransferase / phosphate propionyltransferase resulting in a CoA and a propanoyl phosphate. The latter compound is then dephosphorylated through a ADP driven acetate kinase/propionate kinase protein complex resulting in an ATP and Propionic acid.
Propionic acid can be processed by a reaction with CoA through a ATP-driven propionyl-CoA synthetase resulting in a pyrophosphate, an AMP and a propionyl-CoA.PW000940ec00640MetabolicTaurine and hypotaurine metabolismec00430Fatty acid biosynthesisThe fatty acid biosynthesis starts from acetyl-CoA reacting either with a holo-[acp] through a 3-oxoacyl-[acp] synthase 3 resulting in an acetyl-[acp] or react with hydrogen carbonate through an ATP driven acetyl-CoA carboxylase resulting in a malonyl-CoA.
Malonyl-CoA reacts with a holo-acp] through a malonyl-CoA-ACP transacylase resulting in a malonyl-[acp]. This compound can react with a KASI protein resulting in an acetyl-[acp]. A malonyl-[acp] can also react with an acetyl-[acp] through KASI and KASII or with acetyl-CoA through a beta-ketoacyl-ACP synthase to produce an acetoacetyl-[acp]. An acetoacetyl-[acp] is also known as a 3-oxoacyl-[acp].
A 3-oxoacyl-[acp] is reduced through a NDPH mediated 3-oxoacyl-[acp] reductase resulting in a (3R)-3-hydroxyacyl-[acp] (R3 hydroxydecanoyl-[acp]) which can either join the fatty acid metabolism, be dehydrated by an 3R-hydroxymyristoyl-[acp] dehydratase to produce a trans-2-enoyl-[acp] or be dehydrated by a hydroxydecanoyl-[acp] to produce a trans-delta2 decenoyl-[acp].
Trans-2-enoyl-[acp] is reduced by a NADH driven enoyl-[acp] reductase resulting in a 2,3,4-saturated fatty acyl-[acp]. This product then reacts with malonyl-[acp] through KASI and KASII resulting in a holo-acyl carrier protein and a 3- oxoacyl-[acp].
Trans-delta2 decenoyl-[acp] reacts with a 3-hydroxydecanoyl-[acp] dehydrase producing a cis-delta 3-decenoyl-ACP. This product then reacts with KASI to produce a 3-oxo-cis-delta5-dodecenoyl-[acp], which in turn is reduced by a NADPH driven 3-oxoacyl-[acp] resulting in a 3R-hydroxy cis delta5-dodecenoyl-acp. This product is dehydrated by a (3R)-hydroxymyristoyl-[acp] dehydratase resulting in a trans-delta 3- cis-delta 5-dodecenoyl-[acp] which in turn is reduced by a NADH driven enoyl-[acp] reductase resulting in a cis-delta5-dodecenoyl-acp which goes into fatty acid metabolism
PW000900ec00061Metabolicalpha-Linolenic acid metabolismec00592Lysine degradationec00310Valine, leucine and isoleucine degradationec00280Tetracycline biosynthesisec00253Trinitrotoluene degradationec00633Biosynthesis of unsaturated fatty acidsec01040Benzoate degradation via hydroxylationec00362Fatty acid elongation in mitochondriaec00062Fatty acid metabolismThis pathway depicts the degradation of palmitic acid (C16:0). Fatty acid degradation and synthesis are relatively simple processes that are essentially the reverse of each other. The process of fatty acid degradation, also known as Beta-Oxidation, converts an aliphatic compound into a set of activated acetyl units (acetyl CoA) that can be processed by the citric acid cycle. An activated fatty acid is first oxidized to introduce a double bond; the double bond is then hydrated to introduce an oxygen; the alcohol is then oxidized to a ketone; and, finally, the four carbon fragment is cleaved by coenzyme A to yield acetyl CoA and a fatty acid chain two carbons shorter. If the fatty acid has an even number of carbon atoms and is saturated, the process is simply repeated until the fatty acid is completely converted into acetyl CoA units. Fatty acid synthesis is essentially the reverse of this process. Because the result is a polymer, the process starts with monomers—in this case with activated acyl group and malonyl units. The malonyl unit is condensed with the acetyl unit to form a four-carbon fragment. To produce the required hydrocarbon chain, the carbonyl must be reduced. The fragment is reduced, dehydrated, and reduced again, exactly the opposite of degradation, to bring the carbonyl group to the level of a methylene group with the formation of butyryl CoA. Another activated malonyl group condenses with the butyryl unit and the process is repeated until a C16 fatty acid is synthesized.
The first step converts the hydroxydecanoyl into a trans 2decenoyl acp through a protein complex conformed of a hydroxomyristoyl dehydratase and a hydroxydecanoyl dehydratase. The second step leads to the production of a cis 3 decenoyl acp through a 3-hydroxydecanoyl acp dehydratase. For the third step the cis 3 decenoyl acp enters a cycle involving a synthase, reductase, dehydratase and an enoyl reductase which in turn produce a cis x enoyl-acp, hydroxy cis x enoyl, trans x-2 cis x enoyl acp and cis x enoyl respectively.This is done until a palmitoleoyl is produce. In said case the pathway procedes in two different directions. It can either produce a palmitoleic acid through a acyl-coa thioesterase, or produce a Vaccenic acid through a different set of reactions. This process is achieved through a 3-oxoacyl acp synthase, a 3-oxoacyl acp reductase, a 3r hydroxymyristoyl dehydratase and an enoyl acp reductase that produces a transition through 3-oxo cis vaccenoyl acp, 3 hydroxy cis vaccenoyl acp, cis vaccen 2 enoyl acp and a cis vaccenoyl acp respectively. At this point it goes through one final reaction to produce a Vaccenic acid, through an acyl-CoA thioesterasePW000796ec00071MetabolicGeraniol degradationec00281Ethylbenzene degradationec00642Terpenoid backbone biosynthesisec00900Biphenyl degradationec00621Toluene and xylene degradationec006221,4-Dichlorobenzene degradationec00627Synthesis and degradation of ketone bodiesec00072Microbial metabolism in diverse environmentsec01120Phosphonate and phosphinate metabolismec00440Two-component systemec02020Chloroalkane and chloroalkene degradationec00625Metabolic pathwayseco011002-Oxopent-4-enoate metabolismThe pathway starts with trans-cinnamate interacting with a hydrogen ion, an oxygen molecule, and a NADH through a cinnamate dioxygenase resulting in a NAD and a cis-3-(3-Carboxyethenyl)-3,5-cyclohexadiene-1,2-diol which then interact together through a 2,3-dihydroxy-2,3-dihydrophenylpropionate dehydrogenase resulting in the release of a hydrogen ion, an NADH molecule and a 2,3 dihydroxy-trans-cinnamate.
The second way by which the 2,3 dihydroxy-trans-cinnamate is acquired is through a 3-hydroxy-trans-cinnamate interacting with a hydrogen ion, a NADH and an oxygen molecule through a 3-(3-hydroxyphenyl)propionate 2-hydroxylase resulting in the release of a NAD molecule, a water molecule and a 2,3-dihydroxy-trans-cinnamate.
The compound 2,3 dihydroxy-trans-cinnamate then interacts with an oxygen molecule through a 2,3-dihydroxyphenylpropionate 1,2-dioxygenase resulting in a hydrogen ion and a 2-hydroxy-6-oxonona-2,4,7-triene-1,9-dioate. The latter compound then interacts with a water molecule through a 2-hydroxy-6-oxononatrienedioate hydrolase resulting in a release of a hydrogen ion, a fumarate molecule and (2Z)-2-hydroxypenta-2,4-dienoate. The latter compound reacts spontaneously to isomerize into a 2-oxopent-4-enoate. This compound is then hydrated through a 2-oxopent-4-enoate hydratase resulting in a 4-hydroxy-2-oxopentanoate. This compound then interacts with a 4-hydroxy-2-ketovalerate aldolase resulting in the release of a pyruvate, and an acetaldehyde. The acetaldehyde then interacts with a coenzyme A and a NAD molecule through a acetaldehyde dehydrogenase resulting in a hydrogen ion, a NADH and an acetyl-coa which can be incorporated into the TCA cyclePW001890MetabolicAmino sugar and nucleotide sugar metabolism IThe synthesis of amino sugars and nucleotide sugars starts with the phosphorylation of N-Acetylmuramic acid (MurNac) through its transport from the periplasmic space to the cytoplasm. Once in the cytoplasm, MurNac and water undergo a reversible reaction through a N-acetylmuramic acid 6-phosphate etherase, producing a D-lactic acid and N-Acetyl-D-Glucosamine 6-phosphate. This latter compound can also be introduced into the cytoplasm through a phosphorylating PTS permase in the inner membrane that allows for the transport of N-Acetyl-D-glucosamine from the periplasmic space. N-Acetyl-D-Glucosamine 6-phosphate can also be obtained from chitin dependent reactions. Chitin is hydrated through a bifunctional chitinase to produce chitobiose. This in turn gets hydrated by a beta-hexosaminidase to produce N-acetyl-D-glucosamine. The latter undergoes an atp dependent phosphorylation leading to the production of N-Acetyl-D-Glucosamine 6-phosphate.
N-Acetyl-D-Glucosamine 6-phosphate is then be deacetylated in order to produce Glucosamine 6-phosphate through a N-acetylglucosamine-6-phosphate deacetylase. This compound can either be isomerized or deaminated into Beta-D-fructofuranose 6-phosphate through a glucosamine-fructose-6-phosphate aminotransferase and a glucosamine-6-phosphate deaminase respectively.
Glucosamine 6-phosphate undergoes a reversible reaction to glucosamine 1 phosphate through a phosphoglucosamine mutase. This compound is then acetylated through a bifunctional protein glmU to produce a N-Acetyl glucosamine 1-phosphate.
N-Acetyl glucosamine 1-phosphate enters the nucleotide sugar synthesis by reacting with UTP and hydrogen ion through a bifunctional protein glmU releasing pyrophosphate and a Uridine diphosphate-N-acetylglucosamine.This compound can either be isomerized into a UDP-N-acetyl-D-mannosamine or undergo a reaction with phosphoenolpyruvic acid through UDP-N-acetylglucosamine 1-carboxyvinyltransferase releasing a phosphate and a UDP-N-Acetyl-alpha-D-glucosamine-enolpyruvate.
UDP-N-acetyl-D-mannosamine undergoes a NAD dependent dehydrogenation through a UDP-N-acetyl-D-mannosamine dehydrogenase, releasing NADH, a hydrogen ion and a UDP-N-Acetyl-alpha-D-mannosaminuronate, This compound is then used in the production of enterobacterial common antigens.
UDP-N-Acetyl-alpha-D-glucosamine-enolpyruvate is reduced through a NADPH dependent UDP-N-acetylenolpyruvoylglucosamine reductase, releasing a NADP and a UDP-N-acetyl-alpha-D-muramate. This compound is involved in the D-glutamine and D-glutamate metabolism.
PW000886MetabolicAminobenzoate DegradationDelete
This pathway shows the various process by which various compounds reach Benzoate degradation. The top most reaction catalyzes (3s)-3-hydroxyacyl-Coa from crotonoyl-Coa and Water through 2,3-dehydroadipyl-CoA hydratase.
The second reaction catalyzes Benzoic Acid from benzoyl phosphate through a weak acylphosphatase.
The third reaction is 1,2,4 Benzenetriol which is catalyzed from 4-nitrocatechol through a predicted 2Fe-2s cluster-containing protein. This is a isomer of 4-nitrophenol which is produced from 4-phenylphosphate or 4-nitrophenylphosphate through a phosphoanhydride phosphorylase or alkaline phosphatase respectively
The fourth reaction is the production of pyrocatechol from phenol, aniline or Nitrobenzene through a predicted 2Fe-2S cluster-containing protein.
The fifth reaction is the production of (3s)-3 hydroxyacyl CoA from acetyl oa and 3-hydroxy-5-oxohexanoic through Acetate CoA-transferase
(3s)-3-hydroxyacyl-Coa, Benzoic Acid, pyrocatechol and 1,2,4 Benzenetriol then go into Benzoate degradation. PW000757MetabolicL-glutamate metabolism IIPW001886MetabolicLeucine BiosynthesisLeucine biosynthesis involves a five-step conversion process starting with the valine precursor 2-keto-isovalerate interacting with acetyl-CoA and water through a 2-isopropylmalate synthase resulting in Coenzyme A, hydrogen Ion and 2-isopropylmalic acid. The latter compound reacts with isopropylmalate isomerase which dehydrates the compound resulting in a Isopropylmaleate. This compound reacts with water through a isopropylmalate isomerase resulting in 3-isopropylmalate. This compound interacts with a NAD-driven D-malate / 3-isopropylmalate dehydrogenase results in 2-isopropyl-3-oxosuccinate. This compound interacts spontaneously with hydrogen resulting in the release of carbon dioxide and ketoleucine. Ketoleucine interacts in a reversible reaction with L-glutamic acid through a branched-chain amino-acid aminotransferase resulting in Oxoglutaric acid and L-leucine
L-leucine can then be exported outside the cytoplasm through a transporter: L-amino acid efflux transporter.
The final step in this pathway is catalyzed by two transaminases of broad specificity, IlvE and TyrB.
Both the first enzyme in the pathway, 2-isopropylmalate synthase, and the terminal transaminase TyrB are suppressed by leucine. TyrB is subject to inhibition by the pathway's starting compound, 2-keto-isovalerate, and by one of its off-pathway products, tyrosine. One consequence of this inhibition by 2-keto-isovalerate is that in the absence of IlvE activity, mutations in earlier steps in the pathway cannot be compensated for by any alternate method of introducing 2-ketoisocaproate for conversion to leucine. PW000811MetabolicQuorum SensingBacterial Autoinducer 2 (AI-2) mediates the quorum sensing 2 system. AI-2 is catalyzed by the luxS enzyme. This enzyme is found in E.coli and S.typhimurium.
In E. coli and most pathogenic bacteria that form AI-2 are spontaneous transformations that include cyclization to (2R,4S)-2-methyl-2,4-dihydroxydihydrofuran-3-one and hydration to the final autoinducer (2R,4S)-2-methyl-2,3,3,4-tetrahydroxytetrahydrofuran. This product is released from the cell through the AI-2 transporter (tqsA).
As the level of AI-2 increases, other cells detect it and import it through the autoinducer-2 ABC transporter (lsrACDB). AI-2 is then degraded in the cells by phosphorylating the AI-2 which is then isomerized to P-HPD which follows by the transfer of and acetyl group to coenzyme A and releases dihydroxyacetone phosphatePW000836SignalingS-adenosyl-L-methionine biosynthesisS-adenosyl-L-methionine biosynthesis(SAM) is synthesized in the cytosol of the cell from L-methionine and ATP. This reaction is catalyzed by methionine adenosyltransferase. L methione is taken up from the environment through a complex reaction coupled transport and then proceeds too synthesize the s adenosylmethionine through a adenosylmethionine synthase. The S-adenosylmethionine then interacts with a hydrogen ion through a adenosylmethionine decarboxylase resulting in a carbon dioxide and a S-adenosyl 3-methioninamine.This compound interacts with a putrescine through a spermidine synthase resulting in a spermidine, a hydrogen ion and a S-methyl-5'-thioadenosine. The latter compound is degraded by interacting with a water molecule through a 5' methylthioadenosine nucleosidase resulting in a adenine and a S-methylthioribose which is then release into the environmentPW000837MetabolicSecondary Metabolite: Leucine biosynthesisLeucine biosynthesis involves a five-step conversion process starting with a 3-methyl-2-oxovaleric acid interacting with acetyl-CoA and a water molecule through a 2-isopropylmalate synthase resulting in Coenzyme A, hydrogen Ion and 2-isopropylmalic acid. The latter compound reacts with isopropylmalate isomerase which dehydrates the compound resulting in a Isopropylmaleate. This compound reacts with water through a isopropylmalate isomerase resulting in 3-isopropylmalate. This compound interacts with a NAD-driven D-malate / 3-isopropylmalate dehydrogenase results in 2-isopropyl-3-oxosuccinate. This compound interacts spontaneously with hydrogen resulting in the release of carbon dioxide and ketoleucine. Ketoleucine interacts in a reversible reaction with L-glutamic acid through a branched-chain amino-acid aminotransferase resulting in Oxoglutaric acid and L-leucine
Both the first enzyme in the pathway, 2-isopropylmalate synthase, and the terminal transaminase TyrB are suppressed by leucine. TyrB is subject to inhibition by the pathway's starting compound, 2-keto-isovalerate, and by one of its off-pathway products, tyrosine. One consequence of this inhibition by 2-keto-isovalerate is that in the absence of IlvE activity, mutations in earlier steps in the pathway cannot be compensated for by any alternate method of introducing 2-ketoisocaproate for conversion to leucine. PW000980MetabolicSecondary Metabolites: Glyoxylate cycleThe glyoxylate cycle starts with the interaction of Acetyl-Coa with a water molecule and Oxalacetic acid interact through a Citrate synthase resulting in a release of a coenzyme a and citric acid. The citric acid gets dehydrated through a citrate hydro-lyase resulting in the release of a water molecule and cis-Aconitic acid. The cis-Aconitic acid is then hydrated in an reversible reaction through an aconitate hydratase resulting in an Isocitric acid. The isocitric acid then interacts in a reversible reaction through isocitrate lyase resulting in the release of a succinic acid and a glyoxylic acid. The glyoxylic acid then reacts in a reversible reaction with an acetyl-coa, and a water molecule in a reversible reaction, resulting in a release of a coenzyme A, a hydrogen ion and an L-malic acid. The L-malic acid interacts in a reversible reaction through a NAD driven malate dehydrogenase resulting in the release of NADH, a hydrogen ion and an Oxalacetic acid.PW000967MetabolicSecondary Metabolites: Valine and I-leucine biosynthesis from pyruvateThe biosynthesis of Valine and L-leucine from pyruvic acid starts with pyruvic acid interacting with a hydrogen ion through a acetolactate synthase / acetohydroxybutanoate synthase resulting in a release of a carbon dioxide, a (S)-2-acetolactate. The latter compound then interacts with a hydrogen ion through a NADPH-driven acetohydroxy acid isomeroreductase resulting in the release of a NADP, a (R) 2,3-dihydroxy-3-methylvalerate. The latter compound is then dehydrated by a dihydroxy acid dehydratase resulting in the release of a water molecule an 3-methyl-2-oxovaleric acid.
The 3-methyl-2-oxovaleric acid can produce an L-valine by interacting with a L-glutamic acid through a Valine Transaminase resulting in the release of a Oxoglutaric acid and a L-valine.
The 3-methyl-2-oxovaleric acid then interacts with an acetyl-CoA and a water molecule through a 2-isopropylmalate synthase resulting in the release of a hydrogen ion, a Coenzyme A and a 2-Isopropylmalic acid. The isopropylimalic acid is then hydrated by interacting with a isopropylmalate isomerase resulting in a 3-isopropylmalate. This compound then interacts with an NAD driven 3-isopropylmalate dehydrogenase resulting in a NADH, a hydrogen ion and a 2-isopropyl-3-oxosuccinate. The latter compound then interacts with hydrogen ion spontaneously resulting in a carbon dioxide and a ketoleucine. The ketoleucine then interacts with a L-glutamic acid through a branched-chain amino-acid aminotransferase resulting in the oxoglutaric acid and L-leucine.PW000978MetabolicSecondary Metabolites: cysteine biosynthesis from serineThe pathway starts with a 3-phosphoglyceric acid interacting with an NAD driven D-3-phosphoglycerate dehydrogenase / α-ketoglutarate reductase resulting in an NADH, a hydrogen ion and a phosphohydroxypyruvic acid. This compound then interacts with an L-glutamic acid through a 3-phosphoserine aminotransferase / phosphohydroxythreonine aminotransferase resulting in a oxoglutaric acid and a DL-D-phosphoserine. The latter compound then interacts with a water molecule through a phosphoserine phosphatase resulting in a phosphate and an L-serine. The L-serine interacts with an acetyl-coa through a serine acetyltransferase resulting in a release of a Coenzyme A and a O-Acetylserine. The O-acetylserine then interacts with a hydrogen sulfide through a O-acetylserine sulfhydrylase A resulting in an acetic acid, a hydrogen ion and an L-cysteinePW000977MetabolicSecondary Metabolites: enterobacterial common antigen biosynthesis
The biosynthesis of a enterobacterial common antigen can begin with a di-trans,octa-cis-undecaprenyl phosphate interacts with a Uridine diphosphate-N-acetylglucosamine through undecaprenyl-phosphate α-N-acetylglucosaminyl transferase resulting in a N-acetyl-α-D-glucosaminyl-diphospho-ditrans,octacis-undecaprenol and a Uridine 5'-monophosphate. The N-acetyl-α-D-glucosaminyl-diphospho-ditrans,octacis-undecaprenol then reacts with an UDP-ManNAcA from the Amino sugar and nucleotide sugar metabolism pathway. This reaction is metabolized by a UDP-N-acetyl-D-mannosaminuronic acid transferase resulting in a uridine 5' diphosphate, a hydrogen ion and a Undecaprenyl N-acetyl-glucosaminyl-N-acetyl-mannosaminuronate-4-acetamido-4,6-dideoxy-D-galactose pyrophosphate.
Glucose 1 phosphate can be metabolize by interacting with a hydrogen ion and a thymidine 5-triphosphate by either reacting with a dTDP-glucose pyrophosphorylase or a dTDP-glucose pyrophosphorylase 2 resulting in the release of a pyrophosphate and a dTDP-D-glucose. The latter compound is then dehydrated through an dTDP-glucose 4,6-dehydratase 2 resulting in water and dTDP-4-dehydro-6-deoxy-D-glucose. The latter compound interacts with L-glutamic acid through a dTDP-4-dehydro-6-deoxy-D-glucose transaminase resulting in the release of oxoglutaric acid and dTDP-thomosamine. The latter compound interacts with acetyl-coa through a dTDP-fucosamine acetyltransferase resulting in a Coenzyme A, a hydrogen Ion and a TDP-Fuc4NAc.
Undecaprenyl N-acetyl-glucosaminyl-N-acetyl-mannosaminuronate-4-acetamido-4,6-dideoxy-D-galactose pyrophosphate then interacts with a TDP--Fuc4NAc through a 4-acetamido-4,6-dideoxy-D-galactose transferase resulting in a hydrogen ion, a dTDP and a Undecaprenyl N-acetyl-glucosaminyl-N-acetyl-mannosaminuronate-4-acetamido-4,6-dideoxy-D-galactose pyrophosphate. This compound is then transported through a protein wzxE into the periplasmic space so that it can be incorporated into the outer membrane
Enterobacterial common antigen (ECA) is an outer membrane glycolipid common to all members of Enterobacteriaceae. ECA is a unique cell surface antigen that can be found in the outer leaflet of the outer membrane. The carbohydrate portion consists of N-acetyl-glucosamine, N-acetyl-D-mannosaminuronic acid and 4-acetamido-4,6-dideoxy-D-galactose. These amino sugars form trisaccharide repeat units which are part of linear heteropolysaccharide chains.PW000959MetabolicTCA cycle
The TCA pathway is a catabolic pathway of aerobic respiration. It generates energy and reducing power. It is the first step in generating precursors for biosynthesis. When acetate is the carbon source, citrate synthase is rate-limiting for the TCA cycle. Respiration is an ATP-generating process in which compounds act as electron donors through a chain of electron transfer to electron acceptors. Aerobic respiration uses oxygen as the final acceptor. Anaerobic respiration uses several organic compounds as acceptors such as fumarate, nitrate and hydrogen. During the chain of electron transfer, protons (H+) are transported outside the cytoplasmic membrane, generating a proton motive force. Upon passage of protons back into the cytoplasm, the PMF energy is captured as ATP, catalyzed by a multisubunit ATPase.
