Pyruvate dehydrogenase explained

pyruvate dehydrogenase (acetyl-transferring)
Ec Number:1.2.4.1
Cas Number:9014-20-4
Go Code:0004739

Pyruvate dehydrogenase is an enzyme that catalyzes the reaction of pyruvate and a lipoamide to give the acetylated dihydrolipoamide and carbon dioxide. The conversion requires the coenzyme thiamine pyrophosphate.

Pyruvate dehydrogenase is usually encountered as a component, referred to as E1, of the pyruvate dehydrogenase complex (PDC). PDC consists of other enzymes, referred to as E2 and E3. Collectively E1-E3 transform pyruvate, NAD+, coenzyme A into acetyl-CoA, CO2, and NADH. The conversion is crucial because acetyl-CoA may then be used in the citric acid cycle to carry out cellular respiration.[1] To distinguish between this enzyme and the PDC, it is systematically called pyruvate dehydrogenase (acetyl-transferring).

Mechanism

The thiamine pyrophosphate (TPP) converts to an ylide by deprotonation. The ylide attack the ketone group of pyruvate. The resulting adduct decarboxylates. The resulting 1,3-dipole reductively acetylates lipoamide-E2.[1]

In terms of details, biochemical and structural data for E1 revealed a mechanism of activation of TPP coenzyme by forming the conserved hydrogen bond with glutamate residue (Glu59 in human E1) and by imposing a V-conformation that brings the N4’ atom of the aminopyrimidine to intramolecular hydrogen bonding with the thiazolium C2 atom. This unique combination of contacts and conformations of TPP leads to formation of the reactive C2-carbanion, eventually. After the cofactor TPP decarboxylates pyruvate, the acetyl portion becomes a hydroxyethyl derivative covalently attached to TPP.

Structure

E1 is a multimeric protein. Mammalian E1s, including human E1, are tetrameric, composed of two α- and two β- subunits. Some bacterial E1s, including E1 from Escherichia coli, are composed of two similar subunits, each being as large as the sum of molecular masses of α- and β- subunits.[2]

Active site

E1 has two catalytic sites, each providing thiamine pyrophosphate (TPP) and magnesium ion as cofactors. The α- subunit binds magnesium ion and pyrophosphate fragment while the β-subunit binds pyrimidine fragment of TPP, forming together a catalytic site at the interface of subunits.

The active site for pyruvate dehydrogenase (image created from) holds TPP through metal ligation to a magnesium ion (purple sphere) and through hydrogen bonding to amino acids. While over 20 amino acids can be found in the active site, amino acids Tyr 89, Arg 90, Gly 136, Val 138, Asp 167, Gly 168, Ala 169, Asn, 196, and His 263 actually participate in hydrogen bonding to hold TPP and pyruvate (not shown here) in the active site. The amino acids are shown as wires, and the TPP is in ball and stick form. The active site also aids in the transfer of the acyl on the TPP to a lipoamide waiting on E2.

Regulation

Phosphorylation of E1 by pyruvate dehydrogenase kinase (PDK) inactivates E1 and subsequently the entire complex. PDK is inhibited by dichloroacetic acid and pyruvate, resulting in a higher quantity of active, unphosphorylated PDH.[3] Phosphorylation is reversed by pyruvate dehydrogenase phosphatase, which is stimulated by insulin, PEP, and AMP, but competitively inhibited by ATP, NADH, and Acetyl-CoA.

Pathology

Pyruvate dehydrogenase is targeted by an autoantigen known as anti-mitochondrial antibodies (AMA), which results in progressive destruction of the small bile ducts of the liver, leading to primary biliary cirrhosis. These antibodies appear to recognize oxidized protein that has resulted from inflammatory immune responses. Some ofthese inflammatory responses could be related to gluten sensitivity as over 50% of the acute liver failure patients in one study exhibited a nonmitochondrial autoantibody against tissue transglutaminase.[4] Other mitochondrial autoantigensinclude oxoglutarate dehydrogenase and branched-chain alpha-keto acid dehydrogenase complex, which are antigens recognized by anti-mitochondrial antibodies.