The cycle can start from Acetyl-CoA interacting with Oxalacetic acid and water through a citrate synthase monomer resulting in a hydrogen ion, CoA and a Citric Acid. The latter compound is dehydrated by a Citrate hydro-lyase resulting in the release of water and a cis-Aconitic acid. This compound is then hydrated through a Citrate hydro-lyase resulting in a D-threo-Isocitric acid. This compound is decarboxylated by an NADP dependent Citrate dehydrogenase, resulting in a release of carbon dioxide and NADPH and Oxoglutaric acid. The oxoglutaric acid interacts with a Coenzyme A through a NAD driven 2-oxoglutarate dehydrogenase resulting in a release of carbon dioxide, an NADH and succinyl-CoA. The succinyl-CoA interacts with a phosphate and an ADP through a 2-oxoglutarate dehydrogenase resulting in a CoA, an ATP and Succinic Acid. Succinic acid interacts with a ubiquinone, in this case a ubiquinone 1 through a succinate:quinone oxidoreductase resulting in an ubiquinol, in this case a ubiquinol-1 and a fumaric acid.
The fumaric acid interacts with water through a fumarase hydratase resulting in a L-Malic acid.This compound can either interact with quinone through a malate:quinone oxidoreductase resulting in a release of hydroquinone and oxalacetic acid, or it can react with an NAD through a malate dehydrogenase resulting in a hydrogen ion, NADH and Oxalacetic acid.PW000779MetabolicTCA cycle (ubiquinol-10)The TCA pathway is a catabolic pathway of aerobic respiration. It generates energy and reducing power. It is the first step in generating precursors for biosynthesis. When acetate is the carbon source, citrate synthase is rate-limiting for the TCA cycle. Respiration is an ATP-generating process in which compounds act as electron donors through a chain of electron transfer to electron acceptors. Aerobic respiration uses oxygen as the final acceptor. Anaerobic respiration uses several organic compounds as acceptors such as fumarate, nitrate and hydrogen. During the chain of electron transfer, protons (H+) are transported outside the cytoplasmic membrane, generating a proton motive force. Upon passage of protons back into the cytoplasm, the PMF energy is captured as ATP, catalyzed by a multisubunit ATPase.
The cycle can start from Acetyl-CoA interacting with Oxalacetic acid and water through a citrate synthase monomer resulting in a hydrogen ion, CoA and a Citric Acid. The latter compound is dehydrated by a Citrate hydro-lyase resulting in the release of water and a cis-Aconitic acid. This compound is then hydrated through a Citrate hydro-lyase resulting in a D-threo-Isocitric acid. This compound is decarboxylated by an NADP dependent Citrate dehydrogenase, resulting in a release of carbon dioxide and NADPH and Oxoglutaric acid. The oxoglutaric acid interacts with a Coenzyme A through a NAD driven 2-oxoglutarate dehydrogenase resulting in a release of carbon dioxide, an NADH and succinyl-CoA. The succinyl-CoA interacts with a phosphate and an ADP through a 2-oxoglutarate dehydrogenase resulting in a CoA, an ATP and Succinic Acid. Succinic acid interacts with a ubiquinone, in this case a ubiquinone 1 through a succinate:quinone oxidoreductase resulting in an ubiquinol, in this case a ubiquinol-1 and a fumaric acid.
The fumaric acid interacts with water through a fumarase hydratase resulting in a L-Malic acid.This compound can either interact with quinone through a malate:quinone oxidoreductase resulting in a release of hydroquinone and oxalacetic acid, or it can react with an NAD through a malate dehydrogenase resulting in a hydrogen ion, NADH and Oxalacetic acid.PW001010MetabolicTCA cycle (ubiquinol-2)The TCA pathway is a catabolic pathway of aerobic respiration. It generates energy and reducing power. It is the first step in generating precursors for biosynthesis. When acetate is the carbon source, citrate synthase is rate-limiting for the TCA cycle. Respiration is an ATP-generating process in which compounds act as electron donors through a chain of electron transfer to electron acceptors. Aerobic respiration uses oxygen as the final acceptor. Anaerobic respiration uses several organic compounds as acceptors such as fumarate, nitrate and hydrogen. During the chain of electron transfer, protons (H+) are transported outside the cytoplasmic membrane, generating a proton motive force. Upon passage of protons back into the cytoplasm, the PMF energy is captured as ATP, catalyzed by a multisubunit ATPase.
The cycle can start from Acetyl-CoA interacting with Oxalacetic acid and water through a citrate synthase monomer resulting in a hydrogen ion, CoA and a Citric Acid. The latter compound is dehydrated by a Citrate hydro-lyase resulting in the release of water and a cis-Aconitic acid. This compound is then hydrated through a Citrate hydro-lyase resulting in a D-threo-Isocitric acid. This compound is decarboxylated by an NADP dependent Citrate dehydrogenase, resulting in a release of carbon dioxide and NADPH and Oxoglutaric acid. The oxoglutaric acid interacts with a Coenzyme A through a NAD driven 2-oxoglutarate dehydrogenase resulting in a release of carbon dioxide, an NADH and succinyl-CoA. The succinyl-CoA interacts with a phosphate and an ADP through a 2-oxoglutarate dehydrogenase resulting in a CoA, an ATP and Succinic Acid. Succinic acid interacts with a ubiquinone, in this case a ubiquinone 2 through a succinate:quinone oxidoreductase resulting in an ubiquinol, in this case a ubiquinol-2 and a fumaric acid.
The fumaric acid interacts with water through a fumarase hydratase resulting in a L-Malic acid.This compound can either interact with quinone through a malate:quinone oxidoreductase resulting in a release of hydroquinone and oxalacetic acid, or it can react with an NAD through a malate dehydrogenase resulting in a hydrogen ion, NADH and Oxalacetic acid.PW001002MetabolicTCA cycle (ubiquinol-3)The TCA pathway is a catabolic pathway of aerobic respiration. It generates energy and reducing power. It is the first step in generating precursors for biosynthesis. When acetate is the carbon source, citrate synthase is rate-limiting for the TCA cycle. Respiration is an ATP-generating process in which compounds act as electron donors through a chain of electron transfer to electron acceptors. Aerobic respiration uses oxygen as the final acceptor. Anaerobic respiration uses several organic compounds as acceptors such as fumarate, nitrate and hydrogen. During the chain of electron transfer, protons (H+) are transported outside the cytoplasmic membrane, generating a proton motive force. Upon passage of protons back into the cytoplasm, the PMF energy is captured as ATP, catalyzed by a multisubunit ATPase.
The cycle can start from Acetyl-CoA interacting with Oxalacetic acid and water through a citrate synthase monomer resulting in a hydrogen ion, CoA and a Citric Acid. The latter compound is dehydrated by a Citrate hydro-lyase resulting in the release of water and a cis-Aconitic acid. This compound is then hydrated through a Citrate hydro-lyase resulting in a D-threo-Isocitric acid. This compound is decarboxylated by an NADP dependent Citrate dehydrogenase, resulting in a release of carbon dioxide and NADPH and Oxoglutaric acid. The oxoglutaric acid interacts with a Coenzyme A through a NAD driven 2-oxoglutarate dehydrogenase resulting in a release of carbon dioxide, an NADH and succinyl-CoA. The succinyl-CoA interacts with a phosphate and an ADP through a 2-oxoglutarate dehydrogenase resulting in a CoA, an ATP and Succinic Acid. Succinic acid interacts with a ubiquinone, in this case a ubiquinone-3 through a succinate:quinone oxidoreductase resulting in an ubiquinol, in this case a ubiquinol-3 and a fumaric acid.
The fumaric acid interacts with water through a fumarase hydratase resulting in a L-Malic acid.This compound can either interact with quinone through a malate:quinone oxidoreductase resulting in a release of hydroquinone and oxalacetic acid, or it can react with an NAD through a malate dehydrogenase resulting in a hydrogen ion, NADH and Oxalacetic acid.PW001003MetabolicTCA cycle (ubiquinol-4)The TCA pathway is a catabolic pathway of aerobic respiration. It generates energy and reducing power. It is the first step in generating precursors for biosynthesis. When acetate is the carbon source, citrate synthase is rate-limiting for the TCA cycle. Respiration is an ATP-generating process in which compounds act as electron donors through a chain of electron transfer to electron acceptors. Aerobic respiration uses oxygen as the final acceptor. Anaerobic respiration uses several organic compounds as acceptors such as fumarate, nitrate and hydrogen. During the chain of electron transfer, protons (H+) are transported outside the cytoplasmic membrane, generating a proton motive force. Upon passage of protons back into the cytoplasm, the PMF energy is captured as ATP, catalyzed by a multisubunit ATPase.
The cycle can start from Acetyl-CoA interacting with Oxalacetic acid and water through a citrate synthase monomer resulting in a hydrogen ion, CoA and a Citric Acid. The latter compound is dehydrated by a Citrate hydro-lyase resulting in the release of water and a cis-Aconitic acid. This compound is then hydrated through a Citrate hydro-lyase resulting in a D-threo-Isocitric acid. This compound is decarboxylated by an NADP dependent Citrate dehydrogenase, resulting in a release of carbon dioxide and NADPH and Oxoglutaric acid. The oxoglutaric acid interacts with a Coenzyme A through a NAD driven 2-oxoglutarate dehydrogenase resulting in a release of carbon dioxide, an NADH and succinyl-CoA. The succinyl-CoA interacts with a phosphate and an ADP through a 2-oxoglutarate dehydrogenase resulting in a CoA, an ATP and Succinic Acid. Succinic acid interacts with a ubiquinone, in this case a ubiquinone 1 through a succinate:quinone oxidoreductase resulting in an ubiquinol, in this case a ubiquinol-1 and a fumaric acid.
The fumaric acid interacts with water through a fumarase hydratase resulting in a L-Malic acid.This compound can either interact with quinone through a malate:quinone oxidoreductase resulting in a release of hydroquinone and oxalacetic acid, or it can react with an NAD through a malate dehydrogenase resulting in a hydrogen ion, NADH and Oxalacetic acid.PW001004MetabolicTCA cycle (ubiquinol-5)The TCA pathway is a catabolic pathway of aerobic respiration. It generates energy and reducing power. It is the first step in generating precursors for biosynthesis. When acetate is the carbon source, citrate synthase is rate-limiting for the TCA cycle. Respiration is an ATP-generating process in which compounds act as electron donors through a chain of electron transfer to electron acceptors. Aerobic respiration uses oxygen as the final acceptor. Anaerobic respiration uses several organic compounds as acceptors such as fumarate, nitrate and hydrogen. During the chain of electron transfer, protons (H+) are transported outside the cytoplasmic membrane, generating a proton motive force. Upon passage of protons back into the cytoplasm, the PMF energy is captured as ATP, catalyzed by a multisubunit ATPase.
The cycle can start from Acetyl-CoA interacting with Oxalacetic acid and water through a citrate synthase monomer resulting in a hydrogen ion, CoA and a Citric Acid. The latter compound is dehydrated by a Citrate hydro-lyase resulting in the release of water and a cis-Aconitic acid. This compound is then hydrated through a Citrate hydro-lyase resulting in a D-threo-Isocitric acid. This compound is decarboxylated by an NADP dependent Citrate dehydrogenase, resulting in a release of carbon dioxide and NADPH and Oxoglutaric acid. The oxoglutaric acid interacts with a Coenzyme A through a NAD driven 2-oxoglutarate dehydrogenase resulting in a release of carbon dioxide, an NADH and succinyl-CoA. The succinyl-CoA interacts with a phosphate and an ADP through a 2-oxoglutarate dehydrogenase resulting in a CoA, an ATP and Succinic Acid. Succinic acid interacts with a ubiquinone, in this case a ubiquinone 1 through a succinate:quinone oxidoreductase resulting in an ubiquinol, in this case a ubiquinol-1 and a fumaric acid.
The fumaric acid interacts with water through a fumarase hydratase resulting in a L-Malic acid.This compound can either interact with quinone through a malate:quinone oxidoreductase resulting in a release of hydroquinone and oxalacetic acid, or it can react with an NAD through a malate dehydrogenase resulting in a hydrogen ion, NADH and Oxalacetic acid.PW001005MetabolicTCA cycle (ubiquinol-6)The TCA pathway is a catabolic pathway of aerobic respiration. It generates energy and reducing power. It is the first step in generating precursors for biosynthesis. When acetate is the carbon source, citrate synthase is rate-limiting for the TCA cycle. Respiration is an ATP-generating process in which compounds act as electron donors through a chain of electron transfer to electron acceptors. Aerobic respiration uses oxygen as the final acceptor. Anaerobic respiration uses several organic compounds as acceptors such as fumarate, nitrate and hydrogen. During the chain of electron transfer, protons (H+) are transported outside the cytoplasmic membrane, generating a proton motive force. Upon passage of protons back into the cytoplasm, the PMF energy is captured as ATP, catalyzed by a multisubunit ATPase.
The cycle can start from Acetyl-CoA interacting with Oxalacetic acid and water through a citrate synthase monomer resulting in a hydrogen ion, CoA and a Citric Acid. The latter compound is dehydrated by a Citrate hydro-lyase resulting in the release of water and a cis-Aconitic acid. This compound is then hydrated through a Citrate hydro-lyase resulting in a D-threo-Isocitric acid. This compound is decarboxylated by an NADP dependent Citrate dehydrogenase, resulting in a release of carbon dioxide and NADPH and Oxoglutaric acid. The oxoglutaric acid interacts with a Coenzyme A through a NAD driven 2-oxoglutarate dehydrogenase resulting in a release of carbon dioxide, an NADH and succinyl-CoA. The succinyl-CoA interacts with a phosphate and an ADP through a 2-oxoglutarate dehydrogenase resulting in a CoA, an ATP and Succinic Acid. Succinic acid interacts with a ubiquinone, in this case a ubiquinone 1 through a succinate:quinone oxidoreductase resulting in an ubiquinol, in this case a ubiquinol-1 and a fumaric acid.
The fumaric acid interacts with water through a fumarase hydratase resulting in a L-Malic acid.This compound can either interact with quinone through a malate:quinone oxidoreductase resulting in a release of hydroquinone and oxalacetic acid, or it can react with an NAD through a malate dehydrogenase resulting in a hydrogen ion, NADH and Oxalacetic acid.PW001006MetabolicTCA cycle (ubiquinol-7)The TCA pathway is a catabolic pathway of aerobic respiration. It generates energy and reducing power. It is the first step in generating precursors for biosynthesis. When acetate is the carbon source, citrate synthase is rate-limiting for the TCA cycle. Respiration is an ATP-generating process in which compounds act as electron donors through a chain of electron transfer to electron acceptors. Aerobic respiration uses oxygen as the final acceptor. Anaerobic respiration uses several organic compounds as acceptors such as fumarate, nitrate and hydrogen. During the chain of electron transfer, protons (H+) are transported outside the cytoplasmic membrane, generating a proton motive force. Upon passage of protons back into the cytoplasm, the PMF energy is captured as ATP, catalyzed by a multisubunit ATPase.
The cycle can start from Acetyl-CoA interacting with Oxalacetic acid and water through a citrate synthase monomer resulting in a hydrogen ion, CoA and a Citric Acid. The latter compound is dehydrated by a Citrate hydro-lyase resulting in the release of water and a cis-Aconitic acid. This compound is then hydrated through a Citrate hydro-lyase resulting in a D-threo-Isocitric acid. This compound is decarboxylated by an NADP dependent Citrate dehydrogenase, resulting in a release of carbon dioxide and NADPH and Oxoglutaric acid. The oxoglutaric acid interacts with a Coenzyme A through a NAD driven 2-oxoglutarate dehydrogenase resulting in a release of carbon dioxide, an NADH and succinyl-CoA. The succinyl-CoA interacts with a phosphate and an ADP through a 2-oxoglutarate dehydrogenase resulting in a CoA, an ATP and Succinic Acid. Succinic acid interacts with a ubiquinone, in this case a ubiquinone 1 through a succinate:quinone oxidoreductase resulting in an ubiquinol, in this case a ubiquinol-1 and a fumaric acid.
The fumaric acid interacts with water through a fumarase hydratase resulting in a L-Malic acid.This compound can either interact with quinone through a malate:quinone oxidoreductase resulting in a release of hydroquinone and oxalacetic acid, or it can react with an NAD through a malate dehydrogenase resulting in a hydrogen ion, NADH and Oxalacetic acid.PW001007MetabolicTCA cycle (ubiquinol-8)The TCA pathway is a catabolic pathway of aerobic respiration. It generates energy and reducing power. It is the first step in generating precursors for biosynthesis. When acetate is the carbon source, citrate synthase is rate-limiting for the TCA cycle. Respiration is an ATP-generating process in which compounds act as electron donors through a chain of electron transfer to electron acceptors. Aerobic respiration uses oxygen as the final acceptor. Anaerobic respiration uses several organic compounds as acceptors such as fumarate, nitrate and hydrogen. During the chain of electron transfer, protons (H+) are transported outside the cytoplasmic membrane, generating a proton motive force. Upon passage of protons back into the cytoplasm, the PMF energy is captured as ATP, catalyzed by a multisubunit ATPase.
The cycle can start from Acetyl-CoA interacting with Oxalacetic acid and water through a citrate synthase monomer resulting in a hydrogen ion, CoA and a Citric Acid. The latter compound is dehydrated by a Citrate hydro-lyase resulting in the release of water and a cis-Aconitic acid. This compound is then hydrated through a Citrate hydro-lyase resulting in a D-threo-Isocitric acid. This compound is decarboxylated by an NADP dependent Citrate dehydrogenase, resulting in a release of carbon dioxide and NADPH and Oxoglutaric acid. The oxoglutaric acid interacts with a Coenzyme A through a NAD driven 2-oxoglutarate dehydrogenase resulting in a release of carbon dioxide, an NADH and succinyl-CoA. The succinyl-CoA interacts with a phosphate and an ADP through a 2-oxoglutarate dehydrogenase resulting in a CoA, an ATP and Succinic Acid. Succinic acid interacts with a ubiquinone, in this case a ubiquinone 1 through a succinate:quinone oxidoreductase resulting in an ubiquinol, in this case a ubiquinol-1 and a fumaric acid.
The fumaric acid interacts with water through a fumarase hydratase resulting in a L-Malic acid.This compound can either interact with quinone through a malate:quinone oxidoreductase resulting in a release of hydroquinone and oxalacetic acid, or it can react with an NAD through a malate dehydrogenase resulting in a hydrogen ion, NADH and Oxalacetic acid.PW001008MetabolicTCA cycle (ubiquinol-9)The TCA pathway is a catabolic pathway of aerobic respiration. It generates energy and reducing power. It is the first step in generating precursors for biosynthesis. When acetate is the carbon source, citrate synthase is rate-limiting for the TCA cycle. Respiration is an ATP-generating process in which compounds act as electron donors through a chain of electron transfer to electron acceptors. Aerobic respiration uses oxygen as the final acceptor. Anaerobic respiration uses several organic compounds as acceptors such as fumarate, nitrate and hydrogen. During the chain of electron transfer, protons (H+) are transported outside the cytoplasmic membrane, generating a proton motive force. Upon passage of protons back into the cytoplasm, the PMF energy is captured as ATP, catalyzed by a multisubunit ATPase.
The cycle can start from Acetyl-CoA interacting with Oxalacetic acid and water through a citrate synthase monomer resulting in a hydrogen ion, CoA and a Citric Acid. The latter compound is dehydrated by a Citrate hydro-lyase resulting in the release of water and a cis-Aconitic acid. This compound is then hydrated through a Citrate hydro-lyase resulting in a D-threo-Isocitric acid. This compound is decarboxylated by an NADP dependent Citrate dehydrogenase, resulting in a release of carbon dioxide and NADPH and Oxoglutaric acid. The oxoglutaric acid interacts with a Coenzyme A through a NAD driven 2-oxoglutarate dehydrogenase resulting in a release of carbon dioxide, an NADH and succinyl-CoA. The succinyl-CoA interacts with a phosphate and an ADP through a 2-oxoglutarate dehydrogenase resulting in a CoA, an ATP and Succinic Acid. Succinic acid interacts with a ubiquinone, in this case a ubiquinone 1 through a succinate:quinone oxidoreductase resulting in an ubiquinol, in this case a ubiquinol-1 and a fumaric acid.
The fumaric acid interacts with water through a fumarase hydratase resulting in a L-Malic acid.This compound can either interact with quinone through a malate:quinone oxidoreductase resulting in a release of hydroquinone and oxalacetic acid, or it can react with an NAD through a malate dehydrogenase resulting in a hydrogen ion, NADH and Oxalacetic acid.PW001009Metabolicarginine metabolismThe metabolism of L-arginine starts with the acetylation of L-glutamic acid resulting in a N-acetylglutamic acid while releasing a coenzyme A and a hydrogen ion. N-acetylglutamic acid is then phosphorylated via an ATP driven acetylglutamate kinase which yields a N-acetyl-L-glutamyl 5-phosphate. This compound undergoes a NDPH dependent reduction resulting in N-acetyl-L-glutamate 5-semialdehyde. This compound reacts with L-glutamic acid through a acetylornithine aminotransferase / N-succinyldiaminopimelate aminotransferase to produce a N-acetylornithine which is then deacetylated through a acetylornithine deacetylase which yield an ornithine.
L-glutamine is used to synthesize carbamoyl phosphate through the interaction of L-glutamine, water, ATP, and hydrogen carbonate. This reaction yields ADP, L-glutamic acid, phosphate, and hydrogen ion.
Carbamoyl phosphate and ornithine are used to catalyze the production of citrulline through an ornithine carbamoyltransferase. Citrulline reacts with L-aspartic acid through an ATP dependent enzyme, argininosuccinate synthase to produce pyrophosphate, AMP and argininosuccinic acid. Argininosussinic acid is then lyase to produce L-arginine and fumaric acid.
L-arginine can be metabolized into succinic acid by two different sets of reactions:
1. Arginine reacts with succinyl-CoA through a arginine N-succinyltransferase resulting in N2-succinyl-L-arginine while releasing CoA and Hydrogen Ion. N2-succinyl-L-arginine is then dihydrolase to produce a N2-succinyl-L-ornithine through a N-succinylarginine dihydrolase. This compound in turn reacts with oxoglutaric acid through succinylornithine transaminase resulting in L-glutamic acid and N2-succinyl-L-glutamic acid 5-semialdehyde. This compoud in turn reacts with a NAD dependent dehydrogenase resulting in N2-succinylglutamate while releasing NADH and hydrogen ion. N2-succinylglutamate reacts with water through a succinylglutamate desuccinylase resulting in L-glutamic acid and
a succinic acid. The succinic acid is then incorporated in the TCA cycle
2.Argine reacts with carbon dioxide and a hydrogen ion through a biodegradative arginine decarboxylase, resulting in Agmatine. This compound is then transformed into putrescine by reacting with water and an agmatinase, and releasing urea. Putrescine can be metabolized by reaction with either l-glutamic acid or oxoglutaric acid. If putrescine reacts with L-glutamic acid, it reacts through an ATP mediated gamma-glutamylputrescine producing a hydrogen ion, ADP, phosphate and gamma-glutamyl-L-putrescine. This compound is reduced by interacting with oxygen, water and a gamma-glutamylputrescine oxidoreductase resulting in ammonium, hydrogen peroxide and 4-gamma-glutamylamino butanal. This compound is dehydrogenated through a NADP mediated reaction lead by gamma-glutamyl-gamma-aminobutaryaldehyde dehydrogenase resulting in hydrogen ion, NADPH and 4-glutamylamino butanoate. In turn, the latter compound reacts with water through a gamma-glutamyl-gamma-aminobutyrate hydrolase resulting in L-glutamic acid and Gamma aminobutyric acid. On the other hand, if putrescine reacts with oxoglutaric acid through a putrescine aminotransferase, it results in L-glutamic acid, and a 4-aminobutyraldehyde. This compound reacts with water through a NAD dependent gamma aminobutyraldehyde dehydrogenase resulting in hydrogen ion, NADH and gamma-aminobutyric acid.
Gamma Aaminobutyric acid reacts with oxoglutaric acid through 4-aminobutyrate aminotransferase resulting in L-glutamic acid and succinic acid semialdehyde. This compound in turn can react with with either NADP or NAD to result in the production of succinic acid through succinate-semialdehyde dehydrogenase or aldehyde dehydrogenase-like protein yneI respectively. Succinic acid can then be integrated in the TCA cycle.
L-arginine is eventua lly metabolized into succinic acid which then goes to the TCA cyclePW000790Metaboliccysteine biosynthesisThe pathway of cysteine biosynthesis is a two-step conversion starting from L-serine and yielding L-cysteine. L-serine biosynthesis is shown for context.
L-cysteine can also be synthesized from sulfate derivatives.
The process through L-serine involves a serine acetyltransferase that produces a O-acetylserine which reacts together with hydrogen sulfide through a cysteine synthase complex in order to produce L-cysteine and acetic acid.
Hydrogen sulfide is produced from a sulfate. Sulfate reacts with sulfate adenylyltransferase to produce adenosine phosphosulfate. This compound in turn is phosphorylated through a adenylyl-sulfate kinase into a phosphoadenosine phosphosulfate which in turn reacts with a phosphoadenosine phosphosulfate reductase to produce a sulfite. The sulfite reacts with a sulfite reductase to produce the hydrogen sulfide.
This pathway is regulated at the genetic level in its second step, wtih both cysteine synthase isozymes being under the positive control of the cysteine-responsive transcription factor CysB. It is also subject to very strong feedback inhibition of its first step by the final pathway product, cysteine.
Although two cysteine synthase isozymes exist, only cysteine synthase A (CysK) forms a complex with serine acetyltransferase. CysK is also the only one of the two cysteine synthases that is required for cell viability on cysteine-free medium.
Both steps in this pathway are reversible. Based on genetic and proteomic data, it appears that the cysteine synthases may actually act as a sulfur scavenging system during sulfur starvation, stripping sulfur off of L-cysteine, generating any number of variant amino acids in the process.PW000800Metabolicfatty acid elongation -- saturatedThis pathway shows the reactions that constitute one turn of a cycle that lengthens the chain of an acyl-ACP molecule by two carbons. The pathway is fed acetoacetyl-ACP, produces from malonyl acp, acetyl coa and 3-oxoacyl acp synthase 3. The products of multiple turns of this cycle that are drawn off to become components of fatty acid-containing compounds such as phospholipids, lipid A, and lipoproteins are the saturated fatty acids , lauric (dodecanoic), myristic (tetradecanoic), palmitic (hexadecanoic), and stearic (octadecanoic) acids. E. coli also contains unsaturated fatty acids. These are formed by a pathway that branches at the level of the 10-carbon intermediate. The final step of the cycle, the reductase, once thought to be catalyzed by two enzymes, has been shown to be catalyzed by a single enzyme, FabI, that can use either NADH or NADPH as a cofactor. However, the activity with NADH was over 17-fold higher than with NADPH, The production of acetoacetyl-acp is provided for context. Acetoacetyl-acp reacts spontaneously to produce a 3-oxoacyl acp. This compound will undergo the cycles of the elongation.
The first step is converting the oxoacyl acp into a (3R) 3-hydroxyacyl(acp) through a 3-oxoacyl[acp] reductase.This second step converts the hydroxyacyl into a trans 2 enoyl acp through a protein complex conformed of a hydroxomyristoyl dehydratase and a hydroxydecanoyl dehydratase. The third step can be reached through two different reactions with a enoyl-acp reductase, involving NADPH or NADH. This leads to the production of a 2,3,4-saturated fatty acyl acp. For the final step the 2,3,4 fatty acyl acp is turned into a oxoacyl acp through a 3-oxoacyl acp synthase protein complex. This concludes one cycle.PW000798Metabolicfatty acid oxidationAlthough enzymes of the pathway handle both short and long chain fatty acids, it is the long chain compounds that induce the enzymes of the pathway . Each turn of the cycle removes two carbon atoms until only two or three remain. When even-numbered fatty acids are broken down, a two-carbon compound remains, acetyl-CoA. When odd number fatty acids are broken down, a three-carbon residue results, propionylCoA. Unsaturated fatty acids, with cis double bonds located at odd-numbered carbon atoms, enter the main pathway of saturated fatty acid degradation by converting related metabolites of cis configuration and D stereoisomers, derived from breakdown of unsaturated fatty acids, to the trans- or L isomers of saturated fatty acid breakdown by an isomerase and an epimerase, respectively. When cis double bonds are located at even-numbered carbon atoms, such as linoleic acid (cis,cis(9,12)-octadecadienoic acid), after the fatty acid is degraded to the ten carbon stage an extra step is required to deal with the resulting compound, trans,δ(2)-cis,δ(4)decadienoyl-CoA. The enzyme 2,4-dienoyl-CoA reductase, converts this to trans,δ(2)decenoyl-CoA which enters the normal cycle at the point of the isomerase.
The order of the reaction is as follows:
a 2,3,4 saturated fatty acid is transformed into a 2,3,4 saturated fatty acyl CoA through a Long and short chain fatty acid CoA ligase. The 2,3,4 saturated fatty acyl CoA is then transformed into a trans 2 enoyl CoA. This enoyl can also be produced from a cis 3 enoyl CoA through a fatty acid oxidation protein complex. The trans 2 enoyl is transformed into a 3s 3 hydroxyacyl CoA through a 2,3 dehydroadipyl CoA hydratase. This same enzyme turns the product into a 3-oxoacyl-CoA. This is followed by the last step in the reaction when the oxoacyl-coa is turn into an acetyl coa+ a 2,3,4 saturated fatty acyl CoA through a 3-ketoacyl-CoA thiolasePW000758Metabolicfatty acid oxidation (Butanoate)Although enzymes of the pathway handle both short and long chain fatty acids, it is the long chain compounds that induce the enzymes of the pathway . Each turn of the cycle removes two carbon atoms until only two or three remain. When even-numbered fatty acids are broken down, a two-carbon compound remains, acetyl-CoA. When odd number fatty acids are broken down, a three-carbon residue results, propionylCoA. Unsaturated fatty acids, with cis double bonds located at odd-numbered carbon atoms, enter the main pathway of saturated fatty acid degradation by converting related metabolites of cis configuration and D stereoisomers, derived from breakdown of unsaturated fatty acids, to the trans- or L isomers of saturated fatty acid breakdown by an isomerase and an epimerase, respectively. When cis double bonds are located at even-numbered carbon atoms, such as linoleic acid (cis,cis(9,12)-octadecadienoic acid), after the fatty acid is degraded to the ten carbon stage an extra step is required to deal with the resulting compound, trans,δ(2)-cis,δ(4)decadienoyl-CoA. The enzyme 2,4-dienoyl-CoA reductase, converts this to trans,δ(2)decenoyl-CoA which enters the normal cycle at the point of the isomerase.
The order of the reaction is as follows:
a 2,3,4 saturated fatty acid is transformed into a 2,3,4 saturated fatty acyl CoA through a Long and short chain fatty acid CoA ligase. The 2,3,4 saturated fatty acyl CoA is then transformed into a trans 2 enoyl CoA. This enoyl can also be produced from a cis 3 enoyl CoA through a fatty acid oxidation protein complex. The trans 2 enoyl is transformed into a 3s 3 hydroxyacyl CoA through a 2,3 dehydroadipyl CoA hydratase. This same enzyme turns the product into a 3-oxoacyl-CoA. This is followed by the last step in the reaction when the oxoacyl-coa is turn into an acetyl coa+ a 2,3,4 saturated fatty acyl CoA through a 3-ketoacyl-CoA thiolasePW001017Metabolicfatty acid oxidation (Decanoate)Although enzymes of the pathway handle both short and long chain fatty acids, it is the long chain compounds that induce the enzymes of the pathway . Each turn of the cycle removes two carbon atoms until only two or three remain. When even-numbered fatty acids are broken down, a two-carbon compound remains, acetyl-CoA. When odd number fatty acids are broken down, a three-carbon residue results, propionylCoA. Unsaturated fatty acids, with cis double bonds located at odd-numbered carbon atoms, enter the main pathway of saturated fatty acid degradation by converting related metabolites of cis configuration and D stereoisomers, derived from breakdown of unsaturated fatty acids, to the trans- or L isomers of saturated fatty acid breakdown by an isomerase and an epimerase, respectively. When cis double bonds are located at even-numbered carbon atoms, such as linoleic acid (cis,cis(9,12)-octadecadienoic acid), after the fatty acid is degraded to the ten carbon stage an extra step is required to deal with the resulting compound, trans,δ(2)-cis,δ(4)decadienoyl-CoA. The enzyme 2,4-dienoyl-CoA reductase, converts this to trans,δ(2)decenoyl-CoA which enters the normal cycle at the point of the isomerase.
The order of the reaction is as follows:
a 2,3,4 saturated fatty acid is transformed into a 2,3,4 saturated fatty acyl CoA through a Long and short chain fatty acid CoA ligase. The 2,3,4 saturated fatty acyl CoA is then transformed into a trans 2 enoyl CoA. This enoyl can also be produced from a cis 3 enoyl CoA through a fatty acid oxidation protein complex. The trans 2 enoyl is transformed into a 3s 3 hydroxyacyl CoA through a 2,3 dehydroadipyl CoA hydratase. This same enzyme turns the product into a 3-oxoacyl-CoA. This is followed by the last step in the reaction when the oxoacyl-coa is turn into an acetyl coa+ a 2,3,4 saturated fatty acyl CoA through a 3-ketoacyl-CoA thiolasePW001018Metabolicfatty acid oxidation (hexanoate)Although enzymes of the pathway handle both short and long chain fatty acids, it is the long chain compounds that induce the enzymes of the pathway . Each turn of the cycle removes two carbon atoms until only two or three remain. When even-numbered fatty acids are broken down, a two-carbon compound remains, acetyl-CoA. When odd number fatty acids are broken down, a three-carbon residue results, propionylCoA. Unsaturated fatty acids, with cis double bonds located at odd-numbered carbon atoms, enter the main pathway of saturated fatty acid degradation by converting related metabolites of cis configuration and D stereoisomers, derived from breakdown of unsaturated fatty acids, to the trans- or L isomers of saturated fatty acid breakdown by an isomerase and an epimerase, respectively. When cis double bonds are located at even-numbered carbon atoms, such as linoleic acid (cis,cis(9,12)-octadecadienoic acid), after the fatty acid is degraded to the ten carbon stage an extra step is required to deal with the resulting compound, trans,δ(2)-cis,δ(4)decadienoyl-CoA. The enzyme 2,4-dienoyl-CoA reductase, converts this to trans,δ(2)decenoyl-CoA which enters the normal cycle at the point of the isomerase.
The order of the reaction is as follows:
a 2,3,4 saturated fatty acid is transformed into a 2,3,4 saturated fatty acyl CoA through a Long and short chain fatty acid CoA ligase. The 2,3,4 saturated fatty acyl CoA is then transformed into a trans 2 enoyl CoA. This enoyl can also be produced from a cis 3 enoyl CoA through a fatty acid oxidation protein complex. The trans 2 enoyl is transformed into a 3s 3 hydroxyacyl CoA through a 2,3 dehydroadipyl CoA hydratase. This same enzyme turns the product into a 3-oxoacyl-CoA. This is followed by the last step in the reaction when the oxoacyl-coa is turn into an acetyl coa+ a 2,3,4 saturated fatty acyl CoA through a 3-ketoacyl-CoA thiolasePW001019Metabolicfatty acid oxidation (laurate)Although enzymes of the pathway handle both short and long chain fatty acids, it is the long chain compounds that induce the enzymes of the pathway . Each turn of the cycle removes two carbon atoms until only two or three remain. When even-numbered fatty acids are broken down, a two-carbon compound remains, acetyl-CoA. When odd number fatty acids are broken down, a three-carbon residue results, propionylCoA. Unsaturated fatty acids, with cis double bonds located at odd-numbered carbon atoms, enter the main pathway of saturated fatty acid degradation by converting related metabolites of cis configuration and D stereoisomers, derived from breakdown of unsaturated fatty acids, to the trans- or L isomers of saturated fatty acid breakdown by an isomerase and an epimerase, respectively. When cis double bonds are located at even-numbered carbon atoms, such as linoleic acid (cis,cis(9,12)-octadecadienoic acid), after the fatty acid is degraded to the ten carbon stage an extra step is required to deal with the resulting compound, trans,δ(2)-cis,δ(4)decadienoyl-CoA. The enzyme 2,4-dienoyl-CoA reductase, converts this to trans,δ(2)decenoyl-CoA which enters the normal cycle at the point of the isomerase.
The order of the reaction is as follows:
a 2,3,4 saturated fatty acid is transformed into a 2,3,4 saturated fatty acyl CoA through a Long and short chain fatty acid CoA ligase. The 2,3,4 saturated fatty acyl CoA is then transformed into a trans 2 enoyl CoA. This enoyl can also be produced from a cis 3 enoyl CoA through a fatty acid oxidation protein complex. The trans 2 enoyl is transformed into a 3s 3 hydroxyacyl CoA through a 2,3 dehydroadipyl CoA hydratase. This same enzyme turns the product into a 3-oxoacyl-CoA. This is followed by the last step in the reaction when the oxoacyl-coa is turn into an acetyl coa+ a 2,3,4 saturated fatty acyl CoA through a 3-ketoacyl-CoA thiolasePW001020Metabolicfatty acid oxidation (myristate)Although enzymes of the pathway handle both short and long chain fatty acids, it is the long chain compounds that induce the enzymes of the pathway . Each turn of the cycle removes two carbon atoms until only two or three remain. When even-numbered fatty acids are broken down, a two-carbon compound remains, acetyl-CoA. When odd number fatty acids are broken down, a three-carbon residue results, propionylCoA. Unsaturated fatty acids, with cis double bonds located at odd-numbered carbon atoms, enter the main pathway of saturated fatty acid degradation by converting related metabolites of cis configuration and D stereoisomers, derived from breakdown of unsaturated fatty acids, to the trans- or L isomers of saturated fatty acid breakdown by an isomerase and an epimerase, respectively. When cis double bonds are located at even-numbered carbon atoms, such as linoleic acid (cis,cis(9,12)-octadecadienoic acid), after the fatty acid is degraded to the ten carbon stage an extra step is required to deal with the resulting compound, trans,δ(2)-cis,δ(4)decadienoyl-CoA. The enzyme 2,4-dienoyl-CoA reductase, converts this to trans,δ(2)decenoyl-CoA which enters the normal cycle at the point of the isomerase.
The order of the reaction is as follows:
a 2,3,4 saturated fatty acid is transformed into a 2,3,4 saturated fatty acyl CoA through a Long and short chain fatty acid CoA ligase. The 2,3,4 saturated fatty acyl CoA is then transformed into a trans 2 enoyl CoA. This enoyl can also be produced from a cis 3 enoyl CoA through a fatty acid oxidation protein complex. The trans 2 enoyl is transformed into a 3s 3 hydroxyacyl CoA through a 2,3 dehydroadipyl CoA hydratase. This same enzyme turns the product into a 3-oxoacyl-CoA. This is followed by the last step in the reaction when the oxoacyl-coa is turn into an acetyl coa+ a 2,3,4 saturated fatty acyl CoA through a 3-ketoacyl-CoA thiolasePW001021Metabolicfatty acid oxidation (octanoate)Although enzymes of the pathway handle both short and long chain fatty acids, it is the long chain compounds that induce the enzymes of the pathway . Each turn of the cycle removes two carbon atoms until only two or three remain. When even-numbered fatty acids are broken down, a two-carbon compound remains, acetyl-CoA. When odd number fatty acids are broken down, a three-carbon residue results, propionylCoA. Unsaturated fatty acids, with cis double bonds located at odd-numbered carbon atoms, enter the main pathway of saturated fatty acid degradation by converting related metabolites of cis configuration and D stereoisomers, derived from breakdown of unsaturated fatty acids, to the trans- or L isomers of saturated fatty acid breakdown by an isomerase and an epimerase, respectively. When cis double bonds are located at even-numbered carbon atoms, such as linoleic acid (cis,cis(9,12)-octadecadienoic acid), after the fatty acid is degraded to the ten carbon stage an extra step is required to deal with the resulting compound, trans,δ(2)-cis,δ(4)decadienoyl-CoA. The enzyme 2,4-dienoyl-CoA reductase, converts this to trans,δ(2)decenoyl-CoA which enters the normal cycle at the point of the isomerase.
The order of the reaction is as follows:
a 2,3,4 saturated fatty acid is transformed into a 2,3,4 saturated fatty acyl CoA through a Long and short chain fatty acid CoA ligase. The 2,3,4 saturated fatty acyl CoA is then transformed into a trans 2 enoyl CoA. This enoyl can also be produced from a cis 3 enoyl CoA through a fatty acid oxidation protein complex. The trans 2 enoyl is transformed into a 3s 3 hydroxyacyl CoA through a 2,3 dehydroadipyl CoA hydratase. This same enzyme turns the product into a 3-oxoacyl-CoA. This is followed by the last step in the reaction when the oxoacyl-coa is turn into an acetyl coa+ a 2,3,4 saturated fatty acyl CoA through a 3-ketoacyl-CoA thiolasePW001022Metabolicfatty acid oxidation (palmitate)Although enzymes of the pathway handle both short and long chain fatty acids, it is the long chain compounds that induce the enzymes of the pathway . Each turn of the cycle removes two carbon atoms until only two or three remain. When even-numbered fatty acids are broken down, a two-carbon compound remains, acetyl-CoA. When odd number fatty acids are broken down, a three-carbon residue results, propionylCoA. Unsaturated fatty acids, with cis double bonds located at odd-numbered carbon atoms, enter the main pathway of saturated fatty acid degradation by converting related metabolites of cis configuration and D stereoisomers, derived from breakdown of unsaturated fatty acids, to the trans- or L isomers of saturated fatty acid breakdown by an isomerase and an epimerase, respectively. When cis double bonds are located at even-numbered carbon atoms, such as linoleic acid (cis,cis(9,12)-octadecadienoic acid), after the fatty acid is degraded to the ten carbon stage an extra step is required to deal with the resulting compound, trans,δ(2)-cis,δ(4)decadienoyl-CoA. The enzyme 2,4-dienoyl-CoA reductase, converts this to trans,δ(2)decenoyl-CoA which enters the normal cycle at the point of the isomerase.
The order of the reaction is as follows:
a 2,3,4 saturated fatty acid is transformed into a 2,3,4 saturated fatty acyl CoA through a Long and short chain fatty acid CoA ligase. The 2,3,4 saturated fatty acyl CoA is then transformed into a trans 2 enoyl CoA. This enoyl can also be produced from a cis 3 enoyl CoA through a fatty acid oxidation protein complex. The trans 2 enoyl is transformed into a 3s 3 hydroxyacyl CoA through a 2,3 dehydroadipyl CoA hydratase. This same enzyme turns the product into a 3-oxoacyl-CoA. This is followed by the last step in the reaction when the oxoacyl-coa is turn into an acetyl coa+ a 2,3,4 saturated fatty acyl CoA through a 3-ketoacyl-CoA thiolasePW001023Metabolicfatty acid oxidation (steareate)Although enzymes of the pathway handle both short and long chain fatty acids, it is the long chain compounds that induce the enzymes of the pathway . Each turn of the cycle removes two carbon atoms until only two or three remain. When even-numbered fatty acids are broken down, a two-carbon compound remains, acetyl-CoA. When odd number fatty acids are broken down, a three-carbon residue results, propionylCoA. Unsaturated fatty acids, with cis double bonds located at odd-numbered carbon atoms, enter the main pathway of saturated fatty acid degradation by converting related metabolites of cis configuration and D stereoisomers, derived from breakdown of unsaturated fatty acids, to the trans- or L isomers of saturated fatty acid breakdown by an isomerase and an epimerase, respectively. When cis double bonds are located at even-numbered carbon atoms, such as linoleic acid (cis,cis(9,12)-octadecadienoic acid), after the fatty acid is degraded to the ten carbon stage an extra step is required to deal with the resulting compound, trans,δ(2)-cis,δ(4)decadienoyl-CoA. The enzyme 2,4-dienoyl-CoA reductase, converts this to trans,δ(2)decenoyl-CoA which enters the normal cycle at the point of the isomerase.
The order of the reaction is as follows:
a 2,3,4 saturated fatty acid is transformed into a 2,3,4 saturated fatty acyl CoA through a Long and short chain fatty acid CoA ligase. The 2,3,4 saturated fatty acyl CoA is then transformed into a trans 2 enoyl CoA. This enoyl can also be produced from a cis 3 enoyl CoA through a fatty acid oxidation protein complex. The trans 2 enoyl is transformed into a 3s 3 hydroxyacyl CoA through a 2,3 dehydroadipyl CoA hydratase. This same enzyme turns the product into a 3-oxoacyl-CoA. This is followed by the last step in the reaction when the oxoacyl-coa is turn into an acetyl coa+ a 2,3,4 saturated fatty acyl CoA through a 3-ketoacyl-CoA thiolasePW001024Metabolicfructose metabolismFructose metabolism begins with the transport of Beta-D-fructofuranose through a fructose PTS permease, resulting in a Beta-D-fructofuranose 1-phosphate. This compound is phosphorylated by an ATP driven 1-phosphofructokinase resulting in a fructose 1,6-biphosphate. This compound can either react with a fructose bisphosphate aldolase class 1 resulting in D-glyceraldehyde 3-phosphate and a dihydroxyacetone phosphate or through a fructose biphosphate aldolase class 2 resulting in a D-glyceraldehyde 3-phosphate. This compound can then either react in a reversible triosephosphate isomerase resulting in a dihydroxyacetone phosphate or react with a phosphate through a NAD dependent Glyceraldehyde 3-phosphate dehydrogenase resulting in a glyceric acid 1,3-biphosphate. This compound is desphosphorylated by a phosphoglycerate kinase resulting in a 3-phosphoglyceric acid.This compound in turn can either react with a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase or a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase resulting in a 2-phospho-D-glyceric acid. This compound interacts with an enolase resulting in a phosphoenolpyruvic acid and water. Phosphoenolpyruvic acid can react either through a AMP driven phosphoenoylpyruvate synthase or a ADP driven pyruvate kinase protein complex resulting in a pyruvic acid.
Pyruvic acid reacts with CoA through a NAD driven pyruvate dehydrogenase complex resulting in a carbon dioxide and a Acetyl-CoA which gets incorporated into the TCA cycle pathway.
PW000913Metabolicglycerol metabolismGlycerol metabolism starts with glycerol is introduced into the cytoplasm through a glycerol channel GlpF Glycerol is then phosphorylated through an ATP mediated glycerol kinase resulting in a Glycerol 3-phosphate. This compound can also be obtained through a glycerophosphodiester reacting with water through a glycerophosphoryl diester phosphodiesterase or it can also be introduced into the cytoplasm through a glycerol-3-phosphate:phosphate antiporter.
Glycerol 3-phosphate is then metabolized into a dihydroxyacetone phosphate in both aerobic or anaerobic conditions. In anaerobic conditions the metabolism is done through the reaction of glycerol 3-phosphate with a menaquinone mediated by a glycerol-3-phosphate dehydrogenase protein complex. In aerobic conditions, the metabolism is done through the reaction of glycerol 3-phosphate with ubiquinone mediated by a glycerol-3-phosphate dehydrogenase [NAD(P]+].