Increased pyruvate dehydrogenase (PDH) activity can cause oncogene-induced cellular senescence, as well as promoting aging. Decreased activity of mitochondrial PDH with age has been shown in the heart as well as in certain regions of the brain (the striatum and brainstem).[5]

Pyruvate dehydrogenase (PDH) deficiency is a congenital degenerative metabolic disease resulting from a mutation of the pyruvate dehydrogenase complex (PDC) located on the X chromosome. While defects have been identified in all 3 enzymes of the complex, the E1-α subunit is predominantly the culprit. Malfunction of the citric acid cycle due to PDH deficiency deprives the body of energy and leads to an abnormal buildup of lactate. PDH deficiency is a common cause of lactic acidosis in newborns and often presents with severe lethargy, poor feeding, tachypnea, and cases of death have occurred.

Examples

Human proteins that possess pyruvate dehydrogenase activity include:

Pyruvate dehydrogenase (lipoamide) alpha 1
Hgncid:8806
Symbol:PDHA1
Altsymbols:PDHA
Entrezgene:5160
Omim:300502
Refseq:NM_000284
Uniprot:P08559
Ecnumber:1.2.4.1
Chromosome:X
Arm:p
Band:22.1
pyruvate dehydrogenase (lipoamide) alpha 2
Hgncid:8807
Symbol:PDHA2
Altsymbols:PDHAL
Entrezgene:5161
Omim:179061
Refseq:NM_005390
Uniprot:P29803
Ecnumber:1.2.4.1
Chromosome:4
Arm:q
Band:22
Locussupplementarydata:-q23
pyruvate dehydrogenase (lipoamide) beta
Hgncid:8808
Symbol:PDHB
Altsymbols:PHE1B
Entrezgene:5162
Omim:179060
Refseq:NM_000925
Uniprot:P11177
Ecnumber:1.2.4.1
Chromosome:3
Arm:p
Band:21.1
Locussupplementarydata:-14.2

Related enzymes

In bacteria, a form of pyruvate dehydrogenase (also called pyruvate oxidase, EC 1.2.2.2) exists that links the oxidation of pyruvate into acetate and carbon dioxide to the reduction of ferrocytochrome. In E. coli this enzyme is encoded by the pox B gene and the protein has a flavin cofactor.[6] This enzyme increases the efficiency of growth of E. coli under aerobic conditions.[7]

See also

References

External links

Notes and References

  1. Book: Biochemistry. J. M. Berg. J. L. Tymoczko, L. Stryer. Freeman. 6th. 2007. 978-0-7167-8724-2.
  2. Arjunan P, Nemeria N, Brunskill A, Chandrasekhar K, Sax M, Yan Y, Jordan F, Guest JR, Furey W . 6 . Structure of the pyruvate dehydrogenase multienzyme complex E1 component from Escherichia coli at 1.85 A resolution . Biochemistry . 41 . 16 . 5213–21 . April 2002 . 11955070 . 10.1021/bi0118557 .
  3. 26142699 . Functional response of the isolated, perfused normoxic heart to pyruvate dehydrogenase activation by dichloroacetate and pyruvate. . Jaimes . R 3rd . 10.1007/s00424-015-1717-1 . Jul 2015 . Pflügers Arch . 4701640 . 468 . 1 . 131–42.
  4. Leung PS, Rossaro L, Davis PA, etal . Antimitochondrial antibodies in acute liver failure: Implications for primary biliary cirrhosis . Hepatology. 46. 5. 1436–42. 2007 . 17657817 . 10.1002/hep.21828 . 3731127.
  5. Veech RL, Bradshaw PC, King MT . Ketone bodies mimic the life span extending properties of caloric restriction . . 69 . 5 . 305–314 . 2017 . 10.1002/iub.1627 . 28371201. 19807849 . free .
  6. Recny MA, Hager LP . Reconstitution of native Escherichia coli pyruvate oxidase from apoenzyme monomers and FAD . J. Biol. Chem. . 257 . 21 . 12878–86 . 1982 . 10.1016/S0021-9258(18)33597-X . 6752142 . free .
  7. Abdel-Hamid AM, Attwood MM, Guest JR . Pyruvate oxidase contributes to the aerobic growth efficiency of Escherichia coli . Microbiology . 147 . Pt 6 . 1483–98 . 2001 . 11390679 . 10.1099/00221287-147-6-1483 . free .