Dihydroxyacetone phosphate is then introduced into the fructose metabolism by turning a dihydroxyacetone into an isomer through a triosephosphate isomerase resulting in a D-glyceraldehyde 3-phosphate which in turn reacts with a phosphate through a NAD dependent Glyceraldehyde 3-phosphate dehydrogenase resulting in a glyceric acid 1,3-biphosphate. This compound is desphosphorylated by a phosphoglycerate kinase resulting in a 3-phosphoglyceric acid.This compound in turn can either react with a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase or a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase resulting in a 2-phospho-D-glyceric acid. This compound interacts with an enolase resulting in a phosphoenolpyruvic acid and water. Phosphoenolpyruvic acid can react either through a AMP driven phosphoenoylpyruvate synthase or a ADP driven pyruvate kinase protein complex resulting in a pyruvic acid. Pyruvic acid reacts with CoA through a NAD driven pyruvate dehydrogenase complex resulting in a carbon dioxide and a Acetyl-CoA which gets incorporated into the TCA cycle pathway.PW000914Metabolicglycerol metabolism IIGlycerol metabolism starts with glycerol is introduced into the cytoplasm through a glycerol channel GlpF Glycerol is then phosphorylated through an ATP mediated glycerol kinase resulting in a Glycerol 3-phosphate. This compound can also be obtained through sn-glycero-3-phosphocholine reacting with water through a glycerophosphoryl diester phosphodiesterase producing a benzyl alcohol, a hydrogen ion and a glycerol 3-phosphate or the campound can be introduced into the cytoplasm through a glycerol-3-phosphate:phosphate antiporter. Glycerol 3-phosphate is then metabolized into a dihydroxyacetone phosphate in both aerobic or anaerobic conditions. In anaerobic conditions the metabolism is done through the reaction of glycerol 3-phosphate with a menaquinone mediated by a glycerol-3-phosphate dehydrogenase protein complex. In aerobic conditions, the metabolism is done through the reaction of glycerol 3-phosphate with ubiquinone mediated by a glycerol-3-phosphate dehydrogenase [NAD(P]+]. Dihydroxyacetone phosphate is then introduced into the fructose metabolism by turning a dihydroxyacetone into an isomer through a triosephosphate isomerase resulting in a D-glyceraldehyde 3-phosphate which in turn reacts with a phosphate through a NAD dependent Glyceraldehyde 3-phosphate dehydrogenase resulting in a glyceric acid 1,3-biphosphate. This compound is desphosphorylated by a phosphoglycerate kinase resulting in a 3-phosphoglyceric acid.This compound in turn can either react with a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase or a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase resulting in a 2-phospho-D-glyceric acid. This compound interacts with an enolase resulting in a phosphoenolpyruvic acid and water. Phosphoenolpyruvic acid can react either through a AMP driven phosphoenoylpyruvate synthase or a ADP driven pyruvate kinase protein complex resulting in a pyruvic acid. Pyruvic acid reacts with CoA through a NAD driven pyruvate dehydrogenase complex resulting in a carbon dioxide and a Acetyl-CoA which gets incorporated into the TCA cycle pathway.PW000915Metabolicglycerol metabolism III (sn-glycero-3-phosphoethanolamine)Glycerol metabolism starts with glycerol is introduced into the cytoplasm through a glycerol channel GlpF Glycerol is then phosphorylated through an ATP mediated glycerol kinase resulting in a Glycerol 3-phosphate. This compound can also be obtained through sn-glycero-3-phosphethanolamine reacting with water through a glycerophosphoryl diester phosphodiesterase producing a benzyl alcohol, a hydrogen ion and a glycerol 3-phosphate or the campound can be introduced into the cytoplasm through a glycerol-3-phosphate:phosphate antiporter. Glycerol 3-phosphate is then metabolized into a dihydroxyacetone phosphate in both aerobic or anaerobic conditions. In anaerobic conditions the metabolism is done through the reaction of glycerol 3-phosphate with a menaquinone mediated by a glycerol-3-phosphate dehydrogenase protein complex. In aerobic conditions, the metabolism is done through the reaction of glycerol 3-phosphate with ubiquinone mediated by a glycerol-3-phosphate dehydrogenase [NAD(P]+]. Dihydroxyacetone phosphate is then introduced into the fructose metabolism by turning a dihydroxyacetone into an isomer through a triosephosphate isomerase resulting in a D-glyceraldehyde 3-phosphate which in turn reacts with a phosphate through a NAD dependent Glyceraldehyde 3-phosphate dehydrogenase resulting in a glyceric acid 1,3-biphosphate. This compound is desphosphorylated by a phosphoglycerate kinase resulting in a 3-phosphoglyceric acid.This compound in turn can either react with a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase or a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase resulting in a 2-phospho-D-glyceric acid. This compound interacts with an enolase resulting in a phosphoenolpyruvic acid and water. Phosphoenolpyruvic acid can react either through a AMP driven phosphoenoylpyruvate synthase or a ADP driven pyruvate kinase protein complex resulting in a pyruvic acid. Pyruvic acid reacts with CoA through a NAD driven pyruvate dehydrogenase complex resulting in a carbon dioxide and a Acetyl-CoA which gets incorporated into the TCA cycle pathway.PW000916Metabolicglycerol metabolism IV (glycerophosphoglycerol)Glycerol metabolism starts with glycerol is introduced into the cytoplasm through a glycerol channel GlpF Glycerol is then phosphorylated through an ATP mediated glycerol kinase resulting in a Glycerol 3-phosphate. This compound can also be obtained through glycerophosphoglycerol reacting with water through a glycerophosphoryl diester phosphodiesterase producing a benzyl alcohol, a hydrogen ion and a glycerol 3-phosphate or the campound can be introduced into the cytoplasm through a glycerol-3-phosphate:phosphate antiporter. Glycerol 3-phosphate is then metabolized into a dihydroxyacetone phosphate in both aerobic or anaerobic conditions. In anaerobic conditions the metabolism is done through the reaction of glycerol 3-phosphate with a menaquinone mediated by a glycerol-3-phosphate dehydrogenase protein complex. In aerobic conditions, the metabolism is done through the reaction of glycerol 3-phosphate with ubiquinone mediated by a glycerol-3-phosphate dehydrogenase [NAD(P]+]. Dihydroxyacetone phosphate is then introduced into the fructose metabolism by turning a dihydroxyacetone into an isomer through a triosephosphate isomerase resulting in a D-glyceraldehyde 3-phosphate which in turn reacts with a phosphate through a NAD dependent Glyceraldehyde 3-phosphate dehydrogenase resulting in a glyceric acid 1,3-biphosphate. This compound is desphosphorylated by a phosphoglycerate kinase resulting in a 3-phosphoglyceric acid.This compound in turn can either react with a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase or a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase resulting in a 2-phospho-D-glyceric acid. This compound interacts with an enolase resulting in a phosphoenolpyruvic acid and water. Phosphoenolpyruvic acid can react either through a AMP driven phosphoenoylpyruvate synthase or a ADP driven pyruvate kinase protein complex resulting in a pyruvic acid. Pyruvic acid reacts with CoA through a NAD driven pyruvate dehydrogenase complex resulting in a carbon dioxide and a Acetyl-CoA which gets incorporated into the TCA cycle pathway.PW000917Metabolicglycerol metabolism V (glycerophosphoserine)Glycerol metabolism starts with glycerol is introduced into the cytoplasm through a glycerol channel GlpF Glycerol is then phosphorylated through an ATP mediated glycerol kinase resulting in a Glycerol 3-phosphate. This compound can also be obtained through glycerophosphoserine reacting with water through a glycerophosphoryl diester phosphodiesterase producing a benzyl alcohol, a hydrogen ion and a glycerol 3-phosphate or the campound can be introduced into the cytoplasm through a glycerol-3-phosphate:phosphate antiporter. Glycerol 3-phosphate is then metabolized into a dihydroxyacetone phosphate in both aerobic or anaerobic conditions. In anaerobic conditions the metabolism is done through the reaction of glycerol 3-phosphate with a menaquinone mediated by a glycerol-3-phosphate dehydrogenase protein complex. In aerobic conditions, the metabolism is done through the reaction of glycerol 3-phosphate with ubiquinone mediated by a glycerol-3-phosphate dehydrogenase [NAD(P]+]. Dihydroxyacetone phosphate is then introduced into the fructose metabolism by turning a dihydroxyacetone into an isomer through a triosephosphate isomerase resulting in a D-glyceraldehyde 3-phosphate which in turn reacts with a phosphate through a NAD dependent Glyceraldehyde 3-phosphate dehydrogenase resulting in a glyceric acid 1,3-biphosphate. This compound is desphosphorylated by a phosphoglycerate kinase resulting in a 3-phosphoglyceric acid.This compound in turn can either react with a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase or a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase resulting in a 2-phospho-D-glyceric acid. This compound interacts with an enolase resulting in a phosphoenolpyruvic acid and water. Phosphoenolpyruvic acid can react either through a AMP driven phosphoenoylpyruvate synthase or a ADP driven pyruvate kinase protein complex resulting in a pyruvic acid. Pyruvic acid reacts with CoA through a NAD driven pyruvate dehydrogenase complex resulting in a carbon dioxide and a Acetyl-CoA which gets incorporated into the TCA cycle pathway.PW000918Metabolicglycolate and glyoxylate degradationGlycolic acid is introduced into the cytoplasm through either a glycolate / lactate:H+ symporter or a acetate / glycolate transporter. Once inside, glycolic acid reacts with an oxidized electron-transfer flavoprotein through a glycolate oxidase resulting in a reduced acceptor and glyoxylic acid. Glyoxylic acid can also be obtained from the introduction of glyoxylic acid. It can also be obtained from the metabolism of (S)-allantoin.
S-allantoin is introduced into the cytoplasm through a purine and pyrimidine transporter(allantoin specific). Once inside, the compound reacts with water through a allantoinase resulting in hydrogen ion and allantoic acid. Allantoic acid then reacts with water and hydrogen ion through a allantoate amidohydrolase resulting in a carbon dioxide, ammonium and S-ureidoglycine. The latter compound reacts with water through a S-ureidoglycine aminohydrolase resulting in ammonium and S-ureidoglycolic acid which in turn reacts with a Ureidoglycolate lyase resulting in urea and glyoxylic acid.
Glyoxylic acid can either be metabolized into L-malic acid by a reaction with acetyl-CoA and Water through a malate synthase G which also releases hydrogen ion and Coenzyme A. L-malic acid is then incorporated into the TCA cycle.
Glyoxylic acid can also be metabolized by glyoxylate carboligase, releasing a carbon dioxide and tartronate semialdehyde. The latter compound is then reduced by an NADH driven tartronate semialdehyde reductase 2 resulting in glyceric acid. Glyceric acid is phosphorylated by a glycerate kinase 2 resulting in a 3-phosphoglyceric acid. This compound is then integrated into various other pathways: cysteine biosynthesis, serine biosynthesis and glycolysis and pyruvate dehydrogenase.
PW000827Metabolicglycolysis and pyruvate dehydrogenaseFructose metabolism begins with the transport of Beta-D-glucose 6-phosphate through a glucose PTS permease, resulting in a Beta-D-glucose 6-phosphate. This compound is isomerized by a glucose-6-phosphate isomerase resulting in a fructose 6-phosphate. This compound can be phosphorylated by two different enzymes, a pyridoxal phosphatase/fructose 1,6-bisphosphatase or a ATP driven-6-phosphofructokinase-1 resulting in a fructose 1,6-biphosphate. This compound can either react with a fructose bisphosphate aldolase class 1 resulting in D-glyceraldehyde 3-phosphate and a dihydroxyacetone phosphate or through a fructose biphosphate aldolase class 2 resulting in a D-glyceraldehyde 3-phosphate. This compound can then either react in a reversible triosephosphate isomerase resulting in a dihydroxyacetone phosphate or react with a phosphate through a NAD dependent Glyceraldehyde 3-phosphate dehydrogenase resulting in a glyceric acid 1,3-biphosphate. This compound is desphosphorylated by a phosphoglycerate kinase resulting in a 3-phosphoglyceric acid.This compound in turn can either react with a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase or a 2,3-bisphosphoglycerate-independent phosphoglycerate mutase resulting in a 2-phospho-D-glyceric acid. This compound interacts with an enolase resulting in a phosphoenolpyruvic acid and water. Phosphoenolpyruvic acid can react either through a AMP driven phosphoenoylpyruvate synthase or a ADP driven pyruvate kinase protein complex resulting in a pyruvic acid.
Pyruvic acid reacts with CoA through a NAD driven pyruvate dehydrogenase complex resulting in a carbon dioxide and a Acetyl-CoA which gets incorporated into the TCA cycle pathway.
PW000785Metabolicornithine metabolism
In the ornithine biosynthesis pathway of E. coli, L-glutamate is acetylated to N-acetylglutamate by the enzyme N-acetylglutamate synthase, encoded by the argA gene. The acetyl donor for this reaction is acetyl-CoA. N-acetylglutamic acid is then phosphorylated via an ATP driven acetylglutamate kinase which yields a N-acetyl-L-glutamyl 5-phosphate. This compound undergoes a NADPH dependent reduction resulting in N-acetyl-L-glutamate 5-semialdehyde. This compound reacts with L-glutamic acid through a acetylornithine aminotransferase / N-succinyldiaminopimelate aminotransferase to produce a N-acetylornithine which is then deacetylated through a acetylornithine deacetylase which yield an ornithine. Ornithine interacts with hydrogen ion through a Ornithine decarboxylase resulting in a carbon dioxide release and a putrescine
Putrescine can be metabolized by reaction with either l-glutamic acid or oxoglutaric acid. If putrescine reacts with L-glutamic acid, it reacts through an ATP mediated gamma-glutamylputrescine producing a hydrogen ion, ADP, phosphate and gamma-glutamyl-L-putrescine. This compound is reduced by interacting with oxygen, water and a gamma-glutamylputrescine oxidoreductase resulting in ammonium, hydrogen peroxide and 4-gamma-glutamylamino butanal. This compound is dehydrogenated through a NADP mediated reaction lead by gamma-glutamyl-gamma-aminobutaryaldehyde dehydrogenase resulting in hydrogen ion, NADPH and 4-glutamylamino butanoate. In turn, the latter compound reacts with water through a gamma-glutamyl-gamma-aminobutyrate hydrolase resulting in L-glutamic acid and Gamma aminobutyric acid. On the other hand, if putrescine reacts with oxoglutaric acid through a putrescine aminotransferase, it results in L-glutamic acid, and a 4-aminobutyraldehyde. This compound reacts with water through a NAD dependent gamma aminobutyraldehyde dehydrogenase resulting in hydrogen ion, NADH and gamma-aminobutyric acid.
Gamma Aaminobutyric acid reacts with oxoglutaric acid through 4-aminobutyrate aminotransferase resulting in L-glutamic acid and succinic acid semialdehyde. This compound in turn can react with with either NADP or NAD to result in the production of succinic acid through succinate-semialdehyde dehydrogenase or aldehyde dehydrogenase-like protein yneI respectively. Succinic acid can then be integrated in the TCA cycle.
PW000791Metabolicpalmitate biosynthesisPalmitate is synthesized by stepwise condensation of C2 units to a growing acyl chain. Each elongation cycle results in the addition of two carbons to the acyl chain, and consists of four separate reactions.
The pathway starts with acetyl-CoA interacting with hydrogen carbonate through an ATP driven acetyl-CoA carboxylase resulting in a phosphate, an ADP , a hydrogen ion and a malonyl-CoA. The latter compound interacts with a holo-[acp] through a malonyl-CoA-ACP transacylase resulting in a CoA and a malonyl-[acp]. This compound interacts with hydrogen ion, acetyl-CoA through a KASIII resulting in a CoA, carbon dioxide and an acetoacetyl-[acp].
The latter compound interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (R) 3-Hydroxybutanoyl-[acp](1).
This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a crotonyl-[acp](2).
The crotonyl-[acp] interacts with a hydrogen ion through a NADH enoyl-[acyl-carrier-protein] reductase(NAD) resulting in NAD and a butyryl-[acp](3).
The butyryl-[acp] interacts with a hydrogen ion, a malonyl-[acp] through a KASI resulting in a holo-[acp],carbon dioxide and a 3-oxo-hexanoyl-[acp](4).
The 3-oxo-hexanoyl-[acp] interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (R) 3-Hydroxyhexanoyl-[acp](1).
This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a trans hex-2-enoyl-[acp](2).
The trans hex-2-enoyl-[acp] interacts with a hydrogen ion through a NADH enoyl-[acyl-carrier-protein] reductase(NAD) resulting in NAD and a hexanoyl-[acp](3).
The hexanoyl-[acp] interacts with a hydrogen ion, a malonyl-[acp] through a KASI resulting in a holo-[acp],carbon dioxide and a 3-oxo-octanoyl-[acp](4).
The 3-oxo-octanoyl-[acp] interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (R) 3-Hydroxyoctanoyl-[acp](1).
This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a trans oct-2-enoyl-[acp](2).
The trans oct-2-enoyl-[acp] interacts with a hydrogen ion through a NADH enoyl-[acyl-carrier-protein] reductase(NAD) resulting in NAD and a octanoyl-[acp](3).
The octanoyl-[acp] interacts with a hydrogen ion, a malonyl-[acp] through a KASI resulting in a holo-[acp],carbon dioxide and a 3-oxo-decanoyl-[acp](4).
The 3-oxo-decanoyl-[acp] interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (R) 3-Hydroxydecanoyl-[acp](1).
This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a trans-delta2-decenoyl-[acp](2).
The a trans-delta2-decenoyl-[acp] interacts with a hydrogen ion through a NADH enoyl-[acyl-carrier-protein] reductase(NAD) resulting in NAD and a decanoyl-[acp](3).
The decanoyl-[acp] interacts with a malonyl-[acp] through a KASI resulting in a holo-[acp],carbon dioxide and a 3-oxo-dodecanoyl-[acp](4).
The 3-oxo-dodecanoyl-[acp ]interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (R) 3-Hydroxydodecanoyl-[acp](1).
This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a trans dodec-2-enoyl-[acp](2).
The trans dodec-2-enoyl-[acp] interacts with a hydrogen ion through a NADH enoyl-[acyl-carrier-protein] reductase(NAD) resulting in NAD and a dodecanoyl-[acp](3). This compound can either react with water spontaneously resulting in a hydrogen ion, a holo-[acp] and a dodecanoic acid or it interacts with a hydrogen ion, a malonyl-[acp] through a KASI resulting in a holo-[acp],carbon dioxide and a 3-oxo-myristoyl-[acp](4).
The 3-oxo-myristoyl-[acp] interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (3R) 3-Hydroxymyristoyl-[acp](1).
This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a trans tetradec-2-enoyl-[acp](2).
This compound interacts with a hydrogen ion, through a NADH-driven KASI resulting in a NAD and a myristoyl-[acp].
Myristoyl-[acp] with a hydrogen ion, a malonyl-[acp] through a KASI resulting in a holo-[acp],carbon dioxide and a 3-oxo-palmitoyl-[acp](4).
The 3-oxo-palmitoyl-[acp] interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (3R) 3-Hydroxypalmitoyl-[acp](1).
This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a trans hexadecenoyl-[acp](2).
The trans hexadecenoyl-[acp] interacts with a hydrogen ion through a NADH enoyl-[acyl-carrier-protein] reductase(NAD) resulting in NAD and a palmitoyl-[acp](3).
Palmitoyl then reacts with water spontaneously resulting in a hydrogen ion, a holo-[acp] and palmitic acid.
No integral membrane protein required for long chain fatty acid uptake has been identified in E. coli. The transport of long chain fatty acids across the cytoplasmic membrane is dependent on fatty acyl-CoA synthetase. An energised membrane is necessary for fatty acid transport and it has been suggested that uncharged fatty acids flip across the inner membrane by diffusion.
PW000797Metabolicpeptidoglycan biosynthesis IPeptidoglycan is a net-like polymer which surrounds the cytoplasmic membrane of most bacteria and functions to maintain cell shape and prevent rupture due to the internal turgor.In E. coli K-12, the peptidoglycan consists of glycan strands of alternating subunits of N-acetylglucosamine (GlcNAc) and N-acetylmuramic acid (MurNAc) which are cross-linked by short peptides. The pathway for constructing this net involves two cell compartments: cytoplasm and periplasmic space.
The pathway starts with a beta-D-fructofuranose going through a mannose PTS permease, phosphorylating the compund and producing a beta-D-fructofuranose 6 phosphate. This compound can be obtained from the glycolysis and pyruvate dehydrogenase or from an isomerization reaction of Beta-D-glucose 6-phosphate through a glucose-6-phosphate isomerase.The compound Beta-D-fructofuranose 6 phosphate and L-Glutamine react with a glucosamine fructose-6-phosphate aminotransferase, thus producing a glucosamine 6-phosphate and a l-glutamic acid. The glucosamine 6-phosphate interacts with phosphoglucosamine mutase in a reversible reaction producing glucosamine-1P. Glucosamine-1p and acetyl coa undergo acetylation throuhg a bifunctional protein glmU releasing Coa and a hydrogen ion and producing a N-acetyl-glucosamine 1-phosphate. Glmu, being a bifunctional protein, follows catalyze the interaction of N-acetyl-glucosamine 1-phosphate, hydrogen ion and UTP into UDP-N-acetylglucosamine and pyrophosphate. UDP-N-acetylglucosamine then interacts with phosphoenolpyruvic acid and a UDP-N acetylglucosamine 1- carboxyvinyltransferase realeasing a phosphate and the compound UDP-N-acetyl-alpha-D-glucosamine-enolpyruvate. This compound undergoes a NADPH dependent reduction producing a UDP-N-acetyl-alpha-D-muramate through a UDP-N-acetylenolpyruvoylglucosamine reductase. UDP-N-acetyl-alpha-D-muramate and L-alanine react in an ATP-mediated ligation through a UDP-N-acetylmuramate-alanine ligase releasing an ADP, hydrogen ion, a phosphate and a UDP-N-acetylmuramoyl-L-alanine. This compound interacts with D-glutamic acid and ATP through UDP-N-acetylmuramoylalanine-D-glutamate ligase releasing ADP, A phosphate and UDP-N-acetylmuramoyl-L-alanyl-D-glutamate. The latter compound then interacts with meso-diaminopimelate in an ATP mediated ligation through a UDP-N-acetylmuramoylalanine-D-glutamate-2,6-diaminopimelate ligase resulting in ADP, phosphate, hydrogen ion and UDP-N-Acetylmuramoyl-L-alanyl-D-gamma-glutamyl-meso-2,6-diaminopimelate. This compound in turn with D-alanyl-D-alanine react in an ATP-mediated ligation through UDP-N-Acetylmuramoyl-tripeptide-D-alanyl-D-alanine ligase to produce UDP-N-acetyl-alpha-D-muramoyl-L-alanyl-gama-D-glutamyl-meso-2,6-diaminopimeloyl-Dalanyl-D-alanine and hydrogen ion, ADP, phosphate. UDP-N-acetyl-alpha-D-muramoyl-L-alanyl-gama-D-glutamyl-meso-2,6-diaminopimeloyl-Dalanyl-D-alanine interacts with di-trans,octa-cis-undecaprenyl phosphate through a phospho-N-acetylmuramoyl-pentapeptide-transferase, resulting in UMP and Undecaprenyl-diphospho-N-acetylmuramoyl-L-alanyl-D-glutamyl-meso-2,6-diaminopimeloyl-D-alanyl-D-alanine which in turn reacts with a UDP-N-acetylglucosamine through a N-acetylglucosaminyl transferase to produce a hydrogen, UDP and ditrans,octacis-undecaprenyldiphospho-N-acetyl-(N-acetylglucosaminyl)muramoyl-L-alanyl-gamma-D-glutamyl-meso-2,6-diaminopimeloyl-D-alanyl-D-alanine. This compound ends the cytoplasmic part of the pathway. ditrans,octacis-undecaprenyldiphospho-N-acetyl-(N-acetylglucosaminyl)muramoyl-L-alanyl-gamma-D-glutamyl-meso-2,6-diaminopimeloyl-D-alanyl-D-alanine is transported through a lipi II flippase. Once in the periplasmic space, the compound reacts with a penicillin binding protein 1A prodducing a peptidoglycan dimer, a hydrogen ion, and UDP. The peptidoglycan dimer then reacts with a penicillin binding protein 1B producing a peptidoglycan with D,D, cross-links and a D-alanine.
PW000906Metabolicserine biosynthesis and metabolismSerine biosynthesis is a major metabolic pathway in E. coli. Its end product, serine, is not only used in protein synthesis, but also as a precursor for the biosynthesis of glycine, cysteine, tryptophan, and phospholipids. In addition, it directly or indirectly serves as a source of one-carbon units for the biosynthesis of various compounds.
The biosynthesis of serine starts with 3-phosphoglyceric acid being metabolized by a NAD driven D-3-phosphoglycerate dehydrogenase / α-ketoglutarate reductase resulting in the release of a NADH, a hydrogen ion and a phosphohydroxypyruvic acid. The latter compound then interacts with an L-glutamic acid through a 3-phosphoserine aminotransferase / phosphohydroxythreonine aminotransferase resulting in oxoglutaric acid and DL-D-phosphoserine.
The DL-D-phosphoserine can also be imported into the cytoplasm through a phosphonate ABC transporter. The DL-D-phosphoserine is dephosphorylated by interacting with a water molecule through a phosphoserine phosphatase resulting in the release of a phosphate and an L-serine
L-serine is then metabolized by being dehydrated through either a L-serine dehydratase 2 or a L-serine dehydratase 1 resulting in the release of a water molecule, a hydrogen ion and a 2-aminoacrylic acid. The latter compound is an isomer of a 2-iminopropanoate which reacts spontaneously with a water molecule and a hydrogen ion resulting in the release of Ammonium and pyruvic acid. Pyruvic acid then interacts with a coenzyme A through a NAD driven pyruvate dehydrogenase complex resulting in the release of a NADH, a carbon dioxide and an acetyl-CoA.
PW000809Metabolicsuperpathway of D-glucarate and D-galactarate degradation
Galactarate is a naturally occurring dicarboxylic acid analog of D-galactose. E. coli can use both diacid sugars galactarate and D-glucarate as the sole source of carbon for growth.
The initial step in the degradation of galactarate is its dehydration to 5-dehydro-4-deoxy-D-glucarate(2--) by galactarate dehydratase. Glucaric acid can also be dehydrated by a glucarate dehydratase resulting in water and 5-dehydro-4-deoxy-D-glucarate(2--).
The 5-dehydro-4-deoxy-D-glucarate(2--) is then metabolized by a alpha-dehydro-beta-deoxy-D-glucarate aldolase resulting in pyruvic acid and a tartonate semialdehyde.
Pyruvic acid interacts with coenzyme A through a NAD driven Pyruvate dehydrogenase complex resulting in a carbon dioxide, an NADH and an acetyl-CoA.
The tartronate semialdehyde interacts with a hydrogen ion through a NADPH driven tartronate semialdehyde reductase resulting in a NADP and a glyceric acid. The glyceric acid is phosphorylated by an ATP-driven glycerate kinase 2 resulting in an ADP, a hydrogen ion and a 2-phosphoglyceric acid. The latter compound is dehydrated by an enolase resulting in the release of water and a phosphoenolpyruvic acid.
The phosphoenolpyruvic acid interacts with a hydrogen ion through an ADP driven pyruvate kinase resulting in an ATP and a pyruvic acid. The pyruvic acid then interacts with water and an ATP through a phosphoenolpyruvate synthetase resulting in the release of a hydrogen ion, a phosphate, an AMP and a Phosphoenolpyruvic acid.PW000795Metabolicthreonine biosynthesisThe biosynthesis of threonine starts with oxalacetic acid interacting with an L-glutamic acid through an aspartate aminotransferase resulting in a oxoglutaric acid and an L-aspartic acid. The latter compound is then phosphorylated by an ATP driven Aspartate kinase resulting in an a release of an ADP and an L-aspartyl-4-phosphate. This compound interacts with a hydrogen ion through an NADPH driven aspartate semialdehyde dehydrogenase resulting in the release of a phosphate, an NADP and a L-aspartate-semialdehyde.The latter compound interacts with a hydrogen ion through a NADPH driven aspartate kinase / homoserine dehydrogenase resulting in the release of an NADP and a L-homoserine. L-homoserine is phosphorylated through an ATP driven homoserine kinase resulting in the release of an ADP, a hydrogen ion and a O-phosphohomoserine. The latter compound then interacts with a water molecule threonine synthase resulting in the release of a phosphate and an L-threonine. PW000817Metaboliclipopolysaccharide biosynthesis IIE. coli lipid A is synthesized on the cytoplasmic surface of the inner membrane. The pathway can start from the fructose 6-phosphate that is either produced in the glycolysis and pyruvate dehydrogenase or be obtained from the interaction with D-fructose interacting with a mannose PTS permease. Fructose 6-phosphate interacts with L-glutamine through a D-fructose-6-phosphate aminotransferase resulting into a L-glutamic acid and a glucosamine 6-phosphate. The latter compound is isomerized through a phosphoglucosamine mutase resulting a glucosamine 1-phosphate. This compound is acetylated, interacting with acetyl-CoA through a bifunctional protein glmU resulting in a Coenzyme A, hydrogen ion and N-acetyl-glucosamine 1-phosphate. This compound interact with UTP and hydrogen ion through the bifunctional protein glmU resulting in a pyrophosphate and a UDP-N-acetylglucosamine. This compound interacts with (3R)-3-hydroxymyristoyl-[acp] through an UDP-N-acetylglucosamine acyltransferase resulting in a holo-[acp] and a UDP-3-O[(3R)-3-hydroxymyristoyl]-N-acetyl-alpha-D-glucosamine. This compound interacts with water through UDP-3-O-acyl-N-acetylglucosamine deacetylase resulting in an acetic acid and UDP-3-O-(3-hydroxymyristoyl)-α-D-glucosamine. The latter compound interacts with (3R)-3-hydroxymyristoyl-[acp] through UDP-3-O-(R-3-hydroxymyristoyl)-glucosamine N-acyltransferase releasing a hydrogen ion, a holo-acp and UDP-2-N,3-O-bis[(3R)-3-hydroxytetradecanoyl]-α-D-glucosamine. The latter compound is hydrolase by interacting with water and a UDP-2,3-diacylglucosamine hydrolase resulting in UMP, hydrogen ion and 2,3-bis[(3R)-3-hydroxymyristoyl]-α-D-glucosaminyl 1-phosphate. This last compound then interacts with a UDP-2-N,3-O-bis[(3R)-3-hydroxytetradecanoyl]-α-D-glucosamine through a lipid A disaccharide synthase resulting in a release of UDP, hydrogen ion and a lipid A disaccharide. The lipid A disaccharide is phosphorylated by an ATP mediated tetraacyldisaccharide 4'-kinase resulting in the release of hydrogen ion and lipid IVA. A D-ribulose 5-phosphate is isomerized with D-arabinose 5-phosphate isomerase 2 to result in a D-arabinose 5-phosphate. This compounds interacts with water and phosphoenolpyruvic acid through a 3-deoxy-D-manno-octulosonate 8-phosphate synthase resulting in the release of phosphate and 3-deoxy-D-manno-octulosonate 8-phosphate. This compound interacts with water through a 3-deoxy-D-manno-octulosonate 8-phosphate phosphatase thus releasing a phosphate and a 3-deoxy-D-manno-octulosonate. The latter compound interacts with CTP through a 3-deoxy-D-manno-octulosonate cytidylyltransferase resulting in a pyrophosphate and CMP-3-deoxy-α-D-manno-octulosonate. CMP-3-deoxy-α-D-manno-octulosonate and lipid IVA interact with each other through a KDO transferase resulting in CMP, hydrogen ion and alpha-Kdo-(2-->6)-lipid IVA. The latter compound reacts with CMP-3-deoxy-α-D-manno-octulosonate through a KDO transferase resulting in a CMP, hydrogen ion, and a a-Kdo-(2->4)-a-Kdo-(2->6)-lipid IVA. The latter compound can either interact with a phosphoethanolamine resulting in a 1,2-diacyl-sn-glycerol and a phosphoethanolamine-Kdo2-lipid A which can be exported outside the cell, or it can interact with a dodecanoyl-[acp] lauroyl acyltransferase resulting in a holo-[acp] and a (KDO)2-(lauroyl)-lipid IVA. The latter compound reacts with a myristoyl-[acp] through a myristoyl-acyl carrier protein (ACP)-dependent acyltransferase resulting in a holo-[acp], (KDO)2-lipid A. The latter compound reacts with ADP-L-glycero-beta-D-manno-heptose through ADP-heptose:LPS heptosyltransferase I resulting hydrogen ion, ADP, heptosyl-KDO2-lipid A. The latter compound interacts with ADP-L-glycero-beta-D-manno-heptose through ADP-heptose:LPS heptosyltransferase II resulting in ADP, hydrogen ion and (heptosyl)2-Kdo2-lipid A. The latter compound UDP-glucose interacts with (heptosyl)2-Kdo2-lipid A resulting in UDP, hydrogen ion and glucosyl-(heptosyl)2-Kdo2-lipid A. Glucosyl-(heptosyl)2-Kdo2-lipid A (Escherichia coli) is phosphorylated through an ATP-mediated lipopolysaccharide core heptose (I) kinase resulting in ADP, hydrogen ion and glucosyl-(heptosyl)2-Kdo2-lipid A-phosphate. The latter compound interacts with ADP-L-glycero-beta-D-manno-heptose through a lipopolysaccharide core heptosyl transferase III resulting in ADP, hydrogen ion, and glucosyl-(heptosyl)3-Kdo2-lipid A-phosphate. The latter compound is phosphorylated through an ATP-driven lipopolysaccharide core heptose (II) kinase resulting in ADP, hydrogen ion and glucosyl-(heptosyl)3-Kdo2-lipid A-bisphosphate. The latter compound interacts with UDP-alpha-D-galactose through a UDP-D-galactose:(glucosyl)lipopolysaccharide-1,6-D-galactosyltransferase resulting in a UDP, a hydrogen ion and a galactosyl-glucosyl-(heptosyl)3-Kdo2-lipid A-bisphosphate. The latter compound interacts with UDP-glucose through a (glucosyl)LPS α-1,3-glucosyltransferase resulting in a hydrogen ion, a UDP and galactosyl-(glucosyl)2-(heptosyl)3-Kdo2-lipid A-bisphosphate. This compound then interacts with UDP-glucose through a UDP-glucose:(glucosyl)LPS α-1,2-glucosyltransferase resulting in UDP, a hydrogen ion and galactosyl-(glucosyl)3-(heptosyl)3-Kdo2-lipid A-bisphosphate. This compound then interacts with ADP-L-glycero-beta-D-manno-heptose through a lipopolysaccharide core biosynthesis; heptosyl transferase IV; probably hexose transferase resulting in a Lipid A-core. A lipid A-core is then exported into the periplasmic space by a lipopolysaccharide ABC transporter. The lipid A-core is then flipped to the outer surface of the inner membrane by the ATP-binding cassette (ABC) transporter, MsbA. An additional integral membrane protein, YhjD, has recently been implicated in LPS export across the IM. The smallest LPS derivative that supports viability in E. coli is lipid IVA. However, it requires mutations in either MsbA or YhjD, to suppress the normally lethal consequence of an incomplete lipid A . Recent studies with deletion mutants implicate the periplasmic protein LptA, the cytosolic protein LptB, and the IM proteins LptC, LptF, and LptG in the subsequent transport of nascent LPS to the outer membrane (OM), where the LptD/LptE complex flips LPS to the outer surface.PW001905Metabolictryptophan metabolism IIThe biosynthesis of L-tryptophan begins with L-glutamine interacting with a chorismate through a anthranilate synthase which results in a L-glutamic acid, a pyruvic acid, a hydrogen ion and a 2-aminobenzoic acid. The aminobenzoic acid interacts with a phosphoribosyl pyrophosphate through an anthranilate synthase component II resulting in a pyrophosphate and a N-(5-phosphoribosyl)-anthranilate. The latter compound is then metabolized by an indole-3-glycerol phosphate synthase / phosphoribosylanthranilate isomerase resulting in a 1-(o-carboxyphenylamino)-1-deoxyribulose 5'-phosphate. This compound then interacts with a hydrogen ion through a indole-3-glycerol phosphate synthase / phosphoribosylanthranilate isomerase resulting in the release of carbon dioxide, a water molecule and a (1S,2R)-1-C-(indol-3-yl)glycerol 3-phosphate. The latter compound then interacts with a D-glyceraldehyde 3-phosphate and an Indole. The indole interacts with an L-serine through a tryptophan synthase, β subunit dimer resulting in a water molecule and an L-tryptophan.
The metabolism of L-tryptophan starts with L-tryptophan being dehydrogenated by a tryptophanase / L-cysteine desulfhydrase resulting in the release of a hydrogen ion, an Indole and a 2-aminoacrylic acid. The latter compound is isomerized into a 2-iminopropanoate. This compound then interacts with a water molecule and a hydrogen ion spontaneously resulting in the release of an Ammonium and a pyruvic acid. The pyruvic acid then interacts with a coenzyme A through a NAD driven pyruvate dehydrogenase complex resulting in the release of a NADH, a carbon dioxide and an Acetyl-CoAPW001916MetabolicTCA cycle (ubiquinol-0)The TCA pathway is a catabolic pathway of aerobic respiration. It generates energy and reducing power. It is the first step in generating precursors for biosynthesis. When acetate is the carbon source, citrate synthase is rate-limiting for the TCA cycle. Respiration is an ATP-generating process in which compounds act as electron donors through a chain of electron transfer to electron acceptors. Aerobic respiration uses oxygen as the final acceptor. Anaerobic respiration uses several organic compounds as acceptors such as fumarate, nitrate and hydrogen. During the chain of electron transfer, protons (H+) are transported outside the cytoplasmic membrane, generating a proton motive force. Upon passage of protons back into the cytoplasm, the PMF energy is captured as ATP, catalyzed by a multisubunit ATPase. The cycle can start from Acetyl-CoA interacting with Oxalacetic acid and water through a citrate synthase monomer resulting in a hydrogen ion, CoA and a Citric Acid. The latter compound is dehydrated by a Citrate hydro-lyase resulting in the release of water and a cis-Aconitic acid. This compound is then hydrated through a Citrate hydro-lyase resulting in a D-threo-Isocitric acid. This compound is decarboxylated by an NADP dependent Citrate dehydrogenase, resulting in a release of carbon dioxide and NADPH and Oxoglutaric acid. The oxoglutaric acid interacts with a Coenzyme A through a NAD driven 2-oxoglutarate dehydrogenase resulting in a release of carbon dioxide, an NADH and succinyl-CoA. The succinyl-CoA interacts with a phosphate and an ADP through a 2-oxoglutarate dehydrogenase resulting in a CoA, an ATP and Succinic Acid. Succinic acid interacts with a ubiquinone, in this case a ubiquinone 1 through a succinate:quinone oxidoreductase resulting in an ubiquinol, in this case a ubiquinol-1 and a fumaric acid. The fumaric acid interacts with water through a fumarase hydratase resulting in a L-Malic acid.This compound can either interact with quinone through a malate:quinone oxidoreductase resulting in a release of hydroquinone and oxalacetic acid, or it can react with an NAD through a malate dehydrogenase resulting in a hydrogen ion, NADH and Oxalacetic acid.PW002023Metabolicglycolate and glyoxylate degradation IIOxaloglycolate (2-Hydroxy-3-oxosuccinate) interacts with a tartrate dehydrogenase resulting in a L-tartrate. L-tartrate then interacts with tartrate dehydrogenase resulting in a Oxaloacetate. Oxaloacetate and acetyl-coa interact to result in a citrate which is processed by a aconitate hydratase resulting in a cis-Aconitate and further more into a isocitrate which will eventually be procressed into a glyoxylic acid. Glyoxylic acid can either be metabolized into L-malic acid by a reaction with acetyl-CoA and Water through a malate synthase G which also releases hydrogen ion and Coenzyme A. L-malic acid is then incorporated into the TCA cycle. Glyoxylic acid can also be metabolized by glyoxylate carboligase, releasing a carbon dioxide and tartronate semialdehyde. The latter compound is then reduced by an NADH driven tartronate semialdehyde reductase 2 resulting in glyceric acid. Glyceric acid is phosphorylated by a glycerate kinase 2 resulting in a 3-phosphoglyceric acid. This compound is then integrated into various other pathways: cysteine biosynthesis, serine biosynthesis and glycolysis and pyruvate dehydrogenase.PW002021MetabolicPhenylethylamine metabolismThe process of phenylethylamine metabolism starts with 2-phenylethylamine interacting with an oxygen molecule and a water molecule in the periplasmic space through a phenylethylamine oxidase. This reaction results in the release of a hydrogen peroxide, ammonium and phenylacetaldehyde.
Phenylacetaldehyde is introduced into the cytosol and degraded into phenylacetate by reaction with a phenylacetaldehyde dehydrogenase. This reaction involves phenylacetaldehyde interacting with NAD, and a water molecule and then resulting in the release of NADH, and 2 hydrogen ion.
Phenylacetate is then degraded. The first step involves phenylacetate interacting with an coenzyme A and an ATP driven phenylacetate-CoA ligase resulting in the release of a AMP, a diphosphate and a phenylacetyl-CoA. This resulting compound the interacts with a hydrogen ion, NADPH, and oxygen molecule through a ring 1,2-phenylacetyl-CoA epoxidase protein complex resulting in the release of a water molecule, an NADP and a 2-(1,2-epoxy-1,2-dihydrophenyl)acetyl-CoA. This compound is then metabolized by a ring 1,2 epoxyphenylacetyl-CoA isomerase resulting in a 2-oxepin-2(3H)-ylideneacetyl-CoA. This compound is then hydrolated through a oxepin-CoA hydrolase resulting in a 3-oxo-5,6-didehydrosuberyl-CoA semialdehyde. This commpound then interacts with a water molecule and NADP driven 3-oxo-5,6-dehydrosuberyl-CoA semialadehyde dehydrogenase resulting in 2 hydrogen ions, a NADPH and a 3-oxo-5,6-didehydrosuberyl-CoA. The resulting compound interacts with a coenzyme A and a 3-oxo-5,6 dehydrosuberyl-CoA thiolase resulting in an acetyl-CoA and a 2,3-didehydroadipyl-CoA. This resulting compound is the hydrated by a 2,3-dehydroadipyl-CoA hydratas resulting in a 3-hydroxyadipyl-CoA whuch is dehydrogenated through an NAD driven 3-hydroxyadipyl-CoA dehydrogenase resulting in a NADH, a hydrogen ion and a 3-oxoadipyl-CoA. The latter compound then interacts with conezyme A through a beta-ketoadipyl-CoA thiolase resulting in an acetyl-CoA and a succinyl-CoA. The succinyl-CoA is then integrated into the TCA cycle.PW002027Metabolic1,6-anhydro-<i>N</i>-acetylmuramic acid recyclingAnhydromuropeptides (mainly GlcNAc-1,6-anhMurNAc-L-Ala-γ-D-Glu-DAP-D-Ala) are steadily released during growth by lytic transglycosylases and endopeptidases and imported back into the cytoplasm for recycling. During bacterial growth, a very large proportion of the peptidoglycan polymer is degraded and reused in a process termed cell wall recycling. For example, the Gram-negative bacterium Escherichia coli recovers about half of its cell wall within one generation.
The anhydromuropeptides are imported by the ampG-encoded muropeptide:H+ symporter. Once inside the cytoplasm, the anhydromuropeptides are hydrolyzed by N-acetylmuramoyl-L-alanine amidase (ampD), β-N-acetylhexosaminidase (nagZ) and L,D-carboxypeptidase A (ldcA), yielding N-acetyl-β-D-glucosamine, 1,6-anhydro-N-acetyl-β-muramate, L-alanyl-γ-D-glutamyl-meso-diaminopimelate and D-alanine.
1,6-anhydro-N-acetyl-β-muramate is phosphorylated by anhydro-N-acetylmuramic acid kinase (anmK) and then converted into N-acetyl-D-glucosamine 6-phosphate by N-acetylmuramic acid 6-phosphate etherase (murQ). This is a branch point, as this compound could be directed either for further degradation or for recycling into new peptidoglycan monomers, as described in this pathway. The final product of this pathway, UDP-N-acetyl-α-D-muramate, is one of the precursors for peptidoglycan biosynthesis.
The tripeptide L-alanyl-γ-D-glutamyl-meso-diaminopimelate, which is generated by muramoyltetrapeptide carboxypeptidase, can be degraded further, as described in muropeptide degradation. However, the vast majority is recycled by muropeptide ligase (mpl). This enzyme is a dedicated recycling enzyme that attaches the recovered Ala-Glu-DAP tripeptide to UDP-N-acetyl-α-D-muramate, thereby substituting three amino acid ligases of the peptidoglycan de novobiosynthetic pathway.
Although exogenously provided 1,6-anhydro-N-acetyl-β-muramate can be taken up by Escherichia coli, it can not serve as the sole source of carbon for growth, suggesting that it may be toxic to the cell. (EcoCyc)
PW002064Metabolic2-Oxopent-4-enoate metabolism 2The pathway starts with trans-cinnamate interacting with a hydrogen ion, an oxygen molecule, and a NADH through a cinnamate dioxygenase resulting in a NAD and a Cis-3-(3-carboxyethyl)-3,5-cyclohexadiene-1,2-diol which then interact together through a 2,3-dihydroxy-2,3-dihydrophenylpropionate dehydrogenase resulting in the release of a hydrogen ion, an NADH molecule and a 2,3 dihydroxy-trans-cinnamate. The second way by which the 2,3 dihydroxy-trans-cinnamate is acquired is through a 3-hydroxy-trans-cinnamate interacting with a hydrogen ion, a NADH and an oxygen molecule through a 3-(3-hydroxyphenyl)propionate 2-hydroxylase resulting in the release of a NAD molecule, a water molecule and a 2,3-dihydroxy-trans-cinnamate. The compound 2,3 dihydroxy-trans-cinnamate then interacts with an oxygen molecule through a 2,3-dihydroxyphenylpropionate 1,2-dioxygenase resulting in a hydrogen ion and a 2-hydroxy-6-oxonona-2,4,7-triene-1,9-dioate. The latter compound then interacts with a water molecule through a 2-hydroxy-6-oxononatrienedioate hydrolase resulting in a release of a hydrogen ion, a fumarate molecule and (2Z)-2-hydroxypenta-2,4-dienoate. The latter compound reacts spontaneously to isomerize into a 2-oxopent-4-enoate. This compound is then hydrated through a 2-oxopent-4-enoate hydratase resulting in a 4-hydroxy-2-oxopentanoate. This compound then interacts with a 4-hydroxy-2-ketovalerate aldolase resulting in the release of a pyruvate, and an acetaldehyde. The acetaldehyde then interacts with a coenzyme A and a NAD molecule through a acetaldehyde dehydrogenase resulting in a hydrogen ion, a NADH and an acetyl-coa which can be incorporated into the TCA cyclePW002035MetabolicSecondary Metabolites: enterobacterial common antigen biosynthesis 2The biosynthesis of a enterobacterial common antigen can begin with a di-trans,octa-cis-undecaprenyl phosphate interacts with a Uridine diphosphate-N-acetylglucosamine through undecaprenyl-phosphate α-N-acetylglucosaminyl transferase resulting in a N-acetyl-α-D-glucosaminyl-diphospho-ditrans,octacis-undecaprenol and a Uridine 5'-monophosphate. The N-acetyl-α-D-glucosaminyl-diphospho-ditrans,octacis-undecaprenol then reacts with an UDP-ManNAcA from the Amino sugar and nucleotide sugar metabolism pathway. This reaction is metabolized by a UDP-N-acetyl-D-mannosaminuronic acid transferase resulting in a uridine 5' diphosphate, a hydrogen ion and a Undecaprenyl N-acetyl-glucosaminyl-N-acetyl-mannosaminuronate-4-acetamido-4,6-dideoxy-D-galactose pyrophosphate. Glucose 1 phosphate can be metabolize by interacting with a hydrogen ion and a thymidine 5-triphosphate by either reacting with a dTDP-glucose pyrophosphorylase or a dTDP-glucose pyrophosphorylase 2 resulting in the release of a pyrophosphate and a dTDP-D-glucose. The latter compound is then dehydrated through an dTDP-glucose 4,6-dehydratase 2 resulting in water and dTDP-4-dehydro-6-deoxy-D-glucose. The latter compound interacts with L-glutamic acid through a dTDP-4-dehydro-6-deoxy-D-glucose transaminase resulting in the release of oxoglutaric acid and dTDP-thomosamine. The latter compound interacts with acetyl-coa through a dTDP-fucosamine acetyltransferase resulting in a Coenzyme A, a hydrogen Ion and a TDP-Fuc4NAc. Undecaprenyl N-acetyl-glucosaminyl-N-acetyl-mannosaminuronate-4-acetamido-4,6-dideoxy-D-galactose pyrophosphate then interacts with a TDP--Fuc4NAc through a 4-acetamido-4,6-dideoxy-D-galactose transferase resulting in a hydrogen ion, a dTDP and a Undecaprenyl N-acetyl-glucosaminyl-N-acetyl-mannosaminuronate-4-acetamido-4,6-dideoxy-D-galactose pyrophosphate. This compound is then transported through a protein wzxE into the periplasmic space so that it can be incorporated into the outer membrane Enterobacterial common antigen (ECA) is an outer membrane glycolipid common to all members of Enterobacteriaceae. ECA is a unique cell surface antigen that can be found in the outer leaflet of the outer membrane. The carbohydrate portion consists of N-acetyl-glucosamine, N-acetyl-D-mannosaminuronic acid and 4-acetamido-4,6-dideoxy-D-galactose. These amino sugars form trisaccharide repeat units which are part of linear heteropolysaccharide chains.PW002045MetabolicSecondary Metabolites: enterobacterial common antigen biosynthesis 3The biosynthesis of a enterobacterial common antigen can begin with a di-trans,octa-cis-undecaprenyl phosphate interacts with a Uridine diphosphate-N-acetylglucosamine through undecaprenyl-phosphate α-N-acetylglucosaminyl transferase resulting in a N-acetyl-α-D-glucosaminyl-diphospho-ditrans,octacis-undecaprenol and a Uridine 5'-monophosphate. The N-acetyl-α-D-glucosaminyl-diphospho-ditrans,octacis-undecaprenol then reacts with an UDP-ManNAcA from the Amino sugar and nucleotide sugar metabolism pathway. This reaction is metabolized by a UDP-N-acetyl-D-mannosaminuronic acid transferase resulting in a uridine 5' diphosphate, a hydrogen ion and a Undecaprenyl N-acetyl-glucosaminyl-N-acetyl-mannosaminuronate-4-acetamido-4,6-dideoxy-D-galactose pyrophosphate. Glucose 1 phosphate can be metabolize by interacting with a hydrogen ion and a thymidine 5-triphosphate by either reacting with a dTDP-glucose pyrophosphorylase or a dTDP-glucose pyrophosphorylase 2 resulting in the release of a pyrophosphate and a dTDP-D-glucose. The latter compound is then dehydrated through an dTDP-glucose 4,6-dehydratase 2 resulting in water and dTDP-4-dehydro-6-deoxy-D-glucose. The latter compound interacts with L-glutamic acid through a dTDP-4-dehydro-6-deoxy-D-glucose transaminase resulting in the release of oxoglutaric acid and dTDP-thomosamine. The latter compound interacts with acetyl-coa through a dTDP-fucosamine acetyltransferase resulting in a Coenzyme A, a hydrogen Ion and a TDP-Fuc4NAc. Undecaprenyl N-acetyl-glucosaminyl-N-acetyl-mannosaminuronate-4-acetamido-4,6-dideoxy-D-galactose pyrophosphate then interacts with a TDP--Fuc4NAc through a 4-acetamido-4,6-dideoxy-D-galactose transferase resulting in a hydrogen ion, a dTDP and a Undecaprenyl N-acetyl-glucosaminyl-N-acetyl-mannosaminuronate-4-acetamido-4,6-dideoxy-D-galactose pyrophosphate. This compound is then transported through a protein wzxE into the periplasmic space so that it can be incorporated into the outer membrane Enterobacterial common antigen (ECA) is an outer membrane glycolipid common to all members of Enterobacteriaceae. ECA is a unique cell surface antigen that can be found in the outer leaflet of the outer membrane. The carbohydrate portion consists of N-acetyl-glucosamine, N-acetyl-D-mannosaminuronic acid and 4-acetamido-4,6-dideoxy-D-galactose. These amino sugars form trisaccharide repeat units which are part of linear heteropolysaccharide chains.PW002046Metabolicbiotin-carboxyl carrier protein assemblyThe assembly of a biotin-carboxyl carrier protein starts with a biotin carboxyl carrier protein monomer interacting with an ATP, and a biotin through a biotin -acetyl-coa-carboxylase ligase resulting in the release of a hydrogen ion, an AMP, a diphosphate and a biotynylated BCCP monomer. The latter compound reacts spontaneously to create a biotinylated BCCP dimer. This compound in turn reacts with a hydrogen carbonate and an ATP driven biotin carboxylase resulting in the release of ADP, a hydrogen Ion , a phosphate and a carboxylated biotinylated BCCP dimer.
This complex can be degraded by reacting with water, an acetyl0CoA, and an ATP driven acetyl-CoA carboxyltransferase resulting in the release of a hydrogen ion, a phosphate, an ADP, a malonyl-CoA and a biotynylated BCCP dimerPW002067Metaboliclipopolysaccharide biosynthesis IIIE. coli lipid A is synthesized on the cytoplasmic surface of the inner membrane. The pathway can start from the fructose 6-phosphate that is either produced in the glycolysis and pyruvate dehydrogenase or be obtained from the interaction with D-fructose interacting with a mannose PTS permease. Fructose 6-phosphate interacts with L-glutamine through a D-fructose-6-phosphate aminotransferase resulting into a L-glutamic acid and a glucosamine 6-phosphate. The latter compound is isomerized through a phosphoglucosamine mutase resulting a glucosamine 1-phosphate. This compound is acetylated, interacting with acetyl-CoA through a bifunctional protein glmU resulting in a Coenzyme A, hydrogen ion and N-acetyl-glucosamine 1-phosphate. This compound interact with UTP and hydrogen ion through the bifunctional protein glmU resulting in a pyrophosphate and a UDP-N-acetylglucosamine. This compound interacts with (3R)-3-hydroxymyristoyl-[acp] through an UDP-N-acetylglucosamine acyltransferase resulting in a holo-[acp] and a UDP-3-O[(3R)-3-hydroxymyristoyl]-N-acetyl-alpha-D-glucosamine. This compound interacts with water through UDP-3-O-acyl-N-acetylglucosamine deacetylase resulting in an acetic acid and UDP-3-O-(3-hydroxymyristoyl)-α-D-glucosamine. The latter compound interacts with (3R)-3-hydroxymyristoyl-[acp] through
UDP-3-O-(R-3-hydroxymyristoyl)-glucosamine N-acyltransferase releasing a hydrogen ion, a holo-acp and UDP-2-N,3-O-bis[(3R)-3-hydroxytetradecanoyl]-α-D-glucosamine. The latter compound is hydrolase by interacting with water and a UDP-2,3-diacylglucosamine hydrolase resulting in UMP, hydrogen ion and 2,3-bis[(3R)-3-hydroxymyristoyl]-α-D-glucosaminyl 1-phosphate. This last compound then interacts with a UDP-2-N,3-O-bis[(3R)-3-hydroxytetradecanoyl]-α-D-glucosamine through a lipid A disaccharide synthase resulting in a release of UDP, hydrogen ion and a lipid A disaccharide. The lipid A disaccharide is phosphorylated by an ATP mediated
tetraacyldisaccharide 4'-kinase resulting in the release of hydrogen ion and lipid IVA.
A D-ribulose 5-phosphate is isomerized with D-arabinose 5-phosphate isomerase 2 to result in a D-arabinose 5-phosphate. This compounds interacts with water and phosphoenolpyruvic acid through a 3-deoxy-D-manno-octulosonate 8-phosphate synthase resulting in the release of phosphate and 3-deoxy-D-manno-octulosonate 8-phosphate. This compound interacts with water through a 3-deoxy-D-manno-octulosonate 8-phosphate phosphatase thus releasing a phosphate and a 3-deoxy-D-manno-octulosonate. The latter compound interacts with CTP through a 3-deoxy-D-manno-octulosonate cytidylyltransferase resulting in a pyrophosphate and
CMP-3-deoxy-α-D-manno-octulosonate.
CMP-3-deoxy-α-D-manno-octulosonate and lipid IVA interact with each other through a KDO transferase resulting in CMP, hydrogen ion and alpha-Kdo-(2-->6)-lipid IVA. The latter compound reacts with CMP-3-deoxy-α-D-manno-octulosonate through a KDO transferase resulting in a CMP, hydrogen ion, and a a-Kdo-(2->4)-a-Kdo-(2->6)-lipid IVA. The latter compound can either react with a palmitoleoyl-acp through a palmitoleoyl acyltransferase resulting in the release of a holo-acyl carriere protein and a Kdo2-palmitoleoyl-lipid IVa which in turn reacts with a myristoyl-acp through a myristoyl-acp dependent acyltransferase resulting in a release of a holo-acp and a Kdo2-lipid A, cold adapted, or it can interact with a dodecanoyl-[acp] lauroyl acyltransferase resulting in a holo-[acp] and a (KDO)2-(lauroyl)-lipid IVA. The latter compound reacts with a myristoyl-[acp] through a myristoyl-acyl carrier protein (ACP)-dependent acyltransferase resulting in a holo-[acp], (KDO)2-lipid A. The latter compound reacts with ADP-L-glycero-beta-D-manno-heptose through ADP-heptose:LPS heptosyltransferase I resulting hydrogen ion, ADP, heptosyl-KDO2-lipid A. The latter compound interacts with ADP-L-glycero-beta-D-manno-heptose through ADP-heptose:LPS heptosyltransferase II resulting in ADP, hydrogen ion and (heptosyl)2-Kdo2-lipid A. The latter compound UDP-glucose interacts with (heptosyl)2-Kdo2-lipid A resulting in UDP, hydrogen ion and glucosyl-(heptosyl)2-Kdo2-lipid A. Glucosyl-(heptosyl)2-Kdo2-lipid A (Escherichia coli) is phosphorylated through an ATP-mediated lipopolysaccharide core heptose (I) kinase resulting in ADP, hydrogen ion and glucosyl-(heptosyl)2-Kdo2-lipid A-phosphate.
The latter compound interacts with ADP-L-glycero-beta-D-manno-heptose through a lipopolysaccharide core heptosyl transferase III resulting in ADP, hydrogen ion, and glucosyl-(heptosyl)3-Kdo2-lipid A-phosphate. The latter compound is phosphorylated through an ATP-driven lipopolysaccharide core heptose (II) kinase resulting in ADP, hydrogen ion and glucosyl-(heptosyl)3-Kdo2-lipid A-bisphosphate. The latter compound interacts with UDP-alpha-D-galactose through a UDP-D-galactose:(glucosyl)lipopolysaccharide-1,6-D-galactosyltransferase resulting in a UDP, a hydrogen ion and a galactosyl-glucosyl-(heptosyl)3-Kdo2-lipid A-bisphosphate. The latter compound interacts with UDP-glucose through a (glucosyl)LPS α-1,3-glucosyltransferase resulting in a hydrogen ion, a UDP and galactosyl-(glucosyl)2-(heptosyl)3-Kdo2-lipid A-bisphosphate. This compound then interacts with UDP-glucose through a UDP-glucose:(glucosyl)LPS α-1,2-glucosyltransferase resulting in UDP, a hydrogen ion and galactosyl-(glucosyl)3-(heptosyl)3-Kdo2-lipid A-bisphosphate. This compound then interacts with ADP-L-glycero-beta-D-manno-heptose through a lipopolysaccharide core biosynthesis; heptosyl transferase IV; probably hexose transferase resulting in a Lipid A-core.
A lipid A-core is then exported into the periplasmic space by a lipopolysaccharide ABC transporter.
The lipid A-core is then flipped to the outer surface of the inner membrane by the ATP-binding cassette (ABC) transporter, MsbA. An additional integral membrane protein, YhjD, has recently been implicated in LPS export across the IM. The smallest LPS derivative that supports viability in E. coli is lipid IVA. However, it requires mutations in either MsbA or YhjD, to suppress the normally lethal consequence of an incomplete lipid A . Recent studies with deletion mutants implicate the periplasmic protein LptA, the cytosolic protein LptB, and the IM proteins LptC, LptF, and LptG in the subsequent transport of nascent LPS to the outer membrane (OM), where the LptD/LptE complex flips LPS to the outer surface. PW002059Metabolicpalmitate biosynthesis 2Palmitate is synthesized by stepwise condensation of C2 units to a growing acyl chain. Each elongation cycle results in the addition of two carbons to the acyl chain, and consists of four separate reactions. The pathway starts with acetyl-CoA interacting with hydrogen carbonate through an ATP driven acetyl-CoA carboxylase resulting in a phosphate, an ADP , a hydrogen ion and a malonyl-CoA. The latter compound interacts with a holo-[acp] through a malonyl-CoA-ACP transacylase resulting in a CoA and a malonyl-[acp]. This compound interacts with hydrogen ion, acetyl-CoA through a KASIII resulting in a CoA, carbon dioxide and an acetoacetyl-[acp]. The latter compound interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (R) 3-Hydroxybutanoyl-[acp](1). This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a crotonyl-[acp](2). The crotonyl-[acp] interacts with a hydrogen ion through a NADH enoyl-[acyl-carrier-protein] reductase(NAD) resulting in NAD and a butyryl-[acp](3). The butyryl-[acp] interacts with a hydrogen ion, a malonyl-[acp] through a KASI resulting in a holo-[acp],carbon dioxide and a 3-oxo-hexanoyl-[acp](4). The 3-oxo-hexanoyl-[acp] interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (R) 3-Hydroxyhexanoyl-[acp](1). This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a trans hex-2-enoyl-[acp](2). The trans hex-2-enoyl-[acp] interacts with a hydrogen ion through a NADH enoyl-[acyl-carrier-protein] reductase(NAD) resulting in NAD and a hexanoyl-[acp](3). The hexanoyl-[acp] interacts with a hydrogen ion, a malonyl-[acp] through a KASI resulting in a holo-[acp],carbon dioxide and a 3-oxo-octanoyl-[acp](4). The 3-oxo-octanoyl-[acp] interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (R) 3-Hydroxyoctanoyl-[acp](1). This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a trans oct-2-enoyl-[acp](2). The trans oct-2-enoyl-[acp] interacts with a hydrogen ion through a NADH enoyl-[acyl-carrier-protein] reductase(NAD) resulting in NAD and a octanoyl-[acp](3). The octanoyl-[acp] interacts with a hydrogen ion, a malonyl-[acp] through a KASI resulting in a holo-[acp],carbon dioxide and a 3-oxo-decanoyl-[acp](4). The 3-oxo-decanoyl-[acp] interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (R) 3-Hydroxydecanoyl-[acp](1). This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a trans-delta2-decenoyl-[acp](2). The a trans-delta2-decenoyl-[acp] interacts with a hydrogen ion through a NADH enoyl-[acyl-carrier-protein] reductase(NAD) resulting in NAD and a decanoyl-[acp](3). The decanoyl-[acp] interacts with a malonyl-[acp] through a KASI resulting in a holo-[acp],carbon dioxide and a 3-oxo-dodecanoyl-[acp](4). The 3-oxo-dodecanoyl-[acp ]interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (R) 3-Hydroxydodecanoyl-[acp](1). This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a trans dodec-2-enoyl-[acp](2). The trans dodec-2-enoyl-[acp] interacts with a hydrogen ion through a NADH enoyl-[acyl-carrier-protein] reductase(NAD) resulting in NAD and a dodecanoyl-[acp](3). This compound can either react with water spontaneously resulting in a hydrogen ion, a holo-[acp] and a dodecanoic acid or it interacts with a hydrogen ion, a malonyl-[acp] through a KASI resulting in a holo-[acp],carbon dioxide and a 3-oxo-myristoyl-[acp](4). The 3-oxo-myristoyl-[acp] interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (3R) 3-Hydroxymyristoyl-[acp](1). This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a trans tetradec-2-enoyl-[acp](2). This compound interacts with a hydrogen ion, through a NADH-driven KASI resulting in a NAD and a myristoyl-[acp]. Myristoyl-[acp] with a hydrogen ion, a malonyl-[acp] through a KASI resulting in a holo-[acp],carbon dioxide and a 3-oxo-palmitoyl-[acp](4). The 3-oxo-palmitoyl-[acp] interacts with a hydrogen ion through a NADPH driven 3-oxoacyl-[acyl-carrier-protein] reductase resulting in an NADP and a (3R) 3-Hydroxypalmitoyl-[acp](1). This compound is then dehydrated by a 3-hydroxyacyl-[acyl-carrier-protein] dehydratase resulting in the release of water and a trans hexadecenoyl-[acp](2). The trans hexadecenoyl-[acp] interacts with a hydrogen ion through a NADH enoyl-[acyl-carrier-protein] reductase(NAD) resulting in NAD and a palmitoyl-[acp](3). Palmitoyl then reacts with water spontaneously resulting in a hydrogen ion, a holo-[acp] and palmitic acid. No integral membrane protein required for long chain fatty acid uptake has been identified in E. coli. The transport of long chain fatty acids across the cytoplasmic membrane is dependent on fatty acyl-CoA synthetase. An energised membrane is necessary for fatty acid transport and it has been suggested that uncharged fatty acids flip across the inner membrane by diffusion.PW002044Metabolicpeptidoglycan biosynthesis I 2Peptidoglycan is a net-like polymer which surrounds the cytoplasmic membrane of most bacteria and functions to maintain cell shape and prevent rupture due to the internal turgor.In E. coli K-12, the peptidoglycan consists of glycan strands of alternating subunits of N-acetylglucosamine (GlcNAc) and N-acetylmuramic acid (MurNAc) which are cross-linked by short peptides. The pathway for constructing this net involves two cell compartments: cytoplasm and periplasmic space. The pathway starts with a beta-D-fructofuranose going through a mannose PTS permease, phosphorylating the compund and producing a beta-D-fructofuranose 6 phosphate. This compound can be obtained from the glycolysis and pyruvate dehydrogenase or from an isomerization reaction of Beta-D-glucose 6-phosphate through a glucose-6-phosphate isomerase.The compound Beta-D-fructofuranose 6 phosphate and L-Glutamine react with a glucosamine fructose-6-phosphate aminotransferase, thus producing a glucosamine 6-phosphate and a l-glutamic acid. The glucosamine 6-phosphate interacts with phosphoglucosamine mutase in a reversible reaction producing glucosamine-1P. Glucosamine-1p and acetyl coa undergo acetylation throuhg a bifunctional protein glmU releasing Coa and a hydrogen ion and producing a N-acetyl-glucosamine 1-phosphate. Glmu, being a bifunctional protein, follows catalyze the interaction of N-acetyl-glucosamine 1-phosphate, hydrogen ion and UTP into UDP-N-acetylglucosamine and pyrophosphate. UDP-N-acetylglucosamine then interacts with phosphoenolpyruvic acid and a UDP-N acetylglucosamine 1- carboxyvinyltransferase realeasing a phosphate and the compound UDP-N-acetyl-alpha-D-glucosamine-enolpyruvate. This compound undergoes a NADPH dependent reduction producing a UDP-N-acetyl-alpha-D-muramate through a UDP-N-acetylenolpyruvoylglucosamine reductase. UDP-N-acetyl-alpha-D-muramate and L-alanine react in an ATP-mediated ligation through a UDP-N-acetylmuramate-alanine ligase releasing an ADP, hydrogen ion, a phosphate and a UDP-N-acetylmuramoyl-L-alanine. This compound interacts with D-glutamic acid and ATP through UDP-N-acetylmuramoylalanine-D-glutamate ligase releasing ADP, A phosphate and UDP-N-acetylmuramoyl-L-alanyl-D-glutamate. The latter compound then interacts with meso-diaminopimelate in an ATP mediated ligation through a UDP-N-acetylmuramoylalanine-D-glutamate-2,6-diaminopimelate ligase resulting in ADP, phosphate, hydrogen ion and UDP-N-Acetylmuramoyl-L-alanyl-D-gamma-glutamyl-meso-2,6-diaminopimelate. This compound in turn with D-alanyl-D-alanine react in an ATP-mediated ligation through UDP-N-Acetylmuramoyl-tripeptide-D-alanyl-D-alanine ligase to produce UDP-N-acetyl-alpha-D-muramoyl-L-alanyl-gama-D-glutamyl-meso-2,6-diaminopimeloyl-Dalanyl-D-alanine and hydrogen ion, ADP, phosphate. UDP-N-acetyl-alpha-D-muramoyl-L-alanyl-gama-D-glutamyl-meso-2,6-diaminopimeloyl-Dalanyl-D-alanine interacts with di-trans,octa-cis-undecaprenyl phosphate through a phospho-N-acetylmuramoyl-pentapeptide-transferase, resulting in UMP and N-Acetylmuramoyl-L-alanyl-D-glutamyl-meso-2,6-diaminopimelyl-D-alanyl-D-alanine-diphosphoundecaprenol which in turn reacts with a UDP-N-acetylglucosamine through a N-acetylglucosaminyl transferase to produce a hydrogen, UDP and Undecaprenyl-diphospho-N-acetylmuramoyl-(N-acetylglucosamine)-L-alanyl-D-glutaminyl-meso-2,6-diaminopimeloyl-D-alanyl-D-alanine. This compound ends the cytoplasmic part of the pathway. Undecaprenyl-diphospho-N-acetylmuramoyl-(N-acetylglucosamine)-L-alanyl-D-glutaminyl-meso-2,6-diaminopimeloyl-D-alanyl-D-alanine is transported through a lipi II flippase. Once in the periplasmic space, the compound reacts with a penicillin binding protein 1A prodducing a peptidoglycan dimer, a hydrogen ion, and UDP. The peptidoglycan dimer then reacts with a penicillin binding protein 1B producing a peptidoglycan with D,D, cross-links and a D-alanine.PW002062MetabolicAcetate metabolismThe acetate biosynthesis starts with acetyl-CoA reacting with phosphate through a phosphate acetyltransferase resulting in the release of a coenzyme A and an acetyl phosphate. The latter compound in turn reacts with ADP through an acetate kinase resulting in the release of an ATP and an acetate. The acetate reacts with ATP and coenzyme A through an acetyl-CoA synthase resulting in the release of a diphosphate, an AMP and an acetyl-CoA.
Acetyl-CoA can be biosynthesized by acetoacetate reacting with an acetyl-CoA through an acetoacetyl-CoA transferase resulting in the release of an acetate and an acetoacetyl-CoA. The acetoacetyl-CoA reacts with an acetyl-CoA acetyltransferase resulting in the release of an coenzyme A and 2 acetyl-CoAPW002090MetabolicO-antigen building blocks biosynthesisLipopolysaccharide (LPS), a major outer membrane component, is composed of three domains: Lipid A; the core, which is an oligosaccharide consisting of an inner and outer region; and a distal repeating unit known as O-antigen.
E. coli K12 is capable of producing an O-antigen when all the rfb genes are intact. The O-antigen is part of the lipopolysaccharide and is attached to the lipid A-core component, which is separately synthesized. The O-antigen is a repeat unit composed of four sugars: glucose, N-acetylglucosamine, galactose and rhamnose.
This pathway depicts the synthesis of three of these sugars. UDP-galactose is transformed from its pyranose form to its furanose form. dTTP glucose-1-phosphate is derivatized to dTDP-rhamnose. Fructose-6-phosphate gains an amino group, incorporates an acetate moiety and then acquires a nucleoside diphosphate resulting in UDP-N-acetyl-D-glucosamine.(EcoCyc)PW002089Metabolicpyruvate decarboxylation to acetyl CoAThis multi-enzyme complex, which consists of 24 subunits of pyruvate dehydrogenase, 24 subunits of lipoate acetyltransferase, and 12 subunits of dihydrolipoate dehydrogenase, catalyzes three reactions, which constitute a cycle. The complex contains a lipoyl active site in the form of lipoyllysine, as well as a thiamin diphosphate.
The net consequence of the cycle, in addition to reducing NAD+, is the conversion of pyruvate into acetyl-CoA and CO2, a key reaction of central metabolism because it links glycolysis I, which generates pyruvate, to the TCA cycle, into which the acetyl-CoA flows.
During aerobic growth the cycle is an essential source of acetyl-CoA to feed the TCA cycle and thereby to satisfy the cellular requirements for the precursor metabolites it forms. Mutant strains defective in the complex require an exogenous source of acetate to meet this requirement, but anaerobically such mutants grow without exogenous acetate because under such conditions, pyruvate formate lyase generates acetyl-CoA from pyruvate. Mutant strains lacking pyruvate formate lyase have the reverse phenotype. They require acetate for anaerobic but not for aerobic growth.PW002083Metabolicpyrimidine deoxyribonucleosides degradationPWY0-1298biotin-carboxyl carrier protein assemblyPWY0-1264purine deoxyribonucleosides degradationPWY0-1297cysteine biosynthesis ICYSTSYN-PWYacetate formation from acetyl-CoA IPWY0-1312mixed acid fermentationFERMENTATION-PWYacetoacetate degradation (to acetyl CoA)ACETOACETATE-DEG-PWYornithine biosynthesisGLUTORN-PWYacetate conversion to acetyl-CoAPWY0-1313fatty acid β-oxidation IFAO-PWYphenylacetate degradation I (aerobic)PWY0-321respiration (anaerobic)ANARESP1-PWYglyoxylate cycleGLYOXYLATE-BYPASSTCA cycle I (prokaryotic)TCAethanol degradation IETOH-ACETYLCOA-ANA-PWYsuperpathway of glycol metabolism and degradationGLYOXDEG-PWYthreonine degradation IITHREONINE-DEG2-PWYthreonine degradation IVPWY-5436UDP-<i>N</i>-acetyl-D-glucosamine biosynthesis IUDPNAGSYN-PWYisoleucine biosynthesis I (from threonine)LEUSYN-PWYenterobacterial common antigen biosynthesisECASYN-PWYacetyl-CoA biosynthesis I (pyruvate dehydrogenase complex)PYRUVDEHYD-PWYsuperpathway of glycolysis, pyruvate dehydrogenase, TCA, and glyoxylate bypassGLYCOLYSIS-TCA-GLYOX-BYPASS2-oxopentenoate degradationPWY-5162fatty acid biosynthesis initiation IPWY-4381superpathway of fatty acid biosynthesis initiation (E. coli)FASYN-INITIAL-PWYfatty acid biosynthesis initiation IIPWY-5966Specdb::CMs789921Specdb::CMs789922Specdb::CMs789923Specdb::CMs789924Specdb::CMs789925Specdb::CMs789926Specdb::CMs789927Specdb::CMs789928Specdb::NmrOneD87512Specdb::NmrOneD87513Specdb::NmrOneD87514Specdb::NmrOneD87515Specdb::NmrOneD87516Specdb::NmrOneD87517Specdb::NmrOneD87518Specdb::NmrOneD87519Specdb::NmrOneD87520Specdb::NmrOneD87521Specdb::NmrOneD87522Specdb::NmrOneD87523Specdb::NmrOneD87524Specdb::NmrOneD87525Specdb::NmrOneD87526Specdb::NmrOneD87527Specdb::NmrOneD87528Specdb::NmrOneD87529Specdb::NmrOneD87530Specdb::NmrOneD87531Specdb::MsMs29696Specdb::MsMs29697Specdb::MsMs29698Specdb::MsMs36254Specdb::MsMs36255Specdb::MsMs36256Specdb::MsMs1470771Specdb::MsMs1470772Specdb::MsMs1471106Specdb::MsMs1471107Specdb::MsMs1471108Specdb::MsMs2240271Specdb::MsMs2241450Specdb::MsMs2242301Specdb::MsMs2243548Specdb::MsMs2334370Specdb::MsMs2334371Specdb::MsMs2334372Specdb::MsMs2627849Specdb::MsMs2627850Specdb::MsMs2627851HMDB012066302392413C0002415351ACETYL-COAACOAcetyl-CoAKeseler, I. M., Collado-Vides, J., Santos-Zavaleta, A., Peralta-Gil, M., Gama-Castro, S., Muniz-Rascado, L., Bonavides-Martinez, C., Paley, S., Krummenacker, M., Altman, T., Kaipa, P., Spaulding, A., Pacheco, J., Latendresse, M., Fulcher, C., Sarker, M., Shearer, A. G., Mackie, A., Paulsen, I., Gunsalus, R. P., Karp, P. D. (2011). "EcoCyc: a comprehensive database of Escherichia coli biology." Nucleic Acids Res 39:D583-D590.21097882Kanehisa, M., Goto, S., Sato, Y., Furumichi, M., Tanabe, M. (2012). "KEGG for integration and interpretation of large-scale molecular data sets." Nucleic Acids Res 40:D109-D114.22080510van der Werf, M. J., Overkamp, K. M., Muilwijk, B., Coulier, L., Hankemeier, T. (2007). "Microbial metabolomics: toward a platform with full metabolome coverage." Anal Biochem 370:17-25.17765195Winder, C. L., Dunn, W. B., Schuler, S., Broadhurst, D., Jarvis, R., Stephens, G. M., Goodacre, R. (2008). "Global metabolic profiling of Escherichia coli cultures: an evaluation of methods for quenching and extraction of intracellular metabolites." Anal Chem 80:2939-2948.18331064Bennett, B. D., Kimball, E. H., Gao, M., Osterhout, R., Van Dien, S. J., Rabinowitz, J. D. (2009). "Absolute metabolite concentrations and implied enzyme active site occupancy in Escherichia coli." Nat Chem Biol 5:593-599.19561621Buchholz, A., Takors, R., Wandrey, C. (2001). "Quantification of intracellular metabolites in Escherichia coli K12 using liquid chromatographic-electrospray ionization tandem mass spectrometric techniques." Anal Biochem 295:129-137.11488613Peng, L., Arauzo-Bravo, M. J., Shimizu, K. (2004). "Metabolic flux analysis for a ppc mutant Escherichia coli based on 13C-labelling experiments together with enzyme activity assays and intracellular metabolite measurements." FEMS Microbiol Lett 235:17-23.15158257Park, C., Park, C., Lee, Y., Lee, S.Y., Oh, H.B., Lee, J. (2011) Determination of the Intracellular Concentration of Metabolites in Escherichia coli Collected during the Exponential and Stationary Growth Phases using Liquid Chromatography-Mass Spectrometry. Bull Korean Chem. Soc. 32: 524-530.Al-Buheissi SZ, Patel HR, Meinl W, Hewer A, Bryan RL, Glatt H, Miller RA, Phillips DH: N-Acetyltransferase and sulfotransferase activity in human prostate: potential for carcinogen activation. Pharmacogenet Genomics. 2006 Jun;16(6):391-9.16708048Blank ML, Smith ZL, Fitzgerald V, Snyder F: The CoA-independent transacylase in PAF biosynthesis: tissue distribution and molecular species selectivity. Biochim Biophys Acta. 1995 Feb 9;1254(3):295-301.7857969Wysocki SJ, Wilkinson SP, Hahnel R, Wong CY, Panegyres PK: 3-Hydroxy-3-methylglutaric aciduria, combined with 3-methylglutaconic aciduria. Clin Chim Acta. 1976 Aug 2;70(3):399-406.947633Michno A, Skibowska A, Raszeja-Specht A, Cwikowska J, Szutowicz A: The role of adenosine triphosphate citrate lyase in the metabolism of acetyl coenzyme a and function of blood platelets in diabetes mellitus. Metabolism. 2004 Jan;53(1):66-72.14681844Griffin MJ, Sul HS: Insulin regulation of fatty acid synthase gene transcription: roles of USF and SREBP-1c. IUBMB Life. 2004 Oct;56(10):595-600.15814457Putman CT, Spriet LL, Hultman E, Dyck DJ, Heigenhauser GJ: Skeletal muscle pyruvate dehydrogenase activity during acetate infusion in humans. Am J Physiol. 1995 May;268(5 Pt 1):E1007-17.7762627Szutowicz A, Tomaszewicz M, Jankowska A, Madziar B, Bielarczyk H: [Mechanisms of selective vulnerability of cholinergic neurons to neurotoxic stimuli] Postepy Hig Med Dosw. 1999;53(2):263-75.10355292Ingebretsen OC, Bakken AM, Farstad M: The content of coenzyme A, acetyl-CoA and long-chain acyl-CoA in human blood platelets. Clin Chim Acta. 1982 Dec 23;126(3):307-13.7151284Michno A, Raszeja-Specht A, Jankowska-Kulawy A, Pawelczyk T, Szutowicz A: Effect of L-carnitine on acetyl-CoA content and activity of blood platelets in healthy and diabetic persons. Clin Chem. 2005 Sep;51(9):1673-82. Epub 2005 Jul 14.16020499Constantin-Teodosiu D, Peirce NS, Fox J, Greenhaff PL: Muscle pyruvate availability can limit the flux, but not activation, of the pyruvate dehydrogenase complex during submaximal exercise in humans. J Physiol. 2004 Dec 1;561(Pt 2):647-55. Epub 2004 Oct 7.15579544Crystal HA, Davies P: Cortical substance P-like immunoreactivity in cases of Alzheimer's disease and senile dementia of the Alzheimer type. J Neurochem. 1982 Jun;38(6):1781-4.6176686Evans MK, Savasi I, Heigenhauser GJ, Spriet LL: Effects of acetate infusion and hyperoxia on muscle substrate phosphorylation after onset of moderate exercise. Am J Physiol Endocrinol Metab. 2001 Dec;281(6):E1144-50.11701427Peters SJ: Regulation of PDH activity and isoform expression: diet and exercise. Biochem Soc Trans. 2003 Dec;31(Pt 6):1274-80.14641042Roe CR, Sweetman L, Roe DS, David F, Brunengraber H: Treatment of cardiomyopathy and rhabdomyolysis in long-chain fat oxidation disorders using an anaplerotic odd-chain triglyceride. J Clin Invest. 2002 Jul;110(2):259-69.12122118Skibowska A, Raszeja-Specht A, Szutowicz A: Platelet function and acetyl-coenzyme A metabolism in type 1 diabetes mellitus. Clin Chem Lab Med. 2003 Sep;41(9):1136-43.14598862Girard J: [Contribution of free fatty acids to impairment of insulin secretion and action. mechanism of beta-cell lipotoxicity] Med Sci (Paris). 2005 Dec;21 Spec No:19-25.16598900Szutowicz A, Jankowska A, Tomaszewicz M: [Disturbances of glucose metabolism in epilepsy and other neurodegenerative diseases] Neurol Neurochir Pol. 2000;34 Suppl 8:59-66.11780590Spriet LL, MacLean DA, Dyck DJ, Hultman E, Cederblad G, Graham TE: Caffeine ingestion and muscle metabolism during prolonged exercise in humans. Am J Physiol. 1992 Jun;262(6 Pt 1):E891-8.1616022Constantin-Teodosiu D, Carlin JI, Cederblad G, Harris RC, Hultman E: Acetyl group accumulation and pyruvate dehydrogenase activity in human muscle during incremental exercise. Acta Physiol Scand. 1991 Dec;143(4):367-72.1815472Boden G, Jadali F, White J, Liang Y, Mozzoli M, Chen X, Coleman E, Smith C: Effects of fat on insulin-stimulated carbohydrate metabolism in normal men. J Clin Invest. 1991 Sep;88(3):960-6.1885781Tucek, S. The synthesis of acetyl coenzyme A and acetylcholine from citrate and acetate in the nerve endings of mammalian brain. Biochimica et Biophysica Acta, General Subjects (1966), 117(1), 278-80. Dihydrolipoyllysine-residue acetyltransferase component of pyruvate dehydrogenase complexP06959ODP2_ECOLIaceFhttp://ecmdb.ca/proteins/P06959.xmlGalactoside O-acetyltransferaseP07464THGA_ECOLIlacAhttp://ecmdb.ca/proteins/P07464.xmlMalate synthase AP08997MASY_ECOLIaceBhttp://ecmdb.ca/proteins/P08997.xml2-isopropylmalate synthaseP09151LEU1_ECOLIleuAhttp://ecmdb.ca/proteins/P09151.xmlFormate acetyltransferase 1P09373PFLB_ECOLIpflBhttp://ecmdb.ca/proteins/P09373.xmlAmino-acid acetyltransferaseP0A6C5ARGA_ECOLIargAhttp://ecmdb.ca/proteins/P0A6C5.xml3-oxoacyl-[acyl-carrier-protein] synthase 3P0A6R0FABH_ECOLIfabHhttp://ecmdb.ca/proteins/P0A6R0.xmlRibosomal-protein-alanine acetyltransferaseP0A944RIMI_ECOLIrimIhttp://ecmdb.ca/proteins/P0A944.xmlRibosomal-protein-alanine acetyltransferase_P0A948RIMJ_ECOLIrimJhttp://ecmdb.ca/proteins/P0A948.xmlSpermidine N(1)-acetyltransferaseP0A951ATDA_ECOLIspeGhttp://ecmdb.ca/proteins/P0A951.xmlSerine acetyltransferaseP0A9D4CYSE_ECOLIcysEhttp://ecmdb.ca/proteins/P0A9D4.xmlCitrate lyase subunit betaP0A9I1CITE_ECOLIcitEhttp://ecmdb.ca/proteins/P0A9I1.xmlPhosphate acetyltransferaseP0A9M8PTA_ECOLIptahttp://ecmdb.ca/proteins/P0A9M8.xmlPyruvate formate-lyase 1-activating enzymeP0A9N4PFLA_ECOLIpflAhttp://ecmdb.ca/proteins/P0A9N4.xmlDihydrolipoyl dehydrogenaseP0A9P0DLDH_ECOLIlpdAhttp://ecmdb.ca/proteins/P0A9P0.xmlAcetyl-coenzyme A carboxylase carboxyl transferase subunit betaP0A9Q5ACCD_ECOLIaccDhttp://ecmdb.ca/proteins/P0A9Q5.xmlAldehyde-alcohol dehydrogenaseP0A9Q7ADHE_ECOLIadhEhttp://ecmdb.ca/proteins/P0A9Q7.xml2-amino-3-ketobutyrate coenzyme A ligaseP0AB77KBL_ECOLIkblhttp://ecmdb.ca/proteins/P0AB77.xmlAcetyl-coenzyme A carboxylase carboxyl transferase subunit alphaP0ABD5ACCA_ECOLIaccAhttp://ecmdb.ca/proteins/P0ABD5.xmlBiotin carboxyl carrier protein of acetyl-CoA carboxylaseP0ABD8BCCP_ECOLIaccBhttp://ecmdb.ca/proteins/P0ABD8.xmlCitrate synthaseP0ABH7CISY_ECOLIgltAhttp://ecmdb.ca/proteins/P0ABH7.xmlBifunctional protein glmUP0ACC7GLMU_ECOLIglmUhttp://ecmdb.ca/proteins/P0ACC7.xmlPyruvate dehydrogenase E1 componentP0AFG8ODP1_ECOLIaceEhttp://ecmdb.ca/proteins/P0AFG8.xmlBeta-ketoadipyl-CoA thiolaseP0C7L2PAAJ_ECOLIpaaJhttp://ecmdb.ca/proteins/P0C7L2.xml3-ketoacyl-CoA thiolaseP21151FADA_ECOLIfadAhttp://ecmdb.ca/proteins/P21151.xmlBiotin carboxylaseP24182ACCC_ECOLIaccChttp://ecmdb.ca/proteins/P24182.xmlAcetyl-coenzyme A synthetaseP27550ACSA_ECOLIacshttp://ecmdb.ca/proteins/P27550.xmlFormate acetyltransferase 2P32674PFLD_ECOLIpflDhttp://ecmdb.ca/proteins/P32674.xmlPyruvate formate-lyase 2-activating enzymeP32675PFLC_ECOLIpflChttp://ecmdb.ca/proteins/P32675.xmlMalate synthase GP37330MASZ_ECOLIglcBhttp://ecmdb.ca/proteins/P37330.xmlKeto-acid formate acetyltransferaseP42632TDCE_ECOLItdcEhttp://ecmdb.ca/proteins/P42632.xmlProbable pyruvate-flavodoxin oxidoreductaseP52647NIFJ_ECOLIydbKhttp://ecmdb.ca/proteins/P52647.xmlCitrate lyase alpha chainP75726CILA_ECOLIcitFhttp://ecmdb.ca/proteins/P75726.xmlPutative formate acetyltransferase 3P75793PFLF_ECOLIybiWhttp://ecmdb.ca/proteins/P75793.xmlAcetate CoA-transferase subunit alphaP76458ATOD_ECOLIatoDhttp://ecmdb.ca/proteins/P76458.xmlAcetate CoA-transferase subunit betaP76459ATOA_ECOLIatoAhttp://ecmdb.ca/proteins/P76459.xmlAcetyl-CoA acetyltransferaseP76461ATOB_ECOLIatoBhttp://ecmdb.ca/proteins/P76461.xml3-ketoacyl-CoA thiolase_P76503FADI_ECOLIfadIhttp://ecmdb.ca/proteins/P76503.xmlProbable enoyl-CoA hydratase paaGP77467PAAG_ECOLIpaaGhttp://ecmdb.ca/proteins/P77467.xmlN-hydroxyarylamine O-acetyltransferaseP77567NHOA_ECOLInhoAhttp://ecmdb.ca/proteins/P77567.xmlAcetaldehyde dehydrogenaseP77580ACDH_ECOLImhpFhttp://ecmdb.ca/proteins/P77580.xmlMaltose O-acetyltransferaseP77791MAA_ECOLImaahttp://ecmdb.ca/proteins/P77791.xmlProbable acetyl-CoA acetyltransferaseQ46939YQEF_ECOLIyqeFhttp://ecmdb.ca/proteins/Q46939.xmlPutative lipopolysaccharide biosynthesis O-acetyl transferase wbbJP37750WBBJ_ECOLIwbbJhttp://ecmdb.ca/proteins/P37750.xmlLipopolysaccharide biosynthesis protein rffCP27832RFFC_ECOLIrffChttp://ecmdb.ca/proteins/P27832.xmlFlavodoxin-2P0ABY4FLAW_ECOLIfldBhttp://ecmdb.ca/proteins/P0ABY4.xmlFlavodoxin-1P61949FLAV_ECOLIfldAhttp://ecmdb.ca/proteins/P61949.xmlEthanolamine utilization protein eutDP77218EUTD_ECOLIeutDhttp://ecmdb.ca/proteins/P77218.xmlAutonomous glycyl radical cofactorP68066GRCA_ECOLIgrcAhttp://ecmdb.ca/proteins/P68066.xmlAcyl carrier proteinP0A6A8ACP_ECOLIacpPhttp://ecmdb.ca/proteins/P0A6A8.xmlaldehyde oxidoreductase, ethanolamine utilization proteinP77445eutEhttp://ecmdb.ca/proteins/P77445.xmlpredicted acyltransferase with acyl-CoA N-acyltransferase domainP76112yncAhttp://ecmdb.ca/proteins/P76112.xmlUncharacterized protein ypfIP76562YPFI_ECOLIypfIhttp://ecmdb.ca/proteins/P76562.xmlCoenzyme A + 2 flavodoxin semi oxidized + Pyruvic acid <> Acetyl-CoA + Carbon dioxide +2 Flavodoxin reduced + Hydrogen ionCoenzyme A + Pyruvic acid <> Acetyl-CoA + Formic acidR00212PYRUVFORMLY-RXNCoenzyme A + NAD + Pyruvic acid > Acetyl-CoA + Carbon dioxide + NADHPYRUVDEH-RXNAcetyl-CoA + Adenosine triphosphate + Hydrogen carbonate <> ADP + Hydrogen ion + Malonyl-CoA + PhosphateR00742ACETYL-COA-CARBOXYLTRANSFER-RXNAcetaldehyde + Coenzyme A + NAD <> Acetyl-CoA + Hydrogen ion + NADHR00228ACETALD-DEHYDROG-RXNacyl carrier protein + Acetyl-CoA <> Acetyl-ACP + Coenzyme A3-Oxo-5,6-dehydrosuberyl-CoA + Coenzyme A <> 5-Carboxy-2-pentenoyl-CoA + Acetyl-CoAR09839Acetoacetic acid + Acetyl-CoA > Acetoacetyl-CoA + Acetic acidR01359ACETOACETYL-COA-TRANSFER-RXNAcetyl-CoA + Butyric acid > Acetic acid + Butyryl-CoAAcetyl-CoA + Hexanoate (N-C6:0) > Acetic acid + Hexanoyl-CoA2 Acetyl-CoA <> Acetoacetyl-CoA + Coenzyme AR00238ACETYL-COA-ACETYLTRANSFER-RXNAcetyl-CoA + Phosphate <> Acetylphosphate + Coenzyme AR00230PHOSACETYLTRANS-RXNAcetyl-CoA + Octanoyl-CoA <> 3-Oxodecanoyl-CoA + Coenzyme AR03778Acetyl-CoA + Butyryl-CoA <> 3-Oxohexanoyl-CoA + Coenzyme AAcetyl-CoA + Tetradecanoyl-CoA <> 3-Oxohexadecanoyl-CoA + Coenzyme AR03991Acetyl-CoA + Hexanoyl-CoA <> 3-Oxooctanoyl-CoA + Coenzyme AR04747Acetyl-CoA + Lauroyl-CoA <> 3-Oxotetradecanoyl-CoA + Coenzyme AR03858Acetyl-CoA + Decanoyl-CoA (N-C10:0CoA) <> 3-Oxododecanoyl-CoA + Coenzyme AR047423-Oxooctadecanoyl-CoA + Coenzyme A <> Acetyl-CoA + Palmityl-CoAAcetyl-CoA + Glyoxylic acid + Water <> Coenzyme A + Hydrogen ion + L-Malic acidR00472MALSYN-RXNalpha-Ketoisovaleric acid + Acetyl-CoA + Water + a-Ketoisovaleric acid <> 2-Isopropylmalic acid + Coenzyme A + Hydrogen ionR01213Acetyl-CoA + D-Glucose <> 6-Acetyl-D-glucose + Coenzyme AAcetyl-CoA + D-Maltose <> Acetyl-maltose + Coenzyme AMALTACETYLTRAN-RXNAcetyl-CoA + Water + Oxalacetic acid <> Citric acid + Coenzyme A + Hydrogen ionR00351CITSYN-RXNAcetyl-CoA + Hydrogen ion + Malonyl-[acyl-carrier protein] > Acetoacetyl-ACP + Carbon dioxide + Coenzyme ACoenzyme A + 3-Oxoadipyl-CoA <> Acetyl-CoA + Succinyl-CoAR00829RXN-3641Acetyl-CoA + 2-Aminobenzoic acid > N-Acetylanthranilate + Coenzyme AAcetyl-CoA + Spermidine > N1-Acetylspermidine + Coenzyme A + Hydrogen ionSPERMACTRAN-RXNAcetyl-CoA + Spermidine > Coenzyme A + Hydrogen ion + N8-AcetylspermidineAcetyl-CoA + Rhamanosyl-N-acetylglucosamyl-undecaprenyl diphosphate > O-Acetyl-rhamanosyl-N-acetylglucosamyl-undecaprenyl diphosphate + Coenzyme AAcetyl-CoA + L-Glutamate <> N-Acetyl-L-alanine + Coenzyme A + Hydrogen ion + N-Acetylglutamic acidR00259Acetyl-CoA + L-Serine <> O-Acetylserine + Coenzyme AR00586SERINE-O-ACETTRAN-RXNAcetyl-CoA + Glycine <> L-2-Amino-3-oxobutanoic acid + Coenzyme AR00371AKBLIG-RXNAcetyl-CoA + N-Acetyl-glucosamine 1-phosphate > N-Acetyl-glucosamine 1-phosphate + Coenzyme A + Hydrogen ionAcetyl-CoA + dTDP-D-Fucosamine > Coenzyme A + dTDP-4-Acetamido-4,6-dideoxy-D-galactose + Hydrogen ionTDPFUCACTRANS-RXNAcetic acid + Adenosine triphosphate + Coenzyme A <> Acetyl-CoA + Adenosine monophosphate + PyrophosphateR00235ACETATE--COA-LIGASE-RXNAcetyl-CoA + Formic acid <> Coenzyme A + Pyruvic acidR00212Acetyl adenylate + Coenzyme A <> Adenosine monophosphate + Acetyl-CoAR00236Acetyl-CoA + L-Glutamate <> Coenzyme A + N-Acetyl-L-alanineR00259Citric acid + Coenzyme A <> Acetyl-CoA + Water + Oxalacetic acidR00351L-Malic acid + Coenzyme A <> Acetyl-CoA + Water + Glyoxylic acidR00472Adenosine triphosphate + Acetyl-CoA + Hydrogen carbonate <> ADP + Phosphate + Malonyl-CoAR00742Succinyl-CoA + Acetyl-CoA <> Coenzyme A + 3-Oxoadipyl-CoAR00829Propionyl-CoA + Acetyl-CoA <> Coenzyme A + 2-Methylacetoacetyl-CoAR00927Acetyl-CoA + Putrescine <> Coenzyme A + N-AcetylputrescineR01154Acetyl-CoA + Butanoyl-CoA <> Coenzyme A + 3-Oxohexanoyl-CoAR01177Butanoyl-CoA + Acetic acid <> Butyric acid + Acetyl-CoAR011792 Reduced ferredoxin + Acetyl-CoA + Carbon dioxide + 2 Hydrogen ion + Oxidized ferredoxin <>2 Oxidized ferredoxin + Pyruvic acid + Coenzyme A + Reduced ferredoxinR011962-Isopropylmalic acid + Coenzyme A <> Acetyl-CoA + alpha-Ketoisovaleric acid + WaterR01213Acetoacetyl-CoA + Acetic acid <> Acetoacetic acid + Acetyl-CoAR01359Acetyl-CoA + Acyl-carrier protein <> Coenzyme A + Acetyl-[acyl-carrier protein]R01624Acetyl-CoA + Enzyme N6-(dihydrolipoyl)lysine + Enzyme N6-(dihydrolipoyl)lysine <> Coenzyme A + [Dihydrolipoyllysine-residue acetyltransferase] S-acetyldihydrolipoyllysineR02569Acetyl-CoA + Carboxybiotin-carboxyl-carrier protein <> Malonyl-CoA + Holo-[carboxylase]R04386Acetyl-CoA + alpha-D-Glucosamine 1-phosphate <> Coenzyme A + Glucosamine-1PR05332Benzoyl acetyl-CoA + Coenzyme A <> Benzoyl-CoA + Acetyl-CoAR055063-Hydroxy-5-oxohexanoate + Acetyl-CoA <> 3-Hydroxy-5-oxohexanoyl-CoA + Acetic acidR07832OPC6-CoA + Acetyl-CoA <> Coenzyme A + 3-Oxo-OPC8-CoAR07891OPC4-CoA + Acetyl-CoA <> Coenzyme A + 3-Oxo-OPC6-CoAR07895(+)-7-Isojasmonic acid CoA + Acetyl-CoA <> Coenzyme A + 3-Oxo-OPC4-CoAR078997-Methyl-3-oxo-6-octenoyl-CoA + Coenzyme A <> 5-Methylhex-4-enoyl-CoA + Acetyl-CoAR080915-Methyl-3-oxo-4-hexenoyl-CoA + Coenzyme A <> 3-Methylcrotonyl-CoA + Acetyl-CoAR08095Demethylphosphinothricin + Acetyl-CoA <> N-Acetyldemethylphosphinothricin + Coenzyme AR08871Acetyl-CoA + + Glufosinate <> Coenzyme A + N-Acetylphosphinothricin + N-AcetylphosphinothricinR08938L-Methionine + Acetyl-CoA N-α-acetyl-L-methionine + Coenzyme ARXN0-6948alpha-Ketoisovaleric acid + Acetyl-CoA + Water > Hydrogen ion + 3-Carboxy-3-hydroxy-isocaproate + Coenzyme A2-ISOPROPYLMALATESYN-RXNan <i>N</i>-hydroxy-arylamine + Acetyl-CoA <> an <i>N</i>-acetoxyarylamine + Coenzyme A2.3.1.118-RXNGlucosamine-1P + Acetyl-CoA > Hydrogen ion + <i>N</i>-acetyl-α-D-glucosamine 1-phosphate + Coenzyme A2.3.1.157-RXNa 2,3,4-saturated fatty acyl CoA + Acetic acid <> a fatty acid + Acetyl-CoAACECOATRANS-RXNCoenzyme A + Acetic acid + Adenosine triphosphate > Acetyl-CoA + Pyrophosphate + Adenosine monophosphateR00235ACETATE--COA-LIGASE-RXNAcetoacetic acid + Acetyl-CoA <> Acetoacetyl-CoA + Acetic acidACETOACETYL-COA-TRANSFER-RXNAcetyl-CoA <> Acetoacetyl-CoA + Coenzyme AACETYL-COA-ACETYLTRANSFER-RXNAdenosine triphosphate + Acetyl-CoA + Hydrogen carbonate > Hydrogen ion + Malonyl-CoA + Phosphate + ADPACETYL-COA-CARBOXYLTRANSFER-RXNGlycine + Acetyl-CoA <> Hydrogen ion + L-2-Amino-3-oxobutanoic acid + Coenzyme AAKBLIG-RXNan aliphatic α,ω-diamine + Acetyl-CoA <> an aliphatic <i>N</i>-acetyl-diamine + Coenzyme A + Hydrogen ionDIAMACTRANS-RXNAcetyl-CoA + Dihydrolipoamide Coenzyme A + S-AcetyldihydrolipoamideDIHYDLIPACETRANS-RXNa β-D-galactoside + Acetyl-CoA <> a 6-acetyl-β-D-galactoside + Coenzyme AGALACTOACETYLTRAN-RXNa 2,3,4-saturated fatty acyl CoA + Acetyl-CoA < a 3-oxoacyl-CoA + Coenzyme AKETOACYLCOATHIOL-RXNAcetyl-CoA + Water + Glyoxylic acid > Hydrogen ion + L-Malic acid + Coenzyme AMALSYN-RXNL-Glutamate + Acetyl-CoA <> Hydrogen ion + <i>N</i>-acetyl-L-glutamate + Coenzyme AN-ACETYLTRANSFER-RXNPyruvic acid + Coenzyme A + NAD > Acetyl-CoA + Carbon dioxide + NADHPYRUVDEH-RXNSuccinyl-CoA + Acetyl-CoA < 3-Oxoadipyl-CoA + Coenzyme ARXN-36413-Oxo-5,6-dehydrosuberyl-CoA + Coenzyme A > 2,3-dehydroadipyl-CoA + Acetyl-CoARXN0-6512Acetyl-CoA + Spermidine <> N1-Acetylspermidine + Hydrogen ion + Coenzyme ASPERMACTRAN-RXNAdenosine triphosphate + Acetyl-CoA + Carbonic acid > ADP + Inorganic phosphate + Malonyl-CoAAcetaldehyde + CoA + NAD > Acetyl-CoA + NADHAdenosine triphosphate + Acetic acid + CoA > Adenosine monophosphate + Pyrophosphate + Acetyl-CoAAcetyl-CoA + L-Glutamate > CoA + N-acetyl-L-glutamateAcetyl-CoA + an alkane-alpha,omega-diamine > CoA + an N-acetyldiamineAcyl-CoA + Acetic acid > a fatty acid anion + Acetyl-CoA2 Acetyl-CoA > CoA + Acetoacetyl-CoAAcetyl-CoA + Citric acid > Acetic acid + (3S)-Citryl-CoAAcetyl-CoA + Water + Oxalacetic acid > Citric acid + CoA(3S)-Citryl-CoA > Acetyl-CoA + Oxalacetic acidAcetyl-CoA + L-Serine > CoA + O-AcetylserineAcetyl-CoA + malonyl-[acyl-carrier-protein] > acetoacetyl-[acyl-carrier-protein] + CoA + Carbon dioxideAcyl-CoA + Acetyl-CoA > CoA + 3-oxoacyl-CoAAcetyl-CoA + alpha-D-Glucosamine 1-phosphate > CoA + N-acetyl-alpha-D-glucosamine 1-phosphateAcetyl-CoA + Glycine > CoA + L-2-Amino-3-oxobutanoic acidAcetyl-CoA + a-Ketoisovaleric acid + Water > 2-Isopropylmalic acid + CoAAcetyl-CoA + D-Maltose > CoA + Acetyl-maltoseAcetyl-CoA + Water + Glyoxylic acid > L-Malic acid + CoAAcetyl-CoA + an N-hydroxyarylamine > CoA + an N-acetoxyarylaminePyruvic acid + CoA + oxidized flavodoxin > Acetyl-CoA + Carbon dioxide + reduced flavodoxinAcetyl-CoA + enzyme N(6)-(dihydrolipoyl)lysine > CoA + enzyme N(6)-(S-acetyldihydrolipoyl)lysineSuccinyl-CoA + Acetyl-CoA > CoA + 3-Oxoadipyl-CoA2,3-dehydroadipyl-CoA + Acetyl-CoA > CoA + 3-Oxo-5,6-dehydrosuberyl-CoAAcetyl-CoA + Formic acid > CoA + Pyruvic acidAcetyl-CoA + Inorganic phosphate > CoA + AcetylphosphateAcetyl-CoA + ribosomal-protein L-alanine > CoA + ribosomal-protein N-acetyl-L-alanineAcetyl-CoA + ribosomal-protein L-serine > CoA + ribosomal-protein N-acetyl-L-serineAcetyl-CoA + a beta-D-galactoside > CoA + a 6-acetyl-beta-D-galactoside(Elongator tRNA(Met))-cytidine(34) + Adenosine triphosphate + Acetyl-CoA > (elongator tRNA(Met))-N(4)-acetylcytidine(34) + ADP + Inorganic phosphate + CoAAcetyl-CoA + L-Methionine > CoA + N-Acetyl-L-methionineAcetyl-CoA + Ribosomal-protein L-alanine <> Coenzyme A + Ribosomal-protein N-acetyl-L-alanineR04316 Acetyl-CoA + N-Hydroxyarylamine <> Coenzyme A + N-AcetoxyarylamineR08386 Acetyl-CoA + Alkane-alpha,omega-diamine <> Coenzyme A + N-AcetyldiamineR03910 Acyl-CoA + Acetic acid <> Fatty acid anion + Acetyl-CoAR00393 Acetyl-CoA + dTDP-D-Fucosamine <> Coenzyme A + dTDP-4-acetamido-4,6-dideoxy-alpha-D-galactoseR10142 Acetyl-CoA + beta-D-Galactoside <> Coenzyme A + 6-Acetyl-beta-D-galactosideR02616 Acetyl-CoA + Citric acid <> Acetic acid + (3S)-Citryl-CoAR01323 (3S)-Citryl-CoA <> Acetyl-CoA + Oxalacetic acidR00354 Acetyl-CoA + Oxalic acid <> Acetic acid + Oxalyl-CoAR10614 Acyl-CoA + Acetyl-CoA <> Coenzyme A + 3-Oxoacyl-CoAR00391 Acetyl-CoA + Malonyl-[acyl-carrier protein] <> Acetoacetyl-[acp] + Coenzyme A + Carbon dioxideR10707 Acetyl-CoA + 3-Hydroxy-5-oxohexanoate > Acetic acid + 3-Hydroxy-5-oxohexanoyl-CoA + 3-Hydroxy-5-oxohexanoyl-CoAPW_R002438a 3-oxoacyl-CoA + Coenzyme A > Acetyl-CoA + a 2,3,4-saturated fatty acyl CoA PW_R002909Acetoacetyl-CoA + Coenzyme A + Acetoacetyl-CoA > Acetyl-CoA + Succinyl-CoA + Succinyl-CoAPW_R0037703-Oxodecanoyl-CoA + Coenzyme A > Acetyl-CoA + Lauroyl-CoAPW_R0037753-Oxohexanoyl-CoA + Coenzyme A > Acetyl-CoA + Octanoyl-CoA + Octanoyl-CoAPW_R0037803-Oxododecanoyl-CoA + Coenzyme A > Acetyl-CoA + Tetradecanoyl-CoAPW_R0037853-Oxotetradecanoyl-CoA + Coenzyme A > Acetyl-CoA + Palmityl-CoAPW_R0037903-Oxooctanoyl-CoA + Coenzyme A > Acetyl-CoA + Decanoyl-CoA (n-C10:0CoA) + Decanoyl-CoA (N-C10:0CoA)PW_R0037953-Oxohexadecanoyl-CoA + Coenzyme A > Acetyl-CoA + Stearoyl-CoA + Stearoyl-CoAPW_R0038003-Oxooctadecanoyl-CoA + Coenzyme A + 3-Oxooctadecanoyl-CoA > Acetyl-CoA + Stearoyl-CoA + Stearoyl-CoAPW_R003805Coenzyme A + 7-Methyl-3-oxo-6-octenoyl-CoA > Acetyl-CoA + 5-Methylhex-4-enoyl-CoAPW_R002503Coenzyme A + 5-Methyl-3-oxo-4-hexenoyl-CoA > Acetyl-CoA + 3-Methylcrotonyl-CoAPW_R0025072 Acetyl-CoA <> Acetoacetyl-CoA + Coenzyme A + Acetoacetyl-CoAPW_R002482Acetyl-CoA + Water + Oxalacetic acid > Citric acid + Coenzyme APW_R002575Oxalacetic acid + Water + Acetyl-CoA > Citric acid + Coenzyme A + Hydrogen ionPW_R002588L-Glutamic acid + Acetyl-CoA + L-Glutamate > Coenzyme A + Hydrogen ion + N-Acetylglutamic acid + N-Acetylglutamic acidPW_R002670Tetradecanoyl-CoA + Acetyl-CoA <> 3-Oxohexadecanoyl-CoA + Coenzyme APW_R002732Lauroyl-CoA + Acetyl-CoA > 3-Oxotetradecanoyl-CoA + Coenzyme APW_R002736Decanoyl-CoA (n-C10:0CoA) + Acetyl-CoA + Decanoyl-CoA (N-C10:0CoA) > 3-Oxododecanoyl-CoA + Coenzyme APW_R002738Octanoyl-CoA + Acetyl-CoA + Octanoyl-CoA <> 3-Oxodecanoyl-CoA + Coenzyme APW_R002741Acetyl-CoA + Hexanyl-CoA <> 3-Oxooctanoyl-CoA + Coenzyme APW_R002744Acetyl-CoA + Butyryl-CoA + Butyryl-CoA > 3-Oxohexanoyl-CoA + Coenzyme APW_R002748Acetyl-CoA + Hydrogen carbonate + Adenosine triphosphate > Adenosine diphosphate + Phosphate + Hydrogen ion + Malonyl-CoA + ADP + Malonyl-CoAPW_R002783a malonyl-[acp] + Hydrogen ion + Acetyl-CoA > Carbon dioxide + Coenzyme A + acetoacetyl-[acp] PW_R002785Acetyl-CoA + a holo-[acyl-carrier protein] > Coenzyme A + an acetyl-[acp]PW_R003386L-Serine + Acetyl-CoA + L-Serine > Coenzyme A + O-AcetylserinePW_R0028463-Methyl-2-oxovaleric acid + Water + Acetyl-CoA + 3-Methyl-2-oxovaleric acid > Coenzyme A + Hydrogen ion + 2-Isopropylmalic acidPW_R002875Glyoxylic acid + Water + Acetyl-CoA > Coenzyme A + Hydrogen ion + L-Malic acid + L-Malic acidPW_R0029803-hydroxy-2,4-pentanedione 5-phosphate + Coenzyme A + 3-hydroxy-2,4-pentanedione 5-phosphate > Acetyl-CoA + Dihydroxyacetone phosphatePW_R003073Glucosamine-1P + Acetyl-CoA + Glucosamine-1P > N-Acetyl-glucosamine 1-phosphate + Coenzyme A + Hydrogen ion + N-Acetyl-glucosamine 1-phosphatePW_R003313a malonyl-[acp] + Hydrogen ion + Acetyl-CoA > Carbon dioxide + Coenzyme A + acetoacetyl-[acp] PW_R003385Acetyl-CoA + dTDP-thomosamine > TDP-Fuc4NAc + Coenzyme A + Hydrogen ionPW_R003703Acetyl-CoA + L-Glutamic acid + L-Glutamate <> N-Acetyl-L-alanine + Coenzyme A + Hydrogen ion + N-Acetylglutamic acid + N-Acetyl-L-alanine + N-Acetylglutamic acidPW_R005149Acetaldehyde + Coenzyme A + NAD > Hydrogen ion + NADH + Acetyl-CoAPW_R005163L-2-Amino-3-oxobutanoic acid + Coenzyme A > Acetyl-CoA + GlycinePW_R005169Acetyl-CoA + Dihydrolipoamide + Dihydrolipoamide <> Coenzyme A + S-AcetyldihydrolipoamidePW_R0051723-Oxo-5,6-dehydrosuberyl-CoA + Coenzyme A > Acetyl-CoA + 2,3-didehydroadipyl-CoAPW_R0059233-Oxoadipyl-CoA + Coenzyme A > Acetyl-CoA + Succinyl-CoAPW_R005926a [pyruvate dehydrogenase E2 protein] N6-S-acetyldihydrolipoyl-L-lysine + Coenzyme A > a [pyruvate dehydrogenase E2 protein] N6-dihydrolipoyl-L-lysine + Acetyl-CoAPW_R006083a biotinylated [BCCP dimer] + Hydrogen ion + Phosphate + ADP + Malonyl-CoA < Water + Acetyl-CoA + Adenosine triphosphate + carboxylated-biotinylated [BCCP dimer]PW_R006043Acetyl-CoA + Phosphate > Coenzyme A + AcetylphosphatePW_R006095Acetic acid + Adenosine triphosphate + Coenzyme A > Pyrophosphate + Adenosine monophosphate + Acetyl-CoAPW_R006099Acetoacetyl-CoA > Coenzyme A + Acetyl-CoAPW_R0061013 3-Oxo-5,6-dehydrosuberyl-CoA + Coenzyme A <>5 5-Carboxy-2-pentenoyl-CoA + Acetyl-CoAAcetyl-CoA + Glyoxylic acid + Water <> Coenzyme A + Hydrogen ion + L-Malic acidAcetyl-CoA + Phosphate <> Acetylphosphate + Coenzyme AAcetic acid + Adenosine triphosphate + Coenzyme A <> Acetyl-CoA + Adenosine monophosphate + PyrophosphateAcetyl-CoA + Water + Oxalacetic acid <> Citric acid + Coenzyme A + Hydrogen ionAcetyl-CoA + Ribosomal-protein L-alanine <> Coenzyme A + Ribosomal-protein N-acetyl-L-alanine2 Acetyl-CoA <> Acetoacetyl-CoA + Coenzyme AAcetyl-CoA + Adenosine triphosphate + Hydrogen carbonate <> ADP + Hydrogen ion + Malonyl-CoA + Phosphatealpha-Ketoisovaleric acid + Acetyl-CoA + Water + a-Ketoisovaleric acid <>2 2-Isopropylmalic acid + Coenzyme A + Hydrogen ionAcetyl-CoA + L-Serine <> O-Acetylserine + Coenzyme AAcetyl-CoA + L-Glutamate <> N-Acetyl-L-alanine + Coenzyme A + Hydrogen ion + N-Acetylglutamic acidAcetyl-CoA + alpha-D-Glucosamine 1-phosphate <> Coenzyme A + Glucosamine-1P3 3-Oxo-5,6-dehydrosuberyl-CoA + Coenzyme A <>5 5-Carboxy-2-pentenoyl-CoA + Acetyl-CoAAcetic acid + Adenosine triphosphate + Coenzyme A <> Acetyl-CoA + Adenosine monophosphate + PyrophosphateAcetyl-CoA + Water + Oxalacetic acid <> Citric acid + Coenzyme A + Hydrogen ion2 Acetyl-CoA <> Acetoacetyl-CoA + Coenzyme AAcetyl-CoA + Adenosine triphosphate + Hydrogen carbonate <> ADP + Hydrogen ion + Malonyl-CoA + PhosphateAcetyl-CoA + Adenosine triphosphate + Hydrogen carbonate <> ADP + Hydrogen ion + Malonyl-CoA + PhosphateAcetyl-CoA + Ribosomal-protein L-alanine <> Coenzyme A + Ribosomal-protein N-acetyl-L-alanineGutnick minimal complete medium (4.7 g/L KH2PO4; 13.5 g/L K2HPO4; 1 g/L K2SO4; 0.1 g/L MgSO4-7H2O; 10 mM NH4Cl) with 4 g/L glucoseShake flask and filter culture606.0uM0.037 oCK12 NCM3722Mid-Log Phase24240000Bennett, B. D., Kimball, E. H., Gao, M., Osterhout, R., Van Dien, S. J., Rabinowitz, J. D. (2009). "Absolute metabolite concentrations and implied enzyme active site occupancy in Escherichia coli." Nat Chem Biol 5:593-599.19561621Gutnick minimal complete medium (4.7 g/L KH2PO4; 13.5 g/L K2HPO4; 1 g/L K2SO4; 0.1 g/L MgSO4-7H2O; 10 mM NH4Cl) with 4 g/L glycerolShake flask and filter culture734.0uM0.037 oCK12 NCM3722Mid-Log Phase29360000Bennett, B. D., Kimball, E. H., Gao, M., Osterhout, R., Van Dien, S. J., Rabinowitz, J. D. (2009). "Absolute metabolite concentrations and implied enzyme active site occupancy in Escherichia coli." Nat Chem Biol 5:593-599.19561621Gutnick minimal complete medium (4.7 g/L KH2PO4; 13.5 g/L K2HPO4; 1 g/L K2SO4; 0.1 g/L MgSO4-7H2O; 10 mM NH4Cl) with 4 g/L acetateShake flask and filter culture628.0uM0.037 oCK12 NCM3722Mid-Log Phase25120000Bennett, B. D., Kimball, E. H., Gao, M., Osterhout, R., Van Dien, S. J., Rabinowitz, J. D. (2009). "Absolute metabolite concentrations and implied enzyme active site occupancy in Escherichia coli." Nat Chem Biol 5:593-599.195616214.0 g/L Na2SO4; 5.36 g/L (NH4)2SO4; 1.0 g/L NH4Cl; 7.3 g/L K2HPO4; 1.8 g/L NaH2PO4 H2O; 12.0 g/L (NH4)2-H-citrate; 4.0 mL/L MgSO4 (1 M); 6.0 mL/L trace element solution; 0.02 g/L thiamine, 20 g/L glucoseBioreactor, pH controlled, aerated63.4uM0.037 oCW3110Stationary Phase2536000Park, C., Park, C., Lee, Y., Lee, S.Y., Oh, H.B., Lee, J. (2011) Determination of the Intracellular Concentration of Metabolites in Escherichia coli Collected during the Exponential and Stationary Growth Phases using Liquid Chromatography-Mass Spectrometry. Bull Korean Chem. Soc. 32: 524-530.0.2 g/L NH4Cl, 2.0 g/L (NH4)2SO4, 3.25 g/L KH2PO4, 2.5 g/L K2HPO4, 1.5 g/L NaH2PO4, 0.5 g/L MgSO4; trace substances: 10 mg/L CaCl2, 0.5 mg/L ZnSO4, 0.25 mg/L CuCl2, 0.25 mg/L MnSO4, 0.175 mg/L CoCl2, 0.125 mg/L H3BO3, 2.5 mg/L AlCl3, 0.5 mg/L Na2MoO4, 10Bioreactor, pH controlled, aerated, dilution rate=0.125 L/h300.0uM19.037 oCK12Stationary Phase, glucose limited120000076000Buchholz, A., Takors, R., Wandrey, C. (2001). "Quantification of intracellular metabolites in Escherichia coli K12 using liquid chromatographic-electrospray ionization tandem mass spectrometric techniques." Anal Biochem 295:129-137.11488613M9 Minimal Media, 4 g/L GlucoseBioreactor, pH controlled, O2 controlled, dilution rate: 0.2/h130.0uM40.037 oCBW25113Mid-Log Phase520000160000Peng, L., Arauzo-Bravo, M. J., Shimizu, K. (2004). "Metabolic flux analysis for a ppc mutant Escherichia coli based on 13C-labelling experiments together with enzyme activity assays and intracellular metabolite measurements." FEMS Microbiol Lett 235:17-23.151582574.0 g/L Na2SO4; 5.36 g/L (NH4)2SO4; 1.0 g/L NH4Cl; 7.3 g/L K2HPO4; 1.8 g/L NaH2PO4 H2O; 12.0 g/L (NH4)2-H-citrate; 4.0 mL/L MgSO4 (1 M); 6.0 mL/L trace element solution; 0.02 g/L thiamine, 20 g/L glucoseBioreactor, pH controlled, aerated, dilution rate=0.125 L/h8.3uM0.037 oCW3110Mid Log Phase332000Park, C., Park, C., Lee, Y., Lee, S.Y., Oh, H.B., Lee, J. (2011) Determination of the Intracellular Concentration of Metabolites in Escherichia coli Collected during the Exponential and Stationary Growth Phases using Liquid Chromatography-Mass Spectrometry. Bull Korean Chem. Soc. 32: 524-530.